Any way the wind blows - frequent wind dispersal drives species sorting in ephemeral aquatic communities

Despite an upsurge of interest in spatial interactions between communities and in the impact of dispersal on ecological and evolutionary processes, dispersal patterns and dynamics in natural metacommunities remain poorly understood. Although passive aerial dispersal of freshwater invertebrates is ge...

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Bibliographic Details
Published inOikos Vol. 117; no. 1; pp. 125 - 134
Main Authors Vanschoenwinkel, Bram, Gielen, Saïdja, Seaman, Maitland, Brendonck, Luc
Format Journal Article
LanguageEnglish
Published Copenhagen Copenhagen : Blackwell Publishing Ltd 01.01.2008
Blackwell Publishing Ltd
Blackwell Publishing
Blackwell
Subjects
Animal and plant ecology
Animal populations
Animal, plant and microbial ecology
aquatic communities
Aquatic ecosystems
Aquatic environment
aquatic invertebrates
Aquatic organisms
Biological and medical sciences
Community structure
Dispersal
Drying
Ecology
Eggs
environmental impact
extinction
Freshwater ecology
Freshwater invertebrates
Fundamental and applied biological sciences. Psychology
gene flow
General aspects
Invertebrates
Local communities
mountains
Regression analysis
Rocks
Socks
South Africa
species dispersal
Taxa
Wind direction
Wind erosion
Wind speed
Wind velocity
Zooplankton
South Africa
Wind
Environmental factor
Community
Dispersion
Sorting
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Abstract Despite an upsurge of interest in spatial interactions between communities and in the impact of dispersal on ecological and evolutionary processes, dispersal patterns and dynamics in natural metacommunities remain poorly understood. Although passive aerial dispersal of freshwater invertebrates is generally accepted, the frequency and relative importance of wind as a vector is still subject of considerable debate. We assessed the importance of wind dispersal in an invertebrate metacommunity in a cluster of 36 temporary rock pools on an isolated mountaintop in South Africa. Wind dispersal was quantified every four days using nine windsocks (about 1.5 m above rock base), placed in the field during one month. Distance to the nearest pool varied from 2 up to 16 m. Wind direction and speed were monitored for the entire period. About 850 propagules (mostly resting eggs) of 17 taxa were captured. The presence of water in the pools (level of exposure of the dormant propagule bank) and the dominant wind direction were the key factors affecting the yield. Wind speed was much less important. Our results suggest that wind dispersal of propagules from temporary aquatic systems is more frequent than previously thought. This may stabilise the metacommunity by mediating gene flow among populations and facilitating rapid (re)colonisation of patches. On the other hand, wind erosion of the dormant propagule bank may lead to egg bank depletion and local extinction. The measured frequent wind dispersal most likely fuels strong species sorting processes ultimately shaping the structure of the local communities as observed in an earlier study. To elucidate the link between local dispersal rates and their contribution to long range dispersal is a major challenge for future research on aerial dispersal of aquatic invertebrates.
AbstractList Despite an upsurge of interest in spatial interactions between communities and in the impact of dispersal on ecological and evolutionary processes, dispersal patterns and dynamics in natural metacommunities remain poorly understood. Although passive aerial dispersal of freshwater invertebrates is generally accepted, the frequency and relative importance of wind as a vector is still subject of considerable debate. We assessed the importance of wind dispersal in an invertebrate metacommunity in a cluster of 36 temporary rock pools on an isolated mountaintop in South Africa. Wind dispersal was quantified every four days using nine windsocks (about 1.5 m above rock base), placed in the field during one month. Distance to the nearest pool varied from 2 up to 16 m. Wind direction and speed were monitored for the entire period. About 850 propagules (mostly resting eggs) of 17 taxa were captured. The presence of water in the pools (level of exposure of the dormant propagule bank) and the dominant wind direction were the key factors affecting the yield. Wind speed was much less important.Our results suggest that wind dispersal of propagules from temporary aquatic systems is more frequent than previously thought. This may stabilise the metacommunity by mediating gene flow among populations and facilitating rapid (re)colonisation of patches. On the other hand, wind erosion of the dormant propagule bank may lead to egg bank depletion and local extinction.The measured frequent wind dispersal most likely fuels strong species sorting processes ultimately shaping the structure of the local communities as observed in an earlier study. To elucidate the link between local dispersal rates and their contribution to long range dispersal is a major challenge for future research on aerial dispersal of aquatic invertebrates.
