Knowledge of human NK cells is based primarily on conventional CD56bright and CD56dim NK cells from blood. However, most cellular immune interactions occur in lymphoid organs. Based on the coexpression of CD69 and CXCR6, we identified a third major NK cell subset in lymphoid tissues. This population represents 30–60% of NK cells in marrow, spleen, and lymph node but is absent from blood. CD69+CXCR6+ lymphoid tissue NK cells have an intermediate expression of CD56 and high expression of NKp46 and ICAM-1. In contrast to circulating NK cells, they have a bimodal expression of the activating receptor DNAX accessory molecule 1. CD69+CXCR6+ NK cells do not express the early markers c-kit and IL-7Rα, nor killer cell Ig-like receptors or other late-differentiation markers. After cytokine stimulation, CD69+CXCR6+ NK cells produce IFN-γ at levels comparable to CD56dim NK cells. They constitutively express perforin but require preactivation to express granzyme B and exert cytotoxicity. After hematopoietic stem cell transplantation, CD69+CXCR6+ lymphoid tissue NK cells do not exhibit the hyperexpansion observed for both conventional NK cell populations. CD69+CXCR6+ NK cells constitute a separate NK cell population with a distinct phenotype and function. The identification of this NK cell population in lymphoid tissues provides tools to further evaluate the cellular interactions and role of NK cells in human immunity.
Human lymphoid tissues harbor, in addition to CD56bright and CD56dim natural killer (NK) cells, a third NK cell population: CD69+CXCR6+ lymphoid tissue (lt)NK cells. The function and development of ltNK cells remain poorly understood. In this study, we performed RNA sequencing on the three NK cell populations derived from bone marrow (BM) and blood. In ltNK cells, 1,353 genes were differentially expressed compared to circulating NK cells. Several molecules involved in migration were downregulated in ltNK cells: S1PR1, SELPLG and CD62L. By flow cytometry we confirmed that the expression profile of adhesion molecules (CD49e−, CD29low, CD81high, CD62L−, CD11c−) and transcription factors (Eomeshigh, Tbetlow) of ltNK cells differed from their circulating counterparts. LtNK cells were characterized by enhanced expression of inhibitory receptors TIGIT and CD96 and low expression of DNAM1 and cytolytic molecules (GZMB, GZMH, GNLY). Their proliferative capacity was reduced compared to the circulating NK cells. By performing gene set enrichment analysis, we identified DUSP6 and EGR2 as potential regulators of the ltNK cell transcriptome. Remarkably, comparison of the ltNK cell transcriptome to the published human spleen-resident memory CD8+ T (Trm) cell transcriptome revealed an overlapping gene signature. Moreover, the phenotypic profile of ltNK cells resembled that of CD8+ Trm cells in BM. Together, we provide transcriptional and phenotypic data that clearly distinguish ltNK cells from both the CD56bright and CD56dim NK cells and substantiate the view that ltNK cells are tissue-resident cells, which are functionally restrained in killing and have low proliferative activity.
Background: Immunotherapy may be a rational strategy in leiomyosarcoma (LMS), a tumor known for its genomic complexity. As a prerequisite for therapeutic applications, we characterized the immune microenvironment in LMS, as well as its prognostic value. Methods: CD163+ macrophages, CD3+ T-cells, PD-L1/PD-L2 and HLA class I expression (HCA2, HC10 and β2m) were evaluated using immunohistochemistry in primary tumors (n = 75), local relapses (n = 6) and metastases (n = 19) of 87 LMS patients, as well as in benign leiomyomas (n = 7). Correlation with clinicopathological parameters and survival analyses were assessed. Effect of LMS cells on macrophage differentiation was investigated using coculture of CD14+ monocytes with LMS cell lines or their conditioned media (CM). Results: 58% and 52% of the tumors were highly infiltrated with CD163+ macrophages and T-cells, respectively, with HLA class I expression observed in almost all tumors and PD-L1 expression in 30%. PD-L2 expression was also detected in some PD-L1+ tumors. All these immune markers correlated with high tumor grade but only CD163 associated with overall survival (p = 0.003) and disease-specific survival (p = 0.041). In vitro, CD163 was upregulated in the presence of LMS cells producing M-CSF, suggesting that this tumor drives macrophages towards the M2 phenotype. Conclusion: The clinical significance of M2 macrophages, possibly induced by LMS cell-secreted factors, suggests that 2/3 of high-grade LMS patients might benefit from macrophage-targeting agents. Furthermore, PD-L1 expression together with high T-cell infiltrate and HLA class I expression in around 30% of high grade LMS reflects an active immune microenvironment potentially responsive to immune checkpoint inhibitors.
Cell-based immunotherapy using donor-derived natural killer (NK) cells after allogeneic hematopoietic stem cell transplantation may be an attractive treatment of residual leukemia. This study aimed to optimize clinical grade production of a cytokine-activated NK-cell product. NK cells were isolated either by double depletion (CD3(-), CD19(-)) or by sequential depletion and enrichment (CD3(-,) CD56(+)) via CliniMACS from leukapheresis material and cultured in vitro with interleukin (IL)-2 or IL-15. Both NK cell isolation procedures yielded comparable recovery of NK cells and levels of T-cell contamination. After culture with cytokines, the CD3(-)CD56(+) procedure resulted in NK cells of higher purity, that is, less T cells and monocytes, higher viability, and a slightly higher yield than the CD3(-)CD19- procedure. CD69, NKp44, and NKG2A expression were higher on CD3(-)CD56(+) products, whereas lysis of Daudi cells was comparable. Five days of culture led to higher expression of CD69, NKp44, and NKp30 and lysis of K562 and Daudi cell lines. Although CD69 expression and lysis of Daudi cells were slightly higher in cultures with IL-2, T-cell contamination was lower with IL-15. Therefore, further experiments were performed with CD3(-)CD56(+) products cultured with IL-15. Cryopreservation of IL-15-activated NK cells resulted in a loss of cytotoxicity (>92%), whereas thawing of isolated, uncultured NK cells followed by culture with IL-15 yielded cells with about 43% of the original lytic activity. Five-day IL-15-activated NK cells lysed tumor target cell lines and primary leukemic blasts, providing the basis for NK cell–based immunotherapeutic strategies in a clinical setting.
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