Download Chapter 6 How Cells Harvest Chemical Energy

Chapter 6
How Cells Harvest Chemical Energy
PowerPoint Lectures for
Campbell Biology: Concepts & Connections, Seventh Edition
Reece, Taylor, Simon, and Dickey
Lecture by Edward J. Zalisko
© 2012 Pearson Education, Inc.
Introduction
  In eukaryotes, cellular respiration
–  harvests energy from food,
–  yields large amounts of ATP, and
–  Uses ATP to drive cellular work.
  A similar process takes place in many prokaryotic
organisms.
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Figure 6.0_1
Chapter 6: Big Ideas
Cellular Respiration:
Aerobic Harvesting
of Energy
Fermentation: Anaerobic
Harvesting of Energy
Stages of Cellular
Respiration
Connections Between
Metabolic Pathways
1
CELLULAR RESPIRATION:
AEROBIC HARVESTING
OF ENERGY
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6.1 Photosynthesis and cellular respiration
provide energy for life
  Life requires energy.
  In almost all ecosystems, energy ultimately comes
from the sun.
  In photosynthesis,
–  some of the energy in sunlight is captured by
chloroplasts,
–  atoms of carbon dioxide and water are rearranged, and
–  glucose and oxygen are produced.
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6.1 Photosynthesis and cellular respiration
provide energy for life
  In cellular respiration
–  glucose is broken down to carbon dioxide and water
and
–  the cell captures some of the released energy to make
ATP.
  Cellular respiration takes place in the mitochondria
of eukaryotic cells.
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2
Figure 6.1
Sunlight energy
ECOSYSTEM
Photosynthesis
in chloroplasts
Glucose
CO2
O2
H 2O
Cellular respiration
in mitochondria
(for cellular
ATP
work)
Heat energy
Figure 6.1_1
Sunlight energy
ECOSYSTEM
Photosynthesis
in chloroplasts
Glucose
CO2
O2
H 2O
Cellular respiration
in mitochondria
(for cellular
ATP
work)
Heat energy
6.2 Breathing supplies O2 for use in cellular
respiration and removes CO2
  Respiration, as it relates to breathing, and cellular
respiration are not the same.
–  Respiration, in the breathing sense, refers to an
exchange of gases. Usually an organism brings in
oxygen from the environment and releases waste CO2.
–  Cellular respiration is the aerobic (oxygen requiring)
harvesting of energy from food molecules by cells.
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3
Figure 6.2
O2
Breathing
CO2
Lungs
CO2
O2
Bloodstream
Muscle cells carrying out
Cellular Respiration
Glucose + O2
CO2 + H2O + ATP
6.3 Cellular respiration banks energy in ATP
molecules
  Cellular respiration is an exergonic process that
transfers energy from the bonds in glucose to form
ATP.
  Cellular respiration
–  produces up to 32 ATP molecules from each glucose
molecule and
–  captures only about 34% of the energy originally stored
in glucose.
  Other foods (organic molecules) can also be used
as a source of energy.
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Figure 6.3
C6H12O6
6
Glucose
Oxygen
O2
6 CO2
Carbon
dioxide
6
H 2O
ATP
Water
+ Heat
4
6.4 CONNECTION: The human body uses energy
from ATP for all its activities
  The average adult human needs about 2,200 kcal
of energy per day.
–  About 75% of these calories are used to maintain a
healthy body.
–  The remaining 25% is used to power physical activities.
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6.4 CONNECTION: The human body uses energy
from ATP for all its activities
  A kilocalorie (kcal) is
–  the quantity of heat required to raise the temperature of
1 kilogram (kg) of water by 1oC,
–  the same as a food Calorie, and
–  used to measure the nutritional values indicated on food
labels.
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Figure 6.4
Activity
kcal consumed per hour
by a 67.5-kg (150-lb) person*
Running (8–9 mph)
979
Dancing (fast)
510
Bicycling (10 mph)
490
Swimming (2 mph)
408
Walking (4 mph)
341
Walking (3 mph)
245
Dancing (slow)
Driving a car
Sitting (writing)
204
61
28
*Not including kcal needed for
body maintenance
5
6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  The energy necessary for life is contained in the
arrangement of electrons in chemical bonds in
organic molecules.
