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.     

Hyperreiterated DNA regions are conserved among Bradyrhizobium japonicum serocluster 123 strains.

We have identified and cloned two DNA regions which are highly reiterated in Bradyrhizobium japonicum serocluster 123 strains. While one of the reiterated DNA regions, pFR2503, is closely linked to the B. japonicum common and genotype-specific nodulation genes in strain USDA 424, the other, pMAP9, is located next to a Tn5 insertion site in a host-range extension mutant of B. japonicum USDA 438. The DNA cloned in pFR2503 and pMAP9 are reiterated 18 to 21 times, respectively, in the genomes of B. japonicum serocluster 123 strains. Gene probes from the reiterated regions share sequence homology, failed to hybridize (or hybridized poorly) to genomic DNA from other B. japonicum and Bradyrhizobium spp. strains, and did not hybridize to DNA from Rhizobium meliloti, Rhizobium fredii, Rhizobium leguminosarum biovars trifolii, phaseoli, and viceae, or Agrobacterium tumefacians. The restriction fragment length polymorphism hybridization profiles obtained by using these gene probes are useful for discriminating among serologically related B. japonicum serocluster 123 strains.     

Hyperreiterated DNA regions are conserved among Bradyrhizobium japonicum serocluster 123 strains.

We have identified and cloned two DNA regions which are highly reiterated in Bradyrhizobium japonicum serocluster 123 strains. While one of the reiterated DNA regions, pFR2503, is closely linked to the B. japonicum common and genotype-specific nodulation genes in strain USDA 424, the other, pMAP9, is located next to a Tn5 insertion site in a host-range extension mutant of B. japonicum USDA 438. The DNA cloned in pFR2503 and pMAP9 are reiterated 18 to 21 times, respectively, in the genomes of B. japonicum serocluster 123 strains. Gene probes from the reiterated regions share sequence homology, failed to hybridize (or hybridized poorly) to genomic DNA from other B. japonicum and Bradyrhizobium spp. strains, and did not hybridize to DNA from Rhizobium meliloti, Rhizobium fredii, Rhizobium leguminosarum biovars trifolii, phaseoli, and viceae, or Agrobacterium tumefacians. The restriction fragment length polymorphism hybridization profiles obtained by using these gene probes are useful for discriminating among serologically related B. japonicum serocluster 123 strains.     

Characterization of NopP, a type III secreted effector of Rhizobium sp. strain NGR234

The type three secretion system (TTSS) encoded by pNGR234a, the symbiotic plasmid of Rhizobium sp. strain NGR234, is responsible for the flavonoid- and NodD1-dependent secretion of nodulation outer proteins (Nops). Abolition of secretion of all or specific Nops significantly alters the nodulation ability of NGR234 on many of its hosts. In the closely related strain Rhizobium fredii USDA257, inactivation of the TTSS modifies the host range of the mutant so that it includes the improved Glycine max variety McCall. To assess the impact of individual TTSS-secreted proteins on symbioses with legumes, various attempts were made to identify nop genes. Amino-terminal sequencing of peptides purified from gels was used to characterize NopA, NopL, and NopX, but it failed to identify SR3, a TTSS-dependent product of USDA257. By using phage display and antibodies that recognize SR3, the corresponding protein of NGR234 was identified as NopP. NopP, like NopL, is an effector secreted by the TTSS of NGR234, and depending on the legume host, it may have a deleterious or beneficial effect on nodulation or it may have little effect.     

Phylogeny of fast-growing soybean-nodulating rhizobia support synonymy of Sinorhizobium and Rhizobium and assignment to Rhizobium fredii.

We determined the sequences for a 260-base segment amplified by the polymerase chain reaction (corresponding to positions 44 to 337 in the Escherichia coli 16S rRNA sequence) from seven strains of fast-growing soybean-nodulating rhizobia (including the type strains of Rhizobium fredii chemovar fredii, Rhizobium fredii chemovar siensis, Sinorhizobium fredii, and Sinorhizobium xinjiangensis) and broad-host-range Rhizobium sp. strain NGR 234. These sequences were compared with the corresponding previously published sequences of Rhizobium leguminosarum, Rhizobium meliloti, Agrobacterium tumefaciens, Azorhizobium caulinodans, and Bradyrhizobium japonicum. All of the sequences of the fast-growing soybean rhizobia, including strain NGR 234, were identical to the sequence of R. meliloti and similar to the sequence of R. leguminosarum. These results are discussed in relation to previous findings; we concluded that the fast-growing soybean-nodulating rhizobia belong in the genus Rhizobium and should be called Rhizobium fredii.     

