Denitrification by Azospirillum brasilense Sp 7

Nitrous oxide reduction can consistently be demonstrated with high activities in cells of Azospirillum brasilense Sp 7 which are grown anaerobically in the presence of low amounts of nitrite. Azospirillum can even grow anaerobically with nitrous oxide in the absence of any other respiratory electron acceptor. Nitrous oxide reduction by Azospirillum is inhibited by acetylene, amytal and weakly by carbon monoxide. Azospirillum converts nitrous oxide to molecular nitrogen without the formation of ammonia. The cells must, therefore, be supplied with ammonia from nitrogen fixation during anaerobic growth with nitrous oxide. When no other nitrogen compound besides nitrous oxide is available in the medium, the bacteria synthesize nitrogenase from protein reserves in about 2 h. Nitrogenase synthesis is blocked by chloramphenicol under these conditions. In contrast, the addition of nitrate or nitrite to the medium represses the synthesis of nitrogenase. Nitrous oxide reduction by Azospirillum and other microorganisms is possibly of ecological significance, because the reaction performed by the bacteria may remove nitrous oxide from soils.     

Yield responses of Nepalese spring wheat (Triticum aestivum L.) cultivars to inoculation with Azospirillum spp. of Nepalese origin

Azosprilla were collected in wheat fields from subtropical and temperate soils of central Nepal at various elevations. Different wheat cultivars responded positively and significantly in grain yield, grain N-yield, and total N-yield in plant shoots to the inoculation with Nepalese isolate Azospirillum 10SW. Nepalese wheat cv. Seto responded significantly better with Azospirillum 10SW than with the Brasilian isolate A. lipoferum Sp 108 st, a strain which was found highly efficient in earlier experiments with German wheat cultivars, especially cv. Turbo. Yield of Turbo was increased by inoculations of both Azospirillum strains too, but it showed no significant differences depending from the inoculum used. The higher efficacy of combining Azospirillum 10SW and Seto, both collected from the same locality, indicates the possibility of improved associations using traditional cultivars and local bacteria. ei]{gnR O D}{fnDixon}     

The effect of compatible and incompatible Azospirillum brasilense strains on proton efflux of intact wheat roots

The effect of two Azospirillum strains (SP-7, Dol) was compared on root proton efflux and root enlargement of three wheat cultivars (Ghods, Omid and Roshan). Root colonization varied greatly among strain–plant combinations. Inoculation enhanced proton efflux and root elongation of wheat roots but this effect was directly dependent on the strain–plant combination. Strain SP-7 stimulated the greatest proton efflux and root elongation in cv. Roshan, whereas strain Dol induced the best effect on both these phenomena in cv. Ghods. Based on positive correlation between these two phenomena, it was suggests that proton efflux is related to increasing of root length by Azospirillum inoculation. The number of bacteria of both Azospirillum strains in root of cv. Omid was less than the other cultivars. Proton extrusion and root elongation of cv. Omid failed to respond significantly with these two strains. This may be due to incompatible host-strain combination. Thus compatible strains are necessary for increasing of proton efflux and root extension in wheat cultivars.     

Colonization of wheat by Azospirillum brasilense Cd is impaired by saline stress

The effect of saline stress on the colonization of wheat was analyzed by using Azospirillum brasilense Cd carrying the fusion of the reporter gene lacZ (β-galactosidase) with the N₂ fixation gene promoter nifA. Colonization was also studied by inducing para-nodules on wheat roots using 2,4-D, establishing that these structures acted as bacterium protected niches. Bacteria grown under standard conditions were distributed along the whole root system, except the elongation zone, and colonized the para-nodules. Bacteria experiencing saline stress were mainly localized at the root tips and the lateral roots. In 2,4-D treated plants, most of the bacteria were present around the basal surface of the modified lateral root structures. Using the MPN method, there were not statistical differences between the numbers of control and stressed bacteria. As this method estimates endophytic colonization in contrast with the one using X-gal, which emphasizes colonization on the root surface, both procedures demonstrated to be necessary, concluding that salt treatment reduced surface colonization (X-gal) but not colonization inside the root. The bacterial counts made on inoculated wheat roots indicated higher numbers of both control and stressed bacteria in roots treated with 2,4-D compared with untreated roots. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effect of plant growth regulators and different nitrogen sources on NADP-isocitrate dehydrogenase activity of radish cotyledons

NADP-isocitrate dehydrogenase (NADP-ICDH) activity of radish (Raphanus sativus L.) seedlings pretreated with various plant growth regulators: KiN, GA, and ABA and different nitrogen sources viz. KNO₃, NH₄Cl and NH₄NO₃ in light and dark was investigated. ICDH activity was significantly higher in light than in dark; addition of different nitrogen sources reduced it to a greater extent in NO₃ supplementation. Among hormonal treatment only KiN showed slight promotion with KNO₃ and NH₄NO₃. On the other hand in light KNO₃ and/or NH₄NO₃ promoted ICDH activity and among hormones, KiN significantly promoted the activity in KNO₃ and NH₄NO₃ supplemented seedlings while ABA was effective in NH₄CL. It is suggested that in non-photosynthetic tissues, NADP-ICDH provides both reductant and carbon skeleton for glutamate synthesis.     

