Scott Millhouse scite author profile

Trimethylation of histone H3 on lysine 4 (H3K4me3) localizes near the 5' region of genes and is tightly associated with active loci. Several proteins, such as CHD1, BPTF, JMJD2A, and the ING tumor suppressor family, directly recognize this lysine methyl mark. However, how H3K4me3 recognition participates in active transcription remains poorly characterized. Here we identify specific CHD1-interacting proteins via H3K4me3 affinity purification, including numerous factors mediating postinitiation events. Conventional biochemical purification revealed a stable complex between CHD1 and components of the spliceosome. Depletion of CHD1 in extracts dramatically reduced splicing efficiency in vitro, indicating a functional link between CHD1 and the spliceosome. Knockdown of CHD1 and H3K4me3 levels by siRNA reduced association of U2 snRNP components with chromatin and, more importantly, altered the efficiency of pre-mRNA splicing on active genes in vivo. These findings suggest that methylated H3K4 serves to facilitate the competency of pre-mRNA maturation through the bridging of spliceosomal components to H3K4me3 via CHD1.

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The RNA polymerase II C-terminal domain promotes splicing activation through recruitment of a U2AF65–Prp19 complex

David¹,

Boyne²,

Millhouse³

et al. 2011

Genes Dev.

165

159

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Pre-mRNA splicing is frequently coupled to transcription by RNA polymerase II (RNAPII). This coupling requires the C-terminal domain of the RNAPII largest subunit (CTD), although the underlying mechanism is poorly understood. Using a biochemical complementation assay, we previously identified an activity that stimulates CTD-dependent splicing in vitro. We purified this activity and found that it consists of a complex of two wellknown splicing factors: U2AF65 and the Prp19 complex (PRP19C). We provide evidence that both U2AF65 and PRP19C are required for CTD-dependent splicing activation, that U2AF65 and PRP19C interact both in vitro and in vivo, and that this interaction is required for activation of splicing. Providing the link to the CTD, we show that U2AF65 binds directly to the phosphorylated CTD, and that this interaction results in increased recruitment of U2AF65 and PRP19C to the pre-mRNA. Our results not only provide a mechanism by which the CTD enhances splicing, but also describe unexpected interactions important for splicing and its coupling to transcription.

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Analysis of the HIV-1 LTR NF-κB-Proximal Sp Site III: Evidence for Cell Type-Specific Gene Regulation and Viral Replication

et al. 2000

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It has been widely demonstrated that the human immunodeficiency virus type 1 (HIV-1) envelope, specifically the V3 loop of the gp120 spike, evolves to facilitate adaptation to different cellular populations within an infected host. Less energy has been directed at determining whether the viral promoter, designated the long terminal repeat (LTR), also exhibits this adaptive quality. Because of the unique nature of the cell populations infected during the course of HIV-1 infection, one might expect the opportunity for such adaptation to exist. This would permit select viral species to take advantage of the different array of conditions and factors influencing transcription within a given cell type. To investigate this hypothesis, the function of natural variants of the NF-kappaB-proximal Sp element (Sp site III) was examined in human cell line models of the two major cell types infected during the natural course of HIV-1 infection, T cells and monocytes. Utilizing the HIV-1 LAI molecular clone, which naturally contains a high-affinity Sp site III, substitution of low-affinity Sp sites in place of the natural site III element markedly decreased viral replication in Jurkat T cells. However, these substitutions had relatively small effects on viral replication in U-937 monocytic cells. Transient transfections of HIV-1 LAI-based LTR-luciferase constructs into these cell lines suggest that the large reduction in viral replication in Jurkat T cells, caused by low-affinity Sp site III variants, may result from reduced basal as well as Vpr- and Tat-activated LTR activities in Jurkat T cells compared to those in U-937 monocytic cells. When the function of Sp site III was examined in the context of HIV-1 YU-2-based LTR-luciferase constructs, substitution of a high-affinity element in place of the natural low-affinity element resulted in increased basal YU-2 LTR activity in Jurkat T cells and reduced activity in U-937 monocytic cells. These observations suggest that recruitment of Sp family members to Sp site III is of greater importance to the function of the viral promoter in the Jurkat T cell line as compared to the U-937 monocytic cell line. These observations also suggest that other regions of the LTR may compensate for Sp recruitment defects in specific cell populations.

