Effect of cadmium on the regulatory mechanism of steroidogenic pathway of Leydig cells during spermatogenesis.

Cadmium is a male reproductive toxicant that interacts with a variety of pathogenetic mechanisms. However, the effect of cadmium on the regulatory mechanism of the steroidogenic pathway of Leydig cells during spermatogenesis is still ambiguous. Light microscopy, Western blot, immunohistochemistry, immunofluorescence, and quantitative polymerase chain reaction were performed to study the regulatory mechanism of the steroidogenic pathway of Leydig cells during spermatogenesis. The results indicated that in the control group, Leydig cells showed dynamic immunoreactivity and immunosignaling action with a strong positive significant secretion of 3ß-hydroxysteroid hydrogenase (3ß-HSD) in the interstitial compartment of the testis. Leydig cells showed a high active regulator mechanism of the steroidogenic pathway with increased the proteins and genes expression level of steroidogenic acute regulatory protein (STAR), cytochrome P450 cholesterol (CYP11A1), cytochrome P450 cholesterol (CYP17A1), 3ß-hydroxysteroid hydrogenase (3ß-HSD) 17ß-hydroxysteroid hydrogenase (17ß-HSD), and androgen receptor (AR) that maintained the healthy and vigorous progressive motile spermatozoa. However, on treatment with cadmium, Leydig cells were irregularly dispersed in the interstitial compartment of the testis. Leydig cells showed reduced immunoreactivity and immunosignaling of 3ß-HSD protein. Meanwhile, cadmium impaired the regulatory mechanism of the steroidogenic process of the Leydig cells with reduced protein and gene expression levels of STAR, CYP11A1, CYP17A1, 3ß-HSD, 17ß-HSD, and AR in the testis. Additionally, treatment with cadmium impaired the serum LH, FSH, and testosterone levels in blood as compared to control. This study explores the hazardous effect of cadmium on the regulatory mechanism of the steroidogenic pathway of Leydig cells during spermatogenesis.

Hydrogen Production by CO2 Deprived Photoautotrophic Chlamydomonas reinhardtii Cultures.

Light-dependent hydrogen production by microalgae attracts attention of researchers because of the potential practical application. It is generally recognized that Calvin-Benson-Bassham cycle competes with hydrogen production process for electrons, and substrate (CO2) limitation of the cycle can increase hydrogen production rate. Furthermore, photosystem II is not destroyed by CO2 deficiency. We studied photoautotrophic cultures of Chlamydomonas reimhardtii under CO2 deficiency. Under the flow of air with removed CO2 the cultures reached stationary phase of growth and the photosystem II was downregulated due to overreduction of plastoquinone pool followed by degradation of the entire photosynthetic machinery. Under the Ar flow in the absence of CO2 the cultures were brought to microaerobic conditions producing small amounts of hydrogen (5 ml H2 day-1 liter-1 culture). Similar to the case of incubation under air atmosphere, prolonged incubation of cultures under microaerobic conditions resulted in down-regulation of photosystem II due to overreduction of plastoquinone pool with following degradation of whole photosynthetic machinery. Following removal of CO2, transfer of cultures into dark anaerobic conditions (2.5 h), and illumination with low-intensity light resulted in the cultures producing H2 with high initial rate. Total microalgal hydrogen production under these conditions was 56 ml H2 liter-1 culture. Thus, the CO2-deprived photoautotrophic cultures produce hydrogen. Hydrogen production was limited by the toxic effect of oxygen on hydrogenase but not by the Calvin-Benson-Bassham cycle competition with hydrogen production process.

Proteomic analysis of Rhodospirillum rubrum after carbon monoxide exposure reveals an important effect on metallic cofactor biosynthesis.

Some carboxydotrophs like Rhodospirillum rubrum are able to grow with CO as their sole source of energy using a Carbone monoxide dehydrogenase (CODH) and an Energy conserving hydrogenase (ECH) to perform anaerobically the so called water-gas shift reaction (WGSR) (CO + H2O → CO2 + H2). Several studies have focused at the biochemical and biophysical level on this enzymatic system and a few OMICS studies on CO metabolism. Knowing that CO is toxic in particular due to its binding to heme iron atoms, and is even considered as a potential antibacterial agent, we decided to use a proteomic approach in order to analyze R. rubrum adaptation in term of metabolism and management of the toxic effect. In particular, this study allowed highlighting a set of proteins likely implicated in ECH maturation, and important perturbations in term of cofactor biosynthesis, especially metallic cofactors. This shows that even this CO tolerant microorganism cannot avoid completely CO toxic effects associated with its interaction with metallic ions. SIGNIFICANCE: This proteomic study highlights the fact that even in a microorganism able to handle carbon monoxide and in some way detoxifying it via the intrinsic action of the carbon monoxide dehydrogenase (CODH), CO has important effects on metal homeostasis, metal cofactors and metalloproteins. These effects are direct or indirect via transcription regulation, and amplified by the high interdependency of cofactors biosynthesis.

