The high-content screening approach for the identification of miRs with therapeutic potential in head and neck cancer

Like many solid cancers, in head and neck cancer (HNC) the presence of metastases is an important factor of poor prognosis. To date, studies indicate that, in the tumor inflammatory microenvironment, stimulation with Tumor Necrosis Factor Alpha (TNF-?) leads to the activation of different molecular pathways, such as the Nuclear Factor-Kappa B (NF-kB) and PI3K/AKT pathway, inhibiting GSK3? and the degradation of SNAIL and beta-catenin, stabilizing them promoting their nuclear translocation. In general, in several types of cancer, while beta-catenin acts to promote cell proliferation, members of the SNAIL family induce the epithelial-mesenchymal (EMT) transition process. It is known that EMT events are involved both in the initiation of metastases and generation of cancer stem cells (CSCs), which in turn are associated with therapeutic failure and relapse, due to its properties that confer resistance to conventional treatments. By silencing gene expression in a post-transcriptional fashion, microRNAs (miRs) have been associated with the regulation of both EMT and CSCs generation. Using the HighContent Screening (HCS) approach, we sought to investigate the ability of a group of 30 human miRs, many of them involved in inflammatory pathways and pluripotency, to modulate aspects related to cell survival and EMT, in a HNSCC-derived cell line (FADU) under inflammatory stimuli. Initially, we evaluated the potential of TNF-? in modulating morphometric parameters, as well as the presence/location of EMT-related proteins and migratory capacity. Subsequently, we evaluated the effect of miRs mimetic molecules on suppressing or potentiating cell survival and EMT in TNF-?-stimulated cells, followed by the identification of predicted target transcripts (as well as signaling pathways enriched for these targets) commonly targeted by groups of miRs that led to similar multiparametric changes. Overall, miRs that targeted RELA and AKT2/AKT3 were responsible for the reduction in cell proliferation and EMT, while the opposite was observed in miRs that targeted GSK3B and ARHGAP5 (RhoA inhibitor). Gene silencing by specific siRNAs against RELA and CTNNB1 caused a reduction in cell survival, while silencing of AKT1 and CTNNB1 led to reduced protein expression of SNAIL/SLUG. Finally, the silencing of RELA, AKT1, GSK3B and CTNNB1 led to a reduction in cell survival and induction of apoptosis even in the absence of TNF-? stimulation. As a whole, we demonstrated that the HCS approach allowed the identification of miRs with similar phenotypic effects (in the context of proliferation and EMT) and that the prediction of targets shared by these miRs led to the identification of relevant targets and signaling pathways from the therapeutic point of view. (AU)