Cytokine relay from the peripheral to the central: Secrets behind fever

IF 5.6 2区 医学 Q1 PHYSIOLOGY Acta Physiologica Pub Date : 2024-09-02 DOI:10.1111/apha.14225
Xianshu Bai
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However, the precise mechanisms by which hypothalamic microglia interact with peripheral immune cells to induce fever remain unclear.<span><sup>3</sup></span></p><p>In this issue of <i>Acta Physiologica</i>, Yu et al. elucidate the molecular mechanisms of fever driven by interactions between peripheral macrophages and preoptic anterior hypothalamus (POAH) microglia.<span><sup>4</sup></span> In this study, they administered 20 μg/kg of LPS via the tail vein, which triggered a characteristic biphasic fever at 2 and 6 hours post-injection (hpi). At each time point, the levels of key pro-inflammatory cytokines involved in fever development, including IL-1β, IL-18, interferon (IFN)-β, and TNF-α, were measured. At 2 hpi, there was a slight but not significant increase in the number of macrophages in the blood and in the levels of cytokines in the serum. However, by 6 hpi, there was a significant increase in both peripheral macrophages and CNS microglia, accompanied by a dramatic rise in PGE2 and IL-1β levels in the blood and POAH region. Importantly, this was not due to LPS entering the brain, as neither Evans blue nor FITC-LPS applied peripherally was detected in the brain, indicating that microglia activation was not a direct result of LPS exposure. As these sets of cytokines are mainly expressed by macrophages and microglia, authors hypothesized that the activation of microglia is due to the entry of cytokines derived from macrophages.</p><p>To further investigate, the authors selectively depleted peripheral macrophages by administering clodronate-liposome via tail-vein injection 24 h before LPS treatment. In the absence of macrophages, even after 6 h of LPS injection, neither the microglia number nor the body temperature changed. Depleting macrophages also suppressed the LPS-induced increase in cytokine levels in both serum and the POAH region, suggesting that peripheral macrophages play a key role in fever development. Conversely, when POAH microglia were depleted using the same drug injected directly into the POAH region, cytokine levels in the serum were similarly elevated but remained low in the PO/AH region even after LPS treatment. Although body temperature was significantly reduced in comparison to LPS-treated control mice, it remained slightly higher than in healthy mice, likely due to the remaining action of macrophage-derived cytokines in POAH. Using bulk RNA-sequencing, the authors identified a significant increase in genes associated with the NOD-like receptor signaling pathway, particularly the Caspase11-NLRP3 inflammasome, in the POAH region 6 hpi of LPS, especially in microglia. These observations suggest that the first phase of fever (2 hpi LPS injection) may be attributed to the direct effect of macrophage-derived cytokines entering the brain, while the second temperature peak is driven by cytokine amplification within hypothalamic microglia. These data support the hypothesis of a cytokine relay and amplification mechanism between peripheral macrophages and central microglia in fever development.</p><p>In vitro co-culture experiments revealed that both the LPS-treated activated bone marrow-derived macrophages (BMDM) and BV-2 microglia co-cultured with activated BMDM upregulate cytokines. In addition, these microglia significantly increased the Caspase11 expression. This effect was also observed when BV-2 microglia were treated with a conditioned medium from activated BMDM cells and was further amplified when the co-culture system was incubated at 39°C, mimicking high body temperature. This suggests that microglial Caspase11 is involved in the cytokine relay between macrophages and microglia, contributing to fever development. By selectively silencing microglia-specific Caspase11, the authors were able to suppress the second temperature peak without affecting the first, while cytokine expression in the POAH region returned to healthy levels. Conversely, overexpressing Caspase11 in POAH microglia significantly increased cytokine levels in this region, and the second phase of temperature increase was slightly elevated.</p><p>The study significantly advances our understanding of the molecular mechanisms underlying fever by identifying Caspase11 in microglia as a key player in driving fever through the non-canonical inflammasome pathway. In addition, the intricate cooperation within the body, involving a cytokine relay from the periphery to the CNS, is of great interest, as it could lead to new therapeutic approaches for managing fever in various clinical settings.</p><p>In the future, further studies are needed to determine whether macrophage-derived cytokines directly act on POAH microglia or other cell populations. Endothelial cells lining brain blood vessels also respond to cytokines and produce PGE2, further facilitating the fever response.<span><sup>5</sup></span> A recent study demonstrated that LPS triggers an increase in peripheral adenosine, which acts on astrocytes and further modulates microglial reactivity in a systemically induced sepsis model.<span><sup>6</sup></span> Oligodendrocyte precursor cells, some of which locate on blood vessels,<span><sup>7</sup></span> can interact with immune cells<span><sup>8, 9</sup></span> and participate in immune modulation.<span><sup>10</sup></span> Therefore, it remains to be studied whether, apart from the direct action of macrophage-derived cytokines on POAH microglia, other glial cells in the CNS are involved in driving fever. It is also unclear how microglia-derived cytokines modulate fever, either directly or by interacting with other glial cells, such as oligodendrocytes.<span><sup>11</sup></span> Additionally, detailed investigations are required to clarify whether the interaction between macrophages and microglia involves direct cytokine relay or indirect mechanisms. 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Abstract

