Reduced rhizosphere colonization ability ofAgrobacterium tumefaciens chromosomal virulence (chv) mutants

Mutations in the chromosomal virulence (chv) region ofA. tumefaciens strain A723 reduce virulence, motility, and ability of the bacteria to bind to plant cells. We conducted experiments to assess the ability ofchv mutants to colonize the rhizosphere ofPisum sativum. The mutation had no effect on ability of bacteria to grow with a defined number of root cap cells as the sole carbon and nitrogen source. Ten days after inoculation, there were up to 103-fold more wild type thanchv mutant bacteria present in the rhizosphere of inoculated plants.     

Plasmid-mediated control of nodulation in Rhizobium trifolii

The nodulation ability was effectively eliminated from different Rhizobium trifolii strains incubated at elevated temperature (urkowski and Lorkiewicz, 1978). Non-nodulating (Nod^-) mutants were stable and no reversion of Nod^- to Nod⁺ phenotype was observed. Strains R. trifolii 24 and T12 which showed a high percentage of elimination of nodulation ability were examined in detail. Two plasmids were detected in strain 24 using neutral and alkaline sucrose gradient centrifugation of plasmid preparations. Molecular weights of the plasmids pWZ1 and pWZ2 were 460 Mdal and 190 Mdal, respectively. Rhizobium lysates labeled with ³H-thymidine and ultracentrifuged in caesium chloride — ethidium bromide gradients demonstrated a 40% reduction of the plasmid DNA content in R. trifolii 24 Nod^- mutants in comparison with the nodulating wild type strain 24. It was found further that non-nodulation of mutants 24 Nod^- was due to the absence of plasmid pWZ2. Sucrose gradient data also demonstrated that strain T12 contained two plasmids with molecular weights corresponding to those of pWZ1 and pWZ2, respectively. In Nod^- mutant clones derived from strain T12, pWZ2 plasmid was missing.Non Standard Abbreviations CCC covalently closed circular - OC open cirucular - Sarkosyl sodium N-lauroylsarcosinate     

Variation in Binding and Virulence of Agrobacterium tumefaciens Chromosomal Virulence (chv) Mutant Bacteria on Different Plant Species

Chromosomal virulence (chv) mutants of Agrobacterium tumefaciens have been reported to be deficient in binding to cells of zinnia, tobacco, and bamboo. The mutants are nonpathogenic on stems of Kalanchoë, sunflower, tomato, Jerusalem artichoke, and tobacco, but they cause tumors on tubers of Solanum tuberosum. We used a root cap cell binding assay to test ability of cells from individual plants of 13 different plant species to bind parent or chv mutant bacteria. The same plants were then inoculated to test for disease response. Cells from nine of the plant species were grossly deficient in their abilities to bind mutant bacteria, and the plants inoculated with mutant bacteria failed to form tumors. In contrast, root cap cells as well as root hairs and root surfaces of S. tuberosum, S. okadae, and S. hougasii bound chv mutant bacteria as well as wild type. Nevertheless, S. tuberosum roots inoculated with mutant bacteria did not develop tumors. Although S. okadae plants inoculated with mutant bacteria formed a few tumors, and S. hougasii developed as many tumors in response to chv mutants as in response to the parent strain, the tumors induced by mutant bacteria were smaller.     

Influence ofRhizobium leguminosarum biovartrifolii host specific nodulation genes on the ontogeny of clover nodulation

Summary The infection of white clover seedlings byRhizobium strains with different host range properties was assessed using various microscopic techniques. Several wild-type andRhizobium leguminosarum biovarvicias hybrid strains containing definedR. l. bv.trifolii host range genes were used. The morphological changes in the root tissue of uninoculated and rhizobia inoculated white clovers were identified and compared. In particular, changes were observed in the induction of inner cortical cell division, alterations to nodule development and lateral root formation. The responses of the infected roots and the types of structures formed support the hypothesis that lateral roots and nodules may be physiologically homologous structures. To establish a normal pattern of nodulation on white clover roots, both sets of known host specific nodulation genes (operonsnod FERL andnod MNX) ofR. l. bv.trifolii were required. However, some nodule development occurred when only thenod FERL genes were present in the hybrid strain.     

