Characterization ofAzotobacter spp. and effect of Azotobacter and Azospirillum as inoculant on the yield and N-uptake of wheat crop

Out of ten isolates ofAzospirillum spp. isolated from the root and rhizosphere of wheat plant, seven belonged toA. brasilense and three belonged toA. lipoferum. All eight isolates ofAzotobacter spp. belonged toAzotobacter chroococcum. Two strains, one fromA. lipoferum and another fromA. chroococcum having high nitrogen fixing capacity with negative test for denitrification were used as inoculant to supplement the nitrogen need of wheat crop. Significant increases in the yield of wheat grain and uptake of nitrogen by the crop over the control were found in pot tests when the seeds were inoculated either withAzospirillum spp. orAzotobacter spp. or the combination of both the inoculants.     

Field inoculation of sorghum and rice withAzospirillum spp. andHerbaspirillum seropedicae

Two field experiments were carried out at the UAPNPBS experimental station, Seropédica, with two sorghum and one rice cultivars. The establishment, and inoculation effects, ofAzospirillum spp. andHerbaspirillum strains marked with antibiotic resistance were investigated. One grain sorghum (BR 300) and one sugar sorghum (Br 505) cultivar were used.Azospirillum lipoferum strain S82 (isolated from surface sterilized roots of sorghum) established in both cultivars and comprised 40 to 80% of theAzospirillum spp. population in roots and stems 60 days after plant emergence (DAE).Azospirillum amazonense strain AmS91 (isolated from surface-sterilized roots of sorghum) reached only 50%. At 90 DAE, S82 almost disappeared (less than 30% of establishment) while the establishment of AmS91 remained constant in roots and stems. No establishment ofH. seropedicae strain H25 (isolated from surface-sterilized roots of sorghum) orA. lipoferum strain S65 (isolated from the root surface of sorghum) could be observed on inoculated roots. Inoculation with S82, AmS91 or S65 but not withH. seropedicae H25, increased plant dry weight of both cultivars and total N in grain of the grain sorghum. In rice,A. lipoferum Al 121 andA. brasilense Sp 245 (isolated from surface sterilized rice and wheat roots respectively) established in the roots but there was no increase inAzospirillum spp. numbers due to inoculation. None of the strains affected plant growth or rice grain yield.Azospirillum amazonense, A82 andH. seropedicae Z95, which did not establish in roots, significantly enhanced seed germination.     

Establishment of inoculatedAzospirillum spp. in the rhizosphere and in roots of field grown wheat and sorghum

Summary Four field experiments were carried out with wheat or sorghum in different regions of Brazil. The aim was to study the establishment of inoculatedAzospirillum strains, marked with resistance to various antibiotics, in the rhizosphere and in roots. The levels of the various antibiotics were chosen according to the resistance of the indigenousAzospirillum population.Azospirillum brasilense strains Sp 107 and Sp 245 could be established in all three wheat experiments and predominated within theAzospirillum population in washed, and especially in surface sterilized, roots. Strains Sp 7 and Cd established poorly in wheat roots.Azospirillum lipoferum Sp S82 represented 72% of the root isolates from sorghum inoculated with this strain. This strain and naturalAzospirillum infection became concentrated in the upper parts of the root system. Improved methods for root surface sterilization in which the absence ofAzospirillum on the root surface was established by pre-incubating roots with paraffin-capped ends in NFb medium confirmed the establishment of inoculatedAzospirillum strains within sorghum roots in the field.     

Ecophysiological aspects of growth and nitrogen fixation inAzospirillum spp.

