BIOMOL Midterms 1 PDF

Summary

This document is lecture notes from a midterm exam for a medical biology class, focusing on enzymes and their properties, including active sites, substrates, coenzymes, and different types of enzyme specificity. The notes cover enzyme mechanism, different types of enzyme inhibition, and regulation, which are crucial topics in medical biology.

Full Transcript

0762 BIOMOLECULES 1
Bachelor of Science in Medical Biology Midterm Transes | AY 2024-2025

LEC 1: Enzymes
INTRODUCTION ➔ MACROMOLECULES CONSTRUCTION - Enzymes
PRINCIPLES facilitate biosynthesis, enabling the construction of larger
biomolecules from smaller precursor molecules. This is
essential for growth, repair, and maintaining cell
structure.

➔ CHEMICAL ENERGY USAGE - Enzymes are involved in
metabolic pathways which conserve and transform
chemical energy.

CLASSIFICATION
CHARACTERISTICS ACCORDING TO COMPONENT

ACTIVE SITE - Typically a pocket or groove found on an
enzyme’s surface, uniquely shaped to accommodate its
substrate. Formed by the enzyme's three-dimensional
structure which consists of various amino acid residues that
interact with the substrate, this facilitates conversion of
substrates into products through lowering the activation
energy.

SUBSTRATES - Specific molecules which enzymes act upon.
The binding of this to the active site leads to an
enzyme-substrate complex.

Nature: Most enzymes are globular proteins, with a few COENZYMES - Specific type of organic cofactor derived from
RNA-based enzymes. vitamins that help transfer chemical groups between
Function: Each reaction in the cell requires a specific molecules during enzymatic reactions.
enzyme, thus, thousands of different enzymes exist
within human cells.
Denaturation: Enzymes can denature due to changes in
temperature or pH, which can significantly impact their
activity.

IMPORTANCE

➔ DIGESTION - Enzymes break down complex food
molecules into smaller, absorbable components. This
enzymatic process allows nutrients to be absorbed
efficiently by the body.

Lehninger's Principles of Biochemistry JRPD - DGTT
0762 BIOMOLECULES 2
Bachelor of Science in Medical Biology Midterm Transes | AY 2024-2025
ACCORDING TO LOCATION

MECHANISM OF ENZYME ACTION
ATTACHMENT
COFACTORS - Non-protein molecules or ions that assist
enzymes in catalyzing reactions. They can be either organic or ➔ LOCK AND KEY MODEL - A model of enzyme action that
inorganic and are essential for the enzyme's activity. suggests the active site has a fixed, rigid shape, allowing
only specific substrates to bind, much like a key fits into
a specific lock.

➔ INDUCED FIT MODEL - A model proposing that the
active site is flexible, adjusting its shape to accommodate
the substrate upon binding, allowing for a more precise
CONJUGATED ENZYMES - Composed of an apoenzyme– the
fit and enhancing the enzyme’s catalytic activity.
protein part, and a cofactor. The apoenzyme alone cannot
catalyze reactions, however, when combined with its cofactor,
it forms a functional holoenzyme that is biochemically active.

SPECIFICITY
ACCORDING TO REACTION
1. ABSOLUTE SPECIFICITY - Catalyzes only one specific
substrate. Most restrictive of all specificity.

2. GROUP SPECIFICITY - Acts on similar substrates with
specific functional groups.

3. LINKAGE SPECIFICITY - Acts on particular types of
chemical bonds regardless of molecular structure. Most
general of all enzyme specificity.

4. STEREOCHEMICAL SPECIFICITY - Distinguishes
between stereoisomers. Chirality is inherent in active site
as amino acids are chiral compounds.

INHIBITION AND REGULATION
INHIBITORS

A. COMPETITIVE INHIBITION - An inhibitor resembles
and competes with the substrate for binding at the active
site. This process is reversible by increasing substrate
concentration.

Lehninger's Principles of Biochemistry JRPD - DGTT
0762 BIOMOLECULES 3
Bachelor of Science in Medical Biology Midterm Transes | AY 2024-2025
B. NONCOMPETITIVE INHIBITION - An inhibitor binds to
an allosteric site, altering the enzyme’s tertiary structure
and active site, disabling substrate binding. This type of
inhibition is reversible but depends on reducing inhibitor
concentration.

PROTEASES

PROTEOLYTIC ENZYMES - Enzymes that catalyze the
breaking of peptide bonds in proteins. To prevent them from
damaging the tissues that produce them, they are typically
produced in an inactive form.

ZYMOGENS - The inactive precursors of proteolytic enzymes.
They are activated only when needed, ensuring that these
enzymes are “turned on” at the right time and place.

C. IRREVERSIBLE INHIBITION - An inhibitor
permanently deactivates an enzyme through binding with
its active site using strong covalent bonds. Addition of
excess substrate doesn’t reverse this process.

