Cross-presentation of tumour antigens by human induced pluripotent stem cell-derived CD141(+)XCR1+ dendritic cells.

Monocyte-derived dendritic cells (moDC) have been widely used in cancer immunotherapy but show significant donor-to-donor variability and low capacity for the cross-presentation of tumour-associated antigens (TAA) to CD8(+) T cells, greatly limiting the success of this approach. Given recent developments in induced pluripotency and the relative ease with which induced pluripotent stem (iPS) cell lines may be generated from individuals, we have succeeded in differentiating dendritic cells (DC) from human leukocyte antigen (HLA)-A(*)0201(+) iPS cells (iPS cell-derived DC (ipDC)), using protocols compliant with their subsequent clinical application. Unlike moDC, a subset of ipDC was found to coexpress CD141 and XCR1 that have been shown previously to define the human equivalent of mouse CD8α(+) DC, in which the capacity for cross-presentation has been shown to reside. Accordingly, ipDC were able to cross-present the TAA, Melan A, to a CD8(+) T-cell clone and stimulate primary Melan A-specific responses among naïve T cells from an HLA-A(*)0201(+) donor. Given that CD141(+)XCR1(+) DC are present in peripheral blood in trace numbers that preclude their clinical application, the ability to generate a potentially unlimited source from iPS cells offers the possibility of harnessing their capacity for cross-priming of cytotoxic T lymphocytes for the induction of tumour-specific immune responses.

Biological characterization of a novel class of toll-like receptor 7 agonists designed to have reduced systemic activity.

BACKGROUND AND PURPOSE Toll-like receptor 7 (TLR7) agonists have potential in the treatment of allergic diseases. However, the therapeutic utility of current low molecular weight TLR7 agonists is limited by their systemic activity, resulting in unwanted side effects. We have developed a series of TLR7-selective 'antedrugs', including SM-324405 and AZ12441970, which contain an ester group rapidly cleaved in plasma to reduce systemic exposure. EXPERIMENTAL APPROACH Agonist activity at TLR7 of the parent ester and acid metabolite was assessed in vitro in reporter cells and primary cells from a number of species. Pharmacokinetics following a dose to the lungs was assessed in mice and efficacy evaluated in vivo with a mouse allergic airway model. KEY RESULTS Compounds were selective agonists for TLR7 with no crossover to TLR8 and were metabolically unstable in plasma with the acid metabolite showing substantially reduced activity in a number of assays. The compounds inhibited IL-5 production and induced IFN-α, which mediated the inhibition of IL-5. When dosed into the lung the compounds were rapidly metabolized and short-term exposure of the 'antedrug' was sufficient to activate the IFN pathway. AZ12441970 showed efficacy in a mouse allergic airway model with minimal induction of systemic IFN-α, consistent with the low plasma levels of compound. CONCLUSIONS AND IMPLICATIONS The biological and metabolic profiles of these TLR7-selective agonist 'antedrug' compounds are consistent with a new class of compound that could be administered locally for the treatment of allergic diseases, while reducing the risk of systemic side effects. LINKED ARTICLE This article is commented on by Kaufman and Jacoby, pp. 569-572 of this issue. To view this commentary visit http://dx.doi.org/10.1111/j.1476-5381.2011.01758.x.

Dissecting the contribution of innate and antigen-specific pathways to the breach of self-tolerance observed in a murine model of arthritis.

BACKGROUND: The relative roles of innate immunity and antigen-specific T cells in rheumatoid arthritis remain controversial. Previous studies demonstrated that T-helper type 1 cells of irrelevant antigen specificity (ovalbumin) induced a transient arthritis in BALB/c mice, which recapitulates many of the pre-articular and articular features of human disease and is associated with the emergence of autoreactive T and B-cell responses to joint-specific antigens. However, the mechanisms underlying this phenomenon were unclear. OBJECTIVES: The aim of this study was to dissect the relative contribution of innate and heterologous antigen-specific pathways to the breach of self-tolerance and pathology observed in this model and how this may result from modified T and B-cell interactions. METHODS: To address this issue, experimental arthritis was elicited either by a non-specific inflammatory stimulus alone, by activation of T cells of an irrelevant specificity or a combination of both. RESULTS: The non-specific inflammatory response generated by lipopolysaccharide led to articular inflammation and cartilage erosion, but did not break tolerance to joint-specific antigens. In contrast, local activation of T cells of an irrelevant specificity produced a similar pathological picture but, in addition, induced T-cell responses to unrelated joint-specific antigens with associated activation of autoreactive B cells. These effects could be further potentiated by the addition of lipopolysaccharide. CONCLUSION: These data demonstrate that non-specific inflammation alone is insufficient to breach self-tolerance. In contrast, T cells of an irrelevant specificity, when triggered locally in an antigen-specific manner, can breach self-tolerance leading to arthritis and autoantibody production, which can then be amplified in a non-specific manner.