Fever is often triggered by infections or inflammatory conditions, primarily mediated by the immune system. Immune cells like macrophages and dendritic cells detect pathogens through pathogen-associated molecular patterns, such as lipopolysaccharides (LPS).1 In response, these immune cells release a significant number of inflammatory factors or cytokines, which travel through the bloodstream to the hypothalamus, the body's thermoregulatory center. Once in the hypothalamus, these cytokines stimulate various cells, including microglia—the innate immune cell in the central nervous system.2 This stimulation initiates a complex cascade that raises body temperature. However, the precise mechanisms by which hypothalamic microglia interact with peripheral immune cells to induce fever remain unclear.3

In this issue of Acta Physiologica, Yu et al. elucidate the molecular mechanisms of fever driven by interactions between peripheral macrophages and preoptic anterior hypothalamus (POAH) microglia.4 In this study, they administered 20 μg/kg of LPS via the tail vein, which triggered a characteristic biphasic fever at 2 and 6 hours post-injection (hpi). At each time point, the levels of key pro-inflammatory cytokines involved in fever development, including IL-1β, IL-18, interferon (IFN)-β, and TNF-α, were measured. At 2 hpi, there was a slight but not significant increase in the number of macrophages in the blood and in the levels of cytokines in the serum. However, by 6 hpi, there was a significant increase in both peripheral macrophages and CNS microglia, accompanied by a dramatic rise in PGE2 and IL-1β levels in the blood and POAH region. Importantly, this was not due to LPS entering the brain, as neither Evans blue nor FITC-LPS applied peripherally was detected in the brain, indicating that microglia activation was not a direct result of LPS exposure. As these sets of cytokines are mainly expressed by macrophages and microglia, authors hypothesized that the activation of microglia is due to the entry of cytokines derived from macrophages.

To further investigate, the authors selectively depleted peripheral macrophages by administering clodronate-liposome via tail-vein injection 24 h before LPS treatment. In the absence of macrophages, even after 6 h of LPS injection, neither the microglia number nor the body temperature changed. Depleting macrophages also suppressed the LPS-induced increase in cytokine levels in both serum and the POAH region, suggesting that peripheral macrophages play a key role in fever development. Conversely, when POAH microglia were depleted using the same drug injected directly into the POAH region, cytokine levels in the serum were similarly elevated but remained low in the PO/AH region even after LPS treatment. Although body temperature was significantly reduced in comparison to LPS-treated control mice, it remained slightly higher than in healthy mice, likely due to the remaining action of macrophage-derived cytokines in POAH. Using bulk RNA-sequencing, the authors identified a significant increase in genes associated with the NOD-like receptor signaling pathway, particularly the Caspase11-NLRP3 inflammasome, in the POAH region 6 hpi of LPS, especially in microglia. These observations suggest that the first phase of fever (2 hpi LPS injection) may be attributed to the direct effect of macrophage-derived cytokines entering the brain, while the second temperature peak is driven by cytokine amplification within hypothalamic microglia. These data support the hypothesis of a cytokine relay and amplification mechanism between peripheral macrophages and central microglia in fever development.

