Ehrenreich A, Widdel F
Max-Planck-Institut für Marine Mikrobiologie, Bremen, Germany.
Appl Environ Microbiol. 1994 Dec;60(12):4517-26. doi: 10.1128/aem.60.12.4517-4526.1994.
Anoxic iron-rich sediment samples that had been stored in the light showed development of brown, rusty patches. Subcultures in defined mineral media with ferrous iron (10 mmol/liter, mostly precipitated as FeCO3) yielded enrichments of anoxygenic phototrophic bacteria which used ferrous iron as the sole electron donor for photosynthesis. Two different types of purple bacteria, represented by strains L7 and SW2, were isolated which oxidized colorless ferrous iron under anoxic conditions in the light to brown ferric iron. Strain L7 had rod-shaped, nonmotile cells (1.3 by 2 to 3 microns) which frequently formed gas vesicles. In addition to ferrous iron, strain L7 used H2 + CO2, acetate, pyruvate, and glucose as substrate for phototrophic growth. Strain SW2 had small rod-shaped, nonmotile cells (0.5 by 1 to 1.5 microns). Besides ferrous iron, strain SW2 utilized H2 + CO2, monocarboxylic acids, glucose, and fructose. Neither strain utilized free sulfide; however, both strains grew on black ferrous sulfide (FeS) which was converted to ferric iron and sulfate. Strains L7 and SW2 grown photoheterotrophically without ferrous iron were purple to brownish red and yellowish brown, respectively; absorption spectra revealed peaks characteristic of bacteriochlorophyll a. The closest phototrophic relatives of strains L7 and SW2 so far examined on the basis of 16S rRNA sequences were species of the genera Chromatium (gamma subclass of proteobacteria) and Rhodobacter (alpha subclass), respectively. In mineral medium, the new isolates formed 7.6 g of cell dry mass per mol of Fe(II) oxidized, which is in good agreement with a photoautotrophic utilization of ferrous iron as electron donor for CO2 fixation. Dependence of ferrous iron oxidation on light and CO2 was also demonstrated in dense cell suspensions. In media containing both ferrous iron and an organic substrate (e.g., acetate, glucose), strain L7 utilized ferrous iron and the organic compound simultaneously; in contrast, strain SW2 started to oxidize ferrous iron only after consumption of the organic electron donor. Ferrous iron oxidation by anoxygenic phototrophs is understandable in terms of energetics. In contrast to the Fe3+/Fe2+ pair (E0 = +0.77 V) existing in acidic solutions, the relevant redox pair at pH 7 in bicarbonate-containing environments, Fe(OH)3 + HCO3-/FeCO3, has an E0' of +0.2 V. Ferrous iron at pH 7 can therefore donate electrons to the photosystem of anoxygenic phototrophs, which in purple bacteria has a midpoint potential around +0.45 V. The existence of ferrous iron-oxidizing anoxygenic phototrophs may offer an explanation for the deposition of early banded-iron formations in an assumed anoxic biosphere in Archean times.
储存在光照条件下的缺氧富铁沉积物样本出现了棕色锈斑。在含有亚铁离子(10 mmol/升,大部分以碳酸亚铁形式沉淀)的特定矿物培养基中进行传代培养,富集得到了以亚铁离子为光合作用唯一电子供体的无氧光合细菌。分离出了两种不同类型的紫色细菌,分别以菌株L7和SW2为代表,它们在光照无氧条件下将无色亚铁离子氧化为棕色铁离子。菌株L7具有杆状、不运动的细胞(1.3×2至3微米),常形成气体小泡。除亚铁离子外,菌株L7利用氢气 + 二氧化碳、乙酸盐、丙酮酸盐和葡萄糖作为光合生长的底物。菌株SW2具有小的杆状、不运动的细胞(0.5×1至1.5微米)。除亚铁离子外,菌株SW2利用氢气 + 二氧化碳、一元羧酸、葡萄糖和果糖。两种菌株都不利用游离硫化物;然而,两种菌株都能在黑色硫化亚铁(FeS)上生长,FeS被转化为铁离子和硫酸盐。在无光亚铁离子条件下进行光异养生长的菌株L7和SW2分别呈紫色至棕红色和黄棕色;吸收光谱显示出细菌叶绿素a的特征峰。根据16S rRNA序列,到目前为止所检测的菌株L7和SW2亲缘关系最近的光合细菌分别是嗜色菌属(变形菌纲γ亚类)和红杆菌属(α亚类)的物种。在矿物培养基中,新分离的菌株每氧化1摩尔亚铁离子形成7.6克细胞干重,这与以亚铁离子作为二氧化碳固定的电子供体进行光合自养利用情况相符。在密集细胞悬液中也证实了亚铁离子氧化对光照和二氧化碳的依赖性。在同时含有亚铁离子和有机底物(如乙酸盐、葡萄糖)的培养基中,菌株L7同时利用亚铁离子和有机化合物;相反,菌株SW2仅在消耗有机电子供体后才开始氧化亚铁离子。从能量学角度来看,无氧光合细菌对亚铁离子的氧化是可以理解的。与酸性溶液中存在的Fe3+/Fe2+对(E0 = +0.77 V)不同,在含碳酸氢盐的环境中pH为7时,相关的氧化还原对Fe(OH)3 + HCO3-/FeCO3的E0'为 +0.2 V。因此,pH为7时的亚铁离子可以向无氧光合细菌的光系统提供电子,在紫色细菌中光系统的中点电位约为 +0.45 V。亚铁离子氧化型无氧光合细菌的存在可能为太古代假定的无氧生物圈中早期条带状铁建造的沉积提供了一种解释。