The effect of inoculation with Azospirillum brasilense on growth and nitrogen utilization by wheat plants

Azospirillium brasilense is a rhizosphere bacteria that has been reported to improve yield when inoculated on wheat plants. However, the mechanisms through which this effect is induced is still unclear. In the present work, we have studied the effects of inoculating a highly efficient A. brasilense strain on wheat plant grown in 5 kg pots with soil in a greenhouse, under three N regimes (0, 3 or 16 mM NO₃ ^–, 50 ml/pot once or twice-a -week), and in disinfected or non-disinfected soil. At the booting stage, the inoculated roots in both soils showed a similar colonization by Azospirillum sp. that was not affected by N addition. The plants grown in the disinfected soil showed a higher biomass, N content and N concentration than those in the non-disinfected soil, and in both soils the inoculation stimulated plant growth, N accumulation, and N and NO₃ ^– concentration in the tissues.At maturity, the inoculated plants showed a higher biomass, grain yield and N content than the uninoculated ones in both soils, and a higher grain protein concentration than the uninoculated. It is concluded that in the present experiments, A. brasilenseincreased plant growth by stimulating nitrogen uptake by the roots.     

The participation of the cell wall hydrolytic enzymes in the initial colonization of Azospirillum brasilense on wheat roots

The effect of cellulase and pectinase on bacterial colonization of wheat was studied by three different experiments. In the first experiment, the root colonization of 3 wheat cultivars (Ghods, Roshan and Omid) by two A. brasilense strains (Sp7 and Dol) was compared using pre-treated roots with cellulase and pectinase, and non-treated with these enzymes (control). Although the root colonization varied greatly among strain-plant combinations in controls, the pre-treatment of roots with polysaccharide degrading enzymes significantly increased the bacterial count in roots, regardless of the strain-plant combination. This might be an indication that cell wall may act as an important factor in plant-Azospirillum interaction. In the second experiment, the root cellulase activity of the same wheat cultivars treated with and without the two Azospirillum brasilense, strains (Sp7 and Dol) was compared. The pre-treatment of wheat roots with Azospirillum enhanced the cellulase activity of wheat root extracts. Thus, the cellulase activity might participate in the initial colonization of wheat roots by Azospirillum. The comparison of the cellulase activity of root extracts within inoculated and non-inoculated seedlings showed that the inoculation had enhanced the cellulase activity in root extracts, but this effect was directly dependent on the strain-plant combination. Strain Sp7 stimulated the highest cellulase activity in cv. Roshan, but strain Dol induced the highest enzyme activity in cv. Ghods. In the third experiment, several growth parameters of those 3 wheat cultivars treated with and without those two bacterial strains (Sp7 and Dol) were compared. The highest magnitude of growth responses caused by Sp7 strain was in the cv Roshan, but Dol strain stimulated the highest growth in cv Ghods. Therefore, effective colonization may contribute to more growth responses.     

Construction of an Azospirillum brasilense Sp7 recA mutant

Summary Cosmid clones encoding the recA gene of Azospirillum brasilense were isolated by intergeneric complementation of an Escherichia coli recA mutant. Site-directed Tn5 mutagenesis and subcloning of one complementing cosmid clone allowed us to localize the A. brasilense recA gene on a 1.2 kb DNA fragment. One Tn5 insertion that inactivates the cloned recA gene was crossed into the chromosome of A. brasilense by marker exchange. The resulting A. brasilense recA mutant showed increased sensitivity to the DNA methylating agent methyl methanesulfonate and to ultraviolet light and had at least one hundredfold reduced recombinational activity compared to the parent strain.     

