Cellular Respiration PDF

Summary

This document provides an overview of cellular respiration, outlining two types: aerobic and anaerobic respiration. It details the processes involved, including glycolysis, the link reaction, Krebs cycle, and electron transport chain. The document also explains the roles of NADH and FADH2 in the electron transport chain and the production of ATP. It also covers fermentation types.

Full Transcript

CELLULAR RESPIRATION

Mohd Aminudin Bin Mustapha
 Objectives

Describe two types of cellular respiration: Aerobic cellular respiration and
anaerobic cellular respiration
Briefly describe processes glycolysis, link reaction, Krebs Cycle, electron
transport chain and chemiosmosis
Define facultative anaerobes and obligate anaerobes
Briefly describe alcoholic fermentation and Lactate fermentation
Briefly describe other sources of energy.
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 Cellular Respiration
Definition: A series of biochemical reactions in cells that involve the
breakdown and oxidation of organic molecules, primarily sugars, to release
energy.
Energy Utilization:
Part of the energy is released as heat.
The rest is stored as chemical energy in the form of adenosine
triphosphate (ATP).
Purpose: Living organisms require energy for movement, maintaining
constant body temperature, anabolic processes, and active transport.

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 Types of Cellular Respiration

Aerobic Cellular Respiration:
Food is completely oxidized
with the help of oxygen into
carbon dioxide and water.
Anaerobic Cellular Respiration:
Food is oxidized without using
oxygen, e.g., in yeast and bacteria.

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 Processes Involved in Cellular Respiration

Oxidation: Removal of hydrogen
(involves loss of electrons); the liberated
hydrogen is transferred to another
compound.
Reduction: Addition of hydrogen
(involves gain of electrons).
Phosphorylation: Addition of a
phosphate group to another compound.

Presentation title 5
 Processes Involved in
Cellular Respiration
Substrate-level Phosphorylation:
Transfer of a phosphate group from a
phosphorylated substrate to ADP,
forming ATP.
Isomerization: Conversion of a
compound to its isomer molecule;
isomers have the same formula but
different atom arrangements.
Main Objective: Produce ATP for
energy.

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 Aerobic Cellular Respiration

Definition: Biochemical redox reactions
in living cells in the presence of oxygen.
Redox Reaction: Transfer of electrons
from a reducing agent to an oxidizing
agent, releasing energy.
Example: Oxidation of glucose
(C₆H₁₂O₆) to CO₂ and reduction of
oxygen to water.

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 Stages in Aerobic
Cellular Respiration
1. Glycolysis: Occurs in the cell
cytoplasm.
2. Link Reaction: Occurs in the
mitochondrial matrix.
3. Krebs Cycle: Occurs in the
mitochondrial matrix.
4. Electron Transport Chain: Occurs in
the inner mitochondrial membrane.

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 Glycolysis
1. Phosphorylation of 6C
glucose.
2. Isomerization: Glucose-6-
phosphate to fructose-6-
phosphate.
3. Phosphorylation: Fructose-
6-phosphate to fructose-
1,6-diphosphate.

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 Glycolysis

4. Cleavage: Fructose-1,6-
diphosphate split into two 3C
molecules (G3P and
dihydroxyacetone phosphate).

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 Glycolysis

5. Oxidation, phosphorylation, and
substrate-level phosphorylation:
G3P to 3-phosphoglycerate (3PG),
forming NADH and ATP.
6. 1,3-bisphosphoglycerate is
hydrolyzed to form 3-
phosphoglycerate (3PG), resulting in
the production of ATP.
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 Glycolysis
7. Isomerization: 3PG to 2-
phosphoglycerate (2PG).
8. Dehydration: 2PG to
phosphoenolpyruvate (PEP).
9. Substrate-level phosphorylation:
PEP to pyruvate, forming ATP.

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 Net Products
Glycolysis
2 ATP (net gain)
2 NADH (transported
to the electron
transport chain)
2 pyruvate
(transported to the link
reaction)

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 Link Reaction

Occurs with oxygen.
Carbon dioxide is removed.
Hydrogen atoms are
transferred to NAD+ to
form NADH.
Pyruvate is converted to
acetyl-CoA.

