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Natural and human-induced disturbance of seagrasses

Published online by Cambridge University Press:  15 October 2009

Frederick T. Short*
Affiliation:
Department of Natural Resources, University of New Hampshire, Jackson Estuarine Laboratory, 85 Adams Point Road, Durham, New Hampshire 03824, USA
Sandy Wyllie-Echeverria
Affiliation:
School of Marine Affairs, University of Washington, Seattle, Washington 98195, USA
*
* Dr Frederick T. Short Tel: +1 603 862 2175 Fax: +1 603 862 1101 e-mail: [email protected]

Summary

Many natural and human-induced events create disturbances in seagrasses throughout the world, but quantifying losses of habitat is only beginning. Over the last decade, 90000 ha of seagrass loss have been documented although the actual area lost is certainly greater. Seagrasses, an assemblage of marine flowering plant species, are valuable structural and functional components of coastal ecosystems and are currently experiencing worldwide decline. This group of plants is known to support a complex trophic food web and a detritus-based food chain, as well as to provide sediment and nutrient filtration, sediment stabilization, and breeding and nursery areas for finfish and shellfish.

We define disturbance, natural or human-induced, as any event that measurably alters resources available to seagrasses so that a plant response is induced that results in degradation or loss. Applying this definition, we find a common thread in many seemingly unrelated seagrass investigations. We review reports of seagrass loss from both published and ‘grey’ literature and evaluate the types of disturbances that have caused seagrass decline and disappearance. Almost certainly more seagrass has been lost globally than has been documented or even observed, but the lack of comprehensive monitoring and seagrass. mapping makes an assessment of true loss of this resource impossible to determine.

Natural disturbances that are most commonly responsible for seagrass loss include hurricanes, earthquakes, disease, and grazing by herbivores. Human activities most affecting seagrasses are those which alter water quality or clarity: nutrient and sediment loading from runoff and sewage disposal, dredging and filling, pollution, upland development, and certain fishing practices. Seagrasses depend on an adequate degree of water clarity to sustain productivity in their submerged environment. Although natural events have been responsible for both large-scale and local losses of seagrass habitat, our evaluation suggests that human population expansion is now the most serious cause of seagrass habitat loss, and specifically that increasing anthropogenic inputs to the coastal oceans are primarily responsible for the world-wide decline in seagrasses.

Type
Papers
Copyright
Copyright © Foundation for Environmental Conservation 1996

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References

Ackerman, J.D. (1986) Mechanistic implications for pollination in the marine angiosperm Zostera marina. Aquatic Botany 24: 343–53.CrossRefGoogle Scholar
AES (1994) Eelgrass Dive Survey of Cable Crossings in the San Juan Islands. Applied Environmental Services, Ine Report to Orcas Power & Light Company, P.O. Box 187, Eastsound, Washington, 98245, USA: 22 pp.Google Scholar
Alberte, R.S., Suba, G.S., Procaccini, G., Zimmerman, R.C. & Fain, S.R. (1994) Assessment of genetic diversity of seagrass populations using DNA fingerprinting: implications for population stability and management. Proceedings of the National Academy of Science 91: 1049–53.CrossRefGoogle ScholarPubMed
Arber, A. (1920) Water Plants, a Study of Aquatic Angiosperms. Cambridge: Cambridge University Press.Google Scholar
Armiger, L.C. (1964) An occurrence of Labyrinthula in New Zealand Zostera. New Zealand Journal of Botany 2: 39.CrossRefGoogle Scholar
Backman, T.W.H. (1990) Genotypic and phenotypic variability of Zostera marina on the west coast of North America. Canadian Journal of Botany 69: 1361–71.CrossRefGoogle Scholar
Baldwin, J.R. & Lovvorn, J.R. (1994) Expansion of seagrass habitat by the exotic Zostera japonica and its use by dabbling ducks and brant in Boundary Bay, British Columbia. Marine Ecology Progress Series 103: 119–27.CrossRefGoogle Scholar
Batiuk, R.A., Orth, R.J., Moore, K.A., Dennison, W.C., Stevenson, J.C., Staver, L.W., Carter, V. & Rybicki, N.B. (1992) Chesapeake Bay Submerged Aquatic Vegetation Habitat Requirements and Restoration Targets: A Technical Synthesis. US EPA, 68-WO-0043: 186 pp.Google Scholar