Despite an upsurge of interest in spatial interactions between communities and in the impact of dispersal on ecological and evolutionary processes, dispersal patterns and dynamics in natural metacommunities remain poorly understood. Although passive aerial dispersal of freshwater invertebrates is generally accepted, the frequency and relative importance of wind as a vector is still subject of considerable debate. We assessed the importance of wind dispersal in an invertebrate metacommunity in a cluster of 36 temporary rock pools on an isolated mountaintop in South Africa. Wind dispersal was quantified every four days using nine windsocks (about 1.5 m above rock base), placed in the field during one month. Distance to the nearest pool varied from 2 up to 16 m. Wind direction and speed were monitored for the entire period. About 850 propagules (mostly resting eggs) of 17 taxa were captured. The presence of water in the pools (level of exposure of the dormant propagule bank) and the dominant wind direction were the key factors affecting the yield. Wind speed was much less important. Our results suggest that wind dispersal of propagules from temporary aquatic systems is more frequent than previously thought. This may stabilise the metacommunity by mediating gene flow among populations and facilitating rapid (re)colonisation of patches. On the other hand, wind erosion of the dormant propagule bank may lead to egg bank depletion and local extinction. The measured frequent wind dispersal most likely fuels strong species sorting processes ultimately shaping the structure of the local communities as observed in an earlier study. To elucidate the link between local dispersal rates and their contribution to long range dispersal is a major challenge for future research on aerial dispersal of aquatic invertebrates.
Despite an upsurge of interest in spatial interactions between communities and in the impact of dispersal on ecological and evolutionary processes, dispersal patterns and dynamics in natural metacommunities remain poorly understood. Although passive aerial dispersal of freshwater invertebrates is generally accepted, the frequency and relative importance of wind as a vector is still subject of considerable debate. We assessed the importance of wind dispersal in an invertebrate metacommunity in a cluster of 36 temporary rock pools on an isolated mountaintop in South Africa. Wind dispersal was quantified every four days using nine windsocks (about 1.5 m above rock base), placed in the field during one month. Distance to the nearest pool varied from 2 up to 16 m. Wind direction and speed were monitored for the entire period. About 850 propagules (mostly resting eggs) of 17 taxa were captured. The presence of water in the pools (level of exposure of the dormant propagule bank) and the dominant wind direction were the key factors affecting the yield. Wind speed was much less important. Our results suggest that wind dispersal of propagules from temporary aquatic systems is more frequent than previously thought. This may stabilise the metacommunity by mediating gene flow among populations and facilitating rapid (re)colonisation of patches. On the other hand, wind erosion of the dormant propagule bank may lead to egg bank depletion and local extinction. The measured frequent wind dispersal most likely fuels strong species sorting processes ultimately shaping the structure of the local communities as observed in an earlier study. To elucidate the link between local dispersal rates and their contribution to long range dispersal is a major challenge for future research on aerial dispersal of aquatic invertebrates. [PUBLICATION ABSTRACT]
Author Seaman, Maitland
Vanschoenwinkel, Bram
Gielen, Saïdja
Brendonck, Luc
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Issue 1
Keywords Wind
Environmental factor
Community
Dispersion
Sorting
Language English
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References Ter Braak, C. J. F. and Šmilauer, P.. 1998. CANOCO reference manual and user's guide to Canoco for Windows: software for canonical community ordination, ver. 4. Microcomputer Power, Ithaca, NY, USA.
Lopez, L. C. S. et al. 1999. Frogs and snakes as phoretic dispersal agents of bromeliad ostracods (Limnocytheridae: Elpidium) and annelids (Naididae: Dero). Biotropica 31: 705-708.
Hulsmans, A. et al. 2006. Direct and indirect measures of dispersal in the fairy shrimp Branchipodopsis wolfi indicate a small scale isolation-by-distance pattern. Limnol. Oceanogr. 52: 676-684.
Bohonak, A. J. and Whiteman, H. H.. 1999. Dispersal of the fairy shrimp Branchinecta coloradensis (Anostraca): effects of hydroperiod and salamanders. Limnol. Oceanogr. 44: 487-493.
Neigel, J. E.. 1997. A comparison of alternative strategies for estimating gene flow from molecular markers. Annu. Rev. Ecol. Syst. 28: 105-128.
Zar, J. H.. 1999. Biostatistical Analysis, Fourth edition. Prentice-Hall.
De Meester, L. et al. 2002. The Monopolization hypothesis and the dispersal-gene flow paradox in aquatic organisms. Acta Oecol. 23: 121-135.
Maguire, B.. 1963. The passive dispersal of small aquatic organisms and their colonization of isolated bodies of water. Ecol. Monogr. 33: 161-185.
Kellogg, C. A. and Griffin, D. W.. 2006. Aerobiology and the global transport of desert dust. Trends Ecol. Evol. 21: 638-644.
