Diversity of Plasmid Profiles and Conservation of Symbiotic Nitrogen Fixation Genes in Newly Isolated Rhizobium Strains Nodulating Sulla (Hedysarum coronarium L.)

Forty-five Rhizobium strains nodulating sulla (Hedysarum coronarium L.), isolated from plants grown in different sites in Menorca Island and southern Spain, were examined for plasmid content and the location and organization of nif (nitrogen fixation) and nod (nodulation) sequences. A great diversity in both number and size of the plasmids was observed in this native population of strains, which could be distributed among 19 different groups according to their plasmid profiles. No correlation was found between plasmid profile and geographical origin of the strains. In each strain a single plasmid ranging from 187 to 349 megadaltons hybridized to Rhizobium meliloti nifHD and nodD DNA, and in three strains the spontaneous loss of this plasmid resulted in the loss of the nodulation capacity. In addition to the symbiotic plasmid, 18 different cryptic plasmids were identified. A characteristic cryptic plasmid of >1,000 megadaltons was present in all strains. Total DNA hybridization experiments, with nifHD and portions of nodC and nodD genes (coding for common nodulation functions) from R. meliloti as probes, demonstrated that both the sequence and organization of nif and common nod genes were highly conserved within rhizobia nodulating sulla. Evidence for reiteration of nodD sequences and for linkage of nodC to at least one copy of nodD was obtained for all the strains examined. From these results we conclude that Rhizobium strains nodulating sulla are a homogeneous group of symbiotic bacteria that are closely related to the classical fast-growing group of rhizobia.     

Conservation of symbiotic nitrogen fixation gene sequences in Rhizobium japonicum and Bradyrhizobium japonicum.

Southern hybridization with nif (nitrogen fixation) and nod (nodulation) DNA probes from Rhizobium meliloti against intact plasmid DNA of Rhizobium japonicum and Bradyrhizobium japonicum strains indicated that both nif and nod sequences are on plasmid DNA in most R. japonicum strains. An exception is found with R. japonicum strain USDA194 and all B. japonicum strains where nif and nod sequences are on the chromosome. In R. japonicum strains, with the exception of strain USDA205, both nif and nod sequences are on the same plasmid. In strain USDA205, the nif genes are on a 112-megadalton plasmid, and nod genes are on a 195-megadalton plasmid. Hybridization to EcoRI digests of total DNA to nif and nod probes from R. meliloti show that the nif and nod sequences are conserved in both R. japonicum and B. japonicum strains regardless of the plasmid or chromosomal location of these genes. In addition, nif DNA hybridization patterns were identical among all R. japonicum strains and with most of the B. japonicum strains examined. Similarly, many of the bands that hybridize to the nodulation probe isolated from R. meliloti were found to be common among R. japonicum strains. Under reduced hybridization stringency conditions, strong conservation of nodulation sequences was observed in strains of B. japonicum. We have also found that the plasmid pRjaUSDA193, which possess nif and nod sequences, does not possess sequence homology with any plasmid of USDA194, but is homologous to parts of the chromosome of USDA194. Strain USDA194 is unique, since nif and nod sequences are present on the chromosome instead of on a plasmid as observed with all other strains examined.     

Reiteration of genes involved in symbiotic nitrogen fixation by fast-growing Rhizobium japonicum.

By using cloned Rhizobium meliloti nodulation (nod) genes and nitrogen fixation (nif) genes, we found that the genes for both nodulation and nitrogen fixation were on a plasmid present in fast-growing Rhizobium japonicum strains. Two EcoRI restriction fragments from a plasmid of fast-growing R. japonicum hybridized with nif structural genes of R. meliloti, and three EcoRI restriction fragments hybridized with the nod clone of R. meliloti. Cross-hybridization between the hybridizing fragments revealed a reiteration of nod and nif DNA sequences in fast-growing R. japonicum. Both nif structural genes D and H were present on 4.2- and 4.9-kilobase EcoRI fragments, whereas nifK was present only on the 4.2-kilobase EcoR2 fragment. These results suggest that the nif gene organizations in fast-growing and in slow-growing R. japonicum strains are different.     

