Spatial patterns of spring meroplankton along environmental gradients in a sub-Arctic fjord

IF 1.3 4区生物学 Q3 MARINE & FRESHWATER BIOLOGY

Aquatic Biology Pub Date : 2017-11-02 DOI:10.3354/AB00686

Helena Kling Michelsen, E. M. Nilssen, T. Pedersen, M. Reigstad, C. Svensen

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引用次数: 4

Abstract

The spatial patterns in abundance and composition of benthic invertebrate larvae (meroplankton), the correlation between these patterns and environmental variables (temperature, salinity and chl a) and the relative abundance of meroplankton in the mesozooplankton community were investigated in the sub-Arctic Porsangerfjord, Norway (70° N). Zooplankton samples and CTD-profiles were collected at 17 stations along the fjord in April 2013. A total of 32 morphologically different larval types belonging to 8 phyla were identified. Meroplankton were found at all stations, and their community and abundance differed significantly along the fjord. Meroplankton abundance in the inner and outer parts of the fjord was low and was dominated by Gastropoda and Echinodermata. The greatest numbers were recorded in shallow bays and the middle part of the fjord where Cirripedia and Polychaeta were dominant. Meroplankton contributed significantly to the mesozooplankton community in the bays (30 to 90%) and mid-fjord (13 to 48%) areas. These changes in community structure were attributed to spatial gradients in environmental variables such as chl a, salinity and temperature. The different communities suggested a seasonal succession in reproductive events from the fjord mouth toward the head. Considering that spring is an important season for reproduction in pelagic organisms, meroplankton may play a role in the pelagic ecosystem of high-latitude fjords as grazers and prey. Furthermore, the spatial dynamics and reproductive timing of benthic and holoplanktonic organisms are sensitive to local hydrographical features, illustrating their sensitivity to changing environments.

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亚北极峡湾春季浮游生物沿环境梯度的空间格局

2013年4月，在挪威亚北极Porsangerfjord(70°N)调查了底栖无脊椎动物(meroplankton)幼虫丰度和组成的空间格局、与环境变量(温度、盐度和chl a)的相关性以及中浮游动物群落中meroplankton的相对丰度。共鉴定出形态不同的幼虫32种，隶属于8门。各监测站均发现浮游生物，其群落和丰度沿峡湾有显著差异。峡湾内外浮游生物丰度较低，以腹足类和棘皮类为主。浅水湾和峡湾中部数量最多，以卷毛纲和多毛纲为主。海湾区(30% ~ 90%)和峡湾中区(13% ~ 48%)浮游生物对中浮游动物群落的贡献较大。这些群落结构的变化主要与chl a、盐度和温度等环境变量的空间梯度有关。不同的群落表明，从峡湾口到头部的繁殖事件具有季节性演替。考虑到春季是远洋生物繁殖的重要季节，浮游生物可能在高纬度峡湾的远洋生态系统中扮演食草动物和猎物的角色。此外，底栖生物和全浮游生物的空间动态和繁殖时间对当地水文特征很敏感，说明它们对环境变化的敏感性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Aquatic Biology 生物-海洋与淡水生物学

CiteScore

2.70

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： AB publishes rigorously refereed and carefully selected Feature Articles, Research Articles, Reviews and Notes, as well as Comments/Reply Comments (for details see MEPS 228:1), Theme Sections, Opinion Pieces (previously called ''As I See It'') (for details consult the Guidelines for Authors) concerned with the biology, physiology, biochemistry and genetics (including the ’omics‘) of all aquatic organisms under laboratory and field conditions, and at all levels of organisation and investigation. Areas covered include: -Biological aspects of biota: Evolution and speciation; life histories; biodiversity, biogeography and phylogeography; population genetics; biological connectedness between marine and freshwater biota; paleobiology of aquatic environments; invasive species. -Biochemical and physiological aspects of aquatic life; synthesis and conversion of organic matter (mechanisms of auto- and heterotrophy, digestion, respiration, nutrition); thermo-, ion, osmo- and volume-regulation; stress and stress resistance; metabolism and energy budgets; non-genetic and genetic adaptation. -Species interactions: Environment–organism and organism–organism interrelationships; predation: defenses (physical and chemical); symbioses. -Molecular biology of aquatic life. -Behavior: Orientation in space and time; migrations; feeding and reproductive behavior; agonistic behavior. -Toxicology and water-quality effects on organisms; anthropogenic impacts on aquatic biota (e.g. pollution, fisheries); stream regulation and restoration. -Theoretical biology: mathematical modelling of biological processes and species interactions. -Methodology and equipment employed in aquatic biological research; underwater exploration and experimentation. -Exploitation of aquatic biota: Fisheries; cultivation of aquatic organisms: use, management, protection and conservation of living aquatic resources. -Reproduction and development in marine, brackish and freshwater organisms