Deciphering the relationship between temperature and immunity

Elizabeth Maloney, Darragh Duffy
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Abstract

Summary Fever is a hallmark symptom of disease across the animal kingdom. Yet, despite the evidence linking temperature fluctuation and immune response, much remains to be discovered about the molecular mechanisms governing these interactions. In patients with rheumatoid arthritis, for instance, it is clinically accepted that joint temperature can predict disease progression. But it was only recently demonstrated that the mitochondria of stimulated T cells can rise to an extreme 50°C, potentially indicating a cellular source of these localized ‘fevers’. A challenge to dissecting these mechanisms is a bidirectional interplay between temperature and immunity. Heat shock response is found in virtually all organisms, activating protective pathways when cells are exposed to elevated temperatures. However, the temperature threshold that activates these pathways can vary within the same organism, with human immune cells, in particular, demonstrating differential sensitivity to heat. Such inter-cellular variation may be clinically relevant given the small but significant temperature differences seen between tissues, ages, and sexes. Greater understanding of how such small temperature perturbations mediate immune responses may provide new explanations for persistent questions in disease such as sex disparity in disease prevalence. Notably, the prevalence and severity of many maladies are rising with climate change, suggesting temperature fluctuations can interact with disease on multiple levels. As global temperatures are rising, and our body temperatures are falling, questions regarding temperature–immune interactions are increasingly critical. Here, we review this aspect of environmental interplay to better understand temperature’s role in immune variation and subsequent risk of disease.
解读温度与免疫力之间的关系
摘要 发烧是动物界疾病的标志性症状。然而,尽管有证据表明体温波动与免疫反应有关,但有关这些相互作用的分子机制仍有许多有待发现。以类风湿性关节炎患者为例,临床上公认关节温度可以预测疾病的进展。但直到最近才有人证明,受刺激的 T 细胞线粒体可升高到 50°C 的极端温度,这可能表明这些局部 "发烧 "的细胞来源。温度与免疫之间的双向相互作用是剖析这些机制的一个挑战。热休克反应几乎存在于所有生物体中,当细胞暴露在高温下时,它会激活保护途径。然而,在同一生物体内,激活这些通路的温度阈值可能不同,尤其是人类免疫细胞对热的敏感性不同。鉴于不同组织、年龄和性别之间存在微小但显著的温度差异,这种细胞间差异可能与临床相关。进一步了解这种微小的温度扰动是如何介导免疫反应的,可能会为疾病的顽固问题(如疾病流行的性别差异)提供新的解释。值得注意的是,随着气候变化,许多疾病的发病率和严重程度都在上升,这表明温度波动会在多个层面上与疾病发生相互作用。随着全球气温不断升高,而我们的体温却在不断下降,有关温度-免疫相互作用的问题变得越来越重要。在此,我们回顾了环境相互作用的这一方面,以便更好地理解温度在免疫变异和随后的疾病风险中的作用。
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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