Effects of plant growth regulators on secondary wall thickening of cotton fibres

The effect of plant growth regulators on the secondary wall thickeningof cotton fibre was studied. The results indicated that the GA_S andiP+iPA levels in the fibre of field-grown cotton plantsremained almost constant but the IAA and ABA levels changed considerably duringfibre development. Although the change in both IAA and ABA levels seemed not tobe closely related with the rate of cellulose accumulation, there was still arelationship between the ratio of ABA to IAA and secondary wall thickening. Inin vitro studies, ABA (50mol·L^–1) markedly enhanced theaccumulation of dry matter and cellulose in the fibre cell wall duringsecondarywall thickening, but no similar effect was observed with NAA, GA₃ orkinetin treatments. The role of ABA in secondary wall thickening of cottonfibreis discussed.     

Energy transduction efficiencies in nitrogenous oxide respirations of Azospirillum brasilense Sp7

For Azospirillum brasilense Sp7, the energy transformation efficiencies were measured in anaerobic respirations with either nitrate, nitrite or nitrous oxide as respiratory electron acceptors by determining the maximal molar growth yields and the H⁺-translocations using the oxidant pulse method. In continuous cultures grown with malate limiting, the maximal molar growth yields (Y _s ^max -values) were essentially the same with O₂ or N₂O but were 1/3 and 2/3 lower with NO ₂ ^- or NO ₃ ^- , respectively, as respiratory electron acceptors. Both the maximal molar growth yields and the maintenance energy coefficients were surprisingly high when Azospirillum was grown with nitrite as the sole electron acceptor and source for N-assimilation. Growth under N₂-fixing conditions drastically reduced the Y _s ^max -values in the N₂O and O₂-respiring cells. In the H⁺-translocation measurements, the /oxidant ratios were 5.6 for O₂→H₂O, 2.5–2.8 for NO ₃ ^- →NO ₂ ^- , 2.2 for NO ₂ ^- →N₂O and 3.1 for N₂O→N₂ respirations when the cells were preincubated with valinomycin and K⁺. All the values were enhanced when the experiments were performed with valinomycin plus methyltriphenylphosphonium (=TPMP⁺) cation. The uncoupler carbonyl cyanide-m-chlorophenyl-hydrazone diminished the H⁺-excretion indicating that this translocation was due to vectorial flow across the membrane. In the absence of any ionophore, nitrate and nitrite respirations were accompanied by a H⁺-uptake . Any significant H⁺-translocation could not be detected in N₂O- and O₂-respirations under these conditions. It is concluded that nitrate reduction proceeds inside the cytoplasmic membrane, whereas nitrite is reduced extramembraneously. The data are not conclusive for the location of nitrous oxide reductase. The maximal molar growth yield determinations and the absence of any H⁺-uptake in untreated cells indicate a cytoplasmic orientation of the enzyme similar to the terminal cytochrome oxidase of respiration. The low H⁺-extrusion values for N₂O-respiration compared to O₂-respiration in cells treated with valinomycin plus TPMP⁺ are, however, not in accord with such an interpretation.     

不同植物生长调节剂对小麦衰老及产量构成的调节效应

研究了叶面喷施GA3、NBT、6－BA、TIBA、PP333对小麦旗叶衰老过程中若干生理指标的影响,分析了它们对成产要素的不同作用。结果表明：不同生长调节剂可以以不同的方式调节小麦旗叶的衰老,影响小麦产量构成因素水平。其中6－BA和PP333能够提高单位面积穗数,明显延缓叶片衰老,增加了穗粒数和千粒重,使成产3因素间比例协调合理,产量较高;TIBA可以明显提高叶绿素含量并显著提高千粒重。GA3和NBT对延缓旗叶衰老有一定作用,但增产效果不显著。研究指出,根据小麦生育状况有选择性地使用生长调节剂,协调成产因素关系,是一个有效的增产途径。     

Habituation of plant cells does not mean insensitivity to plant growth regulators

Summary Fully habituated organogenic and nonorganogenic sugarbeet calluses reacted to application of the synthetic auxin [3-benzo(b) selenienyl] acetic acid by changes in growth and ethylene production. Treatment of fully habituated cells of periwinkle with 2,4-dichlorophenoxyacetic acid led to the decrease of free cytokinin contents (isopentenyl adenine, zeatin riboside, and zeatin) during the late exponential phase of growth. The polyamine contents were also modified and the capacity to biotransform secologanin into ajmalicine was decreased. Treatment of the habituated periwinkle cells with zeatin greatly increased the amount of a polypeptide of 16 kDa; this response was more marked than that displayed by the auxin-dependent line. These data show that hormone-independent calluses and cell suspensions can retain some sensitivity to growth hormones. However, differences of responses were observed between the auxin-dependent lines and the habituated lines.     

