Mitochondrial electron transport and oxidative phosphorylation

What Is the P/O Ratio for Mitochondrial Electron Transport and Oxidative Phosphorylation ... 

Hatefi Y. The mitochondrial electron transport and oxidative phosphorylation system. Annu Rev Biochem 54 1015-1069, 1985. 

Hatefi, Y. The Mitochondrial Electron Transport and Oxidative Phosphorylation System. Ann. Rev. Biochem. 54, 1015-1069 (1985). [A review that emphasizes the coupling between oxidation and phosphorylation.]... 

ATP results from the movement of approximately three protons from the cytosol into the matrix through Fg. Altogether this means that approximately four protons are transported into the matrix per ATP synthesized. Thus, approximately one-fourth of the energy derived from the respiratory chain (electron transport and oxidative phosphorylation) is expended as the electrochemical energy devoted to mitochondrial ATP-ADP transport. 

Allelopathic inhibition of mineral uptake results from alteration of cellular membrane functions in plant roots. Evidence that allelochemicals alter mineral absorption comes from studies showing changes in mineral concentration in plants that were grown in association with other plants, with debris from other plants, with leachates from other plants, or with specific allelochemicals. More conclusive experiments have shown that specific allelochemicals (phenolic acids and flavonoids) inhibit mineral absorption by excised plant roots. The physiological mechanism of action of these allelochemicals involves the disruption of normal membrane functions in plant cells. These allelochemicals can depolarize the electrical potential difference across membranes, a primary driving force for active absorption of mineral ions. Allelochemicals can also decrease the ATP content of cells by inhibiting electron transport and oxidative phosphorylation, which are two functions of mitochondrial membranes. In addition, allelochemicals can alter the permeability of membranes to mineral ions. Thus, lipophilic allelochemicals can alter mineral absorption by several mechanisms as the chemicals partition into or move through cellular membranes. Which mechanism predominates may depend upon the particular allelochemical, its concentration, and environmental conditions (especially pH). 

Mitochondria, which are cytoplasmic organelles involved in cellular respiration, have their own chromosome, which contains 16,569 DNA base pairs (bp) arranged in a drcalar molecule. This DNA encodes 13 proteins that are subunits of complexes in the electron transport and oxidative phosphorylation processes (see Section 1, Chapter 13). In addition, mitochondrial DNA encodes 22 transfer RNAs and two ribosomal RNAs. 

The first recognition of mitochondrial disease came in 1959. A 30-year old Swedish woman was found to have an extremely high basal metabolic rate (180% of normal), a high caloric intake (>3000 kcal / day), and an enormous perspiration rate. She had developed these symptoms at age seven. Examination of her mitochondria revealed that electron transport and oxidative phosphorylation were very loosely coupled. This explains the symptoms. However, the disease (Luft disease) is extremely rare and the underlying cause isn t known.1 Its recognition did focus attention on mitochondria, and by 1988,... 

Mitochondrial phospholipids play a role in electron transport and oxidative phosphorylation, two mechanisms by which the cell accomplishes the final oxidation of the metabolites to produce energy. Phospholipids also are linked in the transport of ions, especially sodium, across membranes. 

In eukaryotes, electron transport and oxidative phosphorylation occur in the inner membrane of mitochondria. These processes re-oxidize the NADH and FADH2 that arise from the citric acid cycle (located in the mitochondrial matrix Topic L2), glycolysis (located in the cytoplasm Topic J3) and fatty acid oxidation (located in the mitochondrial matrix Topic K2) and trap the energy released as ATP. Oxidative phosphorylation is by far the major source of ATP in the cell. In prokaryotes, the components of electron transport and oxidative phosphorylation are located in the plasma membrane (see Topic Al). 

A steady flow of metabolites both in and out of the mitochondrial matrix space is necessary for mitochondria to perform functions which involve the participation of enzymes inside the membrane permeability barrier. These functions include oxidative phosphorylation and therefore O2, ADP, phosphate and electron-rich substrates such as pyruvate, fatty acids and ketone bodies must enter the mitochondria, and the products, HjO, CO2 and ATP must leave. Although Oj, HjO and CO2 are permeable to the inner mitochondrial membrane [1,2], most metabolites are not, because of their highly hydrophiUc nature. The outer mitochondrial membrane does not present a significant barrier to hydrophilic metabolites because of the presence of large unregulated channels composed of the membrane protein, porin [3]. The inner mitochondrial membrane has a much larger surface area [4] than the outer membrane and a much higher ratio of protein to lipid [5]. It is composed not only of proteins involved in electron transport and oxidative phosphorylation but also specialized proteins which facilitate, and in many cases provide, directionality to the transport of metabolites [6]. 

Actively respiring fungal cells possess a distinct mitochondrion, which has been described as the power-house of the cell (Fig. 4.2). The enzymes of the tricarboxylic acid cycle (Kreb s cycle) are located in the matrix of the mitochondrion, while electron transport and oxidative phosphorylation occur in the mitochondrial inner membrane. The outer membrane contains enzymes involved in lipid biosynthesis. The mitochondrion is a semiindependent organelle as it possesses its own DNA and is capable of producing its own proteins on its own ribosomes, which are referred to as mitoribosomes. 

