Quaroni A, Kirsch K, Weiser M M
Biochem J. 1979 Jul 15;182(1):203-12. doi: 10.1042/bj1820203.
The biogenesis of plasmalemma glycoproteins of rat small-intestinal villus cells was studied by following the incorporation of l-[1,5,6-(3)H]fucose, given intraperitoneally with and without chase, into Golgi, lateral basal and microvillus membranes. Each membrane fraction showed distinct kinetics of incorporation of labelled fucose and was differently affected by the chase, which produced a much greater decrease in incorporation of label into Golgi and microvillus than into lateral basal membranes. The kinetic data suggest a redistribution of newly synthesized glycoproteins from the site of fucosylation, the Golgi complex, directly into both lateral basal and microvillus membranes. The observed biphasic pattern of label incorporation into the microvillus membrane fraction may be evidence for a second indirect route of incorporation. The selective effect of the chase suggests the presence of two different pools of radioactive fucose in the Golgi complex that differ in (1) their accessibility to dilution with non-radioactive fucose, and (2) their utilization for the biosynthesis of membrane glycoproteins subsequently destined for either the microvillus or the lateral basal parts of the plasmalemma. The radioactively labelled glycoproteins of the different membrane fractions were separated by sodium dodecyl sulphate/polyacrylamide-slab-gel electrophoresis and identified by fluorography. The patterns of labelled glycoproteins in Golgi and lateral basal membranes were identical at all times. At least 14 bands could be identified shortly after radioactive-fucose injection. Most seemed to disappear at later times, although one of them, which was never observed in microvillus membranes, increased in relative intensity. All but two of the labelled glycoproteins present in the microvillus membrane corresponded to those observed in Golgi and lateral basal membranes shortly after fucose injection. The patterns of labelled glycoproteins in all membrane fractions were little affected by the chase. These data support a flow concept for the insertion of most surface-membrane glycoproteins of the intestinal villus cells.
通过追踪腹腔注射有或无追踪情况下的l-[1,5,6-(3)H]岩藻糖掺入高尔基体、侧基膜和微绒毛膜的情况,研究了大鼠小肠绒毛细胞质膜糖蛋白的生物合成。每个膜组分显示出标记岩藻糖掺入的不同动力学,并且受追踪的影响不同,追踪导致标记物掺入高尔基体和微绒毛的减少比掺入侧基膜的减少大得多。动力学数据表明新合成的糖蛋白从岩藻糖基化位点即高尔基体复合体直接重新分布到侧基膜和微绒毛膜中。观察到的标记物掺入微绒毛膜组分的双相模式可能是第二种间接掺入途径的证据。追踪的选择性作用表明高尔基体复合体中存在两种不同的放射性岩藻糖池,它们在以下方面有所不同:(1)它们被非放射性岩藻糖稀释的可及性,以及(2)它们用于随后 destined 到质膜微绒毛或侧基部分的膜糖蛋白生物合成的利用率。不同膜组分的放射性标记糖蛋白通过十二烷基硫酸钠/聚丙烯酰胺平板凝胶电泳分离,并通过荧光自显影鉴定。高尔基体和侧基膜中标记糖蛋白的模式在所有时间都是相同的。放射性岩藻糖注射后不久至少可以鉴定出14条带。大多数在稍后时间似乎消失了,尽管其中一条在微绒毛膜中从未观察到的带在相对强度上增加了。微绒毛膜中存在的标记糖蛋白中除了两条之外,都与岩藻糖注射后不久在高尔基体和侧基膜中观察到的相对应。所有膜组分中标记糖蛋白的模式受追踪的影响很小。这些数据支持了肠绒毛细胞大多数表面膜糖蛋白插入的流动概念。