Phylogeny of nodulation genes and symbiotic properties of Genista tinctoria bradyrhizobia

Pairwise comparisons of Genista tinctoria (dyer’s weed) rhizobium nodA, nodC, and nodZ gene sequences to those available in databanks revealed their highest sequence identities to nodulation loci of Bradyrhizobium sp. (Lupinus) strains and rhizobia from other genistoid legumes. On phylogenetic trees, genistoid microsymbionts were grouped together in monophyletic clusters, which suggested that their nodulation genes evolved from a common ancestor. G. tinctoria nodulators formed symbioses not only with the native host, but also with other plants of Genisteae tribe such as: Lupinus luteus, Sarothamnus scoparius, and Chamaecytisus ratisbonensis, and they were classified as the genistoid cross-inoculation group. The dyer’s weed root nodules were designated as indeterminate with apical meristem consisting of infected and uninfected cells.The GenBank accession numbers for the sequences reported in this paper are as follows: nodC, DQ139776–DQ139781; nodA, DQ135897, Q135898; nodZ, DQ135899–DQ135903.     

Analysis of pss genes of Rhizobium leguminosarum required for exopolysaccharide synthesis and nodulation of peas: their primary structure and their interaction with psi and other nodulation genes

Summary Strains of Rhizobium leguminosarum (R. l.) biovar viciae containing pss mutations fail to make the acidic exopolysaccharides (EPS) and are unable to nodulate peas. It was found that they also failed to nodulate Vicia hirsuta, another host of this biovar. When peas were co-inoculated with pss mutant derivatives of a strain of R.l. bv viciae containing a sym plasmid plus a cured strain lacking a sym plasmid (and which is thus Nod^-, but for different reasons) but which makes the acidic EPS, normal numbers of nodules were formed, the majority of which failed to fix nitrogen (the occasional Fix⁺ nodules were pressumably induced by strains that arose as a result of genetic exchange between cells of the two inoculants in the rhizosphere). Bacteria from the Fix^- nodules contained, exclusively, the strain lacking its sym plasmid. When pss mutant strains were co-inoculated with a Nod^- strain with a mutation in the regulatory gene nodD (which is on the sym plasmid pRL1JI), normal numbers of Fix⁺ nodules were formed, all of which were occupiced solely by the nodD mutant strain. Since a mutation in nodD abolishes activation of other nod genes required for early stages of infection, these nod genes appear to be dispensable for subsequent stages in nodule development. Recombinant plasmids, containing cloned pss genes, overcame the inhibitory effects of psi, a gene which when cloned in the plasmid vector pKT230, inhibits both EPS production and nodulation ability. Determination of the sequence of the pss DNA showed that one, or perhaps two, genes are required for correcting strains that either carry pss mutations or contain multi-copy psi. The predicted polypeptide product of one of the pss genes had a hydrophobic aminoterminal region, suggesting that it may be located in the membrane. Since the psi gene product may also be associated with the bacterial membrane, the products of psi and pss may interact with each other.     

Organization and characterization of the virCD genes from Agrobacterium rhizogenes

Summary We have precisely localized virulent (vir) genes of the hairy root-inducing plasmid pRiA4b on the basis of sequence similarity with the tumor-inducing plasmid pTiA6NC, and shown that the overall organizations of vir genes in both plasmids are fairly analogous, although sizes and spacer lengths in some genes differ from each other. Among the vir genes thus mapped, the virC and virD loci were characterized in detail. Transposon insertions in virD led to loss of tumorigenicity on Kalanchoe stems and carrot discs, and one within virC exhibited an attenuated pathogenicity. The avirulent phenotype of the virD2 strain among these mutants was due to the lack of ability to recombine T-DNA border repeats in Agrobacterium cells. The nucleotide sequence of most parts of the virCD loci were similar in both plasmids. The virCD genes of these two plasmids, therefore, seem comparable both functionally and structurally. Phylogeny of pRi and pTi has also been discussed from the sequence data.     