The belief that alcoholics are more susceptible to the toxicity of 2,4-DNP during occupational exposure (Perkins 1919) may indicate an interaction with ethanol (and possibly other alcohols) or it may simply be a function of the compromised physiological state of alcoholics. 2,4-DNP appears to markedly increase the rate of ethanol metabolism in rat liver slices by 100-160% (Videla and Israel 1970) and in rats in vivo by 20-30% (Israel et al. 1970). Because 2,4-DNP uncouples mitochondrial electron transport from oxidative phosphorylation, the oxidation of NADH to NAD is accelerated in the mitochondria. Reoxidation of NADH rather than the activity of alcohol dehydrogenase is the rate-limiting step in the metabolism of ethanol, and, therefore, the metabolic effect of 2,4-DNP enhances the clearance of ethanol (Eriksson et al. 1974). Because 2,4-DNP is known to augment the rate of respiration and perspiration, 2.7-8.2% of the initial dose of ethanol was also eliminated by expiration and cutaneous evaporation in the rat (Israel et al. 1970). 

Although there is a 5-fold difference between the sizes of the mitochondrial genomes of yeast (84 kb) and mammals (16 kb), the number of proteins synthesized within mitochondria is similar. Proteins produced by mammalian mitochondria are those involved in electron-transport and oxidative-phosphorylation systems. These include cytochrome b, three subunits of cytochrome oxidase, one subunit of ATPase, and six subunits of NADH dehydrogenase. Apart from these differences, protein synthesis in mitochondria follows the same steps and mechanisms as those in the cytoplasm. 

Mitochondria (singular = mitochondrion) are the so-called "power plants" of eukaryotic cells because they are the major source of energy for these cells under aerobic conditions (when oxygen is present). Mitochondria are the sites where complex processes involved in energy generation (such as electron transport and oxidative phosphorylation) are found. The product of mitochondrial action is chemical energy stored in the form of adenosine triphosphate, more commonly called ATP. 

Chemiosmotic coupling is the mechanism most widely used to explain the manner in which electron transport and oxidative phosphorylation are coupled to one another. In this mechanism, the proton gradient is directly linked to the phosphorylation process. The way in which the proton gradient leads to the production of ATP depends on ion channels through the inner mitochondrial membrane these channels are a feature of the structure of ATP synthase. Protons flow back into the matrix through proton channels in the Fq part of the ATP synthase. The flow of protons is accompanied by formation of ATP, which occurs in the Fj unit. 

Electron transport and oxidative phosphorylation are different processes. Electron transport requires the respiratory complexes of the inner mitochondrial membrane, whereas oxidative phosphorylation requires ATP synthase, also located on the inner mitochondrial membrane. Electron transport can take place in the absence of oxidative phosphorylation. 

The two pathways have in common the involvement of acetyl-CoA and thioesters, and each round of breakdown or synthesis involves two-carbon units. The differences are many malonyl-CoA is involved in biosynthesis, not in breakdown thioesters involve CoA in breakdown and involve acyl carrier proteins in biosynthesis biosynthesis occurs in the cytosol, but breakdown occurs in the mitochondrial matrix breakdown is an oxidative process that requires NAD and FAD and produces ATP by electron transport and oxidative phosphorylation, whereas biosynthesis is a reductive process that requires NADPH and ATP. 

Acidic aromatic compounds like 2,4-dinitrophenol (DNP) act as uncouplers of electron transport and oxidative phosphorylation because they carry protons across the inner mitochondrial membrane, disrupting the proton gradient. The structure of the neutral, pro-tonated form of DNP is shown in Figure 18.1. 

Different types of organisms such as daphnia, mussels, algae, and fish have been extensively incorporated in toxicity tests for water assessment systems [65], Most of these assays are developed as test systems with few as laboratory-based sensor systems. Membranes with their active enzyme system have also been implemented in the development of toxicity kits and sensors. An example is the MitoScan Kit (Harvard BioScience, Inc., Holliston, MA), which uses fragmented inner mitochondrial membrane vesicles isolated from beef heart (EPA, 2005 [9]). The submito-chondrial particles contain complexes of enzymes responsible for electron transport and oxidative phosphorylation. When specific toxins are in the sample, the enzyme reactions are slowed or inhibited, and these are monitored spectophotometrically at 340 mn. This is still in a bioassay test kit format but may be developed to optical sensor system. 

Figure 5.1. Summary of the events during respiration of triacylglycerols, carbohydrates, and proteins. PDC, Pyruvate dehydrogenase complex TCA, tricarboxylic acid or Krebs cycle ETC, mitochondrial electron transport OP, oxidative phosphorylation.

The inner membrane of the mitochondrion accounts for 80-95% of the protein found in mitochondrial membranes and over 90% of the lipid. It is the site of the respiratory chain and the synthesis of ATP. It is this membrane, in conjunction with studies on transport through the plasma membrane, that has contributed most forcefully both to the viewpoint of the anisotropic organization of membrane structural elements and of biochemical events carried out by or in membranes. As regards mitochondria, the interaction of the inner membrane components in carrying out electron transport and oxidative phosphorylation is the focal investigative question both for mitochondrial function and for the organization of vectorial events in general. 

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