Please wait a moment until all data is loaded. This message will disappear when all data is loaded.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
ATP + H2O
ADP + phosphate
CTP + H2O
CDP + phosphate
GTP + H2O
GDP + phosphate
UTP + H2O
UDP + phosphate
additional information
?
-
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
ATP + H2O
ADP + phosphate
the enzyme protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively, and malate dehydrogenase from thermal inactivation at 80°C and 85°C. In the presence of ATP, the protective effects of alpha- and beta-subunits on citrate synthase from thermal aggregation and inactivation, and alcohol dehydrogenase from thermal aggregation, are more enhanced, whereas cooperation between chaperonins and ATP in protection activity on alcohol dehydrogenase and malate dehydrogenase (at 85°C) from thermal inactivation is not observed. Specifically, the presence of both alpha- and beta- subunits can effectively protect malate dehydrogenase from thermal inactivation at 80°C in an ATP-dependent manner
-
-
?
ATP + H2O
ADP + phosphate
the enzyme protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively, and malate dehydrogenase from thermal inactivation at 80°C and 85°C. In the presence of ATP, the protective effects of alpha- and beta-subunits on citrate synthase from thermal aggregation and inactivation, and alcohol dehydrogenase from thermal aggregation, are more enhanced, whereas cooperation between chaperonins and ATP in protection activity on alcohol dehydrogenase and malate dehydrogenase (at 85°C) from thermal inactivation is not observed. Specifically, the presence of both alpha- and beta- subunits can effectively protect malate dehydrogenase from thermal inactivation at 80°C in an ATP-dependent manner
-
-
?
ATP + H2O
ADP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
ATP + H2O
ADP + phosphate
-
in the presence of ATP, ApCpnB effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Specifically, the activity of malate dehydrogenase (MDH) at 85°C is greatly stabilized by the addition of ApCpnB and ATP
-
-
?
ATP + H2O
ADP + phosphate
P28769; Q940P8; Q84WV1; Q9LV21; O04450; Q9M888; Q9SF16; Q94K05
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
-
?
ATP + H2O
ADP + phosphate
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
-
-
-
?
ATP + H2O
ADP + phosphate
-
enzyme conformational changes upon ATP binding and throughout the ATPase cycle, structure-function relationship, overview
-
-
?
ATP + H2O
ADP + phosphate
P41988; P47207; Q9N4J8; P47208; P47209; P46550; Q9TZS5; Q9N358
-
-
-
?
ATP + H2O
ADP + phosphate
Q59QB7; Q59YC4; Q5AK16; Q59Z12; A0A1D8PMN9; Q59YH4; P47828
-
-
-
?
ATP + H2O
ADP + phosphate
Q59QB7; Q59YC4; Q5AK16; Q59Z12; A0A1D8PMN9; Q59YH4; P47828
-
-
-
?
ATP + H2O
ADP + phosphate
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
-
-
-
?
ATP + H2O
ADP + phosphate
Q55BM4; Q54ES9; Q54TH8; Q54CL2; Q54TD3; Q76NU3; Q54ER7; Q552J0
-
-
-
?
ATP + H2O
ADP + phosphate
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
-
-
-
?
ATP + H2O
ADP + phosphate
A0A1S6LQX4; A0A1S6LQU3; A0A1S6LQU0; A0A1S6LQU6; A0A1S6LQU1; A0A1S6LQU9; A0A1S6LQW6; A0A1S6LQW7
-
-
-
?
ATP + H2O
ADP + phosphate
-
the enzyme can protect halophilic proteins against denaturation under conditions of cellular hyposaline stress
-
-
?
ATP + H2O
ADP + phosphate
-
P45 forms complexes with halophilic malate dehydrogenase during its salt-dependent denaturation/renaturation and decreases the rate of deactivation of the enzyme in an ATP-dependent manner
-
-
?
ATP + H2O
ADP + phosphate
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
nucleotide binding structure and conformational changes, overview
-
-
?
ATP + H2O
ADP + phosphate
P11983; P80314; P80318; P80315; P80316; P80317; P80313; P42932
-
-
-
?
ATP + H2O
ADP + phosphate
Q8II43; O97247; Q8I5C4; C0H5I7; O97282; C6KST5; O77323; O96220
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
-
?
ATP + H2O
ADP + phosphate
the enzyme exists as a homooligomer in a double-ring structure, which captures non-native proteins in a central cavity to promote correct folding in an ATP-dependent manner. It protects the citrate synthase of a porcine heart from thermal aggregation at 45°C, and does the same on the isopropylmalate dehydrogenase of Thermus thermophilus HB8, at 90°C. It enhances the refolding of green fluorescent protein, which has been unfolded by low pH, in an ATP-dependent manner. It is not effective in the refolding of isopropylmalate dehydrogenase, the refolding efficiency is enhanced by the cooperation of the enzyme with Pyrococcus prefoldin
-
-
?
ATP + H2O
ADP + phosphate
activity of the enzyme as a molecular chaperone is examined using hyperthermophilic inorganic phosphatase from Pyrococcus horikoshii as a model substrate. The enzyme protected the inorganic phosphatase from thermal inactivation at 85°C and 110°C
-
-
?
ATP + H2O
ADP + phosphate
the enzyme exists as a homooligomer in a double-ring structure, which captures non-native proteins in a central cavity to promote correct folding in an ATP-dependent manner. It protects the citrate synthase of a porcine heart from thermal aggregation at 45°C, and does the same on the isopropylmalate dehydrogenase of Thermus thermophilus HB8, at 90°C. It enhances the refolding of green fluorescent protein, which has been unfolded by low pH, in an ATP-dependent manner. It is not effective in the refolding of isopropylmalate dehydrogenase, the refolding efficiency is enhanced by the cooperation of the enzyme with Pyrococcus prefoldin
-
-
?
ATP + H2O
ADP + phosphate
P28480; Q5XIM9; Q6P502; Q7TPB1; Q68FQ0; Q3MHS9; D4AC23; D4ACB8
-
-
-
?
ATP + H2O
ADP + phosphate
P28480; Q5XIM9; Q6P502; Q7TPB1; Q68FQ0; Q3MHS9; D4AC23; D4ACB8
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
-
?
ATP + H2O
ADP + phosphate
-
nucleotide binding structure and conformational changes, overview
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
-
-
-
?
ATP + H2O
ADP + phosphate
Thermochaetoides thermophila
-
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
the enzyme prevents thermal denaturation and enhances thermostability of Saccharomyces cerevisiae alcohol dehydrogenase. CpkB requires ATP for its chaperonin function at a low CpkB concentration. CpkB functions without ATP when present in excess. CpkB is useful for solubilizing insoluble proteins in vivo
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
ATP + H2O
ADP + phosphate
-
nucleotide binding structure and conformational changes, overview
-
-
?
ATP + H2O
ADP + phosphate
-
-
-
?
CTP + H2O
CDP + phosphate
-
-
-
?
CTP + H2O
CDP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
CTP + H2O
CDP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
GTP + H2O
GDP + phosphate
-
-
-
?
GTP + H2O
GDP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
GTP + H2O
GDP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
UTP + H2O
UDP + phosphate
-
-
-
?
UTP + H2O
UDP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
UTP + H2O
UDP + phosphate
addition of ApCpnA (subunit alpha) and ApCpnB (subunit beta) effectively protects citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. Purified enzyme hydrolyzes the nucleotides with the following efficacy (from highest to lowest): ATP > CTP > UTP > GTP
-
-
?
additional information
?
-
subunits ApCpnA and ApCpnB are able to hydrolyze not only ATP, but also CTP, GTP, and UTP, albeit with different efficacies. Addition of subunits ApCpnA and ApCpnB effectively protects porcine heart citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. In particular, the addition of ATP or CTP to subunits ApCpnA and ApCpnB results in the most effective prevention of thermal aggregation and inactivation of the substrate proteins
-
-
?
additional information
?
-
subunits ApCpnA and ApCpnB are able to hydrolyze not only ATP, but also CTP, GTP, and UTP, albeit with different efficacies. Addition of subunits ApCpnA and ApCpnB effectively protects porcine heart citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. In particular, the addition of ATP or CTP to subunits ApCpnA and ApCpnB results in the most effective prevention of thermal aggregation and inactivation of the substrate proteins
-
-
?
additional information
?
-
subunits ApCpnA and ApCpnB are able to hydrolyze not only ATP, but also CTP, GTP, and UTP, albeit with different efficacies. Addition of subunits ApCpnA and ApCpnB effectively protects porcine heart citrate synthase and alcohol dehydrogenase from thermal aggregation and inactivation at 43°C and 50°C, respectively. In particular, the addition of ATP or CTP to subunits ApCpnA and ApCpnB results in the most effective prevention of thermal aggregation and inactivation of the substrate proteins
-
-
?
additional information
?
-
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
chaperonin TRiC/CCT modulates the folding and activity of leukemogenic fusion oncoprotein AML1-ETO.A folding intermediate of AML1-ETO binds to TRiC directly, mainly through its beta-strand rich, DNA-binding domain (AML-(1-175)), with the assistance of HSP70. TRiC contributes to AML1-ETO proteostasis through specific interactions between the oncoprotein's DNA-binding domain
-
-
-
additional information
?
-
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
comparison of the mechanisms of action of the GroEL/GroES and the TRiC chaperonin systems on MreB client protein variants extracted from E.scherichia coli. MreB is a homologue to actin in prokaryotes. Single-molecule fluorescence correlation spectroscopy (FCS) and time-resolved fluorescence polarization anisotropy report the binding interaction of folding MreB with GroEL, GroES and TRiC. Fluorescence resonance energy transfer (FRET) measurements on MreB variants quantifiy molecular distance changes occurring during conformational rearrangements within folding MreB bound to chaperonins
-
-
-
additional information
?
-
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
the CCT complex physically interacts with TOR signaling components including TOR, Rheb, and S6K
-
-
-
additional information
?
-
A0A1S6LQX4; A0A1S6LQU3; A0A1S6LQU0; A0A1S6LQU6; A0A1S6LQU1; A0A1S6LQU9; A0A1S6LQW6; A0A1S6LQW7
GaTRiC acts a chaperonin mediating folding of denatured luciferase to the functional stage
-
-
-
additional information
?
-
-
GaTRiC acts a chaperonin mediating folding of denatured luciferase to the functional stage
-
-
-
additional information
?
-
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
chaperonin TRiC/CCT modulates the folding and activity of leukemogenic fusion oncoprotein AML1-ETO.A folding intermediate of AML1-ETO binds to TRiC directly, mainly through its beta-strand rich, DNA-binding domain (AML-(1-175)), with the assistance of HSP70. TRiC contributes to AML1-ETO proteostasis through specific interactions between the oncoprotein's DNA-binding domain. The interaction between AML1-ETO and TRiC is transient. HSP70 facilitates the direct association of AML1-ETO with TRiC
-
-
-
additional information
?
-
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
TRiC binds to and modulates cancer related proteins
-
-
-
additional information
?
-
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
chaperonin TRiC/CCT recognizes fusion oncoprotein AML1-ETO through subunit-specific interactions. A folding intermediate of AML1-ETO's DNA-binding domain (AML1-175) forms a stable complex with apo-TRiC. TRiC can refold denatured AML1-175 (DBD) and restore its DNA binding activity in vitro. AML1-175 localizes to specific TRiC subunits, it binds to the apical domains of subunits CCT6 and 8
-
-
-
additional information
?
-
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
functional cooperation of TRiC and PFD in actin folding. In the absence of PFD, TRiC mediates actin folding with biphasic kinetics. Upon ATP addition, a burst of folding activity (about 4 min) is followed by a much slower and inefficient folding phase that extended up to 60 min. Following ATP addition, PFD enhances the yield of actin folding and disfavored actin aggregation. Substrate folding and PFD interactions, detailed overview. PFD is not merely capturing actin that is released from TRiC due to ATP cycling. Instead, it appears that transfer is mediated by a ternary TRiC-actin-PFD complex, from which actin partitions between TRiC and PFD. Dynamic TRiC-PFD interaction
-
-
-
additional information
?
-
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
reovirus sigma3 is a TRiC substrate
-
-
-
additional information
?
-
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
the hetero-oligomeric chaperonin of eukarya, TRiC, is required to fold the cytoskeletal protein actin. Actin fails to fold spontaneously even in the absence of aggregation but populates a kinetically trapped, conformationally dynamic state. Analysis of the unique features of TRiC directing the folding pathway of an obligate eukaryotic substrate, overview. Binding to TRiC stabilizes a native-like structure in actin. ATP binding induces an asymmetric TRiC intermediate and selective actin release. Substrate recognition mechanism by GroEL and TRiC, and folding mechanism of actin overview
-
-
-
additional information
?
-
-
group II chaperonin CPN accomplishes the precise folding of Pyrococcus furiosus citrate synthase and Aequorea enhanced green fluorescence protein in an ATP-dependent manner. Both prefoldin and chaperonin CPN interact with Pyrococcus furiosus citrate synthase and Aequorea enhanced green fluorescence protein refolding intermediates. Effects on the refolding reaction vary from passive effects such as ATP-dependent binding and release of CPN towards GFP protein and binding which leads to folding arrest, prefoldin towards GFP protein, to active effects such as net increase in thermal stability, CPN towards citrate synthase to an active improvement in refolding yield, prefoldin towards citrate synthase. PfuCPN cannot assist the refolding of Pyrococcus furiosus citrate synthase, but may contribute to maintaining its active form, while prefolding facilitates the refolding of Pyrococcus furiosus citrate synthase
-
-
?
additional information
?
-
TRiC mediates protein folding by encapsulation. It utilizes a built-in lid mechanism of helical protrusions extending from the apical domains that function similar to the blades of a camera iris. This mechanism allows linker sequences between sequential protein domains to protrude through the narrow oculus of the aperture for domain-wise protein encapsulation. The apical domains of the paralogous subunits differ in their specificity for substrate protein binding, allowing TRiC to mediate the folding of a range of structurally diverse proteins including tubulins and actin, as well as many proteins with WD40 beta-propeller domains. Cavity closure is triggered by ATP hydrolysis, not ATP binding. TRiC also binds and masks polyQ-expanded fragments of the Huntington's disease protein, inhibiting their toxic aggregation
-
-
?
additional information
?
-
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
CCT/TRiC is mixed rapidly with different concentrations of ATP, and the amount of phosphate formed upon ATP hydrolysis is measured as a function of time using the coumarin-labeled phosphate-binding protein method. Two burst phases are observed, followed by a lag phase and then a linear steady-state phase of ATP hydrolysis
-
-
-
additional information
?
-
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
eukaryotic chaperonin TRiC (CCT) shows a staggered ATP binding mechanism, staggrered binding of ATP on the CCT6 side of nucleotide partially preloaded (NPP) stated TRiC. ATP binding affects TRiC inter- and intraring interactions. The ATP binding affinity varies among the eight distinct subunits of TRiC. Multiple modes of nucleotide binding in yeast TRiC, detailed overview. The staggered ATP binding mechanism may actually result from the delayed release of the residual ADP of these three subunits CCT8, CCT6, and CCT3
-
-
-
additional information
?
-
-
eukaryotic chaperonin TRiC (CCT) shows a staggered ATP binding mechanism, staggrered binding of ATP on the CCT6 side of nucleotide partially preloaded (NPP) stated TRiC. ATP binding affects TRiC inter- and intraring interactions. The ATP binding affinity varies among the eight distinct subunits of TRiC. Multiple modes of nucleotide binding in yeast TRiC, detailed overview. The staggered ATP binding mechanism may actually result from the delayed release of the residual ADP of these three subunits CCT8, CCT6, and CCT3
-
-
-
additional information
?
-
TRiC mediates protein folding by encapsulation. It utilizes a built-in lid mechanism of helical protrusions extending from the apical domains that function similar to the blades of a camera iris. This mechanism allows linker sequences between sequential protein domains to protrude through the narrow oculus of the aperture for domain-wise protein encapsulation. The apical domains of the paralogous subunits differ in their specificity for substrate protein binding, allowing TRiC to mediate the folding of a range of structurally diverse proteins including tubulins and actin, as well as many proteins with WD40 beta-propeller domains. Cavity closure is triggered by ATP hydrolysis, not ATP binding. TRiC also binds and masks polyQ-expanded fragments of the Huntington's disease protein, inhibiting their toxic aggregation
-
-
?
additional information
?
-
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
CCT/TRiC is mixed rapidly with different concentrations of ATP, and the amount of phosphate formed upon ATP hydrolysis is measured as a function of time using the coumarin-labeled phosphate-binding protein method. Two burst phases are observed, followed by a lag phase and then a linear steady-state phase of ATP hydrolysis
-
-
-
additional information
?
-
Thermochaetoides thermophila
-
ATP-dependent conformational change starts with the high-affinity hemisphere and progresses to the low-affinity hemisphere of the enzyme complex. CtCCT is immobilized on a Strep-Tactin column and acid-denatured actin and tubulin are applied to it. CtCCT is eluted by D-desthiobiotin, CtCCT binds to denatured actin and tubulin. Detailed analysis of ATP-induced conformational change in recombinant CCT using diffracted X-ray tracking, overview
-
-
-
additional information
?