Evidence for plasmid- and chromosome-borne multiple nif genes in Rhizobium fredii

Rhizobium fredii is a fast-growing rhizobium isolated from the primitive Chinese soybean cultivar Peking and from the wild soybean Glycine soja. This rhizobium harbors nif genes on 150- to 200-megadalton plasmids. By passage on acridine orange plates, we obtained a mutant of R. fredii USDA 206 cured of the 197-megadalton plasmid (USDA 206C) which carries both nif and nod genes. This strain, however, has retained its symbiotic effectiveness. Probing EcoRI digests of wild-type and cured plasmid DNA with a 2.2-kilobase nif DH fragment from Rhizobium meliloti has shown four homologous fragments in the wild-type strain (4.2, 4.9, 10, and 11 kilobases) and two fragments in the cured strain (4.2 and 10 kilobases). EcoRI digests of total DNA show four major bands of homology (4.2, 4.9, 5.8, and 13 kilobases) in both the wild-type and cured strains. The presence of major bands of homology in the total DNA not present in the plasmid DNA indicated chromosomal nif genes. Probing of HindIII digests of total and plasmid DNA led to the same conclusion. Hybridization to the smaller plasmids of USDA 206 and USDA 206C showed the presence of nif genes on at least one of these plasmids, explaining the nif homology in the USDA 206C plasmid digests.     

Evidence for plasmid- and chromosome-borne multiple nif genes in Rhizobium fredii.

Rhizobium fredii is a fast-growing rhizobium isolated from the primitive Chinese soybean cultivar Peking and from the wild soybean Glycine soja. This rhizobium harbors nif genes on 150- to 200-megadalton plasmids. By passage on acridine orange plates, we obtained a mutant of R. fredii USDA 206 cured of the 197-megadalton plasmid (USDA 206C) which carries both nif and nod genes. This strain, however, has retained its symbiotic effectiveness. Probing EcoRI digests of wild-type and cured plasmid DNA with a 2.2-kilobase nif DH fragment from Rhizobium meliloti has shown four homologous fragments in the wild-type strain (4.2, 4.9, 10, and 11 kilobases) and two fragments in the cured strain (4.2 and 10 kilobases). EcoRI digests of total DNA show four major bands of homology (4.2, 4.9, 5.8, and 13 kilobases) in both the wild-type and cured strains. The presence of major bands of homology in the total DNA not present in the plasmid DNA indicated chromosomal nif genes. Probing of HindIII digests of total and plasmid DNA led to the same conclusion. Hybridization to the smaller plasmids of USDA 206 and USDA 206C showed the presence of nif genes on at least one of these plasmids, explaining the nif homology in the USDA 206C plasmid digests.     

In silico structural homology modeling of nif A protein of rhizobial strains in selective legume plants

Symbiosis is a complex genetic regulatory biological evolution which is highly specific pertaining to plant species and microbial strains. Biological nitrogen fixation in legumes is a functional combination of nodulation by nod genes and regulation by nif, fix genes. Three rhizobial strains (Rhizobium leguminosarum, Bradyrhizobium japonicum, and Mesorhizobium ciceri) that we considered for in silico analysis of nif A are proved to be the best isolates with respect to N₂ fixing for ground nut, chick pea and soya bean (in vitro) out of 47 forest soil samples. An attempt has been made to understand the structural characteristics and variations of nif genes that may reveal the factors influencing the nitrogen fixation. The primary, secondary and tertiary structure of nif A protein was analyzed by using multiple bioinformatics tools such as chou-Fasman, GOR, ExPasy ProtParam tools, Prosa -web. Literature shows that the homology modeling of nif A protein have not been explored yet which insisted the immediate development for better understanding of nif A structure and its influence on biological nitrogen fixation. In the present predicted 3D structure, the nif A protein was analyzed by three different software tools (Phyre2, Swiss model, Modeller) and validated accordingly which can be considered as an acceptable model. However further in silico studies are suggested to determine the specific factors responsible for nitrogen fixing in the present three rhizobial strains.     

Phylogenetic position of Rhizobium sp. strain Or 191, a symbiont of both Medicago sativa and Phaseolus vulgaris, based on partial sequences of the 16S rRNA and nifH genes.

Phenotypic and DNA sequence comparisons are presented for eight Rhizobium isolates that were cultured from field-grown alfalfa (Medicago sativa L.) in Oregon. These isolates were previously shown to nodulate both alfalfa and common bean (Phaseolus vulgaris (L.) Savi.). The objective of the present study was to determine their phylogenetic relationships to the normal symbionts of these plants, Rhizobium meliloti and Rhizobium leguminosarum biovar phaseoli, respectively. Phenotypically, the Oregon isolates more nearly resemble strains from P. vulgaris than those from M. sativa. For example, even though nitrogen fixation levels were low with both host species, the symbiotic efficiency of a representative Rhizobium isolate (Or 191) with common bean was twice that observed with alfalfa. Comparative sequencing of a 260-bp segment of the 16S rRNA gene (directly sequenced after amplification by the polymerase chain reaction) demonstrated that Or 191 is not closely related to the type strain of R. meliloti (ATCC 9930), R. leguminosarum (ATCC 10004), or Rhizobium tropici (CIAT 899). Instead, sequence comparisons of the 16S gene indicated that Or 191 belongs to a distinct and previously unrecognized taxonomic group that includes strains that have previously been called R. leguminosarum bv. phaseoli type I. Unlike type I strains, however, Or 191 has only a single copy of the nifH gene (type I strains have three), and the nucleotide sequence of this gene is substantially different from those of other rhizobial and nonrhizobial nifH genes examined thus far.     

