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Zymogen activation confers thermodynamic stability on a key peptide bond and protects human cationic trypsin from degradation.
- Source :
-
The Journal of biological chemistry [J Biol Chem] 2014 Feb 21; Vol. 289 (8), pp. 4753-61. Date of Electronic Publication: 2014 Jan 08. - Publication Year :
- 2014
-
Abstract
- Human cationic trypsinogen, precursor of the digestive enzyme trypsin, can be rapidly degraded to protect the pancreas when pathological conditions threaten, while trypsin itself is impressively resistant to degradation. For either form, degradation is controlled by two necessary initial proteolytic events: cleavage of the Leu81-Glu82 peptide bond by chymotrypsin C (CTRC) and cleavage of the Arg122-Val123 peptide bond by trypsin. Here we demonstrate that the Leu81-Glu82 peptide bond of human cationic trypsin, but not trypsinogen, is thermodynamically stable, such that cleavage by CTRC leads to an equilibrium mixture containing 10% cleaved and 90% uncleaved trypsin. When cleaved trypsin was incubated with CTRC, the Leu81-Glu82 peptide bond was re-synthesized to establish the same equilibrium. The thermodynamic stability of the scissile peptide bond was not dependent on CTRC or Leu-81, as re-synthesis was also accomplished by other proteases acting on mutated cationic trypsin. The Leu81-Glu82 peptide bond is located within a calcium binding loop, and thermodynamic stability of the bond was strictly dependent on calcium and on the calcium-coordinated residue Glu-85. Trypsinolytic cleavage of the Arg122-Val123 site was also delayed in trypsin relative to trypsinogen in a calcium-dependent manner, but for this bond cleavage was modulated by kinetic rather than thermodynamic control. Our results reveal that the trypsinogen to trypsin conformational switch modulates cleavage susceptibility of nick sites by altering both the thermodynamics and kinetics of cleavage to protect human cationic trypsin from premature degradation.
- Subjects :
- Amino Acids metabolism
Calcium metabolism
Cations
Chymotrypsin pharmacology
Enzyme Stability drug effects
Humans
Hydrogen Bonding drug effects
Hydrolysis drug effects
Kinetics
Models, Molecular
Mutation genetics
Pancreatic Elastase metabolism
Protease Inhibitors pharmacology
Thermodynamics
Trypsin chemistry
Enzyme Precursors metabolism
Peptides metabolism
Proteolysis drug effects
Trypsin metabolism
Trypsinogen metabolism
Subjects
Details
- Language :
- English
- ISSN :
- 1083-351X
- Volume :
- 289
- Issue :
- 8
- Database :
- MEDLINE
- Journal :
- The Journal of biological chemistry
- Publication Type :
- Academic Journal
- Accession number :
- 24403079
- Full Text :
- https://doi.org/10.1074/jbc.M113.538884