Plasmid-linked nif and "nod" genes in fast-growing rhizobia that nodulate Glycine max, Psophocarpus tetragonolobus, and Vigna unguiculata

A Minimal Genetic Passkey to Unlock Many Legume Doors to Root Nodulation by Rhizobia

In legume crops, formation of developmentally mature nodules is a prerequisite for efficient nitrogen fixation by populations of rhizobial bacteroids established inside nodule cells. Development of root nodules, and concomitant microbial colonization of plant cells, are constrained by sets of recognition signals exchanged by infecting rhizobia and their legume hosts, with much of the specificity of symbiotic interactions being determined by the flavonoid cocktails released by legume roots and the strain-specific nodulation factors (NFs) secreted by rhizobia. Hence, much of Sinorhizobium fredii strain NGR234 symbiotic promiscuity was thought to stem from a family of >80 structurally diverse NFs and associated nodulation keys in the form of secreted effector proteins and rhamnose-rich surface polysaccharides. Here, we show instead that a mini-symbiotic plasmid (pMiniSym2) carrying only the nodABCIJ, nodS and nodD1 genes of NGR234 conferred promiscuous nodulation to ANU265, a derivative strain cured of the large symbiotic plasmid pNGR234a. The ANU265::pMiniSym2 transconjugant triggered nodulation responses on 12 of the 22 legumes we tested. On roots of Macroptilium atropurpureum, Leucaena leucocephala and Vigna unguiculata, ANU265::pMiniSym2 formed mature-like nodule and successfully infected nodule cells. While cowpea and siratro responded to nodule colonization with defense responses that eventually eliminated bacteria, L. leucocephala formed leghemoglobin-containing mature-like nodules inside which the pMiniSym2 transconjugant established persistent intracellular colonies. These data show seven nodulation genes of NGR234 suffice to trigger nodule formation on roots of many hosts and to establish chronic infections in Leucaena cells.

Decoupled genomic elements and the evolution of partner quality in nitrogen-fixing rhizobia

Understanding how mutualisms evolve in response to a changing environment will be critical for predicting the long-term impacts of global changes, such as increased N (nitrogen) deposition. Bacterial mutualists in particular might evolve quickly, thanks to short generation times and the potential for independent evolution of plasmids through recombination and/or HGT (horizontal gene transfer). In a previous work using the legume/rhizobia mutualism, we demonstrated that long-term nitrogen fertilization caused the evolution of less-mutualistic rhizobia. Here, we use our 63 previously isolated rhizobium strains in comparative phylogenetic and quantitative genetic analyses to determine the degree to which variation in partner quality is attributable to phylogenetic relationships among strains versus recent genetic changes in response to N fertilization. We find evidence of distinct evolutionary relationships between chromosomal and pSym genes, and broad similarity between pSym genes. We also find that nifD has a unique evolutionary history that explains much of the variation in partner quality, and suggest MoFe subunit interaction sites in the evolution of less-mutualistic rhizobia. These results provide insight into the mechanisms behind the evolutionary response of rhizobia to long-term N fertilization, and we discuss the implications of our results for the evolution of the mutualism.

Relationship of the Presence and Copy Number of Plasmids to Exopolysaccharide Production and Symbiotic Effectiveness in Rhizobium fredii USDA 206

Rhizobium fredii USDA 206 harbors four large plasmids, one of which carries nodulation and nitrogen fixation genes. Previously isolated groups of plasmid-cured derivatives of strain USDA 206 were compared with each other to determine possible plasmid functions. Mutant strain 206CANS was isolated as a nonmucoid (Muc) derivative of strain 206CA, a mutant that was cured of two plasmids. The Muc phenotype of 206CANS was only expressed when the strain was grown on certain media, particularly those with polyols as carbon sources. Plasmid pRj206b of strain 206CANS was previously shown to have a higher copy number than the same plasmid in strains USDA 206 and 206CA. When this plasmid was transferred to Muc strains, it conferred a nonmucoid phenotype on recipient strains. The symbiotic effectiveness of the wild-type and cured strains was compared. Overall, few differences were shown, but strains 206CA and 206CANS were found to have higher nitrogenase activities than the other strains. Thus, there appeared to be a possible relationship among exopolysaccharide synthesis, plasmid copy number, and symbiotic effectiveness.

