INVESTIGADORES
SELVA juan pablo
congresos y reuniones científicas
Título:
Novel genotypes of the subtropical grass Eragrostis curvula for the analysis of apomixis (diplospory)
Autor/es:
SUSANA CARDONE; PABLO POLCI; JUAN P. SELVA; MARTÍN A. MECCHIA; SILVINA PESSINO; PAUL W. VOIGT; GERMÁN SPANGENBERG; VIVIANA ECHENIQUE
Lugar:
Aberystwyth, Gales
Reunión:
Congreso; XX th Iinternational Grassland Congres; 2005
Resumen:
Introduction Eragrostis curvula (Schrad.) Nees is a variable grass native to Southern Africa. Its several forms, known as lovegrasses, were introduced to Australia, USA and Argentina as forage perennial grasses. Apomixis is a common trait in the genus Eragrostis, with diplospory being the most frequent type. Sexual reproduction does also occur in Eragrostis, though not frequently. Since most tetraploid Eragrostis lines are apomictic, the generation of a sexual tetraploid strain is a requirement for linkage analysis of the gene(s) governing the apomictic character. Furthermore, isogenic lines of the same ploidy reproducing alternatively by sexuality or apomixis represent an ideal system for comparative transcriptome analysis. The aim of this work was the generation and characterization of two novel genotypes of E. curvula: a dihaploid strain obtained in vitro from an apomictic cultivar and a tetraploid plant derived from the dihaploid after chromosome duplication.   Materials and methods Plants were obtained by in vitro culture of immature inflorescences of the apomictic E. curvula cultivar Tanganyka (2n = 4x = 40) on Murashige and Skoog medium supplemented with 2,4-D and BAP. Morphological and phenological traits of the regenerated plants and the original tetraploid cultivar were comparatively assessed. Chromosome number was determined in root tips by Feulgen staining. The reproductive mode was assessed by the study of megasporogenesis and embryo sac development and by the evaluation of progeny plants using RAPD amplification. Duplication of chromosome number of the dihaploid plant was done by 0.05% colchicine treatment. Progeny tests were performed by RAPD amplification on 8 individuals originated by open pollination from the dihaploid plant.   Results One out of 23 regenerated plants showed 20 chromosomes in root tip cells instead of the normal 40 chromosome count for the original tetraploid cultivar. This plant  (named UNST1122) showed wider and shorter leaves than those of the other regenerated plants and the original cultivar, being also taller than these materials. Other unusual characteristics of this plant are a typical pubescence on the base of the adaxial surface of leaves, a clear tendency to produce aerial tillers, a very small ligula (0.2 mm) and panicles exhibiting variation in shape and size, with rachillas radially arranged forming an angle of approximately 90° with the rachis. Anthers are pale yellow and seeds are ellipsoidal with a light brown coat, smaller and lighter than those produced by control plants (weight of 100 seeds: 23 mgs vs 40 mgs). Under greenhouse conditions, UNST1122 flowers almost all year round, except in the colder months of June and July (Southern hemisphere). However, the number of seeds per inflorescence is lower than that of the original cultivar. Studies of megasporogenesis and megagametophyte development as well as progeny tests using RAPD amplification showed that this dihaploid plant is sexual and self-incompatible. Colchicine treatment of seeds from the dihaploid gave raise to two plants with 40 chromosomes, UNST1112 and UNST1131. Comparison of the amplification profiles obtained for UNST1122 with those of 8 progeny individuals obtained by open pollination revealed polymorphism that ranged from 4.6% to 40% for all analyzed plants. The lack of offspring showing a maternal profile is an evidence of sexual reproduction in UNST1112.   Conclusions The molecular basis underlying mechanisms of diplosporous reproduction remains largely unknown. The novel genotypes described here will allow the future establishment of mapping populations of Eragrostis curvula that can be used in strategies of forward genetics to map and positionally clone the determinants of the apomictic trait. They also represent an excellent system for the identification of genes involved in diplospory and/or ploidy level gene regulation by using transcriptional profiling techniques such as differential display, cDNA-AFLP or ESTs discovery.