Bradyrhizobium sp. S23321 is an oligotrophic bacterium isolated from paddy field soil. Although S23321 is phylogenetically close to Bradyrhizobium japonicum USDA110, a legume symbiont, it is unable to induce root nodules in siratro, a legume often used for testing Nod factor-dependent nodulation. The genome of S23321 is a single circular chromosome, 7,231,841 bp in length, with an average GC content of 64.3%. The genome contains 6,898 potential protein-encoding genes, one set of rRNA genes, and 45 tRNA genes. Comparison of the genome structure between S23321 and USDA110 showed strong colinearity; however, the symbiosis islands present in USDA110 were absent in S23321, whose genome lacked a chaperonin gene cluster (groELS3) for symbiosis regulation found in USDA110. A comparison of sequences around the tRNA-Val gene strongly suggested that S23321 contains an ancestral-type genome that precedes the acquisition of a symbiosis island by horizontal gene transfer. Although S23321 contains a nif (nitrogen fixation) gene cluster, the organization, homology, and phylogeny of the genes in this cluster were more similar to those of photosynthetic bradyrhizobia ORS278 and BTAi1 than to those on the symbiosis island of USDA110. In addition, we found genes encoding a complete photosynthetic system, many ABC transporters for amino acids and oligopeptides, two types (polar and lateral) of flagella, multiple respiratory chains, and a system for lignin monomer catabolism in the S23321 genome. These features suggest that S23321 is able to adapt to a wide range of environments, probably including low-nutrient conditions, with multiple survival strategies in soil and rhizosphere.
Fourteen strains of 2,4-dichrolophenoxyacetic acid (2,4-D)-degrading bacteria were isolated from soil samples from eight different sites in Japan and identified as members of the genera Burkholderia, Cupriavidus, and Sphingobium. To characterize them in view of the 2,4-D-degrading genes that they had, the strains were divided into three groups based on similarities of PCR-amplified partial nucleotide sequences of their 2,4-D-degrading genes to the sequences of well-characterized 2,4-D-degrading genes, tfdA, tfdB, and tfdC in Cupriavidus necator strain JMP134, Achromobacter xylosoxidans strain EST4002, and Sphingomonas sp. strain TFD44. The nucleotide sequences of the tfdA, tfdB, and tfdC gene homologs in eight of the 14 strains were highly similar to those in Burkholderia cepacia strain RASC. The eight strains were classified into the RASC subgroup in the EST4002 group. Southern hybridization indicated that at least one set of the putative tfdA, tfdB, and tfdC genes in each of the 14 strains was located on a replicon (ca. 90-600 kb). In particular, the RASC-type 2,4-D-degrading genes of the eight strains were located on plasmids of similar size (ca. 600 kb), and the hybridization experiments suggested that the 2,4-D-degrading genes of seven strains among the eight were located on restriction fragments of the same length. In view of the fact that the seven strains originated from six distant sites in Japan and had different 16S rRNA gene sequences, our results suggest that the RASC-type 2,4-D-degrading genes on similar plasmids were horizontally transferred among bacteria and were distributed throughout Japan.
Analysis of the complete nucleotide sequence of plasmid pM7012 from 2,4-dichlorophenoxyacetic-acid (2,4-D)-degrading bacterium Burkholderia sp. M701 revealed that the plasmid had 582 142 bp, with 541 putative protein-coding sequences and 39 putative tRNA genes for the transport of the standard 20 aa. pM7012 contains sequences homologous to the regions involved in conjugal transfer and plasmid maintenance found in plasmids byi_2p from Burkholderia sp. YI23 and pBVIE01 from Burkholderia sp. G4. No relaxase gene was found in any of these plasmids, although genes for a type IV secretion system and type IV coupling proteins were identified. Plasmids with no relaxase gene have been classified as non-mobile plasmids. However, nucleotide sequences with a high level of similarity to the genes for plasmid transfer, plasmid maintenance, 2,4-D degradation and arsenic resistance contained on pM7012 were also detected in eight other megaplasmids (~600 or 900 kb) found in seven Burkholderia strains and a strain of Cupriavidus, which were isolated as 2,4-D-degrading bacteria in Japan and the United States. These results suggested that the 2,4-D degradation megaplasmids related to pM7012 are mobile and distributed across various bacterial species worldwide, and that the plasmid group could be distinguished from known mobile plasmid groups.
