E. coli expression and purification of human and cynomolgus IL-15.

The physiological activities of Interleukin-15 (IL-15) suggest that it could be useful as an immunomodulator to activate the innate immune system, however, the expression and purification yields of recombinant mature IL-15 have typically been low. In this report, a method was optimised to generate milligram quantities of this cytokine. Human IL-15 with an N-terminal (His)(6)-tag was expressed in Escherichia coli as an insoluble protein. The IL-15 material was purified from other cellular proteins by dissolution in 6M guanidine HCl, followed by Ni-NTA chromatography in a buffer containing 8M urea. Use of a multi-component screen identified the optimal conditions for folding (His)(6)-tagged human IL-15 and the method was scaled up to produce milligram quantities of folded material in its native conformation, with two intra-molecular disulphides as determined by electrospray mass spectrometry. Mature IL-15 was generated by cleavage with recombinant enterokinase, which was subsequently removed by Ni-NTA chromatography. Identical methods were used to produce mature cynomolgus monkey (Macaca fascicularis) IL-15 in similar quantities. Human and cynomolgus IL-15 were both active in two IL-15 dependent assays; mouse CTLL2 cell proliferation and human and cynomolgus CD69 upregulation on CD3(-) CD8+ lymphocytes in whole blood. Despite being 96% identical at the amino acid level the human IL-15 was 10-fold more potent than the cynomolgus IL-15 in both assays. The methods described here are useful for producing both mature IL-15 proteins in sufficient quantity for in vivo and in vitro studies, including X-ray crystallography.

The specific monocarboxylate transporter-1 (MCT-1) inhibitor, AR-C117977, induces donor-specific suppression, reducing acute and chronic allograft rejection in the rat.

BACKGROUND: In a search for immunosuppressive drugs having novel mechanisms, monocarboxylate transporter (MCT-1) inhibitors were identified that markedly inhibited immune responses. Here, we report the effects of AR-C117977, a potent MCT-1 inhibitor, on alloimmune responses in the rat. METHODS: In vitro activity was determined in a rat mixed lymphocyte response (MLR). In vivo activity was tested in a graft versus host response (GVHR) and in both high (DA to PVG) and low (PVG to DA) responder cardiac allograft models. To assess induction of donor-specific suppression recipients of allogeneic hearts surviving longer than 100 days received a second transplant either of the same donor strain or a third-party donor strain. Effects on chronic graft rejection were assessed histologically by evaluating vasculopathy in long-term surviving grafts and in an obliterative bronchiolitis (OB) model. RESULTS: AR-C117977 inhibited the rat MLR and was more potent than cyclosporin A (CsA). In the rat GVHR model, AR-C117977 gave a dose-related inhibition. In the high responder cardiac allograft model, graft survival in excess of 100 days was achieved with AR-C117977 compared with 20 days with CsA and all the long-term survivors exhibited donor-specific suppression on retransplantation. In the low responder model, both AR-C117977 and CsA induced survival in excess of 100 days. Histology of the long-term surviving grafts suggested reduced vasculopathy associated with chronic rejection. Furthermore, AR-C117977 inhibited the occlusion of transplanted trachea in a OB model. CONCLUSION: This report describes a MCT-1 specific inhibitor having immunosuppressive activity on alloimmune responses and inducing donor-specific suppression.

Monocarboxylate transporter MCT1 is a target for immunosuppression.

Current immunosuppressive therapies act on T lymphocytes by modulation of cytokine production, modulation of signaling pathways or by inhibition of the enzymes of nucleotide biosynthesis. We have identified a previously unknown series of immunomodulatory compounds that potently inhibit human and rat T lymphocyte proliferation in vitro and in vivo in immune-mediated animal models of disease, acting by a novel mechanism. Here we identify the target of these compounds, the monocarboxylate transporter MCT1 (SLC16A1), using a strategy of photoaffinity labeling and proteomic characterization. We show that inhibition of MCT1 during T lymphocyte activation results in selective and profound inhibition of the extremely rapid phase of T cell division essential for an effective immune response. MCT1 activity, however, is not required for many stages of lymphocyte activation, such as cytokine production, or for most normal physiological functions. By pursuing a chemistry-led target identification strategy, we have discovered that MCT1 is a previously unknown target for immunosuppressive therapy and have uncovered an unsuspected role for MCT1 in immune biology.