-
denatured indole-3-glycerol-phosphate synthase of Thermococcus kodakarensis is a CpkA target in vitro, mutant CpkA-E530G is more effective than wild-type enzyme CpkA at facilitating the refolding of chemically unfolded substrate
-
-
?
additional information
?
-
denatured indole-3-glycerol-phosphate synthase of Thermococcus kodakarensis is a CpkA target in vitro, mutant CpkA-E530G is more effective than wild-type enzyme CpkA at facilitating the refolding of chemically unfolded substrate
-
-
?
additional information
?
-
indole-3-glycerol-phosphate synthase, TrpC, is a specific target protein of CpkA
-
-
?
additional information
?
-
indole-3-glycerol-phosphate synthase, TrpC, is a specific target protein of CpkA
-
-
?
additional information
?
-
indole-3-glycerol-phosphate synthase, TrpC, is no target protein for CpkB
-
-
?
additional information
?
-
indole-3-glycerol-phosphate synthase, TrpC, is no target protein for CpkB
-
-
?
additional information
?
-
ATP-dependent rotational motion of a group II chaperonin
-
-
?
additional information
?
-
ATP-dependent rotational motion of a group II chaperonin
-
-
?
additional information
?
-
enzyme TKS1-CPN shows a strong protein-folding activity
-
-
?
additional information
?
-
enzyme TKS1-CPN shows a strong protein-folding activity
-
-
?
additional information
?
-
the enzyme assists in folding of IPMDH
-
-
-
additional information
?
-
ATP-dependent rotational motion of a group II chaperonin
-
-
?
additional information
?
-
ATP-dependent rotational motion of a group II chaperonin
-
-
?
additional information
?
-
enzyme TKS1-CPN shows a strong protein-folding activity
-
-
?
additional information
?
-
enzyme TKS1-CPN shows a strong protein-folding activity
-
-
?
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Adenocarcinoma of Lung
Targeting ?-tubulin/CCT-? complex induces apoptosis and suppresses migration and invasion of highly metastatic lung adenocarcinoma.
Alzheimer Disease
The TRiC/CCT chaperone is implicated in Alzheimer's disease based on patient GWAS and an RNAi screen in A?-expressing Caenorhabditis elegans.
Anthrax
CCT chaperonin complex is required for efficient delivery of anthrax toxin into the cytosol of host cells.
Astrocytoma
Analysis of the antibody repertoire of astrocytoma patients against antigens expressed by gliomas.
Autoimmune Diseases
Chaperonin-containing T-complex Protein 1 Subunit ? Serves as an Autoantigen Recognized by Human V?2 ?? T Cells in Autoimmune Diseases.
Bardet-Biedl Syndrome
MKKS/BBS6, a divergent chaperonin-like protein linked to the obesity disorder Bardet-Biedl syndrome, is a novel centrosomal component required for cytokinesis.
Blindness
Mutation in the Zebrafish cct2 Gene Leads to Abnormalities of Cell Cycle and Cell Death in the Retina: A Model of CCT2-Related Leber Congenital Amaurosis.
Breast Neoplasms
Systematic Characterization of Expression Profiles and Prognostic Values of the Eight Subunits of the Chaperonin TRiC in Breast Cancer.
Breast Neoplasms
Two members of the TRiC chaperonin complex, CCT2 and TCP1 are essential for survival of breast cancer cells and are linked to driving oncogenes.
Carcinogenesis
Contribution of the Type II Chaperonin, TRiC/CCT, to Oncogenesis.
Carcinogenesis
Subcellular and functional proteomic analysis of the cellular responses induced by Helicobacter pylori.
Carcinoma
Expression and significance of p53 and mdm2 in atypical intestinal metaplasia and gastric carcinoma.
Carcinoma
Expression of E-cadherin and beta-catenin in gastric carcinoma and its correlation with the clinicopathological features and patient survival.
Carcinoma
Gatric carcinoma. A prospective study of tumour differentiation correlated to surgical procedures and survival rate.
Carcinoma
[Cancer cells in the blood stream of patients with gatric carcinoma.]
Carcinoma, Hepatocellular
Prognostic Power of a Chaperonin Containing TCP-1 Subunit Genes Panel for Hepatocellular Carcinoma.
Carcinoma, Hepatocellular
The TCP1 ring complex is associated with malignancy and poor prognosis in hepatocellular carcinoma.
Cardiovascular Diseases
Chaperonin-containing TCP-1 complex directly binds to the cytoplasmic domain of the LOX-1 receptor.
Colonic Neoplasms
A novel peptide specifically targeting the vasculature of orthotopic colorectal cancer for imaging detection and drug delivery.
Colonic Neoplasms
Characterization of TCP-1 probes for molecular imaging of colon cancer.
Colorectal Neoplasms
A novel peptide specifically targeting the vasculature of orthotopic colorectal cancer for imaging detection and drug delivery.
Colorectal Neoplasms
A novel vascular-targeting peptide for gastric cancer delivers low-dose TNF? to normalize the blood vessels and improve the anti-cancer efficiency of 5-fluorouracil.
Colorectal Neoplasms
Modulated T-complex protein 1 ? and peptidyl-prolyl cis-trans isomerase B are two novel indicators for evaluating lymph node metastasis in colorectal cancer: Evidence from proteomics and bioinformatics.
Colorectal Neoplasms
Vascular-targeted TNF? and IFN? inhibits orthotopic colorectal tumor growth.
Colorectal Neoplasms
Vascular-targeted TNF? improves tumor blood vessel function and enhances antitumor immunity and chemotherapy in colorectal cancer.
Down Syndrome
Expression patterns of chaperone proteins in cerebral cortex of the fetus with Down syndrome: dysregulation of T-complex protein 1.
Epstein-Barr Virus Infections
Proteomics Analysis of Gastric Epithelial AGS Cells Infected with Epstein-Barr Virus.
Glioma
Analysis of the antibody repertoire of astrocytoma patients against antigens expressed by gliomas.
Hepatitis C
Chaperonin TRiC/CCT participates in replication of hepatitis C virus genome via interaction with the viral NS5B protein.
Hereditary Sensory and Autonomic Neuropathies
Structure of the human TRiC/CCT Subunit 5 associated with hereditary sensory neuropathy.
Infections
Human Papillomavirus infection requires the CCT Chaperonin Complex.
Infections
Identification of candidate protein markers of Bovine Parainfluenza Virus Type 3 infection using an in vitro model.
Infections
[Preliminary investigation of Helicobacter pylori infection in Linqu County of Shandong province]
Leber Congenital Amaurosis
Mutation in the Zebrafish cct2 Gene Leads to Abnormalities of Cell Cycle and Cell Death in the Retina: A Model of CCT2-Related Leber Congenital Amaurosis.
Leukemia, Myeloid, Acute
Chaperonin TRiC/CCT Recognizes Fusion Oncoprotein AML1-ETO through Subunit-Specific Interactions.
Lymphadenopathy
Silencing P2X7 receptor downregulates the expression of TCP-1 involved in lymphoma lymphatic metastasis.
Lymphatic Metastasis
Modulated T-complex protein 1 ? and peptidyl-prolyl cis-trans isomerase B are two novel indicators for evaluating lymph node metastasis in colorectal cancer: Evidence from proteomics and bioinformatics.
Lymphatic Metastasis
Silencing P2X7 receptor downregulates the expression of TCP-1 involved in lymphoma lymphatic metastasis.
Lymphoma
Silencing P2X7 receptor downregulates the expression of TCP-1 involved in lymphoma lymphatic metastasis.
Malaria
The chaperonin TRiC forms an oligomeric complex in the malaria parasite cytosol.
Neoplasm Metastasis
Modulated T-complex protein 1 ? and peptidyl-prolyl cis-trans isomerase B are two novel indicators for evaluating lymph node metastasis in colorectal cancer: Evidence from proteomics and bioinformatics.
Neoplasm Metastasis
Silencing P2X7 receptor downregulates the expression of TCP-1 involved in lymphoma lymphatic metastasis.
Neoplasms
?133p53? isoform pro-invasive activity is regulated through an aggregation-dependent mechanism in cancer cells.
Neoplasms
A novel peptide specifically targeting the vasculature of orthotopic colorectal cancer for imaging detection and drug delivery.
Neoplasms
A novel vascular-targeting peptide for gastric cancer delivers low-dose TNF? to normalize the blood vessels and improve the anti-cancer efficiency of 5-fluorouracil.
Neoplasms
Anti-tumor effect and mechanism of SEA-Fab' coupled protein on gastric tumor.
Neoplasms
Chaperonin containing TCP-1 subunit 3 is critical for gastric cancer growth.
Neoplasms
Chaperonin Containing-TCP-1 Protein Level in Breast Cancer Cells Predicts Therapeutic Application of a Cytotoxic Peptide.
Neoplasms
Chaperonin-Containing TCP1 Complex (CCT) Promotes Breast Cancer Growth Through Correlations With Key Cell Cycle Regulators.
Neoplasms
Characterization of TCP-1 probes for molecular imaging of colon cancer.
Neoplasms
Contribution of the Type II Chaperonin, TRiC/CCT, to Oncogenesis.
Neoplasms
Diverse effects of mutations in exon II of the von Hippel-Lindau (VHL) tumor suppressor gene on the interaction of pVHL with the cytosolic chaperonin and pVHL-dependent ubiquitin ligase activity.
Neoplasms
Formation of the VHL-elongin BC tumor suppressor complex is mediated by the chaperonin TRiC.
Neoplasms
Gatric carcinoma. A prospective study of tumour differentiation correlated to surgical procedures and survival rate.
Neoplasms
Identification of the TRiC/CCT substrate binding sites uncovers the function of subunit diversity in eukaryotic chaperonins.
Neoplasms
Matrine induces papillary thyroid cancer cell apoptosis in vitro and suppresses tumor growth in vivo by downregulating miR-182-5p.
Neoplasms
Molecular and Clinical Characterization of CCT2 Expression and Prognosis via Large-Scale Transcriptome Profile of Breast Cancer.
Neoplasms
Multiple malignant primary neoplasms in patients with gatric neoplasms in the health district of León.
Neoplasms
p53: the TRiC is knowing when to fold 'em.
Neoplasms
Systematic Characterization of Expression Profiles and Prognostic Values of the Eight Subunits of the Chaperonin TRiC in Breast Cancer.
Neoplasms
The cytosolic chaperonin CCT/TRiC and cancer cell proliferation.
Neoplasms
The Hsp70 and TRiC/CCT chaperone systems cooperate in vivo to assemble the von Hippel-Lindau tumor suppressor complex.
Neoplasms
The TCP1 ring complex is associated with malignancy and poor prognosis in hepatocellular carcinoma.
Neoplasms
Tumorigenic mutations in VHL disrupt folding in vivo by interfering with chaperonin binding.
Neoplasms
Understanding the Molecular Mechanism of miR-877-3p Could Provide Potential Biomarkers and Therapeutic Targets in Squamous Cell Carcinoma of the Cervix.
Neoplasms
Vascular-targeted TNF? and IFN? inhibits orthotopic colorectal tumor growth.
Neoplasms
Vascular-targeted TNF? improves tumor blood vessel function and enhances antitumor immunity and chemotherapy in colorectal cancer.
Neoplasms
[Cancer cells in the blood stream of patients with gatric carcinoma.]
Neoplasms
[Effects of RNA interference of CTHRC1 on proliferation and apoptosis of thyroid papillary cancer TCP-1 cells in vitro].
Neoplasms
[Preliminary investigation of Helicobacter pylori infection in Linqu County of Shandong province]
Neoplasms
[Prescription rules of Chinese herbal medicines in treatment of gastric cancer]
Neurodegenerative Diseases
Sirt1s beneficial roles in neurodegenerative diseases - a chaperonin containing TCP-1 (CCT) connection?
Neurofibromatoses
Heat shock factor 1 (HSF1)-targeted anticancer therapeutics: overview of current preclinical progress.
Neurofibromatosis 1
Heat shock factor 1 (HSF1)-targeted anticancer therapeutics: overview of current preclinical progress.
Papillomavirus Infections
Human Papillomavirus infection requires the CCT Chaperonin Complex.
Pleural Effusion
Identification of 10 Candidate Biomarkers Distinguishing Tuberculous and Malignant Pleural Fluid by Proteomic Methods.
Pleural Effusion, Malignant
Identification of 10 Candidate Biomarkers Distinguishing Tuberculous and Malignant Pleural Fluid by Proteomic Methods.
Pulmonary Disease, Chronic Obstructive
Effects of genetic variations in Acads gene on the risk of chronic obstructive pulmonary disease.
Starvation
Regeneration in starved planarians depends on TRiC/CCT subunits modulating the unfolded protein response.
Stomach Diseases
Subcellular and functional proteomic analysis of the cellular responses induced by Helicobacter pylori.
Stomach Neoplasms
A novel vascular-targeting peptide for gastric cancer delivers low-dose TNF? to normalize the blood vessels and improve the anti-cancer efficiency of 5-fluorouracil.
Stomach Neoplasms
Chaperonin containing TCP-1 subunit 3 is critical for gastric cancer growth.
Stroke
A gradient of ATP affinities generates an asymmetric power stroke driving the chaperonin TRIC/CCT folding cycle.
Teratozoospermia
T-complex protein 1 subunit zeta-2 (CCT6B) deficiency induces murine teratospermia.
Thyroid Neoplasms
Effect of Interferon-? on the Basal and the TNF?-Stimulated Secretion of CXCL8 in Thyroid Cancer Cell Lines Bearing Either the RET/PTC Rearrangement Or the BRAF V600e Mutation.
Tuberculosis
Duodenal tuberculosis presenting as gatric outlet obstruction.
