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Chapter 15 Enzymes

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Title: Chapter 15 Enzymes


1
Chapter 15 Enzymes
2
Enzymes
  • Ribbon diagram of cytochrome c oxidase, the
    enzyme that directly uses oxygen during
    respiration.

3
Enzyme Catalysis
  • Enzyme A biological catalyst.
  • With the exception of some RNAs that catalyze
    their own self-cleavage, all enzymes are
    proteins.
  • Enzymes can increase the rate of a reaction by a
    factor of 109 to 1020 over an uncatalyzed
    reaction.
  • Some catalyze the reaction of only one compound.
  • Others are stereoselective for example, enzymes
    that catalyze the reactions of only L-amino
    acids.
  • Others catalyze reactions of specific types of
    compounds or bonds for example, trypsin
    catalyzes hydrolysis of peptide bonds formed by
    the carboxyl groups of Lys and Arg.

4
Enzyme Catalysis
  • Figure 15.1 Trypsin catalyzes the hydrolysis of
    peptide bonds formed by the carboxyl group of
    lysine and arginine.

5
Classification of Enzymes
  • Enzymes are commonly named after the reaction or
    reactions they catalyze.
  • Example lactate dehydrogenase, acid phosphatase.
  • Enzymes are classified into six major groups
    according to the type of reaction catalyzed
  • Oxidoreductases Oxidation-reduction reactions.
  • Transferases Group transfer reactions.
  • Hydrolases Hydrolysis reactions.
  • Lyases Addition of two groups to a double bond,
    or removal of two groups to create a double bond.
  • Isomerases Isomerization reactions.
  • Ligases The joining to two molecules.

6
Classification of Enzymes
  • 1. Oxidoreductase
  • 2. Transferase

7
Classification of Enzymes
3. Hydrolase
4. Lyase
8
Classification of Enzymes
  • 5. Isomerase
  • 6. Ligase

9
Enzyme Terminology
  • Apoenzyme The protein part of an enzyme.
  • Cofactor A nonprotein portion of an enzyme that
    is necessary for catalytic function examples are
    metallic ions such as Zn2 and Mg2.
  • Coenzyme A nonprotein organic molecule,
    frequently a B vitamin, that acts as a cofactor.
  • Substrate The compound or compounds whose
    reaction an enzyme catalyzes.
  • Active site The specific portion of the enzyme
    to which a substrate binds during reaction.

10
Schematic of an Active Site
  • Figure 15.2 Schematic diagram of the active site
    of an enzyme and the participating components.

11
Terms in Enzyme Chemistry
  • Activation Any process that initiates or
    increases the activity of an enzyme.
  • Inhibition Any process that makes an active
    enzyme less active or inactive.
  • Competitive inhibitor A substance that binds to
    the active site of an enzyme thereby preventing
    binding of substrate.
  • Noncompetitive inhibitor Any substance that
    binds to a portion of the enzyme other than the
    active site and thereby inhibits the activity of
    the enzyme.

12
Enzyme Activity
  • Enzyme activity A measure of how much a
    reaction rate is increased.
  • We examine how the rate of an enzyme-catalyzed
    reaction is affected by
  • Enzyme concentration.
  • Substrate concentration.
  • Temperature.
  • pH.

13
Enzyme Activity
  • Figure 15.3 The effect of enzyme concentration
    on the rate of an enzyme-catalyzed reaction.
    Substrate concentration, temperature, and pH are
    constant.

14
Enzyme Activity
  • Figure 15.4 The effect of substrate
    concentration on the rate of an enzyme-catalyzed
    reaction. Enzyme concentration, temperature, and
    pH are constant.

15
Enzyme Activity
  • Figure 23.5 The effect of temperature on the
    rate of an enzyme-catalyzed reaction. Substrate
    and enzyme concentrations and pH are constant.

16
Enzyme Activity
  • Figure 23.6 The effect of pH on the rate of an
    enzyme-catalyzed reaction. Substrate and enzyme
    concentrations and temperature are constant.

17
Mechanism of Action
  • Figure 15.7 Lock-and-key model of enzyme
    mechanism.
  • The enzyme is a rigid three-dimensional body.
  • The enzyme surface contains the active site.

18
Mechanism of Action
  • Figure 15.8 The Induced-fit model of an enzyme
    mechanism.
  • The active site becomes modified to accommodate
    the substrate.

19
Mechanism of Action
  • Figure 23.9 The mechanism of competitive
    inhibition.
  • When a competitive inhibitor enters the active
    site, the substrate cannot enter.

20
Mechanism of Action
  • Figure 15.10 Mechanism of noncompetitive
    inhibition. The inhibitor binds itself to a site
    other than the active site (allosterism), thereby
    changing the conformation of the active site.
    The substrate still binds but there is no
    catalysis.

