Natural killer cell mediated missing-self recognition can protect mice from primary chronic myeloid leukemia in vivo.

BACKGROUND: Natural Killer (NK) cells are thought to protect from residual leukemic cells in patients receiving stem cell transplantation. However, multiple retrospective analyses of patient data have yielded conflicting conclusions regarding a putative role of NK cells and the essential NK cell recognition events mediating a protective effect against leukemia. Further, a NK cell mediated protective effect against primary leukemia in vivo has not been shown directly. METHODOLOGY/PRINCIPAL FINDINGS: Here we addressed whether NK cells have the potential to control chronic myeloid leukemia (CML) arising based on the transplantation of BCR-ABL1 oncogene expressing primary bone marrow precursor cells into lethally irradiated recipient mice. These analyses identified missing-self recognition as the only NK cell-mediated recognition strategy, which is able to significantly protect from the development of CML disease in vivo. CONCLUSION: Our data provide a proof of principle that NK cells can control primary leukemic cells in vivo. Since the presence of NK cells reduced the abundance of leukemia propagating cancer stem cells, the data raise the possibility that NK cell recognition has the potential to cure CML, which may be difficult using small molecule BCR-ABL1 inhibitors. Finally, our findings validate approaches to treat leukemia using antibody-based blockade of self-specific inhibitory MHC class I receptors.

The function of natural killer cells: education, reminders and some good memories.

The effector response of natural killer (NK) cells is determined by opposing signals received through activating and inhibitory receptors. A process termed NK cell education, which is guided by the recognition of Major Histocompatibility Complex class I (MHC-I) molecules, determines how efficiently activating receptors respond to stimulation. This ensures NK cell tolerance to healthy tissues while allowing robust responses to diseased host cells. It was thought that NK cells are educated during their development in the bone marrow and that education fixes the NK cells' functional properties. However, recent findings suggest that the function of mature peripheral NK cells can adapt to changes in their environment and that the persistent exposure to normal-self is essential to maintain NK cell reactivity. Notwithstanding, NK cell stimulation in the context of inflammation can stably improve the functional properties of NK cells.

Jagged1 suppresses collagen-induced arthritis by indirectly providing a negative signal in CD8+ T cells.

Distinct Notch ligands possess a characteristic ability in terms of functional T cell differentiation. However, the precise role or the therapeutic potential of each Notch ligand in autoimmune diseases is largely unknown. In this study, we examined whether Jagged1 modulates a collagen-induced rheumatoid arthritis (CIA) model by altering T cell responses. The injection of a soluble Jagged1-encoding plasmid, sJag1-P, before or even after initial type II collagen (CII) immunization suppressed the disease severity of CIA. However, this treatment did not suppress CII-specific CD4(+) T cell proliferation and CII-specific Ab production. Depletion of either CD4(+) or CD8(+) T cells ameliorated CIA severity and sJag1-P further improved CIA in CD4(+) but not CD8(+) T cell-depleted mice. Injection of OVA and Jagged1-encoding plasmids inhibited proliferation of OVA-specific granzyme B-producing CD8(+) T cells, although Jagged1 could not directly inhibit CD8(+) T cell proliferation in vitro. The blockade of Jagged1 by an anti-Jagged1 Ab exacerbated CIA, whereas this effect was not observed in the absence of CD8(+) T cells. These data indicate that Jagged1 is able to deliver an indirect negative signal into CD8(+) T cells in vivo, which suggests its therapeutic potential in the treatment of CD8(+) T cell-mediated diseases, including rheumatoid arthritis.

Dendritic cell-mediated NK cell activation is controlled by Jagged2-Notch interaction.

Natural killer (NK) cells regulate various immune responses by exerting cytotoxic activity or secreting cytokines. The interaction of NK cells with dendritic cells (DC) contributes to NK cell-mediated antitumor or antimicrobial responses. However, the cellular and molecular mechanisms for controlling this interaction are largely unknown. Here, we show an involvement of Jagged2-Notch interaction in augmenting NK cell cytotoxicity mediated by DC. Enforced expression of Jagged2 on A20 cells (Jag2-A20 cells) suppressed their growth in vivo, which was abrogated by depleting NK cells. Moreover, Jag2-A20 cells exerted a suppression on the growth of nonmanipulated A20 cells in SCID mice in an NK-dependent manner. Consistently, coinoculation of A20 cells with DC overexpressing Jagged2 (Jag2-DC) suppressed the growth of A20 cells in mice. Stimulation of NK cells with Jagged2 directly enhanced their cytotoxicity, IFN-gamma production, and proliferation. Ligation of Notch2 on NK cells enhanced their cytotoxic activity, and Jag2-DC or CpG-treated DC-mediated NK cell cytotoxicity was suppressed by a gamma-secretase inhibitor. These results indicate that the Jagged2-Notch axis plays a crucial role in DC-mediated NK cell cytotoxicity. Furthermore, manipulation of this interaction may provide an approach to induce potent tumor immunity or to inhibit certain autoimmune diseases caused by NK cell activation.

