Nodulation inhibition by Rhizobium leguminosarum multicopy nodABC genes and analysis of early stages of plant infection.

During analysis of early events in the infection and nodulation of Vicia hirsuta roots inoculated with normal and mutant strains of Rhizobium leguminosarum and strains containing cloned nodulation (nod) genes, a number of novel observations were made. (i) Alternating zones of curled and straight root hairs were seen on roots of V. hirsuta inoculated with the wild-type strain of R. leguminosarum. This phasing of root hair curling was not seen if plants were grown under continuous light or continuous dark conditions. (ii) Reduced nodulation and delayed nodule initiation was observed with a strain carrying a Tn5 mutation in the nodE gene. In addition the phased root hair curling was absent, and root hair curling was observed along the length of the root. (iii) The nodABC genes cloned on a multicopy plasmid in a wild-type strain inhibited nodulation but induced a continuous root hair curling response. Those few nodules that eventually formed were found to contain bacteria which had lost the plasmid carrying the nodABC genes. (iv) With a strain of Rhizobium cured of its indigenous symbiotic plasmid, but containing the cloned nodABCDEF genes, continuous root hair curling on V. hirsuta was observed. However, no infection threads were observed, and surprisingly, it did appear that initial stages of nodule development occurred. Observations of thin sections of these early developing nodules indicated that early nodule meristematic divisions may have occurred but that no bacteria were found within the nodules and no infection threads were observed either within the nodule bumps or within any of the root hairs. It was concluded that for normal infections to occur, precise regulation of the nod genes is required and that overexpression of the root hair curling genes inhibits the normal infection process.     

Studies on the Characterization of Root Morphology of White Clover Infected by Transconjugant of Rhizobium leguminosarum

White clover plants were inoculated with transconjugant strain' 290 which was obtained from introduction of host specific nodulation genes of wild-type Rhizobium trifolii strain ANU 843 to Rhizobium leguminosarum strain 300. The characterization of root morphology of white clover induced by the transconjugant was observed and compared to the plants induced by the parent strains. White clover started tO form a typical root hair curling inoculated with transconjugant strain 290 24h after inoculation, at 48h a part of cell wall of root hair was degradated, infection thread was observed in the infected root hair cell, cortical cell divisions occurred extensively. All these characterizations were similar to that infected by strain ANU 843. Plant inoculation test indicated that no nodule was formed when inoculated by R. leguminosarum strain 300, while plants nodulated when inoculated with transconjugant strain 290 as well as R. trifolii ANU 843. This suggests that introduction of host specific nodulation genes of R. trifolii results in conferring the nodulation ability of R. leguminosarum on white clover.     

Sym plasmid genes of Rhizobium trifolii expressed in Lignobacter and Pseudomonas strains.

A 14-kilobase (kb) fragment of Rhizobium trifolii Sym plasmid containing nodulation (nod) genes or the pSym plasmid of R. trifolii cointegrated with a broad-host-range vector R68.45 (pPN1) were transferred to Lignobacter strain K17 and Pseudomonas aeruginosa strain PAO5 by conjugation. Lignobacter transconjugants carrying Sym plasmid pPN1 formed nodules on white, red, and subterranean clover plants. Lignobacter transconjugants containing a 14-kb fragment of nod genes cloned into a multicopy plasmid nodulated only white and subterranean clover plants, whereas transconjugants carrying the same fragment cloned into a low-copy plasmid vector nodulated only white clover plants. All nodules formed by Lignobacter transconjugants showed bacterial release from the infection threads into the host cytoplasm. Pseudomonas transconjugants with plasmid pPN1 formed nodule-like structures on white clover plants. These structures were not invaded by bacteria; however, a few bacteria were found within the intercellular spaces of the outermost cells of the structures. Pseudomonas transconjugants carrying the 14-kb fragment of R. trifolii nod genes did not form nodules on tested clover plants. All clover plants inoculated with either Pseudomonas or Lignobacter transconjugants containing a 14-kb fragment of nod genes (but not entire Sym plasmid) showed the "thick-and-short-root" response when compared to the control plants inoculated with the R. trifolii wild-type strain.     

