Abstract
BackgroundProteases play a central role in cellular homeostasis and are responsible for the spatio- temporal regulation of function. Many putative proteases have been recently identified through genomic approaches, leading to a surge in global profiling attempts to characterize their function. Through such efforts and others it has become evident that many proteases play non-traditional roles. Accordingly, the number and the variety of the substrate repertoire of proteases are expected to be much larger than previously assumed. In line with such global profiling attempts, we present here a method for the prediction of natural substrates of endo proteases (human proteases used as an example) by employing short peptide sequences as specificity determinants.Methodology/Principal FindingsOur method incorporates specificity determinants unique to individual enzymes and physiologically relevant dual filters namely, solvent accessible surface area-a parameter dependent on protein three-dimensional structure and subcellular localization. By incorporating such hitherto unused principles in prediction methods, a novel ligand docking strategy to mimic substrate binding at the active site of the enzyme, and GO functions, we identify and perform subjective validation on putative substrates of matriptase and highlight new functions of the enzyme. Using relative solvent accessibility to rank order we show how new protease regulatory networks and enzyme cascades can be created.ConclusionWe believe that our physiologically relevant computational approach would be a very useful complementary method in the current day attempts to profile proteases (endo proteases in particular) and their substrates. In addition, by using functional annotations, we have demonstrated how normal and unknown functions of a protease can be envisaged. We have developed a network which can be integrated to create a proteolytic world. This network can in turn be extended to integrate other regulatory networks to build a system wide knowledge of the proteome.
Highlights
Proteases can activate or truncate functions of proteins, unfold a cascade of events, trigger development or differentiation and cause cell death [1,2]
We have developed a network which can be integrated to create a proteolytic world
Some investigators have made best use of such information by identifying disallowed amino acids to discriminate between proteases of similar specificity [25]. These short sequences harbor valuable information. Keeping these in mind we asked whether such minimal sequences can be used to link MEROPS, with Protein Data Bank (PDB), DISPROT and the human proteome databases
Summary
Proteases can activate or truncate functions of proteins, unfold a cascade of events, trigger development or differentiation and cause cell death [1,2]. CaSPredictor for the prediction of caspase substrates [14], GraBCas for Granzyme B and caspase substrates [15] are notable among them These tools are classifiers designed for high accuracy and are based on known natural substrates which act as training sets. Many putative proteases have been recently identified through genomic approaches, leading to a surge in global profiling attempts to characterize their function. The number and the variety of the substrate repertoire of proteases are expected to be much larger than previously assumed In line with such global profiling attempts, we present here a method for the prediction of natural substrates of endo proteases (human proteases used as an example) by employing short peptide sequences as specificity determinants
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