Project description:Transcriptome responses to the natural phytotoxin t-chalcone in Arabidopsis thaliana L.

Project description:Quinoa is a highly nutritious seudocereal crop that is not well adapted to heat. Improving understanding of quinoa responses to heat would help expand its cultivation to regions with warmer climates. This study profiled gene expression of quinoa plants from accession QQ74 (PI 614886) treated with high tempreatures during anthesis of the main panicle, which lasted 11 days. Heat was applied in four different treatments to profile gene expression changes from root or shoot heating. Treatments were: 1. control with both roots and shoots at 22°C, 2. heated roots with roots at 30°C and shoots at 22°C, 3. heated shoots with roots at 22 °C and shoots at 35°C, and 4. heated roots and shoots with roots at 30°C and shoots at 35°C. Healthy leaves from 3 plants per treatment were sampled from the mid section of the plants, during the first (day 1) and last day (11) of heat treatment, at Zeitgeber time 2. Gene expression of each of the three heat treatments was compared to control using the Kallisto-Sleuth pipeline. These gene expression profiles of quinoa under heat are made available as a community resource to improve understanding of quinoa responses to heat.

Project description:We performed the transcriptome-wide m6A profiling (MeRIP) with poly(A) RNA samples isolated from shoots and roots of wild type (Nipp), FTO homogeneous transgenic (FTO) and demethylation activity dead mutant variant of FTO transgenic (FTOmut) rice plants. The m6A motif and the distribution of the detected m6A sites along transcripts were consistent with reported results from previous m6A sequencing studies in plants. We then analyzed the differentially methylated m6A sites in poly(A) RNA species including those transcribed from gene loci and from repetitive elements (repeat RNAs). Compared to Nipp plants, both shoots and roots of FTO transgenic plants had showed more hypomethylated m6A peaks (hypo-m6A, 222 in shoots and 3313 in roots) than hypermethylated m6A peaks (hyper-m6A, 63 in shoots and 127 in roots) in mRNAs, while FTOmut rice had showed more hyper-m6A in shoots (349 for hyper vs 31 for hypo) but more hypo-m6A in roots (291 for hyper vs 380 for hypo) than the WT. The hypomethylated m6A peaks in FTO transgenic plants were highly enriched within 3'UTR. Gene Ontology (GO) analysis of these identified hypomethylated m6A-containing coding genes in both FTO transgenic rice shoots and roots revealed an enrichment for functional annotations related to “cellular homeostatic process”, “one-carbon and small molecule metabolic process”, and “gene expression”. We also found the extent of m6A hypomethylation was more pronounced for repeat RNAs than for mRNA species.The quantitative RNA-seq analysis that included ERCC spike-in controls confirmed that FTO plants do indeed accumulate higher overall levels of poly(A) RNA than do WT shoots and roots. Above all, FTO mediated m6A demethylation in plant mRNA and repeats RNA, leading to the activation of transcription.

Project description:Proteomics analyses of roots and shoots of O. sativa plants exposed to cold stress.

Project description:Plant hormones and small secretory peptides often function as environmental stress mediators. Some recent reports indicate that small secretory peptides, such as CLAVATA3/EMBRYO SURROUNDING REGION-RELATED (CLE), also function as mediators of environmental stimuli. CLE３ is induced in roots by defense elicitor treatment. Plants without functional CLE3 showed compromized defense gene responses in shoots when plant roots were treated with NaSA. Here, we identified specific genes downstream of CLE3 in roots and shoots with transformed Arabidopsis plants.

Project description:To identificate long noncoding RNAs in maize, we profiled transcriptome of shoots and roots using stranded single-end RNA-seq based on poly(A) selection. Transcriptom profiling in maize shoots and roots.

Project description:To identificate long noncoding RNAs in maize, we profiled transcriptome of shoots and roots using non-directional paired-end RNA-seq based on poly(A) selection. Transcriptom profiling in maize shoots and roots.

