2012 E + S ES E + P. V 0 = V max. ½V max. k 3. k 1. k 2 [S] K M

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LECTURE 3: ENZYME KINETICS V0

V0 = Vmax

½Vmax

V

k1

E+S

KM

k2

ES

k3

E+P

[S]

LECTURE FLOW 

Enzyme--Substrate Interaction Enzyme 1. Lock and Key" Hypothesis 2. The "Induced Fit" Hypothesi



Enzyme Kinetics  Michalis Michalis--Menten

Equation or Lineweaver Lineweaver--Burk

 Double Double--reciprocal  Eadie Eadie--Hofstee  Hanes Hanes--Woolf

Enzyme--Substrate Interaction Enzyme 1. Lock and Key" Hypothesis 2. The "Induced Fit" Hypothesis

1. "Lock and Key" Hypothesis 



Emil Fischer in 1890 proposed "Lock and Key" Hypothesis The shape, or configuration, of the active site is especially designed for the specific substrate involved.

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Because the configuration is determined by the amino acid sequence of the enzyme, the native configuration of the entire enzyme molecule must be intact for the active site to have the correct configuration. In such a case, the substrate then fits into the active site of the enzyme in much the same way as a key fits into a lock.





P1

E

S

S

E

E P2

2. The "Induced Fit" Hypothesis 



Enzymes are highly flexible, conformationally dynamic molecules, and many of their remarkable properties, including substrate binding and catalysis, are due to their structural pliancy. Realization of the conformational flexibility of proteins led Daniel Koshland to hypothesize that the binding of a substrate (S) by an enzyme is an interactive process. The shape of the enzyme's active site is actually modified upon binding S, in a process of dynamic recognition between enzyme and substrate aptly called induced fit.

E

S

E

S

P1

E P2

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ATP

Mg(2+)



In essence, substrate binding alters the conformation of the protein, so that the protein and the substrate "fit" each other more precisely. The process is truly interactive in that the conformation of the substrate also changes as it adapts to the conformation of the enzyme.

E

S

E

S

P1

E P2

Induced Fit Model

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Enzyme Kinetics 

Basic Prinsiple 





Enzyme kinetics is the study of the chemical reactions that are catalyzed by enzymes or the study of the rates of enzymecatalyzed reactions This study provides information on enzyme specificities and mechanisms The formation of ES complex is the base of enzymic reactions

E+S

ES

E+P

Why are enzyme kinetics important? 1. 2.

3.

It provides valuable information for enzyme mechanism It gives an insight into the role of an enzyme under physiological conditions It can help show how the enzyme activity is controlled and regulated

Enzyme Kinetics 

Enzymes 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 H

H

H O HO

H

OH

OH

H OH

H OH

H HO

H

H

O

HO HO

H H H

OH OH

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



The reaction is reversible which means some substance can be synthesized from the substrate in the reaction If environmental factors are constant, the rate of product formation (reaction velocity, V) is dependent upon the concentration of enzyme and substrate  [E] = enzyme concentration  [S] = substrate concentration

[S] is constant [E] increases V? These reactions are said to be "zero order" because the rates are independent of substrate concentration, and are equal to some constant k Order

Rate k

V

[S] is constant

[E]

Comments

rate is independent of substrate concentration rate is proportional to the first power of k[S] first substrate concentration 2 rate is proportional to the square of the second k[S][S]=k[S] substrate concentration rate is proportional to the first power of k[S1][S2] each of two reactants

zero

[S] increases [E] is constant V? 

The concentration of substrate [S] greatly influences the rate of product formation (the velocity of a reaction, V) 



Studying the effects of [S] on the velocity of a reaction is complicated by the reversibility of enzyme reactions, e.g. conversion of product back to substrate To overcome this problem, initial velocity (vo) measurements are used. At the start of a reaction, [S] is in large excess of [P], thus the initial velocity of the reaction will be dependent on substrate concentration

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When initial velocity is plotted against [S], a hyperbolic curve results, where 



Vmax represents the maximum reaction velocity This occurs at [S] >> E, and all available enzyme is "saturated" with bound substrate, meaning only the ES complex is present.

V0

V0 = Vmax

V

½Vmax



KM

[S]

High [S] Saturating [E] Low [S]

50% [S] Km

MICHAELIS--MENTEN MODEL MICHAELIS 

1.

