Clonal specificity of human gamma delta T cells: V gamma 9+ T-cell clones frequently recognize Plasmodium falciparum merozoites, Mycobacterium tuberculosis, and group-A streptococci

Activation of Human Vδ2+ γδ T Cells by Staphylococcus aureus Promotes Enhanced Anti-Staphylococcal Adaptive Immunity

Murine studies have shown the potential for γδ T cells to mediate immunity to Staphylococcus aureus in multiple tissue settings by the secretion of diverse cytokines. However, the role played by γδ T cells in human immune responses to S. aureus is almost entirely unknown. In this study, we establish the capacity of human Vδ2+ γδ T cells for rapid activation in response to S. aureus In coculture with S. aureus-infected monocyte-derived dendritic cells (DCs), Vδ2+ cells derived from peripheral blood rapidly upregulate CD69 and secrete high levels of IFN-γ. DCs mediate this response through direct contact and IL-12 secretion. In turn, IFN-γ released by Vδ2+ cells upregulates IL-12 secretion by DCs in a positive feedback loop. Furthermore, coculture with γδ T cells results in heightened expression of the costimulatory molecule CD86 and the lymph node homing molecule CCR7 on S. aureus-infected DCs. In cocultures of CD4+ T cells with S. aureus-infected DCs, the addition of γδ T cells results in heightened CD4+ T cell activation. Our findings identify γδ T cells as potential key players in the early host response to S. aureus during bloodstream infection, promoting enhanced responses by both innate and adaptive immune cell populations, and support their consideration in the development of host-directed anti-S. aureus treatments.

Emerging role of γδ T cells in vaccine-mediated protection from infectious diseases

γδ T cells are fascinating cells that bridge the innate and adaptive immune systems. They have long been known to proliferate rapidly following infection; however, the identity of the specific γδ T cell subsets proliferating and the role of this expansion in protection from disease have only been explored more recently. Several recent studies have investigated γδ T‐cell responses to vaccines targeting infections such as Mycobacterium, Plasmodium and influenza, and studies in animal models have provided further insight into the association of these responses with improved clinical outcomes. In this review, we examine the evidence for a role for γδ T cells in vaccine‐induced protection against various bacterial, protozoan and viral infections. We further discuss results suggesting potential mechanisms for protection, including cytokine‐mediated direct and indirect killing of infected cells, and highlight remaining open questions in the field. Finally, building on current efforts to integrate strategies targeting γδ T cells into immunotherapies for cancer, we discuss potential approaches to improve vaccines for infectious diseases by inducing γδ T‐cell activation and cytotoxicity.

Streptococcus induces circulating CLA(+) memory T-cell-dependent epidermal cell activation in psoriasis

Streptococcal throat infection is associated with a specific variant of psoriasis and with HLA-Cw6 expression. In this study, activation of circulating psoriatic cutaneous lymphocyte-associated antigen (CLA)(+) memory T cells cultured together with epidermal cells occurred only when streptococcal throat extracts were added. This triggered the production of Th1, Th17, and Th22 cytokines, as well as epidermal cell mediators (CXCL8, CXCL9, CXCL10, and CXCL11). Streptococcal extracts (SEs) did not induce any activation with either CLA(-) cells or memory T cells cultured together with epidermal cells from healthy subjects. Intradermal injection of activated culture supernatants into mouse skin induced epidermal hyperplasia. SEs also induced activation when we used epidermal cells from nonlesional skin of psoriatic patients with CLA(+) memory T cells. Significant correlations were found between SE induced upregulation of mRNA expression for ifn-γ, il-17, il-22, ip-10, and serum level of antistreptolysin O in psoriatic patients. This study demonstrates the direct involvement of streptococcal infection in pathological mechanisms of psoriasis, such as IL-17 production and epidermal cell activation.

Vgamma2Vdelta2 T Cell Receptor recognition of prenyl pyrophosphates is dependent on all CDRs

gammadelta T cells differ from alphabeta T cells in the Ags they recognize and their functions in immunity. Although most alphabeta TCRs recognize peptides presented by MHC class I or II, human gammadelta T cells expressing Vgamma2Vdelta2 TCRs recognize nonpeptide prenyl pyrophosphates. To define the molecular basis for this recognition, the effect of mutations in the TCR CDR was assessed. Mutations in all CDR loops altered recognition and cover a large footprint. Unlike murine gammadelta TCR recognition of the MHC class Ib T22 protein, there was no CDR3delta motif required for recognition because only one residue is required. Instead, the length and sequence of CDR3gamma was key. Although a prenyl pyrophosphate-binding site was defined by Lys109 in Jgamma1.2 and Arg51 in CDR2delta, the area outlined by critical mutations is much larger. These results show that prenyl pyrophosphate recognition is primarily by germline-encoded regions of the gammadelta TCR, allowing a high proportion of Vgamma2Vdelta2 TCRs to respond. This underscores its parallels to innate immune receptors. Our results also provide strong evidence for the existence of an Ag-presenting molecule for prenyl pyrophosphates.