Bazzaz, F.A. (1983) Characteristics of populations in relation to disturbance in natural and man-modified ecosystems. In: Disturbance and Ecosystems, ed. Mooney, H.A. & Gordon, M., pp. 259–75. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Bowden, K.F. (1967) Circulation and diffusion. In: Estuaries, ed. Lauff, G.H., pp. 1536. Washington, D.C: American Association for the Advancement of Science.Google Scholar
Brackup, I. & Capone, D.G. (1985) The effect of several metal and organic pollutants on nitrogen fixation (acetylene reduction) by the roots and rhizomes of Zostera marina L. Environmental and Experimental Botany 25: 145–51.CrossRefGoogle Scholar
Brasier, M.D. (1975) An outline history of seagrass communities. Paleontology 18: 681702.Google Scholar
Brix, H., Lyngby, J.E. & Schierup, H.H. (1983) Eelgrass (Zostera marina L.) as an indicator organism of trace metals in the Limfjord, Denmark. Marine Environmental Research 8: 165–81.CrossRefGoogle Scholar
Bulthuis, D.A. (1983) Effects of in-situ light reduction on density and growth of the seagrass Heterozostera tasmanica in Western Port, Victoria, Australia. Journal of Experimental Marine Biology and Ecology 67: 91103.CrossRefGoogle Scholar
Burdick, D.M. & Short, F.T. (1995) The Effects of Boat Docks on Eelgrass Beds in Massachusetts Coastal Waters. Final Report, Massachusetts Coastal Zone Management, 100 Cambridge Street, Boston, Massachusetts, 02202, USA: 32 pp.Google Scholar
Burdick, D.M., Short, F.T. & Wolf, J. (1993) An index to assess and monitor the progression of wasting disease in eelgrass Zostera marina. Marine Ecology Progress Series 94: 8390.CrossRefGoogle Scholar
Cambridge, M.L., Chifiings, A.W., Brittan, C., Moore, L. & McComb, A.J. (1986) The loss of seagrass in Cockburn Sound, Western Australia. II. Causes of seagrass decline. Aquatic Botany 24: 269–85.CrossRefGoogle Scholar
Cambridge, M.L. & McComb, A.J. (1984) The loss of seagrass from Cockburn Sound, Western Australia. I. The time course and magnitude of seagrass decline in relation to industrial development. Aquatic Botany 20: 229–43.CrossRefGoogle Scholar
Churchill, A.C., Nieves, G. & Brenowitz, A.H. (1985) Flotation and dispersal of eelgrass seeds by gas bubbles. Estuaries 8: 352–4.CrossRefGoogle Scholar
Coles, R.G., Poiner, I.R. & Kirkman, H. (1989) Regional studies – seagrasses of north-eastern Australia. In: Biology of Seagrasses: A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region, ed. Larkum, A.W.D., McComb, A.J. & Shepherd, S.A., pp. 261–78. Amsterdam: Elsevier.Google Scholar
Cox, P.A. (1988) Hydrophilous pollination. Annual Review of Ecology and Systematic 19: 261–80.CrossRefGoogle Scholar
De Jonge, V.N. & De Jonge, D.J. (1992) Role of tide, light and fisheries in the decline of Zostera marina L. in the Dutch Wadden Sea. Netherlands Institute for Sea Research Publication 20: 161–76.Google Scholar
den Hartog, C. (1970) The Sea Grasses of the World. Amsterdam: NorthHolland Publication Co: 275 pp.Google Scholar
den Hartog, C. (1971) The dynamic aspect in the ecology of sea-grass communities. Thalassia Jugoslavical: 101–12.Google Scholar
den Hartog, C. (1994) Suffocation of a littoral Zostera bed by Enteromorpha radiata. Aquatic Botany 47: 21–8.CrossRefGoogle Scholar
den Hartog, C. & Polderman, P.J.G. (1975) Changes in the seagrass populations of the Dutch Wadden Zee. Aquatic Botany 1: 141–7.CrossRefGoogle Scholar
Dennison, W.C., Orth, R.J., Moore, K.A., Stevenson, J.C., Carter, V., Kollar, S., Bergstrom, P.W. & Batiuk, R.A. (1993) Assessing water quality with submersed aquatic vegetation. Bioscience 43: 8694.CrossRefGoogle Scholar
Dexter, R.W. (1985) Change in the standing crop of eelgrass, Zostera marina L., at Cape Ann, Massachusetts, since the epidemic of 1932. Rhodora 87: 357–65.Google Scholar
Dirnberger, J.M. & Kitting, C.L. (1988) Browsing injuries to blades of Halophila decipiens within a deep seagrass meadow. Aquatic Botany 29: 373–9.CrossRefGoogle Scholar
Domning, D.P. (1977) Sirenian Evolution in the North Pacific Ocean. University of California Publication in Geological Sciences 118: 176 pp.Google Scholar
Dunton, K.H. (1990) Production ecology of Ruppia maritima L. and Halodule wrightii Aschers, in two subtropical estuaries. Journal of Experimental Marine Biology and Ecology 143: 147–64.CrossRefGoogle Scholar
Durako, M.J. & Kuss, K.M. (1994) Effects of Labyrinthula infection on the photosynthetic capacity of Thalassia testudinum. Bulletin of Marine Science 54: 727–32.Google Scholar