Lenore Michaelis and Maud L. Menten proposed a general theory of enzyme action in 1913 The formation of ES Complex 

Their theory was based on the assumption that the enzyme (E) and its substrate (S) associate reversibly to form an enzymeenzyme-substrate complex, ES

E+S

k1 k2

ES

k3 k4

E+P

E = Enzyme, S = Substrate, P = Product ES = Enzyme-Substrate complex , and k1, k2, k3 & k4 = rate constants. k4 is very small and ignored



This association/dissociation is assumed to be a rapid equilibrium, and Ks is the enzyme : substrate dissociation constant. At equilibrium, k2[ES] = k1[E][S [E][S]] and [E][S ] k 2 KS   [ES ] k 1

2.

Steady--State Assumption Steady 

The interpretations of Michaelis and Menten were refined and extended in 1925 by Briggs and Haldane, by assuming [ES] quickly reaches a constant value in such a dynamic system.

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That is, ES is formed as rapidly from E + S, and disappears by its two possible fates



 

This assumption is termed the steady--state assumption and is steady expressed as [ ES ] 0 t



3.

dissociation to regenerate E + S, and reaction to form E + P

Initial Velocity Assumption 

Because enzymes accelerate the rate of the reverse reaction as well as the forward reaction, reaction, the conversion of E+P to ES, and k4(E][P] = 0

E+S 



4.

k1 k2

k3

ES

E+P

However, if we observe only the initial velocity for the However, reaction immediately after E and S are mixed in the absence of P, the rate of any back reaction is negligible because its rate will be proportional to [P], and [P] is essentially 0 Given such simplification, we now analyze the system described by equation above in order to describe the initial velocity v as a function of [S] and amount of enzyme.. enzyme

Total Enzyme 

The total amount of enzyme is fixed and is given by the formula [E]] = free enzyme and [ES] = the amount of [E [E]0 = [E] + [ES] [ES] enzyme in the enzymeenzyme-substrate complex.

The rate of product formation is dependent upon [ES] and k3

v

dP   k 3 ES dt

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

dES  k 1 E S  k 2 ES  k 3 ES dt The assumption of steady state gives The rate of [ES] formation = The rate of [ES] formation ES = k1[E][S] = ES = (k2 + k3) (ES) Michaelis-Menten Cosntant MichaelisKM = (k2 + k3 )/k1

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Michaelis--Menten Equation Michaelis

V Vmax

Vmax[S] KM  [S]

½Vmax

V

KM



[S]

The best substrate for enzyme is that which has the highest Vmax Vmax/K /KM Enzyme

Vmax

Chymotrypsin Carbonic Anhydrase 1.

KM

100 5000 600,000 8000

Vmax/KM 1/50 600/8

KM Michaelis--Menten Equation: Michaelis

V = Vmax Vmax[S]/(K [S]/(KM+[S])    

2.

If V = ½Vmax ½Vmax = Vmax Vmax[S]/(K [S]/(KM+[S]) ½(KM+[S]) = [S] [S]KM+[S] = 2[S] KM = [S]

KM = (k (k2 + k3)/k1

E+S 

This means that KM is equal to the substrate concentration at V = ½ Vmax

k1 k2

ES

k3

E+P

The rate rate--determining step of the reaction is k3, for the formation of product so if k2 >> k3  KM = k2/k1  k2/k1 is known as a dissociation constant for the ES complex  k2/k1 reflects a tendency of ES complex to dissociate to be E and S,  KM = k2/k1 can be used as a relative measure of the affinity of a substrate for an enzyme

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



Low KM  high apparent affinity of a substrate for an enzyme High KM  low apparent affinity of a substrate for an enzyme Enzyme Pyruvate carboxylase 3.

Substrate pyruvate HCO3ATP

Km (µM) 400 1000 60

Turnover number k3 = Vmax Vmax/[E] /[E]0 Moles of substrate transformed per second per mole of active site, or the number of substrate molecules converted to P by an E molecule in a unit time when E is fully saturated.

Penetuan KM dan Vmax 



Harga KM bervariasi sangat besar besar,, tapi dari kebanyakan enzim berkisar diantara 10-1 - 10-6 M (Tabel (Tabel 2.1) tergantung substrat dan lingkungan seperti suhu dan kuantitas ion Untuk mendapatkan harga KM dan Vmax Vmax,, analisis langsung persamaan diatas dapat dilakukan,, tapi cara ini membutuhkan waktu dilakukan yang lama, dan bantuan komputer sangat penting untuk mengoptimasi harga parameter persamaan dengan cepat cepat..

