Interspecific competition between Enteromorpha (Ulvales: Chlorophyceae) and Fucus (Fucales: Phaeophyceae) germlings: effects of nutrient concentration, temperature, and settlement density

Steen, Henning

doi:10.3354/meps278089

Cited by 32 publications

(27 citation statements)

References 56 publications

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“…For example, reduced temperature (7°C vs. 17°C) lowered the competitive power of the ephemeral alga Ulva compressa (formerly known as Enteromorpha compressa) on germling settlement and growth of F . distichus (60% vs. 100% yield reduction) (Steen ). Although temperate species may not outcompete F .…”

Section: Discussionmentioning

confidence: 99%

“…In the Arctic, F. distichus may have a competitive advantage because of its adaptation to cold conditions and long dark periods. For example, reduced temperature (7°C vs. 17°C) lowered the competitive power of the ephemeral alga Ulva compressa (formerly known as Enteromorpha compressa) on germling settlement and growth of F. distichus (60% vs. 100% yield reduction) (Steen 2004). Although temperate species may not outcompete F. distichus in the Arctic, they may truncate its upper and lower zonation boundaries.…”

Section: Changes In Diversity and Biotic Interactionsmentioning

confidence: 99%

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The fate of the Arctic seaweed Fucus distichus under climate change: an ecological niche modeling approach

Jueterbock

Smolina

Coyer

et al. 2016

Ecology and Evolution

124

113

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Rising temperatures are predicted to melt all perennial ice cover in the Arctic by the end of this century, thus opening up suitable habitat for temperate and subarctic species. Canopy-forming seaweeds provide an ideal system to predict the potential impact of climate-change on rocky-shore ecosystems, given their direct dependence on temperature and their key role in the ecological system. Our primary objective was to predict the climate-change induced range-shift of Fucus distichus, the dominant canopy-forming macroalga in the Arctic and subarctic rocky intertidal. More specifically, we asked: which Arctic/subarctic and cold-temperate shores of the northern hemisphere will display the greatest distributional change of F. distichus and how will this affect niche overlap with seaweeds from temperate regions? We used the program MAXENT to develop correlative ecological niche models with dominant range-limiting factors and 169 occurrence records. Using three climate-change scenarios, we projected habitat suitability of F. distichus -and its niche overlap with three dominant temperate macroalgae -until year 2200. Maximum sea surface temperature was identified as the most important factor in limiting the fundamental niche of F. distichus. Rising temperatures were predicted to have low impact on the species' southern distribution limits, but to shift its northern distribution limits poleward into the high Arctic. In cold-temperate to subarctic regions, new areas of niche overlap were predicted between F. distichus and intertidal macroalgae immigrating from the south. While climate-change threatens intertidal seaweeds in warm-temperate regions, seaweed meadows will likely flourish in the Arctic intertidal. Although this enriches biodiversity and opens up new seaweed-harvesting grounds, it will also trigger unpredictable changes in the structure and functioning of the Arctic intertidal ecosystem.

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Section: Discussionmentioning

confidence: 99%

Section: Changes In Diversity and Biotic Interactionsmentioning

confidence: 99%

The fate of the Arctic seaweed Fucus distichus under climate change: an ecological niche modeling approach

Jueterbock

Smolina

Coyer

et al. 2016

Ecology and Evolution

124

113

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“…Increasing nitrogen loading tends to favor fast‐growing species with high nitrogen requirements. In some cases, this may lead to competitive dominance by weedy taxa (Steen , Vermeij et al. ) and – should nutrients trigger a phytoplankton bloom – shading‐out of benthic seaweeds by phytoplankton (Kavanaugh et al.…”

Section: Community‐level Responses: Interspecific Interactions and Inmentioning

confidence: 99%

“…Increasing nitrogen loading tends to favor fast-growing species with high nitrogen requirements. In some cases, this may lead to competitive dominance by weedy taxa (Steen 2004b, Vermeij et al 2010) andshould nutrients trigger a phytoplankton bloomshadingout of benthic seaweeds by phytoplankton (Kavanaugh et al 2009). In other cases, higher nitrogen CLIMATE CHANGE AND SEAWEEDS 1069 merely allows for the persistence of nitrogen-limited taxa and thus enhances algal diversity (Bracken and Nielsen 2004).…”