Eleuterius, L.N. (1987) Seagrass ecology along the coast of Alabama, Louisiana, and Mississippi. In: Proceedings of the Symposium on Subtropical-tropical Seagrasses of the Southeastern United States, held at St Petersburg, Florida, 12 August, 1985, ed. Durako, M.J., Phillips, R.C. & Lewis, R.R., HI, pp. 1124. Florida Marine Research Publication No. 42, Florida, USA.Google Scholar
Eleuterius, L.N. (1989) Catastrophic loss of seagrass in Mississippi Sound. MMS-ITM Presentation Summary, 6 December, 1989, New Orleans, LA. Gulf Coast Research Laboratory, Ocean Spring, Mississippi, 39564, USA: 3 pp.Google Scholar
Eleuterius, L.N. & Miller, G.J. (1976) Observations on seagrasses and seaweeds in Mississippi Sound since Hurricane Camille. Journal of the Mississippi Academy of Science 21: 5863.Google Scholar
Eva, A.N. (1980) Pre-miocene seagrass communities in the Caribbean. Paleontology 23: 231–6.Google Scholar
Everett, R.A., Ruis, G.M. & Carlton, J.T. (1990) Effect of commercial oyster culture on the eelgrass Zostera marina in the South Slough Estuary, Oregon (abstract). Western Society of Naturalists, Moss Landing Marine Laboratories, P.O. Box 450, Moss Landing, California, 95039, USA.Google Scholar
Fonseca, M.S. & Fisher, J.S. (1986) A comparison of canopy friction and sediment movement between four species of seagrass with reference to their ecology and restoration. Marine Ecology Progress Series 29: 1522.CrossRefGoogle Scholar
Fonseca, M.S., Thayer, G.W. & Chester, A.J. (1984) Impact of scallop harvesting on eelgrass (Zostera marina) meadows: implications for management. North American Journal of Fisheries Management 4: 286–93.2.0.CO;2>CrossRefGoogle Scholar
Fortes, M.D. (1991) Seagrass-mangrove ecosystems management: a key to marine coastal conservation in the ASEAN region. Marine Pollution Bulletin 22: 113–16.CrossRefGoogle Scholar
Fourqurean, J.W. & Zieman, J.C. (1991) Photosynthesis, respiration and whole plant carbon budget of the seagrass Thalassia testudinum. Marine Ecology Progress Series 69: 161–70.CrossRefGoogle Scholar
Gallegos, M.E., Marba, N., Merino, M. & Duarte, C.M. (1992) Flowering of Thalassia testudinum in the Mexican Caribbean: age-dependence and interannual variability. Aquatic Botany 43: 249–55.CrossRefGoogle Scholar
Giese, G.S. (1988) Cyclical behavior of the tidal inlet at Nauset Beach, Chatham, Massachusetts. In: Hydrodynamics and Sediment Dynamics of Tidal Inlets, ed. Aubrey, D.G. & Weishar, L., pp. 269–83. New York: Springer-Verlag.Google Scholar
Giesen, W.B.J.T., van Katwijk, M.M. & den Hartog, C. (1990) Temperature, salinity, insolation and wasting disease of eelgrass (Zostera marina L.) in the Dutch Wadden Sea in the 1930’s. Netherlands Journal of Sea Research 25: 395404.CrossRefGoogle Scholar
Güven, K.C., Saygi, N. & Oztürk, B. (1993) Survey of metal contents of Bosphorus algae, Zostera marina and sediments. Botanica Marina 36: 175–8.CrossRefGoogle Scholar
Hanekom, N. & Baird, D. (1988) Distribution and variations in seasonal biomass of eelgrass Zostera capensis in the Kromme Estuary, St Francis Bay, South Africa. South African Journal of Marine Science 7: 51–9.CrossRefGoogle Scholar
Harper, J.L. (1977) Population Biology of Plants. London: Academic Press: 892 pp.Google Scholar
Harris, H.W., Fabris, G.J., Statham, P.J. & Tawfik, F. (1979) Biogeochemistry of selected heavy metals in Western Port, Victoria, and use of invertebrates as indicators with emphasis on Mytilus edulis planulatus. Australian Journal of Marine and Freshwater Research 30: 159–78.CrossRefGoogle Scholar
Hemminga, M.A. & Nieuwenhuize, J. (1990) Seagrass wrack-induced dune formation on a tropical coast (Banc d'Arquin, Mauritania). Estuarine and Coastal Shelf Science 31: 499502.CrossRefGoogle Scholar
Howard, R.K. & Short, F.T. (1986) Seagrass growth and survivorship under the influence of epiphyte grazers. Aquatic Botany 24: 287302.CrossRefGoogle Scholar
Ibarra-Obando, S.E. & Escofet, A. (1987) Industrial development effects on the ecology of a Pacific Mexican estuary. Environmental Conservation 14: 135–41.CrossRefGoogle Scholar
Jacobs, R.P.W.M. (1980) Effects of the ‘Amoco Cadiz’ oil spill on the seagrass community at Roscoff with special reference to the benthic infauna. Marine Ecology Progress Series 2: 207–12.CrossRefGoogle Scholar
Johansen, H.W. (1971) Effects of elevation changes on benthic algae in Prince William Sound. In: The Great Alaska Earthquake of 1964, ed. The Committee on the Alaska Earthquake, Division of Earth Sciences, National Research Council, pp. 3568. National Academy of Sciences, Box 285, Washington, D.C., 20055 USA.Google Scholar
