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.     

Fatty acid analysis of four Azospirillum species reveals three groups

Cellular fatty acid composition of 14 strains from the four species of Azospirillum was determined by gas chromatographic analysis. All strains of Azospirillum lipoferum and Azospirillum brasilense were similar in fatty acid data, thus not revealing an expected distinction between the two long established species. Strains of both Azospirillum halopraeferens and Azospirillum amazonense, however, differed significantly from this first group of strains.     

DNA restriction fingerprint analysis of the soil bacterium Azospirillum.

Total DNAs of 18 strains of Azospirillum from different sources and geographical areas were compared by restriction endonuclease pattern analysis. Fragments obtained with HindIII or BglII were separated by PAGE and stained with silver nitrate. Each strain possessed a unique and reproducible fingerprint with each enzyme, thereby facilitating strain recognition. UPGMA analysis recovered clusters of band patterns that were compared to the distribution of species within the genus Azospirillum.     

Use of random amplified polymorphic DNA (RAPD) for generating specific DNA probes for microorganisms

We report the rapid generation of DNA probes for several Azospirillum strains. This method does not require any knowledge of the genetics and/or the molecular biology of the organism (genome) to be investigated. The procedure is based on the generation of random amplified polymorphic DNA (RAPD) fingerprints using primers with an embedded restriction site. The amplification product(s) peculiar to one strain or common to two or more strains can be purified, cloned, sequenced and used as molecular probes in hybridization experiments for the detection and identification of microorganisms. We have tested this methodology in the nitrogen-fixing bacterium Azospirillum by amplyfing the total DNA extracted from several Azospirillum strains. We have used amplification bands with different specificity as molecular probes in hybridization experiments performed on amplified DNA. Results obtained have demonstrated the usefulness of this methodology for Azospirillum. Its use in microbial ecology studies as a general strategy to generate specific DNA probes is also discussed.     

Wheat root colonization and nitrogenase activity by Azospirillum isolates from crop plants in Korea

Nitrogen-fixing bacteria were isolated from the rhizosphere of different crops of Korea. A total of 16 isolates were selected and characterized. Thirteen of the isolates produced characteristics similar to those of the reference strains of Azospirillum, and the remaining 3 isolates were found to be Enterobacter spp. The isolates could be categorized into 3 groups based on their ARDRA patterns, and the first 2 groups comprised Azospirillum brasilense and Azospirillum lipoferum. The acetylene reduction activity (ARA) of these isolates was determined for free cultures and in association with wheat roots. There was no correlation between pure culture and plant-associated nitrogenase activity of the different strains. The isolates that showed higher nitrogenase activities in association with wheat roots in each group were selected and sequenced. Isolates of Azospirillum brasilense CW301, Azospirillum brasilense CW903, and Azospirillum lipoferum CW1503 were selected to study colonization in association with wheat roots. We observed higher expression of beta-galactosidase activity in A. brasilense strains than in A. lipoferum strains, which could be attributed to their higher population in association with wheat roots. All strains tested colonized and exhibited the strongest beta-galactosidase activity at the sites of lateral roots emergence.     

Pectin decomposition and associated nitrogen fixation by mixed cultures of Azospirillum and Bacillus species.

Cocultures of different Azospirillum species with Bacillus polymyxa or Bacillus subtilis allow the efficient utilization of pectin as carbon and energy sources for nitrogen fixation. The nitrogenase activity obtained with cocultures was as high as 30-80 nmol C2H4 h-1 mL-1, a much higher value than that obtained with pure cultures of either Azospirillum (up to 13 nmol C2H4 h-1 mL-1) or B. polymyxa (up to 2 nmol C2H4 h-1 mL-1) alone. To establish to what extent each partner contributed to nitrogenase activity, acetylene reduction was assayed as a function of time and it was also measured on Azospirillum cultivated in the cultures filtrates of the Bacillus. The results suggested that the nitrogenase activity was mostly produced by Azospirillum. The nitrogenase activity occurred at the expense of the degradation and fermentation products of the pectin. The new pectinolytic species, Azospirillum irakense, utilized both degradation and fermentation products of pectin, whereas the nonpectinolytic strains (Azospirillum brasilense, Azospirillum lipoferum, Azospirillum amazonense) utilized only the fermentation products of pectin, including acetic and succinic acids. These cocultures can be considered as metabolic associations, where the Bacillus produces degradation and fermentation products of pectin, which can be used by Azospirillum species.     

