Cellular Respiration Chapter 5 PDF

Summary

This document details chapter 5 on cellular respiration. It explores energy flow and the mechanisms behind cellular respiration, including the intricacies of glycolysis, the citric acid cycle, and electron transport. The chapter also discusses the efficiency of the process and the role of oxygen.

Full Transcript

Chapter 5

Cellular Respiration
Energy
Flow

But why??
ATP

WORK

LIVE
Energy Flow

The Sun
– Ultimate source of ______

Photosynthesis
– Captures energy of light
– Converts it to chemical energy
--> complex organic molecules

WHY????
 Energy Flow

Unstable

Transfer Transfer
of of Energy
Energy

Stable
What do gasoline and glucose have
in common?
Abundance of carbon-hydrogen bonds

 Good source of ______

WHY???
 Energy Levels of Electrons of an
Atom
What kind of bond is
a C-H bond?

 Electrons are
equidistant from
nuclei.
+

When electrons move towards atomic nucleus, energy
is ________
 C-H bonds

Electronegativities
How do we get the energy that is
stored in organic molecules?
Oxidize it --> remove electrons

Donor is oxidized - lose electrons

Acceptor is reduced - gains electrons

Reduction-oxidation reactions (REDOX)
– Transfer electrons from donor to acceptor
atoms
 What is going to be able to remove the
electrons (oxidization)?

Oxidizing Agent
Higher
Electronegativity
 Redox Reactions

Equal Sharing Unequal Sharing

High Energy Low Energy
Unstable Stable

Why?
 Cellular Respiration

Organisms obtain energy by oxidizing
organic molecules produced by
photosynthesis in a series of reactions

Energy released in oxidations is captured in
ATP___
Done in series of rxn’s

C6H12O6 + 6 O2 + 32 ADP + 32 Pi→ 6 H2O + 6 CO2 + 32 ATP
Cellular Respiration is Controlled
Combustion

YES
EFFICIENT !
!!!

NOT Same G
EFFICIENT ! Different EA
!!!
Energy Transfer

Electrons lose energy as they pass from
donor to acceptor molecule

Released energy is free energy that can do
work

In cellular respiration
– End result is synthesis of _ATP____
 What will carry the energy through
this process?
Electron Carriers  NAD+

Dehydrogenase

Fig. 6-6, p. 118
Cellular Respiration: 3 Stages

1. Glycolysis

2. Citric acid cycle

3. Electron transport and
chemiosmosis
1. Glycolysis

Glucose is converted:

– to 2 molecules of pyruvate by oxidizing and
removing electrons
– From NAD+ to NADH
– Through series of enzyme-catalyzed reactions
– ATP and NADH is synthesized
2. Citric Acid Cycle

Oxidize pyruvate  Acetyl coenzyme A

(acetyl-CoA)
– Enters metabolic cycle
– Oxidized completely to carbon dioxide
– Synthesis of ATP, NADH and FADH2
3. Electron Transport and
Chemiosmosis
NADH synthesized by glycolysis and citric acid cycle
is oxidized (also FADH2)

– Liberated electrons pass along electron transport
chain

– Electrons transferred to O2 --> water

– Free energy establishes proton gradient across
membrane

– Drives synthesis of _ATP____
 Mitochondria
Location for most cellular respiration

But prokaryotes
don’t have
mitochondria !!!
1. Glycolysis
10 steps in the cytosol

Glucose (6 carbons) is oxidized into two
molecules of pyruvate (3 carbons each)
Electrons removed are delivered to NAD+
producing NADH

Each glucose molecule oxidized produces
– 2 ATP
– 2 NADH
– 2 pyruvate
Energy Inputs and Outputs in
Glycolysis
 Glycolysis – Steps 1-3

Energy Input - Consume 2 ATPs

 Phosphorylation

Phosphofructokinase – regulated
enzyme
Glycolysis – Steps 4-5

Energy Input

Splitting - 1 sugar  2 G3P
Glycolysis – Steps 6-7

Energy Output

Production of 2 ATP by
substrate-level phosphorylation

Synthesis of 2 NADH by redox
reaction
Glycolysis – Steps 8-10

Energy Output

Production of 2 ATP by
substrate-level phosphorylation

2 pyruvates – less potential
energy than glucose
ATP
ATP molecules
– Produced in glycolysis
– Result from substrate-level phosphorylation

Substrate-level phosphorylation
– Enzyme-catalyzed reaction
– Transfers phosphate group from substrate to
ADP
ATP Synthesis by Substrate-
Level Phosphorylation

Same in Citric Acid Cycle
Different in Oxidative Phosphorylation
and Chemiosmosis

___ ATP Synthase
 Pyruvate Oxidation

DEHYDROGENATION DECARBOXYLATION

High Energy Intermediate
Pyruvate Oxidation

Takes place in mitochondrial matrix

Pyruvate oxidized to acetyl groups (2C)

Electrons removed are accepted by NAD+

CO2 is produced
Pyruvate Oxidation (cont’d)

