Post on 30-Dec-2015
description
M.Prasad NaiduMSc Medical Biochemistry,Ph.D.Research Scholar
•Diverse and widespread proteolytic enzymes
•Involved in digestion, development, clotting, inflammation…
•Common catalytic mechanism
P-Nitrophenolate is very yellow while the acetate is colorless. This is an example of an artificial substrate!
The kinetics show
1. A “burst phase” where the product is rapidly formed with amounts stoichiometric with the enzyme.
2. Slower steady state that is independent of substrate concentration.
A covalent bond between a Serine and the substrate suggests an “active Serine”. These Serines can be labeled with inhibitors such as diidopropyl phosphofluoridate specifically killing the enzyme.
Ser 195 is specifically labeled
DIPF is extremely toxic because other active Serines can be labeled. Such as acetylcholine esterase.
Nerve gases, serin gas, are very toxic!! Many insecticides also work this way.
His 57 is a second important catalytic residue. A substrate containing a reactive group binds at the active site of the enzyme and reacts with a nearby reactive amino acid group. A Trojan horse effect.
Tosyl-L-phenylalanine chloromethyl ketone (TPCK)
The reaction of TPCK with His 57 of chymotrypsin
Bovine Trypsin
Bovine trypsin catalytic triad
Catalytic mechanism
1. After the substrate binds Ser 195 nucleophilically attacks the scissile peptide bond to form a transition state complex called the tetrahedral intermediate (covalent catalysis) the imidazole His 52 takes up the proton Asp 102 is hydrogen bonded to His 57. Without Asp 102 the rate of catalysis is only 0.05% of wild-type.
2. Tetrahedral intermediate decomposes to the acyl-enzyme intermediate. His 57 acts as an acid donating a proton.
3. The enzyme is deacylated by the reverse of step 1 with water the attacking nucleophile and Ser 195 as the leaving group.
1. Conformational distortion forms the tetrahedral intermediate and causes the carboxyl to move close to the oxyanion hole
2. Now it forms two hydrogen bonds with the enzyme that cannot form when the carbonyl is in its normal conformation.
3. Distortion caused by the enzyme binding allows the hydrogen bonds to be maximal.
Triad charge transfer complex stabilization
Rates of Enzyme Reactions How fast do reactions take place
•Reaction rates
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!!
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”.
Chemical kinetics and Elementary Reactions
A simple reaction like A B may proceed through several elementary reactions like A I1 I2 B Where I1 and I2 are intermediates.
The characterization of elementary reactions comprising an overall reaction process constitutes its mechanistic description.
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
The order of a reaction = the sum of exponents
Generally, 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 B
A second order reaction two molecules react
A + B P + Q
or
2A P
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
dt
Pd
dt
Ad v
= velocity of the reaction
in Molar per min.
or
moles per min per volume
k = the rate constant of the reaction
AdtAd
kv
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
kdt
dv
Or for A + B P + Q
BABA
kdt
d
dt
dv
Percent change in A (ratio ) versus time in first and second order reactions
It is difficult to determine if the reaction is either first or second order by directly plotting changes in
concentration.
Adt
Ad k
dtd
kA
A
t
0
A
A
dtk-A
A
o
d to kAlnAln
-kto eA A
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.
2
A A o Plugging in
to rate equation
2
1
o
A2
A
ln kt
kk
693.02lnt
2
1
The half-life of a first order reaction can be used to determine the amount of material left after a length of time.
The time for half of the reactant which is initially present to decompose or change.
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.
A second order reaction such like 2A P
t
dtk0
A
oA2o
A
Ad-
ktoA
1
A
1
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 o2
1 A
1t
k
A bimolecular reaction A + B C A B + C at some point in the reaction coordinate an intermediate ternary complex will exist
A B C
This forms in the process of bond formation and bond breakage and is called a transition state.
Ha + Hb Hc Ha Hb + Hc
This is a molecule of H2 gas reforming by a collision
An energy contour of the hydrogen reaction as the three molecules approach the transition state at location c. This is called a saddle point and has a higher energy than the starting or ending point.
Energy diagrams for the transition state using the hydrogen molecule
Transition state diagram for a spontaneous reaction. X‡ is the symbol for the species in the transition state
Xk'BAkdt
Pd
Q P B A
For the reaction
‡ Where [X] is the concentration of the transition state species
BA
X K ‡
‡
G RTlnK - ‡ ‡
G‡ is the Gibbs free energy of the activated complex.
k' = rate constant for the decom-position of the activated complex
BAek't
P RT
G-
d
d
‡The greater the G‡, the more unstable the transition
state and the slower the reaction proceeds.
This hump is the activation barrier or kinetic barrier for a reaction.
The activated complex is held together by a weak bond that would fly apart during the first vibration of the bond and can be expressed by k' =where is the vibrational frequency of the bond that breaks the activated complex and is the probability that it goes towards the formation of products.
Now we have to define . E = h and = E/h where h is Planks constant relating frequency to Energy. Also through a statistical treatment of a classical oscillator E= KbT where Kb is Boltzmann constant.
By putting the two together
h
TK k b
RT
Gb
h
TK k
eAnd
The rate of reaction decreases as its free energy of activation, G‡ increases
or the reaction speeds up when thermal energy is added
‡
Consider PA 21 kk IIf one reaction step is much slower than all the rest this step acts as a “bottleneck” and is said to be the rate-limiting step
Catalysts act to lower the activation barrier of the reaction being catalyzed by the enzyme.
Where G‡cat = G‡
uncat- G‡cat
The rate of a reaction is increased by RT
Gcate
G‡cat = 5.71 kJ/mol is a ten fold increase in rate.
This is half of a hydrogen bond!!
G‡cat = 34.25 kJ/mol produces a million fold
increase in rate!!
Rate enhancement is a sensitive function of G‡cat