Human eosinophils release IL-1ß and increase expression of IL-17A in activated CD4+ T lymphocytes.

BACKGROUND: Differentiation and activation of CD4(+) T cells is controlled by various cytokines produced by innate immune cells. We have shown that eosinophils (EOS) have the potential to influence Th1 and Th2 cytokine generation by CD4(+) cells, but their influence on IL-17A (IL-17) has not been established. OBJECTIVE: The purpose of this study is to determine the effect of EOS on IL-17 production by lymphocytes. METHODS: Pre-activated CD4(+) T cells were cultured in the presence of either autologous EOS or EOS culture supernatants. Expression of IL-17 was determined by real-time quantitative PCR (qPCR) after 5 h and protein level was measured after 48 h. To determine the effect of allergen-induced airway EOS on IL-17, subjects with mild allergic asthma underwent bronchoscopic segmental bronchoprovocation with allergen (SBP-Ag) after a treatment with an anti-IL-5 neutralizing antibody (mepolizumab) to reduce airway eosinophilia. IL-17 mRNA was measured in bronchoalveolar lavage (BAL) cells by qPCR. RESULTS: In vitro, EOS significantly increased IL-17 production by CD4(+) T cells. Addition of exogenous IL-1ß increased expression of IL-17 mRNA by CD4(+) T cells. EOS expressed and released IL-1ß. Furthermore, levels of IL-1ß in EOS supernatants highly correlated with their ability to increase IL-17 expression by CD4(+) T cells, and neutralizing antibody to IL-1ß reduced expression of IL-17 mRNA. In vivo, reduction of EOS in the airway using mepolizumab was associated with diminished IL-17 expression after SBP-Ag. CONCLUSIONS AND CLINICAL RELEVANCE: Our data demonstrate that EOS can promote IL-17 production through the release of IL-1ß. Enhanced IL-17 cytokine production is another mechanism by which EOS may participate in pathogenesis of allergic airway inflammation in asthma.

Recurrent superantigen exposure in vivo leads to highly suppressive CD4+CD25+ and CD4+CD25- T cells with anergic and suppressive genetic signatures.

Staphylococcal enterotoxin B (SEB) activates T cells via non-canonical signalling through the T cell receptor and is an established model for T cell unresponsiveness in vivo. In this study, we sought to characterize the suppressive qualities of SEB-exposed CD4(+) T cells and correlate this with genetic signatures of anergy and suppression. SEB-exposed CD25(+) and CD25(-)Vbeta8(+)CD4(+) T cells expressed forkhead box P3 (FoxP3) at levels comparable to naive CD25(+) T regulatory cells and were enriched after exposure in vivo. Gene related to anergy in lymphocytes (GRAIL), an anergy-related E3 ubiquitin ligase, was up-regulated in the SEB-exposed CD25(+) and CD25(-)FoxP3(+)Vbeta8(+)CD4(+) T cells and FoxP3(-)CD25(-)Vbeta8(+)CD4(+) T cells, suggesting that GRAIL may be important for dominant and recessive tolerance. The SEB-exposed FoxP3(+)GRAIL(+) T cells were highly suppressive and non-proliferative independent of CD25 expression level and via a glucocorticoid-induced tumour necrosis factor R-related protein-independent mechanism, whereas naive T regulatory cells were non-suppressive and partially proliferative with SEB activation in vitro. Lastly, adoptive transfer of conventional T cells revealed that induction of FoxP3(+) regulatory cells is not operational in this model system. These data provide a novel paradigm for chronic non-canonical T cell receptor engagement leading to highly suppressive FoxP3(+)GRAIL(+)CD4(+) T cells.

Antigen-specific T cell-mediated gene therapy in collagen-induced arthritis.

Autoantigen-specific T cells have tissue-specific homing properties, suggesting that these cells may be ideal vehicles for the local delivery of immunoregulatory molecules. We tested this hypothesis by using type II collagen-specific (CII-specific) CD4(+) T hybridomas or primary CD4(+) T cells after gene transfer, as vehicles to deliver an immunoregulatory protein for the treatment of collagen-induced arthritis (CIA), a mouse model of rheumatoid arthritis (RA). CII-specific T cells or hybridomas were transduced using retroviral vectors to constitutively express the IL-12 antagonist, IL-12 p40. Transfer of engineered CD4(+) T cells after immunization significantly inhibited the development of CIA, while cells transduced with vector control had no effect. The beneficial effect on CIA of IL-12 p40-transduced T cells required TCR specificity against CII, since transfer of T cells specific for another antigen producing equivalent amounts of IL-12 p40 had no effect. In vivo cell detection using bioluminescent labels and RT-PCR showed that transferred CII-reactive T-cell hybridomas accumulated in inflamed joints in mice with CIA. These results indicate that the local delivery of IL-12 p40 by T cells inhibited CIA by suppressing autoimmune responses at the site of inflammation. Modifying antigen-specific T cells by retroviral transduction for local expression of immunoregulatory proteins thus offers a promising strategy for treating RA.

