Distribution of insertion sequence ISRm1 in Rhizobium meliloti and other gram-negative bacteria

An internal 0.9 kb segment of Rhizobium meliloti insertion sequence ISRm1 was used as a probe to determine the distribution of ISRm1 in strains of R. meliloti and other Gram-negative bacteria. The insertion sequence was detected in 80% (12/15) of R. meliloti strains from different parts of the world. Its copy number ranged from one to at least eleven. The ISRm1 copies detected showed variation in their internal restriction sites and their degree of homology to the probe. ISRm1 was found in a variety of genomic restriction fragments, and was detected in plasmids, including the nod and exo megaplasmids of R. meliloti. Other rhizobia found to contain ISRm1 were a strain of R. leguminosarum biovar phaseoli and two Rhizobium isolates capable of nodulating both Medicago sativa and Phaseolus vulgaris. It was also found in a diazotrophic soil bacterium isolated from the roots of wetland rice.     

Identification of nodule-dominant Rhizobium meliloti strains carrying pRmeGR4b-type plasmid within indigenous soil populations by PCR using primers derived from specific DNA sequences

Abstract: Rhizobium meliloti strain GR4 is a highly infective and competitive bacteria which was isolated in 1975 from a field site in Granada (Spain) and which has a high potential as an inoculant. R. meliloti isolates from alfalfa plants grown in this field site were characterized using polymerase chain reaction. Characterization was based on primers derived from insertion sequence elements (IS Rm3 and IS Rm4 ), plasmid origin of replication (pRmeGR4a repC locus) and plasmid pRmeGR4b specific DNA sequences. Soil isolates harbouring plasmid type pRmeGR4b represented the major infective population in this field site. A direct correlation between the presence of pRmeGR4b-like plasmid and the competitiveness of the strains was found. In addition, four different R. meliloti field populations isolated from Spanish soils were analyzed for the presence of pRmeGR4b related plasmids. Our results indicate that this plasmid type is widespread among R. meliloti field populations and that its frequency within the infective isolates depends on the host plant.     

Characterization, distribution, and localization of ISRl2, and insertion sequence element isolated from Rhizobium leguminosarum bv. viciae.

An insertion sequence (IS) element, ISR12, from Rhizobium leguminosarum bv. viciae strain MSDJ4184 was isolated by insertional inactivation of the sacRB gene of pSUP104-sac, which allows positive selection. ISRl2 is 932 bp long, is flanked by 17-bp imperfect terminal inverted repeats, and generated a 3-bp target site duplication. ISRl2 was found to be 63 to 77% homologous to insertion elements of the IS5 group of the IS4 superfamily. A probe incorporating a full-length copy of ISRl2 was used to screen genomic DNAs from a collection of strains and from two field populations of R. leguminosarum to detect and estimate the copy numbers of homologous sequences. Among the collection of 63 strains representing the different species and genera of members of the family Rhizobiaceae, homology to ISRl2 was found within strains belonging to Sinorhizobium meliloti and S. fredii; within four of the six recognized Rhizobium species. R. leguminosarum, R. tropici, R. etli, and R. galegae; and within Rhizobium sp. (Phaseolus) genomic species 2. The apparent copy numbers of ISRl2 varied from one to eight. Among 139 isolates of R. leguminosarum from two field populations, homology to ISRl2 was detected in 91% of the isolates from one site and in 17% from the other. Analysis of the 95 isolates that hybridize to ISRl2 revealed a total of 20 distinct hybridization patterns composed of one to three bands. Probing blots of Eckhardt gels showed that sequences with homology to ISRl2 may be found on plasmids or the chromosome. Analysis of their genomic distribution demonstrated relationships and diversity among the R. leguminosarum isolates tested.     

Isolation and characterization of insertion sequence elements from gram-negative bacteria by using new broad-host-range, positive selection vectors.

On the basis of an RSF1010-derived broad-host-range vector, three different systems which enable positive detection and isolation of insertion sequence (IS) elements from gram-negative bacteria were constructed. Vectors pSUP104-pheS, pSUP104-rpsL, and pSUP104-sac were used successfully in a number of Rhizobium strains and in Xanthomonas campestris. More than 20 different IS elements were isolated and characterized. The 16 IS elements from Rhizobium meliloti were further used to characterize various R. meliloti strains by hybridization. The resulting hybridization patterns were different for every strain and gave a clear and definite IS fingerprint of each strain. These IS fingerprints can be used to identify and characterize R. meliloti strains rapidly and unequivocally, as they proved to be relatively stable. Some of the IS elements were found to be identical when the IS fingerprints from a given strain were compared. This method of IS fingerprinting can also establish whether IS elements are the same, related, or different.     

