Project description:Purpose of profiling experiment was to examine effects of a mutation of a subunit of TFIIH, ssl1p, which has ubiquitin ligase activity. The whole complex has previously been shown to have both kinase and helicase activities. We wanted to see if 1) there were general transcriptional defects with these mutations, as there are with other mutations to kinase activity, and 2) if there were transcriptional effects on DNA repair machinery when the mutants were treated with MMS, which is an alkylating agent. Keywords: other

Project description:Humans are exposed to a wide range of exogenous and endogenous alkylating agents, including agents frequently used as cytostatic drugs in cancer treatment (Drablos, Feyzi et al. 2004). Alkylating agents are mutagenic and cytotoxic and the major body of research has focused on their effects upon DNA. Less is known about the cellular consequences of alkylation to RNA, proteins and lipids, although such damage is likely quantitatively dominating due to the mere abundance of these macromolecules. DNA and RNA can be alkylated by SN1 and SN2 alkylating agents and alkylation occurs at nucleophilic O and N-atoms in the nucleosides as well as at O atoms in the phosphodiester bonds (Shooter, Howse et al. 1974, Sedgwick 2004). While alkylation at the O atoms in the nucleobases (O6G, O4T and O2C) are not affected by their hydrogen bonding, N1A and N3C contain an electron pair involved in hydrogen bonding. Alkylation at these nitrogens are thus more frequent in RNA and single-stranded DNA than in double stranded DNA (Bodell and Singer 1979). To cope with genomic damage inflicted by alkylating agents, a set of complex signal transduction pathways and DNA repair enzymes, collectively called the DNA damage response (DDR) is essential. The DDR senses the DNA damage and starts a highly choreographed response in order to resolve DNA damage or -replication issues (Ciccia and Elledge 2010). Specific repair mechanisms also exist to repair alkylated RNA (Aas, Otterlei et al. 2003, Wurtmann and Wolin 2009), although the biological significance of such repair yet remains elusive. Nevertheless, alkylation damage has been shown to alter the base-pairing properties of RNA bases and can interfere with tRNA-rRNA (Yoshizawa, Fourmy et al. 1999) as well as mRNA-tRNA (Ougland, Zhang et al. 2004){Hudson, 2015 #259}. Likely, other RNA functions that relies on base pairing might also be affected by alkylation damage, e.g. the correct folding of tRNAs and the function of miRNAs. Alkylation of mRNA may also affect translation indirectly by affecting binding affinities to RNA binding proteins (RBPs), as recently demonstrated for 6-meA. This enzymatically induced modification promotes binding of the 6-maA reader proteins YTHDF1 and 2 . While YTHDF2 reduces the stability of 6-maA modified transcripts (Wang, Lu et al. 2014), YTHDF1 actively promotes protein synthesis by interacting with the translation machinery (Wang, Zhao et al. 2015). To what degree alkylation damage to mRNA may promote similar effects by modulating translation remains, however, to be investigated. Interestingly, several studies have identified RBPs as important players in the DDR (Beli, Lukashchuk et al. 2012, Jungmichel, Rosenthal et al. 2013). Here, RBPs appear to have three major roles: 1) regulate gene expression at both the transcriptional- and post-transcriptional level (Keene and Tenenbaum 2002, Glisovic, Bachorik et al. 2008, Rinn and Chang 2012), 2) prevent formation of R-loops (Skourti-Stathaki and Proudfoot 2014), and 3) participate directly in DNA repair (Montecucco and Biamonti 2013, Dutertre, Lambert et al. 2014, Naro, Bielli et al. 2015). Two large-scale mass spectrometry (MS) based studies of RBPs in human cancer cell lines together identified more than 1100 RBPs (Baltz, Munschauer et al. 2012, Castello, Fischer et al. 2012) and more recently the “RBPomes” of mouse embryonic stem cells (Kwon, Yi et al. 2013) and yeast (Mitchell, Jain et al. 2013) have been published. However, functional studies describing how these complex protein networks are affected during genotoxic cell stress are still largely missing. One previous study has monitored changes in the RBPome of mouse embryonic fibroblasts subsequent to treatment with the topoisomerase inhibitor etoposide {Boucas, 2015 #112}. To our knowledge, however, no such studies have attempted to monitor altered global protein:RNA binding subsequent to treatment with alkylating agents. This could be particularly interesting since base methylation constitutes an important functional modification of RNA. In the present study we aimed at investigating this in more detail by SILAC-based quantitation of proteins differentially binding to poly(A)-RNA in HeLa cells at different time points after treatment with the alkylating agent methyl methanesulfonate.

