铜对游离离子浓度相关细菌的抑制作用。

Inhibitory effects of copper on bacteria related to the free ion concentration.

机构信息

Laboratory of Microbiology, Agricultural University, Wageningen, The Netherlands.

出版信息

Microb Ecol. 1979 Jun;5(2):139-46. doi: 10.1007/BF02010505.

DOI:10.1007/BF02010505

Abstract

Cu(2+) ion determinations were carried out in complex and in inorganic salts-glycerol media, to which increasing amounts of Cu(II) had been added, with the ion-specific Cu(II)-Selectrode. Likewise, complexing capacity of bacterial suspensions was estimated by titration with CuSO4.Copper-sensitive bacteria, e.g.,Klebsiella aerogenes, were inhibited in their growth and survival in the range of 10(-8)-10(-6) M Cu(2+) ion concentrations. In copper-buffered complex media, high copper loads could be tolerated, as growth proceeded with most of the copper bound to medium components. In low-complexing mineral salts media, in which high Cu(2+) ion concentrations exist at low copper loads, there was competition of Cu(2+) for binding sites of the cells. Total allowed copper was then determined by the ratio of copper to biomass.Copper-resistant bacteria could be isolated from a stock solution of CuSO4, containing 100 ppm Cu(II). They were of thePseudomonas type and showed a much higher tolerance towards Cu(2+), up to 10(-3) M.

摘要

在添加了不同量 Cu(II)的配合物和无机盐-甘油介质中，使用离子选择性 Cu(II)-Selectrode 进行了 Cu(2+)离子的测定。同样，通过用 CuSO4 滴定来估计细菌悬浮液的络合能力。在 10(-8)-10(-6) M Cu(2+)离子浓度范围内，铜敏感细菌（例如肺炎克雷伯菌）的生长和存活受到抑制。在铜缓冲配合物介质中，可以耐受高铜负荷，因为大部分铜与介质成分结合，生长得以进行。在低络合矿物盐介质中，在低铜负荷下存在高 Cu(2+)离子浓度，Cu(2+)会与细胞的结合位点竞争。然后通过铜与生物量的比值来确定总允许铜量。可以从含有 100 ppm Cu(II)的 CuSO4 储备液中分离出耐铜细菌。它们是假单胞菌属，对 Cu(2+)的耐受性要高得多，高达 10(-3) M。

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铜对游离离子浓度相关细菌的抑制作用。

Inhibitory effects of copper on bacteria related to the free ion concentration.

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