AIU Medical Biochemistry 2024-2025 Lecture Notes PDF

Summary

These lecture notes cover the basics of enzymes, including their role as biological catalysts, different types of enzymes, and enzyme activity. They’re part of a medical biochemistry course for the academic year 2024-2025.

Full Transcript

Medical Biochemistry 2024-2025

ENZYMES 1 (Week 8)
ILOs:
Describe the role of enzymes as biological catalysts
Define terms used in enzymology
Explain enzyme specificity
Define Ribozymes and recognize their functions

Introduction to Enzymatic reactions
Enzymes are specialized proteins that function in the acceleration of
chemical reactions. Many reactions required for normal activity of cells would
not proceed fast enough at the pH and temperature of the body without these
specialized proteins. The term defining the speed of a chemical reaction,
whether catalyzed or uncatalyzed, is rate or velocity. Rate (velocity) is the
change in amount of starting materials (substrates) or products per unit time.
Enzymes increase the rate by acting as catalysts. A catalyst increases the
rate of a chemical reaction but is not itself changed in the process.
Two important characteristics of enzyme catalysts are that the enzyme is not
changed as a result of catalysis and the enzyme does not change the
equilibrium constant of the reaction but simply increases the rate at which
the reaction approaches equilibrium.
Enzymes may be considered to lower energy barriers for chemical reactions
i.e., reduce activation energy.

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 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.

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Enzymes as biological catalysts
✓ Enzymes are almost all very large globular proteins of high molecular
weight.

✓ 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 is unchanged
✓ Thermolabile, (substance that is subject to destruction
/decomposition/denaturation in response to heat) so lose their activity
when the body temperature is high.

!! RIBOZYMES:
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

Terms used in enzymology
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: The substance that is produced by the action of the enzyme.

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Apoenzyme: protein portion of an enzyme which is catalytically inactive.
Coenzyme: Essential for the activity of enzymes and they may be
considered as second substrates or Co-substrate.
Catalytic site: a particular arrangement of amino acids side chain in the
polypeptide, specific to bind a specific substrate, also contains the
machinery involved in catalyzing the reaction.
Allosteric site: a region of enzyme molecules not at the catalytic site
where small molecules bind and effect a change in the activity of the active
site by change in the conformation of the enzyme. This causes the active
site to become either more active or less active by increasing or
decreasing the affinity of enzyme for substrate.
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

Naming (Nomenclature) of Enzymes
A suffix (ase) is added to indicate enzyme.
The prefix may be:
1. Name indicating general nature of substrate e.g.: protease, lipase
etc.....
2. Real name of substrate: urease, lactase, sucrase.
3. Type of reaction catalyzed e.g.: Aldolase, mutase, transaminase,
dehydrogenase etc...

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4. Combination e.g.: Name of substrate + type of reaction
Lactic acid Dehydrogenase
Name of product + type of reaction
Glycogen Synthetase

Enzyme Specificity
Enzymes show different levels of specificity:
1) Absolute specificity
The enzyme acts only on a specific substrate e.g., Lactase acting on
lactose.
2) Relative specificity
The enzyme acts at different rates on one type of bond in compounds
chemically related, e.g., pancreatic lipase hydrolyzes alpha ester bonds at
position 1 & 3 in Triglycerides, (whether these are tristearin, triolein,
tripalmitin).
3) Group specificity (structural specificity)
The enzyme acts on a special type of bond at specific site and attached to
specific groups.
e.g., Pepsin that acts on peptide bond between amino group of an aromatic
amino acid and carboxylic group of another amino acid. While Trypsin acts on
peptide bond between carboxylic group of basic amino acid and amino group
of another amino acid.

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Figure: Pepsin activity demonstrating group specificity.

4) Stereochemical specificity
D- amino acid oxidase acts only on D- amino acid.
L- amino acid oxidase acts only on L- amino acids.

Figure: L-Alanine oxidase activity demonstrating stereochemical specificity.

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Functional vs Non-functional plasma enzymes
Functional plasma enzymes
Enzymes present in the plasma at high concentrations all the time
because they have functional role, examples include:
✓ Thrombin is associated with blood coagulation.
✓ Plasmin is associated with fibrin dissolution.

Non-functional plasma enzymes
Enzymes present at very low levels in healthy individuals and play no
functional role in plasma.
They result from normal turnover of cells.
In disease, levels of these non- functional enzymes increase in plasma
due to:
** Change in cell membrane permeability
** Increased cell death
Intracellular enzymes of low molecular weight appear in plasma first.
Cytosolic enzymes appear in plasma before mitochondrial enzymes.
The greater the quantity of tissue damaged, the more the increase in
plasma level.

