Mitochondrial respiration of a primary mixed culture of neurons from hippocampus at various stages of differentiation

Abstract

BACKGROUND: Primary mixed culture of neurons is often used to evaluate the molecular mechanisms underlying neurodegenerative disorders. However, isolating cells from the brain is accompanied by profound changes in cell morphology, behavior, and metabolic rate due to enzymatic disintegration and microenvironmental changes in cells. In this regard, the mitochondrial basal respiration of neurons should be considered as an indicator of the formation of functional activity of the cell.
 AIM: To evaluate mitochondrial respiration in a primary mixed culture of hippocampal neurons at various stages of differentiation.
 METHODS: This study included mice of line CD-1 and was conducted in two series: the first studied the primary mixed embryonic culture on the 18th day of gestation (E18) and the second used the postnatal culture on the 2nd day after birth (P2). A Seahorse XF HS Mini (Agilent, USA) was used to measure the functional parameters of cell metabolism. The oxygen consumption rate was calculated based on the results of the mitochondrial respiration profile of the primary mixed culture built during its differentiation.
 RESULTS: On the 5th day of neuronal differentiation in the culture, maximum mitochondrial respiration was established both in the hippocampal culture obtained from embryos on the 18th day of gestation and in the culture taken from mice on the 2nd day after birth. As cells differentiated in culture from days 2 to 11, the substrate oxidation rate increased almost twofold in the culture of hippocampal neurons obtained from embryos, which increased the metabolic potential.
 CONCLUSION: The study results prove that the hippocampus can be used to study the role of mitochondria in neurogenesis.