Identification of <i>cis</i>‐elements regulating the expression of an <i>Arabidopsis</i> histone H4 gene

Chaubet, Nicole; Flénet, Martine; Clément, Bernadette; Brignon, P.; Gigot, Claude

doi:10.1046/j.1365-313x.1996.10030425.x

Cited by 60 publications

(78 citation statements)

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“…Known Cell Cycle-regulated Genes-Although rather few genes are known to be cell cycle-regulated in Arabidopsis, there is direct evidence for regulation of histones (53,59), mitotic cyclins (19, 60 -63), and B-type CDKs (20,22), proliferating cell nuclear antigen, and the CDC6 protein involved in initiation of DNA replication (16,64). We examined the extent to which two classes of likely co-regulated genes were identified as cell cycleregulated and whether known co-regulated genes were assigned to the same or similar clusters.…”

Section: Resultsmentioning

confidence: 99%

“…Phosphorylation of Rb in late G 1 results in activation of E2F-regulated genes including ribonucleotide reductase (100) and CDC6 (16,64). Expression of mitotic cyclins has been shown to depend on specific elements conferring mitotic-specific activation in tobacco and Arabidopsis (61), whereas histone gene expression depends on octamer (Oct) and hexamer (Hex) elements (59). We searched the regions 1 kb upstream of each open reading frame within the regulated gene set for the E2F (TTTYYC-GYY), mitotic-specific activation (YCYAACGGYY), Oct (CGCGGATC), and Hex (CCACGTCA) consensus sequences.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Cell Cycle-regulated Gene Expression inArabidopsis

Menges¹,

Hennig²,

Gruissem³

et al. 2002

Journal of Biological Chemistry

230

172

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Regulated gene expression is an important mechanism for controlling cell cycle progression in yeast and mammals, and genes involved in cell division-related processes often show transcriptional regulation dependent on cell cycle position. Analysis of cell cycle processes in plants has been hampered by the lack of synchronizable cell suspensions for Arabidopsis, and few cell cycle-regulated genes are known. Using a recently described synchrony system, we have analyzed RNA from sequential samples of Arabidopsis cells progressing through the cell cycle using Affymetrix Genearrays. We identify nearly 500 genes that robustly display significant fluctuation in expression, representing the first genomic analysis of cell cycle-regulated gene expression in any plant. In addition to the limited number of genes previously identified as cell cycle-regulated in plants, we also find specific patterns of regulation for genes known or suspected to be involved in signal transduction, transcriptional regulation, and hormonal regulation, including key genes of cytokinin response. Genes identified represent pathways that are cell cycleregulated in other organisms and those involved in plant-specific processes. The range and number of cell cycle-regulated genes show the close integration of the plant cell cycle into a variety of cellular control and response pathways.Cell division is a fundamental biological process and shares conserved features and controls in all eukaryotes (1-3). However, plants have a number of special features that give the control of cell division particular importance, including an indeterminate mode of development, the absence of cell migration, and responsiveness of growth rate and development to changes in environmental conditions. Cell division therefore plays a role both in the developmental processes that create plant architecture and in the modulation of plant growth rate in response to the environment (4, 5). It is therefore not unexpected that plant cell cycle control shows a number of novel aspects, together with conservation of the types of key regulators of cell cycle transitions such as cyclin-dependent kinases (CDKs), 1 CDK inhibitor genes, cyclins, retinoblastoma (Rb) protein homologs, and E2F (6 -16). However, important differences include the absence of direct CDC25 protein phosphatase homologs and the presence of cell cycle-regulated CDKs known as CDKB (17-22). As well as the presence of such novel regulators of the cell cycle, cell division control in plants might also show interactions with plant hormones and developmental regulators as well as with plant-specific processes such as cell wall metabolism. Regulation of gene expression in different phases is proposed to be an important mechanism for control of progression through the cell cycle in yeast and mammalian cells, and around 800 genes have been identified using microarray analysis in both systems as potentially cell cycle-regulated (23-27). The wide scale analysis of cell cycle-regulated expression in plants has been hampered to dat...