Flavonoids induce temporal shifts in gene-expression of nod-box controlled loci in Rhizobium sp. NGR234

Rhizobia, soil bacteria of the Rhizobiales, enter the roots of homologous legumes, where they induce the formation of nitrogen-fixing nodules. Signals emanating from both symbiotic partners control nodule development. Efficient nodulation requires precise, temporal regulation of symbiotic genes. Roots continuously release flavonoids that interact with transcriptional activators of the LysR family. NodD proteins, which are members of this family, act both as sensors of the environment and modulate the expression of genes preceded by conserved promoter sequences called nod-boxes. The symbiotic plasmid of the broad host-range Rhizobium sp. NGR234 caries 19 nod-boxes (NB1 to NB19), all of which were cloned upstream of a lacZ-reporter gene. A flavonoid, daidzein was able to induce 18 of the 19 nod-boxes in a NodD1-dependent manner. Interestingly, induction of four nod-boxes (NB6, NB15, NB16 and NB17) is highly dependent on NodD2 and was delayed in comparison with the others. In turn, NodD2 is involved in the repression of the NB8 nodABCIJnolOnoeI operon. Activation of transcription of nodD2 is also dependent on flavonoids despite the absence of a nod-box like sequence in the upstream promoter region. Mutational analysis showed that syrM 2 (another member of the LysR family), which is controlled by NB19, is also necessary for expression of nodD 2. Thus, NodD1, NodD2 and SyrM2 co-modulate a flavonoid-inducible regulatory cascade that coordinates the expression of symbiotic genes with nodule development.

Symbiotic conditions induce structural modifications of Sinorhizobium sp. NGR234 surface polysaccharides

When the rhizosphere is starved of nitrogen, the soil bacteria Rhizobium are able to infect legume roots and invade root nodules, where they can fix atmospheric nitrogen. Nod boxes, the nod gene promoters located on the rhizobial symbiotic plasmid, are activated by means of flavonoids present in the legume root exudates, leading to the synthesis of lipochitooligomers: the Nod factors. Several recent works pointed out the importance of rhizobial surface polysaccharides in establishing the highly specific symbiosis between rhizobia and legumes. Lipopolysaccharides (LPSs) exhibit specific active roles in the later stages of the nodulation processes, such as the penetration of the infection thread into the cortical cells or the setting up of the nitrogen-fixing phenotype. The study reported here concerns the structural modifications affecting surface (lipo)polysaccharides when Sinorhizobium sp. NGR234 strains are grown with nod gene induction under nitrogen starvation. In the absence of induction, NGR234 only produces fast-migrating LPSs. When cultured in the presence of flavonoids, the same strain produces large quantities of a high-molecular-weight rhamnose-rich lipopolysaccharide (RLPS). Because the synthesis of this compound seems to be coded by the symbiotic plasmid under direct or indirect gene induction by flavonoids, this RLPS is thought to be biologically relevant.

Genetic snapshots of the Rhizobium species NGR234 genome

BACKGROUND

In nitrate-poor soils, many leguminous plants form nitrogen-fixing symbioses with members of the bacterial family Rhizobiaceae. We selected Rhizobium sp. NGR234 for its exceptionally broad host range, which includes more than I 12 genera of legumes. Unlike the genome of Bradyrhizobium japonicum, which is composed of a single 8.7 Mb chromosome, that of NGR234 is partitioned into three replicons: a chromosome of about 3.5 Mb, a megaplasmid of more than 2 Mb (pNGR234b) and pNGR234a, a 536,165 bp plasmid that carries most of the genes required for symbioses with legumes. Symbiotic loci represent only a small portion of all the genes coded by rhizobial genomes, however. To rapidly characterize the two largest replicons of NGR234, the genome of strain ANU265 (a derivative strain cured of pNGR234a) was analyzed by shotgun sequencing.

