Effect of pH on Intracellular Accumulation of Trace Concentrations of Hg(II) in Escherichia coli under Anaerobic Conditions, as Measured Using a mer-lux Bioreporter

The effects of pH on the uptake and accumulation of Hg(II) by Escherichia coli were determined at trace, environmentally relevant, concentrations of Hg and under anaerobic conditions. Hg(II) accumulation was measured using inducible light production from E. coli HMS174 harboring a mer-lux bioreporter plasmid (pRB28). The effect of pH on the toxicity of higher concentrations of Hg(II) was measured using a constitutive lux plasmid (pRB27) in the same bacterial host. In this study, intracellular accumulation and toxicity of Hg(II) under anaerobic conditions were both significantly enhanced with decreasing pH over the pH range of 8 to 5. The pH effect on Hg(II) accumulation was most pronounced at pHs of <6, which substantially enhanced the Hg(II)-dependent light response. This enhanced response did not appear to be due to pH stress, as similar results were obtained whether cells were grown at the same pH as the assay or at a different pH. The enhanced accumulation of Hg(II) was also not related to differences in the chemical speciation of Hg(II) in the external medium resulting from the changes in pH. Experiments with Cd(II), also detectable by the mer-lux bioreporter system, showed that Cd(II) accumulation responded differently to pH changes than the net accumulation of Hg(II). Potential implications of these findings for our understanding of bacterial accumulation of Hg(II) under anaerobic conditions and for bacteria-mediated cycling of Hg(II) in aquatic ecosystems are discussed. Arguments are provided suggesting that this differential accumulation is due to changes in uptake of mercury.     

NSP-interacting GTPase: A cytosolic protein as cofactor for nuclear shuttle proteins

Despite the significant progress in the identification of essential components of the nuclear transport machinery, some events of this process are still unclear. Particularly, functional information about the release of nuclear-exported macromolecules at the cytoplasmic side of the nuclear pore complex and their subsequent trans-cytoplasmic movement is lacking. Recently, we identified a cytoplasmic GTPase, designated NIG (NSP-interacting GTPase), which may play a relevant role in these processes. NIG interacts in vivo with the geminivirus NSP and promotes the translocation of the viral protein from the nucleus to the cytoplasm where it is redirected to the cell surface to interact with the viral movement protein, MP. Here we position the NIG function into the mechanistic model for the intracellular trafficking of viral DNA and discuss the putative role of NIG in general cellular nucleocytoplasmic transport of nucleic acid-protein complexes.Key words: geminivirus, NIG, NSP, nucleocytoplasmic trafficking, transport activity     

Purification of the NADP+:F420 oxidoreductase of Methanosphaera stadtmanae

Methanosphaera stadtmanae (DSM 3091) is a methanogen that requires H2 and CH3OH for methanogenesis. The organism does not possess an F420-dependent hydrogenase and only low levels of F420. It does however possess NADP+:F420 oxidoreductase activity. The NADP+:F420 oxidoreductase, the enzyme which catalyses the electron transfer between NADP+ and F420 in this organism, was purified and characterized. NAD+, NADH, FMN, and FAD could not be used as electron acceptors. Optimal pH for F420 reduction was 6.0, and 8.5 for NADP+ reduction. During the purification process, it was noted that precipitation with (NH4)2SO4 increased total activity 16-fold but reduced the stability of the enzyme. However, recombination of cell-free extracts with resuspended 65-90% (NH4)2SO4 pellet returned activity to near cell-free extract levels. Neither high salt or protease inhibitors were effective in stabilizing the activity of the partially purified enzyme. The purified enzyme from M. stadtmanae possessed a molecular weight of 148 kDa as determined by gel filtration chromatography and native-PAGE, consisting of alpha, beta, and gamma subunits of 60, 50, and 45 kDa, respectively, using SDS-PAGE. The Km values were 370 microM for NADP+, 142 microM for NADPH, 62.5 microM for F420, and 7.7 microM for F420H2. These values were different from the Km values observed in the cell-free extract.     

Pseudo-transposition of a Tn5 derivative in Neisseria gonorrhoeae

Abstract We constructed a Tn5 derivative for potential use in transposon mutagenesis of Neisseria gonorrhoeae . It was incorporated into the chromosome apparently at random following transformation, but the insertion events were dependent on a functional RecA and independent of a functional transposase. Furthermore, in most cases there was an incomplete transposon inserted with little or no IS50 insertion sequence. These observations suggest that TnJ transposition may not be possible in N. gonorrhoeae and that this organism may have an unexplored illegitimate recombination system.     

