DSIF and RNA polymerase II CTD phosphorylation coordinate the recruitment of Rpd3S to actively transcribed genes

The spt5 C-terminal region recruits yeast 3' RNA cleavage factor I

During transcription elongation, RNA polymerase II (Pol II) binds the general elongation factor Spt5. Spt5 contains a repetitive C-terminal region (CTR) that is required for cotranscriptional recruitment of the Paf1 complex (D. L. Lindstrom et al., Mol. Cell. Biol. 23:1368-1378, 2003; Z. Zhang, J. Fu, and D. S. Gilmour, Genes Dev. 19:1572-1580, 2005). Here we report a new role of the Spt5 CTR in the recruitment of 3' RNA-processing factors. Chromatin immunoprecipitation (ChIP) revealed that the Spt5 CTR is required for normal recruitment of pre-mRNA cleavage factor I (CFI) to the 3' ends of Saccharomyces cerevisiae genes. RNA contributes to CFI recruitment, as RNase treatment prior to ChIP further decreases CFI ChIP signals. Genome-wide ChIP profiling detected occupancy peaks of CFI subunits around 100 nucleotides downstream of the polyadenylation (pA) sites of genes. CFI recruitment to this defined region may result from simultaneous binding to the Spt5 CTR, to nascent RNA containing the pA sequence, and to the elongating Pol II isoform that is phosphorylated at serine 2 (S2) residues in its C-terminal domain (CTD). Consistent with this model, the CTR interacts with CFI in vitro but is not required for pA site recognition and transcription termination in vivo.

The Roles of the Paf1 Complex and Associated Histone Modifications in Regulating Gene Expression

The conserved Paf1 complex (Paf1C) carries out multiple functions during transcription by RNA polymerase (pol) II, and these functions are required for the proper expression of numerous genes in yeast and metazoans. In the elongation stage of the transcription cycle, the Paf1C associates with RNA pol II, interacts with other transcription elongation factors, and facilitates modifications to the chromatin template. At the end of elongation, the Paf1C plays an important role in the termination of RNA pol II transcripts and the recruitment of proteins required for proper RNA 3′ end formation. Significantly, defects in the Paf1C are associated with several human diseases. In this paper, we summarize current knowledge on the roles of the Paf1C in RNA pol II transcription.

Updating the CTD Story: From Tail to Epic

Eukaryotic RNA polymerase II (RNAPII) not only synthesizes mRNA but also coordinates transcription-related processes via its unique C-terminal repeat domain (CTD). The CTD is an RNAPII-specific protein segment consisting of repeating heptads with the consensus sequence Y₁S₂P₃T₄S₅P₆S₇ that has been shown to be extensively post-transcriptionally modified in a coordinated, but complicated, manner. Recent discoveries of new modifications, kinases, and binding proteins have challenged previously established paradigms. In this paper, we examine results and implications of recent studies related to modifications of the CTD and the respective enzymes; we also survey characterizations of new CTD-binding proteins and their associated processes and new information regarding known CTD-binding proteins. Finally, we bring into focus new results that identify two additional CTD-associated processes: nucleocytoplasmic transport of mRNA and DNA damage and repair.

FACT, the Bur kinase pathway, and the histone co-repressor HirC have overlapping nucleosome-related roles in yeast transcription elongation

Gene transcription is constrained by the nucleosomal nature of chromosomal DNA. This nucleosomal barrier is modulated by FACT, a conserved histone-binding heterodimer. FACT mediates transcription-linked nucleosome disassembly and also nucleosome reassembly in the wake of the RNA polymerase II transcription complex, and in this way maintains the repression of ‘cryptic’ promoters found within some genes. Here we focus on a novel mutant version of the yeast FACT subunit Spt16 that supplies essential Spt16 activities but impairs transcription-linked nucleosome reassembly in dominant fashion. This Spt16 mutant protein also has genetic effects that are recessive, which we used to show that certain Spt16 activities collaborate with histone acetylation and the activities of a Bur-kinase/Spt4–Spt5/Paf1C pathway that facilitate transcription elongation. These collaborating activities were opposed by the actions of Rpd3S, a histone deacetylase that restores a repressive chromatin environment in a transcription-linked manner. Spt16 activity paralleling that of HirC, a co-repressor of histone gene expression, was also found to be opposed by Rpd3S. Our findings suggest that Spt16, the Bur/Spt4–Spt5/Paf1C pathway, and normal histone abundance and/or stoichiometry, in mutually cooperative fashion, facilitate nucleosome disassembly during transcription elongation. The recessive nature of these effects of the mutant Spt16 protein on transcription-linked nucleosome disassembly, contrasted to its dominant negative effect on transcription-linked nucleosome reassembly, indicate that mutant FACT harbouring the mutant Spt16 protein competes poorly with normal FACT at the stage of transcription-linked nucleosome disassembly, but effectively with normal FACT for transcription-linked nucleosome reassembly. This functional difference is consistent with the idea that FACT association with the transcription elongation complex depends on nucleosome disassembly, and that the same FACT molecule that associates with an elongation complex through nucleosome disassembly is retained for reassembly of the same nucleosome.

