Transfer of a host range plasmid from Rhizobium leguminosaum to fast-growing bacteria that nodulate soybeans

The Rhizobium leguminosarum host range plasmid pJB5JI was transferred to three fast-growing bacterial strains able to nodulate soybeans. These strains, isolated in China, contained plasmids and were able to transfer pJB5JI back to R. leguminosarum . Soybean strains carrying pJB5JI elicited early stages of nodule development on peas.     

Behavior of plasmid pJB5JI in Rhizobium huakuii under free-living and symbiotic conditions

The Rhizobium leguminosarum biovar viceae host-range plasmid pJB5JI was transferred into Rhizobium huakuii strains, both wild-type 7653R and its sym plasmid-cured mutant 7653R-1. Transconjugant 7653R-1 (pJB5JI) acquired the ability to form ineffective nodules on pea plants, whereas transconjugant 7653R (pJB5JI) could not do so, indicating that the indigenous symbiotic plasmid could restrict the functional expression of pJB5JI. On the other hand, transconjugant 7653R (pJB5JI) showed higher nitrogenase activity on A. sinicus and higher shoot dry weight than the recipient strain 7653R. The alien plasmid pJB5JI in both kinds of transconjugants remained stable during frequent transfer on culture media, but in part of the isolates from nodules formed by them the pJB5JI was not visualized on gel by the Eckhardt procedure. Southern hybridization with Tn5 and nod gene probes showed that these isolates still reserved, at least in part, DNA of pJB5JI, which was probably intergrated onto the chromosome of cells.     

Sym plasmid transfer to various symbiotic mutants of Rhizobium trifolii, R. leguminosarum, and R. meliloti.

Two self-transmissible Sym(biosis) plasmids, one encoding pea-specific nodulation and nitrogen-fixation functions (plasmid pJB5JI) and the other encoding clover-specific nodulation and nitrogen-fixation functions (plasmid pBR1AN) were used to determine whether the symbiotic genes encoded on these plasmids are expressed in various members of the Rhizobiaceae. The host specificity of Rhizobium trifolii and R. leguminosarum Sym plasmid-cured strains could be directly determined by the transfer to these strains of the appropriate Sym plasmid. The nodulation of white clovers was restored by either plasmid pJB5JI or pBR1AN when these plasmids were transferred to two transposon Tn5-induced hair-curling (Hac-) R. trifolii mutants. In addition, lucerne nodulation was restored to a Hac- R. meliloti mutant when either plasmid pBR1AN or pJB5JI was transferred to this strain. The phenotype of nonmucoid (Muc-) Rhizobium mutants, which had altered cell surfaces, was not influenced by the transfer to these strains of plasmid pBR1AN or plasmid pJB5JI.     

Transfer of the Pea Symbiotic Plasmid pJB5JI in Nonsterile Soil

Transfer of the pea (Pisum sativum L.) symbiotic plasmid pJB5JI between strains of rhizobia was examined in sterile and nonsterile silt loam soil. Sinorhizobium fredii USDA 201 and HH003 were used as plasmid donors, and symbiotic plasmid-cured Rhizobium leguminosarum 6015 was used as the recipient. The plasmid was carried but not expressed in S. fredii strains, whereas transfer of the plasmid to R. leguminosarum 6015 rendered the recipient capable of nodulating pea plants. Confirmation of plasmid transfer was obtained by acquisition of plasmid-encoded antibiotic resistance genes, nodulation of pea plants, and plasmid profiles. Plasmid transfer in nonsterile soil occurred at frequencies of up to 10⁻⁴ per recipient and appeared to be highest at soil temperatures and soil moisture levels optimal for rhizobial growth. Conjugation frequencies were usually higher in sterile soil than in nonsterile soil. In nonsterile soil, transconjugants were recovered only with strain USDA 201 as the plasmid donor. Increasing the inoculum levels of donor and recipient strains up to 10⁹ cells g of soil⁻¹ increased the number of transconjugants; peak plasmid transfer frequencies, however, were found at the lower inoculum level of 10⁷ cells g of soil⁻¹. Plasmid transfer frequencies were raised in the presence of the pea rhizosphere or by additions of plant material. Transconjugants formed by the USDA 201(pJB5JI) × 6015 mating in soil formed effective nodules on peas.     

