Abstract
Proteases are an important class of enzymes, whose activity is central to many physiologic and pathologic processes. Detailed knowledge of protease specificity is key to understanding their function. Although many methods have been developed to profile specificities of proteases, few have the diversity and quantitative grasp necessary to fully define specificity of a protease, both in terms of substrate numbers and their catalytic efficiencies. We have developed a concept of “selectome”; the set of substrate amino acid sequences that uniquely represent the specificity of a protease. We applied it to two closely related members of the Matrixin family–MMP-2 and MMP-9 by using substrate phage display coupled with Next Generation Sequencing and information theory-based data analysis. We have also derived a quantitative measure of substrate specificity, which accounts for both the number of substrates and their relative catalytic efficiencies. Using these advances greatly facilitates elucidation of substrate selectivity between closely related members of a protease family. The study also provides insight into the degree to which the catalytic cleft defines substrate recognition, thus providing basis for overcoming two of the major challenges in the field of proteolysis: 1) development of highly selective activity probes for studying proteases with overlapping specificities, and 2) distinguishing targeted proteolysis from bystander proteolytic events.
Highlights
Proteases are classified according to their catalytic mechanism into serine, threonine, cysteine, aspartic, glutamic and metalloproteinases [1]
To characterize the tetramer clusters in substrate sets in terms of contribution of the P3-P1՛ sequences to catalytic efficiency of substrates, defined by us as substrate fitness, we introduced the ratio between probabilities (Relative Probability or RP, see the Methods section for formal definition) of finding identical tetramers in the Matrix Metalloproteinase (MMP) selections and the naïve phage display library
The analyses clearly demonstrate that RP is a quantitative measure of contribution of the P3-P1՛ tetramer sequences to catalytic efficiency of hexamer substrates containing them
Summary
Proteases are classified according to their catalytic mechanism into serine, threonine, cysteine, aspartic, glutamic and metalloproteinases [1]. Proteases listed in the MEROPS database of proteolytic enzymes are members of 268 gene families and their number is growing as the number of sequenced genomes increases [2]. 560 unique proteases comprise approximately 3% of the protein-coding genome [3]. Proteases are involved in all aspects of biology from embryonic development to programmed cell death and cellular protein recycling and are an integral part of proteolytic pathways that connect different biological processes into functional networks [3,4,5,6,7,8]. Newly synthesized enzymes often require proenzyme activation, and the mature proteases are subject to inhibition by a variety of endogenous inhibitors
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