Tabel 2.1 Parameter beberapa enzim

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PENDEKATAN LAIN 

Linierisasi persamaan Modifikasi persamaan ke bentuk linier sehingga dapat dianalisis dengan mudah 1. Persamaan “double “double--reciprocal” atau “Lineweaver Lineweaver--Burk” 2. Persamaan “Eadie Eadie--Hofstee Hofstee”” 3. Persamaan “Hanes “Hanes--Woolf”

Persamaan “double “double--reciprocal” atau “Lineweaver Lineweaver--Burk” Vmax[S] KM [S] Jika ruas kiri dibalik dan demikian juga ruas kanan kanan,, maka V



1 KM 1 1  .  V Vmax [S] Vmax 



Sekarang persamaan ini akan mudah dianalisis dengan metode linier sedehana

Sekarang y = 1/V ; x = 1/[S] a = 1/Vmax 1/Vmax ; b = KM/Vmax dapat dianalisis dengan y = a + bx Jika 1/V dihubungkan dengan 1/[S], suatu garis lurus akan dihasilkan yang memotong sumbu y pada 1/ 1/Vmax Vmax dan sumbu x pada -1/KM serta membentuk sudut terhadap sumbu x sebesar KM/Vmax Vmax..

1/V KM/Vmax

-1/KM

1/Vmax

1/[S]

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Persamaan “Eadie Eadie--Hofstee Hofstee”” V

Vmax[S] KM [S]

V ( K M  [ S ])  V max [ S ] V [ S ]   VK M  V max [ S ] V 

 VK M  V max [ S ] [S ]

V  K M



V  Vmax [S]

Sekarang y = V ; x = V/[S] a = Vmax ; b = -KM dapat dianalisis dengan y = a + bx Vmax

Jika V dihubungkan dengan V/[S], suatu garis lurus akan dihasilkan yang memotong sumbu y pada Vmax dan sumbu x pada Vmax/K Vmax /KM serta membentuk sudut terhadap sumbu x sebesar KM

V KM

Vmax /KM

V/[S]

Persamaan “Hanes “Hanes--Woolf” V

Vmax [S] KM  [S]

V (K

M

 [ S ])  V max [ S ]

[S ] K M  [S ]  V V max [S ] K M  V V max



1 V max

.[ S ]

[S] K M 1   .[S ] V Vmax Vmax

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

Sekarang y = [S]/V ; x = [S] a = KM/Vmax ; b = 1/Vmax 1/Vmax dapat dianalisis dengan y = a + bx 

Jika [S]/V dihubungkan dengan [S], suatu garis lurus akan dihasilkan yang memotong sumbu y pada KM/Vmax dan sumbu x pada -KM serta membentuk sudut terhadap sumbu x sebesar 1/ 1/Vmax Vmax..

[S]/V 1/Vmax

KM /Vmax -KM [S]

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STEPS OF MODEL DERIVATION

STEPS OF MODEL DERIVATION 1.

Pembentukan ES adalah inti dari hipotesis tersebut

E+S 1.

2.

k1 k2

ES

k3 k4

E+P

(1)

Reaksi E dengan S terjadi dengan kecepatan k1 dan menghasilkan kompleks ES (enzim (enzim-substrat)) substrat Kompleks ES dapat berubah menjadi E dan S bebas kembali dengan kecepatan k2, atau menjadi E dan P dengan kecepatan k3.

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4.

5.

6.

7.

8.

9.

Jika k3  k4 , maka reaksi bersifat “irreversible”, sehingga produk P tidak ada yang diubah kembali menjadi substrat asal dan k4 dapat diabaikan diabaikan.. Suatu hal penting yang perlu diingat adalah bahwa konstanta k1, k2, k3 dan k4 proporsional dengan G aktivasi substrat dari reaksi yang bersangkutan Pada [S] yang rendah rendah,, kebanyakan enzim berada dalam bentuk bebas bebas,, sehingga penambahan S akan langsung terikat dengan E dan diubah menjadi P dengan demikian kecepatan awal proporsional dengan peningkatan [S]

Pada [S] yang lebih tinggi tinggi,, kecepatan reaksi bervariasi dengan peningkatan [S] karena enzim mulai mengalami kejenuhan Pada [S] yang tinggi tinggi,, semua enzim dijenuhi oleh substrat dan karenanya berada dalam bentuk kompleks ES Jadi enzim dalam suatu reaksi dapat berada dalam keadaan bebas dan terikat dengan substrat,, sehingga total enzim secara substrat matematis adalah

[E]0 = [E]+[ES]

10.