Identification and cloning of nodulation genes from the stem-nodulating bacterium ORS571

Summary After random Tn5 mutagenesis of the stem-nodulating Sesbania rostrata symbiont strain ORS571, Nif^-, Fix^- and Nod^- mutants were isolated. The Nif^- mutants had lost both free-living and symbiotic N₂ fixation capacity. The Fix^- mutants normally fixed N₂ in the free-living state but induced ineffective nodules on S. rostrata. They were defective in functions exclusively required for symbiotic N₂ fixation. A further analysis of the Nod^- mutants allowed the identification of two nod loci. A Tn5 insertion in nod locus 1 completely abolished both root and stem nodulation capacity. Root hair curling, which is an initial event in S. rostrata root nodulation, was no longer observed. A 400 bp region showing weak homology to the nodC gene of Rhizobium meliloti was located 1.5 kb away from this nod Tn5 insertion. A Tn5 insertion in nod locus 2 caused the loss of stem and root nodulation capacity but root hair curling still occurred. The physical maps of a 20.5 kb DNA region of nod locus 1 and of a 40 kb DNA region of nod locus 2 showed no overlaps. The two nod loci are not closely linked to nif locus 1, containing the structural genes for the nitrogenase complex (Elmerich et al. 1982).     

Rhizobium leguminosarum genes required for expression and transfer of host specific nodulation

The contributions of various nod genes from Rhizobium leguminosarum biovar viceae to host-specific nodulation have been assessed by transferring specific genes and groups of genes to R. leguminosarum bv. trifolii and testing the levels of nodulation on Pisum sativum (peas) and Vicia hirsuta. Many of the nod genes are important in determination of host-specificity; the nodE gene plays a key (but not essential) role and the efficiency of transfer of host specific nodulation increased with additional genes such that nodFE < nodFEL < nodFELMN. In addition the nodD gene was shown to play an important role in host-specific nodulation of peas and Vicia whilst other genes in the nodABCIJ gene region also appeared to be important. In a reciprocal series of experiments involving nod genes cloned from R. leguminosarum bv. trifolii it was found that the nodD gene enabled bv. viciae to nodulate Trifolium pratense (red clover) but the nodFEL gene region did not. The bv. trifolii nodD or nodFEL genes did significantly increase nodulation of Trifolium subterraneum (sub-clover) by R. leguminosarum bv. viciae. It is concluded that host specificity determinants are encoded by several different nod genes.     

Cloned nodulation genes of Rhizobium leguminosarum determine host-range specificity

Summary Three nodulation-deficient (nod) mutants of Rhizobium leguminosarum were isolated following insertion of the transposon Tn5 into pRL1JI, the R. leguminosarum plasmid known to carry the nodulation genes. DNA adjacent to the nod: Tn5 alleles was subcloned and used to probe a cosmid clone bank containing DNA from a Rhizobium strain carrying pRL1JI. Two cosmid clones which showed homology with the probe contained about 10 kb of DNA in common. The R. leguminosarum host-range determinants were found to be present within this 10 kb common region since either of the cosmid clones could enable a cured R. phaseoli strain to nodulate peas instead of Phaseolus beans, its normal host. Electron microscopy of nodules induced by Rhizobium strains cured of their normal symbiotic plasmid but containing either of the two cosmid clones showed bacteroid-forms surrounded by a peri-bacteroid membrane, indicating that normal infection had occurred. Thus it is clear that this 10 kb region of nodDNA carries the genes that determine host range and that relatively few bacterial genes may be involved in nodule and bacteroid development.     

Host-specific nodulation is encoded on a 14kb DNA fragment in Rhizobium trifolii

Summary The Rhizobium trifolii genes necessary for nodule induction and development have been isolated on a 14.0kb fragment of symbiotic (Sym) plasmid DNA. When cloned into a broad-host-range plasmid vector, these sequences confer a clover nodulation phenotype on a derivative of R. trifolii which has been cured of its endogenous Sym plasmid. Furthermore, these sequences encode both host specificity and nodulation functions since they confer the ability to recognize and nodulate clover plants on Agrobacterium and a fast-growing cowpea Rhizobium. This indicates that the bacterial genes essential for the initial, highly-specific interaction with plants are closely linked.     

Organisation of nodulation and nitrogen fixation genes on a Rhizobium trifolii symbiotic plasmid

A Rhizobium trifolii symbiotic plasmid specific gene library was constructed and the physical organisation of regions homologous to nifHDK, nifA and nod genes was determined. These symbiotic gene regions were localised to u 25 kb region on the sym-plasmid, pPN1. In addition four copies of a reiterated sequence were identified on this plasmid, with one copy adjacent to nifH. No rearrangement of these reiterated sequences was observed between R. trifolii bacterial and bacteroid DNA. Analysis of a deletion derivative of pPN1 showed that these sequences were spread over a 110 kb region to the left of nifA.     