Bacteria in the gular and paracloacal glands of the American alligator (Alligator mississippiensis; Reptila, Crocodilia)

Plasmid DNA of six strains of Rhizobium galegae was blotted onto nitrocellulose and hybridized with the 4.8 kb PstI fragment of pRme4lb, a megaplasmid carrying the nifH and the nifD genes of Rhizobium meliloti. DNA sequences homologous to the nif genes were localized on the megaplasmid or on the large plasmid bands of the R. galegae strains tested. In three of the strains analysed the nif genes were located on the megaplasmids. In the other three strains investigated, which also possessed megaplasmids, the nif genes were located on the smaller plasmids.     

斜茎黄芪根瘤菌结瘤基因nodA PCR扩增及PCR-RFLP分析

对采自我国北方地区的16株斜茎黄芪根瘤菌代表菌株的共同结瘤基因nodA进行了PCR扩增及PCR-RFLP分析研究。来自Mesorhizobium和Rhizobium系统发育分支的代表菌株都得到了nodA PCR扩增产物;而来自Agrobacterium系统发育分支的代表菌株都没有得到nodA PCR扩增产物。进一步的nodAPCR-RFLP分析结果表明斜茎黄芪根瘤菌具有很大的nodA基因遗传多样性,具有4种不同的16S rDNAPCR-RFLP遗传图谱类型的12株斜茎黄芪根瘤菌具有8种不同的nodA PCR-RFLP遗传图谱类型。但是斜茎黄芪根瘤菌nodA基因遗传多样性随种群而变化,来自M.septentrionale的具有相同的16S rDNA PCR-RFLP遗传图谱类型的4个代表菌株具有4种不同的nodA PCR-RFLP遗传图谱类型;而来自M.tempera-tum的具有相同的16S rDNA PCR-RFLP遗传图谱类型3个代表菌株则具有相同的nodA PCR-RFLP遗传图谱类型。此外,来自不同种的具有不同16S rDNA PCR-RFLP遗传图谱类型的菌株却具有相同的nodA PCR-RFLP遗传图谱类型,说明nodA基因可能在根瘤菌的不同种间发生了水平转移。     

Phylogenetic position of Rhizobium sp. strain Or 191, a symbiont of both Medicago sativa and Phaseolus vulgaris, based on partial sequences of the 16S rRNA and nifH genes.

Phenotypic and DNA sequence comparisons are presented for eight Rhizobium isolates that were cultured from field-grown alfalfa (Medicago sativa L.) in Oregon. These isolates were previously shown to nodulate both alfalfa and common bean (Phaseolus vulgaris (L.) Savi.). The objective of the present study was to determine their phylogenetic relationships to the normal symbionts of these plants, Rhizobium meliloti and Rhizobium leguminosarum biovar phaseoli, respectively. Phenotypically, the Oregon isolates more nearly resemble strains from P. vulgaris than those from M. sativa. For example, even though nitrogen fixation levels were low with both host species, the symbiotic efficiency of a representative Rhizobium isolate (Or 191) with common bean was twice that observed with alfalfa. Comparative sequencing of a 260-bp segment of the 16S rRNA gene (directly sequenced after amplification by the polymerase chain reaction) demonstrated that Or 191 is not closely related to the type strain of R. meliloti (ATCC 9930), R. leguminosarum (ATCC 10004), or Rhizobium tropici (CIAT 899). Instead, sequence comparisons of the 16S gene indicated that Or 191 belongs to a distinct and previously unrecognized taxonomic group that includes strains that have previously been called R. leguminosarum bv. phaseoli type I. Unlike type I strains, however, Or 191 has only a single copy of the nifH gene (type I strains have three), and the nucleotide sequence of this gene is substantially different from those of other rhizobial and nonrhizobial nifH genes examined thus far.     