Zika Virus Infection
TRiC/CCT Complex, a Binding Partner of NS1 Protein, Supports the Replication of Zika Virus in Both Mammalians and Mosquitoes.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
evolution
the chaperonins of group II in the cytosol of archaea and eukaryotic cells share the three-domain subunit topology and cylindrical architecture with the group I chaperonins, EC 3.6.4.9, but function without a GroES-like cofactor
evolution
the chaperonins of group II in the cytosol of archaea and eukaryotic cells share the three-domain subunit topology and cylindrical architecture with the group I chaperonins, EC 3.6.4.9, but function without a GroES-like cofactor
evolution
-
the enzyme belongs to the archetypal group II chaperonins. Group II chaperonins are found in archaea and the eukaryotic cytosol. They consist of two stacked rings, each composed of eight 50- to 60-kDa subunits, but do not have an obligate co-chaperone in the same manner as the group I chaperonins. Rather, they contain a built-in lid that closes the folding chamber and are thus competent to fold substrates in vitro without the assistance of accessory proteins. Group II chaperonins appear to be at the heart of a complex network of co-chaperones. The eukaryotic group II chaperonin, i.e. TRiC/CCT, differs from its simpler archaeal homologues in that it is composed of eight paralogous subunits, while in eukaryotic chaperonin, TRiC/CCT, each ring contains eight distinct, paralogous subunits occupying fixed positions in the complex
evolution
-
the enzyme belongs to the archetypal group II chaperonins. Group II chaperonins are found in archaea and the eukaryotic cytosol. They consist of two stacked rings, each composed of eight 50- to 60-kDa subunits, but do not have an obligate co-chaperone in the same manner as the group I chaperonins. Rather, they contain a built-in lid that closes the folding chamber and are thus competent to fold substrates in vitro without the assistance of accessory proteins. Group II chaperonins appear to be at the heart of a complex network of co-chaperones. The eukaryotic group II chaperonin, i.e. TRiC/CCT, differs from its simpler archaeal homologues in that it is composed of eight paralogous subunits, while in eukaryotic chaperonin, TRiC/CCT, each ring contains eight distinct, paralogous subunits occupying fixed positions in the complex
evolution
-
the enzyme belongs to the eukaryotic group II chaperonins. Group II chaperonins are found in archaea and the eukaryotic cytosol. They consist of two stacked rings, each composed of eight 50- to 60-kDa subunits, but do not have an obligate co-chaperone in the same manner as the group I chaperonins. Rather, they contain a built-in lid that closes the folding chamber and are thus competent to fold substrates in vitro without the assistance of accessory proteins. Group II chaperonins appear to be at the heart of a complex network of co-chaperones, e.g. the phosducin-like proteins that enhance TRiC-mediated folding of several substrates. The eukaryotic group II chaperonin, i.e. TRiC/CCT, differs from its simpler archaeal homologues in that it is composed of eight paralogous subunits, while in eukaryotic chaperonin, TRiC/CCT, each ring contains eight distinct, paralogous subunits occupying fixed positions in the complex
evolution
-
the enzyme belongs to the group II chaperonins
evolution
the enzyme belongs to the group II chaperonins, group II consists of the archaeal (thermosomes) and eukaryotic cytosolic variants (CCT or TRiC). The structure is more complex for group II chaperonins compared to group I chaperonins, EC 3.6.4.9. Evolution of group II chaperonins via rapid multiple gene duplication, folding mechanism, phylogenetic analyses
evolution
the enzyme belongs to the group II chaperonins, group II consists of the archaeal (thermosomes) and eukaryotic cytosolic variants (CCT or TRiC). The structure is more complex for group II chaperonins compared to group I chaperonins, EC 3.6.4.9. Evolution of group II chaperonins via rapid multiple gene duplication, folding mechanism, phylogenetic analyses
evolution
the enzyme belongs to the group II chaperonins, that play important roles in protein homeostasis in the eukaryotic cytosol and in Archaea
evolution
the enzyme belongs to the group II chaperonins, which are found in archaeal (thermosome of Thermoplasma acidophilum) and in eukaryotic (chaperonin-containing TCP-1 or CCT) species, have eight or nine subunits per ring made of two (thermosome) or eight (CCT) types of subunits. Subunit heterogeneity in group II chaperonins, found primarily within the apical domains, has important consequences for the functional specialization of ring components, role of heterogeneity in subunit dynamics. Nonconservation of intra-ring cooperativity among chaperonin classes, overview
evolution
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
chaperonin TRiC is evolutionarily conserved
evolution
chaperonins (CPNs) are subdivided into group I and group II. Group I CPNs are present in bacteria and in the organelles of eukaryotes. Group II CPNs exist in the cytosol of archaea and eukaryotes
evolution
Thermochaetoides thermophila
-
chaperonins are subdivided into two families, group I and group II chaperonins
evolution
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P11983; P80314; P80318; P80315; P80316; P80317; P80313; P42932
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
Q55BM4; Q54ES9; Q54TH8; Q54CL2; Q54TD3; Q76NU3; Q54ER7; Q552J0
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P41988; P47207; Q9N4J8; P47208; P47209; P46550; Q9TZS5; Q9N358
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P28480; Q5XIM9; Q6P502; Q7TPB1; Q68FQ0; Q3MHS9; D4AC23; D4ACB8
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P28769; Q940P8; Q84WV1; Q9LV21; O04450; Q9M888; Q9SF16; Q94K05
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
Q8II43; O97247; Q8I5C4; C0H5I7; O97282; C6KST5; O77323; O96220
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
Q59QB7; Q59YC4; Q5AK16; Q59Z12; A0A1D8PMN9; Q59YH4; P47828
co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
the eukaryotic chaperonin family includes the type I chaperonin, HSP60, and the type II hetero-oligomeric chaperonin, TRiC (T-complex protein-1 ring complex, also known as CCT). Chaperones often function as large protein complexes that include other proteins called co-chaperones
evolution
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
the eukaryotic chaperonin family includes the type I chaperonin, HSP60, and the type II hetero-oligomeric chaperonin, TRiC (T-complex protein-1 ring complex, also known as CCT). Chaperones often function as large protein complexes that include other proteins called co-chaperones
evolution
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
the protein MreB structure is rearranged by a binding-induced expansion mechanism in TRiC, GroEL and GroES. These results are quantitatively comparable to the structural rearrangements found during the interaction of beta-actin with GroEL and TRiC, indicating that the mechanism of chaperonins is conserved during evolution
evolution
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
three BBS proteins which have homology to chaperonins, BBS6, BBS10 and BBS12, and a sub-complex of CCT proteins (CCT1, 2, 3, 4, 5 and 8) mediate the association of two beta-propeller domain-containing proteins, BBS7 and BBS2, during the assembly process of the BBSome. BBS6, -10 and -12 are vertebrate-specific proteins and it may be an evolutionary connection that one of the two absent CCT subunits in the BBS-CCT complex, CCT6, has a vertebrate-specific isoform, CCT6B, which is abundant in testis CCT. CCT6 self-interacts across the CCT rings which probably permits isoform interchange, and therefore, it is possible that one of the BBS subunits has hijacked this mechanism and is able to slot into the CCT6 position in the CCT ring system. Co-evolution of CCT and the eukaryotic cytoskeleton, overview
evolution
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
TRiC has evolved into a complex structurally divided into two sides whose nucleotide binding and ring closure occur in a staggered manner, thus making it a highly coordixadnated macromolecular machine
evolution
-
the enzyme belongs to the group II chaperonins, that play important roles in protein homeostasis in the eukaryotic cytosol and in Archaea
-
evolution
-
chaperonin TRiC is evolutionarily conserved
-
evolution
-
co-evolution of CCT and the eukaryotic cytoskeleton, overview
-
evolution
-
co-evolution of CCT and the eukaryotic cytoskeleton, overview
-
evolution
-
the chaperonins of group II in the cytosol of archaea and eukaryotic cells share the three-domain subunit topology and cylindrical architecture with the group I chaperonins, EC 3.6.4.9, but function without a GroES-like cofactor
-
evolution
-
co-evolution of CCT and the eukaryotic cytoskeleton, overview
-
evolution
-
the enzyme belongs to the group II chaperonins, which are found in archaeal (thermosome of Thermoplasma acidophilum) and in eukaryotic (chaperonin-containing TCP-1 or CCT) species, have eight or nine subunits per ring made of two (thermosome) or eight (CCT) types of subunits. Subunit heterogeneity in group II chaperonins, found primarily within the apical domains, has important consequences for the functional specialization of ring components, role of heterogeneity in subunit dynamics. Nonconservation of intra-ring cooperativity among chaperonin classes, overview
-
evolution
-
the enzyme belongs to the group II chaperonins, group II consists of the archaeal (thermosomes) and eukaryotic cytosolic variants (CCT or TRiC). The structure is more complex for group II chaperonins compared to group I chaperonins, EC 3.6.4.9. Evolution of group II chaperonins via rapid multiple gene duplication, folding mechanism, phylogenetic analyses
-
malfunction
gene disruptant strain DA1 (DELTAcpkA) shows decreased cell growth at 60°C, DA1 cells grow optimally in minimal medium only in the presence of tryptophan but hardly grow in the absence of tryptophan at 60°C. A lesion of functional indole-3-glycerol-phosphate synthase, TrpC, is caused by cpkA disruption, resulting in tryptophan auxotrophy
malfunction
gene disruptant strain DB1 (DELTAcpkB) shows decreased cell growth at 93°C
malfunction
introduction of single mutations into the CpkA C-terminal region show that a single base substitution E530G allows the organism to adapt to a lower temperature
malfunction
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
cardiac-specific knockdown of CCT chaperonin significantly shortens lifespans. Additionally, disruption of circadian rhythm yields further deterioration of cardiac function of hypomorphic CCT mutants. CCT knockdown leads to disorganization of cardiac actin- and myosin-containing myofibrils and severe physiological dysfunction, including restricted heart diameters, elevated cardiac dysrhythmia and compromised cardiac performance
malfunction
P41988; P47207; Q9N4J8; P47208; P47209; P46550; Q9TZS5; Q9N358
deletion of the phosducin III gene causes embryo division arrest with astral microtubule defects
malfunction
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
disrupting the TRiC-PFD interaction in vivo is strongly deleterious, leading to accumulation of amyloid aggregates
malfunction
Q55BM4; Q54ES9; Q54TH8; Q54CL2; Q54TD3; Q76NU3; Q54ER7; Q552J0
gene deletion of the gene encoding cofactor phosducin I in Dictyostelium discoideum causes inhibition of G-protein signalling and Gbetagamma dimer formation, deletion of the phosducin II gene is lethal with cell division collapse after 5 days, while deletion of phosducin IIII gene causes no phenotype
malfunction
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
in zebrafish, TRiC loss causes specific defects in sarcomere and neurite formation. A missense mutation in the CCT5 subunit of TRiC leads to skeletal muscle defects, mutant cct5tf212b. Loss of individual subunits abolishes Z-disk localization. Expression of GFP-tagged subunit CCT3 in the musculature significantly ameliorates the muscle integrity deficits of transgenic cct3sa1761 homozygotes, as evaluated by birefringence analysis, indicating that the fusion protein is functional and integrated normally into TRiC. All cct mutants show retina degeneration, except for cct5tf212b, phenotypes, overview
malfunction
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
knockdown of cct1 and cct2 in zebrafish leads to BBS-like phenotypes
malfunction
Q8II43; O97247; Q8I5C4; C0H5I7; O97282; C6KST5; O77323; O96220
knockdown of the CCT8/theta subunit leads to a severe growth defect in asexual development but does not alter protein trafficking in the red blood cell compartment
malfunction
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
knockdown of the PfTRiC-theta subunit is lethal, the lethality is not due to a change in protein export into the host red blood cell (RBC) compartment
malfunction
Q8II43; O97247; Q8I5C4; C0H5I7; O97282; C6KST5; O77323; O96220
knockdown of the PfTRiC-theta subunit is lethal, the lethality is not due to a change in protein export into the host red blood cell (RBC) compartment. Loss of the PfTRiC complex does not alter export of PfSBP1 or PfREX1. The PfTRiC-theta-MYC clones of teh engineered regulatable line retain between 4 and 10 aptamer elements. The degree of regulation of expression correlates with the number of aptamers in the array, and knockdown reveals that PfTRiC-theta is essential for asexual parasite growth. But loss of one subunit in the heterohexadecamer disrupts formation of the entire complex
malfunction
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
knockdown of TRiC in HEPG2 cells reduces their sensitivity to interleukin-6 induced STAT3 activation
malfunction
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
knockdown of TRiC subunits in the prothoracic gland (PG) causes a prolonged mitotic period, probably due to impaired nuclear translocation of Fizzy-related (Fzr), which also causes loss of ecdysteroidogenic activity. Fzr mediates downregulation of mitotic cyclins
malfunction
P28480; Q5XIM9; Q6P502; Q7TPB1; Q68FQ0; Q3MHS9; D4AC23; D4ACB8
mutations of subunit CCT5 are involved in sensory neuropathy. Mutation C450Y of subunit CCT4 is involved in hereditary sensory neuropathies that show degeneration of the fibres in the sensory periphery neurons
malfunction
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
mutations of subunit CCT5 are involved in sensory neuropathy. Mutation H147R of subunit CCT5 is involved in hereditary sensory neuropathies that show degeneration of the fibres in the sensory periphery neurons
malfunction
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
reduction of subunit CCT4 results in growth defects by affecting both cell size and proliferation. Loss of CCT4 causes preferential cell death anterior to the morphogenetic furrow in the eye disc and within wing pouch in the wing disc. Depletion of any CCT subunit in the eye disc results in headless phenotype and loss-of-function phenotypes by disrupting the function of the CCT complex in vivo. Overgrowth by active TOR signaling is suppressed by CCT RNAi. Loss of CCT leads to decreased phosphorylation of S6K and S6 while increasing phosphorylation of Akt. Insulin/TOR signaling is also necessary and sufficient for promoting CCT complex transcription. Reduction of the CCT complex leads to decreases in phospho-S6K and phospho-S6 while increasing phospho-Akt. CCT4 RNAi in the posterior wing disc under en-Gal4 causes early pupal lethality. Wing discs from en>CCT4 RNAi show almost complete loss of the posterior compartment marked by en>GFP. In comparison to control en>+, CCT4-depleted larvae show considerable developmental delay during its growth up to the third-instar stage, eventually resulting in pupal lethality. Consistent with the expression of ptc-Gal4 in the salivary gland, CCT4 RNAi reduced the size of the gland compared with control. In addition, knockdown of CCT4 in the wing pouch region of the developing wing disc under MS1096-Gal4 leads to loss of adult wing
malfunction
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
RNAi knockdown of each TRiC subunit substantially reduces the levels of intracellular reovirus proteins, providing evidence that TRiC is required for the production or stabilization of viral polypeptides
malfunction
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
RNAi-mediated knockdown targeting CCT2 inhibits growth and colony formation of SUM-52 breast cancer cells
malfunction
the wild-type organism shows reduced growth under GroES/GroEL-limiting conditions. Cells are transformed with plasmids expressing Mm-cpn, Mm-cpn-M223I, and Mm-cpn-K216E and grown at 26°C, 30°C, and 37°C in the presence of sucrose. Apart from the positive control, growth is observed only for cells expressing the mutant Mm-cpn-K216E. These cells show distinct visible colonies after 3 days at 26°C and 30°C in numbers comparable to those observed for cells expressing GroEL. Cells expressing Mm-cpn-K216E also form visible colonies at 37°C after 5 days. Loss of ATPase activity by mutation D386A severely affects the complementing ability of the wild-type and mutant Mm-cpn proteins
malfunction
A0A1S6LQX4; A0A1S6LQU3; A0A1S6LQU0; A0A1S6LQU6; A0A1S6LQU1; A0A1S6LQU9; A0A1S6LQW6; A0A1S6LQW7
three categories of residue substitutions are found in alpha, beta, and gamma subunits: (i) bulky/polar side chains to alanine or valine, (ii) charged residues to alanine, and (iii) isoleucine to valine that is expected to increase intramolecular flexibility within the GaTRiC. The residue substitutions observed in the built structures possibly affect the hydrophobic, hydrogen bonds, and ionic and aromatic interactions which lead to an increase in structural flexibility
malfunction
-
knockdown of TRiC subunits in the prothoracic gland (PG) causes a prolonged mitotic period, probably due to impaired nuclear translocation of Fizzy-related (Fzr), which also causes loss of ecdysteroidogenic activity. Fzr mediates downregulation of mitotic cyclins
-
malfunction
-
mutations of subunit CCT5 are involved in sensory neuropathy. Mutation C450Y of subunit CCT4 is involved in hereditary sensory neuropathies that show degeneration of the fibres in the sensory periphery neurons
-
metabolism
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
CCT-actin system, overview
metabolism
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
CCT-actin system, overview
metabolism
P11983; P80314; P80318; P80315; P80316; P80317; P80313; P42932
CCT-actin system, overview
metabolism
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
CCT-actin system, overview
metabolism
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
CCT-actin system, overview
metabolism
P28480; Q5XIM9; Q6P502; Q7TPB1; Q68FQ0; Q3MHS9; D4AC23; D4ACB8
CCT-actin system, overview
metabolism
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
CCT-actin system, overview. Interactions between CCT, actin and Plp2p in yeast: the actin map shows the CCT-binding sites, I, II and III and hinges, and the essential actin-binding D244 residue located in actin subdomain 4, which biochemically cross-links to the CCT8 subunit. Yeast actin (ACT1) binding to yeast CCT induces protease resistance in Cct4p and Cct8p. The PLP2 component shows its interactions with CCT subunits, CCT1, CCT4 and CCT8
metabolism
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
chaperone network involving HSP70, HSP90, and TRiC, overview
metabolism
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
chaperone network involving HSP70, HSP90, and TRiC, overview
metabolism
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
comparison of the mechanisms of action of the GroEL/GroES and the TRiC chaperonin systems on MreB client protein variants extracted from Escherichia coli. MreB is a homologue to actin in prokaryotes
