Heterotrophic metabolism on substrates other than glucose

Prokaryotic Metabolism and Physiology Pub Date : 2008-02-01 DOI:10.1017/CBO9780511790461.008

Byung Hong Kim, G. Gadd

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引用次数: 1

Abstract

It has been described previously how glucose and mineral salts can support the growth of certain heterotrophs. In this case, the organisms obtain ATP, NADPH and carbon skeletons for biosynthesis through central metabolism. Almost all natural organic compounds can be utilized through microbial metabolism. In this chapter, the bacterial metabolism of organic compounds other than glucose is discussed. Since central metabolism is reversible in one way or another, it can be assumed that an organism can use a compound if that compound is converted to intermediates of central metabolism. Some bacteria can use an extensive variety of organic compounds as sole carbon and energy sources, while some organisms can only use limited numbers of organic compounds; for example, Bacillus fastidiosus can use only urate. Hydrolysis of polymers Plant and animal cells consist mainly of polymers. They include polysaccharides, such as starch and cellulose, as well as proteins, nucleic acids, and many others. Such polymers cannot be easily transported into microbial cells but are first hydrolyzed to monomers or oligomers by extracellular enzymes before being transported into the cell. Starch hydrolysis Starch is a glucose polymer consisting of amylose and amylopectin. The former has a straight chain structure with α -1,4-glucoside bonds, while the latter has side chains with α -1,6-glucoside bonds. Starch is the commonest storage material in plants, and many prokaryotes produce amylase to utilize it as their energy and carbon source.

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在葡萄糖以外的底物上的异养代谢

前面已经描述了葡萄糖和无矿盐如何支持某些异养生物的生长。在这种情况下，生物体通过中枢代谢获得ATP、NADPH和碳骨架进行生物合成。几乎所有的天然有机化合物都可以通过微生物代谢来利用。在本章中，讨论了除葡萄糖以外的有机化合物的细菌代谢。由于中枢代谢在某种程度上是可逆的，因此可以假设，如果一种化合物转化为中枢代谢的中间体，那么生物体就可以使用这种化合物。有些细菌可以使用种类繁多的有机化合物作为唯一的碳和能量来源，而有些生物体只能使用有限数量的有机化合物;例如，挑剔的芽孢杆菌只能使用精确的。植物和动物的细胞主要由聚合物组成。它们包括多糖，如淀粉和纤维素，以及蛋白质、核酸和许多其他物质。这种聚合物不容易运输到微生物细胞中，但在运输到细胞中之前，首先由细胞外酶水解成单体或低聚物。淀粉是一种葡萄糖聚合物，由直链淀粉和支链淀粉组成。前者具有具有α -1,4-葡萄糖苷键的直链结构，后者具有具有α -1,6-葡萄糖苷键的侧链结构。淀粉是植物中最常见的储存物质，许多原核生物产生淀粉酶，将其作为能量和碳源。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Prokaryotic Metabolism and Physiology

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