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Title: Metabolic Pathways


1
Metabolic Pathways
2
Metabolic Pathways
This section will cover the cellular pathways
that produce ATP from glucose and other
nutrients. (Chapter 7)
3
Metabolic Pathways
  • There is potential energy in covalent bonds.
  • But where does the energy come from?

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Metabolic Pathways
The disorder of the system has decreased. or The
entropy has decreased. ?S lt 0
6
Metabolic Pathways
Since ?G - T?S Then If ?Slt0, ?Ggt0
7
?Ggt0 or the potential energy has increased
8
Metabolic Pathways
  • There is potential energy in covalent bonds.
  • But where does the energy come from?

9
Metabolic Pathways
The energy is stored in the electrons.
10
Metabolic Pathways
A covalent bond is the sharing of 2 electrons.
11
Metabolic Pathways
The electrons have a certain degree of
entropy. Because the orbitals overlap in a
covalent bond, there is less entropy.
12
Metabolic Pathways
?Slt0 then ?Ggt0 or
the potential energy has
increased.
13
Bond Energy C-N 308 kJ/mol C-C 348 C-O 360 H-O
366 C-H 413 H-H 436
14
Metabolic Pathways
Strong bonds have low chemical energy
and
weak bonds have high
chemical energy.
15
Metabolic Pathways
  • REDOX reactions
  • oxidation - reduction reactions

16
Metabolic Pathways
  • In a REDOX reaction
    electrons are transferred
    from one atom to another.
  • This transfer of electrons is a transfer of
    energy.

17
Metabolic Pathways
  • Transferring electrons from one molecule to
    another is a means by which energy can be
    transferred from one molecule to another.

18
Metabolic Pathways
  • In the cell, glucose is metabolized to
    carbon dioxide, water, and energy.
  • C6H12O6 6 O2 ? 6 CO2 6 H2O energy
  • The energy yielding steps in the metabolism of
    glucose are REDOX reactions.

19
Metabolic Pathways
  • REDOX reactions are chemical reactions in which
    one of the reactants becomes oxidized (loses an
    electron) and the other
    reactant becomes reduced
    (gains an electron).

20
Metabolic Pathways
  • Oxidation-Reduction reactions or Redox
    reactions are 2
    reactions that always occur together.

21
Metabolic Pathways
  • Oxidation is LOSS of electrons.

22
Metabolic Pathways
  • This loss of electrons can be outright to form an
    ion or the electrons may be shared with a
    substance that has a greater affinity for the
    electrons, such as oxygen.

23
Metabolic Pathways
  • Most oxidation reactions are associated with the
    liberation of energy.

24
Metabolic Pathways
  • Reduction is the GAIN of electrons.

25
Metabolic Pathways
  • All reductions are accompanied by an oxidation.

26
Metabolic Pathways
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Metabolic Pathways
  • An oxidizing agent is the reactant that accepts
    an electron or a hydrogen atom.
  • A reducing agent is the reactant that donates an
    electron or a hydrogen atom.

28
Metabolic Pathways
Reducing Agent
Oxidizing Agent
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Metabolic Pathways
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Metabolic Pathways
C6H12O6 6 O2 ? 6 CO2 6 H2O energy
  • During the metabolism of glucose, glucose donates
    electrons.
  • Therefore, glucose is oxidized.

32
Metabolic Pathways
C6H12O6 6 O2 ? 6 CO2 6 H2O energy
  • Oxygen accepts electrons.
  • Therefore, oxygen is reduced.

33
Metabolic Pathways
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Metabolic Pathways
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Metabolic Pathways
  • Whenever one molecule reduced, another is
    oxidized.
  • In this process, energy is transferred as the
    electron is transferred from molecule to
    molecule.
  • This energy will ultimately be captured in ATP.
  • ADP Pi ? ATP

36
Metabolic Pathways
C6H12O6 6 O2 ? 6 CO2 6 H2O energy
  • However, during glucose oxidation, the
    electrons of glucose are first passed to an
    electron carrier.

37
Metabolic Pathways
  • The cell has 2 electron carriers
  • NAD or FAD.

38
Metabolic Pathways
  • NAD and FAD accept the electrons from glucose
    and transfers them to the mitochondria, where ATP
    is synthesized.