metabolism
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
pathway of actin folding directed by the eukaryotic chaperonin TRiC, overview
metabolism
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
the TCP1 subunit of TRiC is regulated by FGFR2, necessary for proliferation of breast cancer cells and associated with poor overall survival of breast cancer patients. FGFR2 signals through PI3K and Akt to regulate TCP1 expression, this signaling does not require mTOR activity
metabolism
P11983; P80314; P80318; P80315; P80316; P80317; P80313; P42932
Vaccinia-related kinase 2 controls the stability of the eukaryotic chaperonin TRiC/CCT by inhibiting the deubiquitinating enzyme USP25. VRK2 function in the negative regulation of TRiC
metabolism
-
CCT-actin system, overview
-
metabolism
-
CCT-actin system, overview. Interactions between CCT, actin and Plp2p in yeast: the actin map shows the CCT-binding sites, I, II and III and hinges, and the essential actin-binding D244 residue located in actin subdomain 4, which biochemically cross-links to the CCT8 subunit. Yeast actin (ACT1) binding to yeast CCT induces protease resistance in Cct4p and Cct8p. The PLP2 component shows its interactions with CCT subunits, CCT1, CCT4 and CCT8
-
physiological function
-
the enzyme can protect halophilic proteins against denaturation under conditions of cellular hyposaline stress
physiological function
chaperonins are essential for protein folding in all domains of life. They stand out among ATP-dependent chaperones in that they form large 800-1000 kDa double-ring complexes with an internal chamber in each ring. Their basic function is to provide a nano-cage for the folding of single protein molecules to occur in isolation, unimpaired by aggregation
physiological function
chaperonins are essential for protein folding in all domains of life. They stand out among ATP-dependent chaperones in that they form large 800-1000 kDa double-ring complexes with an internal chamber in each ring. Their basic function is to provide a nano-cage for the folding of single protein molecules to occur in isolation, unimpaired by aggregation. Enzyme TRiC mediates protein folding by encapsulation and displays negative inter-ring cooperativity, favoring asymmetric complexes with one ring open and the other closed. The inner surface of the TRiC chamber is divided into two halves with opposite charge character. This charge asymmetry coincides with an asymmetry in ATP binding and hydrolysis: four adjacent subunits have high affinity for ATP and neutral or negative surface charge, while the other four subunits have low affinity for ATP and positive surface charge. Chamber closure and release of substrate protein can initiate asymmetrically and proceed in a sequential mechanism. TRiC also binds and masks polyQ-expanded fragments of the Huntington's disease protein, inhibiting their toxic aggregation
physiological function
chaperonins are molecular machines that use ATP-driven cycles to assist misfolded substrate proteins to reach the native state. During the functional cycle, these machines adopt distinct nucleotide-dependent conformational states, which reflect large-scale allosteric changes in individual subunits. Archaeal and eukaryotic chaperonins undergo sequential subunit motions, analysis of the mode of action and mechanism. The thermosome double-ring structure has large contribution from higher-frequency modes
physiological function
chaperonins are ubiquitous chaperones that are required for correct protein folding, assembly, and degradation
physiological function
chaperonins are ubiquitous molecular chaperones performing an ATP-dependent conformational change of the cavity that induces the folding of an unfolded protein that is captured in the cavity
physiological function
chaperonins have elaborate allosteric mechanisms to regulate their functional cycle. Long-range negative cooperativity between the two rings ensures alternation of the folding chambers. No Positive intra-ring cooperativity in group II enzymes
physiological function
chaperonins have elaborate allosteric mechanisms to regulate their functional cycle. Long-range negative cooperativity between the two rings ensures alternation of the folding chambers. No Positive intra-ring cooperativity in group II enzymes. Thermosomes use a non-specific, hydrophobic-based substrate recognition mechanism involving the helical protrusion, release of trapped substrate after closure of the chaperonin cavity
physiological function
group II chaperonin proteins assist in the folding of nascent polypeptides and also refold unfolded proteins in an ATP-dependent manner. Chaperonin-mediated protein folding is dependent on the closure and opening of a built-in lid, which is controlled by the ATP hydrolysis cycle
physiological function
-
prefoldin is a molecular chaperone that can stabilize tentatively nascent polypeptide chains or non-native forms of mainly cytoskeletal proteins, which are subsequently delivered to group II chaperonin to accomplish their precise folding, active and passive effects of Pyrococcus furiosus prefoldin on the refolding reactions of Pyrococcus furiosus citrate synthase and Aequorea enhanced green fluorescence protein differ in the presence or absence of Pyrococcus furiosus chaperonin, PfuCPN
physiological function
the CpkA C-terminal region plays a key role in cell growth at 60°C
physiological function
-
the enzymes TRiC/CCT are absolutely required for folding many essential proteins, including cytoskeletal proteins such as tubulin and actin, as well as cell cycle regulators such as CDC20 and CDH1. About 10% of cytosolic proteins interact with the eukaryotic chaperonin TRiC/CCT along their folding trajectory
physiological function
the group II chaperonin captures an unfolded protein while in its open conformation and then mediates the folding of the protein during ATP-driven conformational change cycle
physiological function
Q59QB7; Q59YC4; Q5AK16; Q59Z12; A0A1D8PMN9; Q59YH4; P47828
CCT is a key modulator of echinocandin susceptibility
physiological function
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
chaperonin containing TCP-1 (CCT) is a complex that assists protein folding and function. The CCT complex is required for organ growth by interacting with the TOR pathway in Drosophila melanogaster. The CCT complex regulates organ growth by directly interacting with the TOR signaling pathway, interaction with TOR signaling components including TOR, Rheb, and S6K. Analysis of the genetic interaction between CCT complex and growth signaling pathways, overview
physiological function
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
chaperonin TCP-1 ring complex (TRiC) supports proper folding of numerous proteins including cell cycle regulators and mediates protein quality control. TRiC/CCT supports mitotic exit and entry into endocycle in Drosophila melanogaster. The evolutionarily conserved chaperonin TRiC is a regulator of the mitotic-to-endocycle switch (MES), which is critical for the prothoracic gland (PG) to upregulate biosynthesis of the steroid hormone ecdysone. TRiC supports proper MES and endocycle progression by regulating Fzr folding. TRiC-mediated protein quality control is proposed to be a conserved mechanism supporting MES and endocycling, as well as subsequent terminal differentiation. TRiC is required for ecdysone biosynthesis in the PG to induce the larval-to-pupal transition. TRiC downregulates CycA by regulating Fzr nuclear translocation to promote MES and endocycling
physiological function
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
chaperonin TRiC/CCT modulates the folding and activity of leukemogenic fusion oncoprotein AML1-ETO. AML1-ETO is the most common fusion oncoprotein causing acute myeloid leukemia (AML), a disease with a 5-year survival rate of only 24%. AML1-ETO functions as a rogue transcription factor, altering the expression of genes critical for myeloid cell development and differentiation. The biosynthesis and folding of the AML1-ETO protein is facilitated by interaction with the essential eukaryotic chaperonin TRiC (or CCT)
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
chaperonin TRiC/CCT modulates the folding and activity of leukemogenic fusion oncoprotein AML1-ETO. AML1-ETO is the most common fusion oncoprotein causing acute myeloid leukemia (AML), a disease with a 5-year survival rate of only 24%. AML1-ETO functions as a rogue transcription factor, altering the expression of genes critical for myeloid cell development and differentiation. The biosynthesis and folding of the AML1-ETO protein is facilitated by interaction with the essential eukaryotic chaperonin TRiC (or CCT)
physiological function
chaperonins (CPNs) are ubiquitous, double ring-shaped molecular chaperones that capture unfolded proteins in their cavities and assist in protein folding in an ATP-dependent manner. Prefoldin (PFD) captures an unfolded protein substrate and transfers it to a group II chaperonin (CPN). The transfer of a substrate from PFD to CPN involves a direct interaction, PFD interacts with the apical domain of CPN, analysis of protein-folding mechanism of PFD and CPN using the PFD-CPN systems of the hyperthermophilic archaea, overview
physiological function
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
chaperonins are essential for cell survival as they protect against proteotoxic stress that may lead to protein misfolding and aggregation. Chaperonin TRiC (T-complex protein-1 ring complex, also known as CCT) in the development and progression of cancer. Type II chaperonin TRiC/CCT contributes to oncogenesis. TRiC assists productive folding of substrate proteins by undergoing conformational changes that are ATP-dependent. Interaction of TRiC with p53 promotes the protein folding and activity of p53, a tumor suppressor protein that plays a critical role in preventing malignant cancer cell development. p53 primarily functions as a transcription factor that modulates the expression of a variety of genes involved in cellular responses such as cell-cycle arrest and apoptosis. Contribution of TRiC to mutant p53-mediated oncogenesis is not as straightforward as it is for STAT3. TRiC plays a critical role in the regulation of cell cycle progression and modulates cell cycle regulatory proteins
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
chaperonins are essential for cell survival as they protect against proteotoxic stress that may lead to protein misfolding and aggregation. Chaperonin TRiC (T-complex protein-1 ring complex, also known as CCT) is involved in the development and progression of cancer mediated through its critical interactions with oncogenic clients, it modulates growth deregulation, apoptosis, and genome instability in cancer cells. Type II chaperonin TRiC/CCT contributes to oncogenesis. TRiC assists productive folding of substrate proteins by undergoing conformational changes that are ATP-dependent. Interaction of TRiC with p53 promotes the protein folding and activity of p53, a tumor suppressor protein that plays a critical role in preventing malignant cancer cell development. p53 primarily functions as a transcription factor that modulates the expression of a variety of genes involved in cellular responses such as cell-cycle arrest and apoptosis. Contribution of TRiC to mutant p53-mediated oncogenesis is not as straightforward as it is for STAT3. TRiC contributes to STAT protein folding and function, STAT3 requires TRiC for folding and proper functioning. TRiC plays a critical role in the regulation of cell cycle progression and modulates cell cycle regulatory proteins. HSP70 and TRiC appear to function sequentially in the Von Hippel-Lindau protein (VHL) folding pathway, with loss of HSP70 function blocking association with TRiC and loss of TRiC function having no effect on HSP70 association. TRiC subunits, CCT2 and CCT1, are essential for survival and proliferation of breast cancer. Chaperonin TRiC works as an assembly station for the tumor suppressor protein, VHL (Von Hippel-Lindau), mechanism, overview. TRiC chaperonin contributes to carcinogenesis through its contribution to STAT3 signaling
physiological function
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
chaperonins are large, multimeric, barrel-shaped proteins, which assist in the folding and prevent aggregation of non-native proteins. The protein MreB structure is rearranged by a binding-induced expansion mechanism in TRiC, GroEL and GroES. These results are quantitatively comparable to the structural rearrangements found during the interaction of beta-actin with GroEL and TRiC. The chaperonin-bound MreB is also significantly compacted after addition of AMP-PNP for both the GroEL/ES and TRiC systems. Most importantly, GroES may act as an unfoldase by inducing a dramatic initial expansion of MreB (even more than for GroEL) implicating a role for MreB folding, suggesting a delivery mechanism for GroES to GroEL in prokaryotes
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
direct interactions between two chaperonins allow them to feed folding substrates bi-directionally between active sites, preventing aggregation and promoting proteostasis. The essential ring-shaped chaperonin TRiC/CCT cooperates with the chaperone prefoldin/GIMc (PFD). These hetero-oligomeric chaperones associate in a defined architecture, through a conserved interface of electrostatic contacts that serves as a pivot point for a TRiC-PFD conformational cycle. PFD pivots around a conserved electrostatic interface with TRiC/CCT PFD acts on TRiC/CCT-substrate complex to enhance the rate of the folding reaction, overview. The suprachaperone assembly formed by PFD and TRiC is essential to prevent toxic conformations and ensure effective cellular proteostasis
physiological function
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
eukaryotic cytoplasmic chaperonins are key elements responsible for this proper folding of proteins, including that of cytoskeletal components. Protein folding is mediated in the eukaryotic cytosol by the TCP-1 ring large multi-subunit complex (TRiC), also called CCT. TRiC/CCT chaperonins are essential for maintaining myofibril organization, cardiac physiological rhythm, and lifespan. TRiC/CCT chaperonins are essential for actin and myosin containing myofibril integrity. Both the orchestration of protein folding and circadian rhythms mediated by CCT chaperonin are critical for maintaining heart contractility
physiological function
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
subunit CCT1 is involved in fragile X-linked and cell identity, subunit CCT5 is required for autophagy
physiological function
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
subunit CCT5 is involved in thin filament assembly at the sarcomere Z-disk. Three BBS proteins which have homology to chaperonins, BBS6, BBS10 and BBS12, and a sub-complex of CCT proteins (CCT1, 2, 3, 4, 5 and 8) mediate the association of two beta-propeller domain-containing proteins, BBS7 and BBS2, during the assembly process of the BBSome. BBS6, -10 and -12 are vertebrate-specific proteins and it may be an evolutionary connection that one of the two absent CCT subunits in the BBS-CCT complex, CCT6, has a vertebrate-specific isoform, CCT6B, which is abundant in testis CCT. CCT6 self-interacts across the CCT rings which probably permits isoform interchange, and therefore, it is possible that one of the BBS subunits has hijacked this mechanism and is able to slot into the CCT6 position in the CCT ring system
physiological function
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
subunit CCT8 and the CCT complex are involved in Ras signalling and morphogenesis, and in the polarisome and cell polarity, respectively
physiological function
P11983; P80314; P80318; P80315; P80316; P80317; P80313; P42932
subunits CCT1, CCT3, CCT4 and CCT8 are all essential for spermatogenesis. The CCT3/gamma domain in FAB1p is involved in autophagy
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
subunits CCT2 and CCT7 interact with tumour suppressors p53 and VHL, respectively. The enzyme is involved in breast cancer signaling via STAT3, and in apoptosis via CCT2 and PDC5, or BAG3. Subunit CCT8 interacts with AML-ETO in leukemia. Subunits CCT2, 3, and 8 are involved in mRNA overexpression in cancer cells. Subunit CCT7 is involved in fibroblast motility. Subunits CCT2, 5, and 7 are required for autophagy. The CCT complex is involved in disassembly of the mitotic checkpoint, artherosclerosis, and cell survival, and in several other cellular processes, overview
physiological function
A0A1S6LQX4; A0A1S6LQU3; A0A1S6LQU0; A0A1S6LQU6; A0A1S6LQU1; A0A1S6LQU9; A0A1S6LQW6; A0A1S6LQW7
the chaperonin containing t-complex polypeptide-1 which is also known as TRiC plays a central role in cellular homeostasis by facilitating the folding of approximately 10% or more of newly synthesized proteins which include tubulins, actins, luciferin, Von Hippel-Lindau disease tumor suppressor (VHL), histone deacetylase 3, and other client proteins. Enzyme GaTRiC is important in cell regulation
physiological function
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
the chaperonin-containing t-complex polypeptide 1 (CCT or TRiC) assists protein folding in an ATP-dependent manner. CCT/TRiC has been found to mediate the folding of beta-actin, alpha- and beta-tubulin, and several hundred other proteins in addition to several clinically important proteins such as p53 and the oncoprotein AML1-ETO
physiological function
P28769; Q940P8; Q84WV1; Q9LV21; O04450; Q9M888; Q9SF16; Q94K05
the enzyme complex CCT is involved in stem cell identity and protein translocation
physiological function
P41988; P47207; Q9N4J8; P47208; P47209; P46550; Q9TZS5; Q9N358
the enzyme is involved in invasion and lifespan extension
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
the essential mammalian cytosolic chaperonin TRiC (T-complex polypeptide-1 ring complex, also known as CCT or chaperonin containing TCP1) is an ATPase with an intricate architecture, which allows it to fold many essential proteins. TRiC substrates include cell cycle regulators, signaling proteins, and cytoskeletal components. TRiC has been suggested to play a critical role in cancer cell development by modulating the folding and activity of client proteins involved in oncogenesis, such as the tumor suppressor proteins Von Hippel-Lindau (VHL) and p53, as well as the oncogenic protein STAT3 and AML1-ETO. AML1-ETO is the translational product of a chimeric gene created by the stable chromosome translocation. It causes acute myeloid leukemia (AML) by dysregulating the expression of genes critical for myeloid cell development and differentiation and has been reported to bind multiple subunits of the mammalian cytosolic chaperonin TRiC (or CCT), primarily through its DNA binding domain (AML1-175). Through these interactions, TRiC plays an important role in the synthesis, folding, and activity of AML1-ETO. The structure reveals that AML1-175 associates directly with a specific subset of TRiC subunits in the open conformation. The mammalian cytosolic chaperonin TRiC (or CCT) modulates the synthesis, folding and activity of AML1-ETO by direct association, primarily through its DNA-binding domain (AML1-175), and that HSP70 promotes this interaction. AML1-ETO relies on the molecular chaperone network to fold and function properly
physiological function
Thermochaetoides thermophila
-
the eukaryotic group II chaperonin, the chaperonin-containing t-complex polypeptide 1 (CCT), plays an important role in cytosolic proteostasis. About 10% of cytosolic proteins interact with CCT during their folding process. Expression of CCT is not induced by stress conditions, but it seems to be required for folding newly synthesized polypeptides. Despite its substrate specificity, CCT is absolutely required for folding many essential proteins, including cytoskeletal proteins such as tubulin and actin, as well as cell cycle regulators, such as CDC20 and CDH1