RESULTS

Homology searches of public databases with 2,275 random sequences of strain ANU265 resulted in the identification of 1,130 putative protein-coding sequences, of which 922 (41%) could be classified into functional groups. In contrast to the 18% of insertion-like sequences (ISs) found on the symbiotic plasmid pNGR234a, only 2.2% of the shotgun sequences represent known ISs, suggesting that pNGR234a is enriched in such elements. Hybridization data also indicate that the density of known transposable elements is higher in pNGR234b (the megaplasmid) than on the chromosome. Rhizobium-specific intergenic mosaic elements (RIMEs) were found in 35 shotgun sequences, 6 of which carry RIME2 repeats previously thought to be present only in Rhizobium meliloti. As non-overlapping shotgun sequences together represent approximately 10% of ANU265 genome, the chromosome and megaplasmid may carry a total of over 200 RIMEs.

CONCLUSIONS

'Skimming' the genome of Rhizobium sp. NGR234 sheds new light on the fine structure and evolution of its replicons, as well as on the integration of symbiotic functions in the genome of a soil bacterium. Although most putative coding sequences could be distributed into functional classes similar to those in Bacillus subtilis, functions related to transposable elements were more abundant in NGR234. In contrast to ISs that accumulated in pNGR234a and pNGR234b, the hundreds of RIME elements seem mostly attributes of the chromosome.

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.

High-resolution transcriptional analysis of the symbiotic plasmid of Rhizobium sp. NGR234

Most of the bacterial genes involved in nodulation of legumes (nod, nol and noe ) as well as nitrogen fixation (nif and fix ) are carried on pNGR234a, the 536 kb symbiotic plasmid (pSym) of the broad-host-range Rhizobium sp. NGR234. Putative transcription regulators comprise 24 of the predicted 416 open reading frames (ORFs) contained on this replicon. Computational analyses identified 19 nod boxes and 16 conserved NifA-sigma54 regulatory sequences, which are thought to co-ordinate the expression of nodulation and nitrogen fixation genes respectively. To analyse transcription of all putative ORFs, the nucleotide sequence of pNGR234a was divided into 441 segments designed to represent all coding and intergenic regions. Each of these segments was amplified by polymerase chain reactions, transferred to filters and probed with radioactively labelled RNA. RNA was extracted from bacterial cultures grown under various experimental conditions, as well as from bacteroids of determinate and indeterminate nodules. Generally, genes involved in the synthesis of Nod factors (e.g. the three hsn loci) were induced rapidly after the addition of flavonoids, whereas others thought to act within the plant (e.g. those encoding the type III secretion system) responded more slowly. Many insertion (IS) and transposon (Tn)-like sequences were expressed strongly under all conditions tested, while a number of loci other than those known to encode nod, noe, nol, nif and fix genes were also transcribed in nodules. Many more diverse transcripts were found in bacteroids of determinate as opposed to indeterminate nodules.

nolO and noeI (HsnIII) of Rhizobium sp. NGR234 are involved in 3-O-carbamoylation and 2-O-methylation of Nod factors