39
Metabolic Pathways
  • The coenzyme
  • nicotinamide adenine dinucleotide (NAD)
  • is an essential electron carrier
    in cellular redox reactions.

40
NAD
41
NADP
NADP is usually used for anabolic reactions.
42
Metabolic Pathways
  • NAD can be oxidized or reduced.
  • NAD exists in an oxidized form NAD
  • and a reduced form NADH H.

43
Metabolic Pathways
  • NAD accepts 2 electrons 1 hydrogen ion (H)
  • from 2 hydrogen atoms.

44
Metabolic Pathways
  • NADH H NAD energy

45
Metabolic Pathways
  • The reduction of NAD requires an input of energy
    (endergonic)
  • NAD 2H energy ? NADH H

46
Metabolic Pathways
  • The oxidation of NADH H is exergonic
  • NADH H ? NAD energy

47
Energy is required.
Energy is required.
48
Energy is released.
49
Energy is released.
Energy is required.
50
Metabolic Pathways
  • Flavin adenine dinucleotide (FAD) is another
    electron transporter in cellular redox reactions
  • FAD 2H FADH2

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Metabolic Pathways
In principle, reactions can run in both
directions.
53
Metabolic Pathways
  • The direction each reaction goes depends on the
    concentration of products versus substrates.

54
Metabolic Pathways
  • If there are more substrates,
    the reaction will move forward.
  • If there are more products,
    the reaction will move in reverse.

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Metabolic Pathways
  • At some concentration of reactants and products,
    the forward rate will equal
    the reverse rate.

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Metabolic Pathways
When the rate of the forward reaction is equal to
the rate of
the reverse reaction, the reaction is in
equilibrium.
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Metabolic Pathways
If we add 100 mol G-6-P to the reactants (the
left side of the equation), the reaction will
proceed to the formation of more products.
190 mol G-6-P 10 mol G-1-P
62
Metabolic Pathways
If we add 100 mol G-1-P to the products (the
right side of the equation), the reaction will
proceed to the formation of more reactants.
190 mol G-6-P 10 mol G-1-P
63
Metabolic Pathways
Metabolic pathways are a series of chemical
reactions where the product of the first reaction
serves as the substrate for the second reaction.
64
Metabolic Pathways
The addition of A will push the reaction to the
right producing B and since B is a substrate for
the next reaction, the reaction continue toward
the production of C and so on to produce D.
65
Metabolic Pathways
Each reaction is catalyzed by a separate enzyme.
66
Metabolic Pathways
The activity of each metabolic pathway can be
regulated by the activities of key
enzymes.
67
Metabolic Pathways
The production of D can be regulated by limiting
the availability of B or

by controlling the activity of the enzymes
catalyzing the various reactions.
68
Metabolic Pathways
  • Metabolic pathways are similar
    in all organisms.

69
Metabolic Pathways
Glycolysis,
the Krebs cycle
and oxidative
phosphorylation are
metabolic pathways
in the aerobic respiration of glucose.
70
D-Glucose aka dextrose
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Metabolic Pathways
  • In eukaryotes, many metabolic pathways are
    compartmentalized in organelles.

73
Metabolic Pathways
The sugar glucose (C6H12O6) is the most common
form of energy molecule. The energy in glucose
is stored in the chemical bonds.
74
Metabolic Pathways
When burned in a flame, glucose releases carbon
dioxide, water and heat (energy). C6H12O6 6 O2
? 6 CO2 6 H2O energy The same equation
applies for the biological metabolism of glucose.
75
Metabolic Pathways
The chemical bonds in glucose are broken to
release energy (exergonic).
76
Metabolic Pathways
For the complete oxidation of glucose ?G 686
kcal/mol. About half of the energy is captured
in the endergonic formation of ATP. ADP Pi ?
ATP ?G 7.3 kcal/mol.
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79
Glycolysis
  • Complete aerobic metabolism of 1
    glucose molecule will produce 36 ATP.

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Glycolysis
  • Glycolysis begins glucose metabolism in all
    cells.

