Quantitative profiling of protease specificity
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 divers...
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| Published in | PLoS computational biology Vol. 17; no. 2; p. e1008101 |
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| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Public Library of Science
01.02.2021
Public Library of Science (PLoS) |
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| Online Access | Get full text |
| ISSN | 1553-7358 1553-734X 1553-7358 |
| DOI | 10.1371/journal.pcbi.1008101 |
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| 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. |
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| AbstractList | Protease activity has to be tightly regulated, as deleterious consequences of uncontrolled proteolysis can be devastating [4,9]. [...]newly synthesized enzymes often require proenzyme activation, and the mature proteases are subject to inhibition by a variety of endogenous inhibitors. For MMPs, the selectome is defined as a set of unique tetramers recognized by the S3-S1՛ sites in the catalytic cleft and therefore overrepresented in the substrate sets relative to the library of probes used for their selection. Since we used randomized hexapeptides as probes for substrate selections, the selectomes of MMP-2 and 9 were determined using Kullback-Leibler divergence between frequency distributions of the hexapeptide sequences containing identical tetramers in the substrate and the random hexamer sets. Based on the results of these analyses, we conclude that S3-S1՛ catalytic cleft specificity is the main driver of physiologic substrate recognition by MMP-2 and 9 and that other features such as exosites or auxiliary domains are modifiers of specificity. [...]using MMP-2 and 9 as a model system, we show that quantitative analysis of specificity can be used for solving two major problems in protease research: 1) distinguishing between specificities of closely related proteases and 2) distinguishing between targeted and bystander proteolytic events in protein substrates. Since S3 and S1՛ are the main selectivity determinants in the catalytic cleft of MMPs, which together with S2 and S1 form a tetramer binding unit, the P3-P1՛ tetramer is the primary substrate recognition motif of these enzymes (Fig 1A). 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. Protease activity has to be tightly regulated, as deleterious consequences of uncontrolled proteolysis can be devastating [4,9]. [...]newly synthesized enzymes often require proenzyme activation, and the mature proteases are subject to inhibition by a variety of endogenous inhibitors. For MMPs, the selectome is defined as a set of unique tetramers recognized by the S3-S1՛ sites in the catalytic cleft and therefore overrepresented in the substrate sets relative to the library of probes used for their selection. Since we used randomized hexapeptides as probes for substrate selections, the selectomes of MMP-2 and 9 were determined using Kullback-Leibler divergence between frequency distributions of the hexapeptide sequences containing identical tetramers in the substrate and the random hexamer sets. Based on the results of these analyses, we conclude that S3-S1՛ catalytic cleft specificity is the main driver of physiologic substrate recognition by MMP-2 and 9 and that other features such as exosites or auxiliary domains are modifiers of specificity. [...]using MMP-2 and 9 as a model system, we show that quantitative analysis of specificity can be used for solving two major problems in protease research: 1) distinguishing between specificities of closely related proteases and 2) distinguishing between targeted and bystander proteolytic events in protein substrates. Since S3 and S1՛ are the main selectivity determinants in the catalytic cleft of MMPs, which together with S2 and S1 form a tetramer binding unit, the P3-P1՛ tetramer is the primary substrate recognition motif of these enzymes (Fig 1A). 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. Proteases and proteolysis are intimately involved in virtually all biological processes from embryonic development to programmed cell death and cellular protein recycling. As the only irreversible posttranslational modification, proteolysis represents a committed step in regulation of biological networks and pathways. Imbalance of proteolytic activity has catastrophic implications and is the basis of many genetic disorders as well as a multitude of pathological states of varying etiologies. To understand protease function, one must gain insight into the repertoires of substrates targeted by these enzymes. As many proteases recognize a wide variety of sequences in proteins, it is a challenge to establish if a particular cleavage represents a targeted or a bystander proteolytic event. In addition, since many proteases have overlapping specificities, especially among closely related members of the same gene families, it is a challenge to develop highly selective tools for studying or inhibition of these enzymes. In this work, we used two closely related proteases (MMP-2 and 9) as a model system for development of an information theory-based approach to quantification of substrate specificity and demonstrated its potential for distinguishing between the target and bystander proteolytic events as well as for uncovering selectivity between closely related proteases. 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.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. |
| Author | Cieplak, Piotr Smith, Jeffrey W. Ratnikov, Boris I. Nguyen, Elise Remacle, Albert G. |
| AuthorAffiliation | Sanford Burnham Prebys Medical Discovery Institute, La Jolla, California, United States of America University College London, UNITED KINGDOM |
| AuthorAffiliation_xml | – name: University College London, UNITED KINGDOM – name: Sanford Burnham Prebys Medical Discovery Institute, La Jolla, California, United States of America |
| Author_xml | – sequence: 1 givenname: Boris I. orcidid: 0000-0002-7667-6096 surname: Ratnikov fullname: Ratnikov, Boris I. – sequence: 2 givenname: Piotr orcidid: 0000-0003-0700-5691 surname: Cieplak fullname: Cieplak, Piotr – sequence: 3 givenname: Albert G. orcidid: 0000-0003-1475-6346 surname: Remacle fullname: Remacle, Albert G. – sequence: 4 givenname: Elise orcidid: 0000-0001-5632-0714 surname: Nguyen fullname: Nguyen, Elise – sequence: 5 givenname: Jeffrey W. surname: Smith fullname: Smith, Jeffrey W. |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/33617527$$D View this record in MEDLINE/PubMed |
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| CitedBy_id | crossref_primary_10_1371_journal_pone_0316217 crossref_primary_10_1021_acs_biomac_2c01077 crossref_primary_10_1021_acschembio_4c00096 crossref_primary_10_3389_fbioe_2024_1347953 crossref_primary_10_1007_s00395_023_01007_z crossref_primary_10_1016_j_addr_2022_114240 crossref_primary_10_3390_ijms24076243 |
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| ContentType | Journal Article |
| Copyright | 2021 Ratnikov et al. This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. 2021 Ratnikov et al 2021 Ratnikov et al |
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| Title | Quantitative profiling of protease specificity |
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