Abstract
Invasive ecosystem engineers can have far-reaching effects on systems, especially if they provide structure where none was before. The non-native seaweed Gracilaria vermiculophylla has proliferated on estuarine mudflats throughout the southeastern US, including areas (South Carolina and Georgia) that historically were extremely low in seaweed biomass. Quantitative field surveys across 150 km of high salinity estuaries revealed that the density of the native onuphid polychaete Diopatra cuprea and the aboveground height of its biogenic tubes, which Diopatra decorates with drifting debris and seaweed, positively influenced Gracilaria biomass. The abundance of Gracilaria epifauna, composed primarily of amphipods and small snails, increased with Gracilaria biomass at many locations in our field surveys. To examine whether epifauna were facilitated by Gracilaria we experimentally manipulated Gracilaria biomass in two locations. Consistent with the field surveys, we found that increasing Gracilaria biomass facilitated epifauna, particularly amphipods and snails. Epifaunal densities on Gracilaria were higher than on a biologically-inert structural mimic of Gracilaria (plastic aquarium alga), indicating that epifauna colonize Gracilaria because Gracilaria provisions both physical structure and a biological resource. We also quantified the seaweed’s net rate of productivity and decomposition. Primary production of Gracilaria was variable, but massive in some areas (up to 200 % net biomass increase in 8 weeks). The seaweed rapidly degraded upon burial in silty sediments (79 % loss in mass within 10 days) and thus may represent an important new addition to detrital foodwebs. As a copious, novel source of primary production, detritus, and desirable habitat for epifauna, Gracilaria has the potential to transform southeastern US estuaries.
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References
Aikins S, Kikuchi E (2002) Grazing pressure by amphipods on microalgae in Gamo Lagoon, Japan. Mar Ecol Prog Ser 245:171–179
Allen JA (1998) Mangroves as alien species: the case of Hawaii. Glob Ecol Biogeogr Lett 7:61–71
Andersen FO, Hargrave BT (1984) Effects of Spartina detritus enrichment on aerobic anaerobic benthic metabolism in an intertidal sediment. Mar Ecol Prog Ser 16:161–171
Arenas F, Viejo RM, Fernandez C (2002) Density-dependent regulation in an invasive seaweed: responses at plant and modular levels. J Ecol 90:820–829
Bell SS, Coen LD (1982) Investigations on epibenthic meiofauna.2. Influence of microhabitat and macroalgae on abundance of small invertebrates on Diopatra cuprea (Bosc) (Polychaeta, Onuphidae) tube caps in Virginia. J Exp Mar Biol Ecol 61:175–188
Berke SK (2012) Biogeographic variability in ecosystem engineering: patterns in the abundance and behavior of the tube-building polychaete Diopatra cuprea. Mar Ecol Prog Ser 447:1–13
Berke SK, Woodin SA (2008) Tube decoration may not be cryptic for Diopatra cuprea (Polychaeta: Onuphidae). Biol Bull 214:50–56
Blackwelder BC (1972) Algae of the marshlands. In: Port Royal Sound environmental study. S.C. Water Resources Commission, Columbia, pp 265–269
Buchanan JB (1984) Sediment analysis. In: Holme NA, McIntyre AD (eds) Methods for the study of marine benthos. Blackwell, Oxford, pp 41–65
Byers JE (2007) Lessons from disparate ecosystem engineers. In: Cuddington K, Byers JE, Wilson W, Hastings A (eds) Ecosystem engineering: plants to protists. Academic Press, Burlington, MA, pp 203–208
Byers JE, Wright JT, Gribben PE (2010) Variable direct and indirect effects of a habitat-modifying invasive species on mortality of native fauna. Ecology 91:1787–1798
Crooks JA (2002) Characterizing ecosystem-level consequences of biological invasions: the role of ecosystem engineers. Oikos 97:153–166
Edgar GJ (1993) Measurement of the carrying capacity of benthic habitats using a metabolic rate based index. Oecologia 95:115–121
Freshwater DW, Montgomery F, Greene JK, Hamner RM, Williams M, Whitfield PE (2006) Distribution and identification of an invasive Gracilaria species that is hampering commercial fishing operations in southeastern North Carolina, USA. Biol Invasions 8:631–637
Gribben PE, Byers JE, Clements M, McKenzie LA, Steinberg PD, Wright JT (2009) Behavioural interactions between ecosystem engineers control community species richness. Ecol Lett 12:1127–1136
Hastings A, Byers JE, Crooks JA, Cuddington K, Jones CG, Lambrinos JG, Talley TS, Wilson WG (2007) Ecosystem engineering in space and time. Ecol Lett 10:153–164
Hoffmann WA, Poorter H (2002) Avoiding bias in calculations of relative growth rate. Ann Bot 90:37–42
Hooper DU, Chapin FS, Ewel JJ, Hector A, Inchausti P, Lavorel S, Lawton JH, Lodge DM, Loreau M, Naeem S, Schmid B, Setala H, Symstad AJ, Vandermeer J, Wardle DA (2005) Effects of biodiversity on ecosystem functioning: a consensus of current knowledge. Ecol Monogr 75:3–35