83
Glycolysis
  • Glycolysis occurs in the cytoplasm.
  • A 6-carbon (6C) glucose molecule is
    converted to
    two 3-carbon (3C) pyruvate molecules.
  • This produces some usable energy. (2
    ATP molecules are generated)

84
Glucose
85
Glycolysis
Glucose

2 Pyruvate
86
Pyruvate
87
Glycolysis
Glucose

2 Pyruvate
88
Glucose

2 Pyruvate 2 NADH H 2 ATP
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Glycolysis
  • Glycolysis can be divided into two stages
  • Energy-investing reactions that use ATP.
  • Energy-harvesting reactions that produce ATP.

91
Glycolysis
  • The energy-investing reactions of glycolysis
  • In separate reactions,
    glucose is phosphorylated on
    carbon 6 and carbon 1
  • to form fructose 1,6-bisphosphate
  • and 2 ATP are hydrolyzed to ADP Pi.

92
This is the rate-limiting step
93
Glucose
94
Glucose 6-phosphate
95
Glucose 6-phosphate
Fructose 6-phosphate
96
Fructose 6-phosphate
97
Fructose 1,6 bisphosphate
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Glycolysis
  • The enzyme aldolase splits the molecule into two
    3-C molecules that become
  • glyceraldehyde 3-phosphate (G3P).

101

102
H
H
O
C
C
O
H
Glyceraldehyde 3-phosphate (G3P)
Dihydroxyacetone phosphate (DAP)
103
Fructose 1,6 bisphosphate
Aldolase
2x
Glyceraldehyde 3-phosphate (G3P)
Dihydroxyacetone phosphate (DAP)
104
isomerase
Glyceraldehyde 3-phosphate (G3P)
Dihydroxyacetone phosphate (DAP)
105
1 Glucose produces 2 G3P
isomerase
Glyceraldehyde 3-phosphate (G3P)
Dihydroxyacetone phosphate (DAP)
2x
106
Pyruvate
107
2 NAD 2 NADH and 4 ADP 4 ATP
Pyruvate
108
Glycolysis
  • The remaining reactions harvest energy.
  • The first reaction (an oxidation) releases free
    energy that is used to make
  • two molecules of NADH H,
  • one for each of the
  • two Glyceraldehyde 3-phosphate molecules.

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111
Glycolysis
For each glucose molecule 2 pyruvate molecules
are generated. In addition, for each glucose
molecule 2 NAD are reduced to NADH and 4 ATP
molecules are generated from ADP.
112
Glycolysis
  • The generation of ATP in this part of the pathway
    is called substrate-level phosphorylation.
  • In substrate level phosphorylation, a phosphate
    group (P) is transferred from one molecule to ADP
    to form ATP.

113
Glycolysis
  • Main steps in glycolysis
  • One glucose molecule (6C) is converted to two
    pyruvate molecules (3C).
  • 2 ATP are used and 4 ATP are generated.
  • There is a net gain of 2 ATP
    and
  • 2 NAD are reduced to NADH.

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Glycolysis
  • The process takes place in the cytoplasm.

116
Glycolysis
  • The rate limiting enzyme is
  • phosphofructo-kinase (PFK).

117
This is the rate-limiting step
118
Glycolysis
  • The final product of glycolysis is
    two 3-carbon molecules of pyruvate.

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PYRUVATE OXIDATION
The next step in the oxidation of glucose occurs
in the mitochondria
and is call pyruvate
oxidation.
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PYRUVATE OXIDATION
  • Pyruvate oxidation
  • Pyruvate (3C) is oxidized to
  • acetyl CoA (2C) and a CO2 molecule.
  • One NAD is reduced to NADH H during this
    reaction for each pyruvate.

124
Pyruvate
125
PYRUVATE OXIDATION
Pyruvate
Acetyl-CoA CO2
CoA

CH3
C
CO2
Acetyl-CoA
126
PYRUVATE OXIDATION
Pyruvate
Acetyl-CoA CO2
CoA

CH3
C
CO2
Acetyl-CoA
127
PYRUVATE OXIDATION
Pyruvate
Acetyl-CoA CO2
CoA

CH3
C

NADH H
128
PYRUVATE OXIDATION
Pyruvate
Acetyl-CoA CO2
CoA

CH3
C

NADH H
129
PYRUVATE OXIDATION
  • Acetyl CoA is the only molecule that can enter at
    the start of the
    Krebs cycle.

