Project description:Plant cell walls are complex structures that contain a matrix of cellulose, lignin and hemicellulose. The regulation of the biosynthesis of these components has been well-studied in the eudicot plant Arabidopsis thaliana, and a transcriptional network has been elucidated. Several NAC and MYB family transcription factors are key regulators of secondary cell wall biosynthesis, and their functional characterization provides significant insight into the complex underlying transcriptional network. Genetic and structural evidence suggests that genes controlling this process might be different between eudicots and monocots. Here, the model grass Brachypodium distachyon has been selected to characterize the function of GNRF (GRASS NAC REPRESSOR OF FLOWERING), SWAM1 (SECONDARY WALL ASSOCIATED MYB1), and SWAM4 in the regulation of secondary cell wall biosynthesis. Functional characterization was performed by using the overexpression plants GNRF-OE and SWAM4-OE; sodium azide mutant plants from a TILLING (Targeting Induced Local Lesion IN Genome) collection for gnrf-1, gnrf-2, gnrf-3, gnrf-4, gnrf-5, swam4-1, and swam4-2; a T-DNA insertional mutant plant, gnrf-6; and a dominant repressor plant, SWAM4-DR. GNRF-OE plants remained at juvenile stage and exhibited persistent vegetative growth, and some gnrf mutant plants were late flowering. SWAM4-DR plants were severely dwarfed. Stems of all genotypes mentioned above were subjected to RNA-seq analysis.

Project description:ngs2020_04_hipath-differential expression analysis to hight co2 of the brachypodium distachyon-Analysis response of the Brachypodium distachyon to hight CO2 -treatment hight CO2

Project description:The goal of this study was to evaluate the molecular mechanisms by which Brachypodium distachyon grown with and without Pseudomonas fluorescens (P. fluorescens) strain SBW25 respond to Fe deprivation. Fe deprivation induced Brachypodium secretion of phytosiderophores and reduced biomass production while inoculation with P. fluorescens resulted in alterations of extracellular metabolite abundances. Results provide insight into the role of iron in interactions between a host plant and root associated bacteria.

Project description:The goal of this study was to examine the transcriptional events occuring during stress-free Brachypodium distachyon root development via illumina paired-end RNA-seq. 4 time-points were chosen that capture the transition from rapid vegetative growth into slower reproductive growth. Abstract - Root systems are dynamic, adaptable organs that play critical roles in plant development. Roots, however, remain understudied and therefore present opportunities for trait improvement in food and bioenergy crops. A comprehensive growth stage-based root phenotyping integrated with molecular signatures is required to advance our understanding of root growth and development. Here we studied Brachypodium distachyon rooting process by monitoring root biomass, length, branching, root-to-shoot ratio and Carbon-to-Nitrogen ratio during time. To provide insight into gene regulation that accompanies root development and biomass accumulation, we generated comprehensive transcript profiles of Brachypodium whole-root system at four initial developmental stages that capture the transition from vegetative to reproductive growth. Our stringent data analysis revealed that multiple biological processes and various families of transcription factors (TFs) were differentially expressed during root development. In particular, the AUX/IAA, ERFs, WRKY, NAC, and MADS TF family members were upregulated, while ARFs and GRFs were downregulated in a time-dependent manner. Our results suggested particular TF families and biological processes including trehalose metabolism as important factors possibly involved in root biomass accumulation. We introduced several Brachypodium root biomass-promoting genes which can be employed by the genome editing approaches for improving biomass productivity in grasses.

Project description:We used Brachypodium distachyon (BD21) as a model grass to gain insight into the affected host molecular pathways upon infection of Panicum Mosaic Virus (PMV) together with its satellite virus, Satellite Panicum Mosaic Virus (SPMV). Brachypodium plants at 2-3 leaf stage were either mock inoculated or inoculated with PMV and PMV+SPMV. Total RNA was isolated from shoot tissues of control and treated plants and was subjected to microarray analysis.

Project description:Plant height is a major trait affecting yield potential in rice. Using a large-scale hybrid transcription factor approach, we identified the novel MYB-like transcription factor OsMPH1 (MYB-like gene of Plant Height 1), which is involved in the regulation of plant height in rice.Overexpression of OsMPH1 leads to increases of plant height and grain yield in rice, while knockdown of OsMPH1 leads to the opposite phenotypes. RNA-seq is used for exploring differences between OsMPH1 transgenic rice and wild-type plants.

