04746nam 22006014a 450 991083012250332120230617030630.01-280-36681-897866103668110-470-34229-30-471-46141-50-471-26729-5(CKB)111087027109012(EBL)469661(OCoLC)52506780(SSID)ssj0000148611(PQKBManifestationID)11163479(PQKBTitleCode)TC0000148611(PQKBWorkID)10224936(PQKB)11101513(MiAaPQ)EBC469661(EXLCZ)9911108702710901220020828d2003 uy 0engtxtccrEnzyme kinetics[electronic resource] a modern approach /Alejandro G. MarangoniHoboken, N.J. Wiley-Intersciencec20031 online resource (247 p.)Description based upon print version of record.0-471-15985-9 "Bibliography": p. 217-219.Includes bibliographical references and index.ENZYME KINETICS; CONTENTS; PREFACE; 1 TOOLS AND TECHNIQUES OF KINETIC ANALYSIS; 1.1 Generalities; 1.2 Elementary Rate Laws; 1.2.1 Rate Equation; 1.2.2 Order of a Reaction; 1.2.3 Rate Constant; 1.2.4 Integrated Rate Equations; 1.2.4.1 Zero-Order Integrated Rate Equation; 1.2.4.2 First-Order Integrated Rate Equation; 1.2.4.3 Second-Order Integrated Rate Equation; 1.2.4.4 Third-Order Integrated Rate Equation; 1.2.4.5 Higher-Order Reactions; 1.2.4.6 Opposing Reactions; 1.2.4.7 Reaction Half-Life; 1.2.5 Experimental Determination of Reaction Order and Rate Constants1.2.5.1 Differential Method (Initial Rate Method)1.2.5.2 Integral Method; 1.3 Dependence of Reaction Rates on Temperature; 1.3.1 Theoretical Considerations; 1.3.2 Energy of Activation; 1.4 Acid-Base Chemical Catalysis; 1.5 Theory of Reaction Rates; 1.6 Complex Reaction Pathways; 1.6.1 Numerical Integration and Regression; 1.6.1.1 Numerical Integration; 1.6.1.2 Least-Squares Minimization (Regression Analysis); 1.6.2 Exact Analytical Solution (Non-Steady-State Approximation); 1.6.3 Exact Analytical Solution (Steady-State Approximation); 2 HOW DO ENZYMES WORK?3 CHARACTERIZATION OF ENZYME ACTIVITY 3.1 Progress Curve and Determination of Reaction Velocity; 3.2 Catalysis Models: Equilibrium and Steady State; 3.2.1 Equilibrium Model; 3.2.2 Steady-State Model; 3.2.3 Plot of v versus [S]; 3.3 General Strategy for Determination of the Catalytic Constants K(m) and V(max); 3.4 Practical Example; 3.5 Determination of Enzyme Catalytic Parameters from the Progress Curve; 4 REVERSIBLE ENZYME INHIBITION; 4.1 Competitive Inhibition; 4.2 Uncompetitive Inhibition; 4.3 Linear Mixed Inhibition; 4.4 Noncompetitive Inhibition; 4.5 Applications4.5.1 Inhibition of Fumarase by Succinate 4.5.2 Inhibition of Pancreatic Carboxypeptidase A by β-Phenylpropionate; 4.5.3 Alternative Strategies; 5 IRREVERSIBLE ENZYME INHIBITION; 5.1 Simple Irreversible Inhibition; 5.2 Simple Irreversible Inhibition in the Presence of Substrate; 5.3 Time-Dependent Simple Irreversible Inhibition; 5.4 Time-Dependent Simple Irreversible Inhibition in the Presence of Substrate; 5.5 Differentiation Between Time-Dependent and Time-Independent Inhibition; 6 pH DEPENDENCE OF ENZYME-CATALYZED REACTIONS; 6.1 The Model; 6.2 pH Dependence of the Catalytic Parameters6.3 New Method of Determining pK Values of Catalytically Relevant Functional Groups 7 TWO-SUBSTRATE REACTIONS; 7.1 Random-Sequential Bi Bi Mechanism; 7.1.1 Constant [A]; 7.1.2 Constant [B]; 7.2 Ordered-Sequential Bi Bi Mechanism; 7.2.1 Constant [B]; 7.2.2 Constant [A]; 7.2.3 Order of Substrate Binding; 7.3 Ping-Pong Bi Bi Mechanism; 7.3.1 Constant [B]; 7.3.2 Constant [A]; 7.4 Differentiation Between Mechanisms; 8 MULTISITE AND COOPERATIVE ENZYMES; 8.1 Sequential Interaction Model; 8.1.1 Basic Postulates; 8.1.2 Interaction Factors; 8.1.3 Microscopic versus Macroscopic Dissociation Constants8.1.4 Generalization of the ModelPractical Enzyme Kinetics provides a practical how-to guide for beginning students, technicians, and non-specialists for evaluating enzyme kinetics using common software packages to perform easy enzymatic analyses.Enzyme kineticsEnzyme kinetics.572.7572/.7Marangoni Alejandro G.1965-767400MiAaPQMiAaPQMiAaPQBOOK9910830122503321Enzyme kinetics3979365UNINA