Characterization of wheat DP, a heterodimerization partner of the plant E2F transcription factor which stimulates E2F–DNA binding

AbstractRecent studies suggest that the G1/S transition in plants depends on the activity of E2F transcription factors. In animal cells, E2Fs interact with DP proteins, whose identification in plants has been elusive, so far. Here we show that although an E2F-containing DNA-binding activity can be detected in plant cell extracts, purified E2F protein binds poorly to DNA. In a yeast two-hybrid screening, using wheat E2F as a bait, we have isolated a cDNA clone encoding a wheat DP (TmDP) protein. TmDP is expressed ubiquitously and exhibits a domain organization similar to animal DPs. Contrary to the specificity observed for the plant RBR/E2F interaction, human and plant E2F and DP proteins can interact in a heterologous manner. Purified TmDP protein stimulates E2F–DNA complex formation

Relationship of Oligomerization to DNA Binding of Wheat Dwarf Virus RepA and Rep Proteins

AbstractMembers of the genus Mastrevirus (family Geminiviridae) produce a complementary-sense (c-sense) transcription unit with the potential to encode two proteins, RepA and Rep. In the present work, we have studied the DNA–protein complexes formed by the Wheat dwarf virus (WDV) RepA protein within the WDV large intergenic region. WDV RepA forms large nucleoprotein complexes near the TATA boxes of the viral complementary-sense and virion-sense (v-sense) promoters (the RepA C- and V-complexes, respectively), a location similar to those of WDV Rep–DNA complexes but with distinct DNase I footprints. We have also studied the relationship of oligomerization of WDV RepA and Rep proteins to DNA–protein complex formation. Using chemical cross-linking, we have determined that both WDV proteins can form oligomers in solution. Interestingly, the pH is critical for the monomer–oligomer equilibrium and small changes produce a displacement in such a way that at pH ≤ 7.0, the predominant species is an octamer while at pH ≥ 7.4 it is a monomer. Complex formation is also strongly affected by pH and occurs more efficiently at pH 7.0–7.4. We found that preformed oligomers interact very poorly with DNA. Thus, our data are consistent with a stepwise model for protein–DNA complex assembly in which monomers interact with DNA and then with other monomers to assemble an oligomeric structure on the DNA. These results may be relevant for studies on the DNA binding, replication, and transcription properties of geminivirus proteins

ASF1 Proteins are Involved in UV-induced DNA Damage Repair and are Cell Cycle Regulated by E2F Transcription Factors in Arabidopsis thaliana

ASF1 is a key histone H3/H4 chaperone that participates in a variety of DNA and chromatin-related processes, including DNA repair, where chromatin assembly and disassembly is of primaryrelevance. Information concerning the role of ASF1 proteins in post-UV response in higher plants is currently limited. In Arabidopsis thaliana, an initial analysis of in vivo localization of ASF1A andASF1B indicates that both proteins are mainly expressed in proliferative tissues. In silico promoteranalysis identified ASF1A and ASF1B as potential targets of E2F transcription factors. Theseobservations were experimentally validated, both in vitro by electrophoretic mobility shift assays, and in vivo by chromatin immunoprecipitation assays and expression analysis using transgenic plants with altered levels of different E2F transcription factors. These data suggest that ASF1A and ASF1B are regulated during cell cycle progression through E2F transcription factors. In addition, we found that ASF1A and ASF1B are associated with the UV-B induced DNA damage response in A. thaliana. Transcript levels of ASF1A and ASF1B were increased following a UV-B-treatment. Consistent with a potential role in ultraviolet-B (UV-B) response, RNAi silenced plants of both genes showed increased sensitivity to UV-B compared to wild type plants. Finally, by coimmunoprecipitation analysis, we found that ASF1 physically interacts with N-terminal acetylated histones H3 and H4, and with acetyltransferases of the HAM subfamily, which are known to be involved in cell cycle control and DNA repair, among other functions. Together, here we provide evidence that ASF1A and ASF1B are regulated by cell cycle progression and are involved in DNA repair after UV-B irradiation.Fil: Lario, Luciana Daniela. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Rosario. Centro de Estudios Fotosintéticos y Bioquímicos (i); ArgentinaFil: Gutierrez, Crisanto. Universidad Autónoma de Madrid; EspañaFil: Ramirez Parra, Elena. Universidad Politecnica de Madrid; EspañaFil: Spampinato, Claudia Patricia. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Rosario. Centro de Estudios Fotosintéticos y Bioquímicos (i); ArgentinaFil: Casati, Paula. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Rosario. Centro de Estudios Fotosintéticos y Bioquímicos (i); Argentin

Auxin and epigenetic regulation of SKP2B, an F-box that represses lateral root formation

