Enzymes PDF - Biochemistry for Medical Laboratory Science

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This document is a lecture on enzymes, covering enzyme structure and classification. It details important aspects of enzyme naming and various factors affecting enzymatic activity. The document is from a university setting and appears to be lecture notes.

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CHEM 113 LECTURE: BIOCHEMISTRY FOR MEDICAL LABORATORY SCIENCE

WEEK 5: ENZYMES
1st SEMESTER | PRELIMS | A.Y. 2023-2024 TRANSCRIBED BY: ANNE JUSTINE KATIMBANG
PROFESSOR: SIR JOSEPH DEUEL S. CASINSINAN, RMT

ENZYMES - Combined apoenzyme and cofactor
entity.
It is a compound, usually a protein, that acts as a ○ Coenzymes
catalyst for a biochemical reaction. Serves as a cofactor in a conjugated
○ Each cell in a human body contains a thousand enzyme.
different enzymes.
○ Catalysts speed up the chemical reaction. Proteins are one of the components of our cell; within the
○ Speeds up or accelerates the biochemical cell we have an enzyme.
reaction.
Enzymes are important, because “No Enzymes = No NOMENCLATURE AND CLASSIFICATION OF ENZYMES -
Metabolic Reactions”.
Enzymes are selective in what they do or process. Named about the:
○ E.g Glycolysis → Glucose to another substance. ○ Function of the enzyme
Most of the enzymes are proteins but aren’t purely ○ Type of reaction catalyzed
proteins. ○ The substrate identity.
There are 6 functional classes of enzymes which are Substrate - reactant in an enzyme–catalyzed reaction
classified based on the type of reaction in which they are
used to catalyze. 3 Important Aspects In The Naming Process Of Ezymes:
Enzymes are very sensitive to the environment as they
respond quickly. 1. Suffix
Enzyme comes from the Greek word “en” which means a. Most enzymes end in the suffix “ase”
in and “zyme” which means yeast. i. Ex. Urease, Sucrase, Lipase
○ Yeast speeds up the process of bread b. Exception: Digestive enzymes
fermentation. i. Ex. Trypsin, chymotrypsin, pepsin
Cause cellular reactions to occur millions of times 2. Prefix
faster. a. Type of reaction catalyzed by an enzyme
○ Not consumed during the reaction but merely i. Ex. Oxidase - oxidation reaction &
helps the reaction occur more rapidly. Hydrolase - hydrolysis reaction
Enzymes are completely soluble in water. 3. Identity of substrate and type of reaction catalyzed
Mostly, they are globular proteins (glob means a. Ex. Glucose oxidase, pyruvate carboxylase,
spherical). succinate dehydrogenase

ENZYME STRUCTURE -
CLASSIFICATION OF ENZYMES
1. SIMPLE ENZYME
OXIDOREDUCTASE
Composed only of protein.
Consist entirely of amino acid chains. Catalyzes an oxidation – reduction reaction.
○ Oxidation
2. CONJUGATED ENZYME Increases the number of carbon to
oxygen bonds and decreases the
Has a non –protein part in addition to a protein part. number of carbon to hydrogen
They contain additional chemical components in line bonds.
with their reaction. ○ Reduction
○ Apoenzyme Decreases the number of carbon to
Protein of the conjugated enzyme. oxygen bonds and increases the
Needs cofactor. number of carbon to hydrogen bonds
○ Cofactor Requires a coenzyme that is oxidized or reduced as
Non –protein part of the conjugated the substrate is reduced or oxidized.
enzyme.
They are providing additional chemical TRANSFERASE
reactions on that particular functional
group. Catalyzes the transfer of a functional group from one
Beside those present in the molecule to another.
amino acid chain of the ○ Transaminases
apoenzyme. Catalyzes the transfer of amino
○ Holoenzyme group from one molecule to another
Biochemically active conjugated ○ Kinases
enzyme produced from an apoenzyme
and a cofactor.

