High efficiency ex vivo cloning of antigen-specific human effector T cells.

While cloned T cells are valuable tools for the exploration of immune responses against viruses and tumours, current cloning methods do not allow inferences to be made about the function and phenotype of a clone's in vivo precursor, nor can precise cloning efficiencies be calculated. Additionally, there is currently no general method for cloning antigen-specific effector T cells directly from peripheral blood mononuclear cells, without the need for prior expansion in vitro. Here we describe an efficient method for cloning effector T cells ex vivo. Functional T cells are detected using optimised interferon gamma capture following stimulation with viral or tumour cell-derived antigen. In combination with multiple phenotypic markers, single effector T cells are sorted using a flow cytometer directly into multi-well plates, and cloned using standard, non antigen-specific expansion methods. We provide examples of this novel technology to generate antigen-reactive clones from healthy donors using Epstein-Barr virus and cytomegalovirus as representative viral antigen sources, and from two melanoma patients using autologous melanoma cells. Cloning efficiency, clonality, and retention/loss of function are described. Ex vivo effector cell cloning provides a rapid and effective method of deriving antigen-specific T cells clones with traceable in vivo precursor function and phenotype.

Dendritic cell immunotherapy for stage IV melanoma.

Active boosting of the antitumour immune response of patients with solid malignancies has been tested in a large number of trials. Isolated complete clinical responses have been reported, however, they have not been replicated in subsequent studies. We recently reported objective clinical responses to a dendritic cell/irradiated autologous tumour cell 'vaccine' in patients with distant metastatic (stage IV) melanoma. Here we describe our experience in a second cohort of patients with stage IV melanoma, using this dendritic cell-based immunotherapy in a cryopreserved format. Of 46 patients enrolled into the study, three had complete remission of all detectable disease, and a further three had partial clinical responses. These data confirm that dendritic cell-based immunotherapy has potential as a therapy in a limited number of patients with stage IV melanoma. To our knowledge, this is the first demonstration that cryopreserved dendritic cells can elicit complete clinical responses in patients with advanced cancer. Our observations support randomized controlled trials to validate the findings.

Immunological characteristics correlating with clinical response to immunotherapy in patients with advanced metastatic melanoma.

Current treatment options for advanced metastatic melanoma are limited to experimental regimen that provide poor survival outcomes. Immunotherapy is a promising alternative and we recently reported a clinical trial in which 6 out of 19 patients enrolled had objective clinical responses to a fully autologous melanoma/dendritic cell vaccine. The mechanism of the vaccine is not well understood, but we hypothesized that general immunocompetence may be a determinant of clinical response. We therefore examined the immune status of an expanded series of 21 patients who displayed varying clinical responses to the melanoma/dendritic cell vaccine. Immunocompetence was assessed using in vitro assays of lymphocyte function: survival, proliferation and cytokine responses to mitogen stimulation as well as T-cell receptor zeta expression and lymphocyte subset analysis. Although lymphocytes from patients mostly performed comparably to age-matched and sex-matched controls, in some assays we identified significant differences between complete clinical responders and other patients, both before and following vaccination. Surprisingly, before vaccination, only lymphocytes from clinical responder patients showed impaired in vitro survival. Following vaccination, T lymphocyte survival improved and cells recovered their ability to produce the Th1-associated cytokines TNF and IFN-gamma in response to anti-CD3 stimulation in vitro. No increase in Th1 cytokine production was observed in lymphocytes from patients who experienced partial clinical responses or progressive disease. We conclude that, before vaccination, patients who go on to have complete responses have immune characteristics suggestive of high cell turnover and low Th1-associated cytokine production, and that these can be reversed with vaccination. These results have potential implications for future immunotherapeutic strategies.

(Pro)insulin-specific regulatory T cells.

Regulatory anti-diabetogenic T cells (T(reg)) can be induced by the mucosal administration of insulin or proinsulin peptides, in the non-obese diabetic (NOD) mouse model of autoimmune type 1 diabetes. Naso-respirtory insulin (which avoids insulin degradation) induces CD8+ alpha(alpha) TCR gamma(delta) T(reg) whereas peptides that bind to the NOD MHC class II molecule, I-Ag7, insulin B9-23 and proinsulin B24-C36, induce CD4+ T(regs) Following naso-respiratory delivery of insulin to NOD mice increased numbers of CD8+ gamma(delta) T cells expressing interleukin (IL)10 are detected in the pancreatic lymph nodes. Neonatal (3 day) thymectomy (NTX) dramatically accelerates diabetes development in NOD mice, associated with lymphopaenia and a block in the maturation of mucosal intrepithelial lymphocytes (IEL), especially extrathymic-derived CD8+ alpha(alpha) TCR gamma(delta) IEL. Regulatory anti-diabetogenic T cells cannot be elicited by naso-respiratory insulin in NTX-NOD mice. Reconstitution of NTX-NOD mice with CD8+ alpha(alpha) TCR gamma(delta) T cells prevents diabetes. CD8+ gamma(delta) T(reg) are conceivably physiological and insulin-specific, induced by exposure to insulin in maternal milk. These findings infer an immunoregulatory role for extrathymic-derived IEL, developing under the influence of the thymus and conditioned by early exposure to the exogenous environment.

Disabling an integral CTL epitope allows suppression of autoimmune diabetes by intranasal proinsulin peptide.

Insulin is a major target of the autoimmune response associated with destruction of pancreatic beta cells in type 1 diabetes. A peptide that spans the junction of the insulin B chain and the connecting (C) peptide in proinsulin has been reported to stimulate T cells from humans at risk for type 1 diabetes and autoimmune diabetes-prone NOD mice. Here we show that proinsulin B24-C36 peptide binds to I-A(g7), the MHC class II molecule of the NOD mouse, and, after intranasal administration, induces regulatory CD4(+) T cells that, in the absence of CD8(+) T cells, block the adoptive transfer of diabetes. Curiously, however, intranasal B24-C36 did not inhibit development of spontaneous diabetes in treated mice. We then determined that B24-C36, and its core sequence B25-C34, bind to K(d), the NOD mouse MHC class I molecule, and elicit CD8(+) CTLs. When the CD8(+) T lymphocyte epitope was truncated at the C34 valine anchor residue for binding to K(d), the residual CD4(+) T cell epitope, B24-C32/33, significantly inhibited diabetes development after a single intranasal dose. This study identifies a novel CTL epitope in proinsulin and demonstrates that the therapeutic potential of a "tolerogenic" autoantigen peptide can be compromised by the presence of an integral CTL epitope.

Transient blockade of CD40 ligand dissociates pathogenic from protective mucosal immunity.

Antigen administration via oral and other mucosal routes can suppress systemic immunity to the antigen and has been used to prevent experimental autoimmune disease. This approach may prove ineffective or even harmful if it leads to a concomitant induction of cytotoxic T lymphocytes (CTLs), and indeed, mucosal administration of the model antigen ovalbumin (OVA) has been shown to elicit CTL activation while simultaneously inducing oral tolerance. Here we show that induction by oral OVA of CTLs in wild-type mice, and of diabetes in mice expressing OVA transgenically in pancreatic beta cells, can be prevented by transiently blocking the CD40 ligand (CD40L). However, CD40L blockade did not diminish oral tolerance, as measured by suppression of systemic OVA-primed T cell proliferation, IFN-gamma secretion, and Ab production. Consistent with these findings, mice lacking CD40 expression could be orally tolerized to OVA. Transient CD40L blockade therefore dissociates pathogenic from protective immunity and should enhance the efficacy and safety of oral tolerance for preventing autoimmune disease.