Johansson, J.O.R. & Lewis, R.R. (1992) Recent improvements of water quality and biological indicators in Hillsboro Bay, a highly impacted subdivision of Tampa Bay, Florida, USA. Science of the Total Environment Supplement: 1199–215.Google Scholar
Juday, G.P. & Foster, N.R. (1990) A preliminary look at effects of the Exxon Valdez oil spill on Green Island Research Natural Area. Agroborealis 22: 1017.Google Scholar
Kemp, W.M., Boynton, W.R., Twilley, R.R., Stevenson, J.C. & Means, J.C. (1983) The decline of submerged vascular plants in Upper Chesapeake Bay: summary of results concerning possible causes. Marine Society Technology Jourm 17: 7889.Google Scholar
Kenworthy, W.J. (1993) Defining the ecological light compensation point of seagrass in the Indian River Lagoon. In: Proceedings and Conclusions of Workshops on: Submerged Aquatic Vegetation Initiative and Photosynthesis Active Radiation, ed. Morris, L.J. & Tomasko, D.A., pp. 195210. St. Johns River Water Management District, Palatka, Florida, USA.Google Scholar
Kenworthy, W.J., Durako, M.J., Fatemy, S.M.R., Vaiavi, H. & Thayer, G.W. (1994) Ecology of seagrasses in Northeastern Saudi Arabia one year after the Gulf War oil spill. Marine Pollution Bulletin 27: 213–22.CrossRefGoogle Scholar
Kenworthy, W.J. & Haunert, D. (1991) Results and Recommendations of a Workshop Convened to Examine the Capability of Water Quality Criteria, Standards and Monitoring Programs to Protect Seagrasses from Deteriorating Water Transparency. National Oceanic and Atmospheric Administration Coastal Ocean Program, Workshop Report, NOAA Coastal Ocean Office, 1315 East-West Highway, Silver Spring, Maryland 20910, USA: 151 pp.Google Scholar
Kirkman, H. (1978) Decline of seagrass in northern areas of Moreton Bay, Queensland. Aquatic Botany 5: 6376.CrossRefGoogle Scholar
Kirkman, H. (1987) Decline of Seagrass Beds in Princess Royal Harbor and Oyster Harbor, Albany, Western Australia. Technical Series 15, Environmental Protection Authority, Western Perth, Western Australia: 11 pp.Google Scholar
Kitting, C.L. & Wyllie-Echeverria, S. (1992) Seagrasses of San Francisco: status, management, and conservation needs. In: Yosemite Centennial Symposium Proceedings held October 13–20, 1990, A Global Issues Symposium joining the 17th Annual Natural Areas Conference with the Yosemite Centennial Celebration, pp. 388–95. Publications and Graphic Design, National Park Service, USA.Google Scholar
Klumpp, D.W., Howard, R.K. & Pollard, D.A. (1989) Trophodynamics and nutritional ecology of seagrass communities. In: Biology of Seagrasses: A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region, ed. Larkum, A.W.D., McComb, A.J. & Shepherd, S.A., pp. 394457. Amsterdam: Elsevier.Google Scholar
Koehl, M.A.R. & Worcester, S. (1991) Effects of seagrass on water flow at several biological important spatial scales (abstract). 11th Biennial International Estuarine Research Conference, San Francisco, California. ERF, PO Box 544, Crownsville, MD 21032–0544, USA.Google Scholar
Koriba, K. & Miki, S. (1960) Archeozostera, a new genus from Upper Cretaceous in Japan. The Paleobotanistl: 7: 107–13.Google Scholar
Lanyon, J.M., Limpus, C.J. & Marsh, H. (1989) Dugongs and turtles: grazers in seagrass systems. In: Biology of Seagrasses: A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region, ed. Larkum, A.W.D., McComb, A.J. & Shepherd, S.A., pp. 610–34. Amsterdam: Elsevier.Google Scholar
Larkum, A.W.D., McComb, A.J. & Shepherd, S.A. (1989) Biology of Seagrasses: A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region. Amsterdam: Elsevier, xxiv + 841 pp.Google Scholar
Larkum, A.W.D. & West, R.J. (1990) Long-term changes of seagrass meadows in Botany Bay, Australia. Aquatic Botany 37: 5570.CrossRefGoogle Scholar
Lewis, R.R., Durako, M.J., Moffler, M.D. & Phillips, R.C. (1985) Seagrass meadows of Tampa Bay: a review. In: Tampa Bay Area Scientific Information Symposium, pp. 210–46. Florida: Burgess Publishing Co.Google Scholar
Livingston, R.J. (1987) Historic trends of human impacts on seagrass meadows in Florida. In: Proceedings of the Symposium on Subtropical-tropical Seagrasses of the Southeastern United States, held in St Petersburg, Florida, 12 August, 1985, ed. Durako, M.J., Phillips, R.C. & Lewis, R.R. III, pp. 139–51. Florida Marine Research Publication No. 42, Florida, USA.Google Scholar
Mahalingam, R. & Gopinath, K. (1987) Ecological conservation of seagrass beds in the Gulf of Mannar, India. Environmental Conservation 14: 265–8.CrossRefGoogle Scholar