Loci unique to specific rhizobia direct the adjunction of special groups to the core lipo-oligosaccharide Nod factors. Host-specificity of nodulation (Hsn) genes are thus essential for interaction with certain legumes. Rhizobium sp. NGR234, which can nodulate >110 genera of legumes, possesses three hsn loci and secretes a large family of Nod factors carrying specific substituents. Among them are 3-O (or 4-O)- and 6-O-carbamoyl groups, an N-methyl group, and a 2-O-methylfucose residue which may bear either 3-O-sulfate or 4-O (and 3-O)-acetyl substituents. The hsnIII locus comprises a nod box promoter followed by the genes nodABCIJnolOnoeI. Complementation and mutation analyses show that the disruption of any one of nodIJ, nolO, or noeI has no effect on nodulation. Conjugation of nolO into Rhizobium fredii extends the host range of the recipient to the non-hosts Calopogonium caeruleum and Lablab purpureus, however. Chemical analyses of the Nod factors produced by the NodI, NolO, and NoeI mutants show that the nolO and noeI gene products are required for 3 (or 4)-O-carbamoylation of the nonreducing terminus and for 2-O-methylation of the fucosyl group, respectively. Confirmation that NolO is a carbamoyltransferase was obtained from analysis of the Nod factors produced by R. fredii containing nolO; all are carbamoylated at O-3 (or O-4) on the nonreducing terminus. Since mutation of both nolO and nodU fails to completely abolish production of monocarbamoylated NodNGR factors, it is clear that a third carbamoyltransferase must exist. Nevertheless, the specificities of the two known enzymes are clearly different. NodU is only able to transfer carbamate to O-6 while NolO is specific for O-3 (or O-4) of NodNGR factors.

Structure and evolution of NGRRS-1, a complex, repeated element in the genome of Rhizobium sp. strain NGR234

Much of the remarkable ability of Rhizobium sp. strain NGR234 to nodulate at least 110 genera of legumes, as well as the nonlegume Parasponia andersonii, stems from the more than 80 different Nod factors it secretes. Except for nodE, nodG, and nodPQ, which are on the chromosome, most Nod factor biosynthesis genes are dispersed over the 536,165-bp symbiotic plasmid, pNGR234a. Mosaic sequences and insertion sequences (ISs) comprise 18% of pNGR234a. Many of them are clustered, and these IS islands divide the replicon into large blocks of functionally related genes. At 6 kb, NGRRS-1 is a striking example: there is one copy on pNGR234a and three others on the chromosome. DNA sequence comparisons of two NGRRS-1 elements identified three types of IS, NGRIS-2, NGRIS-4, and NGRIS-10. Here we show that all four copies of NGRRS-1 probably originated from transposition of NGRIS-4 into a more ancient IS-like sequence, NGRIS-10. Remarkably, all nine copies of NGRIS-4 have transposed into other ISs. It is unclear whether the accumulation of potentially mutagenic sequences in large clusters is due to the nature of the IS involved or to some selection process. Nevertheless, a direct consequence of the preferential targeting of transposons into such IS islands is to minimize the likelihood of disrupting vital functions.

Molecular basis of symbiosis between Rhizobium and legumes

Access to mineral nitrogen often limits plant growth, and so symbiotic relationships have evolved between plants and a variety of nitrogen-fixing organisms. These associations are responsible for reducing 120 million tonnes of atmospheric nitrogen to ammonia each year. In agriculture, independence from nitrogenous fertilizers expands crop production and minimizes pollution of water tables, lakes and rivers. Here we present the complete nucleotide sequence and gene complement of the plasmid from Rhizobium sp. NGR234 that endows the bacterium with the ability to associate symbiotically with leguminous plants. In conjunction with transcriptional analyses, these data demonstrate the presence of new symbiotic loci and signalling mechanisms. The sequence and organization of genes involved in replication and conjugal transfer are similar to those of Agrobacterium, suggesting a recent lateral transfer of genetic information.