Therapeutic response to single intravenous bolus administration of formate dehydrogenase in methanol-intoxicated rats.

Methanol remains to be a major public and environmental health hazard. Formic acid is the toxic metabolite responsible for the metabolic acidosis observed in methanol poisoning in humans, in non-human primates and in folate-depleted rodents. Cytochrome oxidase inhibition by formate leads to lactic acid accumulation, which contributes significantly to metabolic acidosis. Toxic effects in human beings are characterized by formic acidemia, metabolic acidosis, ocular toxicity, nervous system depression, blindness, coma and death. Elimination of formate is one of the principles of management in methanol poisoning. Hemodialysis facility is not readily available in all the places, in developing countries like India. Formate dehydrogenase (EC 1.2.1.2) acts directly over formate and converts formate into CO(2) in the presence of NAD. Effect of single intravenous bolus infusion of formate dehydrogenase, obtained from Candida boidinii; in methanol-intoxicated folate deficient rat model was evaluated. Folate depletion induced by methotrexate (MTX) treatment. Carbicarb (Carb) (equimolar solution of sodium carbonate and sodium bicarbonate) was used to treat metabolic acidosis. Experimental design consists of seven groups, namely Saline control, methanol control, MTX control, Enzyme control, MTX-methanol control, MTX-methanol-Carb and MTX-methanol-Carb-Enz group. Male wistar rats treated with MTX (0.3mg/kg) for a week, were injected (i.p.) with methanol (4 gm/kg), 12h latter, Carbicarb solution was infused, following this enzyme was infused (i.v.) in bolus. Blood samples were collected every 15 min for an hour from the cannulated left jugular vein and blood methanol, formate were estimated, respectively, with HPLC and fluorimetric assay. Blood pH, blood gases pO(2), pCO(2) and bicarbonate were monitored with blood gas analyzer in order to evaluate acid base status of the animal. Results obtained show that there is significant elimination of formate within 15 min. It may be concluded that single bolus infusion of formate dehydrogenase facilitates fast removal of formate, a highly toxic metabolite in methanol poisoning.

Hydrogenase encapsulation into red blood cells and regeneration of electron acceptor.

Biochemical decompression has been proposed as a method for reducing the amount of time required for deep-sea divers to return to the surface. Divers breathing H2/O2 mixtures would be presented with hydrogenase enzyme, and decompression would be accelerated by means of the enzymic removal of excess H2 from the tissues. We have studied FAD as a hydrogenase electron acceptor that is capable of transferring electrons derived from H2 oxidation directly to O2. Kinetic activity constants for the soluble hydrogenase from the bacterium Alcaligenes eutrophus H16 were determined with FAD, FMN and riboflavin as electron acceptors, and these values were compared with those obtained with the physiological electron acceptor NAD+. The Michaelis constants (K(m)) were similar for FAD, FMN and NAD. However, the maximal catalytic-centre activity (Kcat) was much lower for the flavins, and the catalytic efficiency (Kcat/K(m)) with FAD was 1/20th the value for NAD+. After enzyme-catalysed FAD reduction to FADH2, the FAD could be regenerated by addition of O2 and reduced again by the enzyme in the presence of H2. Thus FAD served as a regenerable electron shuttle between H2 and O2. H2O2, a by-product of FADH2 oxidation by O2, inhibited the enzyme. Much greater inhibition was observed with the reduced form of the enzyme. Active hydrogenase was efficiently encapsulated into human and pig red blood cells. Hydrogen consumption was seen with lysed carrier cells, but was demonstrated with unlysed carrier cells only when FAD was co-encapsulated along with enzyme. These results demonstrate that red blood cells encapsulating hydrogenase and FAD act as a system for continuous H2 consumption in a mammalian tissue without addition of exogenous factors, and such cells may provide a biotherapeutic method for reducing the risk and treatment of decompression sickness.