PACMANS: A bioinformatically informed algorithm to predict, design, and disrupt protease‐on‐protease hydrolysis

Multiple proteases in a system hydrolyze target substrates, but recent evidence indicates that some proteases will degrade other proteases as well. Cathepsin S hydrolysis of cathepsin K is one such example. These interactions may be uni‐ or bi‐directional and change the expected kinetics. To explore...

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Bibliographic Details
Published inProtein science Vol. 26; no. 4; pp. 880 - 890
Main Authors Ferrall‐Fairbanks, Meghan C., Barry, Zachary T., Affer, Maurizio, Shuler, Marc A., Moomaw, Ellen W., Platt, Manu O.
Format Journal Article
LanguageEnglish
Published United States Wiley Subscription Services, Inc 01.04.2017
John Wiley and Sons Inc
Subjects
Algorithms
Amino acids
bioinformatics
Cathepsin K
Cathepsin S
Cathepsins
Cleavage
Gelatinase A
Gelatinase B
Hydrolysis
Matrix metalloproteinases
Methods and Applications
MMPs
mutagenesis
Mutation
Peptide Hydrolases - chemistry
Peptide Hydrolases - genetics
prediction
Protease
proteases
Proteinase
Proteins
Proteolysis
Software
Substrates
cathepsins
MMPs
bioinformatics
proteases
prediction
mutagenesis
hydrolysis
proteolysis
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Summary:Multiple proteases in a system hydrolyze target substrates, but recent evidence indicates that some proteases will degrade other proteases as well. Cathepsin S hydrolysis of cathepsin K is one such example. These interactions may be uni‐ or bi‐directional and change the expected kinetics. To explore potential protease‐on‐protease interactions in silico, a program was developed for users to input two proteases: (1) the protease‐ase that hydrolyzes (2) the substrate, protease. This program identifies putative sites on the substrate protease highly susceptible to cleavage by the protease‐ase, using a sliding‐window approach that scores amino acid sequences by their preference in the protease‐ase active site, culled from MEROPS database. We call this PACMANS, Protease‐Ase Cleavage from MEROPS ANalyzed Specificities, and test and validate this algorithm with cathepsins S and K. PACMANS cumulative likelihood scoring identified L253 and V171 as sites on cathepsin K subject to cathepsin S hydrolysis. Mutations made at these locations were tested to block hydrolysis and validate PACMANS predictions. L253A and L253V cathepsin K mutants significantly reduced cathepsin S hydrolysis, validating PACMANS unbiased identification of these sites. Interfamilial protease interactions between cathepsin S and MMP‐2 or MMP‐9 were tested after predictions by PACMANS, confirming its utility for these systems as well. PACMANS is unique compared to other putative site cleavage programs by allowing users to define the proteases of interest and target, and can also be employed for non‐protease substrate proteins, as well as short peptide sequences.
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Impact Statement: Proteases are enzymes that hydrolyze peptide bonds, and multiple proteases interact with each other in cellular environments. PACMANS is a program to help identify sequences where one protease degrades another to elucidate these protease‐on‐protease interactions that can alter expected kinetics of enzyme‐substrate systems, and to motivate experiments to test the predictions. From PACMANS analysis, scientists can engineer proteins to counteract or exploit the effects of these interactions.
ISSN:0961-8368
1469-896X
DOI:10.1002/pro.3113