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MBB 323

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VP = k2 k1 CA CEinitial /(k1CA k-1 k2), = k2 CA CEinitial /(CA (k-1 k2)/ k1) ... f(cat) = 1/2 when CA = Km. 3. Michaelis-Menten equation ... – PowerPoint PPT presentation

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Title: MBB 323


1
MBB 323
  • Lecture 30
  • Enzymes (Chapter 8)

2
Michaelis-Menten equation
  • This approximation results in the
    Michaelis-Menten equation derived from
  • AE lt-gt EA -gt P E
  • (k1, k-1) k2
  • Equation 1 VP k2 CEA
  • Equation 2 CEA k1 CA CEinitial /(k1CA k-1
    k2),
  • Equation 2 into equation 1 gives
  • VP k2 k1 CA CEinitial /(k1CA k-1 k2),
  • k2 CA CEinitial /(CA (k-1 k2)/ k1),
  • The M-M equation
  • VP VMax CA /(CA Km), with VMax k2
    CEinitial,Km (k-1 k2)/ k1
  • We could define f(cat) VP /VMax in analogy to
    the f used in binding calculations. f(cat) 0 for
    no velocity and 1 for max velocity
  • f(cat) CA /(CA Km), note the similarity
    with the binding calculation on slide 4 of
    this lecture.
  • f(cat) 1/2 when CA Km

3
Michaelis-Menten equation
  • This approximation results in the
    Michaelis-Menten equation derived from
  • AE lt-gt EA -gt P E
  • (k1, k-1) k2
  • The M-M equation
  • VP VMax CA /(CA Km), with VMax k2
    CEinitial,Km (k-1 k2)/ k1
  • Define
  • kcat VMax /CEinitial
  • This is the maximum rate at which an enzyme can
    convert substrate into product (see overhead).

4
Michaelis-Menten equation
  • The M-M equation at low substrate concentrations
    (p408), can be further approximated as
  • VP VMax CA /(CA Km), in the limit CA tends
    to zero.
  • VMax CA /Km,
  • At high substrate concentration the equation also
    reduces to
  • VP VMax CA /(CA Km), in the limit CA tends to
    infinity.
  • VMax,
  • Study p413-414 to understand how more complicated
    situations can also reduce to the M-M form when
    only working with steady-state kinetics.
  • -This means that relaxation techniques are
    required to understand more complicated kinetic
    schemes.

5
Competitive Inhibition
  • The M-M situation consider in the presence of a
    compound I that can bind to the enzyme but not
    react (p416-418).
  • 1. A E lt-gt EA -gt P E
  • (k1, k-1) k2
  • 2. I E lt-gt EI
  • KI
  • We can write using KI CECI/CEI
  • that the total amount of enzyme (which is
    conserved) is
  • CEinitial CE CEA CEI
  • CEinitial CE CEA CECI /KI
  • CE (1CI /KI) CEA
  • CE (CEinitial - CEA)/(1CI /KI) See slide 10
    lecture 29 and page 407-408.
  • The net effect is to change to a new K(I)m Km
    (1CI /KI),
  • This equation makes sense, K(0)m Km, also since
    the inhibition is competitive the maximum
    velocity of the reaction is unaffected even at
    high concentrations of the inhibitor (see
    overhead).

6
Noncompetitive Inhibition
  • A number of general and important classes which
    we will not treat in detail.
  • Irreversible (i.e. covalent or suicide)
    modification of active site residues.
  • -Glyceraldehyde-3-phosphate dehydrogenase (1 mM
    in the cell, substrate is lt 100 mM).
  • (Aldehyde to acyl phosphate using NAD -gt NADH)
  • -Enzyme is inhibited by sulfhydryl reactive
    compounds (iodoacetly derivatives).
  • -Provides evidence of mechanism (thioester
    linkage of substrate to enzyme as intermediate
    step).
  • Allosteric effects
  • 2. Reversible binding, but not at the active
    site
  • 3. Reversible binding, to the enzyme-substrate
    complex.
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