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 Krebs Cycle
Coenzyme A assists the acetyl (2C)
molecule in entering the Krebs
Cycle and then detaches to be
reused.
This process occurs only in the
presence of oxygen.
Its significant role includes the
formation of NADH and FADH2,
which carry high-energy electrons
and H + ions to the Electron
Transport Chain.

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 Krebs Cycle

1. Condensation: Acetyl (2C)
to oxaloacetate (4C),
forming citrate (6C).
2. Isomerization: Citrate to
isocitrate (6C).
3. Oxidative Decarboxylation:
Isocitrate to α-ketoglutarate
(5C), releasing CO₂ and
forming NADH.

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 Krebs Cycle
4. Oxidative
Decarboxylation: α-
ketoglutarate to succinyl-
CoA (4C), releasing CO₂
and forming NADH.
5.Substrate-level
Phosphorylation: Succinyl-
CoA to succinate (4C),
forming GTP (converted to
ATP).

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 Krebs Cycle
6.Oxidation: Succinate to
fumarate (4C), forming
FADH₂.
7.Hydration: Fumarate to
malate (4C).
8.Oxidation: Malate to
oxaloacetate (4C), forming
NADH.

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 Overall Products Krebs
Cycle

6 NADH
2 FADH₂
2 ATP
4 CO₂ (per glucose
molecule, as the cycle
runs twice per glucose)

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 Summary of Glycolysis to Krebs Cycle

This outline provides a structured overview of the key components and
stages involved in cellular respiration, emphasizing the biochemical
processes and their significance in energy production.

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 Electron Transport
Chain

Involves oxidation and reduction
processes
Transfers electrons from NADH
and FADH2
Plays a significant role in ATP
production

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 Electron Transport Chain
Contains three proton pumps (Complexes I, III, and IV) connected by two

mobile electron carriers (Coenzyme Q and Cytochrome C)

Complex
Complex I NADH reductase

Complex II Succinate dehydrogenase

Complex III Cytochrome reductase

Complex IV Cytochrome oxidase

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 Electron Transport Chain

NADH and FADH2 , in their reduced
forms, carry high-energy electrons and
hydrogen ions (H + )
These carrier molecules transport the
high-energy electrons and H + ions
from glycolysis, the link reaction, and
the Krebs cycle to the electron
transport chain in the inner
mitochondrial membrane

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 Electron Transport
Chain
There are two entry
points into the ETC:
Complex I for NADH
and Complex II for
FADH2

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 Electron Transport
Chain
Electron flow from NADH:
Complex I → CoQ →
Complex III → Cyt. c →
Complex IV
Electron flow from FADH2 :
Complex II → CoQ →
Complex III → Cyt. c →
Complex IV

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 Electron Transport
Chain
Complex II does not
transport protons across
the membrane and only
contributes to the proton
gradient minimally, similar
to CoQ and Cyt. c

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 NADH in the Electron
Transport Chain
NADH binds to Complex I and
releases its 2 hydrogen atoms
(H + and electrons) into the
ETC
NAD + returns to the Krebs
cycle
Electrons pass from one carrier
molecule to the next, moving
down the energy gradient from
the high-energy NADH to the
final electron acceptor, oxygen,
where water (H2 O) is formed

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 FADH2 in the Electron Transport Chain
FADH2 at Complex II releases its
H+ and electrons to Coenzyme Q
Each successive acceptor molecule
is reduced when it receives
electrons and then oxidized when
it passes them on
The final transfer involves
combining electrons and H2 atoms
with oxygen to form water at
Complex IV
Oxygen is the final electron
acceptor and has the highest
electronegativity

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 Creation of Hydrogen
Ion Gradient
As electrons are passed
down the chain, some of
their energy is used to
pump H+ ions out of the
mitochondrial matrix into
the intermembrane space
Proton pumping occurs
only at Complexes I, III,
and IV
This creates a
transmembrane
electrochemical proton
gradient.

