A dicarboxylic acid consisting of succinic acid carrying a 2-benzyl substituent.
ChEBI ID: 16054
There is 1 compound belonging to this class, involving 3 study.
| Member | Definition | Role |
|---|---|---|
| (R)-2-benzylsuccinic-acid | The (R)-enantiomer of 2-benzylsuccinic acid. | xenobiotic metabolite |
| Pre-1990 | 1990-2000 | 2001-2010 | 2011-2020 | Post-2020 |
|---|---|---|---|---|
| 0 | 2 | 1 | 0 | 0 |
| Article |
|---|
Nitro as a novel zinc-binding group in the inhibition of carboxypeptidase A.
2-Substituted 3-nitropropanoic acids were designed and synthesized as inhibitors against carboxypeptidase A (CPA). (R)-2-Benzyl- 3-nitropropanoic acid showed a potent inhibition against CPA (K(i)=0.15 microM). X-ray crystallography discloses that the nitro group well mimics the transition state occurred in the hydrolysis catalyzed by CPA, that is, an O,O'-bidentate coordination to the zinc ion and the two respective hydrogen bonds with Glu-270 and Arg-127. Because the nitro group is a planar species, we proposed (R)-2-benzyl-3-nitropropanoic acid as a pseudo-transition-state analog inhibitor against CPA. |
Structure of the complex of L-benzylsuccinate with wheat serine carboxypeptidase II at 2.0-A resolution.
The structure of the complex of L-benzylsuccinate (Ki = 0.2 mM) bound to wheat serine carboxypeptidase II has been analyzed at 2.0-A resolution for native and inhibited crystals at -170 degrees C. The model has been refined and has a standard crystallographic R-factor of 0.176 for 57,734 reflections observed between 20.0- and 2.0-A resolution. The root mean square deviation from ideal bonds is 0.017 A and from ideal angles is 2.6 degrees. The model consists of 400 amino acids, 4 N-linked saccharide residues, and 430 water molecules. L-Benzylsuccinate occupies a narrow slot in the active site defined by Tyr 60, Tyr 239, and the polypeptide backbone. One carboxylate forms hydrogen bonds to Glu 145, Asn 51, the amide of Gly 52, and the catalytic His 397, suggestive of how the peptide C-terminal carboxylate is recognized by the enzyme. The phenyl ring stacks between Tyr 239 and Tyr 60, while the other carboxylate occupies the "oxyanion hole". One of the oxygens accepts hydrogen bonds from the amides of Tyr 147 and Gly 53, while the other forms a very close contact (2.3 A) with the O gamma of Ser 146, forcing the side chain into a conformation alternative to that found in the resting state of the enzyme. The inhibitor occupies the active site in a way that suggests that it can be regarded as a transition-state analogue of serine carboxypeptidases. The model suggests a novel enzymatic mechanism, involving substrate-assisted catalysis, that might account for the low pH optimum (4.0-5.5) of peptidase activity unique to this family of serine proteinases. |
Crystal structure of the complex between carboxypeptidase A and the biproduct analog inhibitor L-benzylsuccinate at 2.0 A resolution.
The X-ray crystal structure of the carboxypeptidase A-L-benzylsuccinate complex has been refined at 2.0 A resolution to a final R-factor of 0.166. One molecule of the inhibitor binds to the enzyme active site. The terminal carboxylate forms a salt link with the guanidinium group of Arg145 and hydrogen bonds with Tyr248 and Asn144. The second carboxylate group binds to the zinc ion in an asymmetric bidentate fashion replacing the water molecule of the native structure. The zinc ion moves 0.5 A from its position in the native structure to accommodate the inhibitor binding. The overall stereochemistry around the zinc can be considered a distorted tetrahedron, although six atoms of the co-ordinated groups lie within 3.0 A from the zinc ion. The key for the strong inhibitory properties of L-benzylsuccinate can be found in its ability both to co-ordinate the zinc and to form a short carboxyl-carboxylate-type hydrogen bond (2.5 A) with Glu270. |