Enzymes PDF

Summary

This document provides a lecture or presentation on enzymes and their functions in biochemistry and molecular biology. It covers subjects like the role of enzymes, enzyme specificity, types of enzymes, and their clinical significance.

Full Transcript

AIU-PT
Prof. Rasha Nassra
Medical Biochemistry & Molecular Biology
SUBJECTS Water
TO BE Macromolecules
COVERED (ECM)
Enzymology
Vitamins & Minerals
Cell Membrane
& Signal Transduction

Molecular Biology
SUBJECTS
TO BE
COVERED

Enzymes

Molecular Biology
1. Define terms used in enzymology
2. Describe the role of enzymes as biological
catalysts
3. Explain enzyme specificity
4. Define Ribozymes and recognize their
functions
 Enzymes

✓ Act at very small concentrations,
✓ Increase the speed of chemical

reactions
Without changing the result.
✓ At the end of the reaction the

structure
of the enzyme
Unchanged
TERMS USED IN ENZYMOLOGY

 Substrate: Is the organic substance on which
the enzyme acts.

 Product: Is the organic substance produced
by the action of the enzyme

 Coenzymes: Essential for the activity of
enzymes and they are considered as second
substrates or Co-substrate
(Substrate)
 SUBSTRATE

 Molecule that enters a reaction to be
transformed by the catalytic activity of an
enzyme.
 All molecules that enter an enzymatic
reaction and are permanently modified are
called substrates.
 PRODUCT

 Molecule that appears during an enzyme
catalyzed reaction.
 The new molecule that results from this
transformation is called the product.
 CATALYTIC SITE

A special sequence of amino acids in the
protein molecule of the enzyme to which
the substrate is attached.
 ACTIVE SITE

A more general term which involves
all sequences of amino acids
which affect the activity of the
enzyme

Includes for example
the catalytic site, the allosteric sites
TERMS USED IN ENZYMOLOGY

Catalytic site
 ENZYMATIC REACTION

 SUBSTRATE ENZYME PRODUCT
 Enzymes are:
Organic catalysts,
Protein in nature
RIBOZYME
 Non-protein Organic catalysts

✓ Segments
of RNA
✓ Display an enzyme activity
in the absence of protein
✓ Acting on
themselves or other RNA molecules

✓ Require divalent metal cations (eg. Mg2+ ) as cofactors
GENERAL PROPERTIES OF
ENZYMES:
They are of high molecular weight,
Thermolabile, (substance that is
subject to destruction /decomposition
or change in response to heat ---------
lose their activity when the body
temperature is high)
NOMENCLATURE
Enzymes which were discovered
early were given general names:

Example: ptyalin, pepsin,
trypsin, cathepsin, emulsin
etc......
 Now a suffix (ase) is added to indicate enzyme
The prefix may be:

General nature of substrate e.g.:
protease, lipase
Name of substrate: urease, lactase
Type of reaction e.g.: transaminase,
dehydrogenase.
 Combination:

Name of substrate + type of reaction
e.g.: Lactate Dehydrogenase

Glycogen Synthase
 1. Absolute
(total)
2. Structural
(group)
3. Relative
(bond)
ENZYME 4.
SPECIFICITY
Stereochemic
al
Absolute
 amino group of an aromatic a.a.
& carboxylic group of another amino acid

carboxylic group of basic a.a.
and amino group of another amino acid

Structural
Relative

Alpha ester bonds at position 1 & 3 in Triglycerides
Stereochemical
1. Absolute specificity(total)

The enzyme acts only on a specific
substrate

 Lactase acts on lactose
2. GROUP SPECIFICITY (STRUCTURAL
SPECIFICITY):
Acts on a special type of bond at specific site
and attached to specific groups
A) Pepsin:
peptide bonds between amino group of
aromatic amino acid and carboxylic group of
another amino acid
B) Trypsin:
peptide bonds between carboxylic group of
basic amino acid and amino group of another
amino acid
3. RELATIVE SPECIFICITY
Acts at different rates on one type of bond in
compounds chemically related

Pancreatic lipase: hydrolyzes alpha ester bonds
at position 1 & 3 in Triglycerides
4. STREOCHEMICAL SPECIFICITY
A) Enzymes act on D or L isomers
D - Amino acid oxidase acts only on D-amino acids
L- Amino acid oxidase acts only on L-amino acids

B) Enzymes act on specific type of linkages
(α ou β)
❖ Amylase hydrolyses α-1.4 glycosidic linkage of
starch.
CLINICAL IMPORTANCE
OF ENZYMES
DIAGNOSIS OF DISEASES

Enzymes are intracellular and when
there is cellular damage, they are
released into
the circulation
ENZYMES IN PLASMA
A. FUNCTIONAL PLASMA ENZYMES
Present normally in blood to perform certain
physiological functions

Synthesized in the liver.
Present in blood in higher concentration than
tissues.
Their substrates are present in the
circulation.
Examples:
✓ Enzymes of blood clotting
NON-FUNCTIONAL PLASMA
ENZYMES
 Present in a very low concentration in blood
due to tissue turn over
1.Perform no physiological function in blood.
2. Their substrates, are absent from blood.
3. Their level is normally low and increase in
tissue damage.
Examples:
1. Alkaline phosphatase:
increases in obstructive jaundice, and
metastatic carcinoma to bone.
NON-FUNCTIONAL PLASMA
ENZYMES

Some enzymes can be used as tumor markers
II. TREATMENT OF DISEASES

Digestiveenzymes in treatment
of maldigestion.
MECHANISM OF ENZYME ACTION:
Most of the chemical reactions in the body fail
to react rapidly because most of them
possess insufficient kinetic energy to overcome
the energy barrier for reaction.

Enzymes may be considered to lower energy
barriers for chemical reactions

✓ reduce activation energy
MECHANISM OF ENZYME ACTION
 Transition state
Unstable arrangement of atoms in which
chemical bonds are in the process of being
formed or broken

Activation energy
The energy required to reach the transition
state from the ground state of the
reactants
 MECHANISM OF
ENZYMATIC CATALYSIS
Enzymes
Increase the rate of the reactions
by lowering the activation energy
(free energy of activation)
REDUCE ACTIVATION ENERGY
MODE OF ACTION OF ENZYME