Studies on Succinic Dehydrogenase

Cyanide Resistance in Achromobacter I. Induced Formation of Cytochrome a(2) and Its Role in Cyanide-Resistant Respiration

Arima, Kei (University of Tokyo, Tokyo, Japan), and Tetuo Oka. Cyanide resistance in Achromobacter. I. Induced formation of cytochrome a(2) and its role in cyanide-resistant respiration. J. Bacteriol. 90:734-743. 1965.-By following the cytochrome concentrations during the growth cycle and under various conditions (aerobic, aerobic plus KCN, reduced aeration, anaerobic plus NaNO(3)) in Achromobacter strain D, a close relationship between the formation of cytochrome a(2) (and a(1)) and the difficulty of oxygen utilization was demonstrated. Cytochrome o, which was the only oxidase found in aerobic log-phase cells, was present in bacterial cells grown under various conditions; the amount present had no relation to the degree of cyanide resistance. On the other hand, cytochrome a(2) (and a(1)) was inducible, and a close relation was observed between the amount of cytochrome and resistance to cyanide. Spectrophotometric observations indicated that, among the cytochromes present in resistant cells, cytochrome a(2) could be oxidized most easily in the presence of cyanide and that cytochrome b(1) could be oxidized without the oxidation of cytochrome a(1). We concluded that cytochrome a(2) is a cyanide-resistant oxidase capable of catalyzing the oxidation of cytochromes in the presence of cyanide. Cytochrome a(2) is also resistant to azide, an inhibitor of cytochrome oxidase.

PHOSPHOLIPIDS OF EHRLICH ASCITES TUMOR

The following phosphatides (in approximate order of concentration) were studied in cells of the Ehrlich ascites carcinoma incubated in a medium containing inorganic P32: lecithin > sphingomyelin > phosphatidyl ethanolamine = phosphatidyl inositol = phosphatidic acid > choline plasmalogen = phosphatidyl serine > ethanolamine plasmalogen. The specific radioactivity of the diacyl-glycerophosphatide fraction exceeded that of both the plasmalogen and the sphingomyelin – glycerol ether phosphatide fraction, the specific radioactivity of the individual phosphatides being as follows: phosphatidic acid > phosphatidyl inositol > ethanolamine plasmalogen > phosphatidyl ethanolamine = choline plasmalogen = lecithin > sphingomyelin. The microsomal fraction contained more phospholipid, followed by the mitochondrial and nuclear fractions, in that order. The specific radioactivities of the phospholipids of the microsomes and nuclei were greater than that of the mitochondria, chiefly because of the high specific radioactivity of the diacylglycerophosphatide fraction. The high specific radioactivity of the diacylglycerophosphatides was largely the result of a very active incorporation of inorganic P32into phosphatidic acid, particularly in the microsomal fraction. The significance of these findings is discussed.

Pyridoxal phosphate-induced dissociation of the succinate: ubiquinone reductase

Treatment of the soluble ubiquinone-deficient succinate: ubiquinone reductase with pyridoxal phosphate results in the inhibition of the carboxin-sensitive ubiquinone-reductase activity of the enzyme. The inactivation is prevented by the soluble homolog of ubiquinone (Q2) but is insensitive to the dicarboxylates interacting with the substrate binding site of succinate dehydrogenase. The reactivity of the pyridoxal phosphate-inhibited enzyme with different electron acceptors suggests that the observed inhibition is due to the dissociation of succinate dehydrogenase from the enzyme complex. The soluble succinate dehydrogenase was recovered in the supernatant after treatment of the insoluble succinate: ubiquinone reductase with pyridoxal phosphate. The data obtained strongly suggest the participation of amino groups in the interaction between succinate dehydrogenase and the ubiquinone reactivity conferring peptide within the complex.