Role of enzymes in Diagnosis of diseases:
Some enzyme levels are increased in plasma in some diseases:
Alkaline phosphatase in obstructive jaundice
Creatine kinase in heart diseases
Acid phosphatase in prostatic carcinoma

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Role of enzymes in Treatment of diseases:
Some enzymes are used in the treatment of some diseases. Examples
include:
Streptokinase in treatment of infarction.
Digestive enzymes in the treatment of maldigestion.

ENZYMES 2 (Week 9)

ILOs:
Outline the process of substrate binding and enzyme action
Discuss different factors affecting enzyme activity
Enumerate different mechanisms of enzyme activation
Compare competitive and non-competitive enzyme inhibitors
Discuss allosteric modifiers
Outline different methods of enzyme regulation
Define isoenzymes and outline their use
Classify enzymes based on type of reaction

Substrate binding and enzyme action
Enzyme and substrate combine to form a complex E + S ↔ ES

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Complex goes through a transition state – not quite a substrate or product
ES ↔ ES*
A complex of the enzyme and the product is produced ES* ↔ EP.
Finally, the enzyme and product separate EP ↔ E + P

Characteristics of the active site of the enzyme
Enzymes are the most specific catalysts known, as regards the substrate and
the type of reaction undergone. Specificity resides in the substrate binding
site on the enzyme surface (catalytic site). The tertiary structure of the
enzyme is folded in such a way as to create a region that has the correct
molecular dimensions and the optimal alignment of counter ionic groups and
hydrophobic regions to accommodate a specific substrate.
Enzymes use weak, mostly non-covalent interactions to hold the
substrate in place based on R groups of amino acids.
Shape is complementary to the substrate and determines the
specificity of the enzyme.

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Complementarity of Substrate and Enzyme Explains Substrate Specificity
Various models have been proposed to explain the substrate specificity of
enzymes.
I- Lock and key model:
This model assumes that only a substrate of the proper shape could fit
with the enzyme.

Figure: Lock and key model.

II- Induced fit model:
A more flexible model of the binding site is provided by the induced fit model
in which the binding and active sites are not fully preformed. The essential
elements of the binding site are present to the extent that the correct
substrate can position itself properly. Interaction of substrate with enzyme
induces a conformational change in the enzyme, resulting in the formation of

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a stronger binding site and the repositioning of the appropriate amino acids to
form the active site.

Factors affecting Enzyme activity
Measurement of the rate of enzyme reaction (velocity)
Rate of change of substrate to product per unit of time.
Vmax is the maximum reaction velocity at which all enzymes become
saturated with substrate

Enzyme activity can be influenced by:
1) Substrate concentration
2) Enzyme Concentration
3) Coenzyme concentration
4) Product concentration
5) pH

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6) Temperature
7) Physical agents
8) Time
9) Enzyme inhibitors
10) Enzyme activators

1) Effect of substrate concentration on Reaction Velocity:
▪ The first part of the curve is called the first order of enzyme activity where
an increase in substrate concentration increases the rate of the enzyme
reaction till Vmax. The second part of the curve is called zero order of
enzyme activity after the Vmax where there is no further increase in reaction
velocity with increased substrate concentration. i.e., The substrate is in
excess. This means all substrate binding sites of the enzyme are occupied
by the substrate.
▪ Km (The Michaelis–Menten constant of an enzyme) is the substrate
concentration at which the enzyme works at half its maximum rate.
(It is used as a measure of the affinity of the enzyme for its substrate)
The higher the affinity of an enzyme for its substrate, the lower the
substrate concentration needed till ½Vmax is reached. The lower the
substrate concentration, the lower the value of Km. So the higher the
affinity of an enzyme for its substrate, the lower its Km will be.
It is a constant for an enzyme, but it differs from enzyme to another.
✓ Small Km means tight binding- high affinity.

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✓ High Km means weak binding- low affinity.

1st order Zero order

Figure: Effect of substrate concentration.

2) Effect of enzyme concentration:
Increase in enzyme concentration increases the rate of reaction (1st order) till
a certain point where the increase in enzyme concentration does not increase

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the rate of reaction (zero order) as the substrate is completely combined with
the enzyme.

Figure: Effect of enzyme concentration.

