Rhodanese activity and total sulfur content in frog and mouse liver

The activity of rhodanese was histochemically tested in cryostat sections of the frog (Rana temporaria) and mouse liver. The activity levels were evaluated in sections, and the results were expressed as the ratio of the area of all granules, products of the enzymatic test, to the total analyzed area (area fraction). The present study confirmed the biochemically detected activity of rhodanese, and showed a large pool of endogenous sulfane sulfur donors, substrates for rhodanese, in the frog liver. The area of a single granule corresponded to the size of the mitochondrium, what suggests enzyme localization in this organelle. In view of this it should be considered whether the rhodanese activity, biochemically detected in the cytosolic fraction of the frog liver, results from the enzyme action. The total content of sulfur in cryostat sections of the mouse and frog liver was calculated and compared on the basis of the Energy Dispersion Spectrum (EDS) obtained by a scanning microscope. These studies showed higher total sulfur content in the frog liver than in the mouse liver. The high total content of sulfur in the frog liver in autumn might be associated with sulfur storing for protein biosynthesis during the period of hibernation.     

Sulfurtransferases and the content of cysteine, glutathione and sulfane sulfur in tissues of the frog Rana temporaria

L-cysteine desulfuration was examined in tissues of Rana temporaria, in October and January. The activities of 3-mercaptopyruvate sulfurtransferase (MPST), cystathionine gamma-lyase (CST) and rhodanese were primarily concentrated in frog liver and kidney. The values of CST and rhodanese activity, as well as sulfane sulfur compounds levels fell in the range characteristic of rat. For each of the investigated tissues changes noted in the enzymatic activities and in the level of glutathione (GSH), protein-bound cysteine (PbCys) and sulfane sulfur compounds were dependent on the month in which the determination was performed, and on the character of the tissue. In such tissues as the liver or gonads, high GSH levels and high activities of MPST (in the liver) or MPST and rhodanese (in the gonads) seemed to accompany protein biosynthesis during hibernation. PbCys, the level of which was consequently diminished in all tissues in January, compensated the absence of exogenous cysteine. A significantly reduced GSH level in the brain in January seemed to be correlated with decreased requirements of the tissue for this important natural antioxidant at diminished thyroid hormones levels in the serum and minimal oxygen consumption during the hibernation. In the kidney, the possible participation of sulfane sulfur compounds in detoxification processes requires elucidation, similarly as in protection against cellular oxidative stress at extremely low levels of GSH.     

Synthesis of rhodanese in Hep 3B cells

Summary The biosynthesis of rhodanese was studied in human hepatoma cell lines by immunoblotting and pulselabeling experiments using polyclonal antibodies raised against the bovine liver enzyme. Rhodanese, partially purified from human liver, showed an apparent molecular weight of 33,000 daltons, coincident with that of rhodanese from Hep 3B cells. After pulse labeling of Hep 3B cells both at 37°C and 25°C, rhodanese in the cytosol fraction exhibited the same molecular weight as the enzyme isolated from the particulate fraction containing mitochondria. Moreover, newly synthesized rhodanese from total Hep 3B RNA translation products showed the same electrophoretic mobility as rhodanese from Hep 3B cells. These results suggest that rhodanese, unlike most mitochondrial proteins, is not synthesized as a higher molecular weight precursor.     

Rhodanese (thiosulfate:cyanide sulfurtransferase) from frog Rana temporaria

The molecular mass of rhodanese from the mitochondrial fraction of frog Rana temporaria liver, equaling 8.7 kDa, was determined by high-performance size exclusion chromatography (HP-SEC). The considerable difference in molecular weight and the lack of common antigenic determinants between frog liver rhodanese and bovine rhodanese suggest the occurrence of different forms of this sulfurtransferase in the liver of these animals.     

Comparative studies on the distribution of rhodanese in different tissues of domestic animals.

1. The activity of rhodanese in different tissues of some domestic animals was measured. 2. Rhodanese was present in all tissues studied. 3. The activity of rhodanese in most tissues of sheep was higher than other animals studied. 4. In sheep and cattle the epithelium of rumen, omasum and reticulum were the richest sources of rhodanese. Significant activity of rhodanese was also present in liver and kidney. 5. In camel the liver contained the highest level of rhodanese followed by lung and rumen epithelium. Camel liver contained a third of the activity of sheep liver. 6. Equine liver had a third of the activity of sheep liver. Other tissues showed low levels of rhodanese activity. 7. Dog liver contained only 4% of the activity of sheep liver. In this animal, brain was the richest source of rhodanese. 8. The results are discussed in terms of efficacy of different tissues of animals in cyanide detoxification.     

