Respiratory bioenergetics is enhanced in human, but not bovine macrophages after exposure to M. bovis PPD: Exploratory insights into overall similar Cellular Metabolic Profiles.

IF 2.8 4区医学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Innate Immunity Pub Date : 2024-08-01 Epub Date: 2024-11-20 DOI:10.1177/17534259241296630

Marie-Christine Bartens, Sam Willcocks, Dirk Werling, Amanda J Gibson

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引用次数: 0

Abstract

The role of macrophage (MØ) cellular metabolism and reprogramming during TB infection is of great interest due to the influence of Mycobacterium spp. on MØ bioenergetics. Recent studies have shown that M. tuberculosis induces a TLR2-dependent shift towards aerobic glycolysis, comparable to the established LPS induced pro-inflammatory M1 MØ polarisation. Distinct differences in the metabolic profile of murine and human MØ indicates species-specific differences in bioenergetics. So far, studies examining the metabolic potential of bovine MØ are lacking, thus the basic bioenergetics of bovine and human MØ were explored in response to a variety of innate immune stimuli. Cellular energy metabolism kinetics were measured concurrently for both species on a Seahorse XFe96 platform to generate bioenergetic profiles for the response to the bona-fide TLR2 and TLR4 ligands, FSL-1 and LPS respectively. Despite previous reports of species-specific differences in TLR signalling and cytokine production between human and bovine MØ, we observed similar respiratory profiles for both species. Basal respiration remained constant between stimulated MØ and controls, whereas addition of TLR ligands induced increased glycolysis, as measured by the surrogate parameter ECAR. In contrast to MØ stimulation with M. tuberculosis PPD, another TLR2 ligand, M. bovis PPD treatment significantly enhanced basal respiration rates and glycolysis only in human MØ. Respiratory profiling further revealed significant elevation of ATP-linked OCR and maximal respiration suggesting a strong OXPHOS activation upon M. bovis PPD stimulation in human MØ. Our results provide an exploratory set of data elucidating the basic respiratory profile of bovine vs. human MØ that will not only lay the foundation for future studies to investigate host-tropism of the M. tuberculosis complex but may explain inflammatory differences observed for other zoonotic diseases.

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人而不是牛的巨噬细胞在暴露于牛海绵状芽孢杆菌 PPD 后呼吸生物能增强：对总体相似细胞代谢特征的探索性见解。

由于分枝杆菌对巨噬细胞（MØ）生物能的影响，巨噬细胞（MØ）在结核病感染过程中的细胞代谢和重编程作用备受关注。最近的研究表明，结核杆菌会诱导 TLR2 依赖性转向有氧糖酵解，与 LPS 诱导的促炎性 M1 MØ 极化相当。小鼠和人类 MØ 新陈代谢谱的明显差异表明生物能的物种特异性差异。迄今为止，还缺乏对牛 MØ 代谢潜力的研究，因此我们探讨了牛和人 MØ 在各种先天性免疫刺激下的基本生物能。在海马 XFe96 平台上同时测量了这两个物种的细胞能量代谢动力学，以生成生物能谱，分别用于对真正的 TLR2 和 TLR4 配体 FSL-1 和 LPS 的反应。尽管之前有报道称人和牛的 MØ 在 TLR 信号传导和细胞因子产生方面存在物种特异性差异，但我们观察到这两个物种的呼吸曲线相似。受刺激的 MØ 和对照组的基础呼吸量保持不变，而添加 TLR 配体会导致糖酵解增加，这是由替代参数 ECAR 测定的。与用结核杆菌 PPD（另一种 TLR2 配体）刺激 MØ 不同的是，牛结核杆菌 PPD 处理只显著提高了人类 MØ 的基础呼吸率和糖酵解率。呼吸谱分析进一步显示，与 ATP 链接的 OCR 和最大呼吸显著升高，这表明在人 M.bovis PPD 刺激下，M.bovis PPD 会强烈激活 OXPHOS。我们的研究结果提供了一组探索性的数据，阐明了牛与人MØ的基本呼吸谱，这不仅为今后研究结核杆菌复合体的宿主趋向性奠定了基础，而且可以解释在其他人畜共患病中观察到的炎症差异。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Innate Immunity 生物-免疫学

CiteScore

7.20

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Innate Immunity is a highly ranked, peer-reviewed scholarly journal and is the official journal of the International Endotoxin & Innate Immunity Society (IEIIS). The journal welcomes manuscripts from researchers actively working on all aspects of innate immunity including biologically active bacterial, viral, fungal, parasitic, and plant components, as well as relevant cells, their receptors, signaling pathways, and induced mediators. The aim of the Journal is to provide a single, interdisciplinary forum for the dissemination of new information on innate immunity in humans, animals, and plants to researchers. The Journal creates a vehicle for the publication of articles encompassing all areas of research, basic, applied, and clinical. The subject areas of interest include, but are not limited to, research in biochemistry, biophysics, cell biology, chemistry, clinical medicine, immunology, infectious disease, microbiology, molecular biology, and pharmacology.