The nitrogenase activity ofAzospirillum spp. is efficiently regulated by environmental factors. InA. brasilense andA. lipoferum a rapid switch off of nitrogenase activity occurs after the addition of ammonium chloride. As in photosynthetic bacteria, a covalent modification of nitrogenase reductase (Fe-protein) is involved. InA. amazonense, a non-covalent mechanism causes only a partial inhibition of nitrogenase activity after ammonium chloride is added. In anaerobic conditions, nitrogenase reductase is also switched off by a covalent modification inA. brasilense andA. lipoferum. Short-time exposure ofAzospirillum to increased oxygen levels causes a partially reversible inhibition of nitrogenase activity, but no covalent modification is involved.Azospirillum spp. show variations in their oxygen tolerance. High levels of carotenoids confer a slightly improved oxygen tolerance. Certain amino acids (e. g. glutamate, aspartate, histidine and serine) affect growth and nitrogen fixation differently inAzospirillum spp. Amino acids may influence growth and nitrogen fixation ofAzospirillum in the association with plants.Azospirillum brasilense andA. halopraeferens are the more osmotolerant species. They utilize most amino acids poorly and accumulate glycine betaine, which also occurs in osmotically stressed grasses as a compatible solute to counteract osmotic stress. Nitrogen fixation is stimulated by glycine betaine and choline. Efficient iron acquisition is a prerequisite for competitive and aerotoleran growth and for high nitrogenase activity.Azospirillum halopraeferens andA. amazonense assimilate iron reasonably well, whereas growth of someA. brasilense andA. lipoferum strains is severely inhibited by iron limitation and by competition with foreign microbial iron chelators. However, growth of certain iron-limitedA. brasilense strains is stimulated by the phytosiderophore mugineic acid. Thus, various plant-derived substances may stimulate growth and nitrogen fixation ofAzospirillum.     

Adsorption and anchoring of Azospirillumstrains to roots of wheat seedlings

Recent microscopic evidence acquired using strain-specific monoclonal antibodies and specific gene probes confirms earlier claims that some strains of Azospirillum lipoferum and A. brasilense, but not others, are capable of infecting the interior of wheat roots. The present study was performed to determine whether this strain specificity in the infection of the interior of wheat roots was apparent in the first 24 h of adsorption (`anchoring') of Azospirillum cells to the root surface. Strains of A. brasilense, originally isolated from surface-sterilised wheat roots (Sp 245, Sp 107) or with a proven ability to infect the interior of wheat roots (Sp 245), showed no greater ability to anchor to the roots than other Azospirillum strains isolated from the wheat rhizosphere (Sp 246) or from the rhizosphere or rhizosphere soil of other gramineae (Sp 7, Cd, S 82). The SEM images showed that at the root tip the Azospirillum cells were principally located in cracks between epidermal cells. In the root hair zone the bacteria were more numerous but again principally located in the depressions between epidermal cells. In all zones of the roots mucilage was present, and near the tip this appeared to have been partially digested, forming `halos' around the bacteria and revealing fibril-like strands attached to the bacteria. Subsequent studies were conducted using a technique originally developed for investigating competition of rhizobia for adsorption sites on legume roots. In the adaptation of this technique it was found that the presence of any significant concentration of Ca⁺⁺ in the incubation medium reduced bacterial adsorption, as did concentrations of (PO₄)^3- above 50 mM. The influence of the pH of the incubation medium on the adsorption of ten different strains of Azospirillum showed, that with one exception, strains isolated from the roots or rhizosphere of wheat showed optimum adsorption at pH 6.0, and all other strains pH 7.0. Apart from this effect of pH no differences in adsorption were detected between strains with a proven capacity to infect wheat roots and those unable to do so. However, strains varied in their capability to compete for adsorption sites, there being a tendency for strains with a proven capacity to invade the internal tissues of wheat roots to be more competitive for adsorption sites.     

Chemotaxis of Azospirillum Species to Aromatic Compounds

Chemotaxis of Azospirillum lipoferum Sp 59b and Azospirillum brasilense Sp 7 and Sp CD to malate and to the aromatic substrates benzoate, protocatechuate, 4-hydroxybenzoate, and catechol was assayed by the capillary method and direct cell counts. A. lipoferum required induction by growth on 4-hydroxybenzoate for positive chemotaxis to this compound. Chemotaxis of Azospirillum spp. to all other substrates did not require induction. Maximum chemotactic responses for most aromatic compounds occurred at concentrations of 1 to 10 mM for A. lipoferum and 100 μM to 1 mM for A. brasilense. Threshold levels of these chemoattractants ranged from nanomolar to micromolar, with A. brasilense Sp CD showing the lowest threshold levels for the substrates tested. Benzoate was the strongest chemoattractant tested, with threshold concentrations in the nanomolar to picomolar range for all strains. Azospirillum spp. clearly have more sensitive chemosensory mechanisms for certain aromatic substrates than previously reported in some other soil bacteria. This sensitivity allows Azospirillum spp. to detect and respond to aromatic substrates at concentrations relevant to the soil and rhizosphere environments. The ability to detect such low concentrations of aromatic compounds in soils may confer advantages in survival and colonization of the rhizosphere by Azospirillum species.     