Project description:The small RNA transcriptomes of bread wheat (Triticum aestivum L.) and its emerging model (Brachypodium distachyon (L.) Beauv) were obtained by using deep sequencing technology. Small RNA compositions were analyzed in these two species. In addition to 70 conserved microRNAs (miRNA) from 25 families, 23 novel wheat miRNAs were identified. For Brachypodium, 12 putative miRNAs were predicted from a limited number of ESTs, of which one was a potential novel miRNA. Also, 94 conserved miRNAs from 28 families were identified in this species. Expression validation was performed for several novel wheat miRNAs. RNA ligase-mediated 5' RACE experiments demonstrated their capability to cleave predicted target genes including three disease resistant gene analogs. Differential expression of miRNAs was observed between Brachypodium vegetative and reproductive tissues, suggesting their different roles at the two growth stages. Our work significantly increases the novel miRNA numbers in wheat and provides the first set of small RNAs in Brachypodium distachyon. Keywords: Small RNA

Project description:ABSTRACT: Exposure to abiotic stresses triggers global changes in the expression of thousands of eukaryotic genes at the transcriptional 70 and post-transcriptional levels. Small RNA (smRNA) pathways and splicing both function as crucial mechanisms regulating stress-responsive gene expression. However, examples of smRNAs regulating gene expression remain largely limited to effects on mRNA stability, translation, and epigenetic regulation. Also, our understanding of the networks controlling plant gene expression in response to environmental changes, and examples of these regulatory pathways intersecting, remains limited. Here, to investigate the role of smRNAs in stress responses we examined smRNA transcriptomes of Brachypodium distachyon plants subjected to various abiotic stresses. We found that exposure to different abiotic stresses specifically induced a group 75 of novel, endogenous small interfering RNAs (stress-induced, UTR-derived siRNAs, or sutr-siRNAs) that originate from the 3M-bM-^@M-2 UTRs of a subset of coding genes. Our bioinformatics analyses predicted that sutr-siRNAs have potential regulatory functions and that over 90% of sutr-siRNAs target intronic regions of many mRNAs in trans. Importantly, a subgroup of these sutr- siRNAs target the important intron regulatory regions, such as branch point sequences, that could affect splicing. Our study indicates that in Brachypodium, sutr-siRNAs may affect splicing by masking or changing accessibility of specific cis-elements 80 through base-pairing interactions to mediate gene expression in response to stresses. We hypothesize that this mode of regulation of gene expression may also serve as a general mechanism for regulation of gene expression in plants and potentially in other eukaryotes. Analysis of smRNA populations in Brachypodium plants challenged by abiotic stresses: To profile the populations of smRNAs in the model monocot Brachypodium distachyon and examine their regulation in response to abiotic stresses, we conducted high-throughput sequencing of small RNAs from plants exposed to four different abiotic stress conditions, cold, heat (air), heat (water immersion), and salt, in the wild type Brachypodium cultivar Bd21. For our experiments we used information from the literature to select two time-points for stress durations, short and long, which differed for each stress: cold (6 and 24 hours), heat-air (1 and 3 hours), heat-water (1 and 3 hours), and salt (48 hours). We generated small RNA libraries for Illumina sequencing (GAII) from the leaves of Brachypodium plants subjected to stresses and selected smRNAs between 15 and 40 nt in length, which we mapped to the Brachypodium genome.

Project description:The wild grass Brachypodium distachyon has emerged as a model system for temperate grasses and biofuel plants. However, the global analysis of miRNAs, molecules known to be key for eukaryotic gene regulation, has been limited in B. distachyon to studies examining a few samples or that rely on computational predictions. Similarly an in-depth global analysis of miRNA-mediated target cleavage using Parallel Analysis of RNA Ends (PARE) data is lacking in B. distachyon. B. distachyon small RNAs were cloned and deeply sequenced from 17 libraries that represent different tissues and stresses. Using a computational pipeline, we identified 116 miRNAs including not only conserved miRNAs that have not been reported in B. distachyon, but also non-conserved miRNAs that were not found in other plants. To investigate miRNA-mediated cleavage function, four PARE libraries were constructed from key tissues and sequenced to a total depth of approximately 70 million sequences. The roughly 5 million distinct genome-matched sequences that resulted represent an extensive dataset to analyze small RNA-guided cleavage events. Analysis of the PARE and miRNA data provided experimental evidence for miRNA-mediated cleavage of 264 sites in predicted miRNA targets. In addition, PARE analysis revealed that differentially expressed miRNAs in the same family guide specific target RNA cleavage in a correspondingly tissue-preferential manner. B. distachyon miRNAs and target RNAs were experimentally identified and analyzed. Knowledge gained from this study should provide insights into the roles of miRNAs and the regulation of their targets in B. distachyon and related plants. Examination of various tissues and stresses in Brachypodium by high throughput sequencing for small RNA profiling and PARE (Parallel Analysis of RNA Ends)

Project description:Comparative RNA-sequencing of the developmental leaf zones in Brachypodium distachyon wild type and bdmute mutants that do not form stomatal subsidiary cells was performed. The aim was to identify genes relevant for subsidiary cell formation in B. distachyon.