The glucanosyltransferase Gas1 functions in transcriptional silencing

Koch, Melissa R.; Pillus, Lorraine

doi:10.1073/pnas.0900809106

Cited by 35 publications

(56 citation statements)

References 49 publications

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“…As previously reported, deletion of GAS1 did not alter levels of H3K9Ac, H3K14Ac at 30° ( Koch and Pillus 2009), which are targets of both Gcn5 and Sas3 (reviewed in Lafon et al 2007). At 37°, a condition under which deletion of SAS3 suppresses gas1 temperature sensitivity, neither the gas1 strain nor gas1 sas3 had altered global levels of H3K9Ac, H3K14Ac ( Figure S2).…”

Section: Resultssupporting

confidence: 75%

“…Whereas loss of SAS3 leads to an increase in silencing at the HM loci (Reifsnyder et al 1996), gas1 mutants have impaired silencing at telomeric loci and improved silencing within rDNA (Koch and Pillus 2009). We demonstrate that deletion of both enzymes leads to restoration of silencing to wild-type levels at all loci analyzed (Figure 2A).…”

Section: Gas1 and Sas3 Counterbalance Silencing At All Three Silencedmentioning

confidence: 60%

“…Specifically, loss of Gas1 catalytic activity increases rDNA silencing and decreases telomeric silencing, yet has no observable change at the HM cryptic mating-type loci. These alterations in silencing are not remediated by the osmoregulator sorbitol (Koch and Pillus 2009), which rescues the cell wall-associated defects of gas1 and other cell wall mutants (Turchini et al 2000;Levin 2005). Combined, these data support a function for Gas1 in chromatin-mediated processes that is separable from its role at the cell wall.…”

mentioning

confidence: 92%

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Unexpected Function of the Glucanosyltransferase Gas1 in the DNA Damage Response Linked to Histone H3 Acetyltransferases in Saccharomyces cerevisiae

Eustice

Pillus

2014

Genetics

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Chromatin organization and structure are crucial for transcriptional regulation, DNA replication, and damage repair. Although initially characterized in remodeling cell wall glucans, the b-1,3-glucanosyltransferase Gas1 was recently discovered to regulate transcriptional silencing in a manner separable from its activity at the cell wall. However, the function of Gas1 in modulating chromatin remains largely unexplored. Our genetic characterization revealed that GAS1 had critical interactions with genes encoding the histone H3 lysine acetyltransferases Gcn5 and Sas3. Specifically, whereas the gas1 gcn5 double mutant was synthetically lethal, deletion of both GAS1 and SAS3 restored silencing in Saccharomyces cerevisiae. The loss of GAS1 also led to broad DNA damage sensitivity with reduced Rad53 phosphorylation and defective cell cycle checkpoint activation following exposure to select genotoxins. Deletion of SAS3 in the gas1 background restored both Rad53 phosphorylation and checkpoint activation following exposure to genotoxins that trigger the DNA replication checkpoint. Our analysis thus uncovers previously unsuspected functions for both Gas1 and Sas3 in DNA damage response and cell cycle regulation.

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Section: Resultssupporting

confidence: 75%

Section: Gas1 and Sas3 Counterbalance Silencing At All Three Silencedmentioning

confidence: 60%

mentioning

confidence: 92%

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Unexpected Function of the Glucanosyltransferase Gas1 in the DNA Damage Response Linked to Histone H3 Acetyltransferases in Saccharomyces cerevisiae

Eustice

Pillus

2014

Genetics

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“…Although several studies establish functional links between the inner nuclear membrane and yeast silencing (37)(38)(39), palmitoylation of Rif1 is unique as an example in which a known silencing protein's association with the inner nuclear membrane is controlled by a fatty acid modification. A recent study shows that carbohydrate modification of Sir2 can regulate silencing (40). Perhaps these unexpected modifications represent an emerging theme for how cells use nonhistone proteins to make chromatin structures more responsive to a cell physiology.…”

Section: Pfa4mentioning

confidence: 99%

Palmitoylation controls the dynamics of budding-yeast heterochromatin via the telomere-binding protein Rif1

