Hancock David G, Shklovskaya Elena, Guy Thomas V, Falsafi Reza, Fjell Chris D, Ritchie William, Hancock Robert E W, Fazekas de St Groth Barbara
Centenary Institute of Cancer Medicine and Cell Biology, New South Wales, Australia; The Discipline of Dermatology, University of Sydney, New South Wales, Australia.
Centre for Microbial Diseases & Immunity Research, University of British Columbia, Vancouver, British Columbia, Canada.
PLoS One. 2014 Jun 20;9(6):e100613. doi: 10.1371/journal.pone.0100613. eCollection 2014.
Dendritic cells (DCs) are critical for regulating CD4 and CD8 T cell immunity, controlling Th1, Th2, and Th17 commitment, generating inducible Tregs, and mediating tolerance. It is believed that distinct DC subsets have evolved to control these different immune outcomes. However, how DC subsets mount different responses to inflammatory and/or tolerogenic signals in order to accomplish their divergent functions remains unclear. Lipopolysaccharide (LPS) provides an excellent model for investigating responses in closely related splenic DC subsets, as all subsets express the LPS receptor TLR4 and respond to LPS in vitro. However, previous studies of the LPS-induced DC transcriptome have been performed only on mixed DC populations. Moreover, comparisons of the in vivo response of two closely related DC subsets to LPS stimulation have not been reported in the literature to date. We compared the transcriptomes of murine splenic CD8 and CD11b DC subsets after in vivo LPS stimulation, using RNA-Seq and systems biology approaches. We identified subset-specific gene signatures, which included multiple functional immune mediators unique to each subset. To explain the observed subset-specific differences, we used a network analysis approach. While both DC subsets used a conserved set of transcription factors and major signalling pathways, the subsets showed differential regulation of sets of genes that 'fine-tune' the network Hubs expressed in common. We propose a model in which signalling through common pathway components is 'fine-tuned' by transcriptional control of subset-specific modulators, thus allowing for distinct functional outcomes in closely related DC subsets. We extend this analysis to comparable datasets from the literature and confirm that our model can account for cell subset-specific responses to LPS stimulation in multiple subpopulations in mouse and man.
树突状细胞(DCs)对于调节CD4和CD8 T细胞免疫、控制Th1、Th2和Th17分化、产生诱导性调节性T细胞以及介导免疫耐受至关重要。据信,不同的DC亚群已经进化以控制这些不同的免疫结果。然而,DC亚群如何对炎症和/或致耐受性信号产生不同反应以完成其不同功能仍不清楚。脂多糖(LPS)为研究密切相关的脾脏DC亚群的反应提供了一个极好的模型,因为所有亚群都表达LPS受体TLR4并在体外对LPS作出反应。然而,先前关于LPS诱导的DC转录组的研究仅在混合DC群体上进行。此外,迄今为止文献中尚未报道两个密切相关的DC亚群对LPS刺激的体内反应比较。我们使用RNA测序和系统生物学方法比较了体内LPS刺激后小鼠脾脏CD8和CD11b DC亚群的转录组。我们鉴定了亚群特异性基因特征,其中包括每个亚群特有的多种功能性免疫介质。为了解释观察到的亚群特异性差异,我们使用了网络分析方法。虽然两个DC亚群都使用一组保守的转录因子和主要信号通路,但这些亚群对共同表达的网络枢纽基因集显示出差异调节。我们提出了一个模型,其中通过共同通路成分的信号传导通过亚群特异性调节剂的转录控制进行“微调”,从而允许密切相关的DC亚群产生不同的功能结果。我们将此分析扩展到文献中的可比数据集,并证实我们的模型可以解释小鼠和人类多个亚群中细胞亚群对LPS刺激的特异性反应。
