Tatiana Alejandra Vega scite author profile

Apomixis is a route of asexual reproduction through seeds, that progresses in the absence of meiosis and fertilization to generate maternal clonal progenies. Gametophytic apomicts are usually polyploid and probably arose from sexual ancestors through a limited number of mutations in the female reproductive pathway. A differential display analysis was carried out on immature inflorescences of sexual and apomictic tetraploid genotypes of Paspalum notatum, in order to identify genes associated with the emergence of apospory. Analysis of approximately 10,000 transcripts led to the identification of 94 high-quality differentially expressed sequences. Assembling analysis, plus validation, rendered 65 candidate unigenes, organized as 14 contigs and 51 singletons. Thirty-four unigenes were isolated from apomictic plants and 31 from sexual ones. A total of 45 (69.2%) unigenes were functionally categorized. While several of the differentially expressed sequences appeared to be components of an extracellular receptor kinase (ERK) signal transduction cascade, others seemed to participate in a variety of central cellular processes like cell-cycle control, protein turnover, intercellular signalling, transposon activity, transcriptional regulation and endoplasmic reticulum-mediated biosynthesis. In silico mapping revealed that a particular group of five genes silenced in apomictic plants clustered in a rice genomic area syntenic with the region governing apospory in Paspalum notatum and Brachiaria brizantha. Two of these genes mapped within the set of apo-homologues in P. notatum. Four genes previously reported to be controlled by ploidy were identified among those expressed differentially between apomictic and sexual plants. In situ hybridization experiments were performed for selected clones.

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Differential expression of acetohydroxyacid synthase genes in sunflower plantlets and its response to imazapyr herbicide

Breccia

Vega

Felitti

et al. 2013

Plant Science

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Contribution of non-target-site resistance in imidazolinone-resistant Imisun sunflower

et al. 2017

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The first commercial herbicide-resistant trait in sunflower (Helianthus annuus L.) is known as 'Imisun'. Imidazolinone resistance in Imisun cultivars has been reported to be genetically controlled by a major gene (known as Imr1 or Ahasl1-1) and modifier genes. Imr1 is an allelic variant of the Ahasl1 locus that codes for the acetohydroxyacid synthase, which is the target site of these herbicides. The mechanism of resistance endowed by modifier genes has not been characterized and it could be related to non-target-site resistance. The objective of this study was to evaluate the role of cytochrome P450 monooxygenases (P450s) in Imisun resistance. The response to imazapyr herbicide in combination with P450s inhibitor malathion was evaluated in 2 Imisun

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Rapid test for detection of imidazolinone resistance in sunflower (Helianthus annuus L.)

et al. 2011

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The development of imidazolinone (IMI) resistant sunflower cultivars represents a great advantage in controlling weeds. The aim of this study was to evaluate the response of sunflower genotypes to the presence of IMIs in a soil-less bioassay. Six genotypes differing in IMI resistance were planted in pots filled with perlite and watered with different imazapyr doses. Differences among resistant, intermediate and susceptible genotypes were observed 8-15 days after planting. The susceptible genotype showed stunted plantlets. The intermediate genotypes developed reduced lateral roots when exposed to imazapyr. The resistant inbred line was only affected at the highest herbicide concentrations. Differences in aerial growth were also observed among genotypes. The bioassay described in this study is a rapid, simple and cost-effective method for early screening herbicide resistant genotypes. This diagnostic test could be a useful tool when breeding for IMI resistance in sunflower.

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