Biochemistry, 4th Edition P64 docx

The standard reduction poten-tial difference describing electron transfer between two species, is related to the free energy change for the process by where n represents the number of el

The smooth outer membrane is about 30% to 40% lipid and 60% to 70% protein

and has a relatively high concentration of phosphatidylinositol The outer

mem-brane contains significant amounts of porin—a transmemmem-brane protein, rich in

-sheets, that forms large channels across the membrane, permitting free diffusion

of molecules with molecular weights of about 10,000 or less The outer membrane

plays a prominent role in maintaining the shape of the mitochondrion The inner

membrane is richly packed with proteins, which account for nearly 80% of its

weight; thus, its density is higher than that of the outer membrane The fatty acids

of inner membrane lipids are highly unsaturated Cardiolipin and

diphosphatidyl-glycerol (see Chapter 8) are abundant The inner membrane lacks cholesterol and

is quite impermeable to molecules and ions Species that must cross the

mitochon-drial inner membrane—ions, substrates, fatty acids for oxidation, and so on—are

carried by specific transport proteins in the membrane Notably, the inner

mem-brane is extensively folded (Figure 20.1) The folds, known as cristae, provide the

inner membrane with a large surface area in a small volume During periods of

ac-tive respiration, the inner membrane appears to shrink significantly, leaving a

com-paratively large intermembrane space

The Mitochondrial Matrix Contains the Enzymes of the TCA Cycle

The space inside the inner mitochondrial membrane is called the matrix, and it

contains most of the enzymes of the TCA cycle and fatty acid oxidation (An

im-portant exception, succinate dehydrogenase of the TCA cycle, is located in the

in-ner membrane itself.) In addition, mitochondria contain circular DNA molecules,

along with ribosomes and the enzymes required to synthesize proteins coded within

the mitochondrial genome Although some of the mitochondrial proteins are made

this way, most are encoded by nuclear DNA and synthesized by cytosolic ribosomes

20.2 What Are Reduction Potentials, and How Are They Used

to Account for Free Energy Changes in Redox Reactions?

On numerous occasions in earlier chapters, we have stressed that NADH and reduced

flavoproteins ([FADH2]) are forms of metabolic energy These reduced coenzymes

have a strong tendency to be oxidized—that is, to transfer electrons to other species

Matrix

Cristae

Intermembrane space

Inner membrane Outer membrane

FIGURE 20.1 (a) A drawing of a mitochondrion with components labeled (b) Tomography of a rat liver

mito-chondrion The tubular structures in red, yellow, green, purple, and aqua represent individual cristae formed from

the inner mitochondrial membrane.(b, Frey, T G., and Mannella, C A., 2000 The internal structure of mitochondria Trends in

Biochemical Sciences 25:319–324.)

594 Chapter 20 Electron Transport and Oxidative Phosphorylation

Oxidative phosphorylation converts the energy of electron transfer into the energy of phosphoryl transfer stored in the phosphoric anhydride bonds of ATP Just as the group transfer potential was used in Chapter 3 to quantitate the energy of

phospho-ryl transfer, the standard reduction potential, denoted by Ᏹo, quantitates the ten-dency of chemical species to be reduced or oxidized The standard reduction poten-tial difference describing electron transfer between two species,

is related to the free energy change for the process by

where n represents the number of electrons transferred; Ᏺ is Faraday’s constant,

96,485 J/V mol; and Ᏹo is the difference in reduction potentials between the donor and acceptor This relationship is straightforward, but it depends on a stan-dard of reference by which reduction potentials are defined