130
the Krebs cycle
131
PYRUVATE OXIDATION
Pyruvate
Acetyl-CoA CO2
CoA

CH3
C

NADH H
132
PYRUVATE OXIDATION
Pyruvate
pyruvate dehydrogenase
Acetyl-CoA CO2
CoA

CH3
C

NADH H
133
PYRUVATE OXIDATION
  • Pyruvate oxidation is a multistep reaction
    catalyzed by an enzyme complex
    (pyruvate dehydrogenase) attached to the
    inner mitochondrial membrane.

134
PYRUVATE OXIDATION
Pyruvate
pyruvate dehydrogenase
Acetyl-CoA CO2


NADH H
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136
Acetyl CoA
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138
Krebs Cycle
  • For each turn of the cycle (for each
    acetyl-CoA), the following
    molecules are generated
  • 3 NADH H
  • 1 ATP
  • 1 FADH2
  • 2 CO2

139
Krebs Cycle
  • For 1 glucose molecule,
    2 acetyl CoA molecules are generated.
  • or 1 glucose molecule will generate
  • 6 NADH H
  • 2 ATP
  • 2 FADH2
  • 4 CO2

140
Acetyl CoA
This is the rate-limiting step
141
Acetyl CoA
NADH
This is the rate-limiting step
NADH CO2
FADH2
NADH CO2
ATP
142
Krebs Cycle
143
Krebs Cycle
  • The citric acid (Krebs) cycle begins when the two
    carbons from the acetyl-coA are added to
    oxaloacetate (a 4-C molecule) to generate
    citrate (a 6-C molecule).


1
144
Krebs Cycle
  • A series of reactions oxidize 2
    carbons from the citrate producing 2 CO2
    molecules.

2
145
Krebs Cycle
  • A series of molecular rearrangements,
    regenerates oxaloacetate,
    which can be used for the next cycle.

3
146
Acetyl CoA
4 carbon molecule
Krebs Cycle

1
6 carbon molecule
3
5 carbon molecule CO2
NADH
2
4 carbon molecule CO2
NADH
ATP
NADH FADH2
147
Krebs Cycle
148
Krebs Cycle
  • The Krebs Cycle
  • occurs in the mitochondria.

149
Krebs Cycle
  • Isocitrate dehydrogenase is the rate limiting
    enzyme.

150
Krebs Cycle
Isocitrate dehydrogenase
151
Krebs Cycle
  • Substrate level phosphorylation is used to
    generate ATP.

152
Acetyl CoA
This is the rate-limiting step
153
Krebs Cycle
  • For each turn of the Krebs Cycle
  • 3 NADH
  • 1 FADH2
  • 1 ATP are generated.

154
Krebs Cycle
155
Krebs Cycle
  • For each glucose molecule the Krebs Cycle turns
    twice, generating
  • 6 NADH
  • 2 FADH2
  • 2 ATP.

156
Electron Transport Chain
  • Electron transport chain
  • The NADH and FADH2 formed in the previous
    steps are oxidized to generate ATP.

157
Electron Transport Chain
  • The flow of electrons in a series of REDOX
    reactions causes the active transport of protons
    across the inner mitochondrial membrane,
    creating a proton concentration gradient (aka
    proton-motive force).

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Electron Transport Chain
  • This process occurs in the mitochondria.
  • The respiratory chain consists of four large
    protein/enzyme complexes bound to the inner
    mitochondrial membrane, plus cytochrome c and
    ubiquinone (Q).

161
Electron Transport Chain
  • The four enzyme complexes are
  • NADH-Q reductase
  • Succinate dehydrogenase
  • Cytochrome c reductase
  • Cytochrome c oxidase.

162
Electron Transport Chain
  • NADH H passes its electrons to the NADH-Q
    reductase protein complex.
  • The NADH-Q reductase passes the electrons on to
    ubiquinone (Q), forming QH2.
  • Ubiquinone is also called Co-enzyme Q10
    (CoQ10).

163
Electron Transport Chain
  • The QH2 passes electrons to cytochrome c
    reductase complex which in turn passes them to
    the
  • cytochrome c oxidase complex.
  • Cytochrome c oxidase is the rate limiting enzyme.

