Epigenetic Treatment Research Articles

EPCO-08. EPIGENETIC THERAPY POTENTIATES TRANSPOSABLE ELEMENT TRANSCRIPTION TO CREATE TUMOR-ENRICHED ANTIGENS IN GLIOBLASTOMA

Abstract Epigenetic treatment has been studied as a means to augment anti-tumor immune cell activity by increasing the expression of antiviral response genes. Previous studies, including our own, have revealed an additional consequence of epigenetic treatment: reactivation of transposable elements (TEs). Normally, most TEs are epigenetically repressed in healthy somatic tissues. However, epigenetic treatment can reactivate TEs as previously unannotated promoters, particularly in rapidly proliferating cells. These reactivated TEs could generate unique proteins that may act as novel antigens for immunotherapy. To study epigenetic treatment as a novel method to augment immunotherapy in cancers with a low number of somatic mutation-derived antigens, we chose glioblastoma as a model. Specifically, we investigated if drug-induced TE expression increases the antigen repertoire upon combinatorial treatment with DNMT inhibitor (Decitabine) and HDAC inhibitor (Panobinostat), agents currently being tested for clinical use in cancers, including CNS tumors. Using patient-derived primary glioblastoma stem cell (GSC) lines and control cell lines (astrocytes and fibroblasts), we first profiled treatment-induced changes in the epigenetic landscape using WGBS-seq and ATAC-seq. Then, using nanoCAGE-seq, both short-read and long-read RNA-seq, we identified treatment-induced, TE-derived transcripts that are predominantly expressed in glioblastoma cells along with upregulation of antiviral gene programs. Finally, using LC-MS/MS, we validated that tumor-enriched reactivated TEs, which mostly originate from the LTR class, encode HLA-I presented antigens in primary GSCs. Notably, epigenetic therapy also reactivated many TEs in proliferating control cell lines, and thus we provide evidence that targeted approaches like CRISPRa might reduce the side effects of activating nonspecific TE loci. Overall, our findings suggest that the therapeutic utilization of epigenetic treatment-induced, TE-derived antigens holds great promise but also provides a cautionary tale regarding the careful selection of tumor-enriched antigen targets.

Epigenetics of Conjunctival Melanoma: Current Knowledge and Future Directions.

The purpose of this article is to provide a literature review of the epigenetic understanding of conjunctival melanoma (CM), with a primary focus on current gaps in knowledge and future directions in research. CM is a rare aggressive cancer that predominantly affects older adults. Local recurrences and distant metastases commonly occur in CM patients; however, their prediction and management remain challenging. Hence, there is currently an unmet need for useful biomarkers and more effective treatments to improve the clinical outcomes of these patients. Like other cancers, CM occurrence and prognosis are believed to be influenced by multiple genetic and epigenetic factors that contribute to tumor development/progression/recurrence/spread, immune evasion, and primary/acquired resistance to therapies. Epigenetic alterations may involve changes in chromatin conformation/accessibility, post-translational histone modifications or the use of histone variants, changes in DNA methylation, alterations in levels/functions of short (small) or long non-coding RNAs (ncRNAs), or RNA modifications. While recent years have witnessed a rapid increase in available epigenetic technologies and epigenetic modulation-based treatment options, which has enabled the development/implementation of various epi-drugs in the cancer field, the epigenetic understanding of CM remains limited due to a relatively small number of epigenetic studies published to date. These studies primarily investigated DNA methylation, ncRNA (e.g., miRNA or circRNA) expression, or RNA methylation. While these initial epigenetic investigations have revealed some potential biomarkers and/or therapeutic targets, they had various limitations, and their findings warrant replication in independent and larger studies/samples. In summary, an in-depth understanding of CM epigenetics remains largely incomplete but essential for advancing our molecular knowledge and improving clinical management/outcomes of this aggressive disease.

Deciphering Depression: Epigenetic Mechanisms and Treatment Strategies.

Depression, a significant mental health disorder, is under intense research scrutiny to uncover its molecular foundations. Epigenetics, which focuses on controlling gene expression without altering DNA sequences, offers promising avenues for innovative treatment. This review explores the pivotal role of epigenetics in depression, emphasizing two key aspects: (I) identifying epigenetic targets for new antidepressants and (II) using personalized medicine based on distinct epigenetic profiles, highlighting potential epigenetic focal points such as DNA methylation, histone structure alterations, and non-coding RNA molecules such as miRNAs. Variations in DNA methylation in individuals with depression provide opportunities to target genes that are associated with neuroplasticity and synaptic activity. Aberrant histone acetylation may indicate that antidepressant strategies involve enzyme modifications. Modulating miRNA levels can reshape depression-linked gene expression. The second section discusses personalized medicine based on epigenetic profiles. Analyzing these patterns could identify biomarkers associated with treatment response and susceptibility to depression, facilitating tailored treatments and proactive mental health care. Addressing ethical concerns regarding epigenetic information, such as privacy and stigmatization, is crucial in understanding the biological basis of depression. Therefore, researchers must consider these issues when examining the role of epigenetics in mental health disorders. The importance of epigenetics in depression is a critical aspect of modern medical research. These findings hold great potential for novel antidepressant medications and personalized treatments, which would significantly improve patient outcomes, and transform psychiatry. As research progresses, it is expected to uncover more complex aspects of epigenetic processes associated with depression, enhance our comprehension, and increase the effectiveness of therapies.