Genome structure of the genus Azospirillum

Azospirillum species are plant-associated diazotrophs of the alpha subclass of Proteobacteria. The genomes of five of the six Azospirillum species were analyzed by pulsed-field gel electrophoresis. All strains possessed several megareplicons, some probably linear, and 16S ribosomal DNA hybridization indicated multiple chromosomes in genomes ranging in size from 4.8 to 9.7 Mbp. The nifHDK operon was identified in the largest replicon.     

Heterologous hybridization of Azospirillum DNA to Rhizobium nod and fix genes

Abstract Probes containing the nod and hsn regions of Rhizobium meliloti and the fixABC genes of Rhizobium japonicum were used to perform hybridization experiments with endonuclease-restricted DNA from Azospirillum brasilense strains and 2 Azospirillum lipoferum strains. Homology to nod, hsn and fixA was found in the 4 Azospirillum strains.     

Plasmid localization and mapping of two Azospirillum brasilense loci that affect exopolysaccharide synthesis

Two Azospirillum brasilense loci that correct Rhizobium meliloti exoB and exoC mutants for exopolysaccharide (EPS) synthesis have been identified previously (K. W. Michiels, J. Vanderleyden, A. P. Van Gool, E. R. Signer, J. Bacteriol., 1988b). A. brasilense exo mutants produce EPS of lower molecular weight than the wild type strain. Here, we show by hybridization that these exo loci are located on a 90-MDa plasmid in A. brasilense Sp7. In four other Azospirillum strains but not in A. lipoferum SpBr17, the loci are likewise located on a plasmid of approximately the same size. Transposon Tn5 insertions in these loci were isolated and mapped on the cloned DNA by restriction analysis. Hybridization of restriction digests of purified 90-MDa plasmid DNA with probes containing the exo loci confirmed their plasmid location. This is the first report on plasmid localization of genes in Azospirillum.     

Influence of substrate composition and flow rate on growth of Azospirillum brasilense Cd in a co-culture with 3 sorghum rhizobacteria

The ability of Azospirillum brasilense Cd to colonize the niche occupied by 3 bacterial strains previously isolated from sorghum rhizosphere was studied by means of the Biolog system. The isolates were identified by different methods as strains belonging to Pseudomonas putida, Stenotrophomonas maltophilia, and Klebsiella terrigena species. Several C sources, also chosen among the constituents of sorghum root exudates, were used to evaluate the metabolic profiles of Azospirillum and the sorghum rhizobacteria. Azospirillum brasilense Cd exploited the same class of C compounds as the sorghum rhizobacteria and overlapped in their niche requirements. Since structure and functioning of a microbial community are largely affected by the flow rate of nutrient supply, the competitive behavior of A. brasilense Cd was studied in a chemostat mixed culture under C-limited conditions using disodium succinate as C source. Only at high growth rates, i.e., when the C source was highly supplied, A. brasilense Cd appeared to be a good competitor and it became the dominant species, whereas at low growth rates, it was outnumbered by the other species. However, the coexistence of all the strains was always maintained, thus suggesting that interactions other than competition or a potential cross-feeding might occur within the mixed culture.     

Characterization of two Azospirillum brasilense Sp7 plasmid genes homologous to Rhizobium meliloti nodPQ

Bacteria belonging to the Azospirillum genus are nitrogen fixers that colonize the roots of grasses, but do not cause the formation of differentiated structures. Sequences from total DNA of several Azospirillum strains are homologous to restriction fragments containing Rhizobium meliloti nodulation genes. A 10-kilobase (kb) EcoRI fragment from A. brasilense Sp7, sharing homology with a 6.8-kb EcoRI fragment carrying nodGEFH and part of nodP of R. meliloti 41, was cloned in pUC18 to yield pAB502. The nucleotide sequence of a 3.5-kb EcoRI-SmaI fragment of the pAB502 insert revealed 60% homology with R. meliloti nodP and nodQ genes. The nodP gene product shares no homology to any known protein sequence. The Azospirillum nodQ gene product shares homology with a family of initiation and elongation factors as does the R. meliloti nodQ gene product. Since the nodQ gene overlaps the nodP gene, the two genes might be cotranscribed. Azospirillum contains large plasmids, and the nodPQ genes were found on the 90-MDa plasmid (p90). A translational nodP-lacZ fusion was constructed in the broad host range plasmid pGD926. No beta-galactosidase activity was detected in Escherichia coli, but the fusion was functional in Azospirillum and constitutively expressed. Deletions and mutations of nodPQ did not modify growth, nitrogen fixation, or interaction with wheat seedlings.     