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 Catalyzes the transfer of phosphate ISOMERASE
groups from ATP to give ADP and a
phosphorylated product. Catalyzes the isomerisation of a substrate in a
Donation of the substrate. reaction converting it to a molecule isomeric with
Will gain a phosphate group itself.
and the high energy ATP One reactant and one product in reactions.
molecule will become ADP. Rearrangement of atoms.

LIGASE

Catalyzes the bonding together of two molecules into
one with the participation of ATP.

HYDROLASE

Catalyzes the hydrolysis reaction. MAIN CLASSES SELECTED TYPE OF REACTION
Central to the process of digestion. SUBSTANCES CATALYZED
Carbohydrases
○ Break down glycosidic linkages Oxidases Oxidation of a substrate
Proteases
○ Break down peptide bonds Reductases Reduction of a
Lipases substrate
○ Break down ester bonds
Dehydrogenases Introduction of double
OXIDOREDUCTASES bond (oxidation) by
They are connected with the lipid metabolism, lipid formal removal of two
synthesis, and fat breakdown. H atoms from
substrate, the H being
LYASE accepted by a
coenzyme.

Catalyzes the addition of a group to a double bond or Transaminases Transfer of an amino
the removal of a group to form a double bond in a group between
manner that does not involve hydrolysis or oxidation. substrates.
○ Hydratase Effect TRANSFERASES
Addition reaction of the component Kinases Transfer of a phosphate
of water to double bond. group between
substrates.
○ Dehydratase
Removal reaction of the component Lipases Hydrolysis of ester
of water to double bond. linkages in lipids.

Proteases Hydrolysis of amide
linkages in proteins.

Nucleases Hydrolysis of
sugar-phosphate ester
HYDROLASES bonds in nucleic acids.

Carbohydrases Hydrolysis of glycosidic
bonds in carbohydrates.

Phosphatases Hydrolysis of
phosphate-ester bonds.

Dehydratases Removal of H2O from
substrate.
LYASES
Decarboxylases Removal of CO2 from

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 substrate. INDUCED–FIT MODEL

Deaminases Removal of NH3 from Enzyme’s active site is not rigid and static.
substrate.
There’s a constant change in shape
Hydratases Addition of H2O from Allows for changes in the shape or geometry of the
substrate. active site of an enzyme to accommodate a substrate.
Result of the enzyme’s flexibility; it adapts the
Racemases Conversion of D to L incoming substrate.
isomer, or vice versa.

ISOMERASES Mutases Transfer of a functional
group from one position
to another in the same
molecule.

Synthetases Formation of a new
bond between two
substrates, with
participation of ATP.
LIGASES
Carboxylases formation of new bond
between a substrate
and CO2, with
participation of ATP,

MODELS OF ENZYME REACTION

Enzyme Active Site
○ Small part of an enzyme’s structure that is
actually involved in catalysis.
○ A three –dimensional entity formed by groups
that come from different parts of the protein
chains. ENZYME SPECIFICITY
○ Area where the substrate will bind; explains
how the enzyme functions in the biochemical Extent to which an enzyme’s activity is restricted to:
system. ○ A specific substrate
○ Crevice-like Locatio ○ A specific group of substrate
Location where the substrate will ○ A specific type of chemical bond or a specific
bind. type of chemical reaction.
Enzyme–Substrate Complex Degree of specificity is determined by the active site.
○ The intermediate reaction species that is
formed when a substrate binds to the active TYPES OF ENZYME SPECIFICITY
site of an enzyme.
○ There is a specific enzyme product complex. ABSOLUTE SPECIFICITY

Catalyze only one reaction.
Most restrictive of all specificities.
Catalase
○ Enzyme with absolute specificity.
Urease
○ For bacterial inhibition; only for bacterial
inhibition

GROUP SPECIFICITY
LOCK–AND–KEY MODEL
Act only on molecules that have a specific functional
Enzyme
group, such as hydroxyl, amino or phosphate groups.
specificity to
Carboxylpeptidase is group specific.
its substrate.
The amino acid group; they are cleaving the amino
Active site in
acid one at a time and they will see that particular
the enzyme
amino acid from the carboxyl from the peptide chain.
has the fixed,
rigid
LINKAGES SPECIFICITY
geometrical
conformation.
Act on the particular type of bond, irrespective of the
Substrates
rest of the molecular structure.
with a
Phosphatases hydrolyze phosphate –ester bonds in
complementary geometry can be accommodated.
all types of phosphate esters.
Most general of the common species.