164
Electron Transport Chain
  • The electrons are passed to molecular
    oxygen (O2)
    the final electron acceptor.
  • Reduced oxygen unites with two hydrogen ions to
    form water.

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166
Electron Transport Chain
  • As electrons pass through the respiratory chain,
    the energy is used to pump protons by active
    transport into the intermembrane space,
    creating a proton gradient.
  • The potential energy generated by this proton
    gradient is called the proton-motive force.

167
Electron Transport Chain
  • This transport results in the production of both
    a concentration and charge
    gradient across the inner
    mitochondrial membrane.
  • There is more H (more positive charge) in the
    intermembrane space than in the matrix.

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169
Electron Transport Chain
  • For every NADH oxidized, enough energy is
    released to transport 3 PROTONS.

170
Electron Transport Chain
  • Because FADH2 donates its electrons to
    succinate dehydrogenase
  • For every FADH2 oxidized, enough energy is
    released to transport 2 PROTONS.

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Oxidative Phosphorylation
  • The protons then diffuse through proton channels
    down the concentration and electrical gradient
    back into the matrix of the mitochondria,
    creating ATP in the process.
  • ATP synthesis by electron transport is called
    oxidative phosphorylation.

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The stoichiometry of transport for the pathway
from NADH to O2 is 10 H/2e-.
176
http//www.brookscole.com/chemistry_d/templates/st
udent_resources/shared_resources/animations/oxidat
ive/oxidativephosphorylation.html
http//highered.mcgraw-hill.com/olcweb/cgi/pluginp
op.cgi?itswf535535/sites/dl/free/0072437316
/120071/bio11.swfElectron20Transport20System2
0and20ATP20Synthesis
177
Ironically, certain cold-adapted animals,
hibernating animals, and newborn animals generate
large amounts of heat by uncoupling oxidative
phosphorylation. Adipose tissue in these
organisms contains so many mitochondria that it
is called brown adipose tissue for the color
imparted by the mitochondria. The inner membrane
of brown adipose tissue mitochondria contains an
endogenous protein called thermogenin (literally,
"heat maker"), or uncoupling protein, that
creates a passive proton channel through which
protons flow from the cytosol to the matrix.
178
Certain plants also use the heat of uncoupled
proton transport for a special purpose. Skunk
cabbage and related plants contain floral spikes
that are maintained as much as 20 degrees above
ambient temperature in this way. The warmth of
the spikes serves to vaporize odiferous
molecules, which attract insects that fertilize
the flowers.
179
The P/O ratio is the number of molecules of ATP
formed in oxidative phosphorylation per two
electrons flowing through a defined segment of
the electron transport chain.
180
In spite of intense study of this ratio, its
actual value remains a matter of contention. If
we accept the value of 10 H transported out of
the matrix per 2 e- passed from NADH to O2
through the electron transport chain, and also
agree (as above) that 4 H are transported into
the matrix per ATP synthesized (and
translocated), then the mitochondrial P/O ratio
is 10/4, or 2.5, for the case of electrons
entering the electron transport chain as NADH.
181
This is somewhat lower than earlier estimates,
which placed the P/O ratio at 3 for mitochondrial
oxidation of NADH. For the portion of the chain
from succinate to O2, the H/2 e- ratio is 6 (as
noted above), and the P/O ratio in this case
would be 6/4, or 1.5 earlier estimates placed
this number at 2.
182
The consensus of experimental measurements of P/O
ratios for these two cases has been closer to the
more modern values of 2.5 and 1.5. Many chemists
and biochemists, accustomed to the integral
stoichiometries of chemical and metabolic
reactions, have been reluctant to accept the
notion of nonintegral P/O ratios. At some
point, as we learn more about these complex
coupled processes, it may be necessary to
reassess the numbers.
183
Hypothetically speaking, how much energy does a
eukaryotic cell extract from the glucose
molecule? Taking a value of 50 kJ/mol for the
hydrolysis of ATP under cellular conditions
(Chapter 3), the production of 32 ATP per glucose
oxidized yields 1600 kJ/mol of glucose . The
cellular oxidation (combustion) of glucose yields
DG -2937 kJ/mol. We can calculate an efficiency
for the pathways of glycolysis, the TCA cycle,
electron transport, and oxidative phosphorylation
of This is the result of approximately 3.5
billion years of evolution.
184
Oxidative phosphorylation
is the production of ATP
using energy derived from
the transfer of electrons in an electron
transport system and occurs by chemiosmosis.
185
The chemiosmotic theory explains the functioning
of electron transport chains. According to this
theory, electrons are transported down an
electron transport system through a series of
oxidation-reduction reactions releases energy.
The energy of the electrons allows certain
carriers in the chain to transport hydrogen ions
(H or protons) across a membrane.
186
As the hydrogen ions accumulate on one side of a
membrane, the concentration of hydrogen ions
creates an electrochemical gradient or potential
difference (voltage) across the membrane. (The
fluid on the side of the membrane where the
protons accumulate acquires a positive charge
the fluid on the opposite side of the membrane is
left with a negative charge.) The energized state
of the membrane as a result of this charge
separation is called proton motive force.
187
In prokaryotic cells,
the protons are transported
from the cytoplasm of the bacterium across the
cytoplasmic membrane to the periplasmic space
located between the cytoplasmic membrane and the
cell wall.
188
Oxidative Phosphorylation
  • Oxidative Phosphorylation is the production of
    ATP using energy derived from the transfer of
    electrons in an electron transport system and
    occurs by chemiosmosis.