Project description:We explored the global transcription profile in response to MMS in C. albicans through RNAseq assay. Here, we identified 407 genes (log2 fold cut off 1.0, P<0.05) whose levels of transcription were significantly affected under the MMS treatment condition; 207 genes were upregulated, and 200 genes were down-regulated. GO term analysis revealed that a small portion of changed genes showed direct roles in DNA repair progress, but a large number of induced genes are involved in antioxidant responses, and some down-regulated genes are involved in nucleosome packing and nitrogen utilization. In addition, the changed transcription of some DNA repair genes, as well as antioxidants genes, are blocked by deleting RAD53. Taken together, treatment of the DNA damage agent MMS induces a global transcriptional change in C. albicans, but not only DNA damage response genes.

Project description:To determine the effect of lack of two Histone H4 genes, CgHHF1 and CgHHF2, on global transcriptional profile, and on transcriptional response towards MMS exposure, RNA-Seq analysis was conducted on log-phase grown Candida glabrata wild-type and Cghhf1∆2∆ cells in the presence and absence of MMS. Comparative transcriptome analysis of wild-type and Cghhf1∆2∆ cells displayed deregulation of 303 genes due to the loss of CgHHF1 and CgHHF2 genes. C. glabrata responded to MMS by upregulating genes involved in transmembrane transport and invasive growth in response to glucose limitation, and by downregulating the aerobic respiration and ergosterol biosynthetic process genes.

Project description:Understanding the mechanisms by which cells respond to chemotherapeutics is key to identifying means to improve therapy effiicacy while reducing systemic toxicity of these widely used classes of drugs. While determining the role of NRF2-GSH and ER stress in cells exposed to alkylating compounds such as methyl-methanesulfonate (MMS), we asked if these pathways could also be a general cell damage response relevant to other clinically used chemotherapeutics or if it is an alkylation specific response. With this intent, we performed RNA sequencing of MDA-MB231 breast cancer and U2OS osteosarcoma cells lines treated for 8 hours with a topoisomerase II inhibitor etoposide (20 µM), the antimitotic beta-tubulin-interacting drug paclitaxel (0.2 µM), doxorubicin (1 µM) and compared to MMS (40 µg/mL) treated cells. Doses represent IC50 level after 72 hours exposure. We observed that even though non-alkylating drugs, especially etoposide, caused an increase in the mRNA expression of some NRF2 and ER stress signaling markers, the number and magnitude of upregulation of genes markers in either pathway was more pronounced in alkylation treatments compared to other drugs. This indicates that alterations in NRF2 and ER stress pathways could be more likely associated with differential sensitivity to alkylating chemotherapies.

Project description:To obtain a better understanding of molecular mechanisms underlying the DNA damage response in Δckb1 and Δckb2 mutants, transcriptome analyses were performed between WT, Δckb1, and Δckb2 strains. Comparative transcriptome analysis of Δckb1 and Δckb2 mutants showed similar transcriptional profiles in the presence and absence of MMS. The data also indicated that compared with WT, about 200 genes were up or downregulated in Δckb1 and Δckb2 strains with or without treatment with 0.01% MMS. GO analysis highlighted that the differentially expressed genes in Δckb1 and Δckb2 were significantly enriched in the processes related to the programmed formation of DNA double-strand breaks (DSBs), recombination, and DNA repair coordination of the meiotic cell cycle.

Project description:We catalogued and quantified the transcripts in livers of wild-type and Aag-deficient mice that had been exposed to the model alkylating agent methyl methanesulfonate (MMS). Gene expression analysis was performed for samples harvested 6 hours post-MMS treatment.

Project description:We are investigating the transcriptional response of mice that are wt or null for Aag in response to alkylating agent MMS; We used microarrays to detail the global programme of gene expression response due to MMS exposure in a DNA repair proficient or deficient mouse Experiment Overall Design: Mice (WT and Aag null) were treated with MMS and livers extracted at 6, 12, 24, and 48 hours

Project description:We are investigating the transcriptional response of mice that are wt or null for Aag in response to alkylating agent MMS We used microarrays to detail the global programme of gene expression response due to MMS exposure in a DNA repair proficient or deficient mouse Keywords: timepoint

Project description:The main goal of this project is to identify proteins in Candida glabrata that interact with histones H3 (CgHht) and H4 (CgHhf) under normal and MMS-treatment conditions.