Nodulation of specific legumes is controlled by several distinct loci in Rhizobium trifolii

Summary Three distinct loci (designated regions III, IV and V) were identified in the 14 kb Nod region of Rhizobium trifolii strain ANU843 and were found to determine the host range characteristics of this strain. Deletion of region III or region V only from the 14 kb Nod region affected clover nodulation capacity. The introduction to R. Leguminosarum of DNA fragments on multicopy vectors carrying regions III, IV and V (but not smaller fragments) extended the host range of R. leguminosarum so that infection threads and nodules occurred on white clover plants. The same DNA fragments were introduced to the Sym plasmid-cured strain (ANU845) carrying the R. meliloti recombinant nodulation plasmid pRmSL26. Plasmid pRmSL26 alone does not confer root hair curling or nodulation on clover plants. However, the introduction to ANU845 (pRmSL26) of a 1.4 kb fragment carrying R. trifolii region IV only, resulted in the phenotypic activation of marked root hair curling ability to this strain on clovers but no infection events or nodules resulted. Only the transfer of regions III, IV and V to strain ANU845 (pRmSL26) conferred normal nodulation and host range ability of the original wild type R. trifolii strain. These results indicate that the host range genes determine the outcome of early plant-bacterial interactions primarily at the stage of root hair curling and infection.     

Interference between Rhizobium meliloti and Rhizobium trifolii nodulation genes: genetic basis of R. meliloti dominance.

Transfer of an IncP plasmid carrying the Rhizobium meliloti nodFE, nodG, and nodH genes to Rhizobium trifolii enabled R. trifolii to nodulate alfalfa (Medicago sativa), the normal host of R. meliloti. Using transposon Tn5-linked mutations and in vitro-constructed deletions of the R. meliloti nodFE, nodG, and nodH genes, we showed that R. meliloti nodH was required for R. trifolii to elicit both root hair curling and nodule initiation on alfalfa and that nodH, nodFE, and nodG were required for R. trifolii to elicit infection threads in alfalfa root hairs. Interestingly, the transfer of the R. meliloti nodFE, nodG, and nodH genes to R. trifolii prevented R. trifolii from infecting and nodulating its normal host, white clover (Trifolium repens). Experiments with the mutated R. meliloti nodH, nodF, nodE, and nodG genes demonstrated that nodH, nodF, nodE, and possibly nodG have an additive effect in blocking infection and nodulation of clover.     

Isolation and expression of Rhizobium japonicum cloned DNA encoding an early soybean nodulation function.

A first visible step in the nodulation of legumes by Rhizobium spp. is the deformation and curling of root hairs. We have identified and cloned DNA sequences encoding this function from two strains of Rhizobium japonicum (USDA 122 and USDA 110) with a weakly homologous probe from Rhizobium meliloti. Root hair curling encoded by the cloned DNA fragments was examined on soybeans (Glycine soja ) after conjugative transfer of these sequences in broad-host-range vectors to various bacterial genera. Pseudomonas putida gave unambiguous expression of the root hair curling genes. This enabled us to identify the 8.7-kilobase EcoRI fragments encoding root hair curling from each strain. The phenotypes encoded by the plasmids pBS1 (derived from strain USDA 122) and pBS2 (derived from strain USDA 110) are distinct and represent a phenotype characteristic of their parent R. japonicum strains. Subclones of pBS1 and pBS2 were generated in single and multicopy vectors, and their expression was analyzed in P. putida. We established that a 4.2-kilobase internal Sa/I fragment of pBS1 and a 3.5-kilobase SstI -EcoRI fragment of pBS2 are sufficient to confer root hair curling on soybeans.     

DNA sequence of the Rhizobium leguminosarum nodulation genes nodAB and C required for root hair curling

A 3.2kb fragment of DNA cloned from Rhizobium leguminosarum has been shown to contain the genes necessary for the induction of root hair curling, the first observed step in the infection of leguminous plants by R. leguminosarum. The DNA sequence of this region has been determined and three open reading frames were identified: genes corresponding to these open reading frames have been called nodA, nodB and nodC and are transcribed in that order. Mutations within the nodC gene completely blocked root hair curling. However, a subcloned fragment containing only the nodC gene did not induce normal root hair curling (although some branching was observed), indicating that the nodA and B genes may also be required for normal root hair curling. From an analysis of the predicted amino acid sequences of the nodAB and C genes it appeared unlikely that their products are secreted; therefore it is concluded that the induction of root hair curling could be due to a secreted metabolite.     

