Project description:Ramie fibers extracted from the stem barks have been utilized for thousands years in China, and its biosynthetic mechanism is poorly understood. Here, we have characterized and compared the expression profiling of the barks from the top and middle part of stem where the secondary cellular walls (SCWs) of fiber cell have not initiated growth and was thickening, respectively; resulting in 4,520 differential expression (DE) protein-coding transcripts (PCTs), 1,287 DE long noncoding RNAs (lncRNAs), 88 DE miRNAs and 78 DE circular RNAs (circRNAs). Among the 4,520 DE PCTs, 75 were identified to be the homolog of the Arabidopsis SCW-biosynthetic genes. Overexpression of whole_GLEAN_10014861 (a homolog of SND1) in Arabidopsis caused a significant up-regulation in the expression of AtMYB46 and AtMYB83 that are two key regulators for SCW biosynthesis, thus conferring more fiber cells, along with a remarkable thickening in the SCWs of these cells. Bioinformatic prediction revealed 14 of the 75 homolog targeted by 16 noncoding RNAs (including 8 miRNAs and 8 lncRNAs), and two involved in the competing endogenous RNAs networks, indicating a complex regulatory network for the SCW biosynthesis of bast fiber in ramie. This study provides important insights into the bast fiber biosynthesis of ramie.

Project description:To gain novel insights into the molecular mechanisms of fiber secondary cell wall development, fiber transcriptomes of the immature fiber mutant (im) with defective secondary cell wall development and its near-isogenic line, TM-1 (wild-type) were compared using cDNA microarray technology. The expression profiling was performed at 5 developmental time points: 13, 16, 19, 22, and 25dpa. Secondary cell wall development related genes were identified by differentially expressed gene analysis. And these genes could be used as potential candidate genes for manipulation to improve fiber quality.

Project description:The Arabidopsis thaliana NAC domain transcription factor, VASCULAR-RELATED NAC-DOMAIN7 (VND7), acts as a key regulator of xylem vessel differentiation. In order to identify direct target genes of VND7, we performed global transcriptome analysis using Arabidopsis transgenic lines in which VND7 activity could be induced post-translationally. This analysis identified 63 putative direct target genes of VND7, which encode a broad range of proteins, such as transcription factors, IRREGULAR XYLEM proteins and proteolytic enzymes, known to be closely associated with xylem vessel formation. Recombinant VND7 protein binds to several promoter sequences present in candidate direct target genes: specifically, in the promoter of XYLEM CYSTEINE PEPTIDASE1, two distinct regions were demonstrated to be responsible for VND7 binding. We also found that expression of VND7 restores secondary cell wall formation in the fiber cells of inflorescence stems of nst1 nst3 double mutants, as well as expression of NAC SECONDARY WALL THICKENING PROMOTING FACTOR3 (NST3, however, the vessel-type secondary wall deposition was observed only as a result of VND7 expression. These findings indicated that VND7 upregulates, directly and/or indirectly, many genes involved in a wide range of processes in xylem vessel differentiation, and that its target genes are partially different from those of NSTs.

Project description:To gain novel insights into the molecular mechanisms of fiber secondary cell wall development, fiber transcriptomes of the immature fiber mutant (im) with defective secondary cell wall development and its near-isogenic line, TM-1 (wild-type) were compared using cDNA microarray technology. The expression profiling was performed at 5 developmental time points: 13, 16, 19, 22, and 25dpa. Secondary cell wall development related genes were identified by differentially expressed gene analysis. And these genes could be used as potential candidate genes for manipulation to improve fiber quality. Cotton plants were grown under field condition. Flowers were tagged and cotton bolls were collected during Fiber development stages. Total RNA was isolated from fiber bearing ovules of wild-type, TM-1 and immature fiber mutant (im) collected at various (13, 16, 19, 22 and 25 dpa) fiber development stages. A total of 15 hybridizations with three biological replicates including a swap-dye experiment for each fiber developmental stage were employed.