3) Effect of Coenzyme concentration on the enzymatic activity
Coenzyme concentration has the same effect and gives the same curve of
substrate concentration on enzymatic activity.

4) Effect of Product concentration on Enzymatic activity
Increased product concentration decreases the enzyme activity due to:
a. Change in the pH.
b. The product may be more or less similar to the substrate so it may
compete with it for binding on its active site.
c. The product may bind the enzyme at an allosteric site.

5) Effects of pH on enzyme activity

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▪ Each enzyme has an optimum pH at which appropriate charges are
present on both S and E.
▪ Below and above this optimum pH, the enzyme activity is diminished.
▪ At the extremes of pH the enzyme activity is lost due to denaturation.

6) Effect of Temperature on enzyme activity
▪ Optimum Temp. is temp. at which the enzyme reaction velocity is
maximal.
▪ It is usually 25-40ºC in the human body.
▪ Exceeding normal temperature ranges always reduces enzyme reaction
rate.
▪ An increase in temperature above 45ºC decreases the enzymatic activity
irreversibly due to enzyme denaturation.

Figure: Effect of pH & temperature on enzyme activity.

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7) Effect of Physical agents on enzymatic activity

Decrease in Enzyme activity Increase in Enzyme activity
Heating Red light
Shaking Blue light
Stirring
Infrared light
Ultraviolet light

Importance of enzyme inhibition studies
The active site of an enzyme fits its substrate perfectly. It is possible,
however, for a molecule which is similar in shape to the substrate (analog) to
enter an enzyme’s active site. This would then inhibit the enzyme’s function.
Many substances can inhibit enzyme activity as substrate analog, toxins,
drugs, metal complexes. Inhibition studies can provide:
Better understanding of enzyme reaction mechanisms.
Information on metabolic pathways.
Insight on how drugs and toxins exert their effects.

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Enzyme inhibitors
Two broad classes of inhibitors have been identified based on the extent of
inhibition:
Reversible:
Forms weak, non-covalent bonds that readily dissociate from an enzyme. The
enzyme is only inhibited when the inhibitor is present.

Irreversible (enzyme poison):
Forms covalent or very strong non-covalent bonds. The site of attack is an
amino acid group that participates in the normal enzymatic reaction.

Types of Reversible Inhibitors
a) Competitive inhibitors
The enzyme can bind substrate forming (ES) complex, or inhibitor forming
(EI) but not both.
Competitive inhibitor (I) binds only to E, not to ES.
Competitive inhibitors resemble the substrate and bind to the active site
of the enzyme.
The substrate is therefore prevented from binding to the same active site.

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A competitive inhibitor diminishes the rate of catalysis by reducing the
proportion of enzyme molecules bound to a substrate.
Competitive inhibition can be overcome by increasing the concentration
of substrate.
Kinetically in competitive inhibition Vmax is not altered, while Km is
increased as the affinity of E to S decreased.

b) Non-competitive inhibition (Allosteric)
The inhibitor and substrate can bind simultaneously to an enzyme
molecule. Hence their binding sites do not overlap.
Non-competitive inhibitor (I) binds either to E and/or to ES.
While the inhibitor is bound to the enzyme, it can seriously affect the
normal arrangement of hydrogen bonds and hydrophobic interactions
holding the enzyme molecule in its three-dimensional shape. The
resulting distortion changes the shape of the active site and therefore
inhibits the ability of the substrate to enter the active site.
While the inhibitor is attached to the enzyme, the enzyme’s function is
blocked.
Non-competitive inhibition cannot be overcome by increasing the
substrate concentration.
▪ Kinetically Vmax is decreased, while Km is not affected.

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Inhibition of an enzyme can be harmful or even fatal but, in many situations,
inhibition is essential. For example, metabolic reactions must be controlled
so that no enzyme can be allowed to work without stopping at some point.
One way of controlling metabolic reactions is to use the end product of a
chain of reactions as a non-competitive, reversible inhibitor (End product or
Feed back inhibition).

Figure: End product allosteric inhibition,

Enzyme Activators
The velocity of the enzymatic reaction is affected by the concentration of an
enzymatic activator.
Some enzymes are activated by different ways:
1) Allosteric activation.
2) Covalent modification, e.g., phosphorylation and dephosphorylation.
3) Removal of an inhibitory peptide converts a zymogen (or proenzyme)
into an active enzyme:

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e.g., Trypsinogen Trypsin + inhibitory peptide
*Proenzyme (Zymogen): inactive precursor form of some enzymes (e.g.
many digestive enzymes) that will be activated by cleavage of a specific
peptide in its structure.

