Systematics, Specificity, and Ecology of New Zealand Rhizobia

Weir, Bevan

January 2006

This research investigated the rhizobia that are associated with New Zealand legume plants. Rhizobia are a diverse group of bacteria that live in symbiosis with legumes in root nodules. Rhizobia fix Nitrogen from the atmosphere and provide this nutrient to the plant. The objectives of this research were to: 1) Determine the identity of the rhizobial species nodulating the native legumes of New Zealand: Sophora (kowhai), Carmichaelia (NZ broom), and Clianthus (kakabeak); and the identity and origin of rhizobial species nodulating invasive exotic legumes in New Zealand: Ulex (gorse), Cytisus (broom), and Acacia (wattles). 2) Determine the specificity and nitrogen fixing capacity of both groups of rhizobia. 3) Investigate the possible exchange of transmissible symbiotic genetic elements. A polyphasic strategy was used to determine the identity of bacterial isolates. The 16S rRNA, atpD, recA, and glnII genes were PCR amplified and sequenced, then analysed by maximum likelihood and Bayesian methods. Phenotypic characters were also assessed by use of the Biolog and FAME techniques. Nodulation and fixation ability was assessed by inoculating legume seedlings with rhizobial strains, then determining nitrogenase activity after ten weeks by gas chromatography, and examining roots for nodules. A gene involved in symbiosis, nodA, was sequenced from rhizobial strains to determine if transmission between strains had occurred. The results of the experiments showed that the native legumes were predominately nodulated by diverse Mesorhizobium spp. that contain three different nodA genotypes (two of which are novel) that have transferred between rhizobial strains. The Mesorhizobium spp. showed little nodulation specificity and could nodulate an exotic legume Astragalus (milk vetch), but not the invasive weed legumes. Rhizobium leguminosarum was also found to nodulate native legumes, albeit ineffectively. The exotic invasive woody legumes of this study were nodulated by diverse Bradyrhizobium spp. that had nodA genotypes typical of Australian and European species. The origins of these bacteria can not be categorically determined. However the evidence is presented to suggest that nodulating Mesorhizobium spp. arrived with the ancestors of the native legumes, while Bradyrhizobium spp. nodulating Ulex and Cytisus arrived recently from Europe. Bradyrhizobium spp. nodulating Acacia may be recently introduced, possibly from Australia, although further work is required to confirm these hypotheses. / This study was supported by a grant from the Marsden Fund of the Royal Society of New Zealand, under contract 97-LAN-LFS-002, and a grant from the Non-Specific Output Fund of Landcare Research.

rhizobia

native legumes

microbiology

mesorhizobium

bradyrhizobium

kowhai

sophora

rhizobium

Systematics, Specificity, and Ecology of New Zealand Rhizobia

Weir, Bevan

January 2006

This research investigated the rhizobia that are associated with New Zealand legume plants. Rhizobia are a diverse group of bacteria that live in symbiosis with legumes in root nodules. Rhizobia fix Nitrogen from the atmosphere and provide this nutrient to the plant. The objectives of this research were to: 1) Determine the identity of the rhizobial species nodulating the native legumes of New Zealand: Sophora (kowhai), Carmichaelia (NZ broom), and Clianthus (kakabeak); and the identity and origin of rhizobial species nodulating invasive exotic legumes in New Zealand: Ulex (gorse), Cytisus (broom), and Acacia (wattles). 2) Determine the specificity and nitrogen fixing capacity of both groups of rhizobia. 3) Investigate the possible exchange of transmissible symbiotic genetic elements. A polyphasic strategy was used to determine the identity of bacterial isolates. The 16S rRNA, atpD, recA, and glnII genes were PCR amplified and sequenced, then analysed by maximum likelihood and Bayesian methods. Phenotypic characters were also assessed by use of the Biolog and FAME techniques. Nodulation and fixation ability was assessed by inoculating legume seedlings with rhizobial strains, then determining nitrogenase activity after ten weeks by gas chromatography, and examining roots for nodules. A gene involved in symbiosis, nodA, was sequenced from rhizobial strains to determine if transmission between strains had occurred. The results of the experiments showed that the native legumes were predominately nodulated by diverse Mesorhizobium spp. that contain three different nodA genotypes (two of which are novel) that have transferred between rhizobial strains. The Mesorhizobium spp. showed little nodulation specificity and could nodulate an exotic legume Astragalus (milk vetch), but not the invasive weed legumes. Rhizobium leguminosarum was also found to nodulate native legumes, albeit ineffectively. The exotic invasive woody legumes of this study were nodulated by diverse Bradyrhizobium spp. that had nodA genotypes typical of Australian and European species. The origins of these bacteria can not be categorically determined. However the evidence is presented to suggest that nodulating Mesorhizobium spp. arrived with the ancestors of the native legumes, while Bradyrhizobium spp. nodulating Ulex and Cytisus arrived recently from Europe. Bradyrhizobium spp. nodulating Acacia may be recently introduced, possibly from Australia, although further work is required to confirm these hypotheses. / This study was supported by a grant from the Marsden Fund of the Royal Society of New Zealand, under contract 97-LAN-LFS-002, and a grant from the Non-Specific Output Fund of Landcare Research.

