Biochem 7_ Enzyme Kinetics PDF

Summary

This document provides an overview of enzyme kinetics, including various aspects of chemical reactions catalyzed by enzymes. Key topics covered are objectives, definitions, comparisons, examples, and applications within the realm of biology and biochemistry. It presents relevant information in the form of notes and diagrams.

Full Transcript

Enzymes Part 2: Reposted
• Objectives slides were added to beginning
• Updates were made to the following original slide

#’s:
• #3: Missing “+” and “H” were added to “NAD+” and

“NADH”
• #24: enzyme is “hexokinase”

Enzymes Part 2
Kinetics

Dr. Heisel

BMS100

Kinetics Objectives
• Define Km, Vmax
• Define what is meant by a first order, pseudo-first

order, and zero order reaction, and state whether
or not each conforms to Michaelis-Menten kinetics
• Compare and contrast glucokinase and hexokinase
• Define Kcat and provide the ratio that determines
enzyme efficiency
• Provide examples of physiologically efficient
enzymes and their roles

Kinetics Objectives
• Use Michaelis-Menten kinetics and

Lineweaver-Burk plots to:
• Determine the Km and Vmax of an enzyme
• Distinguish different types of enzyme inhibition

• Define and provide examples of reversible,

irreversible, and allosteric inhibition
• Use Km and Vmax to different competitive,
uncompetitive and non-competitive inhibition
• Recognize the graph of an allosteric enzyme in the
presence and absence of an inhibitor

Pre Reading Review
• What is meant by a first order reaction?
• What is happening in a zero order reaction?
• What can we use a Lineweaver-Burk plot for?

?
?

?

?

Application of Km: Assignment
Review
NAD+
Ethanol

NAD+
NADH
+ H+
Acetaldehyde

NADH
+ H+

Acetate

E = aldehyde
dehydrogenase

Alcohol consumption
https://freesvg.org/1455185701

Flushing

Back to normal

https://commons.wikimedia.org/wiki/File:Smiley_Face.JPG

Application of Km and Vmax:
Glucokinase
• Hexokinase (in most tissues) contrasts to

glucokinase (liver) in the following ways:
• Lower Vmax
• Lower Km
• It is turned off by high concentrations of glucose-6-P

Glucokinase and
Hexokinase
What same reaction (substrate and product) do
both hexokinase and glucokinase catalyze?
- Glycolysis and glycogenesis
The product can be used for one of two glucose
metabolism pathways: glucose-6-phosphate
• One that breaks down glucose = glycolysis
• One that stores glucose = glycogenesis
?
?

Product

Glucokinase and
Hexokinase
• Which line in the graph

represents:
• Glucokinase
• Hexokinase

A

• Which intercepts (A-D)

represent:
• Vmax
• ½ Vmax
• Km

C

B
Abali, Emine E; Cline, Susan D; Franklin, David S; Viselli, Susan
M. Lippincott Illustrated Reviews: Biochemistry (Lippincott
Illustrated Reviews Series) (p. 108). Wolters Kluwer Health.

D

Glucokinase and Hexokinase
• What does the higher Km tell you about the affinity

of glucokinase for glucose, as compared to the
affinity of hexokinase for glucose?

Which enzyme is therefore active even during fasting?
- hexokinase
• Hint: It is the one that can convert even small amounts of

glucose into energy

Which enzyme doesn’t become active until after a
high-carbohydrate meal? - glucokinase
• Hint: It is the one that needs lots of glucose to be activated
• What do you think is the main role of this enzyme: glycolysis,
or glycogenesis?

Glucokinase and Hexokinase
• Let’s review
• Reaction? Pathways?
• Graph?
• Fasting vs Feeding?

A

C

B

D

Glucokinase and Hexokinase
• How does the liver fit into all this?
• Glucokinase is found here
• Nutrients absorbed from the intestine go here first
• Allows glucokinase to convert excess glucose from a

meal to glycogen

https://commons.wikimedia.org/wiki/File:Depiction_of_a_man_suffering_from_fatty_liver.png

Glucokinase and Hexokinase
• So if hexokinase can’t do glycogenesis, what

pathway does it feed into? - glycolysis and will
trap glucose as needed
• How does this explain its low Km? - low Km = high

affinity

• Why do you think hexokinase is inhibited by

glucose-6-P, but glucokinase is not?

Glucokinase and Hexokinase
High Vmax = high capacity to convert substrate to
product
• Allows

glucokinase to phosphorylate lots of
glucose to glucose-6-P after a meal, so it can be
stored as glycogen
•

Review: What is significant about adding a P to
glucose?

High Glucose
HK pathway
used for
energy
- Runs until
what
happens?

Glucose
Glucose
GK
HK

(-)

Glucose-6-P

Glycolysis

Glycogenesis

Glucose-6-P
GK pathway used for
storage
- High Vmax: lots of
glucose to G-6-P
- Continues as long as
glucose is high. Turns
off when glucose is
low again due to its
low affinity

Km: What else is it good for?
• Km also helps determine enzyme efficiency

Kcat
Km

measures speed of P formation
once ES has been made
measures binding affinity of E and S
to make ES

E+S

ES

E+P

Enzyme Efficiency
• Which is a more efficient enzyme: one with a

larger or smaller value for Kcat/Km?