Formation of Rhizobium phaseoli symbiotic plasmids by genetic recombination

We report here the formation of symbiotic plasmids (pSyms), by genetic recombination between rearranged pSyms, which lack symbiotic information, and resistance plasmids carrying parts of different symbiotic plasmids (R's). This recombination was found to occur both between plasmids derived from different Rhizobium phaseoli isolates, and between plasmids derived from strains obtained from the same original isolate. We also present evidence on the formation of a functional symbiotic plasmid by recombination of an R', carrying nif and nod genes from strain CFN42, and an indigenous plasmid present in this strain (pCFN42e), which was thought to be unrelated to its symbiotic plasmid (pCFN42d). These data are discussed with respect to the stability and transfer of Rhizobium symbiotic information.     

Interaction of nod and exo Rhizobium meliloti in alfalfa nodulation

Among the genes of Rhizobium meliloti SU47 that affect nitrogen-fixing symbiosis with alfalfa are nod genes, in which mutations block nodule induction, and exo genes, in which mutations allow nodule formation but block rhizobial exopolysaccharide production as well as nodule invasion and nitrogen fixation. To investigate whether an exo+ bacterium can "help" (that is, reverse the symbiotic defect of) an exo mutant in trans, we have coinoculated alfalfa with pairs of rhizobia of different genotypes. Coinoculant genotypes were chosen so that the exo+ helper strain was nif while the exo "indicator" strain was nif+, and thus any fixation observed was carried out by the exo coinoculant. We find that a nod exo+ coinoculant can help an exo mutant both to invade nodules and to fix nitrogen. However, a nod+ exo+ coinoculant cannot help an exo mutant: Few exo bacteria are recovered from nodules, some bacteroids differentiate into bizarre aberrant forms, and the nodules fail to fix nitrogen. In a triple coinoculation, the effect of nod+ helper supersedes that of nod helper. Implications of these results for interaction of nod and exo gene products are discussed.     

Sugar-binding activity of pea lectin enhances heterologous infection of transgenic alfalfa plants by Rhizobium leguminosarum biovar viciae

Transgenic alfalfa (Medicago sativa L. cv Regen) roots carrying genes encoding soybean lectin or pea (Pisum sativum) seed lectin (PSL) were inoculated with Bradyrhizobium japonicum or Rhizobium leguminosarum bv viciae, respectively, and their responses were compared with those of comparably inoculated control plants. We found that nodule-like structures formed on alfalfa roots only when the rhizobial strains produced Nod factor from the alfalfa-nodulating strain, Sinorhizobium meliloti. Uninfected nodule-like structures developed on the soybean lectin-transgenic plant roots at very low inoculum concentrations, but bona fide infection threads were not detected even when B. japonicum produced the appropriate S. meliloti Nod factor. In contrast, the PSL-transgenic plants were not only well nodulated but also exhibited infection thread formation in response to R. leguminosarum bv viciae, but only when the bacteria expressed the complete set of S. meliloti nod genes. A few nodules from the PSL-transgenic plant roots were even found to be colonized by R. leguminosarum bv viciae expressing S. meliloti nod genes, but the plants were yellow and senescent, indicating that nitrogen fixation did not take place. Exopolysaccharide appears to be absolutely required for both nodule development and infection thread formation because neither occurred in PSL-transgenic plant roots following inoculation with an Exo(-) R. leguminosarum bv viciae strain that produced S. meliloti Nod factor.     

Nitrogen fixation (nif) genes and large plasmids of Rhizobium japonicum.

The location of structural nitrogen-fixation genes was determined for the slow- and fast-growing types of Rhizobium japonicum. Slow-growing R. japonicum strains do not harbor structural nif genes, homologous to nifD and nifH, on large plasmids (100 to 200 megadaltons). In contrast, all fast-growing R. japonicum strains, except PRC194, contain structural nif genes on large plasmids.     

Identification of a Rhizobium trifolii plasmid coding for nitrogen fixation and nodulation genes and its interaction with pJB5JI, a Rhizobium leguminosarum plasmid

Rhizobium trifolii T37 contains at least three plasmids with sizes of greater than 250 megadaltons. Southern blots of agarose gels of these plasmids probed with Rhizobium meliloti nif DNA indicated that the smallest plasmid, pRtT37a, contains the nif genes. Transfer of the Rhizobium leguminosarum plasmid pJB5JI, which codes for pea nodulation and the nif genes and is genetically marked with Tn5, into R. trifolii T37 generated transconjugants containing a variety of plasmid profiles. The plasmid profiles and symbiotic properties of all of the transconjugants were stably maintained even after reisolation from nodules. The transconjugant strains were placed into three groups based on their plasmid profiles and symbiotic properties. The first group harbored a plasmid similar in size to pJB5JI (130 megadaltons) and lacked a plasmid corresponding to pRtT37a. These strains formed effective nodules on peas but were unable to nodulate clover and lacked the R. trifolii nif genes. This suggests that genes essential for clover nodulation as well as the R. trifolii nif genes are located on pRtT37a and have been deleted. The second group harbored hybrid plasmids formed from pRtT37a and pJB5JI which ranged in size from 140 to ca. 250 megadaltons. These transconjugants had lost the R. leguminosarum nif genes but retained the R. trifolii nif genes. Strains in this group nodulated both peas and clover but formed effective nodules only on clover. The third group of transconjugants contained a hybrid plasmid similar in size to pRtT37b. These strains contained the R. trifolii and R. leguminosarum nif genes and formed N2-fixing nodules on both peas and clover.     