  An important question is how do cells extract this
energy?
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6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  When the carbon-hydrogen bonds of glucose are
broken, electrons are transferred to oxygen.
–  Oxygen has a strong tendency to attract electrons.
–  An electron loses potential energy when it “falls” to
oxygen.
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6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  Energy can be released from glucose by simply
burning it.
  The energy is dissipated as heat and light and is
not available to living organisms.
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6
6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  On the other hand, cellular respiration is the
controlled breakdown of organic molecules.
  Energy is
–  gradually released in small amounts,
–  captured by a biological system, and
–  stored in ATP.
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6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  The movement of electrons from one molecule to
another is an oxidation-reduction reaction, or redox
reaction. In a redox reaction,
–  the loss of electrons from one substance is called
oxidation,
–  the addition of electrons to another substance is called
reduction,
–  a molecule is oxidized when it loses one or more
electrons, and
–  reduced when it gains one or more electrons.
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6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  A cellular respiration equation is helpful to show the
changes in hydrogen atom distribution.
  Glucose
–  loses its hydrogen atoms and
–  becomes oxidized to CO2.
  Oxygen
–  gains hydrogen atoms and
–  becomes reduced to H2O.
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Figure 6.5A
Loss of hydrogen atoms
(becomes oxidized)
6 O2
C6H12O6
Glucose
6 CO2
ATP
6 H 2O
+ Heat
Gain of hydrogen atoms
(becomes reduced)
6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  Enzymes are necessary to oxidize glucose and
other foods.
  NAD+
–  is an important enzyme in oxidizing glucose,
–  accepts electrons, and
–  becomes reduced to NADH.
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Figure 6.5B
Becomes oxidized
2H
NAD+
2 H+
Becomes reduced
2
2H
NADH
H+
(carries
2 electrons)
8
6.5 Cells tap energy from electrons falling
from organic fuels to oxygen
  There are other electron carrier molecules that
function like NAD+.
–  They form a staircase where the electrons pass from
one to the next down the staircase.
–  These electron carriers collectively are called the
electron transport chain.
–  As electrons are transported down the chain, ATP is
generated.
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Figure 6.5C
NADH
ATP
NAD+
2
Controlled
release of
energy for
synthesis
of ATP
H+
El
ec
tr
on
tr
an
sp
or
tc
ha
i
n
2
1 O
2 2
2 H+
H 2O
STAGES OF CELLULAR
RESPIRATION
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9
6.6 Overview: Cellular respiration occurs in
three main stages
  Cellular respiration consists of a sequence of steps
that can be divided into three stages.
–  Stage 1 – Glycolysis
–  Stage 2 – Pyruvate oxidation and citric acid cycle
–  Stage 3 – Oxidative phosphorylation
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6.6 Overview: Cellular respiration occurs in
three main stages
  Stage 1: Glycolysis
–  occurs in the cytoplasm,
–  begins cellular respiration, and
–  breaks down glucose into two molecules of a threecarbon compound called pyruvate.
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6.6 Overview: Cellular respiration occurs in
three main stages
  Stage 2: The citric acid cycle
–  takes place in mitochondria,
–  oxidizes pyruvate to a two-carbon compound, and
–  supplies the third stage with electrons.
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6.6 Overview: Cellular respiration occurs in
three main stages
  Stage 3: Oxidative phosphorylation
–  involves electrons carried by NADH and FADH2,
–  shuttles these electrons to the electron transport chain
embedded in the inner mitochondrial membrane,
–  involves chemiosmosis, and
–  generates ATP through oxidative phosphorylation
associated with chemiosmosis.
