Tn5 mutagenesis of Rhizobium trifolii host-specific nodulation genes result in mutants with altered host-range ability

Summary A 14 kb DNA fragment from the Sym plasmid of the Rhizobium trifolii strain ANU843, known to carry common nodulation nod and host specific nodulation hsn genes, was extensively mutagenised with transposon Tn5. A correlation between the site of Tn5 insertion and the induced nodulation defect led to the identification of three specific regions (designated I, II, III) which affected nodulation ability. Twenty-three Tn5 insertions into region I (ca. 3.5 kb) affected normal root hair curling ability and abolished infection thread formation. The resulting mutants were unable to nodulate all tested plant species. Tn5 insertions in regions II and III resulted in mutants which showed an exaggerated root hair curling (Hac⁺⁺) response on clover plants. Ten region II mutants which occurred over a 1.1 kb area showed a greatly reduced nodulation ability on clovers and produced aborted, truncated infection threads. Tn5 insertions into region III (ca. 1.5 kb) altered the outcome of crucial early plant recognition and infection steps by R. trifolii. Seven region III mutants displayed host-range properties which differed from the original parent strain. Region III mutants were able to induce marked root hair distortions, infection threads, and nodules on Pisum sativum including the recalcitrant Afghanistan variety. In addition region III mutants showed a poor nodulation ability on Trifolium repens even though the ability to induce infection threads was retained on this host. The altered host-range properties of region III mutants could only be revealed by mutation and the mutant phenotype was shown to be recessive.     

Occurrence of lipopolysaccharide alterations among Tn5 mutants of Rhizobium leguminosarum bv. trifolii strain 24.1 with altered colony morphology.

Transposon mutants of Rhizobium leguminosarum bv. trifolii 24.1 showing less glossy or smaller colonies were screened for properties usually associated with lipopolysaccharide (LPS) defects in R. leguminosarum, i.e. motility, growth rate, tendency to agglutination in liquid media and symbiotic efficiency. Neither any of the above mutants nor the earlier isolated 24.12 strain, defective in LPS, showed all these properties changed simultaneously. According to PAGE/sodium deoxycholate analysis the mutant 24.12 was the only one producing defective lipopolysaccharide. GC-MS analysis revealed in this mutant qualitative changes in composition of its LPS in comparison with LPS isolated from the parent strain. Other Tn5 mutants produced LPSs similar in composition, however the proportion between LPS I and LPS II differed from that in the parent strain.     

Characterization of the Rhizobium leguminosarum genes nodLMN involved in efficient host-specific nodulation

Three nodulation genes, nodL, nodM and nodN, were isolated from Rhizobium leguminosarum and their DNA sequences were determined. The three genes are in the same orientation as the previously described nodFE genes and the predicted molecular weights of their products are 20,105 (nodL), 65,795 (nodM) and 18,031 (nodN). Analysis of gene regulation using operon fusions showed that nodL, nodM and nodN are induced in response to flavanone molecules and that this induction is nodD-dependent. In addition, it was shown that the nodM and nodN genes are in one operon which is preceded by a conserved 'nod-box' sequence, whereas the nodL gene is in the same operon as the nodFE genes. DNA hybridizations using specific gene probes showed that strongly homologous genes are present in Rhizobium trifolii but not Rhizobium meliloti or Bradyrhizobium japonicum. A mutation within nodL strongly reduced nodulation of peas, Lens and Lathyrus but had little effect on nodulation of Vicia species. A slight reduction in nodulation of Vicia hirsuta was observed with strains carrying mutations in nodM or nodN.     

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     

Transposon Tn5-induced mutagenesis of Rhizobium japonicum yielding a wide variety of mutants

When the "suicide" vector pSUP1011, which carries transposon Tn5 (Kmr), was introduced into Rhizobium japonicum USDA 110, kanamycin-resistant (Kmr) colonies were detected at a frequency (4.2 X 10-6) ca. 30 times greater than the spontaneous kanamycin resistance frequency (1.4 X 10-7). Ten thousand Kmr mutants were isolated and tested for nutritional auxotrophy. Auxotrophs were detected at a frequency of 0.5%. The following classes of auxotrophs were identified: adenine- (three), histidine- (three), glutamate- (five), adenine plus thiamine- (nine), uracil- (three), pantothenic acid- (one), tryptophan- (three), and methionine- (three). Mutants blocked in symbiotic nitrogen fixation (Fix-) were also identified at a frequency of 3%. The glutamate auxotrophs were studied in more detail, and all five showed an altered expression of nitrogenase activity in free-living cultures.     

Rhizobium phaseoli symbiotic mutants with transposon Tn5 insertions.