Soil and litter respiration rates in different microhabitats of a mixed oak-conifer forest and their control by edaphic conditions and substrate quality

Summary Seven isolates belonged toA. brasilense and 3 belonged toA. lipoferum. Isolates having more denitrifying capacity fixed less nitrogen in nitrogen free semi-solid malate medium. One strain ofA. lipoferum having high nitrogen fixing capacity with negative test for denitrification was tested as inoculant to supplement the nitrogen need of a wheat crop in field condition with different doses of N with and without the inoculant. While control without nitrogen yielded 1260 kg/ha the yield in inoculated treatment was 2070 kg/ha resulting in significant increase. In a treatment receiving 40 kg N/ha the grain yield was 2370 kg/ha as against yield of 3110 kg/ha in a similar treatment receiving fertiliser plus inoculant. Thus increase in yield was about 30%. Further the treatment receiving 80 kg N/ha yielded 2970 kg/ha as against yield of 4150 kg/ha in a treatment receiving inoculant alongwith the above dose of the fertiliser. Thus increase in yield due to application of inoculant was about 36%. Similarly, the uptake of N in different treatments was augmented due to inoculation of seeds with the culture.     

Acetylene reduction and indoleacetic acid production by Azospirillum isolates from Cactaceous plants

Azospirillum isolates were obtained from rhizosphere soil and roots of three cactaceae species growing under arid conditions. All Azospirillum isolates from rhizosphere and roots ofStenocereus pruinosus andStenocereus stellatus were identified asA. brasilense; isolates of surface-sterilized roots fromOpuntia ficus-indica were bothA. brasilense andA. lipoferum. Azospirilla per g of fresh root in the three species ranged from 70×10³ to 11×10³. The most active strains in terms of C₂H₂ reduction (25–49.6 nmol/h·ml) and indoleacetic acid (IAA) production (36.5–77 μg/ml) were those identified asA. brasilense and isolated from Stenocereus roots.A. lipoferum isolated from Opuntia roots produced low amounts of IAA (6.5–17.5 μg/ml) and low C₂H₂-reduction activity (17.8–21.2 nmol/h·ml).     

The phytohormonal interactions betweenAzospirillum and wheat

A simple model system was designed to detect positive effects ofAzospirillum on the root growth of cereals. Cultures ofA. brasilense Sp7 andA. lipoferum Sp59 did not excrete gibberellins and cytokinins in the logarithmic and in the early stationary growth phase. Indoleacetic acid (IAA) was formed, however, only in the stationary phase of the cultures. The addition of D,L-tryptophan to the medium enhanced the formation of IAA. A further, still unidentified substance was produced byAzospirillum under denitrifying conditions in the logarithmic growth phase. The substance was almost twice as active as IAA in increasing the wet weight of wheat root segments. It is suggested that this unidentified substance is the major stimulus affecting the growth of cereals.Dedicated to Professor E.-G. Niemann, Hannover, on the occasion of his 60th birthday.     

Chemotaxis of free-living nitrogen-fixing bacteria towards maize mucilage

Summary A method for collecting sterile mucilage from maize root tips growing in sterile conditions has been devised.Enterobacter andAzospirillum strains were isolated from the rhizosphere of maize and rice using the spermosphere model method. To evaluate chemotaxis of these strains, a modification of Adler's microcapillary method was used. Under these conditions, the number of attracted bacteria was proportional to the concentration of mucilage. When comparing the chemotaxis ofA. lipoferum andE. cloacae from the rhizosphere of maize and from the rhizosphere of rice, it appeared that the strains isolated from maize were strongly attracted by maize mucilage whereas strains isolated from rice were not more attracted than the control (E. coli K12). Thus, bacteria of the same species are not equivalent in their chemotactic behaviour. This could imply that some degree of specificity exists in the establishment of plant-bacteria associations.     

