亚精胺通过eIF5A假说和代谢适应抑制DC激活。

Discovery immunology Pub Date : 2025-05-15 eCollection Date: 2025-01-01 DOI:10.1093/discim/kyaf009

Gavin R Meehan, Utku Gunes, Larissa Camargo da Rosa, Hannah E Scales, George Finney, Ross Deehan, Sofia Sintoris, Aegli Athanasiadou, Jack Jones, Georgia Perona-Wright, James M Brewer

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引用次数: 0

摘要

细胞代谢在免疫效应反应中起着重要作用，免疫细胞通过对代谢信号的响应来适应和调节自身的功能。树突状细胞（DC）中的精氨酸代谢已被证明可以降低T细胞的活化；然而，目前尚不清楚这种免疫抑制状态是如何被诱导的。方法：为了解决这个问题，我们检查了精氨酸代谢的各种代谢物的免疫调节能力。结果：通过使用最近描述的DC:T细胞相互作用实验和流式细胞术，我们证明亚精胺最显著地抑制DC激活，阻止随后与CD4 T细胞的相互作用。通过eIF5A-hypusine轴添加亚精胺代谢抑制剂可以恢复DC功能，这是一些线粒体酶表达所必需的。我们还证明，亚精胺诱导的免疫抑制状态保护DC免受激活诱导的线粒体能量产生能力丧失的影响，线粒体能量产生能力也依赖于催眠。结论：综上所述，这些数据表明亚精胺是精氨酸代谢下游的关键免疫调节成分，它通过刺激DC中OXPHOS的假说依赖性保护来介导这一作用，从而导致DC激活和与T细胞相互作用的能力降低。这一途径可能被免疫系统用来调节过度的免疫反应，但也可能被病原体利用作为免疫逃避的一种方法。

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Spermidine suppresses DC activation via eIF5A hypusination and metabolic adaptation.

Introduction: Cell metabolism plays an important role in immune effector responses and through responding to metabolic signals, immune cells can adapt and regulate their function. Arginine metabolism in dendritic cells (DC) has been shown to reduce T cell activation; however, it is unclear how this immunosuppressive state is induced.

Method: To address this issue, we examined the immunomodulatory capacity of various metabolites from arginine metabolism.

Results: Through the use of a recently described DC:T cell interaction assay and flow cytometry we demonstrated that spermidine most significantly inhibited DC activation, preventing subsequent interactions with CD4 T cells. DC function could be restored by addition of inhibitors of spermidine metabolism via the eIF5A-hypusine axis, required for expression of some mitochondrial enzymes. We also demonstrated that the spermidine induced-immunosuppressive state protected DC against activation-induced loss of mitochondrial capacity for energy generation, which was also hypusination dependent.

Conclusion: Taken together, these data demonstrate that spermidine is the key immunomodulatory component downstream of arginine metabolism and that it mediates this effect by stimulating hypusination-dependent protection of OXPHOS in DC, which in turn results in a reduced ability of DC to activate and interact with T cells. This pathway may be utilized by the immune system to regulate excessive immune responses but could also be exploited by pathogens as a method of immune evasion.

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Discovery immunology

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