Cloning of histidine genes of Azospirillum brasilense: organization of the ABFH gene cluster and nucleotide sequence of the hisB gene

Summary A cluster of four Azospirillum brasilense histidine biosynthetic genes, hisA, hisB, hisF and hisH, was identified on a 4.5 kb DNA fragment and its organization studied by complementation analysis of Escherichia coli mutations and nucleotide sequence. The nucleotide sequence of a 1.3 kb fragment that complemented the E. coli hisB mutation was determined and an ORF of 624 nucleotides which can code for a protein of 207 amino acids was identified. A significant base sequence homology with the carboxyterminal moiety of the E. coli hisB gene (0.53) and the Saccharomyces cerevisiae HIS3 gene (0.44), coding for an imidazole glycerolphosphate dehydratase activity was found. The amino acid sequence and composition, the hydropathic profile and the predicted secondary structures of the yeast, E. coli and A. brasilense proteins were compared. The significance of the data presented is discussed.Abbreviations IGP imidazole glycerolphosphate - HP histidinolphosphate     

Photocatalyzed Anaerobic Oxidation of Nicotinamide Coenzyme Dimers to NAD+ by Adriamycin

The nicotinamide adenine dinucleotide dimers (NAD)₂ obtained by electrochemical reduction of NAD⁺ are oxidized by adriamycin in anaerobic photocatalyzed reaction yielding NAD⁺ and 7-deoxyadriamyci-none. Under the same conditions NADH is not oxidized.     

Pyruvate is transported by a proton symport inLactobacillus plantarum 8014

Pyruvate is a key metabolic intermediate and the substrate for diacetyl and acetoin synthesis. The mechanism of pyruvate transport was determined inLactobacillus plantarum by use of cells and membrane vesicles. In the cells, protonophores inhibited pyruvate transport, whereas valinomycin did not. Pyruvate was accumulated against a gradient in membrane vesicles. The transport rate and the degree of accumulation increased as the proton gradient increased, but an imposed K potential of –61mV did not drive pyruvate transport. The maximum transport rate (35 nmol/min/mg protein) and accumulation ratio (162-fold) were at pH 3.0, with an apparent Km value of 35 M. These results suggested that pyruvate was transported by a proton symport.     

Synthesis of the biologically active β-subunit of human nerve growth factor in Escherichia coli

The gene(NGFB) encoding the β subunit of mature human nerve growth factor (hNGFB) was subcloned into the pJLA503 expression vector under the control of bacteriophage promoters p_R and p_L, and expressed in Escherichia coli. The recombinant protein represented approximately 3% of the total cellular protein. Biologically active hNGFB was solubilized (0.2% total NGFB) and purified by cation-exchange chromatography and it yielded two bands on polyacrylamide-gel electrophoresis under nonreducing conditions, corresponding to the monomeric (14 kDa) and homodimeric (26.5 kDa) forms of the molecule. Both hNGFB forms were immunopositive on Western blots with rabbit anti-NGFB antibodies; however, following additional purification, only the species corresponding to the hNGFB homodimer was biologically active on cultured chicken dorsal root ganglion neurons. These results demonstrate the feasibility of synthesizing the biologically active form of hNGFB in E. coli.     

Pollinosis in trentino (Northern Italy). Aerobiological and clinical research

Summary A study to evaluate and define the atmospheric pollen concentration in Trentino was carried out through the aerobiologic sampling in three localities chosen according to their different climatic conditions.1375 patients with pollinosis living in Trentino were studied retrospectively over the period ranging from 1986 to 1988 and selected according to the area they came from.Results have proved that the most allergenic pollen types are the following: Poaceae, Urticaceae (Parietaria), Compositae (Artemisia) and the tree pollen of Betulaceae and Corylaceae (Alnus, Betula, Corylus), and that pollinosis caused by such pollen, types has different features and frequencies according to the different localities.As far as symptoms are concerned, our data shows that rhinoconjuntivitis is more frequent in those patients who are allergic toParietaria while asthma results being more frequent in patients who are allergic to tree pollen.     