Maher, W.A. (1986) Trace metal concentrations in marine organisms from St Vincent Gulf, South Australia. Water, Air, Soil Pollution 29: 7784.Google Scholar
McMillan, C. (1988) The seed reserve of Habphila decipiens Ostenfeld (Hydrocharitaceae) in Panama. Aquatic Botany 31: 177–82.CrossRefGoogle Scholar
McMillan, C. & Moseley, F.N. (1967) Salinity tolerances of five marine spermatophytes of Redfish Bay, Texas. Ecology 46: 503–6.CrossRefGoogle Scholar
McRoy, C.P. & Helfferich, C. (1980) Applied aspects of seagrasses. In: Handbook of Seagrass Biology: An Ecosystem Perspective, ed. Phillips, R.C. & McRoy, C.P., pp. 297343. New York: STPM Press.Google Scholar
McRoy, C.P. & Lloyd, D.S. (1981) Comparative function and stability of macrophyte-based ecosystems. In: Analysis of Marine Ecosystems, ed. Longhurst, A.R., pp. 473–89. London: Academic Press.Google Scholar
Morris, L.J. & Tomasko, D.A. (1993) Proceedings and Conclusions of Workshops on: Submerged Aquatic Vegetation Initiative and Photo-synthetically Active Radiation. St. Johns River Water Management District, PO Box 1429 Palatka, Florida, 32178–1429, USA: 243 pp.Google Scholar
Muehlstein, L.K. (1989) Perspectives on the wasting disease of eelgrass Zostera marina. Diseases of Aquatic Organisms 7: 211–21.CrossRefGoogle Scholar
Muehlstein, L.K. (1991) Disturbance and recovery of seagrass communities in the U.S. Virgin Islands (abstract). 11th Biennial International Estuarine Research Federation Conference, San Francisco, CA. ERF, PO Box 544, Crownsville, Maryland, 21032–0544, USA.Google Scholar
Muehlstein, L.K., Porter, D. & Short, F.T. (1988) Labyrinthula sp., a marine slime mold producing the symptoms of wasting disease in eelgrass, Zostera marina. Marine Biology 99: 465–72.CrossRefGoogle Scholar
Muehlstein, L.K., Porter, D. & Short, F.T. (1991) Labyrinthula zosterae sp. nov., the causal agent of the wasting disease of eelgrass, Zostera marina. Mycologia 83: 180–91.CrossRefGoogle Scholar
Nicnhuis, P.H. (1983) Temporal and Spatial Patterns of Eelgrass (Zostera marina L.) in a Former Estuary in the Netherlands, Dominated by Human Activities. Marine Technological Society 17: 6977.Google Scholar
Nicnhuis, P.H. (1986) Background levels of heavy metals in nine tropical seagrass species in Indonesia. Marine Pollution Bulletin 17: 508–11.CrossRefGoogle Scholar
Nienhuis, P.H. & van Ierland, E.T. (1978) Consumption of eelgrass, Zostera marina, by birds and invertebrates during the growing season in Lake Grevelingen (SW Netherlands). Netherlands Journal of Sea Research 12: 180–94.CrossRefGoogle Scholar
Ogden, J.C. (1980) Faunal relationships in Caribbean seagrass beds. In: Handbook of Seagrass Biology: An Ecosystem Perspective, ed. Phillips, R.C. & McRoy, C.P., pp. 173–98. New York: STPM Press.Google Scholar
Olinger, L.W., Rogers, R.G., Fore, P.L., Todd, R.L., Mullins, B.L., Bisterfeld, F.T. & Wise, L.A. II, (1975) Environmental and recovery studies of Escambia Bay and the Pensacola Bay system, Florida. U.S. Environmental Protection Agency, Region IV, 345 Courtland Street NE, Atlanta, Georgia, 30365, USA.Google Scholar
Orth, R.J. (1975) Destruction of eelgrass, Zostera marina, by the cownose ray, Rhinoptera bonasus, in the Chesapeake Bay, Virginia. Chesapeake Scientist 16: 205–8.CrossRefGoogle Scholar
Orth, R.J. (1976) The demise and recovery of eelgrass, Zostera marina, in the Chesapeake Bay, Virginia. Aquatic Botany 2: 141–59.CrossRefGoogle Scholar
Orth, R.J., Heck, K.L. Jr & van Montfrans, J. (1984) Faunal communities in seagrass beds: a review of the influence of plant structure and prey characteristics on predatory-prey relationships. Estuaries 7: 339–50.CrossRefGoogle Scholar
Orth, R.J. & Moore, K.A. (1983) Chesapeake Bay: An unprecedented decline in submerged aquatic vegetation. Science 22: 51–2.CrossRefGoogle Scholar
Pearse, J.S. (1992) Long-term trends in a surfgrass-dominated intertidal community following the termination of a small domestic sewage outfall (abstract). The American Zoological Society Meeting, American Society of Zoologists, 401 N. Michigan Ave., Chicago, Illinois, 60611–4267, USA 32: 101.Google Scholar
Peres, J.M. & Picard, J. (1975) Causes of decrease and disappearance of the seagrass Posidonia oceanica on the French Mediterranean coast. Aquatic Botany 1: 133–9.CrossRefGoogle Scholar
Philippart, C.J.M. & Dijkema, K.S. (1995) Wax and wane of Zostera noltii Hornem, in the Dutch Wadden Sea. Aquatic Botany 49: 255–68.CrossRefGoogle Scholar
Philippart, C.J.M., Dijkema, K.S. & Van Der Meer, J. (1992) Wadden Sea Seagrasses: Where and Why? Netherlands Institute of Sea Research Publication 20: 177–91.Google Scholar