Involvement of Rhizobium leguminosarum nodulation genes in gene expression in pea root hairs

The mRNA population in pea root hairs was characterized by means of in vitro translation of total root hair RNA followed by 2-dimensional gel electrophoresis of the translation products. Root hairs contain several mRNAs not detectable in total RNA preparations from roots. Most of these root hair-specific mRNAs occur in elongating root hairs at higher levels than in mature root hairs. The expression of some genes in pea root hairs is typically affected by inoculation with Rhizobium leguminosarum. One gene, encoding RH-42, is specifically induced while the expression of another gene, encoding RH-44, is markedly enhanced. Using R. leguminosarum mutants it was shown that the nodC gene is required for the induction and enhancement of expression of the RH-42 and RH-44 genes, respectively, while the Rhizobium chromosomal gene pss1, involved in exopolysaccharide synthesis, is not essential. After induction of the nod genes with apigenin the bacteria excrete into the culture medium a factor that causes root hair deformation. This deformation factor stimulates the expression of the RH-44 gene but does not induce the expression of the gene encoding RH-42.     

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.     

Rhizobium nodulation genes involved in root hair curling (Hac) are functionally conserved

Summary Five specific transposon-induced nodulation defective (Nod⁻) mutants from different fast-growing species ofRhizobium were used as the recipients for the transfer of each of several endogenous Sym(biosis) plasmids or for recombinant plasmids that encode early nodulation and host-specificity functions. The Nod⁻ mutants were derived fromR. trifolii, R. meliloti and from a broad-host-rangeRhizobium strain which is able to nodulate both cowpea (tropical) legumes and the non-legumeParasponia. These mutants had several common features (a), they were Nod⁻ on all their known plant hosts, (b), they could not induce root hair curling (Hac⁻) and (c), the mutations were all located on the endogenous Sym-plasmid of the respective strain. Transfer to these mutants of Sym plasmids (or recombinant plasmids) encoding heterologous information for clover nodulation (pBR1AN, pRt032, pRt038), for pea nodulation (pJB5JI, pRL1JI::Tn1831), for lucerne nodulation (pRmSL26), or for the nodulation of both tropical legumes and non-legumes (pNM4AN), was able to restore root hair curling capacity and in most cases, nodulation capacity of the original plant host(s). This demonstrated a functional conservation of at least some genes involved in root hair curling. Positive hybridization between Nod DNA sequences fromR. trifolii and from a broad-host-rangeRhizobium strain (ANU240) was obtained to other fast-growingRhizobium strains. These results indicate that at least some of the early nodulation functions are common in a broad spectrum ofRhizobium strains.     

Genetic and functional analysis of the nodulation region of the Rhizobium leguminosarum Sym plasmid pRL1JI

Thirty Tn5- or Tn1831-induced nodulation (nod) mutants of Rhizobium leguminosarum were examined for their genetic and symbiotic properties. Thirteen mutants contained a deletion in Sym plasmid pRL1JI. These deletions cover the whole nod region and are 50 kb in size. All remaining seventeen mutations are located in a 6.6 kb EcoRI nod fragment of the Sym plasmid. Mutations in a 3.5 kb part on the right hand side of this 6.6 kb fragment completely prevent nodulation on Vicia sativa. All mutants in this 3.5 kb area are unable to induce marked root hair curling and thick and short roots.Mutations in a 1.5 kb area on the left hand side of the 6.6 kb nod fragment generate other symbiotic defects in that nodules are only rarely formed and only so after a delay of several days. Moreover, infection thread formation is delayed and root hair curling is more excessive than that caused by the parental strain. Their ability to induce thick and short roots is unaltered.Mutations in this 1.5 kb region are not complemented by pRmSL26, which carries nod genes of R. meliloti, whereas mutations in the 3.5 kb region are all complemented by pRmSL26.Abbreviations Rps repression of production of small bacteriocin - Mep medium bacteriocin production - Nod nodulation - Fix fixation - Tsr thick and short roots - Flac root hair curling - Hsp host specificity - Flad root hair deformation - Tc tetracycline - Km kanamycin - Cm chloramphenicol - Sp spectinomycin - Sm streptomycin - R resistant     

NoIR controls expression of the Rhizobium meliloti nodulation genes involved in the core Nod factor synthesis