Project description:Microarray analysis was used to identify candidate genes involved in the formation of hydroxycinnamoyl-arabinoxylan (AX) and secondary cell walls in rice. Gene expression in the internode pith parenchyma of Fukei71 (F71), the rice dwarf mutant that accumulates large amounts of hydroxycinnamoyl-AX in its pith parenchyma cells, was compared with the gene expression in wild-type pith parenchyma cells. Gene expression in wild-type whole internodes containing cells with thickened secondary cell walls, such as vascular and cortical fiber cells, was compared to the gene expression in wild-type internode pith parenchyma cells without any secondary cell walls.

Project description:MYB46 functions as a transcriptional switch that turns on the genes necessary for secondary wall biosynthesis. Elucidating the transcriptional regulatory network immediately downstream of MYB46 is crucial to our understanding of the molecular and biochemical processes involved in the biosynthesis and deposition of secondary walls in plants. The transcription factors identified here may include direct activators of secondary wall biosynthesis genes. The current study discovered novel hierarchical relationships among the transcription factors involved in the transcriptional regulation of secondary wall biosynthesis and generated several testable hypotheses.

Project description:Secondary cell wall thickening (SCW) has a significant effect in the growth and development of plants, as well as in the resistance to various biotic and abiotic stresses. It is regulated by a multilevel transcriptional regulatory network, in which VASCULAR-RELATED NAC-DOMAINs (VNDs) act as key regulators. Lignin is an important component of SCW, it has a cooperative regulation with the biosynthesis of flavonoids which also originate from phenylpropanoid pathway. However, there are few studies on SCW thickening and flavonoid biosynthesis in flesh fruits. We want to investigate the role of FvVNDs on cell wall and fruit color development in Fragaria vesca.

Project description:MYB46 functions as a transcriptional switch that turns on the genes necessary for secondary wall biosynthesis. Elucidating the transcriptional regulatory network immediately downstream of MYB46 is crucial to our understanding of the molecular and biochemical processes involved in the biosynthesis and deposition of secondary walls in plants. The transcription factors identified here may include direct activators of secondary wall biosynthesis genes. The current study discovered novel hierarchical relationships among the transcription factors involved in the transcriptional regulation of secondary wall biosynthesis and generated several testable hypotheses. To gain insights into the MYB46-mediated transcriptional regulation, we first established an inducible secondary wall thickening system in Arabidopsis by expressing MYB46 under the control of dexamethasone inducible promoter. Then, we used ATH1 GeneChip microarray to obtain a series of time-course transcriptome profiles with regard to the induction of secondary wall development.

Project description:Xylem consists of three types of cells: vessel cells, also referred to as tracheary elements (TEs), parenchyma cells, and fiber cells. TE differentiation includes two essential processes, programmed cell death (PCD) and secondary cell wall formation. These two processes are tightly coupled. However, little is known about the molecular mechanism of their gene regulation. Here, we show that VASCULAR-RELATED NAC-DOMAIN 6 (VND6), a master regulator of TEs, regulates these processes in a coordinated manner. We first identified specific genes downstream of VND6 by comparing them with those of SECONDARY WALL-ASSOCIATES NAC DOMAIN PROTEIN1 (SND1), a master regulator of xylem fiber cells, with transformed suspension culture cells in microarray experiments.

Project description:In plants, secondary wall thickenings play important roles in various biological processes, although the factors regulating these processes remain to be characterized. We show that expression of chimeric repressors derived from NAC SECONDARY WALL THICKENINGS PROMOTING FACTOR1 (NST1) and NST2 in Arabidopsis resulted in an anther dehiscence defect due to loss of secondary wall thickening in anther endothecium. Plants with double, but not single, T-DNA-tagged lines for NST1 and NST2, had the same anther-indehiscent phenotype as transgenic plants that expressed the individual chimeric repressors, indicating that NST1 and NST2 are redundant in regulating secondary wall thickening in anther walls. The activity of the NST2 promoter was particularly strong in anther tissue, while that of the NST1 promoter was detected in various tissues in which lignified secondary walls develop. Ectopic expression of NST1 or NST2 induced ectopic thickening of secondary walls in various above-ground tissues. Epidermal cells with ectopic thickening of secondary walls had structural features similar to those of tracheary elements. However, among genes involved in the differentiation of tracheary elements, only those related to secondary wall synthesis were clearly upregulated. None of the genes involved in programmed cell death was similarly affected. Our results suggest NAC transcription factors as possible regulators of secondary wall thickening in various tissues. Keywords: transgenic vs wt comparison