In vitro co-culture experiments revealed that both the LPS-treated activated bone marrow-derived macrophages (BMDM) and BV-2 microglia co-cultured with activated BMDM upregulate cytokines. In addition, these microglia significantly increased the Caspase11 expression. This effect was also observed when BV-2 microglia were treated with a conditioned medium from activated BMDM cells and was further amplified when the co-culture system was incubated at 39°C, mimicking high body temperature. This suggests that microglial Caspase11 is involved in the cytokine relay between macrophages and microglia, contributing to fever development. By selectively silencing microglia-specific Caspase11, the authors were able to suppress the second temperature peak without affecting the first, while cytokine expression in the POAH region returned to healthy levels. Conversely, overexpressing Caspase11 in POAH microglia significantly increased cytokine levels in this region, and the second phase of temperature increase was slightly elevated.

The study significantly advances our understanding of the molecular mechanisms underlying fever by identifying Caspase11 in microglia as a key player in driving fever through the non-canonical inflammasome pathway. In addition, the intricate cooperation within the body, involving a cytokine relay from the periphery to the CNS, is of great interest, as it could lead to new therapeutic approaches for managing fever in various clinical settings.

In the future, further studies are needed to determine whether macrophage-derived cytokines directly act on POAH microglia or other cell populations. Endothelial cells lining brain blood vessels also respond to cytokines and produce PGE2, further facilitating the fever response.5 A recent study demonstrated that LPS triggers an increase in peripheral adenosine, which acts on astrocytes and further modulates microglial reactivity in a systemically induced sepsis model.6 Oligodendrocyte precursor cells, some of which locate on blood vessels,7 can interact with immune cells8, 9 and participate in immune modulation.10 Therefore, it remains to be studied whether, apart from the direct action of macrophage-derived cytokines on POAH microglia, other glial cells in the CNS are involved in driving fever. It is also unclear how microglia-derived cytokines modulate fever, either directly or by interacting with other glial cells, such as oligodendrocytes.11 Additionally, detailed investigations are required to clarify whether the interaction between macrophages and microglia involves direct cytokine relay or indirect mechanisms. For instance, tracing macrophage-derived cytokines (using Rosa26-methionyl tRNA synthetase reporter) in microglia would be a promising starting point.

Xianshu Bai: Writing – original draft; conceptualization.

