Muscella A, Marsigliante S, Verri T, Urso L, Dimitri C, Bottà G, Paulmichl M, Beck-Peccoz P, Fugazzola L, Storelli C
Department of Biological and Environmental Sciences and Technologies (Di.S.Te.B.A.), Università del Salento, Italy.
J Cell Physiol. 2008 Oct;217(1):103-12. doi: 10.1002/jcp.21478.
We studied the expression and the hormonal regulation of the PDS gene product, pendrin, which is, in thyrocytes, responsible for the iodide transport out of the cell. We show that PC Cl3 cells, a fully differentiated thyroid cell line, grown without TSH and insulin, express very low level of PDS mRNA; such expression is greatly increased after stimulation with insulin or TSH. (125)I pre-loaded cells showed an (125)I efflux accelerated in chloride-containing buffer with respect to chloride-free buffer, suggesting that this efflux is chloride dependent. By immunoblotting, pendrin was found in agonists-stimulated cells, whereas it was barely detectable in un-stimulated cells. An increase in both PDS mRNA and protein was also obtained using phorbol ester PMA, or using 8-Br-cAMP and forskolin. Stimulation with insulin (1 microg/ml; 0-40 min) provoked the cytosol-to-membrane translocation of pendrin and a decrease of intracellular I(-) content in (125)I pre-loaded cells. Insulin- or PMA-treated cells also showed a cytosol-to-membrane translocation of PKC-delta and -epsilon. Inhibition of both PKC-delta and -epsilon activities by GF109203X blocked pendrin translocation, whilst the inhibition of PKA did not. The selective inhibition of PKC-delta by rottlerin did not affect the insulin-provoked translocation of pendrin whilst it was inhibited by a PKC-epsilon translocation inhibitor peptide and also by PKC-epsilon downregulation using the small interfering RNA, thus indicating that such translocation was due to PKC-epsilon activity. In conclusion, our study demonstrates that, in PC Cl3 cells, pendrin expression and localisation are regulated by insulin and influenced by a PKC-epsilon-dependent intracellular pathway.
我们研究了PDS基因产物——耳毒性蛋白的表达及其激素调节,在甲状腺细胞中,耳毒性蛋白负责将碘离子转运出细胞。我们发现,在无促甲状腺激素(TSH)和胰岛素的情况下生长的PC Cl3细胞,这是一种完全分化的甲状腺细胞系,其PDS mRNA表达水平非常低;在用胰岛素或TSH刺激后,这种表达显著增加。预加载了(125)I的细胞在含氯缓冲液中相对于无氯缓冲液显示出加速的(125)I流出,这表明这种流出依赖于氯离子。通过免疫印迹法,在激动剂刺激的细胞中发现了耳毒性蛋白,而在未刺激的细胞中几乎检测不到。使用佛波酯PMA、8-溴-cAMP和福斯高林也能使PDS mRNA和蛋白质增加。用胰岛素(1微克/毫升;0 - 40分钟)刺激会促使预加载了(125)I的细胞中,耳毒性蛋白从细胞质转移到细胞膜,并降低细胞内碘离子含量。胰岛素或PMA处理的细胞还显示蛋白激酶C-δ(PKC-δ)和蛋白激酶C-ε(PKC-ε)从细胞质转移到细胞膜。GF109203X对PKC-δ和PKC-ε活性的抑制阻止了耳毒性蛋白的转移,而蛋白激酶A(PKA)的抑制则没有。rottlerin对PKC-δ的选择性抑制并不影响胰岛素引起的耳毒性蛋白转移,而PKC-ε转移抑制剂肽以及使用小干扰RNA下调PKC-ε则能抑制这种转移,因此表明这种转移是由PKC-ε活性引起的。总之,我们的研究表明,在PC Cl3细胞中,耳毒性蛋白的表达和定位受胰岛素调节,并受PKC-ε依赖的细胞内途径影响。
