Summary of Recent Advances The SAGA complex provides a paradigm for multi-subunit histone modifying complexes. Although first characterized as a histone acetyltransferase, due to the Gcn5 subunit, SAGA is now known to contain a second activity, a histone deubiqutinase, as well as subunits important for interactions with transcriptional activators and the general transcription machinery. The functions of SAGA in transcriptional activation are well-established in S. cerevisiae. Recent studies in S. pombe, Drosophila, and mammalian systems reveal that SAGA also has important roles in transcript elongation, the regulation of protein stability, and telomere maintenance. These functions are essential for normal embryo development in flies and mice, and mutations or altered expression of SAGA subunits correlate with neurological disease and aggressive cancers in humans.
Reprogramming of somatic cells to a pluripotent state via expression of Oct4, Klf4, Myc, and Sox2 is a multistep process involving phased changes in gene expression. Here, we focus on the later stages of reprogramming, termed maturation and stabilization. We show that the stabilization phase and the acquisition of pluripotency are dependent on the removal of transgene expression late in the maturation phase. Clonal analysis of cells undergoing reprogramming revealed subsets of stabilization-competent (SC) and stabilization-incompetent (SI) cells. SC clones acquire a competency gene-expression signature late in the maturation phase. Functional analysis of SC signature genes identified enhancers of the transition to the stabilization phase and a distinct subset of genes required for the maintenance of pluripotency. Thus, the acquisition and maintenance of pluripotency are regulated by distinct molecular networks, and a specific regulatory program not previously implicated in reprogramming is required for the transition to transgene independence.
Networks of coordinated alternative splicing (AS) events play critical roles in development and disease. However, a comprehensive knowledge of the factors that regulate these networks is lacking. We describe a high-throughput system for systematically linking trans-acting factors to endogenous RNA regulatory events. Using this system, we identify hundreds of factors associated with diverse regulatory layers that positively or negatively control AS events linked to cell fate. Remarkably, more than one-third of the regulators are transcription factors. Further analyses of the zinc finger protein Zfp871 and BTB/POZ domain transcription factor Nacc1, which regulate neural and stem cell AS programs, respectively, reveal roles in controlling the expression of specific splicing regulators. Surprisingly, these proteins also appear to regulate target AS programs via binding RNA. Our results thus uncover a large "missing cache" of splicing regulators among annotated transcription factors, some of which dually regulate AS through direct and indirect mechanisms.
Embryonic stem cells are maintained in a self-renewing and pluripotent state by multiple regulatory pathways. Pluripotent-specific transcriptional networks are sequentially reactivated as somatic cells reprogram to achieve pluripotency. How epigenetic regulators modulate this process and contribute to somatic cell reprogramming is not clear. Here we performed a functional RNAi screen to identify the earliest epigenetic regulators required for reprogramming. We identified components of the SAGA histone acetyltransferase complex, in particular Gcn5, as critical regulators of reprogramming initiation. Furthermore, we showed in mouse pluripotent stem cells that Gcn5 strongly associates with Myc and that, upon initiation of somatic reprogramming, Gcn5 and Myc form a positive feed-forward loop that activates a distinct alternative splicing network and the early acquisition of pluripotency-associated splicing events. These studies expose a Myc-SAGA pathway that drives expression of an essential alternative splicing regulatory network during somatic cell reprogramming.
Cilia are hair-like cellular protrusions important in many aspects of eukaryotic biology. For instance, motile cilia enable fluid movement over epithelial surfaces, while primary (sensory) cilia play roles in cellular signalling. The molecular events underlying cilia dynamics, and particularly their disassembly, are not well understood. Phosphatase and tensin homologue (PTEN) is an extensively studied tumour suppressor, thought to primarily act by antagonizing PI3-kinase signalling. Here we demonstrate that PTEN plays an important role in multicilia formation and cilia disassembly by controlling the phosphorylation of Dishevelled (DVL), another ciliogenesis regulator. DVL is a central component of WNT signalling that plays a role during convergent extension movements, which we show here are also regulated by PTEN. Our studies identify a novel protein substrate for PTEN that couples PTEN to regulation of cilia dynamics and WNT signalling, thus advancing our understanding of potential underlying molecular etiologies of PTEN-related pathologies.