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从外周到中枢的细胞因子中继:发烧背后的秘密
发热通常由感染或炎症引发,主要由免疫系统介导。巨噬细胞和树突状细胞等免疫细胞通过脂多糖(LPS)等病原体相关分子模式检测到病原体。1 作为反应,这些免疫细胞会释放大量炎症因子或细胞因子,通过血液循环到达人体的体温调节中枢--下丘脑。一旦进入下丘脑,这些细胞因子就会刺激各种细胞,包括小胶质细胞--中枢神经系统中的先天性免疫细胞2。3 在本期《生理学报》(Acta Physiologica)上,Yu 等人阐明了外周巨噬细胞与视前下丘脑(POAH)小胶质细胞相互作用导致发热的分子机制。4 在这项研究中,他们通过尾静脉注射 20 μg/kg LPS,在注射后 2 小时和 6 小时(hpi)引发了特征性的双相发热。在每个时间点,测量了参与发热的主要促炎细胞因子的水平,包括IL-1β、IL-18、干扰素(IFN)-β和TNF-α。2 小时后,血液中巨噬细胞的数量和血清中细胞因子的水平略有增加,但不明显。然而,到了 6 小时后,外周巨噬细胞和中枢神经系统小胶质细胞都显著增加,同时血液和 POAH 区域的 PGE2 和 IL-1β 水平也急剧上升。重要的是,这并不是因为 LPS 进入了大脑,因为在大脑中既没有检测到埃文斯蓝,也没有检测到外周应用的 FITC-LPS,这表明小胶质细胞的激活并不是 LPS 暴露的直接结果。由于这几组细胞因子主要由巨噬细胞和小胶质细胞表达,作者假设小胶质细胞的活化是由于来自巨噬细胞的细胞因子的进入。为了进一步研究,作者在 LPS 处理前 24 小时通过尾静脉注射氯屈膦酸脂质体,选择性地消耗外周巨噬细胞。在没有巨噬细胞的情况下,即使注射了 6 小时的 LPS,小胶质细胞的数量和体温都没有发生变化。消耗巨噬细胞还能抑制 LPS 诱导的血清和 POAH 区域细胞因子水平的升高,这表明外周巨噬细胞在发热的发生中起着关键作用。相反,当使用直接注射到 POAH 区域的相同药物耗竭 POAH 小胶质细胞时,血清中的细胞因子水平同样升高,但即使在 LPS 处理后,PO/AH 区域的细胞因子水平仍然很低。虽然与经 LPS 处理的对照组小鼠相比,体温明显降低,但仍略高于健康小鼠,这可能是由于 POAH 中仍有巨噬细胞衍生的细胞因子在起作用。通过大量 RNA 测序,作者发现在 LPS 6 hpi 的 POAH 区域,特别是在小胶质细胞中,与 NOD 样受体信号通路相关的基因,尤其是 Caspase11-NLRP3 炎性体显著增加。这些观察结果表明,发热的第一阶段(注射 LPS 2 hpi)可能是巨噬细胞衍生的细胞因子进入大脑的直接效应,而第二个温度峰值则是由下丘脑小胶质细胞内的细胞因子扩增驱动的。体外共培养实验显示,经 LPS 处理的活化骨髓源性巨噬细胞(BMDM)和与活化骨髓源性巨噬细胞共培养的 BV-2 小胶质细胞都会上调细胞因子。此外,这些小胶质细胞还明显增加了 Caspase11 的表达。当用活化的 BMDM 细胞的条件培养基处理 BV-2 小胶质细胞时,也观察到了这种效应。这表明小胶质细胞 Caspase11 参与了巨噬细胞和小胶质细胞之间的细胞因子中继,从而导致发热。通过选择性沉默小胶质细胞特异性 Caspase11,作者能够在不影响第一个温度峰值的情况下抑制第二个温度峰值,而 POAH 区域的细胞因子表达则恢复到健康水平。相反,在 POAH 小胶质细胞中过表达 Caspase11 会显著增加该区域的细胞因子水平,第二阶段的体温升高也会略微升高。这项研究通过确定小胶质细胞中的 Caspase11 是通过非典型炎性体途径驱动发热的关键角色,极大地推动了我们对发热分子机制的理解。 此外,从外周到中枢神经系统的细胞因子中继在机体内的复杂合作关系也非常引人关注,因为这可能为在各种临床环境中控制发热带来新的治疗方法。未来还需要进一步研究,以确定巨噬细胞衍生的细胞因子是否直接作用于 POAH 小胶质细胞或其他细胞群。5 最近的一项研究表明,LPS 会引发外周腺苷的增加,而腺苷会作用于星形胶质细胞,并进一步调节系统诱导的败血症模型中的小胶质细胞反应性。10 因此,除了巨噬细胞衍生的细胞因子对 POAH 小胶质细胞的直接作用外,中枢神经系统中的其他胶质细胞是否参与了发热的驱动,还有待研究。目前还不清楚小胶质细胞衍生的细胞因子是如何直接或通过与其他神经胶质细胞(如少突胶质细胞)相互作用来调节发热的。例如,在小胶质细胞中追踪巨噬细胞衍生的细胞因子(使用 Rosa26-methionyl tRNA 合成酶报告物)将是一个很有希望的起点:写作-原稿;构思。
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
Acta Physiologica
Acta Physiologica 医学-生理学
CiteScore
11.80
自引率
15.90%
发文量
182
审稿时长
4-8 weeks
期刊介绍: Acta Physiologica is an important forum for the publication of high quality original research in physiology and related areas by authors from all over the world. Acta Physiologica is a leading journal in human/translational physiology while promoting all aspects of the science of physiology. The journal publishes full length original articles on important new observations as well as reviews and commentaries.
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