A gene therapy approach to treatment of autoimmune disease.

New insights into the underlying mechanisms for the development of autoimmune diseases in humans and various animal models continue to increase with our understanding of factors that drive polarization of T helper (Th) responses and tolerance. This information has led to the development of new treatment strategies, including oral tolerance clinical trails and the use of altered peptide ligands in animal models. These approaches have shown some promise and provided additional insight into the disease processes. The use of gene therapy in many disease states continues to increase. We are starting to see the application of gene therapy in chronic diseases in humans. Gene therapy has been used in several animal models of autoimmune disease with promising preliminary results. In this article, an overview will be provided for the use of gene therapy in autoimmune disease.

An optimized multi-parameter flow cytometry protocol for human T regulatory cell analysis on fresh and viably frozen cells, correlation with epigenetic analysis, and comparison of cord and adult blood.

Multi-parameter flow cytometry analysis of T regulatory (Treg) cells is a widely used approach in basic and translational research studies. This approach has been complicated by a lack of specific markers for Treg cells and lack of uniformity in the quantification of Treg cells. Given the central role of Treg cells in the inception and perpetuation of diverse immune responses as well as its target as a therapeutic, it is imperative to have established methodologies for Treg cell analysis that are robust and usable for studies with multiple subjects as well as multicenter studies. In this study, we describe an optimized multi-parameter flow cytometry protocol for the quantification of human Treg cells from freshly obtained and viably frozen samples and correlations with epigenetic Treg cell analysis (TSDR demethylation). We apply these two methodologies to characterize Treg cell differences between cord blood and adult peripheral blood. In summary, the optimized protocol appears to be robust for Treg cell quantification from freshly isolated or viably frozen cells and the multi-parameter flow cytometry findings are strongly positively correlated with TSDR demethylation thus providing several options for the characterization of Treg cell frequency and function in large translational or clinical studies.

Preservation of self: an overview of E3 ubiquitin ligases and T cell tolerance.

Until recently ubiquitination of a protein was thought to simply serve the mundane task of targeting a protein for proteasomal degradation. Accumulating evidence over the past decade has demonstrated the importance of ubiquitination in non-degradative functions including regulating cellular signaling, that highlight its role in human disease and thus potential development of novel therapeutics. Much has been written about ubiquitination in the immune system, in this review we will outline our current knowledge of ubiquitination with respect to T cell tolerance. Specifically, we will provide on overview of E3 ubiquitin ligases and their role in various states of CD4+ T cell tolerance: central and peripheral.

Daily subcutaneous injections of peptide induce CD4+ CD25+ T regulatory cells.

Peptide immunotherapy is being explored to modulate varied disease states; however, the mechanism of action remains poorly understood. In this study, we investigated the ability of a subcutaneous peptide immunization schedule to induce of CD4(+) CD25(+) T regulatory cells. DO11.10 T cell receptor (TCR) transgenic mice on a Rag 2(-/-) background were injected subcutaneously with varied doses of purified ovalbumin (OVA(323-339)) peptide daily for 16 days. While these mice have no CD4(+) CD25(+) T regulatory cells, following this injection schedule up to 30% of the CD4(+) cells were found to express CD25. Real-time quantitative polymerase chain reaction (QPCR) analysis of the induced CD4(+) CD25(+) T cells revealed increased expression of forkhead box P3 (FoxP3), suggesting that these cells may have a regulatory function. Proliferation and suppression assays in vitro utilizing the induced CD4(+) CD25(+) T cells revealed a profound anergic phenotype in addition to potent suppressive capability. Importantly, co-injection of the induced CD4(+) CD25(+) T cells with 5,6-carboxy-succinimidyl-fluorescence-ester (CFSE)-labelled naive CD4(+) T cells (responder cells) into BALB/c recipient mice reduced proliferation and differentiation of the responder cells in response to challenge with OVA(323-339) peptide plus adjuvant. We conclude that repeated subcutaneous exposure to low-dose peptide leads to de novo induction of CD4(+) CD25(+) FoxP3(+) T regulatory cells with potent in vitro and in vivo suppressive capability, thereby suggesting that one mechanism of peptide immunotherapy appears to be induction of CD4(+) CD25(+) Foxp3(+) T regulatory cells.

The application of gene therapy in autoimmune diseases.