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 Creation of Hydrogen
Ion Gradient
H+ ions, highly concentrated
in the intermembrane space,
flow back across the
membrane down the
electrochemical gradient
through ATP synthase
The inner mitochondrial
membrane is impermeable
to H+ ions, so they diffuse
through ATP synthase only

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 Phosphorylation of ADP
Chemiosmosis refers to the diffusion
(osmosis) of ions across a selectively
permeable membrane down the
electrochemical gradient
As H + ions move back across the
membrane and release energy, ATP
synthase phosphorylates ADP to
ATP

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 Phosphorylation of ADP

This process is called oxidative
phosphorylation because it
requires oxygen
Inhibitors can bind to
components of the electron
transport chain, blocking
electron transfer and stopping
proton pumping and ATP
synthesis

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 Total ATP Produced:
36 or 38?
ATP formation during
glycolysis involves shuttle
systems
2 NADH molecules from
glycolysis in the cytoplasm
are not directly accessible to
the ETC due to the
mitochondrial inner
membrane being
impermeable to NADH

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 Total ATP Produced:
36 or 38?
Two shuttle systems
transport energy from
NADH across the
membrane:
o Malate-aspartate shuttle
(NADH)
o Glycerol-3-phosphate
shuttle (FADH)
Oxidation of one NADH
molecule synthesizes three
ATP molecules, while
oxidation of FADH2 yields
two ATP molecules
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 Malate-Aspartate Shuttle

Occurs in the liver, kidneys,
and heart during glycolysis
Electrons are carried in the
form of malate
NADH is regenerated
inside the mitochondrial
matrix
Total ATP produced is 38

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 Glycerol-3-Phosphate
Shuttle
Occurs in skeletal muscles
and the brain during
glycolysis
Electrons are transferred
from NADH to FAD in the
mitochondria
FAD is reduced to FADH2
Newly formed FADH2
passes electrons to CoQ of
the ETC, generating 2 ATP
per electron pair
Total ATP produced is 36

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 Aerobic Cellular
Respiration (Lipid)
Fats can serve as a source of
energy
Fats are broken down into
fatty acids and glycerol
Glycerol converts to
glyceraldehyde 3-phosphate,
which undergoes glycolysis,
the link reaction, the Krebs
cycle, and the ETC

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 Aerobic Cellular
Respiration (Lipid)
Fatty acids undergo β-
oxidation, splitting into 2-
carbon fragments and
converting to acetyl groups
that combine with coenzyme
A to form acetyl CoA, which
enters the Krebs cycle
Each β-oxidation process
requires one ATP to prime
but produces one NADH and
one FADH2

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 Anaerobic Respiration
(Fermentation)
Allows glycolysis to occur with a
small amount of ATP production
and regeneration of NAD +
Facultative anaerobes can respire
aerobically or carry out anaerobic
respiration when oxygen is limiting
(lactic acid fermentation)
Obligate anaerobes only respire
anaerobically and live in low- or
no-oxygen environments
(alcoholic fermentation)

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 Alcoholic Fermentation
Occurs in some fungi, yeast, bacteria,
and earthworms
Pyruvate (3C) converts to CO2 and
ethanol (EtOH)
Yeast enzymes remove CO2 from
pyruvate, yielding acetaldehyde (2C) -
decarboxylation
Acetaldehyde accepts electrons from
NADH, converting to EtOH and
regenerating NAD+ needed for
glycolysis
Pyruvate and NADH are products of
glycolysis
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 Lactic Acid Fermentation

Occurs in vertebrate skeletal muscles
that contract actively
Pyruvate is reduced by NADH to form
lactate without releasing CO2 ,
regenerating NAD+ Lactate
accumulation causes fatigue, cramping,
and lower blood pH
Oxygen debt is repaid by deep, rapid
breathing to break down lactate
After strenuous activity, lactate is
oxidized back to pyruvate in the liver

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 Importance of Anaerobic Respiration
Regenerates NAD+ for glycolysis

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