Tridacna is a genus of large and gigantic saltwater clams, marine bivalve mollusks in the subfamily Tridacninae, the giant clams. They have heavy shells, fluted with 4–6 folds. Mantle is brightly coloured. They inhabit shallow waters of coral reefs in warm seas of the Indo-Pacific region. These clams are popular in marine aquaria, and in some areas, such as the Philippines, members of the genus are farmed for the marine aquarium trade. They live in symbiosis with photosynthetic algae (zooxanthellae). Some species are used as seafood.
Systematics and phylogeny
Subgenus Tridacna (Tridacna)
- Tridacna derasa (Röding, 1798)
- Tridacna gigas Linnaeus, 1758
- Tridacna tevoroa Lucas, Ledua & Braley, 1990
Subgenus Tridacna (Chametrachea)
- Tridacna costata Richter, Roa-Quiaoit, Jantzen, Al-Zibdah, Kochzius, 2008
- Tridacna crocea Lamarck, 1819
- Tridacna maxima Röding, 1798( =Tridacna elongata)
- Tridacna rosewateri Sirenho & Scarlato, 1991
- Tridacna squamosa Lamarck, 1819
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An alternative older classification recognises a third subgenus Persikima containing T. derasa and T. tevoroa. Recent biochemical studies have suggested that there may exist morphologically indistinct cryptic species.
Ecology and behaviour
Tridacna clams are common inhabitants of Indo-Pacific coral reef benthic communities in shallower waters. They live in symbiosis with photosynthetic dinoflagellate algae (Symbiodinium) that grow in the mantle tissues They are sessile in adulthood. By day, the clams spread out their mantle so that the algae receive the sunlight they need to photosynthesize, whereas the colour pigments protect the clam against excessive light and UV radiation. They get most (70-100%) of their nutrients from the algae and the rest from filter feeding. When disturbed, the clam closes its shell. The popular opinion that they pose danger to divers who get trapped or injured between the closing sharp-edged shell is not very real, as the closing reaction is quite slow. Their large size and easy accessibility has caused overfishing and collapse of the natural stocks in many places and extirpation in some of the species.
- ^ http://paleodb.org
- ^ WoRMS. (2009). Tridacna. Accessed through the World Register of Marine Species at http://www.marinespecies.org/aphia.php?p=taxdetails&id=205753 on 2009-01-08.
- ^ Schneider, J.A.,and O´Foighil, D. Phylogeny of Giant Clams (Cardiidae: Tridacninae) Based on Partial Mitochondrial 16S rDNA Gene Sequences. Molecular Phylogenetics and Evolution Vol. 13, No. 1, October, pp. 59–66, 1999
- ^ Benzie,J.A.H. and Williams,S.T. Phylogenetic relationships among giant clam species (Mollusca: Tridacnidae) determined by protein electrophoresis. Marine Biology (1998) 132: 123±133
- ^ Mohamed, N.M. et al., Molecular Genetic Analyses of Giant Clam (Tridacna sp.) Populations in the Northern Red Sea. Asian Journal of Biochemistry, 1 (4): 338-342 (2006)
- ^ Rosewater, J., The Family Tridacnidae in the Indo-Pacific. Indo-Pacific Mollusca, 1:347-408. 1965
- ^ Jantzen, C., et al. Photosynthetic performance of giant clams, Tridacna maxima and T. squamosa, Red Sea. Marine Biology (2008) 155:211–221
- ^ Klumpp,D.W., Lucas,J.S., Nutritional ecology of the giant clams Tridacna tevoroa and T. derasa from Tonga: influence of light on filter-feeding and photosynthesis. Mar. Ecol. Prog. Ser. Vol 107, 1994
- ^ J.W. Copland and J.S. Lucas, (Eds.), Giant Clams in Asia and the Pacific Vol. 9, Australian Center for International Agricultural Research, Canberra(1988).
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