Differential Stabilities of Phosphorylated Response Regulator Domains Reflect Functional Roles of the Yeast Osmoregulatory SLN1 and SSK1 Proteins

Osmoregulation in Saccharomyces cerevisiae involves a multistep phosphorelay system requiring three proteins, SLN1, YPD1, and SSK1, that are related to bacterial two-component signaling proteins, in particular, those involved in regulating sporulation in Bacillus subtilis and anaerobic respiration in Escherichia coli. The SLN1-YPD1-SSK1 phosphorelay regulates a downstream mitogen-activated protein kinase cascade which ultimately controls the concentration of glycerol within the cell under hyperosmotic stress conditions. The C-terminal response regulator domains of SLN1 and SSK1 and full-length YPD1 have been overexpressed and purified from E. coli. A heterologous system consisting of acetyl phosphate, the bacterial chemotaxis response regulator CheY, and YPD1 has been developed as an efficient means of phosphorylating SLN1 and SSK1 in vitro. The homologous regulatory domains of SLN1 and SSK1 exhibit remarkably different phosphorylated half-lives, a finding that provides insight into the distinct roles that these phosphorylation-dependent regulatory domains play in the yeast osmosensory signal transduction pathway.     

Regulation of formate dehydrogenase activity in Methanococcus thermolithotrophicus.

Methanococcus thermolithotrophicus can use either H2 or formate as the electron donor for methanogenesis from CO2. Resuspended-cell experiments revealed that the ability to use H2 as the source of electrons for methanogenesis was constitutive; cells grown on formate or H2-CO2 were equally capable of H2-CO2 methanogenesis. The ability to metabolize formate at high rates was observed only in cells previously grown on formate. Two such strains were distinguished: strain F and strain HF. Strain F was repeatedly grown exclusively on formate for over 3 years; this strain showed a constitutive capacity to metabolize formate to methane, even after subsequent repeated transfers to medium containing only H2-CO2. Strain HF could only metabolize formate to methane when grown in the presence of formate with no H2 present; this strain was recently derived from another strain (H) that had been exclusively grown on H2-CO2 and which upon initial transfer to formate medium could only metabolize formate to methane at a very slow rate. Initial adaptation of strain H to growth on formate was preceded by a long lag. The specific activities of hydrogenase and formate dehydrogenase in cell extracts derived from these different strains confirmed these findings. Similar levels of hydrogenase were observed in all strains, independent of the presence of H2 in the growth medium medium. High levels of formate dehydrogenase were also constitutive in strain F. Only low formate dehydrogenase activities were observed in strain H. High levels of formate dehydrogenase were observed in strain HF only when these cells were grown with formate in the absence of H2. In all strains the two- to threefold fluctuations of both hydrogenase and formate dehydrogenase cell-free activities were observed during growth, with peak activities reached in the middle of the exponential phase.     

Biomass pretreatment: fundamentals toward application

Development of sustainable energy systems based on renewable biomass feedstocks is now a global effort. Lignocellulosic biomass contains polymers of cellulose, hemicellulose, and lignin, bound together in a complex structure. Liquid biofuels, such as ethanol, can be made from biomass via fermentation of sugars derived from the cellulose and hemicellulose within lignocellulosic materials, but the biomass must be subjected to pretreatment processes to liberate the sugars needed for fermentation. Production of value-added co-products along-side biofuels through integrated biorefinery processes creates the need for selectivity during pretreatment. This paper presents a survey of biomass pretreatment technologies with emphasis on concepts, mechanism of action and practicability. The advantages and disadvantages, and the potential for industrial applications of different pretreatment technologies are the highlights of this paper.     

Two Genetic Loci for Resistance to Kasugamycin in Escherichia coli

There are two loci for resistance to the antibiotic kasugamycin (Ksg) in Escherichia coli. Mutations at ksgA resulted in 30S ribosomal subunit resistance to Ksg. The map location of ksgA was near minute 0.5: ksgA was 95% cotransducible with pdxA, and the apparent gene order was thr... ksgA... pdxA. Studies in stable ksgA/ksgA⁺ merodiploids showed that sensitivity was dominant over resistance. Mutations at a second gene (ksgB), located between minutes 25 and 39, resulted in phenotypic Ksg^R indistinguishable from ksgA mutations, but ribosomes from ksgB strains were sensitive to the drug in vitro. Spontaneous and induced mutations to Ksg^R were usually of the ksgA (ribosomal) type.