Sinorhizobium fredii USDA257, a cultivar-specific soybean symbiont, carries two copies of y4yA and y4yB, two open reading frames that are located in a region that encodes the type III protein secretion system

Sinorhizobium fredii USDA257 forms nitrogen-fixing nodules on primitive soybean (Glycine max) cultivar Peking but fails to nodulate the improved cultivar McCall. Cultivar specificity is governed by a plasmid-borne locus, nolXBTUV. By DNA sequence analysis, we have identified two open reading frames, y4yA and y4yB, immediately downstream of nolX. Northern (RNA) blot analysis indicated that the expression of both y4yA and y4yB is inducible by isoflavonoids, and an intact copy of nolX is required. Two copies each of y4yA and y4yB are present in S. fredii USDA257, one on the sym plasmid (y4yAsp and y4yBsp), and the other on the chromosome (y4yAc and y4yBc). The cultivar-nonspecific strain USDA191 lacks y4yAc and y4yBc. Introduction of y4yAc plus y4yBc from USDA257 into USDA191 did not influence the ability of the latter strain to nodulate McCall soybean plants. Unlike nolX, the inactivation of y4yAsp and y4yBsp of USDA257 did not extend the host range of this strain. A double mutant, in which both the plasmid and chromosomal copies of y4yA and y4yB were mutated, had no observable effect on symbiotic ability of USDA257. The y4yAsp and y4yBsp mutants did not influence flavonoid-dependent extracellular protein production. Rhizobium sp. strain NGR234 and S. saheli USDA4893 both contain sequences similar to S. fredii USDA257 y4yAsp and y4yBsp; however, Bradyrhizobium spp., the traditional soybean symbionts, lack these genes.     

Rapid identification of Rhizobium strains by targeted PCR fingerprinting

Numerous polymerase chain reaction (PCR) based procedures are routinely used to produce genomic fingerprints of prokaryotes. Many of them have drawbacks however such as sensitivity to experimental variation, lack of reproducibility, poor resolution and the inability to distinguish between closely related strains. To overcome these difficulties, we developed an alternative procedure, Targeted PCR Fingerprinting (TPF) which is based upon the amplification of few but carefully selected markers, followed by high resolution RFLP analysis of the amplified DNA fragments. In contrast to most fingerprinting protocols that use low resolution agarose gels, TPF patterns are produced on denaturing polyacrylamide gels which allow the precise recording of the genomic fingerprints. TPF analysis, which can simultaneously process 96 samples in less than 12 h and remains unaffected by slight experimental variations, is particularly adapted for the rapid identification of target strains amongst many field isolates. Using PCR primers specific for the nifH and recA genes, this procedure was also sufficiently sensitive to discriminate between Rhizobium species NGR234 and R. fredii USDA257, two closely related bacteria in which the symbiotic loci are 98% homologous. Interestingly, comparison of several of their symbiotic genes as well as the partial DNA sequences of their 16S rDNA and recA genes suggest that chromosomes and symbiotic plasmids did not co-evolve, but that symbiotic functions were acquired by lateral gene transfer long after NGR234 and USDA257 diverged from their common ancestors. In this respect, TPF fingerprints produced with distinct chromosomal and plasmid born markers, such as the recA and the nifH genes in NGR234 and USDA257, are probably more likely to detect lateral transfer of genes in bacterial field-populations than procedures relying on the amplification of numerous fragments of unknown genomic position and biological function.     

Genetic structure of a soil population of nonsymbiotic Rhizobium leguminosarum.

The genetic structure of a population of nonsymbiotic Rhizobium leguminosarum strains was determined by the electrophoretic mobilities of eight metabolic enzymes. Nonsymbiotic strains were isolated from the rhizosphere of bean plants and characterized by growth on differential media and at different temperatures, intrinsic antibiotic resistance, the lack of homology to a nifH probe, and their inability to form nodules on bean roots. All the isolates clustered with R. leguminosarum bv. phaseoli reference strains and did not encompass any other Rhizobium taxa. Their rRNA operon restriction fragment length polymorphisms and the nucleotide sequence of a fragment of the 16S rRNA gene were also found to be identical to those of R. leguminosarum bv. phaseoli reference strains. When complemented with an R. leguminosarum bv. phaseoli symbiotic plasmid (p42d), the nonsymbiotic isolates were able to fix nitrogen in symbiosis with bean roots at levels similar to those of the parental strain. The symbiotic isolates were found at a relative frequency of 1 in 40 nonsymbiotic R. leguminosarum strains.     