In plants, lateral roots originate from pericycle founder cells that are specified at regular intervals along the main root. Here, we show that Arabidopsis (Arabidopsis thaliana) SKP2B (for S-Phase Kinase-Associated Protein2B), an F-box protein, negatively regulates cell cycle and lateral root formation as it represses meristematic and founder cell divisions. According to its function, SKP2B is expressed in founder cells, lateral root primordia and the root apical meristem. We identified a novel motif in the SKP2B promoter that is required for its specific root expression and auxin-dependent induction in the pericycle cells. Next to a transcriptional control by auxin, SKP2B expression is regulated by histone H3.1/H3.3 deposition in a CAF-dependent manner. The SKP2B promoter and the 59 end of the transcribed region are enriched in H3.3, which is associated with active chromatin states, over H3.1. Furthermore, the SKP2B promoter is also regulated by H3 acetylation in an auxin-and IAA14-dependent manner, reinforcing the idea that epigenetics represents an important regulatory mechanism during lateral root formation

The genes encoding Arabidopsis ORC subunits are E2F targets and the two ORC1 genes are differently expressed in proliferating and endoreplicating cells

Initiation of eukaryotic DNA replication depends on the function of pre-replication complexes (pre-RC), one of its key component being the six subunits origin recognition complex (ORC). In spite of a significant degree of conservation among ORC proteins from different eukaryotic sources, the regulation of their availability varies considerably in different model systems and cell types. Here, we show that the six ORC genes of Arabidopsis thaliana are regulated at the transcriptional level during cell cycle and development. We found that Arabidopsis ORC genes, except AtORC5, contain binding sites for the E2F family of transcription factors. Expression of AtORC genes containing E2F binding sites peaks at the G1/S-phase. Analysis of AtORC gene expression in plants with reduced E2F activity, obtained by expressing a dominant negative version of DP, the E2F heterodimerization partner, and with increased E2F activity, obtained by inactivation of the retinoblastoma protein, led us to conclude that all AtORC genes, except AtORC5 are E2F targets. Interestingly, Arabidopsis contains two AtORC1 (a and b) genes, highly conserved at the amino acid level but with unrelated promoter sequences. AtORC1b expression is restricted to proliferating cells. However, AtORC1a is preferentially expressed in endoreplicating cells based on our analysis in endoreplicating tissues and in a mutant with altered endocycle pattern. This suggests a differential expression of the two ORC1 genes in Arabidopsis

Retrotransposons are specified as DNA replication origins in the gene-poor regions of Arabidopsis heterochromatin

Genomic stability depends on faithful genome replication. This is achieved by the concerted activity of thousands of DNA replication origins (ORIs) scattered throughout the genome. The DNA and chromatin features determining ORI specification are not presently known. We have generated a high-resolution genome-wide map of 3230 ORIs in cultured Arabidopsis thaliana cells. Here, we focused on defining the features associated with ORIs in heterochromatin. In pericentromeric gene-poor domains ORIs associate almost exclusively with the retrotransposon class of transposable elements (TEs), in particular of the Gypsy family. ORI activity in retrotransposons occurs independently of TE expression and while maintaining high levels of H3K9me2 and H3K27me1, typical marks of repressed heterochromatin. ORI-TEs largely colocalize with chromatin signatures defining GC-rich heterochromatin. Importantly, TEs with active ORIs contain a local GC content higher than the TEs lacking them. Our results lead us to conclude that ORI colocalization with retrotransposons is determined by their transposition mechanism based on transcription, and a specific chromatin landscape. Our detailed analysis of ORIs responsible for heterochromatin replication has implications on the mechanisms of ORI specification in other multicellular organisms in which retrotransposons are major components of heterochromatin and of the entire genome

Distinct roles of Arabidopsis ORC1 proteins in DNA replication and heterochromatic H3K27me1 deposition

13 Pág.Most cellular proteins involved in genome replication are conserved in all eukaryotic lineages including yeast, plants and animals. However, the mechanisms controlling their availability during the cell cycle are less well defined. Here we show that the Arabidopsis genome encodes for two ORC1 proteins highly similar in amino acid sequence and that have partially overlapping expression domains but with distinct functions. The ancestral ORC1b gene, present before the partial duplication of the Arabidopsis genome, has retained the canonical function in DNA replication. ORC1b is expressed in both proliferating and endoreplicating cells, accumulates during G1 and is rapidly degraded upon S-phase entry through the ubiquitin-proteasome pathway. In contrast, the duplicated ORC1a gene has acquired a specialized function in heterochromatin biology. ORC1a is required for efficient deposition of the heterochromatic H3K27me1 mark by the ATXR5/6 histone methyltransferases. The distinct roles of the two ORC1 proteins may be a feature common to other organisms with duplicated ORC1 genes and a major difference with animal cells.This research was supported by grants BFU2015-68396-R, RTI2018-094793-B-I00 (Ministerio de Ciencia e Innovacion) and AdG_833617 (European Research Council) to C.G., grant LABEX: ANR-10-LABX-0036-NETRNA and ANR-19-CE13-0032-01 to P.G. and S.N., and by institutional grants from Banco de Santander and Fundación Ramón Areces to the CBMSO.Peer reviewe