AbstractNPM‐ALK chimeric oncogene is aberrantly expressed in an aggressive subset of T‐cell lymphomas that frequently occurs in children and young adults. The mechanisms underlying the oncogenic effects of NPM‐ALK are not completely elucidated. Inducible nitric oxide synthase (iNOS) promotes the survival and maintains the malignant phenotype of cancer cells by generating NO, a highly active free radical. We tested the hypothesis that iNOS is deregulated in NPM‐ALK+ T‐cell lymphoma and promotes the survival of this lymphoma. In line with this possibility, an iNOS inhibitor and NO scavenger decreased the viability, adhesion, and migration of NPM‐ALK+ T‐cell lymphoma cells, and an NO donor reversed these effects. Moreover, the NO donor salvaged the viability of lymphoma cells treated with ALK inhibitors. In further support of an important role of iNOS, we found iNOS protein to be highly expressed in NPM‐ALK+ T‐cell lymphoma cell lines and in 79% of primary tumours but not in human T lymphocytes. Although expression of iNOS mRNA was identified in NPM‐ALK+ T‐cell lymphoma cell lines and tumours, iNOS mRNA was remarkably elevated in T lymphocytes, suggesting post‐transcriptional regulation. Consistently, we found that miR‐26a contains potential binding sites and interacts with the 3'‐UTR of iNOS. In addition, miR‐26a was significantly decreased in NPM‐ALK+ T‐cell lymphoma cell lines and tumours compared with T lymphocytes and reactive lymph nodes. Restoration of miR‐26a in lymphoma cells abrogated iNOS protein expression and decreased NO production and cell viability, adhesion, and migration. Importantly, the effects of miR‐26a were substantially attenuated when the NO donor was simultaneously used to treat lymphoma cells. Our investigation of the mechanisms underlying the decrease in miR‐26a in this lymphoma revealed novel evidence that STAT3, a major downstream substrate of NPM‐ALK tyrosine kinase activity, suppresses MIR26A1 gene expression. Copyright © 2013 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.