Abstract
Cordgrasses in the genus Spartina are good examples of ecosystem engineers that modify habitat structure in estuaries throughout the world. In San Francisco Bay, California, USA, marshes containing native California cordgrass (Spartina foliosa) are being invaded by a hybrid (S. alterniflora × S. foliosa) formed after introduction of S. alterniflora. This study compared vegetation, sediment structure, and infaunal invertebrates in native and invaded marshes. We hypothesized that differences in the physical structure between S. foliosa and hybrid Spartina would be reflected in differences in density, biomass, diversity, and taxonomic composition of infauna. Hybrid Spartina modifies habitat structure more than S. foliosa by producing taller stems, and greater plant biomass both above- and belowground while occupying a much wider tidal range, thereby transforming open mudflats to a vegetated habitat. In general, S. foliosa areas contained significantly higher densities of benthic infauna than adjacent mudflats, while hybrid Spartina areas never contained greater infaunal densities than mudflats. This is because S. foliosa produces a moderate level of structure that can facilitate benthic invertebrates, whereas hybrid Spartina produces so much structure, particularly belowground, that it actually excludes invertebrates. Therefore, we suggest that these two closely related species both act as ecosystem engineers, but with opposing effects on invertebrate communities.
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References
DR Ayres, DL Smith, K Zaremba, S Klohr and DR Strong, Spread of exotic cordgrasses and hybrids (Spartina spp.) in the tidal marshes of San Francisco Bay. Biological Invasions 6 (2004) 221-231
MD Bertness and GH Leonard, The role of positive interactions in communities: lessons from intertidal habitats. Ecology 78 (1997) 1946-1957
KL Bildstein, GT Bancroft, PJ Dugan, DH Gordon, RM Erwin, E Nol, LX Payne and SE Senner, Approaches to the conservation of coastal wetlands in the western hemisphere. Wilson Bulletin 103 (1991) 218-224
CC Bossard, JM Randall and MC Hoshovsky, Invasive plants of California’s wildlands. Berkeley, CA: University of California Press (2000).
J Bruno and CW Kennedy, Patch-size dependent habitat modification and facilitation on New England cobble beaches by Spartina alterniflora. Oecologia 122 (2000) 98-108
DR Cahoon, JC Lynch and AN Powell, Marsh vertical accretion in a southern California estuary, USA. Estuarine, Coastal, and Shelf Science 43 (1996) 19-32
AA Capehart and C Hackney, The potential role of roots and rhizomes in structuring salt marsh benthic communities. Estuaries 12 (1989) 119-122
JA Crooks, Characterizing ecosystem-level consequences of biological invasions: The role of ecosystem engineers. Oikos 97 (2002) 153-166
CM D’Antonio and PM Vitousek, Biological invasions by exotic grasses, the grass/fire cycle, and global change. Annual Review of Ecology and Systematics 23 (1992) 63-87
ED Grosholz, GR Ruiz, CA Dean, KA Shirley, JL Maron and PG Connors, The impacts of a nonindigenous marine predator in a California bay. Ecology 81 (2000) 1206-1224
DR Hahn, Alteration of microbial community composition and changes in decomposition associated with an invasive intertidal macrophyte. Biological Invasions 5 (2003) 45-51
P Hedge and LK Kriworken, Evidence for effects of Spartina anglica invasion on benthic macrofauna in Little Swanport estuary, Tasmania. Austral Ecology 25 (2000) 150-159
CG Jones, JH Lawton and M Shachak, Organisms as ecosystem engineers. Oikos 689 (1994) 373-386
M Josselyn, The Ecology of San Francisco Bay Tidal Marshes: A Community Profile. Washington, D. C: U. S. Fish and Wildlife Service, Division of Biological Services (1983).