Pervasive transcription - Lessons from yeast

Pervasive transcription is now accepted to be a general feature of eukaryotic genomes, generating short and long non-coding RNAs (ncRNAs). Growing number of examples have shown that regulatory ncRNAs can control gene expression and chromatin domain formation. In this review, we discuss recent reports that show that Saccharomyces cerevisiae's genome also supports pervasive transcription, which is strongly controlled by RNA decay pathways and nucleosome positioning. We therefore propose that S. cerevisiae is an excellent model for studying large ncRNAs, which has already provided important examples of antisense-mediated transcriptional silencing.

Identification of histone mutants that are defective for transcription-coupled nucleosome occupancy

Our previous studies of Saccharomyces cerevisiae described a gene repression mechanism where the transcription of intergenic noncoding DNA (ncDNA) (SRG1) assembles nucleosomes across the promoter of the adjacent SER3 gene that interfere with the binding of transcription factors. To investigate the role of histones in this mechanism, we screened a comprehensive library of histone H3 and H4 mutants for those that derepress SER3. We identified mutations altering eight histone residues (H3 residues V46, R49, V117, Q120, and K122 and H4 residues R36, I46, and S47) that strongly increase SER3 expression without reducing the transcription of the intergenic SRG1 ncDNA. We detected reduced nucleosome occupancy across SRG1 in these mutants to degrees that correlate well with the level of SER3 derepression. The histone chromatin immunoprecipitation experiments on several other genes suggest that the loss of nucleosomes in these mutants is specific to highly transcribed regions. Interestingly, two of these histone mutants, H3 R49A and H3 V46A, reduce Set2-dependent methylation of lysine 36 of histone H3 and allow transcription initiation from cryptic intragenic promoters. Taken together, our data identify a new class of histone mutants that is defective for transcription-dependent nucleosome occupancy.

The role of cotranscriptional histone methylations

The carboxy-terminal domain (CTD) of the RNA polymerase II subunit Rpb1 undergoes dynamic phosphorylation, with different phosphorylation sites predominating at different stages of transcription. Our laboratory studies show how various mRNA-processing and chromatin-modifying enzymes interact with the phosphorylated CTD to efficiently produce mRNAs. The H3K36 methyltransferase Set2 interacts with CTD carrying phosphorylations characteristic of downstream elongation complexes, and the resulting cotranscriptional H3K36 methylation targets the Rpd3S histone deacetylase to downstream transcribed regions. Although positively correlated with gene activity, this pathway actually inhibits transcription elongation as well as initiation from cryptic promoters within genes. During early elongation, CTD serine 5 phosphorylation helps recruit the H3K4 methyltransferase complex containing Set1. Within 5' transcribed regions, cotranscriptional H3K4 dimethylation (H3K4me2) by Set1 recruits the deacetylase complex Set3C. Finally, H3K4 trimethylation at the most promoter-proximal nucleosomes is thought to stimulate transcription by promoting histone acetylation by complexes containing the ING/Yng PHD finger proteins. Surprisingly, the Rpd3L histone deacetylase complex, normally a transcription repressor, may also recognize H3K4me3. Together, the cotranscriptional histone methylations appear to function primarily to distinguish active promoter regions, which are marked by high levels of acetylation and nucleosome turnover, from the deacetylated, downstream transcribed regions of genes.

The chromatin signaling pathway: diverse mechanisms of recruitment of histone-modifying enzymes and varied biological outcomes

Posttranslational modifications of histones are coupled in the regulation of the cellular processes involving chromatin, such as transcription, replication, repair, and genome stability. Recent biochemical and genetic studies have clearly demonstrated that many aspects of chromatin, in addition to posttranslational modifications of histones, provide surfaces that can interact with effectors and the modifying machineries in a context-dependent manner, all as a part of the "chromatin signaling pathway." Here, we have reviewed recent findings on the molecular basis for the recruitment of the chromatin-modifying machineries and their diverse and varied biological outcomes.