真菌中的铁吸收：适用于每种铁源的系统

Iron uptake in fungi: a system for every source.

作者信息

Philpott Caroline C

机构信息

Liver Disease Branch, National Institute of Diabetes and Digestive and Kidney Diseases, National Institutes of Health, Bethesda, MD, USA.

出版信息

Biochim Biophys Acta. 2006 Jul;1763(7):636-45. doi: 10.1016/j.bbamcr.2006.05.008. Epub 2006 May 19.

DOI:10.1016/j.bbamcr.2006.05.008

PMID:16806534

Abstract

Fungi have a remarkable capacity to take up iron when present in any of a wide variety of forms, which include free iron ions, low-affinity iron chelates, siderophore-iron chelates, transferrin, heme, and hemoglobin. Appropriately, these unicellular eukaryotes express a variety of iron uptake systems, some of which are unique to fungi and some of which are present in plants and animals, as well. The reductive system of uptake relies upon the external reduction of ferric salts, chelates, and proteins prior to uptake by a high-affinity, ferrous-specific, oxidase/permease complex. This system recognizes a broad range of substrates. The non-reductive system exhibits specificity for siderophore-iron chelates, and transporters of this system exhibit multiple substrate-dependent intracellular trafficking events.

摘要

真菌具有非凡的能力，能够摄取多种形式存在的铁，这些形式包括游离铁离子、低亲和力铁螯合物、铁载体 - 铁螯合物、转铁蛋白、血红素和血红蛋白。相应地，这些单细胞真核生物表达多种铁摄取系统，其中一些是真菌特有的，还有一些在植物和动物中也存在。摄取的还原系统依赖于在被高亲和力、亚铁特异性氧化酶/通透酶复合物摄取之前，对铁盐、螯合物和蛋白质进行外部还原。该系统识别广泛的底物。非还原系统对铁载体 - 铁螯合物具有特异性，并且该系统的转运蛋白表现出多种依赖于底物的细胞内运输事件。

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真菌中的铁吸收：适用于每种铁源的系统

Iron uptake in fungi: a system for every source.

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