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Enzyme Kinetics

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Km = [S] where the reaction velocity is max. Michaelis-Menten Equation ... Notation developed by Cleland demonstrate these mechanisms. Bisubstrate Reactions. A ... – PowerPoint PPT presentation

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Title: Enzyme Kinetics


1
Chapter 12
  • Enzyme Kinetics

2
Enzyme Kinetics
  • Study of Enzymatic Reaction Rates
  • Start with Chemical Kinetics
  • REACTION ORDER
  • dependent upon the of substrates in a reaction

3
Enzyme Kinetics
  • Describing the simple reaction
  • A?P
  • Each elementary reaction may be characterized by
    a mechanistic description that includes
    intermediates
  • A?I1? I2 ?P

4
REACTION RATES
  • At constant temperature, the rate of an
    elementary reaction is proportional to the
    frequency with which the reacting molecules come
    together.
  • Thus, for A?P, the appearance of P or
    disappearance of A can be expressed as a function
    of a rate constant, k, by determining the
    INSTANTANEOUS VELOCITY which is governed by the
    REACTION ORDER

5
REACTION ORDER
The REACTION ORDER of an elementary reaction
corresponds to the molecularity of the reaction
the number of molecules that must simultaneously
collide First Order Reaction Unimolecular
Reaction where k has units of sec-1
6
Reaction Velocity
7
REACTION ORDER
Second Order Reaction Bimolecular Reaction
where k has units of M-1sec-1 Examples 2 A
? P or A B ? P A bimolecular reaction
that is first order in A and first order in B
8
REACTION ORDER
  • Unimolecular and Bimolecular Reactions are Common
  • Termolecular (third order) and higher reactions
    an unusual because of the extremely low
    probability of the simultaneous collision of
    three molecules thus, rate equations do not
    become overly complex!

9
RATE EQUATION
  • Velocity describes the progress of a reaction as
    a function of time thus, the rate equation can
    be derived from the instantaneous velocity
    equation
  • Taking into account the change of A with time

10
1st ORDER RATE EQUATION
11
1st ORDER RATE EQUATION
Taking the antilog of both sides,
12
1st ORDER RATE EQUATION
y b mx
lnA0
lnA
Slope -k
time
13
1st ORDER RATE EQUATION
Half-life t1/2 is a constant independent of
A0
lnA0
lnA
Slope -k
time
14
RADIOACTIVE DECAY IS 1st ORDER
15
Problem 12.1
If there are 10 ?mol of 32P at t 0, how much
will remain at 7 days?
16
2nd ORDER RATE EQUATION
Taking t1/2 depends on A
17
2nd ORDER RATE EQUATION
To avoid complex calculations, 2nd order
reactions are often made into Pseudo-first-order
reactions by making one reactant significantly
higher than the other. EXAMPLE for A B ? P,
if AgtgtB then the reaction is 1st order with
respect to B
18
Problem 12.2
Determine if the following are 1st or 2nd Order
determine K
19
Problem 12.2
Time versus ln A (1st order) for Reaction A and
Reaction B
Reaction A
Reaction B
lnA
lnA
Time
Time
20
Enzyme Kinetics
  • Enzymes use 6 different mechanisms, yet all can
    be analyzed so that reaction rates and
    efficiencies can be quantified
  • Example ?-fructofuranosidase
  • Sucrose H2O ? Glucose Fructose
  • If SucrosegtgtEnzyme rate becomes 0 order
    with respect to sucrose (rate is independent of
    Sucrose), and

21
Enzyme Kinetics
  • Sucrose H2O ? Glucose Fructose
  • E S ES P E
  • Assume When S is very high the second step
    is the rate-limiting reaction and is irreversible

k1
k2
k-1
22
Michaelis-Menten Equation
  • Sucrose H2O ? Glucose Fructose
  • E S ES P E

k1
k2
k-1
23
Michaelis-Menten Equation
  • Simplification of this equation requires an
    assumption
  • 1. Equilibrium Assumption of Michaelis and
    Menten k-1gtgtk2 so that

