Bereich Mikrobiologie, Department Biologie I, Ludwig-Maximilians-Universität München, Martinsried, Germany.
Environ Microbiol. 2010 May;12(5):1348-62. doi: 10.1111/j.1462-2920.2010.02178.x. Epub 2010 Mar 9.
The Black Sea chemocline represents the largest extant habitat of anoxygenic phototrophic bacteria and harbours a monospecific population of Chlorobium phylotype BS-1. High-sensitivity measurements of underwater irradiance and sulfide revealed that the optical properties of the overlying water column were similar across the Black Sea basin, whereas the vertical profiles of sulfide varied strongly between sampling sites and caused a dome-shaped three-dimensional distribution of the green sulfur bacteria. In the centres of the western and eastern basins the population of BS-1 reached upward to depths of 80 and 95 m, respectively, but were detected only at 145 m depth close to the shelf. Using highly concentrated chemocline samples from the centres of the western and eastern basins, the cells were found to be capable of anoxygenic photosynthesis under in situ light conditions and exhibited a photosynthesis-irradiance curve similar to low-light-adapted laboratory cultures of Chlorobium BS-1. Application of a highly specific RT-qPCR method which targets the internal transcribed spacer (ITS) region of the rrn operon of BS-1 demonstrated that only cells at the central station are physiologically active in contrast to those at the Black Sea periphery. Based on the detection of ITS-DNA sequences in the flocculent surface layer of deep-sea sediments across the Black Sea, the population of BS-1 has occupied the major part of the basin for the last decade. The continued presence of intact but non-growing BS-1 cells at the periphery of the Black Sea indicates that the cells can survive long-distant transport and exhibit unusually low maintenance energy requirements. According to laboratory measurements, Chlorobium BS-1 has a maintenance energy requirement of approximately 1.6-4.9.10(-15) kJ cell(-1) day(-1) which is the lowest value determined for any bacterial culture so far. Chlorobium BS-1 thus is particularly well adapted to survival under the extreme low-light conditions of the Black Sea, and can be used as a laboratory model to elucidate general cellular mechanisms of long-term starvation survival. Because of its adaptation to extreme low-light marine environments, Chlorobium BS-1 also represents a suitable indicator for palaeoceanography studies of deep photic zone anoxia in ancient oceans.
黑海化变层代表了现今存在的最大的贫氧光合作用细菌生境,并且拥有一个专性的 Chlorobium phylotype BS-1 种群。对水下辐照度和硫化物的高灵敏度测量表明,整个黑海盆地的上层水柱的光学性质相似,而硫化物的垂直分布在采样点之间有很大差异,导致绿硫细菌呈三维穹顶状分布。在西部和东部盆地的中心,BS-1 的种群向上延伸到 80 和 95 米的深度,但仅在靠近大陆架的 145 米深处被检测到。使用来自西部和东部盆地中心的高浓度化变层样本,发现这些细胞能够在原位光照条件下进行厌氧光合作用,并表现出与低光适应的 Chlorobium BS-1 实验室培养物相似的光合作用-辐照度曲线。应用一种高度特异性的 RT-qPCR 方法,该方法针对 BS-1 的 rrn 操纵子的内部转录间隔区 (ITS) 区域,证明只有在中央站的细胞在生理上是活跃的,而在黑海边缘的细胞则不是。根据在整个黑海的深海沉积物的絮状表面层中检测到的 ITS-DNA 序列,BS-1 的种群在过去十年中占据了盆地的大部分。在黑海边缘仍存在完整但非生长的 BS-1 细胞表明,这些细胞能够在长距离运输中存活,并表现出异常低的维持能量需求。根据实验室测量,Chlorobium BS-1 的维持能量需求约为 1.6-4.9.10(-15) kJ 细胞(-1) day(-1),这是迄今为止确定的任何细菌培养物的最低值。因此,Chlorobium BS-1 特别适应于黑海极端低光条件下的生存,并且可以用作实验室模型来阐明长期饥饿生存的一般细胞机制。由于其对极端低光海洋环境的适应,Chlorobium BS-1 也代表了古代海洋深层透光缺氧古海洋学研究的合适指标。