Intergeneric complementation by Agrobacterium tumefaciens chromosomal genes and its potential use for linkage mapping

The IncP1 type plasmids pULB113 (RP4:: mini-Mu) and pJB3JI were used for chromosome mobilization and R prime formation in Agrobacterium tumefaciens. With pULB113, R primes were selected for complementation of an auxotrophic marker in an Alcaligenes eutrophus recipient strain. With pJB3JI, R primes containing the Agrobacterium chromosomal virulence region chv, inactivated by a Tn5 insertion, were constructed. Selection was for kanamycin resistance in E. coli strain GV1000. Complementation tests were performed in auxotrophic A. tumefaciens, A. eutrophus and Pseudomonas fluorescens strains. This allowed us to map 9 loci, including the chv loci, in a region accounting for about 10% of the Agrobacterium chromosome.     

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.     

Marking of a Sym plasmid of Rhizobium with Tn7

Summary Transposon Tn7 was inserted into wide host range plasmid pSUP202 and used as a suicide plasmid vehicle for transposon mutagenesis in Rhizobium leguminosarum. Tn7 is transposed with high frequency into the self-transmissible plasmid pJB5JI without affecting the transfer, nodulation and nitrogen fixation functions. Tn7 transposition provides a useful tool for marking symbiotic plasmids.     

豌豆根瘤菌共生基因pJB5JI与华癸中生根瘤菌7653R共生质粒的相互关系

华癸中生根瘤菌(Mesorhizobium huakuii)7653R是分离自我国南方水稻田的一株根瘤菌,含有2个内源质粒:p7653Ra和p7653Rb,其中7653Rb是共生质粒.通过Tn5-sacB的插入方法来消除质粒,获得7653Rb消除的突变株7653RD.将豌豆根瘤菌T83K3的共生质粒pJB5JI导入7653R和7653RD中,盆栽结果表明含有pJB5JI的转移接合子7653R-197的竞争结瘤能力和共生固氮能力均高于7653R.pJB5JI不能恢复7653RD在紫云英上的结瘤能力.含有pJB5JI的7653RD可以在豌豆上结无效瘤,表明pJB5JI可以在7653R的染色体背景下表达其功能.对转移接合子中的质粒稳定性进行检测,结果表明pJB5JI在人工传代的情况下可以稳定存在,但经过共生之后发生了遗传分离,对转移接合子和出发菌株及分离菌株进行kan基因的PCR扩增,除了受体菌外其他菌株都可得到PCR产物,由此推测,pJB5JI可能部分或全部整合到了受体菌的染色体基因组中.     

Relative genetic structure of a population of Rhizobium meliloti isolated directly from soil and from nodules of alfalfa (Medicago sativa) and sweet clover (Melilotus alba)

Insertion sequence (IS) hybridization was used to define the structure of a population of Rhizobium meliloti isolated directly from soil and from nodules of Medicago sativa (alfalfa) and Melilotus alba (sweet clover) grown under controlled conditions and inoculated with a suspension of the same soil. The detection of R. meliloti isolated from soil on agar plates was facilitated by use of a highly species specific DNA probe derived from ISRm5. All R. meliloti obtained directly from soil proved to be symbiotic (i.e. nodulated and fixed nitrogen with alfalfa). Analysis of 293 R. meliloti isolates revealed a total of 17 distinct IS genotypes of which 9, 9 and 15 were from soil, M. alba and M. sativa, respectively; 8 genotypes were common to soil and both plant species. The frequency of R. meliloti genotypes from soil differed markedly from that sampled from nodules of both legume species: 5 genotypes represented about 90% of the isolates from soil whereas a single genotype predominated among isolates from nodules accounting for more than 55% of the total. The distribution of genotypes differed between M. sativa and M. alba indicating species variation in nodulation preferences for indigenous R. meliloti. The data are discussed in the context of competition for nodulation of the host plant and the selection of Rhizobium strains for use in legume inoculants. This study has ecological implications and suggests that the composition of R. meliloti populations sampled by the traditionally used host legume may not be representative of that actually present in soil.     

