Abstract
Knowledge of the ecological mechanisms that influence recovery after oil spills is needed to better manage, mitigate, and restore impacted ecosystems, but the species interactions responsible for these mechanisms are poorly known. Here, we report on a species interaction in the aftermath of the Deepwater Horizon (DwH) oil spill that may facilitate biotic recovery. Although macroinfauna were extirpated in heavily oiled salt marshes after the DwH, amphipods recovered by 4.5 years, and maintained elevated densities, up to 20 × higher, compared to reference sites for 2 years thereafter. Many invertebrates were recovering during this period, and we compared the densities of 10 taxa with the density of amphipods to ask if recovery may have been affected by the abundance of amphipods. Correlation analysis revealed that copepod species richness and the densities of the polychaete Manayunkia aestuarina, ostracods, the kinorhynch Echinoderes coulii, and juvenile gastropods were unrelated to amphipod density. However, the densities of nematodes, copepods (adults and larvae), the tanaid Hargeria rapax, juvenile bivalves, and juvenile polychaetes were positively correlated with amphipod abundance. More than 90% of the amphipods were Apocorophium louisianum. Studies with closely related species indicate that this species is a burrowing and bioturbating ecosystem engineer that grazes benthic microalgae. We hypothesize that amphipod grazing increased the supply and/or availability of microalgae to surface- and suspension-feeding invertebrates either by stimulating microalgal primary production or by suspending microalgal particles, or both. The high abundance of amphipods may therefore have enhanced the resilience of, and ecological benefits provided by, many benthic invertebrates in heavily oiled marshes undergoing ecosystem recovery.
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References
Altieri, A.H., and J.D. Witman. 2006. Local extinction of a foundation species in a hypoxic estuary: Integrating individuals to ecosystem. Ecology 87: 717–730.
Barron, M.G., D.N. Vivian, R.A. Heintz, and U.H. Yim. 2020. Long-term ecological impacts from oil spills: comparison of Exxon Valdez, Hebei Spirit, and Deepwater Horizon. Environmental Science & Technology.
Bat, L., and D. Raffaelli. 1998. Sediment toxicity testing: A bioassay approach using the amphipod Corophium volutator and the polychaete Arenicola marina. Journal of Experimental Marine Biology and Ecology 226: 217–239.
Baumann, M.S., G.F. Fricano, K. Fedeli, C.E. Schlemme, M.C. Christman, and M.V. Carle. 2020. Recovery of salt marsh invertebrates following habitat restoration: Implications for marsh restoration in the northern Gulf of Mexico. Estuaries and Coasts 43: 711–1721.
Bell, S.S. 1982. On the population biology and meiofaunal characteristics of Manayunkia aestuarina (Polychaeta: Sabellidae: Fabricinae) from a South Carolina salt marsh. Estuarine, Coastal and Shelf Science 14: 215–221.
Bertness, M.D. 1984. Ribbed mussels and Spartina alterniflora production in a New England salt-marsh. Ecology 65: 1794–1807.
Bertness, M.D. 1991. Interspecific interactions among high marsh perennials in a New England salt-marsh. Ecology 72: 125–137.
Bilkovic, D.M., M.M. Mitchell, R.E. Isdell, M. Schliep, and A.R. Smyth. 2017. Mutualism between ribbed mussels and cordgrass enhances salt marsh nitrogen removal. Ecosphere 8: e01795.
Borja, A., D.M. Dauer, M. Elliott, and C.A. Simenstad. 2010. Medium- and long-term recovery of estuarine and coastal ecosystems: Patterns, rates and restoration effectiveness. Estuaries and Coasts 33: 1249–1260.
Bouillon, S., T. Moens, N. Koedam, F. Dahdouh-Guebas, W. Baeyens, and F. Dehairs. 2004. Variability in the origin of carbon substrates for bacterial communities in mangrove sediments. FEMS Microbiology Ecology 49: 171–179.