Genetic structure of a soil population of nonsymbiotic Rhizobium leguminosarum.

The genetic structure of a population of nonsymbiotic Rhizobium leguminosarum strains was determined by the electrophoretic mobilities of eight metabolic enzymes. Nonsymbiotic strains were isolated from the rhizosphere of bean plants and characterized by growth on differential media and at different temperatures, intrinsic antibiotic resistance, the lack of homology to a nifH probe, and their inability to form nodules on bean roots. All the isolates clustered with R. leguminosarum bv. phaseoli reference strains and did not encompass any other Rhizobium taxa. Their rRNA operon restriction fragment length polymorphisms and the nucleotide sequence of a fragment of the 16S rRNA gene were also found to be identical to those of R. leguminosarum bv. phaseoli reference strains. When complemented with an R. leguminosarum bv. phaseoli symbiotic plasmid (p42d), the nonsymbiotic isolates were able to fix nitrogen in symbiosis with bean roots at levels similar to those of the parental strain. The symbiotic isolates were found at a relative frequency of 1 in 40 nonsymbiotic R. leguminosarum strains.     

Complete Genome Sequence of the Broad-Host-Range Strain Sinorhizobium fredii USDA257

Here we announce the complete genome sequence of the symbiotic and nitrogen-fixing bacterium Sinorhizobium fredii USDA257. The genome shares a high degree of sequence similarity with the closely related broad-host-range strains S. fredii NGR234 and HH103. Most strikingly, the USDA257 genome encodes a wealth of secretory systems.     

Combined subtraction hybridization and polymerase chain reaction amplification procedure for isolation of strain-specific Rhizobium DNA sequences.

A novel subtraction hybridization procedure, incorporating a combination of four separation strategies, was developed to isolate unique DNA sequences from a strain of Rhizobium leguminosarum bv. trifolii. Sau3A-digested DNA from this strain, i.e., the probe strain, was ligated to a linker and hybridized in solution with an excess of pooled subtracter DNA from seven other strains of the same biovar which had been restricted, ligated to a different, biotinylated, subtracter-specific linker, and amplified by polymerase chain reaction to incorporate dUTP. Subtracter DNA and subtracter-probe hybrids were removed by phenol-chloroform extraction of a streptavidin-biotin-DNA complex. NENSORB chromatography of the sequences remaining in the aqueous layer captured biotinylated subtracter DNA which may have escaped removal by phenol-chloroform treatment. Any traces of contaminating subtracter DNA were removed by digestion with uracil DNA glycosylase. Finally, remaining sequences were amplified by polymerase chain reaction with a probe strain-specific primer, labelled with 32P, and tested for specificity in dot blot hybridizations against total genomic target DNA from each strain in the subtracter pool. Two rounds of subtraction-amplification were sufficient to remove cross-hybridizing sequences and to give a probe which hybridized only with homologous target DNA. The method is applicable to the isolation of DNA and RNA sequences from both procaryotic and eucaryotic cells.     

Combined subtraction hybridization and polymerase chain reaction amplification procedure for isolation of strain-specific Rhizobium DNA sequences.

A novel subtraction hybridization procedure, incorporating a combination of four separation strategies, was developed to isolate unique DNA sequences from a strain of Rhizobium leguminosarum bv. trifolii. Sau3A-digested DNA from this strain, i.e., the probe strain, was ligated to a linker and hybridized in solution with an excess of pooled subtracter DNA from seven other strains of the same biovar which had been restricted, ligated to a different, biotinylated, subtracter-specific linker, and amplified by polymerase chain reaction to incorporate dUTP. Subtracter DNA and subtracter-probe hybrids were removed by phenol-chloroform extraction of a streptavidin-biotin-DNA complex. NENSORB chromatography of the sequences remaining in the aqueous layer captured biotinylated subtracter DNA which may have escaped removal by phenol-chloroform treatment. Any traces of contaminating subtracter DNA were removed by digestion with uracil DNA glycosylase. Finally, remaining sequences were amplified by polymerase chain reaction with a probe strain-specific primer, labelled with 32P, and tested for specificity in dot blot hybridizations against total genomic target DNA from each strain in the subtracter pool. Two rounds of subtraction-amplification were sufficient to remove cross-hybridizing sequences and to give a probe which hybridized only with homologous target DNA. The method is applicable to the isolation of DNA and RNA sequences from both procaryotic and eucaryotic cells.     

Two genes that regulate exopolysaccharide production in Rhizobium meliloti.

