Enzymes chemistry sem241_1ff386ac58e45fc49b5e6887ddf5faf5.pdf

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Enzymes
 Definition of an enzyme
Enzyme is mostly protein catalyst (i.e. increase the rate of reactions)
synthesized intracellularly (but may act extracellularly) NOT changed
during the reaction
Enzymes direct all metabolic reactions occurring in the cells
 Mechanism of action of enzymes:
1-lock & key model (fixed theory)

An enzyme binds a substrate in a region called the active site
Enzyme active site is rigid (stable, not malleable)
Only certain substrate can fit the active site of the enzyme
(i.e. the enzyme can act on only one or few substrates. i.e. specific)

P
+
S
S
P

E + S ES complex E + P
 2-induced fit model (flexible theory)

Active site of the enzyme adjust s its shape to bind the substrate.
Enzyme structure is flexible (not rigid)
This mechanism gives increased range of substrate specificity (many
types of substrates can bind the same enzyme)

P
S
SS
P

E + S ES complex E + P
 Properties of enzymes
1- All Enzymes are Proteins (except ribozymes that are RNA in structure)
2- Active Site
Each enzyme molecules contain a special pocket called the active site.
The substrate bind with the active site to form enzyme substrate-complex
(ES) which is converted to enzyme-product complex (EP).
Then, EP dissociates to enzyme and product

3-Catalytic Efficiency:
Each enzyme molecule is capable of transforming 100 – 1000 substrate
molecules into product each second
4- Specificity:
Enzymes are highly specific i.e. each enzyme interacts
with one or few type of substrates
and catalyzes one type of reactions
e.g urease on urea, amylase on glycogen, starch…

5- Holoenzymes:
Some enzymes require molecules other than proteins for enzymic activity.
Holoenzymes: apoenzyme (protein part) + nonprotein component
Apoenzymes: are inactive without the nonprotein component
- non-protein part: (called cofactors)
1- a metal ion as zinc or ferrous ions
2- small organic molecules (called coenzymes)

Coenzymes : may be only transiently associated with the enzyme
or may be permanently associated with the enzyme
Coenzymes may be derived from vitamins. (e.g. NAD+ contains niacin)
6- Regulation: Enzyme activity can be regulated by activation or inhibition.
7- Location within the cell (Compartmentalization):
Many enzymes are localized in specific organelles within the cell.
This serves to isolate the reaction substrate or product from other opposite
reactions.
Factors affecting enzyme activity
Each enzyme has its own optimum pH

level of blood
3- Substrate concentration
 Km of enzyme
Km (Michaelis Constant) of an enzyme is numerically equal to the substrate
concentration at which the velocity of reaction is equal to 1/2 Vmax

Km is the substrate concentration at which 1/2 maximal velocity is
reached

If Km is small,
the substrate concentration required for the reaction to reach 1/2 maximal
velocity is small.
i.e. the enzyme has a high affinity for the substrate.

If Km is large,
the substrate concentration required for the reaction to reach
1/2 maximal velocity is large.
i.e. the enzyme has a low affinity for the substrate
 4- Enzyme concentration

Increasing enzyme concentration increases the rate of reaction (with
substrate concentration is constant)
 5- Inhibition of enzyme activity
Inhibitor: is an any substance that can diminish the velocity of a reaction
which is catalyzed by an enzyme.
1- Reversible Inhibitors: bind to enzymes through non-covalent bonds
2- Irreversible Inhibitor: bind to enzymes through covalent bonds

Types of inhibitors according to site of binding of inhibitor:
1- Competitive Inhibitor: inhibitor binds at the active site of the enzyme
2- Noncompetitive Inhibitor: inhibitor binds to a site other than active site
 Competitive inhibitors
A competitive inhibitor:
has a structure similar to substrate of the enzyme
occupies active site of the enzyme
competes with substrate for occupying the active site of the enzyme
increases Km of the enzyme to its substrate.
i.e. more substrate is required to reach ½ Vmax
effect can be reversed by increasing substrate concentration.
 Noncompetitive inhibitors
A noncompetitive inhibitor:
Has a structure different from the substrate
Binds to the enzyme at a site different from active site
i.e. does not compete with the substrate of the enzyme for the active site of enzyme
Changes the shape of enzyme and thus active site shape is changed.
Accordingly, substrate cannot fit in the altered active site So, no reaction occurs
Effect is not reversed by adding more substrate
Does not change Km of the enzyme (i.e. increase of substrate concentration will not
lead to reaching of ½ Vmax).
 Regulation of enzyme activity
The regulation of the activity of enzyme is essential for coordinating the metabolic
processes.
Types of regulation:
1- General: (occurs in all types of enzymes in the body)
increasing substrate concentration will lead to increase activity of the enzyme

2-Special regulatory mechanisms: (not all enzymes of the body)
i- Allosteric effectors
ii- Covalent modification
iii. Increase or decrease rate of enzyme synthesis
iiii. Feed back product inhibition
1- Allosteric effectors
Allosteric binding sites are sites on the enzyme different from the active site.
Binding of an allosteric effectors to this site will make changes in shape of the
whole enzyme with an effect on activity.
So, the activity may be increased (positive allosteric effector) or decreased
(negative allosteric effector).
 2- Covalent modification
1- Many enzymes may be regulated by
addition of phosphate groups to the
enzyme (modification by phosphorylation)
Addition of phosphate group may cause
activation or inactivation of the enzyme

2- Some enzymes are released as an inactive
form (zymogen) By removal of a part of
the enzyme (modification), it will be
active. e.g
Trypsinogen is activated by enterokinase
to trypsin and pepsinogen to pepsin by
HCL
3- Increasing or decreasing rate of enzyme
synthesis (At Gene level)

By this mechanism cells regulate the amount of enzyme
by changing the rate of enzyme synthesis

The increase (induction) or decrease (repression) of
enzyme synthesis leads to change total amount of active
site.

This mechanism is slow (takes from hours or days)
4- Feed back product inhibition
Medical importance of enzymes of blood
Blood enzymes can be classified into two major groups:

1- Enzymes that have functions in blood (smaller group):
They are present in blood in high amounts
Example: liver secretes zymogens (inactive precursors) involved in
blood coagulation.

2-Enzymes that do not have functions in blood (large number)
These enzymes are released from cells during normal cell turn over.
They have functions in cells (intracellular)
BUT: they do not have a function in blood

In healthy individuals, levels of these enzymes are constant.
So, the presence of elevated enzyme level in blood may indicate tissue
damage that leads to increase in release of these enzymes.
 Many diseases that cause tissue damage results in increased release of
intracellular enzymes into plasma (blood) So, the enzyme levels in
blood are measured for diagnosis of these diseases

Diseases of the heart, liver, skeletal muscles and other tissues are
diagnosed by an elevation of a blood enzymes.

The level of elevation of an enzyme correlates with the extent of tissue
damage in any of these organs.

Some enzymes may be available in high amount in only one organ
So, the elevation of blood levels of these enzymes are diagnostic for
diseases of this organ only. (specific)

Example: Alanine aminotransferase (ALT) enzyme elevation in blood
indicates disease of the liver (specific for liver cells).