Long-Term Programming of CD8 T Cell Immunity by Perinatal Exposure to Glucocorticoids.

Early life environmental exposure, particularly during perinatal period, can have a life-long impact on organismal development and physiology. The biological rationale for this phenomenon is to promote physiological adaptations to the anticipated environment based on early life experience. However, perinatal exposure to adverse environments can also be associated with adult-onset disorders. Multiple environmental stressors induce glucocorticoids, which prompted us to investigate their role in developmental programming. Here, we report that perinatal glucocorticoid exposure had long-term consequences and resulted in diminished CD8 T cell response in adulthood and impaired control of tumor growth and bacterial infection. We found that perinatal glucocorticoid exposure resulted in persistent alteration of the hypothalamic-pituitary-adrenal (HPA) axis. Consequently, the level of the hormone in adults was significantly reduced, resulting in decreased CD8 T cell function. Our study thus demonstrates that perinatal stress can have long-term consequences on CD8 T cell immunity by altering HPA axis activity.

Intranuclear delivery of the transcription modulation domain of Tbet-improved lupus nephritis in (NZB/NZW) F1 lupus-prone mice.

Excessive expression of Tbet and IFNγ is evidence of systemic lupus erythematosus (SLE) in lupus patients. In this study, the nucleus-transducible form of Transcription Modulation Domain (TMD) of Tbet (ntTbet-TMD), which is a fusion protein between Protein Transduction Domain Hph-1 (Hph-1-PTD) and the TMD of Tbet comprising DNA binding domain and isotype-specific domain, was generated to inhibit Tbet-mediated transcription in the interactomic manner. ntTbet-TMD was effectively delivered into the nucleus of the cells and specifically inhibited Tbet-mediated transcription without influencing the differentiation of other T cell subsets and signaling events for T cell activation. The severity of nephritis was significantly reduced by ntTbet-TMD as effectively as methylprednisolone in lupus-prone mice. The number of Th1, Th2 or Th17 cells and the secretion of their cytokines substantially decreased in the spleen and kidney of lupus-prone mice by ntTbet-TMD treatment. In contrast to methylprednisolone, the marked increase of Treg cells and the secretion of their immunosuppressive cytokine were detected in the spleen of (NZB/NZW) F1 mice treated with ntTbet-TMD. Thus, ntTbet-TMD can improve nephritis in lupus-prone mice by modulating the overall proinflammatory microenvironment and rebalancing T cell subsets, leading to new immune therapeutics for Th1-mediated autoimmune diseases.

RORγt-specific transcriptional interactomic inhibition suppresses autoimmunity associated with TH17 cells.

The nuclear hormone receptor retinoic acid-related orphan receptor gamma t (RORγt) is a transcription factor (TF) specific to TH17 cells that produce interleukin (IL)-17 and have been implicated in a wide range of autoimmunity. Here, we developed a novel therapeutic strategy to modulate the functions of RORγt using cell-transducible form of transcription modulation domain of RORγt (tRORγt-TMD), which can be delivered effectively into the nucleus of cells and into the central nerve system (CNS). tRORγt-TMD specifically inhibited TH17-related cytokines induced by RORγt, thereby suppressing the differentiation of naïve T cells into TH17, but not into TH1, TH2, or Treg cells. tRORγt-TMD injected into experimental autoimmune encephalomyelitis (EAE) animal model can be delivered effectively in the splenic CD4(+) T cells and spinal cord-infiltrating CD4(+) T cells, and suppress the functions of TH17 cells. The clinical severity and incidence of EAE were ameliorated by tRORγt-TMD in preventive and therapeutic manner, and significant reduction of both infiltrating CD4(+) IL-17(+) T cells and inflammatory cells into the CNS was observed. As a result, the number of spinal cord demyelination was also reduced after tRORγt-TMD treatment. With the same proof of concept, tTbet-TMD specifically blocking TH1 differentiation improved the clinical incidence of rheumatoid arthritis (RA). Therefore, tRORγt-TMD and tTbet-TMD can be novel therapeutic reagents with the natural specificity for the treatment of inflammatory diseases associated with TH17 or TH1. This strategy can be applied to treat various diseases where a specific transcription factor has a key role in pathogenesis.

Intranuclear interactomic inhibition of FoxP3 suppresses functions of Treg cells.

Regulatory T cells (Treg cells) are crucial for the maintenance of immunological tolerance, and it has been reported that Treg cells are enriched within the tumor micro-environment for immune evasion due to their immunosuppressive functions. To inhibit Treg cells functions, FoxP3, a lineage-specific transcription factor responsible for the differentiation and functions of Treg cells, was functionally targeted by a nucleus-transducible (nt) form of various FoxP3 functional subdomains. These nt modified domains can be delivered into the nucleus effectively and work as interactomic inhibitors via disruption of the endogenous FoxP3-mediated transcription complex. Among these domains, nt-FoxP3-FKH (Forkhead DNA binding domain) is most effective at restoring NFAT activity suppressed by FoxP3, and inhibiting the binding of endogenous FKH-containing proteins to FKH DNA binding sequences without influencing the viability and activation of T cells. The suppressive functions of TGF-ß-induced iTreg cells and thymus-derived tTreg cells were substantially blocked by nt-FoxP3-FKH, accompanied with down-regulation of CTLA-4 surface expression and IL-10 secretion of Treg cells. In addition, nt-FoxP3-FKH upregulated the expression of IL-2 and IFN-γ in Treg cells. Therefore, nt-FoxP3-FKH has the potential to be a novel therapeutic agent to modulate the immune-evasive tumor environment created by Treg cells without the need for genetic modifications.