An Azospirillum brasilense Tn5 mutant with modified stress response and impaired in flocculation

The analysis of an A. brasilense Tn5 mutant shows significant phenotypic differences compared to the wild type isogenic strain. The transposon was located disrupting an open reading frame of 840 bp (ORF280) which exhibits similarity to the universal stress protein (USP) family. The USP family encompasses proteins that are expressed as a response to cell growth arrest. The mutant revealed a pleiotrophic phenotype with respect to different stress conditions. The ORF mutation results in an increased sensitivity of cells to carbon starvation and heat-shock treatment. However, the mutant strain displays a higher tolerance to oxidative stress agents. In contrast to the isogenic parent strain, colonies of the mutant are weakly stained by Congo red added to solid media and are impaired in flocculation. Scanning electron micrographs revealed that the mutant lacks part of the surface material present as a thick layer of exopolysaccharides on the surface of the wild type cells. The pleiotrophic phenotype revealed for this mutant and the similarity of the C-terminal region of ORF280 to UspA from E. coli indicates that the A. brasilense ORF280 may be a Usp-like protein. This revised version was published online in June 2006 with corrections to the Cover Date.     

Nitrogen fixation inpara-nodules of wheat roots by introduced free-living diazotrophs

Nitrogen-fixation (C₂H₂-reduction) was demonstrated in wheat root nodules (p-nodules) induced by 2,4-dichlorophenoxyacetate (2,4-D) and inoculated withA. brasilense. By lowering the O₂ tension it was possible to distinguish the nitrogenase activity of bacteria located within thep-nodule of the wheat root system from that in the rhizosphere. Using cytological evidence, nitrogenase activity was attributed mainly to be coming from the bacteria within thep-nodule. It was also shown that the host plant was able to supply the necessary substrate required for the bacterial N₂-fixation (C₂H₂-reduction) within thep-nodules.     

Plant growth regulators and amino acids released by Azospirillum sp in chemically defined media

AIMS: To investigate the ability of Azospirillum sp., a facultative endophitic diazotrophic bacterium, to release plant growth regulators (PGR) such as polyamines, ethylene, indoleacetic acid and amino acids in both combined-N and N-free cultures. METHODS AND RESULTS: The presence of those substances was analysed by HPLC. Azospirillum sp. is capable of releasing PGR and amino acids into the culture medium. CONCLUSIONS: The type and quantity of the released substances varied, depending on the presence of combined-N in the medium. SIGNIFICANCE AND IMPACT OF THE STUDY: A better knowledge of PGR produced by Azospirillum sp. has been gained.     

An alternative explanation for plant growth promotion by bacteria of the genus Azospirillum

Experiments were performed to identify the substances that are excreted by the soil bacterium Azospirillum brasilense Sp7 and that were reported to stimulate the formation of lateral roots and of root hairs of grasses. Azospirillum forms indole-3 acetic acid (IAA) but only in the late stationary growth phase or when tryptophan is present in the medium, but not in continuous cultures or in the logarithmic growth phase of batch cultures. Formation of IAA by Azospirillum requires aerobic conditions. Nitrite can replace IAA in several phytohormone assay, and is even more active than IAA in a test with wheat root segments in which the increase of wet weight is determined. Higher amounts of nitrite are necessary for activity in other classical auxin assays. Nitrite shows 40–60% of the activity of IAA in the straight-growth test of Avena coleoptiles and in the formation of C₂H₄ by pea epicotyl segments. Like IAA, nitrite is inactive in promoting C₂H₄ formation by ripe apple tissues. Since nitrite alone can hardly exert phytohormonal effects, it is postulated that nitrite reacts with a substance in the cells and that a product formed by this reaction functions as auxin. Such a substance could be ascorbate. Exogenously added ascorbate enhances the rate of nitrite-dependent C₂H₄ formation by pea epicotyl sections and the nitrite-dependent increase in the wet weight of wheat root segments. Nitrite is formed by nitrate respiration of Azospirillum. The findings that nitrite can have phytohormonal effects offers an alternative explanation of the promotion of the growth of roots and the enhancement of mineral uptake of grasses by Azospirillum. Indole-acetic acid completely and nitrite partly substitute for an inoculation with Azospirillum in an assay where the increase of the dry weight of intact wheat roots is determined after an incubation for 10 d. Nitrite and IAA are, therefore, possibly the only factors causing an enhancement of the growth of roots of grasses.Abbreviations HPLC high-performance liquid chromatography - IAA indole-3-acetic acid     

Effect of nitrogen supply and Azospirillum brasilense Sp-248 on the response of wheat to seawater irrigation