Bousfield, E.L., and P.M. Hoover. 1997. The amphipod superfamily Corophioidea on the Pacific Coast of North America. Part 5. Family Corophiidae: Corophiinae, new subfamily. Systematics and Distributional Ecology. Amphipacifica 3: 67–139.
Braeckman, U., C. Van Colen, K. Soetaert, M. Vincx, and J. Vanaverbeke. 2011. Contrasting macrobenthic activities differentially affect nematode density and diversity in a shallow subtidal marine sediment. Marine Ecology Progress Series 422: 179–191.
Cagle, G., Q. Lin, S.A. Graham, I. Mendelssohn, J.W. Fleeger, D. Deis, D.S. Johnson, J. Zhou, and A. Hou. 2020. Planting Spartina alterniflora in a salt marsh denuded of vegetation by an oil spill induces a rapid response in the soil microbial community. Ecological Engineering 151: 105815.
Chandler, G.T., and J.W. Fleeger. 1983. Meiofaunal colonization of azoic estuarine sediment in Louisiana: Mechanisms of dispersal. Journal of Experimental Marine Biology and Ecology 69: 175–188.
Citadin, M., T.M. Costa, and S.A. Netto. 2018. Response of estuarine meiofauna communities to shifts in spatial distribution of keystone species: An experimental approach. Estuarine, Coastal and Shelf Science 212: 365–371.
De Backer, A., F. Van Coillie, F. Montserrat, P. Provoost, C. Van Colen, M. Vincx, and S. Degraer. 2011. Bioturbation effects of Corophium volutator: Importance of density and behavioural activity. Estuarine Coastal and Shelf Science 91: 306–313.
de Deckere, E., J. van de Koppel, and C.H.R. Heip. 2000. The influence of Corophium volutator abundance on resuspension. Hydrobiologia 426: 37–42.
Decho, A.W. 1986. Water-cover influence on diatom ingestion rates by meiobenthic copepods. Marine Ecology Progress Series 33: 139–146.
Deis, D.R., J.W. Fleeger, S.M. Bourgoin, I.A. Mendelssohn, Q. Lin, and A. Hou. 2017. Shoreline oiling effects and recovery of salt marsh macroinvertebrates from the Deepwater Horizon Oil Spill. PeerJ 5: e3680.
Deis, D.R., J.W. Fleeger, D.S. Johnson, I.A. Mendelssohn, Q. Lin, S.A. Graham, S. Zengel, and A. Hou. 2020. Recovery of the salt marsh periwinkle (Littoraria irrorata) 9 years after the Deepwater Horizon oil spill: size matters. Marine Pollution Bulletin 160: 111581.
Drolet, D., and M.A. Barbeau. 2009. Differential emigration causes aggregation of the amphipod Corophium volutator (Pallas) in tide pools on mudflats of the upper Bay of Fundy, Canada. Journal of Experimental Marine Biology and Ecology 370: 41–47.
Drolet, D., T.T. Bringloe, M.R.S. Coffin, M.A. Barbeau, and D.J. Hamilton. 2012. Potential for between-mudflat movement and metapopulation dynamics in an intertidal burrowing amphipod. Marine Ecology Progress Series 449: 197–209.
Drumm, D., and R. Heard. 2006. Tanaidacea Web Site. <https://gcrl.usm.edu/tanaids/>
Duarte, C.M., A. Borja, J. Carstensen, M. Elliott, D. Krause-Jensen, and N. Marbà. 2015. Paradigms in the recovery of estuarine and coastal ecosystems. Estuaries and Coasts 38: 1202–1212.
Dyson, K.E., M.T. Bulling, M. Solan, G. Hernandez-Milian, D.G. Raffaelli, P.C.L. White, and D.M. Paterson. 2007. Influence of macrofaunal assemblages and environmental heterogeneity on microphytobenthic production in experimental systems. Proceedings of the Royal Society B-Biological Sciences 274: 2547–2554.
