TMIC-63. SINGLE CELL SEQUENCING OF RECURRENT GLIOBLASTOMA DEFINES CELLULAR STATES ASSOCIATED WITH THERAPY RESISTANCE

TMIC-63. SINGLE CELL SEQUENCING OF RECURRENT GLIOBLASTOMA DEFINES CELLULAR STATES ASSOCIATED WITH THERAPY RESISTANCE

Abstract Glioblastoma (GBM), an aggressive, primary tumor is composed of multiple clonal populations. Resistance to therapy is a hallmark of GBM, making it a deadly disease. Upon therapeutic stress, tumor heterogeneity and glial stem cell plasticity within the primary tumor contributes to reprogramm...

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Veröffentlicht in:Neuro-oncology (Charlottesville, Va.) Va.), 2023-11, Vol.25 (Supplement_5), p.v292-v292
Hauptverfasser: Tripathi, Arushi, Shankar, Sunita, Ravikumar, Visweswaran, Loper, Jackson, Ji, Sunjong, Hassan, Zainab, Haydin, Yacoub, Huang, Dah-Luen, Bhadury, Sagnik, Regier, Jeffrey, Rao, Arvind, Al-holou, Wajd
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Tumor Microenvironment
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container_end_page v292
container_issue Supplement_5
container_start_page v292
container_title Neuro-oncology (Charlottesville, Va.)
container_volume 25
creator Tripathi, Arushi
Shankar, Sunita
Ravikumar, Visweswaran
Loper, Jackson
Ji, Sunjong
Hassan, Zainab
Haydin, Yacoub
Huang, Dah-Luen
Bhadury, Sagnik
Regier, Jeffrey
Rao, Arvind
Al-holou, Wajd
description Abstract Glioblastoma (GBM), an aggressive, primary tumor is composed of multiple clonal populations. Resistance to therapy is a hallmark of GBM, making it a deadly disease. Upon therapeutic stress, tumor heterogeneity and glial stem cell plasticity within the primary tumor contributes to reprogramming of the transcriptional activity. This alters the tumor landscape and generates therapy resistant clonal populations. Single cell RNA sequencing studies of primary GBM have defined various tumor cell states namely, the NPC-like (Neuronal precursor-like), OPC-like (oligodendrocyte precursor-like) and MES-like (mesenchymal-like) cellular states. These studies have also defined the immune components and the normal brain cells associated with primary GBM. Yet, there are no studies focused on the single cell analysis of recurrent GBM. To define the tumor landscape at recurrence, we performed single cell RNA sequencing of 180K cells from excised tumor tissue obtained from 11 patients after failure of therapeutic interventions. A corresponding cohort of 240K cells were sequenced from primary tumors obtained from 13 patients. We performed cellular state analyses of tumor cells in both the primary (~70K) and recurrent (~10K) samples. Primary GBM showed higher fractions of AC-like (0.55), compared to NPC-like (0.10), OPC-like (0.20) and MES-like (0.15). On the other hand, recurrent tissues have very low AC-like (0.09) but elevated NPC-like (0.23), OPC-like (0.40) and MES-like (0.27). This data shows a significant decrease in AC-like cells and corresponding increase in MES-like, OPC-like, NPC-like cells after recurrence. Within this dataset we also have matched longitudinal samples for analysis. We are currently performing trajectory analysis to identify genes and transcription programs activated during tumor recurrence. Experimentally, using known markers for the different cellular states we have also performed immunofluorescence analyses to validate the different cell states altered during recurrence. Our efforts to generate comprehensive recurrent GBM atlas will prove to be valuable to the GBM community.
doi_str_mv 10.1093/neuonc/noad179.1129
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SINGLE CELL SEQUENCING OF RECURRENT GLIOBLASTOMA DEFINES CELLULAR STATES ASSOCIATED WITH THERAPY RESISTANCE</title><source>Oxford University Press Journals All Titles (1996-Current)</source><source>EZB-FREE-00999 freely available EZB journals</source><source>PubMed Central</source><creator>Tripathi, Arushi ; Shankar, Sunita ; Ravikumar, Visweswaran ; Loper, Jackson ; Ji, Sunjong ; Hassan, Zainab ; Haydin, Yacoub ; Huang, Dah-Luen ; Bhadury, Sagnik ; Regier, Jeffrey ; Rao, Arvind ; Al-holou, Wajd</creator><creatorcontrib>Tripathi, Arushi ; Shankar, Sunita ; Ravikumar, Visweswaran ; Loper, Jackson ; Ji, Sunjong ; Hassan, Zainab ; Haydin, Yacoub ; Huang, Dah-Luen ; Bhadury, Sagnik ; Regier, Jeffrey ; Rao, Arvind ; Al-holou, Wajd</creatorcontrib><description>Abstract Glioblastoma (GBM), an aggressive, primary tumor is composed of multiple clonal populations. Resistance to therapy is a hallmark of GBM, making it a deadly disease. Upon therapeutic stress, tumor heterogeneity and glial stem cell plasticity within the primary tumor contributes to reprogramming of the transcriptional activity. This alters the tumor landscape and generates therapy resistant clonal populations. Single cell RNA sequencing studies of primary GBM have defined various tumor cell states namely, the NPC-like (Neuronal precursor-like), OPC-like (oligodendrocyte precursor-like) and MES-like (mesenchymal-like) cellular states. These studies have also defined the immune components and the normal brain cells associated with primary GBM. Yet, there are no studies focused on the single