Posttranslational modifications of histone proteins play important roles in the modulation of gene expression. The Saccharomyces cerevisiae (yeast) 2-MDa SAGA (Spt-Ada-Gcn5) complex, a well-studied multisubunit histone modifier, regulates gene expression through Gcn5-mediated histone acetylation and Ubp8-mediated histone deubiquitination. Using a proteomics approach, we determined that the SAGA complex also deubiquitinates nonhistone proteins, including Snf1, an AMP-activated kinase. Ubp8-mediated deubiquitination of Snf1 affects the stability and phosphorylation state of Snf1, thereby affecting Snf1 kinase activity. Others have reported that Gal83 is phosphorylated by Snf1, and we found that deletion of UBP8 causes decreased phosphorylation of Gal83, which is consistent with the effects of Ubp8 loss on Snf1 kinase functions. Overall, our data indicate that SAGA modulates the posttranslational modifications of Snf1 in order to fine-tune gene expression levels.Ubiquitination of cellular targets regulates many biological processes, from intracellular trafficking to gene expression. Although ubiquitination by ubiquitin (Ub) ligases is widely studied, less is known about subsequent deubiquitination (DUB) of cellular substrates. The identification of genes coding 16 deubiquitinases in the Saccharomyces cerevisiae (yeast) genome and genes coding at least 60 deubiquitinases in the human genome suggests that not only is deubiquitination important but also that deubiquitination may also occur in a substratespecific manner to regulate specific cellular processes. Despite the lack of knowledge of the targets of many of these deubiquitinases, it is known that some of these enzymes impact cellular growth and function (3,21,46). Overexpression of certain deubiquitinases is associated with progression of malignancy in neuroblastomas and a variety of carcinomas, indicating that these enzymes may be oncogenic (27,31,38).USP22, a deubiquitinase associated with the SAGA histone acetyltransferase (HAT) complex, was identified as a member of an 11-gene "death-from-cancer" signature that serves as a predictor of treatment resistance, aggressive growth, and metastasis of human tumors when overexpressed (7,8). The SAGA complex is highly conserved, and its functions are best characterized in yeast (4,9,17,23,35). In addition to acetylating histone H3 via the Gcn5 subunit, SAGA also proteolytically cleaves ubiquitin moieties from histone H2B via the Ubp8 subunit, which is an ortholog of USP22 (13, 47). Ubp8-mediated deubiquitination of histone H2B regulates the expression of target genes by modulating the level of histone H3 lysine 4 methylation, a mark that is associated with active transcription (13). In addition, Ubp8 facilitates the recruitment of the Cterminal domain kinase (Ctk1) to target gene promoters via histone H2B deubiquitination, which facilitates the transition from transcription initiation to elongation (43).Interestingly, recent studies indicate that the functions of USP22 extend beyond histone H2B, as it also deubiquiti...
The yeast Cyc8 (also known as Ssn6)-Tup1 complex regulates gene expression through a variety of mechanisms, including positioning of nucleosomes over promoters of some target genes to limit accessibility to the transcription machinery. To further define the functions of Cyc8-Tup1 in gene regulation and chromatin remodeling, we performed genome-wide profiling of changes in nucleosome organization and gene expression that occur upon loss of CYC8 or TUP1 and observed extensive nucleosome alterations in both promoters and gene bodies of derepressed genes. Our improved nucleosome profiling and analysis approaches revealed low-occupancy promoter nucleosomes (P nucleosomes) at locations previously defined as nucleosome-free regions. In the absence of CYC8 or TUP1, this P nucleosome is frequently lost, whereas nucleosomes are gained at -1 and +1 positions, accompanying up-regulation of downstream genes. Our analysis of public ChIPseq data revealed that Cyc8 and Tup1 preferentially bind TATA-containing promoters, which are also enriched in genes derepressed upon loss of CYC8 or TUP1. These results suggest that stabilization of the P nucleosome on TATA-containing promoters may be a central feature of the repressive chromatin architecture created by the Cyc8-Tup1 corepressor, and that releasing the P nucleosome contributes to gene activation.
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