Difference between revisions of "Monitoring changes in North Atlantic plankton communities"

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* evaluate management actions.
 
* evaluate management actions.
  
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[[Image:ShipsofOpp.CPR.PNG|thumb|550px|center|Black dots show zooplankton sampling sites in the North Atlantic, background shows SeaWiFS satellite chlorophyll distribution.  Map: Todd O’Brien, NMFS-COPEPOD, USA]]
 
==Climate change==
 
==Climate change==
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[[Image:CPR.graph.PNG|thumb|400px|right|Changes in the mean number of copepod species from 1951-2002, showing northward extension of warm water species and northward retreat of cold water species. Recalculated after Beaugrand et al., 2002.]]
 
Long-term variations in plankton abundance in the North Atlantic ecosystem have been investigated by the [[Continuous Plankton Recorder (CPR)]] survey  since 1946 as well as at several fixed coastal monitoring stations.
 
Long-term variations in plankton abundance in the North Atlantic ecosystem have been investigated by the [[Continuous Plankton Recorder (CPR)]] survey  since 1946 as well as at several fixed coastal monitoring stations.
  
[[Image:ShipsofOpp.CPR.PNG|thumb|350px|right|Black dots show zooplankton sampling sites in the North Atlantic, background shows SeaWiFS satellite chlorophyll distribution.  Map: Todd O’Brien, NMFS-COPEPOD, USA]]
 
  
Studies show that key mechanisms link environmental forcing and plankton response i.e. timing and intensity of the spring [[Algal bloom | phytoplankton bloom]] resulting from changes in stratification levels, changes in temperature, and, in the case of the copepod ''Calanus finmarchicus'', advection of the population into the North Sea at the end of the winter season. The NE Atlantic has warmed 2-3°C over the last 50 years. This has resulted in a northwards shift (of approximately 1000km) in warm water plankton communities.  There has also been a decrease in the key copepod Calanus finmarchicus and an increase Calanus helgolandicus.  Such a shift could impact on the whole ecosystem, for example larval/juvenile cod feed on C. finmarchicus, its replacement by  C. helgolandicus may therefore have a detrimental effect on their overall viability because both species are abundant at different times of the year.  Such changes may have exacerbated the impact of over-fishing in reducing recruitment of North Sea cod since the mid-1980s.
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Studies show that key mechanisms link environmental forcing and plankton response i.e. timing and intensity of the spring [[Algal bloom | phytoplankton bloom]] resulting from changes in stratification levels, changes in temperature, and, in the case of the copepod ''Calanus finmarchicus'', advection of the population into the North Sea at the end of the winter season. The NE Atlantic has warmed 2-3°C over the last 50 years. This has resulted in a northwards shift (of approximately 1000km) in warm water plankton communities.  There has also been a decrease in the key copepod ''Calanus finmarchicus'' and an increase ''Calanus helgolandicus''.  Such a shift could impact on the whole ecosystem, for example larval/juvenile cod feed on ''C. finmarchicus'', its replacement by  ''C. helgolandicus'' may therefore have a detrimental effect on their overall viability because both species are abundant at different times of the year.  Such changes may have exacerbated the impact of over-fishing in reducing recruitment of North Sea cod since the mid-1980s.
 +
 