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Figure 6.6
CYTOPLASM
NADH
Electrons
carried by NADH
Glycolysis
Glucose
Pyruvate
NADH
Pyruvate
Oxidation
FADH2
Oxidative
Phosphorylation
(electron transport
and chemiosmosis)
Citric Acid
Cycle
Mitochondrion
ATP
Substrate-level
phosphorylation
ATP
Substrate-level
phosphorylation
ATP
Oxidative
phosphorylation
Figure 6.6_1
CYTOPLASM
NADH
Electrons
carried by NADH
Glycolysis
Pyruvate
Glucose
Pyruvate
Oxidation
NADH
Citric Acid
Cycle
FADH2
Oxidative
Phosphorylation
(electron transport
and chemiosmosis)
Mitochondrion
ATP
ATP
ATP
Substrate-level
phosphorylation
Substrate-level
phosphorylation
Oxidative
phosphorylation
11
6.7 Glycolysis harvests chemical energy by
oxidizing glucose to pyruvate
  In glycolysis,
–  a single molecule of glucose is enzymatically cut in half
through a series of steps,
–  two molecules of pyruvate are produced,
–  two molecules of NAD+ are reduced to two molecules of
NADH, and
–  a net of two molecules of ATP is produced.
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Figure 6.7A
Glucose
2 ADP
2 NAD+
2 P
2 NADH
2
ATP
2 H+
2 Pyruvate
6.7 Glycolysis harvests chemical energy by
oxidizing glucose to pyruvate
  ATP is formed in glycolysis by substrate-level
phosphorylation during which
–  an enzyme transfers a phosphate group from a
substrate molecule to ADP and
–  ATP is formed.
  The compounds that form between the initial
reactant, glucose, and the final product, pyruvate,
are called intermediates.
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12
Figure 6.7B
Enzyme
P
Enzyme
ADP
ATP
P
P
Substrate
Product
6.7 Glycolysis harvests chemical energy by
oxidizing glucose to pyruvate
  The steps of glycolysis can be grouped into two
main phases.
–  In steps 1–4, the energy investment phase,
–  energy is consumed as two ATP molecules are used to
energize a glucose molecule,
–  which is then split into two small sugars that are now primed
to release energy.
–  In steps 5–9, the energy payoff,
–  two NADH molecules are produced for each initial glucose
molecule and
–  ATP molecules are generated.
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Figure 6.7Ca_s1
Glucose
Steps 1 – 3 A fuel
ATP
molecule is energized,
using ATP.
ADP
Step
ENERGY
INVESTMENT
PHASE
1
P
Glucose 6-phosphate
P
Fructose 6-phosphate
P
Fructose
1,6-bisphosphate
2
ATP
3
ADP
P
13
Figure 6.7Ca_s2
ENERGY
INVESTMENT
PHASE
Glucose
Steps 1 – 3 A fuel
ATP
molecule is energized,
using ATP.
ADP
Step
1
P
Glucose 6-phosphate
P
Fructose 6-phosphate
P
Fructose
1,6-bisphosphate
2
ATP
3
ADP
Step 4 A six-carbon
intermediate splits
into two three-carbon
intermediates.
P
4
P
P
Figure 6.7Cb_s1
Step 5
A redox reaction
generates NADH.
NAD+
5
P
NADH
H+
P
H+
P
P
ENERGY
PAYOFF
PHASE
NAD+
5
P
NADH
H+
5
P
NADH
H+
P
ADP
P
P
1,3-Bisphosphoglycerate
P
3-Phosphoglycerate
ADP
6
6
ATP
ATP
P
7
7
P
P
8
H 2O
8
H 2O
P
2-Phosphoglycerate
P
ADP
Phosphoenolpyruvate (PEP)
ADP
9
9
ATP
1,3-Bisphosphoglycerate
P
P
NAD+
P
Steps 6 – 9
ATP and pyruvate
are produced.
5
NADH
P
P
Step 5
A redox reaction
generates NADH.
ENERGY
PAYOFF
PHASE
P
P
NAD+
Figure 6.7Cb_s2
Glyceraldehyde
3-phosphate (G3P)
ATP
Pyruvate
14
6.8 Pyruvate is oxidized prior to the citric acid
cycle
  The pyruvate formed in glycolysis is transported
from the cytoplasm into a mitochondrion where
–  the citric acid cycle and
–  oxidative phosphorylation will occur.
