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:The Arabidopsis basic leucine zipper transcription factor bZIP29 of the bZIP group I TF family, expressed mainly in proliferative tissues, is functionally characterized in this study. In roots, bZIP29 is highly expressed in the quiescent centre and the columella cells of the root apical meristem. Mutant analyses demonstrate that bZIP29 regulates root meristem cell number and root gravitropic responses. RNA-seq transcriptome profiling of the root meristem shows that bZIP29 target genes are linked to cell wall organization, and that gene regulatory networks controlling proper root meristem organization are intensively rewired upon its perturbation.

Project description:DNA methylation is an epigenetic modification that differs between plant organs and tissues, but the extent of variation between cell types is not known. Here, we report single-base resolution whole genome DNA methylomes, mRNA transcriptomes, and small RNA transcriptomes for six cell populations covering the major cell types of the Arabidopsis root meristem. We identify widespread cell type specific patterns of DNA methylation, especially in the CHH sequence context. The genome of the columella root cap is the most highly methylated Arabidopsis cell characterized to date. It is hypermethylated within transposable elements, accompanied by increased abundance of transcripts encoding RNA-directed DNA methylation (RdDM) pathway components and 24 nt small RNAs. Absence of the nucleosome remodeler DECREASED DNA METHYLATION 1, required for maintenance of DNA methylation, and low abundance of histone transcripts involved in heterochromatin formation suggests a loss of heterochromatin may occur in the columella, thus allowing access of RdDM factors to the whole genome, and producing excess 24 nt small RNAs in this tissue. Together, these maps provide new insights into the epigenomic diversity that exists between distinct plant somatic cell types. RNA-seq from six cell populations covering the major cell types of the Arabidopsis root meristem.

Project description:DNA methylation is an epigenetic modification that differs between plant organs and tissues, but the extent of variation between cell types is not known. Here, we report single-base resolution whole genome DNA methylomes, mRNA transcriptomes, and small RNA transcriptomes for six cell populations covering the major cell types of the Arabidopsis root meristem. We identify widespread cell type specific patterns of DNA methylation, especially in the CHH sequence context. The genome of the columella root cap is the most highly methylated Arabidopsis cell characterized to date. It is hypermethylated within transposable elements, accompanied by increased abundance of transcripts encoding RNA-directed DNA methylation (RdDM) pathway components and 24 nt small RNAs. Absence of the nucleosome remodeler DECREASED DNA METHYLATION 1, required for maintenance of DNA methylation, and low abundance of histone transcripts involved in heterochromatin formation suggests a loss of heterochromatin may occur in the columella, thus allowing access of RdDM factors to the whole genome, and producing excess 24 nt small RNAs in this tissue. Together, these maps provide new insights into the epigenomic diversity that exists between distinct plant somatic cell types. MethylC-seq from six cell populations covering the major cell types of the Arabidopsis root meristem.

Project description:DNA methylation is an epigenetic modification that differs between plant organs and tissues, but the extent of variation between cell types is not known. Here, we report single-base resolution whole genome DNA methylomes, mRNA transcriptomes, and small RNA transcriptomes for six cell populations covering the major cell types of the Arabidopsis root meristem. We identify widespread cell type specific patterns of DNA methylation, especially in the CHH sequence context. The genome of the columella root cap is the most highly methylated Arabidopsis cell characterized to date. It is hypermethylated within transposable elements, accompanied by increased abundance of transcripts encoding RNA-directed DNA methylation (RdDM) pathway components and 24 nt small RNAs. Absence of the nucleosome remodeler DECREASED DNA METHYLATION 1, required for maintenance of DNA methylation, and low abundance of histone transcripts involved in heterochromatin formation suggests a loss of heterochromatin may occur in the columella, thus allowing access of RdDM factors to the whole genome, and producing excess 24 nt small RNAs in this tissue. Together, these maps provide new insights into the epigenomic diversity that exists between distinct plant somatic cell types.

Project description:DNA methylation is an epigenetic modification that differs between plant organs and tissues, but the extent of variation between cell types is not known. Here, we report single-base resolution whole genome DNA methylomes, mRNA transcriptomes, and small RNA transcriptomes for six cell populations covering the major cell types of the Arabidopsis root meristem. We identify widespread cell type specific patterns of DNA methylation, especially in the CHH sequence context. The genome of the columella root cap is the most highly methylated Arabidopsis cell characterized to date. It is hypermethylated within transposable elements, accompanied by increased abundance of transcripts encoding RNA-directed DNA methylation (RdDM) pathway components and 24 nt small RNAs. Absence of the nucleosome remodeler DECREASED DNA METHYLATION 1, required for maintenance of DNA methylation, and low abundance of histone transcripts involved in heterochromatin formation suggests a loss of heterochromatin may occur in the columella, thus allowing access of RdDM factors to the whole genome, and producing excess 24 nt small RNAs in this tissue. Together, these maps provide new insights into the epigenomic diversity that exists between distinct plant somatic cell types.