 +
[[Image:CPR.C.wailesii.PNG|thumb|200px|right|Abundance estimates, based on CPR monitoring, of ''Coscinodiscus wailesii''  in the North East Atlantic between 1985-1995. Image: Martin Edwards, SAHFOS, UK.]]
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[[Image:C.wailesii.PNG|thumb|200px|left|Picture of  C. wailesii from sample taken off Plymouth in March 2000. Notice the size of the species in comparison to the copepod and the almost mono-specific nature of the sample. Photograph: Karl Embelton, SAHFOS, UK.]]
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==Long-term plankton monitoring and non-indigenous species==
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The introduction of non-indigenous marine plankton species can have a considerable ecological and economic effect on regional systems.  For example the introduction of the ‘comb jelly’ (''Mnemiopsis leidyi'') to the Black Sea is known to have had dramatic consequences on the food web. The main pathway for invasive species introduction is via ship ballast waters. There has been increasing concern about the apparent increase in species introductions worldwide, but their presence can go unnoticed until they reach nuisance status.  As a consequence there are few case-histories providing information on their initial appearance and their spatio-temporal patterns. Since the 1980’s phytoplankton biomass has increased in the North Sea.  How much of this increase can be attributed to the introduced phytoplankton species ''Coscinodiscus wailesii'' is yet to be determined. There is however, already strong evidence to suggest that under certain conditions  ''C. wailesii'' can displace indigenous plankton species.  As many native phytoplankton feeders find the species unpalatable, its dominance can have detrimental effect on the food web. Such shifts in ecology of the North Sea need to be monitored by sustained long-term observations. The case of ''C. wailesii'' is the first of its kind to show the spatial evolution of an invasive phytoplankton species over a decadal period and highlights the need for continuous monitoring to assess the effectiveness of any management strategy put in place to limit invasions.
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==See also==
 +
Sir Alister Hardy Foundation for Ocean Science (SAHFOS) [http://www.sahfos.org www.sahfos.org]
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<div style="border:1px solid #000000;float: right; background-color:#FFD700; padding:0.5em 0.5em 2em 0.5em; font-size:100%">
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==Action points==
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* The plankton community in the NE Atlantic and the North Sea are changing as a consequence of climate change and species introductions.
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* Long-term monitoring plankton programmes in the North Atlantic are essential to evaluate the consequences of these changes.
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* EUR-OCEANS considers that monitoring is essential to determine whether the climate-plankton connections observed  during several decades will persist in the future or will be overruled by other mechanisms and principally human-induced impacts.
 +
* EUR-OCEANS support:
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** the development of effective international mechanisms for sharing plankton monitoring data
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** optimising the control of ballast waters
 +
** implementing an ecosystem approach to fisheries management by taking into account changes in plankton biodiversity.
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[[Image:PML.logo.PNG|float:center | 150px|]]
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|abstract=
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<div style="font-size:95%;color: #000000;padding:1em 0em 0em 0em">This Wiki page was adapted from [http://www.eur-oceans.eu/?q=node/18114 EUR-OCEANS Fact Sheet no. 4] composed by scientists involved in the ICES Working Group on Zooplankton Ecology as well as colleagues from The Sir Alister Hardy Foundation for Ocean Science in Plymouth, UK. For further information please contact Luis Valdes (luis.valdes@gi.ieo.es), Martin Edwards (maed@sahfos.ac.uk) or Delphine Bonnet (bode@pml.ac.uk). For the ICES Zooplankton Status Report go to http://www.ices.dk/products/cooperative.asp  </div>
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'''Fact Sheet by: EUR-OCEANS Knowledge Transfer Unit, hosted by the GLOBEC IPO at Plymouth Marine Laboratory. For further information contact, Jessica Heard: jessh@pml.ac.uk or visit the Website: www.eur-oceans.org/KTU'''
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[[Category:Euroceans fact sheets]]

Revision as of 13:48, 7 November 2013

Background

The North Atlantic is the largest oceanic water mass associated with Europe and thus a key area for the EUR-OCEANS network. The outcome of many nationally-funded research programmes over the last decade had been the realisation that human impacts (e.g. climate change, species introductions) apply across the North Atlantic basin, thus requiring the cohesive and coordinated research promoted by EUR-OCEANS. This Fact Sheet introduces some of the conclusions regarding possible human induced changes in the North East Atlantic planktonic communities over the last 50 years. These conclusions are based on long-term plankton records which are valuable for documenting ecosystem changes, for helping to separate natural and anthropogenic changes, and for generating and analyzing testable hypotheses. Over the last decade, interest in long-term plankton sampling has increased. However, long timeseries are still uncommon. The purpose of long-term monitoring is to establish a baseline for the various components of the ecosystem, and how they interact. Information can be used to:

  • distinguish between the effects of human activities and natural variability
  • define baselines and estimate the recovery time of the system after human or environmental perturbations
  • develop hypotheses about causal relationships which can then be investigated
  • verify and validate models used to predict changes in marine ecosystems on the basis of climate scenarios, and
  • evaluate management actions.
Black dots show zooplankton sampling sites in the North Atlantic, background shows SeaWiFS satellite chlorophyll distribution. Map: Todd O’Brien, NMFS-COPEPOD, USA

Climate change

Changes in the mean number of copepod species from 1951-2002, showing northward extension of warm water species and northward retreat of cold water species. Recalculated after Beaugrand et al., 2002.