Comparative properties of bovine heart and liver rhodaneses and the regulatory role of the rhodaneses in energy metabolism

In previous studies on the rhodanese activity of bovine liver mitochondria, we have shown that in addition to activity observed in the soluble protein fraction, there is rhodanese activity that is bound to the mitochondrial membrane. The latter activity accounts for as much as 40% of the total and, in situ, is associated in a multiprotein complex that forms iron-sulfur centers. In the present studies, we have investigated the rhodanese activity of bovine heart muscle. We have found that the major part of this enzyme activity is localized in the mitochondria and, further, that at least 25% of the total rhodanese activity of heart mitochondria is membrane-bound. As in liver tissue, the heart activity at least in part is associated in a multiprotein complex that forms iron-sulfur centers. Upon purification of the heart rhodanese in the soluble protein fraction, there is a 10- to 30-fold decrease inK _m values for the standard assay substrates thiosulfate and cyanide ions. These observations are consistent with the interpretation that there are activated and deactivated (low activity) forms of the heart enzyme in crude extracts, but only the activated form survives purification. The present results, together with our recent finding that liver mitochondrial rhodanese is subject to phosphorylation, lend support to our proposal that the rhodaneses serve as converter enzymes which regulate the rate of electron transport through sulfuration of respiratory chain components. The rhodaneses, in turn, are controlled by protein kinases and the local ATP concentration.     

Effect of ethanol on the DNA-polymerase activity in the liver subcellular fractions of adult and old rats

The effect of 5% ethanol on DNA polymerase activity in nuclei, mitochondria, microsomes and cytosol of intact and regenerating liver of adult and old rats has been studied. No changes in DNA polymerase activity were detected in subcellular fractions of adult rat liver. On the contrary, the increased activity of intact liver nuclei and decreased activity of regenerating liver microsomes was observed with ageing. These age-dependent peculiarities of DNA polymerase activity in response to 5% ethanol may be related to changes in the enzyme molecules or microenvironment associated with ageing.     

The subcellular distribution of rat liver l-alanine–glyoxylate aminotransferase in relation to a pathway for glucose formation involving glyoxylate

1. The distribution of l-alanine-glyoxylate aminotransferase activity between subcellular fractions prepared from rat liver homogenates was investigated. The greater part of the homogenate activity (about 80%) was recovered in the ;total-particles' fraction sedimented by high-speed centrifugation and the remainder in the cytosol fraction. 2. Subfractionation of the particles by differential sedimentation and on sucrose density gradients revealed a specific association between the aminotransferase and the mitochondrial enzymes glutamate dehydrogenase and rhodanese. 3. The aminotransferase activities in the cytosol and the mitochondria are due to isoenzymes. The solubilized mitochondrial enzyme has a pH optimum of 8.6, an apparent K(m) of 0.24mm with respect to glyoxylate and is inhibited by glyoxylate at concentrations above 5mm. The cytosol aminotransferase shows no distinct pH optimum (over the range 7.0-9.0) and has an apparent K(m) of 1.11mm with respect to glyoxylate; there is no evidence of inhibition by glyoxylate. 4. The mitochondrial location of the bulk of the rat liver l-alanine-glyoxylate aminotransferase activity is discussed in relation to a pathway for gluconeogenesis involving glyoxylate.     

Peculiarities of functioning of liver mitochondria of river lamprey Lampetra fluviatilis and common frog Rana temporaria at periods of suppression and activation of energy metabolism

The work dealt with study of mitochondria in reversible metabolic suppression of hepatocytes of the river lamprey Lampetra fluviatilis in the course of prespawning starvation and of liver mitochondria of the common frog Rana temporaria during hibernation and activity. In winter the metabolic depression of lamprey hepatocytes, unlike that of frog hepatocytes, has been found to be due to deactivation of complex I of the electron transport mitochondrial chain, a low rate of NAD-dependent substrate oxidation, a low content of adenine nucleotide content, and a high degree of mitochondrial membrane permeability to H+ and other monovalent ions (KCl-, K+). The mitochondrial membrane permeability decreases in the presence of ethyleneglycoldiamineethyltetraacetic acid (EGTA), cyclosporine A (CsA), adenosine-5'-diphosphate (ADP), and Mg+. These facts indicate the presence in these mitochondria of the Ca2+ -dependent unspecific pore in the low-conductance state. Histological studies showed the lamprey and the frog to have principal differences in use of energy substrates at the period of metabolic depression. Lampreys utilize predominantly lipids, whereas frogs--glycogen. The clearly pronounces activation of lipid consumption is observed at the spring period before spawning and death of lamprey. Possible causes of metabolic depression are discussed as well as similarity and difference in behavior of mitochondria of cyclostomes and amphibians throughout metabolic depression and activity.     

