Effect of substrates on reconstitution of the mitochondrial respiratory chain under various conditions

The reconstitution of NADH oxidase, succinate oxidase and the complete respiratory chain from NADH: cytochrome c oxidoreductase, succinate: coenzyme Q oxidoreductase, cytochrome oxidase and cytochrome c was studied under various conditions. The formation of these multi-enzyme systems was prevented by cobra venom phospholipase. Reconstitution was possible in the presence of cobra venom only if the medium contained NADH (or succinate) and O₂. Bovine serum albumin prevented the formation of NADH oxidase at low temperatures but hardly affected this process at 38–42°. It also increased the thermal stability of the reconstituted system. Reconstitution of NADH oxidase did not occur in the presence of potassium oleate, and bovine serum albumin completely eliminated the effect of the latter. However, bovine serum albumin did not protect the respiratory chain from the action of phospholipase. Therefore, the presence of NADH was necessary for the reconstitution of NADH oxidase at 38° in a medium containing bovine serum albumin and cobra venom.

Thus, the natural agents indicated above have a substantial effect on the reconstitution of the respiratory chain. Reconstitution becomes possible with a strictly definite ratio between the effects of different external factors. A special part in the formation of the respiratory chain is played by substrates having a specific influence on its structure.     

Formation and degradation of mitochondria in the cell

Summary Prolonged deaeration ofSaccharomyces cerevisiae cells results in degenerative changes in mitochondria which can be revealed when measuring the enzymic activities of the respiratory chain in isolated organelles and by electron microscope examination of the cells. The same changes are observed after a 3-h incubation of the cells with cyanide or carbonyl cyanide, m-chlorophenyl hydrazone in aerobic conditions. These results suggest the important role of oxidative phosphorylation in the maintenance of the integrity of mitochondria in the cell.The sensitivity of yeast mitochondria to anaerobiosis and cyanide changes as the culture grows. Mitochondria are especially labile during the early exponential growth phase when their respiratory system and structure are not fully formed. Possible reasons for and the mechanism of degradation of mitochondriain vivo are discussed.     

Cytochemical and biochemical determination of acid phosphatase activity in yeasts]

Optimal conditions of the cytochemical assay for acid phosphatase in protoplasts and whole cells of S. cerevisiae have been described. Dimethyl sulfoxide was used to increase the permeability of the yeast cell envelope. In the yeast cells, grown up to the end of the exponential phase, acid phosphatase is shown to be located mainly in the central vacuole and on the cell envelope surface. A considerable activity of acid phosphatase is demonstrable on the surface of the plasma membrane and within adjacent vesicles that represent, presumably, part of the endoplasmic reticulum. Acid phosphatase can be considered as a marker enzyme for yeast cell vacuoles.     

Formation and functioning of fused cholesterol side-chain cleavage enzymes

We studied the properties of various fused combinations of the components of the mitochondrial cholesterol side-chain cleavage system including cytochrome P450scc, adrenodoxin (Adx), and adrenodoxin reductase (AdR). When recombinant DNAs encoding these constructs were expressed in Escherichia coli, both cholesterol side-chain cleavage activity and sensitivity to intracellular proteolysis of the three-component fusions depended on the species of origin and the arrangement of the constituents. To understand the assembly of the catalytic domains in the fused molecules, we analyzed the catalytic properties of three two-component fusions: P450scc-Adx, Adx-P450scc, and AdR-Adx. We examined the ability of each fusion to carry out the side-chain cleavage reaction in the presence of the corresponding missing component of the whole system and examined the dependence of this reaction on the presence of exogenously added individual components of the double fusions. This analysis indicated that the active centers in the double fusions are either unable to interact or are misfolded; in some cases they were inaccessible to exogenous partners. Our data suggest that when fusion proteins containing P450scc, Adx, and AdR undergo protein folding, the corresponding catalytic domains are not formed independently of each other. Thus, the correct folding and catalytic activity of each domain is determined interactively and not independently.     

Comparative study of topogenesis of cytochrome P450scc (CYP11A1) and its hybrids with adrenodoxin expressed in <Emphasis Type="Italic">Escherichia coli</Emphasis> cells

Hybrid proteins consisting of the mature form of cytochrome P450scc (mP) and adrenodoxin (Ad), attached to either the NH2- or COOH-terminus (Ad-mP and mP-Ad, respectively), were expressed in E. coli. Spectral and catalytic properties of P450scc were studied using the membrane fraction of E. coli cells. It has been shown that the Ad amino acid sequence attached to the termini of the P450scc-domain neither affects the insertion of a hybrid protein into the cytoplasmic membrane nor influences its heme binding ability. The results suggest that Ad attached to the NH2-terminus does not markedly affect the folding of the P450scc-domain, but cholesterol hydroxylase/lyase activity of the Ad-mP hybrid was found to be much lower than that of the native P450scc enzyme. The modification of the COOH-terminus does not alter the specific P450scc activity, but results in a dramatic increase in the amount of hybrid protein with incorrectly folded P450scc domain.     

In vitro assembly of cytochrome oxidase from separately accumulated subunits: a reconsideration

Trehalase activity in a yeast protoplast lysate increased 40-times upon preincubation with cAMP and ATP. The activity present without the preincubation could all be sedimentated at 8000 × g, for 10 min confirming the previously reported localization of the active trehalase (Ta) in the vacuoles. Virtually all the trehalase activity newly formed upon the preincubation, however, was found in the soluble fraction, indicating that a trehelase-zymogen (Tz) is located in the cytosol. This raises the possibility that a cAMP-dependent phosphorylation not only transforms Tz to Ta but also initiates the transfer of trehalase from the cytosol into the vacuoles.     

Glucose repression and autolysis ofSaccharomyces cerevisiae cells: alterations in the cytochemical localization of acid phosphatase

Summary Allerations in the localization of acid phosphatase inSaccharomyces cerevisiae during glucose repression and during autolysis have been studied. Cell morphology becomes distinctly changed after only 2 h in the presence of high glucose concentration while after 3 h of glucose repression the majority of the mitochondirial structures resemble promitochondria. Yeast cells repressed for 6 h contain almost completely degraded mitochondrial structures and numerous lipid droplets in the central vacuole and cytoplasm. Destruction of mitochondria is accompanied by the accumulation of acid phosphatase in these organelles and in the cytoplasm whereas its activity in the central vacuole is lowered, most probably because of the leakage of the enzyme into the cytoplasm.No preferential breakdown of mitochondria is observed during autolysis. On the contrary, mitochondria are apparently the last to be degraded. Digestion of cytoplasmic regions and membranous elements occurs intravacuolarly after sequestration by protrusions of the central vacuole which are formed at the initial stages of autolysis. Acid phosphatase is not released from the central vacuole, suggesting indirectly that vacuole enzymes do not migrate into the cytoplasm during autolysis.