Standard Reduction Potentials Are Measured in Reaction Half-Cells

Standard reduction potentials are determined by measuring the voltages generated

in reaction half-cells (Figure 20.2) A half-cell consists of a solution containing 1 M

concentrations of both the oxidized and reduced forms of the substance whose re-duction potential is being measured and a simple electrode (Together, the oxidized

and reduced forms of the substance are referred to as a redox couple.) Such a sample half-cell is connected to a reference half-cell and electrode via a conductive

bridge (usually a salt-containing agar gel) A sensitive potentiometer (voltmeter) con-nects the two electrodes so that the electrical potential (voltage) between them can

be measured The reference half-cell normally contains 1 M Hin equilibrium with

H2gas at a pressure of 1 atm The H/H2reference half-cell is arbitrarily assigned a standard reduction potential of 0.0 V The standard reduction potentials of all other redox couples are defined relative to the H/H2reference half-cell on the basis of the sign and magnitude of the voltage (electromotive force, emf) registered on the po-tentiometer (Figure 20.2)

If electron flow between the electrodes is toward the sample half-cell, reduction occurs spontaneously in the sample half-cell and the reduction potential is said to

be positive If electron flow between the electrodes is away from the sample half-cell and toward the reference cell, the reduction potential is said to be negative because electron loss (oxidation) is occurring in the sample half-cell Strictly speaking, the standard reduction potential, Ᏹo, is the electromotive force generated at 25°C and

pH 7.0 by a sample half-cell (containing 1 M concentrations of the oxidized and

re-duced species) with respect to a reference half-cell (Note that the reduction po-tential of the hydrogen half-cell is pH-dependent The standard reduction

poten-tial, 0.0 V, assumes 1 M H The hydrogen half-cell measured at pH 7.0 has an Ᏹo

of0.421 V.)

Two Examples Figure 20.2a shows a sample/reference half-cell pair for measure-ment of the standard reduction potential of the acetaldehyde/ethanol couple Be-cause electrons flow toward the reference half-cell and away from the sample half-cell, the standard reduction potential is negative, specifically 0.197 V In contrast, the fumarate/succinate couple (Figure 20.2b) causes electrons to flow from the reference half-cell to the sample half-cell; that is, reduction occurs, and the reduction potential

is thus positive For each half-cell, a half-cell reaction describes the reaction taking

place For the fumarate/succinate half-cell coupled to a H/H2reference half-cell, the reaction occurring is indeed a reduction of fumarate:

Fumarate 2 H 2 e⎯⎯→ succinate Ᏹ  0.031 V (20.3)

Reduced donor Oxidized donor

Oxidized acceptor Reduced acceptor

Agar bridge

Electron

flow

Electron flow

Fumarate

Succinate

Agar bridge

(a) Ethanol acetaldehyde

Electron

flow

Electron flow Potentiometer –0.197 V

Ethanol

acetaldehyde

H +

Reference /1 atm H2

Sample:

acetaldehyde/

ethanol

H +

Reference /1 atm H2

Sample:

fumarate/

succinate

2

H +

(b) Fumarate succinate

H2 2

+0.031 V

ACTIVE FIGURE 20.2 Experimental

apparatus used to measure the standard reduction

potential of the indicated redox couples: (a) the

acetaldehyde/ethanol couple, (b) the fumarate/

succinate couple Test yourself on the concepts in

this figure at www.cengage.com/login.

However, the reaction occurring in the acetaldehyde/ethanol half-cell is the

oxida-tion of ethanol:

Ethanol⎯⎯→ acetaldehyde  2 H 2 e Ᏹo  0.197 V (20.4)

Ᏹoⴕ Values Can Be Used to Predict the Direction of Redox Reactions

Some typical half-cell reactions and their respective standard reduction potentials are

listed in Table 20.1 Whenever reactions of this type are tabulated, they are uniformly

written as reduction reactions, regardless of what occurs in the given half-cell The sign

of the standard reduction potential indicates which reaction really occurs when the

given half-cell is combined with the reference hydrogen half-cell Redox couples that

