21 research outputs found
Search for Polymorphisms in the Genes for Herpesvirus Entry Mediator, Nectin‐1, and Nectin‐2 in Immune Seronegative Individuals
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Search for Polymorphisms in the Genes for Herpesvirus Entry Mediator, Nectin‐1, and Nectin‐2 in Immune Seronegative Individuals
Development of an interferon-gamma ELISPOT assay to detect human T cell responses to HSV-2
CTL Are Inactivated by Herpes Simplex Virus-Infected Cells Expressing a Viral Protein Kinase
Detailed Characterization of T Cell Responses to Herpes Simplex Virus-2 in Immune Seronegative Persons
Diversity of the CD8(+) T-Cell Response to Herpes Simplex Virus Type 2 Proteins among Persons with Genital Herpes
Cytolytic T cells play a major role in controlling herpes simplex virus type 2 (HSV-2) infections in humans. In an effort to more thoroughly evaluate the response to HSV-2 directly, ex vivo, we developed an enzyme-linked immunospot (ELISPOT) assay that utilized pools of overlapping synthetic peptides presented by autologous dendritic cells to purified CD8(+) T cells. Donor response rates to individual open reading frames (ORFs) ranged from fewer than 5% responding to as many as 70% responding, with the greatest frequency of responses (by ORF) being directed against UL39, UL25, UL27, ICP0, UL46, and UL47 in descending order of frequency. HSV-2-seropositive subjects responded to as few as 3 or as many as 46 of the 48 ORFs tested, with a median of 11 ORFs recognized. HLA-B*07 expression correlated with stronger responses overall that were directed primarily against UL49 and UL46. Cumulative precursor frequencies in the blood ranged from 500 to almost 6,000 HSV-2 spot-forming units/10(6) CD8(+) T cells. The magnitude and breadth of the response in the infected population were greater than previously appreciated. Whether this variability in the CD8(+) T-cell response within individuals is associated with the frequency of viral reactivation warrants further study
Extensive CD4 and CD8 T Cell cross-reactivity between alphaherpesviruses
The alphaherpesvirinae subfamily includes HSV types 1 and 2 and the sequence-divergent pathogen varicella zoster virus (VZV). T cells, controlled by TCR and HLA molecules that tolerate limited epitope amino acid variation, might cross-react between these microbes. We show that memory PBMC expansion with either HSV or VZV enriches for CD4 T cell lines that recognize the other agent at the whole virus, protein, and peptide levels, consistent with bi-directional cross-reactivity. HSV-specific CD4 T cells recovered from HSV seronegative persons can be partially explained by such VZV cross-reactivity. HSV-1-reactive CD8 T cells also cross-react with VZV-infected cells, full-length VZV proteins, and VZV peptides, and kill VZV-infected dermal fibroblasts. Mono- and cross-reactive CD8 T cells use distinct TCRB CDR3 sequences. Cross-reactivity to VZV is reconstituted by cloning and expressing TCRA/TCRB receptors from T-cells that are initially isolated using HSV reagents. Overall, we define 13 novel CD4 and CD8 HSV-VZV cross-reactive epitopes and strongly imply additional cross-reactive peptide sets. Viral proteins can harbor both CD4 and CD8 HSV/VZV cross-reactive epitopes. Quantitative estimates of HSV/VZV cross-reactivity for both CD4 and CD8 T cells vary from 10-50%. Based on these findings, we hypothesize host herpesvirus immune history may influence the pathogenesis and clinical outcome of subsequent infections or vaccinations for related pathogens, and that cross-reactive epitopes and TCRs may be useful for multi-alphaherpesvirus vaccine design and adoptive cellular therapy