Project description:Investigation of HSL2 effect in root cap sloughing

Project description:The root cap surrounds the root meristem, protecting it from harsh environments and facilitating root movement through soil. In Arabidopsis, new root cap cells produced in the meristem displace older cells toward the root periphery, where they undergo programmed cell death and are released from the root. This rapid cell turnover is a unique feature of the root cap and is modulated in part by the combined action of four NAC transcription factors, as well as cell wall modification enzymes. Here we show that the transcription factor NIN-LIKE PROTEIN 7 (NLP7) regulates root cap maturation in Arabidopsis by modulating expression of each of the NAC TFs as well as several cell wall modifying enzymes. NLP7 is a homolog of NIN, a transcription factor required for nodulation in Lotus japonicas, and is highly expressed in the columella root cap. Mutants have altered columella root cap development and decreased levels of homogalacturonan, a major component of pectin. Reverse genetic analysis of genes differentially expressed in nlp7 roots showed that two cell wall modifying enzymes, CELLULASE5 and XTH5, modulate root cap maturation likely downstream of NLP7. Plant cell wall modification is critical for nodulation, and we propose that this characteristic is also present in NLPs. We used microarrays to identify the differences in gene expression between whole roots of WT and nlp7-1 Arabidopsis plants

Project description:The root cap surrounds the root meristem, protecting it from harsh environments and facilitating root movement through soil. In Arabidopsis, new root cap cells produced in the meristem displace older cells toward the root periphery, where they undergo programmed cell death and are released from the root. This rapid cell turnover is a unique feature of the root cap and is modulated in part by the combined action of four NAC transcription factors, as well as cell wall modification enzymes. Here we show that the transcription factor NIN-LIKE PROTEIN 7 (NLP7) regulates root cap maturation in Arabidopsis by modulating expression of each of the NAC TFs as well as several cell wall modifying enzymes. NLP7 is a homolog of NIN, a transcription factor required for nodulation in Lotus japonicas, and is highly expressed in the columella root cap. Mutants have altered columella root cap development and decreased levels of homogalacturonan, a major component of pectin. Reverse genetic analysis of genes differentially expressed in nlp7 roots showed that two cell wall modifying enzymes, CELLULASE5 and XTH5, modulate root cap maturation likely downstream of NLP7. Plant cell wall modification is critical for nodulation, and we propose that this characteristic is also present in NLPs. We used microarrays to identify the differences in gene expression between whole roots of WT and nlp7-1 Arabidopsis plants Roots were cut at the root/hypocotyl junction and collected into RLT buffer in the RNeasy plant mini kit. Approximately 60 roots were collected per replicate, with two biological replicates. RNA was extracted using the RNeasy Micro Kit. Probes for array analysis were preparedfrom 1μg total RNA with the one-cycle amplification protocol by Affymetrix according to the manufacturer's instructions. Samples were submitted to Expression Analysis Inc. (Durham, NC) for hybridization to Arabidopsis Whole Genome ATH1 Affymetrix GeneChips.

Project description:To identify the genes regulated by PIF3 under higher temperatures in the endosperm and embryo, we performed an RNA-seq analysis. We compared the transcriptome of WT and pif3 endosperm from seeds imbibed for 24h and 48h at 30˚C, which is a time when WT and pif3 seeds have not yet germinated We also compared the transcriptome of WT and pif3 embryos, after removing their endosperm 4h upon seed imbibition, cultured for 24h and 48h at 30˚C, which are times when WT and pif3 hypocotyl length was comparable

Project description:Dark-grown seedlings exhibit skotomorphogenic development. Genetic and molecular evidence indicates that a quartet of Arabidopsis Phytochrome (phy)-Interacting bHLH Factors (PIF1, 3, 4 and 5) are critically necessary to maintaining this developmental state, and that light activation of phy induces a switch to photomorphogenic development by inducing rapid degradation of the PIFs. Here, using combined ChIP-seq and RNA-seq analyses, we have identified genes that are direct targets of PIF3 transcriptional regulation, and we provide evidence that the quartet collectively regulate these genes by shared, direct binding to the target promoters in promoting skotomorphogenesis. Four biological replicates data of PIF3-binding sites were collected by comparing the parallel ChIP samples from transgenic seedlings overexpressing Myc-epitope-tagged PIF3 (35S:PIF3-5xMyc, P3M) in pif3-3 null mutant background and the wild-type (WT) control.

