Components of the Electron-Transport Chain

The electron-transport chain, or respiratory chain in mitochondria forms the means by which electrons, from the reduced electron carriers of intermediary metabolism, are channeled to oxygen and protons to yield H2O. The main components of the chain are as follows. 

The electron-transport reaction for the NAD+/NADH conjugate redox pair is  

NADH has a characteristic light absorbance maximum at a wavelength of 340 nm, which is absent in NAD+. Hence electron transport involving NAD+/NADH can be monitored by measuring the change in absorbance of a sample at 340 nm in a spectrophotometer. 

NADH is oxidized by the electron-transport chain inside mitochondria. The inner mitochondrial membrane is not permeable to nucleotides. How can NADH generated in the cytoplasm (for example during glycolysis) participate in the electron-transport chain  

The reducing equivalents of cytosolic NADH are transferred into mitochondria via shuttle mechanisms, such as the one involving aspartate and malate, shown in Fig. 11-19 (page 333). The net effect of this shuttle is the transport of NADH into the mitochondrion. 

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Although electrons move from more negative to more positive reduction potentials in the electron transport chain, it should be emphasized that the electron 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. 

P. Mitchell (Nobel Prize for Chemistry, 1978) explained these facts by his chemiosmotic theory. This theory is based on the ordering of successive oxidation processes into reaction sequences called loops. Each loop consists of two basic processes, one of which is oriented in the direction away from the matrix surface of the internal membrane into the intracristal space and connected with the transfer of electrons together with protons. The second process is oriented in the opposite direction and is connected with the transfer of electrons alone. Figure 6.27 depicts the first Mitchell loop, whose first step involves reduction of NAD+ (the oxidized form of nicotinamide adenosine dinucleotide) by the carbonaceous substrate, SH2. In this process, two electrons and two protons are transferred from the matrix space. The protons are accumulated in the intracristal space, while electrons are transferred in the opposite direction by the reduction of the oxidized form of the Fe-S protein. This reduces a further component of the electron transport chain on the matrix side of the membrane and the process is repeated. The final process is the reduction of molecular oxygen with the reduced form of cytochrome oxidase. It would appear that this reaction sequence includes not only loops but also a proton pump, i.e. an enzymatic system that can employ the energy of the redox step in the electron transfer chain for translocation of protons from the matrix space into the intracristal space. 

The spatial separation between the components of the electron transport chain and the site of ATP synthesis was incompatible with simple interpretations of the chemical coupling hypothesis. In 1964, Paul Boyer suggested that conformational changes in components in the electron transport system consequent to electron transfer might be coupled to ATP formation, the conformational coupling hypothesis. No evidence for direct association has been forthcoming but conformational changes in the subunits of the FI particle are now included in the current mechanism for oxidative phosphorylation. 

Mitochondrial diseases are often expressed as neuropathies and myopathies because brain and muscle are highly dependent on oxidative phosphorylation. Mitochondrial genes code for some of the components of the electron transport chain and oxidative phosphorylation, as well as some mitochondrial tRNA molecules. 

Structure of the mitochondrion The components of the electron transport chain are located in the inner membrane. Although the outer membrane contains special pores, making it freely perme-... 

A second group of electron carriers in mitochondrial membranes are the iron-sulfur [Fe-S] clusters which are also bound to proteins. Iron-sulfur proteins release Fe3+ or Fe2+ plus H2S when acidified. The "inorganic clusters" bound into the proteins have characteristic compositions such as Fe2S2 and Fe4S4. The sulfur atoms of the clusters can be regarded as sulfide ions bound to the iron ions. The iron atoms are also attached to other sulfur atoms from cysteine side chains from the proteins. The Fe-S proteins are often tightly associated with other components of the electron transport chain. For example, the flavoproteins Flavin 1, Flavin 2, and Flavin 3 shown in Fig. 10-5 all contain Fe-S clusters as does the Q-cytochrome b complex. All of these Fe-S clusters seem to be one-electron carriers. 

Components of the electron transport chain in bacteria have been shown to include b- and c-type cytochromes, ubiquinone (fat-soluble substitute quinone, also found in mitochondria), ferredox (an enzyme containing nonheme iron, bound to sulfide, and having the lowest potential of any known electron-canying enzyme) and one or more flavin enzymes. Of these a cytochrome (in some bacteria, with absorption maximum at 423.5 micrometers, probably Cj) has been shown to be closely associated with the initial photoact. Some investigators were able to demonstrate, in chromatium, the oxidation of the cytochrome at liquid nitrogen temperatures, due to illumination of the chlorophyll. At the very least this implies that the two are bound very closely and no collisions are needed for electron transfers to occur. 

TPhe properties of Cytochrome c, a vital component of the electron transport chain, have been studied widely (1). The reduction potential (E° ) of Cytochrome c has been measured by a variety of techniques and under different conditions, namely in the presence of various salts, as a function of temperature, bound to phospholipid vesicles and in the presence of other components of the electron transport chain. These studies have yielded a wide range of values for E° vs. the standard... 

