Anthropocene invasion of an ecosystem engineer: resolving the history of<i>Corophium volutator</i>(Amphipoda: Corophiidae) in the North Atlantic

Einfeldt, Anthony L.; Addison, Jason A.

doi:10.1111/bij.12507

Cited by 11 publications

(9 citation statements)

References 118 publications

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“…Two population genetic studies on mudflat species that lack planktonic larval development (Corophium volutator: Einfeldt and Addison 2013; Hediste diversicolor: Einfeldt et al 2014) suggest that there is little or no gene flow between the Bay of Fundy and the Gulf of Maine. Although these results are consistent with reduced connectivity across this major biogeographic break, both species were recently introduced from Europe and thus may show patterns of genetic subdivision arising from independent founder events (Einfeldt and Addison 2015). Investigating species with high dispersal potential (i.e., species with pelagic larva) will help assess the degree to which the biogeographic break between the Bay of Fundy and the Gulf of Maine is a general feature limiting connectivity throughout the region.…”

Section: Introductionmentioning

confidence: 63%

Genetic discontinuity in two high dispersal marine invertebrates in the northwest Atlantic

Einfeldt

Zhou

Addison

2017

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Oceanic circulation patterns shape both the distribution of species and spatial patterns of intraspecific genetic variation by influencing passively dispersed marine invertebrates. In the northwest Atlantic, strong and consistent currents at the mouth of the Bay of Fundy are expected to restrict dispersal in this region, but the relationship between populations of high dispersal species along the surrounding coastal regions has been largely underrepresented in the phylogeographic literature. We analyzed phylogeographic patterns in two intertidal invertebrates with high dispersal abilities, Tritia obsoleta (Mollusca: Gastropoda) and Macoma petalum (Mollusca: Bivalvia), between Cape Cod and the Gulf of St. Lawrence using mitochondrial DNA (mtDNA). Hierarchical analysis of molecular variance revealed population structuring among regions defined by circulation patterns, highly divergent lineages within M. petalum, and strong concordant genetic subdivision in both species between the Bay of Fundy and Gulf of Maine. Our results suggest that the gyre at the mouth of the bay is influential in restricting alongshore dispersal, allowing genetic divergence between regions to arise through genetic drift. These findings are concordant with biogeographic and phylogeographic studies of other marine organisms, suggesting that the genetic isolation of widely distributed species may be a common feature of intertidal invertebrate communities in the Bay of Fundy.

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Section: Introductionmentioning

confidence: 63%

Genetic discontinuity in two high dispersal marine invertebrates in the northwest Atlantic

Einfeldt

Zhou

Addison

2017

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“…However, if populations of both species are reduced to low levels, then our microcosm experiment suggests that nutrient flux, and thus pelagic productivity, may consequently decline (Fig 3B). The risk of such collapses may be particularly great in the Northwest Atlantic, where populations of both species have recently been shown to consist of introduced subsets of European populations [55,56], whose low genetic diversity may make them highly vulnerable to environmental change [57,58]. …”

Section: Discussionmentioning

confidence: 99%

Species-Specific Effects on Ecosystem Functioning Can Be Altered by Interspecific Interactions

et al. 2016

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Biological assemblages are constantly undergoing change, with species being introduced, extirpated and experiencing shifts in their densities. Theory and experimentation suggest that the impacts of such change on ecosystem functioning should be predictable based on the biological traits of the species involved. However, interspecific interactions could alter how species affect functioning, with the strength and sign of interactions potentially depending on environmental context (e.g. homogenous vs. heterogeneous conditions) and the function considered. Here, we assessed how concurrent changes to the densities of two common marine benthic invertebrates, Corophium volutator and Hediste diversicolor, affected the ecological functions of organic matter consumption and benthic-pelagic nutrient flux. Complementary experiments were conducted within homogenous laboratory microcosms and naturally heterogeneous field plots. When the densities of the species were increased within microcosms, interspecific interactions enhanced effects on organic matter consumption and reduced effects on nutrient flux. Trait-based predictions of how each species would affect functioning were only consistently supported when the density of the other species was low. In field plots, increasing the density of either species had a positive effect on organic matter consumption (with no significant interspecific interactions) but no effect on nutrient flux. Our results indicate that species-specific effects on ecosystem functioning can be altered by interspecific interactions, which can be either facilitative (positive) or antagonistic (negative) depending on the function considered. The impacts of biodiversity change may therefore not be predictable based solely on the biological traits of the species involved. Possible explanations for why interactions were detected in microcosms but not in the field are discussed.