Moore, W. G. and Faust, B. F.. 1972. Crayfish as possible agents of dissemination of fairy shrimp into temporary ponds. Ecology 53: 314-316.
Brendonck, L. and Riddoch, B. J.. 2000a. Dispersal in the desert rock pool anostracan Branchipodopsis wolfi (Branchiopoda: Anostraca). Crust. Iss. 12: 109-118.
Michels, E. et al. 2001. Zooplankton on the move: first results on the quantification of dispersal in a set of interconnected ponds. Hydrobiologia 442: 117-126.
Darwin, C. R.. 1859. The origin of species by means of natural selection, or the preservation of favoured races in the struggle for life. John Murray.
Bilton, D. T. et al. 2001. Dispersal in freshwater invertebrates. Annu. Rev. Ecol. Syst. 32: 159-181.
Nathan, R. et al. 2005. Long-distance biological transport processes through the air: can nature's complexity be unfolded in-silico?. Div. Distrib. 11: 131-137.
Cáceres, C. E. and Soluk, D. A.. 2002. Blowing in the wind: a field test of overland dispersal and colonization by aquatic invertebrates. Oecologia 131: 402-408.
Cáceres, C. E. and Tessier, A. J.. 2003. How long to rest: the ecology of optimal dormancy and environmental constraint. Ecology 84: 1189-1198.
Figuerola, J. and Green, A. J.. 2002. Dispersal of aquatic organisms by waterbirds: a review of past research and priorities for future studies. Freshwater Biol. 47: 483-494.
Kovach, W. L.. 2006. Oriana for windows, ver. 2.02. Kovach Computer Services, Wales, UK.
Bohonak, A. J. and Jenkins, D. G.. 2003. Ecological and evolutionary significance of dispersal by freshwater invertebrates. Ecol. Lett. 6: 783-796.
Hairston, N. G. Jr.. 1996. Zooplankton egg banks as biotic reservoirs in changing environments. Limnol. Oceanogr. 41: 1087-1092.
LepŠ, J. and Šmilauer, P.. 2003. Multivariate analysis of ecological data using CANOCO. Cambridge Univ. Press.
Borcard, D. P. et al. 1992. Partialling out the spatial component of ecological variation. Ecology 73: 1045-1055.
Duffner, K. et al. 2001. Passive dispersal of the grape rust mite Calepitrimerus vitis Nalepa 1905 (Acari, Eriophyoidea) in vineyards. J. Pest Sci. 74: 1-6.
Levin, S. A.. 1974. Dispersion and population interactions. Am. Nat. 108: 207-228.
Brendonck, L. and Riddoch, B. J.. 1999. Wind-borne shortrange egg dispersal in anostracans (Crustacea: Branchiopoda). Biol. J. Linn. Soc. 67: 87-95.
Cohen, G. M. and Shurin, J. B.. 2003. Scale-dependence and mechanisms of dispersal in freshwater zooplankton. Oikos 103: 603-617.
Engelbrecht, C. M.. 1975. New ameronothoid (Oribatidae, Acari) taxa from the republic of South Africa and the islands Gough and Marion. Navorsinge van die Nasionale museum Bloemfontein 3: 53-72.
Bossart, J. L. and Prowell, D. P.. 1998. Genetic estimates of population structure and gene flow: limitations, lessons and new directions. Trends Ecol. Evol. 13: 202-206.
Louette, G. and De Meester, L.. 2005. High dispersal capacity of cladoceran zooplankton in newly founded communities. Ecology 86: 353-359.
Warner, R. R. and Chesson, P. L.. 1985. Coexistence mediated by recruitment fluctuations: a field guide to the storage effect. Am. Nat. 125: 769-787.
Panov, V. E. et al. 2004. Role of diapause in dispersal and invasion success by aquatic invertebrates. J. Limnol. 63: 56-69.
Green, A. J. and Figuerola, J.. 2005. Recent advances in the study of long-distance dispersal of aquatic invertebrates via birds. Div. Distr. 11: 149-156.
Nathan, R. et al. 2002. Mechanisms of long-distance dispersal of seeds by wind. Nature 418: 409-413.
Vandekerckhove, J. et al. 2004. Use of ephippial morphology to assess richness of anomopods: potentials and pitfalls. J. Limnol. 63: 75-84.
Vanschoenwinkel, B. et al. 2007. The role of metacommunity processes in shaping invertebrate rock pool communities along a dispersal gradient. Oikos 116: 1255-1266.
