Diversity of rhizobia and interactions among the host legumes and rhizobial genotypes in an agricultural-forestry ecosystem

To investigate the diversity of rhizobia and interactions among the host legumes and rhizobial genotypes in the same habitat, a total of 97 rhizobial strains isolated from nine legume species grown in an agricultural-forestry ecosystem were identified into seven genomic species and 12 symbiotic genotypes within the genera Bradyrhizobium, Mesorhizobium, Rhizobium and Sinorhizobium based upon analyses of genomic DNA regions and symbiotic genes. The results evidenced that the symbiotic genotypes of rhizobia were consistent with their hosts of origin; revealed that vertical transfer was the main mechanism in rhizobia to maintain the symbiotic genes but lateral transfer of symbiotic genes might have happened between the closely related rhizobial species; suggested the existence of co-distribution and co-evolution among the legume hosts and compatible rhizobia. All of these data demonstrated that the biogeography of rhizobia was a result of interactions among the host legumes, bacterial genomic backgrounds and environments.     

Rhizobial Resource Associated with Epidemic Legumes in Tibet

A total of 128 bacterial test strains originated from Astragalus, Caragana, Gueldenstaedtia, Medicago, Melilotus, Oxytropis, Trifolium, and Vicia grown in Tibet were characterized phenotypically and genomically. Based upon the consensus of grouping results, they were identified as 16 putative species. Twenty-five test strains belonging to seven putative species of Agrobacterium, Bradyrhizobium, and Rhizobium might be nonsymbiotic bacteria and the remaining 103 test strains were symbiotic bacteria belonging to Mesorhizobium, Rhizobium, and Sinorhizobium meliloti. Although no novel taxon was detected in the symbiotic bacteria, several characters including the alkaliphilic psychrotolerance revealed that the Tibetan rhizobia could be ecotypes adapted to the local conditions. The results also demonstrated that frequent lateral transfer of symbiotic genes might have happened in the Tibetan rhizobia since nodC genes similar to that of S. meliloti were found in several Rhizobium test strains and all the Mesorhizobium species had very similar nodC genes despite their genomic background. All of these findings demonstrated that the Tibetan rhizobia were an important resource for further studies on rhizobial ecology and application. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Genetic diversity of fast-growing rhizobia that nodulate soybean ( Glycine max L. Merr)

The fast-growing Rhizobium sp. strain NGR234, isolated from Papua New Guinea, and 13 strains of Sinorhizobium fredii, isolated from China and Vietnam, were fingerprinted by means of RAPD, REP, ERIC and ARDRA. ERIC, REP and RAPD markers revealed a considerable genetic diversity among fast-growing rhizobia. Chinese isolates showed higher levels of diversity than those strains isolated from Vietnam. ARDRA analysis revealed three different genotypes among fast-growing rhizobia that nodulate soybean, even though all belonged to a subcluster that included Sinorhizobium saheli and Sinorhizobium meliloti. Among S. fredii rhizobia, two strains, SMH13 and HH303, might be representatives of other species of nitrogen-fixing organisms. Although restriction analysis of the nifD–nifK intergenic DNA fragment confirmed the unique nature of Rhizobium sp. strain NGR234, several similarities between Rhizobium sp. strain NGR234 and S. fredii USDA257, the ARDRA analysis and the full sequence of the 16S rDNA confirmed that NGR234 is a S. fredii strain. In addition, ARDRA analysis and the full sequence of the 16S rDNA suggested that two strains of rhizobia might be representatives of other species of rhizobia.     