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
the eukaryotic TRiC chaperonin controls reovirus replication through outer-capsid folding, TRiC (also called CCT) is a cellular factor required for late events in the replication of mammalian reovirus. TRiC is essential for reovirus replication. TRiC forms a complex with the reovirus sigma3 outer-capsid protein and folds sigma3 into its into a native, assembly-competent conformation. TRiC renders sigma3 into a conformation that can assemble onto mature particles, which is a critical step in viral assembly, determination of a dynamic pathway for the efficient folding of viral capsid components mediated by the TRiC chaperonin, overview. Six of the eight subunits of the TRiC chaperonin (CCT1, CCT2, CCT3, CCT4, CCT5, and CCT8) are implicated in viral replication, siRNA mutational analysis, overview
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
The hetero-oligomeric chaperonin of eukarya, TRiC, is required to fold the cytoskeletal protein actin. The eukaryotic chaperone complex TRiC, but not the simpler bacterial chaperonin system, GroEL/GroES, is able to induce the proper folding of actin. Actin fails to fold spontaneously, strictly requiring TRiC chaperonin for folding. Actin binding to TRiC specifies a unique topology for productive folding. ATP binding induces an asymmetric TRiC intermediate and selective actin release. Stepwise folding on and inside TRiC allows actin to access the native state
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
the malaria parasite exports numerous proteins into its host red blood cell (RBC). Proteins are first routed through the secretory system, into the parasitophorous vacuole (PV), a membranous compartment enclosing the parasite. Proteins are then translocated across the PV membrane in a process requiring ATP and unfolding. Once in the RBC compartment the exported proteins are then refolded and further trafficked to their final localizations. Chaperones are important in the unfolding and refolding processes. The parasite TRiC chaperonin complex is exported, and is involved in trafficking of exported effectors. Essential role for PfTRiC within the parasite compartment
physiological function
Q8II43; O97247; Q8I5C4; C0H5I7; O97282; C6KST5; O77323; O96220
the malaria parasite exports numerous proteins into its host red blood cell (RBC). Proteins are first routed through the secretory system, into the parasitophorous vacuole (PV), a membranous compartment enclosing the parasite. Proteins are then translocated across the PV membrane in a process requiring ATP and unfolding. Once in the RBC compartment the exported proteins are then refolded and further trafficked to their final localizations. Chaperones are important in the unfolding and refolding processes. The parasite TRiC chaperonin complex is exported, and is involved in trafficking of exported effectors. Essential role for PfTRiC within the parasite compartment. Subunit PfTRiC-theta is essential for asexual parasite growth
physiological function
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
the TCP-1 ring complex (TRiC) is a multi-subunit group II chaperonin that assists nascent or misfolded proteins to attain their native conformation in an ATP-dependent manner. Zebrafish chaperonin TRiC has a specific role in the biogenesis of skeletal muscle alpha-actin during sarcomere assembly in myofibers. TRiC only enhances the folding of skeletal alpha-actin at the sarcomeric Z-disk. ATP binding by subunit CCT5 is required for folding of alpha-actin, but probably not tubulin. TRiC function is required for myopathic actin to form rods in nemaline myopathy. TRiC causes aggregation of myopathic alpha-actin mutant variants in nemaline myopathy. ATP Binding by CCT5 is specific for skeletal muscle alpha-actin but not tubulin processing. TRiC function is required for nemaline rod formation resulting from the expression of disease-causing skeletal muscle alpha-actin variants
physiological function
P11983; P80314; P80318; P80315; P80316; P80317; P80313; P42932
TRiC directly interacts with heat shock factor protein 1 (HSF1) and represses its transcriptional activity
physiological function
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
TRiC is a multi-protein chaperone complex that functions to assist polypeptides in achieving a functional three-dimensional configuration. It has an essential role in folding the highly abundant cytoskeletal proteins actin and tubulin The TCP1 and CCT2 genes both encode for components of a multi-protein chaperone complex in the cell known as the TCP1 containing ring complex (TRiC). The TRiC subunits TCP1 and CCT2, and potentially the entire TRiC complex, play a role in breast cancer. TCP1 and CCT2 are recurrently altered in breast cancer and necessary for growth/survival of breast cancer cells in vitro, they are determinants of overall survival in breast cancer patients. Expression of TCP1 is regulated by driver oncogene activation of PI3K signaling in breast cancer. Role for CCT2 in cell cycle progression. The TCP1 subunit of TRiC is both regulated by FGFR2 and necessary for cell growth in SUM-52 cells. the TCP1 subunit of TRiC is regulated by FGFR2, necessary for proliferation of breast cancer cells and associated with poor overall survival of breast cancer patients
physiological function
-
the group II chaperonin captures an unfolded protein while in its open conformation and then mediates the folding of the protein during ATP-driven conformational change cycle
-
physiological function
-
group II chaperonin proteins assist in the folding of nascent polypeptides and also refold unfolded proteins in an ATP-dependent manner. Chaperonin-mediated protein folding is dependent on the closure and opening of a built-in lid, which is controlled by the ATP hydrolysis cycle
-
physiological function
-
chaperonins are ubiquitous molecular chaperones performing an ATP-dependent conformational change of the cavity that induces the folding of an unfolded protein that is captured in the cavity
-
physiological function
-
chaperonin TCP-1 ring complex (TRiC) supports proper folding of numerous proteins including cell cycle regulators and mediates protein quality control. TRiC/CCT supports mitotic exit and entry into endocycle in Drosophila melanogaster. The evolutionarily conserved chaperonin TRiC is a regulator of the mitotic-to-endocycle switch (MES), which is critical for the prothoracic gland (PG) to upregulate biosynthesis of the steroid hormone ecdysone. TRiC supports proper MES and endocycle progression by regulating Fzr folding. TRiC-mediated protein quality control is proposed to be a conserved mechanism supporting MES and endocycling, as well as subsequent terminal differentiation. TRiC is required for ecdysone biosynthesis in the PG to induce the larval-to-pupal transition. TRiC downregulates CycA by regulating Fzr nuclear translocation to promote MES and endocycling
-
physiological function
-
CCT is a key modulator of echinocandin susceptibility
-
physiological function
-
chaperonins are essential for protein folding in all domains of life. They stand out among ATP-dependent chaperones in that they form large 800-1000 kDa double-ring complexes with an internal chamber in each ring. Their basic function is to provide a nano-cage for the folding of single protein molecules to occur in isolation, unimpaired by aggregation. Enzyme TRiC mediates protein folding by encapsulation and displays negative inter-ring cooperativity, favoring asymmetric complexes with one ring open and the other closed. The inner surface of the TRiC chamber is divided into two halves with opposite charge character. This charge asymmetry coincides with an asymmetry in ATP binding and hydrolysis: four adjacent subunits have high affinity for ATP and neutral or negative surface charge, while the other four subunits have low affinity for ATP and positive surface charge. Chamber closure and release of substrate protein can initiate asymmetrically and proceed in a sequential mechanism. TRiC also binds and masks polyQ-expanded fragments of the Huntington's disease protein, inhibiting their toxic aggregation
-
physiological function
-
subunit CCT8 and the CCT complex are involved in Ras signalling and morphogenesis, and in the polarisome and cell polarity, respectively
-
physiological function
-
the chaperonin-containing t-complex polypeptide 1 (CCT or TRiC) assists protein folding in an ATP-dependent manner. CCT/TRiC has been found to mediate the folding of beta-actin, alpha- and beta-tubulin, and several hundred other proteins in addition to several clinically important proteins such as p53 and the oncoprotein AML1-ETO
-
physiological function
-
chaperonins are molecular machines that use ATP-driven cycles to assist misfolded substrate proteins to reach the native state. During the functional cycle, these machines adopt distinct nucleotide-dependent conformational states, which reflect large-scale allosteric changes in individual subunits. Archaeal and eukaryotic chaperonins undergo sequential subunit motions, analysis of the mode of action and mechanism. The thermosome double-ring structure has large contribution from higher-frequency modes
-
physiological function
-
chaperonins have elaborate allosteric mechanisms to regulate their functional cycle. Long-range negative cooperativity between the two rings ensures alternation of the folding chambers. No Positive intra-ring cooperativity in group II enzymes. Thermosomes use a non-specific, hydrophobic-based substrate recognition mechanism involving the helical protrusion, release of trapped substrate after closure of the chaperonin cavity
-
physiological function
-
chaperonins are ubiquitous molecular chaperones performing an ATP-dependent conformational change of the cavity that induces the folding of an unfolded protein that is captured in the cavity
-
additional information
-
ATP hydrolysis enhances the intra-ring TRiC subunit interactions, asymmetrically closed conformation of TRiC and expansion of the folding chambers in the ATP hydrolysis transition state, and chamber closing mechanisms of TRiC, structure modeling, overview. Mechanism of TRiC negative inter-ring cooperativity. The TRiC lid remains open in three states of the cycle: ATP bound, ADP bound, and nucleotide free
additional information
chaperonins are ubiquitous molecular chaperones with the subunit molecular mass of 60 kDa. They exist as double-ring oligomers with central cavities. An ATP-dependent conformational change of the cavity induces the folding of an unfolded protein that is captured in the cavity. Inter-ring communication is dispensable in the reaction cycle of group II chaperonins. Group II chaperonins do not require a co-chaperonin but have a built-in lid that is composed of a helical protrusion in the apical domain. The built-in lid seals off the central cavity and induces a conformational change to assist the folding of the trapped substrate, molecular mechanism analysis. Structure modeling of wild-type and mutant enzyme oligomers using structure of Thermococcus sp. JCM 11816, PDB ID 1Q2V, overview
additional information
chaperonins are ubiquitous molecular chaperones with the subunit molecular mass of 60 kDa. They exist as double-ring oligomers with central cavities. An ATP-dependent conformational change of the cavity induces the folding of an unfolded protein that is captured in the cavity. Inter-ring communication is dispensable in the reaction cycle of group II chaperonins. Group II chaperonins do not require a co-chaperonin but have a built-in lid that is composed of a helical protrusion in the apical domain. The built-in lid seals off the central cavity and induces a conformational change to assist the folding of the trapped substrate, molecular mechanism analysis. Structure modeling of wild-type and mutant enzyme oligomers using structure of Thermococcus sp. JCM 11816, PDB ID 1Q2V, overview
additional information
determination of ATP-dependent dynamics of a group II chaperonin at the single-molecule level with highly accurate rotational axes views by UV light-triggered diffracted X-ray tracking, using caged-ATP and stopped-flow fluorometry. The closed ring twists counterclockwise and the twisted ring reverted to the original open-state with a clockwise motion, the biphasic lid-closure process occurs with unsynchronized closure and a synchronized counterclockwise twisting motion
additional information
determination of ATP-dependent dynamics of a group II chaperonin at the single-molecule level with highly accurate rotational axes views by UV light-triggered diffracted X-ray tracking, using caged-ATP and stopped-flow fluorometry. The closed ring twists counterclockwise and the twisted ring reverted to the original open-state with a clockwise motion, the biphasic lid-closure process occurs with unsynchronized closure and a synchronized counterclockwise twisting motion
additional information
-
enzyme structure and architecture comparisons and modeling, structure-function analysis of group II chaperonins, ATP-driven conformational cycle of the group II chaperonin, overview
additional information
-
enzyme structure and architecture comparisons and modeling, structure-function analysis of group II chaperonins, ATP-driven conformational cycle of the group II chaperonin, overview
additional information
-
enzyme structure and architecture comparisons and modeling, structure-function analysis of group II chaperonins, ATP-driven conformational cycle of the group II chaperonin, overview
additional information
group II chaperonins cycle between an open, substrate-receptive conformation and a closed, substrate-trapping conformation CCT (chaperonin containing TCP1) or TRiC (TCP1 ring complex) is composed of eight distinct subunits (CCTalpha-1, CCTbeta-2, CCTgamma-3, CCTdelta-4, CCTepsilon-5, CCTzeta-6, CCTeta-7 and CCTtheta-8) organized in a unique intra- and inter-ring arrangement, structure modeling, detailed overview. The substrate-binding region in each of the subunits bears charged and hydrophilic residues in some subunits, whereas other subunits have hydrophobic residues
additional information
group II chaperonins cycle between an open, substrate-receptive conformation and a closed, substrate-trapping conformation, structure modeling, detailed overview
additional information
group II chaperonins cycle between an open, substrate-receptive conformation and a closed, substrate-trapping conformation, structure modeling, detailed overview
additional information
group II chaperonins exist as an 8- or 9-membered rotationally symmetrical double-ring in a toridal structure composed of homologous subunits of about 60 kDa. Each ring has a large central cavity in which a non-native protein can undergo productive folding in an ATP-dependent manner. A unique structural feature, termed the helical protrusion, acts as a built-in lid to seal off the central cavity of group II chaperonins during folding. Opening and closing of the folding chamber is controlled by a conformational cycle driven by ATP binding and hydrolysis. All chaperonins share a similar subunit architecture consisting of three distinct domains as follows: an ATP-binding equatorial domain, a distal apical domain harboring the polypeptide-binding sites, and an intermediate hinge domain
additional information
group II chaperonins exist as an 8- or 9-membered rotationally symmetrical double-ring in a toridal structure composed of homologous subunits of about 60 kDa. Each ring has a large central cavity in which a non-native protein can undergo productive folding in an ATP-dependent manner. A unique structural feature, termed the helical protrusion, acts as a built-in lid to seal off the central cavity of group II chaperonins during folding. Opening and closing of the folding chamber is controlled by a conformational cycle driven by ATP binding and hydrolysis. All chaperonins share a similar subunit architecture consisting of three distinct domains as follows: an ATP-binding equatorial domain, a distal apical domain harboring the polypeptide-binding sites, and an intermediate hinge domain
additional information
group II chaperonins exist as an 8- or 9-membered rotationally symmetrical double-ring in a toridal structure composed of homologous subunits of about 60 kDa. Each ring has a large central cavity in which a non-native protein can undergo productive folding in an ATP-dependent manner. A unique structural feature, termed the helical protrusion, acts as a built-in lid to seal off the central cavity of group II chaperonins during folding. Opening and closing of the folding chamber is controlled by a conformational cycle driven by ATP binding and hydrolysis. All chaperonins share a similar subunit architecture consisting of three distinct domains as follows: an ATP-binding equatorial domain, a distal apical domain harboring the polypeptide-binding sites, and an intermediate hinge domain
additional information
group II chaperonins generally contain eight subunits per ring and have a tendency to heterooligomer formation. TRiC contains eight paralogous subunits per ring assembled in a defined order
additional information
group II chaperonins generally contain eight subunits per ring and have a tendency to heterooligomer formation. TRiC contains eight paralogous subunits per ring assembled in a defined order
additional information
mechanisms and the structure-function relationships in the complex protein systems, structural dynamics, allostery, and associated conformational rearrangements, overview. Group II chaperonins cycle between an open, substrate-receptive conformation and a closed, substrate-trapping conformation, structure modeling, detailed overview
additional information
mechanisms and the structure-function relationships in the complex protein systems, structural dynamics, allostery, and associated conformational rearrangements, overview. Group II chaperonins cycle between an open, substrate-receptive conformation and a closed, substrate-trapping conformation, structure modeling, detailed overview
additional information
possesses two chaperonins, cold-inducible CpkA and heat-inducible CpkB, which are involved in adaptation to low and high temperatures, respectively
additional information
possesses two chaperonins, cold-inducible CpkA and heat-inducible CpkB, which are involved in adaptation to low and high temperatures, respectively
additional information
possesses two chaperonins, cold-inducible CpkA and heat-inducible CpkB, which are involved in adaptation to low and high temperatures, respectively. Clear correlation between the CpkA-type chaperonin gene copy number and growth temperature
additional information
possesses two chaperonins, cold-inducible CpkA and heat-inducible CpkB, which are involved in adaptation to low and high temperatures, respectively. Clear correlation between the CpkA-type chaperonin gene copy number and growth temperature
additional information
reaction cycle model for group II chaperonins, ATP-binding, stopped-flow fluorometry and stopped-flow small-angle X-ray scattering, overview
additional information
reaction cycle model for group II chaperonins, ATP-binding, stopped-flow fluorometry and stopped-flow small-angle X-ray scattering, overview
additional information
three-dimensional structures of nucleotide states of thermosome and allosteric communications within the archaeal chaperonin thermosome, open and closed states and transitional conformation changes, computational analysis, overview
additional information
three-dimensional structures of nucleotide states of thermosome and allosteric communications within the archaeal chaperonin thermosome, open and closed states and transitional conformation changes, computational analysis, overview
additional information
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