Tackenberg, O. et al. 2003. Dandelion seed dispersal: the horizontal wind speed does not matter for long-distance dispersal-it is updraft!. Plant. Biol. 5: 451-454.
Gillette, D. A.. 1978. A wind tunnel simulation of the erosion of soil: effect of soil texture, sandblasting, wind speed, and soil consolidation on dust production. Atmos. Environ. 12: 1735-1743.
Jenkins, D. G. and Underwood, M. O.. 1998. Zooplankton may not disperse readily in wind, rain, or waterfowl. Hydrobiologia 388: 15-21.
Flößner, D.. 2000. Die Haplopoda und Cladocera (ohne Bosminidae) Mitteleuropas. Backhuys Publishers.
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2004; 63
2001; 442
2006; 52
2002; 131
1978; 12
1998
1999; 67
1999; 44
1974; 108
2005; 86
1997; 28
1985; 125
2006
2002; 418
2000a; 12
2003
1859
1992; 73
1999
2002; 47
1963; 33
2007; 116
2000
2006; 21
2003; 6
2002; 23
1996; 41
2003; 5
1999; 31
1972; 53
2000b; 148
2003; 103
2003; 84
1998; 388
2005; 11
2001; 74
1975; 3
2001; 32
1998; 13
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References_xml – reference: Brendonck, L. and Riddoch, B. J.. 2000a. Dispersal in the desert rock pool anostracan Branchipodopsis wolfi (Branchiopoda: Anostraca). Crust. Iss. 12: 109-118.
– reference: Levin, S. A.. 1974. Dispersion and population interactions. Am. Nat. 108: 207-228.
– reference: Tackenberg, O. et al. 2003. Dandelion seed dispersal: the horizontal wind speed does not matter for long-distance dispersal-it is updraft!. Plant. Biol. 5: 451-454.
– reference: Nathan, R. et al. 2005. Long-distance biological transport processes through the air: can nature's complexity be unfolded in-silico?. Div. Distrib. 11: 131-137.
– reference: Figuerola, J. and Green, A. J.. 2002. Dispersal of aquatic organisms by waterbirds: a review of past research and priorities for future studies. Freshwater Biol. 47: 483-494.
– reference: Gillette, D. A.. 1978. A wind tunnel simulation of the erosion of soil: effect of soil texture, sandblasting, wind speed, and soil consolidation on dust production. Atmos. Environ. 12: 1735-1743.
– reference: Jenkins, D. G. and Underwood, M. O.. 1998. Zooplankton may not disperse readily in wind, rain, or waterfowl. Hydrobiologia 388: 15-21.
– reference: Kellogg, C. A. and Griffin, D. W.. 2006. Aerobiology and the global transport of desert dust. Trends Ecol. Evol. 21: 638-644.
– reference: Moore, W. G. and Faust, B. F.. 1972. Crayfish as possible agents of dissemination of fairy shrimp into temporary ponds. Ecology 53: 314-316.
– reference: Bohonak, A. J. and Jenkins, D. G.. 2003. Ecological and evolutionary significance of dispersal by freshwater invertebrates. Ecol. Lett. 6: 783-796.
– reference: Cáceres, C. E. and Tessier, A. J.. 2003. How long to rest: the ecology of optimal dormancy and environmental constraint. Ecology 84: 1189-1198.
– reference: Vanschoenwinkel, B. et al. 2007. The role of metacommunity processes in shaping invertebrate rock pool communities along a dispersal gradient. Oikos 116: 1255-1266.
– reference: Michels, E. et al. 2001. Zooplankton on the move: first results on the quantification of dispersal in a set of interconnected ponds. Hydrobiologia 442: 117-126.
– reference: Engelbrecht, C. M.. 1975. New ameronothoid (Oribatidae, Acari) taxa from the republic of South Africa and the islands Gough and Marion. Navorsinge van die Nasionale museum Bloemfontein 3: 53-72.
– reference: Vandekerckhove, J. et al. 2004. Use of ephippial morphology to assess richness of anomopods: potentials and pitfalls. J. Limnol. 63: 75-84.
– reference: Cáceres, C. E. and Soluk, D. A.. 2002. Blowing in the wind: a field test of overland dispersal and colonization by aquatic invertebrates. Oecologia 131: 402-408.
– reference: Duffner, K. et al. 2001. Passive dispersal of the grape rust mite Calepitrimerus vitis Nalepa 1905 (Acari, Eriophyoidea) in vineyards. J. Pest Sci. 74: 1-6.
– reference: Warner, R. R. and Chesson, P. L.. 1985. Coexistence mediated by recruitment fluctuations: a field guide to the storage effect. Am. Nat. 125: 769-787.