Mitochondrial rhodanese: membrane-bound and complexed activity

We have proposed that phosphorylated and dephosphorylated forms of the mitochondrial sulfurtransferase, rhodanese, function as converter enzymes that interact with membrane-bound iron-sulfur centers of the electron transport chain to modulate the rate of mitochondrial respiration (Ogata, K., Dai, X., and Volini, M. (1989) J. Biol. Chem. 204, 2718-2725). In the present studies, we have explored some structural aspects of the mitochondrial rhodanese system. By sequential extraction of lysed mitochondria with phosphate buffer and phosphate buffer containing 20 mM cholate, we have shown that 30% of the rhodanese activity of bovine liver is membrane-bound. Resolution of cholate extracts on Sephadex G-100 indicates that part of the bound rhodanese is complexed with other mitochondrial proteins. Tests with the complex show that it forms iron-sulfur centers when incubated with the rhodanese sulfur-donor substrate thiosulfate, iron ions, and a reducing agent. Experiments on the rhodanese activity of rat liver mitochondria give similar results. Taken together, the findings indicate that liver rhodanese is in part bound to the mitochondrial membrane as a component of a multiprotein complex that forms iron-sulfur centers. The findings are consistent with the role we propose for rhodanese in the modulation of mitochondrial respiratory activity.     

Effects of thiazolidine-4(R)-carboxylates and other low-molecular-weight sulfur compounds on the activity of mercaptopyruvate sulfurtransferase, rhodanese and cystathionase in Ehrlich ascites tumor cells and tumor-bearing mouse liver

Summary Changes of the specific activity of 3-mercaptopyruvate sulfurtransferase (MPST), rhodanese and cystathionase in Ehrlich ascites tumor cells (EATC) and tumor-bearing mouse liver after intraperitoneal administration of thiazolidine derivatives, L-cysteine, D,L-methionine, thiocystine or thiosulfate were estimated. Thiazolidine derivatives used were: thiazolidine-4-carboxylic acid (CF), 2-methyl-thiazolidine-2,4-dicarboxylic acid (CP) and 2-methyl-thiazolidine-4-carboxylic acid (CA). In the liver, the activity of MPST was significantly increased by all the studied compounds, whereas the activity of rhodanese was by CF and thiocystine and that of cystathionase was by the administration of cysteine and CP. Un the other hand, cysteine lowered the rhodanese activity and the activity of cystathionase was decreased by the administration of methionine and thiocystine. Activities of MPST and rhodanese were even lower in EATC than those in the liver of tumor-bearing mouse and the activity of cystathionase in EATC was not be detected. The thiazolidine derivatives significantly increased the level of MPST activity in EATC, but decreased the rhodanese activity. Thiosulfate also increased the activity of MPST to a lesser degree, but cysteine, methionine and thiocystine gave little change in the activity. The rhodanese activity in EATC was slightly increased only by thiocystine. These findings suggest that the sulfur metabolism in the tumor-bearing mouse liver is different from that in the normal mouse liver, and that sulfur compounds are minimally metabolized to sulfane sulfur, a labile sulfur, in EATC.     

Bioenergetic parameters of lamprey and frog liver mitochondria during metabolic depression and activity

The objective of this study is to elucidate the role of mitochondria in reversible metabolic depression of hepatocytes of the Baltic lamprey (Lampetra fluviatilis) taking place in the last year of its life cycle and to compare their main bioenergetic parameters with those of the frog (Rana temporaria) and the white outbred mouse (Mus musculus). Using isolated mitochondria as a model, we have revealed significant seasonal variations in the main bioenergetic parameters of the lamprey liver. These changes indicate that the metabolic depression is mediated by prolonged reversible alterations of mitochondrial functions, which manifest in low activity of the mitochondrial respiratory chain, low oxidative phosphorylation, low content of mitochondrial adenine nucleotides, high level of reduced mitochondrial pyridine nucleotides and leaky mitochondrial membranes observed in winter. The enhanced ion membrane permeability of winter lamprey liver mitochondria is found to be sensitive to EGTA and to cyclosporine A in combination with ADP and Mg²⁺ and is likely mediated opening the mitochondrial permeability transition pore in its low conductance state. The sharp activation of oxidation and phosphorylation in the lamprey liver mitochondria followed by spawning and death of the animal is observed in spring. The possible causes of the phenomenon and the differences obtained between lamprey, frog and mouse are under discussion.     