Progesterone may be a regulator and B12 could be an indicator of the proximal D4Z4 repeat methylation status on 4q35ter.

Facioscapulohumeral dystrophy (FSHD) has a hypomethylation-related epigenetic background and exhibits a different course in male and female patients. The differences between males and females have been linked to the levels of sex hormones. This study is the first to investigate the possible effect of these hormones on methylation status. We hypothesized that the levels of sex-related hormones, estradiol, testosterone, progesterone, and prolactin might be associated with the methylation status of the proximal part of the D4Z4. We also investigated the effect of fT3, folic acid, and vitamin B12 levels. We collected blood from 28 FSHD patients and 28 controls. DNA was extracted from each individual for bisulfite methylation analysis and serum was separated for biochemical analysis of estradiol, testosterone, progesterone, prolactin, fT3, folic acid, and B12 analysis. Methylation analysis was specified to the DR1, 5P regions and the proximal region covering both DR1 and 5P. Methylation levels were compared between FSHD patients and controls. The correlation of methylation levels with estradiol, testosterone, progesterone, prolactin, fT3, folic acid, and B12 was investigated. We found that the 5P region and the proximal region were significantly hypomethylated in FSHD patients compared to the controls, but not the DR1 region. Male patients exhibited a significant reduction in DNA methylation compared to male controls. Older FSHD patients exhibited a notable decrease in fT3 levels and hypomethylation of the 5P region. Analyses of each CpG revealed seven hypomethylated positions that were significantly different from the control group. Two of the positions demonstrated a correlation with progesterone in the control group. With the exception of one position, the methylation levels were inversely correlated with vitamin B12 in FSHD patients. The results of our study indicate that the methylation of the proximal D4Z4 region, particularly at specific positions, may be associated with progesterone. In addition, vitamin B12 may be an indicator of hypomethylation. We suggest that examining position-specific methylations may be a useful approach for the development of epigenetic treatment modalities.

Computational insights into CRISP3 downregulation in cervical cancer and its cervical lineages pattern.

Cysteine-rich secretory protein 3 (CRISP3) emerges as a potential biomarker in the study of many cancers, including cervical cancer (CC). This study aimed to analyze the expression pattern of CRISP3 in CC patients and CC cell lineages, following treatment with the epigenetic drugs: trichostatin A (TSA) and 5-aza-2'-deoxycytidine (5-aza). The differentially expressed genes identified in GSE63514 were used to construct a protein-protein interaction network. CRISP3 was selected for subsequent analyses. We utilized data from the TCGA and GENT2 projects to evaluate the expression profile and clinical behavior of CRISP3. Additionally, we conducted cell culture experiments to analyze the expression profile of CRISP3 in cells. Low levels of CRISP3 were observed in squamous cell carcinoma (SCC) and human papillomavirus (HPV)16+, along with being associated with worse overall survival (OS). MIR-1229-3p was analyzed, and its high expression was associated with worse prognostic outcomes. In CC-derived cell lines, we observed low levels of CRISP3 in SiHa, followed by SW756, C33A, HeLa, and higher levels in CaSki. All cells were treated with TSA, 5-aza, or both. In all cell lines, treatment with TSA resulted in increased transcription of CRISP3. We identified a significant downregulation of CRISP3 in CC, particularly in cases with HPV16 infection and SCC, which was associated with poorer OS. Preliminary findings suggest that epigenetic treatments with TSA and 5-aza may modulate CRISP3 expression, warranting further research to elucidate its regulatory mechanisms and potential as a prognostic biomarker.

Efficient activation of hundreds of LTR12C elements reveals cis-regulatory function determined by distinct epigenetic mechanisms.

Long terminal repeats (LTRs), which often contain promoter and enhancer sequences of intact endogenous retroviruses (ERVs), are known to be co-opted as cis-regulatory elements for fine-tuning host-coding gene expression. Since LTRs are mainly silenced by the deposition of repressive epigenetic marks, substantial activation of LTRs has been found in human cells after treatment with epigenetic inhibitors. Although the LTR12C family makes up the majority of ERVs activated by epigenetic inhibitors, how these epigenetically and transcriptionally activated LTR12C elements can regulate the host-coding gene expression remains unclear due to genome-wide alteration of transcriptional changes after epigenetic inhibitor treatments. Here, we specifically transactivated >600 LTR12C elements by using single guide RNA-based dCas9-SunTag-VP64, a site-specific targeting CRISPR activation (CRISPRa)system, with minimal off-target events. Interestingly, most of the transactivated LTR12C elements acquired the H3K27ac-marked enhancer feature, while only 20% were co-marked with promoter-associated H3K4me3 modifications. The enrichment of the H3K4me3 signal was intricately associated with downstream regions of LTR12C, such as internal regions of intact ERV9 or other types of retrotransposons. Here, we leverage an optimized CRISPRa system to identify two distinct epigenetic signatures that define LTR12C transcriptional activation, which modulate the expression of proximal protein-coding genes.

