Muller W A, Steinman R M, Cohn Z A
J Cell Biol. 1983 Jan;96(1):29-36. doi: 10.1083/jcb.96.1.29.
In previous publications (Muller, W.A., R.M. Steinman, Z.A. Cohn. 1980, J.Cell Biol. 86:292-314), we found that the membrane of macrophage phagolysosomes could be selectively radioiodinated in living cells, The technique required phagocytosis of lactoperoxidase covalently coupled to latex spheres (LPO-latex), followed by iodination on ice with Na(125)I and hydrogen peroxide. In this paper, we use the LPO-latex system to further analyze the composition and recycling of phagocytic vacuole membrane. Three approaches were employed to examine the polypeptide composition of the phagolysosome (PL) and plasma membranes (PM). (a) The efficiency of intracellular iodination was increased by increasing lysosomal pH with chloroquine. By one-dimensional SDS PAGE, the heavily labeled chloroquine-treated PL exhibited the same labeled polypeptides as PM iodinated extracellularly with LPO-latex. (b) Iodinated PL and PM were compared by two-dimensional gel electrophoresis. No differences in the isoelectric point and molecular weight of the major iodinated species were detected. (c) Quantitative immune precipitation was performed with five specific antibodies directed against cell surface antigens. Four antibodies precipitated similar relative amounts of labeled antigen on the cell surface and endocytic vacuole. One antibody, secreted by hybridoma 2.6, detected a 21-kdalton polypeptide that was enriched sevenfold in PL membrane. This enrichment was cell surface-derived, since the amount of labeled 2.6 was increased sevenfold when iodinated PM was driven into the cell during latex uptake. Therefore, intracellular iodination primarily detects PL proteins that are identical to their PM counterparts. Additional studies employed electron microscope autoradiography to monitor the centrifugal flow of radiolabeled polypeptides from PL to PM. Cells were iodinated intralysosomally and returned to culture for only 5-10 min at 37 degrees C. Most of the cell-associated label then redistributed to the cell surface or its adjacent area. Significant movement out of the lysosome compartment occurred even at 2 degrees C and 22 degrees C. Extensive and rapid membrane flow through the secondary lysosome presumably contributes to the great similarity between PM and PL membrane polypeptides.
在之前的出版物中(Muller, W.A., R.M. Steinman, Z.A. Cohn. 1980, J.Cell Biol. 86:292 - 314),我们发现巨噬细胞吞噬溶酶体的膜在活细胞中能够被选择性地放射性碘化。该技术需要吞噬与乳胶球共价偶联的乳过氧化物酶(LPO - 乳胶),随后在冰上用Na(125)I和过氧化氢进行碘化。在本文中,我们使用LPO - 乳胶系统进一步分析吞噬泡膜的组成和循环利用。采用了三种方法来检测吞噬溶酶体(PL)和质膜(PM)的多肽组成。(a)通过用氯喹提高溶酶体pH值来增加细胞内碘化的效率。通过一维SDS - PAGE分析,经氯喹处理后被大量标记的PL呈现出与用LPO - 乳胶在细胞外碘化的PM相同的标记多肽。(b)通过二维凝胶电泳比较碘化的PL和PM。未检测到主要碘化物种的等电点和分子量存在差异。(c)用五种针对细胞表面抗原的特异性抗体进行定量免疫沉淀。四种抗体沉淀出细胞表面和内吞泡上相似相对量的标记抗原。一种由杂交瘤2.6分泌的抗体检测到一种21 kDa的多肽,其在PL膜中富集了7倍。这种富集来源于细胞表面,因为在摄取乳胶期间将碘化的PM驱入细胞时,标记的2.6的量增加了7倍。因此,细胞内碘化主要检测到与质膜对应物相同的PL蛋白。额外的研究采用电子显微镜放射自显影术来监测放射性标记多肽从PL到PM的离心流动。细胞在溶酶体内进行碘化,然后在37℃下仅放回培养5 - 10分钟。然后,大多数与细胞相关的标记重新分布到细胞表面或其相邻区域。即使在2℃和22℃时,也发生了从溶酶体区室的显著移动。通过次级溶酶体的广泛且快速的膜流动大概导致了PM和PL膜多肽之间的高度相似性。