Correlation between streptomycin resistance and infectiveness in Rhizobium trifolii

Summary Strains ofRhizobium trifolii became non-infective for red clover after acquiring a defined level of streptomycin resistance (str-r) by mutation or transformation.     

Conjugational transfer of the nodulation-conferring plasmid pWZ2 in Rhizobium trifolii

Summary When the nodulating Rhizobium trifolii strain 24Vio^r containing plasmid RP4 was conjugated with the non-nodulating R. trifolii mutant strain 24Str^rNod^-35, plasmid RP4 was transferred at a frequency 10^-3–10^-4. Two out of nearly three thousand tested transconjugants which contained plasmid RP4 had acquired the ability to form nodules on clovers. Molecular studies of the DNA of both these nodulating transconjugants showed the presence of plasmid RP4 and another plasmid which was not found in the original recipient strain. The size of this second plasmid corresponded to that of the plasmid pWZ2, the elimination of which was correlated with irreversible loss of the nodulating ability of R. trifolii strain 24 (Zurkowski and Lorkiewicz 1979). Plasmid RP4 was eliminated from cells by ethidium bromide, without the loss of nodulating properties. The nodulation capacity, however, was eliminated from transconjugants after incubation of bacteria at elevated temperature. Non-nodulating clones obtained after such incubation did not contain the plasmid pWZ2. The results indicate that the plasmid pWZ2 is a necessary element for induction of nodules by R. trifolii, and that it can be mobilized by plasmid RP4.     

Localization of his genes on the Rhizobium trifolii RS800 linkage map

Summary We have studied N-methyl-N-nitro-N-nitrosoguanidine (NTG)- and Tn5-induced histidine auxotrophic mutants in Rhizobium trifolii. HisGE, hisD and hisH mutants have been characterized. Using the Kemper's equation we have located them on the R. trifolii linkage map. The hisGE and hisD genes are clustered in the same region and are closely linked to the spectinomycin marker. The hisH gene is located in another region equidistant from the streptomycin and rifampicin markers. The two regions carrying his genes are separated by a distance approximately one-third of the length of the chromosome.     

Species-specific, symbiotic plasmid-located repeated DNA sequences in Rhizobium trifolii

Summary A repeated DNA sequence has been characterized in the clover symbiont, Rhizobium trifolii. Analysis of three copies of this repeated sequence revealed that it constitutes a reiteration of the nifHDK promoter region and, in some copies, an additional reiteration of the N-terminal end of the nifH gene. This sequence, as exemplified by the nifHDK promoter region, is highly conserved within all the geographically-distinct isolates of R. trifolii examined, and is located exclusively on the Sym (symbiotic) plasmid. The R. trifolii repeated sequences (designated RtRS) were shown by DNA hybridization analysis to be specific for R. trifolii and not to hybridize to DNA of any other fastgrowing Rhizobium species examined. Based on the observed species-specificity and Sym-plasmid location of these sequences, as well as the available genetic evidence, we propose a model in which the expression of symbiotic genes is host-specifically activated via these species-specific repeated (promoter) sequences. The results presented indicate that the RtRS sequences can be used as a molecular probe for both species and strain identification and should facilitate the molecular taxonomy of Rhizobium.Dedicated to Professor Georg Melchers to celebrate his 50-year association with the journal     

A molecular linkage map of nitrogenase and nodulation genes in Rhizobium trifolii

Summary A molecular map was constructed linking the nitrogenase structural genes (nif) and nodulation genes (nod) in the white clover symbiont, Rhizobium trifolii. In R. trifolii strain ANU843 these two genetic regions are located some 16 kilobases (kb) apart on the 180 kb symbiotic (Sym) plasmid. The molecular linkage of nod and nif genetic regions was established by hybridization analysis using recombinant plasmids containing overlapping cloned sequences. Nodulation genes were located by means of a Tn5-induced nodulation-defective mutant that failed to induce clover root hair curling (Hac^- phenotype). A cloned wild-type DNA fragment was shown to phenotypically correct the Hac^- mutation by complementation. The nifHDK genes were cloned by positive hybridization to another R. trifolii nif-specific probe. Location of the nif genes relative to the nod genes was established by analysis of a Sym plasmid deletion derivative.     