Rhizobium sp. Strain NGR234 Possesses a Remarkable Number of Secretion Systems

Rhizobium sp. strain NGR234 is a unique alphaproteobacterium (order Rhizobiales) that forms nitrogen-fixing nodules with more legumes than any other microsymbiont. We report here that the 3.93-Mbp chromosome (cNGR234) encodes most functions required for cellular growth. Few essential functions are encoded on the 2.43-Mbp megaplasmid (pNGR234b), and none are present on the second 0.54-Mbp symbiotic plasmid (pNGR234a). Among many striking features, the 6.9-Mbp genome encodes more different secretion systems than any other known rhizobia and probably most known bacteria. Altogether, 132 genes and proteins are linked to secretory processes. Secretion systems identified include general and export pathways, a twin arginine translocase secretion system, six type I transporter genes, one functional and one putative type III system, three type IV attachment systems, and two putative type IV conjugation pili. Type V and VI transporters were not identified, however. NGR234 also carries genes and regulatory networks linked to the metabolism of a wide range of aromatic and nonaromatic compounds. In this way, NGR234 can quickly adapt to changing environmental stimuli in soils, rhizospheres, and plants. Finally, NGR234 carries at least six loci linked to the quenching of quorum-sensing signals, as well as one gene (ngrI) that possibly encodes a novel type of autoinducer I molecule.Diverse soil bacteria interact with plants in ways that range from symbiotic to pathogenic. Symbiotic Eubacteria (both alpha- and betaproteobacteria, collectively called rhizobia) form nitrogen-fixing associations of tremendous environmental importance (41, 66). Although some rhizobia are able to reduce atmospheric nitrogen to ammonia under saprophytic, free-living conditions, the reduced oxygen tensions found within the intracellular environment of specialized organs called nodules, maximizes this process (16). As legume roots penetrate the soil, they come in contact with rhizobia. Symbiotic interactions are initiated by the exchange of diverse molecules between the partners. Among them, plants liberate flavonoids into the rhizosphere that upregulate rhizobial genes. As a result, lipo-chito-oligo-saccharidic Nod factors are produced that trigger the nodulation pathway in susceptible legumes. Then, in many hosts, rhizobia enter the roots through root hairs, make their way to the cortex, multiply and fill the intracellular spaces of mature nodules. Centripetal progression of rhizobia into the plant and their maturation into nitrogen-fixing symbiosomes depends on the continued exchange of diverse signals. Many, but not all of these signals have been identified; one sure way to take stock of what is necessary for effective symbiosis is to sequence the partners. We began this work by assembling overlapping sets of cosmids (contigs) of the microsymbiont Rhizobium sp. strain NGR234 (hereafter NGR234) (63), which enabled us to elucidate the nucleotide sequence of the symbiotic (pNGR243a) plasmid (29). Similar techniques permitted the assembly of sections of the extremely large megaplasmid pNGR234b (86), and some snapshot genome information was made available earlier (91); however, the use of pyrosequencing methods greatly facilitated this process. We report here the genome sequence of NGR234 that is able to nodulate more than 120 genera of legumes and the nonlegume Parasponia andersonii (69). It seems likely that the vast richness of secretory systems might be a major key to the broad host range.     

Roots and Their Symbiotic Microbes: Strategies to Obtain Nitrogen and Phosphorus in a Nutrient-Limiting Environment

The association between Rhizobium and legumes and that between arbuscular mycorrhizal (AM) fungi and most land plants display a remarkable degree of similarity. Both events involve the recognition of, entrance into, and coexistence within the plant root, with the development of a specialized interface that always separates the two partners and at which nutrient exchange occurs. Molecules produced by rhizobia during the early stages of the symbiosis are related to fungal chitin, and the plant responds to both microbes with an increase in the production of flavonoids, which may assist in recognition and development of the symbioses. Many of the same plant genes are up-regulated in the two symbiotic pathways, and notably plants that are Nod^– are often defective in the AM association as well. However, there are a number of differences between the associations, and these are important for understanding the relationship between the two symbioses. The Rhizobium and AM symbioses will be compared and the question of whether the nitrogen-fixing association evolved from the much more ancient AM symbiosis will be discussed.     

Infection and Invasion of Roots by Symbiotic, Nitrogen-Fixing Rhizobia during Nodulation of Temperate Legumes

Bacteria belonging to the genera Rhizobium, Mesorhizobium, Sinorhizobium, Bradyrhizobium, and Azorhizobium (collectively referred to as rhizobia) grow in the soil as free-living organisms but can also live as nitrogen-fixing symbionts inside root nodule cells of legume plants. The interactions between several rhizobial species and their host plants have become models for this type of nitrogen-fixing symbiosis. Temperate legumes such as alfalfa, pea, and vetch form indeterminate nodules that arise from root inner and middle cortical cells and grow out from the root via a persistent meristem. During the formation of functional indeterminate nodules, symbiotic bacteria must gain access to the interior of the host root. To get from the outside to the inside, rhizobia grow and divide in tubules called infection threads, which are composite structures derived from the two symbiotic partners. This review focuses on symbiotic infection and invasion during the formation of indeterminate nodules. It summarizes root hair growth, how root hair growth is influenced by rhizobial signaling molecules, infection of root hairs, infection thread extension down root hairs, infection thread growth into root tissue, and the plant and bacterial contributions necessary for infection thread formation and growth. The review also summarizes recent advances concerning the growth dynamics of rhizobial populations in infection threads.     