Interleukin-2 augmented activation of tumor associated macrophage plays the main role in MHC class I in vivo induction in tumor cells that are MHC negative in vitro.

The contribution of tumor associated macrophage (TAM) to the induction of major histocompatibility complex (MHC) class I expression in vivo has not been reported precisely. In this study, we utilized Interleukin-2 (IL-2) cDNA-introduced B16 melanoma cells (B16/IL-2) and vehicle-alone control cells (B16/mock) to examine whether TAM could contribute to the induction of MHC class I on B16 cells in vivo. Interestingly, although B16/mock and B16/IL-2 did not express MHC class I in vitro, MHC class I was strongly expressed in vivo in B16/IL-2 in comparison to B16/mock. Although in vivo treatment of anti-NK1.1 antibody abolished MHC expression in B16/mock in vivo, the same treatment did not influence MHC expression in B16/IL-2. Interestingly, both anti-asialo GM1 and anti-CD11b treatment strongly decreased MHC expression in B16/IL-2. TAM expressed both asialo GM1 and CD11b antigen, and TAM recovered from B16/IL-2 produced interferon gamma (IFNgamma) 6 times more than that from B16/mock. In addition, TAM recovered from B16/IL-2 secreted 33.64 times more IFNgamma in response to in vitro administration of IL-2. Therefore, we checked whether or not IL-2 could influence the expression of IL-2 receptors. TAM recovered from IL-2 expressed middle affinity receptor of IL-2 (CD122 and CD132) while that from B16/mock expressed low affinity receptor (CD25 and CD132). Finally, we observed that B16 cells became apoptotic with IFNgamma treatment in vitro. These results suggested that IL-2 augmented activation of TAM would play the main role in induction of the MHC class I molecule through secretion of IFNgamma, and would contribute to the IFNgamma-mediated apoptosis induction in tumor cells.

Natural killer cells play a role in MHC class I in vivo induction in tumor cells that are MHC negative in vitro.

The natural killer (NK) cell is one of the key cells in discriminating major histocompatibility complex (MHC) negative 'missing-self' target tumor cells, and interleukin 2 (IL-2) treatment was effective in inducing NK cell activation. In this study, we tried to clarify how poorly-immunogenic murine B16 melanoma could be discriminated in vivo by creating an IL-2 cDNA-transduced immunogene therapy model (B16/IL-2). In vitro study showed that IL-2 introduction did not induce MHC class I. However, immune cells depleted total tumor digest, which consisted of 90% anti-melanoma MM2-9B6-positive cells that revealed B16/IL-2 strongly, and control tumor cells (B16/mock) partially expressed MHC class I in vivo. In the B16/IL-2 model, NK cell infiltration was 10 times higher than B16/mock (7.6 versus 0.73, p=0.017). In addition, the cell surface of CD69-expressing NK cell population was increased in B16/IL-2, and the interferon gamma (IFNgamma) message level in NK cells was significantly increased in B16/IL-2 (p=0.0359). Interestingly, NK cell depletion in vivo completely abolished MHC class I expression on B16/mock, and decreased MHC class I expression and T-cell infiltration in B16/IL-2. These data suggest that NK cells are not only important for missing-self recognition, but are also crucial for induction of tumor cell MHC molecule expression and play an important role in helping acquired immunity to recognize tumor cells.

In situ detection of O6-methylguanine-DNA methyltransferase messenger RNA in paraffin-embedded human astrocytic tumor tissues by nested in situ RT-PCR is useful in predicting chemotherapy-resistance of tumors.

O6-methylguanine-DNA methyltransferase (MGMT) is an enzyme that interferes with chemotherapeutic effect of alkylating agents. We performed in situ detection of MGMT mRNA utilizing the nested RT-PCR method in tissue sections (nested in situ RT-PCR). We analyzed 34 samples of paraffin-embedded astrocytic tumor tissue sections with this method [3 astrocytomas, 14 anaplastic astrocytomas (AA), and 17 glioblastoma multiformes (GBM)]. Twenty-five cases (73.5% of all cases) were positive for MGMT either with our method or immunohistochemistry (IHC). Moreover, with our method >25% of the cells in the tumor tissue expressed MGMT in contrast to >4% with IHC among the population of MGMT positive cases. Our method was significantly more sensitive than IHC (p=0.0004). The present results suggest that potentially there is a greater population of MGMT positive cells in astrocytic tumor tissues than the one evaluated with IHC. These findings suggest that the >25% of the MGMT positive cells are involved in the interference with the chemotherapeutic effect of alkylating agents. The MGMT expressing cell population was markedly decreased in GBM compared with AA (26.1% vs 62.1%). The main reason for this marked decrease was that MGMT was expressed in only 9 of 17 cases of GBM in contrast to all AA cases that expressed MGMT. This result suggests that there are potentially two populations of GBM on the basis of MGMT expression, in which the negative population might be mainly composed of de novo GBM. Therefore, it is suggested that our method is practically useful to detect any drug resistance gene product with high sensitivity and would provide a chance to evaluate the chemotherapeutic effect of any agents in an individual patient based manner.