KiSS-1 Modulation by Epigenetic Agents Improves the Cisplatin Sensitivity of Lung Cancer Cells.

Epigenetic alterations my play a role in the aggressive behavior of Non-Small Cell Lung Cancer (NSCLC). Treatment with the histone deacetylase inhibitor suberoylanilide hydroxamic acid (SAHA, vorinostat) has been reported to interfere with the proliferative and invasive potential of NSCLC cells. In addition, the DNA methyltransferase inhibitor azacytidine (AZA, vidaza) can modulate the levels of the metastasis suppressor KiSS-1. Thus, since cisplatin is still clinically available for NSCLC therapy, the aim of this study was to evaluate drug combinations between cisplatin and SAHA as well as AZA using cisplatin-sensitive H460 and -resistant H460/Pt NSCLC cells in relation to KiSS-1 modulation. An analysis of drug interaction according to the Combination-Index values indicated a more marked synergistic effect when the exposure to SAHA or AZA preceded cisplatin treatment with respect to a simultaneous schedule. A modulation of proteins involved in apoptosis (p53, Bax) was found in both sensitive and resistant cells, and compared to the treatment with epigenetic agents alone, the combination of cisplatin and SAHA or AZA increased apoptosis induction. The epigenetic treatments, both as single agents and in combination, increased the release of KiSS-1. Finally, the exposure of cisplatin-sensitive and -resistant cells to the kisspeptin KP10 enhanced cisplatin induced cell death. The efficacy of the combination of SAHA and cisplatin was tested in vivo after subcutaneous inoculum of parental and resistant cells in immunodeficient mice. A significant tumor volume inhibition was found when mice bearing advanced tumors were treated with the combination of SAHA and cisplatin according to the best schedule identified in cellular studies. These results, together with the available literature, support that epigenetic drugs are amenable for the combination treatment of NSCLC, including patients bearing cisplatin-resistant tumors.

Evolving Strategies in NSCLC Care: Targeted Therapies, Biomarkers, Predictive Models, and Patient Management

Abstract: Lung cancer, primarily Non-Small Cell Lung Cancer (NSCLC), is a global public health concern responsible for 80-85% of cases, with over two million new cases occurring annually, and 50% of them in Asia. While there has been a gradual reduction in United States (US) cases over the last decade, with 238,340 new cases and 127,070 deaths reported in 2023, managing metastatic NSCLC remains crucial, focusing on prolonging survival and enhancing quality of life. Integration of early palliative care shows promise in this regard. International guidelines recommend personalized treatment guided by genetic mutations (Epidermal Growth Factor Receptor (EGFR), Anaplastic Lymphoma Kinase, C-Ros oncogene [1ROS1]) and systemic therapies, including chemotherapy, targeted therapy, and immunotherapy, which play pivotal roles in redefining care. Treatment effectiveness hinges on factors such as cancer stage, patient health, and therapy type, with surgery and radiation therapy common in early stages and advanced stages requiring chemotherapy, targeted therapy, or immunotherapy. Despite advancements in treatment modalities, NSCLC continues to pose a significant challenge globally, particularly in Asia, where a substantial portion of new cases arise. While there has been an uncertain reduction in the incidence of lung cancer in the US over the past decade, the burden of the disease persists, with substantial mortality rates reported annually. Additionally, upon diagnosis, many NSCLC patients present with distant metastases, necessitating effective treatment strategies to improve overall survival and quality of life. The objectives include investigating targeted treatments for NSCLC with specific genetic mutations, examining mechanisms of novel therapies under study, evaluating preclinical and clinical studies for therapy efficacy and safety, identifying genetic and epigenetic biomarkers for diagnosis, prognosis, and treatment selection, developing predictive models for lung cancer recurrence and survival, assessing the efficacy of treatment approaches for early-stage lung cancer, and enhancing patient outcomes through collaborative care and lifestyle interventions. These collective efforts promise to improve patient outcomes and quality of life in the battle against NSCLC.