Echols, B.S. 2021. Toxicity evaluation of Louisiana nearshore marsh sediments following the Deepwater Horizon oil spill. Marine Pollution Bulletin 168: 112380. https://doi.org/10.1016/j.marpolbul.2021.112380.
Fleeger, J.W. 2020. How do indirect effects of contaminants inform ecotoxicology? A Review. Processes 8: 1659. https://doi.org/10.3390/pr8121659.
Fleeger, J.W., K.R. Carman, M.R. Riggio, I.A. Mendelssohn, Q.X. Lin, A. Hou, D.R. Deis, and S. Zengel. 2015. Recovery of salt marsh benthic microalgae and meiofauna following the Deepwater Horizon oil spill linked to recovery of Spartina alterniflora. Marine Ecology Progress Series 536: 39–54.
Fleeger, J.W., D.S. Johnson, S. Zengel, I.A. Mendelssohn, D.R. Deis, S.A. Graham, Q. Lin, M.C. Christman, M.R. Riggio, and M. Pant. 2020. Macroinfauna responses and recovery trajectories after an oil spill differ from those following saltmarsh restoration. Marine Environmental Research 155: 104881–104881.
Fleeger, J.W., M.R. Riggio, I.A. Mendelssohn, Q. Lin, D.R. Deis, D.S. Johnson, K.R. Carman, S.A. Graham, S. Zengel, and A. Hou. 2019. What promotes the recovery of salt marsh infauna after oil spills? Estuaries and Coasts 42: 204–217.
Fleeger, J.W., M.R. Riggio, I.A. Mendelssohn, Q. Lin, A. Hou, and D.R. Deis. 2018. Recovery of saltmarsh meiofauna six years after the Deepwater Horizon oil spill. Journal of Experimental Marine Biology and Ecology 502: 182–190.
Fleeger, J.W., P.O. Yund, and B. Sun. 1995. Active and passive processes associated with initial settlement and post-settlement dispersal of suspended meiobenthic copepods. Journal of Marine Research 53: 609–645.
Fodrie, F.J., K.W. Able, F. Galvez, K.L. Heck, O.P. Jensen, P.C. Lopez-Duarte, C.W. Martin, R.E. Turner, and A. Whitehead. 2014. Integrating organismal and population responses of estuarine fishes in Macondo spill research. BioScience 64: 778–788.
Fricano, G.F., M.S. Baumann, K. Fedeli, C.E. Schlemme, M.V. Carle, and M. Landry. 2020. Modeling coastal marsh restoration benefits in the northern Gulf of Mexico. Estuaries and Coasts 43: 1804–1820.
Galván, K.A., J.W. Fleeger, B.J. Peterson, D.C. Drake, L.A. Deegan, and D.S. Johnson. 2011. Natural abundance stable isotopes and dual isotope tracer additions help to resolve resources supporting a saltmarsh food web. Journal of Experimental Marine Biology and Ecology 410: 1–11.
Gansfort, B., D. Fontaneto, and M. Zhai. 2020. Meiofauna as a model to test paradigms of ecological metacommunity theory. Hydrobiologia 847: 2645–2663.
Giere, O. 2009. Meiobenthology. The microscopic motile fauna of aquatic sediments. Berlin: Springer-Verlag.
Hentschel, B.T., and B.S. Herrick. 2005. Growth rates of interface-feeding spionid polychaetes in simulated tidal currents. Journal of Marine Research 63: 983.
Hook, S.E. 2020. Beyond thresholds: A holistic approach to impact assessment is needed to enable accurate predictions of environmental risk from oil spills. Integrated Environmental Assessment and Management 16: 813–830.
Hughes, R.G. 1988. Dispersal by benthic invertebrates - the in situ swimming behavior of the amphipod Corophium volutator. J. Mar. Biol. Ass. u. K 68: 565–580.
