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. 1997 Mar;71(3):2252–2263. doi: 10.1128/jvi.71.3.2252-2263.1997

Functional phenotype of transformed human alphabeta and gammadelta T cells determined by different subgroup C strains of herpesvirus Saimiri.

H Fickenscher 1, C Bökel 1, A Knappe 1, B Biesinger 1, E Meinl 1, B Fleischer 1, B Fleckenstein 1, B M Bröker 1
PMCID: PMC191333  PMID: 9032360

Abstract

Based on sequence divergence in the transformation-relevant region, herpesvirus saimiri strains are classified into three subgroups. Only members of subgroup C transform human T lymphocytes to continuous interleukin-2-dependent growth in culture. In this study, human cord blood T cells were immortalized by using different subgroup C strains (C488, C484, and C139). The resulting T-cell lines represented different types of T-cell clones. They were either CD4+ or CD8+ and expressed either the alphabeta or the gammadelta type of T-cell receptors. If transformed by the same virus strain, alphabeta and gammadelta clones were similar with respect to viral persistence, virus gene expression, proliferation, and Th1-type cytokine production. However, major differences were observed in T cells immortalized by different subgroup C strains. Strain C139 persisted at low copy number, compared to the high copy number of prototype C488. The transformation-associated genes stpC and tip of strain C488 were strongly induced after T-cell stimulation. The homologous genes of strain C139 were only weakly expressed and not induced after activation. After CD2 ligation, the C488-transformed T cells produced interleukin-2, whereas the C139-transformed cells did not. Correspondingly, the C139-transformed T cells were less sensitive to cyclosporin A. Sequence comparison from different subgroup C strains revealed a variability of the stpC/tip promoter region and of the Lck-binding viral protein Tip. Thus, closely related subgroup C strains of herpesvirus saimiri cause major differences in the functional phenotype of growth-transformed human T cells.

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Selected References

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