Changes in cytosolic Ca2+ levels correspond to fluctuations of lactate levels in crosstalk of astrocyte-neuron cell lines.

Neurons and astrocytes differentially express isoenzymes of lactate dehydrogenase (LDH). The metabolic consequences for the variations in mRNA expression of LDH isoenzyme subtypes in neurons and astrocytes control cerebral vasoregulation. Moreover, cellular signalling consequences for functional neurovascular control may also be dependent on LDH isoenzyme subtype profiles. Initial computer simulations revealed glutamate-induced calcium waves in connected astrocytes, and showed concomitant changes in the expression of nitric oxide synthase (NOS) and lactic acid metabolism. To validate these findings, the nature and extent of glutamate-dependent signalling crosstalk in murine cell lines were investigated through correlated lactate levels and calcium upregulation. Neuro2A and C8D1A cells were separately treated with timed supernatant extracts from each other and their LDH1 and LDH5 isoenzyme responses were recorded. Western blot analysis showed LDH1/LDH5 isoenzyme ratio in the astrocytes to be positively correlated with Neuro2A-derived lactate levels estimated by the amplitude of 1.33-ppm spectral peak in 1H-NMR, and LDH1/LDH5 isoenzyme ratio in neurons is negatively correlated with CSD1A-derived lactate levels. Significant modulations of the calcium-responsive protein pCamKII levels were also observed in both cell lines, particularly correlations between pCamKII and lactate in C8D1A cells, thus explaining the calcium dependence of the lactate response. Together, these observations indicate that lactate is a key indicator of the metabolic state of these cell types, and may be a determinant of release of vasoregulatory factors.

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