Husseneder, C., J.-S. Park, and L.D. Foil. 2018. Recovery of horse fly populations in Louisiana marshes following the Deepwater Horizon oil spill. Scientific Reports 8.
Ingels, J., S.L. Dashfield, P.J. Somerfield, S. Widdicombe, and M.C. Austen. 2014. Interactions between multiple large macrofauna species and nematode communities — mechanisms for indirect impacts of trawling disturbance. Journal of Experimental Marine Biology and Ecology 456: 41–49.
Johnson, D.S., J.W. Fleeger, M.R. Riggio, I.A. Mendelssohn, Q. Lin, S.A. Graham, D.R. Deis, and A. Hou. 2018. Saltmarsh plants, but not fertilizer, facilitate benthic invertebrate recolonization after an oil spill. Ecosphere 9: e02082.
Krebs, C.T., and K.A. Burns. 1977. Long-Term effects of an oil spill on populations of the salt-marsh crab Uca pugnax. Science 197: 484–487.
Larsen, M.H., and K.N. Mouritsen. 2014. Temperature-parasitism synergy alters intertidal soft-bottom community structure. Journal of Experimental Marine Biology and Ecology 460: 109–119.
Limia, J., and D. Raffaelli. 1997. The effects of burrowing by the amphipod Corophium volutator on the ecology of intertidal sediments. Journal of the Marine Biological Association of the United Kingdom 77: 409–424.
Lin, Q., I.A. Mendelssohn, S. Graham, A. Hou, J.W. Fleeger, and D.R. Deis. 2016. Response of salt marshes to oiling from the Deepwater Horizon Spill: Implications for plant growth, soil surface-erosion, and shoreline stability. Science of the Total Environment 557–558: 369–377.
Lin, Q.X., and I.A. Mendelssohn. 2012. Impacts and recovery of the Deepwater Horizon oil spill on vegetation structure and function of coastal salt marshes in the northern Gulf of Mexico. Environmental Science & Technology 46: 3737–3743.
McCall, J.N., and J.W. Fleeger. 1995. Predation by juvenile fish on hyperbenthic meiofauna: A review with data on post-larval Leiostomus xanthurus. Vie Et Milieu - Life and Environment 45: 61–73.
McLusky, D.S., and T. Martins. 1998. Long-term study of an estuarine mudflat subjected to petro-chemical discharges. Marine Pollution Bulletin 36: 791–798.
Meadows, P.S., and A. Reid. 1966. The behaviour of Corophium volutator (Crustacea: Amphipoda). Journal of Zoology 150: 387–399.
Mendelssohn, I.A., I.C. Anderson, D.M. Baltz, R. Caffey, K.R. Carman, J.W. Fleeger, S.B. Joye, Q. Lin, E. Maltby, E.B. Overton, and L. Rozas. 2012. Oil impacts to coastal wetlands: Implications for the Mississippi River Delta ecosystem after the Deepwater Horizon oil spill. BioScience 62: 562–574.
Middelburg, J.J., C. Barranguet, H.T.S. Boschker, P.M.J. Herman, T. Moens, and C.H.R. Heip. 2000. The fate of intertidal microphytobenthos carbon: an in situ 13C-labeling study. limnology and Oceanography 45: 1224–1234.
Modig, H., W.J. van de Bund, and E. Olafsson. 2000. Uptake of phytodetritus by three ostracod species from the Baltic Sea: Effects of amphipod disturbance and ostracod density. Marine Ecology Progress Series 202: 125–134.
Montagna, P.A., J.G. Baguley, C. Cooksey, I. Hartwell, L.J. Hyde, J.L. Hyland, R.D. Kalke, L.M. Kracker, M. Reuscher, and A.C. Rhodes. 2013. Deep-sea benthic footprint of the Deepwater Horizon blowout. Plos One 8.
Munguia, P. 2015. Role of sources and temporal sinks in a marine amphipod. Biology Letters 11: 20140864.
