John D. Mahon

Specificity of strain and genotype in the susceptibility of pea to Agrobacterium tumefaciens.

SummaryTo determine the best combination for potential use in transformation of Pisum sativum L., 13 genotypes were inoculated with wild-type Agrobacterium tumefaciens strains A281, C58 and Ach5. A281 appeared to be the most virulent strain, as determined by size and number of tumours, followed by C58 and Ach5. Genotypes differed considerably in their response to inoculation and genotype x strain interaction was evident. Genotypes also responded differently to in vivo or in vitro inoculation. Axenic calli from tumours could be grown on hormone-free medium and the presence of the specific opines for each strain in the callus indicated successful transfer and expression of T-DNA. Southern blot analysis of DNA from callus of A281-inoculated material showed that both TR and TL T-DNA had been incorporated into the pea genome.

Agrobacterium tumefaciens-mediated transformation of chickpea (Cicer arietinum L.): gene integration, expression and inheritance

A reproducible method of Agrobacterium-mediated transformation was developed for Cicer arietinum (chickpea). Initial explants consisted of longitudinal slices from embryonic axes of imbibed, mature seed. The plasmid contained a bi-functional fusion gene conferring both β-glucuronidase and neomycin phosphotransferase activities, under the control of a 35S35SAMV promoter. Using a series of tissue culture media for co-cultivation, shoot initiation and rooting, we recovered transgenic plants from approximately 1.3% of the sliced embryo axes. The addition of a shoot elongation medium to the protocol improved the success rate to 3.1% but increased the time in tissue culture. Inheritance of the gus gene was followed through four generations, both through expression and Southern hybridization assays, and showed the expected Mendelian inheritance pattern.

Genotype- and promoter-induced variability in transient β-glucuronidase expression in pea protoplasts.

SummaryLeaf mesophyll protoplasts isolated from pea (Pisum sativum L.) genotypes Century and PI244253 showed transient expression of β-glucuronidase (GUS) when electroporated with plasmid DNA containing various promoter-leader sequence constructs driving the GUS gene. The optimum conditions for transient expression were: using protoplasts isolated from leaf material that had been kept in the dark for 90 h; electroporating at 250 V and 960 μF; and using 125 μg of calf thymus carrier DNA and 75 μ of plasmid DNA. PI244253 had 5 to 20 times the GUS activity levels of Century. Similar levels of transient expression were obtained using either the nopaline synthase or cauliflower mosaic virus 35S (35S) promoters. These levels were lower than that obtained using a duplicated 35S promoter derivative. The presence of an untranslated coat protein mRNA leader sequence from alfalfa mosaic virus between each promoter and the GUS gene resulted in increased GUS activity. Leaf mesophyll protoplasts and root protoplasts of PI244253 did not differ in levels of transient expression.

Genetic variability in the amount of ribulose-1,5-bisphosphate carboxylase/oxygenase and its small subunit mRNA in pea.

The amount of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco; EC 4.1.1.39) was studied during greening in 12Pisum sativum L. genotypes. The proportion of mRNA coding for the small subunit of Rubisco (SSU mRNA) was also monitored by hybridization with a cDNA (complementary DNA) probe from one of the nuclear genes coding for SSU (rbcS). Both the SSU mRNA and Rubisco (in g·FW)−1) contents rapidly increased in all genotypes on illumination of dark-grown seedlings. Natural genetic variability was found in the amounts of SSU mRNA, Rubisco· (g FW)−1, total RNA·(g FW)−1 and mRNA·(μg total RNA)−1. Differences among genotypes in SSU mRNA were apparently the result of differences in the rate of light-induced accumulation of therbcS gene transcripts. Genotype means for SSU mRNA and Rubisco· (g FW)−1 amounts during greening were significantly correlated (r=0.788;P<0.01). This indicates a relationship between genetic differences in the rate of light-induced accumulation of therbcS gene transcripts and the Rubisco amount, and establishes a link between natural genetic variability at the molecular and the physiological levels. Genotypic variability in SSU mRNA during greening was also positively correlated to the Rubisco content per unit leaf area in fully greened leaves. Although Southern-blot analysis indicated that there was also natural genetic variability in the copy number of therbcS genes, this difference in copy number could not account for the differences in SSU mRNA production.

Effects of the Overexpression of a Soybean Cytosolic Glutamine Synthetase Gene (GS15) Linked to Organ-Specific Promoters on Growth and Nitrogen Accumulation of Pea Plants

A soybean cytosolic glutamine synthetase gene (GS15) fused to a constitutive promoter (CaMV 35S), a putative nodule-specific promoter (LBC(3)), or a putative root-specific promoter (rolD) was transformed into Pisum sativum L. cv. Greenfeast. Four lines with single copies (Lines 1, 7, 8 and 9) and four lines with two copies each of GS15 (Lines 2, 4, 6 and 11) were compared to the wild-type (WT) parental line for levels of cytosolic glutamine synthetase (GS1), glutamine synthetase (GS) activity, N accumulation, N derived form the atmosphere (NDFA), and biomass of plants grown on 0.0, 0.1, 1.0 or 10.0 mM NH(4)(+). Enhanced levels of GS1 were detected in leaves of one of the two lines transformed with the 35S-GS15 construct, and all three lines containing the rolD-GS15 construct. All three lines containing the LBC(3)-GS15 construct had increased levels of GS1 in nodules. Despite the increased levels of GS1 in many transformants, only the roots of lines containing the rolD-GS15 construct consistently demonstrated enhanced levels of GS activity (up to 12-fold). Positive responses in plant N content, NDFA, and biomass were rare, but increases in plant biomass and N content of up to 17% and 54%, respectively, occurred in some of the rolD-GS15 lines at certain levels of ammonium. In general, GS15 copy number did not seem to differentially affect phenotype of the transformants, and transformants respond to ammonium concentrations in similar patterns to that previously observed with nitrate. Despite the fact that the rolD-GS15 transformants consistently resulted in increased GS activity in roots and resulted in some occurrences of increases in biomass and plant N content, the lack of consistent positive growth effect across all transformants indicates that the generalized overexpression of GS1 in tissues holds little potential for positive growth responses in pea.

Genetic Control of Photosynthesis in Relation to Growth of Pea (Pisum sativum L.) Plants

The genetic improvement of photosynthesis has often been proposed as a route to increased crop productivity. However, although there is extensive genotypic variability in photosynthesis per unit of leaf area or leaf weight in many crop species, the exploitation of this variability remains difficult. Not only is photosynthesis very sensitive to environmental factors, but there are reports of considerable genotype by environment and genotype by developmental stage interactions. Under such conditions, selection progress would be difficult and large numbers of measurements would be needed to assess phenotypic expression.