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“…Combined with a restricted natural dispersal ability of both species, geographic barriers are expected to facilitate genetic differentiation between populations reflecting isolation‐by‐distance (IBD; e.g., Bockelmann, Reusch, Bijlsma, & Bakker, 2003; Launey, Ledu, Boudry, Bonhomme, & Naciri‐Graven, 2002), vicariance (e.g., Exadactylos, Geffen, Panagiotaki, & Thorpe, 2003; Panova et al., 2011), and local adaptation (e.g., Butlin et al., 2014). Europe had persistent coastal refugia during the last glacial maximum 18,000 years BP, and both species have distinct mitochondrial lineages consistent with persistence in multiple refugia (Einfeldt & Addison, 2015; Einfeldt et al., 2014; Virgilio, Fauvelot, Costantini, Abbiati, & Backeljau, 2009). Throughout the Holocene, soft‐sediment habitat was fragmented along coastlines by regions of coarse sediment and rocky substrata, with major discontinuities between the British Isles and continental Europe (Andersen et al., 2018).…”

Section: Introductionmentioning

confidence: 99%

“…We focus on two intertidal invertebrates, the amphipod Corophium volutator (Pallas, 1766) and annelid Hediste diversicolor (Müller, 1776, previously Nereis diversicolor ), which inhabit soft‐sediment habitat in the Bay of Biscay, North, and Baltic Seas in Europe and the Gulf of Maine and Bay of Fundy in North America. Until recently, they were thought to be native in North America (for review, see Einfeldt & Addison, 2015; Einfeldt, Doucet, & Addison, 2014). Three main lines of evidence suggest they were once moved between Europe and North America in ballast sediments before sediment movement was reduced when water ballast was adopted: (a) these soft‐sediment dwelling intertidal invertebrates are abundant in Europe and North America, but are not reported in intermediate land masses (Iceland and Greenland) which are expected to be inhabited by natural colonizers (Ingolfsson, 1992); (b) genetic diversity in both species is consistent with North American populations representing a subsample from more diverse European populations (Einfeldt & Addison, 2015; Einfeldt et al., 2014); (c) they lack a pelagic phase, brood‐rear their young, and reside in shallow constructed burrows (Peer, Linkletter, & Hicklin, 1986; Scaps, 2002).…”

Section: Introductionmentioning

confidence: 99%

“…Until recently, they were thought to be native in North America (for review, see Einfeldt & Addison, 2015; Einfeldt, Doucet, & Addison, 2014). Three main lines of evidence suggest they were once moved between Europe and North America in ballast sediments before sediment movement was reduced when water ballast was adopted: (a) these soft‐sediment dwelling intertidal invertebrates are abundant in Europe and North America, but are not reported in intermediate land masses (Iceland and Greenland) which are expected to be inhabited by natural colonizers (Ingolfsson, 1992); (b) genetic diversity in both species is consistent with North American populations representing a subsample from more diverse European populations (Einfeldt & Addison, 2015; Einfeldt et al., 2014); (c) they lack a pelagic phase, brood‐rear their young, and reside in shallow constructed burrows (Peer, Linkletter, & Hicklin, 1986; Scaps, 2002). This is expected to impart limited natural long‐distance dispersal capabilities (via drifting, swimming, or oceanic rafting), as well as a strong association with sediments used in historical ballast, and a weak association with water ballast (Hewitt, Gollasch, & Minchin, 2009).…”

Section: Introductionmentioning

confidence: 99%

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Historical human activities reshape evolutionary trajectories across both native and introduced ranges

Einfeldt

Jesson

Addison

2020

Ecology and Evolution

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The same vectors that introduce species to new ranges could move them among native populations, but how human‐mediated dispersal impacts native ranges has been difficult to address because human‐mediated dispersal and natural dispersal can simultaneously shape patterns of gene flow. Here, we disentangle human‐mediated dispersal from natural dispersal by exploiting a system where the primary vector was once extensive but has since ceased. From 10th to 19th Centuries, ships in the North Atlantic exchanged sediments dredged from the intertidal for ballast, which ended when seawater ballast tanks were adopted. We investigate genetic patterns from RADseq‐derived SNPs in the amphipod Corophium volutator (n = 121; 4,870 SNPs) and the annelid Hediste diversicolor (n = 78; 3,820 SNPs), which were introduced from Europe to North America, have limited natural dispersal capabilities, are abundant in intertidal sediments, but not commonly found in modern water ballast tanks. We detect similar levels of genetic subdivision among introduced North American populations and among native European populations. Phylogenetic networks and clustering analyses reveal population structure between sites, a high degree of phylogenetic reticulation within ranges, and phylogenetic splits between European and North American populations. These patterns are inconsistent with phylogeographic structure expected to arise from natural dispersal alone, suggesting human activity eroded ancestral phylogeographic structure between native populations, but was insufficient to overcome divergent processes between naturalized populations and their sources. Our results suggest human activity may alter species' evolutionary trajectories on a broad geographic scale via regional homogenization and global diversification, in some cases precluding historical inference from genetic data.

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Anthropocene invasion of an ecosystem engineer: resolving the history ofCorophium volutator(Amphipoda: Corophiidae) in the North Atlantic

Cited by 11 publications

References 118 publications

Genetic discontinuity in two high dispersal marine invertebrates in the northwest Atlantic

Genetic discontinuity in two high dispersal marine invertebrates in the northwest Atlantic

Species-Specific Effects on Ecosystem Functioning Can Be Altered by Interspecific Interactions

Historical human activities reshape evolutionary trajectories across both native and introduced ranges

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