Identification of Rhizobium-specific intergenic mosaic elements within an essential two-component regulatory system of Rhizobium species.

Analysis of the DNA regions upstream of the phosphoenolpyruvate carboxykinase gene (pckA) in Rhizobium meliloti and Rhizobium sp. strain NGR234 identified an open reading frame which was highly homologous to the Agrobacterium tumefaciens chromosomal virulence gene product ChvI. A second gene product, 500 bp downstream of the chvI-like gene in R. meliloti, was homologous to the A. tumefaciens ChvG protein. The homology between the R. meliloti and A. tumefaciens genes was confirmed, because the R. meliloti chvI and chvG genes complemented A. tumefaciens chvI and chvG mutants for growth on complex media. We were unable to construct chvI or chvG insertion mutants of R. meliloti, whereas mutants carrying insertions outside of these genes were readily obtained. A 108-bp repeat element characterized by two large palindromes was identified in the chvI and chvG intergenic regions of both Rhizobium species. This element was duplicated in Rhizobium sp. strain NGR234. Another structurally similar element with a size of 109 bp was present in R. meliloti but not in Rhizobium sp. strain NGR234. These elements were named rhizobium-specific intergenic mosaic elements (RIMEs), because their distribution seems to be limited to members of the family Rhizobiaceae. A homology search in GenBank detected six more copies of the first element (RIME1), all in Rhizobium species, and three extra copies of the second element (RIME2), only in R. meliloti. Southern blot analysis with a probe specific to RIME1 showed the presence of several copies of the element in the genome of R. meliloti, Rhizobium sp. strain NGR234, Rhizobium leguminosarum, and Agrobacterium rhizogenes, but none was present in A. tumefaciens and Bradyrhizobium japonicum.     

Phylogenetic analysis of 23S rRNA gene sequences of. Agrobacterium, Rhizobium and Sinorhizobium strains

The phylogenetic relationship among twelve Agrobacterium, four Rhizobium, and two Sinorhizobium strains originating from various host plants and geographical regions was studied by analysis of the 23S rDNA sequences. The study included Agrobacterium strains belonging to biovars 1, 2 (with tumor- or hairy-root inducing and non-pathogenic strains), A. vitis, A. rubi; representative species of the Rhizobium genus: R. galegae, R. leguminosarum and R. tropici and Sinorhizobium meliloti strains. The phylogenetic analysis showed that within Agrobacterium, the biovar designation was reflected in the 23S rDNA similarity and that strains of Agrobacterium and Rhizobium are closely related to each other. The results suggest that the taxonomic definition of Agrobacterium and Rhizobium should be considered for revision and that the Agrobacterium-biovar identity is probably a reliable taxonomic trait.     

The persistence of bioluminescent Rhizobium meliloti strains L1 (RecA-) and L33 (RecA+) in non-sterile microcosms depends on the soil type,on the co-cultivation of the host legume alfalfa and on the presence of an indigenous R. meliloti population

In comparative analyses the influence of soil type, the rhizosphere of plants and the presence of an indigenous R. meliloti population on the population dynamics of bioluminescent R. meliloti strains L1 (RecA-) and L33 (RecA+) was assessed in microcosm studies. Both strains established better in a loamy and a clayey soil compared to a sandy soil. RecA- strain L1 showed a slightly but statistically significant reduced survival ability compared to RecA+ strain L33 (p 0.05). The presence of the host plant alfalfa stimulated the growth of both strains in non-sterile soil and no differences in the survival between both strains were observed. Co-cultivation of clover or wheat plants, respectively, neither positively nor negatively influenced the strains' survival. The most pronounced effect on the survival of both strains was exerted by the presence of an indigenous R. meliloti population. RecA- strain L1 showed a significantly impaired survival compared to RecA+ strain L33 (p 0.002). Moreover, no growth stimulation of strains L1 and L33 by the presence of the host plant alfalfa could be observed. These results indicate that the recA mutation affects the long-term rather than the short-term persistence of R. meliloti after environmental release.     