Mineral Soils as Carriers for Rhizobium Inoculants

Mineral soil-based inoculants of Rhizobium meliloti and Rhizobium phaseoli survived better at 4°C than at higher temperatures, but ca. 15% of the cells were viable at 37°C after 27 days. Soil-based inoculants of R. meliloti, R. phaseoli, Rhizobium japonicum, and a cowpea Rhizobium sp. applied to seeds of their host legumes also survived better at low temperatures, but the percent survival of such inoculants was higher than peat-based inoculants at 35°C. Survival of R. phaseoli, R. japonicum, and cowpea rhizobia was not markedly improved when the cells were suspended in sugar solutions before drying them in soil. Nodulation was abundant on Phaseolus vulgaris derived from seeds that had been coated with a soil-based inoculant and stored for 165 days at 25°C. The increase in yield and nitrogen content of Phaseolus angularis grown in the greenhouse was the same with soil-and peat-based inoculants. We suggest that certain mineral soils can be useful and readily available carriers for legume inoculants containing desiccation-resistant Rhizobium strains.     

Hydrogen Evolution from Alfalfa and Clover Nodules and Hydrogen Uptake by Free-Living Rhizobium meliloti

A series of Rhizobium meliloti and Rhizobium trifolii strains were used as inocula for alfalfa and clover, respectively, grown under bacteriologically controlled conditions. Replicate samples of nodules formed by each strain were assayed for rates of H₂ evolution in air, rates of H₂ evolution under Ar and O₂, and rates of C₂H₂ reduction. Nodules formed by all strains of R. meliloti and R. trifolii on their respective hosts lost at least 17% of the electron flow through nitrogenase as evolved H₂. The mean loss from alfalfa nodules formed by 19 R. meliloti strains was 25%, and the mean loss from clover nodules formed by seven R. trifolii strains was 35%. R. meliloti and R. trifolii strains also were cultured under conditions that were previously established for derepression of hydrogenase synthesis. Only strains 102F65 and 102F51 of R. meliloti showed measurable activity under free-living conditions. Bacteroids from nodules formed by the two strains showing hydrogenase activity under free-living conditions also oxidized H₂ at low rates. The specific activity of hydrogenase in bacteroids formed by either strain 102F65 or strain 102F51 of R. meliloti was less than 0.1% of the specific activity of the hydrogenase system in bacteroids formed by H₂ uptake-positive Rhizobium japonicum USDA 110, which has been investigated previously. R. meliloti and R. trifolii strains tested possessed insufficient hydrogenase to recycle a substantial proportion of the H₂ evolved from the nitrogenase reaction in nodules of their hosts. Additional research is needed, therefore, to develop strains of R. meliloti and R. trifolii that possess an adequate H₂-recycling system.     

A Positive Strain Identification Method for Rhizobium meliloti

About 80% of Rhizobium meliloti strains contain 1 to 11 copies of insertion sequence ISRm1 in their genomes (R. Wheatcroft and R. J. Watson, J. Gen. Microbiol. 134:113-121, 1988). Hybridization to separated genomic DNA fragments with an ISRm1-specific probe produces patterns of hybridization bands which are distinctive for each strain. These patterns can be compared between strains to prove or disprove common identity. In most cases relatedness can be inferred despite phenotypic differences or minor genomic alterations.     

