ALBERT

Description: Adoptive transfer of cytomegalovirus (CMV)-specific T cells can restore long-lasting, virus-specific immunity and clear CMV viremia in recipients of allogeneic stem cell transplants if CD4+ and CD8+ CMV-specific T cells are detected in the recipient after transfer. Current protocols for generating virus-specific T cells use live virus, require leukapheresis of the donor, and are time consuming. To circumvent these limitations, a clinical-scale protocol was developed to generate CMV-specific T cells by using autologous cellular and serum components derived from a single 500-mL blood draw. CMV-specific T cells were stimulated simultaneously with CMV-specific major histocompatibility complex class I (MHC I)- restricted peptides and CMV antigen. Activated T cells were isolated with the interferon-γ (IFN-γ) secretion assay and expanded for 10 days. In 8 randomly selected, CMV-seropositive donors, 1.34 × 108 combined CD4+ and CD8+ CMV-specific T cells, on average, were generated, as determined by antigen-triggered IFN-γ production. CMV-infected fibroblasts were efficiently lysed by the generated T cells, and CMV-specific CD4+ and CD8+ T cells expanded if they were stimulated with natural processed antigen. On the other hand, CD4+ and CD8+ T cell-mediated alloreactivity of generated CMV-specific T-cell lines was reduced compared with that of the starting population. In conclusion, the culture system developed allowed the rapid generation of allodepleted, highly enriched, combined CD4+ and CD8+ CMV-specific T cells under conditions mimicking good manufacturing practice. (Blood. 2004; 103:3565-3572)

Description: Relapse is the leading cause of treatment failure after allogeneic SCT of Hodgkin Disease (HD). As Ebstein-Barr infection (EBV) is associated with 60% of all HD cases, adoptive immunotherapy with donor derived EBV-specific T-cells lines has resulted in disease control of allogeneic SCT. Potential targets for the adoptively transferred T-cells are the type II latency protein LMP-1 and LMP-2a, which are both homogenously expressed by HD cells. In healthy individuals, both LMP-1 and LMP-2a elicits subdominant CD8+ T-cell responses with frequencies of less than 1:10000. LMP-1 and LMP-2a specific T-cells from 1x108 PBMC derived from HLA A*0201+healthy donors were stimulated with the HLA A*0201 LMP1-epitopes YLLEMLWRL and YLGQNWWTL and the HLA A*0201 LMP-2a epitope CLGGLLTM. Activated T-cells were selected by the cytokine secretion assay and expanded for 10 days. In 85% of donors 1.7 x106 (range 0.7 –4.5 x106; n=13) LMP-1 or LMP-2a specific CD8+ T-cell could be generated with an average purity of 83% as determined by tetramer staining. LMP1- and LMP2a-specific CD8+ T-cells were then expanded 3000 x in 14 d by the rapid expansion protocol and evaluated functionally for cytokine production and specific lysis. Both LMP-1 and LMP-2a specific CD8+ T-cells retained specific cytokine production if stimulated with peptide pulsed targets, efficiently lysed peptid pulsed targets. Surprisingly, if LMP-1 was presented endogenously by EBV positive targets or by targets cells transduced with LMP-1, no cytokine production or specific lysis was detected despite protein expression of LMP-1 in all targets. In contrast, IFN-γ production could be readily detected in LMP-2a-specific CD8+ T-cells after stimulation with target cells processing endogenously the LMP-2a antigen as well as specific lysis of EBV positive target cells. Furthermore, LMP2a specific CD8+ demostrated also specific lyse of Hodgkin-cells expressing the LMP2a (30:1 E/T ratio; 29,3%) where as LMP-1-specific CD8+ T-cells could not lyse HD-cells. In summary, LMP-1 and LMP-2a specific T-cells, although present at undectable levels in healthy donors, can be readily selected and expanded to up to 6x109 antigen-specific T-cells in less than 4 weeks starting from 1x108 PBMC. Based on this data, adoptive immunotherapy of relapsed EBV positive HD after allogeneic SCT should be preferentially performed with LMP-2a specific CD8+ T-cells rather than with LMP-1 specific CD8+ T-cells.

Description: Effective cancer therapy with a minimum of undesired side effects in multiple myeloma (MM) requires specifity of the therapeutic agent against the neoplastic cells. One approach to reach this aim is virotherapy using oncolytic measles virus. Attenuated replication-competent Edmonston lineage strains of measles virus (MV-Edm) have proven anti-tumor activity against xenograft models of human multiple myeloma, ovarian cancer, lymphoma and glioma. The virus is selectively oncolytic, causing extensive lethal cell to cell fusion via CD46, which is more highly expressed on tumor cells than on normal cells. However, MV-Edm retains the capacity to infect a variety of nontransformed cell types via its native receptors, CD46 and SLAM which are present on many different cell types. One approach to avoid this risk is to engineer the viral attachment protein to ablate its natural tropisms and at the same time, redirect its specificity to interact with alternative tumor specific receptors. The native measles Hemagglutinin (H) protein recognizes CD46 or SLAM resulting in membrane fusion and syncytia formation of cells. In this work the H protein was engineered to restrict and retarget membrane fusion through the display of a single-chain antibody (scFv) recognizing the Wue-1-antigen known to be highly specific for MM cells and abrogation of native measles binding domains for CD46 and SLAM by mutation. This modified H protein (chimeric H) was cloned in a full-length viral backbone including EGFP enabling to detect infected cells and syncytia formation under the UV light emitting green fluorescence (EGFP). On the basis of the parental measles virus expressing EGFP (MV-GFP) two different viruses were generated: non-ablated virus expressing the chimeric H protein including the scFv Wue-1 still competent to infect cells expressing CD46 and SLAM (MV-W1) with the chimeric H protein but ablated for the interactions with CD46 and SLAM (MV-W2). The genetically modified viruses propagated as recently described (Nat. Biotech., Vol.23, Nr.2, Feb.2005, pp.209–214.). To determine if the fully retargeted MV-Edm would be able to infect MM cell lines selectively a first array of infection assays was performed using the MM cell lines RPMI 8226 and ARH-77 expressing the Wue-1 antigen as expected targets and K562 and healthy CD40L activated CD19 positive B cells as controls. 24 to 96 hours after infection with MV-GFP, MV-W1 and MV-W2 we observed syncytia formation and expression of EGFP with MV-GFP and MV-W1 in all cells indicating that the modification of the virus with the scFv-Wue-1 doesn’t alter the potential to infect and kill cells compared to the parental virus. In contrast MV-W2 was able to form only EGFP positive plaques with the Wue-1 antigen positive cells RPMI 8226 and ARH-77 but did not infect K562 or CD19 positve B cells both negative for Wue-1 antigen. These results indicate that the measles virus vaccine strain Edmonston B can be modified to express a scFv recognizing the Wue-1 antigen. In addition the native H protein can be mutated resulting in ablation of the natural tropism towards CD46 and SLAM positive cells. Viruses with these modifications can be rescued and propagated in vitro and selectively infected Multiple Myeloma cells without causing damage to normal B-cell progenitors.