Abstract 2865: Efficacy of MDM2 and epigenetic inhibitors treatments for neuroblastoma

Abstract Pediatric Neuroblastoma (NB) is one of the most prevalent solid tumors in children that arise from embryonic neural crest cells and poses a significant challenge in the field of oncology. There are about 700 to 800 new cases of neuroblastoma diagnosed each year in the United States, and accounts for approximately 15% of all childhood cancer mortalities. Since this malignancy predominantly affects infants and young children, it is imperative to decipher the underlying molecular factors driving its pathogenesis. The novel molecular therapeutic approach includes the use of epigenetic modifiers as drugs. This approach aims to reverse significant epigenetic events underlying cancer pathogenesis, particularly abnormalities in histone modifications and DNA methylation. The reduction of both DNA and histone methylation levels leads to the reactivation of tumor suppressor genes and inhibits cancer cell proliferation and cell growth. In this study, we used selective and reversible small molecule agents such as MDM2 inhibitor (RG7388) and epigenetic modifiers (CM272 and SAHA) to block cell proliferation by inducing cell cycle arrest via enforcing Epigenetic alterations. Our initial experiments were designed to understand the effects of RG7388, CM272, and SAHA treatments on NB and their impact on cell cycle progression. It was hypothesized that the decrease in DNA methylation and increase in histone modification- augment p21 expression via the use of MDM2 inhibitors and epigenetic modifiers. To test this hypothesis, the NB cells (SK-N-SK and IMR-32) were treated with RG7388, CM272, and SAHA for 24 hours. The extent of Cell death was determined for NB cells by using the Trypan Blue Dye Exclusion (TBDE) method, and CellTiter-Glo® Luminescent Cell Viability Assay. Induction of apoptosis was determined by using the Immunofluorescence staining method with DEVD-amc substrate. The results of our study suggested that RG7388, CM272, and SAHA were able to induce cell death in the SK-N-SH cells following 24-hour treatment. Furthermore, we analyzed the levels of Tumor suppressor (p53), cell cycle arrest (p21, p27, AurkB, CDC25A, CyclinD) cell death (Bax, Bcl2, LC3, Beclin, PARP, Cleaved PARP, RIP1, RIP3, MLKL, p-AKT), and Epigenetic biomarker (DNMT1, DNMT3A, DNMT3B, acetyl histoneH3, H4, and H2b) protein expression levels using western blot analysis. The results showed significant elevation of p53, p21, p27, and acetylation of histone family biomarkers after treatment when compared with the control group. In summary, our results indicate that RG7388, CM272, and SAHA treatments can effectively induce cellular responses and prevent cell growth and progression by enforcing epigenetic changes in the NB cells. (This research was supported by the National Pediatric Cancer Foundation, Tampa, Florida, and the Royal Dames of Cancer Research Inc. of Ft. Lauderdale, Florida) Citation Format: Tahani Momenah, Umamaheswari Natarajan, Shyam Jaganathan, Appu Rathinavelu. Efficacy of MDM2 and epigenetic inhibitors treatments for neuroblastoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 2865.

Abstract 7014: Integrative DNA methylation cancer profiling reveals patterns associated with tumor progression and treatment response

Abstract DNA methylation plays a critical role in tumor progression and response to chemotherapy. Frequently dysregulated during tumor development, it is closely intertwined with mixed effects from patient epigenetic background, tissue context, and treatment pressure. Here, we leveraged methylomic and transcriptomic profiling of 400 whole-genome sequencing samples from 125 patients with ovarian high-grade serous carcinoma (HGSC), belonging to the prospective, longitudinal, multi-region DECIDER trial (NCT04846933). This cohort included 120 samples from tubo-ovarian tumors, 209 samples from intra-abdominal metastases, and 71 ascites, representing all major sites of HGSC metastases. We profiled cancer methylome across tissues, patient groups, and various anticancer treatments using decomposition method, which allows separating the effects of tumor microenvironment and treatment, tissue, and patient specific changes, thus, facilitating integration of the heterogeneous collection of samples. First, we systematically examined the tissue-specific carcinogenesis and characterized methylomes of all types of metastases and excess fluid accumulations in the abdominal cavity. In our analyses, the cancer spread from tubo-ovarian sites to metastatic deposits involved gradual loss of DNA methylation and increase in transcriptomic levels, possibly indicating stemness. Specifically, several members of the ATP-binding-cassette (ABC) family of transporters, as well as receptor tyrosine kinases were frequently hypomethylated in bowel and omentum. The methylome of ascites showed most commonality to the tubo-ovarian tumors and peritoneum. Our results confirmed that several well-known tumor-associated genes, such as PTEN, GSK3B, ESR1, FGFR2, TNC, BCL6, HIF1A, NOTCH2 are regulated epigenetically, and this dysregulation stems early from the sites of origin. Next, we built methylomic profiles of patients with various treatment responses. Direct comparisons between good and poor responders revealed pronounced methylation differences, with refractory disease being associated with severely aberrated methylome prior to chemotherapy treatment. Neoadujuvant chemotherapy resulted in very few changes to these epigenetic aberrations and no acquired mechanisms, suggesting that intrinsic methylomes of poor responders accommodate multiple drivers for EMT, hypoxia, and chronic inflammation to resist chemotherapy-induced cell death already prior to treatment. In conclusion, using a large whole-genome sequencing DNA methylation dataset we elucidated the major underlying epigenetic mechanisms of tumorigenesis and platinum resistance, which provide possible drug targets for improving platinum sensitivity. Our multi-omics analyses enabled the identification of aberrated patterns that drive transcriptional changes, shedding light on epigenetic landscape of HGSC. Citation Format: Alexandra Lahtinen, Giovanni Marchi, Daria Afenteva, Kari Lavikka, Susanna Holmström, Elsi Pöllänen, Giulia Micoli, Ilari Maarala, Yilin Li, Taru A. Muranen, Jaana Oikkonen, Sakari Hietanen, Anni Virtanen, Johanna Hynninen, Antti Häkkinen, Sampsa Hautaniemi. Integrative DNA methylation cancer profiling reveals patterns associated with tumor progression and treatment response [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 7014.