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6.8 Pyruvate is oxidized prior to the citric acid
cycle
  Two molecules of pyruvate are produced for each
molecule of glucose that enters glycolysis.
  Pyruvate does not enter the citric acid cycle, but
undergoes some chemical grooming in which
–  a carboxyl group is removed and given off as CO2,
–  the two-carbon compound remaining is oxidized while a
molecule of NAD+ is reduced to NADH,
–  coenzyme A joins with the two-carbon group to form
acetyl coenzyme A, abbreviated as acetyl CoA, and
–  acetyl CoA enters the citric acid cycle.
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Figure 6.8
NAD+
NADH
H+
2
CoA
Pyruvate
Acetyl coenzyme A
1
CO2
3
Coenzyme A
15
6.9 The citric acid cycle completes the oxidation of
organic molecules, generating many NADH
and FADH2 molecules
  The citric acid cycle
–  is also called the Krebs cycle (after the German-British
researcher Hans Krebs, who worked out much of this
pathway in the 1930s),
–  completes the oxidation of organic molecules, and
–  generates many NADH and FADH2 molecules.
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Figure 6.9A
Acetyl CoA
CoA
CoA
2 CO2
Citric Acid Cycle
3 NAD+
FADH2
3 NADH
FAD
3 H+
ATP
ADP
P
6.9 The citric acid cycle completes the oxidation of
organic molecules, generating many NADH
and FADH2 molecules
  During the citric acid cycle
–  the two-carbon group of acetyl CoA is added to a fourcarbon compound, forming citrate,
–  citrate is degraded back to the four-carbon compound,
–  two CO2 are released, and
–  1 ATP, 3 NADH, and 1 FADH2 are produced.
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16
6.9 The citric acid cycle completes the oxidation of
organic molecules, generating many NADH
and FADH2 molecules
  Remember that the citric acid cycle processes two
molecules of acetyl CoA for each initial glucose.
  Thus, after two turns of the citric acid cycle, the
overall yield per glucose molecule is
–  2 ATP,
–  6 NADH, and
–  2 FADH2.
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Figure 6.9B_s1
Acetyl CoA
CoA
CoA
2 carbons enter cycle
Oxaloacetate
1
Citric Acid Cycle
Step 1
Acetyl CoA stokes
the furnace.
Figure 6.9B_s2
Acetyl CoA
CoA
CoA
2 carbons enter cycle
Oxaloacetate
1
Citrate
NAD+
NADH
2
Citric Acid Cycle
H+
CO2 leaves cycle
Alpha-ketoglutarate
3
CO2 leaves cycle
NAD+
ADP
Step 1
Acetyl CoA stokes
the furnace.
P
NADH
H+
Steps 2 – 3
ATP
NADH, ATP, and CO2
are generated during redox reactions.
17
Figure 6.9B_s3
Acetyl CoA
CoA
CoA
2 carbons enter cycle
Oxaloacetate
1
Citrate
NADH
H+
NAD+
5
NAD+
NADH
2
Citric Acid Cycle
CO2 leaves cycle
Malate
FADH2
H+
Alpha-ketoglutarate
4
3
FAD
CO2 leaves cycle
NAD+
Succinate
ADP
Step 1
Acetyl CoA stokes
the furnace.
P
Steps 2 – 3
ATP
NADH, ATP, and CO2
are generated during redox reactions.
NADH
H+
Steps 4 – 5
Further redox reactions generate
FADH2 and more NADH.
6.10 Most ATP production occurs by oxidative
phosphorylation
  Oxidative phosphorylation
–  involves electron transport and chemiosmosis and
–  requires an adequate supply of oxygen.
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6.10 Most ATP production occurs by oxidative
phosphorylation
  Electrons from NADH and FADH2 travel down the
electron transport chain to O2.
  Oxygen picks up H+ to form water.
  Energy released by these redox reactions is used
to pump H+ from the mitochondrial matrix into the
intermembrane space.
