Abstract
Cmr1 (changed mutation rate 1) is a largely uncharacterized nuclear protein that has recently emerged in several global genetic interaction and protein localization studies. It clusters with proteins involved in DNA damage and replication stress response, suggesting a role in maintaining genome integrity. Under conditions of proteasome inhibition or replication stress, this protein localizes to distinct sub-nuclear foci termed as intranuclear quality control (INQ) compartments, which sequester proteins for their subsequent degradation. Interestingly, it also interacts with histones, chromatin remodelers and modifiers, as well as with proteins involved in transcription including subunits of RNA Pol I and Pol III, but not with those of Pol II. It is not known whether Cmr1 plays a role in regulating transcription of Pol II target genes. Here, we show that Cmr1 is recruited to the coding regions of transcribed genes of S. cerevisiae. Cmr1 occupancy correlates with the Pol II occupancy genome-wide, indicating that it is recruited to coding sequences in a transcription-dependent manner. Cmr1-enriched genes include Gcn4 targets and ribosomal protein genes. Furthermore, our results show that Cmr1 recruitment to coding sequences is stimulated by Pol II CTD kinase, Kin28, and the histone deacetylases, Rpd3 and Hos2. Finally, our genome-wide analyses implicate Cmr1 in regulating Pol II occupancy at transcribed coding sequences. However, it is dispensable for maintaining co-transcriptional histone occupancy and histone modification (acetylation and methylation). Collectively, our results show that Cmr1 facilitates transcription by directly engaging with transcribed coding regions.
Highlights
The S. cerevisiae protein Ydl156w/Cmr1 is a putative WD40 domain containing protein [1], with suggested homology to two human proteins: Ddb2 (DNA damage binding protein 2) and Wdr76 (WD repeat protein 76), based on sequence similarity [2]
Cmr1 has been shown to interact with histones and various transcription factors, including chromatin remodelers (RSC and SWI/SNF), the histone deacetylase Rpd3, and the Paf1 complex [8]
Under non-inducing conditions (-sulfometuron methyl (SM)), there was no significant difference in Cmr1 occupancies observed at the ARG1 promoter (TATA), or the 5’ and 3’ open reading frames (ORFs) (Fig 1A)
Summary
The S. cerevisiae protein Ydl156w/Cmr (changed mutation rate 1) is a putative WD40 domain containing protein [1], with suggested homology to two human proteins: Ddb (DNA damage binding protein 2) and Wdr (WD repeat protein 76), based on sequence similarity [2]. Identified in a screen for altered sensitivity to Tirapazamine (an anticancer drug) [3], the cmr1Δ mutation was among those showing a marked increase in resistance to Tirapazamine, which under hypoxic conditions is converted into radical species inducing DNA damage leading to cell death [4]. It was found in a genome-wide screen that in response to methyl methanesulphonate (MMS) and hydroxyl urea (HU) treatment (induces DNA damage and replication stress) Cmr localizes to sub-nuclear foci. The Cmr focus was distinct from the canonical Rad DNA repair focus [5], suggesting that it may perform a different function than Rad or its associated proteins in regulating genome integrity
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