Plasmid visualization and nif gene location in nitrogen-fixing Azospirillum strains.

A modified gel electrophoresis technique provided a reproducible way of detecting and isolating plasmids with molecular weights ranging from 12 X 10(6) to 370 X 10(6) for Azospirillum species. Analysis with the nifHD region of Rhizobium trifolii showed that the Azospirillum nif genes were chromosomally located in all eight strains investigated and not on endogenous plasmids.     

Molecular and physiological comparison of Azospirillum spp. isolated from Rhizoctonia solani mycelia, wheat rhizosphere, and human skin wounds

Four phenotypically similar bacterial strains isolated from fungal, plant, and human sources were identified as Azospirillum species. Strains RC1 and LOD4 were isolated from the mycelium of the apple root pathogen Rhizoctonia solani AG 5 and from the rhizosphere of wheat grown in apple orchard soil, respectively. Strains C610 and F4626 isolated from human wounds were previously misclassified as Roseomonas genomospecies 3 and 6. All four strains demonstrated close similarities in 16S rRNA gene sequences, having > or =97% identity to Azospirillum brasilense type strain ATCC 29145 and <90% identity to Roseomonas gilardii, the Roseomonas type strain. Extensive phenotypic similarities among the four strains included the ability of free-living cells to fix N2. Cells of strains RC1, LOD4, and C610 but not of strain F4626 could be induced to flocculate by incubation with 10 mmol.L-1 glycerol or fructose in medium containing 0.5 mmol.L-1 NO3-. Our results indicate a wide range of potential sources for Azospirillum spp. with the isolation of Azospirillum spp. from human wounds warranting further investigation.     

Applicability of the 16S–23S rDNA internal spacer for PCR detection of the phytostimulatory PGPR inoculant Azospirillum lipoferum CRT1 in field soil

Aims:  To assess the applicability of the 16S–23S rDNA internal spacer regions (ISR) as targets for PCR detection of Azospirillum ssp. and the phytostimulatory plant growth-promoting rhizobacteria seed inoculant Azospirillum lipoferum CRT1 in soil.
Methods and Results:  Primer sets were designed after sequence analysis of the ISR of A. lipoferum CRT1 and Azospirillum brasilense Sp245. The primers fAZO/rAZO targeting the Azospirillum genus successfully yielded PCR amplicons (400–550 bp) from Azospirillum strains but also from certain non- Azospirillum strains in vitro , therefore they were not appropriate to monitor indigenous Azospirillum soil populations. The primers fCRT1/rCRT1 targeting A. lipoferum CRT1 generated a single 249-bp PCR product but could also amplify other strains from the same species. However, with DNA extracts from the rhizosphere of field-grown maize, both fAZO/rAZO and fCRT1/rCRT1 primer sets could be used to evidence strain CRT1 in inoculated plants by nested PCR, after a first ISR amplification with universal ribosomal primers. In soil, a 7-log dynamic range of detection (10²–10⁸ CFU g⁻¹ soil) was obtained.
Conclusions:  The PCR primers targeting 16S–23S rDNA ISR sequences enabled detection of the inoculant A. lipoferum CRT1 in field soil.
Significance and Impact of the Study:  Convenient methods to monitor Azospirillum phytostimulators in the soil are lacking. The PCR protocols designed based on ISR sequences will be useful for detection of the crop inoculant A. lipoferum CRT1 under field conditions.     

Restriction endonucleases in Azospirillum

Azospirillum brasilense, A. amazonense, and A. lipoferum strains were screened for restriction endonucleases using phage lambda DNA. The extract of A. brasilense 29711 cleaved lambda DNA into specific fragments. It was concluded that this strain possesses a class II restriction endonuclease which was named AbrI. AbrI has a single recognition site on lambda DNA at position of approx. 33 500 bp. AbrI was characterized as an isoschizomer of XhoI, which cuts lambda DNA at 33 498 bp and cleaves double-stranded DNA at the sequence 5'-C TCGAG-3'. From other Azospirilla strains only A. amazonense QRZ42 extracts (AamI activity) cleaved DNA into specific fragments under certain conditions.     

