2.7.3.2	ADP + phosphocreatine	-	Gallus gallus	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Homo sapiens	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Homo sapiens	ATP + creatine	-	r	358150	
2.7.3.2	ADP + phosphocreatine	-	Rattus norvegicus	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Rattus norvegicus	ATP + creatine	-	r	358150	
2.7.3.2	ADP + phosphocreatine	-	Bos taurus	ATP + creatine	-	r	358150	
2.7.3.2	ADP + phosphocreatine	-	Oryctolagus cuniculus	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Torpedo marmorata	ATP + creatine	-	r	358150	
2.7.3.2	ADP + phosphocreatine	-	Tethya aurantium	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Chaetopterus variopedatus	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Clupea harengus	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Ginglymostoma cirratum	ATP + creatine	-	r	358150	
2.7.3.2	ADP + phosphocreatine	-	Rhamdia quelen	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Rhamdia quelen	ATP + creatine	-	r	358150	
2.7.3.2	ADP + phosphocreatine	-	Mus musculus	ATP + creatine	-	r	358150	
2.7.3.2	ADP + phosphocreatine	synergistic substrate binding, mitochondrial isoform sMiCK	Physeter catodon	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	synergistic substrate binding, muscle-type isoform MCK	Physeter catodon	ATP + creatine	-	?	358150	
2.7.3.2	ADP + phosphocreatine	-	Rattus norvegicus Wistar	ATP + creatine	-	?	358150	
2.7.3.2	alpha-(RP)-borano-ADP + phosphocreatine	the SP-ADPalphaB isomer is a 70fold better substrate for creatine kinase than the RP isomer	Oryctolagus cuniculus	alpha-(RP)-borano-ATP + creatine	-	?	396380	
2.7.3.2	alpha-(SP)-borano-ADP + phosphocreatine	the SP-ADPalphaB isomer is a 70fold better substrate for creatine kinase than the RP isomer	Oryctolagus cuniculus	alpha-(SP)-borano-ATP + creatine	-	?	396381	
2.7.3.2	ATP + creatine	-	Gallus gallus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Gallus gallus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Mammalia	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Mus musculus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Homo sapiens	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Homo sapiens	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Rattus norvegicus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Rattus norvegicus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Sus scrofa	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Sus scrofa	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Bos taurus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Bos taurus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Oryctolagus cuniculus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Oryctolagus cuniculus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Canis lupus familiaris	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Canis lupus familiaris	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Equus caballus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Pagrus major	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Scomber japonicus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Cyprinus carpio	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Columba livia	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Scyliorhinus canicula	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Strongylocentrotus purpuratus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Strongylocentrotus purpuratus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Urocitellus richardsonii	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Clupea harengus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Chaenocephalus aceratus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Lepomis cyanellus	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	-	Danio rerio	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Gallus gallus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Rattus norvegicus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Sus scrofa	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Bos taurus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Oryctolagus cuniculus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Torpedo marmorata	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Papio anubis	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	trout	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Discopyge tschudii	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Ginglymostoma cirratum	ADP + creatine phosphate	-	?	358130	
2.7.3.2	ATP + creatine	ATP required as MgATP2-	Homo sapiens	ADP + creatine phosphate	in the reverse direction ADP can be replaced by IDP with 18% efficiency, ADP cannot be replaced by GDP, CDP, UDP, dTDP	r	358130	
2.7.3.2	ATP + creatine	creatine cannot be replaced by creatinine	Oryctolagus cuniculus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	Mg-complexes of ATP and ADP are the true substrates for the mitochondrial enzymes	Rattus norvegicus	ADP + creatine phosphate	-	r	358130	
