Cross-sectional analysis of CD8 T cell immunity to human herpesvirus 6B.

Human herpesvirus 6 (HHV-6) is prevalent in healthy persons, causes disease in immunosuppressed carriers, and may be involved in autoimmune disease. Cytotoxic CD8 T cells are probably important for effective control of infection. However, the HHV-6-specific CD8 T cell repertoire is largely uncharacterized. Therefore, we undertook a virus-wide analysis of CD8 T cell responses to HHV-6. We used a simple anchor motif-based algorithm (SAMBA) to identify 299 epitope candidates potentially presented by the HLA class I molecule B*08:01. Candidates were found in 77 of 98 unique HHV-6B proteins. From peptide-expanded T cell lines, we obtained CD8 T cell clones against 20 candidates. We tested whether T cell clones recognized HHV-6-infected cells. This was the case for 16 epitopes derived from 12 proteins from all phases of the viral replication cycle. Epitopes were enriched in certain amino acids flanking the peptide. Ex vivo analysis of eight healthy donors with HLA-peptide multimers showed that the strongest responses were directed against an epitope from IE-2, with a median frequency of 0.09% of CD8 T cells. Reconstitution of T cells specific for this and other HHV-6 epitopes was also observed after allogeneic hematopoietic stem cell transplantation. We conclude that HHV-6 induces CD8 T cell responses against multiple antigens of diverse functional classes. Most antigens against which CD8 T cells can be raised are presented by infected cells. Ex vivo multimer staining can directly identify HHV-6-specific T cells. These results will advance development of immune monitoring, adoptive T cell therapy, and vaccines.

Specific CD8⁺ T cells recognize human herpesvirus 6B.

The importance of human herpesvirus 6 (HHV-6) species as human pathogens is increasingly appreciated. However, we do not understand how infection is controlled in healthy virus carriers, and why control fails in patients with disease. Other persistent viruses are under continuous surveillance by antigen-specific T cells, and specific T-cell repertoires have been well characterized for some of them. In contrast, knowledge on HHV-6-specific T-cell responses is limited, and missing for CD8(+) T cells. Here we identify CD8(+) T-cell responses to HHV-6B, the most widespread HHV-6 species, in healthy virus carriers. HHV-6B-specific CD8(+) T-cell lines and clones recognized HLA-A2-restricted peptides from the viral structural proteins U54 and U11, and displayed various antigen-specific antiviral effector functions. These CD8(+) T cells specifically recognized HHV-6B-infected primary CD4(+) T cells in an HLA-restricted manner, produced antiviral cytokines, and killed infected cells, whereas HHV-6A-infected cells were not recognized. Thus, HHV-6B-specific CD8(+) T cells are likely to contribute to control of infection, overcoming the immunomodulatory effects exerted by the virus. Potentially, HHV-6-associated disease could be addressed by active or passive immunotherapy that reconstitutes virus-specific CD8(+) T-cell responses.

A single TCR alpha-chain with dominant peptide recognition in the allorestricted HER2/neu-specific T cell repertoire.

T cells can recognize tumor cells specifically by their TCR and the transfer of TCR-engineered T cells is a promising novel tool in anticancer therapies. We isolated and characterized four allorestricted TCRs with specificity for the HER2/neu-derived peptide 369 (HER2(369)) demonstrating high peptide specificity. PBMCs transduced with especially one TCR, HER2-1, mediated specific tumor reactivity after TCR optimization suggesting that this TCR represents a potential candidate for targeting HER2 by TCR-transduced effector cells. Another TCR showed high-peptide specificity without tumor reactivity. However, the TCR alpha-chain of this TCR specifically recognized HER2(369) not only in combination with the original beta-chain but also with four other beta-chains of the same variable family deriving from TCRs with diverse specificities. Pairing with one beta-chain derived from another HER2(369)-specific TCR potentiated the chimeric TCRs in regard to functional avidity, CD8 independency, and tumor reactivity. Although the frequency of such TCR single chains with dominant peptide recognition is currently unknown, they may represent interesting tools for TCR optimization resulting in enhanced functionality when paired to novel partner chains. However, undirected mispairing with novel partner chains may also result in enhanced cross-reactivity and self-reactivity. These results may have an important impact on the further design of strategies for adoptive transfer using TCR-transduced T cells.

CMV-specific TCR-transgenic T cells for immunotherapy.

Reactivation of CMV can cause severe disease after allogeneic hemopoietic stem cell transplantation. Adoptive T cell therapy was successfully used for patients who had received transplants from CMV-positive donors. However, patients with transplants from CMV-negative donors are at highest risk, and an adoptive therapy is missing because CMV-specific T cells are not available from such donors. To address this problem, we used retroviral transfer of CMV-specific TCR genes. We generated CMV-specific T cell clones of several HLA restrictions recognizing the endogenously processed Ag pp65. The genes of four TCRs were cloned and transferred to primary T cells from CMV-negative donors. These CMV-TCR-transgenic T cells displayed a broad spectrum of important effector functions (secretion of IFN-gamma and IL-2, cytotoxicity, proliferation) in response to endogenously processed pp65 and could be enriched and expanded by strictly Ag-specific stimulation. Expansion of engineered T cells was accompanied by an increase in specific effector functions, indicating that the transferred specificity is stable and fully functional. Hence, we expect these CMV-TCR-transgenic T cells to be effective in controlling acute CMV disease and establishing an antiviral memory.