Phylogeny of the genus Azospirillum based on 16S rDNA sequence

Abstract The 16S rDNA of 17 strains of Azospirillum , 14 assigned to one of the known species A. amazonense A. brasilense A. halopraeferens A. irakense and A. lipoferum , and the other three of uncertain taxonomic position, was sequenced after polymerase chain reaction amplification and analysed in order to investigate the phylogenetic relationships at the intra-generic and super-generic level. The phylogenetic analysis confirms that the genus Azospirillum constitutes a phylogenetically separate entity within the a subclass of Proteobacteria and that the five species are well defined. A. brasilense and A. lipoferum are closely related species and form one cluster together with A. halopraeferens ; the pair of species A. amazonense and A. irakense forms a second cluster in which Rhodospirillum centenum is also placed.     

Diversity of azospirillum strains isolated from rice plants grown in saline and nonsaline sites of coastal agricultural ecosystem

The diversity of indigenous Azospirillum spp. associated with rice cultivated along the coastline of Tamil Nadu was analyzed. Twelve sites with varying soil characteristics such as salinity, texture, and the host variety were chosen. Of the 402 strains isolated using NFB media, 302 were confirmed to be Azospirillum spp. and subjected to DNA polymorphism analysis using PCR-RFLP of 16S rDNA. They were also screened for their salt tolerance and microaerobic N2-fixing-dependent growth. On species identification, all the strains were found to be A. brasilense, A. lipoferum, or unidentified. On comparing the influence of the previously noted variability on the indigenous population, soil salinity was found to play a dominant role. This was revealed by PCR-RFLP studies and salt tolerance studies. A high association between soil salinity and the distribution of Azospirillum genotypes reveals that soil salinity should be taken into consideration while developing biofertilizers specifically for the coastal agricultural ecosystem.     

Azospirilli of Uzbekistan Soils and their Influence on Growth and Development of Wheat Plants

Associative nitrogen-fixing bacteria have been isolated, which were related to Azospirillum genus, by their morphological–cultural and physiological–biochemical ability to grow in microaerophilic conditions, as well as by a number of phenotypic traits. They comprised two species, namely, Azospirillum brasilense and Azospirillum lipoferum. Azospirilli strains displayed a varying salt resistance on potato medium containing a range of NaCl concentrations from 100 to 800 mM. The decrease in the nitrogen-fixing activity of azospirilli was detected starting from 200 mM NaCl. The biomass of the inoculated local varieties of wheat, Unumdor Bugdoi and Karlik 85, in microvegetation experiments exceeded the biomass of control plants by 20–50%. During the vegetation, some azospirilli strains formed spontaneous nodules on the wheat roots.     

Recent approaches to the taxonomy of the Gracilariaceae (Gracilariales,Rhodophyta) and the Gracilaria verrucosa problem

Recognition of species in the Gracilariaceae, often notoriously difficult, is being aided by a combination of classical and modern techniques. We review some recent findings and present new results that may lead to redefinition of Gracilaria verrucosa, the type species of its genus. Plastid DNA restriction profiles (patterns of banding obtained by electrophoresis of DNA after restriction endonuclease digestion) from eleven strains ascribed to G. verrucosa indicated that the concept of this species in northern Europe includes possibly three taxa, one of which is known now to be a species of Gracilariopsis. In contrast, restriction profiles from Argentinian and Japanese strains were closely similar to the predominant pattern for European G. verrucosa. Profiles of several other strains, from the western Atlantic and eastern Pacific, were dissimilar to the European group and to each other. A chromosome number of n = 24 was determined for a representative of the predominant European group, and preliminary results of hybridization trials suggest that these strains, and others with approximately the same plastid DNA restriction pattern, are interfertile.NRCC 30559     

Determination of the structure of the repeated unit of the Azospirillum brasilense SR75 O-specific polysaccharide and homology of the lps loci in the plasmids of Azospirillum brasilense strains SR75 and Sp245

The structural identity of the repeated unit in O-specific polysaccharides (OPSs) present in the outer membrane of strain SR75 of the bacterium Azospirillum brasilense, isolated from wheat rhizosphere in Saratov oblast, and the OPSs of previously studied A. brasilense strain Sp245, isolated from surface-sterilized wheat roots in Brazil, has been demonstrated. Plasmid profiles, DNA restriction, and hybridization assays suggested that A. brasilense strains SR75 and Sp245 have different genomic structures. It was shown that homologous lps loci of both strains was localized in their plasmid DNA. This fact allows us to state that, despite their different origin, the development of the strains studied was convergent. Presumably, the habitation of these bacteria in similar ecological niches influenced this process in many respects.