<Emphasis Type="Italic">Bradyrhizobium</Emphasis> spp. and <Emphasis Type="Italic">Sinorhizobium fredii</Emphasis> are predominant in root nodules of <Emphasis Type="Italic">Vigna angularis</Emphasis>, a native legume crop in the subtropical region of China

Adzuki bean (Vigna angularis) is an important legume crop native to China, but its rhizobia have not been well characterized. In the present study, a total of 60 rhizobial strains isolated from eight provinces of China were analyzed with amplified 16S rRNA gene RFLP, IGS-RFLP, and sequencing analyses of 16S rRNA, atpD, recA, and nodC genes. These strains were identified as genomic species within Rhizobium, Sinorhizobium, Mesorhizobium, Bradyrhizobium, and Ochrobactrum. The most abundant groups were Bradyrhizobium species and Sinorhizobium fredii. Diverse nodC genes were found in these strains, which were mainly co-evolved with the housekeeping genes, but a possible lateral transfer of nodC from Sinorhizobium to Rhizobium was found. Analyses of the genomic and symbiotic gene backgrounds showed that adzuki bean shared the same rhizobial gene pool with soybean (legume native to China) and the exotic Vigna species. All of these data demonstrated that nodule formation is the interaction of rhizobia, host plants, and environment characters. Electronic Supplementary Material  Supplementary material is available for this article at and is accessible for authorized users.     

Genetic diversity and biogeography of rhizobia associated with Caragana species in three ecological regions of China

Twenty-two genospecies belonging mainly to Mesorhizobium, and occasionally to Rhizobium and Bradyrhizobium, were defined among the 174 rhizobia strains isolated from Caragana species. Highly similar nodC genes were found in the sole Bradyrhizobium strain and among all the detected Mesorhizobium strains. A clear correlation between rhizobial genospecies and the eco-regions where they were isolated was found using homogeneity analysis. All these results demonstrated that Caragana species had stringently selected the rhizobia symbiotic genotype, but not the genomic background; lateral transfer of symbiotic genes from Mesorhizobium to Bradyrhizobium and among the Mesorhizobium species has happened in the Caragana rhizobia; and biogeography of Caragana rhizobia exists. Furthermore, a combined cluster analysis, based upon the patterns obtained from amplified 16S rRNA gene and 16S–23S intergenic spacer restriction analyses, BOX PCR and SDS-PAGE of proteins, was reported to be an efficient method to define the genospecies.     

Characterization of extrachromosomal replicons present in the extended host range Rhizobium sp. LPU83

In several rhizobia, bacteria that inhabit the soil in free-living conditions and associate in symbiosis with the root of legumes as nitrogen-fixing organisms, plasmid DNA can constitute a high percentage of the genome. We have characterized acid-tolerant isolates of rhizobia-here represented by the strain Rhizobium sp. LPU83-that have an extended nodulation-host range including alfalfa, the common bean, and Leucena leucocephala. In this study we analyzed the plasmids of R. sp. LPU83 in order to characterize their role in the evolution of Medicago symbionts and their involvement in symbiotic behavior. The pLPU83a plasmid was found to be transmissible with no associated phenotypic traits. The symbiotic plasmid pLPU83b could be transferred at very low frequencies under laboratory conditions only when pLPU83a was present; could restore nodulation to a strain cured of its symbiotic plasmid, S. meliloti A818; but could not restore the full nitrogen fixation associated with alfalfa.     