Salinity stress responses in the plant growth promoting rhizobacteria,Azospirillum spp

In order to adapt to the fluctuations in soil salinity/osmolarity the bacteria of the genusAzospirillum accumulate compatible solutes such as glutamate, proline, glycine betaine, trehalose, etc. Proline seems to play a major role in osmoadaptation. With increase in osmotic stress the dominant osmolyte inA. brasilense shifts from glutamate to proline. Accumulation of proline inA. brasilense occurs by both uptake and synthesis. At higher osmolarityA. brasilense Sp7 accumulates high intracellular concentration of glycine betaine which is taken up via a high affinity glycine betaine transport system. A salinity stress induced, periplasmically located, glycine betaine binding protein (GBBP) of ca. 32 kDa size is involved in glycine betaine uptake inA. brasilense Sp7. Although a similar protein is also present inA. brasilense Cd it does not help in osmoprotection. It is not known ifA. brasilense Cd can also accumulate glycine betaine under salinity stress and if the GBBP-like protein plays any role in glycine betaine uptake. This strain, under salt stress, seems to have inadequate levels of ATP to support growth and glycine betaine uptake simultaneously. ExceptA. halopraeferens, all other species ofAzospirillum lack the ability to convert choline into glycine betaine. Mobilization of thebet ABT genes ofE. coli intoA. brasilense enables it to use choline for osmoprotection. Recently, aproU-like locus fromA. lipoferum showing physical homology to theproU gene region ofE. coli has been cloned. Replacement of this locus, after inactivation by the insertion of kanamycin resistance gene cassette, inA. lipoferum genome results in the recovery of mutants which fail to use glycine betaine as osmoprotectant.     

Nitrogenase activity and nitrate respiration inAzospirillum spp.

The interaction between nitrate respiration and nitrogen fixation inAzospirillum lipoferum andA. brasilense was studied. All strains examined were capable of nitrogen fixation (acetylene reduction) under conditions of severe oxygen limitation in the presence of nitrate. A lag phase of about 1 h was observed for both nitrate reduction and nitrogenase activity corresponding to the period of induction of the dissimilatory nitrate reductase. Nitrogenase activity ceased when nitrate was exhausted suggesting that the reduction of nitrate to nitrite, rather than denitrification (the further reduction of nitrite to gas) is coupled to nitrogen fixation. The addition of nitrate to nitrate reductase negative mutants (nr^-) ofAzospirillum did not stimulate nitrogenase activity. Under oxygen-limited conditionsA. brasilense andA. lipoferum were also shown to reduce nitrate to ammonia, which accumulated in the medium. Both species, including strains ofA. brasilense which do not possess a dissimilatory nitrite reductase (nir^-) were also capable of reducing nitrous oxide to N₂.     

Transfer of an insecticidal protein gene ofBacillus thuringiensis into plant-colonizingAzospirillum

A fusion plasmid, pRKC, was constructed, using pACYC184, RSF1010 and a kanamycin-resistance cartridge from pUC4K, to convey thecryIA(a) gene intoAzospirillum spp. With the pRKC plasmid, the number of putative transconjugants obtained inA. lipoferum was about 300-fold higher than inA. brasilense. Conjugation frequency and plasmid stability inA. lipoferum were less for pBTF8, which carries thecryIA(a) gene in the correct orientation for a constitutive promoter, than for pBTF9, which carries the gene in the opposite orientation. Expression of thecryIA(a) gene was not apparent in SDS-PAGE analysis ofA. lipoferum transconjugants harbouring pBTF8. However,Escherichia coli transformants with the pBTF8 rescued fromA. lipoferum transconjugants produced an approximately 135 kDa Cry protein, indicating that thecry gene is intact in the transconjugants.V. Udayasuriyan was and A. Nakamura, H. Masaki and T. Uozumi are with the Department of Biotechnology, Faculty of Agriculture, The University of Tokyo, Yayoi 1-1-1, Bunkyo-Ku, Tokyo 113, Japan; V. Udayasuriyan is now with the Department of Plant Molecular Biology and Biotechnology, Tamil Nadu Agricultral University, Coimbatore-641 003, India.     