Cytochrome f (Fe3) e88n cytochrome f (Fe2) 0.365

Cytochrome a3(Fe3) e88n cytochrome a3(Fe2) 0.350

Cytochrome a(Fe3) e88n cytochrome a(Fe2) 0.290

Rieske Fe-S(Fe3) e88n Rieske Fe-S(Fe2) 0.280

Cytochrome c (Fe3) e88n cytochrome c (Fe2) 0.254

Cytochrome c1(Fe3) e88n cytochrome c1(Fe2) 0.220

UQH  H e88n UQH2(UQ coenzyme Q) 0.190

Cytochrome b H(Fe3) e88n cytochrome b H(Fe2) 0.050

Cytochrome b5(Fe3) e88n cytochrome b5(Fe2) 0.020

Cytochrome b L(Fe3) e88n cytochrome b L(Fe2) 0.100

Glutathione (oxidized) 2 H 2 e88n 2 glutathione (reduced) 0.230

Lipoic acid 2 H 2 e88n dihydrolipoic acid 0.290

1,3-Bisphosphoglycerate 2 H 2 e88n 0.290

glyceraldehyde-3-phosphate Pi

Lipoyl dehydrogenase [FAD] 2 H 2 e88n 0.340

lipoyl dehydrogenase [FADH2]

-Ketoglutarate  CO2 2 H 2 e88n isocitrate 0.380

Ferredoxin (spinach) (Fe3) e88n ferredoxin (spinach) (Fe2) 0.430

Succinate CO2 2 H 2 e88n -ketoglutarate  H2O 0.670

*Typical values for reduction of bound FAD in flavoproteins such as succinate dehydrogenase (see Bonomi, F., Pagani, S.,

Cerletti, P., and Giori, C., 1983 Modification of the thermodynamic properties of the electron-transferring groups in

mito-TABLE 20.1 Standard Reduction Potentials for Several Biological Reduction Half-Reactions

596 Chapter 20 Electron Transport and Oxidative Phosphorylation

have large positive reduction potentials have a strong tendency to accept electrons, and the oxidized form of such a couple (O2, for example) is a strong oxidizing agent Re-dox couples with large negative reduction potentials have a strong tendency to un-dergo oxidation (that is, donate electrons), and the reduced form of such a couple (NADPH, for example) is a strong reducing agent

ᏱoⴕValues Can Be Used to Analyze Energy Changes in Redox Reactions

The half-reactions and reduction potentials in Table 20.1 can be used to analyze en-ergy changes in redox reactions The oxidation of NADH to NADcan be coupled with the reduction of -ketoglutarate to isocitrate:

NAD isocitrate ⎯⎯→ NADH  H -ketoglutarate  CO2 (20.5) This is the isocitrate dehydrogenase reaction of the TCA cycle Writing the two half-cell reactions, we have

NAD 2 H 2 e⎯⎯→ NADH  H

-Ketoglutarate  CO2 2 H 2 e⎯⎯→ isocitrate

In a spontaneous reaction, electrons are donated by (flow away from) the half-reaction with the more negative reduction potential and are accepted by (flow to-ward) the half-reaction with the more positive reduction potential Thus, in the pre-sent case, isocitrate donates electrons and NADaccepts electrons The convention definesᏱo as

In the present case, isocitrate is the donor and NADthe acceptor, so we write

From Equation 20.2, we can now calculate G° as

G°  11.58 kJ/mol

Note that a reaction with a net positive Ᏹo yields a negative G°, indicating a

spontaneous reaction

The Reduction Potential Depends on Concentration

We have already noted that the standard free energy change for a reaction, G°, does not reflect the actual conditions in a cell, where reactants and products are not at

standard-state concentrations (1 M ) Equation 3.13 was introduced to permit

calcu-lations of actual free energy changes under non–standard-state conditions Similarly, standard reduction potentials for redox couples must be modified to account for the actual concentrations of the oxidized and reduced species For any redox couple,

the actual reduction potential is given by

Reduction potentials can also be quite sensitive to molecular environment The in-fluence of environment is especially important for flavins, such as FAD/FADH2 and FMN/FMNH2 These species are normally bound to their respective flavoproteins; the reduction potential of bound FAD, for example, can be very different from the value shown in Table 20.1 for the free FAD/FADH2couple of 0.219 V Problem 7 at the end of the chapter addresses this case