2.7.3.2	ATP + creatine	-	Mus musculus	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Mus musculus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Homo sapiens	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Homo sapiens	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Rattus norvegicus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Bos taurus	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Bos taurus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Oryctolagus cuniculus	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Oryctolagus cuniculus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Lethenteron camtschaticum	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Oncorhynchus mykiss	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Gadus morhua	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Pelodiscus sinensis	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Tetronarce californica	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Tetronarce californica	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Danio rerio	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Chaetopterus variopedatus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Clupea harengus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Hediste diversicolor	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Ginglymostoma cirratum	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Trachemys scripta elegans	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Rhamdia quelen	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Rhamdia quelen	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Dendronephthya gigantea	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Cryptosporidium muris	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Gallus gallus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Cryptosporidium andersoni	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	role in anaerobic metabolism	Trachemys scripta	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	regeneration of ATP as primary energy source	Mammalia	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	mitochondrial model of CK in energy transport	Gallus gallus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	coupled to (Na+,K+)ATPase system	Rattus norvegicus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Gallus gallus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Homo sapiens	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Rattus norvegicus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Sus scrofa	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Bos taurus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Oryctolagus cuniculus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Columba livia	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	physiological roles: 1. buffering of ADP/ATP ratio, 2. transport of high-energy phosphates from sites of ATP production to sites of ATP consumption	Strongylocentrotus purpuratus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	overview on physiological roles	Gallus gallus	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	overview on physiological roles	Mus musculus	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	overview on physiological roles	Rattus norvegicus	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	overview on physiological roles	Oryctolagus cuniculus	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	overview on physiological roles	Frog	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	overview on physiological roles	Columba livia	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	evolution of enzyme, phylogenetics	echinodermata	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	key enzyme in energy homeostasis	Homo sapiens	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	key enzyme in energy homeostasis	Bos taurus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	key enzyme in energy homeostasis	Oryctolagus cuniculus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	key enzyme in energy homeostasis	Tetronarce californica	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	key enzyme in energy homeostasis	Gallus gallus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	key enzyme of energy homeostasis	Rattus norvegicus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	the enzyme is involved in energy homeostasis	Chaetopterus variopedatus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	the reaction equilibrium lies towards ATP production	Homo sapiens	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	the brain-type cytosolic isoform of creatine kinase, which is found mainly in the brain and retina, is a key enzyme in brain energy metabolism, because high-energy phosphates are transfered through the creatine kinase/phosphocreatine shuttle system	Homo sapiens	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	the mitochondrial isozyme MtCK catalyzes the almost complete transphosphorylation of mitochondrial ATP and cytosolic creatine into ADP and phophocreatine. ADP locally generated by MtCK is transferred into the matrix for rephosphorylation and phosphocreatine is released from mitochondria into the cytosol, direct channelling of ATP and ADP between mitochondrial matrix and MtCK via adenine nucleotide transporter	Mus musculus	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	the enzyme has a 20fold greater preference for creatine compared to glycocyamine	Cryptosporidium muris	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	the enzyme shows a 20fold greater preference for creatine than glycocyamine	Cryptosporidium muris	ADP + phosphocreatine	-	?	358162	