Murawski, S.A., J.P. Kilborn, A.C. Bejarano, D. Chagaris, D. Donaldson, F.J. Hernandez, T.C. MacDonald, C. Newton, E. Peebles, and K.L. Robinson. 2021. A synthesis of deepwater horizon impacts on coastal and nearshore living marine resources. Frontiers in Marine Science 7.
Nascimento, F.J.A., A.M.L. Karlson, J. Naslund, and R. Elmgren. 2011. Diversity of larger consumers enhances interference competition effects on smaller competitors. Oecologia 166: 337–347.
Nordstroem, M.C., C.A. Currin, T.S. Talley, C.R. Whitcraft, and L.A. Levin. 2014. Benthic food-web succession in a developing salt marsh. Marine Ecology Progress Series 500: 43-U69.
Ölafsson, E. 2003. Do macrofauna structure meiofauna assemblages in marine soft-bottoms? A review of experimental studies. Vie Et Milieu - Life and Environment 53: 249–265.
Partyka, M.L., and M.S. Peterson. 2008. Habitat quality and salt-marsh species assemblages along an anthropogenic estuarine landscape. Journal of Coastal Research 24: 1570–1581.
Pascal, P.-Y., J.W. Fleeger, H.T.S. Boschker, H.M. Mitwally, and D.S. Johnson. 2013. Response of the benthic food web to short- and long-term nutrient enrichment in saltmarsh mudflats. Marine Ecology Progress Series 474: 27–41.
Peterson, C.H., K.W. Able, C.F. DeJong, M.F. Piehler, C.A. Simenstad, and J.B. Zedler. 2008. Chapter 4 practical proxies for tidal marsh ecosystem services: application to injury and restoration. In Advances in Marine Biology, 221–266: Academic Press.
Peterson, C.H., S.D. Rice, J.W. Short, D. Esler, J.L. Bodkin, B.E. Ballachey, and D.B. Irons. 2003. Long-term ecosystem response to the Exxon Valdez oil spill. Science 302: 2082–2086.
Pinto, T.K., M.C. Austen, and C.E. Bemvenuti. 2006. Effects of macroinfauna sediment disturbance on nematode vertical distribution. Journal of the Marine Biological Association of the United Kingdom 86: 227–233.
Powers, S.P., S. Rouhani, M.C. Baker, H. Roman, J.H. Grabowski, S.B. Scyphers, J.M. Willis, and M.W. Hester. 2017. Ecosystem services are lost when facilitation between two ecosystem engineers is compromised by oil. Marine Ecology Progress Series 576: 189–202.
Quade, A.H. 2019. Long-term impacts of Deepwater Horizon oil exposure on salt marsh-stabilizing facilitation of southern ribbed mussels. Geukensia granosissima: NIcholls State University Thibodaux, Louisiana.
Renzi, J.J., Q. He, and B.R. Silliman. 2019. Harnessing positive species interactions to enhance coastal wetland restoration. Frontiers in Ecology and Evolution 7.
Sakamaki, T., and J.S. Richardson. 2009. Dietary responses of tidal flat macrobenthos to reduction of benthic microalgae: A test for potential use of allochthonous organic matter. Marine Ecology-Progress Series 386: 107–113.
Sanders, H.L., J.F. Grassle, G.R. Hampson, L.S. Morse, S. Garnerprice, and C.C. Jones. 1980. Anatomy of an oil-spill - long-term effects from the grounding of the barge Florida off West Falmouth, Massachusetts. Journal of Marine Research 38: 265–380.
Schratzberger, M., and J. Ingels. 2018. Meiofauna matters: The roles of meiofauna in benthic ecosystems. Journal of Experimental Marine Biology and Ecology 502: 12–25.
Stock, J.H. 1952. Some notes on the taxonomy, the distribution and the ecology of four species of the genus Corophium (Crustacea, Malacostraca). Beaufortia 21: 1–10.