Kcat
Km

measures speed of P formation
once ES has been made
measures binding affinity of E
and S to make ES

Enzyme Efficiency
• Not surprisingly, enzymes with very important

physiological functions tend be very efficient.
• What is the general purpose of each of the following

very efficient enzymes?
•
•
•
•

Carbonic anhydrase
Triose phosphate isomerase
Fumarase
Acetylcholinesterase

Enzyme Inhibition
• M & M kinetics also aids in the study of enzyme

inhibition
What are some applications of enzyme inhibition? example G6P will shut down hexokinase
• Physiological feedback mechanisms
• What example of this did we just see?

Clinical therapies
• Ex: Use of pharmaceuticals to inhibit viral enzymes from

replicating in HIV

Enzyme Inhibition
Types
• Reversible inhibition
• Competitive, uncompetitive, noncompetitive
• Follow M & M kinetics

Irreversible inhibition
Inhibition of allosteric enzymes (multisubunit)

Reversible Enzyme Inhibition:
Competitive
• Competitive inhibition
• Reversible binding of the inhibitor to the active site of
the enzyme

I

No product

S

Product

https://commons.wikimedia.org/wiki/File:Enzyme_inhibition_schemes.pn

Reversible Enzyme Inhibition:
Competitive
Example: Methotrexate
Used for chemotherapy
• Competitively inhibits the enzyme that helps
convert folate (B9) into its coenzyme form
•

•
•

FYI: E = dihydrofolate reductase

Folate coenzymes normally feed into purine and
pyrimidine production – what are these used for?

• How

does methotrexate help prevent the spread
of cancer cells?

Reversible Enzyme Inhibition:
Competitive
• Competitive inhibition
• Why doesn’t Vmax change?
• Does the affinity of the enzyme
appear to go up or down in the
presence of the inhibitor? Why?
• Kmapp or Ki

https://commons.wikimedia.org/wiki/File:Enzyme_Inhibition_lineweaver-burk_plots.gif

Reversible Enzyme Inhibition:
Uncompetitive
• Uncompetitive
• Reversible binding of I to ES
• Rare
Substrate
Product
formation
Inhibitor
No product
formation

https://commons.wikimedia.org/wiki/File:Enzyme_inhibition_schemes.pn

Reversible Enzyme Inhibition:
Uncompetitive
• Uncompetitive inhibition
• Is Vmax lower or higher with I?
Why?
• Does the affinity of the enzyme
appear to go up or down in the
presence of the inhibitor? Why?

https://commons.wikimedia.org/wiki/File:Enzyme_Inhibition_lineweaver-burk_plots.gif

Reversible Enzyme Inhibition:
Noncompetitive
• Noncompetitive
• Reversible binding of I to E or ES
• Example: Product inhibition
• G-6-P inhibition of hexokinase
Substrate
Product
formation
Inhibitor
No product
formation
https://commons.wikimedia.org/wiki/File:Enzyme_inhibition_schemes.pn

Reversible Enzyme Inhibition:
Noncompetitive
• Noncompetitive inhibition
• Is Vmax lower or higher with I? Why?
• Ki does not change
• Binding to E appears to lower

affinity, binding to ES appears to
increase affinity: cancel out!

https://commons.wikimedia.org/wiki/File:Enzyme_Inhibition_lineweaver-burk_plots.gif

Practice At Home
• Which are competitive, uncompetitive,

noncompetitive? How do you know?

https://commons.wikimedia.org/wiki/File:Enzyme_Inhibition_lineweaver-burk_plots.gif

Irreversible Enzyme
Inhibition
Irreversible
• Occurs when an inhibitor forms a covalent bond
with the active site of the enzyme
•

Compare and contrast to competitive inhibition

Examples
• Penicillin: Blocks the enzyme required for synthesis
of bacterial cell walls
• Lead poisoning: Review: Pb+2 binds to sulfhydryl
groups in an enzyme involved in heme synthesis
•

Changes its shape so it no longer functions
•

How can this lead to anemia?

Inhibition of Multi-subunit
Allosteric Enzymes
• Multi-subunit allosteric enzymes
• Review: What happens when an activator, which could
be the substrate, binds?
• What is the resulting shape of the binding graph?
• What effect would an inhibitor have on the graph?
Enzyme

Substrate

Slow

Faster

Fastest

Inhibition of Multi-subunit
Allosteric Enzymes
• Sigmoidal graph
• Inhibitor produces a right shift
Enzyme

A
Enzyme plus
B inhibitor

C

Inhibition of Multi-subunit
Allosteric Enzymes
Example: Phosphofructokinase 1 (PFK1)
• Binding of F-6-P to one subunit enhances binding of
F-6-P to other subunits
•

Creates a sigmoidal graph

• Allosterically inhibited by ATP
•

What does the term “allosteric inhibition” tell us about
where ATP binds when it is acting as an inhibitor vs a
substrate? - there has to be 2 sites on the enzyme
• There is an active site and an allosteric
•

How do you think the Km for these different sites
compare?

End of Enzyme Kinetics