Abstract 3201: Preclinical development of a novel Romidepsin nanoparticle for the treatment of T-Cell lymphoid malignancies

Abstract The histone deacetylase inhibitors (HDACi) have long been regarded as an important class of drugs for treating T-cell lymphoid malignancies (TCL). Romidepsin (Romi), a bicyclic peptide, was approved for patients with relapsed or refractory cutaneous (CTCL) and peripheral T-cell lymphomas (PTCL). Unfortunately, the approval of Romi for relapsed/refractory PTCL was withdrawn due to a negative Phase 4 post-marketing requirement. Given its potent activity against Class I HDACs, Romi is considered one of the most effective HDAC inhibitors studied and used in patients with TCL. Herein, we report on a first-in-class nanoparticle of Romi (NanoRomi) with a superior safety and efficacy profile compared to the free drug in preclinical models of PTCL and large granular lymphocyte leukemia (LGLL). We developed a first-in-class NanoRomi using our proprietary amphiphilic di-block copolymer-based nanochemistry platform. NanoRomi was characterized in cell viability, flow cytometry, and western blotting (WB) assays to determine the concentration-effect relationships with regard to the induction of apoptosis and histone acetylation in cell lines representative of TCL and LGLL, as well as primary LGLL patient PBMC samples. In addition, we performed extensive in vivo modeling using murine xenografts of CTCL, including repeated dose toxicity, biodistribution, efficacy, and survival studies. Cytotoxicity assays demonstrated superior/comparable activity of NanoRomi (IC50: 1.1-2.3 nM) compared to free Romi (IC50: 4.8-10.6 nM) across all PTCL and LGLL cell lines studied, while in primary LGLL samples, NanoRomi exhibited superior cytotoxicity (2-fold) compared to Romi. WB analysis showed that NanoRomi induced apoptosis and increased acetylation of histone H3 and H4 in a time and concentration-dependent manner in cell lines representing CTCL, ALK+-ALCL, and LGLL. Repeat dose toxicity studies in CTCL xenografts confirmed that the overall tolerability of NanoRomi was substantially better than Romi. Tracking studies with a fluorescent dye (DiO) in the NanoRomi demonstrated preferential localization of NanoRomi in tumors of mice compared to the normal organs after 6 hours of drug administration. NanoRomi exhibited superior efficacy in the murine CTCL xenograft models, including a significant improvement in overall survival compared to Romi. Collectively, these data show that NanoRomi exhibits markedly superior pharmacokinetics, tolerability, and efficacy in models of TCL. We anticipate that the improved activity and tolerability of NanoRomi relate to the altered pharmacologic profile and superior bioavailability of the drug, which optimizes the effects of the drug for its influence on epigenetic biology. This unique platform offers the prospect of improving the tolerability and efficacy of epigenetic treatment strategies in these challenging diseases. Citation Format: Ipsita Pal, Anuradha Illendula, Andrea Joyner, Tess M. Deddens, Deepthi P. Damera, Todd E. Fox, Marya E. Dunlap-Brown, Kallesh D. Jayappa, Thomas P. Loughran, David J. Feith, Owen A. O'Connor. Preclinical development of a novel Romidepsin nanoparticle for the treatment of T-Cell lymphoid malignancies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 3201.

Abstract IA020: Targeting transposable elements with epigenetic modulators to reverse ovarian cancer immune evasion

