Transcription corepressors are general regulators controlling the expression of genes involved in multiple signaling pathways and developmental programs. Repression is mediated through mechanisms including the stabilization of a repressive chromatin structure over control regions and regulation of Mediator function inhibiting RNA polymerase II activity. Using whole-genome arrays we show that the Arabidopsis thaliana corepressor LEUNIG, a member of the GroTLE transcription corepressor family, regulates the expression of multiple targets in vivo. LEUNIG has a role in the regulation of genes involved in a number of different physiological processes including disease resistance, DNA damage response, and cell signaling. We demonstrate that repression of in vivo LEUNIG targets is achieved through histone deacetylase (HDAC)-dependent and -independent mechanisms. HDAC-dependent mechanisms involve direct interaction with HDA19, a class 1 HDAC, whereas an HDAC-independent repression activity involves interactions with the putative Arabidopsis Mediator components AtMED14/SWP and AtCDK8/HEN3. We suggest that changes in chromatin structure coupled with regulation of Mediator function are likely to be utilized by LEUNIG in the repression of gene transcription.The Arabidopsis thaliana gene LEUNIG (LUG) encodes a member of the conserved transcription corepressor family that includes Tup1 in yeast (Saccharomyces cerevisiae, Schizosaccharomyces pombe, and Candida albicans), Groucho (Gro) in Drosophila melanogaster, and Transducin-Like Enhancer of split (TLE) in mammals. These corepressors do not possess DNA binding motifs but repress a diverse number of target genes through targeted recruitment by site-specific DNA binding transcription factors. In Arabidopsis, LUG represses target gene transcription by interacting with DNA binding transcription factors through an adaptor protein, SEUSS (SEU), in a fashion analogous to the interaction between the yeast corepressor components Tup1 and Ssn6 (27,28). Once recruited, corepressors mediate repression through mechanisms that include stabilization of a repressive chromatin structure over control regions, inhibition of recruitment of the transcription machinery, and direct inhibition of the RNA polymerase II (Pol II) holoenzyme regulated through the associated Mediator complex. The LUG-SEU corepressor fails to repress transcription in the presence of a histone deacetylase (HDAC) inhibitor, suggesting that one mechanism of LUG repression is through the recruitment of HDAC activities (27). This observation is consistent with Arabidopsis plants that harbor mutations in HDAC-encoding genes displaying pleotropic phenotypes similar to those reported for lug mutants (31). In lug mutant flowers the class C floral homeotic MADS box gene AGAMOUS (AG) is expressed in all four floral whorls, resulting in the ectopic formation of carpels and stamens in the outer two whorls (19), suggesting that LUG is a repressor of AG. In addition, plants harboring mutations in LUG exhibit further pleotropic defects,...
V(D)J recombination of the multigene antigen receptor loci is essential for the generation of a diverse antigen receptor repertoire. Recombination is strictly regulated, occurring only in lymphocytes due to restricted expression of the recombination activating gene enzymes, RAG1 and RAG2, therein. Further, T cell receptors only recombine in T cells, B cell receptors only recombine in B cells, and the loci only recombine at specific stages in lymphocyte differentiation. In B cells, the Igh recombines before the Ig light chains. Finally some antigen receptor loci (e.g. the Igh) have two ordered recombination events. A D gene first recombines with a J gene on both alleles, followed by recombination of a V gene to the DJ recombined segment. Once a productive VDJ rearrangement has been generated, further V to DJ recombination is prevented on the second allele, a process termed allelic exclusion, which in B cells ensures that each B cell expresses a monoclonal IgH (1).Ordered recombination is crucial for antigen receptor integrity, but key questions remain: how is recombination order achieved, and how is it regulated? Numerous studies have suggested that order is achieved through alterations in the chromatin conformation of individual gene domains at sequential stages of lymphocyte development (2). In the mouse Igh locus, the D-J-C region acquires histone post-translational modifications characteristic of open chromatin before the V region (3, 4). Non-coding RNA transcripts, including I, generated from E, located 3Ј of the J genes (5), and o, transcribed from the promoter of the most 3Ј D gene, DQ52, occur on germ line alleles (6). Following D to J recombination, non-coding transcripts are generated from the V genes (7,8). Furthermore, extensive antisense intergenic transcription occurs throughout the D and J domains before D to J, and then throughout the V domain before V to DJ recombination (9, 10). Nuclear positioning may also play a role in ordered V(D)J recombination. The Igh locus is tethered at the nuclear periphery via the V region in non-B cells (11,12). Relocation toward euchromatic regions occurs preferentially from the DJC end, favoring D to J recombination. Furthermore, locus compaction through DNA looping is required for distal V gene recombination (13,14). Several transcription factors, including Pax5 (13), YY1 (15), and Ikaros (16), play a role in looping, and in their absence, only the D-proximal V genes recombine. Following productive V(D)J recombination and cell surface expression of an IgH polypeptide, several of the above processes are reversed to silence V to DJ recombination of the second allele by allelic exclusion. Both Igh V regions decontract, V region germ line transcription is lost, and the second Igh allele is recruited to pericentric heterochromatin via the D-distal V genes (1). In contrast, both DJC regions remain transcriptionally active (9, 17). Thus, there is differential chromatin regulation of both activation and inactivation of the DJC versus V regions of the Igh locus.
Cellular identity is determined by the switching on and off of lineage-specific genes. This dynamic process is regulated by a highly co-ordinated series of chromatin remodelling mechanisms that control DNA accessibility to facilitate transcription, replication and recombination. The identity of an individual B-lymphocyte is defined by the expression of a unique antibody protein, composed of two identical immunoglobulin heavy and two identical light chain polypeptides, which recognize a single foreign antigen with high specificity. However, the mammalian adaptive immune system requires an enormous variety of antibody-expressing B cells to combat the millions of foreign antigens it may encounter. This diversity is generated primarily at the multigene immunoglobulin loci by V(D)J recombination, a specialised form of DNA recombination in which numerous variable (V), diversity (D) and joining (J) genes are cut and pasted together in a strict order to allow shuffling of immunoglobulin genes. The mouse immunoglobulin heavy chain (Igh) locus is the largest known multigene locus. It spans approximately 3 Mb and comprises more than 200 genes. Its size and complexity pose an enormous logistic challenge to the chromatin remodelling machinery, but recent major advances in our understanding of how the 200 genes are shuffled have begun to reveal an exquisitely co-ordinated set of chromatin remodelling mechanisms which exploit every aspect of nuclear dynamics, and provide a global view of multigene regulation. This review will explore the numerous processes implicated in opening up and positioning of the locus to enable shuffling of the Igh locus genes, including non-coding RNA transcription, histone modifications, transcription factors, nuclear relocation and locus contraction.
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