[ox]

[red]

20.3 How Is the Electron-Transport Chain Organized?

As we have seen, the metabolic energy from oxidation of food materials—sugars, fats,

and amino acids—is funneled into formation of reduced coenzymes (NADH) and

re-duced flavoproteins ([FADH2]) The electron-transport chain reoxidizes the

coen-zymes and channels the free energy obtained from these reactions into the creation

of a proton gradient This reoxidation process involves the removal of both protons

and electrons from the coenzymes Electrons move from NADH and [FADH2] to

mo-lecular oxygen, O2, which is the terminal acceptor of electrons in the chain The

re-oxidation of NADH,

NADH (reductant)  H O2(oxidant)⎯⎯→ NAD H2O (20.13)

involves the following half-reactions:

NAD 2 H 2 e⎯⎯→ NADH  H Ᏹo  0.32 V (20.14)

12O2 2 H 2 e⎯⎯→ H2O Ᏹo  0.816 V (20.15)

Here, half-reaction 20.15 is the electron acceptor and half-reaction 20.14 is the

elec-tron donor Then

and, according to Equation 20.2, the standard-state free energy change, G°, is

219 kJ/mol Molecules along the electron-transport chain have reduction

poten-tials between the values for the NAD/NADH couple and the oxygen/H2O couple,

so electrons move down the energy scale toward progressively more positive

reduc-tion potentials (Figure 20.3)

Although electrons move from more negative to more positive reduction

po-tentials in the electron-transport chain, it should be emphasized that the electron

0

+200

+400

+600

–200

–400

Complex I

Complex II

Complex III

Complex IV

(Fe/S)N4 (Fe/S)N3

Q10

b L

b H

c1

a3

FIGURE 20.3 Ᏹ o  and Ᏹ values for the components of the mitochondrial electron-transport chain Values indi-cated are consensus values for animal mitochondria Black bars represent Ᏹ ; red bars, Ᏹ.

598 Chapter 20 Electron Transport and Oxidative Phosphorylation

carriers do not operate in a simple linear sequence This will become evident when the individual components of the electron-transport chain are discussed in the following paragraphs

The Electron-Transport Chain Can Be Isolated in Four Complexes

The electron-transport chain involves several different molecular species, including:

1 Flavoproteins, which contain tightly bound FMN or FAD as prosthetic groups

and which may participate in one- or two-electron transfer events

2 Coenzyme Q, also called ubiquinone (and abbreviated CoQ or UQ) (see Figure

20.5), which can function in either one- or two-electron transfer reactions

3 Several cytochromes (proteins containing heme prosthetic groups [see Chapter

5], which function by carrying or transferring electrons), including cytochromes

b, c, c1, a, and a3 Cytochromes are one-electron transfer agents in which the heme iron is converted from Fe2to Fe3and back

4 A number of iron–sulfur proteins, which participate in one-electron transfers

in-volving the Fe2and Fe3states

5 Protein-bound copper, a one-electron transfer site that converts between Cu

and Cu2

All these intermediates except for cytochrome c are membrane associated (either

in the mitochondrial inner membrane of eukaryotes or in the plasma membrane of prokaryotes) Three types of proteins involved in this chain—flavoproteins,

cytochromes, and iron–sulfur proteins—possess electron-transferring prosthetic groups.