Effect of Inoculation with Various Rhizobia Strains on the Fatty Acid Composition of Peribacteroid and Bacteroid Membranes of the Nodule Symbiosomes

The fatty acid (FA) composition of bacteroid and peribacteroid membranes was studied in the symbiotic pairs differing in their nitrogen-fixing efficiency; the results are compared with the FA composition of plasmalemma and free-living rhizobia. The experiments involved lupine plants inoculated with strains of Bradyrhizobium lupini359a (Nod⁺Fix⁺) and 400 (Nod⁺Fix L) manifesting high and low nitrogen-fixing efficiency, respectively, and broad bean plants inoculated with strains of Rhizobium leguminosarum97 (Nod⁺Fix⁺) and 87 (Nod⁺Fix L) of high and low nitrogen-fixing efficiency, respectively. We showed that the rhizobia of the strains 359a and 97 were able to form nodules with peribacteroid membranes containing FA mainly or exclusively of plant origin. These strains were able to develop effective symbiotic pairs with legume plants. The use of strains 400 and 87 resulted in the formation of nodules with peribacteroid membranes containing typical bacterial (branched-chain) FAs; these strains were characterized by an ineffective symbiosis.     

Corresponding 16S rRNA gene segments in Rhizobiaceae and Aeromonas yield discordant phylogenies

Previous evidence has indicated that the 16S rRNA genes in certain species of Aeromonas may have a history of lateral transfer and recombination. A comparative analysis of patterns of 16S nucleotide sequence polymorphism among species of Rhizobium and Agrobacterium was conducted to determine if there is similar evidence for chimeric 16S genes in members of the Rhizobiaceae. Results from phylogenetic analyses and comparison of patterns of nucleotide sequence polymorphism in portions of rhizobial 16S genes revealed the same type of segment-dependent polymorphic site partitioning that was previously reported for Aeromonas. These results support the hypothesis that certain 16S segments in rhizobia may have a history of lateral transfer and recombination.Abbreviations 16S rRNA 16S ribosomal ribonucleic acid - 16S the 16S rRNA gene     

Quorum Sensing in Nitrogen-Fixing Rhizobia

Members of the rhizobia are distinguished for their ability to establish a nitrogen-fixing symbiosis with leguminous plants. While many details of this relationship remain a mystery, much effort has gone into elucidating the mechanisms governing bacterium-host recognition and the events leading to symbiosis. Several signal molecules, including plant-produced flavonoids and bacterially produced nodulation factors and exopolysaccharides, are known to function in the molecular conversation between the host and the symbiont. Work by several laboratories has shown that an additional mode of regulation, quorum sensing, intercedes in the signal exchange process and perhaps plays a major role in preparing and coordinating the nitrogen-fixing rhizobia during the establishment of the symbiosis. Rhizobium leguminosarum, for example, carries a multitiered quorum-sensing system that represents one of the most complex regulatory networks identified for this form of gene regulation. This review focuses on the recent stream of information regarding quorum sensing in the nitrogen-fixing rhizobia. Seminal work on the quorum-sensing systems of R. leguminosarum bv. viciae, R. etli, Rhizobium sp. strain NGR234, Sinorhizobium meliloti, and Bradyrhizobium japonicum is presented and discussed. The latest work shows that quorum sensing can be linked to various symbiotic phenomena including nodulation efficiency, symbiosome development, exopolysaccharide production, and nitrogen fixation, all of which are important for the establishment of a successful symbiosis. Many questions remain to be answered, but the knowledge obtained so far provides a firm foundation for future studies on the role of quorum-sensing mediated gene regulation in host-bacterium interactions.     

Roots and Their Symbiotic Microbes: Strategies to Obtain Nitrogen and Phosphorus in a Nutrient-Limiting Environment

The association between Rhizobium and legumes and that between arbuscular mycorrhizal (AM) fungi and most land plants display a remarkable degree of similarity. Both events involve the recognition of, entrance into, and coexistence within the plant root, with the development of a specialized interface that always separates the two partners and at which nutrient exchange occurs. Molecules produced by rhizobia during the early stages of the symbiosis are related to fungal chitin, and the plant responds to both microbes with an increase in the production of flavonoids, which may assist in recognition and development of the symbioses. Many of the same plant genes are up-regulated in the two symbiotic pathways, and notably plants that are Nod^? are often defective in the AM association as well. However, there are a number of differences between the associations, and these are important for understanding the relationship between the two symbioses. The Rhizobium and AM symbioses will be compared and the question of whether the nitrogen-fixing association evolved from the much more ancient AM symbiosis will be discussed.     

