Lu Anwei, Lin Shuying, Li Jiajing, Luo Haijuan, Lu Chengyu, Wang Yuzhen, Cao Yuye, Cao Xiaojuan, Peng Jiaxin, Zhang Jiaming, Zhou Li, Yin Minuo
Department of Obstetrics and Gynecology, Shenzhen Hospital, Southern Medical University, Shenzhen, Guangdong, PR China.
The First School of Clinical Medicine, Southern Medical University, Guangzhou, Guangdong, PR China.
Hum Reprod. 2025 Jul 29. doi: 10.1093/humrep/deaf130.
Can harmine mitigate endometriosis by modulating oxidative phosphorylation (OXPHOS) suppression and macrophage polarization?
Harmine induces apoptosis in endometriotic lesions by inhibiting OXPHOS while also modulating macrophage polarization through the reduction of extracellular adenosine (eADO), a metabolic byproduct of OXPHOS.
Endometriosis is associated with mitochondrial dysfunction while ectopic endometrial stromal cells (EESCs) exhibit heightened susceptibility to oxidative stress. Macrophages accumulate in the peritoneal cavity and peritoneal fluid, constituting a dominant immune cell population within endometriotic lesions.
STUDY DESIGN, SIZE, DURATION: A total of 25 patients diagnosed with ovarian endometriosis and 25 healthy donors undergoing surgical treatment at a university-affiliated hospital within 6 months were included. Primary normal endometrial stromal cells (NESCs) and EESCs were isolated, cultured, and subjected to pharmacological drug intervention, small interfering RNA (siRNA) transfection, OXPHOS analysis, and transcriptomic profiling. Macrophage cell line RAW264.7 was used to study macrophage polarization. The in vivo study involved 24 C57BL/6 female mice to establish an endometriosis model.
PARTICIPANTS/MATERIALS, SETTING, METHODS: The impact of harmine on cellular viability in vitro was assessed using Cell Counting Kit-8 (CCK-8) clonogenic assays, 5-ethynyl-2'-deoxyuridine (EdU) incorporation, and flow cytometry. OXPHOS inhibition was evaluated through mitochondrial ultrastructural changes observed via transmission electron microscopy and fluorescence staining. Oxidative stress was quantified using JC-1 mitochondrial membrane potential assays and reactive oxygen species (ROS) detection kits. Seahorse oxygen consumption rate assay was conducted to measure OXPHOS activity. Immunohistochemistry was employed to examine key protein expression in endometrial tissues. ATP and eADO levels were quantified using an ATP Assay Kit and Adenosine Assay Kit, respectively. We used RNA sequencing (RNA-seq) to identify enriched biological pathways. Flow cytometry was used to characterize macrophage populations in peritoneal fluid, and CIBERSORTx software was applied to generate immune cell expression profiles. Samples with P-values <0.05 were selected for analysis, with macrophage subtype (Mφ2/Mφ1) alterations statistically evaluated using the Wilcoxon test.
EESCs exhibited greater susceptibility to harmine treatment compared to NESCs (P < 0.05). RNA-seq analysis revealed that harmine primarily influences pathways related to cell proliferation, oxidative stress, and HIF-1 signaling. Differentially expressed genes were enriched in complexes regulating mitochondrial OXPHOS. Harmine intervention significantly increased mitochondrial fission in EESCs compared to NESCs and markedly suppressed OXPHOS activity in EESCs. Treatment with harmine decreased total ROS levels in cultured EESCs (P < 0.05 vs NESCs). The eADO/CD73-mediated adenosine pathway was upregulated in endometriotic lesions, accompanied by a predominance of Mφ2 macrophages in the microenvironment (Wilcoxon test, P < 0.05). In the murine model, harmine treatment decreased eADO production and shifted macrophage polarization toward a pro-inflammatory Mφ1 phenotype, contributing to endometriotic lesion regression.
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LIMITATIONS, REASONS FOR CAUTION: The study's reliance on primary cells was constrained by their limited passage potential and inherent heterogeneity, precluding co-culture investigations. Further mechanistic elucidation requires cell line-based studies. More subtypes should be included in the research, not just models of ovarian endometriosis. Eutopic endometrial cells should be included in the experiment if conditions permit. Additionally, primate models with menstrual cycles, such as rhesus monkeys, should be considered for future in vivo validation.
These findings indicate that harmine may serve as a promising alkaloid-based therapeutic for endometriosis by modulating energy metabolism and immune responses.
