26, 27 However, in ethanol- or TSA-treated cells, no such collars were detected. Although the class 3 profiles were invaginated, the necks were not elongated nor were the sides of the necks apposed, indicating that dynamin oligomers were likely
not assembling there. Furthermore, overexpressed wild-type dynamin failed to rescue the ethanol-induced defect and was not detected at the plasma membrane, indicating impaired dynamin membrane recruitment. Previously, we determined Saracatinib order that impaired clathrin-mediated internalization required ethanol metabolism and was likely mediated by acetaldehyde (see Supporting Fig. 1).15, 28 Thus, one exciting possibility is that a critical clathrin-coat component(s) is prone to adduction by acetaldehyde or other reactive metabolites, thereby impairing proper dynamin recruitment. Alternatively, (additionally?), hyperacetylation of key coat components may be at fault. This hypothesis is supported by the findings that actin and cortactin
are hyperacetylated upon ethanol exposure.4 Although how cortactin, actin, and dynamin function to promote vesicle release BVD-523 datasheet is not completely elucidated, acetylation of cortactin is known to prevent its association with actin.29 Thus, we propose that alcohol-induced hyperacetylation leads to decreased interactions between actin, cortactin, and/or dynamin, thereby inhibiting dynamin recruitment and subsequent vesicle fission. Although our coimmunoprecipitation results are fully consistent with this hypothesis, identification of the hyperacetylated lysines in both actin and cortactin (and dynamin?) is needed to test this hypothesis. Previously, we found that ethanol exposure led to increased microtubule acetylation and stability.6 In an effort to determine the
mechanism responsible for this observation, we examined the distributions and biochemical properties of histone deacetylase-6 (HDAC6), a tubulin (and cortactin) deacetylase. We found that HDAC6 binding to endogenous microtubules was impaired in ethanol-treated cells, whereas its ability to bind or deacetylate exogenous tubulin did not change, suggesting fantofarone that tubulin from ethanol-treated cells was modified, thereby preventing HDAC6 binding.30 Because both impaired HDAC6 microtubule binding and tubulin hyperacetylation require ethanol metabolism and are likely mediated by acetaldehyde6, 30 and because tubulin can be acetaldehyde adducted,31, 32 we propose that tubulin-acetaldehyde adducts impede HDAC6-tubulin binding, thereby preventing deacetylation. It is possible that an analogous scenario may explain impaired clathrin-mediated internalization in ethanol-treated cells, a possibility we are currently exploring.