Cognate CD4 T-cell licensing of dendritic cells heralds anti-cytomegalovirus CD8 T-cell immunity after human allogeneic umbilical cord blood transplantation.

UNLABELLED: Reactivation of human cytomegalovirus (CMV) is hazardous to patients undergoing allogeneic cord blood transplantation (CBT), lowering survival rates by approximately 25%. While antiviral treatment ameliorates viremia, complete viral control requires CD8+ T-cell-driven immunity. Mouse studies suggest that cognate antigen-specific CD4+ T-cell licensing of dendritic cells (DCs) is required to generate effective CD8+ T-cell responses. For humans, this was not fully understood. We here show that CD4+ T cells are essential for licensing of human DCs to generate effector and memory CD8+ T-cell immunity against CMV in CBT patients. First, we show in CBT recipients that clonal expansion of CMV-pp65-specific CD4+ T cells precedes the rise in CMV-pp65-specific CD8+ T cells. Second, the elicitation of CMV-pp65-specific CD8+ T cells from rare naive precursors in cord blood requires DC licensing by cognate CMV-pp65-specific CD4+ T cells. Finally, also CD8+ T-cell memory responses require CD4+ T-cell-mediated licensing of DCs in our system, by secretion of gamma interferon (IFN-γ) by pp65-specific CD4+ T cells. Together, these data show that human DCs require licensing by cognate antigen-specific CD4+ T cells to elicit effective CD8+ T-cell-mediated immunity and fight off viral reactivation in CBT patients. IMPORTANCE: Survival rates after stem cell transplantation are lowered by 25% when patients undergo reactivation of cytomegalovirus (CMV) that they harbor. Immune protection against CMV is mostly executed by white blood cells called killer T cells. We here show that for generation of optimally protective killer T-cell responses that respond to CMV, the early elicitation of help from a second branch of CMV-directed T cells, called helper T cells, is required.

Multi-cistronic vector encoding optimized safety switch for adoptive therapy with T-cell receptor-modified T cells.

T-cell receptor (TCR) gene transfer is an attractive strategy to equip T cells with defined antigen-specific TCRs using short-term in vitro procedures to target both hematological malignancies and solid tumors. TCR gene transfer poses different safety issues that might warrant the inclusion of a suicide gene. High affinity TCRs may result in on-target toxicity, and off-target reactivity directed against healthy tissue can be observed due to mixed TCR dimers. Inclusion of a suicide gene as a safety switch may abrogate these unwanted toxicities. Human CD20 has been proposed as a nonimmunogenic suicide gene targeted by widely used clinical-grade anti-CD20 antibodies that can additionally function as a selection marker. However, transduction of T cells with a multi-cistronic vector encoding both TCR and CD20 resulted in poor coexpression. In this study, we demonstrated that codon optimization of TCR and CD20 resulted in profound coexpression of both the preferentially expressed antigen in melanoma (PRAME)-TCR and CD20, allowing selective as well as efficient elimination of these engineered T cells in vitro. These results demonstrate the great potential of codon optimized CD20 to be broadly used in clinical trials as a safety switch.