Sorting nexin 10 sustains PDGF receptor signaling in glioblastoma stem cells via endosomal protein sorting
Ryan C. Gimple, … , Sameer Agnihotri, Jeremy N. Rich
Ryan C. Gimple, … , Sameer Agnihotri, Jeremy N. Rich
Published February 16, 2023
Citation Information: JCI Insight. 2023;8(6):e158077. https://doi.org/10.1172/jci.insight.158077.
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Research Article Oncology Stem cells

Sorting nexin 10 sustains PDGF receptor signaling in glioblastoma stem cells via endosomal protein sorting

Abstract

Glioblastoma is the most malignant primary brain tumor, the prognosis of which remains dismal even with aggressive surgical, medical, and radiation therapies. Glioblastoma stem cells (GSCs) promote therapeutic resistance and cellular heterogeneity due to their self-renewal properties and capacity for plasticity. To understand the molecular processes essential for maintaining GSCs, we performed an integrative analysis comparing active enhancer landscapes, transcriptional profiles, and functional genomics profiles of GSCs and non-neoplastic neural stem cells (NSCs). We identified sorting nexin 10 (SNX10), an endosomal protein sorting factor, as selectively expressed in GSCs compared with NSCs and essential for GSC survival. Targeting SNX10 impaired GSC viability and proliferation, induced apoptosis, and reduced self-renewal capacity. Mechanistically, GSCs utilized endosomal protein sorting to promote platelet-derived growth factor receptor β (PDGFRβ) proliferative and stem cell signaling pathways through posttranscriptional regulation of the PDGFR tyrosine kinase. Targeting SNX10 expression extended survival of orthotopic xenograft–bearing mice, and high SNX10 expression correlated with poor glioblastoma patient prognosis, suggesting its potential clinical importance. Thus, our study reveals an essential connection between endosomal protein sorting and oncogenic receptor tyrosine kinase signaling and suggests that targeting endosomal sorting may represent a promising therapeutic approach for glioblastoma treatment.

Authors

Ryan C. Gimple, Guoxin Zhang, Shuai Wang, Tengfei Huang, Jina Lee, Suchet Taori, Deguan Lv, Deobrat Dixit, Matthew E. Halbert, Andrew R. Morton, Reilly L. Kidwell, Zhen Dong, Briana C. Prager, Leo J.Y. Kim, Zhixin Qiu, Linjie Zhao, Qi Xie, Qiulian Wu, Sameer Agnihotri, Jeremy N. Rich

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Figure 10

SNX10 interacts with PDGFRβ in the endosomal compartment via its phox homology domain.

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SNX10 interacts with PDGFRβ in the endosomal compartment via its phox ho...
(A) Western blot of SNX10 and PDGFRβ in GSC 387 and GSC 3565 following cell fractionation. Pan-cadherin and EGFR were used as membrane markers, GAPDH was used as a cytoplasmic marker, and OLIG2 and histone H3 were used as nuclear markers. EEA1 was used as an early endosome marker. Samples were run contemporaneously in separate gels with whole gels shown in the supplemental material. (B) Immunofluorescent staining of EEA1 and SNX10 in MES28 and 3565. Scale bars: 10 μm and 5 μm (zoomed-in images). (C) Western blot showing immunoprecipitation with pulldown of PDGFRβ in GSC 3565 and GSC 23 compared to a nonspecific IgG control. Immunoblotting was performed with anti-PDGFRβ and -SNX10 antibodies. Samples were run in a single gel with entire gels shown in the supplemental material. (D) Western blot showing protein levels of FLAG, PDGFRβ, and tubulin after transduction with PCDH-SNX10 or PCDH-SNX10MUT (PX-domain deficient). Samples were run in a single gel with entire gels shown in the supplemental material.