Wheat inoculation with Azospirillum brasilense Sp6 and some mutants altered in nitrogen fixation and indole-3-acetic acid production

Abstract Inoculation of wheat seedlings with Azospirillum brasilense Sp6 produced an increase in the number and length of the lateral roots as a plant response. Inoculation with a Nif⁻ mutant, A. brasilense SpF103, which is producer of indole-3-acetic acid (IAA), yielded a very similar plant response. However, inoculation with a Nif⁻ mutant, A. brasilense SpF57, which is a low producer of IAA, did not elitic any response from the plant. The data suggest that the root system response of wheat seedlings to bacterial inoculation is due mainly to production of auxin-type substances by the microorganism.     

A critical evaluation of the prospects for nitrogen fixation with non-legumes

Some twenty years ago many speculations were made about possibilities to improve the use of the well-known nitrogen-fixing plant symbioses and to extend the use of atmospheric nitrogen to the most important agricultural plants, like cereals. Since then our understanding of the molecular biology of nitrogenase and the symbiotic interactions during root nodule formation and activity enable a reconsideration of these original speculations. Besides the possibilities for better practical use of the existing systems some more far-reaching speculations will be discussed: the introduction ofnif genes into cells of higher plants, the extension of the host range ofRhizobium orFrankia and the possibilities to transform rhizosphere bacteria, likeAzospirillum, into more efficient endosymbionts. In all cases it will be evident that the more we know, the more we realize what we still have to understand.     

Growth promoting effect of Azospirillum brasilense on Casuarina cunninghamiana Miq. seedlings

The growth of Casuarina cunninghamiana seedlings was stimulated when inoculated with Azospirillum brasilense. This resulted in a higher biomass production than in uninoculated controls in the presence or absence of a non-nodulating strain of Frankia.Increase in whole plant dry weight was due to a significant increase in both shoot and root biomass, which corresponded with a higher total N content of the plants inoculated with Azospirillum. No such effects were observed under inoculation with a non-nodulating Frankia strain. These results suggest that the growth-promoting substances provided by A. brasilense may have enhanced the growth of Casuarina seedlings.     

Effect of soil organic matter on chickpea inoculated withAzospirillum brasilense andRhizobium leguminosarum bv.ciceri

Azosprillum inoculated withRhizobium improved the nodulation of chickpea-Cicer arietinum. This interaction was further enhanced by organic matter present in the growth medium.     

Active attachment ofAzospirillum brasilense to root surface of non-cereal plants and to sand particles

The rhizosphere bacteriumAzospirillum brasilense Cd adsorbed strongly to light-textured and heavy-textured soils, but only slightly to quartz sand. Bacterial attachment to sand particles was mediated by a network made up of various sizes and shapes of fibrillar material. Inoculation of sand with an aggregate-deficient mutant resulted in no detectable fibrillar formation. Rinsing or agitating the sand, colonized by the wild-type and the mutant, had a greater effect on the mutant than on the parental strain. We propose that bacterial fibrils are essential for anchoring ofA. brasilense to sand. A. brasilense Cd was capable of efficiently colonizing the elongation and root-hair zones of tomato, pepper, cotton and soybean plants as well as of wheat plants. All inoculated plants demonstrated: (i) larger amounts of a mucigel-like substance on the root surface than non-inoculated plants, and (ii) fibrillar material which anchored the bacterial cells to the root surface. These fibrils established also connections between cells within bacterial aggregates. On non-water stressed soybean roots, mostA. brasilense Cd cells occurred as vibroid forms. Whereas, those on roots of water-stressed plants.(wilting) were cyst-like. A lower rhizosphere bacterial population was observed on water-stressed plants. When water stress conditions were eliminated, cells reverted to the vibroid form. A concomitant increase in the bacterial population was observed. We suggest that cyst-like formation is a natural response forA. brasilense Cd in the rhizosphere of water-stressed plants.     

Response to oxygen of diazotrophic Azospirillum brasilense — Arthrobacter giacomelloi mixed batch culture

Azospirillum brasilense and Arthrobacter giacomelloi were grown together in batch culture under different oxygen pressures. The response to oxygen of growth, nitrogenase activity and respiration rate was determined. The two microorganisms were found to be able to coexist all over the range of partial oxygen pressures examined, that is from 0.004–0.20 bar. Nitrogenase activity by mixed culture of A. brasilense and A. giacomelloi always appeared higher than that of A. brasilense pure culture. Low respiratory activity at partial oxygen pressures higher than 0.02 bar by both pure and mixed cultures seemed not to account for the high nitrogenase activity and improved oxygen tolerance of the mixed culture.Abbreviations pO₂ partial oxygen pressure     

Occurrence of nitrogen-fixing Azospirillum in vesicular-arbuscular mycorrhizal fungi

Nitrogenase activity measured by acetylene reduction, was detected when surface-sterilized spores of vesicular-arbuscular (VA) mycorrhizal fungi (Glomus fasciculatum, G. intraradices, G. scientillans, G. mosseae, Gigaspora gilmorei andEndogone dusii) were inoculated into nitrogen-free liquid medium containing malic acid and incubated under microaerophilic conditions (99% N₂+1% O₂) at 30°C.Azospirillum species were isolated from the nitrogenase-active cultures.     

The Role of Wheat Germ Agglutinin in Plant–Bacteria Interactions: A Hypothesis and the Evidence in Its Support

Wheat plants are known to develop the associative symbiosis with the rhizobacterium Azospirillum brasilense.We studied the interaction of a lectin, wheat germ agglutinin (WGA), which is also found in wheat roots, with A. brasilense, strain sp245. When added to the azospirillum culture to the final concentration of 10^–8to 10^–9M, WGA enhanced IAA production, dinitrogen fixation, and ammonium excretion by bacterial cells. WGA also promoted the synthesis of proteins, both new and those already present in bacterial cells. The hypothesis that WGA is a signal molecule rerouting the bacterial metabolism in the direction favorable for the growth and development of the host plant has been put forward. It is suggested that signal properties of WGA are the basis for one of the functions of this lectin and essential for the effective associative symbiosis.     

Alterations in membrane potential and in proton efflux in plant roots induced byAzospirillum brasilense

Inoculation of soybean seedlings withAzospirillum brasilense Cd significantly reduced the membrane potential in every root part and was being maximal in the root elongation zone. Monitoring the proton efflux pattern of inoculated wheat roots by severalA. brasilense strains and byPseudomonas sp. for prolonged periods (up to 200h) revealed a change from the bimodal pattern of proton efflux of non inoculated roots. This change was not related to root colonization ability but to bacterial capacity to induce changes in root surface area. Continuous perfusion of the plant nutrient solution with a fresh solution (from inoculation time), eliminated the enhancing effect of inoculation on proton efflux. We propose thatA. brasilense inoculation influences membrane activity and subsequently proton efflux in roots, probably through the release of an as yet unidentified bacterial signal.     

Identification of Azospirillum strains by restriction fragment length polymorphism of the 16S rDNA and of the histidine operon

Abstract DNA fingerprints of several Azospirillum strains, belonging to the five known species A. amazonense, A. brasilense, A. halopraeferens, A. irakense and A. lipoferum , were obtained by restriction analysis of the amplified 16S rDNA and by restriction fragment length polymorphism of the histidine biosynthetic genes. Data obtained showed that amplified rDNA restriction analysis is an easy, fast, reproducible and reliable tool for identification of Azospirillum strains, mainly at the species level, whereas restriction fragment length polymorphism could, in some cases, differentiate strains belonging to the same species. Moreover, both analyses gave congruent results in grouping strains and in the assignment of new strains to a given species.