Project description:The proteome profiles in the shoots of two sesame genotypes with contrasting salinity tolerance were investigated under saline condition using an iTRAQ-based quantitative proteomics approach.
2019-03-08 | PXD013013 |
Project description:Transcriptome analysis of two zombi pea varieties with contrasting waterlogging tolerance
Project description:Sampada and Sujata are two contrasting genotypes of Papaver somniferum that are contrasting in terms of their latex and alkaloid profiles. The major objective of the present study was to use a small-scale (750 target genes) microarray of P. somniferum for identification of genes that are differentially expressed in the capsule walls of the two contrasting genotypes, Sampada and Sujata. Nidarshana Chaturvedi and Mridula Singh made equal contribution as first authors to this data.
Project description:The physiological indicators, transcriptome, and metabolome of two melon varieties with contrasting chilling tolerance (‘162’, chilling-tolerant; ‘13-5A’ ,chilling-sensitive) were analyzed under chilling stress.
Project description:Tissue-specific transcriptional profiling of the abscission layer (AL) at the base of young flower in rice using laser micro-dissection: NIL(qSH1) vs. Nipponbare. We used two rice varieties, NIL(qSH1) and Nipponbare. NIL(qSH1) is a nearly isogenic line containing the seed shattering gene qSH1. Seed shattering is easy in NIL(qSH1), but it is not in Nipponbare. So, we used some stages of young flower in NIL(qSH1) and some in Nipponbare. Four regions: 1. abscission layer region of NIL(qSH1), 2. upper abscission region of NIL(qSH1), 3. lower abscission layer region of NIL(qSH1), and 4. abscission layer region of Nipponbare. Sample experiments: NIL(qSH1) AL vs. Nipponbare AL, NIL(qSH1) AL vs. NIL(qSH1) upper region of AL, and NIL(qSH1) AL vs. NIL(qSH1) lower region of AL.
Project description:Sesame seeds is an important traditional crop with high oil content and other abundant nutrients which are very beneficial for diet and health of human being. However, the molecular mechanism for metabolite accumulation, especially for oil and phenylpropanoid biosynthesis, is still not very clear in sesame. In this study, the transcriptome profiles of black and white sesame seeds were compared by RNA-sequencing. Transcriptome analysis showed that the expression patterns of genes encoding phenylpropanoid pathway enzymes were different between the two sesame cultivars. Compared with white sesame, most of genes involved in oil biosynthesis were significantly down-regulated in black sesame.
