Expansion of human CMV-specific cytotoxic T lymphocytes to a clinical scale: a simple culture system using tetrameric HLA–peptide complexes

Modifying interleukin-2 concentrations during culture improves function of T cells for adoptive immunotherapy

BACKGROUND

Adoptive immunotherapy with cytotoxic T cells has shown promising clinical results in patients with metastatic melanoma and post-transplant-associated viral infections. Cell transfer therapies often require the ex vivo expansion of large numbers of reactive lymphocytes. Therefore interleukin-2 (IL-2), a potent T-cell mitogenic cytokine that critically affects the features and effectiveness of T cells, is frequently added to cell culture media.

METHODS

We examined the influence of various IL-2 concentrations on cell growth, cytotoxicity, cytokine release and surface marker expression of tumor-infiltrating lymphocytes (TIL) during a standard 14-day rapid expansion phase. The study was conducted under good manufacturing practice (GMP) conditions, using approved reagents in a class 10000 laboratory.

RESULTS

T-cell cultures grown in very high IL-2 concentrations (600-6000 IU/mL) expanded massively and maximally secreted interferon (IFN)-gamma in response to antigenic stimulation, but exhibited only low direct cytotoxicity. On the other hand, TIL cultures grown in low concentrations of IL-2 throughout the rapid expansion phase expanded to a lower extent and barely secreted IFN-gamma but displayed high cytotoxic activity. A combined approach of starting with 10-120 IU/mL IL-2 during the first week, followed by increasing the IL-2 concentration to 6000 IU/mL during the second week, results in T cells that expand well, maximally produce IFN-gamma and are highly cytotoxic against tumor cells.

DISCUSSION

Fine tuning of the IL-2 concentration during ex vivo expansion of T cells can yield high numbers of T cells with optimal features for clinical use.

Improving outcome of allogeneic stem cell transplantation by immunomodulation of the early post-transplant environment

There has been great progress in understanding the alloresponse and the process of immune recovery after stem cell transplantation. Here, we highlight ways in which transplant outcome is determined by unique immunological features of the early post-transplant period that modulate the growth and function of the grafted donor T cells and stem cells. Better understanding of these early events and more detailed knowledge of the phenotype and function of transplanted donor cells facilitate strategies to optimize immune recovery, prevent graft-versus-host disease (GVHD) and boost immunity to viruses and leukemia. Approaches that optimize CD34 cell dose, techniques to remove GVHD-reacting T cells by T cell subset selection, suicide gene insertion or selective allodepletion, and the adoptive transfer of antigen-specific T cells have reached the stage of clinical trials. Furthermore, murine transplant experiments indicate ways to prevent GVHD while preserving immune function by depletion of naïve cells, T cytotoxic 1 and T helper 1 cells, or by enrichment of regulatory T cells. Many of these approaches appear feasible in clinical transplantation and have yielded promising initial results, but proof that the goal of controlled selective immune reconstitution can be achieved is still awaited.

Improving T cell therapy for cancer

Adoptive transfer of antigen-specific T cells has been most effective in treating cytomegalovirus (CMV) disease and Epstein-Barr virus (EBV)-associated lymphoproliferative disease (LPD). Both of these diseases develop only during periods of acute immune suppression, and both involve highly immunogenic infected cells, and thus respond well to T cell therapies. In contrast, tumours that develop in the presence of a competent immune system evolve complex immune evasion strategies to avoid and subvert T cell-mediated killing. Therefore, even T cells that display potent cytotoxic activity against tumour cells in vitro may not be effective in vivo without altering the tumour:T cell balance in favour of the T cell. This review discusses several new areas of research aimed at improving adoptive T cell therapy for the treatment of cancer, including the genetic modification of antigen-specific T cells to allow them to perform better in vivo, and conditioning the host to improve in vivo expansion and function of transferred cells.