Jones CG, Lawton JH, Shachak M (1994) Organisms as ecosystem engineers. Oikos 69:373–386
Kennedy TA, Hobbie SE (2004) Saltcedar (Tamarix ramosissima) invasion alters organic matter dynamics in a desert stream. Freshw Biol 49:65–76
Kotta J, Paalme T, Kersen P, Martin G, Herkul K, Moller T (2008) Density dependent growth of the red algae Furcellaria lumbricalis and Coccotylus truncatus in the West Estonian Archipelago Sea, northern Baltic Sea. Oceanologia 50:577–585
Nyberg CD, Wallentinus I (2009) Long-term survival of an introduced red alga in adverse conditions. Mar Biol Res 5:304–308
Nyberg CD, Thomsen MS, Wallentinus I (2009) Flora and fauna associated with the introduced red alga Gracilaria vermiculophylla. Eur J Phycol 44:395–403
Parker IM, Simberloff D, Lonsdale WM, Goodell K, Wonham M, Kareiva PM, Williamson MH, Von Holle B, Moyle PB, Byers JE, Goldwasser L (1999) Impact: toward a framework for understanding the ecological effects of invaders. Biol Invasions 1:3–19
Reed DC (1990) An experimental evaluation of density dependence in a subtidal algal population. Ecology 71:2286–2296
Ricciardi A, Atkinson SK (2004) Distinctiveness magnifies the impact of biological invaders in aquatic ecosystems. Ecol Lett 7:781–784
Sandifer PA, Miglarese JV, Calder DR, Manzi JJ, Barclay LA (1980) Ecological characterization of the sea island coastal region of South Carolina and Georgia. Volume III: biological features of the characterization area. U.S. Fish and Wildlife Service, Washington, DC
Stephenson T, Stephenson A (1952) Life between tide-marks in North America: II. Northern Florida and the Carolinas. J Ecol 40:1–49
Tenore KR (1977a) Utilization of aged detritus derived from different sources by polychaete Capitella capitata. Mar Biol 44:51–55
Tenore KR (1977b) Growth of Capitella capitata cultured on various levels of detritus derived from different sources. Limnol Oceanogr 22:936–941
Thomsen MS (2010) Experimental evidence for positive effects of invasive seaweed on native invertebrates via habitat-formation in a seagrass bed. Aquat Invasions 5:341–346
Thomsen M, McGlathery K (2005) Facilitation of macroalgae by the sedimentary tube forming polychaete. Estuar Coast Shelf Sci 62:63–73
Thomsen MS, McGlathery KJ (2007) Stress tolerance of the invasive macroalgae Codium fragile and Gracilaria vermiculophylla in a soft-bottom turbid lagoon. Biol Invasions 9:499–513
Thomsen MS, McGlathery KJ, Tyler AC (2006) Macroalgal distribution patterns in a shallow, soft-bottom lagoon, with emphasis on the nonnative Gracilaria vermiculophylla and Codium fragile. Estuaries Coasts 29:465–473
Thomsen MS, Wernberg T, Staehr P, Krause-Jensen D, Risgaard-Petersen N, Silliman BR (2007) Alien macroalgae in Denmark: a broad-scale national perspective. Mar Biol Res 3:61–72
Thomsen MS, McGlathery KJ, Schwarzschild A, Silliman BR (2009) Distribution and ecological role of the non-native macroalga Gracilaria vermiculophylla in Virginia salt marshes. Biol Invasions 11:2303–2316
Thomsen MS, Wernberg T, Altieri AH, Tuya F, Gulbransen D, McGlathery KJ, Holmer M, Silliman BR (2010) Habitat cascades: the conceptual context and global relevance of facilitation cascades via habitat formation and modification. Integr Comp Biol 50:158–175
Weinberger F, Buchholz B, Karez R, Wahl M (2008) The invasive red alga Gracilaria vermiculophylla in the Baltic Sea: adaptation to brackish water may compensate for light limitation. Aquat Biol 3:251–264
Wright JT, Byers JE, Koukoumaftsis LP, Ralph PJ, Gribben PE (2010) Native species behaviour mitigates the impact of habitat-forming invasive seaweed. Oecologia 163:527–534
Wright JT, Byers JE, Koukoumaftsis LP, Gribben PE (2012) Differences in anti-predator traits of a native bivalve following invasion by a habitat-forming seaweed. Mar Freshw Res 63:246–250. doi:10.1071/MF11184
Zuur AF, Ieno EN, Walker NJ, Saveliev AA, Smith GM (2009). Mixed effects models and extensions in ecology with R. Springer, Berlin
Acknowledgments
We thank Katie Hilleke for generating sequencing data, Loren Danese and Jacob Gantz for logistical help, and Devin Lyons for editorial and statistical input. Funding came from the National Science Foundation (OCE-1057707 to JEB; and DEB-0919064 and OCE-1057713 to EES). This is Grice Publication #388.
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Byers, J.E., Gribben, P.E., Yeager, C. et al. Impacts of an abundant introduced ecosystem engineer within mudflats of the southeastern US coast. Biol Invasions 14, 2587–2600 (2012). https://doi.org/10.1007/s10530-012-0254-5
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DOI: https://doi.org/10.1007/s10530-012-0254-5