Park¹,

Patterson

Cobb³

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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The posttranslational addition of palmitate to cysteines occurs ubiquitously in eukaryotic cells, where it functions in anchoring target proteins to membranes and in vesicular trafficking. Here we show that the Saccharomyces cerevisiae palmitoyltransferase Pfa4 enhanced heterochromatin formation at the cryptic mating-type loci HMR and HML via Rif1, a telomere regulatory protein. Acylated Rif1 was detected in extracts from wild-type but not pfa4Δ mutant cells. In a pfa4Δ mutant, Rif1-GFP dispersed away from foci positioned at the nuclear periphery into the nucleoplasm. Sir3-GFP distribution was also perturbed, indicating a change in the nuclear dynamics of heterochromatin proteins. Genetic analyses indicated that PFA4 functioned upstream of RIF1. Surprisingly, the pfa4Δ mutation had only mild effects on telomeric regulation, suggesting Rif1's roles at HM loci and telomeres were more complexly related than previously thought. These data supported a model in which Pfa4-dependent palmitoylation of Rif1 anchored it to the inner nuclear membrane, influencing its role in heterochromatin dynamics.transcriptional silencing | chromosome architecture

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“…This was done because fusion proteins frequently cannot fold correctly in yeast and thus are incapable of interacting. Moreover, full-length proteins can be locked in a "closed" formation that masks binding domains (59,60). This effect might explain why, for example, subfragment Rab1-B interacts with several fusion proteins, whereas its full-length variant Rab1-FL fails to bind the respective proteins.…”

Section: Discussionmentioning

confidence: 99%

Identification of a Chloroplast Ribonucleoprotein Complex Containing Trans-splicing Factors, Intron RNA, and Novel Components

Jacobs

Marx

Kock

et al. 2013

Molecular & Cellular Proteomics

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Maturation of chloroplast psaA pre-mRNA from the green alga Chlamydomonas reinhardtii requires the trans-splicing of two split group II introns. Several nuclear-encoded trans-splicing factors are required for the correct processing of psaA mRNA. Among these is the recently identified Raa4 protein, which is involved in splicing of the tripartite intron 1 of the psaA precursor mRNA. Part of this tripartite group II intron is the chloroplast encoded tscA RNA, which is specifically bound by Raa4. Using Raa4 as bait in a combined tandem affinity purification and mass spectrometry approach, we identified core components of a multisubunit ribonucleoprotein complex, including three previously identified trans-splicing factors (Raa1, Raa3, and Rat2). We further detected tscA RNA in the purified protein complex, which seems to be specific for splicing of the tripartite group II intron. Intron-containing genes from prokaryotic or organellar genomes carry either group I or group II introns, each of which has distinct features. The splicing mechanism of group II introns and the secondary structures of their presumed active sites were used as early arguments for the hypothesis that this class of introns represents the ancestors of eukaryotic spliceosomal introns (1, 2). It was further assumed that group II introns invaded the eukaryotic nucleus and subsequently proliferated at various genomic sites, leading to the degeneration of the catalytic intron structure into small nuclear RNAs (snRNAs).1 This assumption was supported by the observation of naturally occurring variants of group II introns that are split into two or more pieces (3), reminiscent of eukaryotic spliceosomal RNA (1). Group II intron RNAs are characterized by six conserved domains, and tertiary interactions among these domains generate the compact native and catalytic complex. Some of these group II intron domains have been shown to act in trans on the splicing of other introns that lack the corresponding domain (4). In vivo, various RNA-binding proteins promote the formation of catalytically active intron RNA. In contrast to the nuclear spliceosome, which acts generally on a broad range of nuclear-encoded pre-mRNAs, proteins involved in organellar intron splicing seem to more efficiently stabilize the active three-dimensional RNA structure in vivo. Several splicing factors in higher plants, such as the chloroplast RNA-splicing and ribosome maturation (CRM) domain protein CRS1, as well as the pentatricopeptide repeat proteins OTP51 and PPR4, have been reported to be involved in the splicing of single transcripts (5, 6). Nonetheless, there are splicing factors that carry out functions on a broad range of transcripts, including CRS2 and its associated proteins CAF1 and CAF2, and WTF1, a splicing factor containing a plant organelle RNA-recognition domain (5, 6). Sedimentation and co-fractionation experiments in, for example, maize have demonstrated that these proteins are part of large multiprotein and ribonucleoprotein complexes with their cognate RNAs (5, 7). I...

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The glucanosyltransferase Gas1 functions in transcriptional silencing

Cited by 35 publications

References 49 publications

Unexpected Function of the Glucanosyltransferase Gas1 in the DNA Damage Response Linked to Histone H3 Acetyltransferases in Saccharomyces cerevisiae

Unexpected Function of the Glucanosyltransferase Gas1 in the DNA Damage Response Linked to Histone H3 Acetyltransferases in Saccharomyces cerevisiae

Palmitoylation controls the dynamics of budding-yeast heterochromatin via the telomere-binding protein Rif1

Identification of a Chloroplast Ribonucleoprotein Complex Containing Trans-splicing Factors, Intron RNA, and Novel Components

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