Modulation of chromatin by MARs and MAR binding oncogenic transcription factor SMAR1

The orchestration of the events in the cell during the progression of the cell cycle is modulated by various phenomenon which are regulated by structural modules of the cell. The nucleus is a major hub for all these regulatory units which harbour the nuclear matrix, matrix proteins and chromatin. The histone modifications etch a complex code on the chromatin and the matrix proteins in consort with the histone code regulate the gene expression. SMAR1 is a matrix attachment region binding protein that interacts with chromatin modulators like HDAC1, Sin3A and causes chromatin condensation. SMAR1 modulates the chromatin at the Vβ locus and plays a prominent role in V(D)J recombination. Such indispensable function of SMAR1 by the modulation of chromatin in the context of malignancy and V(D)J recombination emphasizes that MAR binding proteins regulate the complex events of the cell and perturbed expression causes disease conditions.     

Abnormal V(D)J recombination of T cell receptor beta locus in SMAR1 transgenic mice

Scaffold/matrix-associated region-1-binding protein (SMAR1) specifically interacts with the MARbeta sequence, which is located 400-bp upstream of the murine TCRbeta enhancer and is highly expressed during the DP stage of thymocyte development. To further analyze the functions of SMAR1, transgenic mice were generated that express SMAR1 in a tissue-independent manner. SMAR1-overexpressing mice exhibit severely altered frequency of the T cells expressing commonly used Vbetas (Vbeta5.1/5.2 and Vbeta8.1/8.2/8.3). The rearrangements of Vbeta5.1/5.2, Vbeta8.1/8.2/8.3 loci are also reduced in SMAR1 transgenic mice. The T cells in SMAR1 transgenic mice exhibit a mild perturbation at the early DN stage. SMAR1 transgenic mice exhibit hypercellular lymph nodes and spleen accompanied with prominent architectural defects in these organs. These results indicate that SMAR1 plays an important role in the regulation of T cell development as well as V(D)J recombination besides maintaining the architecture of the lymphoid organs.     

Genetic ablation of the CDP/Cux protein C terminus results in hair cycle defects and reduced male fertility

Murine CDP/Cux, a homologue of the Drosophila Cut homeoprotein, modulates the promoter activity of cell cycle-related and cell-type-specific genes. CDP/Cux interacts with histone gene promoters as the DNA binding subunit of a large nuclear complex (HiNF-D). CDP/Cux is a ubiquitous protein containing four conserved DNA binding domains: three Cut repeats and a homeodomain. In this study, we analyzed genetically targeted mice (Cutl1(tm2Ejn), referred to as Delta C) that express a mutant CDP/Cux protein with a deletion of the C terminus, including the homeodomain. In comparison to the wild-type protein, indirect immunofluorescence showed that the mutant protein exhibited significantly reduced nuclear localization. Consistent with these data, DNA binding activity of HiNF-D was lost in nuclear extracts derived from mouse embryonic fibroblasts (MEFs) or adult tissues of homozygous mutant (Delta C(-/-)) mice, indicating the functional loss of CDP/Cux protein in the nucleus. No significant difference in growth characteristics or total histone H4 mRNA levels was observed between wild-type and Delta C(-/-) MEFs in culture. However, specific histone genes (H4.1 and H1) containing CDP/Cux binding sites have reduced expression levels in homozygous mutant MEFs. Stringent control of growth and differentiation appears to be compromised in vivo. Homozygous mutant mice have stunted growth (20 to 50% weight reduction), a high postnatal death rate of 60 to 70%, sparse abnormal coat hair, and severely reduced fertility. The deregulated hair cycle and severely diminished fertility in Cutl1(tm2Ejn/tm2Ejn) mice suggest that CDP/Cux is required for the developmental control of dermal and reproductive functions.     

A novel colonic repressor element regulates intestinal gene expression by interacting with Cux/CDP

Intestinal gene regulation involves mechanisms that direct temporal expression along the vertical and horizontal axes of the alimentary tract. Sucrase-isomaltase (SI), the product of an enterocyte-specific gene, exhibits a complex pattern of expression. Generation of transgenic mice with a mutated SI transgene showed involvement of an overlapping CDP (CCAAT displacement protein)-GATA element in colonic repression of SI throughout postnatal intestinal development. We define this element as CRESIP (colon-repressive element of the SI promoter). Cux/CDP interacts with SI and represses SI promoter activity in a CRESIP-dependent manner. Cux/CDP homozygous mutant mice displayed increased expression of SI mRNA during early postnatal development. Our results demonstrate that an intestinal gene can be repressed in the distal gut and identify Cux/CDP as a regulator of this repression during development.