2.7.3.2	ATP + creatine	-	Mus musculus R6/2	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Mus musculus CF-1	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + creatine	-	Rattus norvegicus Wistar	ADP + phosphocreatine	-	r	358162	
2.7.3.2	ATP + cyclocreatine	i.e. 1-carboxymethy-2-iminoimidazolidine	Oryctolagus cuniculus	ADP + phospho-cyclocreatine	-	?	379280	
2.7.3.2	ATP + cyclocreatine	i.e. 1-carboxymethyl-2-iminoimidazolidine	Homo sapiens	ADP + phospho-cyclocreatine	-	?	379280	
2.7.3.2	ATP + glycocyamine	-	Cryptosporidium muris	ADP + phosphoglycocyamine	-	?	358161	
2.7.3.2	ATP + glycocyamine	-	Cryptosporidium andersoni	ADP + phosphoglycocyamine	-	?	358161	
2.7.3.2	ATP + glycocyamine	very low activity	Homo sapiens	ADP + glycocyamine phosphate	-	?	379350	
2.7.3.2	ATP + glycocyamine	very low activity	Oryctolagus cuniculus	ADP + glycocyamine phosphate	-	?	379350	
2.7.3.2	ATP + N-ethylglycocyamine	-	Homo sapiens	ADP + N-ethylglycocyamine phosphate	-	?	379429	
2.7.3.2	ATP + N-ethylglycocyamine	-	Oryctolagus cuniculus	ADP + N-ethylglycocyamine phosphate	-	?	379429	
2.7.3.2	dADP + phosphocreatine	-	Oryctolagus cuniculus	?	-	?	423278	
2.7.3.2	additional information	ATP undergoes substrate channelling between enzyme and myosin ATPase	Rattus norvegicus	?	-	?	89	
2.7.3.2	additional information	enzyme inhibition, e.g. by branched chain alpha-amino acids, might contribute to the brain damage maple syrup urine disease MSUD	Rattus norvegicus	?	-	?	89	
2.7.3.2	additional information	probable enzyme evolution, overview	Homo sapiens	?	-	?	89	
2.7.3.2	additional information	probable enzyme evolution, overview	Bos taurus	?	-	?	89	
2.7.3.2	additional information	probable enzyme evolution, overview	Oryctolagus cuniculus	?	-	?	89	
2.7.3.2	additional information	probable enzyme evolution, overview	Tetronarce californica	?	-	?	89	
2.7.3.2	additional information	probable enzyme evolution, overview	Gallus gallus	?	-	?	89	
2.7.3.2	additional information	substrate binding structure, arginine residues R130, R132, R236, R292, and R320 form a nucleotide phosphate bindig pocket, reaction equilibrium is highly influenced by pH and Mg2+ concentration, substrate specificity of isozymes	Homo sapiens	?	-	?	89	
2.7.3.2	additional information	substrate binding structure, reaction equilibrium is highly influenced by pH and Mg2+ concentration, assay methods, overview, structure-function analysis, substrate specificity of isozymes, the cytosolic isozymes of skeletal muscle shows broad substrate specificity	Oryctolagus cuniculus	?	-	?	89	
2.7.3.2	additional information	substrate binding structure, reaction equilibrium is highly influenced by pH and Mg2+ concentration, substrate specificity of isozymes	Bos taurus	?	-	?	89	
2.7.3.2	additional information	substrate binding structure, reaction equilibrium is highly influenced by pH and Mg2+ concentration, substrate specificity of isozymes	Gallus gallus	?	-	?	89	
2.7.3.2	additional information	substrate binding structure, substrate binding at both subunits	Tetronarce californica	?	-	?	89	
2.7.3.2	additional information	ADP re-cycling accomplished by mitochondrial creatine kinase regulates reactive oxygen species generation, particularly in high glucose concentrations. Key role of enzyme as a preventive antioxidant against oxidative stress	Rattus norvegicus	?	-	?	89	
2.7.3.2	additional information	using a yeast two-hybrid screening to search for molecules that interact with NCX1 (sodium-calcium exchanger) it is shown that sarcomeric mitochondrial creatine kinase (sMiCK) interacts with NCX1IL. In addition to sMiCK, cytoplasmic muscle-type CK (CKM) is also able to interact with NCX1 in mammalian cells	Homo sapiens	?	-	?	89	
2.7.3.2	additional information	membrane proteins VAMP2/3 and JWA are putative BCK interaction partners. At the plasma membrane, BCK interacts with at least two members of the family of cation-coupled chloride transporters (solute carrier family 12): the K+/Cl- cotransporters 2 (KCC2 or SLC12A5) and 3 (KCC3 or SLC12A6), BCK may be required for maximal phosphorylation efficiency	Mus musculus	?	-	?	89	
2.7.3.2	additional information	synaptical vesicle protein VAMP2/3 and membrane protein and JWA are BCK interaction partners, by Y2H assays. VAMP3 interacts with both, wild-type BCK and truncated DELTABCK mutant. The common and characteristic SNARE domain of VAMPs (amino acids 14-74 in VAMP3) is not sufficient for BCK interaction. JWA and VAMP both link BCK to energy-requiring intracellular vesicle transport	Rattus norvegicus	?	-	?	89	
2.7.3.2	additional information	the enzyme binds to 1,2-dipalmitoyl-sn-glycero-3-phosphate with the highest affinity (dissociation constant: 0.002 mM)	Mus musculus	?	-	-	89	
2.7.3.2	additional information	the enzyme binds to 1,2-dipalmitoyl-snglycero-3-phosphate with the highest affinity (dissociation constant 0.002 mM). The enzyme preferentially interacts with saturated fatty acid- and/or monounsaturated fatty acid-containing phosphatidic acids, but not with polyunsaturated fatty acid-containing phosphatidic acids	Mus musculus	?	-	-	89	
2.7.3.2	additional information	synaptical vesicle protein VAMP2/3 and membrane protein and JWA are BCK interaction partners, by Y2H assays. VAMP3 interacts with both, wild-type BCK and truncated DELTABCK mutant. The common and characteristic SNARE domain of VAMPs (amino acids 14-74 in VAMP3) is not sufficient for BCK interaction. JWA and VAMP both link BCK to energy-requiring intracellular vesicle transport	Rattus norvegicus Wistar	?	-	?	89