Swd2/Cps35 determines H3K4 tri-methylation via interactions with Set1 and Rad6.

BACKGROUND: 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. RESULTS: 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 the 5' region and 3' region of genes, which are overlapped with its tightly bound two complexes, Set1 and cleavage and polyadenylation factor (CPF), respectively. In the absence of Rad6/H2Bub, Set1 predominantly localized to the 5' region of genes, while Swd2 lost all the chromatin binding. However, in the absence of Set1, Swd2 occupancy near the 5' region was impaired and rather increased in the 3' region. CONCLUSIONS: This study highlights that the catalytic activity of Rad6 is essential for all the ways of Swd2's binding to the transcribed genes and Set1 redistributes the Swd2 to the 5' region for accomplishments of H3K4me3 in the genome-wide level.

An epitope-tagged Swd2 reveals the different requirements of Swd2 concentration in H3K4 methylation and viability.

Swd2/Cps35 is a common component of the COMPASS H3K4 methyltransferase and CPF transcription termination complex in Saccharomyces cerevisiae. The deletion of SWD2 is lethal, which results from transcription termination defects in snoRNA genes. This study isolated a yeast strain that showed significantly reduced protein level of Swd2 following epitope tagging at its N-terminus (9MYC-SWD2). The reduced level of Swd2 in the 9MYC-SWD2 strain was insufficient for the stability of the Set1 H3K4 methyltransferase, H3K4me3 and snoRNA termination, but the level was enough for viability and growth similar to the wildtype strain. In addition, we presented the genes differentially regulated by the essential protein Swd2 under optimal culture conditions for the first time. The expression of genes known to be decreased in the absence of Set1 and H3K4me3, including NAD biosynthetic process genes and histone genes, was decreased in the 9MYC-SWD2 strain, as expected. However, the effects of Swd2 on the ribosome biogenesis (RiBi) genes were opposite to those of Set1, suggesting that the expression of RiBi genes is regulated by more complex relationship between COMPASS and other Swd2-containing complexes. These data suggest that different concentrations of Swd2 are required for its roles in H3K4me3 and viability and that it may be either contributory or contrary to the transcriptional regulation of Set1/H3K4me3, depending on the gene group.

The 80th Threonine Residue of Histone H3 Is Important for Maintaining HM Silencing in Saccharomyces cerevisiae.

Gene expression in eukaryotic cells is intricately regulated by chromatin structure and various factors, including histone proteins. In Saccharomyces cerevisiae, transcriptionally silenced regions, such as telomeres and homothallic mating (HM) loci, are essential for genome stability and proper cellular function. We firstly observed the defective HM silencing in alanine substitution mutant of 80th threonine residue of histone H3 (H3T80A). To identify which properties in the H3T80 residue are important for the HM silencing, we created several substitution mutants of H3T80 residue by considering the changed states of charge, polarity, and structural similarity. This study reveals that the structural similarity of the 80th position of H3 to the threonine residue, not the polarity and charges, is the most important thing for the transcriptional silencing in the HM loci.

N-Terminally arginylated ubiquitin is attached to histone H2A by RING1B E3 ligase in human cells.

Ubiquitin (Ub) is highly conserved in all eukaryotic organisms and begins at the N-terminus with Met and Gln. Our recent research demonstrates that N-terminally (Nt-) arginylated Ub can be produced in the yeast Saccharomyces cerevisiae. However, the existence of Nt-arginylated Ub in multicellular organisms remains unknown. Here we explore the mechanism for creating Nt-arginylated Ub using human embryonic kidney HEK293 cells that express various Nt-modified Ubs. We found that Gln-starting Q-Ub was converted into Glu-starting E-Ub by NTAQ1 Nt-deamidase and subsequently Nt-arginylated by ATE1 arginyltransferase in HEK293 cells. We also found that the resulting Arg-Glu-starting RE-Ub was mainly deposited on the Lys119 residue of histone H2A. Furthermore, RING1B E3 Ub ligase mediated the attachment of RE-Ub to H2A. These findings reveal a previously unknown type of histone ubiquitylation which greatly increases the combinatorial complexity of histone and ubiquitin codes.

