The aim of this study was to examine the effect of cytokines on different subsets of NK cells, while especially focusing on CD16− CD56dim cells and CD16− CD56bright cells. When human peripheral blood mononuclear cells (PBMC) were cultured with a combination of IL‐2, IL‐12 and IL‐15 for several days, a minor population of CD56bright NK cells expanded up to 15%, and also showed potent cytotoxicities against various cancer cells. Sorting experiments revealed that unconventional CD16− CD56+ NK cells (CD16− CD56dim NK cells and CD16− CD56bright NK cells, both of which are less than 1% in PBMC) much more vigorously proliferated after cytokine stimulation, whereas predominant CD16+ CD56dim NK cells proliferated poorly. In addition, many of the resting CD16− CD56bright NK cells developed into CD16+ CD56bright NK cells, and CD16− CD56dim NK cells developed into CD16− CD56bright NK cells and also further into CD16+ CD56bright NK cells by the cytokines. CSFE label experiments further substantiated the proliferation capacity of each subset and the developmental process of CD16+ CD56bright NK cells. Both CD16− CD56dim NK cells and CD16− CD56bright NK cells produced large amounts of IFN‐γ and Fas‐ligands. The CD16+ CD56bright NK cells showed strong cytotoxicities against not only MHC class I (−) but also MHC class I (+) tumours regardless of their expression of CD94/NKG2A presumably because they expressed NKG2D as well as natural cytotoxicity receptors. The proliferation of CD16+ CD56bright NK cells was also induced when PBMC were stimulated with penicillin‐treated Streptococcus pyogenes, thus suggesting their role in tumour immunity and bacterial infections.
The identification of genes that participate in melanomagenesis should suggest strategies for developing therapeutic modalities. We used a public array comparative genomic hybridization (CGH) database and real-time quantitative PCR (qPCR) analyses to identify the AMP kinase (AMPK)-related kinase NUAK2 as a candidate gene for melanomagenesis, and we analyzed its functions in melanoma cells. Our analyses had identified a locus at 1q32 where genomic gain is strongly associated with tumor thickness, and we used real-time qPCR analyses and regression analyses to identify NUAK2 as a candidate gene at that locus. Associations of relapsefree survival and overall survival of 92 primary melanoma patients with NUAK2 expression measured using immunohistochemistry were investigated using Kaplan-Meier curves, log rank tests, and Cox regression models. Knockdown of NUAK2 induces senescence and reduces S-phase, decreases migration, and down-regulates expression of mammalian target of rapamycin (mTOR). In vivo analysis demonstrated that knockdown of NUAK2 suppresses melanoma tumor growth in mice. Survival analysis showed that the risk of relapse is greater in acral melanoma patients with high levels of NUAK2 expression than in acral melanoma patients with low levels of NUAK2 expression (hazard ratio = 3.88; 95% confidence interval = 1.44-10.50; P = 0.0075). These data demonstrate that NUAK2 expression is significantly associated with the oncogenic features of melanoma cells and with the survival of acral melanoma patients. NUAK2 may provide a drug target to suppress melanoma progression. This study further supports the importance of NUAK2 in cancer development and tumor progression, while AMPK has antioncogenic properties.sucrose nonfermenting-like kinase | chromosome 1q T he identification of genes that participate in melanomagenesis should suggest strategies for developing effective therapeutic modalities (1, 2). For more than three decades, cytogenetic analyses have been used to identify genes that have an impact on tumorigenesis (3). However, those cytogenetic analyses have had limited success in elucidating such genes in solid tumors such as malignant melanoma because of the complexity of chromosomal and genomic aberrations (4, 5). Recent advances in microarray technologies, including array-based comparative genomic hybridization (CGH), have allowed the genomic characterization of cancer cells in solid tumors (6-10). Gains of chromosome 1q are frequent events in many types of cancers, including breast cancer, medulloblastoma, retinoblastoma, hepatocellular carcinoma, nonsmall cell lung carcinoma, cervical cancer, and others (11-16). Cytogenetic studies have revealed that melanoma cells have several characteristic abnormalities including a recurring translocation involving chromosomes 1 and 6 that results in gains of chromosome 1q (17,18). We previously reported a CGH analysis which showed that gains of chromosomes 1q and 6p correlate strongly with the clinical outcome of patients with primary cutaneous melanomas (19).NUAK2 ...
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