Fig. 5.2. Possible metabolic pathways in facultative anaerobic mitochondria. Shaded boxes show components of the electron-transport chain used during hypoxia, open boxes are components used during aerobiosis, and the hatched boxes (complex I and ATP-synthase) are components used under aerobic as well as anaerobic conditions. ASCT acetate succinate CoA-transferase, C cytochrome c, Cl, CIII and CIV complexes I, III and IV of the respiratory chain, CITR citrate, ECR enoyl-CoA reductase (such as present in Ascaris suum), ETF electron-transfer flavoprotein, ETF RQ OR electron-transfer flavoproteimrhodoquinone oxidoreductase, FRD fumarate reductase, FUM fumarate, MAE malate, OXAC oxaloacetate, PYR pyruvate, RQ rhodoquinone, SDH succinate dehydrogenase, SUCC succinate, Succ-CoA succinyl-CoA, TER trans-2-enoyl-CoA reductase (such as present in E. gracilis), UQ ubiquinone...

Studied by redox potentiometry, the components of the electron-transport chain have been assigned the E0 values shown below ... 

In these mechanisms, electron transport through the various components of the electron-transport chain leads to structural changes in the proteins of the chain, such that changes in their pKa values (Chap. 3) of ionizable amino acid residues occurs. For example, an increase in the pKa of a residue adjacent to the matrix side of the membrane would lead to proton uptake from the matrix, while a decrease in the pKa of a residue adjacent to the intermembranous side of the membrane could lead to release of a proton. The net effect of these processes is the transfer of protons from the matrix to the intermembranous side of the membrane. However, proton-pump mechanisms do not make strong predictions of the H+/e stoichiometries. 

In an experiment, a suspension of mitochondria provided with adequate oxygen and pyruvate, but no ADP, consumed oxygen at a very low rate. The relative states of reduction of components of the electron-transport chain were determined NAD, 100 percent coenzyme Q, 40 percent cytochrome b, 38 percent cytochrome c, 14 percent and cytochrome a, 0 percent. How could these data allow definition of the sites of oxidative phosphorylation ... 

Biochemists use the changes in the ultraviolet-visible absorption spectra of the individual components of the electron transport chain to follow the... 

Because Photosystem II tends to occur in the grana and Photosystem I in the stromal lamellae, the intervening components of the electron transport chain need to diffuse in the lamellar membranes to link the two photosystems. We can examine such diffusion using the time-distance relationship derived in Chapter 1 (Eq. 1.6 x je = 4Djtife). In particular, the diffusion coefficient for plastocyanin in a membrane can be about 3 x 10 12 m2 s-1 and about the same in the lumen of the thylakoids, unless diffusion of plastocyanin is physically restricted in the lumen by the appres-sion of the membranes (Haehnel, 1984). For such a D , in 3 x 10-4 s (the time for electron transfer from the Cyt b(f complex to P ), plastocyanin could diffuse about [(4)(3 x 10-12 m2 s-1) (3 x 10-4 s)]1/2 or 60 nm, indicating that this complex in the lamellae probably occurs in relatively close proximity to its electron acceptor, Photosystem I. Plastoquinone is smaller and hence would diffuse more readily than plastocyanin, and a longer time (2 x 10-3 s) is apparently necessary to move electrons from Photosystem II to the Cyt b(f complex hence, these two components can be separated by greater distances than are the Cyt b f complex and Photosystem I. 

Figure 3. Diagram of a section through the cell wall of Acidithiobacillus ferrooxidans modified from Blake et al. (1992) showing the relationship between iron oxidation and pyrite dissolution. OM =outer membrane, P = periplasm, IM = inner or (cytoplasmic) membrane, cty = cytochrome, pmf = proton motive force. Passage of a proton (driven by proton motive force) into the cell catalyzes the conversion of ADP to ATP. Ferrous iron binds to a component of the electron transport chain, probably a cytochrome c, and is oxidized. The electrons are passed to a terminal reductase where they are combined with O2 and to form water, preventing acidification of the cytoplasm. Ferric iron can either oxidize pyrite (e.g. within the ore body) or form nanocrystalline iron oxyhydroxide minerals (often in surrounding groundwater or streams).

Agents that act on components of the electron transport chain... 

C. If cytochrome c cannot function, all components of the electron transport chain between it and 02 remain in the oxidized state, and the components of the chain before cytochrome c are reduced. The electron transport chain will not function, 02 will not be consumed, a proton gradient will not be generated, and ATP will not he produced. NADH will not he oxidized, so the TCA cycle will slow down and, therefore, C02 production will decrease. 

The arrangement of components of the electron transport chain was deduced experimentally. Since electrons pass only from electronegative systems to electropositive systems, the carriers react according to their standard redox potential (Table 14-2). Specific inhibitors and spectroscopic analysis of respiratory chain components are used to identify the reduced and oxidized forms and also aid in the determination of the sequence of carriers. 

Standard Oxidation-Reduction Potential (E" ) of Components of the Electron-Transport Chain... 

The components of the electron transport chain have various cofactors. Complex I, NADH dehydrogenase, contains a flavin cofactor and iron sulfur centers, whereas complex ID, cytochrome reductase, contains cytochromes b and Cj. Complex IV, cytochrome oxidase, which transfers electrons to oxygen, contains copper ions as well as cytochromes a and a. The general structure of the cytochrome cofactors is shown in Figure 16-2. Each of the cytochromes has a heme cofactor but they vary slightly. The b-type cytochromes have protoporphyrin IX, which is identical to the heme in hemoglobin. The c-type cytochromes are covalently bound to cysteine residue 10 in the protein. The a-type... 

Ostrander, D. B., et al. 2001. Lack of mitochondrial anionic phospholipids causes an inhibition of translation of protein components of the electron transport chain a yeast genetic model system for the study of anionic phospholipid function in mitochondria. J. Biol. Chem. 276 25262-25272. 

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