STUDY FUNDING/COMPETING INTEREST(S): This research was supported by the National Natural Science Foundation of China (NSFC No. 82201814), the Guangdong Basic and Applied Basic Research Foundation (2021A1515110444), and the Foundation of Shenzhen Hospital of Southern Medical University (PY2022YM03). The authors declare no conflicts of interest.
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哈尔明碱能否通过调节氧化磷酸化(OXPHOS)抑制和巨噬细胞极化来减轻子宫内膜异位症?
哈尔明碱通过抑制氧化磷酸化诱导子宫内膜异位症病变细胞凋亡,同时还通过减少细胞外腺苷(eADO,氧化磷酸化的一种代谢副产物)来调节巨噬细胞极化。
子宫内膜异位症与线粒体功能障碍有关,而异位子宫内膜间质细胞(EESCs)对氧化应激表现出更高的易感性。巨噬细胞积聚在腹腔和腹腔液中,是子宫内膜异位症病变中主要的免疫细胞群体。
研究设计、规模、持续时间:纳入了6个月内在一所大学附属医院接受手术治疗的25例诊断为卵巢子宫内膜异位症的患者和25名健康供体。分离、培养原代正常子宫内膜间质细胞(NESCs)和EESCs,并进行药物干预、小干扰RNA(siRNA)转染、氧化磷酸化分析和转录组分析。使用巨噬细胞系RAW264.7研究巨噬细胞极化。体内研究涉及24只C57BL/6雌性小鼠以建立子宫内膜异位症模型。
参与者/材料、环境、方法:使用细胞计数试剂盒-8(CCK-8)克隆形成试验、5-乙炔基-2'-脱氧尿苷(EdU)掺入和流式细胞术评估哈尔明碱对体外细胞活力的影响。通过透射电子显微镜和荧光染色观察到的线粒体超微结构变化评估氧化磷酸化抑制。使用JC-1线粒体膜电位测定法和活性氧(ROS)检测试剂盒对氧化应激进行定量。进行海马耗氧率测定以测量氧化磷酸化活性。采用免疫组织化学法检测子宫内膜组织中的关键蛋白表达。分别使用ATP测定试剂盒和腺苷测定试剂盒对ATP和eADO水平进行定量。我们使用RNA测序(RNA-seq)来识别富集的生物学途径。使用流式细胞术对腹腔液中的巨噬细胞群体进行表征,并应用CIBERSORTx软件生成免疫细胞表达谱。选择P值<0.05的样本进行分析,使用Wilcoxon检验对巨噬细胞亚型(Mφ2/Mφ1)的变化进行统计学评估。
与NESCs相比EESCs对哈尔明碱治疗表现出更高的易感性(P<0.05)。RNA-seq分析表明,哈尔明碱主要影响与细胞增殖、氧化应激和HIF-1信号传导相关的途径。差异表达基因富集于调节线粒体氧化磷酸化的复合物中。与NESCs相比,哈尔明碱干预显著增加了EESCs中的线粒体分裂,并显著抑制了EESCs中的氧化磷酸化活性。哈尔明碱处理降低了培养的EESCs中的总ROS水平(与NESCs相比,P<0.05)。eADO/CD73介导的腺苷途径在子宫内膜异位症病变中上调,同时微环境中以Mφ2巨噬细胞为主(Wilcoxon检验,P<0.05)。在小鼠模型中,哈尔明碱治疗降低了eADO的产生,并使巨噬细胞极化转向促炎Mφ1表型,有助于子宫内膜异位症病变消退。
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局限性、谨慎原因:该研究对原代细胞的依赖受到其有限传代潜力和固有异质性的限制,排除了共培养研究。进一步的机制阐明需要基于细胞系的研究。研究应纳入更多亚型,而不仅仅是卵巢子宫内膜异位症模型。如果条件允许,实验中应纳入在位子宫内膜细胞。此外,未来体内验证应考虑使用具有月经周期的灵长类动物模型,如恒河猴。
这些发现表明,哈尔明碱可能作为一种有前景的基于生物碱的子宫内膜异位症治疗药物,通过调节能量代谢和免疫反应发挥作用。
研究资金/利益冲突:本研究得到中国国家自然科学基金(NSFC No. 82201814)、广东省基础与应用基础研究基金(2021A1515110444)和南方医科大学深圳医院基金(PY2022YM03)的支持。作者声明无利益冲突。
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