Host-Symbiont Specificity Expressed during Early Adsorption of Rhizobium meliloti to the Root Surface of Alfalfa

Early (4 h) adsorption of Rhizobium meliloti L5-30 in low numbers to alfalfa roots in mineral solution was examined for competition with other bacterial strains. All tested competitor strains decreased the adsorption of L5-30 by extents which depended on the strain and its concentration. The decrease of adsorption by R. meliloti competitors (all of them infective in alfalfa) was nearly complete at saturation (97 to 99% decrease). All other heterologous rhizobia and Agrobacterium tumefaciens at saturating concentrations (10⁶ to 10⁷ per ml) decreased adsorption of L5-30 only partially, less than 60%. The differential effects of homologous and heterologous competitors indicate that initial adsorption of R. meliloti to the root surface of its host occurs in symbiont-specific as well as nonspecific modes and suggest the existence of binding sites on roots which are highly selective for the specific microsymbiont in the presence of other heterologous bacteria even in very unfavorable (less than 10⁻⁴) symbiont-competitor concentration ratios.     

Degradation of the Herbicide Glyphosate by Members of the Family Rhizobiaceae

Several strains of the family Rhizobiaceae were tested for their ability to degrade the phosphonate herbicide glyphosate (isopropylamine salt of N-phosphonomethylglycine). All organisms tested (seven Rhizobium meliloti strains, Rhizobium leguminosarum, Rhizobium galega, Rhizobium trifolii, Agrobacterium rhizogenes, and Agrobacterium tumefaciens) were able to grow on glyphosate as the sole source of phosphorus in the presence of the aromatic amino acids, although growth on glyphosate was not as fast as on P_i. These results suggest that glyphosate degradation ability is widespread in the family Rhizobiaceae. Uptake and metabolism of glyphosate were studied by using R. meliloti 1021. Sarcosine was found to be the immediate breakdown product, indicating that the initial cleavage of glyphosate was at the C—P bond. Therefore, glyphosate breakdown in R. meliloti 1021 is achieved by a C—P lyase activity.     

A chromosomal linkage map of Agrobacterium tumefaciens and a comparison with the maps of Rhizobium spp

Summary Plasmid R68.45 was found to mobilize the Agrobacterium tumefaciens chromosome apolarly. With the aid of this R plasmid the linkage between 26 markers was determined, from which a circular genetic map of the A. tumefaciens chromosome could be constructed. The recombinants obtained were stable i.e. they did not segregate strains, with the parental phenotype upon purification. A system for the polar transfer of chromosomal material from a fixed origin was developed for A. tumefaciens. It was found that R plasmid pRL189, which carries a copy of transposon Tn5, is able to mobilize the chromosome polarly from chromosomal Tn5-insertion sites. A. tumefaciens phe-1 and trp-22 auxotrophs became prototrophic after the introduction of R primes pAJ21JI and pAJ73JI, respectively, which carry the corresponding phe and trp genes of Rhizobium meliloti. This result enabled a preliminary comparison of the gene orders in A. tumefaciens and Rhizobium spp. which suggested that the chromosome maps of these organisms are quite similar.     

Phosphoenolpyruvate carboxylase in Corynebacterium glutamicum is dispensable for growth and lysine production

Abstract The symbiotic plasmid pRHc1J and the helper plasmid pJB3JI were transferred from Rhizobium "hedysari" strain RJ77 to Agrobacterium tumefaciens strain GMI9023. Transconjugants harboured recombinant plasmids (R-prime plasmids) consisting of pJB3JI carrying DNA fragments, of different sizes, surrounding the Tn 5 mob insert in pRHc1J. Two of these R-prime plasmids (pR1 and pR2) carried nod genes and were able to restore the Nod⁺ phenotype of pSym⁻ derivatives of R. "hedysari" . The R. "hedysari" nod genes harboured by both R-primes were expressed in R. leguminosarum biovar trifolii wild-type but not in a pSym⁻ derivative.     

