Th17 cell plasticity towards a T-bet-dependent Th1 phenotype is required for bacterial control in Staphylococcus aureus infection

Staphylococcus aureus is frequently detected in patients with sepsis and thus represents a major health burden worldwide. CD4⁺ T helper cells are involved in the immune response to S. aureus by supporting antibody production and phagocytosis. In particular, Th1 and Th17 cells secreting IFN-γ and IL-17A, are involved in the control of systemic S. aureus infections in humans and mice.To investigate the role of T cells in severe S. aureus infections, we established a mouse sepsis model in which the kidney was identified to be the organ with the highest bacterial load and abundance of Th17 cells. In this model, IL-17A but not IFN-γ was required for bacterial control. Using Il17aCre × R26YFP mice we could show that Th17 fate cells produce Th17 and Th1 cytokines, indicating a high degree of Th17 cell plasticity. Single cell RNA-sequencing of renal Th17 fate cells uncovered their heterogeneity and identified a cluster with a Th1 expression profile within the Th17 cell population, which was absent in mice with T-bet/Tbx21-deficiency in Th17 cells (Il17aCre x R26eYFP x Tbx21-flox). Blocking Th17 to Th1 transdifferentiation in Th17 fate cells in these mice resulted in increased S. aureus tissue loads.In summary, we highlight the impact of Th17 cells in controlling systemic S. aureus infections and show that T-bet expression by Th17 cells is required for bacterial clearance. While targeting the Th17 cell immune response is an important therapeutic option in autoimmunity, silencing Th17 cells might have detrimental effects in bacterial infections.     

A regulatory role for IL-10 receptor signaling in development and B cell help of T follicular helper cells in mice

IL -10 is widely accepted as a survival, proliferation, and differentiation factor for B cells. However, IL-10 deficiency accelerates disease progression as the result of autoantibody production in many autoimmune disease models. It was demonstrated that T follicular helper cells (T(FH) cells) play a key role in helping B cells that are secreting Abs. In this study, we demonstrated a regulatory role for IL-10R signaling on the development and B cell help function of T(FH) cells in vitro and in vivo. IL-1R subunit β-deficient (Il10rb(-/-)) Th cells were able to differentiate more readily into T(FH) cells, as well as secrete more IL-21 and IL-17 compared with wild-type Th cell-derived T(FH) cells. Increased IL-21 and IL-17 contributed to the enhanced B cell help functions of T(FH) cells. Further experiments demonstrated that IL-6 and IL-23 from dendritic cells in Il10rb(-/-) mice contributed to the differentiation of naive Th cells into T(FH) cells, as well as the generation of IL-21- and IL-17-producing T(FH) cells. Our results provide useful information for clarifying the immunoregulatory mechanisms associated with IL-10 deficiency in certain autoimmune disease models. This information could also be of benefit for the development of vaccines.     

STAT1-activating cytokines limit Th17 responses through both T-bet-dependent and -independent mechanisms

Given the association with autoimmune disease, there is great interest in defining cellular factors that limit overactive or misdirected Th17-type inflammation. Using in vivo and in vitro models, we investigated the molecular mechanisms for cytokine-mediated inhibition of Th17 responses, focusing on the role of STAT1 and T-bet in this process. These studies demonstrate that, during systemic inflammation, STAT1- and T-bet-deficient T cells each exhibit a hyper-Th17 phenotype relative to wild-type controls. However, IL-17 production was greater in the absence of T-bet, and when both STAT1 and T-bet were deleted, there was no further increase, with the double-deficient cells instead behaving more like STAT1-deficient counterparts. Similar trends were observed during in vitro priming, with production of Th17-type cytokines greater in T-bet(-/-) T cells than in either STAT1(-/-) or STAT1(-/-) T-bet(-/-) counterparts. The ability of IFN-γ and IL-27 to suppress Th17 responses was reduced in T-bet-deficient cells, and most importantly, ectopic T-bet could suppress signature Th17 gene products, including IL-17A, IL-17F, IL-22, and retinoic acid-related orphan receptor γT, even in STAT1-deficient T cells. Taken together, these studies formally establish that, downstream of IFN-γ, IL-27, and likely all STAT1-activating cytokines, there are both STAT1 and T-bet-dependent pathways capable of suppressing Th17 responses.     

