Glutathione transport across intestinal brush-border membranes: effects of ions, pH, delta psi, and inhibitors

We characterized glutathione transport in brush-border membrane vesicles (BBMV) that were prepared from rabbit small intestine in which gamma-glutamyl transpeptidases (gamma-glutamyltransferases, EC 2.3.2.2) had been inactivated by a specific affinity-labeling reagent (AT125). Intact GSH transport was strongly increased by the presence of Na+, K+, LI+, Ca2+ and Mn2+ and, of all these, the Ca2+ activation effect was prevalent. This cation effect was selective and catalytic but not energetic; Vmax obtained in the presence of both Na+ and Ca2+ was about 6-times higher than it was in their absence, while Km did not change. Moreover, these cations almost completely eliminated GSH binding on the membrane surface. Na+ activation cannot be explained as a stimulation effect on the Na+-H+ antiport system, since a GSH proton-driven transport was excluded. We determined a pH optimum (7.5), while low or high extravesicular pH values diminished the GSH uptake rate. The Ca2+ effect on GSH transport, when an electrical potential difference was imposed across BBMV, was different from that of monovalent cations. Indeed, experiments performed by valinomycin-induced K+ diffusion potential or by anion substitution showed that the GSH transport system was an electroneutral process in the presence of Na+ or K+, but that it was electrogenic in the presence of Ca2+ or in the absence of extravesicular cations. These results suggest that GSH is also cotransported with these cations, without its accumulation inside vesicles. Moreover, since GSH is negatively charged, the effect of pH changes and of cation activation on GSH transport is arguably mediated by changes in the ionization state of certain groups as the carrier site and of GSH itself, indicating the electrostatic nature of GSH binding sites on the transporter. The high Ca2+ activation effect is perhaps also partly due to fluidity changes in the lipoproteic microenvironment of the GSH transporter. Moreover, this transport system has high affinity with GSH, given the low Km value (17 microM) and the fact that it was only inhibited by GSH S-derivatives and by GSH monoethyl ester, which probably share the same transport system.     

Heterotrophic metabolism and diazotrophic growth ofNostoc sp. fromCycas circinalis

The cyanobiont ofCycas circinalis (identified asNostoc sp.) was isolated and its heterotrophic metabolism was studied in free culture under nitrogen-fixing conditions. Morphology, growth rate, nitrogenase activity, biochemical composition, efficiency of assimilation of organic carbon and molecular nitrogen were determined under different conditions of energy and carbon supply. The study has revealed the high potential of the heterotrophic metabolism in this symbiotic cyanobacterium. Although low rates of metabolic activities were attained under heterotrophic conditions, the efficiencies of organic carbon utilization (0.48 g cell-carbon per g glucose-carbon in chemoheterotrophy, from 0.65 to 0.74 under photoheterotrophy) and of N₂ assimilation (35.0 mg N₂ fixed per g glucose used in chemoheterotrophy, from 58.3 to 61.9 under photoheterotrophy) displayed by this organism were among the highest ever found in diazotrophically grown microorganisms. The isolate fromC. circinalis was able to grow indefinitely in the dark under nitrogen-fixing conditions, maintaining a well balanced biosynthetic activity and the capacity to resume photosynthetic metabolism quickly. The significance of the heterotrophic potential of this symbioticNostoc is discussed.     

Effects of growth conditions on exopolysaccharide production by Cyanospira capsulata

Batch cultures of Cyanospira capsulata, a heterocystous cyanobacterium possessing a thick polysaccharidic capsule, were characterized by increasing viscosity owing to the continuous release of a soluble polysaccharide (EPS) into the culture medium. Both capsulated trichomes and solubilized EPS contributed to the flow properties of whole cultures. A typical pseudoplastic behaviour, the more marked the more aged were the cultures, was evidenced.The production of EPS was investigated under different growth conditions by changing some nutritional and physical parameters known to affect the synthesis of exopolysaccharides in algae and cyanobacteria. Among the factors tested (Ca²⁺, Mg²⁺ or PO₄⁻⁴ deficiencies, salinity and pH) only Mg²⁺ shortage caused a significant enhancement of the EPS production. Under continuous illumination in open ponds, the EPS productivity of batch cultures on standard mineral medium was about 5·8 g m⁻² day⁻¹, whereas under Mg²⁺ deficiency with a consequent increase of the cultures' viscosity     

Rapid detection and quantification of yeast species during spontaneous wine fermentation by PCR-RFLP analysis of the rDNA ITS region

L. GRANCHI, M. BOSCO, A. MESSINI and M. VINCENZINI.1999.PCR–RFLP analysis of the rDNA–ITS (internal transcribed spacer) region was applied to 174 yeast strains belonging to 30 species of oenological significance and including 27 type strains in order to define a rapid identification protocol for yeast colonies. Dra I-or Hae III-PCR–RFLP patterns were species-specific with the exception of teleomorphic and anamorphic forms. An improved protocol taking about 30 h was used for the detection and quantification of yeast species occurring in the course of a spontaneous wine fermentation at industrial level. Wine samples were taken and plated daily on an agar medium and the developed colonies were analysed by PCR–RFLP after 24 h of incubation. A representative sample of these colonies was also identified by traditional methods. Both procedures gave identical results. However, PCR–RFLP analysis allowed a more precise enumeration of the yeast populations, proving to be a reliable and simple method for monitoring the development of the yeast community throughout wine fermentation.     

