Besides their role in destruction of altered self-cells, NK cells have been shown to potentiate T-cell responses by interacting with DC. To take advantage of NK-DC crosstalk in therapeutic DC-based vaccination for infectious diseases and cancer, it is essential to understand the biology of this crosstalk. We aimed to elucidate the in vitro mechanisms responsible for NK-cell recruitment and activation by DC during infection. To mimic bacterial infection, DC were exposed to a membrane fraction of Klebsiella pneumoniae, which triggers TLR2/4. DC matured with these bacterial fragments can actively recruit NK cells in a CCR5-dependent manner. An additional mechanism of DC-induced NK-cell recruitment is characterized by the induction of CCR7 expression on CD56 dim CD16 1 NK cells after physical contact with membrane fraction of K. pneumoniae-matured DC, resulting in an enhanced migratory responsiveness to the lymph node-associated chemokine CCL19. Bacterial fragment-matured DC do not only mediate NK-cell migration but also meet the prerequisites needed for augmentation of NK-cell cytotoxicity and IFN-c production, the latter of which contributes to Th1 polarization.Key words: CCR5 . CCR7 . NK-DC interaction . Th1 polarization Supporting Information available online Introduction NK cells are important effector cells in the innate immune response against virally infected or malignantly transformed cells and their cytotoxicity is regulated by a delicate balance of inhibitory and activating signals [1]. Recent studies suggest that the interplay between NK cells and DC, the specialized antigenpresenting cell of the innate immune system [2], is critical in shaping the adaptive immune response [3]. This concept originates from several lines of evidence including: the discovery of NK cells colocalizing with DC in the T-cell areas of lymph nodes [4,5], the coupling of NK-cell recruitment to lymph nodes à These authors contributed equally to this work. 3138with the induction of more potent Th1 skewing [3], and the identification of NK-cell subpopulations with helper properties [6]. Although the exact mechanisms of NK-DC interaction remain to be elucidated, increasing evidence supports the importance of bidirectional NK-DC crosstalk [7,8].On the one hand, NK-DC crosstalk is characterized by the capacity of activated NK cells to induce DC maturation with elevated IL-12p70 production and subsequently an increased capacity to induce Th1 and CTL responses [9]. This NK-induced DC maturation depends at least in part on soluble factors such as and as well as on engagement of the natural cytotoxicity triggering receptor 30 [12]. Moreover, NK cells control the quality of the adaptive immune response by natural cytotoxicity triggering receptor 30-mediated lysis of immature or inadequately matured DC [13], enabling only fully mature DC to migrate into lymph nodes and subsequently prime T cells. On the other hand, DC are able to induce NK-cell proliferation, augmentation of cytotoxicity and cytokine secretion [8]. The DC-induced modulati...
International audienceAims: Mucin 1 (MUC1) is an important tumour-associated antigen (TAA), both over-expressed and aberrantly glycosylated in adenocarcinomas. The objective of this study was to examine the MUC1-glycosylation status in primary ovarian adenocarcinomas and metastatic lesions. Methods and results: Paraffin-embedded tissue sections of 37 primary ovarian adenocarcinomas representing all histotypes (22 serous, 5 mucinous, 2 clear cell, 8 endometrioid), 4 serous borderline tumours with intraepithelial carcinoma, 7 sections of ovarian endometriosis and 13 metastatic lesions were analysed by immuno-histochemistry. Non-neoplastic ovarian surface epithelium and serous cystadenomas were used as controls. All epithelia expressed MUC1 protein. Of primary tumours, 76% expressed the differentiation-dependent glycoform and 84% the cancer-associated glycoform (Tn/Sialyl-Tn-epitopes). In metastatic lesions this was 77% and 85%, respectively. Notably, in 57% of ovarian endometriosis and 75% of intraepithelial lesions, the cancer-associated MUC1 epitopes were expressed, whereas normal ovarian surface epithelium and serous cystadenomas did not express these epitopes. Conclusions: The underglycosylated MUC1 epitopes are expressed by all histotypes of primary ovarian adenocarcinomas, by the vast majority of metastatic lesions and by ovarian cancer precursor lesions, whereas not by normal ovarian tissue. These results indicate that MUC1-associated Tn/STn-epitopes are important targets for immunotherapy and diagnostic imaging in ovarian cancer patients
Metastatic breast cancer is currently incurable despite initial responsiveness, assumingly due to the presence of chemoresistant subpopulations that can be characterized as label retaining cells (LRC). In the 4T1 mouse breast cancer model, we previously achieved cure after Cyclophosphamide and Total Body Irradiation (CY + TBI) followed by haploidentical bone marrow and spleen transplantation (BMSPLT). CY + TBI without transplantation induced only transient impaired tumor growth indicating a critical role of donor immune cells. As it remained unknown if the 4T1 model resembles human disease with respect to the presence of subpopulations of chemoresistant LRC, we now demonstrate this is indeed the case. Chemoresistance of 4T1 LRC was demonstrated by in vitro co-incubation of fluorescently labeled 4T1 cells in limiting dilution with cyclophosphamide, doxorubicin or cisplatinum, after which only LRC containing colonies remained. LRC also remain in vivo after treatment with CY + TBI. Succeeding experiments set up to identify the haploidentical effector cell responsible for cure and, therefore, for the elimination of chemoresistant LRC designate donor NK cells crucial for the anti-tumor effect. NK cell depletion of the haploidentical graft fully abrogated the anti-tumor effect. Increased disease-free survival retained after transplantation of haploidentical bone marrow and NK cell-enriched spleen cell grafts, even in the absence of donor T-cells or of donor bone marrow. Tumor growth analysis indicates the anti-tumor effect being immediate (days). Based on these data, it is worthwhile to explore alloreactive adoptive NK cell therapy as consolidation for patients with metastasized breast cancer.