Isolation and characterization of transposon Tn5-induced symbiotic mutants of Rhizobium loti

Rhizobium loti NZP2037 and NZP2213, each cured of its single large indigenous plasmid, formed effective nodules on Lotus spp., suggesting that the symbiotic genes are carried on the chromosome of these strains. By using pSUP1011 as a vector for introducing transposon Tn5 into R. loti NZP2037, symbiotic mutants blocked in hair curling (Hac), nodule initiation (Noi), bacterial release (Bar), and nitrogen fixation (Nif/Cof) on Lotus pedunculatus were isolated. Cosmids complementing the Hac, Noi, and Bar mutants were isolated from a pLAFR1 gene library of NZP2037 DNA by in planta complementation and found to contain EcoRI fragments of identical sizes to those into which Tn5 had inserted in the mutants. The cosmids that complemented the mutants of these phenotypic classes did not share common fragments, nor did cosmids that complemented four mutants within the Noi class, suggesting that these symbiotically important regions are not tightly linked on the R. loti chromosome.     

A non-nodulating alfalfa mutant displays neither root hair curling nor early cell division in response to Rhizobium meliloti.

The early events in the alfalfa-Rhizobium meliloti symbiosis include deformation of epidermal root hairs and the approximately concurrent stimulation of cell dedifferentiation and cell division in the root inner cortex. These early steps have been studied previously by analysis of R. meliloti mutants. Bacterial strains mutated in nodABC, for example, fail to stimulate either root hair curling or cell division events in the plant host, whereas exopolysaccharide (exo) mutants of R. meliloti stimulate host cell division but the resulting nodules are uninfected. As a further approach to understanding early symbiotic interactions, we have investigated the phenotype of a non-nodulating alfalfa mutant, MnNC-1008 (NN) (referred to as MN-1008). Nodulating and non-nodulating plants were inoculated with wild-type R. meliloti and scored for root hair curling and cell divisions. MN-1008 was found to be defective in both responses. Mutant plants inoculated with Exo- bacteria also showed no cell division response. Therefore, the genetic function mutated in MN-1008 is required for both root hair curling and cell division, as is true for the R. meliloti nodABC genes. These observations support the model that the distinct cellular processes of root hair curling and cell division are triggered by related mechanisms or components, or are causally linked.     

Hair Curling Induced in Heterologous Legumes and Monocots by Flavonoid-Treated Rhizobia

The curling of root hairs and the deformation response wereobserved when white clover was infected with homologous strainsof Rhizobium leguminosarum biovar trifolii 4S and 0403. In thecase of Rhizobium meliloti NZ and Rhizobium leguminosarum biovarviciae 128C53, however, curling was only induced when thesebacteria were pretreated with flavonoids: luteolin in the caseof R. meliloti and naringenin for R.I. viciae. The same resultswere obtained with oat, a monocotyledonous non-leguminous plant.The two flavonoids mentioned are secreted from the host plantsand induce the expression of genes for root hair curling (Hac)on Sym plasmid in homologous rhizobia, therefore, the curlingresponse in both white clover and oat appears to be correlatedwith the activation of the Hac genes. These results suggestthat a factor(s) that activates the Hac genes, such as 7,4'-dihydroxyflavonewhich is known as the factor required by R. I. trifolii, issecreted from the oat roots. (Received June 12, 1989; Accepted November 9, 1989)     

Nodules are induced on alfalfa roots by Agrobacterium tumefaciens and Rhizobium trifolii containing small segments of the Rhizobium meliloti nodulation region.

Regions of the Rhizobium meliloti nodulation genes from the symbiotic plasmid were transferred to Agrobacterium tumefaciens and Rhizobium trifolii by conjugation. The A. tumefaciens and R. trifolii transconjugants were unable to elicit curling of alfalfa root hairs, but were able to induce nodule development at a low frequency. These were judged to be genuine nodules on the basis of cytological and developmental criteria. Like genuine alfalfa nodules, the nodules were initiated from divisions of the inner root cortical cells. They developed a distally positioned meristem and several peripheral vascular bundles. An endodermis separated the inner tissues of the nodule from the surrounding cortex. No infection threads were found to penetrate either root hairs or the nodule cells. Bacteria were found only in intercellular spaces. Thus, alfalfa nodules induced by A. tumefaciens and R. trifolii transconjugants carrying small nodulation clones of R. meliloti were completely devoid of intracellular bacteria. When these strains were inoculated onto white clover roots, small nodule-like protrusions developed that, when examined cytologically, were found to more closely resemble roots than nodules. Although the meristem was broadened and lacked a root cap, the protrusions had a central vascular bundle and other rootlike features. Our results suggest that morphogenesis of alfalfa root nodules can be uncoupled from infection thread formation. The genes encoded in the 8.7-kilobase nodulation fragment are sufficient in A. tumefaciens or R. trifolii backgrounds for nodule morphogenesis.     