11.

12.

(2)

Penurunan persamaan Michaelis Michaelis--Menten tergantung pada asumsi yang disebut ”Briggs--Haldane Steady”Briggs Steady-State” Keadaan "steady state" adalah suatu keadaan dimana konsentrasi intermediat (perantara perantara)) ES tetap konstan konstan,, sementara konsentrasi substrat dan produk berubah Keadaan demikian terjadi apabila kecepatan pembentukan ES sama dengan kecepatan peruraian ES

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13.

Keadaan “steady” dapat dinyatakan secara matematis seperti dengan persamaan berikut

[ES]/ [ES]/t = 0

(3)

dimana t = waktu (menit menit)) 14.

Pernyataan [ES]/ [ES]/t dapat ditulis dari sudut konstanta dan konsentrasi pers (1) yaitu Kecepatan pembentukan ES

ES = k1[E][S]

(4a)

Kecepatan peruraian ES

ES = (k2 + k3) (ES) 15.

(4b)

Dalam keadaan "steady state" kedua persaman (4a) dan (4b) adalah sama sama,, sehingga

[ES]/ [ES]/t = k1[E][S] [E][S]--(k2+k3)(ES) = 0 (5)

16.

Subsitusi E dari pers (2) kedalam pers (5) menghasilkan (2) [E]0 = [E]+[ES] [E] = [E]0-[ES] (5) [ES]/ [ES]/t = k1[S][E] [S][E]--(k2+k3)(ES) k1[S][E] = k1[S]( [S]([E] [E]0-[ES] [ES])) = k1[S] [S][E] [E]0-k1[S] [S][ES] [ES] Hence k1[S] [S][E] [E]0-k1[S] [S][ES] [ES] - (k2+k3)(ES) = 0 k1[S][E]0–(k1[S]+k2+k3)[ES]=0

(6)

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17.

Pengaturan persamaan lebih lanjut (k1[S]+k2+k3)[ES] = k1[S][E]0 (7)

18.

Persamaan ini dapat dimodifikasi dengan cara ruas kanan dibagi dengan k1[S], [ES] 

19.

[E]0 1  (k2  k3 ) / k1[S]

(8)

Karena k1, k2, dan k3 adalah konstanta konstanta,, maka ketiga konstanta ini dapat dijadikan satu konstanta yaitu (k2 + k3 )/k1 = KM yang dikenal sebagai konstanta Michaelis Michaelis--Menten

20.

Untuk kebanyakan enzim k3  k2, sehingga KM akan mendekati (k2 + k1), sedang (k2 + k3 )/ k1 adalah Ks (konstanta dissosiasi kompleks enzim enzim--substrat substrat). ).

21.

Jika KM, yang merupakan ukuran affinitas enzim akan substrat,, disubsitusikan kedalam pers (8), maka substrat

[ ES ]  22.

[ P ]  k 3 [ ES ] t

(10)

Subsitusi [ES] dari pers. (10) ke dalam pers (9) memberikan

V  24.

(9)

Kecepatan reaksi katalisis dapat dinyatakan dengan jumlah produk yang tebentuk per satuan waktu yaitu produk dari konsentrasi kompleks ES dengan kapasitas katalisis enzim k3 (turnover number).

V

23.

[ E ]0 1  ( K M /[ S ])

k 3 [ E ]0 1  ( K M /[ S])

(12)

Pada keadaan E dijenuhi S yang berarti semua enzim terikat dengan substrat dalam kompleks ES, maka V = Vmax = k3[E]0. Kemudian persamaan diatas dapat ditulis dalam bentuk berikut.. berikut

V

Vmax Vmax[S] 1 (KM / [S]) atau V  K  [S] M

(13)

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25. 26.

Persamaan diatas dikenal sebagai persamaan Michaelis--Menten yang digunakan secara luas Michaelis Stoikiometri pers (13) didasarkan atas satu substrat dan satu produk (uni uni--uni uni), ), sementara banyak reaksi enzimatis yang melibatkan stoikiometri yang lebih kompleks seperti berikut berikut;;

S  P1 + P2 (Ui-Bi) S1 + S2  P (Bi-Uni) S1 + S2  P1 + P2 (Bi-Bi) 27.

Tetapi, persamaan Michaelis Tetapi, Michaelis--Menten berlaku untuk reaksi yang lebih kompleks sekalipun dengan mekanisme yang berbeda berbeda..

THANK YOU

Спасибо 謝謝 ً ‫ﺷﻛرا‬

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