GM1-oligosaccharide rescues rotenone-impaired neuronal polarization through RhoA/ROCK modulation and mitochondrial protection

Abstract

Neuronal polarization is a fundamental process in the formation of functional neural circuits, relying on the precise coordination between cytoskeletal regulatory signals and mechanisms that sustain cellular integrity. Disruption of these processes compromises neuronal differentiation and survival, and various neurotoxic compounds, including certain pesticides, have been associated with such dysfunctions. In this context, identifying molecules that counteract these detrimental effects is of significant therapeutic interest. Neuronal polarization is essential for the establishment of functional neural circuits and relies on coordinated regulation of actin cytoskeleton dynamics, RhoA/ROCK signaling, and mitochondrial function. Here, we investigated the neuroprotective and neurorestorative potential of the ganglioside GM1 and its oligosaccharide derivative, osGM1, in primary hippocampal pyramidal neurons exposed to the mitochondrial neurotoxin rotenone. Rotenone induced a marked arrest of neuronal development, impaired axonal elongation, and disrupted mitochondrial organization and membrane potential. Both GM1 and osGM1 promoted recovery of neuronal polarity and axonal growth, exerting protective and restorative effects even under continuous toxin exposure, with osGM1 showing superior efficacy. Notably, osGM1 also reversed axonal growth deficits caused by pathological actin stabilization. Mechanistically, osGM1 normalized rotenone-induced hyperactivation of the RhoA/ROCK pathway without altering basal signaling and partially restored mitochondrial network integrity and function. Collectively, these findings identify osGM1 as a multi-target modulator of cytoskeletal and mitochondrial dysfunction and support its translational potential as a therapeutic strategy to counteract neurotoxin-induced neuronal damage.

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