Phillips, R.C. (1984) The ecology of eelgrass meadows in the Pacific Northwest: a community profile. U.S. Fish Wildlife Service FWS/OBS-84/24, 18th and C Street, NW, Mail Stop 111, Arlington Square Building, Washington, D.C. 20240, USA: 85 pp.Google Scholar
Phillips, R.C. & Lewis, R.L. III, (1983) Influence of environmental gradients on variations in leaf widths and transplant success in North American seagrasses. Marine Technology Society Journal 17: 5968.Google Scholar
Phillips, R.C. & Menez, E.G. (1988) Seagrasses. Washington, D.C.: Smithsonian Institution Press: 104 pp.Google Scholar
Pirc, H., Buia, M.C. & Mazzella, L. (1986) Germination and seedling development of Cymodocea nodosa (Ucria) Ascherson under laboratory conditions and ‘in situ.’ Aquatic Botany 26: 181–8.CrossRefGoogle Scholar
Poiner, I.R., Walker, D.I. & Coles, R.G. (1989) Regional studies: seagrasses of tropical Australia. In: Biology of Seagrasses: A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region, ed. Larkum, A.W.D., McComb, A.J. & Shepherd, S.A., pp. 279303. Amsterdam: Elsevier.Google Scholar
Pulich, W.M., Bames, S. & Parker, P. (1976) Trace metal cycles in seagrass communities. In: Estuarine Processes, ed. Wiley, M., pp. 493506. New York: Academic Press.CrossRefGoogle Scholar
Pulich, W.M. & White, W.A. (1991) Decline of submerged vegetation in the Galveston Bay system: chronology and relationships to physical processes. Journal of Coastal Research 7: 1125–38.Google Scholar
Quammen, M.L. & Onuf, W.A. (1993) Laguna Madre: seagrass changes contínue decades after salinity reduction. Estuaries 16: 302–9.CrossRefGoogle Scholar
Rasmussen, E. (1977) The wasting disease of eelgrass (Zostera marina) and its effects on environmental factors and fauna. In: Seagrass ecosystems, ed. McRoy, C.P. and Helfferich, C., pp. 151. New York: Marcel Dekker.Google Scholar
Reise, K. (1985) Tidal flat ecology. Berlin: Springer-Verlag: 191 pp.CrossRefGoogle Scholar
Renn, C.E. (1934) Wasting disease of Zostera in American waters. Nature 134: 416.CrossRefGoogle Scholar
Robblee, M.B., Barber, T.R., Carlson, P.R., Durako, M.J., Fourqurean, J.W., Muehlstein, L.K., Porter, D. & Yarbro, L.A. (1991) Mass mortality of the tropical seagrass Thalassia testudinum in Florida Bay (USA). Marine Ecology Progress Series 71: 291–9.CrossRefGoogle Scholar
Robertson, A.I. & Mann, K.H. (1984) Disturbance by ice and life history adaptations of the seagrass Zostera marina. Marine Biology 80: 131–42.CrossRefGoogle Scholar
Sargent, F.J., Leary, T.J., Crewz, D.W. & Kruer, C.R. (1995) Scarring of Florida's Seagrasses: Assessment and Management Options. Florida Department of Environmental Protection, FMRI Technical Report TR-I. Florida Marine Resource Institute, St Petersburg, Florida, 33701, USA: 37 pp.Google Scholar
Schneider, F.I. & Mann, K.H. (1991) Rapid recovery of fauna following simulated ice rafting in a Nova Scotian seagrass bed. Marine Ecology Progress Series 78: 5770.CrossRefGoogle Scholar
Shepherd, S.A., McComb, A.J., Bulthius, D.A., Neverauskas, V., Steffensen, D.A. & West, R. (1989) Decline of seagrasses. In: Biology of Seagrasses: A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region, ed. Larkum, A.W.D., McComb, A.J. & Shepherd, S.A., pp. 346–87. Amsterdam: Elsevier.Google Scholar
Short, F.T. (1983) The response of interstitial ammonium in eelgrass ( Zostera marina L.) beds to environmental perturbations. Journal of Experimental Marine Biology and Ecology 68: 195208.CrossRefGoogle Scholar
Short, F.T. & Burdick, D.M. (in press) Quantifying eelgrass habitat loss in relation to housing development and nitrogen loading in Waquoit Bay, Massachusetts. Estuaries 19.CrossRefGoogle Scholar
Short, F.T., Burdick, D.M., Granger, S. & Nixon, S.W. (1996) Long-term decline in eelgrass, Zostera marina L., linked to increased housing development. In: Seagrass Biology Proceedings of an International Workshop, Rottnest Island, Western Australia 25–29 January 1996, ed. Kuo, J., Phillips, R.C., Walker, D.I. & Kirkman, H., pp. 291–8. Nedlands, Western Australia: Sciences UWA.Google Scholar
Short, F.T., Burdick, D.M., Wolf, J. & Jones, G.E. (1993 a) Eelgrass in Estuarine Research Reserves Along the East Coast, U.S.A., Part I: Declines from Pollution and Disease and Part II: Management of Eelgrass Meadows. National Oceanic and Atmospheric Administration Coastal Ocean Program Publication, NOAA Coastal Ocean Office, 1315 East-West Highway, Silver Spring, Maryland, 20910, USA: 83 pp.+M-24.Google Scholar
