Regulatory T (Treg) cells, expressing abundant amounts of the IL-2 receptor (IL-2R), are reliant on IL-2 produced by activated T cells. This feature implied a key role for a simple network based on IL-2 consumption by Treg cells in their suppressor function. However, congenital deficiency in IL-2R results in reduced expression of the Treg cell lineage specification factor Foxp3, confounding experimental efforts to understand the role of IL-2R expression and signaling in Treg suppressor function. Using genetic gain and loss of function approaches, we demonstrate that IL-2 capture is dispensable for control of CD4+ T cells, but is important for limiting CD8+ T cell activation, and that IL-2R dependent STAT5 transcription factor activation plays an essential role in Treg cell suppressor function separable from T cell receptor signaling.
Recent studies in Drosophila melanogaster of the protocadherins Dachsous and Fat suggest that they act as ligand and receptor, respectively, for an intercellular signaling pathway that influences tissue polarity, growth and gene expression, but the basis for signaling downstream of Fat has remained unclear. Here, we characterize functional relationships among D. melanogaster tumor suppressors and identify the kinases Discs overgrown and Warts as components of a Fat signaling pathway. fat, discs overgrown and warts regulate a common set of downstream genes in multiple tissues. Genetic experiments position the action of discs overgrown upstream of the Fat pathway component dachs, whereas warts acts downstream of dachs. Warts protein coprecipitates with Dachs, and Warts protein levels are influenced by fat, dachs and discs overgrown in vivo, consistent with its placement as a downstream component of the pathway. The tumor suppressors Merlin, expanded, hippo, salvador and mob as tumor suppressor also share multiple Fat pathway phenotypes but regulate Warts activity independently. Our results functionally link what had been four disparate groups of D. melanogaster tumor suppressors, establish a basic framework for Fat signaling from receptor to transcription factor and implicate Warts as an integrator of multiple growth control signals.
SUMMARY In multicellular organisms, specialized functions are delegated to distinct cell types whose identity and functional integrity is maintained upon challenge. However, little is known about the mechanisms enabling lineage inheritance and their biological implications. Regulatory T (Treg) cells, which express the transcription factor Foxp3, suppress fatal autoimmunity throughout the lifespan of animals. Here, we show that a dedicated Foxp3 intronic element CNS2 maintains Treg cell lineage identity by acting as a sensor of the essential Treg cell growth factor IL-2 and its downstream target STAT5. CNS2 sustains Foxp3 expression during division of mature Treg cells when IL-2 is limiting and counteracts pro-inflammatory cytokine signaling that leads to the loss of Foxp3. CNS2 mediated stable inheritance of Foxp3 expression is critical for adequate suppression of diverse types of chronic inflammation by Treg cells and prevents their differentiation into inflammatory effector cells. The described mechanism may represent a general principle of the inheritance of differentiated cell states.
The transcription factor Foxp3 is indispensable for the ability of regulatory T (Treg) cells to suppress fatal inflammation. Here, we characterized the role of Foxp3 in chromatin remodeling and regulation of gene expression in actively suppressing Treg cells in an inflammatory setting. Although genome-wide Foxp3 occupancy of DNA regulatory elements was similar in resting and in vivo activated Treg cells, Foxp3-bound enhancers were poised for repression only in activated Treg cells. Following activation, Foxp3-bound sites showed reduced chromatin accessibility and selective H3K27 tri-methylation, which was associated with Ezh2 recruitment and downregulation of nearby gene expression. Thus, Foxp3 poises its targets for repression by facilitating formation of repressive chromatin in regulatory T cells upon their activation in response to inflammatory cues.
