Chan Farrah T, MacIsaac Hugh J, Bailey Sarah A
Great Lakes Institute for Environmental Research, University of Windsor, Windsor, ON N9B 3P4 Canada ; Great Lakes Laboratory for Fisheries and Aquatic Sciences, Fisheries and Oceans Canada, Burlington, ON L7S 1A1 Canada.
Great Lakes Institute for Environmental Research, University of Windsor, Windsor, ON N9B 3P4 Canada.
Mar Biol. 2016;163(12):250. doi: 10.1007/s00227-016-3029-1. Epub 2016 Nov 11.
Human-mediated vectors often inadvertently translocate species assemblages to new environments. Examining the dynamics of entrained species assemblages during transport can provide insights into the introduction risk associated with these vectors. Ship biofouling is a major transport vector of nonindigenous species in coastal ecosystems globally, yet its magnitude in the Arctic is poorly understood. To determine whether biofouling organisms on ships can survive passages in Arctic waters, we examined how biofouling assemblage structure changed before, during, and after eight round-trip military voyages from temperate to Arctic ports in Canada. Species richness first decreased (70% loss) and then recovered (27% loss compared to the original assemblages), as ships travelled to and from the Arctic, respectively, whereas total abundance typically declined over time (~55% total loss). Biofouling community structure differed significantly before and during Arctic transits as well as between those sampled during and after voyages. Assemblage structure varied across different parts of the hull; however, temporal changes were independent of hull location, suggesting that niche areas did not provide protection for biofouling organisms against adverse conditions in the Arctic. Biofouling algae appear to be more tolerant of transport conditions during Arctic voyages than are mobile, sessile, and sedentary invertebrates. Our results suggest that biofouling assemblages on ships generally have poor survivorship during Arctic voyages. Nonetheless, some potential for transporting nonindigenous species to the Arctic via ship biofouling remains, as at least six taxa new to the Canadian Arctic, including a nonindigenous cirripede, appeared to have survived transits from temperate to Arctic ports.
人类介导的载体常常不经意间将物种组合转移到新的环境中。研究运输过程中夹带的物种组合的动态变化,可以深入了解与这些载体相关的引入风险。船舶生物污损是全球沿海生态系统中非本土物种的主要运输载体,但其在北极地区的规模却鲜为人知。为了确定船舶上的生物污损生物能否在北极水域的航行中存活下来,我们研究了八次从加拿大温带港口到北极港口的往返军事航行过程中,生物污损组合结构在航行前、航行中和航行后的变化情况。随着船舶往返北极,物种丰富度首先下降(损失约70%),然后恢复(与原始组合相比损失约27%),而总丰度通常随时间下降(总损失约55%)。北极航行前后以及航行期间和航行后采样的生物污损群落结构存在显著差异。组合结构在船体的不同部位有所不同;然而,时间变化与船体位置无关,这表明生态位区域并不能为生物污损生物提供保护,使其免受北极恶劣条件的影响。与活动的、固着的和定居的无脊椎动物相比,生物污损藻类似乎在北极航行期间对运输条件更具耐受性。我们的研究结果表明,船舶上的生物污损组合在北极航行期间的生存能力普遍较差。尽管如此,通过船舶生物污损将非本土物种运输到北极仍存在一定可能性,因为至少有六个加拿大北极地区新出现的分类单元,包括一种非本土藤壶,似乎在从温带港口到北极港口的航行中存活了下来。
