MicroRNA-137 and its downstream target LSD1 inversely regulate anesthetics-induced neurotoxicity in dorsal root ganglion neurons

PURPOSE

Anesthetic reagents, such as bupivacaine (Bv), induce significant neurotoxicity in dorsal root ganglion neurons (DRGNs). In this study, we investigated the expression, function and cross-association of microRNA-137-3p (miR-137-3p) and lysine (K)-specific demethylase 1A (LSD1) in a murine model of Bv-induced neural injury in DRGNs.

METHODS

Murine DRGNs were culture in vitro and treated with Bv. QPCR was used to evaluate miR-137-3p expression in Bv-injured DRGNs. MiR-137-3p was genetically downregulated to evaluate its rescuing effect on Bv-induced DRGN apoptosis and neurite retraction. The association of miR-137-3p on its downstream target, LSD1 coding gene KDM1A, was evaluated by dual-luciferase activity assay and qPCR. In miR-137-3p-downregulated DRGNs, KDM1A was inhibited to evaluate its involvement in miR-137-3p-mediated modulation on Bv-induced DRGN neurotoxicity. Furthermore, KDM1A expression in Bv-injured DRGN was evaluated by qPCR, and LSD1 was overexpressed in DRGN to evaluate its direct effect on Bv-induced neurotoxicity.

RESULTS

MiR-137-3p was upregulated in Bv-injured DRGNs. MiR-137-3p downregulation rescued Bv-induced DRGN apoptosis and neurite retraction. LSD1 was demonstrated to be downstream to, and inversely modulated by miR-137-3p in DRGN. In Bv-injured DRGNs, LSD1 downregulation reversed miR-137-3p-downregualtion-induced neural protection. Furthermore, LSD1 upregulation directly rescued Bv-induced apoptosis and neurite retraction in DRGNs.

CONCLUSIONS

MiR-137-3p and its downstream target LSD1 are inversely associated to regulate anesthetics-induced neurotoxicity in DRGN. This signaling pathway may be a therapeutic candidate to reduce anesthetics-induced neurological damage in human patients.

Cdon, a cell surface protein, mediates oligodendrocyte differentiation and myelination

During central nervous system development, oligodendrocyte progenitors (OLPs) establish multiple branched processes and axonal contacts to initiate myelination. A complete understanding of the molecular signals implicated in cell surface interaction to initiate myelination/remyelination is currently lacking. The objective of our study was to assess whether Cdon, a cell surface protein that was shown to participate in muscle and neuron cell development, is involved in oligodendrocyte (OLG) differentiation and myelination. Here, we demonstrate that endogenous Cdon protein is expressed in OLPs, increasing in the early differentiation stages and decreasing in mature OLGs. Immunocytochemistry of endogenous Cdon showed localization on both OLG cell membranes and cellular processes exhibiting puncta- or varicosity-like structures. Cdon knockdown with siRNA decreased protein levels by 62% as well as two myelin-specific proteins, MBP and MAG. Conversely, overexpression of full-length rat Cdon increased myelin proteins in OLGs. The complexity of OLGs branching and contact point numbers with axons were also increased in Cdon overexpressing cells growing alone or in coculture with dorsal root ganglion neurons (DRGNs). Furthermore, myelination of DRGNs was decreased when OLPs were transfected with Cdon siRNA. Altogether, our results suggest that Cdon participates in OLG differentiation and myelination, most likely in the initial stages of development.