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Glycolysis II Regulation

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To understand the different ways enzymes can be regulated ... gluconeogenesis. Fructose 1,6 bisphosphate. is an allosteric activator. of PK... and... – PowerPoint PPT presentation

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Title: Glycolysis II Regulation


1
Glycolysis II- Regulation
  • Lecturer Rick Kahn
  • October 11, 2001
  • RRC G-217
  • Phone 404-727-3561
  • E-mail rkahn_at_emory.edu

Objectives To begin to think about enzymes as
regulated catalysts To understand the different
ways enzymes can be regulated To learn the key,
regulated steps in glycolysis, the mediators of
regulation, and how it is connected to other
pathways
2
Glycolysis is just one of many pathways all going
on in a cell
YOU ARE HERE
3
Enzymes are REGULATED catalysts
  • Regulation can occur as a result of
  • limiting substrate availability - OFTEN
  • limiting enzyme concentration Genetic disease?
  • limiting turnover rate different isoforms?
  • covalent modification of the enzyme (e.g.
    phosphorylation)PFK2 and FBPase
  • compartmentation not many examples yet
  • through interaction(s) with modulators that bind
    to the substrate binding site (competitive
    inhibition)
  • to the product binding site (product inhibition)
  • or another, termed allosteric, site, that can be
    stimulatory or inhibitory Key concept

4
Catalytic sites on enzymes flicker between
having a substrate and a product binding sites
The Substrate
The Enzyme
The Product
5
Straightforward catalysis
Substrate
Enzyme in substrate binding conformation
Product
Enzyme in product binding conformation
6
Competitive inhibition
Substrate
Inhibitor
Note Inhibitor can be an alternate substrate or
simply bind to the catalytic site
7
Product InhibitionExcess product ties up the
enzyme in one state and thus slows catalysis
8
Allosteric inhibitionBinding of a ligand
outside the catalytic sitecan activate OR inhibit
Enzyme with Allosteric activating site
Enzyme with Allosteric activation and
inhibitory sites
Enzyme with Allosteric inhibitory site
Simple Enzyme
Allosteric Activator
Allosteric Inhibitor
Substrate
9
Allosteric activation
KD for substrate 0.10 µM
KD for substrate 10 µM
10
Allosteric Inhibition
In the absence of the allosteric inhibitor,
activity is high
In the presence of allosteric inhibitor, activity
is low substrate can accumulate
11
Highly regulated (important) enzymes can have
both allosteric activator and inhibitor sites
High Activity
Low Activity
Moderate Activity
12
A highly specialized (rare) case activator and
inhibitor sites overlap (PFK1)
Activator e.g., ADP
High Activity
Gamma phosphate of ATP
PFK1
Low Activity
Inhibitor ATP
13
Hypothetical Metabolic Pathway
In enzyme-limited steps the substrate accumulates
In substrate-limited reactions the substrate is
quickly metabolized so does not accumulate
Regulation can only occur at sites that are
enzyme-limited
14
Which steps in a pathway are the ones you would
want to regulate?
  • Entry to the pathway (the committed step)--PFK1
  • Exit from a pathway--Pyruvate Kinase
  • Entry/exit points within one pathway that go to
    or come from another pathway--Hexokinase (kind of)

15
Glucose transporters simply facilitate diffusion
(0 energy reqd)
  • Transport would be
  • readily reversible BUT
  • Glucose constantly
  • being metabolized
  • Rapid phosphorylation
  • prevents leakage out

16
Hexokinase and Glucokinase each catalyze the same
reaction but
Brain Muscle
Liver
Hexokinase is subject to product inhibition but
glucokinase is not When glycolysis (PFK1) is
inhibited, the pathway gets constipated and backs
up, resulting in shut down of hexokinase
17
The primary site of regulation of the glycolytic
pathway is PFK1
Commitment to Glycolysis
18
PFK 1 can sense the energy charge of the cell
because both ATP (inhibitory) and ADP
(stimulatory) are allosteric modulators
Glucose 6-phosphate
Regulators of PFK1 Adenine nucleotides (ATP,
ADP, AMP) Citrate F2,6 bisphosphate pH
Fructose 6-phosphate
Phosphofructokinase 1 (PFK1)
Fructose 1,6-bisphosphate
?
?
?
Glycolysis
ATP
ADP
Work
Pyruvate
Citrate
TCA cycle
19
Phosphofructokinase 2 (PFK2) generates fructose
2,6-bisphosphate, an allosteric activator of PFK1
Glucose 6-phosphate
Fructose 6-phosphate
Fructose 2,6-bisphosphatase
PFK1
PFK2
?
Fructose 1,6-bisphosphate
Fructose 2,6-bisphosphate
Fructose 2,6-bisphosphate is a dead end and can
only be cleaved by phosphatase back to fructose
6-phosphate Why, why, why? Why is there PFK2 and
fructose 2,6 bisphosphate? PFK2 is the
supercharger of glycolysis.
Glycolysis
20
PFK2 allows for endocrine (insulin and glucagon)
regulation of glycolysis
21
Last step (Pyruvate Kinase) is also regulated by
glucagon and F1,6BP
When GlucoseBLOOD is low, glucagon is up, PKA
is active, liver PK gets phosphorylated, and is
turned off this is part of the switch to
gluconeogenesis Fructose 1,6 bisphosphate is
an allosteric activator of PK and ATP is an
allosteric inhibitor
22
Summary of Glycolysis Regulation
  • Three enzymes involved are PFK1, PK, and
    hexokinase (and PFK2)
  • The changes all make sense.
  • When there is plenty of ATP in the cell, slow it
    down to allow storage of glycogen in the liver
    thus hexokinase off, PFK off (ATP and citrate
    allosteric inhibition, little ADP to activate).
  • When blood glucose is high, insulin is up, PFK1
    is on, PFK2 is on (further activating PFK1), PK
    is on
  • When blood glucose is low, most cells go into
    energy sparing mode to conserve for
    brain/muscle glucagon is up, PFK1 is off, PFK2
    is off, PK is off

23
Regulation of input and output from glycolytic
pathway integrates it with other metabolic
pathways
REGULATED
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