LA Levin, DF Boesch, A Covich, C Dahm, C Erseus, KC Ewel, RT Kneib, A Moldenke and JM Weslawski, The function of marine critical transition zones and the importance of sediment biodiversity. Ecosystems 4 (2001) 430-451
LA Levin, TS Talley and J Hewitt, Macrobenthos of Spartina foliosa (Pacific cordgrass) salt marshes in southern California: community structure and comparison to a Pacific mudflat and a Spartina alterniflora (Atlantic smooth cordgrass) marsh. Estuaries 21 (1998) 129-144
KB Macdonald, Coastal salt marsh. In: MG Barbour and J Major (eds.) Terrestrial Vegetation of California. Sacramento, CA: California Native Plant Society (1988) pp. 263-294
WJ Mitsch and JG Gosselink, Wetlands. New York: Van Nostrand Reinhold (1993).
CL Montague and JA Ley, A possible effect of salinity fluctuation on abundance of benthic vegetation and associated fauna in northeastern Florida Bay. Estuaries 16 (1993) 703-717
C Neira, LA Levin and ED Grosholz, Benthic macrofaunal communities of three sites invaded by hybrid Spartina in San Francisco Bay, with comparison to uninvaded habitats. Marine Ecology Progress Series 292 (2005) 111-126
SA Netto and PC Lana, Intertidal zonation of benthic macrofauna in a subtropical salt marsh and nearby unvegetated flat (SE, Brazil). Hydrobiologia 353 (1997) 171-180
SA Netto and PC Lana, The role of above- and below-ground components of Spartina alterniflora (Loisel) and detritus biomass in structuring macrobenthic associations of Paranagua Bay (SE, Brazil). Hydrobiologia 400 (1999) 167-177
FJJ Nieva, EM Castellanos, JM Castillo and ME Figueroa, Clonal growth and tiller demography of the invader cordgrass (Spartina densiflora Brongn.) at two contrasting habitats in SW European salt marshes. Wetlands 25 (2005) 122-129
HM Page, Importance of vascular plant and algal production to macro-invertebrate consumers in a southern California salt marsh. Estuarine, Coastal and Shelf Science 45 (1997) 823-834
SC Pennings and MD Bertness, Salt Marsh Communities. In: MD Bertness and SD Gaines (eds.) Marine Community Ecology. Sunderland, MA: Sinauer Associates, Inc. (2001) pp. 289-316
MH Posey, Community changes associated with the spread of an introduced seagrass, Zostera marina. Ecology 69 (1988) 974-983
ML Quammen, Predation by shorebirds, fish, and crabs on invertebrates in intertidal mudflats: an experimental test. Ecology 65 (1984) 529-537
Ratchford SG (1995) Changes in the density and size of newly settled clams in Willapa Bay, WA, due to the invasion of smooth cordgrass, Spartina alterniflora Loisel. University of Washington, Seattle, WA. (Unpublished M.S. thesis).
DH Rader, Salt-marsh benthic invertebrates: small-scale patterns of distribution and abundance. Estuaries 7 (1984) 413-420
LP Rozas and RJ Zimmerman, Small-scale patterns of nekton use among marsh and adjacent shallow nonvegetated areas of the Galveston Bay Estuary, Texas (USA). Marine Ecology Progress Series 193 (2000) 217-239
Z Shi, LJ Hamilton and E Wolanski, Near-bed currants and suspended sediment transport in saltmarsh canopies. Journal of Coastal Research 16 (2000) 909-914
SPSS Inc. (1998) Systat Version 9.0. for Windows. SPSS, Inc.
MJ Sullivan and CA Currin, Community structure and functional dynamics of benthic microalgae in salt marshes. In: MP Weinstein and DA. Kreeger (eds.) Concepts and Controversies in Tidal Marsh Ecology. Dordrecht, The Netherlands: Kluwer Academic Publishers (2000) pp. 81-106
TS Talley and LA Levin, Macrofaunal succession and community structure of Salicornia marshes of southern California. Estuarine, Coastal, and Shelf Science 49 (1999) 713-731
TS Talley and LA Levin, Modification of sediments and macrofauna by an invasive marsh plant. Biological Invasions 3 (2001) 51-68
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Brusati, E.D., Grosholz, E.D. Native and Introduced Ecosystem Engineers Produce Contrasting Effects on Estuarine Infaunal Communities. Biol Invasions 8, 683–695 (2006). https://doi.org/10.1007/s10530-005-2889-y
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DOI: https://doi.org/10.1007/s10530-005-2889-y