Cellular immunotherapy for cytomegalovirus and HIV-1 infection

Current antiviral drugs do not fully reconstitute the specific antiviral immune control in chronically human immunodeficiency virus (HIV)-1-infected patients or in cytomegalovirus (CMV)-infected patients after hematopoietic stem cell transplantation. Therefore, immunotherapy in which the patient's immune system is manipulated to enhance antiviral immune responses has become a promising area of viral immunology research. In this review, an overview is provided on the cellular immunotherapy strategies that have been developed for HIV infection and CMV reactivation in immunocompromised patients. As an introduction, the mechanisms behind the cellular immune system and their importance for the development of a workable immunotherapy approach are discussed. Next, the focus is shifted to the immunopathogenesis of CMV and HIV-1 infections to correlate these findings with the concepts and ideas behind the viral-specific immunotherapies discussed. Current and future perspectives of active and passive cellular immunotherapy for the treatment of CMV and HIV-1 infections are reviewed. Finally, pitfalls and key issues with regard to the development of immunotherapy protocols that can be applied in a clinical setting are addressed.

Evaluation of cytomegalovirus-specific cytotoxic T-lymphocytes in patients with the HLA-A*02 or HLA-A*24 phenotype undergoing hematopoietic stem cell transplantation

Cytomegalovirus-specific cytotoxic T-lymphocytes (CMV-CTL) are essential for the control of CMV reactivation. To monitor the quantity and function of CMV-CTL after hematopoietic stem cell transplantation (HSCT), two CMV epitopes that bind to HLA-A*0201 NLVPMVATV (A*02NLV) and HLA-A*2402 QYDPVAALF (A*24QYD) were evaluated for their immunological potential. Samples from patients with the HLA-A*02 or HLA-A*24 serotype were analyzed by tetramer, intracellular cytokine staining and enzyme-linked immunospot (ELISPOT) assay. There were significantly more A*02NLV-specific CMV-CTL than A*24QYD (23 x 10(6) vs 0.4 x 10(6)/l). The frequency of IFN-gamma-producing cells was also higher upon stimulation with A*02NLV than with A*24QYD (2.5 vs 0.1%/CD8). Furthermore, the magnitude of CMV-CTL expansion was two- to 50-fold when cells were cultured with A*02NLV, while only an insignificant increase was observed in culture with A*24QYD. Although the number of A*24QYD-specific CMV-CTL was very low in most of the HLA-A*24 patients, the incidence of CMV reactivation did not differ between those with HLA-A*02 and HLA-A*24 serotype alone. These results suggest that an epitope other than A*24QYD plays a major role in patients with HLA-A*24. Our study also showed that A*02NLV may be a useful epitope for monitoring CMV-CTL not only in patients with HLA-A*0201 but also in those with the A*0206 genotype.

Analysis of memory T lymphocyte activity following stimulation with overlapping HLA-A*2402, A*0101 and Cw*0402 restricted CMV pp65 peptides

The continuous efforts aimed at the identification of new immune epitopes across the MHC system has led to the discovery that more than one peptide may be restricted to the same HLA antigen and function as an immune determinant for that association. The aim of this study was to compare the ability of two overlapping peptides, the nonamer (9-mer) cytomegalovirus (CMV) pp65_341–349 (QYDPVAALF) and the decamer (10-mer) CMV pp65_341–350 (QYDPVAALFF), and the esadecamer (16-mer) peptide containing both the 9-mer and 10-mer sequences, CMV pp65_340–355 (RQYDPVAALFFFDIDL), to stimulate and maintain over time a T cell immune reactivation by HLA-A*2402, A*0101, and Cw*0402 cells from CMV-seropositive subjects. The 9-mer, 10-mer, and 16-mer peptides effectively stimulated CTLs from HLA-A*2402, HLA-A*0101, and HLA-Cw*0402 CMV seropositive donors. This data confirms that both the 9-mer and the 10-mer peptides are promiscuous and are not restricted to a single HLA antigen. CMV pp65_341–349 and CMV pp65_341–350 have the ability to produce CMV-specific CTLs in subjects with several different HLA types, presenting a practical advantage over other peptides that are restricted only to a single HLA antigen, and thus being optimal for CMV adoptive immune therapy. Moreover, since the 16-mer peptide encompasses both the 9-mer and 10-mer peptides, it may be better than either of these peptides for CMV adoptive immune therapy.