We describe a new Rhizobium meliloti gene, exoX, that regulates the synthesis of the exopolysaccharide, succinoglycan, exoX resembled the psi gene of R. leguminosarum bv. phaseoli and the exoX gene of Rhizobium sp. strain NGR234 in its ability to inhibit exopolysaccharide synthesis when present in multiple copies, exoX did not appear to regulate the expression of exoP. The effect of exoX was counterbalanced by another R. meliloti gene, exoF. exoF is equivalent to Rhizobium sp. strain NGR234 exoY and resembles R. leguminosarum bv. phaseoli pss2 in its mutant phenotype and in portions of its deduced amino acid sequence. The effect of exoF on the succinoglycan-inhibiting activity of exoX depended on the relative copy numbers of the two genes. exoX-lacZ fusions manifested threefold-higher beta-galactosidase activities in exoF backgrounds than in the wild-type background. exoX mutants produced increased levels of succinoglycan. However, the exoF gene was required for succinoglycan synthesis even in an exoX mutant background. exoF did not affect the expression of exoP. Strains containing multicopy exoX formed non-nitrogen-fixing nodules on alfalfa that resembled nodules formed by exo mutants defective in succinoglycan synthesis. exoX mutants formed nitrogen-fixing nodules, indicating that, if the inhibition of succinoglycan synthesis within the nodule is necessary for nitrogen fixation, then exoX is not required for this inhibition. We present indirect evidence that succinoglycan synthesis within the nodule is not necessary for bacteroid function.     

Degradation of trehalose by rhizobia and characteristics of a trehalose-degrading enzyme isolated from Rhizobium species NGR234

AIMS: This study was designed to examine the breakdown of trehalose by rhizobia and to characterize the trehalose-degrading enzyme isolated from Rhizobium sp. NGR234. METHODS AND RESULTS: Rhizobium sp. NGR234, Rhizobium fredii USDA257, R. phaseoli RCR3622, R. tropici CIAT899 and R. etli CE3 showed good growth in the presence of carbohydrate. Validamycin A did not prevent the growth of NGR234 on trehalose. The expression of a trehalose-degrading enzyme by NGR234 was intracellular and inducible by trehalose. The isolated enzyme digested other disaccharides, p-nitrophenyl-alpha-d-glucopyranoside and the substrate. The enzyme showed optimum activities at pH 7.0 and 30 degrees C. Its pI was 4.75 and the V(max) of the enzyme occurred at 35.7 micromol s(-1) mg(-1) protein with the K(m) of 23 mmol when trehalose was hydrolysed. CONCLUSIONS: An enzyme capable of breaking down trehalose was produced. Some of the properties of the trehalose-degrading enzyme are similar to those isolated from other organisms but, this enzyme was validamycin resistant. These rhizobia like other trehalose-degrading microbes use trehalose by enzymatic catabolic action. SIGNIFICANCE AND IMPACT OF THE STUDY: Trehalose which accumulates during legume-rhizobia symbiosis is toxic to plants. Detoxification by trehalose-degrading enzymes is important for the progress of symbiosis.     

Characterization of RFRS9, a second member of the Rhizobium fredii repetitive sequence family from the nitrogen-fixing symbiont R. fredii USDA257.

The genome of the nitrogen-fixing symbiont, Rhizobium fredii USDA257, contains nine copies of repetitive sequences known as the R. fredii repetitive sequence (RFRS) family. We previously sequenced RFRS3, which is linked to symbiosis plasmid-borne nodulation genes of this organism and has substantial homology to the T-DNA of Agrobacterium rhizogenes and lesser homology to reiterated sequences of Bradyrhizobium japonicum. Here we characterize a second family member, RFRS9. The EcoRI fragment containing RFRS9 is 1,248 bp in length and contains a single 666-bp open reading frame that is flanked by perfect 8-bp inverted repeats. Nucleic and amino acid sequences corresponding to the C terminus of the putative RFRS9 protein are nearly identical to those of RFRS3, and they retain homology to DNA from A. rhizogenes. The central portion of the RFRS9 protein also appears to be related to the S locus-specific glycoprotein family of pollen stigma incompatibility glycoproteins from Brassica oleracea, which are involved in signal perception. Sequences that define the RFRS family are restricted to the open reading frame of RFRS9 and associated upstream sequences. These regions also contain a second group of repetitive sequences, which is present in four copies within the genome of USDA257. Both families of repetitive sequences are ubiquitous in R. fredii, and they are preferentially localized on symbiosis plasmids. Southern hybridization confirms that sequences homologous to RFRS9 are present in broad-host-range Rhizobium sp. strain NGR234, in A. rhizogenes, and in two biotype 3 strains of Agrobacterium tumefaciens.     