The components of the electron-transport chain can be purified from the mito-chondrial inner membrane Solubilization of the membranes containing the electron-transport chain results in the isolation of four distinct protein complexes, and the

com-plete chain can thus be considered to be composed of four parts: (I) NADH–coenzyme

reductase,and (IV) cytochrome c oxidase (Figure 20.4) Complex I accepts electrons

from NADH, serving as a link between glycolysis, the TCA cycle, fatty acid oxidation,

NADH–coenzyme Q

oxidoreductase

Succinate–coenzyme Q

oxidoreductase

Coenzyme Q–cytochrome c

oxidoreductase

Cytochrome c oxidase

Fatty acyl-CoA dehydrogenase

Electron-transferring flavoprotein, FAD, Fe-S centers

NADH dehydrogenase,

FMN, Fe-S centers

Succinate dehydrogenase,

FAD (covalent),

Fe-S centers,

b-type heme

UQ/UQH2 pool

Flavoprotein 3 Flavoprotein 1

Flavoprotein 2

Sn-glycerophosphate

dehydrogenase FAD, Fe-S centers

Cytochrome bc1 complex,

2 b-type hemes,

Rieske Fe-S center,

C-type heme (cyt c1)

Flavoprotein 4 Complex II

O2

H2O

Cytochrome c

1 2

Complex I

Complex III

Cytochrome aa3 complex,

2 a-type hemes,

Cu ions

Complex IV

FIGURE 20.4 An overview of the complexes and pathways in the mitochondrial electron-transport chain.(Adapted from Nicholls, D G., and Ferguson, S J., 2002

Bioener-getics 3 London: Academic Press.)

and the electron-transport chain Complex II includes succinate dehydrogenase and

thus forms a direct link between the TCA cycle and electron transport Complexes I

and II produce a common product, reduced coenzyme Q (UQH2), which is the

sub-strate for coenzyme Q–cytochrome c reductase (Complex III) As shown in Figure

20.4, there are two other ways to feed electrons to UQ: the electron-transferring

flavoprotein,which transfers electrons from the flavoprotein-linked step of fatty

acyl-CoA dehydrogenase, and sn-glycerophosphate dehydrogenase Complex III oxidizes

UQH2while reducing cytochrome c, which in turn is the substrate for Complex IV,

cytochrome c oxidase Complex IV is responsible for reducing molecular oxygen Each

of the complexes shown in Figure 20.4 is a large multisubunit complex embedded

within the inner mitochondrial membrane

Complex I Oxidizes NADH and Reduces Coenzyme Q

As its name implies, this complex transfers a pair of electrons from NADH to

cozyme Q , a small, hydrophobic, yellow compound Another common name for this

en-zyme complex is NADH dehydrogenase The complex (with an estimated mass of

980 kD) involves at least 45 polypeptide chains, one molecule of flavin

mononu-cleotide (FMN), and eight or nine Fe-S clusters, together containing a total of 20 to

26 iron atoms (Table 20.2) By virtue of its dependence on FMN, NADH–UQ

reduc-tase is a flavoprotein

Although the precise mechanism of the NADH–UQ reductase is unknown, the

first step involves binding of NADH to the enzyme on the matrix side of the inner

mitochondrial membrane and transfer of electrons from NADH to tightly bound

FMN:

The second step involves the transfer of electrons from the reduced [FMNH2]

to a series of Fe-S proteins, including both 2Fe-2S and 4Fe-4S clusters (see page

577) The versatile redox properties of the flavin group of FMN are important

here NADH is a two-electron donor, whereas the Fe-S proteins are one-electron

transfer agents The flavin of FMN has three redox states—the oxidized,

semi-quinone, and reduced states It can act as either a one-electron or a two-electron

transfer agent and may serve as a critical link between NADH and the Fe-S

proteins

The final step of the reaction involves the transfer of two electrons from iron–

sulfur clusters to coenzyme Q Coenzyme Q is a mobile electron carrier Its isoprenoid

NADH–UQ reductase 980 45 FMN NADH (matrix side)

Fe-S UQ (lipid core) Succinate–UQ reductase 140 4 FAD Succinate (matrix side)

Fe-S UQ (lipid core)

UQ–Cyt c reductase 250 9–10 Heme b L Cyt c (intermembrane

Heme b H space side)