rhizobia

native legumes

microbiology

mesorhizobium

bradyrhizobium

kowhai

sophora

rhizobium

Genetic diversity and flowering in Clianthus and New Zealand Sophora (Fabaceae) : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Plant Molecular Biology at Massey University, Palmerston North, New Zealand

Song, Jiancheng

January 2005

Clianthus and New Zealand Sophora species are woody legumes endemic to New Zealand, with high ornamental value and biodiversity significance. Research was conducted to address the fact that little is known about the details of their developmental characteristics, genetic structure and relatedness of the wild populations, and their molecular mechanism of flowering. Genetic diversity and relatedness of all remaining wild populations of Clianthus and samples of all New Zealand Sophora species were investigated using ISSR and AFLP markers. Genetic relationships were established for Sophora species, Clianthus wild populations and cultivars, and most individuals in each of the wild Clianthus populations. The molecular evidence did not support the recent separation on morphological grounds of the two Clianthus species, C. maximus and C. puniceus. Postharvest treatments were tested to extend vase life of the short-lived cut Clianthus maximus and Sophora tetraptera flowers. Appropriately treated Clianthus cut flowers lasted 10-12 days in the vase, with over 80% of flowers opening. Similar postharvest treatments did not improve the vase performance of cut Sophora flowers. Detailed calendars of vegetative and reproductive growth, and of floral ontogeny were developed for Clianthus and Sophora. Contrasting behaviours of both vegetative and reproductive growth were observed between these two legumes. A long period of summer-autumn dormancy of vegetative and reproductive growth in Sophora, and mass abortion of initiated Clianthus inflorescences during most of the year were observed. Unusual floral ontogeny processes, with precocious carpel initiation and delayed petal development, were observed in both species. An efficient two-step quantitative real-time RT-PCR protocol for detailed gene expression analysis of large numbers of samples was developed using SYBR Green DNA dye and a LightCycler instrument. The consistency of this protocol was optimised with regards to sample and template preparation, primer design, and determination of appropriate internal controls for gene expression quantification. Differences of gene expression in the range of 5-7 orders were effectively detected. Putative partial homologues of LEAFY, APETALAI, PISTILLATA, and AGAMOUS were isolated from both Clianthus and Sophora. Detailed temporal and spatial expression of each floral identity gene was investigated using quantitative real-time RT-PCR. The expression patterns, together with the sequence similarity, showed that these new isolated gene fragments were most probably LEAFY, APETALAI, PISTILLATA, and AGAMOUS homologues in Clianthus and Sophora, and that the ABC model of floral development is generally applicable to both species. However, there were important variations in temporal expression patterns compared to those of herbaceous species. A bimodal expression pattern of LEAFY and APETALAI homologues was observed in Sophora, but not in Clianthus, coincident with their contrasting patterns of floral initiation and development.