The structure of the O-antigenic side chain of the lipopolysaccharide of Vibrio cholerae 569B (Inaba)

Mineral acid hydrolysis of the lipopolysaccharide from Vibrio cholerae 569B (Inaba) gives an oligosaccharide fraction which was shown, by use of ¹³C NMR and chemical methods, to be a regular α-(1 → 2) linked chain of d-perosamine (4-amino-4,6-dideoxy-d-mannose) units. This chain represents the O-antigen of the lipopolysaccharide, in which the amino functions are acylated with 3-hydroxypropionyl groups. The chromatographic properties of some hydroxamic acids are described and used to characterize these acyl groups.     

The structure of the O-antigenic side chain of the lipopolysaccharide of Vibrio cholerae 569B (Inaba).

Mineral acid hydrolysis of the lipopolysaccharide from Vibrio cholerae 569B (Inaba) gives an oligosaccharide fraction which was shown, by use of 13C NMR and chemical methods, to be a regular alpha-(1 leads to 2) linked chain of D-perosamine (4-amino-4,6-dideoxy-D-mannose) units. This chain represents the O-antigen of the lipopolysaccharide, in which the amino functions are acylated with 3-hydroxypropionyl groups. The chromatographic properties of some hydroxamic acids are described and used to characterize these acyl groups.     

Tn5 mutagenesis of Rhizobium trifolii host-specific nodulation genes result in mutants with altered host-range ability

Summary A 14 kb DNA fragment from the Sym plasmid of the Rhizobium trifolii strain ANU843, known to carry common nodulation nod and host specific nodulation hsn genes, was extensively mutagenised with transposon Tn5. A correlation between the site of Tn5 insertion and the induced nodulation defect led to the identification of three specific regions (designated I, II, III) which affected nodulation ability. Twenty-three Tn5 insertions into region I (ca. 3.5 kb) affected normal root hair curling ability and abolished infection thread formation. The resulting mutants were unable to nodulate all tested plant species. Tn5 insertions in regions II and III resulted in mutants which showed an exaggerated root hair curling (Hac⁺⁺) response on clover plants. Ten region II mutants which occurred over a 1.1 kb area showed a greatly reduced nodulation ability on clovers and produced aborted, truncated infection threads. Tn5 insertions into region III (ca. 1.5 kb) altered the outcome of crucial early plant recognition and infection steps by R. trifolii. Seven region III mutants displayed host-range properties which differed from the original parent strain. Region III mutants were able to induce marked root hair distortions, infection threads, and nodules on Pisum sativum including the recalcitrant Afghanistan variety. In addition region III mutants showed a poor nodulation ability on Trifolium repens even though the ability to induce infection threads was retained on this host. The altered host-range properties of region III mutants could only be revealed by mutation and the mutant phenotype was shown to be recessive.     

The structure of the homopolymeric O-specific chain from the phenol soluble LPS of the Rhizobium loti type strain NZP2213

The O-specific polysaccharide of the phenol soluble lipopolysaccharide (LPS) (LPS-P) of the Rhizobium loti NZP2213 strain consists of a homopolymeric chain of α-1, 3-linked units of 2-O-acetyl-6-deoxy- -talopyranose, very probably terminated by a single unit of 2-O-acetyl-6-deoxy- -talopyranose. The hydrophobic character of the long O-chains explains the phenol solubility of LPS-P, in contrast to the water solubility of LPS-W, which is of R-character and accordingly lacks the O-acetyl-6d-talose units.     