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The C-Terminal Domain of RNA Polymerase II Functions as a Phosphorylation-Dependent Splicing Activator in a Heterologous Protein

Millhouse

Manley

2005

Molecular and Cellular Biology

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RNA polymerase II, and specifically the C-terminal domain (CTD) of its largest subunit, has been demonstrated to play important roles in capping, splicing, and 3 processing of mRNA precursors. But how the CTD functions in these reactions, especially splicing, is not well understood. To address some of the basic questions concerning CTD function in splicing, we constructed and purified two fusion proteins, a protein in which the CTD is positioned at the C terminus of the splicing factor ASF/SF2 (ASF-CTD) and an RS domain deletion mutant protein (ASF⌬RS-CTD). Significantly, compared to ASF/SF2, ASF-CTD increased the reaction rate during the early stages of splicing, detected as a 20-to 60-min decrease in splicing lag time depending on the pre-mRNA substrate. The increased splicing rate correlated with enhanced production of prespliceosomal complex A and the early spliceosomal complex B but, interestingly, not the very early ATP-independent complex E. Additional assays indicate that the RS domain and CTD perform distinct functions, as exemplified by our identification of an activity that cooperates only with the CTD. Dephosphorylated ASF⌬RS-CTD and a glutathione S-transferase-CTD fusion protein were both inactive, suggesting that an RNA-targeting domain and CTD phosphorylation were necessary. Our results provide new insights into the mechanism by which the CTD functions in splicing.Synthesis of mature mRNAs in the nuclei of eukaryotic cells involves a series of pre-mRNA processing events, including the addition of a cap structure to the 5Ј end, removal of intronic sequences (splicing), and 3Ј cleavage and polyadenylation. Recently, it has become increasingly evident that all three mRNA-processing steps are integrated with transcription in vivo, presumably to facilitate accurate and efficient processing of RNA polymerase II (RNAP II) transcripts, and that the RNAP II C-terminal domain (CTD) is important for all three processing reactions (2,24,36,48). The CTD is conserved among eukaryotes and consists of multiple heptapeptide repeats with the consensus sequence YSPTSPS (9). The number of repeats varies from 26 or 27 in the yeast Saccharomyces cerevisiae to 52 in mammals. The heptapeptide consensus contains five potential phosphoacceptor amino acids, but experimental evidence suggests that the serines (or threonines) at positions 2 and 5 are the predominant sites of phosphorylation (63). Two forms of RNAP II can be distinguished based on the phosphorylation status of CTD, a hypophosphorylated IIA form, which preferentially enters the preinitiation complex at the promoter, and a hyperphosphorylated IIO form, which is associated with elongation complexes (12). More recently, different phosphorylated forms of RNAP II have been observed on genes depending on the location of the polymerase along the gene (7, 33), and specific kinases have been implicated in directing serine-specific phosphorylation of the CTD during the transcription cycle (16,49,56,65).Splicing of most mRNAs occurs in a large macromolecular complex compo...

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Scott Millhouse

Recognition of Trimethylated Histone H3 Lysine 4 Facilitates the Recruitment of Transcription Postinitiation Factors and Pre-mRNA Splicing

The RNA polymerase II C-terminal domain promotes splicing activation through recruitment of a U2AF65–Prp19 complex

Analysis of the HIV-1 LTR NF-κB-Proximal Sp Site III: Evidence for Cell Type-Specific Gene Regulation and Viral Replication

The C-Terminal Domain of RNA Polymerase II Functions as a Phosphorylation-Dependent Splicing Activator in a Heterologous Protein

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