Ikaros Sets the Potential for Th17 Lineage Gene Expression through Effects on Chromatin State in Early T Cell Development

Th17 cells are important effectors of immunity to extracellular pathogens, particularly at mucosal surfaces, but they can also contribute to pathologic tissue inflammation and autoimmunity. Defining the multitude of factors that influence their development is therefore of paramount importance. Our previous studies using Ikaros^−/− CD4+ T cells implicated Ikaros in Th1 versus Th2 lineage decisions. Here we demonstrate that Ikaros also regulates Th17 differentiation through its ability to promote expression of multiple Th17 lineage-determining genes, including Ahr, Runx1, Rorc, Il17a, and Il22. Ikaros exerts its influence on the chromatin remodeling of these loci at two distinct stages in CD4+ T helper cell development. In naive cells, Ikaros is required to limit repressive chromatin modifications at these gene loci, thus maintaining the potential for expression of the Th17 gene program. Subsequently, Ikaros is essential for the acquisition of permissive histone marks in response to Th17 polarizing signals. Additionally, Ikaros represses the expression of genes that limit Th17 development, including Foxp3 and Tbx21. These data define new targets of the action of Ikaros and indicate that Ikaros plays a critical role in CD4+ T cell differentiation by integrating specific cytokine cues and directing epigenetic modifications that facilitate activation or repression of relevant genes that drive T cell lineage choice.     

Differential histone H3 Lys-9 and Lys-27 methylation profiles on the X chromosome

Histone H3 tail modifications are among the earliest chromatin changes in the X-chromosome inactivation process. In this study we investigated the relative profiles of two important repressive marks on the X chromosome: methylation of H3 lysine 9 (K9) and 27 (K27). We found that both H3K9 dimethylation and K27 trimethylation characterize the inactive X in somatic cells and that their relative kinetics of enrichment on the X chromosome as it undergoes inactivation are similar. However, dynamic changes of H3K9 and H3K27 methylation on the inactivating X chromosome compared to the rest of the genome are distinct, suggesting that these two modifications play complementary and perhaps nonredundant roles in the establishment and/or maintenance of X inactivation. Furthermore, we show that a hotspot of H3K9 dimethylation 5' to Xist also displays high levels of H3 tri-meK27. However, analysis of this region in G9a mutant embryonic stem cells shows that these two methyl marks are dependent on different histone methyltransferases.     

Whole-genome analysis of histone H3 lysine 4 and lysine 27 methylation in human embryonic stem cells

We mapped Polycomb-associated H3K27 trimethylation (H3K27me3) and Trithorax-associated H3K4 trimethylation (H3K4me3) across the whole genome in human embryonic stem (ES) cells. The vast majority of H3K27me3 colocalized on genes modified with H3K4me3. These commodified genes displayed low expression levels and were enriched in developmental function. Another significant set of genes lacked both modifications and was also expressed at low levels in ES cells but was enriched for gene function in physiological responses rather than development. Commodified genes could change expression levels rapidly during differentiation, but so could a substantial number of genes in other modification categories. SOX2, POU5F1, and NANOG, pluripotency-associated genes, shifted from modification by H3K4me3 alone to colocalization of both modifications as they were repressed during differentiation. Our results demonstrate that H3K27me3 modifications change during early differentiation, both relieving existing repressive domains and imparting new ones, and that colocalization with H3K4me3 is not restricted to pluripotent cells.     

Distinct localization of histone H3 methylation in the vegetative nucleus of lily pollen

We analysed the distribution of histone H3 modifications in the nucleus of the vegetative cell (the vegetative nucleus) during pollen development in lily (Lilium longiflorum). Among the modifications specifically and/or abundantly present in the vegetative nucleus, dimethylation of histone H3 at lysine 9 (H3K9me2) and lysine 27 (H3K27me2) were found in heterochromatin, whereas trimethylation of histone H3 at lysine 27 (H3K27me3) was localized in euchromatin in the vegetative nucleus. Such unique localization of the histone H3 methylation marks, particularly of H3K27me3, within a nucleus was not observed in lily nuclei other than the vegetative nucleus. The level of H3K27me3 increased in the euchromatic region of the vegetative nucleus during pollen maturation. The results suggest that H3K27me3 controls the gene expression of the vegetative cell during pollen maturation.     

Chromatin signatures of pluripotent cell lines

Epigenetic genome modifications are thought to be important for specifying the lineage and developmental stage of cells within a multicellular organism. Here, we show that the epigenetic profile of pluripotent embryonic stem cells (ES) is distinct from that of embryonic carcinoma cells, haematopoietic stem cells (HSC) and their differentiated progeny. Silent, lineage-specific genes replicated earlier in pluripotent cells than in tissue-specific stem cells or differentiated cells and had unexpectedly high levels of acetylated H3K9 and methylated H3K4. Unusually, in ES cells these markers of open chromatin were also combined with H3K27 trimethylation at some non-expressed genes. Thus, pluripotency of ES cells is characterized by a specific epigenetic profile where lineage-specific genes may be accessible but, if so, carry repressive H3K27 trimethylation modifications. H3K27 methylation is functionally important for preventing expression of these genes in ES cells as premature expression occurs in embryonic ectoderm development (Eed)-deficient ES cells. Our data suggest that lineage-specific genes are primed for expression in ES cells but are held in check by opposing chromatin modifications.