Risks for larvae mediated by plasticity in hatching

Risks associated with benthic and planktonic development can be mediated by plasticity in hatching. The ability to delay hatching while awaiting favorable planktonic conditions, combined with the ability to accelerate hatching when encapsulated offspring are at risk, should be advantageous. We teste...

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Veröffentlicht in:	Invertebrate biology 2014-06, Vol.133 (2), p.158-169
Hauptverfasser:	Branscomb, E. Sanford, Vedder, Karen, Strathmann, Richard R
Format:	Artikel
Sprache:	eng
Schlagworte:	adults Balanus Balanus glandula barnacle brooding Crabs crushing death Decapoda defense Embryos encapsulation Hatching ingestion Larvae Larval development Marine Nauplii nauplius parents Predation Predators progeny risk Seasons snails spring summer Whelks winter
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creator	Branscomb, E. Sanford Vedder, Karen Strathmann, Richard R
description	Risks associated with benthic and planktonic development can be mediated by plasticity in hatching. The ability to delay hatching while awaiting favorable planktonic conditions, combined with the ability to accelerate hatching when encapsulated offspring are at risk, should be advantageous. We tested this predicted association of hatching plasticities with a barnacle. In the winter, broods of barnacles (Balanus glandula) reached hatching‐capable stages at widely varying times, but these broods hatched in the spring within about 2 weeks, consistent with a synchronizing environmental stimulus for hatching. In contrast, the same adults held subsequent broods (during later spring and summer) briefly. Either an environmental stimulus for hatching was not needed later in the season, or it was more frequently present. Dissections of brood lamellae that scattered smaller clumps of the encapsulated nauplii induced hatching. Crabs eating brooding adults had a similar effect: crabs broke the barnacles' tests, and many nauplii hatched. In contrast, when whelks ate barnacles, they left the barnacles' wall plates and opercula in place, and few nauplii were released. In some cases, numerous hatched nauplii were trapped within the test of the killed mother. At a field site with abundant whelks, many dead barnacles had opercular plates in place. Plasticity in hatching of broods adjusted risks for planktonic larvae against risks of death of the parent before release of embryos, but escape or death of brooded offspring depended on the kind of damage to the brooding mother and thus on the kind of predator. Although both predators killed brooding parents, subtle snails imposed a greater risk than crushing crabs.
doi_str_mv	10.1111/ivb.12051
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Sanford</creatorcontrib><creatorcontrib>Vedder, Karen</creatorcontrib><creatorcontrib>Strathmann, Richard R</creatorcontrib><title>Risks for larvae mediated by plasticity in hatching</title><title>Invertebrate biology</title><addtitle>Invertebr Biol</addtitle><description>Risks associated with benthic and planktonic development can be mediated by plasticity in hatching. The ability to delay hatching while awaiting favorable planktonic conditions, combined with the ability to accelerate hatching when encapsulated offspring are at risk, should be advantageous. We tested this predicted association of hatching plasticities with a barnacle. In the winter, broods of barnacles (Balanus glandula) reached hatching‐capable stages at widely varying times, but these broods hatched in the spring within about 2 weeks, consistent with a synchronizing environmental stimulus for hatching. In contrast, the same adults held subsequent broods (during later spring and summer) briefly. 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subjects	adults Balanus Balanus glandula barnacle brooding Crabs crushing death Decapoda defense Embryos encapsulation Hatching ingestion Larvae Larval development Marine Nauplii nauplius parents Predation Predators progeny risk Seasons snails spring summer Whelks winter
title	Risks for larvae mediated by plasticity in hatching
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