Project description:We analyzed global transcriptional changes in both shoots and roots of root-flooded Arabidopsis seedlings by microarrays. We also interpreted the significance of the systemic communication between roots and shoots by functional classification of affected genes. We performed genetic analysis with an ethylene signaling mutant, ein2-5, to correlate systemic flooding responses with ethylene signaling. We identified a class of genes that were up- or downregulated in shoots, but not affected in roots, under hypoxic conditions. A comprehensive managing program of carbohydrate metabolism was observed, providing an example of how systemic communications might facilitate the survival of plants under flooding. A proportion of long-distance hypoxic regulation was altered in ein2-5.

Project description:microRNAs (miRNAs) play important roles in responses to abiotic stresses, including nutrition stress, by regulating target gene expression. Phosphate (Pi) is often lacking in natural and agro-climatic environments, and plants have developed strategies to cope with low Pi (LP) availability. However, the miRNA-mediated regulation of these adaptive responses and their underlying coordinating signals are still poorly understood in forestry trees such as Betula luminifera. Four small RNA (sRNA) libraries, a mixed degradome cDNA library, and four transcriptomic libraries of B. luminifera roots and shoots treated under LP and normal conditions (CK) were constructed and sequenced using next-generation deep sequencing. sRNA sequencing analyses indicated that 66 and 60 miRNAs were differentially expressed in roots and shoots, respectively, under LP conditions. A total of 109 and 112 miRNA–target pairs were further validated in the roots and shoots, respectively, using degradome sequencing, including several novel target genes that were cleaved by isomiRNAs with lengths of 18 or 19 nucleotides, which were only differentially expressed in roots. Kyoto Encyclopedia of Genes and Genomes pathway enrichment analysis of differential miRNA targets indicated that the “ascorbate and aldarate metabolism” pathway responded to LP, and “circadian rhythm – plant” was specifically enriched in shoots. A comprehensive B. luminifera transcriptome derived from its roots and shoots was constructed, and a total of 76,899 unigenes were generated. A comparison of transcriptome identified 8,095 and 5,584 differentially expressed genes in roots and shoots, respectively, under LP conditions. Integrated analysis uncovered 14 and 16 miRNA–target pairs that showed negatively correlated expression profiles in roots and shoots, respectively. Moreover, a putative model of miRNA–target interaction involved in plant responses to LP stress is proposed. These results suggest that comprehensive analyses of sRNAs, degradome, and transcriptome provide a useful platform for investigating LP stress in B. luminifera, and may provide new insights into the genetic engineering of high use efficiency of Pi in forestry trees.

Project description:microRNAs (miRNAs) play important roles in responses to abiotic stresses, including nutrition stress, by regulating target gene expression. Phosphate (Pi) is often lacking in natural and agro-climatic environments, and plants have developed strategies to cope with low Pi (LP) availability. However, the miRNA-mediated regulation of these adaptive responses and their underlying coordinating signals are still poorly understood in forestry trees such as Betula luminifera. Four small RNA (sRNA) libraries, a mixed degradome cDNA library, and four transcriptomic libraries of B. luminifera roots and shoots treated under LP and normal conditions (CK) were constructed and sequenced using next-generation deep sequencing. sRNA sequencing analyses indicated that 66 and 60 miRNAs were differentially expressed in roots and shoots, respectively, under LP conditions. A total of 109 and 112 miRNA–target pairs were further validated in the roots and shoots, respectively, using degradome sequencing, including several novel target genes that were cleaved by isomiRNAs with lengths of 18 or 19 nucleotides, which were only differentially expressed in roots. Kyoto Encyclopedia of Genes and Genomes pathway enrichment analysis of differential miRNA targets indicated that the “ascorbate and aldarate metabolism” pathway responded to LP, and “circadian rhythm – plant” was specifically enriched in shoots. A comprehensive B. luminifera transcriptome derived from its roots and shoots was constructed, and a total of 76,899 unigenes were generated. A comparison of transcriptome identified 8,095 and 5,584 differentially expressed genes in roots and shoots, respectively, under LP conditions. Integrated analysis uncovered 14 and 16 miRNA–target pairs that showed negatively correlated expression profiles in roots and shoots, respectively. Moreover, a putative model of miRNA–target interaction involved in plant responses to LP stress is proposed. These results suggest that comprehensive analyses of sRNAs, degradome, and transcriptome provide a useful platform for investigating LP stress in B. luminifera, and may provide new insights into the genetic engineering of high use efficiency of Pi in forestry trees.