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 STEREOCHEMICAL SPECIFICITY Operates in the small intestines,
function best at pH 8.0
Act on a particular isomer.
NOTE:
Enzymes are acidic because of zwitterion.
ENZYME ACTIVITY Enzymes are pH sensitive because neutral pH is
what it prefers.
Measures the rate at which an enzyme converts Acidic - goes up fast.
substrate to products in a biochemical reaction. Basic - goes down slow

FACTORS THAT AFFECT ENZYME ACTIVITY SUBSTRATE CONCENTRATION

TEMPERATURE Increased
concentration of
Measure of kinetic substrate will obtain the
energy of enzyme activity.
molecules. Turnover Number
More than 37 deg C ○ Number of
(body temperature) substrate
will cause the molecules
enzyme to transformed per
denature. minute by one
Higher molecule of
temperatures mean enzyme under optimum conditions of
molecules are temperature, pH and saturation.
moving faster and Higher substrate = High enzyme activity
colliding more
frequently.
When the
temperature
increases beyond a
certain point, the
increased energy begins to cause disruption to the
tertiary structure of enzymes.
ENZYME CONCENTRATION
○ It will result in denaturation of the enzyme.
Optimum temperature
○ Temperature at which an enzyme exhibits Kept in a low number
maximum activity. because enzymes are not
consumed in the reaction.
pH The greater the enzyme
concentration, the greater the
The charge on acidic reaction rate.
and basic amino
acids located at the
active site depends
on pH
Small pH changes
can result in enzyme
denaturation and
EXTREMOZYMES
subsequent loss of
catalytic activity.
A microbial enzyme active at a condition that would
Biochemical buffers
inactivate human enzymes as well as enzymes present in
help maintain the
other types of higher organisms.
optimum pH for an
enzyme. Extremophile Microorganisms that thrives in
Can also affect extreme environments
substrate, causing
either protonation or deprotonation of groups on the Acidophile Optimal growth at pH levels of
substrate. 3.0 or below.
Optimum pH
○ pH at which an enzyme exhibits maximum Alkaliphile Optimal growth at pH levels of
activity 9.0 or above.
○ Physiological pH ranges from 7.0 – 7.5
○ Pepsin Hyperthermophile Temperature between 80C and
Active in the stomach, functions best 122C needed to thrive
at pH 2.0
○ Trypsin Halophile Includes bacteria,
Archaebacteria and some

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 eukaryotic – chain group at the enzymes active site.
Hyper saline in environment ○ Do not have structures similar to that of the
enzyme’s normal substrate.
Other term is psychrophile It cannot bring back the original function.
They are categorized as Locks onto the active site and permanently changes
extremophilic organisms its shape.
Cryophile Growth in lower temperature
From -20C to 10C
REGULATION OF ENZYME ACTIVITY -
Places that are permanently cold
such as polar regions and deep
1. A cell that continually produces a large amount of
areas of the sea
enzyme for which substrate concentration is always
very low is wasting energy.
a. The production of the enzyme needs to be “
ENZYME INHIBITION
turned off”.
2. A product of an enzyme – Catalyzed reaction that is
Enzyme Inhibitor
present in plentiful amounts in a cell is a waste of energy
○ Substance that slows or stops the normal
if the enzyme continues to catalyze the reaction that
catalytic function of an enzyme by binding to
produces the product.
it.
a. The enzyme needs to be turned off.
REVERSIBLE COMPETITIVE INHIBITION
Body will run out of energy if enzymes do not shut off
Competitive Enzyme Inhibitor
○ Molecules that sufficiently ALLOSTERIC ENZYME
resemble an enzyme
substrate in shape and 1. Have Quaternary Structure
charge distribution that it a. 2 or more protein chains.
can compete with the 2. Have 2 kinds of binding sites
substrate for occupancy of a. For substrates and for regulators
the enzyme's active site. 3. Active and regulatory binding sites are distinct from
○ Remains in changed as it each other in both location and shape.
binds to the enzyme's 4. Binding of a molecule at the regulatory site causes
active site. changes in the overall three – dimensional structure
It can bring back function. of the enzyme, including structural changes at the
Duct tape mouth analogy. active site.
Reversible process because it is
maintained but weak interactions.
Can be reduced by increasing the
concentration of the substrate.