189
Oxidative Phosphorylation
  • The potential energy from the proton-motive
    force is harnessed by ATP synthase to
    synthesize ATP from ADP Pi.
  • As each proton diffuses through the ATP synthase,
  • ADP Pi is converted to ATP.

190
Oxidative Phosphorylation
  • The synthesized ATP is transported out of the
    mitochondrial matrix as quickly as it is made.
  • The proton gradient is maintained by the pumping
    of H by the
    electron transport chain.

191
Oxidative Phosphorylation
  • For every NADH oxidized, enough energy is
    released to drive the formation of 3 ATP.

192
Oxidative Phosphorylation
  • For every FADH2 oxidized, enough energy is
    released to drive the formation of 2 ATP.
  • This is because FADH2 donates its electrons to
    succinate dehydrogenase.

193
Metabolic Pathways
  • ATP generated from 1 Glucose molecule
  • ATP NADH FADH2
  • Glycolysis 2 2
  • Pyruvate
  • oxidation 2
  • Krebs cycle 2 6
    2
  • Total ATP 4 30
    4 38

194
Metabolic Pathways
  • Actually 36 ATP are generated because the NADH
    generated in glycolysis cannot enter the
    mitochondria.
  • Their electrons are passed across the membrane to
    an FADH2 molecule.
    FADH2 only yields 2 ATP.

195
Metabolic Pathways
  • ATP generated from 1 Glucose molecule
  • ATP NADH FADH2
  • Glycolysis 2 2
  • Pyruvate
  • oxidation 2
  • Krebs cycle 2 6
    2
  • Total ATP 4 28
    4 36

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Metabolic Pathways
Cyanide inhibits cytochrome
c oxidase (complex IV).
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199
Statins
CoQ10
200
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202
Metabolic Pathways
  • Without O2,
    a cell cannot reoxidize cytochrome c.
  • Then QH2 cannot be oxidized back to Q, and soon
    all the Q is reduced.
  • This continues until the entire respiratory chain
    is reduced.
  • At this point the respiratory chain stops.

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204
Metabolic Pathways
  • NAD and FAD are not regenerated from their
    reduced form.
  • Because glycolysis requires NAD, glycolysis
    stops.
  • Because Pyruvate Oxidation requires NAD,
    Pyruvate Oxidation stops.
  • Likewise, the Krebs cycle stops.

205
Metabolic Pathways
Some cells under anaerobic conditions continue
glycolysis and produce a limited amount of ATP.
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207
FERMENTATION
Pyruvate
O-
Ethanol
Lactate
CO2
208
FERMENTATION
  • When O2 is not available, glycolysis is followed
    by fermentation.
  • Fermentation uses NADH H to reduce pyruvate,
    and consequently NAD is regenerated.

209
FERMENTATION
  • Fermentation occurs in the cytoplasm.
  • Pyruvate is converted to lactic acid or ethanol.
  • This is an anaerobic process,
    it does not involve O2.
  • The breakdown of glucose is incomplete. Only
    2 ATP are produced.