24
Michaelis-Menten Equation
  • Simplification of this equation requires an
    assumption
  • 2. Steady State Assumption of Briggs and Haldane
    when SgtgtE, the ES is constant after the
    first milliseconds, i.e.,
  • Figure 12.2

25
Michaelis-Menten Equation
  • These two assumptions allow substitutions in the
    original rate equations to yield the
    Michaelis-Menten Equation for kinetics
  • Where

26
Michaelis-Menten Equation
  • Sucrose H2O ? Glucose Fructose
  • E S ES P E
  • Assumes k2 is small with respect to k-1, and that
    k2is irreversible

k2
k1
k-1
27
Michaelis-Menten Equation
  • Importance of the M-M Equation
  • Where SKm, v0Vmax/2 or
  • Km S where the reaction velocity is ½ max

28
Michaelis-Menten Equation
  • Km is a function of the enzyme, substrate,
    temperature and pH
  • Km is also a measure of the substrates affinity
    for the enzyme if k2ltltk-1 (Equilibrium
    Assumption)
  • Km k-1/k1 k2/k1 Ks k2/k1
  • As Km or Ks decrease, S affinity increases

29
Michaelis-Menten Equation
  • The double-reciprocal of the M-M equation yields
    a linear relationship that is often shown as as a
    Lineweaver-Burk Plot

30
Michaelis-Menten Equation
  • The double-reciprocal of the M-M equation yields
    a linear relationship that is often shown as as a
    Lineweaver-Burk Plot
  • Problem 12.6

31
Michaelis-Menten Equation
  • Catalytic Constant or Kcat (Turn over number per
    unit time) ?k2 in the M-M model
  • Table 12-1

32
Michaelis-Menten Equation
  • Catalytic Constant or Kcat is limited by k1 ES
    can go to E P no faster than E S come
    together
  • Kcat/Km represents the catalytic efficiency of
    the enzyme and is limited by the rate of
    diffusion (108 to 109 M-1 s-1)
  • Such enzymes do exist and virtually catalyze a
    reaction every time they come in contact with a
    substrate molecule

33
(No Transcript)
34
1st ORDER RATE EQUATION
Taking the antilog of both sides,
35
2nd ORDER RATE EQUATION
Taking t1/2 depends on A
36
Problem 12.2
Determine if the following are 1st or 2nd Order
determine K
37
Problem 12.2
Time versus lnA (1st order) for Reaction A and
Reaction B
Reaction A
Reaction B
lnA
lnA
Time
Time
38
Problem 12.2
Time versus 1/A (2nd order) for Reaction A
Reaction A
1/A
Time
39
Michaelis-Menten Equation
  • Importance of the M-M Equation
  • Where SKm, v0Vmax/2 or
  • Km S where the reaction velocity is ½ max

40
Michaelis-Menten Equation
  • The double-reciprocal of the M-M equation yields
    a linear relationship that is often shown as as a
    Lineweaver-Burk Plot

41
Michaelis-Menten Equation
  • The double-reciprocal of the M-M equation yields
    a linear relationship that is often shown as a
    Lineweaver-Burk Plot
  • Problem 12.6
  • Vmax 1.20 mM/s
  • Km 0.25 ?M

42
Bisubstrate Reactions
  • 2 substrate 2 product reactions 60 of
    biochemical reactions
  • A B ? P Q
  • P-X B ? P B-X
  • Examples Transfer Rxns Peptide hydrolysis
    with water
  • Redox Rxns Alcohol dehydrogenase hydride
    transfer

43
Bisubstrate Reactions
  • Classifications
  • Binding Order Rxns in which all substrates
    bind before any are released are termed
    Sequential or Single-displacement Reactions
  • Single-displacement reactions involve a single
    group transfer from A to B
  • These Rxns may be ORDERED or RANDOM
  • Notation developed by Cleland demonstrate these
    mechanisms

