Peripheral blood-derived virus-specific memory stem T cells mature to functional effector memory subsets with self-renewal potency.

Memory T cells expressing stem cell-like properties have been described recently. The capacity of self-renewal and differentiation into various memory/effector subsets make them attractive for adoptive T cell therapy to combat severe virus infections and tumors. The very few reports on human memory stem T cells (T(SCM)) are restricted to analyses on polyclonal T cells, but extensive data on Ag-specific T(SCM )are missing. This might be due to their very low frequency limiting their enrichment and characterization. In this article, we provide functional and phenotypic data on human viral-specific T(SCM), defined as CD8(+)CD45RA(+)CCR7(+)CD127(+)CD95(+). Whereas <1% of total T cells express the T(SCM) phenotype, human CMV-specific T(SCM) can be detected at frequencies similar to those seen in other subsets, resulting in ∼ 1 /10,000 human CMV-specific T(SCM). A new virus-specific expansion protocol of sort-purified T(SCM) reveals both upregulation of various T cell subset markers and preservation of their stem cell phenotype in a significant proportion, indicating both self-renewal and differentiation potency of virus-specific T cells sharing their TCR repertoire. Furthermore, we describe a simplified culture protocol that allows fast expansion of virus-specific T(SCM) starting from a mixed naive T/T(SCM) pool of PBLs. Due to the clinical-grade compatibility, this might be the basis for novel cell therapeutic options in life-threatening courses of viral and tumor disease.

Preferential expansion of human virus-specific multifunctional central memory T cells by partial targeting of the IL-2 receptor signaling pathway: the key role of CD4+ T cells.

Effector memory T cells are effective in controlling acute infections, but central memory T cells play a key role in long-lasting protection against viruses and tumors. In vivo/in vitro challenge by Ag commonly supports the generation of effector memory T cells with limited longevity. To our knowledge, this study demonstrates for the first time in the human system and under rechallenge conditions that targeting IL-2R by partial mammalian target of rapamycin inhibition or blocking IL-2Rα enriches human CD4(+)/CD8(+) central memory T cells within the virus-specific T cell product associated with enhanced functionality (i.e., multicytokine secretors, including IL-2; enhanced CD137 and CD107a expression on CD8(+) and CD4(+) T cells, respectively; and killing infected target cells). Remarkably, the effects on CD8(+) T cells are mainly mediated via the enhancement of CD4(+) T cell function. The data reveal new insights into the role of CD4(+) T cell support for the quality of CD8(+) T cell memory, even under rechallenge conditions. Moreover, our method offers a new approach to improve the long-lasting efficacy of adoptive T cell therapy in patients.

HCMV-specific T-cell therapy: do not forget supply of help.

Human cytomegalovirus infections have a major negative effect on morbidity and mortality of immunosuppressed allograft recipients and indirectly on graft function and survival. The adoptive antiviral T-cell therapy is a novel therapeutic tool to restore immune competence after solid organ transplantation. Till now, the antiviral T-cell products mainly focused on cytotoxic CD8(+) T cells, whereas CD4(+) T cells played a minor role. Here, we demonstrate the importance of CD4(+) T cells within T-cell lines specific for human cytomegalovirus besides its essential support for the quality of CD8(+) T-cell memory. Virus-specific CD4(+) T cells elicit profound functionality after rechallenge (multicytokine secretors, CD137, CD154, and CD107a expression and killing of infected target cells). The CD4(+) T cells show predominantly a Th1 phenotype with cytolytic properties that is mainly perforin-dependent. The data demonstrate the significance of CD4(+) T cells within T-cell products to achieve a successful adoption with enhanced efficacy.