Long-term variations in plankton abundance in the North Atlantic ecosystem have been investigated by the Continuous Plankton Recorder (CPR) survey since 1946 as well as at several fixed coastal monitoring stations.



Studies show that key mechanisms link environmental forcing and plankton response i.e. timing and intensity of the spring phytoplankton bloom resulting from changes in stratification levels, changes in temperature, and, in the case of the copepod Calanus finmarchicus, advection of the population into the North Sea at the end of the winter season. The NE Atlantic has warmed 2-3°C over the last 50 years. This has resulted in a northwards shift (of approximately 1000km) in warm water plankton communities. There has also been a decrease in the key copepod Calanus finmarchicus and an increase Calanus helgolandicus. Such a shift could impact on the whole ecosystem, for example larval/juvenile cod feed on C. finmarchicus, its replacement by C. helgolandicus may therefore have a detrimental effect on their overall viability because both species are abundant at different times of the year. Such changes may have exacerbated the impact of over-fishing in reducing recruitment of North Sea cod since the mid-1980s.

Abundance estimates, based on CPR monitoring, of Coscinodiscus wailesii in the North East Atlantic between 1985-1995. Image: Martin Edwards, SAHFOS, UK.
Picture of C. wailesii from sample taken off Plymouth in March 2000. Notice the size of the species in comparison to the copepod and the almost mono-specific nature of the sample. Photograph: Karl Embelton, SAHFOS, UK.

Long-term plankton monitoring and non-indigenous species

The introduction of non-indigenous marine plankton species can have a considerable ecological and economic effect on regional systems. For example the introduction of the ‘comb jelly’ (Mnemiopsis leidyi) to the Black Sea is known to have had dramatic consequences on the food web. The main pathway for invasive species introduction is via ship ballast waters. There has been increasing concern about the apparent increase in species introductions worldwide, but their presence can go unnoticed until they reach nuisance status. As a consequence there are few case-histories providing information on their initial appearance and their spatio-temporal patterns. Since the 1980’s phytoplankton biomass has increased in the North Sea. How much of this increase can be attributed to the introduced phytoplankton species Coscinodiscus wailesii is yet to be determined. There is however, already strong evidence to suggest that under certain conditions C. wailesii can displace indigenous plankton species. As many native phytoplankton feeders find the species unpalatable, its dominance can have detrimental effect on the food web. Such shifts in ecology of the North Sea need to be monitored by sustained long-term observations. The case of C. wailesii is the first of its kind to show the spatial evolution of an invasive phytoplankton species over a decadal period and highlights the need for continuous monitoring to assess the effectiveness of any management strategy put in place to limit invasions.


See also

Sir Alister Hardy Foundation for Ocean Science (SAHFOS) www.sahfos.org

Action points

  • The plankton community in the NE Atlantic and the North Sea are changing as a consequence of climate change and species introductions.
  • Long-term monitoring plankton programmes in the North Atlantic are essential to evaluate the consequences of these changes.
  • EUR-OCEANS considers that monitoring is essential to determine whether the climate-plankton connections observed during several decades will persist in the future or will be overruled by other mechanisms and principally human-induced impacts.
  • EUR-OCEANS support:
    • the development of effective international mechanisms for sharing plankton monitoring data
    • optimising the control of ballast waters
    • implementing an ecosystem approach to fisheries management by taking into account changes in plankton biodiversity.
PML.logo.PNG
This Wiki page was adapted from EUR-OCEANS Fact Sheet no. 4 composed by scientists involved in the ICES Working Group on Zooplankton Ecology as well as colleagues from The Sir Alister Hardy Foundation for Ocean Science in Plymouth, UK. For further information please contact Luis Valdes (luis.valdes@gi.ieo.es), Martin Edwards (maed@sahfos.ac.uk) or Delphine Bonnet (bode@pml.ac.uk). For the ICES Zooplankton Status Report go to http://www.ices.dk/products/cooperative.asp
FS4LOGO.PNG

Fact Sheet by: EUR-OCEANS Knowledge Transfer Unit, hosted by the GLOBEC IPO at Plymouth Marine Laboratory. For further information contact, Jessica Heard: jessh@pml.ac.uk or visit the Website: www.eur-oceans.org/KTU