Project description:RNA-seq of leaves in Mesona chinensis Benth under drought stress

Project description:RNA-seq of Mesona chinensis Benth leaves

Project description:RNA-seq of leaves in Mesona chinensis Benth under salt stress

Project description:Chloroplast genome sequencing of Mesona chinensis Benth

Project description:The Mitochondrial genome of Mesona chinensis Benth

Project description:Genome survey sequence of Mesona chinensis Benth

Project description:To investigate the changes in metabolite of bamboo under drought and rewatering treatments, transcriptome sequencing of bamboo leaves was performed under control, drought, and rehydration conditions at three time points: early morning (06:00), midday (14:00), and night (23:00).

Project description:Drought stress imposes severe challenges on agriculture by impacting crop performance. Understanding drought responses in plants at a cellular level is a crucial first step towards engineering improved drought resilience. The molecular responses to drought are however very complex as they depend on multiple factors including the severity of drought, the profiled organ, its developmental stage and even the cell types therein. As such, deciphering the transcriptional responses to drought is specifically challenging.In the study associated with this data submission, we investigated tissue-specific responses to mild drought in young Arabidopsis thaliana (Arabidopsis) leaves using single-cell RNA sequencing (scRNA-seq, deposited under another id, GSE273033). To preserve transcriptional integrity during cell isolation, we fixed the RNA prior to cell isolation using the transcription inhibitor actinomycin D, demonstrating the benefits of fixation for studying mild stress responses at single-cell level. The transcriptome data deposited here corresponds to the bulk RNA-sequencing experiments described in this study. The samples presented here are undigested leaves, leaves digested by cell wall degradation without fixation, and leaves digested by cell wall degradation with RNA fixation. All sample types were collected from plants growing under well-watered and mild drought conditions.

Project description:To dissect the molecular mechanisms underlying drought tolerance (DT) in rice, transcriptome differences of a DT introgression line H471, the DT donor P28 and the drought sensitive recurrent parent HHZ under drought stress were investigated using deep transcriptome sequencing. Results revealed a differential constitutive gene expression prior to stress and distinct global transcriptome reprogramming among three genotypes under time-series drought stress, consistent with their differential genotypes and DT phenotypes. DT introgression line H471, the DT donor P28 and the drought sensitive recurrent parent HHZ under drought stress were investigated using deep transcriptome sequencing.The drought stress treatment was started by withholding water at the tillering stage. The days were counted after the AWC in the soil reached 20% to allow drought measurements at precisely determined intervals, and the soil water content reached 15%, 10% and 7.5% after 1d, 3d and 4d drought treatment, respectively.Three top leaves for each sample were harvested for each genotype under 1d and 3d drought stress and control conditions. All samples were immediately frozen in liquid nitrogen and stored at -80C and then for transcriptome sequencing.

Project description:the SiNRX1 of foxtail millet was knocked out by means of the CRISPR/Cas9 technology, and the drought resistance of SiNRX1 was identified at both the germination stage and the seedling stage. Moreover, through transcriptome sequencing and Data-independent acquisition (DIA) quantitative proteomics determination of sinrx1 mutants and wild types (WT) at the seedling stage under drought and control conditions, the molecular mechanism of SiNRX1 regulating drought resistance was preliminarily analyzed.