Radiotherapy‐Induced Astrocyte Senescence Promotes an Immunosuppressive Microenvironment in Glioblastoma to Facilitate Tumor Regrowth

Ji, Jianxiong; Ding, Kaikai; Cheng, Bo; Zhang, Xin; Luo, Tao; Huang, Bin; Yu, Hao; Chen, Yike; Xu, Xiaohui; Lin, Haopu; Zhou, Jiayin; Wang, Tingtin; Jin, Mengmeng; Liu, Aixia; Yan, Danfang; Liu, Fuyi; Wang, Chun; Chen, Jingsen; Yan, Feng; Wang, Lin; Zhang, Jianmin; Yan, Senxiang; Wang, Jian; Li, Xingang; Chen, Gao

doi:10.1002/advs.202304609

Cited by 4 publications

(1 citation statement)

References 50 publications

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“…Finally, it has been found recently that irradiation-induced senescent astrocytes play a substantial tumor-promoting role after radiotherapy. In preclinical models of the aforementioned scenario, senolytic agents substantially prolonged the time of survival [57].…”

Section: Astrocytesmentioning

confidence: 99%

Non-Tumor Cells within the Tumor Microenvironment—The “Eminence Grise” of the Glioblastoma Pathogenesis and Potential Targets for Therapy

Bugakova,

Chudakova,

Myzina

et al. 2024

Cells

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Glioblastoma (GBM) is the most common malignancy of the central nervous system in adults. GBM has high levels of therapy failure and its prognosis is usually dismal. The phenotypic heterogeneity of the tumor cells, dynamic complexity of non-tumor cell populations within the GBM tumor microenvironment (TME), and their bi-directional cross-talk contribute to the challenges of current therapeutic approaches. Herein, we discuss the etiology of GBM, and describe several major types of non-tumor cells within its TME, their impact on GBM pathogenesis, and molecular mechanisms of such an impact. We also discuss their value as potential therapeutic targets or prognostic biomarkers, with reference to the most recent works on this subject. We conclude that unless all “key player” populations of non-tumor cells within the TME are considered, no breakthrough in developing treatment for GBM can be achieved.

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Section: Astrocytesmentioning

confidence: 99%

Non-Tumor Cells within the Tumor Microenvironment—The “Eminence Grise” of the Glioblastoma Pathogenesis and Potential Targets for Therapy

Bugakova,

Chudakova,

Myzina

et al. 2024

Cells

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Sequential Release HydroLipo System for STING Gene Epigenetic Reprogramming and Immune Activation in Glioblastoma

Yu,

Liu,

Ding

et al. 2024

Advanced Science

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Glioblastoma (GBM) remains a daunting oncological challenge because of its aggressive nature and resistance to conventional therapies. Inhibition of the intrinsic STING pathway in GBM hampers the effectiveness of immunotherapies. To overcome this clinical limitation, a Sequential Release HydroLipo System (SRHLS) is developed, in which hydrogels and nanoparticles are combined for controlled drug release. The SRHLS sequentially released decitabine and STING agonists, thereby correcting STING signaling dysfunction through epigenetic reprogramming and enhancing antitumor immunity. According to in vitro and in vivo experiments, the SRHLS reshaped the tumor microenvironment and markedly inhibited tumor growth, recurrence, and metastasis. These findings underscore the potential of the SRHLS as a promising therapeutic strategy for GBM.

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Defective autophagy of pericytes enhances radiation-induced senescence promoting radiation brain injury

Luo,

Zhu,

et al. 2024

Neuro-Oncology

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Background Radiation-induced brain injury (RBI) represents a major challenge for cancer patients undergoing cranial radiotherapy. However, the molecular mechanisms and therapeutic strategies of RBI remain inconclusive. With the continuous exploration of the mechanisms of RBI, an increasing number of studies have implicated cerebrovascular dysfunction as a key factor in RBI-related cognitive impairment. As pericytes are a component of the neurovascular unit, there is still a lack of understanding in current research about the specific role and function of pericytes in RBI. Methods We constructed a mouse model of RBI-associated cognitive dysfunction in vivo and an in vitro radiation-induced pericyte model to explore the effects of senescent pericytes on the blood-brain barrier and normal CNS cells, even glioma cells. To further clarify the effects of pericyte autophagy on senescence, molecular mechanisms were explored at the animal and cellular levels. Finally, we validated the clearance of pericyte senescence by using senolytic drug and all-trans retinoic acid to investigate the role of radiation-induced pericyte senescence. Results Our findings indicated that radiation-induced pericyte senescence plays a key role in blood-brain barrier dysfunction, leading to RBI and subsequent cognitive decline. Strikingly, pericyte senescence also contributes to the growth and invasion of glioma cells. We further demonstrate that defective autophagy in pericytes is a vital regulatory mechanism for pericyte senescence. Moreover, autophagy activated by rapamycin can reverse pericyte senescence. Notably, the elimination of senescent cells by senolytic drugs significantly mitigated radiation-induced cognitive dysfunction. Disscussion Our results demonstrated that pericyte senescence may be a promising therapeutic target for RBI and glioma progression

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Radiotherapy‐Induced Astrocyte Senescence Promotes an Immunosuppressive Microenvironment in Glioblastoma to Facilitate Tumor Regrowth

Cited by 4 publications

References 50 publications

Non-Tumor Cells within the Tumor Microenvironment—The “Eminence Grise” of the Glioblastoma Pathogenesis and Potential Targets for Therapy

Non-Tumor Cells within the Tumor Microenvironment—The “Eminence Grise” of the Glioblastoma Pathogenesis and Potential Targets for Therapy

Sequential Release HydroLipo System for STING Gene Epigenetic Reprogramming and Immune Activation in Glioblastoma

Defective autophagy of pericytes enhances radiation-induced senescence promoting radiation brain injury

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