Your search keyword '"Geulah Livshits"' showing total 3 results

1. MLL3 regulates the CDKN2A tumor suppressor locus in liver cancer

Author

Changyu Zhu, Yadira M Soto-Feliciano, John P Morris, Chun-Hao Huang, Richard P Koche, Yu-jui Ho, Ana Banito, Chun-Wei Chen, Aditya Shroff, Sha Tian, Geulah Livshits, Chi-Chao Chen, Myles Fennell, Scott A Armstrong, C David Allis, Darjus F Tschaharganeh, and Scott W Lowe

Subjects

liver cancer, MLL3, chromatin, cancer, tumor suppressor, Medicine, Science, Biology (General), QH301-705.5

Abstract

Mutations in genes encoding components of chromatin modifying and remodeling complexes are among the most frequently observed somatic events in human cancers. For example, missense and nonsense mutations targeting the mixed lineage leukemia family member 3 (MLL3, encoded by KMT2C) histone methyltransferase occur in a range of solid tumors, and heterozygous deletions encompassing KMT2C occur in a subset of aggressive leukemias. Although MLL3 loss can promote tumorigenesis in mice, the molecular targets and biological processes by which MLL3 suppresses tumorigenesis remain poorly characterized. Here, we combined genetic, epigenomic, and animal modeling approaches to demonstrate that one of the mechanisms by which MLL3 links chromatin remodeling to tumor suppression is by co-activating the Cdkn2a tumor suppressor locus. Disruption of Kmt2c cooperates with Myc overexpression in the development of murine hepatocellular carcinoma (HCC), in which MLL3 binding to the Cdkn2a locus is blunted, resulting in reduced H3K4 methylation and low expression levels of the locus-encoded tumor suppressors p16/Ink4a and p19/Arf. Conversely, elevated KMT2C expression increases its binding to the CDKN2A locus and co-activates gene transcription. Endogenous Kmt2c restoration reverses these chromatin and transcriptional effects and triggers Ink4a/Arf-dependent apoptosis. Underscoring the human relevance of this epistasis, we found that genomic alterations in KMT2C and CDKN2A were associated with similar transcriptional profiles in human HCC samples. These results collectively point to a new mechanism for disrupting CDKN2A activity during cancer development and, in doing so, link MLL3 to an established tumor suppressor network.

Published

2023

2. Arid1a restrains Kras-dependent changes in acinar cell identity

Author

Geulah Livshits, Direna Alonso-Curbelo, John P Morris IV, Richard Koche, Michael Saborowski, John Erby Wilkinson, and Scott W Lowe

Subjects

pancreas cancer, SWI/SNF, acinar cell, mouse model, RNAi, plasticity, Medicine, Science, Biology (General), QH301-705.5

Abstract

Mutations in members of the SWI/SNF chromatin remodeling family are common events in cancer, but the mechanisms whereby disruption of SWI/SNF components alters tumorigenesis remain poorly understood. To model the effect of loss of function mutations in the SWI/SNF subunit Arid1a in pancreatic ductal adenocarcinoma (PDAC) initiation, we directed shRNA triggered, inducible and reversible suppression of Arid1a to the mouse pancreas in the setting of oncogenic KrasG12D. Arid1a cooperates with Kras in the adult pancreas as postnatal silencing of Arid1a following sustained KrasG12D expression induces rapid and irreversible reprogramming of acinar cells into mucinous PDAC precursor lesions. In contrast, Arid1a silencing during embryogenesis, concurrent with KrasG12D activation, leads to retention of acinar cell fate. Together, our results demonstrate Arid1a as a critical modulator of Kras-dependent changes in acinar cell identity, and underscore an unanticipated influence of timing and genetic context on the effects of SWI/SNF complex alterations in epithelial tumorigenesis.

Published

2018

3. Arid1a restrains Kras-dependent changes in acinar cell identity

Author

John P. Morris, Direna Alonso-Curbelo, Richard Koche, Scott W. Lowe, John E. Wilkinson, Michael Saborowski, and Geulah Livshits

Subjects

0301 basic medicine, Pancreatic Cell Fate, ARID1A, Mouse, Carcinogenesis, cells, Cellular differentiation, genetic processes, pancreatic cancer, Acinar Cells, medicine.disease_cause, Mice, Morphogenesis, Biology (General), Cancer Biology, Mutation, General Neuroscience, food and beverages, Nuclear Proteins, Cell Differentiation, General Medicine, acinar cell, SWI/SNF, 3. Good health, Chromatin, Cell biology, DNA-Binding Proteins, Cell Transformation, Neoplastic, Medicine, biological phenomena, cell phenomena, and immunity, Insight, chromatin remodeling protein, Carcinoma, Pancreatic Ductal, QH301-705.5, mouse model, Science, macromolecular substances, Biology, digestive system, General Biochemistry, Genetics and Molecular Biology, Proto-Oncogene Proteins p21(ras), 03 medical and health sciences, pancreas cancer, stomatognathic system, medicine, Acinar cell, Animals, General Immunology and Microbiology, fungi, enzymes and coenzymes (carbohydrates), 030104 developmental biology, Gene Expression Regulation, RNAi, plasticity, Cancer cell, Kras, Arid1a, Transcription Factors

Abstract

The pancreas produces many different hormones, as well as several substances important for digestion. To perform these roles, the pancreas contains different types of cells; for example, acinar cells make digestive enzymes that help to break down food. But, like other cells in the body, pancreatic cells can accumulate mutations in their DNA that cause them to divide, acquire an altered identity and form a cancerous tumor. The DNA of cells is packed into a structure called chromatin. While the DNA sequence is essentially the same across all normal cells of a given individual, chromatin can be more or less compacted in the different cell types that comprise our body tissues. A collection of proteins called the SWI/SNF complex can reorganize the chromatin to change how tightly the DNA is packed. This determines which genes in the DNA are accessible and can be activated, and which ones cannot. Around 25% of pancreatic cancers contain mutations in genes that produce proteins of the SWI/SNF complex. These mutations normally occur with an additional mutation that over-activates the gene that produces a potentially cancer-causing protein called Kras. Livshits et al. have now genetically engineered mice to investigate how one such SWI/SNF complex protein, called Arid1a, affects how pancreatic cancer develops using a genetic approach that made possible to temporarily halt the production of Arid1a in acinar cells by feeding these mice an antibiotic. The gene that produces Kras was also over-activated in the pancreases of the mice, making them more likely to develop cancer. Within just two weeks of stopping the production of Arid1a, the acinar cells stopped producing digestive enzymes and started making other proteins that are typically found in cancerous cells, indicating that Arid1a is involved in maintaining the normal identity and activity of these cells. Restoring the ability of altered acinar cells to produce normal levels of Arid1a (by removing the mice from the antibiotic diet) did not reverse these changes. Biochemical experiments showed that acinar cells with reduced levels of Arid1a have altered chromatin. In particular, the genes that produce digestive enzymes, which are normally active in healthy pancreases, were less accessible in mice who had over-active Kras and reduced levels of Arid1a. The results presented by Livshits et al. provide the first evidence of how alterations to Arid1a can lead to irreversible changes in the identity and activity of pancreatic acinar cells. These results will need to be carefully considered by researchers who are developing treatments for cancer patients with mutations in Arid1a and other SWI/SNF proteins. In particular, methods that attempt to restore the functions of absent SWI/SNF proteins to cancer cells are unlikely to treat the cancer successfully.

Published

2018