Project description:To identify salt-resistant related genes by histone deacetylase inhibitor Ky-2, expression profiles between plants treated with or without Ky-2 under salt stress were analyzed using the custom microarray (GPL20781). Wild-type plants (Arabidopsis thaliana ecotype Columbia) were grown on 1/2 MS 0.1 % Agar medium for four days. Then, the plants were administrated to Ky-2 for 24 hours and then treated 100 mM Nacl for two hours. Expression profiles were analyzed using the custom array (GPL20781).

Project description:Salinity tolerance is a complex trait and, despite many efforts to obtain rice plants resistant to salt, few results have been achieved since a deeper understanding of the tolerance mechanisms is still needed. We used imaging of photosynthetic parameters, ion analysis and transcriptomic approaches to unveil differences between two rice varieties differing in salt sensitivity. Moreover, we analysed H2O2 production in roots, using a fluorescent probe, and the ensuing gene regulation. Transcriptomic analyses conducted in tolerant plants supported the set-up of an adaptive program consisting of allocating sodium preferentially to roots, restricting it to the oldest leaves and activating regulatory mechanisms of photosynthesis in new leaves. As a consequence, plants resumed growth even under prolonged salt stress. By contrast, in the susceptible variety, RNA profiling unveiled a mis-targeted response, leading to senescence and cell death. In roots of tolerant plants, an increase in H2O2 was observed as early as 5 minutes after treatment. Consequently, the expression of genes involved in perception, signal transduction and response to salt were induced at earlier times when compared to susceptible plant roots. Our results demonstrate that a prompt H2O2 signalling in roots participates to a coordinated response resulting in adaptation instead of senescence in salt treated rice plants.

Project description:Soil salinity presents a notable challenge to agriculture and to increasing the use marginal lands for farming. Here we provide a detailed analysis of the physiology, chemistry and gene expression patterns in roots and shoots of Camelina sativa in response to salt stress. Salt treatment reduced shoot, but not root length. Root and shoot weight were affected by salt, as was photosynthetic capacity. Salt treatment did not alter micro-element concentration in shoots, but increased macro-element (Ca and Mg) levels. Gene expression patterns in shoots indicated that salt stress may have led to shuttling of Na+ from the cytoplasm to the tonoplast and to an increase in K+ and Ca+2 import into the cytoplasm. In roots, gene expression patterns indicated that Na+ was exported from the cytoplasm by the SOS pathway and that K+ was imported in response to salt. Genes encoding proteins involved in chelation and storage were highly up-regulated in shoots, while metal detoxification appeared to involve various export mechanisms in roots. In shoots, genes involved in secondary metabolism leading to lignin, anthocyanin and wax production were up-regulated, probably to improve desiccation tolerance. Partial genome expression partitioning was observed in roots and shoots based on the expression of homeologous genes from the three C. sativa genomes. Genome I and II were involved in the response to salinity stress to about the same degree, while about 10 % more differentially-expressed genes were associated with Genome III. This study has provided valuable information and insight into the response of camelina to salt stress. Examination of this data and comparison to similar studies in more halophytic species will allow development of even more salt-tolerant varieties of this emerging industrial crop.

Project description:Changes in the gene expression during exposure to salinity stress were compared among nodal roots, S-type lateral roots, and L-type lateral roots.

Project description:Salt stress is a rising threat to agriculture system. The accumulation of salts near the plant roots hampers the normal uptake of water causing osmotic stress and ionic toxicity to the plant. Thompson Seedless is a popular table grape variety of Vitis vinifera L., which is sensitive to salt stress when grown on its own roots; grafting it onto a wild rootstock such as 110 Richtor (110R) makes it tolerant to salt stress. In the present study, shotgun-proteomics approach was used for the investigation of salt stress induced molecular response of own rooted and 110R grafted Thompson Seedless grapevines. A salt stress experiment was conducted on sixteen month old potted grapevines. The grapevines were treated with 150mM NaCl solution for seven days and the control vines were irrigated with tap water. The young leaf samples were collected from control and treated vines at three time-points viz. 6 hours, 48 hours and 7 days of salt stress. The stress responsive proteins identified through statistical analysis revealed a distinct response to salinity in both the vines.

Project description:To investigate the role of TSPO in the sequelae of sepsis induced by cecal ligation and puncture (CLP), hippocampal gene expression changes after CLP surgery were examined in wild-type and TSPO KO mice

Project description:Here, we first systematically identified and characterized responsive mRNAs expressed in roots of sugar beet at a genome-wide scale, focusing on salt-responsive mRNAs.

Project description:Changes in the gene expression during exposure to salinity stress were compared among nodal roots, S-type lateral roots, and L-type lateral roots.

Project description:Differences in gene expression were compared among nodal roots, S-type lateral roots, and L-type lateral roots of salinity tolerant and sensitive rice varieties.

Project description:Translocator Protein (18kDa, TSPO) is a mitochondria outer membrane transmembrane protein and which expression is elevated during inflammation and injury. However, the exact function of TSPO is still controversial. Here, we constructed TSPO global knockout (KO) mice by Cre-LoxP system independently, which abolished TSPO protein expression in all tissues and shown normal phenotypes. The birth rate of TSPO heterozygote (Het)/Het breeding was consistent with the Mendel’s Law, suggesting a normal viability of TSPO KO mice at birth. RNAseq analysis showed no significant difference in the gene expression profile of lung tissues from TSPO KO mice compared with that of wild type mice, even the genes associated with bronchial alveoli immune homeostasis. The alveolar macrophage population was also not affected by TSPO deletion in the physiological condition. Our findings contradicts the results of Papadopoulos, but confirmed Selvaraj’s findings. This study reveals TSPO deficiency does not affect the viability and bronchial alveoli immune homeostasis.