Sodium-dependent amino acid transport in preimplantation mouse embryos. III. Na+-k+-atpase-linked mechanism in blastocysts.

Mouse blastocysts collapse in cytochalasin B (CB), reexpand (accumulate fluid) in control medium, but cannot reexpand in ouabain, an inhibitor of Na⁺K⁺-ATPases. These ATPases, then, seem to be necessary for fluid accumulation in blastocysts. Since intact blastocysts are relatively insensitive to ouabain, CB seems to make it possible for ouabain to reach the Na⁺K⁺-ATPases localized on the blastocoelic surface. CB-Collapsed blastocysts were found to transport alanine and lysine at the same rate as intact blastocysts, indicating that, in 1 hr, amino acids are transported into the cells of the intact blastocyst, and not into the fluid-filled blastocoel. Transport rates in CB-collapsed blastocysts do not exceed those in intact blastocysts, suggesting that hypothetical amino acid carriers are located only on the external blastocyst surface. Most important, ouabain strongly inhibits sodium-dependent alanine transport in CB-collapsed blastocysts, but not in intact blastocysts, providing strong evidence that Na⁺K⁺-ATPases, localized on the blastocoelic surface, are necessary for this transport. Ouabain does not inhibit sodium-independent lysine transport in CB-collapsed blastocysts. Thus, the dependency of both sodium-dependent amino acid transport and fluid accumulation upon Na⁺K⁺-ATPases, and the separate localization of amino acid carriers and these ATPases, provides functional evidence for an epithelial tissue type of mechanism for sodium-dependent amino acid transport in mouse blastocysts.