José Luis Boiardi

The carbon source influences the energetic efficiency of the respiratory chain of N2-fixing Acetobacter diazotrophicus

Acetobacter diazotrophicus is a diazotrophic bacterium that colonizes sugarcane tissues. Glucose is oxidized to gluconate in the periplasm prior to uptake and metabolism. A membrane-bound glucose dehydrogenase quinoenzyme [which contains pyrroloquinoline quinone (PQQ) as the prosthetic group] is involved in that oxidation. Gluconate is oxidized further via the hexose monophosphate pathway and tricarboxylic acid cycle. A. diazotrophicus PAL3 was grown in a chemostat with atmospheric nitrogen as the sole N source provided that the dissolved oxygen was maintained at 1.0–2.0% air saturation. The biomass yields of A. diazotrophicus growing with glucose or gluconate with fixed N were very low compared with other heterotrophic bacteria. The biomass yields under N-fixing conditions were more than 30% less than with ammonium as the N source using gluconate as the carbon source but, surprisingly, were only about 14% less with glucose. The following scheme for the metabolism of A. diazotrophicus through the different pathways emerged: (1) the respiratory chain of this organism had a different efficiency of ATP production in the respiratory chain (P:O ratio) under different culture conditions; and (2) N fixation was one (but not the sole) condition under which a higher P:O ratio was observed. The other condition appears to be the expression of an active PQQ-linked glucose dehydrogenase.

Cultural conditions required for the induction of an adaptive acid-tolerance response (ATR) in Sinorhizobium meliloti and the question as to whether or not the ATR helps rhizobia improve their symbiosis with alfalfa at low pH

Sinorhizobium meliloti associates with Medicago and Melilotus species to develop nitrogen-fixing symbioses. The agricultural relevance of these associations, the worldwide distribution of acid soils, and the remarkable acid sensitivity of the microsymbiont have all stimulated research on the responses of the symbionts to acid environments. We show here that an adaptive acid-tolerance response (ATR) can be induced in S. meliloti, as shown previously for Sinorhizobium medicae, when the bacteria are grown in batch cultures at the slightly acid pH of 6.1. In marked contrast, no increased tolerance to hydrogen ions is obtained if rhizobia are grown in a chemostat under continuous cultivation at the same pH. The adaptive ATR appears as a complex process triggered by an increased hydrogen-ion concentration, but operative only if other--as yet unknown--concomitant factors that depend on the culture conditions are present (although not provided under continuous cultivation). Although the stability of the ATR and its influence on acid tolerance has been characterized in rhizobia, no data have been available on the effect of the adapted state on symbiosis. Coinoculation experiments showed that acid-adapted indicator rhizobia (ATR+) were present in >90% of the nodules when nodulation was performed at pH 5.6, representing a >30% increase in occupancy compared with a control test. We show that the ATR represents a clear advantage in competing for nodulation at low pH. It is not yet clear whether such an effect results from an improved performance in the acid environment during preinfection, an enhanced ability to initiate infections, or both conditions. The practical use of ATR+ rhizobia will depend on validation experiments with soil microcosms and on field testing, as well as on the possibility of preserving the physiology of ATR+ bacteria in inoculant formulations.

Symbiotic phenotype of a membrane-bound glucose dehydrogenase mutant of Sinorhizobium meliloti

We have previously reported detection of significant pyrroloquinoline quinone-linked glucose dehydrogenase activity in Sinorhizobium meliloti cells isolated from alfalfa (Medicago sativa L.) nodules. In this work, we report the expression of the gcd gene (SMc00110) during root nodule development and characterize the symbiotic phenotype of S. meliloti gcd mutant RmH580. Using a S. meliloti strain carrying a gcd–lacZ transcriptional fusion, gcd expression was detected from very early stages of plant–bacteria interactions, at the rhizosphere level, and during further stages of nodule development. Alfalfa plants inoculated with RmH580 showed a delay in nodule emergence and a reduced ability for nodulation at various inoculum dosages. RmH580 was also deficient in its competitive ability; in coinoculation experiments a mutant:wild-type inoculum ratio higher than 100:1 was necessary to obtain an equal ratio of nodule occupancy. These results indicate that PQQ-linked glucose dehydrogenase is required by S. meliloti for optimal nodulation efficiency and competitiveness on alfalfa roots.

Metabolic cost of nitrogen incorporation by N2-fixingAzotobacter vinelandii is affected by the culture pH

SummaryN2-fixing continuous cultures ofAzotobacter vinellandii ATCC 9046 were carried out under various dissolved oxygen tensions (2, 25 and 50% air saturation) and, for each of these oxygen concentrations, the culture pH was controlled at 6.2 and 7.4. The culture pH exerted a profound influence on the specific consumption rates of glucose and oxygen and on the growth yields. Parallely, the total metabolic cost for N-incorporation was affected: for incorporating a given amount of N an extra glucose consumption of more than 70% took place when the culture pH was changed from 7.4 to 6.2. This effect was observed when the dissolved oxygen tension in the cultures was 25 or 50% but was less pronounced when it was 2% air saturation.