Short, F.T., Ibelings, B.W. & den Hartog, C. (1988) Comparison of a current eelgrass disease to the wasting disease of the 1930's. Aquatic Botany 30: 295304.CrossRefGoogle Scholar
Short, F.T., Jones, G.E. & Burdick, D.M. (1991) Seagrass decline: problems and solutions. In: Coastal Wetlands, ed. Bolton, H.S., pp. 439–53. American Society of Civil Engineers, New York, NY, USA.Google Scholar
Short, F.T., Mathieson, A.C. & Nelson, J.J. (1986) Recurrence of the eelgrass wasting disease at the border of New Hampshire and Maine, USA. Marine Ecology Progress Series 29: 8992.CrossRefGoogle Scholar
Short, F.T., Muehlstein, L.K. & Porter, D. (1987) Eelgrass wasting disease: cause and recurrence of a marine epidemic. Biological Bulletin 173: 557–62.CrossRefGoogle ScholarPubMed
Short, F.T. & Neckles, H.A. (in review) Global climate change effects on seagrass and tidal freshwater submerged macrophytes: a review. Aquatic Botany.Google Scholar
Short, F.T., Porter, D., Iizumi, H. & Aioi, K. (1993 b) Occurrence of the eelgrass pathogen, Labyrinthula zosterae, in Japan. Diseases of Aquatic Organisms 16: 73–7.CrossRefGoogle Scholar
Short, F.T., Wolf, J. & Jones, G.E. (1989) Sustaining eelgrass to manage a healthy estuary. In: Coastal Zone ‘89, Volume 4, ed. Magoon, O.T., Converse, H., Miner, D., Tobin, L.T. & Clark, D., pp. 3689–706. American Society of Civil Engineers, New York, NY, USA.Google Scholar
Silberstein, K., Chiffings, A.W. & McComb, A.J. (1986) The loss of seagrass in Cockburn Sound, Western Australia. III. The effect of epiphytes on productivity of Posidonia australis. Aquatic Botany 24: 355–72.CrossRefGoogle Scholar
Simenstad, C.A. (1994) Faunal associations and ecological interactions in seagrass communities of the Pacific Northwest coast. In: Seagrass Science and Policy in the Pacific Northwest, ed. Wyllie-Echeverria, S., Olson, A.M. & Hershman, M.J., pp. 1118. EPA 910/R-94–004 Environmental Protection Agency, Region 10, 1200 Sixth Avenue, Seattle, Washington, 98101, USA.Google Scholar
Smith, R.D., Dennison, W.C. & Alberte, R.S. (1984) Role of seagrass photosynthesis in root aerobic processes. Plant Physiology 74: 1055–8.CrossRefGoogle ScholarPubMed
Stenner, R.D. & Nickless, G. (1975) Heavy metals in organisms of the Atlantic coast of S.W. Spain and Portugal. Marine Pollution Bulletin 6: 8992.CrossRefGoogle Scholar
Thayer, G.W., Engel, D.W. & Bjorndal, K.A. (1982) Evidence for shortcircuiting of the detritus cycle of seagrass beds by the green turtle, Chelonia mydas. Journal of Experimental Marine Biology and Ecology 62: 173–5.CrossRefGoogle Scholar
Thayer, G.W., Kenworthy, W.J. & Fonseca, M.S. (1984) The ecology of eel-grass meadows of the Atlantic coast: a community profile. U.S. Fish and Wildlife Service, FWS/OBSO-84/02, Washington, DC, USA: 147 pp.Google Scholar
Thom, R.M. & Hallum, L. (1990) Long-term Changes in the Aerial Extent of Tidal Marshes, Eelgfass Meadows and Kelp Forests ofPuget Sound. Final report to U.S. Environmental Protection Agency, EPA 910/9–91–005 Environmental Protection Agency, Region 10, 1200 Sixth Avenue, Seattle, Washington 98101, USA: 108 pp.Google Scholar
Thorn, R.M., Miller, B. & Kennedy, M. (1991) Temporal Pattern of Grazers and Vegetation in a Temperate Seagrass System. Fisheries Research Institute Publication, FRI-UW-9122, University Washington, Seattle, Washington, USA: 28 pp.Google Scholar
Tiller, K.G., Merry, R.H., Zarcinas, B.A. & Ward, T.J. (1989) Regional geochemistry of metal-contaminated surficial sediments and seagrasses in Upper Spencer Gulf, South Australia. Estuarine, Coastal and Shelf Science 28: 473–93.Google Scholar
Tomasko, D.A. & Lapointe, B.E. (1991) Productivity and biomass of Thalassia testudinum as related to water column nutrient availability and epiphyte levels: field observations and experimental studies. Marine Ecology Progress Series 75: 917.CrossRefGoogle Scholar
Tubbs, C.R. & Tubbs, J.M. (1983) The distribution of Zostera and its exploitation by wildfowl in the Solent, Southern England. Aquatic Botany 15: 223–9.CrossRefGoogle Scholar
Valentine, J.F. & Heck, K.L. (1991) The role of sea urchin grazing in regulating subtropical seagrass meadows: evidence from field manipulations in the northern Gulf of'Mexico. Journal of Experimental Marine Biology and Ecology 154: 6374.CrossRefGoogle Scholar
Valiela, I. & Costa, J. (1988) Eutrophication of Buttermilk Bay, a Cape Cod coastal embayment: concentrations of nutrients and watershed nutrient budgets. Environmental Management 12: 539–51.CrossRefGoogle Scholar
