Physical barriers and environmental gradients cause spatial and temporal genetic differentiation of an extensive algal bloom

Anna Godhe; Conny Sjöqvist; Sirje Sildever; Josefin Sefbom; Sara Harðardóttir; Mireia Bertos-Fortis; Carina Bunse; Susanne Gross; Emma Johansson; Per R. Jonsson; Saghar Khandan; Catherine Legrand; Inga Nips; Nina Lundholm; Karin E. Rengefors; Ingrid Sassenhagen; Sanna Suikkanen; Lisa Sundqvist; Anke Kremp

doi:10.1111/jbi.12722

Physical barriers and environmental gradients cause spatial and temporal genetic differentiation of an extensive algal bloom

Anna Godhe, Conny Sjöqvist, Sirje Sildever, Josefin Sefbom, Sara Harðardóttir, Mireia Bertos-Fortis, Carina Bunse, Susanne Gross, Emma Johansson, Per R. Jonsson, Saghar Khandan, Catherine Legrand, Inga Nips, Nina Lundholm, Karin E. Rengefors, Ingrid Sassenhagen, Sanna Suikkanen, Lisa Sundqvist, Anke Kremp

30 Citationer (Scopus)

Abstract

Aim: To test if a phytoplankton bloom is panmictic, or whether geographical and environmental factors cause spatial and temporal genetic structure. Location: Baltic Sea. Method: During four cruises, we isolated clonal strains of the diatom Skeletonema marinoi from 9 to 10 stations along a 1132 km transect and analysed the genetic structure using eight microsatellites. Using F-statistics and Bayesian clustering analysis we determined if samples were significantly differentiated. A seascape approach was applied to examine correlations between gene flow and oceanographic connectivity, and combined partial Mantel test and RDA based variation partitioning to investigate associations with environmental gradients. Results: The bloom was initiated during the second half of March in the southern and the northern- parts of the transect, and later propagated offshore. By mid-April the bloom declined in the south, whereas high phytoplankton biomass was recorded northward. We found two significantly differentiated populations along the transect. Genotypes were significantly isolated by distance and by the south-north salinity gradient, which illustrated that the effects of distance and environment were confounded. The gene flow among the sampled stations was significantly correlated with oceanographic connectivity. The depletion of silica during the progression of the bloom was related to a temporal population genetic shift. Main conclusions: A phytoplankton bloom may propagate as a continuous cascade and yet be genetically structured over both spatial and temporal scales. The Baltic Sea spring bloom displayed strong spatial structure driven by oceanographic connectivity and geographical distance, which was enhanced by the pronounced salinity gradient. Temporal transition of conditions important for growth may induce genetic shifts and different phenotypic strategies, which serve to maintain the bloom over longer periods.

Originalsprog	Engelsk
Tidsskrift	Journal of Biogeography
Vol/bind	43
Udgave nummer	6
Sider (fra-til)	1130–1142
Antal sider	13
ISSN	0305-0270
DOI	https://doi.org/10.1111/jbi.12722
Status	Udgivet - 1 jun. 2016

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10.1111/jbi.12722

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Godhe, A., Sjöqvist, C., Sildever, S., Sefbom, J., Harðardóttir, S., Bertos-Fortis, M., Bunse, C., Gross, S., Johansson, E., Jonsson, P. R., Khandan, S., Legrand, C., Nips, I., Lundholm, N., Rengefors, K. E., Sassenhagen, I., Suikkanen, S., Sundqvist, L., & Kremp, A. (2016). Physical barriers and environmental gradients cause spatial and temporal genetic differentiation of an extensive algal bloom. Journal of Biogeography, 43(6), 1130–1142. https://doi.org/10.1111/jbi.12722

Godhe, A, Sjöqvist, C, Sildever, S, Sefbom, J, Harðardóttir, S, Bertos-Fortis, M, Bunse, C, Gross, S, Johansson, E, Jonsson, PR, Khandan, S, Legrand, C, Nips, I, Lundholm, N, Rengefors, KE, Sassenhagen, I, Suikkanen, S, Sundqvist, L & Kremp, A 2016, 'Physical barriers and environmental gradients cause spatial and temporal genetic differentiation of an extensive algal bloom', Journal of Biogeography, bind 43, nr. 6, s. 1130–1142. https://doi.org/10.1111/jbi.12722

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title = "Physical barriers and environmental gradients cause spatial and temporal genetic differentiation of an extensive algal bloom",

abstract = "Aim: To test if a phytoplankton bloom is panmictic, or whether geographical and environmental factors cause spatial and temporal genetic structure. Location: Baltic Sea. Method: During four cruises, we isolated clonal strains of the diatom Skeletonema marinoi from 9 to 10 stations along a 1132 km transect and analysed the genetic structure using eight microsatellites. Using F-statistics and Bayesian clustering analysis we determined if samples were significantly differentiated. A seascape approach was applied to examine correlations between gene flow and oceanographic connectivity, and combined partial Mantel test and RDA based variation partitioning to investigate associations with environmental gradients. Results: The bloom was initiated during the second half of March in the southern and the northern- parts of the transect, and later propagated offshore. By mid-April the bloom declined in the south, whereas high phytoplankton biomass was recorded northward. We found two significantly differentiated populations along the transect. Genotypes were significantly isolated by distance and by the south-north salinity gradient, which illustrated that the effects of distance and environment were confounded. The gene flow among the sampled stations was significantly correlated with oceanographic connectivity. The depletion of silica during the progression of the bloom was related to a temporal population genetic shift. Main conclusions: A phytoplankton bloom may propagate as a continuous cascade and yet be genetically structured over both spatial and temporal scales. The Baltic Sea spring bloom displayed strong spatial structure driven by oceanographic connectivity and geographical distance, which was enhanced by the pronounced salinity gradient. Temporal transition of conditions important for growth may induce genetic shifts and different phenotypic strategies, which serve to maintain the bloom over longer periods.",