Project description:Myosins are evolutionarily conserved motor proteins that interact with actin filaments to regulate organelle transport, cytoplasmic streaming and cell growth. Plant specific Class XI myosin proteins direct cell division and root organogenesis. However, the roles of Class VIII myosin proteins in plant growth and development are less understood. Here, we investigated the function of an auxin-regulated Class VIII myosin, Arabidopsis thaliana Myosin 1 (ATM1), using genetics and live cell microscopy. ATM1 is a plasmodesmata-localized protein that is enriched in actively dividing cells in the root apical meristem (RAM). Loss of ATM1 function results in impaired primary root growth due to decreased RAM size and reduced cell proliferation in a sugar dependent manner. Examination of stem cell marker line expression in atm1-1 indicated impaired division of the lateral root cap and columella cells and a diminished auxin response. Transcriptome analysis of atm1-1 linked these growth defects to dysregulation of cell cycle and auxin pathway genes. Complementation of ATM1 loss-of- function mutant restored root growth and cell cycle progression in the root meristem. Collectively, these results provide novel evidence that ATM1 functions to influence cell proliferation and differentiation in primary roots in response to auxin and sugar cues.

Project description:Plants modulate gene expression profile in response to nitrate through NIN-LIKE PROTEIN (NLP) transcription factors in order to promote nitrate uptake and utilization. Although there are 9 NLP proteins in Arabidopsis, NLP7 had attracted most of the attention. Here, we focused on NLP2, because the nlp2 and nlp7 knockout mutants displayed different phenotypes. To gain insight into genes whose expression was affected by the nlp2 mutation, we compared gene expression profiles in the wild-type Columiba and the nlp2 mutant that were treated with 10 mM KNO3 for 1 hour. Columbia and nlp2 that were treated with 10 mM KCl for 1 hour were used as controls. We found that nitrate induction of 6 genes was compromised only in the nlp2 mutant.

Project description:Transciptome profileing analysis of wt, nlp6, nlp7 and nlp6nlp7 before nitrate treatment and after 35 minutes of 25mM nitrate induction. NLP7 (NIN-LIKE-PROTEIN 7) (NLP7) is the major transcriptional factor responsible for the primary nitrate response (PNR), but the role of its closest homologue , NLP6, in nitrogen signaling and the interplay between NLP6 and NLP7 remain to be elucidated. In this study, we show that, like NLP7, nuclear localization of NLP6 via a nuclear retention mechanism is nitrate-dependent, but nucleocytosolic shuttling of both NLP6 and NLP7 is independent of each other. Compared to single mutants, the nlp6 nlp7 double mutant displays a synergistic growth retardation phenotype in response to nitrate. The transcriptome analysis of primary nitrate response (the PNR) showed that NLP6 and NLP7 govern ~50% of nitrate-induced genes, with cluster analysis highlighting two distinct patterns. In the A1 cluster, NLP7 plays the major role, whereas in the A2 cluster, NLP6 and NLP7 are partially functionally redundant. Interestingly, comparing the growth phenotype and PNR under high and low nitrate conditions demonstrated that NLP6 and NLP7 exert a more dominant role in the response to high nitrate. Apart from nitrate signaling, NLP6 and NLP7 also participated in ammonium conditions . Growth phenotypes and transcriptome data uncovered revealed that NLP6 and NLP7 are completely functionally redundant, and may acting as repressors in response to ammonium. Other NLP family members also participated in the PNR, with NLP2 and NLP7 acting as broader regulators and NLP4, -5, -6, and -8 regulating PNR in a gene-dependent manner. Thus, our findings indicate that multiple modes of interplay exist between NLP6 and NLP7 that, which differ depending on nitrogen sources and gene clusters. To determine the genome-wide contributions of NLP7 and NLP6 to the overall nitrate response, we performed a transcriptomics analysis on nlp6, nlp7 and nlp6nlp7 for comparison to wild-type (Col-0) plants. A similar approach has been applied previously for NLP7 (Marchive et al., 2013), but not for NLP6. We collected root tissue before nitrate induction and 35 min after nitrate induction and assessed alterations in gene expression.

Project description:the proteome of root cap and non-root cap cells from Arabidopsis after short-term salt stress treatment