Abstract Transposable elements (TEs) comprise the majority of the human genome. In most somatic tissues, TEs are silenced by DNA methylation and other epigenetic modifications. Tumors exhibit changes in DNA methylation including global loss of methylation at regions that are silenced for genome stability, like TEs, and gain of methylation at the promoter regions of tumor suppressor genes. We showed that low doses of DNMT inhibitors (DNMTis) upregulate immune signaling in solid tumor cell lines and patient samples. DNMTis activate type I interferon signaling by reducing methylation and increasing expression of endogenous retroviruses (ERVs), a type of TE, that activate dsRNA sensors. DNMTis plus HDACis (histone deacetylase inhibitors, which increase histone acetylation) increase TEs in a mouse model of ovarian cancer, activating interferon signaling and recruiting CD8+ T cells to kill cancer cells and sensitize to immune checkpoint blockade therapy. We performed a genome-wide analysis of the response to DNMTi, HDACi, and combination HDACi/DNMTi in four ovarian cancer cell lines (RNA-Seq, global methylome profiling, ATAC-Seq, and P53 chIP-Seq). The addition of HDACis to DNMTis augments the upregulation of specific ERVs and the resulting downstream interferon response in human ovarian cancer cell lines. Other TE species, including LINE1 and Alu elements, are increased by DNMTi and HDACi and may contribute to the interferon response. Alu elements, which can directly bind to the dsRNA sensor MDA5, are the most significantly demethylated TEs after DNMTi treatment. Importantly, we find considerable overlap between TEs upregulated by DNMTi in cell lines and TEs upregulated by DNMTi in ovarian cancer patients from a DNMTi clinical trial. We observed that ovarian cancer cell lines with TP53 mutations exhibited significantly fewer upregulated TEs with epigenetic therapy than wild-type TP53 cell lines. This observation was validated using isogenic cell lines; the CRISPR-edited TP53-mutant cell line had significantly higher baseline expression of TEs but upregulated fewer upon epigenetic treatment. p53 bound directly to TE DNA by chIP-Seq analysis and upregulated TEs in wild type but not mutant cell lines. In addition, our RNA-sequencing analysis indicated that A-to-I RNA editing of TEs by ADAR1 was increased after DNMTi treatment. This A-to-I editing makes TE RNA less immunogenic and inhibits the immune response to DNMTi. We find that combining ADAR1 knockdown and DNMTi treatment significantly increases type I interferon signaling, recruitment and activation of host immune cells, and survival in a murine model of ovarian cancer. These data thus give a comprehensive, genome-wide picture of TE chromatin and transcription-related changes in ovarian cancer after epigenetic treatment and implicate novel regulators (p53 and ADAR1) in response to epigenetic therapies for cancer. Citation Format: Katherine B. Chiappinelli. Targeting transposable elements with epigenetic modulators to reverse ovarian cancer immune evasion [abstract]. In: Proceedings of the AACR Special Conference on Ovarian Cancer; 2023 Oct 5-7; Boston, Massachusetts. Philadelphia (PA): AACR; Cancer Res 2024;84(5 Suppl_2):Abstract nr IA020.

Dual-Epigenetically Relieving the MYC-Correlated Immunosuppression via an Advanced Nano-Radiosensitizer Potentiates Cancer Immuno-Radiotherapy.

Cancer cells can upregulate the MYC expression to repair the radiotherapy-triggered DNA damage, aggravating therapeutic resistance and tumor immunosuppression. Epigenetic treatment targeting the MYC-transcriptional abnormality may intensively solve this clinical problem. Herein, 5-Aza (a DNA methyltransferase inhibitor) and ITF-2357 (a histone deacetylase inhibitor) are engineered into a tungsten-based nano-radiosensitizer (PWAI), to suppress MYC rising and awaken robust radiotherapeutic antitumor immunity. Individual 5-Aza depletes MYC expression but cannot efficiently awaken radiotherapeutic immunity. This drawback can be overcome by the addition of ITF-2357, which triggers cancer cellular type I interferon (IFN-I) signaling. Coupling 5-Aza with ITF-2357 ensures that PWAI does not evoke the treated model with high MYC-related immune resistance while amplifying the radiotherapeutic tumor killing, and more importantly promotes the generation of IFN-I signal-related proteins involving IFN-α and IFN-β. Unlike the radiation treatment alone, PWAI-triggered immuno-radiotherapy remarkably enhances antitumor immune responses involving the tumor antigen presentation by dendritic cells, and improves intratumoral recruitment of cytotoxic T lymphocytes and their memory-phenotype formation in 4T1 tumor-bearing mice. Downgrading the radiotherapy-induced MYC overexpression via the dual-epigenetic reprogramming strategy may elicit a robust immuno-radiotherapy.

Differential expression and regulation of ADAD1, DMRTC2, PRSS54, SYCE1, SYCP1, TEX101, TEX48, and TMPRSS12 gene profiles in colon cancer tissues and their in vitro response to epigenetic drugs.

Colon cancer (CC) is a significant cause of death worldwide, particularly in Saudi Arabia. To increase the accuracy of diagnosis and treatment, it is important to discover new specific biomarkers for CC. The main objectives of this research are to identify potential specific biomarkers for the early diagnosis of CC by analyzing the expressions of eight cancer testis (CT) genes, as well as to analyze how epigenetic mechanisms control the expression of these genes in CC cell lines. Tissue samples were collected from 15 male patients with CC tissues and matched NC tissues for gene expression analysis. The expression levels of specific CT genes, including ADAD1, DMRTC2, PRSS54, SYCE1, SYCP1, TEX101, TEX48, and TMPRSS12, were assessed using quantitative techniques. To validate the gene expression patterns, we used publicly available CC statistics. To investigate the effect of inhibition of DNA methylation and histone deacetylation on CT gene expression, in vitro experiments were performed using HCT116 and Caco-2 cell lines. There was no detected expression of the genes neither in the patient samples nor in NC tissues, except for TEX48, which exhibited upregulation in CC samples compared to NC tissues in online datasets. Notably, CT genes showed expression in testis samples. In vitro, experiments demonstrated significant enhancement in mRNA expression levels of ADAD1, DMRTC2, PRSS54, SYCE1, SYCP1, TEX101, TEX48, and TMPRSS12 following treatment with 5-aza-2'-deoxycytidine and trichostatin A in HCT116 and Caco-2 cell lines. Epigenetic treatments modify the expression of CT genes, indicating that these genes can potentially be used as biomarkers for CC. The importance of conducting further research to understand and target epigenetic mechanisms to improve CC treatment cannot be overemphasized.