Variation of clonal, mesquite-associated rhizobial and bradyrhizobial populations from surface and deep soils by symbiotic gene region restriction fragment length polymorphism and plasmid profile analysis

Genetic characteristics of 14 Rhizobium and 9 Bradyrhizobium mesquite (Prosopis glandulosa)-nodulating strains isolated from surface (0- to 0.5-m) and deep (4- to 6-m) rooting zones were determined in order to examine the hypothesis that surface- and deep-soil symbiont populations were related but had become genetically distinct during adaptation to contrasting soil conditions. To examine genetic diversity, Southern blots of PstI-digested genomic DNA were sequentially hybridized with the nodDABC region of Rhizobium meliloti, the Klebsiella pneumoniae nifHDK region encoding nitrogenase structural genes, and the chromosome-localized ndvB region of R. meliloti. Plasmid profile and host plant nodulation assays were also made. Isolates from mesquite nodulated beans and cowpeas but not alfalfa, clover, or soybeans. Mesquite was nodulated by diverse species of symbionts (R. meliloti, Rhizobium leguminosarum bv. phaseoli, and Parasponia bradyrhizobia). There were no differences within the groups of mesquite-associated rhizobia or bradyrhizobia in cross-inoculation response. The ndvB hybridization results showed the greatest genetic diversity among rhizobial strains. The pattern of ndvB-hybridizing fragments suggested that surface and deep strains were clonally related, but groups of related strains from each soil depth could be distinguished. Less variation was found with nifHDK and nodDABC probes. Large plasmids (>1,500 kb) were observed in all rhizobia and some bradyrhizobia. Profiles of plasmids of less than 1,000 kb were related to the soil depth and the genus of the symbiont. We suggest that interacting selection pressures for symbiotic competence and free-living survival, coupled with soil conditions that restrict genetic exchange between surface and deep-soil populations, led to the observed patterns of genetic diversity.     

Comparison between Rhizobium galegae and Rhizobium meliloti plasmid contents

Plasmid profiles of two strains of a newly classified rhizobial species- Rhizobium galegae -were compared with the profiles of several strains of another fast-growing Rhizobium species- Rhizobium meliloti .
The existence of a plasmid DNA band with a lower electrophoretic mobility than the R. meliloti megaplasmid band was demonstrated in the two R. galegae strains by a modified horizontal Eckhardt method. Thus R. galegae species contain giant plasmid(s) larger than the R. meliloti 1000 MD megaplasmids, previously considered to be the largest plasmids in the Rhizobiaceae family.
In one of the R. galegae strains an additional middle-size plasmid only a little smaller than 140 MD pRme41a of R. meliloti 41 was observed.     

The construction of recA–deficient Rhizobium meliloti and R. leguminosarum strains marked with gusA or luc cassettes for use in risk–assessment studies

A vector system was developed employing the recA genes of Rhizobium meliloti and Rhizobium leguminosarum biovar. viciae as target sequences for the stable genomic integration of foreign DNA. The plasmid vectors can be used either as integration vectors (single cross–over), or as gene replacement vectors (double cross–over). Gene replacement results in the antibiotic–marker–free integration of cloned DNA into the recA genes of R. meliloti and R. leguminosarum bv. viciae. Consequently, the recombinant strains become recombination deficient (RecA^-). The expression of integrated genes is under the control of the neomycin phosphotransferase II (nptll) promoter of transposon Tn5. The system was used to construct recA mutant strains of R. meliloti and R. leguminosarum by. viciae, carrying the Escherichia coli gusA gene encoding β–glucuronidase as well as the firefly (Photinus pyralis) luc gene encoding luciferase as marker genes. The GUS activity in the constructed strains was found to be absolutely stable over more than 100 generations of non–selective growth in liquid culture. The stability was also confirmed in root–nodule passages. In addition, the potential use of the luc gene as a stable genetic marker in the unequivocal identification of tagged strains among indigenous microbes in non–sterile soil was demonstrated. It is proposed to use bioluminescent recA mutants as model organisms in risk assessment studies with genetically engineered Rhizobium strains.     

