The Czech Academy of Sciences, Institute of Vertebrate Biology, Květná 8, 603 65, Brno, Czech Republic.
Department of Botany and Zoology, Faculty of Science, Masaryk University, Kotlářská 2, 611 37, Brno, Czech Republic.
BMC Evol Biol. 2018 Jul 4;18(1):105. doi: 10.1186/s12862-018-1219-9.
Anthropogenic factors can have a major impact on the contemporary distribution of intraspecific genetic diversity. Many freshwater fishes have finely structured and locally adapted populations, but their natural genetic structure can be affected by river engineering schemes across river basins, fish transfers in aquaculture industry and conservation management. The European bitterling (Rhodeus amarus) is a small fish that is a brood parasite of freshwater mussels and is widespread across continental Europe. Its range recently expanded, following sharp declines in the 1970s and 1980s. We investigated its genetic variability and spatial structure at the centre of its distribution at the boundary of three watersheds, testing the role of natural and anthropogenic factors in its genetic structure.
Sequences of mitochondrial cytochrome B (CYTB) revealed that bitterling colonised central Europe from two Ponto-Caspian refugia, which partly defines its contemporary genetic structure. Twelve polymorphic microsatellite loci revealed pronounced interpopulation differentiation, with significant small-scale differentiation within the same river basins. At a large scale, populations from the Baltic Sea watershed (middle Oder and Vistula basins) were distinct from those from the Black Sea watershed (Danube basin), while populations from rivers of the North Sea watershed (Rhine, Elbe) originated from the admixture of both original sources. Notable exceptions demonstrated the potential role of human translocations across watersheds, with the upper River Oder (Baltic watershed) inhabited by fish from the Danube basin (Black Sea watershed) and a population in the southern part of the River Elbe (North Sea watershed) basin possessing a signal of admixture from the Danube basin.
Hydrography and physical barriers to dispersal are only partly reflected in the genetic structure of the European bitterling at the intersection of three major watersheds in central Europe. Drainage boundaries have been obscured by human-mediated translocations, likely related to common carp, Cyprinus carpio, cultivation and game-fish management. Despite these translocations, populations of bitterling are significantly structured by genetic drift, possibly reinforced by its low dispersal ability. Overall, the impact of anthropogenic factors on the genetic structure of the bitterling populations in central Europe is limited.
人为因素会对物种内遗传多样性的现代分布产生重大影响。许多淡水鱼类具有精细结构和局部适应的种群,但它们的自然遗传结构可能会受到流域间河流工程计划、水产养殖行业鱼类转移和保护管理的影响。欧洲鳑鲏(Rhodeus amarus)是一种小鱼,是淡水贻贝类的寄生种,广泛分布于整个欧洲大陆。其分布范围在 20 世纪 70 年代和 80 年代急剧下降后最近有所扩大。我们在三个流域边界的分布中心研究了它的遗传变异性和空间结构,检验了自然和人为因素在其遗传结构中的作用。
线粒体细胞色素 B(CYTB)序列显示,鳑鲏从两个里海-黑海避难所向欧洲中部地区殖民,这部分解释了其现代遗传结构。12 个多态微卫星位点揭示了明显的种群间分化,同一河流流域内存在显著的小规模分化。在大尺度上,波罗的海流域(奥得河和维斯瓦河盆地)的种群与黑海流域(多瑙河盆地)的种群明显不同,而北海流域(莱茵河、易北河)的种群则来自两个原始来源的混合。值得注意的例外表明了人类跨流域迁移的潜在作用,奥得河上游(波罗的海流域)栖息着来自多瑙河流域(黑海流域)的鱼类,易北河南部流域的一个种群也存在来自多瑙河流域的混合信号。
在中欧三个主要流域的交汇处,欧洲鳑鲏的遗传结构仅部分反映了水文和扩散的物理障碍。排水边界已经被人为介导的迁移所掩盖,这可能与鲤鱼、Cyprinus carpio 的养殖和渔猎管理有关。尽管存在这些迁移,鳑鲏种群的遗传结构仍受到显著的遗传漂变的影响,这可能是由其低扩散能力加强的。总的来说,人为因素对中欧鳑鲏种群遗传结构的影响是有限的。