3E) These data indicated that the activated phenotype of NK cell

3E). These data indicated that the activated phenotype of NK cells was determined by MHC class I down-regulation

rather than by NKG2D-L levels expressed on early-stage tumors. Nevertheless, the higher MHC class I and lower NKG2D-L expression levels found in late tumor stages suggested that both, MHC class I MK-2206 cost recovery and loss of NKG2D-L, may provide mechanisms of immune escape. To directly test the role of NKG2D-L loss in immune escape, we established cell lines from lymphoma-bearing mice with reduced MHC class I expression and selected variants with different NKG2D-L levels. Cell line myc-E showed background levels of NKG2D-L. In contrast, cell line myc-B had a 20-fold enhanced expression of NKG2D-L (Fig. 4A). After transfer into naïve WT mice, the myc-B line grew out slowly PLX-4720 nmr and was even rejected in 50% of the animals. In contrast, all mice injected with myc-E cells rapidly succumbed to tumor growth (Fig. 4B). Importantly, when NKG2D-L on myc-B cells were blocked with NKG2D multimers

prior to injection, protection was lost, and mice died as rapidly as those receiving the myc-E line. Protection against myc-B was also abrogated by NK-cell depletion (Fig. 4B). The data show that in these cell lines showing low MHC class I levels, expression of NKG2D-L is a signal that is required for NK cell-mediated elimination of tumor cells. To test the hypothesis that tumor escape from NK-cell surveillance results from re-expression of MHC class I and from suppression of NKG2D-L, we analyzed the outgrowing lymphomas in mice having received cell line myc-B. Indeed, the tumor cells that grew out after challenge with MHC

class Ilow/NKG2D-Lhigh myc-B cells were converted to MHC class Ihigh/NKG2D-Llow cells (Fig. 4C). NK cells isolated upon growth of myc-B also showed an activated status and decreased NKG2D expression (data not shown). The data demonstrate that tumor progression is not only due to exhaustion or paralysis of NK cells following their initial activation, as described above. In addition, loss of NKG2D-L as well as recovery of MHC class I on tumor cells contribute to escape from NK-cell surveillance. Protection from NK-cell attack and the NKG2D modulation observed on NK cells from tumor-bearing mice 4��8C might be an effect of NKG2D-L shedded from tumor cells. In two different assay systems (See the Materials and methods section), there was no evidence for the presence of soluble NKG2D-L in sera from tumor mice (Supporting Information), but a clear NKG2D down-regulation was seen when WT NK cells were incubated with ligand-expressing lymphoma cells in vitro (Fig. 4D). If NKG2D-L expression is needed for tumor elimination (Fig. 4B, C) although it was not correlated with the expression of NK-cell activation markers (Fig.

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