Abstract
Oysters are ecosystem engineers in marine ecosystems, but the functions of oyster shell deposits in intertidal salt marshes are not well understood. The annual plant Suaeda linearis is associated with oyster shell deposits in Georgia salt marshes. We hypothesized that oyster shell deposits promoted the distribution of Suaeda linearis by engineering soil conditions unfavorable to dominant salt marsh plants of the region (the shrub Borrichia frutescens, the rush Juncus roemerianus, and the grass Spartina alterniflora). We tested this hypothesis using common garden pot experiments and field transplant experiments. Suaeda linearis thrived in Borrichia frutescens stands in the absence of neighbors, but was suppressed by Borrichia frutescens in the with-neighbor treatment, suggesting that Suaeda linearis was excluded from Borrichia frutescens stands by interspecific competition. Suaeda linearis plants all died in Juncus roemerianus and Spartina alterniflora stands, regardless of neighbor treatments, indicating that Suaeda linearis is excluded from these habitats by physical stress (likely water-logging). In contrast, Borrichia frutescens, Juncus roemerianus, and Spartina alterniflora all performed poorly in Suaeda linearis stands regardless of neighbor treatments, probably due to physical stresses such as low soil water content and low organic matter content. Thus, oyster shell deposits play an important ecosystem engineering role in influencing salt marsh plant communities by providing a unique niche for Suaeda linearis, which otherwise would be rare or absent in salt marshes in the southeastern US. Since the success of Suaeda linearis is linked to the success of oysters, efforts to protect and restore oyster reefs may also benefit salt marsh plant communities.
This is a preview of subscription content, access via your institution.
References
Adam P (1990) Saltmarsh ecology. Cambridge University Press, New York
Anderson WD, Keith WJ, Tuten WR, Mills FH (1979) A survey of South Carolina’s washed shell recource. South Carolina Wildlife and Marine Resources Department, Technical Report No. 36. Charleston, SC, USA
Andrews JD, Frierman M (1974) Epizootiology of Minchinia nelsoni in susceptible wild oysters in Virginia, 1959 to 1971. J Invertebr Pathol 24:127–140
Armas C, Ordiales R, Pugnaire FI (2004) Measuring plant interactions: a new comparative index. Ecology 85:2682–2686
Auster PJ, Malatesta RJ, LaRosa SC, Cooper RA, Stewart LL (1991) Microhabitat utilization by the megafaunal assemblage at a low relief outer continental shelf site-Middle Atlantic Bight, USA. J Northwest Atl Fish Sci 11:59–69
Bahr LM, Lanier WP (1981) The ecology of intertidal oyster reefs of the South Atlantic Coast: a community profile. FWS/OBS-81/15. United States Fish and Wildlife Service, Washington, DC, USA
Bakker JP, de Vries Y (1992) Germination and early establishment of lower salt-marsh species in grazed and mown salt marsh. J Veg Sci 3:247–252
Banks P et al (2007) Status review of the eastern oyster (Crassostrea virginica). Report to the National Marine Fisheries Service, Northeast Regional Office, Gloucester, MA, USA
Bertness MD, Ellison AM (1987) Determinants of pattern in a New England salt marsh plant community. Ecol Monogr 57:129–147
Bertness MD, Gough L, Shumway SW (1992) Salt tolerances and the distribution of fugitive salt marsh plants. Ecology 73:1842–1851
Bigelow SW, Canham CD (2002) Community organization of tree species along soil gradients in a north-eastern USA forest. J Ecol 90:188–200
Brewer JS, Grace JB (1990) Plant community structure in an oligohaline tidal marsh. Vegetatio 90:93–107
Brewer JS, Levine JM, Bertness MD (1998) Interactive effects of elevation and burial with wrack on plant community structure in some Rhode Island salt marshes. J Ecol 86:125–136
Bruno JF (2000) Facilitation of cobble beach plant communities through habitat modification by Spartina alterniflora. Ecology 81:1179–1192
