From a pool of Medicago truncatula mutants--obtained by gamma-irradiation or ethyl methanesulfonate mutagenesis--impaired in symbiosis with the N-fixing bacterium Sinorhizobium meliloti, new mutants are described and genetically analysed, and for already reported mutants, complementary data are given on their phenotypic and genetic analysis. Phenotypic data relate to nodulation and mycorrhizal phenotypes. Among the five new mutants, three were classified as [Nod+ Fix- Myc+] and the mutations were ascribed to two loci, Mtsym20 (TRV43, TRV54) and Mtsym21 (TRV49). For the two other new mutants, one was classified as [Nod-/+ Myc+] with a mutation ascribed to gene Mtsym15 (TRV48), and the other as [Nod- Myc-/+] with a mutation ascribed to gene Mtsym16 (TRV58). Genetic analysis of three previously described mutants has shown that [Nod-/+ Myc+] TR74 mutant can be ascribed to gene Mtsym14, and that [Nod-/+ Myc-/+] TR89 and TRV9 mutants are ascribed to gene Mtsym2 (dmi2). Using a detailed analysis of mycorrhizal phenotype, we have observed a delayed typical arbuscular mycorrhizal formation on some mutants that present thick lens-shaped appressoria. This phenotype was called [Myc-/+] and mutants TR25, TR26, TR89, TRV9, P1 and Y6 were reclassified as [Myc-/+]. Mutant P1 was reclassified as [Nod-/+] because of a late nodulation observed on roots of this mutant.
Pisum sativum L. is known for high seed and protein yields but also for yield instability. Because legumes utilize two sources of nitrogen (atmospheric Nz fixed in nodules and assimilation of soil mineral N), studies on their nitrogen nutrition is more complex than in other plants. In this work, pea symbiotic mutants (with no nodules at all ([Nod-]), with inefficient nodules ([Nod+Fix-I) or showing an hypernodulating and a 'nitrate-tolerant symbiosis' character ([Nod++Nts]), their semi-leafless isogenic homologues and the parental control line cv Frisson were fertilized with three levels of mineral nitrogen (0, 25 or 50 g N m -2) to generate a range of mineral nitrogen regimes in the same genetic background. Impact of the source and level of nitrogen nutrition was measured on reproductive development, growth, nitrogen accumulation and seed yield. It was shown that a N deficiency induced flowering termination. It also led to a large decrease in the number of seeds produced and the amount of N accumulated in forage and in seeds, when little effect was observed on the progression rates of reproductive stages along the stem. The single seed weight and the amount of dry matter accumulated in forage neither responded strongly to N deficiency. The source of nitrogen was shown to be of little importance to yield but the application of about 50 g N m 2 was necessary to reach the yield of the control cv Frisson when exclusive assimilation was ensuring the N requirements of the plant. Despite the fact that the nitrate-tolerant and hypernodulating mutant P64 used in this study did not yield as well as the parent cv Frisson, it is proposed that [Nod + +Nts] characters could act as a yield regulating factor.
The pea mutant line P55 is defective in root nodule formation, and this phenotype is controlled by a single recessive gene. Complementation analysis revealed that the mutation in P55 is allelic to sym19, which has previously been mapped to linkage group I. Detailed mapping revealed that the sym19 and ENOD40 loci are separated by 2.7 cM. We identified four recombination events, demonstrating that the nodulation defect caused by mutation of the sym19 locus cannot be due to mutation of ENOD40. RT-PCR experiments showed that P55 expresses ENOD12A, but there was little or no increase in the level of its transcript in response to Nod factor or infection with Rhizobium. To investigate this expression pattern further, transgenic peas carrying a pENOD12A-GUS reporter construct were made. One transgenic line was crossed with line P55, to generate F2 progeny homozygous for sym19 and carrying pENOD12A-GUS. In both WT and sym19 mutant lines, ENOD12A-GUS expression was induced at sites of lateral root emergence in uninoculated plants. In Nod+ plants pENOD12A-GUS was induced in response to Rhizobium leguminosarumn bv. viciae, but no such induction was seen in the Nod- (sym19) mutants.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.