Literature summary extracted from

Heberling, M.; Masman, M.; Bartsch, S.; Wybenga, G.; Dijkstra, B.; Marrink, S.; Janssen, D.
Ironing out their differences Dissecting the structural determinants of a phenylalanine aminomutase and ammonia lyase (2015), ACS Chem. Biol., 10, 989-997 .

No PubMed abstract available

Crystallization (Commentary)

EC Number	Crystallization (Comment)	Organism
5.4.3.10	crystal structure analysis of TcdPAM, PDB ID 3NZ4	Taxus canadensis
5.4.3.10	crystal structure analysis of TcPAM mutants, PDB IDs 4V2R and 4V2Q	Taxus chinensis

Protein Variants

EC Number	Protein Variants	Comment	Organism
5.4.3.10	A77T/I79S/C89T/L97G	site-directed mutagenesis, the mutant shows an altered structure compared to wild-type enzyme with reduced beta-ladder and 3_10-helix contents	Taxus chinensis
5.4.3.10	L97G	site-directed mutagenesis, the mutant shows an altered structure compared to wild-type enzyme, the mutant has a significant increase in 310-helix and beta-ladder, compared to wild-type, with the highest coil percent among the PAM variants and improved activity. The mutant shows reduced temperature stability and optimum for PAM activity, in contrast to PAL activity	Taxus chinensis
5.4.3.10	L97G/A77T/C89T	site-directed mutagenesis, the mutant shows an altered structure compared to wild-type enzyme with reduced beta-ladder and 3_10-helix contents	Taxus chinensis
5.4.3.10	L97G/C89T	site-directed mutagenesis, the mutant shows an altered structure compared to wild-type enzyme, the mutant has a significant increase in 310-helix and beta-ladder compared to wild-type. The mutant shows reduced temperature stability and optimum for PAM activity, in contrast to PAL activity	Taxus chinensis
5.4.3.10	additional information	mutation of the inner loop region, that closes the active site of PAM, within PAM (PAM residues 77-97) in a stepwise approach. Almost all of the single loop mutations trigger a lyase phenotype in PAM. Experimental and computational evidence suggest that the induced lyase features result from inner loop mobility enhancements, which are possibly caused by a 310-helix cluster, flanking alpha-helices, and hydrophobic interactions. The application of wild-type PAM for the synthesis of beta-amino acids is hindered by low reaction rates and the mixture of alpha-Phe and beta-Phe generated from the asymmetric synthetic route. Molecular dynamic simulations	Taxus chinensis

KM Value [mM]

EC Number	KM Value [mM]	KM Value Maximum [mM]	Substrate	Comment	Organism	Structure
5.4.3.10	0.008	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant wild-type enzyme	Taxus chinensis
5.4.3.10	0.028	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant wild-type enzyme	Taxus chinensis
5.4.3.10	0.058	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G/C89T	Taxus chinensis
5.4.3.10	0.067	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G	Taxus chinensis
5.4.3.10	0.29	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G/C89T	Taxus chinensis
5.4.3.10	0.31	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G	Taxus chinensis

Natural Substrates/ Products (Substrates)

EC Number	Natural Substrates	Organism	Comment (Nat. Sub.)	Natural Products	Comment (Nat. Pro.)	Rev.	Reac.
5.4.3.10	D-alpha-phenylalanine	Taxus chinensis	-	L-beta-phenylalanine	-	r
5.4.3.10	L-phenylalanine	Taxus canadensis	-	L-beta-phenylalanine	-	r

Organism

EC Number	Organism	UniProt	Comment	Textmining
5.4.3.10	Taxus canadensis	Q6GZ04	-	-
5.4.3.10	Taxus chinensis	Q68G84	i.e. Taxus chinensis	-

Substrates and Products (Substrate)

EC Number	Substrates	Comment Substrates	Organism	Products	Comment (Products)	Rev.	Reac.
5.4.3.10	D-alpha-phenylalanine	-	Taxus chinensis	L-beta-phenylalanine	-	r
5.4.3.10	L-beta-phenylalanine	-	Taxus chinensis	D-alpha-phenylalanine	-	r
5.4.3.10	L-phenylalanine	-	Taxus canadensis	L-beta-phenylalanine	-	r
5.4.3.10	L-phenylalanine	L-alpha-phenylalanine	Taxus canadensis	L-beta-phenylalanine	-	r
5.4.3.10	additional information	the enzyme catalyzes a 2,3-amine shift that reversibly interconverts alpha-Phe to beta-Phe	Taxus canadensis	?	-	?
5.4.3.10	additional information	the enzyme catalyzes a 2,3-amine shift that reversibly interconverts alpha-Phe to beta-Phe	Taxus chinensis	?	-	?

