Project description:Histone modifications coupled to transcription elongation play important roles in regulating the accuracy and efficiency of gene expression. The mono-ubiquitylation of a conserved lysine in H2B (K123 in Saccharomyces cerevisiae and K120 in humans) occurs co-transcriptionally and is required for initiating a histone modification cascade on active genes. H2BK123 ubiquitylation (H2BK123ub) requires the RNA polymerase II (RNAPII)-associated Paf1 transcription elongation complex (Paf1C). Through its Histone Modification Domain (HMD), the Rtf1 subunit of Paf1C directly interacts with the ubiquitin conjugase Rad6, leading to the stimulation of H2BK123ub in vivo and in vitro. To understand the molecular mechanisms that specifically target Rad6 to its histone substrate, we identified the site of interaction for the HMD on Rad6. Using in vitro crosslinking followed by mass spectrometry, we localized the primary contact surface for the HMD to the highly conserved N-terminal helix of Rad6. Using a combination of genetic and biochemical experiments, we identified separation-of-function mutations in RAD6 that greatly impair H2BK123 ubiquitylation but not other Rad6 functions. Finally, by employing RNA-sequencing as a sensitive approach for comparing mutant phenotypes, we show that mutating either side of the proposed Rad6-HMD interface yields strikingly similar transcriptome profiles that extensively overlap with those of a mutant that lacks the site of ubiquitylation in H2B. Our results fit a model in which a specific interface between a transcription elongation factor and a ubiquitin conjugase guides substrate selection toward a highly conserved chromatin target during active gene expression.

Project description:Rad6 E2 ubiquitin-conjugating enzyme and Bre1 E3 ubiquitin ligase catalyze histone H2B Lysine-123 monoubiquitination (H2Bub1), which stabilizes nucleosomes and regulates the trans-histone H3K4 and K79 methylation during gene transcription and other nuclear processes. The interaction interfaces within the Rad6-Bre1-containing H2B ubiquitin-conjugating complex have remained unknown. By solving the crystal structure of Rad6 along with a non-RING domain N-terminal region of Bre1, we report a beta-turn in Rad6's so-called backside region away from catalytic pocket as a binding site for a homodimer of Bre1 E3 ligase. Using quantitative ChIP-seq or ChIP-Rx, we further demonstrate that Rad6's backside beta-turn residues also govern the chromatin binding dynamics and transcriptional regulatory functions of the Rad6-Bre1 complex.

Project description:Rad6 E2 ubiquitin-conjugating enzyme and Bre1 E3 ubiquitin ligase catalyze histone H2B Lysine-123 monoubiquitination (H2Bub1), which stabilizes nucleosomes and regulates the trans-histone H3K4 and K79 methylation during gene transcription and other nuclear processes. The interaction interfaces within the Rad6-Bre1-containing H2B ubiquitin-conjugating complex has remained unknown. By solving the crystal structure of Rad6 along with a non-RING domain N-terminal region of Bre1, we report a beta-turn in Rad6's so-called backside region away from catalytic pocket as a binding site for a homodimer of Bre1 E3 ligase. Using quantitative ChIP-seq or ChIP-Rx, we further demonstrate that Rad6's backside beta-turn residues also govern the chromatin binding dynamics of the Rad6-Bre1 complex.

Project description:RNA polymerase II (RNAPII) transcription elongation directs an intricate pattern of histone modifications. Formation of this pattern involves a highly conserved regulatory axis, key components of which are the elongation factor Rtf1, monoubiquitylation of histone H2B (H2Bub1), and methylation of histone H3 on lysine 4 (H3K4me). Direct contact between Rtf1 and the ubiquitylation complex Rad6-Bre1 stimulates H2Bub1, which in turn promotes H3K4me by stimulating the activity of the Set1C/COMPASS methyltransferase complex. Previous studies have defined the molecular basis for these regulatory relationships, but it remains unclear how they regulate chromatin and transcription in vivo. We found that mutations affecting multiple components of the Rtf1-H2Bub1-H3K4me axis in the model eukaryote Schizosaccharomyces pombe caused resistance to the ribonucleotide reductase inhibitor hydroxyurea (HU). Resistance correlated with a reduced effect of HU on dNTP pools, bypass of the S-phase checkpoint in the presence of HU, and blunting of the transcriptional response to HU treatment. Mutations in the C-terminal repeat domain (CTD) of the RNAPII large subunit Rpb1 led to a similar spectrum of phenotypes. Moreover, all the HU resistant mutants we identified also exhibited resistance to several azole class antifungal agents. Our results suggest a novel, shared gene regulatory function of the Rtf1-H2Bub1-H3K4me axis and the Rpb1 CTD in controlling fungal drug tolerance.

Project description:RNA polymerase II (RNAPII) transcription elongation directs an intricate pattern of histone modifications. Formation of this pattern involves a highly conserved regulatory axis, key components of which are the elongation factor Rtf1, monoubiquitylation of histone H2B (H2Bub1), and methylation of histone H3 on lysine 4 (H3K4me). Direct contact between Rtf1 and the ubiquitylation complex Rad6-Bre1 stimulates H2Bub1, which in turn promotes H3K4me by stimulating the activity of the Set1C/COMPASS methyltransferase complex. Previous studies have defined the molecular basis for these regulatory relationships, but it remains unclear how they regulate chromatin and transcription in vivo. We found that mutations affecting multiple components of the Rtf1-H2Bub1-H3K4me axis in the model eukaryote Schizosaccharomyces pombe caused resistance to the ribonucleotide reductase inhibitor hydroxyurea (HU). Resistance correlated with a reduced effect of HU on dNTP pools, bypass of the S-phase checkpoint in the presence of HU, and blunting of the transcriptional response to HU treatment. Mutations in the C-terminal repeat domain (CTD) of the RNAPII large subunit Rpb1 led to a similar spectrum of phenotypes. Moreover, all the HU resistant mutants we identified also exhibited resistance to several azole class antifungal agents. Our results suggest a novel, shared gene regulatory function of the Rtf1-H2Bub1-H3K4me axis and the Rpb1 CTD in controlling fungal drug tolerance.