Rhizobium sp. strain NGR234 and R. fredii USDA257 share exceptionally broad, nested host ranges

Genetically, Rhizobium sp. strain NGR234 and R. fredii USDA257 are closely related. Small differences in their nodulation genes result in NGR234 secreting larger amounts of more diverse lipo-oligosaccharidic Nod factors than USDA257. What effects these differences have on nodulation were analyzed by inoculating 452 species of legumes, representing all three subfamilies of the Leguminosae, as well as the nonlegume Parasponia andersonii, with both strains. The two bacteria nodulated P. andersonii, induced ineffective outgrowths on Delonix regia, and nodulated Chamaecrista fasciculata, a member of the only nodulating genus of the Caesalpinieae tested. Both strains nodulated a range of mimosoid legumes, especially the Australian species of Acacia, and the tribe Ingeae. Highest compatibilities were found with the papilionoid tribes Phaseoleae and Desmodieae. On Vigna spp. (Phaseoleae), both bacteria formed more effective symbioses than rhizobia of the "cowpea" (V. unguiculata) miscellany. USDA257 nodulated an exact subset (79 genera) of the NGR234 hosts (112 genera). If only one of the bacteria formed effective, nitrogen-fixing nodules it was usually NGR234. The only exceptions were with Apios americana, Glycine max, and G. soja. Few correlations can be drawn between Nod-factor substituents and the ability to nodulate specific legumes. Relationships between the ability to nodulate and the origin of the host were not apparent. As both P. andersonii and NGR234 originate from Indonesia/Malaysia/Papua New Guinea, and NGR234's preferred hosts (Desmodiinae/Phaseoleae) are largely Asian, we suggest that broad host range originated in Southeast Asia and spread outward.     

Sinorhizobium fredii HH103 has a truncated nolO gene due to a -1 frameshift mutation that is conserved among other geographically distant S. fredii strains

Strain SVQ121 is a mutant derivative of Sinorhizobium fredii HH103 carrying a transposon Tn5-lacZ insertion into the nolO-coding region. Sequence analysis of the wild-type gene revealed that it is homologous to that of Rhizobium sp. NGR234, which is involved in the 3 (or 4)-O-carbamoylation of the nonreducing terminus of Nod factors. Downstream of nolO, as in Rhizobium sp. NGR234, the noeI gene responsible for methylation of the fucose moiety of Nod factors was found. SVQ121 Nod factors showed lower levels of methylation into the fucosyl residue than those of HH103-suggesting a polar effect of the transposon insertion into nolO over the noel gene. A noeI HH103 mutant was constructed. This mutant, SVQ503, produced Nod factors devoid of methyl groups, confirming that the S. fredii noeI gene is functional. Neither the nolO nor the noeI mutation affected the ability of HH103 to nodulate several host plants, but both mutations reduced competitiveness to nodulate soybean. The Nod factors produced by strain HH103, like those of other S. fredii isolates, lack carbamoyl residues. By using specific polymerase chain reaction primers, we sequenced the nolO gene of S. fredii strains USDA192, USDA193, USDA257, and 042B(s). All the analyzed strains showed the same -1 frameshift mutation that is present in the HH103 nolO-coding region. From these results, it is concluded that, regardless of their geographical origin, S. fredii strains carry the nolO-coding region but that it is truncated by the same base-pair deletion.     

The sym plasmid pRP2JI and at least two other loci of Rhizobium leguminosarum biovar phaseoli can confer resistance to infection by the virulent bacteriophage RL38

Abstract The virulent Rhizobium bacteriophage RL38 did not form plaques on R.leguminosarum by phaseoli but did so at high efficiency on a derivative of that strain lacking its symbiotic plasmid pRP2JI. Other strains with large deletions in pRP2JI which removed many nod and nif genes retained resistance to RL38, showing that the gene which confers phage resistance lies elsewhere on the plasmid. Although the wild-type strain of R. leguminosarum bv. phaseoli failed to plate RL38, it was possible to transduce chromosomal markers into this strain, indicating that the 'block' was not at an early stage in the infection process. Two different recombinant plasmids obtained from a clone bank of genomic DNA of R. leguminosarum bv. phaseoli , which appeared to have no DNA in common, both conferred resistance to RL38. Surprisingly, the DNA cloned in each of these plasmids did not originate from pRP2JI. Therefore, several different loci both on the Sym plasmid and elsewhere on the bacterial genome can be involved in conferring resistance to this bacteriophage.