Start Date: | 12/15/2021 | Start Time: | 3:00 PM |
End Date: | 12/15/2021 | End Time: | 5:00 PM |
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Event Description
BIOMED PhD Research Proposal
Title:
Multi-omics Characterization of the Loss of Transcriptomic Modulators BAP1 and SOX10 in Uveal and Cutaneous Melanoma Speaker: Timothy Purwin, PhD Candidate School of Biomedical Engineering, Science and Health Systems Drexel University
Advisors: Ahmet Sacan, PhD Associate Teaching Professor School of Biomedical Engineering, Science and Health Systems Drexel University
Andrew Aplin, PhD The Kalbach-Newton Professor in Cancer Research Department of Cancer Biology Thomas Jefferson University
Abstract: Identifying alterations to the transcriptomic networks in cancers is crucial for studying their mechanisms and exploiting their weaknesses. In cutaneous melanoma (CM), the deadliest form of skin cancer, and uveal melanoma (UM), the most common type of intraocular cancer, loss of specific transcriptomic modulators significantly impacts the control of these networks and is associated with disease progression. In CM, recent research into transcriptomics at the cellular level has revealed that cell state plasticity plays a major role in therapeutic resistance. Loss of SOX10 activity has been linked to drug tolerance and an invasive phenotype. Its involvement with immunotherapy resistance is currently unknown. Identifying gene targets and determining its activity in transcriptomic data is important for studying its role in disease progression. In UM, the median overall survival time for a patient with metastatic disease is between six months and a year. Loss-of-function mutations in BAP1, an epigenetic regulator that deubiquitinates monoubiquitinated Histone H2A, occur in 45% of primary-site tumors. Despite this, 80% of metastatic tumors present genomic loss of BAP1. The goals of this study are to characterize a transcriptome profile due to SOX10 loss in CM and to identify transcriptomic targets linked to disease progression due to BAP1 loss in UM.
We propose that by integrating multiple datasets, layers of 'omics data, and gene-dependent results with patient-derived data, we can identify genes core to the loss of SOX10 in CM and BAP1 in UM. We develop a robust SOX10 loss regulatory gene signature by integrating SOX10 ChIP-seq with time-course knockdown ATAC-seq and CRISPR knockout RNA-seq data. We validate the gene signature using multiple SOX10 knockdown, cell line panel, and drug-resistant gene expression datasets. We determine if SOX10 activity is lower in immunotherapy-resistant tumors using patient-derived single-cell RNA-seq data. We use similar methods to reveal BAP1 dependent cell migration and invasion pathway genes in UM. Comparisons between BAP1 mutant and wild-type patient tumors, cell line panels, re-expression, and knockdown datasets reveal consistent changes in gene expression. Patient-derived single-cell RNA-seq data show a selective expression of these genes in malignant cells, and reverse-phase protein array (RPPA) data confirm these differences at the protein level. Genes and mechanisms central to the loss of SOX10 and BAP1 activity identified in this study will enable further investigation into disease progression and discovery of targets for therapeutic intervention in CM and UM. |
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Audience: Undergraduate StudentsGraduate StudentsFacultyStaff |
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