Noe B D, Debo G, Spiess J
J Cell Biol. 1984 Aug;99(2):578-87. doi: 10.1083/jcb.99.2.578.
In previous work we have examined the nature of converting enzymes for proinsulin, proglucagon, and prosomatostatin-I (PSS-I) in secretory granules isolated from anglerfish islets. The purpose of the present study was to extend the examination of precursor conversion to islet microsomes and to compare prohormone processing, including that of PSS-I and prosomatostatin-II (PSS-II), in islet secretory granules and microsomes. Microsomes (rough endoplasmic reticulum [RER] and Golgi complex) and secretory granules were prepared from anglerfish islets by differential and discontinuous density-gradient centrifugation. Microsomes were further fractionated into Golgi- and RER-enriched subfractions. Lysed secretory granule or microsome preparations were incubated in the presence of a mixture of radioactively labeled islet prohormones. Extracts of products generated were subjected to analysis by gel filtration and high-pressure liquid chromatography. Accuracy of product cleavage was monitored by comparing high-pressure liquid chromatography retention times from the radiolabeled in vitro conversion products with the retention times of labeled products from tissue extracts. All converting activity in microsomes was found to be similar to that in granules in that it had a pH optimum near pH 5 and was inhibited by p-chloromercuribenzoate. No significant differences in the converting activity of Golgi complex- and RER-enriched subfractions of microsomes was observed. The proinsulin, proglucagon, and PSS-II converting-enzymes, which were found in islet secretory granules, were also present and membrane-associated in islet microsomes. However, converting activity for PSS-I was displayed only in secretory granules. This suggests that two or more separate enzymes are involved in processing PSS-I and PSS-II, and that these enzymes have either differential distribution or differential activity in RER/Golgi complex and secretory granules. The demonstration of converting enzyme activity in islet microsomes supports the proposal that these enzymes may be synthesized at the RER and are internalized along with the prohormones.
在之前的工作中,我们研究了从安康鱼胰岛分离出的分泌颗粒中胰岛素原、胰高血糖素原和生长抑素-I前体(PSS-I)转化酶的性质。本研究的目的是将前体转化的研究扩展到胰岛微粒体,并比较胰岛分泌颗粒和微粒体中前激素的加工过程,包括PSS-I和生长抑素-II(PSS-II)的加工过程。通过差速离心和不连续密度梯度离心从安康鱼胰岛中制备微粒体(粗面内质网[RER]和高尔基体复合体)和分泌颗粒。微粒体进一步分离为富含高尔基体和RER的亚组分。在放射性标记的胰岛前激素混合物存在的情况下,孵育裂解的分泌颗粒或微粒体制剂。对产生的产物提取物进行凝胶过滤和高压液相色谱分析。通过比较放射性标记的体外转化产物的高压液相色谱保留时间与组织提取物中标记产物的保留时间,监测产物切割的准确性。发现微粒体中的所有转化活性与颗粒中的活性相似,其最适pH接近pH 5,并被对氯汞苯甲酸抑制。未观察到微粒体中富含高尔基体和RER的亚组分的转化活性有显著差异。在胰岛分泌颗粒中发现的胰岛素原、胰高血糖素原和PSS-II转化酶在胰岛微粒体中也存在且与膜相关。然而,PSS-I的转化活性仅在分泌颗粒中表现出来。这表明在加工PSS-I和PSS-II过程中涉及两种或更多种不同的酶,并且这些酶在RER/高尔基体复合体和分泌颗粒中具有不同的分布或活性。胰岛微粒体中转化酶活性的证明支持了这些酶可能在RER合成并与前激素一起内化的提议。