580 13 Chemical Reaction Mechanisms II: Catalysis and Miscellaneous Topics
Use the data of Example 13.5 to make a linear least-squares fit ofri/[R] as a function ofri. Find
the value of the Michaelis–Menten constant for the reaction of Example 13.5 and compare it
with the value from the Lineweaver–Burk plot of Example 13.5.
aG. S. Eadie,J. Biol. Chem., 146 , 85 (1942).
Enzyme Inhibition
Many enzyme-catalyzed reactions are subject toinhibition. That is, the rate of the
process is decreased by the presence of some substance, which is called aninhibitor.
Thedegree of inhibitionis defined as
i 1 −
r
r 0
(13.1-49)
whereris the rate of the catalyzed reaction in the presence of the inhibitor and r 0 is
the rate in the absence of the inhibitor. Acompetitive inhibitoris one for which the
degree of inhibition decreases if the reactant concentration is increased with constant
concentration of the inhibitor. Anoncompetitive inhibitoris one for which the degree of
inhibition is independent of the reactant concentration, and ananticompetitive inhibitor
is one for which the degree of inhibition increases if the concentration of the reactant
is increased.
CH 3
CH 3
Acetylcholine
CH 3 N+CH 2 CH 2 O C CH 3
O
HF
CH 3 H
Diisopropyl fluorophosphate
CH 3 CH 3
CH 3
CCO P O
O
Figure 13.9 The Structural For-
mulas of Acetylcholine and Diiso-
propyl Fluorophosphate.
The accepted mechanism for competitive inhibition is that the inhibitor can occupy
the same active site as the reactant.Acetylcholineis aneurotransmitter(a substance that
diffuses across the synapse between two nerve cells and triggers a signal in the second
nerve cell). This substance is hydrolyzed by the enzymecholinesterase, which causes
the signal to be ended by lowering the concentration of acetylcholine. Figure 13.9
shows the structural formulas of acetylcholine and of diisopropyl fluorophosphate,
which is a competitive inhibitor for this hydrolysis. The diisopropyl fluorophosphate
molecules compete with the acetylcholine molecules for the active sites, which inhibits
the catalyzed reaction since those enzyme molecules with diisopropyl fluorophosphate
molecules in their active sites are not available for acetylcholine hydrolysis. With suffi-
cient inhibition the neurotransmitter remains in the synapse and the nerve cell transmits
a signal repeatedly. If the nerve cell repeatedly stimulates a muscle to contract the mus-
cle soon succumbs to fatigue and the organism could die. Various substances similar
to diisopropyl fluorophosphate have been prepared as insecticides and as chemical
warfare agents (“nerve gases”).
A proposed mechanism for a noncompetitive inhibitor is that an enzyme has a second
site, other than the catalytic active site, to which the inhibitor can bind. The inhibited
enzyme molecule is assumed unable to catalyze the reaction, although the active site
is not occupied.
PROBLEMS
Section 13.1: Catalysis
13.1 a.The hydrogenation of ethylene on a copper surface
appears to follow the Langmuir–Hinshelwood
mechanism, with the rate law
rate
ka[H 2 ][C 2 H 4 ]
( 1 +kb[C 2 H 4 ])^2
What conclusion can you draw from this rate law?