all CCT subunits are required for the CCT complex function
additional information
analysis of molecular mechanisms of group II CPNs, ATP is involved in the protein folding inducing conformational changes of substrate and enzyme, overview
additional information
ATP hydrolysis is important to attain the closed conformation of the enzyme
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
conformational dynamics of native and chaperonin-bound actin by equilibrium hydrogen/deuterium exchange-mass spectrometry, overview
additional information
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
determination of kinetic intermediates in the sequential allosteric pathway of CCT/TRiC, kinetic mechanism and model, overview
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
eight distinct subunits are uniquely organized, providing a favorable folding cavity for specific client proteins such as tubulin and actin. Because of its heterogeneous subunit composition, CCT complex has polarized inner faces, which may underlie an essential part of its chaperonin function. Molecular organization of the eukaryote chaperonin known as CCT/TRiC complex, overview. Dynamics-based structural profiling of asymmetrically oriented chaperonin function
additional information
-
eight distinct subunits are uniquely organized, providing a favorable folding cavity for specific client proteins such as tubulin and actin. Because of its heterogeneous subunit composition, CCT complex has polarized inner faces, which may underlie an essential part of its chaperonin function. Molecular organization of the eukaryote chaperonin known as CCT/TRiC complex, overview. Dynamics-based structural profiling of asymmetrically oriented chaperonin function
additional information
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
enzyme structure homology modelling using the structure of TRiC/ADP (PDB ID 4A13, Bos taurus) and of GroES and GroEL/ES/ATP (PDB ID 1AON, Escherichia coli). Structure comparisons, overview
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
human TRiC subunits interact with each other, but do not interact with export related parasite proteins from Plasmodium falciparum in extracts from trophozoite-stage infected red blood cells
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
individual subunits of TRiC have been shown to have protein-folding capacity
additional information
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
large conformational changes occur upon nucleotide binding and hydrolysis. The conformational cycling begins with the binding of ATP and a transition of the complex to the closed conformation required for ATP hydrolysis to bring the lid helices into close proximity. Opening of the lid occurs in conjunction with releasing ADP from the active site. The complex can exist in an asymmetrical conformation with one ring closed and one open even during ATP cycling conditions, suggesting a inter-ring allosteric model mediated through a two-stroke mechanism. Molecular architecture of TRiC/CCT from the crystal structure, PDB ID 2XSM
additional information
Thermochaetoides thermophila
-
protein-folding mechanism mediated by group II chaperonins, overview. Asymmetry in the function and dynamics is shown by the cytosolic group II chaperonin CCT/TRiC. CtCCT subunits had similar characteristics in the ATP-binding pocket
additional information
Q32L40; Q3ZBH0; Q3T0K2; F1N0E5; F1MWD3; Q3MHL7; Q2NKZ1; Q3ZCI9
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
Q55BM4; Q54ES9; Q54TH8; Q54CL2; Q54TD3; Q76NU3; Q54ER7; Q552J0
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
P41988; P47207; Q9N4J8; P47208; P47209; P46550; Q9TZS5; Q9N358
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
P28480; Q5XIM9; Q6P502; Q7TPB1; Q68FQ0; Q3MHS9; D4AC23; D4ACB8
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
P28769; Q940P8; Q84WV1; Q9LV21; O04450; Q9M888; Q9SF16; Q94K05
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
Q59QB7; Q59YC4; Q5AK16; Q59Z12; A0A1D8PMN9; Q59YH4; P47828
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
additional information
P11983; P80314; P80318; P80315; P80316; P80317; P80313; P42932
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview. CCT protein recognition sequences and structure
additional information
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview. The individual CCT subunits have different functions in cells. CCT-folding activity stalls at low ATP concentrations. Binding of the non-hydrolysable ATP analog adenosine 5'-(beta,gamma-imino)-triphosphate to the ternary complex leads to 3fold faster release of actin from CCT following the addition of ATP, suggesting a two-step folding process with a conformational change occurring upon closure of the cavity and a subsequent near-final folding step involving packing of the C-terminus to the native-like state. Proposed one-dimensional free-energy landscape for actin folding, overview. Actin folding and unfolding behaviour in vitro and thermodynamics
additional information
Q8II43; O97247; Q8I5C4; C0H5I7; O97282; C6KST5; O77323; O96220
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview. The Plasmodium falciparum actin proteins are more divergent compared with other eukaryotic actins, about 80% homologous, and so are their eight CCT complex and three phosducin-like cofactor proteins. CCT subunits and actin and tubulin are ART molecular target(s) in the asexual stages of the malaria parasite
additional information
A0A1S6LQX4; A0A1S6LQU3; A0A1S6LQU0; A0A1S6LQU6; A0A1S6LQU1; A0A1S6LQU9; A0A1S6LQW6; A0A1S6LQW7
structure-functional analysis, the three-dimensional structure of GaTRiC is modeled using the Saccharomyces cerevisiae TRiC structure (PDB ID 4V81) as template. Determination of ionic interactions of GaTRiC residues
additional information
-
structure-functional analysis, the three-dimensional structure of GaTRiC is modeled using the Saccharomyces cerevisiae TRiC structure (PDB ID 4V81) as template. Determination of ionic interactions of GaTRiC residues
additional information
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
the CCT2 subunit pair forms an unexpected Z shape. ATP binding induces a dramatic conformational change on the CCT2 side, thereby suggesting that CCT2 plays an essential role in TRiC allosteric cooperativity. The TRiC nucleotide cycle coordinates with its mechanical cycle in preparing folding intermediates for further productive folding, overview. The five ATP-binding subunits (CCT1-CCT4-CCT2-CCT5-CCT7) are located symmetrically around the on-axis CCT2 subunit in both rings and occupying one entire side of the complex. Accordingly, the ATP-driven conformational changes prixadmarily occur on that side. In contrast, the opposite CCT6 side of the complex (CCT8-CCT6-CCT3), most probably with ADP bound or partially occupying the nucleotide pocket, remains mostly poised in the ATP binding process. Thus, it appears that TRiC has evolved to be structurally divided into two sides. In addition, all of the sixteen subunits have their nucleotide pockets fully occupied in the further-refined yeast TRiC X-ray structure in the conformation with both rings tightly closed, thus suggesting that the subunits on the CCT6 side also have ATP-binding and ATP-hydrolysis abilities
additional information
-
the CCT2 subunit pair forms an unexpected Z shape. ATP binding induces a dramatic conformational change on the CCT2 side, thereby suggesting that CCT2 plays an essential role in TRiC allosteric cooperativity. The TRiC nucleotide cycle coordinates with its mechanical cycle in preparing folding intermediates for further productive folding, overview. The five ATP-binding subunits (CCT1-CCT4-CCT2-CCT5-CCT7) are located symmetrically around the on-axis CCT2 subunit in both rings and occupying one entire side of the complex. Accordingly, the ATP-driven conformational changes prixadmarily occur on that side. In contrast, the opposite CCT6 side of the complex (CCT8-CCT6-CCT3), most probably with ADP bound or partially occupying the nucleotide pocket, remains mostly poised in the ATP binding process. Thus, it appears that TRiC has evolved to be structurally divided into two sides. In addition, all of the sixteen subunits have their nucleotide pockets fully occupied in the further-refined yeast TRiC X-ray structure in the conformation with both rings tightly closed, thus suggesting that the subunits on the CCT6 side also have ATP-binding and ATP-hydrolysis abilities
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
TRiC redistributes to sites of viral replication. The TRiC chaperonin forms a complex with the reovirus sigma3 outer-capsid protein through an ATP-dependent mechanism
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
while AML1-175 is folded by TRiC to achieve its native function, ATP hydrolysis does not suffice to trigger its release from the chaperonin
additional information
-
reaction cycle model for group II chaperonins, ATP-binding, stopped-flow fluorometry and stopped-flow small-angle X-ray scattering, overview
-
additional information
-
determination of ATP-dependent dynamics of a group II chaperonin at the single-molecule level with highly accurate rotational axes views by UV light-triggered diffracted X-ray tracking, using caged-ATP and stopped-flow fluorometry. The closed ring twists counterclockwise and the twisted ring reverted to the original open-state with a clockwise motion, the biphasic lid-closure process occurs with unsynchronized closure and a synchronized counterclockwise twisting motion
-
additional information
-
chaperonins are ubiquitous molecular chaperones with the subunit molecular mass of 60 kDa. They exist as double-ring oligomers with central cavities. An ATP-dependent conformational change of the cavity induces the folding of an unfolded protein that is captured in the cavity. Inter-ring communication is dispensable in the reaction cycle of group II chaperonins. Group II chaperonins do not require a co-chaperonin but have a built-in lid that is composed of a helical protrusion in the apical domain. The built-in lid seals off the central cavity and induces a conformational change to assist the folding of the trapped substrate, molecular mechanism analysis. Structure modeling of wild-type and mutant enzyme oligomers using structure of Thermococcus sp. JCM 11816, PDB ID 1Q2V, overview
-
additional information
-
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
-
additional information
-
possesses two chaperonins, cold-inducible CpkA and heat-inducible CpkB, which are involved in adaptation to low and high temperatures, respectively
-
additional information
-
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview
-
additional information
-
group II chaperonins generally contain eight subunits per ring and have a tendency to heterooligomer formation. TRiC contains eight paralogous subunits per ring assembled in a defined order
-
additional information
-
structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring, overview. The individual CCT subunits have different functions in cells. CCT-folding activity stalls at low ATP concentrations. Binding of the non-hydrolysable ATP analog adenosine 5'-(beta,gamma-imino)-triphosphate to the ternary complex leads to 3fold faster release of actin from CCT following the addition of ATP, suggesting a two-step folding process with a conformational change occurring upon closure of the cavity and a subsequent near-final folding step involving packing of the C-terminus to the native-like state. Proposed one-dimensional free-energy landscape for actin folding, overview. Actin folding and unfolding behaviour in vitro and thermodynamics
-
additional information
-
determination of kinetic intermediates in the sequential allosteric pathway of CCT/TRiC, kinetic mechanism and model, overview
-
additional information
-
three-dimensional structures of nucleotide states of thermosome and allosteric communications within the archaeal chaperonin thermosome, open and closed states and transitional conformation changes, computational analysis, overview
-
additional information
-
mechanisms and the structure-function relationships in the complex protein systems, structural dynamics, allostery, and associated conformational rearrangements, overview. Group II chaperonins cycle between an open, substrate-receptive conformation and a closed, substrate-trapping conformation, structure modeling, detailed overview
-
additional information
-
group II chaperonins cycle between an open, substrate-receptive conformation and a closed, substrate-trapping conformation, structure modeling, detailed overview
-
additional information
-
chaperonins are ubiquitous molecular chaperones with the subunit molecular mass of 60 kDa. They exist as double-ring oligomers with central cavities. An ATP-dependent conformational change of the cavity induces the folding of an unfolded protein that is captured in the cavity. Inter-ring communication is dispensable in the reaction cycle of group II chaperonins. Group II chaperonins do not require a co-chaperonin but have a built-in lid that is composed of a helical protrusion in the apical domain. The built-in lid seals off the central cavity and induces a conformational change to assist the folding of the trapped substrate, molecular mechanism analysis. Structure modeling of wild-type and mutant enzyme oligomers using structure of Thermococcus sp. JCM 11816, PDB ID 1Q2V, overview
-
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
H147R
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
naturally occuring mutation of subunit CCT5
D386A
site-directed mutagenesis, introduction of D386A into Mm-cpn significantly reduces its ability to complement for loss of GroES and GroEL, loss of ATPase activity severely affects the complementing ability of the wild-type and mutant Mm-cpn proteins
G160S
-
the TRiC-like mutant G160S of MmCpn has a drastically slower rate of ATP hydrolysis, roughly equivalent to the steady-state hydrolysis of eukaryotic TRiC
K216A
site-directed mutagenesis, the mutant enzyme moderately complements the GroEL-deletion mutant Escherichia coli strain TAB21
K216C
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
K216D
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
K216E
random mutagenesis, growth for the mutants is clearly faster than for wild-type Mm-cpn organisms under GroES/GroEL-limiting conditions, improved phenotype in Escherichia coli under GroEL- and GroES-depleting conditions. The mutant can effectively hydrolyze ATP
K216E/D386A
site-directed mutagenesis, introduction of D386A into Mm-cpn significantly reduces its ability to complement for loss of GroES and GroEL, loss of ATPase activity severely affects the complementing ability of the wild-type and mutant Mm-cpn proteins
K216F
site-directed mutagenesis, the mutant enzyme moderately complements the GroEL-deletion mutant Escherichia coli strain TAB21
K216G
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
K216L
site-directed mutagenesis, the mutant enzyme moderately complements the GroEL-deletion mutant Escherichia coli strain TAB21
K216P
site-directed mutagenesis, the mutant enzyme moderately complements the GroEL-deletion mutant Escherichia coli strain TAB21
K216Q
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
K216R
site-directed mutagenesis, the mutant enzyme slightly complements the GroEL-deletion mutant Escherichia coli strain TAB21
K216S
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
K216T
site-directed mutagenesis, the mutant enzyme moderately complements the GroEL-deletion mutant Escherichia coli strain TAB21
K216V
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
K216Y
site-directed mutagenesis, the mutant enzyme moderately complements the GroEL-deletion mutant Escherichia coli strain TAB21
M223E
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223F
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223G
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223I/D386A
site-directed mutagenesis, introduction of D386A into Mm-cpn significantly reduces its ability to complement for loss of GroES and GroEL, loss of ATPase activity severely affects the complementing ability of the wild-type and mutant Mm-cpn proteins
M223L
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223R
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223S
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223V
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223W
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
M223Y
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
D545G
site-directed mutagenesis, the mutant shows a stabilities similar to the wild-type CpkA
D545M
site-directed mutagenesis, the mutant shows slightly higher stabilities than that of wild-type CpkA
E530G
site-directed mutagenesis, the mutant strain DA4 shows increased ATPase activity. The CpkA-E530G mutation prevents cold denaturation of proteins under cold-stress conditions, thereby enabling cells to grow in cooler environments
E530M
site-directed mutagenesis, the mutant shows a stabilities similar to the wild-type CpkA
P538G
site-directed mutagenesis, the mutant shows slightly higher stabilities than that of wild-type CpkA
P538M
site-directed mutagenesis, the mutant shows a stabilities similar to the wild-type CpkA
Q533G
site-directed mutagenesis
Q533M
site-directed mutagenesis, the mutant shows a stabilities similar to the wild-type CpkA
D64A/D393A
site-directed mutagenesis, an ATPase-deficient mutant, the mutant also does not exhibit ATPase-dependent conformational change
D64A/D393A/K485W
site-directed mutagenesis, an ATPase-deficient mutant, the mutant also does not exhibit ATPase-dependent conformational change, the mutant lacks ATP-dependent refolding activity, nucleotide binding and ATP-dependent conformational change kinetics, overview
K165A/K485W
site-directed mutagenesis, ATPase inactive mutant that can partially prevent the spontaneous refolding ofGFP and refold it in an ATP-dependent manner
L265W
site-directed mutagenesis, replacement of amino acid L265 with Trp partially impairs the protein folding activity, eight Trp residues are thought to come close in the closed conformation. The resulting steric hindrance might interrupt the conformational changes required for protein folding. Although ATP hydrolysis activity is almost completely lost in the absence of K+, slight ATP-dependent folding activity is observed
L56W
site-directed mutagenesis, the mutant exhibits nearly the same level of protein folding activity as the wild-type protein
D64A/D393A
-
site-directed mutagenesis, an ATPase-deficient mutant, the mutant also does not exhibit ATPase-dependent conformational change
-
D64A/D393A/K485W
-
site-directed mutagenesis, an ATPase-deficient mutant, the mutant also does not exhibit ATPase-dependent conformational change, the mutant lacks ATP-dependent refolding activity, nucleotide binding and ATP-dependent conformational change kinetics, overview
-
K165A/K485W
-
site-directed mutagenesis, ATPase inactive mutant that can partially prevent the spontaneous refolding ofGFP and refold it in an ATP-dependent manner
-
L265W
-
site-directed mutagenesis, replacement of amino acid L265 with Trp partially impairs the protein folding activity, eight Trp residues are thought to come close in the closed conformation. The resulting steric hindrance might interrupt the conformational changes required for protein folding. Although ATP hydrolysis activity is almost completely lost in the absence of K+, slight ATP-dependent folding activity is observed
-
L56W
-
site-directed mutagenesis, the mutant exhibits nearly the same level of protein folding activity as the wild-type protein
-
K165A/K485W
-
site-directed mutagenesis, ATPase inactive mutant that can partially prevent the spontaneous refolding ofGFP and refold it in an ATP-dependent manner
-
K485W
-