COVALENT MODIFICATION

COVALENT MODIFICATIONS - Represent the third
mechanism of enzyme activity regulation, involving the
alteration of enzyme activity through covalent changes to the
enzyme's structure. This process typically entails the addition
REGULATORS or removal of a functional group from the enzyme. The most
common type of covalent modification is the addition or
ALLOSTERIC ENZYMES - Exhibit a quaternary structure, removal of a phosphate group, which is frequently derived
consisting of two or more protein chains. These enzymes from an ATP molecule.
possess multiple binding sites, including an active site for the
substrate and a regulatory site for a regulator molecule. The Phosphate Addition: Phosphorylation is catalyzed by a
active and regulatory binding sites are distinct in both shape Kinase enzyme
and location. Binding of a regulator molecule to its regulatory Phosphate Removal: Dephosphorylation is catalyzed by
site causes changes in three-dimensional structure. a Phosphatase enzyme.

Positive Regulator: Up-regulates enzyme activity by
enhancing the active site, making it more capable of
accepting substrates.
Negative Regulator: Non-competitive inhibitor that
down-regulates enzyme activity by compromising the
active site, thereby reducing its ability to accept
substrates.
QUESTIONS
FEEDBACK CONTROL
❖ Why is an enzyme active site important to the function of
FEEDBACK CONTROL - A regulatory process where the the enzyme?
activation or inhibition of an earlier reaction step in a ❖ Why is the enzyme regulatory binding site important for
sequence is influenced by the product of that sequence. This controlling the activity of the enzyme?
mechanism is one of the ways allosteric enzymes are ❖ Why are coenzymes important to the function of some
regulated. In most biochemical processes, reactions occur in enzymes?
multiple steps, with each step catalyzed by a different
enzyme, where the product of one step serves as the HEALTHCARE APPLICATIONS
substrate for the subsequent enzyme. PRESCRIPTION DRUG INHIBITOR

1. ACE INHIBITORS - Lower blood pressure by inhibiting
the Angiotensin-Converting Enzyme.

2. SULFA DRUGS - Antibiotics that function as competitive
inhibitors of bacterial enzymes responsible for converting
PABA to folic acid. Folic acid deficiency hinders bacterial
growth, ultimately leading to bacterial death.

Lehninger's Principles of Biochemistry JRPD - DGTT
0762 BIOMOLECULES 4
Bachelor of Science in Medical Biology Midterm Transes | AY 2024-2025
3. PENICILLINS - β-lactam antibiotics that inhibit the
transpeptidase enzyme, which is crucial for strengthening
the bacterial cell wall by forming peptide cross-links
between polysaccharide strands. When transpeptidase is
inhibited by penicillin, the bacterial cell wall weakens,
ultimately leading to bacterial death.

DIAGNOSIS AND TREATMENT

1. LACTATE DEHYDROGENASE - Typically found within
cells and not in high levels in the bloodstream. However,
elevated levels of LDH in the blood can indicate a
myocardial infarction or heart attack.

2. TISSUE PLASMINOGEN ACTIVATOR - A medication
D. ENZYME CONCENTRATION - Enzyme concentration
that activates the enzyme plasminogen, helping to
directly affects enzyme activity, with increased
dissolve blood clots. It is commonly used for treating
concentrations generally leading to higher reaction rates
myocardial infarction.
until a saturation point is reached, beyond which
additional enzymes cannot further enhance the rate.
3. BLOOD UREA NITROGEN - The enzyme urease
converts urea into ammonia, which can be easily
measured and serves as an indicator of urea levels. BUN
tests are commonly used to assess kidney function, as
elevated urea levels in the blood can indicate potential
kidney malfunction.

QUESTIONS

❖ What is the function of an enzyme in a chemical reaction?
FACTORS AFFECTING ENZYME ACTION ❖ What happens to the enzymes when the body
temperature rises from 37°C to 42°C?
A. TEMPERATURE - Increased temperature generally ❖ If an enzyme has broken down and is non-functional,
increases reaction rates up to an optimal point, usually what would happen to the chemical reaction normally
around 37°C for human enzymes. Beyond this point, facilitated by the enzyme? Explain.
enzymes may denature.
ADDITIONAL ENZYME VARIANTS

➔ ALDOLASE - An enzyme which plays a crucial role in
converting glucose into energy and is predominantly
found in high levels in muscle tissue throughout the body.
When muscle damage occurs, aldolase levels in the blood
tend to rise. Consequently, an aldolase blood test may be
ordered to diagnose and monitor specific conditions
related to skeletal muscle. In addition, it specifically
catalyzes the reversible reaction converting fructose
1,6-bisphosphate into dihydroxyacetone phosphate and
glyceraldehyde 3-phosphate.

B. POWER OF HYDROGEN - Each enzyme has an optimal
pH range for stability and efficiency. pH regulation is
essential for effective enzyme function in biological
systems.

➔ ISOENZYMES - Catalyze the same reaction in different
tissues throughout the body. Specifically, the LDH1
isoenzyme is predominantly found in heart muscle, while
the LDH5 form is more prevalent in skeletal muscle and
C. SUBSTRATE CONCENTRATION - Enzyme activity the liver. Because isoenzymes are specific to certain
increases with substrate concentration until reaching a tissues, they can be used as markers to identify damaged
saturation point where all active sites are occupied, or diseased organs or tissues.
resulting in a maximum reaction rate (Vmax). The
Michaelis-Menten constant (Km) indicates the substrate
concentration needed to achieve half of Vmax, reflecting
the enzyme's affinity for the substrate.

Lehninger's Principles of Biochemistry JRPD - DGTT