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The Effects of the Wood-boring Isopod Sphaeroma terebrans on the Mangrove Communities of Florida

Published online by Cambridge University Press:  24 August 2009

Andrew E. Rehm
Affiliation:
Marine Biologist, William F. Clapp Laboratories, Inc., of Battelle's Columbus Laboratory, Washington Street, Duxbury, Massachusetts 02332, U.S.A.

Extract

Investigations conducted along the west coast of Florida from Tampa to Cape Sable have shown that mangroves are confined to the upper portion of the intertidal zone by the wood-boring isopod, Sphaeroma terebrans Bate. As a result of this activity, mangroves are unable to become established throughout the intertidal zone and to extend shorelines in their usual manner.

The attack on mangroves is most severe from Marco to Cape Sable, and is probably the single most important factor responsible for the erosion that is currently occurring along this section of coastline. Throughout its length, tides, temperature, and salinity, appear to influence the severity of the attack on mangroves by S. terebrans.

Mangrove-dominated estuaries from Tampa to Cape Sable serve as nursery areas and feeding grounds for several commercially important marine fishes and Crustacea. The continual loss of mangroves as a result of S. terebrans activity, erosion, and human interference, may well decrease the extent to which these vital estuaries can be used as nurseries by commercially important species.

Type
Main Papers
Copyright
Copyright © Foundation for Environmental Conservation 1976