  In chemiosmosis, the H+ diffuses back across the
inner membrane through ATP synthase
complexes, driving the synthesis of ATP.
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18
Figure 6.10
H+
Intermembrane
space
H+
H+
H+
H+
III
H+ ATP
synthase
IV
I
Inner mitochondrial
membrane
H+
H+
H+ Mobile
electron
carriers
Protein
complex
of electron
carriers
II
FADH2
Electron
flow
NADH
FAD
2 H+
NAD+
1
2 O2
H 2O
H+
Mitochondrial
matrix
ADP
P
ATP
H+
Chemiosmosis
Electron Transport Chain
Oxidative Phosphorylation
Figure 6.10_1
H+
H+
H+
H+
H+
H+ Mobile
electron
carriers
Protein
complex
of electron
carriers
H+
H+
III
H+ ATP
synthase
IV
I
II
FADH2
Electron
flow
NADH
NAD+
FAD
2 H+
1
O
2 2
H 2O
H+
ADP
P
ATP
H+
Electron Transport Chain
Chemiosmosis
Oxidative Phosphorylation
6.11 CONNECTION: Interrupting cellular respiration
can have both harmful and beneficial effects
  Three categories of cellular poisons obstruct the
process of oxidative phosphorylation. These
poisons
1.  block the electron transport chain (for example,
rotenone, cyanide, and carbon monoxide),
2.  inhibit ATP synthase (for example, the antibiotic
oligomycin), or
3.  make the membrane leaky to hydrogen ions (called
uncouplers, examples include dinitrophenol).
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19
Figure 6.11
Rotenone
Cyanide,
carbon monoxide
H+
H+
H+
Oligomycin
ATP
synthase
H+
H+ H+ H+
DNP
FADH2
NAD+
NADH
H+
FAD
1
O
2 2
2 H+
H 2O
ADP
P
ATP
6.11 CONNECTION: Interrupting cellular respiration
can have both harmful and beneficial effects
  Brown fat is
–  a special type of tissue associated with the generation
of heat and
–  more abundant in hibernating mammals and newborn
infants.
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6.11 CONNECTION: Interrupting cellular respiration
can have both harmful and beneficial effects
  In brown fat,
–  the cells are packed full of mitochondria,
–  the inner mitochondrial membrane contains an
uncoupling protein, which allows H+ to flow back down
its concentration gradient without generating ATP, and
–  ongoing oxidation of stored fats generates additional
heat.
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20
6.12 Review: Each molecule of glucose yields
many molecules of ATP
  Recall that the energy payoff of cellular respiration
involves
1.  glycolysis,
2.  alteration of pyruvate,
3.  the citric acid cycle, and
4.  oxidative phosphorylation.
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6.12 Review: Each molecule of glucose yields
many molecules of ATP
  The total yield is about 32 ATP molecules per
glucose molecule.
  This is about 34% of the potential energy of a
glucose molecule.
  In addition, water and CO2 are produced.
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Figure 6.12
CYTOPLASM
Electron shuttles
across membrane
2 NADH
Mitochondrion
2 NADH
or
2 FADH2
6 NADH
2 NADH
Glycolysis
2
Pyruvate
Glucose
Pyruvate
Oxidation
2 Acetyl
CoA
Citric Acid
Cycle
2 FADH2
Oxidative
Phosphorylation
(electron transport
and chemiosmosis)
Maximum
per glucose:
+2
ATP
by substrate-level
phosphorylation
+2
ATP
by substrate-level
phosphorylation
+ about
28 ATP
About
32 ATP
by oxidative
phosphorylation
21
FERMENTATION: ANAEROBIC
HARVESTING OF ENERGY
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6.13 Fermentation enables cells to produce ATP
without oxygen
  Fermentation is a way of harvesting chemical energy
that does not require oxygen. Fermentation
–  takes advantage of glycolysis,
–  produces two ATP molecules per glucose, and
–  reduces NAD+ to NADH.
  The trick of fermentation is to provide an anaerobic
path for recycling NADH back to NAD+.
