The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin

The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin

Abstract Background Glioblastoma multiforme (GBM), a lethal brain tumor, remains the most daunting challenge in cancer therapy. Overexpression and constitutive activation of PDGFs and PDGFRα are observed in most GBM; however, available inhibitors targeting isolated signaling pathways are minimally e...

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Main Authors: Gong Peng, Yin Wang, Pengfei Ge, Christopher Bailey, Peng Zhang, Di Zhang, Zhaoli Meng, Chong Qi, Qian Chen, Jingtao Chen, Junqi Niu, Pan Zheng, Yang Liu, Yan Liu
Format: Article
Language:English
Published: BMC 2021-09-01
Series:Journal of Experimental & Clinical Cancer Research
Subjects:
HIF1α
PDGFRα
PDGF-D
Glioblastoma
Echinomycin
Online Access:https://doi.org/10.1186/s13046-021-02082-7
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language English
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author Gong Peng
Yin Wang
Pengfei Ge
Christopher Bailey
Peng Zhang
Di Zhang
Zhaoli Meng
Chong Qi
Qian Chen
Jingtao Chen
Junqi Niu
Pan Zheng
Yang Liu
Yan Liu
spellingShingle Gong Peng
Yin Wang
Pengfei Ge
Christopher Bailey
Peng Zhang
Di Zhang
Zhaoli Meng
Chong Qi
Qian Chen
Jingtao Chen
Junqi Niu
Pan Zheng
Yang Liu
Yan Liu
The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin
Journal of Experimental & Clinical Cancer Research
HIF1α
PDGFRα
PDGF-D
Glioblastoma
Echinomycin
author_facet Gong Peng
Yin Wang
Pengfei Ge
Christopher Bailey
Peng Zhang
Di Zhang
Zhaoli Meng
Chong Qi
Qian Chen
Jingtao Chen
Junqi Niu
Pan Zheng
Yang Liu
Yan Liu
author_sort Gong Peng
title The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin
title_short The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin
title_full The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin
title_fullStr The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin
title_full_unstemmed The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin
title_sort hif1α-pdgfd-pdgfrα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycin
publisher BMC
series Journal of Experimental & Clinical Cancer Research
issn 1756-9966
publishDate 2021-09-01
description Abstract Background Glioblastoma multiforme (GBM), a lethal brain tumor, remains the most daunting challenge in cancer therapy. Overexpression and constitutive activation of PDGFs and PDGFRα are observed in most GBM; however, available inhibitors targeting isolated signaling pathways are minimally effective. Therefore, better understanding of crucial mechanisms underlying GBM is needed for developing more effective targeted therapies. Methods Target genes controlled by HIF1α in GBM were identified by analysis of TCGA database and by RNA-sequencing of GBM cells with HIF1α knockout by sgRNA-Cas9 method. Functional roles of HIF1α, PDGFs and PDGFRs were elucidated by loss- or gain-of-function assays or chemical inhibitors, and compared in response to oxygen tension. Pharmacological efficacy and gene expression in mice with intracranial xenografts of primary GBM were analyzed by bioluminescence imaging and immunofluorescence. Results HIF1α binds the PDGFD proximal promoter and PDGFRA intron enhancers in GBM cells under normoxia or mild-hypoxia to induce their expression and maintain constitutive activation of AKT signaling, which in turn increases HIF1α protein level and activity. Paradoxically, severe hypoxia abrogates PDGFRα expression despite enhancing HIF1α accumulation and corresponding PDGF-D expression. Knockout of HIF1A, PDGFD or PDGFRA in U251 cells inhibits cell growth and invasion in vitro and eradicates tumor growth in vivo. HIF1A knockdown in primary GBM extends survival of xenograft mice, whereas PDGFD overexpression in GL261 shortens survival. HIF1α inhibitor Echinomycin induces GBM cell apoptosis and effectively inhibits growth of GBM in vivo by simultaneously targeting HIF1α-PDGFD/PDGFRα-AKT feedforward pathway. Conclusions HIF1α orchestrates expression of PDGF-D and PDGFRα for constitutive activation of AKT pathway and is crucial for GBM malignancy. Therefore, therapies targeting HIF1α should provide an effective treatment for GBM.
topic HIF1α
PDGFRα
PDGF-D
Glioblastoma
Echinomycin