Bruno JF (2002) Causes of landscape-scale rarity in cobble beach plant communities. Ecology 83:2304–2314
Carlsson R, Haeggstrom CA, Kraufvelin P (2008) The vascular plant flora of shell gravel deposits on the Aland Islands, SW Finland—community structure in relation to calcium. Boreal Environ Res 13:45–65
Chapman VJ (1974) Salt marshes and salt deserts of the world. In: Reimold RJ, Queen WH (eds) Ecology of halophytes. Academic, New York, pp 3–19
Coen L, Grizzle R (2007) The importance of habitat created by molluscan shellfish to managed species along the Atlantic Coast of the United States. In: Thomas J, Nygard J (eds) Atlantic states marine fisheries commission habitat management series No. 8. Atlantic States Marine Fisheries Commission, Washington, DC, USA, pp 1–108
Coen LD, Luckenbach MW, Breitburg DL (1999) The role of oyster reefs as essential fish habitat: a review of current knowledge and some new perspectives. Am Fish Soc Symp 22:438–454
Connell JH (1978) Diversity in tropical rain forests and coral reefs. Science 199:1302–1310
Cook T, Folli M, Klinck J, Ford S, Miller J (1998) The relationship between increasing sea-surface temperature and the northward spread of Perkinsus marinus (Dermo) disease epizootics in oysters. Estuar Coast Shelf Sci 46:587–597
Crooks JA (2002) Characterizing ecosystem-level consequences of biological invasions: the role of ecosystem engineers. Oikos 97:153–166
Cuddington K, Hastings A (2004) Invasive engineers. Ecol Model 178:335–347
de Souza JP, Araujo GM, Haridasan M (2007) Influence of soil fertility on the distribution of tree species in a deciduous forest in the Triangulo Mineiro region of Brazil. Plant Ecol 191:253–263
Dittel A, Epifanio CE, Natunewicz C (1996) Predation on mud crab megalopae, Panopeus herbstii H. Milne Edwards: effect of habitat complexity, predator species and postlarval densities. J Exp Mar Biol Ecol 198:191–202
Drake BG (1989) Photosynthesis of salt marsh species. Aquat Bot 34:167–180
Ellison AM (1987) Effects of competition, disturbance, and herbivory on Salicornia europaea. Ecology 68:576–586
Etherington JR (1981) Limestone heaths in south-west Britain: their soils and the maintenance of their calcicole–calcifuge mixtures. J Ecol 69:277–294
Gough L, Grace JB (1998) Herbivore effects on plant species density at varying productivity levels. Ecology 79:1586–1594
Grabowski JH, Peterson CH (2007) Restoring oyster reefs to recover ecosystem services. In: Cuddington K, Byers JE, Wilson WG, Hastings A (eds) Theoretical ecology series, vol 4. Academic, Waltham, pp 281–298
Gutiérrez J, Iribarne O (1999) Role of Holocene beds of the stout razor clam Tagelus plebeius in structuring present benthic communities. Mar Ecol Prog Ser 185:213–228
Gutiérrez JL, Jones CG, Strayer DL, Iribarne OO (2003) Mollusks as ecosystem engineers: the role of shell production in aquatic habitats. Oikos 101:79–90
Harding JM, Mann R (2001) Oyster reefs as fish habitat: opportunistic use of restored reefs by transient fishes. J Shellfish Res 20:951–959
Hargis WJ Jr, Haven DS (1999) Chesapeake oyster reefs, their importance, destruction, and guidelines for restoring them. In: Luckenbach MW, Mann R, Wesson JA (eds) Oyster reef habitat restoration: a synopsis, and a synthesis of approaches. Virginia Institute of Marine Science, Gloucester Point, pp 329–358
Hastings A et al (2007) Ecosystem engineering in space and time. Ecol Lett 10:153–164
He Q, Cui BS, Cai YZ, Deng JF, Sun T, Yang ZF (2009) What confines an annual plant to two separate zones along coastal topographic gradients? Hydrobiologia 630:327–340
Hessini K, Ghandour M, Albouchi A, Soltani A, Werner K, Abdelly C (2008) Biomass production, photosynthesis, and leaf water relations of Spartina alterniflora under moderate water stress. J Plant Res 121:311–318
Hik DS, Jefferies RL, Sinclair ARE (1992) Foraging by geese, isostatic uplift and asymmetry in the development of salt marsh plant communities. J Ecol 80:395–406