2085 Background: Patients with metastasized breast cancer cannot be cured by current standard treatment options. One hypothesis is that slow cycling chemo-resistant tumor stem cells give rise to new tumors after cytoreductive treatment, ultimately leading to chemoresistant tumors. Last year we showed that the 4T1 mouse breast cancer model contains slow-cycling chemo-resistant cells that induce renewed growth of the tumor after chemo- and radiotherapy (abstract 4082). We also showed that haploidentical spleen and bone marrow transplantation (BMT) cures the mice and that donor NK cells are a prerequisite. Our current aim was to study the need of long term BM engraftment and to study the role of the conditioning in the curative process. Methods: The 4T1 breast cancer cell line, originating from a spontaneous Balb/c (H-2d) breast cancer, was cultured under standard conditions. Fifty thousand 4T1 cells were injected s.c. in the flank. For the experiments addressing the need for haploidentical BMT tumor bearing CB6F1 (H-2b/d) recipients were treated with 2x 2Gy total body irradiation and 200 mg/kg cyclophosphamide (CY+TBI) followed by in vitro NK cell enriched haploidentical B6CBAF1 (H-2b/k) spleen cell infusion with or without additional BM cells. Chimerism in tumor-free surviving recipients was measured by flowcytometry of spleens at least 100 days after the treatment. The role of the conditioning in the alloreactive NK cell effect was studied in fully H-2 mismatched B6CBAF1 mice. When indicated, in vivo NK cell depletion was by i.p. injection of anti-AsialoGM1. Results: Figure A shows overall survival of mice with breast cancer after various treatments (10 mice per group). Haploidentical BMT plus spleen cells cured 50% of tumor bearing mice after CY+TBI (♦, dashed line) and survival was at least as good when NK cell enriched spleen cells were co-transplanted (▴, solid line). Transplantation of spleen cells from NK cell depleted mice (•, dotted line) obliterated the beneficial effect of haploidentical transplantation and resulted is similar poor survival as syngeneic BMT plus spleen cells (▪, solid line). The majority of mice that received NK cell enriched spleen cells (10 out of 14 tested) had no bone marrow engraftment and in the other four only 1–5% donor cells were detectable at 150 days. Recipients of unmanipulated haploidentical spleen and BM cells had >90% donor chimerism in 10 out of 14 tested. The cure rate in both groups was nevertheless similarly high. In a subsequent experiment (Figure B, 10 mice per group) we infused haploidentical NK cells only after CY+TBI (▴, solid line); other groups received T cell depleted (x, solid line) or T cell replete (♦, solid line) haploidentical BMT, or syngeneic BMT (▪, solid line). This resulted in a similar superior tumor-free survival (80-90%) than in mice co-transplanted with haploidentical BM (90%), as compared with syngeneic BM and spleen cell transplantation (•, dotted line). We then planned to study the role of the conditioning in the curative process. For this purpose 4T1 breast cancer cells were injected in fully H-2 mismatched B6CBAF1 mice (H-2b/k). Surprisingly, 4T1 breast cancer is not rejected by B6CBAF1 mice despite the full MHC mismatch. Tumors are only rejected when the mice were treated with CY+TBI. Tumor rejection proved to be NK cell dependant and not a direct result of the conditioning as it was prevented by in vivo NK cell depletion. Conclusions: This report provides the first evidence that chemo resistant tumor cells can be eliminated in vivo by alloreactive NK cells resulting in cure without the need for long term donor bone marrow engraftment. Conditioning with CY+TBI seems essential for this effect. These results set the stage for the exploration of alloreactive NK therapy in patients with metastasized breast cancer. Disclosures: No relevant conflicts of interest to declare.
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