Sequencing the 500-kb GC-rich symbiotic replicon of Rhizobium sp. NGR234 using dye terminators and a thermostable "sequenase": a beginning

Genomes of the soil-borne nitrogen-fixing symbionts of legumes [Azo(Brady)Rhizobium species] typically have GC contents of 59-65 mol%. As a consequence, compressions (up to 400 per cosmid) are common using automated dye primer shotgun sequencing methods. To overcome this difficulty, we have exclusively applied dye terminators in combination with a thermostable "sequenase" for shotgun sequencing GC-rich cosmids from pNGR234a, the 500-kbp symbiotic replicon of Rhizobium sp. NGR234. A thermostable sequenase incorporates dye terminators into DNA more efficiently than Taq DNA polymerase, thus reducing the concentrations needed (20- to 250-fold). Unincorporated dye terminators can simply be removed by ethanol precipitation. Here, we present data of pXB296, one of 23 overlapping cosmids representing pNGR234a. We demonstrate that the greatly reduced number of compressions results in a much faster assembly of cosmid sequence data by comparing assembly of the shotgun data from pXB296 and the data from another pNGR234a cosmid (pXB110) sequenced using dye primer methods. Within the 34,010-bp sequence from pXB296, 28 coding regions were predicted. All of them showed significant homologies to known proteins, including oligopeptide permeases, an essential cluster for nitrogen fixation, and the C4-dicarboxylate transporter DctA.

Organization of host-inducible transcripts on the symbiotic plasmid of Rhizobium sp. NGR234

In a systematic approach to identify genes involved in the early steps of the legume-Rhizobium symbiosis, we studied transcription patterns of symbiotic plasmid-borne loci. A competitive hybridization procedure was used to identify DNA restriction fragments carrying genes whose expression is enhanced by plant root exudates or by purified flavonoids. Fragments containing induced genes were then located on the physical map of the 500 kb pNGR234a. New inducible loci as well as previously described genes were identified and their time course of induction determined. After initial induction, transcription of loci such as nodABC and the host-specificity genes nodSU decreased to undetectable levels 24 h after incubation with purified flavonoids. In contrast, expression of other loci is detectable only after several hours of induction. Surprisingly, many genes remained transcribed in the nodD1- mutant suggesting the presence of other flavonoid-dependent activators in NGR234. The hsnl region, which is involved in host specificity, was shown to carry several inducible but independently regulated transcripts. Sequencing analysis revealed several open reading frames whose products, based on sequence similarities, may be involved in L-fucose metabolism and its adjunction to the Nod factors.

Molecular cloning and characterization of a sym plasmid locus that regulates cultivar-specific nodulation of soybean by Rhizobium fredii USDA257

Rhizobium fredii strain USDA257 produces nitrogen-fixing nodules on primitive soybean cultivars such as Peking but fails to nodulate agronomically improved cultivars such as McCall. Transposon-mutant 257DH4 has two new phenotypes: it nodulates McCall, and its ability to do so is sensitive to the presence of parental strain USDA257, i.e. it is subject to competitive nodulation blocking. We have isolated a cosmid containing DNA that corresponds to the site of transposon insertion in 257DH4 and have localized Tn5 on an 8.0 kb EcoRI fragment. The 5596 bp DNA sequence that surrounds the insertion site contains seven open reading frames. Five of these, designated nolBTU, ORF4, and nolV, are closely spaced and of the same polarity. nolW and nolX are of the opposite polarity. The initiation codon for nolW lies 155 bp upstream from that of nolB, and its is separated from nolX by 281 bp. The predicted NolT and NolW proteins have putative membrane-spanning regions. The N-terminus of the hypothetical NolW protein also has limited homology to NodH of Rhizobium meliloti, but none of the deduced protein sequences has significant homology to known nodulation gene products. Site-directed mutagenesis with mudII1734 confirms that inactivation of nolB, nolT, nolU, nolV, nolW, or nolX extends host range for nodulation to McCall soybean. This phenotype could not be genetically dissected from sensitivity to competitive nodulation blocking. Expression of nolBTU and nolX is induced as much as 30-fold by flavonoid signal molecules, even though these genes lack nod-box promoters. Histochemical staining of McCall roots inoculated with nolB-, nolU-, or nolX-lacZ fusions verifies that these genes are expressed continuously from preinfection to the stage of the functional nodule. Although a nolU-ORF4-nolV clone hybridizes to a single 8.0 kb EcoRI fragment from 10 strains of R. fredii and broad-host-range Rhizobium sp. NGR234, hybridizing sequences are not detectable in other rhizobia.