Slow-growing Rhizobium japonicum comprises two highly divergent symbiotic types

We examined the interrelationships of the genomes of 10 slow-growing strains of Rhizobium japonicum to provide a foundation for molecular genetic studies of these agriculturally important endosymbiotic bacteria of commercial soybeans. The degree of base substitution in and around known symbiotic genes (nif and presumptive nod), constitutively expressed genes (glnA and recA), and two other cloned sequences was estimated from restriction site variation by using cloned DNAs as hybridization probes to genomic Southern blots. Two highly divergent patterns of conservation of nifDH genes and nod-homologous sequences were found. On this basis, we classified the strains as the symbiotic genotypes sTI or sTII. Existing maps of the nif genes of R. japonicum apply only to strains of the sTI genotype. This division was further characterized by four other probes which also distinguished two sublines within sTI. Phenograms were constructed depicting interrelationships according to DNA sequence divergence. sTI and sTII are two highly divergent evolutionary lines consistent with the status of individual species. Neither is related to fast-growing Rhizobium strains (PRC strains) nodulating soybeans.     

Natural endophytic association between Rhizobium etli and maize (Zea mays L.)

Maize (Zea mays) and bean (Phaseolus vulgaris) have been traditionally grown in association for thousands of years in Mesoamerica. From surface sterilized maize roots, we have isolated over 60 Rhizobium strains that correspond to Rhizobium etli bv. phaseoli (the main symbiont of bean) on the basis of 16S rRNA gene restriction patterns, metabolic enzyme electropherotypes, organization of nif genes, and the ability to nodulate beans. The colonization capacity of some of the isolates was tested with an unimproved maize cultivar and with 30 maize land races. Increases in plant dry weight upon R. etli inoculation were recorded with some of the land races, and these increases may be related to plant growth promotion effects. Additionally, from within maize grown in monoculture we have also recovered R. etli isolates recognizable by their 16S rRNA gene types, which lack nif genes and are incapable of nodulating bean. These strains are presumed to correspond to the earlier described non-symbiotic R. etli obtained from bean rhizosphere.     

Large plasmids of fast-growing rhizobia: homology studies and location of structural nitrogen fixation (nif) genes.

A single large plasmid was isolated from multiplasmid-harboring strains Rhizobium leguminosarum 1001 and R. trifolii 5. These single plasmids, as well as the largest plasmid detectable in R. phaseoli 3622, hybridized with part of the nif structural genes of Klebsiella pneumoniae. In contrast, the plasmids of R. meliloti strains V7 and L5-30 did not show hybridization with the nif genes of K. pneumoniae, indicating that these genes might be located either on the chromosome or on a much larger plasmid which as yet has not been isolated. Studies of the homology between plasmids of fast-growing Rhizobium species showed that a specific deoxyribonucleic acid sequence, which carries the structural genes for nitrogenase, is highly conserved on a plasmid in R. leguminosarum, R. trifolii, and R. phaseoli. Furthermore, it was found that this type of plasmid in the different species shares extensive deoxyribonucleic acid homology, suggesting that strains in the R. leguminosarum cluster have preserved a nif plasmid.     

Molecular diversity and phylogeny of rhizobia associated with wild legumes native to Xinjiang, China

A total of 111 rhizobial strains were isolated from wild legumes in Xinjiang, an isolated region of northwest China. Nine genomic species belonging to four genera of Rhizobium, Mesorhizobium, Ensifer, and Bradyrhizobium were defined among these strains based on the characterization of amplified 16S ribosomal DNA restriction analysis (ARDRA), restriction fragment length polymorphism (RFLP) analysis of 16S-23S rDNA intergenic spacers (IGS), 16S rRNA gene sequencing and multilocus sequence analysis (MLSA). Twenty-five nodC types corresponding to eight phylogenetic clades were divided by RFLP and sequence analysis of the PCR-amplified nodC gene. The acid-producing Rhizobium and Mesorhizobium species were predominant, which may be related to both the local environments and the hosts sampled. The present study also showed the limitation of using nod genes to estimate the host specificity of rhizobia.