Project description:To identify key genes in the regulation of salt tolerance in the mangrove plant Bruguiera gymnorhiza, the transcriptome profiling under salt stress was carried out. Main roots and lateral roots were collected from the mangrove plants at 0, 1, 3, 6, 12 and 24 h, 3 6 and 12 days after NaCl-treatment. Keywords: time course, stress response, root type comparison
Project description:To identify key genes in the regulation of salt tolerance in the mangrove plant Bruguiera gymnorhiza, the transcriptome profiling under salt stress was carried out. Main roots and lateral roots were collected from the mangrove plants at 0, 1, 3, 6, 12 and 24 h, 3 6 and 12 days after NaCl-treatment. Samples were collected from each set of three trees at 0, 1, 3, 6, 12 and 24 h, 3 6 and 12 days after NaCl-treatment, that is 27 trees were used in total. RNA was extracted from mixture of the samples from 3 trees to average genotypes of 3 trees.
Project description:Generally, salt stress causes both osmotic and ionic stress. To discern the effects of osmotic and ionic specific effects on Burma mangrove transcriptome, we conducted expression profiling in 500 mM NaCl or 1M solbitol treated leaves. This study will lead to a rapid and effective selection of gene that confers high salt tolerance in transgenic plants and to a comprehensive understanding of plant stress response. Keywords: Stress response
Project description:Purpose:to identify the response of Frankia sp.strain CcI6 to salt and osmotic stress. Frankia sp.strain CcI6 was exposed to salt and osmotic stress for seven days. RNAseq analysis was carried out to ge an insight into the response of the bacterium under salt and osmotic stress conditons
Project description:Hernandia nymphaeifolia is an endangered mangrove associate with high ecological, ornamental, and medicinal values. Its special combination of glycophytic and halophytic characteristics provides an ideal system for investigating salt-responsive mechanisms that may be easily extended to genetic improvement of crops with high salt tolerance. However, little is known regarding salt-responsive mechanisms in H. nymphaeifolia. In this study, we posed gradient salt treatments on H. nymphaeifolia seedlings and investigated their physiological and transcriptional reprogramming in response to salinity stress. The results revealed that hyper-salinity stress posed more adverse impacts on leaf growth, cell integrity and photosynthetic performance of H. nymphaeifolia seedlings compared to those in growing in fresh water or low salt condition, mirroring its nature as a mangrove associate. Genes associated with osmolarity sensor and regulator, ROS scavenging and ion homeostasis were differentially expressed accordingly to alleviate the destructive effects. Furthermore, our results unraveled some pivotal kinases and proteins that regulate the synergistic expression of salt-responsive genes, which may act a key role in regulating the transcriptional remodeling upon salinity stress. These findings enrich our knowledge on the molecular mechanisms underlying the phenotypic plasticity of mangrove associates, and also provide valuable genetic resources for mangrove’s conservation and potential bioengineering application in agricultural field.
