The miRSodium project’s findings on how miRNAs control sodium ion channels is important for DS and other epilepsies. Our analyses disclosed that miRNAs control the gene expression differently in the brains of mice at different ages between birth and day 22 (in both DS and control mice). This brings us closer to the understanding of gene expression regulation in the young postnatal brain. The differences in miRNA regulation observed in animals after DS onset (and the detected sex-specific alterations) point towards altered mechanisms in the DS brain beyond the sodium channel mutation. Importantly, we confirmed that sodium channel subunits as well as other genes relevant for epilepsy are regulated by miRNAs in young brains before and during the onset of DS. While miRNAs exert control over sodium channels, our data indicate that rather than triggering the transition between Scn1a and Scn3a, miRNAs fine-tune the expression of these genes. To unlock the potential to intervene with their transition, additional mechanisms of gene expression regulation (e.g. epigenetic manipulations, long RNAs with regulatory functions or activity of protein regulators) need to be addressed by future research.
We validated the control over sodium channels Scn1a and Scn3a for five miRNAs, opening up their potential use for manipulation of sodium channel levels in DS and other sodium channel-related pathologies (e.g. neuropathic pain). While we did not observe the improvement of DS symptoms in mice undergoing treatment with miRNA inhibitors, we detected an increase in sodium channel expression in these mice, proving that miRNA manipulation can adjust levels of these channels in the brain. Further investigation is needed to explore if the miRNA-based increase of sodium channel expression can achieve favourable outcomes in DS. We will continue this work and apply for funding for a follow-up project(s) focused on the deeper scrutiny of miRNA manipulation of sodium channels in DS (testing a wider range of miRNA inhibitor doses, testing additional routes of administration or investigating additional miRNA candidates) and investigation of both short-term and long-term outcomes in the mouse model.
Via completion of the miRSodium MSCA PF, the postdoctoral fellow gained experience with the state-of-the-art research methodology in the area of neuroscience as well as skills and competencies essential for research career progression, including project management, leadership and innovation and established a rich network of (potential) collaborators.