Enzymes 1-3 PDF

Summary

This document provides an overview of enzyme structure, function, and role in various biological processes. It includes discussions of key concepts like enzyme catalysis, induced fit, and enzyme inhibition. The document also explains the impact of environmental factors on enzyme activity.

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 CELLULAR
ENERGETICS
Topics 1-3: Enzyme Structure,
Catalysis, and Environmental
Impacts
 Learning
Points
I can describe the Enzyme
Structure, Catalysis, and
Environmental Impacts
What are
enzymes?
Enzymes are proteins
which catalyze or
speed up a chemical
reaction.
Reduce activation
energy required for
reactions.
Analysis
Why are enzymes
Question:
crucial for living
organisms?
Answer:
Enzymes are vital because they
accelerate biochemical
reactions, enabling essential
life processes to occur efficiently
 Star
ch Carbohyd
rases
Carbohydrases are enzymes
which break down
carbohydrates into simple
Gluco sugars. Carbohydrates
se provide us with energy.
Starch is a form of
carbohydrate. The enzyme
amylase breaks starch down
Carbohyd
rase
Example
Salivary amylase is
produced in our salivary
glands.
It breaks down starch into
maltose, which is a sugar.
 Proteases
Proteases are enzymes
which break down
proteins into amino
Prot acids.
ein
Amino
Acid
 Protease
Example
The protease enzyme pepsin is
produced in the gastric glands in
the stomach.
Pepsin starts the process of
breaking down proteins into amino
acids.
Other protease enzymes then
 Lipases
Lipases are enzymes
which break down lipids
into fatty acids and
glycerol.
Fatty
Glycer acid
ol chains
 Lipase
Example
Lipase enzymes are produced
in the pancreas.

They work in the small
intestine (duodenum) to turn
lipids into fatty acids and
glycerol.
 Enzyme
Structure
 Enzyme
Composed of amino acid chains folded into
Structure
specific shapes
Active site: Region where
substrate
Substrate:binds
Molecule that
enzyme acts upon
Lock and key model:
Enzyme and substrate fit
precisely
Analysis
How does enzyme structure relate
Question: to its function?

Answer:
The specific 3D structure of an enzyme,
particularly its active site, determines
which substrates it can bind to and
catalyze.
Analysis
How does enzyme structure relate
Question: to its function?

Answer:
Lactase enzyme
specifically
breaking down
Induced Fit
Model
 Induced Fit
Refinement of lock and key model

Model
Active site slightly changes shape when
substrate
Enhances binds
enzyme-substrate
Increases interaction
catalytic efficiency

https://www.youtube.com/watch?v=V8TOWTp71tE
Analysis
What advantage does the induced
Question:
fit model provide over the lock
and key model?
Answer:
The induced fit model explains how
enzymes can be more flexible and efficient
in catalyzing reactions by adapting to the
Drug design considering induced fit for
better enzyme inhibition
Enzyme
Catalysis
Enzyme
Catalysis

https://www.youtube.com/watch?v=Dr0WVeJaHS8
 Enzyme
Lowers activation energy for chemical
Catalysis
reactions
Does not change the reaction's
equilibrium
Remains unchanged after
catalysis
Can catalyze both forward and
reverse reactions
Analysis
How do enzymes affect the rate of
Question: chemical reactions?

Answer:
Enzymes lower the activation energy
required for reactions, significantly
increasing the rate at which products are
Example: Catalase enzyme rapidly
formed.
decomposing hydrogen peroxide in cells
Cofactors and
Coenzymes
Cofactors
Non-protein components necessary for
enzyme
Can be metal function.
ions or organic
molecules
Coenzymes
Organic cofactors (often derived from
vitamins)
NAD+, FAD, coenzyme A
https://www.youtube.com/watch?v=2bYnIGqe5aY
Analysis:
How do cofactors contribute to
enzyme function

Answer:
Cofactors assist enzymes in
catalyzing reactions by providing
necessary chemical components
Answer:
Cofactors assist enzymes in catalyzing
reactions by providing necessary chemical
components or facilitating electron transfer.
Example: Iron in hemoglobin acting as a
cofactor for oxygen transport

https://www.britannica.com/video/Learn-how-
hemoglobin-proteins-blood-transport-oxygen-
lungs-to-tissues/-246612
 Enzyme
Inhibition
Inhibitors
Enzyme inhibitors are molecules that interact
with enzymes (temporary or permanent) in some
way and reduce the rate of an enzyme-catalyzed
reaction or prevent enzymes to work in a normal
Types:
manner.
CompetitiveUn-Competitive
Non-Competitive

https://www.youtube.com/watch?v=SqjVB8WT1xo
Analysis:
How does competitive
inhibition differ from non-
competitive inhibition?
Answer:
Competitive inhibitors bind to the
active site, while non-competitive
inhibitors bind elsewhere, affecting
Analysis:
How does the non-competitive
inhibitors affect the enzyme’s shape

Answer:
and function?

binding to a site on the enzyme separate
from the active site
(called
which then an allosteric
causes site)
a conformational
change in the enzyme's structure,
ultimately altering the shape of the
Real-Life
Designing pharmaceutical drugs to inhibit

Example: specific enzymes
Environmental
Impacts on
Enzyme
Function
Temperature
Increased temperature generally increases
reaction rate
Optimal temperature for peak enzyme
activitycan denature
High temperatures
enzymes
Cold temperatures slow down
enzyme activity
pH
Each enzyme has an optimal pH range
(7)
pH affects enzyme shape and charge
distribution
Extreme pH can denature
enzymes
Some enzymes adapted to function in
extreme pH environments
(pepsin 2.5
pH)
Example: pH-dependent enzymes in laundry
detergents for effective cleaning
 Salt
Salt concentration affects enzyme activity and

Concentratio stability
Can influence enzyme-substrate
interactions
Some enzymes require specific ion
n
Example: concentrations

“carbonic anhydrase”
facilitates the conversion of carbon dioxide
(CO2) into bicarbonate ions (HCO3-), which is
Salt
Other

Concentratio
Examples:

n
Analysis:
Why are some enzymes adapted to
high salt concentrations?

Answer:
Enzymes in organisms living in high-salt
environments have evolved to maintain their
structure and function under these
conditions.
Answer:
Answer:

Halobacterium Haloarcula
Halomonas

Salinibacter