Energy Generation by Extracellular Aldose Oxidation in N2-Fixing Gluconacetobacter diazotrophicus

ABSTRACT Gluconacetobacter diazotrophicus PAL3 was grown in a chemostat with N2 and mixtures of xylose and gluconate. Xylose was oxidized to xylonate, which was accumulated in the culture supernatants. Biomass yields and carbon from gluconate incorporated into biomass increased with the rate of xylose oxidation. By using metabolic balances it is demonstrated that extracellular xylose oxidation led N2-fixing G. diazotrophicus cultures to increase the efficiency of energy generation.

The role of magnesium and calcium ions in the glucose dehydrogenase activity of Klebsiella pneumoniae NCTC 418

Magnesium-limited chemostat cultures of Klebsiella pneumoniae NCTC 418 with 20 μM CaCl2 in the medium showed a low rate of gluconate plus 2-ketogluconate production relative to potassium- or phosphate-limited cultures. However, when the medium concentration of CaCl2 was increased to 1 mM, the glucose dehydrogenase (GDH) activities also increased and became similar to those observed in potassium- or phosphate limited cultures. It is concluded that this is due to Mg2+ and Ca2+ ions being involved in the binding of pyrroloquinoline quinone (PQQ) to the GDH apoenzyme. There seems to be an absolute requirement of divalent cations for proper enzyme functioning and in this respect Ca2+ ions could replace Mg2+ ions. The high GDH activity which has been found in cells grown under Mg2−-limited conditions in the presence of higher concentrations of Ca2+ ions, is compatible with the earlier proposal that GDH functions as an auxiliary energy generating system involved in the maintenance of high transmembrane ion gradients.

A consolidated analysis of the physiologic and molecular responses induced under acid stress in the legume-symbiont model-soil bacterium Sinorhizobium meliloti.

Abiotic stresses in general and extracellular acidity in particular disturb and limit nitrogen-fixing symbioses between rhizobia and their host legumes. Except for valuable molecular-biological studies on different rhizobia, no consolidated models have been formulated to describe the central physiologic changes that occur in acid-stressed bacteria. We present here an integrated analysis entailing the main cultural, metabolic, and molecular responses of the model bacterium Sinorhizobium meliloti growing under controlled acid stress in a chemostat. A stepwise extracellular acidification of the culture medium had indicated that S. meliloti stopped growing at ca. pH 6.0–6.1. Under such stress the rhizobia increased the O2 consumption per cell by more than 5-fold. This phenotype, together with an increase in the transcripts for several membrane cytochromes, entails a higher aerobic-respiration rate in the acid-stressed rhizobia. Multivariate analysis of global metabolome data served to unequivocally correlate specific-metabolite profiles with the extracellular pH, showing that at low pH the pentose-phosphate pathway exhibited increases in several transcripts, enzymes, and metabolites. Further analyses should be focused on the time course of the observed changes, its associated intracellular signaling, and on the comparison with the changes that operate during the sub lethal acid-adaptive response (ATR) in rhizobia.

Mineral Phosphate Solubilization in Burkholderia tropica Involves an Inducible PQQ-Glucose Dehydrogenase

Fil: Bernabeu, Pamela Romina. Consejo Nacional de Investigaciones Cientificas y Tecnicas. Centro Cientifico Tecnologico Conicet - La Plata. Centro de Investigacion y Desarrollo en Fermentaciones Industriales. Universidad Nacional de la Plata. Facultad de Ciencias Exactas. Centro de Investigacion y Desarrollo en Fermentaciones Industriales; Argentina

Role of bean lectins inRhizobium phaseoli-Phaseolus vulgaris interactions. Some properties of lectins from two bean cultivars

Lectins from twoPhaseolus vulgaris L. cultivars were isolated and purified by salt fractionation, affinity chromatography and gel permeation chromatography. The cultivars used were: ‘alubia’, with a low-nodulating ability, and Bat 76 with a good symbiotic aptitude. Differences in properties of the two lectins were noted: ‘alubia’ lectin gave only one peak with haemagglutinating activity following gel permeation chromatography while Bat 76 yielded two active peaks, although both lectins had several bands of about 30 kDa following gel electrophoresis, Bat 76 lecting had three bands of about 50 kDa which were not present in ‘alubia’ and red kidney bean lectins. Peptide-mapping, by limited proteolysis and two dimensional gel electrophoresis, also showed differences between the lectins which are therefore judged to be different.