Enzyme Kinetics for Complex System Enables Accurate Determination of Specificity Constants of Numerous Substrates in a Mixture by Proteomics Platform

Many important experiments in proteomics including protein digestion, enzyme substrate screening, enzymatic labeling, etc., involve the enzymatic reactions in a complex system where numerous substrates coexists with an enzyme. However, the enzyme kinetics in such a system remains unexplored and poor...

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Veröffentlicht in:	Molecular & cellular proteomics 2017-01, Vol.16 (1), p.135-145
Hauptverfasser:	Deng, Zhenzhen, Mao, Jiawei, Wang, Yan, Zou, Hanfa, Ye, Mingliang
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Sprache:	eng
Schlagworte:	Algorithms Catalysis Complex systems Computer simulation Enzyme kinetics Enzymes - metabolism Experiments High-Throughput Screening Assays Iterative methods Kinetics Mathematical models Models, Theoretical Peptides - analysis Proteomics Proteomics - methods Reaction kinetics Screening Substrate Specificity Substrates
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creator	Deng, Zhenzhen Mao, Jiawei Wang, Yan Zou, Hanfa Ye, Mingliang
description	Many important experiments in proteomics including protein digestion, enzyme substrate screening, enzymatic labeling, etc., involve the enzymatic reactions in a complex system where numerous substrates coexists with an enzyme. However, the enzyme kinetics in such a system remains unexplored and poorly understood. Herein, we derived and validated the kinetics equations for the enzymatic reactions in complex system. We developed an iteration approach to depict the enzymatic reactions in complex system. It was validated by 630 time-course points from 24 enzymatic reaction experiments and was demonstrated to be a powerful tool to simulate the reactions in the complex system. By applying this approach, we found that the ratio of substrate depletion is independent of other coexisted substrates under specific condition. This observation was then validated by experiments. Based on this striking observation, a simplified model was developed to determine the catalytic efficiencies of numerous competing substrates presented in the complex enzyme reaction system. When coupled with high-throughput quantitative proteomics technique, this simplified model enabled the accurate determination of catalytic efficiencies for 2369 peptide substrates of a protease by using only one enzymatic reaction experiment. Thus, this study provided, in the first time, a validated model for the large scale determination of specificity constants which could enable the enzyme substrate screening approach turned from a qualitative method of identifying substrates to a quantitative method of identifying and prioritizing substrates. Data are available via ProteomeXchange with identifier PXD004665.
doi_str_mv	10.1074/mcp.M116.062869
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When coupled with high-throughput quantitative proteomics technique, this simplified model enabled the accurate determination of catalytic efficiencies for 2369 peptide substrates of a protease by using only one enzymatic reaction experiment. Thus, this study provided, in the first time, a validated model for the large scale determination of specificity constants which could enable the enzyme substrate screening approach turned from a qualitative method of identifying substrates to a quantitative method of identifying and prioritizing substrates. 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subjects	Algorithms Catalysis Complex systems Computer simulation Enzyme kinetics Enzymes - metabolism Experiments High-Throughput Screening Assays Iterative methods Kinetics Mathematical models Models, Theoretical Peptides - analysis Proteomics Proteomics - methods Reaction kinetics Screening Substrate Specificity Substrates
title	Enzyme Kinetics for Complex System Enables Accurate Determination of Specificity Constants of Numerous Substrates in a Mixture by Proteomics Platform
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