url https://doi.org/10.1186/s13046-021-02082-7
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spelling doaj-5f16d70476f349bdb968538fc330e3712021-09-05T11:24:17ZengBMCJournal of Experimental & Clinical Cancer Research1756-99662021-09-0140111610.1186/s13046-021-02082-7The HIF1α-PDGFD-PDGFRα axis controls glioblastoma growth at normoxia/mild-hypoxia and confers sensitivity to targeted therapy by echinomycinGong Peng0Yin Wang1Pengfei Ge2Christopher Bailey3Peng Zhang4Di Zhang5Zhaoli Meng6Chong Qi7Qian Chen8Jingtao Chen9Junqi Niu10Pan Zheng11Yang Liu12Yan Liu13Institute of Translational Medicine, the First Hospital of Jilin UniversityDivision of Immunotherapy, Department of Surgery and Comprehensive Cancer Center, Institute of Human Virology, University of Maryland School of MedicineDepartment of Neurosurgery, Neuroscience Research Center, The First Hospital of Jilin UniversityDivision of Immunotherapy, Department of Surgery and Comprehensive Cancer Center, Institute of Human Virology, University of Maryland School of MedicineBeijing Key Laboratory for Genetics of Birth Defects, Beijing Pediatric Research Institute, Beijing Children’s Hospital, Capital Medical University, National Cancer for Children’s HealthDepartment of Neurosurgery, Beijing Children’s Hospital, Capital Medical University, National Cancer for Children’s HealthInstitute of Translational Medicine, the First Hospital of Jilin UniversityInstitute of Translational Medicine, the First Hospital of Jilin UniversityInstitute of Translational Medicine, the First Hospital of Jilin UniversityInstitute of Translational Medicine, the First Hospital of Jilin UniversityInstitute of Translational Medicine, the First Hospital of Jilin UniversityDivision of Immunotherapy, Department of Surgery and Comprehensive Cancer Center, Institute of Human Virology, University of Maryland School of MedicineDivision of Immunotherapy, Department of Surgery and Comprehensive Cancer Center, Institute of Human Virology, University of Maryland School of MedicineDivision of Immunotherapy, Department of Surgery and Comprehensive Cancer Center, Institute of Human Virology, University of Maryland School of MedicineAbstract Background Glioblastoma multiforme (GBM), a lethal brain tumor, remains the most daunting challenge in cancer therapy. Overexpression and constitutive activation of PDGFs and PDGFRα are observed in most GBM; however, available inhibitors targeting isolated signaling pathways are minimally effective. Therefore, better understanding of crucial mechanisms underlying GBM is needed for developing more effective targeted therapies. Methods Target genes controlled by HIF1α in GBM were identified by analysis of TCGA database and by RNA-sequencing of GBM cells with HIF1α knockout by sgRNA-Cas9 method. Functional roles of HIF1α, PDGFs and PDGFRs were elucidated by loss- or gain-of-function assays or chemical inhibitors, and compared in response to oxygen tension. Pharmacological efficacy and gene expression in mice with intracranial xenografts of primary GBM were analyzed by bioluminescence imaging and immunofluorescence. Results HIF1α binds the PDGFD proximal promoter and PDGFRA intron enhancers in GBM cells under normoxia or mild-hypoxia to induce their expression and maintain constitutive activation of AKT signaling, which in turn increases HIF1α protein level and activity. Paradoxically, severe hypoxia abrogates PDGFRα expression despite enhancing HIF1α accumulation and corresponding PDGF-D expression. Knockout of HIF1A, PDGFD or PDGFRA in U251 cells inhibits cell growth and invasion in vitro and eradicates tumor growth in vivo. HIF1A knockdown in primary GBM extends survival of xenograft mice, whereas PDGFD overexpression in GL261 shortens survival. HIF1α inhibitor Echinomycin induces GBM cell apoptosis and effectively inhibits growth of GBM in vivo by simultaneously targeting HIF1α-PDGFD/PDGFRα-AKT feedforward pathway. Conclusions HIF1α orchestrates expression of PDGF-D and PDGFRα for constitutive activation of AKT pathway and is crucial for GBM malignancy. Therefore, therapies targeting HIF1α should provide an effective treatment for GBM.https://doi.org/10.1186/s13046-021-02082-7HIF1αPDGFRαPDGF-DGlioblastomaEchinomycin

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