4) Keeping -SH group in an active site of some enzymes in its reduced
form by a reducing agent such as vitamin C.
5) Some enzymes need a metal ion to be active.
Key Regulatory Enzymes
The thousands of reactions involved in metabolism are grouped in sequence.
There is a step or more involve regulatory enzymes that control the rate for the
entire sequence.
Committed-Step Enzyme The first irreversible enzyme unique to the
pathway.
Rate-limiting Enzyme:
The enzyme with the lowest Vmax.
Usually occurs early in the pathway.
Enzyme activity is regulated in multiple ways:
 Long term- Slow (regulating the amount) through synthesis &/or
degradation.
 Short term- Rapid (regulating the activity).
 Compartmentation
Enzyme Regulation by Changing Enzyme amount (Quantitative)

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a) Induction
Increase in the synthesis of the enzyme by the effect of an inducer,
which may be a hormone or a metabolite.
Enzymes subject to induction (Inducible Enzymes) are those needed at
only one stage of development, or under selected physiological
conditions.
Enzymes that are in constant use are not regulated by altering the rate
of synthesis and are called Constitutive Enzymes.
b) Repression
Inhibition of enzyme synthesis by a repressor, which may be a hormone
or a metabolite.
c) Enzyme degradation
Individual enzyme molecules have different lifespans.
Some enzymes last for many days, others for only minutes or less.
Enzymes at key control points are more rapidly degraded.

Enzyme Regulation by Compartmentation
The activity of the pathway can be regulated by physical partitioning of
the pathway from its initial substrate.
This controls the access of the substrate to the enzyme of the pathway.
Anabolic and catabolic pathways are usually segregated into different
organelles in the cell to maximize the cellular economy.
Most synthetic enzymes are present extra- mitochondrial.

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Most of the oxidative (degradative) enzymes are present in the
mitochondria.

Isoenzymes
Enzymes that differ somewhat in primary structure and properties from tissue
to tissue, but retain essentially the same function, are called tissue-specific
isoforms or isoenzymes.
Act on the same substrate and give the same product.
Have quaternary structure.
Differ in physical and chemical properties, so are different in
electrophoretic mobility.
They differ in kinetics: different Km and Vmax values; differ in their
affinity for substrates.
Since present in different tissues, they are used in diagnosis of the exact
site of their release in case of elevation of the enzyme.

Example of clinically important isoenzymes:
I- Lactate dehydrogenase (LDH)
▪ The best isoenzymes known which catalyze the conversion of pyruvate to
lactate.
▪ It is a Tetrameric enzyme containing two different subunits designated H
(for heart) and M (for muscle).
▪ These subunits are made by separate genes.

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▪ The subunits have slightly different amino acid sequences and so have
different catalytic properties.
▪ The subunits associate to form tetramers randomly.
▪ A total of five different isoenzymes of LDH are found in the body.

Type of Structure Organs
isoenzyme

LDH-1 HHHH (H4) 1. Cardiac muscle

LDH-2 HHHM (H3M) 1. Reticuloendothelial

LDH-3 HHMM(H2M2) 1. Mainly lung tissue
2. Pancreas
3. Spleen
4. Lymphocytes

LDH-4 HMMM (HM3) 1. Kidney
2. Pancreas
3. Intestine

LDH-5 MMMM (M4) 1. Liver
2. Skeletal muscles

II- Creatine kinase (CK)
▪ Dimer with two types of subunits, M (muscle type) and B (brain type)
▪ In brain, BB (CK1)
▪ In heart, MB (CK2)
▪ In muscle, MM (CK3)
▪ In other tissues variable amounts of MM and BB are present

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International Classification of Enzymes
No. Class Type of reaction catalyzed
1 Oxidoreductases Transfer of electrons
2 Transferases Group transfer reactions (not hydrogen)
3 Hydrolases Hydrolysis reactions (bond cleavage by water
introduction & transfer of functional groups to
water)
4 Lyases Addition of groups to double bonds, or
formation of double bonds by removal of groups
(break C-O, C-C or C-N bonds without using
water)
5 Isomerases Rearrangement of groups within molecules to
yield isomeric forms.
** enzymes catalyzing movement of a
phosphate from one atom to another are called
mutases
6 Ligases Formation of C-C, C-S, C-O, and C-N bonds by
condensation reactions coupled to ATP
cleavage

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