Intracellular lactate dynamics in Drosophila neurons.
Matthew S Price, Elham Rastegari, Richa Gupta, Katie Vo, Travis I Moore, Kartik Venkatachalam
Abstract
Open AccessRates of lactate production and consumption reflect the metabolic state of many cell types, including neurons. Here, we investigated the effects of nutrient deprivation on lactate dynamics in Drosophila neurons by leveraging the limiting effects of the unstirred layer, a diffusion barrier that forms around cells in culture. We found that neurons constitutively consume lactate when the availability of trehalose, a glucose disaccharide preferred by insects, is limited by the unstirred layer. Acute mechanical disruption of the unstirred layer reduced this reliance on lactate. Through kinetic modeling and experimental validation, we demonstrate that neuronal lactate consumption rates under unstirred layer conditions correlate inversely with the cells' mitochondrial density. Furthermore, neuronal lactate levels exhibited temporal correlations that allowed postperturbation lactate dynamics to be predicted by preperturbation values. Collectively, our findings reveal the influence of naturally forming diffusion barriers on neuronal metabolic preferences and demonstrate the existence of temporal correlations between lactate dynamics under conditions of nutrient deprivation and those evoked by the subsequent restoration of nutrient availability.