Lipopolysaccharides in four strains of the unicellular cyanobacterium Synechocystis

The results of the cross reactions of the 27 strains of Azospirillum spp. with 4 fluorescent antibodies (FA) show a neat differentiation between the two species. A. lipoferum represents a more homogenous group in respect to FA reactions and highly fluorescent preparations were obtained with strains from a large scope origin against Sp59 FA, the type strain. In contrast A. brasilense contains at least three sub groups in respect to FA reactions. The first includes all denitrifing strains (nir⁺) which react with FA from Sp7 the type strain. None of the nir^- strains reacted strongly with Sp7 FA. One part of the A. brasilense nir^- group which includes the strains isolated from well sterilized rice and wheat roots (Sp 107, 107 st, 106 and 109 st) reacts with FA of their reference strain Sp107 but not with that of Sp28 FA. The strains isolated from unsterilized roots and soils reacted with SP28 FA and not with that of Sp107 FA. In addition there were 3 strains (Sp A4, 34 and 67) which reacted with neither of the FAs.Abbreviations Fa fluorescent antibody - FITC fluorescein isothiocyanate - Rh ITC gelatin-rhodamine isothiocyanate - nir⁺ nitrite reductase positive - nir^- nitrite reductase negative     

Azospirillum brasilense colonisation of wheat roots and the role of lectin–carbohydrate interactions in bacterial adsorption and root-hair deformation

The dynamics of adsorption of the nitrogen-fixing soil bacteria Azospirillum brasilense 75 and 80 (isolated from soil samples collected in Saratov Oblast, southern Russia) and A. brasilense Sp245 to the roots of seedlings of common spring wheat was studied in relation to inoculum size, period of incubation with the roots and bacterial-growth phase. The number of root-attached cells increased with increasing size of inoculum and time of contact. The saturation of root-surface adsorption was observed by 24 h of co-incubation for A. brasilense 75, by 6 h for A. brasilense 80, and by 3 h for A. brasilense Sp245. The firmness of bacterial–root attachment increased after extended co-incubation. Differences in the adsorption kinetics of the azospirilla were found that were associated with bacterial-growth phases. Azospirilla attached to the roots of their host cultivar more actively than they did to the roots of a non-host cultivar. Adsorption was partially inhibited when the roots were treated with N-acetyl-D-glucosamine. Maximal inhibition occurred after a 3-h exposure of the roots to the bacteria. Root-hair deformation induced with polysaccharide-containing complexes from the Azospirillum capsular material was inhibited by N-acetyl-D-glucosamine and chitotriose, specific haptens of wheat germ agglutinin. A possible mechanism of the mutual influence of bacteria and plants may involve key roles of wheat germ agglutinin, present on the roots, and the polysaccharide-containing components of the Azospirillum capsule.     

Quantification of Azospirillum brasilense FP2 Bacteria in Wheat Roots by Strain-Specific Quantitative PCR

Azospirillum is a rhizobacterial genus containing plant growth-promoting species associated with different crops worldwide. Azospirillum brasilense strains exhibit a growth-promoting effect by means of phytohormone production and possibly by N₂ fixation. However, one of the most important factors for achieving an increase in crop yield by plant growth-promoting rhizobacteria is the survival of the inoculant in the rhizosphere, which is not always achieved. The objective of this study was to develop quantitative PCR protocols for the strain-specific quantification of A. brasilense FP2. A novel approach was applied to identify strain-specific DNA sequences based on a comparison of the genomic sequences within the same species. The draft genome sequences of A. brasilense FP2 and Sp245 were aligned, and FP2-specific regions were filtered and checked for other possible matches in public databases. Strain-specific regions were then selected to design and evaluate strain-specific primer pairs. The primer pairs AzoR2.1, AzoR2.2, AzoR5.1, AzoR5.2, and AzoR5.3 were specific for the A. brasilense FP2 strain. These primer pairs were used to monitor quantitatively the population of A. brasilense in wheat roots under sterile and nonsterile growth conditions. In addition, coinoculations with other plant growth-promoting bacteria in wheat were performed under nonsterile conditions. The results showed that A. brasilense FP2 inoculated into wheat roots is highly competitive and achieves high cell numbers (∼10⁷ CFU/g [fresh weight] of root) in the rhizosphere even under nonsterile conditions and when coinoculated with other rhizobacteria, maintaining the population at rather stable levels for at least up to 13 days after inoculation. The strategy used here can be applied to other organisms whose genome sequences are available.     

