The type 2 diabetes factor methylglyoxal mediates axon initial segment shortening and neuronal network activity changes

Abstract

AbstractRecent evidence suggests that alteration of axon initial segment (AIS) geometry (i.e., length or position along the axon) contributes to CNS dysfunction in neurological diseases. For example, AIS length is shorter in the prefrontal cortex of type 2 diabetic mice with cognitive impairment. The key type 2 diabetes-related factor that alters AIS geometry is unknown. Here, we tested whether modifying the levels of insulin, glucose, or methylglyoxal, a reactive carbonyl species that is a metabolite of glucose, changes AIS geometry in mature cultures of dissociated postnatal mouse cortex using immunofluorescent imaging of the AIS proteins AnkyrinG and βIV spectrin. Neither insulin nor glucose modification appreciably altered AIS length. Elevation of methylglyoxal produced reversible AIS shortening without cell death. Multi-electrode array recordings revealed a biphasic effect of methylglyoxal on neuronal network activity: an immediate, transient ∼300% increase in spiking and bursting rates was followed by a ∼20% reduction from baseline at 3 h. AIS length was unchanged at 0.5 h or 3 h after adding methylglyoxal, whereas development of AIS shortening at 24 h was associated with restoration of spiking to baseline levels. Immunostaining for the excitatory neuron marker Ca2+/calmodulin-dependent protein kinase II alpha revealed AIS shortening in both excitatory and inhibitory neuron populations. This suggests that complex mechanisms maintain neuronal network operation after acute exposure to the disease metabolite methylglyoxal. Importantly, our results indicate that methylglyoxal could be a key mediator of AIS shortening during type 2 diabetes.Significance StatementSmall changes in the structure of the axon initial segment affect neuronal function and may be a key mediator of neurological complications in various disease states. However, the specific disease factors that mediate structural changes at the axon initial segment are relatively unknown. This is the first study to show that increase of methylglyoxal is sufficient to reduce axon initial segment length and modulate neuronal network function. Methylglyoxal is a disease factor implicated in a wide variety of conditions including type 2 diabetes, Alzheimer’s disease, and aging. Thus, these findings could significantly impact the understanding of neurological complications in several disease states and are of broad pathophysiological relevance.