Becker's World of the Cell 9th Edition by Lewis Kleinsmith, Jeff Hardin, Gregory Paul Bertoni

Question

Becker's World of the Cell 9th Edition by Lewis Kleinsmith, Jeff Hardin, Gregory Paul Bertoni

Edition 9ISBN: 9780134295510

Becker's World of the Cell 9th Edition by Lewis Kleinsmith, Jeff Hardin, Gregory Paul Bertoni

Edition 9ISBN: 9780134295510

Exercise 12

Derivation of the Michaelis-Menten Equation. For the enzyme-catalyzed reaction in which a substrate S is converted into a product P (see Reaction 6-5), velocity can be defined as the disappearance of substrate or the appearance of product per unit time:
$Derivation of the Michaelis-Menten Equation. For the enzyme-catalyzed reaction in which a substrate S is converted into a product P (see Reaction 6-5), velocity can be defined as the disappearance of substrate or the appearance of product per unit time: (1) Beginning with this definition and restricting your consideration to the initial stage of the reaction when [P] is essentially zero, derive the Michaelis-Menten equation (see Equation 6-7). The following points may help you in your derivation: (a)Begin by expressing the rate equations for d[S]/dt, d\P]/dt, and d[ES]/dt in terms of concentrations and rate constants. (b)Assume a steady state at which the enzyme-substrate complex of Reaction 6-6 is being broken down at the same rate as it is being formed such that the net rate of change, d[ES]/dt, is zero. (c)Note that the total amount of enzyme present, E t , is the sum of the free form, E f , plus the amount of complexed enzyme ES1: E t = E f + ES. (d)When you get that far, note that V max and K m can be defined as follows: (1)$ (1)
Beginning with this definition and restricting your consideration to the initial stage of the reaction when [P] is essentially zero, derive the Michaelis-Menten equation (see Equation 6-7). The following points may help you in your derivation:
(a)Begin by expressing the rate equations for d[S]/dt, d\P]/dt, and d[ES]/dt in terms of concentrations and rate constants.
(b)Assume a steady state at which the enzyme-substrate complex of Reaction 6-6 is being broken down at the same rate as it is being formed such that the net rate of change, d[ES]/dt, is zero.
(c)Note that the total amount of enzyme present, E t , is the sum of the free form, E f , plus the amount of complexed enzyme ES1: E t = E f + ES.
(d)When you get that far, note that V max and K m can be defined as follows:
$Derivation of the Michaelis-Menten Equation. For the enzyme-catalyzed reaction in which a substrate S is converted into a product P (see Reaction 6-5), velocity can be defined as the disappearance of substrate or the appearance of product per unit time: (1) Beginning with this definition and restricting your consideration to the initial stage of the reaction when [P] is essentially zero, derive the Michaelis-Menten equation (see Equation 6-7). The following points may help you in your derivation: (a)Begin by expressing the rate equations for d[S]/dt, d\P]/dt, and d[ES]/dt in terms of concentrations and rate constants. (b)Assume a steady state at which the enzyme-substrate complex of Reaction 6-6 is being broken down at the same rate as it is being formed such that the net rate of change, d[ES]/dt, is zero. (c)Note that the total amount of enzyme present, E t , is the sum of the free form, E f , plus the amount of complexed enzyme ES1: E t = E f + ES. (d)When you get that far, note that V max and K m can be defined as follows: (1)$ (1)

Explanation

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(a)
The enzymatic process occurs through...