Distribution and diversity of rhizobia associated with wild soybean (Glycine soja Sieb. & Zucc.) in Northwest China

A total of 155 nodule isolates that originated from seven sites in Northwest China were characterized by PCR-RFLP of the 16S rRNA gene and sequence analysis of multiple core genes (16S rRNA, recA, atpD, and glnII) in order to investigate the diversity and biogeography of Glycine soja-nodulating rhizobia. Among the isolates, 80 were Ensifer fredii, 19 were Ensifer morelense, 49 were Rhizobium radiobacter, and 7 were putative novel Rhizobium species. The phylogenies of E. fredii and E. morelense isolates in a concatenate tree (assembly of all housekeeping genes) were generally consistent with those in individual gene trees. However, incongruence was found in the phylogenies of the different genes of Rhizobium isolates, indicating that lateral transfer or recombination possibly occurred in these gene loci. Despite their species identity, all the isolates in this study formed a single lineage related to E. fredii in nodAand nifH gene phylogenies, which also indicated that the symbiotic genes were laterally transferred between different species. Biogeographic patterns were found at the species and strain genomic type levels, as revealed by BOXA1R fingerprinting, demonstrating that the evolution of rhizobial populations in different geographic locations was related to soil types, altitude and spatial effects. This study is the first to report that E. morelense, R. radiobacter, and Rhizobium sp. are microsymbionts of G. soja, as well as showing that the diversity of G. soja rhizobia is enhanced and new rhizobia have evolved in Northwest China.     

Molecular diversity and phylogeny of rhizobia associated with Lablab purpureus (Linn.) grown in Southern China

As an introduced plant, Lablab purpureus serves as a vegetable, herbal medicine, forage and green manure in China. In order to investigate the diversity of rhizobia associated with this plant, a total of 49 rhizobial strains isolated from ten provinces of Southern China were analyzed in the present study with restriction fragment length polymorphism and/or sequence analyses of housekeeping genes (16S rRNA, IGS, atpD, glnII and recA) and symbiotic genes (nifH and nodC). The results defined the L. purpureus rhizobia as 24 IGS-types within 15 rrs-IGS clusters or genomic species belonging to Bradyrhizobium, Rhizobium, Ensifer (synonym of Sinorhizobium) and Mesorhizobium. Bradyrhizobium spp. (81.6%) were the most abundant isolates, half of which were B. elkanii. Most of these rhizobia induced nodules on L. purpureus, but symbiotic genes were only amplified from the Bradyrhizobium and Rhizobium leguminosarum strains. The nodC and nifH phylogenetic trees defined five lineages corresponding to B. yuanmingense, B. japonicum, B. elkanii, B. jicamae and R. leguminosarum. The coherence of housekeeping and symbiotic gene phylogenies demonstrated that the symbiotic genes of the Lablab rhizobia were maintained mainly through vertical transfer. However, a putative lateral transfer of symbiotic genes was found in the B. liaoningense strain. The results in the present study clearly revealed that L. purpureus was a promiscuous host that formed nodules with diverse rhizobia, mainly Bradyrhizobium species, harboring different symbiotic genes.     

Genomic insight into the taxonomy of Rhizobium genospecies that nodulate Phaseolus vulgaris

Due to the wide cultivation of bean (Phaseolus vulgaris L.), rhizobia associated with this plant have been isolated from many different geographical regions. In order to investigate the species diversity of bean rhizobia, comparative genome sequence analysis was performed in the present study for 69 Rhizobium strains mainly isolated from root nodules of bean and clover (Trifolium spp.). Based on genome average nucleotide identity, digital DNA:DNA hybridization, and phylogenetic analysis of 1,458 single-copy core genes, these strains were classified into 28 clusters, consistent with their species definition based on multilocus sequence analysis (MLSA) of atpD, glnII, and recA. The bean rhizobia were found in 16 defined species and nine putative novel species; in addition, 35 strains previously described as Rhizobium etli, Rhizobium phaseoli, Rhizobium vallis, Rhizobium gallicum, Rhizobium leguminosarum and Rhizobium spp. should be renamed. The phylogenetic patterns of symbiotic genes nodC and nifH were highly host-specific and inconsistent with the genomic phylogeny. Multiple symbiovars (sv.) within the Rhizobium species were found as a common feature: sv. phaseoli, sv. trifolii and sv. viciae in Rhizobium anhuiense; sv. phaseoli and sv. mimosae in Rhizobium sophoriradicis/R. etli/Rhizobium sp. III; sv. phaseoli and sv. trifolii in Rhizobium hidalgonense/Rhizobium acidisoli; sv. phaseoli and sv. viciae in R. leguminosarum/Rhizobium sp. IX; sv. trifolii and sv. viciae in Rhizobium laguerreae. Thus, genomic comparison revealed great species diversity in bean rhizobia, corrected the species definition of some previously misnamed strains, and demonstrated the MLSA a valuable and simple method for defining Rhizobium species.     