cell analysis of recurrent GBM. To define the tumor landscape at recurrence, we performed single cell RNA sequencing of 180K cells from excised tumor tissue obtained from 11 patients after failure of therapeutic interventions. A corresponding cohort of 240K cells were sequenced from primary tumors obtained from 13 patients. We performed cellular state analyses of tumor cells in both the primary (~70K) and recurrent (~10K) samples. Primary GBM showed higher fractions of AC-like (0.55), compared to NPC-like (0.10), OPC-like (0.20) and MES-like (0.15). On the other hand, recurrent tissues have very low AC-like (0.09) but elevated NPC-like (0.23), OPC-like (0.40) and MES-like (0.27). This data shows a significant decrease in AC-like cells and corresponding increase in MES-like, OPC-like, NPC-like cells after recurrence. Within this dataset we also have matched longitudinal samples for analysis. We are currently performing trajectory analysis to identify genes and transcription programs activated during tumor recurrence. Experimentally, using known markers for the different cellular states we have also performed immunofluorescence analyses to validate the different cell states altered during recurrence. Our efforts to generate comprehensive recurrent GBM atlas will prove to be valuable to the GBM community.</description><identifier>ISSN: 1522-8517</identifier><identifier>EISSN: 1523-5866</identifier><identifier>DOI: 10.1093/neuonc/noad179.1129</identifier><language>eng</language><publisher>US: Oxford University Press</publisher><subject>Tumor Microenvironment</subject><ispartof>Neuro-oncology (Charlottesville, Va.), 2023-11, Vol.25 (Supplement_5), p.v292-v292</ispartof><rights>The Author(s) 2023. Published by Oxford University Press on behalf of the Society for Neuro-Oncology. All rights reserved. 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SINGLE CELL SEQUENCING OF RECURRENT GLIOBLASTOMA DEFINES CELLULAR STATES ASSOCIATED WITH THERAPY RESISTANCE</title><title>Neuro-oncology (Charlottesville, Va.)</title><description>Abstract Glioblastoma (GBM), an aggressive, primary tumor is composed of multiple clonal populations. Resistance to therapy is a hallmark of GBM, making it a deadly disease. Upon therapeutic stress, tumor heterogeneity and glial stem cell plasticity within the primary tumor contributes to reprogramming of the transcriptional activity. This alters the tumor landscape and generates therapy resistant clonal populations. Single cell RNA sequencing studies of primary GBM have defined various tumor cell states namely, the NPC-like (Neuronal precursor-like), OPC-like (oligodendrocyte precursor-like) and MES-like (mesenchymal-like) cellular states. These studies have also defined the immune components and the normal brain cells associated with primary GBM. Yet, there are no studies focused on the single cell analysis of recurrent GBM. To define the tumor landscape at recurrence, we performed single cell RNA sequencing of 180K cells from excised tumor tissue obtained from 11 patients after failure of therapeutic interventions. A corresponding cohort of 240K cells were sequenced from primary tumors obtained from 13 patients. We performed cellular state analyses of tumor cells in both the primary (~70K) and recurrent (~10K) samples. Primary GBM showed higher fractions of AC-like (0.55), compared to NPC-like (0.10), OPC-like (0.20) and MES-like (0.15). On the other hand, recurrent tissues have very low AC-like (0.09) but elevated NPC-like (0.23), OPC-like (0.40) and MES-like (0.27). This data shows a significant decrease in AC-like cells and corresponding increase in MES-like, OPC-like, NPC-like cells after recurrence. Within this dataset we also have matched longitudinal samples for analysis. We are currently performing trajectory analysis to identify genes and transcription programs activated during tumor recurrence. Experimentally, using known markers for the different cellular states we have also performed immunofluorescence analyses to validate the different cell states altered during recurrence. 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SINGLE CELL SEQUENCING OF RECURRENT GLIOBLASTOMA DEFINES CELLULAR STATES ASSOCIATED WITH THERAPY RESISTANCE</atitle><jtitle>Neuro-oncology (Charlottesville, Va.)</jtitle><date>2023-11-10</date><risdate>2023</risdate><volume>25</volume><issue>Supplement_5</issue><spage>v292</spage><epage>v292</epage><pages>v292-v292</pages><issn>1522-8517</issn><eissn>1523-5866</eissn><abstract>Abstract Glioblastoma (GBM), an aggressive, primary tumor is composed of multiple clonal populations. Resistance to therapy is a hallmark of GBM, making it a deadly disease. Upon therapeutic stress, tumor heterogeneity and glial stem cell plasticity within the primary tumor contributes to reprogramming of the transcriptional activity. This alters the tumor landscape and generates therapy resistant clonal populations. 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subjects Tumor Microenvironment
title TMIC-63. SINGLE CELL SEQUENCING OF RECURRENT GLIOBLASTOMA DEFINES CELLULAR STATES ASSOCIATED WITH THERAPY RESISTANCE
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