Heme c1 Fe-S

Cyt a Cytochrome c oxidase 162 13 Heme a Cyt c (intermembrane

Heme a3 space side) CuA

CuB

TABLE 20.2 Protein Complexes of the Mitochondrial Electron-Transport Chain

600 Chapter 20 Electron Transport and Oxidative Phosphorylation

tail makes it highly hydrophobic, and it diffuses freely in the hydrophobic core of the inner mitochondrial membrane As a result, it shuttles electrons from Complexes I and II to Complex III The redox cycle of UQ is shown in Figure 20.5 The structural and functional organization of Complex I is shown in Figure 20.6

Complex I Transports Protons from the Matrix to the Cytosol The oxidation of one NADH and the reduction of one UQ by NADH–UQ reductase results in the net

O •

OH

CH3 R

+

OH

H3CO

H3CO

CH3 R OH

Coenzyme Q, oxidized form

O

O

H3CO

H3CO

CH3 (CH2 CH C CH2)10 H

CH3O

CH3O

CH3

(a)

Semiquinone intermediate (QH•)

Coenzyme Q, reduced form (QH 2 , ubiquinol) (Q, ubiquinone)

(b)

FIGURE 20.5 (a) The three oxidation states of coenzyme Q (b) A space-filling

model of coenzyme Q.

HUMAN BIOCHEMISTRY

Solving a Medical Mystery Revolutionized Our Treatment of Parkinson’s Disease

A tragedy among illegal drug users was the impetus for a

revolu-tionary treatment of Parkinson’s disease In 1982, several

mysteri-ous cases of paralysis came to light in southern California The

vic-tims, some of them teenagers, were frozen like living statues,

unable to talk or move The case was baffling at first, but it was

soon traced to a batch of synthetic heroin that contained MPTP

(1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) as a contaminant

MPTP is rapidly converted in the brain to MPP

(1-methyl-4-phenylpyridine) by the enzyme monoamine oxidase B MPPis a potent inhibitor of mitochondrial Complex I (NADH–UQ

reduc-tase), and it acts preferentially in the substantia nigra, an area of

the brain that is essential to movement and also the region of the brain that deteriorates slowly in Parkinson’s disease

Parkinson’s disease results from the inability of the brain to produce sufficient quantities of dopamine, a neurotransmitter Neurologist J William Langston, asked to consult on the treat-ment of some of these patients, recognized that the symptoms of this drug-induced disorder were in fact similar to those of parkin-sonism He began treatment of the patients with L-dopa, which is decarboxylated in the brain to produce dopamine The treated pa-tients immediately regained movement Langston then took a bold step He implanted fetal brain tissue into the brains of several

of the affected patients, prompting substantial recovery from the Parkinson-like symptoms Langston’s innovation sparked a revolu-tion in the use of tissue implantarevolu-tion for the treatment of neu-rodegenerative diseases

Other toxins may cause similar effects in neural tissue Timothy Greenmyre at Emory University has shown that rats exposed to the pesticide rotenone (see Figure 20.27) over a period of weeks expe-rience a gradual loss of function in dopaminergic neurons and then develop symptoms of parkinsonism, including limb tremors and rigidity This finding supports earlier research that links long-term pesticide exposure to Parkinson’s disease

Cell death

in substantia nigra

Monoamine oxidase B

H H

H CH3

H

H H

CH3

+

transport of protons from the matrix side to the cytosolic side of the inner

mem-brane The cytosolic side, where Haccumulates, is referred to as the P (for

posi-tive) face; similarly, the matrix side is the N (for negaposi-tive) face Some of the energy

liberated by the flow of electrons through this complex is used in a coupled process

to drive the transport of protons across the membrane (This is an example of

ac-tive transport, a phenomenon examined in detail in Chapter 9.) Available

experi-mental evidence suggests a stoichiometry of four Htransported per two electrons