An investigation of the impact of the location and timing of antigen-specific T cell division on airways inflammation.

It is widely accepted that allergic asthma is orchestrated by T helper type 2 lymphocytes specific for inhaled allergen. However, it remains unclear where and when T cell activation and division occurs after allergen challenge, and whether these factors have a significant impact on airways inflammation. We therefore employed a CD4-T cell receptor transgenic adoptive transfer model in conjunction with laser scanning cytometry to characterize the location and timing of T cell division in asthma in vivo. Thus, for the first time we have directly assessed the division of antigen-specific T cells in situ. We found that accumulation of divided antigen-specific T cells in the lungs appeared to occur in two waves. The first very early wave was apparent before dividing T cells could be detected in the lymph node (LN) and coincided with neutrophil influx. The second wave of divided T cells accumulating in lung followed the appearance of these cells in LN and coincided with peak eosinophilia. Furthermore, accumulation of antigen-specific T cells in the draining LN and lung tissue, together with accompanying pathology, was reduced by intervention with the sphingosine 1-phosphate receptor agonist FTY720 2 days after challenge. These findings provide greater insight into the timing and location of antigen-specific T cell division in airways inflammation, indicate that distinct phases and locations of antigen presentation may be associated with different aspects of pathology and that therapeutics targeted against leukocyte migration may be useful in these conditions.

Tumour necrosis factor-alpha blockade suppresses murine allergic airways inflammation.

Asthma is a heterogeneous disease that has been increasing in incidence throughout western societies and cytokines, including proinflammatory tumour necrosis factor alpha (TNF-alpha), have been implicated in the pathogenesis of asthma. Anti-TNF-alpha therapies have been established successfully in the clinic for diseases such as rheumatoid arthritis and Crohn's disease. TNF-alpha-blocking strategies are now being trialled in asthma; however, their mode of action is poorly understood. Based on the observation that TNF-alpha induces lymph node hypertrophy we have attempted to investigate this as a mechanism of action of TNF-alpha in airway inflammation by employing two models of murine airway inflammation, that we have termed short and long models, representing severe and mild/moderate asthma, respectively. The models differ by their immunization schedules. In the short model, characterized by eosinophilic and neutrophilic airway inflammation the effect of TNF-alpha blockade was a reduction in draining lymph node (DLN) hypertrophy, eosinophilia, interleukin (IL)-5 production and immunoglobulin E (IgE) production. In the long model, characterized by eosinophilic inflammation, TNF-alpha blockade produced a reduction in DLN hypertrophy and IL-5 production but had limited effects on eosinophilia and IgE production. These results indicate that anti-TNF-alpha can suppress DLN hypertrophy and decrease airway inflammation. Further investigations showed that anti-TNF-alpha-induced inhibition of DLN hypertrophy cannot be explained by preventing l-selectin-dependent capture of lymphocytes into the DLN. Given that overall TNF blockade was able to suppress the short model (severe) more effectively than the long model (mild/moderate), the results suggest that TNF-alpha blocking therapies may be more effective in the treatment of severe asthma.

T cell responses modulated through interaction between CD8alphaalpha and the nonclassical MHC class I molecule, TL.

The thymus leukemia antigen (TL) is a nonclassical class I molecule, expressed abundantly on intestinal epithelial cells. We show that, in contrast to other major histocompatibility complex (MHC) class I molecules that bind CD8alphabeta, TL preferentially binds the homotypic form of CD8alpha (CD8alphaalpha). Thus, TL tetramers react specifically to CD8alphaalpha-expressing cells, including most intestinal intraepithelial lymphocytes. Compared with CD8alphabeta, which recognizes the same MHC as the T cell receptor (TCR) and thus acts as a TCR coreceptor, high-affinity binding of CD8alphaalpha to TL modifies responses mediated by TCR recognition of antigen presented by distinct MHC molecules. These findings define a novel mechanism of lymphocyte regulation through CD8alphaalpha and MHC class I.

Th1 and Th2 CD4+ T cells provide help for B cell clonal expansion and antibody synthesis in a similar manner in vivo.

