Crassostrea virginica (Gmelin, 1791)
Family: Ostreidae
Common names: American Oyster,  more...
Crassostrea virginica image
Crassostrea virginica  

Species Description: Crassostrea virginica (family Ostreidae) is a prolific member of estuaries on the eastern coast of the Americas (Meyers and Townsend 2000, Wilson et al. 2005). The shell of the eastern oyster is thick, flattened, and highly variable in shape. It grows from round (irregular) to oval and usually bears concentric ridges. The exterior color of the shell is dirty white to gray while the interior is bright white with a deep purple or red-brown muscle scar (Kay 1979).

C. virginica is a key structural component of estuaries (Berquist et al. 2006) playing a major role in the function of estuary ecosystems (Dame 1972). Large beds provide habitat for numerous fish and invertebrate species, reduce water turbidity through filter-feeding, and physically serve as filter removing large material from the water as it passes over the reef (Meyers and Townsend 2000, Berquist et al. 2006). The eastern oyster has been selected as a "natural resource of ecological significance" and methods for management are currently being developed (see the Introduction to Oyster Reefs for more information) (Wilson et al. 2005).

Regional Occurrence: Crassostrea virginica naturally occurs in the Gulf of the St. Lawrence, Canada, along the Atlantic coast of the United States, to the Gulf of Mexico to the Yucatan Peninsula, Mexico, and to the West Indies and the coast of Brazil (Buroker 1983). It is also found in the estuaries of the main Hawaiian Islands where it was introduced in 1866.

IRL Distribution: The eastern oyster forms extensive reefs both intertidally and subtidally on the eastern coast of Florida including the estuaries of the Indian River Lagoon (Grizzle et al. 2002, Boudreaux et al. 2006).

Age, Size, Lifespan: Crassostrea virginica has a lifespan of up to 20 years (Buroker 1983) growing to 100 - 115 mm in length in two years. Individuals can reach sexual maturity at 4 months.

Abundance: Small individuals (spat) of the eastern oyster live in dense aggregations of up to 1,416 oysters per m2 in the higher intertidal and 576 oysters per m2 in the lower intertidal. Larger individuals reaching legal size (75 mm) for harvesting, were recorded in densities of 336 oyster per m2 in the higher intertidal, and 228 individuals per m2 in the lower intertidal (Berquist et al. 2006).

Reproduction: Crassostrea virginica spawn in late June to November peaking in June and July when seawater temperatures are warmest (Dame 1972). The eastern oyster has separate sexes (Buroker 1983, Wallace 2001). A female oyster can produce 15 to 114 million eggs in a single reproductive cycle (Buroker 1983).

Embryology: The fertilized egg of Crassostrea virginica initially develops into a non-feeding swimming trochophore. Within 24 - 48 hrs, the trochophore develops into a veliger larva with a long dispersal period (Buroker 1983, Wallace 2001). The veliger has a thin shell and feeds on phytoplankton (Wallace 2001). After two to three weeks the veliger develops into a pediveliger with a foot and eye spots and begins to test the substratum for a suitable habitat to settle (Buroker 1983, Wallace 2001). The larva will cement itself to whole or broken oyster or clam shells and metamorphose into a spat (tiny oyster) (Wallace 2001). Attachment takes place between March and September in the Indian River Lagoon (Wislon et al. 2005), between July and December in the Gulf of Mexico, and between July and September in the north Atlantic coast of the United States (Buroker 1983). Metamorphosed spat are usually males with some individuals transforming into females after the first or second spawning. In some instances, female C. virginica reverse to males.

Temperature: The reproduction of Crassostrea virginica is regulated by temperature change. Spawning occurs in northern oysters when seawater reaches temperatures between 15.5 and 20°C and in southern oysters spawn when seawater is above 20°C (Wallace 2001, Wilson et al. 2005).

Salinity: Crassostrea virginica appears to have a higher tolerance of salinity fluctuation than other oyster species (Berquist et al. 2006). The optimal salinity for growth and reproduction is 10 - 28 ppt (Wilson et al. 2005). Larvae will not settle and metamorphose into spat when salinity is less than 6 ppt (Wilson et al. 2005). Adult C. virginica can live in salinities up to 35 ppt (Buroker 1983). A study of the population genetics of the eastern oyster suggests that there is gene selection in some populations for high salinity tolerance (Buroker 1983).

Trophic Mode: The eastern oyster is a filter feeder, removing particulate matter from the water column (Berquist et al. 2006). It has small laterofrontal cilli that facilitate the retention of particles between 5-6 m. The filtration rate of Crassostrea virginica was measured at 6.80 liters of seawater per hour in laboratory experiments (RiisgŒrd 1988). Other sources suggest that it is as high as 36 liters per hour (Brusca and Brusca 1990).

In laboratory experiments, Crassostrea virginica was shown to selectively ingest nutritional organic material. The cilli present in the gills were used to sort out unwanted material from the mucus layer by pushing it out of the gill (Newell and Jordan 1983).

Associated Species: Oyster reefs built by Crassostrea virginica provide habitats for numerous invertebrate and fish species (Berquist et al. 2006). The eastern oyster is also a common host of the symbiotic xanthid crab Tumidotheres (Pinnotheres) maculates (Kruczynski 1973).