Simulation of marked root hair curling in Rhizobium-legume symbiosis

The soil bacterium Rhizobium infects its leguminous host plants in temperate regions of the world mostly by way of the growing root hairs. Root hair curling is a prerequisite for root hair infection, although sidelong root hair infections occasionally have been observed. The processes underlying Rhizobium -induced root hair curling are unknown.
Computer simulation of root hair growth indicates that one-sided tip growth inhibition by Rhizobium can result in root hair curling when three conditions are simultaneously fulfilled: 1) rhizobial growth inhibition is strong enough to prevent removal out of the tip growth range: 2) root hair surface growth between the attached Rhizobium and the root hair top is inhibited; 3) rhizobial growth inhibition is limited to one side of the root hair.
The results predict that root hair curling by stimulation of tip growth is improbable. This study accentuates the need for information about the growth processes contributing to tip growth in leguminous root hairs.     

A Structural Comparison of the Acidic Extracellular Polysaccharides from Rhizobium trifolii Mutants Affected in Root Hair Infection

The structures of the acidic extracellular polysaccharides (EPSs) from several R. trifolii mutants were compared by examining their compositions and their sugar linkages as determined by methylation analysis. These mutant strains were derived from the wild-type R. trifolii ANU843 and were unable to induce normal root hair curling (Hac- phenotype) or nodulation response (Nod- phenotype) in clover plants. These strains included several transposon Tn5-induced Nod-mutants, strain ANU871, which possesses a 40 to 50 kilobase deletion of the resident Sym plasmid, and strain ANU845 which is missing the Sym plasmid (pSym-). Strains ANU845(pSym-) containing either plasmid pRt150 or pBR1AN were also used. The recombinant plasmid pRt150 restores only root hair curling capacity to ANU845 while plasmid pBR1AN (an R. trifolii pSym) restores both root hair curling and nodulation capacity to this strain. Our composition and methylation results show that the EPSs from all these strains have the same glycosyl and pyruvyl linkages. Thus we suggest that neither the nod genes involved in root hair curling nor the entire pSym encodes for the arrangement of glycosyl or pyruvyl residues in these EPSs. Whether or not the nod genes dictate the location of acetyl or β-hydroxybutyrate substituent groups remains to be determined.     

Control of nodule number by the phytohormone abscisic Acid in the roots of two leguminous species

The effects of the phytohormone abscisic acid (ABA) on plant growth and root nodule formation were analyzed in Trifolium repense (white clover) and Lotus japonicus, which form indeterminate and determinate nodules, respectively. In T. repense, although the number of nodules formed after inoculation with Rhizobium leguminosarum bv. trifolii strain 4S (wild type) was slightly affected by exogenous ABA, those formed by strain H1(pC4S8), which forms ineffective nodules, were dramatically reduced 28 days after inoculation (DAI). At 14 and 21 DAI, the number of nodules formed with the wild-type strain was decreased by exogenous ABA. In L. japonicus, the number of nodules was also reduced by ABA treatment. Thus, exogenous ABA inhibits root nodule formation after inoculation with rhizobia. Observation of root hair deformation revealed that ABA blocked the step between root hair swelling and curling. When the ABA concentration in plants was decreased by using abamine, a specific inhibitor of 9-cis-epoxycarotenoid dioxygenase, the number of nodules on lateral roots of abamine-treated L. japonicus increased dramatically, indicating that lower-than-normal concentrations of endogenous ABA enhance nodule formation. We hypothesize that the ABA concentration controls the number of root nodules.     

The Rhizobium meliloti host range nodQ gene encodes a protein which shares homology with translation elongation and initiation factors.

The Rhizobium meliloti nod region IIb is involved in host-range determination: (i) the presence of region IIb is necessary for transfer of alfalfa root hair curling ability to Rhizobium leguminosarum biovar trifolii; (ii) a mutation in region IIb extends the R. meliloti infection host range to Vicia sativa nigra; (iii) dominance of R. meliloti nod genes over R. leguminosarum biovar viciae nod genes is abolished by mutations in region IIb. The nucleotide sequence of this region has been determined. Genes corresponding to the two open reading frames identified are designated nodP and nodQ. The predicted amino acid sequence of the NodQ protein shows homology with translation initiation and elongation factors. The consensus sequence involved in the GTP-binding domain is conserved.     

