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炎症状态下巨噬细胞和间充质干细胞中的糖酵解重编程。

Glycolytic reprogramming in macrophages and MSCs during inflammation.

机构信息

Department of Orthopaedic Surgery, Stanford University School of Medicine, Stanford, CA, United States.

Department of Orthopaedic Surgery, First Affiliated Hospital of Soochow University, Suzhou, China.

出版信息

Front Immunol. 2023 Aug 22;14:1199751. doi: 10.3389/fimmu.2023.1199751. eCollection 2023.

DOI:10.3389/fimmu.2023.1199751
PMID:37675119
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10477714/
Abstract

BACKGROUND

Dysregulated inflammation is associated with many skeletal diseases and disorders, such as osteolysis, non-union of fractures, osteonecrosis, osteoarthritis and orthopaedic infections. We previously showed that continuous infusion of lipopolysaccharide (LPS) contaminated polyethylene particles (cPE) caused prolonged inflammation and impaired bone formation. However, the metabolic and bioenergetic processes associated with inflammation of bone are unknown. Mitochondria are highly dynamic organelles that modulate cell metabolism and orchestrate the inflammatory responses that involve both resident and recruited cells. Glycolytic reprogramming, the shift from oxidative phosphorylation (OXPHOS) to glycolysis causes inappropriate cell activation and function, resulting in dysfunctional cellular metabolism. We hypothesized that impaired immunoregulation and bone regeneration from inflammatory states are associated with glycolytic reprogramming and mitochondrial dysfunction in macrophages (Mφ) and mesenchymal stromal cells (MSCs).

METHODS

We used the Seahorse XF96 analyzer and real-time qPCR to study the bioenergetics of Mφ and MSCs exposed to cPE. To understand the oxygen consumption rate (OCR), we used Seahorse XF Cell Mito Stress Test Kit with Seahorse XF96 analyzer. Similarly, Seahorse XF Glycolytic Rate Assay Kit was used to detect the extracellular acidification rate (ECAR) and Seahorse XF Real-Time ATP Rate Assay kit was used to detect the real-time ATP production rates from OXPHOS and glycolysis. Real-time qPCR was performed to analyze the gene expression of key enzymes in glycolysis and mitochondrial biogenesis. We further detected the gene expression of proinflammatory cytokines in Mφ and genes related to cell differentiation in MSC during the challenge of cPE.

RESULTS

Our results demonstrated that the oxidative phosphorylation of Mφ exposed to cPE was significantly decreased when compared with the control group. We found reduced basal, maximal and ATP-production coupled respiration rates, and decreased proton leak in Mφ during challenge with cPE. Meanwhile, Mφ showed increased basal glycolysis and proton efflux rates (PER) when exposed to cPE. The percentage (%) of PER from glycolysis was higher in Mφ exposed to cPE, indicating that the contribution of the glycolytic pathway to total extracellular acidification was elevated during the challenge of cPE. In line with the results of OCR and ECAR, we found Mφ during cPE challenge showed higher glycolytic ATP (glycoATP) production rates and lower mitochondrial ATP (mitoATP) production rates which is mainly from OXPHOS. Interestingly, MSCs showed enhanced glycolysis during challenge with cPE, but no significant changes in oxygen consumption rates (OCR). In accordance, seahorse assay of real-time ATP revealed glycoATP rates were elevated while mitoATP rates showed no significant differences in MSC during challenge with cPE. Furthermore, Mφ and MSCs exposed to cPE showed upregulated gene expression levels of glycolytic regulators and Mφ exposed to cPE expressed higher levels of pro-inflammatory cytokines.

CONCLUSION

This study demonstrated the dysfunctional bioenergetic activity of bone marrow-derived Mφ and MSCs exposed to cPE, which could impair the immunoregulatory properties of cells in the bone niche. The underlying molecular defect related to disordered mitochondrial function could represent a potential therapeutic target during the resolution of inflammation.

摘要

背景

炎症失调与许多骨骼疾病和紊乱有关,例如骨溶解、骨折不愈合、骨坏死、骨关节炎和骨科感染。我们之前的研究表明,持续输注污染聚乙稀颗粒的脂多糖(LPS)会导致长期炎症和骨形成受损。然而,与骨炎症相关的代谢和生物能量过程尚不清楚。线粒体是高度动态的细胞器,可调节细胞代谢并协调涉及驻留细胞和募集细胞的炎症反应。糖酵解重编程,即从氧化磷酸化(OXPHOS)向糖酵解的转变,导致细胞不当激活和功能障碍,导致细胞代谢功能障碍。我们假设,炎症状态下免疫调节受损和骨再生与巨噬细胞(Mφ)和间充质基质细胞(MSCs)中的糖酵解重编程和线粒体功能障碍有关。

方法

我们使用 Seahorse XF96 分析仪和实时 qPCR 来研究 cPE 暴露的 Mφ 和 MSC 的生物能量。为了了解耗氧率(OCR),我们使用 Seahorse XF 细胞线粒体应激测试试剂盒与 Seahorse XF96 分析仪。同样,使用 Seahorse XF 糖酵解速率测定试剂盒检测细胞外酸化率(ECAR),使用 Seahorse XF 实时 ATP 速率测定试剂盒检测 OXPHOS 和糖酵解的实时 ATP 产生率。通过实时 qPCR 分析糖酵解和线粒体生物发生关键酶的基因表达。我们进一步检测了 cPE 刺激后 Mφ 中的促炎细胞因子基因表达和 MSC 中的细胞分化相关基因表达。

结果

我们的结果表明,与对照组相比,cPE 暴露的 Mφ 的氧化磷酸化显著降低。我们发现 cPE 刺激时,Mφ 的基础、最大和 ATP 产生偶联呼吸率降低,质子泄漏增加。同时,cPE 暴露时 Mφ 的基础糖酵解和质子外排率(PER)增加。cPE 刺激时 Mφ 的糖酵解途径对总细胞外酸化的贡献百分比(% PER)更高,表明糖酵解途径的贡献增加。与 OCR 和 ECAR 的结果一致,我们发现 cPE 刺激时 Mφ 的糖酵解 ATP(glycoATP)产生率更高,而线粒体 ATP(mitoATP)产生率更低,这主要来自 OXPHOS。有趣的是,cPE 刺激时 MSCs 表现出增强的糖酵解,但耗氧量(OCR)没有显著变化。与此一致,cPE 刺激时实时 ATP 的 Seahorse 测定显示 glycoATP 率升高,而 MSC 中的 mitoATP 率没有显著变化。此外,cPE 暴露的 Mφ 和 MSCs 表现出糖酵解调节因子的基因表达水平上调,cPE 暴露的 Mφ 表达更高水平的促炎细胞因子。

结论

这项研究表明,骨髓来源的 Mφ 和 MSCs 暴露于 cPE 时会出现生物能量功能障碍,这可能会损害骨龛中细胞的免疫调节特性。与线粒体功能障碍相关的潜在分子缺陷可能代表炎症消退期间的潜在治疗靶点。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c83c/10477714/64c386b4f26c/fimmu-14-1199751-g009.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c83c/10477714/64c386b4f26c/fimmu-14-1199751-g009.jpg

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