The Key Role of GM1 Ganglioside in Parkinson's Disease

We have endeavored in this review to summarize our findings, which point to a systemic deficiency of ganglioside GM1 in Parkinson's disease (PD) tissues. These include neuronal tissues well known to be involved in PD, such as substantia nigra of the brain and those of the peripheral nervous system, such as the colon and heart. Moreover, we included skin and fibroblasts in the study as well as peripheral blood mononuclear cells; these are tissues not directly involved in neuronal signaling. We show similar findings for ganglioside GD1a, which is the metabolic precursor to GM1. We discuss the likely causes of these GM1 deficiencies and the resultant biochemical mechanisms underlying loss of neuronal viability and normal functioning. Strong support for this hypothesis is provided by a mouse PD model involving partial GM1 deficiency based on mono-allelic disruption of the B4galnt1 gene. We point out that progressive loss of GM1/GD1a occurs in the periphery as well as the brain, thus obviating the need to speculate PD symptom transfer between these tissues. Finally, we discuss how these findings point to a potential disease-altering therapy for PD:GM1 replacement, as is strongly implicated in animal studies and clinical trials.

Automated summary

In this review, we summarize our findings of a systemic deficiency of ganglioside GM1 in Parkinson's disease (PD) tissues. The deficiency is observed in various neuronal and non-neuronal tissues, which suggests a potential underlying mechanism for loss of neuronal viability and normal functioning. We discuss the causes of these deficiencies and propose GM1 replacement as a potential therapy for PD based on strong evidence from animal studies and clinical trials.