REVERSIBLE NON-COMPETITIVE INHIBITION

Non-competitive Enzyme Inhibitor
○ Molecule that decreases
enzyme activity by binding
to a site on an enzyme
other than the active site.
○ Presence of this causes a
change in the structure of
the enzyme sufficient to
prevent the catalytic
groups at the active site
from properly affecting
their catalyzing action.
Choking analogy.
It changes the shape of the active site so that the
substrate cannot be processed.

IRREVERSIBLE INHIBITION

Irreversible Enzyme
Inhibitor
○ Molecule that
inactivates
enzymes by
forming a strong
covalent bond to
an amino acid side

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ENZYME WITH TWO OR MORE PROTEIN CHAINS AND 2 COVALENT MODIFICATION OF ENZYME
KINDS OF BINDING SITES
Process in which enzyme activity is altered by
Regulators covalently modifying the structure of the enzyme
○ Substances that bind at the regulatory sites of through attachment of a chemical group or removal of
allosteric enzymes. a chemical group from a particular amino acid within
the enzyme structure.
A. Positive Regulator
a. Increase enzyme activity Phosphorylation Process of addition of the
b. The shape of the active site is changed phosphate group to the enzyme by
such that it can more readily accept protein kinases.
substrates.
c. Positive Catalysis Dephosphorylation Removal of the phosphate group
B. Negative Regulator from the enzyme by phosphatases.
a. Decrease enzyme activity
b. Changes to the active site are such that
MEDICAL USES OF ENZYMES -
substrate is less readily accepted.
c. Negative Catalysis
1. Used to diagnose certain diseases.
2. Appearance of these enzymes in the blood often
indicates that there is tissue damage in an organ and
FEEDBACK CONTROL
that cellular contents are spilling out into the
bloodstream.
A process in which activation or inhibition of the first
3. Used in the treatment of disease.
reaction in a reaction sequence is controlled by a
product of reaction sequence.
NOTE:
Negative Feedback
Plasminogen - enzyme that breaks down clots.
○ Product turns into a regulatory substance and
shuts down enzyme 1 by attaching to the
regulatory site. ENZYME CONDITION INDICATED
BY ABNORMAL LEVEL

Lactate dehydrogenase (LDH) Heart disease; Liver
disease

Creatinine phosphokinase Heart disease
PROTEOLYTIC ENZYMES (CPK)

Aspartate transaminase (AST) Heart disease; Liver
Catalyzes the breaking of peptide bonds that
disease; Muscle damage
maintain the primary structure of protein.
Generated in an inactive form and converted to active
Alanine transaminase (ALT) Heart disease; Liver
form when they are needed.
disease; Muscle damage
Regulate enzymes.
Inactive form of enzyme that turns into active when
Gamma-glutamyl Heart disease; Liver
needed to stop another enzyme.
transpeptidase (GGTP) disease
ZYMOGEN
Alkaline phosphatase (ALP) Bone disease; Liver
disease
Inactive precursor of a proteolytic enzyme.
Requires another enzyme to turn active.
AST, ALT, GGPT, & ALP - are used for liver profile tests.
Activation of a zymogen requires an enzyme –
Serum Glutamic Pyruvic Transaminase (SGPT) &
controlled reaction that moves some part of the
Serum Glutamic-Oxaloacetic Transaminase (SGOT) -
zymogen structure which changes the 3 –
are two most common types of liver enzymes,
dimensional structure of zymogen, which affects
○ Besides the liver, SGOT is found in the kidney,
active site conformation.
muscles, heart and even the brain. On the
contrary, SGPT is predominantly found in the
liver only.

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