Extended Region of Nodulation Genes in Rhizobium meliloti 1021. I. Phenotypes of Tn5 Insertion Mutants

Rhizobium meliloti Nod^- mutant WL131, a derivative of wild-type strain 102F51, was complemented by a clone bank of wild-type R. meliloti 1021 DNA, and clone pRmJT5 was recovered. Transfer of pRmJT5 conferred alfalfa nodulation on other Rhizobium species, indicating a role in host range determination for pRmJT5. Mutagenesis of pRmJT5 revealed several segments in which transposon insertion causes delay in nodulation, and/or marked reduction of the number of nodules formed on host alfalfa plants. The set of mutants indicated five regions in which nod genes are located; one mutant, nod-216, is located in a region not previously reported to encode a nodulation gene. Other mutant phenotypes correlated with the positions of open reading frames for nodH, nodF and nodE , and with a 2.2-kb EcoRI fragment. A mutant in nodG had no altered phenotype in this strain. One nodulation mutant was shown to be a large deletion of the common nod gene region. We present a discussion comparing the various studies made on this extended nod gene region.     

Serological Relatedness of Rhizobium fredii to Other Rhizobia and to the Bradyrhizobia

Several isolates of Rhizobium fredii were examined for their serological relatedness to each other, to Bradyrhizobium japonicum, and to other fast- and slow-growing rhizobia. Immunofluorescence, agglutination, and immunodiffusion analyses indicated that R. fredii contains at least three separate somatic serogroups, USDA 192, USDA 194, and USDA 205. There was no cross-reaction between any of the R. fredii isolates and 13 of the 14 B. japonicum somatic serogroups tested. Cross-reactions were obtained with antisera from R. fredii and serogroup 122 of B. japonicum, Rhizobium meliloti, and several fast-growing Rhizobium spp. for Leucaena, Sesbania, and Lablab species. The serological relationship between R. fredii and R. meliloti was examined in more detail, and of 23 R. meliloti strains examined, 8 shared somatic antigens with the type strains from all three R. fredii serogroups. The serological relatedness of R. fredii to B. japonicum and R. meliloti appears to be unique since the strains are known to be biochemically and genetically diverse.     

A chromosomal genetic map of Rhizobium sp. NGR234 generated with Tn5-Mob

Summary Rhizobium sp. NGR234 in a fast-growing Rhizobium strain with a broad host range. The location and role of chromosomal genes involved in cellular metabolism or in the legume symbioses is unknown. We isolated a series of auxotrophic and antibiotic resistant mutants of NGR234 and utilized a chromosome mobilization system based on Tn5-Mob and pJB3JI; Tn5-Mob donor strains behaved like Hfr strains, transferring the chromosome polarly at high frequency from a fixed point of insertion. The use of four different strains with Tn5-Mob located at different nutritional loci in crosses with double auxotrophic recipients, allowed us to build up a circular linkage map of NGR234 based on relative recombination frequencies. Also, symbiotically important genes identified by site-directed mutagenesis, such as hemA and ntrA, could be located and mapped on the chromosome.Abbreviations Tc tetracycline - Sp spectinomycin - Rif rifampicin - Km kanamycin     

Identification of the host-range DNA which allows Rhizobium leguminosarum strain TOM to nodulate cv. Afghanistan peas

Summary The special ability of Rhizobium leguminosarum strain TOM to nodulate cv. Afghanistan peas had previously been shown to be determined by the symbiotic plasmid, pRL5JI, of this strain. A region of pRL5JI, 2.0 kb in size, was found to confer the ability to nodulate cv. Afghanistan peas when transferred to strains of R. leguminosarum which normally fail to nodulate this host. This region of pRL5JI, responsible for the extension of host-range, was closely linked to, but did not include, the genes required for root hair curling. Although extensive homology has been found between the R. leguminosarum nod genes on pRL5JI and those on the normal symbiotic plasmid pRL1JI, a fragment from the 2.0 kb region involved in nodulation of cv. Afghanistan has been identified, which was not homologous to DNA in strains which do not nodulate cv. Afghanistan.