Multiple host-specificity loci of the broad host-range Rhizobium sp. NGR234 selected using the widely compatible legume Vigna unguiculata

Specificity in legume-Rhizobium symbiosis depends on plant and rhizobial genes. As our objective was to study broad host-range determinants of rhizobia, we sought a legume and a Rhizobium with the lowest possible specificity. By inoculating 12 different legumes with a heterogenous collection of 35 fast-growing rhizobia, we found Rhizobium sp. NGR234 to be the Rhizobium and Vigna unguiculata to be the plant with the lowest specificities. Transfer of cloned fragments of the Sym-plasmid pNGR234a into heterologous rhizobia, screening for extension of host-range of the transconjugants to include V. unguiculata, and restriction mapping of the Hsn- and overlapping clones, proved that there were at least three distinct Hsn-regions (HsnI, II, and III) on pNGR234a. HsnI is located next to nodD, HsnII is linked to nifKDH and HsnIII to nodC. In addition to nodulation of Vigna, HsnI conferred upon the transconjugants the ability to nodulate Glycine max, Macroptilium atropurpureum and Psophocarpus tetragonolobus. All three Hsn-regions, when transferred to the appropriate recipients, induced root-hair-curling on M. atropurpureum. Hsn-region III was able to complement a mutation in the host-range gene nodH of R. meliloti strain 2011. Homology to nod-box-sequences could be shown only for the sub-clones containing HsnII and HsnIII, thus suggesting different regulation mechanisms for HsnI and HsnII/III.     

Plasmids impact on rhizobia-legumes symbiosis in diverse environments

Rhizobia are a well-known group of soil bacteria that establish symbiotic relationship with leguminous plants, fix atmospheric nitrogen, and improve soil fertility. To fulfill multiple duties in soil, rhizobia are elaborated with a large and complex multipartite genome composed of several replicons. The genetic material is divided among various replicons, in a way to cope with, and satisfy the diverse functions of rhizobia. In addition to the main chromosome, which is carrying the essential (core) genes required for sustaining cell life, the rhizobia genomes contain several extra-chromosomal plasmids, carrying the nonessential (accessory) genes. Occasionally, some mega-plasmids, denoted as secondary chromosomes or chromids, carry some essential (core) genes. Furthermore, specific accessory gene sequences (the symbiotic chromosomal islands) are incorporated in the main chromosome of some rhizobia species in Bradyrhizobium and Mesorhizobium genera. Plasmids in rhizobia are of variable sizes. All of the plasmids in a Rhizobium cell constitute about 30–50% of the genome. Rhizobia plasmids have specific characters such as miscellaneous genes, independent replication system, self-transmissibility, and instability. The plasmids regulate several cellular metabolic functions and enable the host rhizobia to survive in diverse habitats and even under stress conditions. Symbiotic plasmids in rhizobia are receiving increased attention because of their significance in the symbiotic nitrogen fixation process. They carry the symbiotic (nod, nif and fix) genes, and some non-symbiotic genes. Symbiotic plasmids are conjugally-transferred by the aid of the non-symbiotic, self-transmissible plasmids, and hence, brings about major changes in the symbiotic interactions and host specificity of rhizobia. Besides, the rhizobia cells harbor one or more accessory, non-symbiotic plasmids, carrying genes regulating various metabolic functions, rhizosphere colonization, and nodulation competitiveness. The entire rhizobia-plasmid pool interacting in harmony and provides rhizobia with substantial abilities to fulfill their complex symbiotic and non-symbiotic functions in variable environments. The above concepts are extensively reviewed and fairly discussed.