Amide Rotation Hindrance Predicts Proteolytic Resistance of Cystine-Knot Peptides.

Cystine-knot peptides have remarkable stability against protease degradation and are attractive scaffolds for peptide-based therapeutic and diagnostic agents. In this work, by studying the hydrolysis reaction of a cystine-knot inhibitor MCTI-A and its variants with ab initio QM/MM molecular dynamics simulations, we have elucidated an amide rotation hindrance mechanism for proteolysis resistance: The proteolysis of MCTI-A is retarded due to the higher free energy cost during the rotation of NH group around scissile peptide bond at the tetrahedral intermediate of acylation, and covalent constraint provided by disulfide bonds is the key factor to hinder this rotation. A nearly linear correlation has been revealed between free energy barriers of the peptide hydrolysis reaction and the amide rotation free energy changes at the protease-peptide Michaelis complex state. This suggests that amide rotation hindrance could be one useful feature to estimate peptide proteolysis stability.

[1]  F. V. Cochran,et al.  A Chemically Cross-Linked Knottin Dimer Binds Integrins with Picomolar Affinity and Inhibits Tumor Cell Migration and Proliferation , 2014, Journal of the American Chemical Society.

[2]  J. Cochran,et al.  Cystine-knot peptides: emerging tools for cancer imaging and therapy , 2014, Expert review of proteomics.

[3]  Miriam Góngora-Benítez,et al.  Multifaceted roles of disulfide bonds. Peptides as therapeutics. , 2014, Chemical reviews.

[4]  Wilfred F van Gunsteren,et al.  Multi-resolution simulation of biomolecular systems: a review of methodological issues. , 2013, Angewandte Chemie.

[5]  Patrick S Daugherty,et al.  Protease-resistant peptide ligands from a knottin scaffold library. , 2011, ACS chemical biology.

[6]  Norelle L Daly,et al.  Bioactive cystine knot proteins. , 2011, Current opinion in chemical biology.

[7]  P. Oyston,et al.  Molecular Recognition of Chymotrypsin by the Serine Protease Inhibitor Ecotin from Yersinia pestis , 2011, The Journal of Biological Chemistry.

[8]  Yingkai Zhang,et al.  Serine protease acylation proceeds with a subtle re-orientation of the histidine ring at the tetrahedral intermediate. , 2011, Chemical communications.

[9]  Walter Thiel,et al.  QM/MM methods for biomolecular systems. , 2009, Angewandte Chemie.

[10]  D. Goldenberg,et al.  Functional and structural roles of the Cys14-Cys38 disulfide of bovine pancreatic trypsin inhibitor. , 2008, Journal of molecular biology.

[11]  M. Page,et al.  Serine peptidases: Classification, structure and function , 2008, Cellular and Molecular Life Sciences.

[12]  J. D. Del Valle,et al.  Chemistry and biology of the aeruginosin family of serine protease inhibitors. , 2008, Angewandte Chemie.

[13]  D. Goldenberg,et al.  Rigidification of a flexible protease inhibitor variant upon binding to trypsin. , 2007, Journal of molecular biology.

[14]  V. Hornak,et al.  Comparison of multiple Amber force fields and development of improved protein backbone parameters , 2006, Proteins.

[15]  Yingkai Zhang,et al.  Pseudobond ab initio QM/MM approach and its applications to enzyme reactions , 2006 .

[16]  Gene Kwan,et al.  Role of the intramolecular hydrogen bond network in the inhibitory power of chymotrypsin inhibitor 2. , 2005, Biochemistry.

[17]  J. Otlewski,et al.  The many faces of protease–protein inhibitor interaction , 2005, The EMBO journal.

[18]  Yingkai Zhang,et al.  Improved pseudobonds for combined ab initio quantum mechanical/molecular mechanical methods. , 2005, The Journal of chemical physics.

[19]  Toyokazu Ishida,et al.  Role of Asp102 in the catalytic relay system of serine proteases: a theoretical study. , 2004, Journal of the American Chemical Society.

[20]  Toyokazu Ishida,et al.  Theoretical perspectives on the reaction mechanism of serine proteases: the reaction free energy profiles of the acylation process. , 2003, Journal of the American Chemical Society.

[21]  D. Koshland,et al.  The role of the protein core in the inhibitory power of the classic serine protease inhibitor, chymotrypsin inhibitor 2. , 2003, Biochemistry.

[22]  Daniel E. Koshland,et al.  A clogged gutter mechanism for protease inhibitors , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[23]  D. Fairlie,et al.  Macrocycles mimic the extended peptide conformation recognized by aspartic, serine, cysteine and metallo proteases. , 2001, Current medicinal chemistry.

[24]  M. Qasim,et al.  What can the structures of enzyme-inhibitor complexes tell us about the structures of enzyme substrate complexes? , 2000, Biochimica et biophysica acta.

[25]  A. Olson,et al.  Revisiting Catalysis by Chymotrypsin Family Serine Proteases Using Peptide Substrates and Inhibitors with Unnatural Main Chains* , 1999, The Journal of Biological Chemistry.

[26]  Y. Konishi,et al.  Bovine thrombin complexed with an uncleavable analog of residues 7-19 of fibrinogen A alpha: geometry of the catalytic triad and interactions of the P1', P2', and P3' substrate residues. , 1996, Biochemistry.

[27]  B. Roux The calculation of the potential of mean force using computer simulations , 1995 .

[28]  P. Kollman,et al.  A second generation force field for the simulation of proteins , 1995 .

[29]  C. Brooks,et al.  Constant-temperature free energy surfaces for physical and chemical processes , 1993 .

[30]  Q Huang,et al.  Refined 1.6 A resolution crystal structure of the complex formed between porcine beta-trypsin and MCTI-A, a trypsin inhibitor of the squash family. Detailed comparison with bovine beta-trypsin and its complex. , 1993, Journal of molecular biology.

[31]  B. C. Garrett,et al.  Current status of transition-state theory , 1983 .

[32]  Tai-Sung Lee,et al.  A pseudobond approach to combining quantum mechanical and molecular mechanical methods , 1999 .

[33]  I. Kato,et al.  Protein inhibitors of proteinases. , 1980, Annual review of biochemistry.