The effect of cAMP and some sulphur compounds upon the activity of mercaptopyruvate sulphurtransferase and rhodanese in mouse liver.

The aim of the experiments was to evaluate the effect of administration of cysteine, methionine, thiocystine, and thiosulphate upon the activity of mercaptopyruvate sulphurtransferase (MPST) and rhodanese in mouse liver. It was found that rhodanese activity increased following thiocystine and methionine administration and showed a smaller increase after cysteine and thiosulphate. The MPST activity significantly increased after cysteine and to a lesser extent after thiocystine and thiosulphate. On the other hand, methionine seemed to exert no effect upon the enzymatic activity. The results suggested that methionine metabolic cycle in mouse liver proceeded from cysteine to sulphane sulphur as thiocystine and, therefore, these three compounds increased rhodanese activity. Thiosulphate seemed rather to be involved in metabolic changes related to maintaining the stability of the physiological thiosulphate level and activated both the enzymes.     

Intracellular distribution of fumarase in various animals

The subcellular distribution of fumarase was investigated in the liver of various animals and in several tissues of the rat. In the rat liver, fumarase was predominantly located in the cytosolic and mitochondrial fractions, but not in the peroxisomal fraction. The amount of fumarase associated with the microsomes was less than 5% of the total enzyme activity. The investigation of the intracellular distribution of hepatic fumarase of the rat, mouse, rabbit, dog, chicken, snake, frog, and carp revealed that the amount of the enzyme located in the cytosol was comparable to that in the mitochondria of all these animals. The subcellular distribution of the enzyme in the kidney, brain, heart, and skeletal muscle of rat, and in hepatoma cells (AH-109A) was also investigated. Among these tissues, the brain was the only exception, having no fumarase activity in the cytosolic fraction, and the other tissues showed a bimodal distribution of fumarase in the cytosol and the mitochondria. The mitochondrial fumarase was predominantly located in the matrix. About 10% of the total fumarase was found in the outer and inner membrane, although it was unclear whether this fumarase was originally located in these fractions. No fumarase activity was detected in the intermembranous space.     

Participation of ADP/ATP- and Aspartate/Glutamate Antiporters in the Uncoupling Action of Fatty Acids in Liver Mitochondria of the Frog Rana temporaria

Data are presented on molecular mechanisms of uncoupling of oxidative phosphorylation by fatty acids (laurate) in liver mitochondria of one of the poikilothermal animals, the frog Rana temporaria. It has been shown that the uncoupling action of laurate in frog liver mitochondria, like in those of mammals, occurs with participation of protein carriers of anions of the inner mitochondrial membrane, ADP/ATP- and aspartate/glutamate antiporters. At the same time, in frog liver mitochondria the uncoupling activity of laurate is lower than in liver mitochondria of mammals (white mice). Seasonal differences in the laurate uncoupling activity in frog liver mitochondria are revealed: it is much lower in April, than in January, the season of metabolic depression. This difference is due to that in January the degree of participation of the aspartate/glutamate antiporter in the uncoupling is considerably decreased.     

Mercaptopyruvate sulfurtransferase as a defense against cyanide toxication: molecular properties and mode of detoxification.

In cyanide poisoning, metalloproteins and carbonyl groups containing proteins are the main target molecules of nucleophilic attack by cyanide. To defend against this attack, cyanide is metabolized to less toxic thiocyanate via transsulfuration. This reaction is catalyzed by rhodanese and mercaptopyruvate sulfurtransferase (MST). Rhodanese is a well characterized mitochondrial enzyme. On the other hand, little was known about MST because it was unstable and difficult to purify. We first purified MST to homogeneity and cloned MST cDNA from rat liver to characterize MST. We also found that MST was an evolutionarily related enzyme of rhodanese. MST and rhodanese are widely distributed in rat tissues, and the kidney and liver prominently contain these enzymes. Immunohistochemical study revealed that MST is mainly distributed in proximal tubular epithelial cells in the kidney, pericentral hepatocytes in the liver, the perinuclear area of myocardial cells in the heart, and glial cells in the brain, and immunoelectron microscopical study concluded that MST was distributed in both cytoplasm and mitochondria, so that MST first detoxifies cyanide in cytoplasm and the cyanide which escapes from catalysis due to MST enters mitochondria. MST then detoxifies cyanide again in cooperation with rhodanese in mitochondria. Tissues other than the liver and kidney are more susceptible to cyanide toxicity because they contain less MST and rhodanese. Even in the same tissue, sensitivity to cyanide toxicity may differ according to the kind of cell. It is determined by a balance between the amount of proteins to be attacked and that of enzymes to defend.     

