Sadashiv M. Gokhale scite author profile

Edited by Wolfgang PetiSerine peptidases of the prolyl oligopeptidase (POP) family are of substantial therapeutic importance because of their involvement in diseases such as diabetes, cancer, neurological diseases, and autoimmune disorders. Proper annotation and knowledge of substrate specificity mechanisms in this family are highly valuable. Although endopeptidase, dipeptidyl peptidase, tripeptidyl peptidase, and acylaminoacyl peptidase activities have been reported previously, here we report the first instance of carboxypeptidase activity in a POP family member. We determined the crystal structures of this carboxypeptidase, an S9C subfamily member from Deinococcus radiodurans, in its active and inactive states at 2.3-Å resolution, providing an unprecedented view of assembly and disassembly of the active site mediated by an arginine residue. We observed that this residue is poised to bind substrate in the active structure and disrupts the catalytic triad in the inactive structure. The assembly of the active site is accompanied by the ordering of gating loops, which reduces the effective size of the oligomeric pore. This prevents the entry of larger peptides and constitutes a novel mechanism for substrate screening. Furthermore, we observed structural adaptations that enable its carboxypeptidase activity, with a unique loop and two arginine residues in the active site cavity orienting the peptide substrate for catalysis. Using these structural features, we identified homologs of this enzyme in the POP family and confirmed the presence of carboxypeptidase activity in one of them. In conclusion, we have identified a new type within POP enzymes that exhibits not only unique activity but also a novel substrate-screening mechanism.

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Glycophorin A interferes in the agglutination of human erythrocytes by concanavalin A Explanation of the requirement for enzymic predigestion

Gokhale¹,

Mehta²

1987

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Human erythrocytes become agglutinable with concanavalin A (Con A) after treatment with various proteinases or neuraminidase. The extent of agglutinability achieved with different enzymes is, however, different: Pronase, papain, trypsin, neuraminidase and chymotrypsin enhance the agglutinability in decreasing order, the last being barely effective. The actions of the enzymes on band 3, the Con A receptor, do not correlate with their abilities to increase the agglutinability: Pronase, papain and chymotrypsin cleave the protein, but not trypsin or neuraminidase. No significant differences are found in the number of Con A-binding sites or the affinities for the lectin between the normal and trypsin- or Pronase-treated cells. Thus the receptor does not seem to play a role in determining the Con A-agglutinability of erythrocytes. On the other hand, the cleavage of glycophorins, especially glycophorin A, and the release of sialic acid (in the peptide-bound form) are well-correlated with the enhancement in agglutination after the action of proteinases. The release of sialic acid by graded neuraminidase digestion and the increase in Con A-agglutinability show a correlation coefficient of 0.88. The major inhibitory role of glycophorin A in the process is indicated by the agglutination of En(a) heterozygous erythrocytes; the cells, known to bear about 50% glycophorin A molecules in their membrane, are agglutinated approximately half as well without proteolysis as are the trypsin-treated cells. Possible mechanisms by which glycophorin A could affect Con A-mediated agglutination are discussed.

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Membrane skeleton-bilayer interaction is not the major determinant of membrane phospholipid asymmetry in human erythrocytes

Gudi¹,

Kumar²,

Bhakuni³

et al. 1990

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Structure of Asp‐bound peptidase E from Salmonella enterica: Active site at dimer interface illuminates Asp recognition

et al. 2018

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Peptidase-E, a nonclassical serine peptidase, is specific for dipeptides with an N-terminal aspartate. This stringent substrate specificity remains largely unexplained. We report an aspartate-bound structure of peptidase-E at 1.83 Å resolution. In contrast to previous reports, the enzyme forms a dimer, and the active site is located at the dimer interface, well shielded from the solvent. Our findings further suggest that the stringent aspartate specificity of the enzyme is due to electrostatics and molecular complementarity in the active site. The new structural information presented herein may provide insights into the role of functionally important residues in peptidase-E.

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Catalytic triad heterogeneity in S51 peptidase family: Structural basis for functional variability

et al. 2019

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Peptidase E (PepE) is a nonclassical serine peptidase with a Ser‐His‐Glu catalytic triad. It is specific for dipeptides with an N‐terminal aspartate residue (Asp‐X dipeptidase activity). Its homolog from Listeria monocytogenes (PepElm) has a Ser‐His‐Asn “catalytic triad.” Based on sequence alignment we predicted that the PepE homolog from Deinococcus radiodurans (PepEdr) would have a Ser‐His‐Asp “catalytic triad.” We confirmed this by solving the crystal structure of PepEdr to 2.7 Å resolution. We show that PepElm and PepEdr lack the Asp‐X dipeptidase activity. Our analyses suggest that absence of P1 pocket in the active site could be the main reason for this lack of typical activity. Sequence and structural data reveal that the PepE homologs can be divided into long and short PepEs based on presence or absence of a C‐terminal tail which adopts a β‐hairpin conformation in the canonical PepE from Salmonella enterica. A long PepE from Bacillus subtilis with Ser‐His‐Asp catalytic triad exhibits Asp‐X dipeptidase activity. Whereas the three long PepEs enzymatically characterized till date have been found to possess the Asp‐X dipeptidase activity, the three enzymatically characterized short PepEs lack this activity irrespective of the nature of their catalytic triads. This study illuminates the structural and functional heterogeneity in the S51 family and also provides structural basis for the functional variability among PepE homologs.

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