Elizabeth Gosling

Marine Mussels


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size limit that can be opened being directly related to the size of the crab (references in Seed 1976). Crabs will almost always choose small‐sized prey when offered a range of sizes. It is handling time rather than the energetic costs of handling, estimated as a mere 2% of corresponding gains, that is the basis on which prey are selected (Rovero et al. 2000). During the handling period, the crab is at risk from other predators, competitors and even claw damage. Small mussels are therefore particularly vulnerable to predation, since they are easily crushed by most size classes of crab. A mussel must attain a shell length of at least 45 mm before it is relatively safe from crab predation. Once again, mussels show several defence mechanisms. In laboratory experiments, M. edulis increased byssus volume in response to waterborne cues from Cancer pagurus and Carcinus maenas (Cote 1995; Leonard et al. 1999). Similar findings were reported when P. viridis were exposed to crab (Thalamita danae) that had recently consumed conspecifics (Chiu et al. 2011). In addition, mussels subject to heavy predation develop thicker and more robust shells in response not just to crabs but also to the broken shells of other mussels (Leonard et al. 1999; see also Freeman & Byers 2006 and comments from Rawson et al. 2007 and Freeman & Byers 2007). Similar effects have also been reported in mussels subject to heavy whelk predation (Smith & Jennings 2000), and increased production of byssal threads has been shown in P. viridis in response to crab and gastropod predation (Cheung et al. 2004a,b, 2006, 2009). A behavioural strategy in response to crab predation has been reported in the Wadden Sea, Germany, where oysters (Crassostrea gigas) have invaded native mussel (M. edulis) beds (Eschweiler & Christensen 2011). Mussels subjected to direct contact with crabs (C. maenas) migrated from the top of the oyster reef to interspaces at the bottom of the reef, where they showed significantly reduced growth rates and conditions to mussels on the top of the reef. Mussels experience a trade‐off between survival and food supply, preferring to take refuge from predation even when this decreases growth and condition. In a previous study, Shin et al. (2008) investigated the effect of cues from damaged conspecifics and heterospecifics on the induction of refuge seeking and enhancement of byssus production as responses to the crab Carcinus maenas in the mussel Brachidontes variabilis, hypothesising that the mussel would seek refuge more readily and prefer a smaller refuge. More byssal threads (thicker and longer ones) should also be produced. They found that B. variabilis was able to differentiate between the sizes of available refuges and to stay in appropriate ones according to the level of risk they perceived. Staying in a smaller refuge would reduce the chance of the mussels being dislodged and consumed by the crabs. This helps explain why B. variabilis tended to stay in smaller refuges when predation risk was high, as simulated by the presence of damaged conspecifics and heterospecifics. In contrast, higher food and oxygen availabilities were found in large refuges, although the predation risk was also higher. Staying in larger refuges would be advantageous to the mussels only when predation risk was low. The preference toward certain sizes of refuge, therefore, should be a trade‐off between physiological requirements and the risk of predation.