ATP synthesis is driven by an imposed delta pH or delta mu H+ but not by an imposed delta pNa+ or delta mu Na+ in alkalophilic Bacillus firmus OF4 at high pH

Starved whole cells of alkalophilic Bacillus firmus OF4 that are equilibrated at either pH 10.2, 9.5, or 8.5 synthesize ATP in response to a pH gradient that is imposed by rapid dilution of the cyanide-treated cells into buffer at pH 7.5. If a valinomycin-mediated potassium diffusion potential (positive out) is generated simultaneously with the pH gradient, then the rate of ATP synthesis and the level of synthesis achieved is much higher than upon imposition of a pH gradient alone. By contrast, imposition of a large chemical gradient of Na+, either in the presence or absence of a concomitant diffusion potential, fails to result in ATP synthesis. We conclude that this organism does not possess a sodium-motive ATPase that can be made to synthesize detectable levels of ATP by imposition of a suitably large chemical or electrochemical gradient of Na+. On the other hand, a proton-translocating ATPase is in evidence when protons are provided at very high pH, corroborating our earlier work on extremely alkalophilic bacilli. Oxidative phosphorylation must, then, be catalyzed in these organisms by a proton-translocating ATPase even though the putative bulk driving forces for such a catalyst are low under optimal growth conditions. Stable, imposed pH gradients of 1 unit, comparable to the magnitude of the total electrochemical proton gradient of growing cells, result in much lower ATP concentrations than observed in such cells. We hypothesize that ATP synthesis in growing cells utilizes protons that are made available by some localized pathway between proton pumps and the ATP synthase.     

Buffering capacity of bacilli that grow at different pH ranges.

Cytoplasmic buffering capacities and buffering by whole cells were examined in six bacterial species: Bacillus acidocaldarius, Bacillus stearothermophilus, Escherichia coli, Bacillus subtilis, Bacillus alcalophilus, and Bacillus firmus RAB. Acid-base titrations were conducted on whole cells and cells permeabilized with Triton X-100 or n-butanol. In all of the species examined, the buffering capacity of intact cells was generally a significant proportion of the total buffering capacity, but the magnitude of the buffering capacity varied from species to species. Over the entire range of pH values from 4 to 9.5, B. subtilis exhibited a cytoplasmic buffering capacity that was much higher than that of B. stearothermophilus, B. acidocaldarius, or E. coli. The latter three species had comparable cytoplasmic buffering capacities at pH 4 to 9.5, as long as optimal conditions for cell permeabilization were employed. All of the nonalkalophiles exhibited a decrease in cytoplasmic buffering capacity as the external pH increased from pH 5 to 7. At alkaline pH values, the two thermophiles in the study had particularly low cytoplasmic buffering capacities, and the two alkalophilic bacteria had appreciably higher cytoplasmic buffering capacities than any of the other species studied. Cytoplasmic buffering capacities as high as 1,100 nmol of H+ per pH unit per mg of protein were observed in alkalophilic B. firmus RAB. Since previous studies have shown that immediate cytoplasmic alkalinization occurs upon loss of the active mechanisms for pH homeostasis in the alkalophiles, the very high buffering capacities apparently offer no global protection of internal pH. Perhaps, the high buffering capacities reflect protective mechanisms for specific macromolecules or process rather than part of the mechanisms for bulk pH homeostasis.     

Presence of a nonmetabolizable solute that is translocated with Na+ enhances Na+-dependent pH homeostasis in an alkalophilic Bacillus

The presence of a nonmetabolizable solute whose uptake is coupled to the inward translocation of Na+ has been found to enhance Na+-dependent pH homeostasis and survival of an obligately alkalophilic bacterium. Upon shift of cells of Bacillus firmus RAB from growth medium to buffers at pH 10.5, viability and maintenance of a relatively acidified cytoplasm depended upon the presence of Na+ and was augmented by the inclusion of alpha-aminoisobutyric acid in the buffer. Similarly, when cells were first equilibrated at pH 8.5 and then shifted to buffer at pH 10.5, an extraordinary capacity to maintain a relatively low pHin was exhibited, but only in the presence of Na+. In this protocol, the inclusion of alpha-aminoisobutyric acid actually resulted in an early overshoot of proton influx and also rendered a suboptimal concentration of Na+ efficacious in pH homeostasis. When a protonophoric uncoupler was added to the equilibration and shift buffers, Na+-dependent acidification of the interior was inhibited at early time points. The results support the conclusion drawn from earlier work that a Na+/H+ antiporter plays a critical role in pH homeostasis in the obligately alkalophilic bacilli. Moreover, the current findings indicate that the Na+/solute symporters are a physiologically functional pathway for completing the sodium cycle that controls pHin.