Sanmoy Pathak, T. Hogan, S. Rane, Yundi Huang, Charles Sinclair, Simon Barry, Larissa Carnevalli, Andrew J Yates, Benedict Seddon
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Here, we use a combination of fate mapping approaches in mice to map the ontogeny of Treg subsets throughout life and estimate rates of production, loss and self-renewal. We find that naive and effector/memory (EM) Treg subsets exhibit distinct dynamics but are both continuously replenished by de novo generation throughout life. Using an inducible Foxp3-dependent Cre fate reporter system, we show that naive Treg and not conventional T cells, are the predominant precursors of EM Treg in adults. Tonic development of new EM Treg is not influenced by foreign antigens from commensals, rather suggesting a role for self recognition. To investigate the ontogeny of Treg development in malignant disease, we used the same fate reporter systems to characterise the Treg infiltrate of three different model tumours. In all three cases, we found that Treg derived from pre-existing, EM Treg. 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引用次数: 0
摘要
Foxp3+ 调节性 T 细胞(Treg)是 CD4+ T 细胞的一个亚群,在维持对自身抗原的耐受性、抑制自身免疫、调节对病原体的免疫反应等方面发挥着重要功能,并在抗肿瘤免疫的病理生理学中发挥作用。Treg的本体发生非常复杂,因为它们是在正常T细胞发育过程中胸腺识别自身抗原后产生的(胸腺Treg),但当外来抗原通过适当的额外线索激活时,也会从成熟的常规T细胞中诱导产生(诱导性Treg)。目前还不清楚这些不同的本体形成途径如何有助于成熟 Treg 区系在健康和疾病中的维持和功能。在这里,我们在小鼠体内综合使用了命运图谱方法,绘制了Treg亚群在整个生命过程中的本体发育图,并估算了其产生、丢失和自我更新的速率。我们发现,幼稚和效应/记忆(EM)Treg亚群表现出不同的动态变化,但在整个生命过程中都在不断地从头生成补充。利用诱导性 Foxp3 依赖性 Cre 命运报告系统,我们发现天真 Treg 而非传统 T 细胞是成人 EM Treg 的主要前体。新的EM Treg的发育不受外来抗原(来自共生体)的影响,这表明了自我识别的作用。为了研究 Treg 在恶性疾病中的发育过程,我们使用了相同的命运报告系统来描述三种不同肿瘤模型中 Treg 浸润的特征。在所有三种情况下,我们都发现 Treg 来自于预先存在的 EM Treg。这些结果共同揭示了与恶性疾病病理生理学相关的 Treg 从胸腺起源到 EM Treg 的主要线性发展途径,该途径自始至终由自身抗原识别驱动。
A linear ontogeny accounts for the development of naive, memory and tumour-infiltrating regulatory T cells in mice
Foxp3+ Regulatory T cells (Treg) are a subset of CD4+ T cells that play critical functions in maintaining tolerance to self antigens and suppressing autoimmunity, regulating immune responses to pathogens and have a role in the pathophysiology of anti-tumoural immunity. Treg ontogeny is complex since they are generated following recognition of self antigens in the thymus during normal T cell development (thymic Treg), but are also induced from mature conventional T cells when activated by foreign antigen with appropriate additional cues (inducible Treg). How these distinct ontogenic pathways contribute to the maintenance and function of the mature Treg compartment in health and disease remains unclear. Here, we use a combination of fate mapping approaches in mice to map the ontogeny of Treg subsets throughout life and estimate rates of production, loss and self-renewal. We find that naive and effector/memory (EM) Treg subsets exhibit distinct dynamics but are both continuously replenished by de novo generation throughout life. Using an inducible Foxp3-dependent Cre fate reporter system, we show that naive Treg and not conventional T cells, are the predominant precursors of EM Treg in adults. Tonic development of new EM Treg is not influenced by foreign antigens from commensals, rather suggesting a role for self recognition. To investigate the ontogeny of Treg development in malignant disease, we used the same fate reporter systems to characterise the Treg infiltrate of three different model tumours. In all three cases, we found that Treg derived from pre-existing, EM Treg. Together, these results reveal a predominantly linear pathway of Treg development from thymic origin to EM Treg associated with pathophysiology of malignant disease, that is driven by self antigen recognition throughout.