Your search keyword '"Kelly Mitchell"' showing total 3 results

1. CNSC-36. VRK1 IS A PARALOG SYNTHETIC LETHAL TARGET IN VRK2-METHYLATED GLIOBLASTOMA

Author

Julie Shields, Samuel Meier, Madhavi Bandi, Maria Dam Ferdinez, Justin Engel, Erin Mulkearns-Hubert, Nicole Hajdari, Binzhang Shen, Christopher Hubert, Kelly Mitchell, Wenhai Zhang, Shan-chuan Zhao, Alborz Bejnood, Minjie Zhang, Robert Tjin Tham Sjin, Erik Wilker, Justin Lathia, Jannik Andersen, Yingnan Chen, Fang Li, Barbara Weber, Alan Huang, and Natasha Emmanuel

Subjects

Cancer Research, Oncology, Neurology (clinical)

Abstract

Synthetic lethality — a genetic interaction that results in cell death when two genetic deficiencies co-occur but not when either deficiency occurs alone — can be co-opted for cancer therapeutics. A pair of paralog genes is among the most straightforward synthetic lethal interaction by virtue of their redundant functions. Here we demonstrate a paralog-based synthetic lethality by targeting Vaccinia-Related Kinase 1 (VRK1) in Vaccinia-Related Kinase 2 (VRK2)-methylated glioblastoma (GBM). VRK2 is silenced by promoter methylation in approximately two-thirds of GBM, an aggressive cancer with few available targeted therapies. Genetic knockdown of VRK1 in VRK2-methylated GBM cell lines and patient-derived models was lethal and resulted in decreased activity of the downstream substrate Barrier to Autointegration Factor (BAF), a regulator of post-mitotic nuclear envelope formation. VRK1 knockdown, and thus reduced BAF activity, caused nuclear lobulation, blebbing and micronucleation, which subsequently resulted in G2/M arrest and DNA damage. The VRK1-VRK2 synthetic lethal interaction was dependent on VRK1 kinase activity and was rescued by ectopic VRK2 expression. Knockdown of VRK1 led to robust tumor growth inhibition in VRK2-methylated GBM xenografts. These results indicate that inhibiting VRK1 kinase activity could be a viable therapeutic strategy in VRK2-methylated GBM.

Published

2022

2. STEM-14. THE WRAD COMPLEX REPRESENTS A THERAPEUTIC TARGET FOR CANCER STEM CELLS IN GLIOBLASTOMA

Author

Sadie Johnson, Rachel Schafer, Shaun Stauffer, Jonathan Macdonald, Gustavo Roversi, Justin D. Lathia, Joseph Alvarado, Erin E. Mulkearns-Hubert, Anjali Kashyap, Jeremy N. Rich, Adam Lauko, Christopher Goins, Kristen Kay, Daniel J. Silver, Kelly Mitchell, Steven Martinez, and Christopher G. Hubert

Subjects

Cancer Research, Standard of care, Growth retardation, business.industry, Cell cycle quiescence, Tumor initiation, 26th Annual Meeting & Education Day of the Society for Neuro-Oncology, medicine.disease, Oncology, Cancer stem cell, Cancer research, Medicine, Neurology (clinical), Epigenetics, Stem cell, business, Glioblastoma

Abstract

Glioblastoma (GBM) progression and resistance to conventional therapies is driven in part by cells within the tumor with stem cell properties including quiescence, self-renewal and drug efflux potential. It is thought that eliminating these cancer stem cells (CSCs) is a key component to successful clinical management of GBM. However, currently, few known molecular mechanisms driving CSCs can be exploited for therapeutic development. Core transcription factors such as SOX2, OLIG2, OCT4 and NANOG maintain the CSC state in GBM. Our laboratory recently uncovered a self-renewal signaling axis involving RBBP5 that is necessary and sufficient for CSC maintenance through driving expression of these core stem cell maintenance transcription factors. RBBP5 is a component of the WRAD complex, which promotes Lys4 methylation of histone H3 to positively regulate transcription. We hypothesized that targeting RBBP5 could be a means to disrupt epigenetic programs that maintain CSCs in stemness transcriptional states. We found that genetic and pharmacologic inhibition of the WRAD complex reduced CSC growth, self-renewal and tumor initiation potential. WRAD inhibitors partially dissembled the WRAD complex and reduced H3K4 trimethylation both globally and at the promoters of key stem cell maintenance transcription factors. Using a CSC reporter system, we demonstrated that WRAD complex inhibition decreased growth of SOX2/OCT4 expressing CSCs in a concentration-dependent manner as quantified by live imaging. Overall, our studies assess the function of the WRAD complex and the effect of WRAD complex inhibitors in preclinical models and specifically on the stem cell state for the first time in GBM. Studying the functions of the WRAD complex in CSCs may improve understanding of GBM pathogenesis and elucidate how CSCs survive despite aggressive chemotherapy and radiation. Our ongoing studies aim to develop brain penetrant inhibitors targeting the WRAD complex as an anti-CSC strategy that could potentially synergize with standard of care treatments.

Published

2021

3. The evolution of the cancer stem cell state in glioblastoma: emerging insights into the next generation of functional interactions

Author

Katie M. Troike, Kelly Mitchell, Daniel J. Silver, and Justin D. Lathia

Subjects

Cancer Research, education.field_of_study, Brain Neoplasms, Malignant brain tumor, Population, Reviews, Disease, Biology, medicine.disease, Oncology, Cellular heterogeneity, Cancer stem cell, Resistant cancer, medicine, Neoplastic Stem Cells, Humans, Neurology (clinical), Stem cell, education, Glioblastoma, Neuroscience

Abstract

Cellular heterogeneity is a hallmark of advanced cancers and has been ascribed in part to a population of self-renewing, therapeutically resistant cancer stem cells (CSCs). Glioblastoma (GBM), the most common primary malignant brain tumor, has served as a platform for the study of CSCs. In addition to illustrating the complexities of CSC biology, these investigations have led to a deeper understanding of GBM pathogenesis, revealed novel therapeutic targets, and driven innovation towards the development of next-generation therapies. While there continues to be an expansion in our knowledge of how CSCs contribute to GBM progression, opportunities have emerged to revisit this conceptual framework. In this review, we will summarize the current state of CSCs in GBM using key concepts of evolution as a paradigm (variation, inheritance, selection, and time) to describe how the CSC state is subject to alterations of cell intrinsic and extrinsic interactions that shape their evolutionarily trajectory. We identify emerging areas for future consideration, including appreciating CSCs as a cell state that is subject to plasticity, as opposed to a discrete population. These future considerations will not only have an impact on our understanding of this ever-expanding field but will also provide an opportunity to inform future therapies to effectively treat this complex and devastating disease.

Published

2020