SUMMARY The Fat pathway controls both planar cell polarity (PCP) and organ growth [1, 2]. Fat signaling is regulated by the graded expression of the Fat ligand Dachsous (Ds), and the cadherin-domain kinase Four-jointed (Fj). The vectors of these gradients influence PCP [1], whereas their slope can influence growth [3, 4]. The Fj and Ds gradients direct the polarized membrane localization of the myosin Dachs, which is a crucial downstream component of Fat signaling [5–7]. Here we show that re-polarization of Dachs by differential expression of Fj or Ds can propagate through the wing disc, which indicates that Fj and Ds gradients can be measured over long range. Through characterization of tagged genomic constructs, we show that Ds and Fat are themselves partially polarized along the endogenous Fj and Ds gradients, providing a mechanism for propagation of PCP within the Fat pathway. We also identify a biochemical mechanism that might contribute to this polarization by showing that Ds is subject to endoproteolytic cleavage, and that the relative levels of Ds isoforms are modulated by Fat.
The Drosophila tumor suppressors fat and discs overgrown (dco) function within an intercellular signaling pathway that controls growth and polarity. fat encodes a transmembrane receptor, but post-translational regulation of Fat has not been described. We show here that Fat is subject to a constitutive proteolytic processing, such that most or all cell surface Fat comprises a heterodimer of stably associated N-and C-terminal fragments. The cytoplasmic domain of Fat is phosphorylated, and this phosphorylation is promoted by the Fat ligand Dachsous. dco encodes a kinase that influences Fat signaling, and Dco is able to promote the phosphorylation of the Fat intracellular domain in cultured cells and in vivo.
The conserved Drosophila tumor suppressors Fat and Expanded have both recently been implicated in regulating the activity of the Warts tumor suppressor. However, there has been disagreement as to the nature of the links among Fat, Expanded, and Warts and the significance of these links to growth control. We report here that mutations in either expanded or fat can be rescued to viability simply by overexpressing Warts, indicating that their essential function is their influence on Warts rather than reported effects on endocytosis or other pathways. These rescue experiments also separate the transcriptional from the planar cell polarity branches of Fat signaling and reveal that Expanded does not directly affect polarity. We also investigate the relationship between expanded and fat and show, contrary to prior reports, that they have additive effects on imaginal disk growth and development. Although mutation of fat can cause partial loss of Expanded protein from the membrane, mutation of fat promotes growth even when Expanded is overexpressed and accumulates at its normal subapical location. These observations argue against recent proposals that Fat acts simply as a receptor for the Hippo signaling pathway and instead support the proposal that Fat and Expanded can act in parallel to regulate Warts through distinct mechanisms.Drosophila ͉ Hippo ͉ protocadherin
SUMMARYT cell receptor (TCR) signaling plays a key role in T cell fate determination. Precursor cells expressing TCRs within a certain low affinity range for self peptide-MHC complexes undergo positive selection and differentiate into naïve T cells expressing a highly diverse self-MHC restricted TCR repertoire. In contrast, precursors displaying TCRs with a high affinity for “self” are either eliminated through TCR agonist induced apoptosis (negative selection)1 or restrained by regulatory CD4+ T (Treg) cells, whose differentiation and function are controlled by the X-chromosome encoded transcription factor Foxp3 (review2). Foxp3 is expressed in a fraction of self-reactive T cells that escape negative selection in response to agonist driven TCR signals combined with interleukin-2 (IL-2) receptor signaling. In addition to Treg cells, TCR agonist-driven selection results in the generation of several other specialized T cell lineages like NKT and MAIT cells3. Although the latter exhibit a restricted TCR repertoire, Treg cells display a highly diverse collection of TCRs4-6, Here we explored whether a specialized mechanism enables agonist driven selection of Treg cells with a diverse TCR repertoire and its significance for self-tolerance. We found that intronic Foxp3 enhancer CNS3 acts as an epigenetic switch that confers a poised state to the Foxp3 promoter in precursor cells to make Treg cell lineage commitment responsive to a broad range of TCR stimuli, particularly to suboptimal ones. CNS3-dependent expansion of the TCR repertoire enables Treg cells to effectively control self-reactive T cells, especially when thymic negative selection was genetically impaired. Our findings highlight the complementary roles of these two main mechanisms of self-tolerance.
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