Tetrazolium method for studying the catalytic properties of oxidoreductases in cellular organelles immobilized on glass surfaces

A new quantitative method allowing the measurement of the activity of oxidoreductases, as well as the study of their catalytic properties, is proposed. The method is based on photometering a smear of cellular organelles in the course of incubation in medium containing the reductase substrate and an artificial electron acceptor, tetrazolium salt. Catalytic properties of succinate:p-nitrotetrazolium violet reductase, as revealed on the smears, are shown to be identical to those of the reductase in mitochondrial suspension. Under similar conditions the maximal oxidation rate of succinate with p-nitrotetrazolium violet is the same as that in the presence of an acceptor of another type, Wurster's blue. The method allows the study of a number of reductases.

Human succinate dehydrogenase: biochemical and genetic characterization

A simple procedure for the preparation of soluble human succinate dehydrogenase is described. These preparations have proved suitable for analysis by zone electrophoresis, using a specific stain to detect activity after separation. In a survey of succinate dehydrogenase from various tissues and different individuals, no evidence for genetic heterogeneity due to the expression of either multiple loci or alternative alleles at the succinate dehydrogenase locus was found. However, epigenetic heterogeneity in both molecular size and charge was seen and various explanations for the occurrence of the isoenzymes are explored. Estimates of molecular size (93,300 +/- 9100) suggest that the smallest active unit of succinate dehydrogenase accounts for the major part of the solubilized activity. Kinetic studies have shown that the apparent Km values for succinate (0.9 mM) and PMS (0.4 mM) are comparable to those previously described for the beef heart enzyme, and these parameters were not significantly altered when the enzyme was removed from the membrane milieu. However a marked non-succinate-dependent activation of the membrane-associated enzyme at 38 C is apparently lost on solubilization, and this observation may have some bearing on earlier reports of an apparent decrease in Vmax on solubilization of succinate dehydrogenase.

Studies on the succinate dehydrogenating system. I. Kinetics of the succinate dehydrogenase interaction with a semiquindiimine radical of N,N,N',N'-tetramethyl-p-phenylenediamine

1. The activities of the soluble reconstitutively active succinate dehydrogenase (EC 1.3.99.1) measured with three artificial electron acceptors, e.g. ferricyanide, phenazine methosulfate and free radical of N,N,N',N'-tetramethyl-p-phenylenediamine (WB), have been compared. The values estimated by extrapolation to infinite acceptor concentration using double reciprocal plots 1/v versus 1/[acceptor] are nearly the same for ferricyanide and phenazine methosulfate and about twice as high for the WB. 2. The double reciprocal plots 1/v versus 1/[succinate] in the presence of malonate at various concentrations of WB give a series of straight lines intercepting in the third quadrant. The data support the mechanism of the overall reaction, in which the reduced enzyme is oxidized by WB before dissociation of the enzyme-product complex. 3. The dependence of the rate of the overall reaction on WB concentration shows that only one kinetically significant redox site of the soluble succinate dehydrogenase is involved in the reduction of WB. 4. Studies of the change of V and Km values during aerobic inactivation of the soluble enzyme suggest that only 'the low Km ferricyanide reactive site' (Vinogradov, A.D., Gavrikova, E.V. and Goloveshkina, V.G. (1975) Biochem. Biophys, Res. Commun. 65, 1264--1269) is involved in reoxidation of the reduced enzyme by WB. 5. The pH dependence of V for the succinate-WB reductase reaction shows that the group of the enzyme with the pKa value of 6.7 at 22 degrees C is responsible for the reduction of dehydrogenase in the enzyme-substrate complex. 6. When WB interacts with the succinate-ubiquinone region of the respiratory chain, the double reciprocal plot 1/v versus 1/[WB] gives a straight line. The thenoyltrifluoroacetone inhibition of succinate-ubiquinone reductase or extraction of ubiquinone alter the 1/v versus 1/[WB] plots for the curves with a positive initial slope intercepting the ordinate at the same V as in the native particles. The data support the mechanism of succinate-ubiquinone reduction, in which no positive modulation of succinate dehydrogenase by ubiquinone exist in the membrane.