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Cell Cycle-regulated Gene Expression inArabidopsis

Menges¹,

Hennig²,

Gruissem³

et al. 2002

Journal of Biological Chemistry

230

172

View full text Add to dashboard Cite

show abstract

“…HISTONE H4 expression, which is expressed predominately during S-phase (Chaubet et al, 1996), peaked sharply at 4 h and then remained relatively low throughout the remainder of the time course ( Figure 8A). FIS1a, FIS1b, DRP3A, PEX11c, PEX11d, and PEX11e ( Figures 8B and 8D) exhibited similar expression profiles at earlier time points with peak expression levels apparent at 2 and 12 h after amphidicolin release.…”

Section: Peroxisome Replication Occurs Before M-phase In Synchronizedmentioning

confidence: 99%

ArabidopsisPEROXIN11c-e, FISSION1b, and DYNAMIN-RELATED PROTEIN3A Cooperate in Cell Cycle–Associated Replication of Peroxisomes

et al. 2008

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Although participation of PEROXIN11 (PEX11), FISSION1 (FISl), and DYNAMIN-RELATED PROTEIN (DRP) has been well established during induced peroxisome proliferation in response to external stimuli, their roles in cell cycle-associated constitutive replication/duplication have not been fully explored. Herein, bimolecular fluorescence complementation experiments with Arabidopsis thaliana suspension cells revealed homooligomerization of all five PEX11 isoforms (PEX11a-e) and heterooligomerizations of all five PEX11 isoforms with FIS1b, but not FIS1a nor DRP3A. Intracellular protein targeting experiments demonstrated that FIS1b, but not FIS1a nor DRP3A, targeted to peroxisomes only when coexpressed with PEX11d or PEX11e. Simultaneous silencing of PEX11c-e or individual silencing of DRP3A, but not FIS1a nor FIS1b, resulted in ;40% reductions in peroxisome number. During G2 in synchronized cell cultures, peroxisomes sequentially enlarged, elongated, and then doubled in number, which correlated with peaks in PEX11, FIS1, and DRP3A expression. Overall, these data support a model for the replication of preexisting peroxisomes wherein PEX11c, PEX11d, and PEX11e act cooperatively during G2 to promote peroxisome elongation and recruitment of FIS1b to the peroxisome membrane, where DRP3A stimulates fission of elongated peroxisomes into daughter peroxisomes, which are then distributed between daughter cells.

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“…Consistent with increased intergenic upstream distances for multistimuli response genes, TATA box-containing genes were also observed to have longer upstream regions (2,370 nucleotides versus 1,737 nucleotides for TATA-less genes, p ¼ 3.4EÀ34). Motifs reported to control housekeeping genes (TELO-box promoter motif [18]; hexamer promoter motif [19]) or implicated to confer tissue-specific expression (LEAFYATAG [20]) were found to be more associated with genes with narrow range of differential expression response, i.e., their expression is constitutive or their differential expression response is very specific.…”

Section: Author Summarymentioning

confidence: 99%

The regulatory code for transcriptional response diversity and its relation to genome structural properties in Arabidopsis thaliana

Walther¹,

Brunnemann²,

Selbig³

2005

PLoS Genet

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Regulation of gene expression via specific cis-regulatory promoter elements has evolved in cellular organisms as a major adaptive mechanism to respond to environmental change. Assuming a simple model of transcriptional regulation, genes that are differentially expressed in response to a large number of different external stimuli should harbor more distinct regulatory elements in their upstream regions than do genes that only respond to few environmental challenges. We tested this hypothesis in Arabidopsis thaliana using the compendium of gene expression profiling data available in AtGenExpress and known cis-element motifs mapped to upstream gene promoter regions and studied the relation of the observed breadth of differential gene expression response with several fundamental genome architectural properties. We observed highly significant positive correlations between the density of ciselements in upstream regions and the number of conditions in which a gene was differentially regulated. The correlation was most pronounced in regions immediately upstream of the transcription start sites. Multistimuli response genes were observed to be associated with significantly longer upstream intergenic regions, retain more paralogs in the Arabidopsis genome, are shorter, have fewer introns, and are more likely to contain TATA-box motifs in their promoters. In abiotic stress time series data, multistimuli response genes were found to be overrepresented among early-responding genes. Genes involved in the regulation of transcription, stress response, and signaling processes were observed to possess the greatest regulatory capacity. Our results suggest that greater gene expression regulatory complexity appears to be encoded by an increased density of cis-regulatory elements and provide further evidence for an evolutionary adaptation of the regulatory code at the genomic layout level. Larger intergenic spaces preceding multistimuli response genes may have evolved to allow greater regulatory gene expression potential.Citation: Walther D, Brunnemann R, Selbig J (2007) The regulatory code for transcriptional response diversity and its relation to genome structural properties in A. thaliana. PLoS Genet 3(2): e11.

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Identification of cis‐elements regulating the expression of an Arabidopsis histone H4 gene

Cited by 60 publications

References 0 publications

Cell Cycle-regulated Gene Expression inArabidopsis

Cell Cycle-regulated Gene Expression inArabidopsis

ArabidopsisPEROXIN11c-e, FISSION1b, and DYNAMIN-RELATED PROTEIN3A Cooperate in Cell Cycle–Associated Replication of Peroxisomes

The regulatory code for transcriptional response diversity and its relation to genome structural properties in Arabidopsis thaliana

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