Inhibition of rat liver rhodanese by di-, tricarboxylic, and alpha-keto acids.

Rat liver rhodanese [EC 2.8.1.1] purified by ammonium sulfate fractionation, CM-cellulose and Sephadex G-200 chromatography yielded two active fractions (I & II). Their molecular weights were estimated to be 1.75 X 10(4) (I) and 1.26 X 10(4) (II) by the gel filtration method. Kinetic studies revealed that Fraction I rat liver rhodanese catalyzes thiocyanate formation from thiosulfate and cyanide by a double displacement mechanism. Carboxylic acids such as DL-isocitric, citric malic, pyruvic, and oxaloacetic acid were competitive inhibitors with respect to thiosulfate, whereas fumaric, succinic, and alpha-ketoglutaric acids were noncompetitive inhibitors with respect ot thiosulfate. Incubation of mitochondria with sulfate and alpha-ketoglutaric acid caused a significant decrease in rhodanese activity.     

Neurophysiological characteristics of the resting forms of primary sleep and hypobiosis in the frog Rana temporaria

Neurophysiological studies have been made on natural resting forms of the primary sleep, wakefulness and hypobiosis in the frog. New method of presentation of the distribution density of EEG signal by a frequency spectrum was used. New data were presented concerning seasonal changes in the frequency parameters of one of the resting forms of the primary sleep, SLS-2. The role of this form of rest in the origin of hypobiosis in the frog Rana temporaria is discussed. Besides, new data were obtained which confirm that the resting form, SLS-3, of the primary sleep is an evolutionary precursor of the intermediate form of the sleep in reptiles and slow wave and activated phase of the sleep in warm-blooded vertebrates.     

Effect of cold acclimatization of grass frogs on the heat resistance of their somatic muscles in summer]

During cold acclimation (+5 degrees C) of the grass frog Rana temporaria L. changes in heat resistance were observed for six of seven skeletal muscles examined. Changes in the resistance of different muscles were directed differently. Low-resistant muscles demonstrated an increased resistance, wheras high-resistant muscles showed a decrease resistance. Within 24 hours of acclimation, all the muscles demonstrated totally decreased heat resistance. By the end of acclimation (30 days), the resistance of muscles increased to approach the initial level. On the background of those situation changes, seasonal changes in resistance of muscles proceeded.     

Synthesis of phosphoenolpyruvate from propionate in sheep liver

1. Utilization of propionate by sheep liver mitochondria was stimulated equally by pyruvate or alpha-oxoglutarate, with formation predominantly of malate. Pyruvate increased conversion of propionate carbon into citrate, whereas alpha-oxoglutarate increased formation of phosphoenolpyruvate. The fraction of metabolized propionate converted into phosphoenolpyruvate was about 17% in the presence or absence of alpha-oxoglutarate and about 7% in the presence of pyruvate. Pyruvate consumption was inhibited by 80% by 5mm-propionate. 2. Compared with rat liver, sheep liver was characterized by very high activities of phosphoenolpyruvate carboxykinase and moderately high activities of aconitase in the mitochondria and by low activities of ;malic' enzyme, pyruvate kinase and lactate dehydrogenase in the cytosol. Activities of phosphoenolpyruvate carboxy-kinase were similar in liver cytosol from rats and sheep. Activities of malate dehydrogenase and NADP-linked isocitrate dehydrogenase in sheep liver were about half those in rat liver. 3. The phosphate-dicarboxylate antiport was active in sheep liver mitochondria, but compared with rat liver mitochondria the citrate-malate antiport showed only low activity and mitochondrial aconitase was relatively inaccessible to external citrate. The rate of swelling of mitochondria induced by phosphate in solutions of ammonium malate was inversely related to the concentration of malate. 4. The results are discussed in relation to gluconeogenesis from propionate in sheep liver. It is proposed that propionate is converted into malate by the mitochondria and the malate is converted into phosphoenolpyruvate by enzymes in the cytosol. In this way sufficient NADH would be generated in the cytosol to convert the phosphoenolpyruvate into glucose.