Department of Toxicology, University of Kentucky, Lexington, KY 40536, USA.
FEMS Yeast Res. 2010 Nov;10(7):839-57. doi: 10.1111/j.1567-1364.2010.00677.x. Epub 2010 Aug 31.
The yeast vacuolar membrane protein Ycf1p and its mammalian counterpart, MRP1, belong to the ABCC subfamily of ATP-binding cassette transporters. Genetic evidence suggests that the yeast casein kinase 2α, Cka1p, negatively regulates Ycf1p function via phosphorylation of Ser251 within the N-terminus. In this study, we provide strong evidence that Cka1p regulates Ycf1p function via phosphorylation of Ser251. We show that the CK2 holoenzyme interacts with Ycf1p. However, genetic analysis suggests that only Cka1p is required for Ser251 phosphorylation, as the deletion of CKA1 significantly reduces Ser251 phosphorylation in vivo. Furthermore, purified recombinant Cka1p phosphorylates a Ycf1p-derived peptide containing Ser251. We also demonstrate that Ycf1p function is induced in response to high salt stress. Induction of the Ycf1p function strongly correlates with reduced phosphorylation of Ser251. Importantly, Cka1p activity in vivo is similarly reduced in response to salt stress, consistent with our finding that Cka1p directly phosphorylates Ser251 of Ycf1p. We provide genetic and biochemical evidence that strongly suggests that the induction of Ycf1p function is the result of decreased phosphorylation of Ser251. In conclusion, our work demonstrates a novel biochemical role for Cka1p regulation of Ycf1p function in the cellular response of yeast to salt stress.
酵母液泡膜蛋白 Ycf1p 和其哺乳动物对应物 MRP1 属于 ABC 转运蛋白的 ABCC 亚家族。遗传证据表明,酵母酪蛋白激酶 2α(Cka1p)通过磷酸化 N 端的 Ser251 负调控 Ycf1p 的功能。在本研究中,我们提供了强有力的证据表明 Cka1p 通过 Ser251 磷酸化来调节 Ycf1p 的功能。我们表明 CK2 全酶与 Ycf1p 相互作用。然而,遗传分析表明只有 Cka1p 是 Ser251 磷酸化所必需的,因为 CKA1 的缺失显著降低了体内 Ser251 的磷酸化。此外,纯化的重组 Cka1p 可磷酸化含有 Ser251 的 Ycf1p 衍生肽。我们还证明 Ycf1p 的功能在高盐胁迫下被诱导。Ycf1p 功能的诱导与 Ser251 磷酸化的减少强烈相关。重要的是,盐胁迫下体内 Cka1p 的活性也相应降低,这与我们的发现一致,即 Cka1p 直接磷酸化 Ycf1p 的 Ser251。我们提供了遗传和生化证据,强烈表明 Ycf1p 功能的诱导是 Ser251 磷酸化减少的结果。总之,我们的工作证明了 Cka1p 调节 Ycf1p 功能在酵母细胞对盐胁迫反应中的新的生化作用。