Identification of guinea pig gammadelta T cells and characterization during pulmonary tuberculosis

Guinea pigs are an alternative small animal model for many disease studies. Here we describe a pan-gammadelta monoclonal antibody (anti-TCRdelta1) specific for the constant region of human T cell receptor delta chains that cross-reacts with a subpopulation of guinea pig (Cavia porcellus) lymphocytes. The phenotype and distribution of this subpopulation is consistent with the guinea pig gammadelta T cell subset. FACS analysis of fresh PBMC and splenocytes from naïve guinea pigs revealed the presence of a subset of cells that stained with the anti-TCRdelta1 mAb. The relative percentage of anti-TCRdelta1 positive cells in PBMC and tissues is similar to that described for gammadelta T cells in other species. Immunohistochemistry of tissues also revealed a distribution of anti-TCRdelta1 positive cells consistent with gammadelta T cells. These data are further supported by staining of a polyclonal guinea pig T cell line that became progressively CD4 and CD8 negative in long-term culture. Analysis of PBMC from guinea pigs following aerosol infection with virulent Mycobacterium tuberculosis revealed no apparent changes in the steady-state percentage of blood gammadelta+ T cells. Taken together, these data suggest that the anti-TCRdelta1 antibody recognizes the gammadelta T cell subset in guinea pigs. This reagent may be useful for examining gammadelta T cells in various disease models where the guinea pig is a more desirable model for study.

Gamma delta T cells: their immunobiology and role in malaria infections

The status of research on gamma delta T cells is reviewed. Recent research shows that gamma delta T cells may see antigens in an immunoglobulin-like manner and that non-peptidic substance can be antigens for these cells. Considerable advances have been made in defining the immunobiology of gamma delta T cells, with evidence for sentinel, protective and immunoregulatory roles. Research on gamma delta T cells in malaria infections suggests that gamma delta T cells are mediators of protective immunity, most probably through the production of Th1 cytokines such as TNF alpha, TNF delta and IFN gamma and that excessive production of such cytokines may contribute to pathology. Our data on the features of the peripheral blood gamma delta T cells response in humans infected with Plasmodium falciparum show that there is considerable variation between individuals in the relative expansion of gamma delta T lymphocytes following primary or secondary infection. They confirm that activation of gamma delta T cells occurs during P. falciparum infection and that activated cells can persist for many weeks after treatment. The possibility that gamma delta T cells have an immunoregulatory function in malaria infections is proposed.

The response of gamma delta T cells to Plasmodium falciparum is dependent on activated CD4+ T cells and the recognition of MHC class I molecules

Peripheral blood gamma delta T cells from non-exposed individuals respond to antigens of the malaria parasite, Plasmodium falciparum, in vitro. This response, largely caused by T cells bearing the V gamma 9+ chain of the T-cell receptor, is stimulated by components of the parasite expressed on the schizont stage and released at schizont rupture. The response of V gamma 9+ T cells to parasite components is inhibited by antibodies to major histocompatibility complex (MHC) class I and class II. However, the inhibition by anti-MHC class II antibodies can be overcome by the addition of interleukin-2 (IL-2) to the cultures, suggesting that gamma delta T cells themselves do not recognize MHC class II molecules but require an MHC class II-dependent response taking place in the culture. In contrast, the inhibition by anti-class I antibodies cannot be reversed by addition of IL-2. Since an accompanying CD4+ T-cell response occurred in peripheral blood mononuclear cells cultured with P falciparum antigens, it was considered that these cells provide the cytokines necessary for the subsequent activation and expansion of V gamma 9+ T cells recognizing components of the parasite and MHC class I molecules. This was confirmed by reconstituting the response of enriched gamma delta T cells to P falciparum schizont extract by addition of purified CD4+ T cells.

Delayed expansion of V delta 2+ and V delta 1+ gamma delta T cells after acute Plasmodium falciparum and Plasmodium vivax malaria

T lymphocytes that express T-cell receptors encoded by the gamma and delta T-cell receptor genes (gamma delta T cells), and preferentially those expressing the V gamma 9 and V delta 2 gene segments, are activated by microbial and parasitic organisms in vitro and have been implicated in the pathogenesis of the fever and rigors during acute malaria. We have found, in a cohort of nine nonimmune patients who contracted malaria during travel to endemic areas (five with Plasmodium falciparum and four with P. vivax infections) that gamma delta T lymphocytes expanded to comprise 17.92% +/- 11% of the peripheral blood mononuclear cells (vs 3.08% +/- 2.4% gamma delta cells in normal control subjects). Although V delta 2+ cells predominated among the gamma delta subset, gamma delta lymphocytes expressing the V delta 1 gene segment also expanded significantly in some patients. Importantly, the gamma delta cells continued to expand for 2 months after the infection, and the mean level of gamma delta cells peaked during the second month after the acute clinical syndrome, when patients were free of symptoms. Thus although gamma delta T cells may contribute to the pathogenesis of the acute clinical syndrome, our findings suggest that gamma delta lymphocytes could also play a role in generating an immune response to plasmodia.