site-directed mutagenesis, the mutant shows ATP binding and conformational change upon ATP binding
-
M223I
random mutagenesis, growth for the mutants is clearly faster than for wild-type Mm-cpn organisms under GroES/GroEL-limiting conditions, improved phenotype in Escherichia coli under GroEL- and GroES-depleting conditions. The mutant can effectively hydrolyze ATP
M223I
site-directed mutagenesis, the mutant enzyme complements the GroEL-deletion mutant Escherichia coli strain TAB21 well
C450Y
P28480; Q5XIM9; Q6P502; Q7TPB1; Q68FQ0; Q3MHS9; D4AC23; D4ACB8
naturally occuring mutation in subunit CCT4
C450Y
-
naturally occuring mutation in subunit CCT4
-
G345D
P12612; P39076; P39077; P39078; P40413; P39079; P42943; P47079
site-directed mutagenesis in subunit CCT4 decreases cooperativity in ATP binding compared to wild-type
G345D
-
site-directed mutagenesis in subunit CCT4 decreases cooperativity in ATP binding compared to wild-type
-
K485W
site-directed mutagenesis, the mutant lacks ATP-dependent refolding activity, nucleotide binding and ATP-dependent conformational change kinetics, overview
K485W
site-directed mutagenesis, the mutant shows ATP binding and conformational change upon ATP binding
K485W
-
site-directed mutagenesis, the mutant lacks ATP-dependent refolding activity, nucleotide binding and ATP-dependent conformational change kinetics, overview
-
K485W
-
site-directed mutagenesis, the mutant shows ATP binding and conformational change upon ATP binding
-
additional information
Q9PW76; Q6PBW6; Q7T2P2; Q6P123; Q6NVI6; E9QGU4; B3DKJ0; A0A0R4IJT8
a missense mutation in cct5 causes muscle impairment within cct5tf212b, mapping of tf212b links the phenotype-causing mutation to the gene encoding the TRiC subunit Cct5 on chromosome 24, severe reduction in the amount of myofibrils. Knockdown of cct5 by two independent morpholinos, both validated for their functionality, results in a reduction of birefringence comparable with cct5tf212b homozygotes. A second mutant allele of cct5, cct5hi2972Tg, carries a single retroviral insertion in cct5 and fails to complement the bire-fringence reduction of cct5tf212b. In addition, both cct5 mutants are significantly ameliorated by injection of full-length cct5 mRNA, confirming that the phenotype-causing mutation of cct5tf212b resides within cct5. In addition to the trunk muscle, the head musculature of cct5tf212b mutants is also affected. Mutations in other TRiC subunits, e.g. CCT3 or CCT4, also cause impaired myofibril assembly. Mutants cct3sa1761 and cct4x0114 null develop into relatively normal larvae that exhibit skeletal muscle defects grossly similar to the other cct mutants
additional information
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
cardiac-specific knockdown of chaperonin CCT in Drosophila melanogaster resulting in disorganization of cardiac actin- and myosin-containing myofibrils and severe physiological dysfunction, including restricted heart diameters, elevated cardiac dysrhythmia and compromised cardiac performance. Knockdown of Cct3, Cct4, Cct5, Cct6 or Cct7 with the TinCDELTA4 driver resulted in cardiac morphological defects in one or more non-beating regions of the heart and completely non-beating hearts. These defects are not observed with TinC/+. Moreover, defects are even more severe with knockdown of Cct3, Cct4, Cct5, Cct6 or Cct7 with the Hand-Gal4 driver, whereas Hand/+ hearts do not show these defects.In addition to cardiac defects, cardiac-specific knockdown of Cct3, Cct4, Cct5, Cct6 or Cct7 has a drastic impact on the lifespan of the flies (female and male combined) compared to TinCDELTA4/+ and Hand/+ flies. Extremely severe cardiac dysfunction observed with Hand/+ upon cardiac-specific knockdown of Cct3, Cct4, Cct5, Cct6 or Cct7, correlate with further shortening of lifespan compared to TinCDELTA4/+. Quantitative analysis of additional cardiac physiological parameters, mutant phenotypes, overview
additional information
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
gene CCT4 is knocked down by RNAi (v106099) in eye discs by using ey-Gal4 that drives GAL4 expression in eye and head primordia, all progeny die during the late pupal stage. Similar results are obtained by an additional CCT4 RNAi line (5525R-3). Dead flies in pupal cases have relatively intact thorax and abdomen but completely lack the eye-head structures. The eye-head field in larval eye discs targeted by ey-Gal4 is lost, resulting in the headless phenotype and late pupal lethality. Loss of any CCT subunit leads to similar loss-of-function phenotypes by disrupting the function of the CCT complex in vivo. Mutant phenotype, overview
additional information
P12613; Q9W392; P48605; Q9VK69; Q7KKI0; Q9VXQ5; Q9VHL2; Q7K3J0
knockdown of each cct subunit gene in the prothoracic gland (PG). Cell number and C value in the mutant PG are increased compared to wild-type. Usage of an PG-selective RNAi screen to identify MES regulator(s). A statistically significant difference occurs in pH3 expression between control and cct RNAi. cct genes are also required for proper progression of mitotic cell cycle, development is mainly arrested at the L3 stage in cct RNAi animals (phm>cct-RNAi). Ecdysteroidogenic gene expression is significantly reduced in cct RNAi, and 20E administration restores larval-to-pupal transition in 20-30% of animals
additional information
-
knockdown of each cct subunit gene in the prothoracic gland (PG). Cell number and C value in the mutant PG are increased compared to wild-type. Usage of an PG-selective RNAi screen to identify MES regulator(s). A statistically significant difference occurs in pH3 expression between control and cct RNAi. cct genes are also required for proper progression of mitotic cell cycle, development is mainly arrested at the L3 stage in cct RNAi animals (phm>cct-RNAi). Ecdysteroidogenic gene expression is significantly reduced in cct RNAi, and 20E administration restores larval-to-pupal transition in 20-30% of animals
-
additional information
A0A1S6LQX4; A0A1S6LQU3; A0A1S6LQU0; A0A1S6LQU6; A0A1S6LQU1; A0A1S6LQU9; A0A1S6LQW6; A0A1S6LQW7
three categories of residue substitutions are found in alpha, beta, and gamma subunits: (i) bulky/polar side chains to alanine or valine, (ii) charged residues to alanine, and (iii) isoleucine to valine that is expected to increase intramolecular flexibility within the GaTRiC
additional information
-
three categories of residue substitutions are found in alpha, beta, and gamma subunits: (i) bulky/polar side chains to alanine or valine, (ii) charged residues to alanine, and (iii) isoleucine to valine that is expected to increase intramolecular flexibility within the GaTRiC
additional information
P17987; P78371; P49368; P50991; P48643; P40227; Q99832; P50990
RNAi based gene knockout via shRNA expressing lentivirus constructs. Analysis of overexpressed genes playing a role in mediating the growth and survival of SUM-52 breast cancer cells via large-scale RNAi-based growth and viability screen, overview. RNAi-mediated knockdown targeting CCT2 inhibits growth and colony formation of SUM-52 breast cancer cells. Knocking downTCP1 has a cell-type-specific effect on cell growth and colony forming capacity in SUM-52 cells
additional information
-
RNAi based gene knockout via shRNA expressing lentivirus constructs. Analysis of overexpressed genes playing a role in mediating the growth and survival of SUM-52 breast cancer cells via large-scale RNAi-based growth and viability screen, overview. RNAi-mediated knockdown targeting CCT2 inhibits growth and colony formation of SUM-52 breast cancer cells. Knocking downTCP1 has a cell-type-specific effect on cell growth and colony forming capacity in SUM-52 cells
additional information
summary of the functional growth analysis of Escherichia coli TAB21 cells expressing diverse Mm-cpn-M223 and Mm-cpn-K216 mutants at 30°C, overview. The Mm-cpn-K216E and Mm-cpn-M223I mutants act as genuine chaperonins and must complete an ATP-dependent chaperonin cycle to function in Escherichia coli
additional information
Q8II43; O97247; Q8I5C4; C0H5I7; O97282; C6KST5; O77323; O96220
generation of a regulatable PfTRiC-theta line expressing Myc-tagged subunit theta that forms a large complex in the parasite cytosol, and a theta subunit knockout line. The PfTRiC-theta-MYC clones retain between 4 and 10 aptamer elements. Knockout of PfTRiC-alpha and -zeta subunits using double homologous recombination
additional information
-
generation of a regulatable PfTRiC-theta line expressing Myc-tagged subunit theta that forms a large complex in the parasite cytosol, and a theta subunit knockout line. The PfTRiC-theta-MYC clones retain between 4 and 10 aptamer elements. Knockout of PfTRiC-alpha and -zeta subunits using double homologous recombination
additional information
Thermochaetoides thermophila
-
generation of CtCCT variants containing ATPase-deficient subunits. Removal of all surface exposed cysteine residues for diffracted X-ray tracking experiment, and addition of cysteine residues at the tip of helical protrusions of selected two subunits. Gold nanocrystals are attached onto CtCCTs via gold-thiol bonds and applied for the analysis by diffracted X-ray tracking. Irrespective of the locations of cysteines, ATP binding induces tilting motion followed by rotational motion in the CtCCT molecule, like the archaeal group II chaperonins. When gold nanocrystals are attached onto two subunits in the high ATPase activity hemisphere, the CtCCT complex exhibits a fairly rapid response to the motion. In contrast, the response of CtCCT, which has gold nanocrystals attached to the low-activity hemisphere, is slow. Change from an open to a closed state using caged-ATP, which is a derivative of ATP that is inactive and does not bind to the ATP binding site of the chaperonin
additional information
construction of gene cpkA disruption mutant strains. Gene disruptant strain DA1 (DELTAcpkA) shows decreased cell growth at 60°C as compared to 85°C for the wild-type strain KOD1. The DB2 mutant (DELTAcpkA::cpkB DELTAcpkB), whose cpkB gene is expressed under the control of the cpkA promoter, does not grow at 60°C, and the DB3 mutant (DELTAcpkA(1-524)::cpkB(1-524) DELTAcpkB), whose CpkA amino acid residues 1 to 524 are replaced with corresponding CpkB residues that maintains the C-terminal region intact, grows at 60°C, implying that the CpkA C-terminal region plays a key role in cell growth at 60°C. Proteins coimmunoprecipitated with anti-Cpk from DB1 cells cultivated at 60°C, overview
additional information
construction of gene cpkA disruption mutant strains. Gene disruptant strain DA1 (DELTAcpkA) shows decreased cell growth at 60°C as compared to 85°C for the wild-type strain KOD1. The DB2 mutant (DELTAcpkA::cpkB DELTAcpkB), whose cpkB gene is expressed under the control of the cpkA promoter, does not grow at 60°C, and the DB3 mutant (DELTAcpkA(1-524)::cpkB(1-524) DELTAcpkB), whose CpkA amino acid residues 1 to 524 are replaced with corresponding CpkB residues that maintains the C-terminal region intact, grows at 60°C, implying that the CpkA C-terminal region plays a key role in cell growth at 60°C. Proteins coimmunoprecipitated with anti-Cpk from DB1 cells cultivated at 60°C, overview
additional information
construction of gene cpkB disruption mutant strains. Gene disruptant strain DB1 (DELTAcpkB) shows decreased cell growth at 93°C as compared to 85°C for the wild-type strain KOD1. The DB2 mutant (DELTAcpkA::cpkB DELTAcpkB), whose cpkB gene is expressed under the control of the cpkA promoter, does not grow at 60°C, and the DB3 mutant (DELTAcpkA(1-524)::cpkB(1-524) DELTAcpkB), whose CpkA amino acid residues 1 to 524 are replaced with corresponding CpkB residues that maintains the C-terminal region intact, grows at 60°C, implying that the CpkA C-terminal region plays a key role in cell growth at 60°C. Proteins coimmunoprecipitated with anti-Cpk from DB1 cells cultivated at 60°C, overview
additional information
construction of gene cpkB disruption mutant strains. Gene disruptant strain DB1 (DELTAcpkB) shows decreased cell growth at 93°C as compared to 85°C for the wild-type strain KOD1. The DB2 mutant (DELTAcpkA::cpkB DELTAcpkB), whose cpkB gene is expressed under the control of the cpkA promoter, does not grow at 60°C, and the DB3 mutant (DELTAcpkA(1-524)::cpkB(1-524) DELTAcpkB), whose CpkA amino acid residues 1 to 524 are replaced with corresponding CpkB residues that maintains the C-terminal region intact, grows at 60°C, implying that the CpkA C-terminal region plays a key role in cell growth at 60°C. Proteins coimmunoprecipitated with anti-Cpk from DB1 cells cultivated at 60°C, overview
additional information
construction of the asymmetric ring complex of a group II chaperonin using circular permutated covalent mutants, TKS1-CPNASR. Although one ring of the asymmetric ring complex lacks ATPase or ATP binding activity, the other wild-type ring undergoes an ATP-dependent conformational change and maintains protein-folding activity. It is possible to construct covalent chaperonin complexes by connecting N and C-termini. Circular permutated covalent enzyme TKS1-CPN (CPNCPC) is constructed by applying circular permutation to the covalent TKS1-CPN dimer, the circular permutated covalent TKS1-CPN dimer that has the deletion of 95 amino acids from its N-terminus and the addition of the same 95 amino acids to its C-terminus can assemble into a doublering structure similar to the wild-type. The 95th amino acid residue is located at the loop region between Helix 4 and Helix 5. The complex of the TKS1-CPN variant has ann molecular weight of approximately 120 kDa determined by SDS-PAGE. The ATPase activity of mutant CPNASR is half that of the recombinant His-tagged CPNwild-type homooligomer. Phenotypes, overview
additional information
construction of the asymmetric ring complex of a group II chaperonin using circular permutated covalent mutants, TKS1-CPNASR. Although one ring of the asymmetric ring complex lacks ATPase or ATP binding activity, the other wild-type ring undergoes an ATP-dependent conformational change and maintains protein-folding activity. It is possible to construct covalent chaperonin complexes by connecting N and C-termini. Circular permutated covalent enzyme TKS1-CPN (CPNCPC) is constructed by applying circular permutation to the covalent TKS1-CPN dimer, the circular permutated covalent TKS1-CPN dimer that has the deletion of 95 amino acids from its N-terminus and the addition of the same 95 amino acids to its C-terminus can assemble into a doublering structure similar to the wild-type. The 95th amino acid residue is located at the loop region between Helix 4 and Helix 5. The complex of the TKS1-CPN variant has ann molecular weight of approximately 120 kDa determined by SDS-PAGE. The ATPase activity of mutant CPNASR is half that of the recombinant His-tagged CPNwild-type homooligomer. Phenotypes, overview
additional information
construction of three CPNbeta mutants, with the truncation of 1, 2 and 6 amino acids from the C-terminus, named CPNbetaTc1, CPNbetaTc2 and CPNbetaTc6, respectively. CPNbetaTc2 and CPNbetaTc6 are designed to delete two hydrophobic amino acid residues from the CPNbeta C-terminus (Gly-Ser-Glu-Asp-/Phe-Gly-Ser-Asp-/Leu-Asp, with / indicating Tc6 and Tc2 truncation positions). The mutants form hexadecameric homooligomers, similar to the wild-type CPNbeta (CPNbetaWT). The thermal aggregation of CS is completely suppressed by the presence of an equimolar amount of the CPNbeta mutant variants. The truncation mutants exhibit the same protection abilities as CPNbetaWT. The mutant isoforms CPNbeta and PFDalpha1beta1 from strain KS1 interact with each other at high affinity, interaction analysis using immobilized PFDalpha1beta1, overview
additional information
-
construction of the asymmetric ring complex of a group II chaperonin using circular permutated covalent mutants, TKS1-CPNASR. Although one ring of the asymmetric ring complex lacks ATPase or ATP binding activity, the other wild-type ring undergoes an ATP-dependent conformational change and maintains protein-folding activity. It is possible to construct covalent chaperonin complexes by connecting N and C-termini. Circular permutated covalent enzyme TKS1-CPN (CPNCPC) is constructed by applying circular permutation to the covalent TKS1-CPN dimer, the circular permutated covalent TKS1-CPN dimer that has the deletion of 95 amino acids from its N-terminus and the addition of the same 95 amino acids to its C-terminus can assemble into a doublering structure similar to the wild-type. The 95th amino acid residue is located at the loop region between Helix 4 and Helix 5. The complex of the TKS1-CPN variant has ann molecular weight of approximately 120 kDa determined by SDS-PAGE. The ATPase activity of mutant CPNASR is half that of the recombinant His-tagged CPNwild-type homooligomer. Phenotypes, overview
-
additional information
-
construction of the asymmetric ring complex of a group II chaperonin using circular permutated covalent mutants, TKS1-CPNASR. Although one ring of the asymmetric ring complex lacks ATPase or ATP binding activity, the other wild-type ring undergoes an ATP-dependent conformational change and maintains protein-folding activity. It is possible to construct covalent chaperonin complexes by connecting N and C-termini. Circular permutated covalent enzyme TKS1-CPN (CPNCPC) is constructed by applying circular permutation to the covalent TKS1-CPN dimer, the circular permutated covalent TKS1-CPN dimer that has the deletion of 95 amino acids from its N-terminus and the addition of the same 95 amino acids to its C-terminus can assemble into a doublering structure similar to the wild-type. The 95th amino acid residue is located at the loop region between Helix 4 and Helix 5. The complex of the TKS1-CPN variant has ann molecular weight of approximately 120 kDa determined by SDS-PAGE. The ATPase activity of mutant CPNASR is half that of the recombinant His-tagged CPNwild-type homooligomer. Phenotypes, overview
-
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
Shin, E.J.; Lee, J.W.; Kim, J.H.; Jeon, S.J.; Kim, Y.H.; Nam, S.W.
Overexpression, purification, and characterization of beta-subunit group II chaperonin from hyperthermophilic Aeropyrum pernix K1
J. Microbiol. Biotechnol.
20
542-549
2010
Aeropyrum pernix K1
brenda
Yan, Z.; Fujiwara, S.; Kohda, K.; Takagi, M.; Imanaka, T.
In vitro stabilization and in vivo solubilization of foreign proteins by the beta subunit of a chaperonin from the hyperthermophilic archaeon Pyrococcus sp. strain KOD1
Appl. Environ. Microbiol.
63
785-789
1997
Thermococcus kodakarensis (Q52500)
brenda
Okochi, M.; Matsuzaki, H.; Nomura, T.; Ishii, N.; Yohda, M.
Molecular characterization of the group II chaperonin from the hyperthermophilic archaeum Pyrococcus horikoshii OT3
Extremophiles
9
127-134
2004
Pyrococcus horikoshii (O57762), Pyrococcus horikoshii OT-3 (O57762)
brenda
Franzetti, B.; Schoehn, G.; Ebel, C.; Gagnon, J.; Ruigrok, R.W.; Zaccai, G.
Characterization of a novel complex from halophilic archaebacteria, which displays chaperone-like activities in vitro
J. Biol. Chem.
276
29906-29914
2001
Haloarcula marismortui
brenda
Kim, J.H.; Lee, J.W.; Shin, E.J.; Nam, S.W.
Cooperativity of alpha- and beta-subunits of group II chaperonin from the hyperthermophilic archaeum Aeropyrum pernix K1
J. Microbiol. Biotechnol.
21
212-217
2011
Aeropyrum pernix (Q9YDK6 and Q9YA66), Aeropyrum pernix, Aeropyrum pernix DSM 11879 (Q9YDK6 and Q9YA66)
brenda
Lee, J.W.; Kim, S.W.; Kim, J.H.; Jeon, S.J.; Kwon, H.J.; Kim, B.W.; Nam, S.W.
Functional characterization of the alpha- and beta-subunits of a group II chaperonin from Aeropyrum pernix K1
J. Microbiol. Biotechnol.
23
818-825
2013
Aeropyrum pernix (Q9YA66), Aeropyrum pernix (Q9YDK6), Aeropyrum pernix (Q9YDK6 and Q9YA66), Aeropyrum pernix DSM 11879 (Q9YDK6 and Q9YA66)
brenda
Gao, L.; Danno, A.; Fujii, S.; Fukuda, W.; Imanaka, T.; Fujiwara, S.