The relative ability of Th1 and Th2 T cells to help B cells remains controversial as do the mechanisms by which both T cell subsets provide help in vivo. Whether this help affects the clonal expansion and/or differentiation of B cells has been difficult to assess due to the low frequency of Ag-specific T and B lymphocytes. We have employed a novel technique to directly monitor the clonal expansion of Ag-specific T and B lymphocytes in vivo. OVA-specific TCR transgenic T lymphocytes were polarized toward a Th1 or Th2 phenotype in vitro. These cells were then transferred into syngeneic recipients, along with B cell receptor transgenic hen egg lysozyme-specific B lymphocytes. Our results indicate that Th1 and Th2 cells support B cell responses to a similar extent in vivo and that they achieve this in the same manner by migrating into B cell follicles to promote CD154-dependent B cell clonal expansion and Ab production.

Induction of oral tolerance in the primed immune system: influence of antigen persistence and adjuvant form.

Oral tolerance is being promoted as a therapy for autoimmune diseases and therefore will need to be functional in a primed immune system. In previous studies, we found that although primed mice could be tolerized by feeding ovalbumin (OVA), the degree of the tolerance and its effects on individual components of the systemic immune response were more limited than that found in naive animals. Here we increased the dose and frequency of antigen feeding in an attempt to extend the effects of oral tolerance in primed mice and to understand why its effects are limited under these conditions. Increasing the amounts of OVA fed, up to a single dose of 400 mg, or using multiple feeds of 5 x 5 or 5 x 25 mg OVA, did not radically alter the extent of tolerance, with DTH responses, antigen-specific proliferation, and IL5 and IFN-gamma production still being tolerized, but antibody responses remaining generally resistant. The deficient tolerance in primed mice could not be overcome by waiting for maximum clonal expansion to wane and was not influenced by persistent release of antigen from a depot adjuvant. We conclude that the resistance of primed mice to oral tolerance may be due to the fact that antigen-experienced T cells may be inherently resistant to induction of tolerance, or that the microenvironment of the primed immune system inhibits the delivery of tolerogenic signals to antigen-specific T cells.

Normal induction of oral tolerance in the absence of a functional IL-12-dependent IFN-gamma signaling pathway.

There is considerable evidence that regulatory cytokines play an important role in mediating the systemic tolerance found after oral administration of protein Ags. Although most existing work has focused on cytokines such as IL-4, IL-10, and TGF-beta, recent evidence from TCR transgenic systems suggests that the induction of oral tolerance is accompanied by priming of Ag-specific IFN-gamma production. IFN-gamma has also been implicated as a mediator of T cell tolerance in other models in vivo and in vitro, including that induced by aerosol administration of protein. We show here that feeding tolerogenic doses of OVA primes for IFN-gamma production in the spleen of mice with a normal T cell repertoire. However, depleting IFN-gamma at the time of feeding OVA had no effect on the induction of tolerance. In addition, tolerance was induced normally in both IFN-gamma receptor knockout (IFN-gammaR-/-) and IL-12 p40 knockout (IL-12-/-) mice. This was the case for all components of the systemic immune response and also with a variety of feeding protocols, including those believed to induce distinct regulatory mechanisms. We conclude that IL-12-dependent IFN-gamma-mediated regulation does not play an essential role in oral tolerance.

Immunological consequences of intervention in established immune responses by feeding protein antigens.

The usual result of feeding protein antigens to naive animals is the induction of profound immunological unresponsiveness and this is currently being exploited to treat inflammatory disease. Because the most useful therapeutic application of feeding antigen would be to suppress established disease, the aim of this study was to compare the immunological basis of oral tolerance induced by feeding a model antigen to naive and primed animals. We show that feeding 2-200 mg ovalbumin (OVA) to mice 7 days after immunisation with OVA in adjuvant produces dose-dependent suppression of delayed-type hypersensitivity (DTH), T cell proliferation, and both TH1 and TH2 cytokines, although serum IgG levels were unaffected. Feeding OVA before immunisation suppressed all these responses. Although feeding up to 8 days after immunisation could suppress some subsequent responses, tolerance was induced much more effectively when antigen was fed in the first 4 days after immunisation. Tolerance in primed mice was intact in IL-4-/- mice, indicating that it was not caused by selective upregulation of TH2 cells in vivo. We conclude that oral administration of protein antigen can inhibit ongoing responses by all effector T cell subsets, but the exact consequences, and therefore possibly the mechanisms, are different from those induced by tolerising naive mice. These findings may have important implications for designing therapeutic regimes exploiting oral tolerance.