溶酶体己糖氨酸酶同工酶。

Isozymes Pub Date : 1985-01-01

D Mahuran, A Novak, J A Lowden

{"title":"溶酶体己糖氨酸酶同工酶。","authors":"D Mahuran, A Novak, J A Lowden","doi":"","DOIUrl":null,"url":null,"abstract":"In the 15 years since the demonstration that HEX A is the defective enzyme in patients with TSD, intensive efforts in many laboratories have revealed much about the HEX group of enzymes. In contradistinction to the two isozymes described by Robinson and Stirling [1968], we now know that there are several different species. They include the products of at least three genes which code for the alpha and beta polypeptides as well as for an enzyme that we have called HEX D. The different species of HEX found in human tissues and fluids include significant amounts of larger, unprocessed polypeptides as well as mature enzyme. Thus the HEX A of serum (HEX AS) is a more primitive form of the enzyme than that found in lysosomes. The role of biosynthesis in the formation of multiple species of HEX is not confined to the polypeptide chains of the enzyme. All lysosomal enzymes are glycosylated and HEX is not an exception. The carbohydrate side-chains are essential to the packaging process that places HEX in the lysosome. Carbohydrates on lysosomal HEX species clearly differ from those on HEX in serum. Characterization of HEX oligosaccharides is still in the preliminary stages. Many minor species of HEX have been described. The more important ones are the intermediate isozymes (HEX Is). In tissues the HEX Is appear to contain mixtures of processed and unprocessed alpha and beta polypeptides. In serum, on the other hand, they contain unprocessed beta chains and differ in the carbohydrate side-chains. Most species of HEX show microheterogeneity. Native, mature HEX B separates into several bands on isoelectric focusing. The nature of this microheterogeneity has not been defined. Clear differences have been described, however, between the two chains in the beta subunit. The chains are always united in non-random fashion and are probably derived by cleavage of a single gene product. Studies of hydrolytic activity have been interesting. Like other lysosomal enzymes, HEX A requires a specific protein activator for optimum activity. This small polypeptide has been partially characterized but its mode of action is as yet unclear. Defects in activator synthesis lead to a form of GM2 ganglioside storage disease. Clinically many different phenotypes have been identified which appear to result from defects in each of the HEX genes. The differences between the defects have not been characterized in molecular terms.(ABSTRACT TRUNCATED AT 400 WORDS)","PeriodicalId":77729,"journal":{"name":"Isozymes","volume":"12 ","pages":"229-88"},"PeriodicalIF":0.0000,"publicationDate":"1985-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"The lysosomal hexosaminidase isozymes.\",\"authors\":\"D Mahuran, A Novak, J A Lowden\",\"doi\":\"\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In the 15 years since the demonstration that HEX A is the defective enzyme in patients with TSD, intensive efforts in many laboratories have revealed much about the HEX group of enzymes. In contradistinction to the two isozymes described by Robinson and Stirling [1968], we now know that there are several different species. They include the products of at least three genes which code for the alpha and beta polypeptides as well as for an enzyme that we have called HEX D. The different species of HEX found in human tissues and fluids include significant amounts of larger, unprocessed polypeptides as well as mature enzyme. Thus the HEX A of serum (HEX AS) is a more primitive form of the enzyme than that found in lysosomes. The role of biosynthesis in the formation of multiple species of HEX is not confined to the polypeptide chains of the enzyme. All lysosomal enzymes are glycosylated and HEX is not an exception. The carbohydrate side-chains are essential to the packaging process that places HEX in the lysosome. Carbohydrates on lysosomal HEX species clearly differ from those on HEX in serum. Characterization of HEX oligosaccharides is still in the preliminary stages. Many minor species of HEX have been described. The more important ones are the intermediate isozymes (HEX Is). In tissues the HEX Is appear to contain mixtures of processed and unprocessed alpha and beta polypeptides. In serum, on the other hand, they contain unprocessed beta chains and differ in the carbohydrate side-chains. Most species of HEX show microheterogeneity. Native, mature HEX B separates into several bands on isoelectric focusing. The nature of this microheterogeneity has not been defined. Clear differences have been described, however, between the two chains in the beta subunit. The chains are always united in non-random fashion and are probably derived by cleavage of a single gene product. Studies of hydrolytic activity have been interesting. Like other lysosomal enzymes, HEX A requires a specific protein activator for optimum activity. This small polypeptide has been partially characterized but its mode of action is as yet unclear. Defects in activator synthesis lead to a form of GM2 ganglioside storage disease. Clinically many different phenotypes have been identified which appear to result from defects in each of the HEX genes. The differences between the defects have not been characterized in molecular terms.(ABSTRACT TRUNCATED AT 400 WORDS)\",\"PeriodicalId\":77729,\"journal\":{\"name\":\"Isozymes\",\"volume\":\"12 \",\"pages\":\"229-88\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"1985-01-01\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Isozymes\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Isozymes","FirstCategoryId":"1085","ListUrlMain":"","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