The lack of a universal method to extract RNA from soil hinders the progress of studies related to nitrification in soil, which is an important step in the nitrogen cycle. It is particularly difficult to extract RNA from certain types of soils such as Andosols (volcanic ash soils), which is the dominant agricultural soil in Japan, because of RNA adsorption by soil. To obtain RNA from these challenging soils to study the bacteria involved in nitrification, we developed a soil RNA extraction method for gene expression analysis. Autoclaved casein was added to an RNA extraction buffer to recover RNA from soil, and high-quality RNA was successfully extracted from eight types of agricultural soils that were significantly different in their physicochemical characteristics. To detect bacterial ammonia monooxygenase subunit A gene (amoA) transcripts, bacterial genomic DNA and messenger RNA were co-extracted from two different types of Andosols during incubation with ammonium sulfate. Polymerase chain reaction-denaturing gradient gel electrophoresis and reverse transcription polymerase chain reaction-denaturing gradient gel electrophoresis analyses of amoA in soil microcosms revealed that only few amoA, which had the highest similarities to those in Nitrosospira multiformis, were expressed in these soils after treatment with ammonium sulfate, although multiple amoA genes were present in the soil microcosms examined.
Denitrification ability is sporadically distributed among diverse bacteria, archaea, and fungi. In addition, disagreement has been found between denitrification gene phylogenies and the 16S rRNA gene phylogeny. These facts have suggested potential occurrences of horizontal gene transfer (HGT) for the denitrification genes. However, evidence of HGT has not been clearly presented thus far. In this study, we identified the sequences and the localization of the nitrite reductase genes in the genomes of 41 denitrifyingAzospirillumsp. strains and searched for mobile genetic elements that contain denitrification genes. AllAzospirillumsp. strains examined in this study possessed multiple replicons (4 to 11 replicons), with their sizes ranging from 7 to 1,031 kbp. Among those, the nitrite reductase genenirKwas located on large replicons (549 to 941 kbp). Genome sequencing showed thatAzospirillumstrains that had similarnirKsequences also shared similarnir-norgene arrangements, especially between the TSH58, Sp7T, and Sp245 strains. In addition to the high similarity betweennir-norgene clusters among the threeAzospirillumstrains, a composite transposon structure was identified in the genome of strain TSH58, which contains thenir-norgene cluster and the novel IS6family insertion sequences (ISAz581and ISAz582). ThenirKgene within the composite transposon system was actively transcribed under denitrification-inducing conditions. Although not experimentally verified in this study, the composite transposon system containing thenir-norgene cluster could be transferred to other cells if it is moved to a prophage region and the phage becomes activated and released outside the cells. Taken together, strain TSH58 most likely acquired its denitrification ability by HGT from closely relatedAzospirillumsp. denitrifiers.IMPORTANCEThe evolutionary history of denitrification is complex. While the occurrence of horizontal gene transfer has been suggested for denitrification genes, most studies report circumstantial evidences, such as disagreement between denitrification gene phylogenies and the 16S rRNA gene phylogeny. Based on the comparative genome analyses ofAzospirillumsp. denitrifiers, we identified denitrification genes, includingnirKandnorCBQD, located on a mobile genetic element in the genome ofAzospirillumsp. strain TSH58. ThenirKwas actively transcribed under denitrification-inducing conditions. Since this gene was the sole nitrite reductase gene in strain TSH58, this strain most likely benefitted by acquiring denitrification genes via horizontal gene transfer. This finding will significantly advance our scientific knowledge regarding the ecology and evolution of denitrification.
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