Canonical ordered cosmid library of the symbiotic plasmid of Rhizobium species NGR234

Many of the bacterial genes involved in nodulation (nod) and nitrogen fixation (nif) are dispersed over the 500-kilobase plasmid pNGR234a of the broad host-range Rhizobium species NGR234. As a first step toward generating a complete physical and genetic map of the plasmid, a full overlapping collection of cosmids was derived from a total genomic library. Clones were aligned by combining fingerprinting, hybridization, and pulsed-field gel electrophoresis data. Symbiotic loci were localized by probing a representative set of cosmids with both homologous and heterologous genes. nodABC, nodD1, nodD2, nodSU, nolB, and region II are widely dispersed over pNGR234a, while the two functional copies of nifKDH are separated by only 28 kilobases. Interestingly, sequences homologous to nodE, nodG, nodP, and nodQ have been assigned to another autonomously replicating element in Rhizobium species NGR234. Similarly one copy of the structural dctA gene is located on the symbiotic plasmid (dctA1) while the other is on what we assume to be the chromosome.

Which steps are essential for the formation of functional legume nodules?

Nodulation is reviewed in terms of the phenotypes proposed by Vincent (1980). Individual legumes may be infectible by one or more of the three bacterial genera (collectively known as rhizobia) Rhizobium, Bradyrhizobium, or Azorhizobium. The type of infection process by which rhizobia gain entry is largely governed by the host genotype. In addition to the widely studied root-hair pathway, infections may be associated with lateral root emergence or occur between root epidermal cells. The exact chemical and physical nature of the root hair/epidermal cell wall is likely to be a critical factor in determining whether infections can proceed. In addition to differing with species, wall composition may be influenced by soil chemical (e.g. Ca²⁺ ) and biotic factors (e.g. bacteria). Rhizobial features essential for infection include particular surface polysaccharides and the induction of nodulation genes by plant root exudates. Neither of these is likely to be a major barrier to the extension of nodulation to new hosts. Dissemination of rhizobia within developing nodules may be intercellular, via infection threads or by division of a small number of infected cells. All functional symbioses eventually have 'intracellular' bacteria, in the sense that rhizobia are geographically located within the boundary of the host cell walls. However, they remain extracellular in the sense that they are always confined by a membrane which is largely of host cell origin. In some genera they are also surrounded by infection thread walls, probably modified forms of 'invasive' infection thread walls, which allow differentiation of rhizobia into the nitrogen-fixing form. Thus, natural, functional, symbioses may (a) never involve a stage in which bacteria are confined within tubular infection threads or (b) never release bacteria from infection threads. These features are determined by host genotype. The one feature of legume nodules so far found never to vary is the stem-like character of a peripheral vascular system. This contrasts with the central vascular system of actinorhizas and the rhizobial-induced nodules on the Ulmaceous genus Parasponia. Although of great intrinsic interest, this character is unlikely to present an insurmountable barrier to the extension of nodulation to new species. Other features, such as the ability to produce haemoglobin are now known to the in the genetic makeup of many higher plants. The discovery of the wide range of nodule structures occurring in nature, together with work on mutant rhizobia which may bypass critical stages in the nodulation process, suggest various ways in which the extension of nodulation to non-nodulated legumes and to other (initially at least, dicotyledonous) plants may be engineered. CONTENTS Summary 129 I. Introduction 130 II. The symbionts 130 III. Stages in nodulation 132 IV. Stems and nodules 143 V. Prospects for finding/making new symbioses 144 VI. Conclusions 145 Acknowledgements 147 References 147.