author = "Anna Godhe and Conny Sj{\"o}qvist and Sirje Sildever and Josefin Sefbom and Sara Har{\dh}ard{\'o}ttir and Mireia Bertos-Fortis and Carina Bunse and Susanne Gross and Emma Johansson and Jonsson, {Per R.} and Saghar Khandan and Catherine Legrand and Inga Nips and Nina Lundholm and Rengefors, {Karin E.} and Ingrid Sassenhagen and Sanna Suikkanen and Lisa Sundqvist and Anke Kremp",

year = "2016",

month = jun,

day = "1",

doi = "10.1111/jbi.12722",

language = "English",

volume = "43",

pages = "1130–1142",

journal = "Journal of Biogeography",

issn = "0305-0270",

publisher = "Wiley-Blackwell",

number = "6",

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TY - JOUR

T1 - Physical barriers and environmental gradients cause spatial and temporal genetic differentiation of an extensive algal bloom

AU - Godhe, Anna

AU - Sjöqvist, Conny

AU - Sildever, Sirje

AU - Sefbom, Josefin

AU - Harðardóttir, Sara

AU - Bertos-Fortis, Mireia

AU - Bunse, Carina

AU - Gross, Susanne

AU - Johansson, Emma

AU - Jonsson, Per R.

AU - Khandan, Saghar

AU - Legrand, Catherine

AU - Nips, Inga

AU - Lundholm, Nina

AU - Rengefors, Karin E.

AU - Sassenhagen, Ingrid

AU - Suikkanen, Sanna

AU - Sundqvist, Lisa

AU - Kremp, Anke

PY - 2016/6/1

Y1 - 2016/6/1

N2 - Aim: To test if a phytoplankton bloom is panmictic, or whether geographical and environmental factors cause spatial and temporal genetic structure. Location: Baltic Sea. Method: During four cruises, we isolated clonal strains of the diatom Skeletonema marinoi from 9 to 10 stations along a 1132 km transect and analysed the genetic structure using eight microsatellites. Using F-statistics and Bayesian clustering analysis we determined if samples were significantly differentiated. A seascape approach was applied to examine correlations between gene flow and oceanographic connectivity, and combined partial Mantel test and RDA based variation partitioning to investigate associations with environmental gradients. Results: The bloom was initiated during the second half of March in the southern and the northern- parts of the transect, and later propagated offshore. By mid-April the bloom declined in the south, whereas high phytoplankton biomass was recorded northward. We found two significantly differentiated populations along the transect. Genotypes were significantly isolated by distance and by the south-north salinity gradient, which illustrated that the effects of distance and environment were confounded. The gene flow among the sampled stations was significantly correlated with oceanographic connectivity. The depletion of silica during the progression of the bloom was related to a temporal population genetic shift. Main conclusions: A phytoplankton bloom may propagate as a continuous cascade and yet be genetically structured over both spatial and temporal scales. The Baltic Sea spring bloom displayed strong spatial structure driven by oceanographic connectivity and geographical distance, which was enhanced by the pronounced salinity gradient. Temporal transition of conditions important for growth may induce genetic shifts and different phenotypic strategies, which serve to maintain the bloom over longer periods.

AB - Aim: To test if a phytoplankton bloom is panmictic, or whether geographical and environmental factors cause spatial and temporal genetic structure. Location: Baltic Sea. Method: During four cruises, we isolated clonal strains of the diatom Skeletonema marinoi from 9 to 10 stations along a 1132 km transect and analysed the genetic structure using eight microsatellites. Using F-statistics and Bayesian clustering analysis we determined if samples were significantly differentiated. A seascape approach was applied to examine correlations between gene flow and oceanographic connectivity, and combined partial Mantel test and RDA based variation partitioning to investigate associations with environmental gradients. Results: The bloom was initiated during the second half of March in the southern and the northern- parts of the transect, and later propagated offshore. By mid-April the bloom declined in the south, whereas high phytoplankton biomass was recorded northward. We found two significantly differentiated populations along the transect. Genotypes were significantly isolated by distance and by the south-north salinity gradient, which illustrated that the effects of distance and environment were confounded. The gene flow among the sampled stations was significantly correlated with oceanographic connectivity. The depletion of silica during the progression of the bloom was related to a temporal population genetic shift. Main conclusions: A phytoplankton bloom may propagate as a continuous cascade and yet be genetically structured over both spatial and temporal scales. The Baltic Sea spring bloom displayed strong spatial structure driven by oceanographic connectivity and geographical distance, which was enhanced by the pronounced salinity gradient. Temporal transition of conditions important for growth may induce genetic shifts and different phenotypic strategies, which serve to maintain the bloom over longer periods.

U2 - 10.1111/jbi.12722

DO - 10.1111/jbi.12722

M3 - Journal article

SN - 0305-0270

VL - 43

SP - 1130

EP - 1142

JO - Journal of Biogeography

JF - Journal of Biogeography

IS - 6

ER -

Physical barriers and environmental gradients cause spatial and temporal genetic differentiation of an extensive algal bloom

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