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Predators Induce Phenotypic Plasticity in Echinoderms across Life History Stages.

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    Marine invertebrate larvae can change their juvenile defenses before settlement when exposed to predator cues. This phenotypic plasticity helps protect them from immediate post-metamorphosis threats, though responses vary by species and predator type.

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    Area of Science:

    • Marine Biology
    • Developmental Biology
    • Ecology

    Background:

    • Marine invertebrates with biphasic life cycles transition from benthic adults to planktonic larvae and back to benthic juveniles.
    • Metamorphosis exposes newly settled juveniles to novel predators, often resulting in high mortality.
    • Phenotypic plasticity allows juvenile invertebrates to develop defenses in response to predator cues, but timing can be critical.

    Purpose of the Study:

    • To investigate if planktonic echinoderm larvae alter their juvenile phenotypes in response to waterborne predator cues before settlement.
    • To test the hypothesis that larvae can anticipate post-metamorphic predation risk and adjust defenses accordingly.

    Main Methods:

    • Larvae of green urchins (Strongylocentrotus droebachiensis) and Pacific sand dollars (Dendraster excentricus) were exposed to predator cues (crabs) during development and settlement.
    • Control groups were maintained without predator cues.
    • Juvenile morphology (spine length, number, disk area) and settlement timing were compared between exposed and control groups.

    Main Results:

    • Green urchin larvae exposed to predator cues settled with significantly more juvenile spines.
    • Sand dollar larvae exposed to benthic predator cues settled earlier, with larger disk area, fewer, and shorter spines.
    • Sand dollar larvae exposed to planktonic predator cues exhibited even more pronounced changes, settling sooner and larger with reduced spines.

    Conclusions:

    • Echinoderm larvae demonstrate phenotypic plasticity, altering juvenile morphology in response to predator cues detected in the water column.
    • The specific defensive responses vary between species (urchins vs. sand dollars).
    • Larvae may prioritize responses to planktonic threats over benthic ones, suggesting complex adaptive strategies during the vulnerable settlement phase.