Indole-3-glycerol-phosphate synthase is recognized by a cold-inducible group II chaperonin in Thermococcus kodakarensis
Appl. Environ. Microbiol.
78
3806-3815
2012
Thermococcus kodakarensis (P61111), Thermococcus kodakarensis (Q52500)
brenda
Jayasinghe, M.; Shrestha, P.; Wu, X.; Tehver, R.; Stan, G.
Weak intra-ring allosteric communications of the archaeal chaperonin thermosome revealed by normal mode analysis
Biophys. J.
103
1285-1295
2012
Thermoplasma acidophilum (P48424), Thermoplasma acidophilum (P48425), Thermoplasma acidophilum ATCC 25905 (P48424), Thermoplasma acidophilum ATCC 25905 (P48425)
brenda
Cong, Y.; Schroeder, G.; Meyer, A.; Jakana, J.; Ma, B.; Dougherty, M.; Schmid, M.; Reissmann, S.; Levitt, M.; Ludtke, S.; Frydman, J.; Chiu, W.
Symmetry-free cryo-EM structures of the chaperonin TRiC along its ATPase-driven conformational cycle
EMBO J.
31
720-730
2012
Bos taurus
brenda
Skjaerven, L.; Cuellar, J.; Martinez, A.; Valpuesta, J.M.
Dynamics, flexibility, and allostery in molecular chaperonins
FEBS Lett.
589
2522-2532
2015
Saccharomyces cerevisiae (P12612), Thermoplasma acidophilum (P48424), Thermoplasma acidophilum (P48425), Bos taurus (Q32L40), Methanococcus maripaludis (Q877G8), Saccharomyces cerevisiae ATCC 204508 (P12612), Thermoplasma acidophilum ATCC 25905 (P48424), Thermoplasma acidophilum ATCC 25905 (P48425)
brenda
Gao, L.; Imanaka, T.; Fujiwara, S.
A mutant chaperonin that is functional at lower temperatures enables hyperthermophilic Archaea to grow under cold-stress conditions
J. Bacteriol.
197
2642-2652
2015
Thermococcus kodakarensis (P61111), Thermococcus kodakarensis (Q52500), Thermococcus kodakarensis KU216 (Q52500)
brenda
Hongo, K.; Itai, H.; Mizobata, T.; Kawata, Y.
Varied effects of Pyrococcus furiosus prefoldin and P. furiosus chaperonin on the refolding reactions of substrate proteins
J. Biochem.
151
383-390
2012
Pyrococcus furiosus
brenda
Yamamoto, Y.Y.; Abe, Y.; Moriya, K.; Arita, M.; Noguchi, K.; Ishii, N.; Sekiguchi, H.; Sasaki, Y.C.; Yohda, M.
Inter-ring communication is dispensable in the reaction cycle of group II chaperonins
J. Mol. Biol.
426
2667-2678
2014
Thermococcus sp. (O24730), Thermococcus sp. (P61112), Thermococcus sp. KS-1 (O24730), Thermococcus sp. KS1 (P61112)
brenda
Nakagawa, A.; Moriya, K.; Arita, M.; Yamamoto, Y.; Kitamura, K.; Ishiguro, N.; Kanzaki, T.; Oka, T.; Makabe, K.; Kuwajima, K.; Yohda, M.
Dissection of the ATP-dependent conformational change cycle of a group II chaperonin
J. Mol. Biol.
426
447-459
2014
Thermococcus sp. (O24730), Thermococcus sp. (P61112), Thermococcus sp. KS-1 (O24730), Thermococcus sp. KS-1 (P61112)
brenda
Lopez, T.; Dalton, K.; Frydman, J.
The mechanism and function of group II chaperonins
J. Mol. Biol.
427
2919-2930
2015
Saccharomyces cerevisiae, Methanococcus maripaludis, Thermoplasma acidophilum
brenda
Sekiguchi, H.; Nakagawa, A.; Moriya, K.; Makabe, K.; Ichiyanagi, K.; Nozawa, S.; Sato, T.; Adachi, S.; Kuwajima, K.; Yohda, M.; Sasaki, Y.C.
ATP dependent rotational motion of group II chaperonin observed by X-ray single molecule tracking
PLoS ONE
8
e64176
2013
Thermococcus sp. (O24730), Thermococcus sp. (P61112), Thermococcus sp. KS-1 (O24730), Thermococcus sp. KS-1 (P61112)
brenda
Kim, J.; Shin, E.; Jeon, S.; Kim, Y.; Kim, P.; Lee, C.; Nam, S.
Overexpression, purification, and functional characterization of the group II chaperonin from the hyperthermophilic archaeum Pyrococcus horikoshii OT3
Biotechnol. Bioprocess Eng.
14
551-558
2009
Pyrococcus horikoshii (O57762)
-
brenda
Willison, K.R.
The structure and evolution of eukaryotic chaperonin-containing TCP-1 and its mechanism that folds actin into a protein spring
Biochem. J.
475
3009-3034
2018
Arabidopsis thaliana (P28769 AND Q940P8 AND Q84WV1 AND Q9LV21 AND O04450 AND Q9M888 AND Q9SF16 AND Q94K05), Bos taurus (Q32L40 AND Q3ZBH0 AND Q3T0K2 AND F1N0E5 AND F1MWD3 AND Q3MHL7 AND Q2NKZ1 AND Q3ZCI9), Caenorhabditis elegans (P41988 AND P47207 AND Q9N4J8 AND P47208 AND P47209 AND P46550 AND Q9TZS5 AND Q9N358), Candida albicans (Q59QB7 AND Q59YC4 AND Q5AK16 AND Q59Z12 AND A0A1D8PMN9 AND Q59YH4 AND P47828), Candida albicans ATCC MYA-2876 (Q59QB7 AND Q59YC4 AND Q5AK16 AND Q59Z12 AND A0A1D8PMN9 AND Q59YH4 AND P47828), Danio rerio (Q9PW76 AND Q6PBW6 AND Q7T2P2 AND Q6P123 AND Q6NVI6 AND E9QGU4 AND B3DKJ0 AND A0A0R4IJT8), Dictyostelium discoideum (Q55BM4 AND Q54ES9 AND Q54TH8 AND Q54CL2 AND Q54TD3 AND Q76NU3 AND Q54ER7 AND Q552J0), Drosophila melanogaster (P12613 AND Q9W392 AND P48605 AND Q9VK69 AND Q7KKI0 AND Q9VXQ5 AND Q9VHL2 AND Q7K3J0), Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990), Mus musculus (P11983 AND P80314 AND P80318 AND P80315 AND P80316 AND P80317 AND P80313 AND P42932), Plasmodium falciparum (Q8II43 AND O97247 AND Q8I5C4 AND C0H5I7 AND O97282 AND C6KST5 AND O77323 AND O96220), Rattus norvegicus (P28480 AND Q5XIM9 AND Q6P502 AND Q7TPB1 AND Q68FQ0 AND Q3MHS9 AND D4AC23 AND D4ACB8), Rattus norvegicus Sprague-Dawley (P28480 AND Q5XIM9 AND Q6P502 AND Q7TPB1 AND Q68FQ0 AND Q3MHS9 AND D4AC23 AND D4ACB8), Saccharomyces cerevisiae (P12612 AND P39076 AND P39077 AND P39078 AND P40413 AND P39079 AND P42943 AND P47079), Saccharomyces cerevisiae ATCC 204508 (P12612 AND P39076 AND P39077 AND P39078 AND P40413 AND P39079 AND P42943 AND P47079)
brenda
Korobko, I.; Nadler-Holly, M.; Horovitz, A.
Transient kinetic analysis of ATP hydrolysis by the CCT/TRiC chaperonin
J. Mol. Biol.
428
4520-4527
2016
Saccharomyces cerevisiae (P12612 AND P39076 AND P39077 AND P39078 AND P40413 AND P39079 AND P42943 AND P47079), Saccharomyces cerevisiae ATCC 204508 (P12612 AND P39076 AND P39077 AND P39078 AND P40413 AND P39079 AND P42943 AND P47079)
brenda
Araki, K.; Suenaga, A.; Kusano, H.; Tanaka, R.; Hatta, T.; Natsume, T.; Fukui, K.
Functional profiling of asymmetrically-organized human CCT/TRiC chaperonin
Biochem. Biophys. Res. Commun.
481
232-238
2016
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990), Homo sapiens
brenda
Roh, S.H.; Kasembeli, M.M.; Galaz-Montoya, J.G.; Chiu, W.; Tweardy, D.J.
Chaperonin TRiC/CCT recognizes fusion oncoprotein AML1-ETO through subunit-specific interactions
Biophys. J.
110
2377-2385
2016
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990)
brenda
Balchin, D.; Milicic, G.; Strauss, M.; Hayer-Hartl, M.; Hartl, F.U.
Pathway of actin folding directed by the eukaryotic chaperonin TRiC
Cell
174
1507-1521.e16
2018
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990)
brenda
Gestaut, D.; Roh, S.H.; Ma, B.; Pintilie, G.; Joachimiak, L.A.; Leitner, A.; Walzthoeni, T.; Aebersold, R.; Chiu, W.; Frydman, J.
The chaperonin TRiC/CCT associates with prefoldin through a conserved electrostatic interface essential for cellular proteostasis
Cell
177
751-765.e15
2019
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990)
brenda
Berger, J.; Berger, S.; Li, M.; Jacoby, A.S.; Arner, A.; Bavi, N.; Stewart, A.G.; Currie, P.D.
In vivo function of the chaperonin TRiC in beta-actin folding during sarcomere assembly
Cell Rep.
22
313-322
2018
Danio rerio (Q9PW76 AND Q6PBW6 AND Q7T2P2 AND Q6P123 AND Q6NVI6 AND E9QGU4 AND B3DKJ0 AND A0A0R4IJT8)
brenda
Yusof, N.A.; Kamaruddin, S.; Abu Bakar, F.D.; Mahadi, N.M.; Abdul Murad, A.M.
Structural and functional insights into TRiC chaperonin from a psychrophilic yeast, Glaciozyma antarctica
Cell Stress Chaperones
24
351-368
2019
Glaciozyma antarctica (A0A1S6LQX4 AND A0A1S6LQU3 AND A0A1S6LQU0 AND A0A1S6LQU6 AND A0A1S6LQU1 AND A0A1S6LQU9 AND A0A1S6LQW6 AND A0A1S6LQW7), Glaciozyma antarctica
brenda
Spillman, N.J.; Beck, J.R.; Ganesan, S.M.; Niles, J.C.; Goldberg, D.E.
The chaperonin TRiC forms an oligomeric complex in the malaria parasite cytosol
Cell. Microbiol.
19
e12719
2017
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990), Plasmodium falciparum (Q8II43 AND O97247 AND Q8I5C4 AND C0H5I7 AND O97282 AND C6KST5 AND O77323 AND O96220), Plasmodium falciparum
brenda
Guest, S.T.; Kratche, Z.R.; Bollig-Fischer, A.; Haddad, R.; Ethier, S.P.
Two members of the TRiC chaperonin complex, CCT2 and TCP1 are essential for survival of breast cancer cells and are linked to driving oncogenes
Exp. Cell Res.
332
223-235
2015
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990), Homo sapiens
brenda
Melkani, G.C.; Bhide, S.; Han, A.; Vyas, J.; Livelo, C.; Bodmer, R.; Bernstein, S.I.
TRiC/CCT chaperonins are essential for maintaining myofibril organization, cardiac physiological rhythm, and lifespan
FEBS Lett.
591
3447-3458
2017
Drosophila melanogaster (P12613 AND Q9W392 AND P48605 AND Q9VK69 AND Q7KKI0 AND Q9VXQ5 AND Q9VHL2 AND Q7K3J0)
brenda
Roh, S.H.; Kasembeli, M.; Bakthavatsalam, D.; Chiu, W.; Tweardy, D.J.
Contribution of the type II chaperonin, TRiC/CCT, to oncogenesis
Int. J. Mol. Sci.
16
26706-26720
2015
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990), Bos taurus (Q32L40 AND Q3ZBH0 AND Q3T0K2 AND F1N0E5 AND F1MWD3 AND Q3MHL7 AND Q2NKZ1 AND Q3ZCI9)
brenda
Shah, R.; Large, A.T.; Ursinus, A.; Lin, B.; Gowrinathan, P.; Martin, J.; Lund, P.A.
Replacement of GroEL in Escherichia coli by the group II chaperonin from the archaeon Methanococcus maripaludis
J. Bacteriol.
198
2692-2700
2016
Methanococcus maripaludis (Q877G8)
brenda
Roh, S.H.; Kasembeli, M.; Galaz-Montoya, J.G.; Trnka, M.; Lau, W.C.; Burlingame, A.; Chiu, W.; Tweardy, D.J.
Chaperonin TRiC/CCT modulates the folding and activity of leukemogenic fusion oncoprotein AML1-ETO
J. Biol. Chem.
291
4732-4741
2016
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990), Bos taurus (Q32L40 AND Q3ZBH0 AND Q3T0K2 AND F1N0E5 AND F1MWD3 AND Q3MHL7 AND Q2NKZ1 AND Q3ZCI9)
brenda
Zako, T.; Sahlan, M.; Fujii, S.; Yamamoto, Y.Y.; Tai, P.T.; Sakai, K.; Maeda, M.; Yohda, M.
Contribution of the C-terminal region of a group II chaperonin to its interaction with prefoldin and substrate transfer
J. Mol. Biol.
428
2405-2417
2016
Thermococcus sp. JCM 11816 (P61112 AND O24730)
brenda
Kim, S.; Lee, D.; Lee, J.; Song, H.; Kim, H.J.; Kim, K.T.
Vaccinia-related kinase 2 controls the stability of the eukaryotic chaperonin TRiC/CCT by inhibiting the deubiquitinating enzyme USP25
Mol. Cell. Biol.
35
1754-1762
2015
Mus musculus (P11983 AND P80314 AND P80318 AND P80315 AND P80316 AND P80317 AND P80313 AND P42932)
brenda
Knowlton, J.J.; Fernandez de Castro, I.; Ashbrook, A.W.; Gestaut, D.R.; Zamora, P.F.; Bauer, J.A.; Forrest, J.C.; Frydman, J.; Risco, C.; Dermody, T.S.
The TRiC chaperonin controls reovirus replication through outer-capsid folding
Nat. Microbiol.
3
481-493
2018
Homo sapiens (P17987 AND P78371 AND P49368 AND P50991 AND P48643 AND P40227 AND Q99832 AND P50990)
brenda
Zang, Y.; Jin, M.; Wang, H.; Cui, Z.; Kong, L.; Liu, C.; Cong, Y.
Staggered ATP binding mechanism of eukaryotic chaperonin TRiC (CCT) revealed through high-resolution cryo-EM
Nat. Struct. Mol. Biol.
23
1083-1091
2016
Saccharomyces cerevisiae (P12612 AND P39076 AND P39077 AND P39078 AND P40413 AND P39079 AND P42943 AND P47079), Saccharomyces cerevisiae
brenda
Kim, A.R.; Choi, K.W.
TRiC/CCT chaperonins are essential for organ growth by interacting with insulin/TOR signaling in Drosophila
Oncogene
38
4739-4754
2019
Drosophila melanogaster (P12613 AND Q9W392 AND P48605 AND Q9VK69 AND Q7KKI0 AND Q9VXQ5 AND Q9VHL2 AND Q7K3J0)
brenda
Ohhara, Y.; Nakamura, A.; Kato, Y.; Yamakawa-Kobayashi, K.
Chaperonin TRiC/CCT supports mitotic exit and entry into endocycle in Drosophila
PLoS Genet.
15
e1008121
2019
Drosophila melanogaster (P12613 AND Q9W392 AND P48605 AND Q9VK69 AND Q7KKI0 AND Q9VXQ5 AND Q9VHL2 AND Q7K3J0), Drosophila melanogaster Oregon R (P12613 AND Q9W392 AND P48605 AND Q9VK69 AND Q7KKI0 AND Q9VXQ5 AND Q9VHL2 AND Q7K3J0)
brenda
Yamamoto, Y.Y.; Uno, Y.; Sha, E.; Ikegami, K.; Ishii, N.; Dohmae, N.; Sekiguchi, H.; Sasaki, Y.C.; Yohda, M.
Asymmetry in the function and dynamics of the cytosolic group II chaperonin CCT/TRiC
PLoS ONE
12
e0176054
2017
Thermochaetoides thermophila
brenda
Moparthi, S.B.; Carlsson, U.; Vincentelli, R.; Jonsson, B.H.; Hammarstroem, P.; Wenger, J.
Differential conformational modulations of MreB folding upon interactions with GroEL/ES and TRiC chaperonin components
Sci. Rep.
6
28386
2016
Bos taurus (Q32L40 AND Q3ZBH0 AND Q3T0K2 AND F1N0E5 AND F1MWD3 AND Q3MHL7 AND Q2NKZ1 AND Q3ZCI9)
brenda