γδ T cells in malaria infections

The association of a pronounced gammadelta T-cell response with Plasmodium infections is intriguing. The ability of parasite material to activate gammadelta T cells in vitro, and the localization of these cells in vivo in the red pulp of the spleen, suggests that these cells could play a role in the killing of bloodstage malaria parasites. However, the magnitude, the response and the predominance of inflammatory cytokines secreted by these cells may also indicate a role in the pathology of malaria infections. In this article, Jean Langhorne reveiws the current status of gammadelta T cells in malaria in the context of what is known about the function and specificity of gammadelta T cells in general.

The antituberculous Mycobacterium bovis BCG vaccine is an attenuated mycobacterial producer of phosphorylated nonpeptidic antigens for human gamma delta T cells

The mycobacterial antigens stimulating human gamma delta T lymphocytes (R. L. Modlin, C. Permitz, F. M. Hofman, V. Torigian, K. Uemura, T. H. Rea, B. R. Bloom, and M. B. Brenner, Nature (London) 339:544-548, 1989; D. H. Raulet, Annu. Rev. Immunol. 7:175-207, 1989) have been characterized recently in Mycobacterium tuberculosis H37Rv as a group of four structurally related nucleotidic or phosphorylated molecules, termed TUBag1 to -4 (tuberculous antigens 1 to 4) (P. Constant, F. Davodeau, M. A. Peyrat, Y. Poquet, G. Puzo, M. Bonneville, and J. J. Fournie, Science 264:267-270, 1994). Here, we analyzed their distribution in different mycobacterial species of the M. tuberculosis group, with special emphasis on the human vaccine Mycobacterium bovis BCG. We show that the same four TUBag1 to -4 molecules are shared by these mycobacteria. Quantitative comparison reveals, however, that while the pathogen M. bovis and M. tuberculosis species produce rather high amounts of TUBag, all of the BCG strains have a surprisingly reduced production of TUBag. These observations suggest that among tuberculous mycobacteria, the bacterial TUBag load could, to some extent, constitute an immunological determinant of mycobacterial virulence for humans.

Human T-cell responses to blood stage antigens in Plasmodium falciparum malaria

Immunity to malaria involves both cell-mediated and humoral immune mechanisms. T cells are essential both in regulating antibody formation and in inducing antibody-independent immunity. Thus, acquisition and maintenance of protective immunity to malaria is T-cell dependent. Although relatively neglected until recently basic knowledge of T-cell subsets and cytokine production determining the course of a malaria infection is advancing rapidly at present. In this paper we will review recent findings contributing to the understanding of immune mechanisms against the asexual blood stages of human P. falciparum malaria.

V gamma gene usage in peripheral blood gamma delta T cells

The majority (50-90%) of gamma delta T cells in the peripheral blood of adult individuals expresses a T-cell receptor (TCR) which uses V gamma 9 and V delta 2 as variable elements. Little is known about the distribution of other V gamma gene elements in the remaining 10-50% of gamma delta T cells. Here we have studied the V gamma gene expression in peripheral blood gamma delta T cells by 3-color flow cytometry analysis applying established monoclonal antibodies (mAb) directed against V gamma 9 and V gamma 4, as well as a novel mAb directed against V gamma 2, V gamma 3 and V gamma 4. On average, 79.9% of gamma delta T cells expressed V gamma 9, 11.9% V gamma 2/V gamma 3, 4.4% V gamma 4, and 7.5% one of the remaining V gamma 5, V gamma 8, V gamma 10 or V gamma 11 elements. There were remarkable variations in the gamma delta subset composition between individual donors. The majority (69.8%) of V gamma 2/V gamma 3/V gamma 4-bearing cells co-expressed V delta 1, while on average only 17.8% of V gamma 2/V gamma 3/V gamma 4-bearing cells co-expressed V delta 2. This is in contrast to V gamma 9-bearing gamma delta T cells, of which 83.1% used V delta 2 and only 12.7% V delta 1. Taken together, this data identifies V gamma 2/V gamma 3 as the second most frequently used set of V gamma elements in human peripheral blood gamma delta T cells.