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大肠杆菌中tonB基因座与铁转运的关系。

Relationship between the tonB locus and iron transport in Escherichia coli.

作者信息

Frost G E, Rosenberg H

出版信息

J Bacteriol. 1975 Nov;124(2):704-12. doi: 10.1128/jb.124.2.704-712.1975.

Abstract

When a strain (arcB-) of Escherichia coli, unable to synthesize the iron transport compound enterochelin, was transduced to tonB-, it became resistant to phage phi80 and simultaneously lost the growth response to enterochelin and the ability to transport its iron complex. However, enterochelin precursors (shikimate and 2,3-dihydroxybenzoate) still supported growth, via the synthesis of enterochelin. Dihydroxybenzoate was a better growth factor at a low concentration than it was at higher levels. The evidence suggests that tonB- strains lack an outer membrane component necessary both for the uptake of ferric-enterochelin and for the adsorption of phage phi80. Thus, although ferric-enterochelin cannot penetrate the cell surface from outside, the complex that is formed within the envelope is transported normally into the cell. The aroB-, tonB- mutant also lacked growth reponses to citrate and various hydroxamate siderochromes, which supported growth in the tonB+ parent strain via inducible transport systems for their ferric complexes. The aroB-, tonB- mutant was unable to transport iron in the presence of citrate, but the low-affinity uptake of uncomplexed iron and the transport of amino acids and phosphate were unimpaired. The tonB locus, thus, affects all the known active transport systems for iron, possibly indicating that they share some common outer membrane component.

摘要

当无法合成铁转运化合物肠螯合素的大肠杆菌菌株(arcB-)被转导为tonB-时,它对噬菌体phi80产生抗性,同时失去了对肠螯合素的生长反应以及转运其铁复合物的能力。然而,肠螯合素前体(莽草酸和2,3-二羟基苯甲酸)仍可通过肠螯合素的合成来支持生长。在低浓度下,二羟基苯甲酸作为生长因子比在较高浓度时效果更好。证据表明,tonB-菌株缺乏摄取铁-肠螯合素和吸附噬菌体phi80所需的外膜成分。因此,尽管铁-肠螯合素无法从外部穿透细胞表面,但在包膜内形成的复合物能正常转运到细胞中。aroB-、tonB-突变体对柠檬酸盐和各种异羟肟酸铁载体也缺乏生长反应,这些物质在tonB+亲本菌株中可通过其铁复合物的诱导转运系统来支持生长。aroB-、tonB-突变体在有柠檬酸盐存在时无法转运铁,但对未结合铁的低亲和力摄取以及氨基酸和磷酸盐的转运未受影响。因此,tonB位点影响所有已知的铁主动转运系统,这可能表明它们共享一些共同的外膜成分。

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