Unveiling Arformoterol as a potent LSD1 inhibitor for breast cancer treatment: A comprehensive study integrating 3D-QSAR pharmacophore modeling, molecular docking, molecular dynamics simulations and in vitro assays

Lysine Specific Demethylase 1 (LSD1) has been identified as a chromatin-modifying enzyme implicated in various cancer pathogeneses, highlighting the potential for novel epigenetic cancer treatments through the development of effective inhibitors. We employed 3D-QSAR pharmacophore modeling, molecular docking, and molecular dynamics simulations to identify a promising drug candidate for LSD1 inhibition. RMSD, RMSF, H-bond, and DSSP analysis demonstrated that ZINC02599970 (Arformoterol) and ZINC13453966 exhibited the highest LSD1 inhibitory potential.Experimental validation using MCF-7 and MDA-MB-231 cell lines revealed that Arformoterol displayed potent antiproliferative activity with IC50 values of 12.30 ± 1.48 μM and 19.69 ± 1.15 μM respectively. In contrast, the IC50 values obtained for the control (tranylcypromine) in exposure to MCF-7 and MDA-MB-231 cells were 104.6 ± 1.69 μM and 77 ± 0.67 μM, respectively. Arformoterol demonstrated greater LSD1 inhibitory potency in MCF-7 cells compared to MDA-MB-231 cells. Also, the expression of genes involved in chromatin rearrangement (LSD1), angiogenesis (VEGF1), cell migration (RORα), signal transduction (S100A8), apoptosis, and cell cycle (p53) were investigated. Arformoterol enhanced apoptosis and induced cell cycle arrest at the G2/M phase, both in MCF-7 and MDA-MB-231 cancer cells. Based on our findings, we propose that Arformoterol represents a promising candidate for breast cancer treatment, owing to its potent LSD1 inhibitory activity.

On minimising tumoural growth under treatment resistance

Drug resistance is a major challenge for curative cancer treatment, representing the main reason of death in patients. Evolutionary biology suggests pauses between treatment rounds as a way to delay or even avoid resistance emergence. Indeed, this approach has already shown promising preclinical and early clinical results, and stimulated the development of mathematical models for finding optimal treatment protocols. Due to their complexity, however, these models do not lend themself to a rigorous mathematical analysis, hence so far clinical recommendations generally relied on numerical simulations and ad-hoc heuristics. Here, we derive two mathematical models describing tumour growth under genetic and epigenetic treatment resistance, respectively, which are simple enough for a complete analytical investigation. First, we find key differences in response to treatment protocols between the two modes of resistance. Second, we identify the optimal treatment protocol which leads to the largest possible tumour shrinkage rate. Third, we fit the “epigenetic model” to previously published xenograft experiment data, finding excellent agreement, underscoring the biological validity of our approach. Finally, we use the fitted model to calculate the optimal treatment protocol for this specific experiment, which we demonstrate to cause curative treatment, making it superior to previous approaches which generally aimed at stabilising tumour burden. Overall, our approach underscores the usefulness of simple mathematical models and their analytical examination, and we anticipate our findings to guide future preclinical and, ultimately, clinical research in optimising treatment regimes.

Using long-read CAGE sequencing to profile cryptic-promoter-derived transcripts and their contribution to the immunopeptidome.

Recent studies have shown that the noncoding genome can produce unannotated proteins as antigens that induce immune response. One major source of this activity is the aberrant epigenetic reactivation of transposable elements (TEs). In tumors, TEs often provide cryptic or alternate promoters, which can generate transcripts that encode tumor-specific unannotated proteins. Thus, TE-derived transcripts (TE transcripts) have the potential to produce tumor-specific, but recurrent, antigens shared among many tumors. Identification of TE-derived tumor antigens holds the promise to improve cancer immunotherapy approaches; however, current genomics and computational tools are not optimized for their detection. Here we combined CAGE technology with full-length long-read transcriptome sequencing (long-read CAGE, or LRCAGE) and developed a suite of computational tools to significantly improve immunopeptidome detection by incorporating TE and other tumor transcripts into the proteome database. By applying our methods to human lung cancer cell line H1299 data, we show that long-read technology significantly improves mapping of promoters with low mappability scores and that LRCAGE guarantees accurate construction of uncharacterized 5' transcript structure. Augmenting a reference proteome database with newly characterized transcripts enabled us to detect noncanonical antigens from HLA-pulldown LC-MS/MS data. Lastly, we show that epigenetic treatment increased the number of noncanonical antigens, particularly those encoded by TE transcripts, which might expand the pool of targetable antigens for cancers with low mutational burden.

