Biochemistry
Biochemistry
6th Edition
ISBN: 9781305577206
Author: Reginald H. Garrett, Charles M. Grisham
Publisher: Cengage Learning
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Chapter 13, Problem 15P
Interpretation Introduction

(a)

To predict:

The equation should be determined for υwhich is the rate of the enzyme-catalyzed reaction SPin the terms of modified Michaelis- Menten model.

Introduction:

The Michaelis- Menten Equation relates reaction velocity with substrate concentration where they form enzyme-substrate complex which further reacts irreversibly to form a product and free enzyme.

E+SESE+P

  υ=d[P]dt=Vmax[S]Km+[S]

Where,

  • Vmax= maximum velocity
  •   Km

  • = Michaelis- Menten constant
  •   [S]

  • = substrate concentration

Expert Solution
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Explanation of Solution

Normally, simple Michaelis-Menten equation represents one equation in equilibrium and another is going to complete.

E+Sk1k1ESk2E+P

After modification in Michaelis-Menten equation, two equations in equilibrium can be represented as below:

E+Sk1k1ESk2k1E+P

In the simple Michaelis-Menten equation, there is an assumption that [ES]remains constant throughout whole reaction. We can use this same assumption for modified equation which can also indicates that rate of ES formation must equal the rate of ES disappearance.

k1[E][S]+k2[E][P]=k1[ES]+k2[ES]......(1)

The rate of reaction is the rate of production of P which can be represented by the forward k2reaction as below.

υ=k2[ES].....(2) where rate can be determined by [ES].

With the help of equation-(1), we can solve [ES]as below.

k1[E][S]+k2[E][P]=k1[ES]+k2[ES][E](k1[S]+k2[P])=(k1+k2)[ES][E](k1[S]+k2[P])(k1+k2)=[ES]....(3)

The total enzyme concentration and the concentration of enzyme bound to the substrate can be used for calculation of the concentration of free enzyme as below.

[E]=[Er][ES]....(4)

In the equation (3), substituting values and rearranging for solving [ES]as follow.

[E](k1[S]+k2[P])(k1+k2)=[ES]....(3)([Er][ES])(k1[S]+k2[P])(k1+k2)=[ES]([Er](k1[S]+k2[P]))(k1+k2)[ES](k1[S]+k2[P])(k1+k2)=[ES]([Er](k1[S]+k2[P]))(k1+k2)=[ES]+[ES](k1[S]+k2[P])(k1+k2)....(5)[ES]=([Er](k1[S]+k2[P]))(k1+k2)[ES](k1[S]+k2[P])(k1+k2)

In the equation (2), substituting values as below,

υ=k2[ES].....(2) υ=k2([Er](k1[S]+k2[P]))(k1+k2)[ES](k1[S]+k2[P])(k1+k2)....(6)

The above equation (6) can be used for getting value of Vmax and two Kmvalue. When all available enzymes is combined with the substrate then the maximum rate can be achieved.

In the equation (2), we can substitute value of [ET]for[ES]as below.

Vmax=k2[ES]Vmax=k2[ET]

With the help of rate constants, we can determine the two value of Km.

1KmS=k1k1+k21Kmp=k2k1+k2

In the equation (6), substituting values,

υ=k2([Er](k1[S]+k2[P]))(k1+k2)[ES](k1[S]+k2[P])(k1+k2)υ=Vmax([S]KmS+[P]KmP)1+([S]KmS+[P]KmP)

Interpretation Introduction

(b)

To predict:

The equilibrium constant should be determined for solved Michaelis-Menten equation when υ=0.

Introduction:

The Michaelis- Menten Equation relates reaction velocity with substrate concentration where they form enzyme-substrate complex which further reacts irreversibly to form a product and free enzyme.

E+SESE+P

  υ=d[P]dt=Vmax[S]Km+[S]

Where,

  • Vmax= maximum velocity
  •   Km

  • = Michaelis- Menten constant
  • [S]= substrate concentration

Expert Solution
Check Mark

Explanation of Solution

We have the solved Michaelis-Menten equation as below.

υ=Vmax([S]KmS+[P]KmP)1+([S]KmS+[P]KmP)

Now, we have υ=0, so the above equation would be,

υ=Vmax([S]KmS+[P]KmP)1+([S]KmS+[P]KmP)0=Vmax([S]KmS+[P]KmP)1+([S]KmS+[P]KmP)0=Vmax([S]KmS+[P]KmP)([S]KmS+[P]KmP)=0[S]KmS=[P]KmP

Therefore the equilibrium constant would be,

[S]KmS=[P]KmPKmPKmS=[P][S][P][S]=KmPKmS

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