Response of wheat to Azospirillum brasilense Sp-248 inoculation with different N-fertilizer levels using seawater irrigation was investigated. All inoculated treatments increased plant height, shoot and root dry weight, and tiller number in compared with uninoculated treatments. Yield parameters measured were also increased due to the inoculation. In terms of the effect of saline irrigation, there were no significant differences in growth and yield parameters in plants treated with tap water and others irrigated with 8.0% seawater concentration. This would indicate a relatively high tolerance of A. brasilense to saline irrigation and its ability to reduce the deleterious effects of saline on growth by increasing the plant’s adaptation. However, increasing the seawater concentration in the irrigation water to 16.0% significantly decreased all tested parameters. Inoculation treatments generally increased NPKCa contents and decreased sodium ratio of the grains in compared with the uninoculated treatments. Overall results clearly revealed that the Azospirillum inoculation saved about 20 units of N-fertilizer and that saving was made economically feasible by decreasing the chemical fertilizers needed, improving the nitrogen content and counteracting the effects of salinity.     

The interface between the cell cycle and plant growth regulators: a mini review

The aim was to review knowledge about the interface betweenplant growth regulators and molecular checkpoints of the cell cycle. Atwhat level of biochemical regulation of the cell cycle do plant growthregulators interface? Are there different levels of interfacingdependent on the plant growth regulator involved? As a preamble totackling these questions, we overview the eukaryotic cell cycle withparticular emphasis on checkpoints that regulate the transition fromG0-G1-S-phase and G2-M. Cytokinins feature strongly as activators ofcell division in plants both in vivo and in vitro.Recent research has shown that zeatin treatment led to the up-regulationof CycD3 in Arabidopsis. This is a D-type cyclin showing stronghomology with vertebrate D cyclins which themselves are up-regulated byextracellular growth factors. Benzyladenine treatment can also shortenthe duration of S-phase through recruitment of latent origins of DNAreplication. Kinetin is involved in the phosphoregulation of the G2-Mcheckpoint; the major cyclin-dependent kinase (Cdk) at this checkpointhas recently been shown to be dephosphorylated as a result of cytokinintreatment, an effect which can also be mimicked by the fission yeastCdc25 phosphatase. Hence, a picture emerges of a cytokinin-inducedcontinuum of cell cycle activation through the up-regulation of a plantD-type cyclin at the G1 checkpoint and the phosphoregulation of the Cdkat the G2/M checkpoint. During S-phase, we argue for a link betweencytokinins and the proteins associated with replication origins.Gibberellic acid (GA) treatment induces internode elongation. Indeepwater rice, this response is mediated, at least partly, by aGA-induced up-regulation of a cyclin-Cdk at the G2-M checkpoint. Recentevidence has also linked abscisic acid to a cyclin-dependent kinaseinhibitor. These, so-called CKIs are negative regulators of Cdks whichfits with ABA's general role in growth inhibition; we await news ofethylene interactions. We highlight two instances of plant growthregulator-cell cycle interfacing during development, arguing for aninvolvement in microtubule orientation as a prerequisite to leafinitiation, and suggest a link between IAA and the activation of celldivisions in the pericycle required for lateral root initiation. A newD-type cyclin, recently discovered in Arabidopsis, may have akey role in this process. Finally, a model is presented which features ageneralised cyclin-Cdk checkpoint exhibiting various interfaces with theplant growth regulators.     

Field release of genetically marked Azospirillum brasilense in association with Sorghum bicolor L.

The agronomic impact of genetically tagged azospirilla (Azospirillum brasilense)was assessed in open field and their fluctuation were monitored in the soil/rhizosphere. Strain performance, upon inoculation of sorghum, was evaluated over a two-years period; agronomic treatments included nitrogen application (0, 80, 160 kg ha^–1), and types of inoculant (Sp245 lacZ, Sp6 gusA, Sp6 IAA⁺⁺ gusA). Grain yield was higher for inoculated seed plots than in non-inoculated ones, whereas nitrogen content, biomass of plant residues and nitrogen in plant residues gave values that were not statistically different. Root length density (RLD) of sorghum at the end of the stem elongation stage was affected only by the indole-3-acetic acid (IAA) overproducer Azospirillum strain (A. brasilense Sp6 IAA⁺⁺ gusA) with respect to the normal IAA producer (A. brasilense Sp6 gusA), being higher in the first 40 cm of depth, notwithstanding the level of nitrogen fertilization. The traceability of the released genetically modified strains enabled to monitor their ability to colonise soil and roots. Moreover, the genetic modification per se vs. the non-modified counterpart, did not affect the culturable aerobic population in soil, microfungi, streptomycetes, fluorescent pseudomonads, soil microbial biomass, or some microbial activities, all selected as important indicators.