Litwin C M, Calderwood S B
Infectious Disease Unit, Massachusetts General Hospital, Boston 02114.
J Bacteriol. 1994 Jan;176(1):240-8. doi: 10.1128/jb.176.1.240-248.1994.
Iron concentration influences the expression of a number of genes involved in iron uptake and virulence in bacteria. In Escherichia coli, coordinate regulation of these genes by iron depends on the product of the fur gene, which acts as an iron-responsive, DNA-binding repressor protein. Several genes in Vibrio cholerae are also repressed by iron; and a fur gene, homologous to E. coli fur, has been previously cloned from this organism. The present study was undertaken to define the roles of Fur and iron in regulating gene expression in V. cholerae. V. cholerae strains with a mutation in fur by virtue of suicide plasmid integration into this gene showed derepressed expression of two previously characterized, iron-regulated genes, irgA and viuA, in high concentrations of iron; even in the fur mutants, however, residual two- to threefold regulation by iron persisted. The fur mutant strains constructed by suicide plasmid integration required antibiotic selection to maintain the mutation. To analyze further the effect of Fur and iron on gene regulation in V. cholerae without the need for antibiotic selection, we used in vivo marker exchange to construct a nonrevertible V. cholerae fur mutant. This V. cholerae fur mutant grew significantly less well in Luria-Bertani medium than the wild-type parent but grew slightly better than the wild type under iron-restricted conditions. The V. cholerae fur mutant was unable to utilize a number of carbon sources including glycerol, acetate, succinate, lactate, and fumarate, that supported growth of the wild-type strain on minimal media. We utilized two-dimensional gel electrophoresis of whole-cell protein extracts from the fur mutant and wild-type strains following growth in conditions of either low or high concentrations of iron to identify proteins regulated by iron and/or Fur. Twenty-two proteins were negatively regulated by iron in the wild-type strain but constitutively expressed in the fur mutant, consistent with the model of Fur as an iron-dependent repressor. However, many other proteins were regulated in a different manner by iron and/or Fur. Seventeen proteins were negatively regulated by iron but independent of Fur, suggesting the presence of an additional iron-dependent repressor(s). Six proteins were strongly iron regulated in the fur mutant but hardly expressed at all in the wild-type strain regardless of the iron concentration, suggesting an interaction between Fur and another iron regulatory mechanism. There were 11 proteins that were induced rather than repressed by iron, in four different regulatory classes. Gene regulation in V. cholerae by Fur and iron is much more complex than previously thought and is reminiscent of the Lrp regulon in E.coli.
铁浓度会影响许多参与细菌铁摄取和毒力的基因的表达。在大肠杆菌中,铁对这些基因的协同调节取决于fur基因的产物,该产物作为一种铁响应性DNA结合阻遏蛋白发挥作用。霍乱弧菌中的几个基因也受到铁的抑制;并且,与大肠杆菌fur基因同源的一个fur基因此前已从该生物体中克隆出来。本研究旨在确定Fur和铁在调节霍乱弧菌基因表达中的作用。通过自杀质粒整合到该基因中而导致fur基因突变的霍乱弧菌菌株,在高浓度铁条件下显示出两个先前已鉴定的铁调节基因irgA和viuA的去抑制表达;然而,即使在fur突变体中,铁仍存在两到三倍的残留调节作用。通过自杀质粒整合构建的fur突变体菌株需要抗生素选择来维持突变。为了在无需抗生素选择的情况下进一步分析Fur和铁对霍乱弧菌基因调节的影响,我们使用体内标记交换构建了一个不可逆的霍乱弧菌fur突变体。该霍乱弧菌fur突变体在Luria-Bertani培养基中的生长明显不如野生型亲本,但在铁限制条件下比野生型生长得稍好一些。霍乱弧菌fur突变体无法利用包括甘油、乙酸盐、琥珀酸盐、乳酸盐和富马酸盐在内的多种碳源,而这些碳源能支持野生型菌株在基本培养基上生长。我们利用在低铁或高铁条件下生长后的fur突变体和野生型菌株的全细胞蛋白提取物进行二维凝胶电泳,以鉴定受铁和/或Fur调节的蛋白质。在野生型菌株中,有22种蛋白质受到铁的负调节,但在fur突变体中组成性表达,这与Fur作为铁依赖性阻遏物的模型一致。然而,许多其他蛋白质受到铁和/或Fur的不同方式调节。17种蛋白质受到铁的负调节但与Fur无关,这表明存在一种额外的铁依赖性阻遏物。6种蛋白质在fur突变体中受到强烈的铁调节,但在野生型菌株中无论铁浓度如何几乎都不表达,这表明Fur与另一种铁调节机制之间存在相互作用。有11种蛋白质被铁诱导而非抑制,分为四个不同的调节类别。霍乱弧菌中Fur和铁对基因的调节比以前认为的要复杂得多,这让人联想到大肠杆菌中的Lrp调节子。
