RESUMO
In the post-genomic era, increasingly sophisticated genetic tools are being developed with the long-term goal of understanding how the coordinated activity of genes gives rise to a complex organism. With the advent of the next generation sequencing associated with effective computational approaches, wide variety of plant species have been fully sequenced giving a wealth of data sequence information on structure and organization of plant genomes. Since thousands of gene sequences are already known, recently developed functional genomics approaches provide powerful tools to analyze plant gene functions through various gene manipulation technologies. Integration of different omics platforms along with gene annotation and computational analysis may elucidate a complete view in a system biology level. Extensive investigations on reverse genetics methodologies were deployed for assigning biological function to a specific gene or gene product. We provide here an updated overview of these high throughout strategies highlighting recent advances in the knowledge of functional genomics in plants.
RESUMO
Salt stress adversely affects the growth of grapevine plants. In order to understand the molecular basis of salt stress response in grapevine plants, suppression subtractive hybridization (SSH) and microarray based screening approaches were combined. Two leaf-specific subtractive cDNA libraries were constructed from grapevine plants subjected to a moderate, incremental salt stress treatment. SSH were performed 6h and 24h after NaCl peaked at 100mM using cDNAs prepared from leaves of a salt tolerant cultivar (Razegui) as testers and cDNAs from unstressed leaves as drivers. Then, a pre-screened subset of cDNA clones from these SSH libraries were used to construct a Vitis vinifera cDNA array, in order to verify the expression changes of the genes upon salt treatment. Expression profiles were compared between the salt tolerant and a susceptible cultivar (Syrah) under both control conditions and after salt stress treatment. Seven cDNA clones were identified which were up-regulated by salt stress in two independent growth experiments and confirmed by RNA blot analysis. The transcript expression patterns of the selected genes differed between the contrasting grapevine cultivars tested with respect to stress-regulation. The possible relationship of individual cDNAs with salinity tolerance mechanisms is discussed.
RESUMO
RNA interference (RNAi) was established in Nicotiana benthamiana plants by introducing constructs containing a defective interfering (DI) sequence from Tomato bushy stunt virus (TBSV) in combination with a conserved sense-sequence from the target Grapevine fanleaf virus (GFLV). Silencing in plants was confirmed by Agrobacterium-mediated infiltration of a GFP-sensor containing the GFLV-derived target sequence. The transgene-induced RNAi led to silencing of the GFP-sensor and GFP fluorescence was absent post-infiltration. In plants without GFP fluorescence after infiltration with the GFP-sensor, siRNA specific to GFP and the target virus sequence could not be detected. In contrast, infiltrated leaves of wild type and transgenic plants showing GFP fluorescence after infiltration revealed accumulation of siRNA specific to the sequence of the sensor. Silencing could be inhibited by co-infiltration using a p19 silencing suppressor construct together with the GFP-sensor, which always resulted in bright GFP fluorescence. In parallel, virus resistance of transgenic Nicotiana benthamiana was investigated via challenge inoculation with GFLV. Our results indicate that efficient RNAi in transgenic plants does not necessarily lead to a detectable accumulation of siRNA.