21
Mechanism of Action
  • Figure 15.11 Enzyme kinetics in the presence and
    the absence of inhibitors.

22
Mechanism of Action
  • Both the lock-and-key model and the induced-fit
    model emphasize the shape of the active site.
  • However, the chemistry of the active site is the
    most important.
  • Just five amino acids participate in the active
    site in more than 65 of the enzymes studied to
    date.
  • These five are His gt Cys gt Asp gt Arg gt Glu.
  • Four of these amino acids have either acidic or
    basic side chains the fifth has a sulfhydryl
    group (-SH).

23
Catalytic Power
  • Figure 23.12 Enzymes provide an alternative
    pathway for reaction. (a) The activation energy
    profile for a typical reaction. (b) A comparison
    of the activation energy profiles for a catalyzed
    and uncatalyzed reactions.

24
Enzyme Regulation
  • Feedback control An enzyme-regulation process
    where the product of a series of
    enzyme-catalyzed reactions inhibits an earlier
    reaction in the sequence.
  • The inhibition may be competitive or
    noncompetitive.

25
Enzyme Regulation
  • Proenzyme (zymogen) An inactive form of an
    enzyme that must have part of its polypeptide
    chain hydrolyzed and removed before it becomes
    active.
  • An example is trypsin, a digestive enzyme.
  • It is synthesized and stored as trypsinogen,
    which has no enzyme activity.
  • It becomes active only after a six-amino acid
    fragment is hydrolyzed and removed from the
    N-terminal end of its chain.
  • Removal of this small fragment changes not only
    the primary structure but also the tertiary
    structure, allowing the molecule to achieve its
    active form.

26
Enzyme Regulation
  • Allosterism Enzyme regulation based on an event
    occurring at a place other than the active site
    but that creates a change in the active site.
  • An enzyme regulated by this mechanism is called
    an allosteric enzyme.
  • Allosteric enzymes often have multiple
    polypeptide chains.
  • Negative modulation Inhibition of an allosteric
    enzyme.
  • Positive modulation Stimulation of an allosteric
    enzyme.
  • Regulator A substance that binds to an
    allosteric enzyme.

27
Enzyme Regulation
  • Figure 15.14 The allosteric effect. Binding of
    the regulator to a site other than the active
    site changes the shape of the active site.

28
Enzyme Regulation
  • Figure 15.15 Effects of binding activators and
    inhibitors to allosteric enzymes. The enzyme has
    an equilibrium between the T form and the R form.

29
Enzyme Regulation
  • Protein modification The process of affecting
    enzyme activity by covalently modifying it.
  • The best known examples of protein modification
    involve phosphorylation/dephosphorylation.
  • Example Pyruvate kinase (PK) is the active form
    of the enzyme it is inactivated by
    phosphorylation to pyruvate kinase phosphate
    (PKP).

30
Enzyme Regulation
  • Isoenzyme (Isozymes) An enzyme that occurs in
    multiple forms each catalyzes the same reaction.
  • Example lactate dehydrogenase (LDH) catalyzes
    the oxidation of lactate to pyruvate.
  • The enzyme is a tetramer of H and M chains.
  • H4 is present predominately in heart muscle.
  • M4 is present predominantly in the liver and in
    skeletal muscle.
  • H3M, H2M2, and HM3 also exist.
  • H4 is allosterically inhibited by high levels of
    pyruvate while M4 is not.
  • H4 in serum correlates with the severity of heart
    attack.

31
Enzyme Regulation
  • Figure 15.16 The isozymes of lactate
    dehydrogenase (LDH). The electrophoresis gel
    depicts the relative isozyme types found in
    different tissues.

32
p649
33
Enzymes Used in Medicine
Table 15.2 Enzyme Assays useful in Medical
Diagnosis
Insert Table 23.2, page 648
34
Transition-State Analogs
  • Transition state analog A molecule whose shape
    mimics the transition state of a substrate.
  • Figure 15.17 The proline racemase reaction.
    Pyrrole-2-carboxylate mimics the planar
    transition state of the reaction (next screen).

35
Transition-State Analog
36
Transition-State Analogs
  • Abzyme An antibody that has catalytic activity
    because it was created using a transition state
    analog as an immunogen. (a) The molecule below is
    a transition analog for the reaction of an amino
    acid with pyridoxal-5-phosphate. (b) The abzyme
    is then used to catalyze the reaction on the next
    screen.

37
Transition-State Analogs
38
Catalytic Antibodies Against Cocaine
p652
39
Catalytic Antibodies Against Cocaine
p652
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