1978
DOI: 10.1111/j.1469-7998.1978.tb03339.x
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The diurnal rhythm and the processes of feeding and digestion in Tridacna crocea (BivaMa: Tridacnidae)

Abstract: Tridacna crocea Lamarck 1819 possesses a diurnal rhythm of activity. During the daylight hours the hypertrophied siphonal tissues, containing zooxanthellae, are expanded and phasic adductions occur that pump fresh sea water into and filtered water and pseudofaeces out of the mantle cavity. During the night the shell valves become more apposed, the mantle folds are withdrawn and few phasic adductions occur. Such a pattern of activity is similar to that described for other sublittoral bivalves. With this cycle o… Show more

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Cited by 33 publications
(24 citation statements)
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“…First of all, the transfer of the excess of carbon from the symbiotic zooxanthellae to the host's tissues, which seems to satisfy the main nutritional requirements (Trench et al, 1981;Fisher et al, 1985). Furthermore, they possess a digestive system typical of heterotrophic filter-feeding bivalves (Morton, 1978;Reid et al, 1984). Thanks to these autotrophic and heterotrophic nutritional sources, which act synergistically, giant clams can act as trophic opportunists in oligotrophic environments, such as tropical coral reefs (Yonge, 1982;Heslinga and Fitt, 1987).…”
Section: Discussionmentioning
confidence: 99%
“…First of all, the transfer of the excess of carbon from the symbiotic zooxanthellae to the host's tissues, which seems to satisfy the main nutritional requirements (Trench et al, 1981;Fisher et al, 1985). Furthermore, they possess a digestive system typical of heterotrophic filter-feeding bivalves (Morton, 1978;Reid et al, 1984). Thanks to these autotrophic and heterotrophic nutritional sources, which act synergistically, giant clams can act as trophic opportunists in oligotrophic environments, such as tropical coral reefs (Yonge, 1982;Heslinga and Fitt, 1987).…”
Section: Discussionmentioning
confidence: 99%
“…The feeding behaviour in giant clams has a marked circadian rhythm (Fankboner 1971 ; Morton 1978 ; Reid et al 1984 ; Fankboner and Reid 1990 ); solar and lunar cycles which determine food availability in turn influence the diurnal feeding activity. At night, they withdraw their mantles and close their valves either half-way or fully, remaining quiescent till dawn (Gwyther and Munro 1981 ; Heslinga et al 1984 ).…”
Section: Feedingmentioning
confidence: 99%
“…SCUBA divers often observe that giant clams are able to sense their presence and respond to shadows by closing their valves to varying degrees (Rosewater 1966 ; Hickman and Gruffydd 1971 ; Morton 1978 ). Adults possess numerous (>3,000 for a 900 mm T. gigas ) pinhole eyes along their mantle margins, constituting the visual mechanism to mediate defensive withdrawal responses (Fankboner 1981 ).…”
Section: Anti-predator Behaviourmentioning
confidence: 99%
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“…), puffer fish ( Tetradon stellatus ), and eagle rays ( Aetobatis narinari ) (Chambers, 2007). Giant clams can detect predator stimuli through at least two mechanisms: visual (Fankboner, 1981; Wilkens, 1986) and mechanical (bites or grazes from predators) (McMichael, 1974; Morton, 1978; Soo and Todd, 2014). Clams possess several hundred pinhole eyes on their mantle that are capable of detecting light or shade (Fankboner, 1981).…”
Section: Introductionmentioning
confidence: 99%