05-850 Sigma-AldrichAnti-p68 Antibody, clone204

It is widely accepted that different forms of stress activate a common target, p53, yet different outcomes are triggered in a stress-specific manner. For example, activation of p53 by genotoxic agents, such as camptothecin (CPT), triggers apoptosis, while non-genotoxic activation of p53 by Nutlin-3 (Nut3) leads to cell-cycle arrest without significant apoptosis. Such stimulus-specific responses are attributed to differential transcriptional activation of various promoters by p53. In this study, we demonstrate that CPT, but not Nut3, induces miR-203, which downregulates anti-apoptotic bcl-w and promotes cell death in a p53-dependent manner. We find that acetylation of K120 in the DNA-binding domain of p53 augments its association with the Drosha microprocessor and promotes nuclear primary miRNA processing. Knockdown of human orthologue of Males absent On the First (hMOF), the acetyltransferase that targets K120 in p53, abolishes induction of miR-203 and cell death mediated by CPT. Thus, this study reveals that p53 acetylation at K120 plays a critical role in the regulation of the Drosha microprocessor and that post-transcriptional regulation of gene expression by p53 via miRNAs plays a role in determining stress-specific cellular outcomes.

Dnmt3a1 and Dnmt3a2 are two de novo DNA methyltransferases expressed in mouse embryonic stem cells (mESCs). They differ in that a 219-amino-acid (aa) amino (N)-terminal noncatalytic domain is present only in Dnmt3a1. Here, we examined the unique functions of Dnmt3a1 in mESCs by targeting the coding sequence of the Dnmt3a1 N-terminal domain tagged with enhanced green fluorescent protein (GFP) for insertion into the mouse Rosa26 locus. Using these targeted cells (GFP-3a1Nter), we showed that Dnmt3a1 was efficiently recruited to the silenced Oct3/4 and activated Vtn (vitronectin) gene promoters via its unique N-terminal domain. This recruitment affected the two genes in contrasting ways, compromising Oct3/4 gene promoter DNA methylation to prevent consolidation of the silent state while significantly reducing Vtn transcription. We used this negative effect of the Dnmt3a1 N-terminal domain to investigate the extent of transcriptional regulation by Dnmt3a1 in mESCs by using microarrays. A small group of all-trans retinoic acid (tRA)-inducible genes had lower transcript levels in GFP-3a1Nter cells than in wild-type mESCs. Intriguingly, this group included genes that are important for fetal nutrition, placenta development, and metabolic functions and is enriched for a distinct set of imprinted genes. We also identified a larger group of genes that showed higher transcript levels in the GFP-3a1Nter-expressing cells than in wild-type mESCs, including pluripotency factors and key regulators of primordial germ cell differentiation. Thus, Dnmt3a1 in mESCs functions primarily as a negative and to a lesser extent as a positive regulator of transcription. Our findings suggest that Dnmt3a1 positively affects transcription of specific genes at the promoter level and targets chromosomal domains to epigenetically silence gene clusters in mESCs.

MicroRNAs (miRNAs) have emerged as key post-transcriptional regulators of gene expression, involved in diverse physiological and pathological processes. Although miRNAs can function as both tumour suppressors and oncogenes in tumour development, a widespread downregulation of miRNAs is commonly observed in human cancers and promotes cellular transformation and tumorigenesis. This indicates an inherent significance of small RNAs in tumour suppression. However, the connection between tumour suppressor networks and miRNA biogenesis machineries has not been investigated in depth. Here we show that a central tumour suppressor, p53, enhances the post-transcriptional maturation of several miRNAs with growth-suppressive function, including miR-16-1, miR-143 and miR-145, in response to DNA damage. In HCT116 cells and human diploid fibroblasts, p53 interacts with the Drosha processing complex through the association with DEAD-box RNA helicase p68 (also known as DDX5) and facilitates the processing of primary miRNAs to precursor miRNAs. We also found that transcriptionally inactive p53 mutants interfere with a functional assembly between Drosha complex and p68, leading to attenuation of miRNA processing activity. These findings suggest that transcription-independent modulation of miRNA biogenesis is intrinsically embedded in a tumour suppressive program governed by p53. Our study reveals a previously unrecognized function of p53 in miRNA processing, which may underlie key aspects of cancer biology.