CPT1A induction following epigenetic perturbation promotes MAVS palmitoylation and activation to potentiate antitumor immunity

Targeting epigenetic regulators to potentiate anti-PD-1 immunotherapy converges on the activation of type I interferon (IFN-I) response, mimicking cellular response to viral infection, but how its strength and duration are regulated to impact combination therapy efficacy remains largely unknown. Here, we show that mitochondrial CPT1A downregulation following viral infection restrains, while its induction by epigenetic perturbations sustains, a double-stranded RNA-activated IFN-I response. Mechanistically, CPT1A recruits the endoplasmic reticulum-localized ZDHHC4 to catalyze MAVS Cys79-palmitoylation, which promotes MAVS stabilization and activation by inhibiting K48- but facilitating K63-linked ubiquitination. Further elevation of CPT1A incrementally increases MAVS palmitoylation and amplifies the IFN-I response, which enhances control of viral infection and epigenetic perturbation-induced antitumor immunity. Moreover, CPT1A chemical inducers augment the therapeutic effect of combined epigenetic treatment with PD-1 blockade in refractory tumors. Our study identifies CPT1A as a stabilizer of MAVS activation, and its link to epigenetic perturbation can be exploited for cancer immunotherapy.

EPCO-50. THE TRANSCRIPTIONAL LANDSCAPE OF KEY INNATE DNA SENSORS WITHIN PRIMARY BRAIN TUMORS

Abstract Primary brain tumors are notoriously resistant to immunotherapy. The efficacy of these treatments potentially requires normal expression of DNA innate sensors within both the immune and tumor compartments. Recently, we found that STING1, involved in the CGAS/STING pathway, is epigenetically silenced in the neoplastic cells of primary brain tumors. This silencing can be traced back to the normal brain. We and others have shown that rescue of STING1 expression can be modulated with epigenetic treatments. The mechanism by which DNA damage in cancer leads to an inflammatory response sheds light on the significance of other DNA sensors. We hypothesize that innate immune silencing within the tumor contributes to immunotherapy resistance and the addition of epigenetic treatments could increase efficacy. We evaluated the transcriptional landscape of DNA innate sensors within normal adult brain and in patient derived tumors including glioblastoma, pilocytic astrocytoma, and diffuse midline gliomas, H3K27M mutant. We found low expression of additional cytosolic DNA sensors including cGAS, AIM2, ZBP1 in normal neuronal as well as tumor cells. Since epigenetic silencing is modulated during normal development, we compared the transcriptional innate profiles from normal cortex brain development to primary brain cancers. DNA innate immune sensor expression correlates with pre-oligodendrocyte progenitor cells and oligodendrocyte progenitor cells. These results suggest the innate immune suppression of these key cytosolic DNA sensors is established early in fetal brain development and retained in the context of primary brain tumors. We are currently exploring the epigenetic profiles of fetal brain and brain tumors to determine how these innate immune expression patterns affect tumorigenesis and response to immunotherapy treatment.

Advances in the Delivery and Development of Epigenetic Therapeutics for the Treatment of Cancer.

Gene expression at the transcriptional level is altered by epigenetic modifications such as DNA methylation, histone methylation, and acetylation, which can upregulate, downregulate, or entirely silence genes. Pathological dysregulation of epigenetic processes can result in the development of cancer, neurological problems, metabolic disorders, and cardiovascular diseases. It is of promising therapeutic interest to find medications that target these epigenetic alterations. Despite the enormous amount of work that has been done in this area, very few molecules have been approved for clinical purposes. This article provides a comprehensive review of recent advances in epigenetic therapeutics for cancer, with a specific focus on emerging delivery and development strategies. Various delivery systems, including pro-drugs, conjugated molecules, nanoparticles (NPs), and liposomes, as well as remedial strategies such as combination therapies, and epigenetic editing, are being investigated to improve the efficacy and specificity of epigenetic drugs (epi-drugs). Furthermore, the challenges associated with available epi-drugs and the limitations of their translation into clinics have been discussed. Target selection, isoform selectivity, physiochemical properties of synthesized molecules, drug screening, and scalability of epi-drugs from preclinical to clinical fields are the major shortcomings that are addressed. This Review discusses novel strategies for the identification of new biomarkers, exploration of the medicinal chemistry of epigenetic modifiers, optimization of the dosage regimen, and design of proper clinical trials that will lead to better utilization of epigenetic modifiers over conventional therapies. The integration of these approaches holds great potential for improving the efficacy and precision of epigenetic treatments, ultimately benefiting cancer patients.