Melanin Production by Rhizobium Strains

Different Rhizobium and Bradyrhizobium strains were screened for their ability to produce melanin. Pigment producers (Mel + ) were found among strains of R. leguminosarum biovars viceae, trifolii , and phaseoli, R. meliloti , and R. fredii ; none of 19 Bradyrhizobium strains examined gave a positive response. Melanin production and nod genes were plasmid borne in R. leguminosarum biovar trifolii RS24. In R. leguminosarum biovar phaseoli CFN42 and R. meliloti GR015, mel genes were located in the respective symbiotic plasmids. In R. fredii USDA 205, melanin production correlated with the presence of its smallest indigenous plasmid.

Multiple host-specificity loci of the broad host-range Rhizobium sp. NGR234 selected using the widely compatible legume Vigna unguiculata

Specificity in legume-Rhizobium symbiosis depends on plant and rhizobial genes. As our objective was to study broad host-range determinants of rhizobia, we sought a legume and a Rhizobium with the lowest possible specificity. By inoculating 12 different legumes with a heterogenous collection of 35 fast-growing rhizobia, we found Rhizobium sp. NGR234 to be the Rhizobium and Vigna unguiculata to be the plant with the lowest specificities. Transfer of cloned fragments of the Sym-plasmid pNGR234a into heterologous rhizobia, screening for extension of host-range of the transconjugants to include V. unguiculata, and restriction mapping of the Hsn- and overlapping clones, proved that there were at least three distinct Hsn-regions (HsnI, II, and III) on pNGR234a. HsnI is located next to nodD, HsnII is linked to nifKDH and HsnIII to nodC. In addition to nodulation of Vigna, HsnI conferred upon the transconjugants the ability to nodulate Glycine max, Macroptilium atropurpureum and Psophocarpus tetragonolobus. All three Hsn-regions, when transferred to the appropriate recipients, induced root-hair-curling on M. atropurpureum. Hsn-region III was able to complement a mutation in the host-range gene nodH of R. meliloti strain 2011. Homology to "nod-box"-sequences could be shown only for the sub-clones containing HsnII and HsnIII, thus suggesting different regulation mechanisms for HsnI and HsnII/III.

Genetic locus in Rhizobium japonicum (fredii) affecting soybean root nodule differentiation

A genetic locus in fast-growing Rhizobium japonicum (fredii) USDA 191 (Fix+ on several contemporary soybean cultivars) was identified by random Tn5 mutagenesis as affecting the development and differentiation of root nodules. This mutant (MU042) is prototrophic and shows no apparent alterations in its surface properties. It induces aberrant nodules, arrested at the same early level of differentiation, on all its host plants. An 8.1-kilobase EcoRI fragment containing Tn5 was cloned from MU042. In USDA 191 as well as another fast-growing strain, USDA 201, the affected locus was found to be unlinked to the large symbiotic plasmid and appears to be chromosomal. An analogous sequence has been shown to be present in Bradyrhizobium japonicum (J. Stanley, G.G. Brown, and D.P.S. Verma, J. Bacteriol. 163:148-154, 1985) as well as in R. trifolii and R. meliloti. MU042 was complemented for effective nodulation of soybean by a cosmid clone from USDA 201, and the complementing locus was delimited to a 6-kilobase EcoRI subfragment. An R. trifolii strain (MU225), whose indigenous symbiotic plasmid was replaced by that of strain USDA 191, induced more highly differentiated nodules on soybean than did MU042. This suggests that the mutation in MU042 can be functionally substituted by similar loci of other fast-growing rhizobia. Leghemoglobin and nodulin-35 (uricase II) were present in the differentiated Fix- nodules induced by MU225, whereas both were absent in MU042-induced pseudonodule structures.