摘要

自证明HEX A是TSD患者的缺陷酶以来的15年中，许多实验室的密集努力已经揭示了HEX组酶的许多信息。与Robinson和Stirling[1968]描述的两种同工酶不同，我们现在知道有几种不同的物种。它们包括至少三种基因的产物，这些基因编码α和β多肽以及一种我们称之为HEX d的酶。在人体组织和液体中发现的不同种类的HEX包括大量较大的、未加工的多肽以及成熟的酶。因此，血清中的HEX A (HEX AS)是一种比溶酶体中发现的更原始的酶形式。生物合成在形成多种HEX中的作用并不局限于酶的多肽链。所有溶酶体酶都是糖基化的，HEX也不例外。碳水化合物侧链对于将HEX放入溶酶体的包装过程至关重要。溶酶体HEX的碳水化合物种类与血清中HEX的碳水化合物种类明显不同。HEX寡糖的表征仍处于初步阶段。许多次要种类的HEX已被描述。更重要的是中间同工酶(HEX Is)。在组织中，HEX似乎含有加工和未加工的α多肽和β多肽的混合物。另一方面，在血清中，它们含有未加工的-链，不同的是碳水化合物侧链。大多数种类的HEX表现出微观异质性。天然的、成熟的HEX B在等电聚焦上分成几个波段。这种微观非均质性的性质尚未确定。然而，在β亚基的两条链之间已经描述了明显的差异。这些链总是以非随机的方式结合在一起，可能是由单个基因产物的裂解产生的。对水解活性的研究一直很有趣。像其他溶酶体酶一样，HEX A需要特定的蛋白质激活剂才能获得最佳活性。这种小多肽已被部分表征，但其作用方式尚不清楚。激活剂合成缺陷导致一种形式的GM2神经节苷脂储存病。临床上已经确定了许多不同的表型，这些表型似乎是由每个HEX基因的缺陷引起的。这些缺陷之间的差异还没有用分子术语来描述。(摘要删节为400字)

本文章由计算机程序翻译，如有差异，请以英文原文为准。

本刊更多论文

The lysosomal hexosaminidase isozymes.

In the 15 years since the demonstration that HEX A is the defective enzyme in patients with TSD, intensive efforts in many laboratories have revealed much about the HEX group of enzymes. In contradistinction to the two isozymes described by Robinson and Stirling [1968], we now know that there are several different species. They include the products of at least three genes which code for the alpha and beta polypeptides as well as for an enzyme that we have called HEX D. The different species of HEX found in human tissues and fluids include significant amounts of larger, unprocessed polypeptides as well as mature enzyme. Thus the HEX A of serum (HEX AS) is a more primitive form of the enzyme than that found in lysosomes. The role of biosynthesis in the formation of multiple species of HEX is not confined to the polypeptide chains of the enzyme. All lysosomal enzymes are glycosylated and HEX is not an exception. The carbohydrate side-chains are essential to the packaging process that places HEX in the lysosome. Carbohydrates on lysosomal HEX species clearly differ from those on HEX in serum. Characterization of HEX oligosaccharides is still in the preliminary stages. Many minor species of HEX have been described. The more important ones are the intermediate isozymes (HEX Is). In tissues the HEX Is appear to contain mixtures of processed and unprocessed alpha and beta polypeptides. In serum, on the other hand, they contain unprocessed beta chains and differ in the carbohydrate side-chains. Most species of HEX show microheterogeneity. Native, mature HEX B separates into several bands on isoelectric focusing. The nature of this microheterogeneity has not been defined. Clear differences have been described, however, between the two chains in the beta subunit. The chains are always united in non-random fashion and are probably derived by cleavage of a single gene product. Studies of hydrolytic activity have been interesting. Like other lysosomal enzymes, HEX A requires a specific protein activator for optimum activity. This small polypeptide has been partially characterized but its mode of action is as yet unclear. Defects in activator synthesis lead to a form of GM2 ganglioside storage disease. Clinically many different phenotypes have been identified which appear to result from defects in each of the HEX genes. The differences between the defects have not been characterized in molecular terms.(ABSTRACT TRUNCATED AT 400 WORDS)

求助全文

通过发布文献求助，成功后即可免费获取论文全文。去求助

来源期刊

Isozymes

自引率

0.00%

发文量