Transduction in Rhizobium meliloti

Summary Of 21Rhizobium meliloti temperate phages, 12 transduced streptomycin resistance (str-r) with a frequency of 10⁻⁵ to 10⁻⁷. Lysine dependence was transduced with frequency of 10⁻⁷. Five transducing phages were used in experiments on the transfer of effectiveness from effective donor strain to 11 ineffective strains. However, plant tests did not reveal changes in recipient effectiveness.     

Presence of Rhizobium Etli bv . Phaseoli and Rhizobium Gallicum bv . Gallicum in Egyptian Soils

Seven bean rhizobial strains EBRI 2, 3, 21, 24, 26, 27 and 29 identified as Rhizobium etli, and EBRI 32 identified as Rhizobium gallicum, isolated from Egyptian soils and which nodulated Phaseolus vulgaris efficiently, were subjected to hybridization with a nifH probe in order to estimate the copy number of this gene. Seven strains (EBRI 2, 3, 21, 24, 26, 27 and 29) which were only able to nodulate Phaseolus vulgaris, contained three copies of the nifH gene, consistent with their identification as Rhizobium etli bv. phaseoli. Only one strain (EBRI 32) which nodulated both Phaseolus vulgaris and Leucaena leucocephala, had one copy of nifH gene. This confirmed the classification of this strain as Rhizobium gallicum bv. gallicum.     

Localized mutagenesis in Rhizobium japonicum

Summary The slow-growing soybean symbiont, Rhizobium japonicum, has not readily been accessible so far to classical mutational analysis of genes responsible for symbiotic nitrogen fixation. We have overcome part of this problem by the successful application of a site-directed mutagenesis technique to this organism. The following steps are involved: (i) local Tn5 mutagenesis, in E. coli, of cloned R. japonicum DNA (e.g. the nifDK operon); (ii) conjugational transfer of the mutated DNA into R. japonicum using vectors which are unable to replicate there; (iii) selection of R. japonicum exconjugants which have exchanged their wild-type genomic DNA region for the Tn5-containing fragment by homologous recombination. While using this technique it appeared mandatory to distinguish double-crossover-events (true replacements) from single-crossover events (replicon fusions or cointegrations). Only the true replacement mutants were genetically stable; their phenotypes were determined with respect to nodulation (Nod) and nitrogen fixation (Fix) by plant infection tests. Tn5 mutations within nifD and nifK caused a Nod⁺ Fix^- phenotype, whereas mutants with insertions in the immediate vicinity on either side of nifDK were found to be Nod⁺ Fix⁺, suggesting that genes flanking nifDK may not be involved in the nitrogen fixing symbiosis. Nodule reisolates were found to carry Tn5 at their original locations.     

Transposon mutagenesis of Rhizobium japonicum

Summary We report here successful mutagenesis with Transposon Tn5 of three slow-growing strains of Rhizobium japonicum USDA 122, 61A76, USDA 74 and one fast-growing strain, USDA 191. Strains were chosen as representatives of different DNA homology and serogroups of this divergent species, which effectively nodulate North American soybean cultivars. The source of Tn5 was the suicide plasmid pGS9, which possesses broad host range N-type transfer genes in a narrow host range p15A replicon. The selection of Tn5 mutants was facilitated by the expression of the Tn5 encoded streptomycin gene in R. japonicum. Kanamycin and streptomycin resistant colonies appeared from interspecific crosses with E. coli at optimal frequencies of 10^-6 for R. japonicum USDA 61A76 and USDA 191 and 5x10^-7 for R. japonicum USDA 122 and USDA 74. Altogether, 6550 Tn5 mutants were isolated in USDA 122 and 61A76, and a small number from USDA 74 and USDA 191. Colony hybridization showed that all tested mutants of 61A76 and USDA 122 contained Tn5. Physical analysis of total DNAs from representative numbers of USDA 122, 61A76 and USDA 191 mutants revealed that each of them carried one copy of the transposon integrated randomly in the genome. This was also true for most USDA 74 mutants. Screening of mutants for auxotrophy showed frequencies of 0.2% for USDA 122 and 0.08% for 61A76. Several symbiotically defective mutants were identified on plants, Glycine soja and G. max.     