Identification of Rhizobium plasmid sequences involved in recognition of Psophocarpus, Vigna, and other legumes

Symbiotic DNA sequences involved in nodulation by Rhizobium must include genes responsible for recognizing homologous hosts. We sought these genes by mobilizing the symbiotic plasmid of a broad host-range Rhizobium MPIK3030 (= NGR234) that can nodulate Glycine max, Psophocarpus tetragonolobus, Vigna unguiculata, etc., into two Nod- Rhizobium mutants as well as into Agrobacterium tumefaciens. Subsequently, cosmid clones of pMPIK3030a were mobilized into Nod+ Rhizobium that cannot nodulate the chosen hosts. Nodule development was monitored by examining the ultrastructure of nodules formed by the transconjugants. pMPIK3030a could complement Nod- and Nif- deletions in R. leguminosarum and R. meliloti as well as enable A. tumefaciens to nodulate. Three non-overlapping sets of cosmids were found that conferred upon a slow-growing Rhizobium species, as well as on R. loti and R. meliloti, the ability to nodulate Psophocarpus and Vigna, thus pointing to the existence of three sets of host-specificity genes. Recipients harboring these hsn regions had truly broadened host-range since they could nodulate both their original hosts as well as MPIK3030 hosts.

Nodulins and nodulin genes of Glycine max

Nodulins are organ-specific plant proteins induced during symbiotic nitrogen fixation. Nodulins play both metabolic and structural roles within infected and uninfected nodule cells. In soybean, several nodulin genes, coding for abundant nodulins, have been identified and isolated. Structural analysis of some of these genes has revealed their possible mode of regulation and the subcellar location of the protein product. Studies of ineffective symbiosis based on cultivar-strain genotype differences suggested that both partners influence the expression of nodulin genes. Concomitant with nodule organogenesis, the Rhizobium undergoes substantial differentiation leading to the accumulation of nodule-specific bacterial proteins, bacteroidins. The major structural alteration occuring in the infected cell is the formation of a membrane enclosing the bacteroid (peribacteroid membrane). A number of nodulins are specifically targetted to this membrane during endosymbiosis. The induction of nodulins and bacteroidins leads to the formation of an effective nodule. Nodulin genes can be induced in vitro by factors derived from nodules suggesting that trans-activators may be involved in derepression of the host genes necessary for Rhizobium-legume symbiosis.

Isolation and characterization of the DNA region encoding nodulation functions in Bradyrhizobium japonicum

The DNA region encoding early nodulation functions of Bradyrhizobium japonicum 3I1b110 (I110) was isolated by its homology to the functionally similar region from Rhizobium meliloti. Isolation of a number of overlapping recombinant clones from this region allowed the construction of a restriction map of the region. The identified nodulation region of B. japonicum shows homology exclusively to those regions of R. meliloti and Rhizobium leguminosarum DNA known to encode early nodulation functions. The region of homology with these two fast-growing Rhizobium species was narrowed to an 11.7-kilobase segment. A nodulation-defective mutant of Rhizobium fredii USDA 201, strain A05B-2, was isolated and found to be defective in the ability to curl soybean root hairs. Some of the isolated recombinant DNA clones of B. japonicum were found to restore wild-type nodulation function to this mutant. Analysis of the complementation results allows the identification of a 1.8-kilobase region as essential for restoration of Hac function.

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.

Mode of infection, nodulation specificity, and indigenous plasmids of 11 fast-growing Rhizobium japonicum strains

Eleven fast-growing strains of Rhizobium japonicum were characterized with respect to indigenous plasmids and abilities to infect (Inf+) and nodulate (Nod+) cowpea, siratro, wild soybean, and three commercial cultivars of soybean. All strains caused infection via infection threads in root hairs and consistently nodulated cowpea, siratro, and wild soybean in growth pouches. Interactions with commercial cultivars of soybean were strikingly strain specific. Some combinations were Nod-, and infection was delayed in others. The ratios of infections to nodules and the distribution of nodules on primary and lateral roots also varied substantially. A modified in-gel lysis procedure was devised for electrophoretic separation of plasmids from the strains. Plasmids (ranging in size from 35 to greater than 300 megadaltons) were reproducibly detected in all strains.