Huston MA (1994) Biological diversity. The coexistence of species on changing landscapes. Cambridge University Press, Cambridge
Ingold A, Havill DC (1984) The influence of sulphide on the distribution of higher plants in salt marshes. J Ecol 72:1043–1054
Jones CG, Lawton JH, Shachak M (1994) Organisms as ecosystem engineers. Oikos 69:373–386
Jones CG, Lawton JH, Shachak M (1997) Positive and negative effects of organisms as physical ecosystem engineers. Ecology 78:1946–1957
Jones CG, Gutierrez JL, Byers JE, Crooks JA, Lambrinos JG, Talley TS (2010) A framework for understanding physical ecosystem engineering by organisms. Oikos 119:1862–1869
Krantz GE, Jordan SJ (1996) Management alternatives for protecting Crassostrea virginica fisheries in Perkinsus marinus enzootic and epizootic areas. J Shellfish Res 15:167–176
Larsen PF (1985) The benthic macrofauna associated with the oyster reefs of the James River Estuary, Virginia, USA. Int Rev Gesamten Hydrobiol Hydrogr 70:797–814
Lee CH, Lee DK, Ali MA, Kim PJ (2008) Effects of oyster shell on soil chemical and biological properties and cabbage productivity as a liming materials. Waste Manag 28:2702–2708
Lehnert R, Allen D (2002) Nekton use of subtidal oyster shell habitat in a southeastern US estuary. Estuaries 25:1015–1024
Lenihan HS (1999) Physical–biological coupling on oyster reefs: how habitat structure influences individual performance. Ecol Monogr 69:251–275
Linthurst RA, Seneca ED (1981) Aeration, nitrogen and salinity as determinants of Spartina alterniflora Loisel. growth response. Estuaries 4:53–63
MacArthur RH, MacArthur JW (1961) On bird species diversity. Ecology 42:594–598
McDonald J (1982) Divergent life history patterns in the co-occurring intertidal crabs Panopeus herbstii and Eurypanopeus depressus (Crustacea: Brachyura: Xanthidae). Mar Ecol Prog Ser 8:173–180
Meade RH (1982) Sources, sinks, and storage of river sediment in the Atlantic drainage of the United States. J Geol 90:235–252
Meyer DL (1994) Habitat partitioning between the xanthid crabs Panopeus herbstii and Eurypanopeus depressus on intertidal oyster reefs (Crassostrea virginica) in Southeastern North Carolina. Estuaries 17:674–679
Meyer DL, Townsend EC, Thayer GW (1997) Stabilization and erosion control value of oyster cultch for intertidal marsh. Restor Ecol 5:93–99
Milliman J, Pilkey O, Ross D (1972) Sediments of the continental margin off the eastern United States. Geol Soc Am Bull 83:1315–1334
NCDENR (2001) North Carolina oyster fishery management plan. North Carolina Department of Environment and Natural Resources, North Carolina Division of Marine Fisheries, Morehead City, NC, USA
Pennings SC, Bertness MD (2001) Salt marsh communities. In: Bertness MD, Gaines SD, Hay ME (eds) Marine community ecology. Sinauer, Sunderland, pp 289–316
Pennings SC, Callaway RM (1996) Impact of a parasitic plant on the structure and dynamics of salt marsh vegetation. Ecology 77:1410–1419
Pennings SC, Moore DJ (2001) Zonation of shrubs in western Atlantic salt marshes. Oecologia 126:587–594
Pennings SC, Richards CL (1998) Effects of wrack burial in salt-stressed habitats: Batis maritima in a southwest Atlantic salt marsh. Ecography 21:630–638
Pennings SC, Grant MB, Bertness MD (2005) Plant zonation in low-latitude salt marshes: disentangling the roles of flooding, salinity and competition. J Ecol 93:159–167
Pezeshki SR (1997) Photosynthesis and root growth in Spartina alterniflora in relation to root zone aeration. Photosynthetica 34:107–114
Powell EN, Klinck JM (2007) Is oyster shell a sustainable estuarine resource? J Shellfish Res 26:181–194
Powell EN, Ashton-Alcox KA, Kraeuter JN, Ford SE, Bushek D (2008) Long-term trends in oyster population dynamics in Delaware Bay: Regime shifts and response to disease. J Shellfish Res 27:729–755
R Development Core Team (2010) R: A language and environment for statistical computing. Version 2.12.0. Vienna, Austria