The regional sequestration of heterochromatin structural proteins is critical to form and maintain silent chromatin.

Budding yeast Saccharomyces cerevisiae and fission yeast Schizosaccharomyces pombe are good models for heterochromatin study. In S. pombe, H3K9 methylation and Swi6, an ortholog of mammalian HP1, lead to heterochromatin formation. However, S. cerevisiae does not have known epigenetic silencing markers and instead has Sir proteins to regulate silent chromatin formation. Although S. cerevisiae and S. pombe form and maintain heterochromatin via mechanisms that appear to be fundamentally different, they share important common features in the heterochromatin structural proteins. Heterochromatin loci are localized at the nuclear periphery by binding to perinuclear membrane proteins, thereby producing distinct heterochromatin foci, which sequester heterochromatin structural proteins. In this review, we discuss the nuclear peripheral anchoring of heterochromatin foci and its functional relevance to heterochromatin formation and maintenance.

Spreading-dependent or independent Sir2-mediated gene silencing in budding yeast.

BACKGROUND: In the budding yeast Saccharomyces cerevisiae, a silent chromatin structure is formed at three distinct loci, including telomeres, rDNA, and mating-type loci, which silence the expression of genes within their structures. Sir2 is the only common factor, regulating the three silent chromatin regions. S. cerevisiae has 32 telomeres, but studies on gene silencing in budding yeast have been performed using some reporter genes, artificially inserted in the telomeric regions. Therefore, insights into the global landscape of Sir-dependent silencing of genes within the silent chromatin regions are required. OBJECTIVE: This study aimed to obtain global insights into Sir2-dependent gene silencing on all silent chromatin regions in budding yeast. METHODS: RNA-sequencing was performed to identify genes that are silenced by Sir2. By comparing with the chromatin immunoprecipitation-sequencing (ChIP-seq) of Sir2 in the wild-type strain, we confirmed Sir2-regulated genes. RESULTS: Using Sir2 ChIP-seq data, we identified that the Sir2 binding domain length caused by Sir2 spreading from the chromosomal end is different in each telomere in budding yeast. Expression of most subtelomeric genes increased in the ∆sir2 strain. Some Sir2-regulated subtelomeric genes were positioned within the telomeric Sir2-binding domain, while the others were outside the Sir2-binding domain. In addition, Sir2 was bound to the mating-type loci and rDNA region, and gene expression increased in the ∆sir2 strain. CONCLUSION: We concluded that S. cerevisiae has two modes of Sir2-mediated gene silencing: one is dependent on chromatin binding and spreading of Sir2, and the other is independent of spreading of Sir2.

Positive Charge of Arginine Residues on Histone H4 Tail Is Required for Maintenance of Mating Type in Saccharomyces cerevisiae.

Transcriptional gene silencing is regulated by the chromatin structure, which is by various factors including histones. Saccharomyces cerevisiae contains transcriptionally silenced regions such as telomeric regions and hidden mating (HM) loci. The positively-charged amino acids on the histone H4 tail were reported to be critical for the telomeric silencing in yeast, by interacting with Dot1, a specific methyltransferase for the 79th. lysine on histone H3. However, Dot1 did not affect gene silencing within HM loci, but whether the positively-charged amino acids on the H4 tail affect HM silencing has not been defined. To elucidate the function of the H4 tail on HM silencing, we created several MATa-type yeast strains bearing the substitution of arginine with alanine or lysine on the histone H4 tail and checked the sensitivity of MATa-type yeast to alpha pheromone. The arginine point mutants substituted by alanine (R17A, R19A, and R23A) did not show sensitivity to alpha pheromone, but only two arginine mutants substituted by lysine (R17K and R19K) restored the sensitivity to alpha pheromone-like wild type. These data suggested that the basic property of arginine at 17th and 19th positions in the histone H4 tail is critical for maintaining HM silencing, but that of the 23rd arginine is not. Our data implicated that the positive charge of two arginine residues on the histone H4 tail is required for HM silencing in a manner independent of Dot1.