Kakabeak

Kowhai

Systematics, Specificity, and Ecology of New Zealand Rhizobia

Weir, Bevan

January 2006

This research investigated the rhizobia that are associated with New Zealand legume plants. Rhizobia are a diverse group of bacteria that live in symbiosis with legumes in root nodules. Rhizobia fix Nitrogen from the atmosphere and provide this nutrient to the plant. The objectives of this research were to: 1) Determine the identity of the rhizobial species nodulating the native legumes of New Zealand: Sophora (kowhai), Carmichaelia (NZ broom), and Clianthus (kakabeak); and the identity and origin of rhizobial species nodulating invasive exotic legumes in New Zealand: Ulex (gorse), Cytisus (broom), and Acacia (wattles). 2) Determine the specificity and nitrogen fixing capacity of both groups of rhizobia. 3) Investigate the possible exchange of transmissible symbiotic genetic elements. A polyphasic strategy was used to determine the identity of bacterial isolates. The 16S rRNA, atpD, recA, and glnII genes were PCR amplified and sequenced, then analysed by maximum likelihood and Bayesian methods. Phenotypic characters were also assessed by use of the Biolog and FAME techniques. Nodulation and fixation ability was assessed by inoculating legume seedlings with rhizobial strains, then determining nitrogenase activity after ten weeks by gas chromatography, and examining roots for nodules. A gene involved in symbiosis, nodA, was sequenced from rhizobial strains to determine if transmission between strains had occurred. The results of the experiments showed that the native legumes were predominately nodulated by diverse Mesorhizobium spp. that contain three different nodA genotypes (two of which are novel) that have transferred between rhizobial strains. The Mesorhizobium spp. showed little nodulation specificity and could nodulate an exotic legume Astragalus (milk vetch), but not the invasive weed legumes. Rhizobium leguminosarum was also found to nodulate native legumes, albeit ineffectively. The exotic invasive woody legumes of this study were nodulated by diverse Bradyrhizobium spp. that had nodA genotypes typical of Australian and European species. The origins of these bacteria can not be categorically determined. However the evidence is presented to suggest that nodulating Mesorhizobium spp. arrived with the ancestors of the native legumes, while Bradyrhizobium spp. nodulating Ulex and Cytisus arrived recently from Europe. Bradyrhizobium spp. nodulating Acacia may be recently introduced, possibly from Australia, although further work is required to confirm these hypotheses. / This study was supported by a grant from the Marsden Fund of the Royal Society of New Zealand, under contract 97-LAN-LFS-002, and a grant from the Non-Specific Output Fund of Landcare Research.

rhizobia

native legumes

microbiology

mesorhizobium

bradyrhizobium

kowhai

sophora

rhizobium

Systematics, Specificity, and Ecology of New Zealand Rhizobia

Weir, Bevan

January 2006

This research investigated the rhizobia that are associated with New Zealand legume plants. Rhizobia are a diverse group of bacteria that live in symbiosis with legumes in root nodules. Rhizobia fix Nitrogen from the atmosphere and provide this nutrient to the plant. The objectives of this research were to: 1) Determine the identity of the rhizobial species nodulating the native legumes of New Zealand: Sophora (kowhai), Carmichaelia (NZ broom), and Clianthus (kakabeak); and the identity and origin of rhizobial species nodulating invasive exotic legumes in New Zealand: Ulex (gorse), Cytisus (broom), and Acacia (wattles). 2) Determine the specificity and nitrogen fixing capacity of both groups of rhizobia. 3) Investigate the possible exchange of transmissible symbiotic genetic elements. A polyphasic strategy was used to determine the identity of bacterial isolates. The 16S rRNA, atpD, recA, and glnII genes were PCR amplified and sequenced, then analysed by maximum likelihood and Bayesian methods. Phenotypic characters were also assessed by use of the Biolog and FAME techniques. Nodulation and fixation ability was assessed by inoculating legume seedlings with rhizobial strains, then determining nitrogenase activity after ten weeks by gas chromatography, and examining roots for nodules. A gene involved in symbiosis, nodA, was sequenced from rhizobial strains to determine if transmission between strains had occurred. The results of the experiments showed that the native legumes were predominately nodulated by diverse Mesorhizobium spp. that contain three different nodA genotypes (two of which are novel) that have transferred between rhizobial strains. The Mesorhizobium spp. showed little nodulation specificity and could nodulate an exotic legume Astragalus (milk vetch), but not the invasive weed legumes. Rhizobium leguminosarum was also found to nodulate native legumes, albeit ineffectively. The exotic invasive woody legumes of this study were nodulated by diverse Bradyrhizobium spp. that had nodA genotypes typical of Australian and European species. The origins of these bacteria can not be categorically determined. However the evidence is presented to suggest that nodulating Mesorhizobium spp. arrived with the ancestors of the native legumes, while Bradyrhizobium spp. nodulating Ulex and Cytisus arrived recently from Europe. Bradyrhizobium spp. nodulating Acacia may be recently introduced, possibly from Australia, although further work is required to confirm these hypotheses. / This study was supported by a grant from the Marsden Fund of the Royal Society of New Zealand, under contract 97-LAN-LFS-002, and a grant from the Non-Specific Output Fund of Landcare Research.

rhizobia

native legumes

microbiology

mesorhizobium

bradyrhizobium

kowhai

sophora

rhizobium