Marine Mussels. Elizabeth Gosling
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Название: Marine Mussels

Автор: Elizabeth Gosling

Издательство: John Wiley & Sons Limited

Жанр: Техническая литература

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isbn: 9781119293934

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СКАЧАТЬ as a model system, they explored how (1) predator type, (2) predator diet and (3) injured conspecifics and heterospecifics influence Nucella behaviour. Taking laboratory flumes, they found that N. lapillus responded only to the invasive green crab, Carcinus maenas – the predator it most frequently encounters – and not to rock crabs (Cancer irroratus) or Jonah crabs (Cancer borealis), which are sympatric predators but do not frequently encounter N. lapillus because they are primarily subtidal. Predator diet did not affect whelk responses to risk, although starved predator response was not significantly different from controls. Since green crabs are generalist predators, diet cues do not reflect predation risk, and thus altering behaviour as a function of predator diet would not likely benefit N. lapillus. However, the whelk did react to injured conspecifics – a strategy that may allow it to recognise threats when predators are difficult to detect. N. lapillus did not react to injured heterospecifics including M. edulis and herbivorous snails, Littorina littorea, suggesting that they respond to chemical cues unique to their species, allowing them to minimise costs associated with predator avoidance. The ability of prey to detect and respond to predator signals varies with environmental conditions (Large et al. 2011 and references therein).

      Sea stars are also important predators that influence the distribution and abundance of mussels on the lower shore and in the sublittoral zone. Sea stars predate on mussels and other bivalves either by using force or by secreting an anaesthetic from their stomach that numbs the mussel and causes it to gape. They then extrude their stomach through their mouth into the shell opening and digest the prey. Sea stars with short or inflexible arms (e.g. Astropecten or Luidia spp.) usually swallow their prey whole while digestion occurs in the stomach, before egesting shell pieces through the mouth. Semmens et al. (2013) have reported a novel neurophysin‐associated neuropeptide that triggers stomach eversion and retraction, which may provide a basis for development of nonpeptidic small molecule agonists or antagonists that mimic or block the effects of neuropeptides; this could be used for chemical control of starfish feeding.

Photos depict the sea star Pisaster ochraceus predating on mussels, Mytilus californianus, on the US Pacific coast.

      Source: David Cowles, http://rosario.wallawalla.edu/inverts. Reproduced with permission. (See colour plate section for colour representation of this figure).

      Until recently, the accepted explanation for the distinct zonation patterns on wave‐exposed rocky shores was that dense populations of sedentary organisms, such as mussels, form in static prey refuges above the reach of natural predators. Robles et al. (2009) showed that prey refuges are not in fact static. On the West Coast of the United States, experimental alteration of starfish (P. ochraceus) densities caused the downward extension of the lower boundaries of the mussel M. californianus, while experimental increases in sea star densities caused the upward recession of the lower boundary well into the zone presumed to be a spatial refuge for mussels from predation. As small mussel prey are depleted by sea stars over time, larger mussels are attacked, including those that would otherwise represent the lower boundary of their distribution. Based partly on what is known of Pisaster’s feeding behaviour, moving into the higher reaches of the mussel bed at high tide, then retreating to the lower parts of the bed at low tide, one might predict that the predators are more susceptible to stress than their prey. This was tested in Oregon by transfering mid‐tidal‐level mussels in April to high and low edges of the mussel bed and caging half of them with Pisaster (Petes et al. 2008). Three caging combinations were employed: mussels with and without sea stars, and sea stars without mussels. At four four‐weekly intervals in the summer, both mussels and sea stars were assessed for growth and reproductive status, and tissues were sampled for levels of Hsp70 (see Chapter 9). Results showed that mussels in the high‐level cages spawned earlier and had significantly higher levels of Hsp70 than those in the low‐level cages. There was no significant difference in growth of mussels at the two levels. Sea stars suffered higher mortality at the upper edge of the mussel bed, while those at the lower edge lost body mass but saw less mortality. Sea stars at either level exhibited no significant changes in the level of Hsp70. The authors concluded that intertidal stress factors, such as desiccation and temperature, affect the motile predator more than its sedentary prey. In a subsequent study, Hayne & Palmer (2013) found that P. ochraceus on wave‐exposed shores had narrower arms and were lighter per unit arm length than those from sheltered sites. Narrower arms probably reduce both lift and drag in breaking waves, while on protected shores fatter arms may provide more thermal inertia to resist overheating, or more body volume for gametes.