Targeting DNM1L/DRP1-FIS1 axis inhibits high-grade glioma progression by impeding mitochondrial respiratory cristae remodeling.

IF 11.4 1区医学 Q1 ONCOLOGY

Journal of Experimental & Clinical Cancer Research Pub Date : 2024-09-30 DOI:10.1186/s13046-024-03194-6

Xiaodong Li, Jingjing Tie, Yuze Sun, Chengrong Gong, Shizhou Deng, Xiyu Chen, Shujiao Li, Yaoliang Wang, Zhenhua Wang, Feifei Wu, Hui Liu, Yousheng Wu, Guopeng Zhang, Qingdong Guo, Yanling Yang, Yayun Wang

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Abstract

Background: The dynamics of mitochondrial respiratory cristae (MRC) and its impact on oxidative phosphorylation (OXPHOS) play a crucial role in driving the progression of high-grade glioma (HGG). However, the underlying mechanism remains unclear.

Methods: In the present study, we employed machine learning-based transmission electron microscopy analysis of 7141 mitochondria from 54 resected glioma patients. Additionally, we conducted bioinformatics analysis and multiplex immunohistochemical (mIHC) staining of clinical glioma microarrays to identify key molecules involved in glioma. Subsequently, we modulated the expression levels of mitochondrial dynamic-1-like protein (DNM1L/DRP1), and its two receptors, mitochondrial fission protein 1 (FIS1) and mitochondrial fission factor (MFF), via lentiviral transfection to further investigate the central role of these molecules in the dynamics of glioblastoma (GBM) cells and glioma stem cells (GSCs). We then evaluated the potential impact of DNM1L/DRP1, FIS1, and MFF on the proliferation and progression of GBM cells and GSCs using a combination of CCK-8 assay, Transwell assay, Wound Healing assay, tumor spheroid formation assay and cell derived xenograft assay employing NOD/ShiLtJGpt-Prkdc^em26Cd52Il2rg^em26Cd22/Gpt (NCG) mouse model. Subsequently, we validated the ability of the DNM1L/DRP1-FIS1 axis to remodel MRC structure through mitophagy by utilizing Seahorse XF analysis technology, mitochondrial function detection, MRC abundance detection and monitoring dynamic changes in mitophagy.

Results: Our findings revealed that compared to low-grade glioma (LGG), HGG exhibited more integrated MRC structures. Further research revealed that DNM1L/DRP1, FIS1, and MFF played pivotal roles in governing mitochondrial fission and remodeling MRC in HGG. The subsequent validation demonstrated that DNM1L/DRP1 exerts a positive regulatory effect on FIS1, whereas the interaction between MFF and FIS1 demonstrates a competitive inhibition relationship. The down-regulation of the DNM1L/DRP1-FIS1 axis significantly impaired mitophagy, thereby hindering the remodeling of MRC and inhibiting OXPHOS function in glioma, ultimately leading to the inhibition of its aggressive progression. In contrast, MFF exerts a contrasting effect on MRC integrity, OXPHOS activity, and glioma progression.

Conclusions: This study highlights that the DNM1L/DRP1-FIS1 axis stabilizes MRC structures through mitophagy in HGG cells while driving their OXPHOS activity ultimately leading to robust disease progression. The inhibition of the DNM1L/DRP1-FIS1 axis hinders MRC remodeling and suppresses GBM progression. We propose that down-regulation of the DNM1L/DRP1-FIS1 axis could be a potential therapeutic strategy for treating HGG.

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靶向 DNM1L/DRP1-FIS1 轴可通过阻碍线粒体呼吸嵴重塑抑制高级别胶质瘤的进展。

背景：线粒体呼吸嵴（MRC）的动态及其对氧化磷酸化（OXPHOS）的影响在推动高级别胶质瘤（HGG）的进展中起着至关重要的作用。然而，其潜在机制仍不清楚：在本研究中，我们采用基于机器学习的透射电子显微镜分析了 54 例切除胶质瘤患者的 7141 个线粒体。此外，我们还对临床胶质瘤芯片进行了生物信息学分析和多重免疫组化（mIHC）染色，以确定参与胶质瘤的关键分子。随后，我们通过慢病毒转染调节了线粒体动态-1样蛋白（DNM1L/DRP1）及其两种受体线粒体裂变蛋白1（FIS1）和线粒体裂变因子（MFF）的表达水平，进一步研究了这些分子在胶质母细胞瘤（GBM）细胞和胶质瘤干细胞（GSCs）动态变化中的核心作用。然后，我们采用 CCK-8 试验、Transwell 试验、伤口愈合试验、肿瘤球形成试验和细胞衍生异种移植试验（NOD/ShiLtJGpt-Prkdcem26Cd52Il2rgem26Cd22/Gpt (NCG)小鼠模型），评估了 DNM1L/DRP1、FIS1 和 MFF 对 GBM 细胞和 GSC 增殖和进展的潜在影响。随后，我们利用海马 XF 分析技术、线粒体功能检测、MRC 丰度检测和有丝分裂动态变化监测，验证了 DNM1L/DRP1-FIS1 轴通过有丝分裂重塑 MRC 结构的能力：我们的研究结果表明，与低级别胶质瘤（LGG）相比，HGG表现出更完整的MRC结构。进一步的研究发现，DNM1L/DRP1、FIS1和MFF在HGG的线粒体分裂和MRC重塑中起着关键作用。随后的验证表明，DNM1L/DRP1 对 FIS1 具有正向调控作用，而 MFF 与 FIS1 之间的相互作用则表现出竞争性抑制关系。DNM1L/DRP1-FIS1轴的下调会显著损害有丝分裂，从而阻碍MRC的重塑，抑制胶质瘤的OXPHOS功能，最终导致抑制其侵袭性进展。与此相反，MFF对MRC的完整性、OXPHOS活性和胶质瘤的进展产生了相反的影响：本研究强调，DNM1L/DRP1-FIS1 轴通过 HGG 细胞中的有丝分裂来稳定 MRC 结构，同时驱动其 OXPHOS 活性，最终导致疾病的强劲进展。抑制 DNM1L/DRP1-FIS1 轴会阻碍 MRC 重塑并抑制 GBM 的进展。我们认为，下调 DNM1L/DRP1-FIS1 轴可能是治疗 HGG 的一种潜在治疗策略。

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来源期刊

Journal of Experimental & Clinical Cancer Research 医学-肿瘤学

CiteScore

18.20

自引率

1.80%

发文量

333

审稿时长

1 months

期刊介绍： The Journal of Experimental & Clinical Cancer Research is an esteemed peer-reviewed publication that focuses on cancer research, encompassing everything from fundamental discoveries to practical applications. We welcome submissions that showcase groundbreaking advancements in the field of cancer research, especially those that bridge the gap between laboratory findings and clinical implementation. Our goal is to foster a deeper understanding of cancer, improve prevention and detection strategies, facilitate accurate diagnosis, and enhance treatment options. We are particularly interested in manuscripts that shed light on the mechanisms behind the development and progression of cancer, including metastasis. Additionally, we encourage submissions that explore molecular alterations or biomarkers that can help predict the efficacy of different treatments or identify drug resistance. Translational research related to targeted therapies, personalized medicine, tumor immunotherapy, and innovative approaches applicable to clinical investigations are also of great interest to us. We provide a platform for the dissemination of large-scale molecular characterizations of human tumors and encourage researchers to share their insights, discoveries, and methodologies with the wider scientific community. By publishing high-quality research articles, reviews, and commentaries, the Journal of Experimental & Clinical Cancer Research strives to contribute to the continuous improvement of cancer care and make a meaningful impact on patients' lives.