Additional file 5: Figure S1. of Genome-wide identification of soybean microRNA responsive to soybean cyst nematodes infection by deep sequencing

Expression levels of all RNA-seq libraries. The boxplot of CPM normalized expression for all 24 libraries. (PDF 6 kb

Additional file 1: Table S1. of microRNA-dependent gene regulatory networks in maize leaf senescence

Summary of small RNA classes in the samples. Table S2. Expression abundance of the known miRNAs. Table S3. Regions of the target genes identified by degradome sequencing. Table S4. Primers used in miRNA and target gene validation. (DOCX 61 kb

Additional file 3: Table S3. of Genome-wide identification of soybean microRNA responsive to soybean cyst nematodes infection by deep sequencing

Novel miRNA prediction. A table of new miRNAs predicted by miRDeep2 with a score of one or greater. (XLSX 21 kb

Additional file 1: Table S1. of Genome-wide identification of soybean microRNA responsive to soybean cyst nematodes infection by deep sequencing

Total known miRNAs identified in Glycines max from all small RNA-seq libraries. The value was the mean of three replicates for each treatment and normalized as CPM. (XLSX 51 kb

Additional file 2: Table S2. of Genome-wide identification of soybean microRNA responsive to soybean cyst nematodes infection by deep sequencing

Significantly Differentially expressed miRNAs identified in SCN-infected soybean roots compared with control. A table of all DE miRNAs identified from each treatment. The q-value was used to consider for statistical significance, with log2 ratio of normalized miRNA expression in SCN infection compared with control. (XLSX 14 kb

Additional file 2: Figure S1. of microRNA-dependent gene regulatory networks in maize leaf senescence

T-plot of miRNA target genes. Five different categories of T-plots are shown. The degradome tag distributions along the target mRNA sequence are exhibited. The red line represents the sliced target transcripts. (TIF 4679 kb

L'Auto-vélo : automobilisme, cyclisme, athlétisme, yachting, aérostation, escrime, hippisme / dir. Henri Desgranges

23 janvier 19431943/01/23 (A44,N15330)-1943/01/24

PHB promotes <i>ABI4</i> expression by directly binding to its promoter.

<p>(A) <i>ABI4</i> expression was analyzed in wild type and STTM165/166 2-day-old seedlings using qRT-PCR. (B) <i>ABI4</i> expression was analyzed in <i>PHB</i>:<i>PHB G202G-YFP</i> lines using qRT-PCR. (C) Analysis of <i>ABI4</i> promoter. A 3.0kb fragment upstream of ATG was chosen for the promoter analysis. (D) EMSA assay showed that PHB binds to an <i>ABI4</i> promoter region. Labeled probe of the <i>ABI4</i> promoter region was incubated with GST-PHB fusion protein. For the competition test, a non-labeled probe was added at 10-fold and 100-fold concentrations.</p

STTM165/166 plants exhibit drought stress resistance phenotype.

<p>(A) Drought resistance phenotype. 3-week-old plants (upper panel) were grown under the same conditions but without irrigation for 14 days (middle panel), and then rewatered for 2 days (lower panel). (B) Quantification of the survival rate. Forty plants of wild type and STTM165/166 were used in each experiment, and the survival rate was calculated from the results of four independent experiments. (C) Water loss assay. Aerial parts of 3-week-old plants were detached and weighed at the indicated time points. Water content at any time point was calculated as percentage of the fresh weight at time zero. Data were derived from four independent experiments (±SD).</p

The miR165/166 Mediated Regulatory Module Plays Critical Roles in ABA Homeostasis and Response in <i>Arabidopsis thaliana</i>

<div><p>The function of miR165/166 in plant growth and development has been extensively studied, however, its roles in abiotic stress responses remain largely unknown. Here, we report that reduction in the expression of miR165/166 conferred a drought and cold resistance phenotype and hypersensitivity to ABA during seed germination and post-germination seedling development. We further show that the ABA hypersensitive phenotype is associated with a changed transcript abundance of ABA-responsive genes and a higher expression level of <i>ABI4</i>, which can be directly regulated by a miR165/166 target. Additionally, we found that reduction in miR165/166 expression leads to elevated ABA levels, which occurs at least partially through the increased expression of <i>BG1</i>, a gene that is directly regulated by a miR165/166 target. Taken together, our results uncover a novel role for miR165/166 in the regulation of ABA and abiotic stress responses and control of ABA homeostasis.</p></div