210
FERMENTATION
  • In lactic acid fermentation, an enzyme,
    lactate dehydrogenase, uses the reducing power of
    NADH H to convert pyruvate
    into lactate (lactic acid).

211
Pyruvate NADH
Ethanol NAD
Lactate NAD
CO2
212
FERMENTATION
  • NAD is replenished in the process.
  • Lactic acid fermentation occurs in some
    microorganisms and in muscle cells when they are
    starved for oxygen.

213
FERMENTATION
  • NAD is replenished in the process.
  • This allows glycolysis to proceed.
  • However, only 2 ATP molecules are formed from
    glucose in this process.

214
FERMENTATION
  • Anaerobic respiration of glucose 2 ATP
  • Aerobic respiration of glucose 36 ATP

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FERMENTATION
  • Alcoholic fermentation involves the use of two
    enzymes to metabolize pyruvate.
  • First CO2 is removed from pyruvate, producing
    acetaldehyde.
  • Then acetaldehyde is reduced by NADH H,
    producing NAD and ethanol.
  • Yeast are efficient at doing alcoholic
    fermentation.

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FERMENTATION
  • Fermentation has a net yield of 2 ATP molecules
    from each glucose molecule.
  • The end products of fermentation contain much
    more unused energy than the end products of
    aerobic respiration.

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Metabolic Pathways
  • Polysaccharides (glycogen) are hydrolyzed into
    glucose which passes on to glycolysis.

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Metabolic Pathways
  • Lipids (triglycerides) are broken down by the
    enzyme lipase into the three fatty acids and
    glycerol.
  • Glycerol ( a 3 carbon sugar-alcohol) is converted
    to an intermediate in glycolysis an enters that
    pathway.
  • The Fatty Acids are broken down by a process
    called beta oxidation.

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Metabolic Pathways
  • Beta oxidation
  • Fatty Acids are broken down 2 carbons at a time
    to yield acetyl-coA.
  • The acetyl-coA enters the Krebs cycle.

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Metabolic Pathways
  • Proteins are hydrolyzed into amino acids
  • Proteins are deaminated (amino group is removed)
    or transaminated (amino group is transferred to
    another molecule).
  • The remaining molecule is usually an intermediate
    found in glycolysis or the Krebs cycle.

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Metabolic Pathways
  • When food supplies are insufficient
  • Some cells will use glycogen stores as a source
    for glucose.
  • Next, the cell will use fats (triglycerides).
  • Finally, the cell will breakdown proteins to
    amino acids, which are used as an energy source.

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Metabolic Pathways
  • REGULATION
  • The levels of the products and substrates of
    energy metabolism are remarkably constant.
  • Cells regulate the enzymes of catabolism and
    anabolism to maintain a balance
    (metabolic homeostasis).

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Metabolic Pathways
  • Metabolic pathways work together to provide cell
    homeostasis.
  • Positive and negative feedback control whether a
    molecule of glucose is used in anabolic or
    catabolic pathways.
  • i.e. if there is no ATP, glucose is used for
    energy, if there is plenty of ATP, glucose is
    used to synthesize molecules .usually fat!

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Metabolic Pathways
  • The amount and balance of products a cell has is
    regulated by allosteric control of enzyme
    activities.
  • Control points use both positive and negative
    feedback mechanisms.

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Metabolic Pathways
  • The main control point in glycolysis is the
    enzyme phosphofructokinase.
  • Phosphofructokinase is inhibited by ATP
    and
    activated by ADP and AMP.

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Metabolic Pathways
  • The main control point of the Krebs cycle is the
    enzyme isocitrate dehydrogenase, which converts
    isocitrate to ?-ketoglutarate.
  • Isocitrate dehydrogenase is
    inhibited by NADH H and ATP
    and
    activated by NAD and ADP.

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Metabolic Pathways
  • Accumulation of isocitrate and citrate occurs,
    but is limited by the inhibitory effects of high
    ATP and NADH.
  • Citrate acts as an additional inhibitor to slow
    the fructose 6-phosphate reaction of glycolysis
    and also switches acetyl CoA to the synthesis of
    fatty acids.

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