Fluorescent-Antibody Approach to Study of Rhizobia in Soil

Application of fluorescent-antibody (FA) techniques to the study of rhizobia as free-living soil bacteria was explored. Antiserum to a particular strain of Rhizobium japonicum proved specific in both agglutination and FA tests. Within the R. japonicum group, 2 of 12 strains were stained by the conjugate and these fluoresced brightly; all others were entirely negative. FA tests were negative for 7 strains of R. meliloti, 9 strains of R. leguminosarum, 9 strains of R. trifolii, 6 strains of R. phaseoli, and 65 unidentified bacteria isolated from 12 soils. R. japonicum grew in autoclaved soil and was readily detectable by FA examination of contact slides. The FA technique also detected antibody-reacting bacteria in a field soil whose rhizobial content was unknown. Fluorescent cells were probably R. japonicum, since nodules developed on soybean plants grown in the same soil sample and FA preparations of the crushed nodules proved positive. Autofluorescence was not a problem, but nonspecific adsorption of conjugate restricted observations to microscopic fields free from soil particles. Nonspecific adsorption was substantial, irrespective of the soil used.     

Lipopolysaccharide and protein patterns of Rhizobium sp. (Galega)

Abstract Strains of Rhizobium sp. (Galega) (R. galegae), R. meliloti, R. leguminosarum , and R. loti were compared for their lipopolysaccharide (LPS) and whole cell protein patterns. Antigenic properties of these LPS and proteins were tested by immunoblotting with rabbit antiserum raised against R. galegae strain HAMBI 540. The LPS and protein patterns of R. galegae strains differed from those of the other rhizobia tested. By immunoblotting, a species-specific R. galegae LPS antigen and two proteins specific for R. galegae were identified. Our results support the suggestion that R. galegae strains form a distinct taxonomic group within the genus Rhizobium .     

Sequence and distribution of IS1312: evidence for horizontal DNA transfer from Rhizobium meliloti to Agrobacterium tumefaciens.

Two novel insertion sequences, IS1312 and IS1313, were found in pTiBo542, the Ti plasmid of Agrobacterium tumefaciens strains Bo542 and A281. Nucleotide sequencing and Southern hybridization revealed that IS1312 and IS1313 are homologous to Rhizobium meliloti ISRm1 and ISRm2, respectively. IS1312, ISRm1, and another Agrobacterium insertion sequence, IS426, belong to the same IS3 family of insertion sequences; however, IS1312 is more closely related to the Rhizobium ISRm1 than it is to the Agrobacterium IS426. The distribution patterns of these insertion elements and their sequence similarities suggest that IS1312 and IS1313 were horizontally transferred from R. meliloti to A. tumefaciens.     

Comparative analysis of the genetic structure of a Rhizobium meliloti field population before and after environmental release of the highly competitive R. meliloti strain GR4

Abstract: Rhizobium meliloti strain GR4, which exhibits a highly competitive ability for alfalfa root nodule occupancy, was used in a field release experiment in Granada, Spain. In order to analyze the ecological impact of the GR4 release, we characterized the R. meliloti indigenous population of the field site by ERIC-(enterobacterial repetitive intergenic consensus) PCR and IS (insertion sequence) fingerprinting. Both fingerprinting methods resulted in the same grouping of the isolates. Data obtained were compared with a previous analysis by plasmid based sequence-specific PCR. Isolates belonging to the major infective group, as defined by dominant plasmid types, were shown to have identical or nearly identical ERIC and IS fingerprint patterns. Hence, we conclude that all three typing methods are suited to characterize the genetic structure of the field population. The possible impact of the introduction of strain GR4 was examined two years after its release in its original environment. No effect on the genetic structure of the indigenous R. meliloti field population was observed.     

Influence of arbuscular mycorrhiza and Rhizobium on phytoremediation by alfalfa of an agricultural soil contaminated with weathered PCBs: a field study

A field experiment was conducted to study the effects of inoculation with the arbuscular mycorrhizal fungus Glomus caledonium and/or Rhizobium meliloti on phytoremediation of an agricultural soil contaminated with weathered PCBs by alfalfa grown for 180 days. Planting alfalfa (P), alfalfa inoculated with G. caledonium (P + AM), alfalfa inoculated with R. meliloti (P + R), and alfalfa co-inoculated with R. meliloti and G. caledonium (P+AM+R) decreased significantly initial soil PCB concentrations by 8.1, 12.0, 33.8, and 43.5%, respectively. Inoculation with R. meliloti and/or G. caledonium (P+AM+R) increased the yield of alfalfa, and the accumulation of PCBs in the shoots. Soil microbial counts and the carbon utilization ability of the soil microbial community increased when alfalfa was inoculated with R. meliloti and/or G. caledonium. Results of this field study suggest that synergistic interactions between AMF and Rhizobium may have great potential to enhance phytoremediation by alfalfa of an agricultural soil contaminated with weathered PCBs.     

