Enzymes PDF - Almaaqal University

Summary

This document contains lecture notes on enzymes, covering topics such as mechanism, theories of enzyme action, rate of enzyme reactions, temperature and pH effects, enzyme concentration and substrate concentration effects on enzyme activity, denaturation, and enzyme inhibitors. It is helpful for students studying biochemistry.

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Almaaqal University

Enzymes
Dr/ Wael Sobhy Darwish
Biochemistry PhD
Lec-3
 Mechanism of enzyme action
 Enzymes are very specific and it was suggested by Fischer in 1890 that
this was because the enzyme had a particular shape into which the
substrate or substrates fit exactly.
 Theories of Enzyme Action
1- The Key and Lock (Fisher model) Theory:
The active site of the enzyme is complementary in conformation to the
substrate, so that enzyme and substrate recognize each other.
- This theory postulates that active site has fixed shape.
2- The Induced Fit Theory (Khoshland model)
It is a flexible model.
An enzyme-substrate complex forms when the enzyme’s active
site binds with the substrate like a key fitting a lock.
The substrate molecule does not fit exactly in the active site.
This induces a change in the enzymes shape to make a closer fit.
 Rate of enzyme reactions
The rate of enzyme reaction is measured by the amount of
substrate changed or amount of product formed during a period
of time.
The rate is determined by measuring the slope of the tangent to
the curve in the initial stage of the reaction. The steeper the slope,
the greater is the rate.
If enzyme activity is measured over a period of time, the rate of
reaction usually falls, most commonly as a result of a fall in the
substrate concentration.
 Temperature:
 Raising temperature generally speeds up a reaction, and
lowering temperature slows down a reaction. However, extreme
high temperatures can cause an enzyme to lose its shape
(denature) and stop working.
 pH
pH: Each enzyme has an optimum pH range. Changing the pH
outside of this range will slow enzyme activity. Extreme pH values
can cause enzymes to denature.
 ENZYME CONCENTRATION
Enzyme concentration: Increasing enzyme concentration will
speed up the reaction, as long as there is substrate available to
bind to. Once all of the substrate is bound, the reaction will no
longer speed up, since there will be nothing for additional
enzymes to bind to.
 SUBSTRATE CONCENTRATION
Increasing substrate concentration also increases the rate of
reaction to a certain point. Once all of the enzymes have bound,
any substrate increase will have no effect on the rate of reaction,
as the available enzymes will be saturated and working at their
maximum rate.
 Denaturation:
If the hydrogen bonds within an enzyme are broken, the enzyme
may unfold or take on a different shape. The enzyme is
denatured.
A denatured enzyme will not function properly because the shape
of the active site has changed.
If the denaturation is not severe, the enzyme may regain its
original shape and become functional.
-Causes of denaturation:
– Heat
– Changes in pH (Acids and bases).
Heavy-metal ions (lead, arsenic, mercury).
– Organic Solvents (Alcohol, acetone).
– UV radiation.
 Enzyme Inhibitors
Enzyme inhibitors are chemicals that bind to an enzyme and
prevent the formation of an enzyme-substrate complex,
thereby preventing the formation of products.
The Inhibitors: poisons, like cyanide, antibiotics, anti-
metabolites and some drugs.

Enzyme Inhibitors

Reversible Irreversible

Competitive Non-competitive Uncompetitive
 Irreversible inhibitors:
1. The inhibitor occupying the active sites by forming covalent bonds or they
may physically block the active sites.
2. The inhibitor destroying the globular structure.
 Reversible inhibitors
Reversible inhibitors attach to enzymes via non-covalent
interactions like hydrogen bonds, hydrophobic contacts, and ionic
bonds.
When attached to an enzyme, reversible inhibitors do not undergo
chemical reactions and can be easily eliminated by dilution or
dialysis.
 Competitive Inhibition
The inhibitor binds at the active site and directly prevents the substrate from
binding
The inhibitor is structurally and chemically similar to the substrate
The competitive inhibitor blocks the active site and thus prevents substrate
binding
As the inhibitor is in competition with the substrate, its effects can be reduced by
increasing substrate concentration.
 Noncompetitive Inhibition
Non-competitive inhibition involves a molecule binding to a site
other than the active site (an allosteric site) leading to a
conformational change to the enzyme’s active site and indirectly
prevents the substrate from binding.
As the inhibitor is not in direct competition with the substrate,
increasing substrate levels cannot mitigate the inhibitor’s effect.
 Uncompetitive inhibition,
Uncompetitive inhibition, also known as anti-competitive
inhibition, takes place when an enzyme inhibitor binds only
to the complex formed between the enzyme and the substrate
(the E-S complex).
 Category Irreversible Inhibitor Reversible Inhibitor

There is covalent bonding Enzymes have a loose
Bonding between enzymes and noncovalent bond with an
inhibitors inhibitor

They permanently block They temporarily block
Affect
enzyme activity enzyme activity

Competitive Inhibitor
Group-specific reagent
Non-competitive inhibitor
Types Reactive Substrate Analogs
Uncompetitive Inhibitor
Suicide Inhibitors
Mixed Inhibitor

Enzyme activity can not be Enzyme activity can be
Enzyme activity
restored restored

Their activity can be reduced
Substrate concentration has
Substrate concentration by increasing substrate
no effect on their activity
concentration