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References

Børgesen, F. (1909). Notes on the shore vegetation of the Danish West Indies. Bot. Tidsskr., 29, pp. 201–59Google Scholar
Carlton, J. M. (1974). Land-building and stabilization by mangroves. Environmental Conservation, 1(4), pp. 285–94. 7 figs.CrossRefGoogle Scholar
Chapman, V. J. (1944). 1939 Cambridge University Expedition to Jamaica, II. A study of the environment of Avicennicnitida Jacq. in Jamaica. J. Linn. Soc. London (Bot.), 52 pp. 448–86.CrossRefGoogle Scholar
Craig, A., McJonkin, D. M. & Stone, P. A. (1971). Phytogeography of Pavilion Key. Dept of Geography, Florida Atlantic University, Boca Raton, Florida: pp. not numbered.Google Scholar
Craighead, F. C. (1971). The Trees of South Florida, I. University of Miami Press, Coral Gables, Florida: xvi + 212pp., illustr.Google Scholar
Curtiss, A. H. (1888). How the mangroves form islands. Garden and Forest, 1, p. 100.Google Scholar
Davis, J. H. (1938). Mangroves, makers of land. Nature Mag., 31, pp. 551–3.Google Scholar
Davis, J. H. (1940). The ecology and geologic roll of mangroves in Florida. Carnegie Inst., Washington, Pub. 517, Papers, from the Tortugas Laboratory, 32(16), pp. 307409.Google Scholar
Dawes, C. J. (1974). Marine Algae of the West Coast of Florida. Univ. Miami Press, Coral Gables, Florida: xi + 201 pp.Google Scholar
Dragovich, A., Finucane, J. R. & May, G. Z. (1961). Counts of red tide organisms, Gymnodinium breve, and associated oceanographic data from Florida west coast, 1957–1959. U.S. Fish and Wildlife Service, Special Sci. Kept, Fisheries, No. 369, 175 pp.Google Scholar
Earle, S. A. (1969). Phaeophyta of the eastern Gulf of Mexico. Phycologia, 7(2), pp. 71254.CrossRefGoogle Scholar
Egler, F. E. (1948). The dispersal and establishment of Red Mangrove, Rhizophora, in Florida. Caribbean Forester, 9, pp. 299320.Google Scholar
Green, J. (1968). The Biology of Estuarine Animals. Univ. of Washington [Press], Seattle & London: vii + 401 pp., illustr.Google Scholar
Harshberger, J. W. (1914). The vegetation of South Florida. Trans. Wagner Free Inst., 7, pp. 49189.Google Scholar
Heald, E. J. (1970). Atlas of the Principal Fishery Resources of the Continental Shelf from the West Coast of Florida to Texas. Sea Grant Tech. Bull. No. 4, Univ. Miami Press, Coral Gables, Florida: 174 pp.Google Scholar
Heald, E. J. (1971). The production of organic detritus in a South Florida estuary. Sea Grant Tech. Bull. No. 6, Univ. of Miami Press, Coral Gables, Florida: 110 pp.Google Scholar
Humm, H. J. (1973). Mangroves. Pp. III D-l-III D-6 in A Summary of Knowledge of the Eastern Gulf of Mexico. Coordinated by the State Univ. System Institute of Oceanography, St Petersburg, Florida: xii + I-l-VII-74 pp.Google Scholar
Idyll, C. P., Tabb, D. C. & Yokel, B. J. (1968). The value of estuaries to shrimp. Proc. Marsh and Estuary Management Symposium, Louisiana State University, July 1967, pp. 8390.Google Scholar
Iredale, T., Johnson, R. A. & McNeill, F. A. (1932). Destruction of timber by marine organisms in the port of Sydney. Sydney Harbour Trust, Sydney, Australia: 148 pp.Google Scholar
Joyce, E. A. (1965). The commercial shrimps of the northeast coast of Florida. Florida Dept Nat. Resources, Prof. Pap. Ser. No. 6, 224 pp.Google Scholar
Macnae, W. (1968). A general account of the fauna and flora of mangrove swamps in the Indo–West Pacific region. Pp. 73270 in Advances in Marine Biology, 6, Academic Press, New York: x + 406 pp., illustr.Google Scholar
Mcmillan, C. (1971). Environmental factors affecting seedling establishment of the Black Mangrove on the central Texas Coast. Ecology, 52(5), pp. 927–30.CrossRefGoogle Scholar
Menzies, R. J. & Frankenberg, D. (1966). Handbook of the Common Marine Isopod Crustacea of Georgia. Univ. of Georgia Press, Athens, Georgia: viii + 93 pp., illustr.Google Scholar
Odum, W. E. & Heald, E. J. (1972). Trophic analyses of an estuarine mangrove community. Bull. Mar. Sci., 22(3), pp. 671738.Google Scholar
Pollard, C. L. (1903). Plant agencies in the formation of the Florida Keys. Plant World, 5, pp. 810.Google Scholar
Pratt, H. S. (1935). A Manual of the Common Invertebrate Animals. McGraw-Hill, New York: xi + 854 pp., illustr.Google Scholar
Price, W. A. (1954). Shorelines and the coast of the Gulf of Mexico. Pp. 3162 in Gulf of Mexico, its Origin, Waters, and Marine Life. U.S. Fishery Bull. No. 89, 604 pp.Google Scholar
Rehm, A. E. & Humm, H. J. (1973). Sphaeroma terebrans: A threat to the mangroves of southwestern Florida. Science, 182, pp. 173–4.CrossRefGoogle Scholar
Richardson, H. (1897). Description of a new species of Sphaeroma. Biological Society of Washington, 10, pp. 105–7.Google Scholar
Richardson, H. (1905). A monograph of the isopods of North America. Bull. U. S. Nat. Museum, 54, pp. 1727.Google Scholar
Saloman, C. H. & Taylor, J. L. (1971). Hydrographic observations in Tampa Bay and adjacent Gulf of Mexico, 1967. U.S. Dept Commerce Rept, 55, Washington, D.C.: pp. 164.Google Scholar
Sargent, C. S. (1893). The mangrove tree. Garden and Forest, 6, pp. 9798.Google Scholar
Savage, T. (1972). Florida mangroves as shoreline stabilizers. Florida Dept Nat. Resources, Professional Paper Series No. 19, 46 pp.Google Scholar
Scholl, W. D. (1964 a). Recent sedimentary record in man-rove swamps and rise in sea-level over southwestern coast of Florida, Part 1. Marine Geology, 1, pp. 344–66.CrossRefGoogle Scholar
Scholl, W. D. (1964 b). Recent sedimentary record in mangrove swamps and rise in sea-level over southwestern coast of Florida, Part 2. Marine Geology, 2, pp. 343–64.CrossRefGoogle Scholar
Schultz, G. A. (1969). The marine isopod crustaceans. Wm. C. Brown, Dubuque, Iowa: vii + 359 pp., illustr.Google Scholar
Shier, D. E. (1969). Vermetid reefs and coastal development in the Ten Thousand Islands, southwest Florida. Geological Soc. Amer. Bull., 80, pp. 485508.CrossRefGoogle Scholar
Spackman, W., Scholl, D. W. & Taft, W. H. (1964). Field Guidebook to Environments of Coal Formation in Southern Florida. Geol. Soc. of America, 67 pp.Google Scholar
Stephens, W. M. (1962). Mangroves: trees that make land. Smithsonian Inst. Annual Report, pp. 491–6.Google Scholar
Tabb, D. C., Manning, R. B. & Dubrow, D. L. (1962 a). The ecology of northern Florida Bay and adjacent estuaries. State of Florida, Board of Conservation, Tech. Series No. 39, 81 pp.Google Scholar
Tabb, D. C., Dubrow, D. L. & Jones, A. E. (1962 b). Studies on the biology of the Pink Shrimp Penaeus duorarum Burkenroad, in Everglades National Park, Florida. State of Florida, Board of Conservation, Tech. Ser. No. 37, 31 pp.Google Scholar
Tanner, W. F. (1960). Florida coastal classification. Trans-Gulf Coast Assoc. Geol. Soc., 10, pp. 259–66.Google Scholar
Thomas, T. M. (1974). A detailed analysis of climatological and hydrological records of South Florida with reference to Man's influence upon ecosystem evolution. Pp. 82122 in Environments of South Florida: Present and Past (Ed. Gleason, P. J.). Miami Geological Society, 4600 Ricken-bocker Causeway, Miami, Florida: vi + 452 pp., illustr.Google Scholar
U.S. Coast and Geodetic Survey (1960). Surface Water Temperature and Salinity, Atlantic Coast, North and South America. U.S. Govt Printing Office, Washington, D.C.: Pub. 31–1.Google Scholar
U.S. Department of Commerce (1971). Tide Tables (1972): East coast of North and South America including Greenland. U.S. Govt Printing Office: vi + 288 pp.Google Scholar
Vaughan, T. W. (1909). The geologic work of mangroves in southern Florida. Smithsonian Misc. Collection, 52, pp. 461–4.Google Scholar