Assessment of SCAR markers to design real‐time PCR primers for rhizosphere quantification of Azospirillum brasilense phytostimulatory inoculants of maize

Aims: To assess the applicability of sequence characterized amplified region (SCAR) markers obtained from BOX, ERIC and RAPD fragments to design primers for real‐time PCR quantification of the phytostimulatory maize inoculants Azospirillum brasilense UAP‐154 and CFN‐535 in the rhizosphere. Methods and Results: Primers were designed based on strain‐specific SCAR markers and were screened for successful amplification of target strain and absence of cross‐reaction with other Azospirillum strains. The specificity of primers thus selected was verified under real‐time PCR conditions using genomic DNA from strain collection and DNA from rhizosphere samples. The detection limit was 60 fg DNA with pure cultures and 4 × 10³ (for UAP‐154) and 4 × 10⁴ CFU g^?1 (for CFN‐535) in the maize rhizosphere. Inoculant quantification was effective from 10⁴ to 10⁸ CFU g^?1 soil. Conclusion: BOX‐based SCAR markers were useful to find primers for strain‐specific real‐time PCR quantification of each A. brasilense inoculant in the maize rhizosphere. Significance and Impact of the Study: Effective root colonization is a prerequisite for successful Azospirillum phytostimulation, but cultivation‐independent monitoring methods were lacking. The real‐time PCR methods developed here will help understand the effect of environmental conditions on root colonization and phytostimulation by A. brasilense UAP‐154 and CFN‐535.     

Denitrification and nitrogen fixation by Azospirillum

A model system is described where Azospirillum and germinated wheat seeds were grown in association for a week and then assayed for nitrogen fixation (C₂H₂-reduction) and denitrification (N₂O-formation) activities. The association performed C₂H₂-reduction and N₂O-formation under microaerobic conditions. Both activities were measurable after already 3–5 h of incubation with substantial rates and were strictly dependent on the presence of both plants and bacteria. During the week of the growth of the association, the bacteria had lived exclusively from the carbon compounds supplied by the roots of the plants. C₂H₂-reduction activity by the association was more or less the same with all the Azospirillum brasilense strains, but lower with A. lipoferum and with the A. amazonense strains tested. Two nitrogenase negative mutants of Azospirillum brasilense showed virtually no activity in the association. C₂H₂-reduction activity was strongly dependent on the growth temperature of the association. Denitrification (N₂O-formation) was high also at higher temperatures and at pH-values in the medium around 7.8 but not at neutrality and was strictly dependent on nitrate. The Azospirillum strain used strongly determined the rate of the N₂O-formation in the association. It is suggested that Azospirillum may be beneficial to crops particularly under tropical conditions.Dedicated to Professor Dr. Gerhart Drews, Freiburg, on the occasion of his 60th birthday     

Occurrence of poly-3-hydroxybutyrate inAzospirillum sp.

Azospirillum strains isolated from the roots and rhizosphere of some plants growing in West Bengal were subjected to qualitative and quantitative evaluation for poly-3-hydroxybutyrate (PHB) production. Out of the total 49 isolates, 13 (26%) were confirmed as PHB producers according to staining and chemical assay methods. The majority of these strains belonged toAzospirillum brasilense butA. amazonense andA. lipoferum were also present. When grown in the presence of NH₄Cl in the medium, the PHB content of the strains ranged from 1 to 14% of cell dry mass. The identity of the PHB extracted fromAzospirillum strain 24P-N-72 was confirmed by the characteristic UV and IR absorption peaks at 235 nm and 1730 cm⁻¹, respectively.     

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.