Abdullah Al Emran scite author profile

Methylation of DNA at CpG sites is the most common and stable of epigenetic changes in cancer. Hypermethylation acts to limit immune checkpoint blockade immunotherapy by inhibiting endogenous interferon responses needed for recognition of cancer cells. By contrast, global hypomethylation results in the expression of programmed death ligand 1 (PD-L1) and inhibitory cytokines, accompanied by epithelial-mesenchymal changes that can contribute to immunosuppression. The drivers of these contrasting methylation states are not well understood. DNA methylation also plays a key role in cytotoxic T cell 'exhaustion' associated with tumor progression. We present an updated exploratory analysis of how DNA methylation may define patient subgroups and can be targeted to develop tailored treatment combinations to help improve patient outcomes. DNA Methylation, ICB, and Cancer DNA methylation can have major effects on gene expression and is the most commonly studied type of epigenetic modification (see Glossary). It comprises the covalent modification of the nucleotide cytosine at the 5ʹ position at sites preceding guanine (CpG) [1]. During mammalian cell division, it is replicated by the maintenance enzyme DNA methyltransferase 1 (DNMT1) on the daughter strand cytosine at the complementary CpG, usually resulting in gene silencing. New sites of DNA methylation, known as de novo methylation, can be introduced by DNMT3a or DNMT3b (Box 1). Conversely, methyl groups can be erased by ten-eleven translocation (TET) family proteins followed by glycosylation and replacement with an unmethylated cytosine. DNMT1 recruitment to replicating chromatin is facilitated by the 'ubiquitin-like with PHD and ring-finger domains' (UHRF) E3 ubiquitin ligase UHRF1 [2,3]. Methylation at CpG sites can also be recognized by methyl CpG binding 'reader' proteins such as methyl-CpG binding domain protein 1 (MBD1) and methyl-CpG binding protein 2 (MeCP2) harboring transcriptionally repressive activity. The latter may bind histone deacetylases (HDACs), which can contribute to the repression of certain genes [4]. Highlights Genome-wide DNA methylation is a relatively stable epigenetic characteristic of cells, which can be dysregulated in cancer cells by oncogenic signals.

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Design of an epitope-based peptide vaccine against spike protein of human coronavirus: an in silico approach

Oany¹,

Emran²,

Pervin³

2014

DDDT

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Human coronavirus (HCoV), a member of Coronaviridae family, is the causative agent of upper respiratory tract infections and “atypical pneumonia”. Despite severe epidemic outbreaks on several occasions and lack of antiviral drug, not much progress has been made with regard to an epitope-based vaccine designed for HCoV. In this study, a computational approach was adopted to identify a multiepitope vaccine candidate against this virus that could be suitable to trigger a significant immune response. Sequences of the spike proteins were collected from a protein database and analyzed with an in silico tool, to identify the most immunogenic protein. Both T cell immunity and B cell immunity were checked for the peptides to ensure that they had the capacity to induce both humoral and cell-mediated immunity. The peptide sequence from 88–94 amino acids and the sequence KSSTGFVYF were found as the most potential B cell and T cell epitopes, respectively. Furthermore, conservancy analysis was also done using in silico tools and showed a conservancy of 64.29% for all epitopes. The peptide sequence could interact with as many as 16 human leukocyte antigens (HLAs) and showed high cumulative population coverage, ranging from 75.68% to 90.73%. The epitope was further tested for binding against the HLA molecules, using in silico docking techniques, to verify the binding cleft epitope interaction. The allergenicity of the epitopes was also evaluated. This computational study of design of an epitope-based peptide vaccine against HCoVs allows us to determine novel peptide antigen targets in spike proteins on intuitive grounds, albeit the preliminary results thereof require validation by in vitro and in vivo experiments.

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Distinct histone modifications denote early stress-induced drug tolerance in cancer

et al. 2017

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Besides somatic mutations or drug efflux, epigenetic reprogramming can lead to acquired drug resistance. We recently have identified early stress-induced multi-drug tolerant cancer cells termed induced drug-tolerant cells (IDTCs). Here, IDTCs were generated using different types of cancer cell lines; melanoma, lung, breast and colon cancer. A common loss of the H3K4me3 and H3K27me3 and gain of H3K9me3 mark was observed as a significant response to drug exposure or nutrient starvation in IDTCs. These epigenetic changes were reversible upon drug holidays. Microarray, qRT-PCR and protein expression data confirmed the up-regulation of histone methyltransferases (SETDB1 and SETDB2) which contribute to the accumulation of H3K9me3 concomitantly in the different cancer types. Genome-wide studies suggest that transcriptional repression of genes is due to concordant loss of H3K4me3 and regional increment of H3K9me3. Conversely, genome-wide CpG site-specific DNA methylation showed no common changes at the IDTC state. This suggests that distinct histone methylation patterns rather than DNA methylation are driving the transition from parental to IDTCs. In addition, silencing of SETDB1/2 reversed multi drug tolerance. Alterations of histone marks in early multi-drug tolerance with an increment in H3K9me3 and loss of H3K4me3/H3K27me3 is neither exclusive for any particular stress response nor cancer type specific but rather a generic response.

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