Generation of Human Alloantigen-Specific Regulatory T Cells Under Good Manufacturing Practice-Compliant Conditions for Cell Therapy.

Natural regulatory T cells (Tregs) may have a great therapeutic potential to induce tolerance in allogeneic cells and organ transplantations. In mice, we showed that alloantigen-specific Tregs (spe-Tregs) were more efficient than polyclonal Tregs (poly-Tregs) in controlling graft-versus-host disease (GVHD). Here we describe a clinical-grade compliant method for generating human spe-Tregs. Tregs were enriched from leukapheresis products with anti-CD25 immunomagnetic beads, primed twice by allogeneic mature monocyte-derived dendritic cells (mDCs), and cultured during 3 weeks in medium containing interleukin 2 (IL-2), IL-15, and rapamycin. After 3 weeks of culture, final cell products were expanded 8.3-fold from the initial CD25(+) purifications. Immunophenotypic analyses of final cells indicate that they were composed of 88 ± 2.6% of CD4(+) T cells, all expressing Treg-specific markers (FOXP3, Helios, GARP, LAP, and CD152). Spe-Tregs were highly suppressive in vitro and also in vivo using a xeno-GVHD model established in immunodeficient mice. The specificity of their suppressive activity was demonstrated on their ability to significantly suppress the proliferation of autologous effector T cells stimulated by the same mDCs compared to third-party mDCs. Our data provide evidence that functional alloantigen Tregs can be generated under clinical-grade compliant conditions. Taking into account that 130 × 10(6) CD25(+) cells can be obtained at large scale from standard leukapheresis, our cell process may give rise to a theoretical final number of 1 × 10(9) spe-Tregs. Thus, using our strategy, we can propose to prepare spe-Tregs for clinical trials designed to control HLA-mismatched GVHD or organ transplantation rejection.

Clinical-grade preparation of human natural regulatory T-cells encoding the thymidine kinase suicide gene as a safety gene.

BACKGROUND: Human CD4+CD25+FOXP3+ natural regulatory T-cells (nTreg) have a great therapeutic potential for the induction of tolerance in allo-transplanted patients or for the control of severe auto-immune diseases. However, clinical-grade production of nTreg remains difficult to achieve because of the absence of a truly specific surface marker and of their low frequency that implies a need for their ex vivo expansion. Furthermore, safety issues should be taken into consideration due to the risk of either uncontrolled nTreg-induced immunosuppression or uncontrolled proliferation of autoreactive contaminating T-cells particularly in an auto-immune context. METHODS: We compared different clinical-grade conditions for immuno-magnetic selection and ex vivo expansion of nTreg. For safety, expanded cells were genetically modified with retroviral vectors co-expressing human CD90 and HSV1 thymidine kinase. The CD90 surface marker and thymidine kinase allow for selection and elimination of transduced cells by ganciclovir, respectively. RESULTS: We showed that (i) nTreg could be enriched in a one step using CD25 microbeads, were functionally suppressive and mainly FOXP3+; (ii) using anti-CD28- and anti-CD3-coated beads, interleukin-2 and rapamycin, nTreg were expanded 150-200-fold after 3 weeks. Under these clinical-grade conditions, they remained suppressive, and no major alteration of the TCR repertoire was observed; (iii) after efficient retroviral transduction and CD90 selection, nTreg maintained their suppressive activity; (iv) transduced nTreg could be eliminated by ganciclovir upon activation. CONCLUSIONS: The efficient procedure reported here for the preparation of nTreg, whose safety has been ensured, is now applicable for further clinical trials.

Increased VEGFR2 expression during human late endothelial progenitor cells expansion enhances in vitro angiogenesis with up-regulation of integrin alpha(6).

In vitro expansion of late endothelial progenitor cells (EPCs) might yield a cell therapy product useful for myocardial and leg ischaemia, but the influence of EPC expansion on the angiogenic properties of these cells is unknown. In the present study, we investigated the effect of in vitro EPC expansion on vascular endothelial growth factor (VEGF) receptor expression. EPCs were obtained from CD34(+) cord blood cells and expanded for up to 5 weeks. Real-time quantitative reverse-transcription polymerase chain reaction (RT-PCR) showed that VEGFR2 expression, contrary to VEGFR1 and VEGFR3 expression, was significantly higher on expanded EPCs than on freshly isolated CD34(+) cells or on human umbilical vein endothelial cells (HUVECs). Quantitative flow cytometry confirmed that VEGFR2 density on EPCs increased during the expansion process and was significantly higher than on HUVECs. The impact of VEGFR2 increase was studied on the three theoretical steps of angiogenesis, i.e., EPC proliferation, migration and differentiation. VEGFR2 up-regulation had no effect on VEGF-induced cell proliferation, but significantly enhanced EPC migration and pseudotubes formation dependent on integrin alpha(6) subunit overexpression. In vitro expansion of late EPCs increases the expression of VEGFR2, the main VEGF receptor, with possible implications for EPC-based angiogenic therapy.