Rothschild BJ, Ault JS, Goulletquer P, Heral M (1994) Decline of the Chesapeake Bay oyster populations: a century of habitat destruction and overfishing. Mar Ecol Prog Ser 111:29–39
Saunders R (2002) The Fig Island Ring Complex (38CH42): coastal adaptation and the question of ring function in the Late Archaic. Report prepared for the South Carolina Department of Archives and History, Columbia, SC, USA
Szedlmayer ST, Howe JC (1997) Substrate preference in age-0 red snapper, Lutjanus campechanus. Environ Biol Fishes 50:203–207
Tessier M, Gloaguen JC, Lefeuvre JC (2000) Factors affecting the population dynamics of Suaeda maritima at initial stages of development. Plant Ecol 147:193–203
Tessier M, Gloaguen JC, Bouchard V (2002) The role of spatio-temporal heterogeneity in the establishment and maintenance of Suaeda maritima in salt marshes. J Veg Sci 13:115–122
Thibodeau PM, Gardner LR, Reeves HW (1998) The role of groundwater flow in controlling the spatial distribution of soil salinity and rooted macrophytes in a southeastern salt marsh, USA. Mangroves Salt Marshes 2:1–13
Thompson V, Worth J (2011) Dwellers by the sea: native American adaptations along the southern coasts of eastern North America. J Archaeol Res19 (1):51–101
Tilman D (1982) Resource competition and community structure. Princeton University Press, Princeton, NJ, USA
USDA (2004) Soil survey laboratory methods manual. Version 4. United States Department of Agriculture, Natural Resources Conservation Service. Washington, DC, USA
van de Koppel J, Altieri AH, Silliman BR, Bruno JF, Bertness MD (2006) Scale-dependent interactions and community structure on cobble beaches. Ecol Lett 9:45–50
van Wesenbeeck BK, Crain CM, Altieri AH, Bertness MD (2007) Distinct habitat types arise along a continuous hydrodynamic stress gradient due to interplay of competition and facilitation. Mar Ecol Prog Ser 349:63–71
Varty AK, Zedler JB (2008) How waterlogged microsites help an annual plant persist among salt marsh perennials. Estuaries Coasts 31:300–312
Vivian-Smith G (1997) Microtopographic heterogeneity and floristic diversity in experimental wetland communities. J Ecol 85:71–82
Walker DA, Bockheim JG, Chapin FS, Eugster W, Nelson FE, Ping CL (2001) Calcium-rich tundra, wildlife, and the “Mammoth Steppe”. Quat Sci Rev 20:149–163
Watkinson AR, Davy AJ (1985) Population biology of salt marsh and sand dune annuals. Plant Ecol 62:487–497
Whitaker JD et al (2004) An ecological characterization of coastal hammock islands in South Carolina. Ocean and Coastal Resources Management, South Carolina Department of Health and Environmental Control. Charleston, SC, USA
Wiegert RG, Freeman BJ (1990) Tidal salt marshes of the southeast Atlantic coast: A community profile. US Fish and Wildlife Service Biological Report 85:1–80
Woods H, Hargis WJ, Hershner CH, Mason P (2005) Disappearance of the natural emergent 3-dimensional oyster reef system of the James River, Virginia, 1871–1948. J Shellfish Res 24:139–142
Wright JP, Jones CG (2006) The concept of organisms as ecosystem engineers ten years on: progress, limitations, and challenges. Bioscience 56:203–209
Acknowledgments
We thank Jane Buck, Christine Ewers, Daniel Saucedo, Jacob Shalack, Kazimierz Więski, and Yihui Zhang for field assistance, and John Silander and two anonymous reviewers for constructive comments. The experiments described in this paper complied with the current laws of the United States. This is a contribution of the Georgia Coastal Ecosystems Long-Term Ecological Research program, which is funded by NSF (OCE06-20959). This is contribution number 1014 from the University of Georgia Marine Institute.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by John Silander.
Rights and permissions
About this article
Cite this article
Guo, H., Pennings, S.C. Post-mortem ecosystem engineering by oysters creates habitat for a rare marsh plant. Oecologia 170, 789–798 (2012). https://doi.org/10.1007/s00442-012-2356-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00442-012-2356-2