Rhizobium phaseoli CFN42 DNA was mutated by random insertion of Tn5 from suicide plasmid pJB4JI to obtain independently arising strains that were defective in symbiosis with Phaseolus vulgaris but grew normally outside the plant. When these mutants were incubated with the plant, one did not initiate visible nodule tissue (Nod-), seven led to slow nodule development (Ndv), and two led to superficially normal early nodule development but lacked symbiotic nitrogenase activity (Sna-). The Nod- mutant lacked the large transmissible indigenous plasmid pCFN42d that has homology to Klebsiella pneumoniae nitrogenase (nif) genes. The other mutants had normal plasmid content. In the two Sna- mutants and one Ndv mutant, Tn5 had inserted into plasmid pCFN42d outside the region of nif homology. The insertions of the other Ndv mutants were apparently in the chromosome. They were not in plasmids detected on agarose gels, and, in contrast to insertions on indigenous plasmids, they were transmitted in crosses to wild-type strain CFN42 at the same frequency as auxotrophic markers and with the same enhancement of transmission by conjugation plasmid R68.45. In these Ndv mutants the Tn5 insertions were the same as or very closely linked to mutations causing the Ndv phenotype. However, in two mutants with Tn5 insertions on plasmid pCFN42d, an additional mutation on the same plasmid, rather than Tn5, was responsible for the Sna- or Ndv phenotype. When plasmid pJB4JI was transferred to two other R. phaseoli strains, analysis of symbiotic mutants was complicated by Tn5-containing deleted forms of pJB4JI that were stably maintained.     

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.     

Expression of Rhizobium trifolii early nodulation genes on maize and rice plants.

An IncQ multicopy vector (pKT230) and an IncP1 low-copy-number vector (pRK290), both carrying Rhizobium trifolii root hair curling (Hac) genes, were transferred to a Sym plasmid-cured derivative of R. trifolii ANU843. The resulting transconjugants were used to inoculate the monocotyledonous plants sorghum, maize, rice, and wheat. Transconjugants carrying the Hac genes on the multicopy vector caused a root hair curling response on maize and rice plants 14 days after inoculation.     

Rhizobium trifolii mutants deficient in exopolysaccharide production

Spontaneous mutants of Rhizobium trifolii 24AR5 which did not produce exopoly-saccharide were isolated. The non-mucoid mutants formed small white and ineffective nodules on both red and white clover. These nodules contained infection threads, but only a small number of bacteria were released into nodule cells, and bacteroids were rarely observed. The non-mucoid phenotype was not complemented by the symbiotic plasmid (pJB5JI) of Rhizobium leguminosarum.     

Transfer of Rhizobium meliloti pSym genes into Agrobacterium tumefaciens: host-specific nodulation by atypical infection

The pSym megaplasmid of Rhizobium meliloti 2011 mobilized by plasmid RP4, or plasmid pGMI42, an RP4-prime derivative which carries a 290-kilobase pSym fragment including nitrogenase and nod genes, was introduced into Agrobacterium tumefaciens. The resulting transconjugants induced root deformations specifically on the homologous hosts Medicago sativa and Melilotus alba and not on the heterologous hosts Trifolium pratense and Trifolium repens. The root deformations were shown to be genuine nodules by physiological and cytological studies. Thus, host specificity nodulation genes are located on the pSym megaplasmid. Host nodulation specificity did not seem to require recognition at the root hair level since no infection threads could be detected in the root hairs. Cytological observations indicated that bacteria penetrated only the superficial layers of the host root tissue by an atypical infection process. The submeristematic zone and the central tissue of the nodules were bacteria free. Thus, nodule organogenesis was probably triggered from a distance by the bacteria. Agrobacterium transconjugants carrying pSym induced the formation of more numerous and larger nodules than those carrying the RP4-prime plasmid pGMI42, suggesting that some genes influencing nodule organogenesis are located in a pSym region(s) outside that which has been cloned into pGMI42.     

Identification of a Rhizobium trifolii plasmid coding for nitrogen fixation and nodulation genes and its interaction with pJB5JI, a Rhizobium leguminosarum plasmid

Rhizobium trifolii T37 contains at least three plasmids with sizes of greater than 250 megadaltons. Southern blots of agarose gels of these plasmids probed with Rhizobium meliloti nif DNA indicated that the smallest plasmid, pRtT37a, contains the nif genes. Transfer of the Rhizobium leguminosarum plasmid pJB5JI, which codes for pea nodulation and the nif genes and is genetically marked with Tn5, into R. trifolii T37 generated transconjugants containing a variety of plasmid profiles. The plasmid profiles and symbiotic properties of all of the transconjugants were stably maintained even after reisolation from nodules. The transconjugant strains were placed into three groups based on their plasmid profiles and symbiotic properties. The first group harbored a plasmid similar in size to pJB5JI (130 megadaltons) and lacked a plasmid corresponding to pRtT37a. These strains formed effective nodules on peas but were unable to nodulate clover and lacked the R. trifolii nif genes. This suggests that genes essential for clover nodulation as well as the R. trifolii nif genes are located on pRtT37a and have been deleted. The second group harbored hybrid plasmids formed from pRtT37a and pJB5JI which ranged in size from 140 to ca. 250 megadaltons. These transconjugants had lost the R. leguminosarum nif genes but retained the R. trifolii nif genes. Strains in this group nodulated both peas and clover but formed effective nodules only on clover. The third group of transconjugants contained a hybrid plasmid similar in size to pRtT37b. These strains contained the R. trifolii and R. leguminosarum nif genes and formed N2-fixing nodules on both peas and clover.     

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.     

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

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