Physical and genetic characterization of symbiotic and auxotrophic mutants of Rhizobium meliloti induced by transposon Tn5 mutagenesis

We have physically and genetically characterized 20 symbiotic and 20 auxotrophic mutants of Rhizobium meliloti, the nitrogen-fixing symbiont of alfalfa (Medicago sativa), isolated by transposon Tn5 mutagenesis. A "suicide plasmid" mutagenesis procedure was used to generate TN-5-induced mutants, and both auxotrophic and symbiotic mutants were found at a frequency of 0.3% among strains containing random TN5 insertions. Two classes of symbiotic mutants were isolated: 4 of the 20 formed no nodules at all (Nod-), and 16 formed nodules which failed to fix nitrogen (Fix-). We used a combination of physical and genetic criteria to determine that in most cases the auxotrophic and symbiotic phenotypes could be correlated with the insertion of a single Tn5 elements. Once the Tn5 element was inserted into the R. meliloti genome, the frequency of its transposition to a new site was approximately 10-8 and the frequency of precise excision was less than 10-9. In approximately 25% of the mutant strains, phage Mu DNA sequences, which originated from the suicide plasmid used to generate the Tn5 transpositions, were also found in the R. meliloti genome contiguous with Tn5. These later strains exhibited anomalous conjugation properties, and therefore we could not correlate the symbiotic phenotype with a Tn5 insertion. In general, we found that both physical and genetic tests were required to fully characterize transposon-induced mutations.     

Application of subtraction hybridization for the development of a Rhizobium leguminosarum biovar phaseoli and Rhizobium tropici group-specific DNA probe

Abstract A combined subtraction hybridization and polymerase chain reaction/amplification technique was used to develop a DNA probe which was specific for the Rhizobium leguminosarum biovar phaseoli and the Rhizobium tropici group. Total genomic DNA preparations from Rhizobium leguminosarum biovar viciae, Rhizobium leguminosarum biovar trifolii, Rhizobium sp., Agrobacterium tumefaciens, Rhizobium fredii, Bradyrhizobium japonicum, Bradyrhizobium ssp. and Rhizobium meliloti were pooled and used as subtracter DNA against total genomic DNA from the Rhizobium leguminosarum biovar phaseolo strain KIM5s. Only one round of subtraction hybridization at 65°C was necessary to remove all cross-hybridizing sequences. Dot blot hybridizations with total genomic DNA of the eight subtracter organisms and 29 bacteria of different groups confirmed the high specificity of the isolated DNA sequences. Dot blot hybridizations and total genomic DNA from ten different R. Leguminosarum biovar phaseoli and R. tropici strains resulted in strong hybridization signals for all strains tested. The DNA probe for the R. tropici and R. leguminosarum biovar phaseoli group was used for dot blot hybridization with DNA extracts from three tropical and one boreal soil. When correlated with data from Most Probable Number analyses the probe was capable of detecting as low as 3 × 10⁴ homologous indigenous rhizobia per g soil. The technique offers great benefits for the development of DNA probes for monitoring bacterial populations in environmental samples.     

Coaggregation amongst aquatic biofilm bacteria

In a comparative study, the PCR-based RAPD and ERIC fingerprint methods were evaluated for their resolving power to discriminate among 21 isolates of a natural Rhizobium meliloti population. PCR fingerprint patterns were analysed by using an automated laser fluorescent (ALF) DNA sequencer, thus allowing the automated on-line storage of data. Results obtained were compared to a classification system using insertion sequence (IS) fingerprinting. Both PCR fingerprint methods were comparable in their ability to resolve differences amongst Rh. meliloti isolates. Grouping of strains on the basis of their RAPD as well as their ERIC fingerprints correlated with grouping of strains according to their IS fingerprints. Moreover, strains displaying identical PCR patterns could be further differentiated according to their IS fingerprints, thus allowing a detailed insight into phylogenetic relationship among strains. The automated evaluation of strain-specific fingerprint patterns has the potential to become a valuable tool for studies of bacterial population genetics. Moreover, the rapid identification of single strains, e.g. pathogens in epidemiological studies seems feasible.