Docosahexaenoic acid (22:6n‐3) enrichment of membrane phospholipids increases gap junction coupling capacity in cultured astrocytes

Although it is agreed that n‐3 polyunsaturated fatty acids (PUFAs) are important for brain function, it has yet to be demonstrated how they are involved in precise cellular mechanisms. We investigated the role of enhanced n‐3 PUFA in astrocyte membranes on the gap junction capacity of these cells. Astrocytes isolated from newborn rat cortices were grown in medium supplemented with docosahexaenoic acid (DHA), the main n‐3 PUFA in cell membranes, or arachidonic acid (AA), the main n‐6 PUFA, plus an antioxidant (α‐tocopherol or N ‐acetyl‐cystein) to prevent peroxidation. The resulting three populations of astrocytes differed markedly in their n‐3 : n‐6 PUFA ratios in phosphatidylethanolamine and phosphatidylcholine, the main phospholipids in membranes. DHA‐supplemented cells had a physiological high n‐3 : n‐6 ratio (1.58), unsupplemented cells had a low n‐3 : n‐6 ratio (0.66) and AA‐supplemented cells had a very low n‐3 : n‐6 ratio (0.36), with excess n‐6 PUFA. DHA‐supplemented astrocytes had a greater gap junction capacity than unsupplemented cells or AA‐supplemented cells. The enhanced gap junction coupling of DHA‐enriched cells was associated with a more functional distribution of connexin 43 at cell interfaces (shown by immunocytochemistry) and more of the main phosphorylated isoform of connexin 43. These findings suggest that the high n‐3 : n‐6 PUFA ratio that occurs naturally in astrocyte membranes is needed for optimal gap junction coupling in these cells.