The application of gene therapy in autoimmune disease represents a novel use of this technology. The goal of gene therapy in the treatment of autoimmune disease is to restore 'immune homeostasis' by countering the pro-inflammatory effects of the CD4+ T cells in the lesions of autoimmunity. This can be accomplished by adoptive therapy with transduced T cells which can specifically home to the site of inflammation and secrete 'regulatory' protein(s) to ameliorate the inflammation or by direct targeting of the retroviral vector to activated T cells in the sites of inflammation. Transduction of autoantigen recognizing CD4+ T cells, to secrete anti-inflammatory products, may become the 'magic bullet' to combat the ravages of autoimmune inflammation and tissue destruction. Gene Therapy (2000) 7, 9-13.

Gene therapy for autoimmune disease.

Autoantigen-specific CD4(+) T lymphocytes have been implicated in the pathogenesis of autoimmune diseases. Tissue-specific homing properties of autoantigen-specific CD4(+) T cells suggested that these cells might be ideal vehicles for delivery of retroviral-encoded regulatory proteins in a site-specific manner as a therapy for autoimmune diseases. Application of retroviral transduction of autoantigen-reactive CD4(+) T cells in gene therapy of autoimmunity must include systems capable of targeting these rare populations of antigen-activated T cells. Studies discussed below suggest that retroviral transduction of autoantigen-specific murine CD4(+) T cells may provide a method to target and isolate nontransformed autoantigen-specific murine CD4(+) T cells and provide a rational approach to gene therapy in animal models of autoimmunity.

Targeting rare populations of murine antigen-specific T lymphocytes by retroviral transduction for potential application in gene therapy for autoimmune disease.

CD4+ T cells are important mediators in the pathogenesis of autoimmunity and would therefore provide ideal candidates for lymphocyte-based gene therapy. However, the number of Ag-specific T cells in any single lesion of autoimmunity may be quite low. Successful gene transfer into autoantigen-specific CD4+ T cells would serve as an ideal vehicle for site-targeted gene therapy if it were possible to transduce preferentially the small number of autoantigen-specific T cells. In this study we have demonstrated that retroviral infection of CD4+ lymphocytes from either autoantigen-stimulated TCR transgenic mice, or Ag-activated immunized nontransgenic mice, with a retroviral vector (pGCIRES), resulted in the transduction of only the limited number of Ag-reactive CD4+ T cells. In contrast, polyclonal activation of the same cultures resulted in transduction of non-antigen-specific lymphocytes. Transduction of Ag-reactive CD4+ T cells with pGCIRES retrovirus encoding the regulatory genes IL-4 (IL4) and soluble TNF receptor (STNFR) resulted in stable integration and long-term expression of recombinant gene products. Moreover, expression of the pGCIRES marker protein, GFP, directly correlated with the expression of the upstream regulatory gene. Retroviral transduction of CD4+ T cells targeted specifically Ag-reactive cells and was cell cycle-dependent and evident only during the mitosis phase. These studies suggest that retroviral transduction of autoantigen-specific murine CD4+ T cells, using the pGCIRES retroviral vector, may provide a potential method to target and isolate the low frequency of autoantigen-specific murine CD4+ T cells, and provides a rational approach to gene therapy in animal models of autoimmunity.

Cytokine profile of a long-term pediatric HIV survivor with hyper-IgE syndrome and a normal CD4 T-cell count.

BACKGROUND: An elevated IgE level and increased production of T(H2) cytokines are factors associated with poor prognosis in HIV infection. We report a pediatric long-term survivor of vertically acquired HIV infection with a normal CD4 count and a low viral burden despite the lack of antiretroviral therapy and a phenotype resembling hyper-IgE syndrome. OBJECTIVE: We sought to characterize the patient's T(H1) versus T(H2) cytokine profile and anti-HIV-specific immune responses. METHODS: Supernatants collected from cultures of peripheral blood T cells stimulated with phorbol myristate acetate plus ionomycin were assayed for T(H1) and T(H2) cytokines by means of ELISA. Specific IgE antibodies were determined by immunoblot. HIV-specific cytotoxic T-lymphocyte responses were measured from cell lysis by fresh T cells of autologous B-lymphoblastoid cells expressing recombinant HIV proteins. RESULTS: Patient CD4(+) T cells secreted significantly more T(H2) cytokines, IL-4 (P <.003) and IL-5 (P <.03), than HIV-infected and seronegative control cells. No difference was noted in T(H1) cytokine production. IgE specific for HIV gp160, p24, p17, and p66 proteins and Aspergillus fumigatus was detected in patient sera. Despite predominance of T(H2) cytokines, HIV-specific cytotoxic T-lymphocyte activity was vigorous. CONCLUSIONS: The patient demonstrated predominantly T(H2) cytokine production in vitro. Unlike other patients with HIV who have hyper-IgE and increased T(H2) cytokine production, our patient has maintained HIV-specific immune responses, a low viral load, and a normal CD4 count without antiretroviral therapy. These findings support a diagnosis of primary hyper-IgE syndrome. Presence of anti-HIV-specific IgE may represent a protective mechanism against HIV replication in our patient.