Nuclear signaling by estrogens rapidly induces the global recruitment of estrogen receptors (ERs) to thousands of highly specific locations in the genome. Here, we have examined whether ER binding sites that are located distal from the transcription start sites of estrogen target genes are functionally relevant. Similar to ER binding sites near the proximal promoter region, ER binding sites located at distal locations are occupied by ERs after estrogen stimulation. And, like proximal bound ERs, ERs occupied at distal sites can recruit coactivators and the RNA polymerase transcription machinery and mediate specific structural changes to chromatin. Furthermore, ERs occupied at the distal sites are capable of communicating with ERs bound at the promoter region, possibly via long range chromosome looping. In functional analysis, disruption of the response elements in the distal ER binding sites abrogated ER binding and significantly reduced transcriptional response. Finally, sequence comparison of the response elements at the distal sites suggests a high level of conservation across different species. Together, our data indicate that distal ER binding sites are bona fide transcriptional enhancers that are involved in long range chromosomal interaction, transcription complex formation, and distinct structural modifications of chromatin across large genomic spans.

Transcriptional activation of a gene involves an orchestrated recruitment of components of the basal transcription machinery and intermediate factors, concomitant with an alteration in local chromatin structure generated by posttranslational modifications of histone tails and nucleosome remodeling. We provide here a comprehensive picture of events resulting in transcriptional activation of a gene, through evaluating the estrogen receptor-alpha (NR3A1) target pS2 gene promoter in MCF-7 cells. This description integrates chromatin remodeling with a kinetic evaluation of cyclical networks of association of 46 transcription factors with the promoter, as determined by chromatin immunoprecipitation assays. We define the concept of a "transcriptional clock" that directs and achieves the sequential and combinatorial assembly of a transcriptionally productive complex on a promoter. Furthermore, the unanticipated findings of key roles for histone deacetylases and nucleosome-remodeling complexes in limiting transcription implies that transcriptional activation is a cyclical process that requires both activating and repressive epigenetic processes.

Modulation of the interaction between U1 snRNP and the 5' splice site (5'ss) is a key event that governs 5'ss recognition and spliceosome assembly. Using the methylene blue-mediated cross-linking method (Z. R. Liu, A. M. Wilkie, M. J. Clemens, and C. W. Smith, RNA 2:611-621, 1996), a 65-kDa protein (p65) was shown to interact with the U1-5'ss duplex during spliceosome assembly (Z. R. Liu, B. Sargueil, and C. W. Smith, Mol. Cell. Biol. 18:6910-6920, 1998). In this report, p65 was identified as p68 RNA helicase and shown to be essential for in vitro pre-mRNA splicing. Depletion of endogenous p68 RNA helicase does not affect the loading of the U1 snRNP to the 5'ss during early stage of splicing. However, dissociation of the U1 from the 5'ss is largely inhibited. The data suggest that p68 RNA helicase functions in destabilizing the U1-5'ss interactions. Furthermore, depletion of p68 RNA helicase arrested spliceosome assembly at the prespliceosome stage, suggesting that p68 may play a role in the transition from prespliceosome to spliceosome.

The p68 protein is a highly conserved nuclear antigen that is thought to be important in the regulation of cell growth and division. It is found in dividing cells of all mammals and amphibians tested, but not in quiescent cells. The protein shows a distinct granular distribution in the nucleus and is induced within four hours of serum stimulation of quiescent mouse fibroblasts. The p68 protein was first identified because of its specific immunological cross-reaction with the DNA tumour virus nuclear oncogene SV40 large T, detected with the anti-SV40 large T monoclonal antibody DL3C4, now renamed PAb204. Sequencing of human complementary DNA coding for the growth-regulated p68 nuclear protein has revealed the molecular basis for its cross-reaction with SV40 large T antigen and its extensive homology with the translation initiation factor eIF-4A. The sequence similarity between p68 and eIF-4A is interesting because eIF-4A acts as an ATP-dependent RNA helicase and T antigen is an ATP-dependent DNA helicase. We suggest that p68 could be a DNA or RNA helicase in the cell nucleus which is involved in replication, transcription or RNA processing and is required for cell growth.

The large T protein coded by the early region of simian virus 40 (SV40) is involved in the induction and maintenance of cell transformation. It is not clear which properties of T are important in causing the transformation, since the protein is multifunctional. To clarify the action of T proteins in transformation, we have prepared several monoclonal antibodies directed against different regions of the T molecule. One of these antibodies, DL 3C4, recognizes an antigenic determinant on T that is also present on a host cell protein of molecular weight 68,000. This cross-reactive 68K protein is located within the nucleus of all mammalian cell types examined and has a characteristic granular distribution as shown by immunofluorescence. The antigenic determinant recognized by DL 3C4 is resistant to denaturation. Studies on Adeno-SV40 hybrid viruses show that the antigenic site on T is coded for by sequences located between 0.44 and 0.29 on the SV40 map.