Subunits

EC Number	Subunits	Comment	Organism
5.4.3.10	More	secondary structural analysis of the simulated PAM systems at the resting state, wild-type and mutant enzymes, overview	Taxus chinensis

Synonyms

EC Number	Synonyms	Comment	Organism
5.4.3.10	PAM	-	Taxus canadensis
5.4.3.10	PAM	-	Taxus chinensis
5.4.3.10	phenylalanine AM	-	Taxus canadensis
5.4.3.10	phenylalanine AM	-	Taxus chinensis
5.4.3.10	phenylalanine aminomutase	-	Taxus canadensis
5.4.3.10	phenylalanine aminomutase	-	Taxus chinensis
5.4.3.10	TcPAM	-	Taxus canadensis
5.4.3.10	TcPAM	-	Taxus chinensis

Temperature Optimum [°C]

EC Number	Temperature Optimum [°C]	Temperature Optimum Maximum [°C]	Comment	Organism
5.4.3.10	70	-	-	Taxus chinensis

Temperature Range [°C]

EC Number	Temperature Minimum [°C]	Temperature Maximum [°C]	Comment	Organism
5.4.3.10	30	70	no activity at 15°C, increasing activity with increasing temperature, highest at 70°C, profile overview	Taxus chinensis

Turnover Number [1/s]

EC Number	Turnover Number Minimum [1/s]	Turnover Number Maximum [1/s]	Substrate	Comment	Organism	Structure
5.4.3.10	0.0032	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant wild-type enzyme	Taxus chinensis
5.4.3.10	0.0088	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G/C89T	Taxus chinensis
5.4.3.10	0.0092	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant wild-type enzyme	Taxus chinensis
5.4.3.10	0.0184	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G	Taxus chinensis
5.4.3.10	0.062	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G/C89T	Taxus chinensis
5.4.3.10	0.117	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G	Taxus chinensis

Cofactor

EC Number	Cofactor	Comment	Organism	Structure
5.4.3.10	3,5-dihydro-5-methylidene-4H-imidazol-4-one	i.e. MIO, essential cofactor	Taxus canadensis
5.4.3.10	3,5-dihydro-5-methylidene-4H-imidazol-4-one	i.e. MIO, essential cofactor	Taxus chinensis

General Information

EC Number	General Information	Comment	Organism
5.4.3.10	evolution	structural determinant that dictates the activity differences between a phenylalanine ammonia lyase (PAL, EC 4.3.1.24) and aminomutase (PAM), overview. An inner loop region closes the active sites of both PAM and PAL. The inner loop is a structural determinant of the lyase and mutase activities of PAM. Three-dimensional structure comparisons of Taxus canadensis PAM with PAM from Taxus chinensis and phenylalanine ammonia lyase from Petroselinum crispum (PcPAL)	Taxus canadensis
5.4.3.10	evolution	structural determinant that dictates the activity differences between a phenylalanine ammonia lyase (PAL, EC 4.3.1.24) and aminomutase (PAM), overview. An inner loop region closes the active sites of both PAM and PAL. The inner loop is a structural determinant of the lyase and mutase activities of PAM. Three-dimensional structure comparisons of Taxus chinensis PAM with PAM from Taxus canadensis and phenylalanine ammonia lyase from Petroselinum crispum (PcPAL)	Taxus chinensis
5.4.3.10	additional information	the inner loop is a structural determinant of the lyase and mutase activities of PAM	Taxus canadensis
5.4.3.10	additional information	the inner loop is a structural determinant of the lyase and mutase activities of PAM. Three-dimensional structure comparisons of Taxus chinensis PAM with PAM from Taxus canadensis and phenylalanine ammonia lyase from Petroselinum crispum (PcPAL). The latter contains an open inner loop conformation. The active-site inner loop, which contains the catalytic base Tyr, appears more rigid in PAM and more open or flexible in PAL. The rigidity of this loop in PAM is considered crucial for sequestering the trans-cinnamic acid and MIO-amine adduct in the active site to promote readdition of the amino-group to either the alpha- or beta-carbon positions of trans-cinnamic acid. Molecular dynamic simulations	Taxus chinensis

kcat/KM [mM/s]

EC Number	kcat/KM Value [1/mMs^-1]	kcat/KM Value Maximum [1/mMs^-1]	Substrate	Comment	Organism	Structure
5.4.3.10	0.15	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G/C89T	Taxus chinensis
5.4.3.10	0.21	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G/C89T	Taxus chinensis
5.4.3.10	0.28	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G	Taxus chinensis
5.4.3.10	0.32	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant wild-type enzyme	Taxus chinensis
5.4.3.10	0.38	-	L-beta-phenylalanine	pH and temperature not specified in the publication, recombinant mutant L97G	Taxus chinensis
5.4.3.10	0.4	-	D-alpha-phenylalanine	pH and temperature not specified in the publication, recombinant wild-type enzyme	Taxus chinensis

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Release 2023.1 (January 2023)