Project description:The conserved yeast E3 ligase Bre1 and its partner E2 Rad6 monoubiquitinate histone H2B across gene bodies during the transcription cycle. While processive ubiquitination might in principle arise from Bre1/Rad6 traveling with RNA polymerase II, we provide a different explanation. Here we implicate liquid-liquid phase separation as the underlying mechanism. Biochemical reconstitution shows that Bre1 binds the scaffold protein Lge1, whose intrinsically disordered region phase separates via dynamic, multivalent interactions. The resulting condensates comprise a core of Lge1 encapsulated by an outer catalytic shell of Bre1. This layered liquid recruits Rad6 and the nucleosomal substrate, accelerating H2B ubiquitination. In vivo, the condensate-forming region of Lge1 is required to ubiquitinate H2B in gene bodies beyond the +1 nucleosome. Our data suggest that layered condensates of histone modifying enzymes generate chromatin-associated reaction chambers with augmented catalytic activity along gene bodies. Equivalent processes may occur in human cells, causing neurological disease when impaired.

Project description:Project abstract : The trimethylation of histone H3 lysine 4 (H3K4me3) is a crucial factor in defining the promoter regions of active genes in all eukaryotes ranging from Saccharomyces cerevisiae (yeast) to humans. In budding yeast, this trimethylation process facilitated by the Set1 complex results in H3K4me3 requiring a prior mono-ubiquitination at the histone H2BK123 residue (H2Bub) by E2 enzyme Rad6 and E3 enzyme Bre1. A previous in vitro study suggested that ubiquitinated H2B directly facilitates H3K4me3. However, even low levels of global H2Bub is sufficient for the required H3K4me3 in yeast cells, thereby indicating that other factors resulting in the H2Bub-dependent H3K4me3 remain unknown. This study revealed the high level of correlation of H3K4me3 with chromatin recruitment of Rad6 at the genome-wide level. Rad6 is confirmd to interact and co-localize with Swd2/Cps35, a key factor for the H2Bub-dependent H3K4me3 in genes with high levels of H3K4me3 and intronic genes rather than non-intronic genes. This study therefore provides a mechanistic insight of the H2Bub-Rad6- Swd2/Cps35-H3K4me3 axis and its potential role in RNA biogenesis.

Project description:Paf1 and Ski8 were selected as representative subunits of the Paf1 complex (PAF1C), and RNA-seq analysis was performed in triplicate to compare the genes affected by Paf1, Ski8, and Rtf1 knockdown in HeLa cells.

Project description:Histone H3K4 tri-methylation (H3K4me3) catalyzed by Set1/COMPASS, is a prominent epigenetic mark found in promoter-proximal regions of actively transcribed genes. H3K4me3 relies on prior monoubiquitination at the histone H2B (H2Bub) by Rad6 and Bre1. Swd2/Cps35, a Set1/COMPASS component, has been proposed as a key player in facilitating H2Bub-dependent H3K4me3. However, a more comprehensive investigation regarding the relationship among Rad6, Swd2 and Set1 is required to further understand the mechanisms and functions of the H3K4 methylation. We investigated the genome-wide occupancy patterns of Rad6, Swd2 and Set1 under various genetic conditions, aiming to clarify the roles of Set1 and Rad6 for occupancy of Swd2. Swd2 peaks appear on both 5’region and 3’region of genes, which are overlapped with its tightly bound two complexes, Set1 and CPF (Cleavage and Polyadenylation Factor), respectively. In the absence of Rad6/H2Bub, Set1 predominantly localized to the 5ʹ region of genes, while Swd2 lost all the chromatin binding. However, in the absence of Set1, Swd2 occupancy near the 5’region was impared and rather increased in the 3’ region. This study highlights that catalytic activity of Rad6 is essential for all the ways of Swd2’s binding to the transcribed genes and Set1 redistributes the Swd2 to 5’region for accomplishments of H3K4me3 in the genome-wide level.

Project description:During heart development, an evolutionarily conserved network of cardiac transcription factors collaborate to define the precise timing and location of cardiac progenitor specification. Accumulating evidence suggests that cardiac progenitor specification is subject to transcriptional control beyond the level of transcription initiation. The PAF1C component Rtf1 is a multifunctional transcription regulatory protein that modulates pausing and elongation of RNA Pol II, as well as histone epigenetic modifications. By transient knockdown and CRISPR mutagenesis, we found that Rtf1 is essential for cardiogenesis and that without Rtf1 activity, cardiac progenitors arrest in an immature state. This role in early cardiogenesis was evolutionarily conserved between fish and mammals. We also found that Rtf1's Plus3 domain, which confers interaction with the pausing/elongation factor Spt5, was required for Rtf1's ability to support cardiac progenitor formation, while other regions of the protein were dispensable. We examined the occupancy of RNA Pol II at cardiac genes in rtf1 morphants using ChIP-seq and found that Pol II signals at the TSS of genes was reduced, suggesting a reduction in transcriptional pausing. Intriguingly, pharmacological or morpholino antisense reduction of pause release in rtf1 morphants and mutants restored the formation of cardiac cells and improved Pol II occupancy at the TSS of key cardiac genes. Our findings highlight the crucial role that transcriptional pausing plays in promoting normal levels of gene expression in a cardiac developmental context.