van Tussenbroek, B.I. (1994) The impact of Hurricane Gilbert on the vegetative development of Thalassia testudinum in Puerto Morelos coral reef lagoon, Mexico: a retrospective study. Botanica Marina 37: 421–8.Google Scholar
Vergeer, L.H.T. & den Hartog, C. (1991) Occurrence of wasting disease in Zostera noltii. Aquatic Botany 40: 155–63.CrossRefGoogle Scholar
Vergeer, L.H.T. & den Hartog, C. (1994) Omnipresence of Labyrinthulaceae in seagrass. Aquatic Botany 48: 120.CrossRefGoogle Scholar
Walker, D.I., Lukatelich, R.J., Bastyan, G. & McComb, A.J. (1989) Effect of boat moorings on seagrass beds near Perth, Western Australia. Aquatic Botany 36: 6977.CrossRefGoogle Scholar
Walker, D.I. & McComb, A.J. (1992) Seagrass degradation in Australian coastal waters. Marine Pollution Bulletin 25: 191–5.CrossRefGoogle Scholar
Wanless, H.R., Tedesco, L.P. & Tyrrell, K.M. (1988) Production of subtidal tubular and surficial tempestites by Hurricane Kate, Caicos Platform, British West Indies. Journal of Sedimentary Petrology 58: 739–50.Google Scholar
Ward, D. (1983) The relationship of two seagrasses: Zostera marina and Ruppia maritima to black brant, Branta bernicla nigrans in San Ignacio Lagoon, Baja California, Mexico. M.S. Thesis, University of Oregon, Oregon, USA: 57 pp.Google Scholar
Ward, T.J. (1989) The accumulation and effects of metals in seagrass habitats. In: Biology of Seagrasses: A Treatise on the Biology of Seagrasses with Special Reference to the Australian Region, ed. by Larkum, A.W.D., McComb, A.J. & Shepherd, S.A., pp. 797820. Amsterdam: Elsevier.Google Scholar
Wigand, C. & Churchill, A.C. (1988) Laboratory studies on eelgrass seed and seedling predation. Estuaries 11: 180–3.CrossRefGoogle Scholar
Williams, S.L. (1988) Thalassia testudinum productivity and grazing by green turtles in a highly disturbed seagrass bed. Marine Biology 98: 447–55.CrossRefGoogle Scholar
Williams, S.L. (1990) Experimental studies of Caribbean seagrass bed development. Ecological Monographs 60: 449–69.CrossRefGoogle Scholar
Wilson, U.W. & Atkinson, J.B. (1995) Black brant winter and spring-stages use at two Washington coastal areas in relation to eelgrass abundance. The Condor 97: 91–8.CrossRefGoogle Scholar
Wium-Andersen, S. & Borum, J. (1984) Biomass variation and autotrophic production of an epiphyte-macrophyte community in a coastal Danish area: I. Eelgrass (Zostera marina L.) biomass and net production. Ophelia 23: 3346.CrossRefGoogle Scholar
Wyllie-Echeverria, S. & Betcher, C. (1994) Assessment of Possible Injury to Zostera marina, Eelgrass, During the Filming of Free Willy II. Report to Free Willy II Productions, Inc., 4000 Warner Blvd., Producers #2, Suite 1102A, Burbank, California, 91522, USA: 10 pp.Google Scholar
Wyllie-Echeverria, S., Olson, A.M. & Hershman, M.J. (1994) Seagrass Science and Policy in the Pacific Northwest. EPA 910/R-94–004. Environmental Protection Agency, Region 10, 1200 Sixth Avenue, Seattle, Washington, 98101, USA: 63 pp.Google Scholar
Young, E.L. (1943) Studies on Labyrinthula. The etiologic agent of the wasting disease of eelgrass. American Journal of Botany, 301: 586–93.CrossRefGoogle Scholar
Zieman, J.C. (1970) The effects of thermal effluent stress on the seagrasses and macroalgae in the vicinity of Turkey Point, Biscayne Bay, Florida. PhD dissertation, University of Miami, Coral Gables, Florida, USA.Google Scholar
Zieman, J.C. (1976) The ecological effects of physical damage from motor-boats on turtle grass beds in southern Florida. Aquatic Botany 2: 127–39.CrossRefGoogle Scholar
Zieman, J.C. (1982) The ecology of the seagrasses of South Florida: a community profile. U.S. Fish and Wildlife Service FWS/OBS 82/25, 18th and C Street, NW, Mail Stop 111, Arlington Square Building, Washington, D.C. 20240, USA: viii+123 pp.+A26.Google Scholar
Zieman, J.C., Orth, R.J., Phillips, R.C., Thayer, G.W. & Thorhaug, A. (1984) The effects of oil on seagrass ecosystems. In: Recovery and restoration of marine ecosystems, ed. Cairns, J. & Buikema, A., pp. 3764. Stoneham, Massachusetts, USA: Butterworth Publications.Google Scholar
Zieman, J.C. & Zieman, R.T. (1989) Ecology of the seagrass meadows of the west coast of Florida: a community profile. US Fish and Wildlife Service Biological Report 85 (7.25), NTIS Order No.: PB90–138280/GAR, 18th and C Street, NW, Mail Stop 111, Arlington Square Building, Washington, D.C. 20240, USA: 155 pp.Google Scholar
Zimmerman, R.C., Reguzzoni, J.L., Wyllie-Echeverria, S., Josselyn, M. & Alberte, R.S. (1991) Assessment of environmental suitability for growth of Zostera marina L. eelgrass in San Francisco Bay, California, USA. Aquatic Botany 39: 353–66.CrossRefGoogle Scholar