The human pathogen Vibrio vulnificus is also found in the tissues of some populations of Crassostrea virginica. V. vulnificus causes primary septicemia in patients with compromised immune systems. The infection occurs when the oyster are eaten raw (Tamplin and Capers 1992, Motes et al. 1998).

Fishery: The total harvest of Crassostrea virginica is approximately 22 million pounds of meat per year, making up 70% of all the oyster harvest. Less than one half of the harvesting is from cultivated populations, making a considerable impact on natural oyster reef. The harvestable size of the eastern oyster is 75 mm. In cultivated oyster beds, individuals of C. virginica will grow to 75 mm in 12 - 36 months depending upon the food supply and environmental conditions. The demand for this fishery has decreased in recent years. This has been attributed to the instance of disease associated with eating live oysters and a general change in the eating habits of the targeted market (Wallace 2001). Despite this, over-fishing has had a major negative impact on oyster reef habitats (Meyer and Townsend 2000, Wilson et al. 2005).

Aquaculture: Oyster culture serves two purposes: 1) to provide enough Crassostrea virginica to meet the demand of the oyster fishery; and 2) to restore oyster reef habitats in estuaries along the eastern Atlantic coast and the Caribbean. The eastern oyster is cultured in both natural estuaries and hatcheries. In some regions, oyster clutches are seeded in estuaries considered optimal for oyster growth and reproduction. Alternatively, larvae from controlled spawning events settled on carefully treated shells in hatcheries are then placed in large mesh bags that are subsequently taken to a nursery area in natural waters. Nursery areas are chosen for optimal environmental conditions and the absence of large numbers of potential predators (Wallace 2001).

Oyster culture has been successfully used in efforts to restore reefs on the coast of North Carolina. The reefs created by seeding with live oyster clutches reached the size of natural reefs in adjacent areas within one year. C. virginica spat readily settled on the created reefs within 3 months and reached harvestable size (>75 mm) within two years. In addition, invertebrate species known to be associated with C. virginica oyster reefs were found at densities equivalent to those on natural reefs within 2 years (Meyer and Townsend 2000).

Berquist DC, Hale JA, Baker P, and SM Baker. 1006. Estuaries and Coasts 29:353-360.

Bishop Museum and University of Hawaii Guidebook of Introduced Marine Species of Hawaii. Available online.

Boudreax ML, Stiner JL, and LJ Walters. 2006. Biodiversity of sessile and motile macrofauna on intertidal oyster reefs in Mosquito Lagoon, Florida. Journal of Shellfish Research 25:1079-1089.

Brusca RC and GJ Brusca. 1990. Invertebrates. Sinauer Associates, Inc., Sunderland, MA pp.736-737.

Buroker NE. 1983. Population genetics of the American oyster Crassostrea virginica along the Atlantic coast and Gulf of Mexico. Marine Biology 75:99-112.

Dame RF. 1972. The ecological energies of growth, respiration, and assimilation in the intertidal American oyster Crassostrea virginica. Marine Biology 17:243-250.

Grizzle RE, Adams JR, and LJ Walters. 2002. Historical changes in intertidal oyster (Crassostrea virginica) reefs in a Florida lagoon potentially related to boating activities. Journal of Shellfish Research 21:749-756.

Kay EA. 1979. Hawaiian Marine Shells. Reef and Shore Fauna of Hawaii, Section 4: Mollusca. BP Bishop Museum Special Publication 64(4), 653 pp.

Kruczynski W.L. 1973. Distribution and abundance of Pinnotheres maculates Say in Bogue Sound, North Carolina. Biological Bulletin 145:482-491.

Meyer DL and EC Townsend. 2000. Faunal utilization of created intertidal eastern oyster (Crassostrea virginica) reefs in the southeastern United States. 23:34-45.

Motes ML, DePaola A, Cook DW, Veazey JE, Hunsucker JC, Garthright WE, Blodgett RJ, and SJ.Chirtel. 1998. Influence of water temperature and salinity on Vibrio vulnificus in Northern Gulf and Atlantic coast oysters (Crassostrea virginica). Applied and Environmental Microbiology 64:1459-1465.

Newell RIE and SJ Jordan. 1983. Preferential ingestion of organic material by the American oyster Crassostrea virginica. Marine Ecology Progress Series 13:47-53.

RiisgŒrd HU. 1988. Efficiency of particle retention and filtration rate in 6 species of Northeast American bivalves. Marine Ecology Progress Series 45:217-223.

Tamplin ML and GM Capers. 1992. Persistence of Vibrio vulnificus in tissues of Crassostrea virginica of gulf coast oysters, Crassostrea virginica, exposed to seawater disinfected with UV light. Applied and Environmental Microbiology 58:1506-1510.

Wallace RK. 2001. Cultivating the Eastern oyster, Crassostrea virginica. Southern Regional Aquaculture Center Publication Number 432. pp. 4.

Wilson C, Scotto L, Scarpa J, Volety A, Laramore S, and D Haunert. 2005. Survey of water quality, oyster reproduction and oyster health status in the St. Lucie Estuary. Journal of Shellfish Research 24:157-165.

Crassostrea virginica image
Crassostrea virginica  
Crassostrea virginica image
Crassostrea virginica