Differential response of soybean (Glycine max (L.) Merr.) genotypes to lipo-chito-oligosaccharide Nod Bj V (C(18:1) MeFuc)

Lipo-chito-oligosaccharides (LCOs) are bacteria-to-plant signal molecules essential for the establishment of rhizobia-legume symbioses. LCOs invoke a number of physiological changes in the host plants, such as root hair deformation, cortical cell division and ontogeny of complete nodule structures. The responses of five soybean cultivars to Nod BJ: V (C(18:1) MeFuc) isolated from Bradyrhizobium japonicum strain 532C were studied with a new technique. Two distinct types of root hair deformation were evident (i) bulging, in which root hairs were swollen at the tip or at the base depending on the cultivars and (ii) curling. The nodulating capacity of B. japonicum 532C varied among cultivars. Cultivars that produced a bulging reaction when treated with LCO had fewer nodules and the roots had low phenol contents. Cultivars that produced curling had higher numbers of nodules and the roots had higher amounts of phenol. Further, the roots of cultivars that showed root hair bulging were able to degrade LCO much faster than cultivars that manifested curling. The results of the present study establish relationships among the type of LCO-induced root hair deformation, root system LCO-degrading ability and nodulation capacity of soybean cultivars.     

Rhizobium meliloti host range nodH gene determines production of an alfalfa-specific extracellular signal.

The Rhizobium meliloti nodH gene is involved in determining host range specificity. By comparison with the wild-type strain, NodH mutants exhibit a change in host specificity. That is, although NodH mutants lose the ability to elicit root hair curling (Hac-), infection threads (Inf-), and nodule meristem formation (Nod-) on the homologous host alfalfa, they gain the ability to be Hac+ Inf+ Nod+ on a nonhomologous host such as common vetch. Using root hair deformation (Had) bioassays on alfalfa and vetch, we have demonstrated that sterile supernatant solutions of R. meliloti cultures, in which the nod genes had been induced by the plant flavone luteolin, contained symbiotic extracellular signals. The wild-type strain produced at least one Had signal active on alfalfa (HadA). The NodH- mutants did not produce this signal but produced at least one factor active on vetch (HadV). Mutants altered in the common nodABC genes produced neither of the Had factors. This result suggests that the nodABC operon determines the production of a common symbiotic factor which is modified by the NodH product into an alfalfa-specific signal. An absolute correlation was observed between the specificity of the symbiotic behavior of rhizobial cells and the Had specificity of their sterile filtrates. This indicates that the R. meliloti nodH gene determines host range by helping to mediate the production of a specific extracellular signal.     

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.     

Identification of a Rhizobium meliloti pSym2011 region controlling the host specificity of root hair curling and nodulation.

In Rhizobium meliloti 2011 nodulation genes (nod) required to nodulate specifically alfalfa are located on a pSym megaplasmid. Nod- derivatives carrying large pSym deletions were isolated. By complementation of these strains with in vivo- and in vitro-constructed episomes containing pSym of sequences and introduction of these episomes into Agrobacterium tumefaciens, we show (i) that from a region of pSym of about 360 kilobases, genes required for specific alfalfa nodulation are clustered in a DNA fragment of less than 30 kilobases and (ii) that a nod region located between nifHDK and the common nod genes is absolutely required for alfalfa nodulation and controls the specificity of root hair curling and nodule organogenesis initiation.     

Transgene behaviour in populations of rice plants transformed using a new dual binary vector system: pGreen/pSoup

Transgene integration, expression level and stability have been studied, across two generations, in a population of rice plants transformed using a new dual binary vector system: pGreen/pSoup. pGreen is a small Ti binary vector unable to replicate in Agrobacterium without the presence of another binary plasmid, pSoup, in the same strain. We engineered both pGreen and pSoup to contain each a different T-DNA. Transformation experiments were conducted using a pGreen vector containing the bar and gusA expression units (no transgene in pSoup) or with a pSoup vector containing an aphIV and gfp expression units (no transgene in pGreen). High plant transformation frequencies (up to 40%) were obtained using herbicide resistance ( bar) or antibiotic resistance ( aphIV) genes. Around 80% of the independently transformed plants expressed unselected reporter genes ( gusA or gfp) present in the vectors. Backbone sequences transfer was frequent (45% of lines) and occurred often in multicopy lines. Around 15-20% of the rice plant lines contained a single T-DNA integration without backbone. Integration of additional transgene copies did not improve expression levels in either T(0) plants or T(1) progenies. Nearly all multicopy lines contained transgenes integrated at several loci in the plant genome, showing that T-DNAs from either pGreen or pSoup frequently integrated at unlinked loci. Precise determination of loci number required the analysis of transgene presence in progeny. Segregation of transgene phenotype was generally misleading and tended to underestimate the real number of transgenic loci. The contribution of this new dual-binary vector system to the development of high-throughput rice transformation systems and to the production of marker-free transgenic rice plants is discussed.