44
Bisubstrate Reactions
A
B
P
Q
E
EA
EAB?EPQ
EQ
E
Ordered
A
B
P
Q
EA
EQ
E
E
EAB?EPQ
EB
EP
B
Random
A
P
Q
45
Bisubstrate Reactions
  • Rxns in which some products are released before
    others bind are termed Ping Pong Reactions
  • These reactions may still involve a single group
    transfer from A to B but are termed
    double-displacement reactions substrates A and
    B never meet on the enzyme surface

46
Bisubstrate Reactions
Double-Displacement/Ping Pong Reactions
A
B
P
Q
E
EA?FP
FB?EQ
E
F
Example Trypsin / Serine Proteases (Fig. 11-26,
p.313)
Peptide
ILT
H2O
VAK
Trypsin (His57-Ser195 H-bond)
Trypsin (His57-Ser195 H-bond)
TrypsinPeptideVAKILT ?TrypsinH--VAK-ILT
TrypsinH--VAK
TrypsinH--VAK-H2O ?Trypsin VAK
47
Bisubstrate Reactions
  • Rate equations beyond this course
  • Steady State measurements can, however,
    distinguish between mechanisms
  • Stop-flow techniques of biochemistry become
    necessary for measuring rates of ES formation

48
Enzyme Inhibition
  • Basis for much of pharmacology AZTreverse
    transcriptase inhibitor peptidometicsviral
    protease inhibitor
  • Side Effects
  • Bioavailability
  • Developed Resistance
  • Can be enzyme-specific issues

49
Enzyme Inhibition
  • Modes of Inhibition
  • Competitive
  • Uncompetitive
  • Mixed or Noncompetitive
  • All can be diagnosed by M-M kinetics using
    Lineweaver-Burk plots

50
Competitive Enzyme Inhibition
  • Competitive Inhibition
  • I directly competes with S for E-binding
    site, but will not react like substrate
  • e.g. Succinate Dehydrogenase

COO-
COO-
COO-
CH
CH2
CH2
CH
CH2
COO-
COO-
COO-
Succinate S
Fumarate P
Malonate I
51
Competitive Enzyme Inhibition
E S ? ES ? P E I ? EI S ?
NO REACTION Km appears larger because more S
is needed to outcompete I, but ultimately the
same Vmax may be achieved
X
52
Competitive Enzyme Inhibition
Vmax
I2
I1
I0
Slope?Km/Vmax
-1/?Km (Apparent Km)
53
Uncompetitive Enzyme Inhibition
  • Uncompetitive Inhibition
  • Inhibitor binds to ES (Michaelis) Complex, but
    not to free enzyme
  • Inhibitor affects the catalytic function but not
    substrate binding
  • Rare in single-substrate enzymes

54
Uncompetitive Enzyme Inhibition
E S ? ES ? P E
I ?
EIS ? NO REACTION Km and Vmax both
decrease (increasing S cannot overcome
I)
X
55
Uncompetitive Enzyme Inhibition
Apparent Vmax
I1
I2
I0
Y intercept?/Vmax
Apparent -1/Km
56
Mixed Enzyme Inhibition
E S ? ES ? P E I
I ? ? EI
EIS ? NO REACTION Vmax decreases Km may
increase or decrease
X
57
Mixed Enzyme Inhibition
Apparent Vmax
I1
I2
I0
Slope?Km/Vmax
Y intercept?/Vmax
Apparent -1/Km
58
Mixed Enzyme Inhibition
  • Mixed or NONcompetitive Inhibition
  • Inhibitor binds both to free enzyme to block
    substrate binding and to ES (Michaelis) Complex
  • Most common in multi-substrate reaction
  • Irreversible inactivation (inactivators) will
    resemble noncompetitive inhibition by reducing
    the effective level of ET, producing with an
    intersection on the x-axis (1/S)

59
Regulation of Enzyme Activity
  • Enzme Availability
  • Enzyme Synthesis Degradation
  • Activity
  • Covalent Modification (Phosphorelation)
  • Allosteric Effectors
  • Sigmoidal Kinetics
  • Symmetrical, Multisubunit
  • Communication via quaternary shifts

60
QUIZ 5
  • TRY PROBLEM 12.11
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