GSH system in relation to redox state in dystrophic skin fibroblasts

Glutathione and GSH-related enzymes were determined in human Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) skin fibroblasts in order to relate muscular dystrophy to the redox state of the cell. The analysis of GSH, GSSG and total GSH levels in normal and dystrophic-cultured fibroblasts shows no differences in normal growth condition. However, the specific activity of two GSH-related enzymes, glutathione S-transferases (GST) and gamma-glutamylcysteine synthetase (gamma-GCS), shows significant variations between normal and both types of dystrophic skin fibroblasts. These results suggest that even in normal growth condition some components of GSH metabolism may be altered. A condition of sublethal oxidation obtained by H(2)O(2) treatment was able to show a difference in the cellular response of GSH system components between normal and dystrophic cells. While in DMD cells there is a decrease of roughly 55% in GSH and of 30% in total GSH concentration, no changes are measured in normal and BMD cells. The remarkable increase in glutathione peroxidase (GPx) activity and decrease in GSH-reductase (GR) activity measured in DMD cells can in part explain these changes. These results indicate a different capacity of DMD cells to support oxidative stress with respect to BMD and normal cells, and suggest a possible role of the GSH-antioxidant system in dystrophic pathology.     

Involvement of the tyrosine phosphorylation on GSH transport in NIH3T3 fibroblasts

This study demonstrates the involvement of phosphotyrosine phosphatases on the activity and regulation of GSH ATP-dependent transport system that we have previously identified in NIH3T3 fibroblasts. This is shown by the fact that increases of the initial rate of GSH uptake were measured in NIH3T3 overexpressing a synthetic gene coding for a low-Mr-phosphotyrosine protein phosphatase (LMW-PTP), while decreases were obtained in NIH3T3 overexpressing the phosphatase inactive mutant (LMW-C12SPTP), with respect to NIH3T3neo. Moreover, these results have been confirmed by experiments performed in the same cells by vanadate, and H2O2 treatment on both GSH transport and mediated passive transport of glucose. A possible regulation of this transport system by platelet-derived growth factor receptor (PDGFr) with tyrosine kinase activity is also demonstrated. Moreover, these data show a relationship among GSH, PDGFr and phosphotyrosine phosphatase activity, and suggest a role of GSH transport systems on the cell proliferation process.     

Potential of Unicellular Cyanobacteria from Saline Environments as Exopolysaccharide Producers

Fifteen Cyanothece strains isolated from saline environments have been characterized with regard to exopolysaccharide (EPS) production. The polymers contained six to eight monosaccharides, with one or two acidic sugars. In some EPS samples, the additional presence of acetyl, pyruvyl, and/or sulfate groups was also detected.     

Carbohydrate synthesis by two Navicula strains isolated from benthic and pelagic mucilages in the Tyrrhenian Sea (Tuscan Archipelago)

Two exopolysaccharide (EPS)-producing strains of the diatom Navicula, were isolated from benthic and pelagic mucilaginous aggregates sampled in the Tyrrhenian Sea and cultured under laboratory conditions. The amount of carbohydrate formed over the growth period and on a per cell basis was quite similar. However, the benthic strain showed a preferential synthesis of the bound (i.e., cellular and capsular) carbohydrate fraction, whereas the pelagic strain preferentially synthesised soluble, polymeric carbohydrates. The polysaccharides released into the medium by the two strains showed the same qualitative monosaccharidic composition, being constituted by two acidic and six neutral sugars. It is suggested that the difference between the benthic and the pelagic strain in the synthesis of bound or soluble carbohydrates may be related to the different role of these compounds in the particular habitats of the strains.     

Exopolysaccharide-producing cyanobacteria and their possible exploitation: A review

Since the early 1950s, more than one hundred cyanobacterial strains,belonging to twenty different genera, have been investigated with regard tothe production and the released exocellular polysaccharides (RPS) into theculture medium. The chemical and rheological properties show that suchpolysaccharides are complex anionic heteropolymers, in about 80% casescontaining six to ten different monosaccharides and in about 90% casescontaining one or more uronic acids; almost all have non-saccharidiccomponents, such as peptidic moieties, acetyl, pyruvyl and/or sulphategroups. Based on such ingredients, cyanobacterial RPSs show promise asthickening or suspending agents, emulsifying or cation-chelating compoundsand the residual capsulated cyanobacterial biomass, following RPSextraction, could be an effective cation-chelating material. Indeed, wheneleven unicellular and filamentous RPS-producing cyanobacteria, selectedon the basis of the anion density of their RPSs and on the abundance oftheir outermost investments, were screened for their ability to removeCu²⁺ from aqueous solutions, a quick and most effective heavy metaladsorption was observed for the unicellular Cyanothece CE 4 and thefilamentous Cyanospira capsulata. These results suggest the possibilityto accomplish, through the exploitation of RPS-producing cyanobacteria,a multiproduct strategy to procure a wide range of biopolymers suited tovarious industrial applications, in addition to the residual biomass effectivein the recovery of heavy metals from polluted waters.