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    DNA homology within the Rhizobiaceae : a thesis presented in partial fulfilment of the requirements for the degree of Master of Science in Microbiology at Massey University
    (Massey University, 1984) Wedlock, David Neil
    The relationship of rhizobia that nodulate Galega officinalis to the known species of Rhizobium and Bradyrhizobium was investigated. Similarly, the recently discovered fast­ growing soybean nodulating group of rhizobia was studied. Both groups were investigated using DNA:DNA hybridization as well as nodulation on legumes and phage-typing. The Galega nodulating rhizobia were found to form a distinct DNA homology group. The mean relative homology of 11 strains of Galega nodulating rhizobia with the reference strains gal 1 and gal NW 3, which effectively nodulate Galega officinalis, was significantly higher than the mean relative homology of other groups of rhizobia. The Galega rhizobia only nodulated Galega officinalis and formed a distinct phage-typing group in agreement with the DNA homology results. These rhizobia therefore appear to form a unique taxonomic group within the genus Rhizobium. The fast-growing soybean nodulating rhizobia formed a distinct DNA homology group with at least two subgroups. The mean relative homology of 11 of these strains with the reference strains USDA 208 and USDA 191 which nodulate Glycine max, was significantly higher than the mean relative homology of other groups of rhizobia. Low DNA homologies were found between the fast-growing soybean strains and Bradyrhizobium japonicum ATCC 10324. The fast-growing soybean nodulating rhizobia nodulated glycine max and formed ineffective nodules on Lotus pedunculatus. None of these strains were lysed by the bacteriophages used in the study, but as yet, no bacteriophage specific for this group of rhizobia has been isolated. The fast­ growing soybean nodulating rhizobia were concluded to be taxonomically distinct from other species of Rhizobium. The thermal stability of reassociated DNA duplexes was examined for both the Galega and fast-growing soybean rhizobia and further indicated the uniqueness of both groups. The use of colony hybridization as a means of identifying different strains of Rhizoiium was investigated and was found to be useful in distinguishing between genetically distinct rhizobia and to identify rhizobia within root nodules.
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    A molecular and genetical analysis of symbiotic genes in Lotus rhizobia : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Microbiology at Massey University, Palmerston North, New Zealand
    (Massey University, 1984) Chua, Kaw-Yan
    Relative DNA homologies were determined among 24 strains of fast-growing rhizobia and 26 strains of slow-growing rhizobia with particular reference to those which nodulate Lotus species. Two major DNA homology groups were identified which shared less than 10% relative DNA homology. Fast-growing Lotus rhizobia were grouped with related fast-growing strains in DNA homology group I, and these strains are designated as Rhizobium loti. Slow-growing strains from Lotus, (Bradyrhizobium spp. (Lotus)), Glycine max (Bradyrhizobium japonicum), Ornithopus and Lupinus formed DNA homology group II which was further divided into 4 DNA homology subgroups. Bradyrhizobium spp. (Lotus) were shown to be genetically distinct from B. japonicum. Plasmid profiles were determined for strains of R. loti and Bradyrhizobium spp. (Lotus). All R. loti strains contained a single large indigenous plasmid, whereas strains from Bradyrhizobium spp. (Lotus) carried multiple plasmids of molecular weights ranging from 130-280 MDal. A plasmid-cured derivative of R. loti NZP2213 was isolated and found to still form effective nodules on Lotus tenuis, suggesting that nodulation and nitrogen fixation genes are not plasmid-borne in this strain. The functions of the indigenous plasmids carried in Lotus rhizobia are unknown. Symbiotic mutants of R. loti strain NZP2037 were isolated by random Tn5-mutagenesis. Mutants included strains blocked in root hair curling (Hac), nodule initiation (Noi), bacterial release (Bar) and nitrogen fixation (Cof) on Lotus pedunculatus. The nodulation (nod) gene region from R. loti strain NZP2037 was isolated from a pLAFR1-NZP2037 gene library using the cloned Tn5 containing EcoRI fragment from the Nod¯ mutant as a probe. Two cosmids were isolated and were found to complement the NZP2037 Nod¯ mutant. Hybridisation and complementation experiments confirmed that a 7.1 kb EcoRI fragment present in both nod cosmids carried gene sequences involved in nodulation. An EcoRI and Hind III restriction enzyme map of the nod gene region in R. loti NZP2037 was constructed using nod cosmids pPN305 and pPN306. Using the cloned R. loti NZP2037 nod gene region (7.1 kb EcoRI fragment from pPN305) as a hybridisation probe, highly conserved DNA sequences from other strains of R. loti and Bradyrhizobium spp. (Lotus) were identified. The nod gene region from Bradyrhizobium spp. (Lotus) strain NZP2309 was isolated by direct 'in planta' complementation of the R. loti Nod¯ mutant using a NZP2309 pLAFR1 gene library. Comparative physical and genetical studies showed that the R. loti NZP2037 nod gene region isolated shared functional similarities with previously isolated nod gene regions from R. trifolii and R. meliloti despite the fact that only weak DNA homology was observed between the corresponding regions. This suggested that at least some of the nod gene sequences carried on the cloned R. loti nod gene region belong to the highly conserved 'common' nod gene sequence category.