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6.13 Fermentation enables cells to produce ATP
without oxygen
  Your muscle cells and certain bacteria can oxidize
NADH through lactic acid fermentation, in which
–  NADH is oxidized to NAD+ and
–  pyruvate is reduced to lactate.
Animation: Fermentation Overview
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22
6.13 Fermentation enables cells to produce ATP
without oxygen
  Lactate is carried by the blood to the liver, where it
is converted back to pyruvate and oxidized in the
mitochondria of liver cells.
  The dairy industry uses lactic acid fermentation by
bacteria to make cheese and yogurt.
  Other types of microbial fermentation turn
–  soybeans into soy sauce and
–  cabbage into sauerkraut.
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Figure 6.13A
2 ADP
2 P
2 ATP
Glycolysis
Glucose
2 NAD+
2 NADH
2 Pyruvate
2 NADH
2 NAD+
2 Lactate
6.13 Fermentation enables cells to produce ATP
without oxygen
  The baking and winemaking industries have used
alcohol fermentation for thousands of years.
  In this process yeasts (single-celled fungi)
–  oxidize NADH back to NAD+ and
–  convert pyruvate to CO2 and ethanol.
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23
Figure 6.13B
Glucose
2 ATP
2 NAD+
Glycolysis
2 ADP
2 P
2 NADH
2 Pyruvate
2 NADH
2 CO2
2 NAD+
2 Ethanol
6.13 Fermentation enables cells to produce ATP
without oxygen
  Obligate anaerobes
–  are poisoned by oxygen, requiring anaerobic conditions,
and
–  live in stagnant ponds and deep soils.
  Facultative anaerobes
–  include yeasts and many bacteria, and
–  can make ATP by fermentation or oxidative
phosphorylation.
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6.14 EVOLUTION CONNECTION: Glycolysis
evolved early in the history of life on Earth
  Glycolysis is the universal energy-harvesting
process of life.
  The role of glycolysis in fermentation and
respiration dates back to
–  life long before oxygen was present,
–  when only prokaryotes inhabited the Earth,
–  about 3.5 billion years ago.
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6.14 EVOLUTION CONNECTION: Glycolysis
evolved early in the history of life on Earth
  The ancient history of glycolysis is supported by its
–  occurrence in all the domains of life and
–  location within the cell, using pathways that do not
involve any membrane-bounded organelles.
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CONNECTIONS BETWEEN
METABOLIC PATHWAYS
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6.15 Cells use many kinds of organic molecules
as fuel for cellular respiration
  Although glucose is considered to be the primary
source of sugar for respiration and fermentation,
ATP is generated using
–  carbohydrates,
–  fats, and
–  proteins.
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6.15 Cells use many kinds of organic molecules
as fuel for cellular respiration
  Fats make excellent cellular fuel because they
–  contain many hydrogen atoms and thus many energyrich electrons and
–  yield more than twice as much ATP per gram than a
gram of carbohydrate or protein.
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Figure 6.15
Food, such as
peanuts
Carbohydrates
Sugars
Fats
Proteins
Glycerol Fatty acids
Amino acids
Amino
groups
Glucose
G3P
Pyruvate
Glycolysis
Pyruvate
Oxidation
Acetyl CoA
Citric
Acid
Cycle
Oxidative
Phosphorylation
ATP
6.16 Food molecules provide raw materials for
biosynthesis
  Cells use intermediates from cellular respiration for
the biosynthesis of other organic molecules.
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Figure 6.16
ATP needed
to drive
biosynthesis
Citric
Acid
Cycle
ATP
Pyruvate
Oxidation
Acetyl CoA
Glucose Synthesis
Pyruvate
G3P
Glucose
Amino
groups
Amino acids
Proteins
Fatty acids Glycerol
Fats
Sugars
Carbohydrates
Cells, tissues, organisms
6.16 Food molecules provide raw materials for
biosynthesis
  Metabolic pathways are often regulated by
feedback inhibition in which an accumulation of
product suppresses the process that produces the
product.
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