Each pyruvate molecule produces
– 1 acetyl group
– 1 NADH
– 1 CO
2

Acetyl groups attached to coenzyme A
–  Acetyl-CoA
– Delivered to citric acid cycle
Summary: Pyruvate Oxidation

pyruvate + CoA + NAD+

acetyl-CoA + NADH + H+ + CO2

Based on 1 pyruvate but need to double if based on 1 glucose
Pyruvate Oxidation and Citric Acid
Cycle

Pyruvate
Oxidation

Citric
Acid
Cycle
2. Citric Acid Cycle

8 enzymatic reactions

Acetyl groups completely oxidized to CO2

Electrons removed in oxidations
– Accepted by NAD+ or FAD
Citric Acid Cycle (cont’d)
Substrate-level phosphorylation
– Produces _ATP___

Each acetyl group oxidized produces
– 2 CO
2
– 1 ATP
– 3 NADH
– 1 FADH2
Summary: Citric Acid Cycle

1 acetyl-CoA + 3 NAD+ + 1 FAD + 1 ADP + 1 Pi + 2 H2O

2 CO2 + 3 NADH + 1 FADH2 + 1 ATP + 3 H+ + 1 CoA

Based on 1 pyruvate but need to double if based on 1 glucose
Citric Acid Cycle High
Energy

Redox Rxn

Isomerization

Hydration H2O

High CO2 loss
Energy
Redox Rxn Redox Rxn

CO2 loss
ATP Synthesis
Redox Rxn
Electron Transfer and Chemiosmosis
Respiratory Electron Transport Chain
Inner mitochondrial membrane
In eukaryotes
Includes
– 4 major protein complexes (I, II, III and IV)
– 2 smaller shuttle carriers
Respiratory Electron Transport
Chain (cont’d)
Electrons passed from NADH and FADH2 to O2
through carriers in a stepwise manner

Oxygen is the final electron acceptor

Electrons are depleted of energy

Some energy used by complexes I and IV
– To pump protons (H+) across inner mitochondrial
membrane
– Electrochemical gradient
Electron Transfer System and
Oxidative Phosphorylation

Electrochemical
gradient

Proton-
motive
force
 Redox Components of Electron
Transport Chain
Prosthetic High energy state
Groups
transfer
electrons

_No___
ATP Low energy state
Production
Oxidative Phosphorylation and
Chemiosmosis
ATP synthase catalyzes ATP synthesis using
energy from the H+ gradient across the
membrane (chemiosmosis)

ATP synthase
– Embedded in inner mitochondrial membrane
with electron transfer system
ATP Synthase – A Molecular Motor

Driven by
proton-
motive
force
Uncoupling of Electron Transport
and ATP Synthesis
Efficiency of Cellular Respiration

More than 30% efficiency for utilization of energy
released by glucose oxidation if the H+ gradient
is used only for ATP____ production
ATP Production
Approximate
1 NADH  2.5 ATP
1 FADH2  1.5 ATP

Optimal
Amount
 Energy Calculation
ATP  ADP + Pi = 7.3 kcal/mol

32 ATP = 32 x 7.3 kcal/mol = 233.6 kcal/mol

1 glucose = 686 kcal/mol

% efficiency = 233.6 kcal/mol = ___ %
686 kcal/mol

What happened to the other ~ 66 %?
Oxidation of Carbohydrates, Fats,
and Proteins
Control of Cellular Respiration

Allosteric Activator

Feedback Inhibition
Oxygen and Cellular Respiration
Fermentation

Reaction pathways
In the cytosol
– NADH delivers electrons
– From glycolysis to organic acceptor molecules
– Converting NADH back to NAD+
– Pyruvate is reduced
Fermentation (cont’d)

NAD+ free to accept more electrons
– Removed from sugars in glycolysis

ATP production by glycolysis
– Continues in absence of oxygen
Fermentation
Fermentation
Anaerobic Respiration
Prokaryotes - respiratory electron transport
chains on internal membrane systems

Possess anaerobic respiration

Sulphate, nitrate, and ferric ion are common
electron acceptors

Still make ATP??
Lifestyles Dictated by Oxygen
Strict anaerobes: Cannot grow in presence of
oxygen

Strict aerobes:
can not survive without oxygen Require oxygen

Facultative anaerobes: Can grow in presence of
oxygen and can grow using fermentative
pathways
Paradox of Aerobic Life

Although many organisms cannot exist
without oxygen because it is required for
electron transport, oxygen itself is inherently
dangerous to all forms of life
 Reduction of Oxygen to Water

Reactive
Oxygen
Species
Defence Against Reactive Oxygen
Species
Reactive oxygen species (ROS)
– Include superoxide, hydrogen peroxide and hydroxyl
radical
– Strong oxidizing agents
– Lead to Alzheimers, cancer, heart disease

Antioxidant defence system
– Enzymes
– Superoxide dismutase and catalase

– Nonenzymes
– Antioxidants: Vitamin C and vitamin E
Putting it into Perspective

1. Why do we eat?

2. What are three stages of energy transfer?

3. How do we store the energy? Through

glycolysis

4. How efficient is the process? 30-35%

efficient

5. What’s the alternative pathway when no