passed from NADH to UQ

Complex II Oxidizes Succinate and Reduces Coenzyme Q

Complex II is perhaps better known by its other name—succinate dehydrogenase,

the only TCA cycle enzyme that is an integral membrane protein in the inner

mitochondrial membrane This complex (Figure 20.7) has a mass of 124 kD and

is composed of two hydrophilic subunits, a flavoprotein (Fp, 68 kD) and an

iron–sulfur protein (Ip, 29 kD), and two hydrophobic, membrane-anchored

sub-units (15 kD and 11 kD), which contain one heme b and provide the binding site

for UQ Fp contains an FAD covalently bound to a His residue (see Figure 19.12),

and Ip contains three Fe-S centers: a 4Fe-4S cluster, a 3Fe-4S cluster, and a 2Fe-2S

cluster When succinate is converted to fumarate in the TCA cycle, concomitant

re-duction of bound FAD to FADH occurs in succinate dehydrogenase This FADH

NADH+ + H+

2 H+

2 H+

2 H+

(a)

2 H+

2 H+

FMN FMNH2

2 Fe-S

centers

2 Fe-S centers UQ

UQH2

NAD+

2

2

(b)

12 13

7/11/14 8/10

(c)

N1a

N6a

N3

FMN

N1b

N6b

N4

N5

N7

N2

ACTIVE FIGURE 20.6 (a) Structural organization of mammalian Complex I, based on electron

microscopy, showing functional relationships within the L-shaped complex Electron flow from NADH to UQH2in the membrane pool is indicated (b) Structure of the hydrophilic domain of Complex I from Thermus

thermophilus is shown on a model of the membrane-associated complex (pdb id  2FUG).The locations of

individual subunits are indicated (c) Arrangement of the redox centers in Complex I The various iron–sulfur

centers of Complex I are designated by capital N (Part a adapted from Janssen, R J., Nijtmans, L G., van den Heuvel, L P.,

and Smeitink, J A., 2006 Mitochondrial complex I: Structure, function, and pathology Journal of Inherited Metabolic Diseases

29:499–515; and parts b and c adapted from Figure 1 of Sazanov, L., and Hinchliffe, P., 2006 Structure of the hydrophilic

domain of respiratory Complex I from Thermus thermophilus Science 311:1430–1436.)Test yourself on the concepts in this figure at www.cengage.com/login.

602 Chapter 20 Electron Transport and Oxidative Phosphorylation

transfers its electrons immediately to Fe-S centers, which pass them on to UQ Elec-tron flow from succinate to UQ ,

Net rxn: Succinate  UQ ⎯⎯→ fumarate  UQH2 Ᏹo  0.029 V (20.20) yields a net reduction potential of 0.029 V (Note that the first half-reaction is

writ-ten in the direction of the eflow As always, Ᏹo is calculated according to Equa-tion 20.8.) The small free energy change of this reacEqua-tion does not contribute to the transport of protons across the inner mitochondrial membrane

This is a crucial point because (as we will see) proton transport is coupled with ATP synthesis Oxidation of one FADH2in the electron-transport chain results in synthesis

of approximately two molecules of ATP, compared with the approximately three ATPs produced by the oxidation of one NADH Other flavoproteins can also supply

(a)

UQ UQH2

Intermembrane space

Matrix

Complex III

Complex II

2Fe 2 +

2Fe3+

FAD

Succinate Fumarate

FADH2

2 H+

3Fe4S 4Fe4S 2Fe2S Heme b

Heme b

Fe-S centers

FAD

ACTIVE FIGURE 20.7 (a) A scheme for

electron flow in Complex II Oxidation of succinate

occurs with reduction of [FAD] Electrons are then

passed to Fe-S centers and then to coenzyme Q (UQ).

Proton transport does not occur in this complex (b) The

structure of Complex II from pig heart (pdb id  1ZOY).

(c) The arrangement of redox centers Electron flow is

from bottom to top Test yourself on the concepts in

this figure at www.cengage.com/login.