Membrane asymmetry is a key organizational feature of the plasma membrane. Type IV P-type ATPases (P4-ATPases) are phospholipid flippases that establish membrane asymmetry by translocating phospholipids, such as phosphatidylserine (PS) and phospatidylethanolamine, from the exofacial leaflet to the cytosolic leaflet. Saccharomyces cerevisiae expresses five P4-ATPases: Drs2, Neo1, Dnf1, Dnf2, and Dnf3. The inactivation of Neo1 is lethal, suggesting Neo1 mediates an essential function not exerted by the other P4-ATPases. However, the disruption of ANY1, which encodes a PQ-loop membrane protein, allows the growth of neo1Δ and reveals functional redundancy between Golgi-localized Neo1 and Drs2. Here we show Drs2 PS flippase activity is required to support neo1Δ any1Δ viability. Additionally, a Dnf1 variant with enhanced PS flipping ability can replace Drs2 and Neo1 function in any1Δ cells. any1Δ also suppresses drs2Δ growth defects but not the loss of membrane asymmetry. Any1 overexpression perturbs the growth of cells but does not disrupt membrane asymmetry. Any1 coimmunoprecipitates with Neo1, an association prevented by the Any1-inactivating mutation D84G. These results indicate a critical role for PS flippase activity in Golgi membranes to sustain viability and suggests Any1 regulates Golgi membrane remodeling through protein-protein interactions rather than a previously proposed scramblase activity.
The type IV P-type ATPases (P4-ATPases) thus far characterized are lipid flippases that transport specific substrates, such as phosphatidylserine (PS) and phosphatidylethanolamine (PE), from the exofacial leaflet to the cytofacial leaflet of membranes. This transport activity generates compositional asymmetry between the two leaflets important for signal transduction, cytokinesis, vesicular transport, and host-pathogen interactions. Most P4-ATPases function as a heterodimer with a β-subunit from the Cdc50 protein family, but Neo1 from Saccharomyces cerevisiae and its metazoan orthologs lack a β-subunit requirement and it is unclear how these proteins transport substrate. Here we tested if residues linked to lipid substrate recognition in other P4-ATPases also contribute to Neo1 function in budding yeast. Point mutations altering entry gate residues in the first (Q209A) and fourth (S457Q) transmembrane segments of Neo1, where phospholipid substrate would initially be selected, disrupt PS and PE membrane asymmetry, but do not perturb growth of cells. Mutation of both entry gate residues inactivates Neo1, and cells expressing this variant are inviable. We also identified a gain-of-function mutation in the second transmembrane segment of Neo1 (Neo1[Y222S]), predicted to help form the entry gate, that substantially enhances Neo1's ability to replace the function of a well characterized phospholipid flippase, Drs2, in establishing PS and PE asymmetry. These results suggest a common mechanism for substrate recognition in widely divergent P4-ATPases.
1alpha,25-Dihydroxy vitamin D3 (1,25D3) activates conventional PKC and may subsequently lead to insulin resistance. Previous studies from our laboratory have shown that pretreatment with 10 nM-10 microM 1,25D3 dose-responsively suppressed insulin-induced glucose. To assess PKC(beta)-mediated inhibition of insulin-induced glucose uptake in rat adipocytes, we preincubated with Go6976 and LY379196, conventional PKC inhibitors, and found they abolished the 1,25D3-mediated inhibitory effect on insulin-induced 2-deoxyglucose (DOG) uptake. Moreover, the inhibitory effect of 1,25D3 on insulin-induced DOG uptake was abrogated in adipocytes overexpressed with dominant negative PKC(beta), but not in those overexpressed with wild type PKC(beta). These results suggest that 1,25D3 reduces insulin-induced glucose uptake via activation of PKC(beta) in rat adipocytes.
Insulin stimulates glucose uptake in association with phosphatidylinositol (PI) 3-kinase activation mechanisms in rat adipocytes. Insulin stimulated glucose uptake to 6.5-fold, and 12-o-tetradecanoyl phorbol 13-acetate (TPA) also stimulated glucose uptake to 4.5-fold in rat adipocytes. We examined these differences in glucose uptake, PKCzeta activation, and PI 3-kinase activation after stimulation with insulin and TPA. TPA stimulated PI 3-kinase activity and increased the p85 subunit of PI 3-kinase immunoreactivity in anti-phosphotyrosine antibody-immunoprecipitated protein. Insulin and TPA provoked increases in membrane PKCzeta immunoreactivity. The PI 3-kinase inhibitor, wortmannin, suppressed insulin-induced increases in glucose uptake, PI 3-kinase activity, and PKCzeta activation. Wortmannin also suppressed TPA-induced PI 3-kinase activity and PKCzeta activation but suppressed TPA-induced glucose uptake to only a small extent. The PKC inhibitor, Go6976, which only inhibits conventional PKCalpha and _, suppressed TPA-induced glucose uptake, but suppressed insulin-induced glucose uptake to only a small extent. On the other hand, the PKC inhibitor, RO32-0432, which inhibits conventional, novel, and atypical PKCs, markedly suppressed both insulin- and TPA-induced glucose uptake. These results suggest that insulin-induced glucose uptake is mainly mediated by PI 3-kinase-PKCzeta signaling, whereas phorbol ester-induced glucose uptake is mainly mediated by conventional PKC despite PI 3-kinase and PKCzeta activations.
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