Your search keyword '"Moksa, Michelle"' showing total 2 results

1. Genome-Wide CRISPR Screen Identifies KEAP1 Perturbation as a Vulnerability of ARID1A-Deficient Cells.

Author

Fournier, Louis-Alexandre, Kalantari, Forouh, Wells, James P., Lee, Joon Seon, Trigo-Gonzalez, Genny, Moksa, Michelle M., Smith, Theodore, White, Justin, Shanks, Alynn, Wang, Siyun L., Su, Edmund, Wang, Yemin, Huntsman, David G., Hirst, Martin, and Stirling, Peter C.

Subjects

PROTEINS, EPITHELIAL cells, RESEARCH funding, EARLY detection of cancer, OVARIAN tumors, CELLULAR signal transduction, GENE expression, CELL lines, CRISPRS, GENETIC mutation, GENOMES, PHENOTYPES

Abstract

Simple Summary: Cancer is a disease caused by mutations in DNA differentiating cancer cells from normal cells. Precision medicine could exploit these genetic differences to identify and create therapeutic opportunities that selectively kill cancer cells while sparing normal cells. In some cancers, the same mutations recur, making them desirable biomarkers for genetics-based therapeutic strategies. This is the case for the gene ARID1A which is lost in about 50% of ovarian clear cell carcinomas. We used genetic screening to identify targets for killing an ovarian clear cell carcinoma cell line lacking the ARID1A gene. We identified a cancer stress response regulator called KEAP1 as a potential target for ARID1A-deficient ovarian clear cell carcinomas. Using different approaches and cell lines, we observed a relationship where ARID1A-deficient cells required KEAP1 for fitness. Together these data suggest that KEAP1 could be pursued as a means to selectively kill certain types of ARID1A-deficient cancer. ARID1A is the core DNA-binding subunit of the BAF chromatin remodeling complex and is mutated in about 8% of all cancers. The frequency of ARID1A loss varies between cancer subtypes, with clear cell ovarian carcinoma (CCOC) presenting the highest incidence at > 50% of cases. Despite a growing understanding of the consequences of ARID1A loss in cancer, there remains limited targeted therapeutic options for ARID1A-deficient cancers. Using a genome-wide CRISPR screening approach, we identify KEAP1 as a genetic dependency of ARID1A in CCOC. Depletion or chemical perturbation of KEAP1 results in selective growth inhibition of ARID1A-KO cell lines and edited primary endometrial epithelial cells. While we confirm that KEAP1-NRF2 signalling is dysregulated in ARID1A-KO cells, we suggest that this synthetic lethality is not due to aberrant NRF2 signalling. Rather, we find that KEAP1 perturbation exacerbates genome instability phenotypes associated with ARID1A deficiency. Together, our findings identify a potentially novel synthetic lethal interaction of ARID1A-deficient cells. [ABSTRACT FROM AUTHOR]

Published

2024

2. Prenatal Adversity Alters the Epigenetic Profile of the Prefrontal Cortex: Sexually Dimorphic Effects of Prenatal Alcohol Exposure and Food-Related Stress.

Author

Lussier, Alexandre A., Bodnar, Tamara S., Moksa, Michelle, Hirst, Martin, Kobor, Michael S., and Weinberg, Joanne

Subjects

PRENATAL alcohol exposure, FETAL alcohol syndrome, EPIGENETICS, DNA methyltransferases, ALCOHOL, DNA methylation

Abstract

Prenatal adversity or stress can have long-term consequences on developmental trajectories and health outcomes. Although the biological mechanisms underlying these effects are poorly understood, epigenetic modifications, such as DNA methylation, have the potential to link early-life environments to alterations in physiological systems, with long-term functional implications. We investigated the consequences of two prenatal insults, prenatal alcohol exposure (PAE) and food-related stress, on DNA methylation profiles of the rat brain during early development. As these insults can have sex-specific effects on biological outcomes, we analyzed epigenome-wide DNA methylation patterns in prefrontal cortex, a key brain region involved in cognition, executive function, and behavior, of both males and females. We found sex-dependent and sex-concordant influences of these insults on epigenetic patterns. These alterations occurred in genes and pathways related to brain development and immune function, suggesting that PAE and food-related stress may reprogram neurobiological/physiological systems partly through central epigenetic changes, and may do so in a sex-dependent manner. Such epigenetic changes may reflect the sex-specific effects of prenatal insults on long-term functional and health outcomes and have important implications for understanding possible mechanisms underlying fetal alcohol spectrum disorder and other neurodevelopmental disorders. [ABSTRACT FROM AUTHOR]

Published

2021