Project description:PIF3 plays a role as repressor of photomorphogenesis in darkness. To identify PIF3-regulated genes that might be implementing this action, we have performed whole-genome expression analysis in the pif3 mutant.

Project description:Transcriptome analysis of root development related genes in terrestrial and hydroponic ramie. Ramie seedlings were cultivated in soil, and in hydroponic with the shoot-cutting propagation method. The root samples from hydrophonic ramie were collected from the early stage (5-day-old seedling) and the late stage (30-day-old seedling) of acquatic roots induction. The roots of ramie seedling cultivated in soil were also collected for comparative analysis. Our study represents the detailed analysis of ramie root transcriptomes with biologic replicates.

Project description:The acquisition of water and nutrients by plant roots is a fundamental aspect of agriculture and strongly depends on root architecture. Root branching and expansion of the root system is achieved through the development of lateral roots and is to a large extent controlled by the plant hormone auxin. However, the pleiotropic effects of auxin or auxin-like molecules on root systems complicate the study of lateral root development. Here we describe a small-molecule screen in Arabidopsis thaliana that identified naxillin as what is to our knowledge the first non-auxin-like molecule that promotes root branching. By using naxillin as a chemical tool, we identified a new function for root cap-specific conversion of the auxin precursor indole-3-butyric acid into the active auxin indole-3-acetic acid and uncovered the involvement of the root cap in root branching. Delivery of an auxin precursor in peripheral tissues such as the root cap might represent an important mechanism shaping root architecture. To further explore the specificity of naxillin for lateral root development, we compared the early effects of naxillin at the transcriptome level with NAA (1-Naphthaleneacetic acid) in roots of 3-day-old seedlings after 2-h and 6-h treatment.

Project description:Dark-grown seedlings exhibit skotomorphogenic development. Genetic and molecular evidence indicates that a quartet of Arabidopsis Phytochrome (phy)-Interacting bHLH Factors (PIF1, 3, 4 and 5) are critically necessary to maintaining this developmental state, and that light activation of phy induces a switch to photomorphogenic development by inducing rapid degradation of the PIFs. Here, using combined ChIP-seq and RNA-seq analyses, we have identified genes that are direct targets of PIF3 transcriptional regulation, and we provide evidence that the quartet collectively regulate these genes by shared, direct binding to the target promoters in promoting skotomorphogenesis. Transcriptomic profiles of the wild-type (WT), pif3 monogenic mutant, pif1pif4pif5 (pif145) triple mutant, and pif1pif3pif4pif5 (pifq) quadruple mutant were collected from biological triplicates using 3'-end-captured directional RNA-seq analysis.

Project description:The acquisition of water and nutrients by plant roots is a fundamental aspect of agriculture and strongly depends on root architecture. Root branching and expansion of the root system is achieved through the development of lateral roots and is to a large extent controlled by the plant hormone auxin. However, the pleiotropic effects of auxin or auxin-like molecules on root systems complicate the study of lateral root development. Here we describe a small-molecule screen in Arabidopsis thaliana that identified naxillin as what is to our knowledge the first non-auxin-like molecule that promotes root branching. By using naxillin as a chemical tool, we identified a new function for root cap-specific conversion of the auxin precursor indole-3-butyric acid into the active auxin indole-3-acetic acid and uncovered the involvement of the root cap in root branching. Delivery of an auxin precursor in peripheral tissues such as the root cap might represent an important mechanism shaping root architecture. To further explore the specificity of naxillin for lateral root development, we compared the early effects of naxillin at the transcriptome level with NAA (1-Naphthaleneacetic acid) in roots of 3-day-old seedlings after 2-h and 6-h treatment. Arabidopsis thaliana (L). Heynh., Col-0 seeds were germinated vertically on solid medium derived from standard MS medium supplemented with 10 μM NPA (1-N-Naphthylphthalamic acid). Three days after germination, plants were transferred to 10 μM NAA (1-Naphthaleneacetic acid) or 50 μM naxillin for 2 and 6 hours. Plants were sampled before (Roots at T0, NPA) or after treatment (Roots at T1 and T2). RNA isolation was performed on 500 root sections (only root without meristems) for each sample. All sampling points were performed in three independent experiments.