Section: Interactions and Indirect Effectsmentioning

confidence: 99%

Effects of Climate Change on Global Seaweed Communities

Harley

Anderson

Demes

et al. 2012

Journal of Phycology

559

417

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Seaweeds are ecologically important primary producers, competitors, and ecosystem engineers that play a central role in coastal habitats ranging from kelp forests to coral reefs. Although seaweeds are known to be vulnerable to physical and chemical changes in the marine environment, the impacts of ongoing and future anthropogenic climate change in seaweed-dominated ecosystems remain poorly understood. In this review, we describe the ways in which changes in the environment directly affect seaweeds in terms of their physiology, growth, reproduction, and survival. We consider the extent to which seaweed species may be able to respond to these changes via adaptation or migration. We also examine the extensive reshuffling of communities that is occurring as the ecological balance between competing species changes, and as top-down control by herbivores becomes stronger or weaker. Finally, we delve into some of the ecosystem-level responses to these changes, including changes in primary productivity, diversity, and resilience. Although there are several key areas in which ecological insight is lacking, we suggest that reasonable climate-related hypotheses can be developed and tested based on current information. By strategically prioritizing research in the areas of complex environmental variation, multiple stressor effects, evolutionary adaptation, and population, community, and ecosystem-level responses, we can rapidly build upon our current understanding of seaweed biology and climate change ecology to more effectively conserve and manage coastal ecosystems.

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“…For P. globosa, although a negative effect of phosphorous upon this harmful alga was detected from the field data, this result should be considered with caution as it was derived from field observation during the increasing phase of bloom when rapid uptake by the colonial algae and consequently P-depletion were supposed to be happened simultaneously. Nonetheless, these bottom-up processes, involving the ambient physic-chemical factors such as temperature, salinity, light and nutrients, played a most important role in coastal and particular estuarine and bay ecosystems (Steen 2004;Cohen and Fong 2004;Worm and Lotze 2006). This …”

Section: Discussionmentioning

confidence: 99%

Planktonic community structure during a harmful bloom of Phaeocystis globosa in a subtropical bay, with special reference to the ciliate assemblages

Liu

Huang

et al. 2015

Ecotoxicology

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Planktonic community structure was investigated during outbreak of harmful Phaeocystis globosa bloom in a subtropical bay, the Maowei Sea, South China Sea. The phytoplankton assemblage was numerically dominated by colonial P. globosa, with its abundance ranging from 1.23 × 10(8) to 11.12 × 10(8) cells m(-3) and contributing nearly 90 % to the total abundance. Totally 66 mesozooplankton (>169 µm) and 19 ciliates species were recorded, with the densities ranged from 169 to 1633 ind m(-3) and 74 to 1118 cells L(-1), respectively. The dominant species for mesozooplankton were Copepoda (larvae), Bestiola sinicus, B. amoyensis, Macrura (larvae) and Acartia spinicauda, respectively. The ciliate assemblage was numerically dominated by Codonella rapa, Strombidium globosaneum and Mesodinium rubrum. During the bloom, P. globosa seemed to be negatively affected by the nutrient phosphate significantly (p < 0.05). However, no correlation between P. globosa and ciliate assemblage was detected, but P. globosa was negatively correlated with total biomass of mesozooplankton and abundance of B. sinicus (p < 0.05), suggesting that P. globosa was uncoupled from the grazing by both ciliates and mesozooplankton when appearing as colonies form. On the other hand, both positive and negative correlations among the dominant groups of mesozooplankton and ciliates were observed (p < 0.05) which possibly indicated that the predation of mesozooplankton upon ciliates might be strengthened during the Phaeocystis bloom and the complex effect also varied from species to species.

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Interspecific competition between Enteromorpha (Ulvales: Chlorophyceae) and Fucus (Fucales: Phaeophyceae) germlings: effects of nutrient concentration, temperature, and settlement density

Cited by 32 publications

References 56 publications

The fate of the Arctic seaweed Fucus distichus under climate change: an ecological niche modeling approach

The fate of the Arctic seaweed Fucus distichus under climate change: an ecological niche modeling approach

Effects of Climate Change on Global Seaweed Communities

Planktonic community structure during a harmful bloom of Phaeocystis globosa in a subtropical bay, with special reference to the ciliate assemblages

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