Sun, B., and J.W. Fleeger. 1994. Field experiments on the colonization of meiofauna into sediment depressions. Marine Ecology Progress Series 110: 167–175.
Thomson, J.A., D.A. Burkholder, M.R. Heithaus, J.W. Fourqurean, M.W. Fraser, J. Statton, and G.A. Kendrick. 2015. Extreme temperatures, foundation species, and abrupt ecosystem change: An example from an iconic seagrass ecosystem. Global Change Biology 21: 1463–1474.
Urban-Malinga, B., M. Zalewski, and N. Barnes. 2016. Effects of various bivalves on meiobenthic and nematode assemblages in shallow sandy sediments. Hydrobiologia 772: 131–144.
Washburn, T.W., M.G. Reuscher, P.A. Montagna, C. Cooksey, and J.L. Hyland. 2017. Macrobenthic community structure in the deep Gulf of Mexico one year after the Deepwater Horizon blowout. Deep-Sea Research Part I-Oceanographic Research Papers 127: 21–30.
Watzin, M.C. 1983. The effects of meiofauna on settling macrofauna: Meiofauna may structure macrofaunal communities. Oecologia 59: 163–166.
Weerman, E.J., P.M.J. Herman, and J. van de Koppel. 2011. Macrobenthos abundance and distribution on a spatially patterned intertidal flat. Marine Ecology Progress Series 440: 95–103.
Widbom, B., and C.A. Oviatt. 1994. The World Prodigy oil spill in Narragansett Bay, Rhode Island - acute effects on macrobenthic crustacean populations. Hydrobiologia 291: 115–124.
WoRMS Editorial Board (2021). World Register of Marine Species. Available from http://www.marinespecies.org at VLIZ. Accessed 2021–01–31. https://doi.org/10.14284/170
Zengel, S., B.M. Bernik, N. Rutherford, Z. Nixon, and J. Michel. 2015. Heavily oiled salt marsh following the Deepwater Horizon oil spill, ecological comparisons of shoreline cleanup treatments and recovery. Plos One 10.
Zengel, S., C.L. Montague, S.C. Pennings, S.P. Powers, M. Steinhoff, G. Fricano, C. Schlemme, M.N. Zhang, J. Oehrig, Z. Nixon, S. Rouhani, and J. Michel. 2016a. Impacts of the Deepwater Horizon oil spill on salt marsh periwinkles (Littoraria irrorata). Environmental Science & Technology 50: 643–652.
Zengel, S., S.C. Pennings, B. Silliman, C. Montague, J. Weaver, D.R. Deis, M.O. Krasnec, N. Rutherford, and Z. Nixon. 2016b. Deepwater Horizon oil spill impacts on salt marsh fiddler crabs (Uca spp.). Estuaries and Coasts 39: 1154–1163.
Zengel, S., J. Weaver, S.C. Pennings, B. Silliman, D.R. Deis, C.L. Montague, N. Rutherford, Z. Nixon, and A.R. Zimmerman. 2017. Five years of Deepwater Horizon oil spill effects on marsh periwinkles Littoraria irrorata. Marine Ecology Progress Series 576: 135–144.
Acknowledgements
We thank Dr. Walter Sikora for constructive comments on an earlier version of this manuscript. Contribution No. 4020 of the Virginia Institute of Marine Science, William & Mary.
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This research was made possible by a grant from The Gulf of Mexico Research Initiative.
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Fleeger, J.W., Johnson, D.S., Zengel, S.A. et al. A Macroinfaunal Ecosystem Engineer May Facilitate Recovery of Benthic Invertebrates and Accompanying Ecosystem Services After an Oil Spill. Estuaries and Coasts 45, 582–591 (2022). https://doi.org/10.1007/s12237-021-00978-3
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DOI: https://doi.org/10.1007/s12237-021-00978-3