enzyme kinetics i 10/15/2009. enzyme kinetics rates of enzyme reactions thermodynamics says i know...

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Enzyme Kinetics I 10/15/2009

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Enzyme kinetics are important 1. Substrate binding constants can be measured as well as inhibitor strengths and maximum catalytic rates. 2. Kinetics alone will not give a chemical mechanism but combined with chemical and structural data mechanisms can be elucidated. 3. Kinetics help understand the enzymes role in metabolic pathways. 4. Under “proper” conditions rates are proportional to enzyme concentrations and these can be determine “ metabolic problems”.

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Page 1: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Enzyme Kinetics I

10/15/2009

Page 2: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Enzyme Kinetics

Rates of Enzyme Reactions

Thermodynamics says I know the difference between state 1 and state 2 and G = (Gf - Gi)

But Changes in reaction rates in response to differing

conditions is related to path followed by the reaction and

is indicative of the reaction mechanism!!

Page 3: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Enzyme kinetics are important

1. Substrate binding constants can be measured as well as inhibitor strengths and maximum catalytic rates.

2. Kinetics alone will not give a chemical mechanism but combined with chemical and structural data mechanisms can be elucidated.

3. Kinetics help understand the enzymes role in metabolic pathways.

4. Under “proper” conditions rates are proportional to enzyme concentrations and these can be determine “ metabolic problems”.

Page 4: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Chemical kinetics and Elementary Reactions

Rate Equations

Consider aA + bB + • • • + zZ. The rate of a reaction is proportional to the frequency with which the reacting molecules simultaneously bump into each other

zba ZBAk Rate

Page 5: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

The order of a reaction = the sum of exponentsGenerally, the order means how many molecules have to bump into each other at one time for a reaction to occur.

A first order reaction one molecule changes to another

A BA second order reaction two molecules react

A + B P + Q

or

2A P

Page 6: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

3rd order rates A + B + C P + Q + R rarely occur

and higher orders are unknown.

Let us look at a first order rate

A B

dtPd

dtAd v

= velocity of the reaction

in Molar per min.

or

moles per min per volume

k = the rate constant of the reaction

AdtAd kv

Page 7: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Instantaneous rate: the rate of reaction at any specified time point that is the definition of the derivative.

We can predict the shape of the curve if we know the order of the reaction.

A second order reaction: 2A P

2AA kdtdv

Or for A + B P + Q

BABA kdtd

dtdv

Page 8: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Percent change in A (ratio ) versus time in first and second order reactions

Page 9: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

It is difficult to determine if the reaction is either first or second order by directly plotting changes in

concentration.

AdtAd k

dtd kAA

t

0

A

A

dtk-AA

o

d to kAlnAln

-kto eA A

Page 10: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

However, the natural log of the concentration is directly proportional to the time.

- for a first order reaction-

The rate constant for the first order reaction has units of s-1 or min-1 since velocity = molar/sec

and v = k[A] : k = v/[A]

Gather your data and plot ln[A] vs time.

Page 11: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

The half-life of a first order reaction

2

A A oPlugging in

to rate equation

21

o

A2

A

ln kt

kk693.02lnt

21

The half-life of a first order reaction is the time for half of the reactant which is initially present to decompose or react.32P, a common radioactive isotope, emits an energetic particle and has a half-life of 14 days. 14C has a half life of 5715 years.

Page 12: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

A second order reaction such like 2A P

t

dtk0

A

oA2o

AAd-

ktoA

1A1

When the reciprocal of the concentration is plotted verses time a second order reaction is characteristic of a straight line.

The half-life of a second order reaction is

and shows a dependents on the initial concentration o21 A

1tk

Page 13: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Kinetics of EnzymesEnzymes follow zero order kinetics when substrate

concentrations are high. Zero order means there is no increase in the rate of the reaction when more substrate is added.

Given the following breakdown of sucrose to glucose and fructose

Sucrose + H20 Glucose + Fructose

O

H

HO

H

HO

H

OH

OHHH

OH

OH

HOH

H OH

O

HH

HO

H

H

H

OH

Page 14: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

P EES S E 21

1-

kk

k

E = Enzyme S = Substrate P = Product

ES = Enzyme-Substrate complex

k1 rate constant for the forward reaction

k-1 = rate constant for the breakdown of the ES to substrate

k2 = rate constant for the formation of the products

Page 15: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

When the substrate concentration becomes large enough to force the equilibrium to form completely all ES the second step in the reaction becomes rate limiting because no more ES can be made and the enzyme-substrate complex is at its maximum value.

ESP2kdt

dv [ES] is the difference between the rates of ES formation minus the rates of its disappearance.

ESESSEES211 kkk

dtd

1

Page 16: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Assumption of equilibriumk-1>>k2 the formation of product is so much

slower than the formation of the ES complex. That we can assume:

ES

SE

1

1

kkK s

Ks is the dissociation constant for the ES complex.

Page 17: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Assumption of steady stateTransient phase where in the course of a reaction the concentration of ES does not change

0ES

dtd

2

Page 18: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

ES E E T 3

Combining 1 + 2 + 3

ESk k SES-Ek 21-T1

SEk Sk k kES T1121-

S KSE ES T

M1

21-

kk k K

M

rearranging

Divide by k1 and solve for [ES] Where

Page 19: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

SKSEESP T2

20

Mto

kkdtdv

vo is the initial velocity when the reaction is just starting out.

And is the maximum velocity T2max Ek V

SKSVmax

Mov

The Michaelis - Menten equation

Page 20: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

The Km is the substrate concentration where vo equals one-half Vmax

Page 21: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

The KM widely varies among different enzymes

The KM

can be expressed as:1

2

1

2

1

1 KKkk

kk

kk

sM

As Ks decreases, the affinity for the substrate increases. The KM can be a measure for substrate affinity if k2<k-1

Page 22: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

There are a wide range of KM, Vmax , and efficiency seen in enzymes

But how do we analyze kinetic data?

Page 23: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

The double reciprocal plot

maxmax

M

V1

S1

VK1

ov

Page 24: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G
Page 25: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Lineweaver-Burk plot: slope = KM/Vmax,

1/vo intercept is equal to 1/Vmax

the extrapolated x intercept is equal to -1/KM

For small errors in at low [S] leads to large errors in 1/vo

Tmax

EV

catkkcat is how many reactions an enzyme can catalyze per second

The turnover number

Page 26: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

For Michaelis -Menton kinetics k2= kcat

When [S] << KM very little ES is formed and [E] = [E]T

and SEKkSE

Kk

M

catT

M

2 ov

Kcat/KM is a measure of catalytic efficiency

Page 27: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

What is catalytic perfection?

When k2>>k-1 or the ratio 21

21

kkkk

is maximum

Then1

MKkkcat

Or when every substrate that hits the enzyme causes a reaction totake place. This is catalytic perfection.

Diffusion-controlled limit- diffusion rate of a substrate is in the range of 108 to 109 M-1s-1. An enzyme lowers the transition state so there is no activation energy and the catalyzed rate is as fast as molecules collide.

Page 28: Enzyme Kinetics I 10/15/2009. Enzyme Kinetics Rates of Enzyme Reactions Thermodynamics says I know the difference between state 1 and state 2 and  G

Lecture 16 – Dr. LeggeThursday 10/15/09Enzyme Kinetics II