Rijnboutt S, Jansen G, Posthuma G, Hynes J B, Schornagel J H, Strous G J
Department of Cell Biology, Faculty of Medicine, Universiteit Utrecht, The Netherlands.
J Cell Biol. 1996 Jan;132(1-2):35-47. doi: 10.1083/jcb.132.1.35.
GPI-linked membrane folate receptors (MFRs) have been implicated in the receptor-mediated uptake of reduced folate cofactors and folate-based chemotherapeutic drugs. We have studied the biosynthetic transport to and internalization of MFR isoform alpha in KB-cells. MFR-alpha was synthesized as a 32-kD protein and converted in a maturely glycosylated 36-38-kD protein 1 h after synthesis. 32-kD MFR-alpha was completely soluble in Triton X-100 at 0 degree C. In contrast, only 33% of the 36-38-kD species could be solubilized at these conditions whereas complete solubilization was obtained in Triton X-100 at 37 degrees C or in the presence of saponin at 0 degree C. Similar solubilization characteristics were found when MFR-alpha at the plasma membrane was labeled with a crosslinkable 125I-labeled photoaffinity-analog of folic acid as a ligand. Triton X-100-insoluble membrane domains containing MFR-alpha could be separated from soluble MFR-alpha on sucrose flotation gradients. Only Triton X-100 soluble MFR-alpha was internalized from the plasma membrane. The reduced-folate-carrier, an integral membrane protein capable of translocating (anti-)folates across membranes, was completely excluded from the Triton X-100-resistant membrane domains. Internalized MFR-alpha recycled slowly to the cell surface during which it remained soluble in Triton X-100 at 0 degree C. Using immunoelectron microscopy, we found MFR-alpha along the entire endocytic pathway: in clathrin-coated buds and vesicles, and in small and large endosomal vacuoles. In conclusion, our data indicate that a large fraction, if not all, of internalizing MFR-alpha bypasses caveolae.
糖基磷脂酰肌醇(GPI)连接的膜叶酸受体(MFRs)与受体介导的还原型叶酸辅因子和基于叶酸的化疗药物摄取有关。我们研究了MFR亚型α在KB细胞中的生物合成转运和内化过程。MFR-α最初合成时为32-kD蛋白,合成后1小时转化为成熟糖基化的36 - 38-kD蛋白。32-kD的MFR-α在0℃时完全可溶于Triton X-100。相比之下,在这些条件下,只有33%的36 - 38-kD蛋白可被溶解,而在37℃的Triton X-100中或0℃存在皂素的情况下可实现完全溶解。当用可交联的125I标记的叶酸光亲和类似物作为配体标记质膜上的MFR-α时,发现了类似的溶解特性。含有MFR-α的Triton X-100不溶性膜结构域可通过蔗糖漂浮梯度与可溶性MFR-α分离。只有Triton X-100可溶性MFR-α从质膜内化。还原型叶酸载体是一种能够跨膜转运(抗)叶酸的整合膜蛋白,完全被排除在Triton X-100抗性膜结构域之外。内化的MFR-α缓慢循环回到细胞表面,在此过程中它在0℃时仍可溶于Triton X-100。使用免疫电子显微镜,我们在整个内吞途径中都发现了MFR-α:在网格蛋白包被的芽和小泡中,以及在小的和大的内体空泡中。总之,我们的数据表明,内化的MFR-α即使不是全部,也有很大一部分绕过了小窝。