The synthesis of Rhizobium meliloti Nod signal molecules, encoded by the nod gene products, is finely regulated. A negative control of plasmid-borne nod gene expression is provided by the NoIR repressor encoded by the chromosomal noIR gene. NoIR was previously shown to downregulate the expression of the activator nodD1 gene and the common nodABC operon by binding to an overlapping region of the two promoters adjacent to the n1 nod-box (Kondorosi et al., 1989). We demonstrate here that NoIR also controls the expression of two additional genes, nodD2 and nodM, but does not directly regulate the expression of the host-specific nod genes located downstream of the n2, n3 and n5 nod-boxes. Thus, the nod genes are differentially regulated by NoIR and only those providing common nodulation functions, by determining the synthesis of the core Nod factor structure, are subjected to this negative regulation. Furthermore, NoIR has a strong negative effect on the production of Nod metabolites, the level of which may serve as a fine-tuning mechanism for optimal nodulation, specific to host-plant genotypes. In addition, it elicits preferential synthesis of Nod factors carrying unsaturated C₁₆ fatty acids. Expression of noIR was high both in the free-living bacterium and in the bacteroid and it was downregulated by its own product and by the nod gene inducer luteolin.     

Identification and cloning of nodulation genes from the wide host range Rhizobium strain MPIK3030

Summary A 70 kbp segment of the megaplasmid from a broad host range Rhizobium strain (MPIK3030) was mapped with the aid of cosmid clones made in the vector pJB8. A 7.9 kbp EcoRI fragment from this region, 55 kbp away from the nif gene cluster, was shown to hybridize to the common nod genes from R. meliloti. Using several R. meliloti nod probes it was possible to delimit an 830 bp region as being the center of greatest homology. Sequence data from two sections of this region gave a nucleotide homology of 73.7% to the nodC gene of R. meliloti. Using Tn5 mutagenesis a clone was isolated carrying Tn5 in the highly homologous region. When tested on Macroptilium atropurpureum, this MPIK3030 derivative was shown to have a Nod^– phenotype. When the wild-type allele was reintroduced into the Tn5 mutant, nodulation was restored. Interspecies complementation also showed that both R. meliloti and Rhizobium sp. MPIK3030 nod regions were able to restore nodulation to Tn5-induced nodC mutants from either strain.Dedicated to Professor Georg Melchers to celebrate his 50-year association with the journal     

Microscopic analysis of the effect ofRhizobium leguminosarum biovartrifolii host specific nodulation genes in the infection of white clovers

Summary A microscopic assessment is presented of the comparative infection capacity of wild-type and hybrid strains ofRhizobium leguminosarum bv.viciae withR. l. bv.trifolii strain ANU 843 on white clover seedlings. TheR. l. bv.viciae hybrid strains contained defined DNA segments coding for different combinations ofR. l. bv.trifolii host-specific nodulation genes. White clover plants were examined over a 72 h period to assessRhizobium infectivity, the morphological changes in root hair growth; colonisation ability of rhizobia; infection thread initiation and the ability to induce cortical cell division.R. l. bv.viciae strain 300 induced root hair curling more slowly than strain ANU 843 or any of the hybrid strain 300 bacteria, and when curling had taken place, there was poorer colonization by strain 300 within the folded hair cell, no evidence of infection thread formation and only limited cortical cell division 72 h after inoculation. The addition of the host-specific nodulation genes ofR. l. bv.trifolii to strain 300 was necessary to induce infection threads and establish a normal pattern of nodulation of the roots of white clovers.     

Root nodulation studies inAeschynomene aspera

Summary Fifteen isolates of nodule bacteria were isolated from root and stem nodules ofAeschynomene aspera and they were characterized as Rhizobium by well known laboratory tests. All these isolates together with other efficient strains of known rhizobia belonging to different cross-inoculation groups were evaluated for their nodulation abilities onAeschynomene aspera, Cajanus cajan (pigeon pea),Cicer arietinum (chickpea),Pisum sativum (pea),Trifolium repens (clover),Medicago sativa (lucerne),Lens culinaris (lentil),Glycine max (soybean),Vigna sinensis (cowpea),Vigna radiata (mung bean),Vigna mungo (urd bean) andArachis hypogea (peanut). The results demonstrated that Rhizobium fromAeschynomene could form nodules only on its homologous host (Aeschynomene) but not on other legumes tested. Secondly, none of the rhizobia of other cross-inoculation groups could nodulateA. aspera.