– reference: Lopez, L. C. S. et al. 1999. Frogs and snakes as phoretic dispersal agents of bromeliad ostracods (Limnocytheridae: Elpidium) and annelids (Naididae: Dero). Biotropica 31: 705-708.
– reference: Brendonck, L. and Riddoch, B. J.. 2000b. Egg bank dynamics in anostracan desert rock pool populations (Crustacea: Branchiopoda). Arch. Hydrobiol. 148: 71-84.
– reference: Brendonck, L. and Riddoch, B. J.. 1999. Wind-borne shortrange egg dispersal in anostracans (Crustacea: Branchiopoda). Biol. J. Linn. Soc. 67: 87-95.
– reference: Darwin, C. R.. 1859. The origin of species by means of natural selection, or the preservation of favoured races in the struggle for life. John Murray.
– reference: Maguire, B.. 1963. The passive dispersal of small aquatic organisms and their colonization of isolated bodies of water. Ecol. Monogr. 33: 161-185.
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– reference: Panov, V. E. et al. 2004. Role of diapause in dispersal and invasion success by aquatic invertebrates. J. Limnol. 63: 56-69.
– reference: Hulsmans, A. et al. 2006. Direct and indirect measures of dispersal in the fairy shrimp Branchipodopsis wolfi indicate a small scale isolation-by-distance pattern. Limnol. Oceanogr. 52: 676-684.
– reference: Bilton, D. T. et al. 2001. Dispersal in freshwater invertebrates. Annu. Rev. Ecol. Syst. 32: 159-181.
– reference: Neigel, J. E.. 1997. A comparison of alternative strategies for estimating gene flow from molecular markers. Annu. Rev. Ecol. Syst. 28: 105-128.
– reference: Green, A. J. and Figuerola, J.. 2005. Recent advances in the study of long-distance dispersal of aquatic invertebrates via birds. Div. Distr. 11: 149-156.
– reference: Hairston, N. G. Jr.. 1996. Zooplankton egg banks as biotic reservoirs in changing environments. Limnol. Oceanogr. 41: 1087-1092.
– reference: Louette, G. and De Meester, L.. 2005. High dispersal capacity of cladoceran zooplankton in newly founded communities. Ecology 86: 353-359.
– reference: Bossart, J. L. and Prowell, D. P.. 1998. Genetic estimates of population structure and gene flow: limitations, lessons and new directions. Trends Ecol. Evol. 13: 202-206.
– reference: Flößner, D.. 2000. Die Haplopoda und Cladocera (ohne Bosminidae) Mitteleuropas. Backhuys Publishers.
– reference: Zar, J. H.. 1999. Biostatistical Analysis, Fourth edition. Prentice-Hall.
– reference: Nathan, R. et al. 2002. Mechanisms of long-distance dispersal of seeds by wind. Nature 418: 409-413.
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– reference: Cohen, G. M. and Shurin, J. B.. 2003. Scale-dependence and mechanisms of dispersal in freshwater zooplankton. Oikos 103: 603-617.
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  start-page: 1735
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  publication-title: J. Pest Sci.
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  end-page: 128
  article-title: A comparison of alternative strategies for estimating gene flow from molecular markers
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  year: 2005
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  publication-title: Div. Distr.
– volume: 11
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  publication-title: Navorsinge van die Nasionale museum Bloemfontein
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  year: 2002
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  publication-title: Freshwater Biol.
– volume: 44
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Snippet Despite an upsurge of interest in spatial interactions between communities and in the impact of dispersal on ecological and evolutionary processes, dispersal...
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SubjectTerms Animal and plant ecology
Animal populations
Animal, plant and microbial ecology
aquatic communities
Aquatic ecosystems
Aquatic environment
aquatic invertebrates
Aquatic organisms
Biological and medical sciences
Community structure
Dispersal
Drying
Ecology
Eggs
environmental impact
extinction
Freshwater ecology
Freshwater invertebrates
Fundamental and applied biological sciences. Psychology
gene flow
General aspects
Invertebrates
Local communities
mountains
Regression analysis
Rocks
Socks
South Africa
species dispersal
Taxa
Wind direction
Wind erosion
Wind speed
Wind velocity
Zooplankton
Title Any way the wind blows - frequent wind dispersal drives species sorting in ephemeral aquatic communities
URI https://api.istex.fr/ark:/67375/WNG-5LS7FF8L-X/fulltext.pdf
https://www.jstor.org/stable/40235461
https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fj.2007.0030-1299.16349.x
https://www.proquest.com/docview/211517309
https://www.proquest.com/docview/20467182
https://www.proquest.com/docview/48145766
Volume 117
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