Toye Ashley M, Banting George, Tanner Michael J A
Department of Biochemistry, University of Bristol, University Walk, Bristol BS8 1TD, UK.
J Cell Sci. 2004 Mar 15;117(Pt 8):1399-410. doi: 10.1242/jcs.00974. Epub 2004 Mar 2.
Distal renal tubular acidosis (dRTA) is characterised by defective acid secretion by kidney alpha-intercalated cells. Some dominantly inherited forms of dRTA result from anion exchanger 1 (AE1) mutations. We have developed a stably transfected cell model for the expression of human kidney AE1 (kAE1) and mutant kAE1 proteins in MDCKI cells. Normal kAE1 was delivered to the plasma membrane of non-polarised cells and to the basolateral membrane of polarised cells. The AE1 N-glycan was processed to a complex form. Surprisingly, expression of kAE1 increased the permeability of the paracellular barrier of polarised MDCKI monolayers. All dominant dRTA mutations examined altered the targeting of kAE1 in MDCKI cells. The mutant proteins kAE1(R589H), kAE1(S613F) and kAE1(R901Stop) were retained in the ER in non-polarised cells, but the kAE1(R901Stop) protein was also present in late endosomes/lysosomes. The complex N-glycan of kAE1(R901Stop) was larger than that of normal kAE1. In polarised cells, the mutant kAE1(R901Stop) was mis-targeted to the apical membrane, while the kAE1(R589H) and kAE1(S613F) mutants did not reach the cell surface. These results demonstrate that dominant dRTA mutations cause aberrant targeting of kAE1 in polarised kidney cells and provide an explanation for the origin of dominant dRTA. Our data also demonstrate that the 11 C-terminal residues of kAE1 contain a tyrosine-dependent basolateral targeting signal that is not recognised by mu 1B-containing AP-1 adaptor complexes. In the absence of the N-terminus of kAE1, the C-terminus was not sufficient to localise kAE1 to the basolateral membrane. These results suggest that a determinant within the kAE1 N-terminus co-operates with the C-terminus for kAE1 basolateral localisation.
远端肾小管酸中毒(dRTA)的特征是肾α-闰细胞的酸分泌功能缺陷。一些显性遗传形式的dRTA是由阴离子交换蛋白1(AE1)突变引起的。我们已经开发出一种稳定转染的细胞模型,用于在MDCK I细胞中表达人肾AE1(kAE1)和突变型kAE1蛋白。正常的kAE1被转运至非极化细胞的质膜以及极化细胞的基底外侧膜。AE1 N-聚糖被加工成复合形式。令人惊讶的是,kAE1的表达增加了极化的MDCK I单层细胞旁细胞屏障的通透性。所有检测的显性dRTA突变均改变了kAE1在MDCK I细胞中的靶向定位。突变蛋白kAE1(R589H)、kAE1(S613F)和kAE1(R901Stop)在非极化细胞中滞留在内质网中,但kAE1(R901Stop)蛋白也存在于晚期内体/溶酶体中。kAE1(R901Stop)的复合N-聚糖比正常kAE1的更大。在极化细胞中,突变型kAE1(R901Stop)被错误靶向至顶端膜,而kAE1(R589H)和kAE1(S613F)突变体未到达细胞表面。这些结果表明,显性dRTA突变导致kAE1在极化肾细胞中的靶向异常,并为显性dRTA的起源提供了解释。我们的数据还表明,kAE1的11个C末端残基包含一个酪氨酸依赖性基底外侧靶向信号,该信号不被含μ1B的AP-1衔接复合物识别。在没有kAE1 N末端的情况下,C末端不足以将kAE1定位至基底外侧膜。这些结果表明,kAE1 N末端内的一个决定因素与C末端协同作用以实现kAE1的基底外侧定位。