Fertility inhibition in Rhizobium lupini by the resistance plasmid RP4

Summary R plasmid RP4 inhibits the fertility of R. lupini. An RP4 carrying R. lupini donor strain is no longer capable of transferring chromosomal genes. After loss of RP4 the R. lupini fertility reappears. Plasmid RP4 spontaneously mutates at high frequency in R. lupini. RP4 mutants which do not inhibit fertility were isolated. These mutants were always transfer-defective, too. It is postulated that the genetic information for fertility inhibition in R. lupini is a substantial part of the transfer unit of the RP4 plasmid.     

Characterization of recA genes and recA mutants of Rhizobium meliloti and Rhizobium leguminosarum biovar viciae

Summary DNA fragments carrying the recA genes of Rhizobium meliloti and Rhizobium leguminosarum biovar viciae were isolated by complementing a UV-sensitive recA ^– Escherichia coli strain. Sequence analysis revealed that the coding region of the R. meliloti recA gene consists of 1044 by coding for 348 amino acids whereas the coding region of the R. leguminosarum bv. viciae recA gene has 1053 bp specifying 351 amino acids. The R. meliloti and R. leguminosarum bv. viciae recA genes show 84.8% homology at the DNA sequence level and of 90.1% at the amino acid sequence level. recA ^– mutant strains of both Rhizobium species were constructed by inserting a gentamicin resistance cassette into the respective recA gene. The resulting recA mutants exhibited an increased sensitivity to UV irradiation, were impaired in their ability to perform homologous recombination and showed a slightly reduced growth rate when compared with the respective wild-type strains. The Rhizobium recA strains did not have altered symbiotic nitrogen fixation capacity. Therefore, they represent ideal candidates for release experiments with impaired strains.The accession numbers: X59956 R. LEGUMINOSARUM REC A ALAS-DNA; X59957 R. MELITOTI REC A ALAS-DNA     

Generalized transduction in Rhizobium meliloti

Summary The phage 11 of R. meliloti performs generalized transduction. This was confirmed by the variety of single markers transferred and by separating transducing particles containing BUdR-labelled bacterial DNA. The transduction frequencies depended on the marker. Linked alleles were mapped by cotransduction on fragments of bacterial DNA equal in size to the phage DNA. With crosses between antibiotic resistancy and auxotrophic markers a partial map was constructed with str, cml, pur-19, and leu-44 sites. With a few multi-auxotrophic mutants linkage data of conjugation were compared with the linkage by cotransduction.     

The Rhizobium etli FixL protein differs in structure from other known FixL proteins

The central heme-binding domain in the FixL proteins of Sinorhizobium meliloti, Bradyrhizobium japonicum, Rhizobium leguminosarum biovar viciae and Azorhizobium caulinodans, is highly conserved. The similarity with the corresponding domain in the Rhizobium etli FixL protein is considerably less. This observation prompted us to analyze the heme-binding capacities of the R. etli FixL protein. The R. etlifixL gene was overexpressed in Escherichia coli. In the presence of S. meliloti FixJ, the overexpressed R. etli FixL protein was able to enhance FixJ-mediated activation of an S. meliloti pnifA-lacZ fusion, indicating that the R.␣etli FixL protein possesses an active conformation in E. coli. Subsequently, using a non-denaturing gel assay for heme, we analyzed the heme-binding capacity of the R.␣etli FixL protein expressed in E. coli, taking the S.␣meliloti FixL protein as a positive control. The R. etli FixL protein expressed in E. coli does not contain a heme group, in contrast to the S. meliloti FixL protein. Therefore we conclude that the R. etli FixL is a non-heme protein in the nif regulatory cascade. Received: 22 August 1997 / Accepted: 20 October 1997