Horn Point Laboratory, University of Maryland Center for Environmental Science, Cambridge, MD, USA.
Microb Ecol. 2011 Aug;62(2):374-82. doi: 10.1007/s00248-011-9805-z. Epub 2011 Feb 1.
Coastal zones encompass a complex spectrum of environmental gradients that each impact the composition of bacterioplankton communities. Few studies have attempted to address these gradients comprehensively. We generated a synoptic, 16S rRNA gene-based bacterioplankton community profile of a coastal zone by applying the fingerprinting technique denaturing gradient gel electrophoresis to water samples collected from the Columbia River, estuary, and plume, and along coastal transects covering 360 km of the Oregon and Washington coasts and extending to the deep ocean (>2,000 m). Communities were found to cluster into five distinct groups based on location in the system (ANOSIM, p < 0.003): estuary, plume, epipelagic, shelf bottom (depth < 150 m), and slope bottom (depth > 650 m). Across all environments, abiotic factors (salinity, temperature, depth) explained most of the community variability (ρ = 0.734). But within each coastal environment, biotic factors explained most of the variability. Thus, structuring physical factors in coastal zones, such as salinity and temperature, define the boundaries of many distinct microbial habitats, but within these habitats variability in microbial communities is explained by biological gradients in primary and secondary productivity.
沿海区域包含一系列复杂的环境梯度,这些梯度都会影响到浮游细菌群落的组成。目前,鲜有研究能全面解决这些梯度问题。我们采用变性梯度凝胶电泳指纹图谱技术,对采集自哥伦比亚河、河口、羽流以及沿俄勒冈州和华盛顿州长达 360 公里的沿海岸线(延伸至深海 >2000 米)的水样进行分析,从而综合描绘了一幅沿海区域浮游细菌群落图谱。研究发现,根据系统内的位置,群落可分为五个不同的群组(ANOSIM,p<0.003):河口、羽流、表水层、大陆架底层(<150 米深)和斜坡底层(>650 米深)。在所有环境中,非生物因素(盐度、温度、深度)解释了群落大部分的变异性(ρ=0.734)。但是,在每个沿海环境中,生物因素解释了大部分的变异性。因此,沿海区域的物理结构因素(如盐度和温度)决定了许多不同微生物生境的边界,但在这些生境中,微生物群落的变异性是由初级和次级生产力的生物梯度来解释的。
