A High-Throughput Screening Identifies MicroRNA Inhibitors That Influence Neuronal Maintenance and/or Response to Oxidative Stress
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Small non-coding RNAs (sncRNAs), including microRNAs
(miRNAs) are important post-transcriptional gene expression
regulators relevant in physiological and pathological processes.
Here, we combined a high-throughput functional screening
(HTFS) platform with a library of antisense oligonucleotides
(ASOs) to systematically identify sncRNAs that affect neuronal
cell survival in basal conditions and in response to oxidative
stress (OS), a major hallmark in neurodegenerative diseases.
We considered hits commonly detected by two statistical
methods in three biological replicates. Forty-seven ASOs targeting miRNAs (miRNA-ASOs) consistently decreased cell
viability under basal conditions. A total of 60 miRNA-ASOs
worsened cell viability impairment mediated by OS, with
36.6% commonly affecting cell viability under basal conditions.
In addition, 40 miRNA-ASOs significantly protected neuronal
cells from OS. In agreement with cell viability impairment,
damaging miRNA-ASOs specifically induced increased free
radical biogenesis. miRNAs targeted by the detrimental ASOs
are enriched in the fraction of miRNAs downregulated by
OS, suggesting that the miRNA expression pattern after OS
contributes to neuronal damage. The present HTFS highlighted potentially druggable sncRNAs. However, future
studies are needed to define the pathways by which the identified ASOs regulate cell survival and OS response and to explore
the potential of translating the current findings into clinical
applications