Effects of embryo energy, egg size, and larval food supply on the development of asteroid echinoderms

Trackenberg, Stacy N.; Richardson, Emily L.; Allen, Jonathan D.

doi:10.1002/ece3.6511

Cited by 5 publications

(5 citation statements)

References 60 publications

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“…Or is this an example of animals that are desperate to feed following an energetically expensive metamorphic transition that has burned up their energetic reserves? The former is supported by the observation that A. forbesi juveniles can survive for months without feeding or growing (Mead 1900, Trackenberg et al 2020, and the latter is supported by field observations of cannibalism in "young" sea stars when "pressed by hunger" (Mead 1899). Observations of cannibalism in juvenile sea stars have been noted in efforts to aquaculture tropical seastars (Luidia clathrata; Brocco-French and Allen, unpublished observations), invasive sea stars (Asterias amurensis; M. Byrne, personal communication) and sunflower stars (Pycnopodia helianthoides; J. Hodin, personal communication) from the northern Pacific.…”

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confidence: 84%

“…Experiments were conducted at William & Mary (W&M) in Williamsburg, Virginia, USA, and at the Bowdoin College Schiller Coastal Studies Center (SCSC) on Orrs Island, Maine, USA between 2015 and 2016. Adult A. forbesi were collected in Rockland, Maine, USA, spawned through injection of 100 µmol/L 1-methyladenine, and the resulting larvae were reared to metamorphosis as in Trackenberg et al (2020). To determine the relationship between juvenile cannibalism and juvenile density, juveniles were randomly placed into beakers with filtered sea water (FSW) at densities of 1, 2, 10, and 20 juveniles/beaker and counted every day for 2 weeks.…”

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confidence: 99%

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Cannibalism of newly metamorphosed juvenile sea stars

French

Allen

2021

Ecology

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confidence: 84%

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confidence: 99%

Cannibalism of newly metamorphosed juvenile sea stars

French

Allen

2021

Ecology

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“…When the first larvae developed brachiolar arms and the beginnings of a juvenile rudiment, beakers were no longer cleaned to allow biofilm growth (Cameron and Hinegardner 1974) and a blue mussel shell (Mytilus edulis) was placed in each beaker to encourage larval settlement (Trackenberg et al 2020). Shells and beakers were checked for settlement once per day and age at settlement was recorded.…”

Section: Larval Feeding Experimentsmentioning

confidence: 99%

Carryover effects in a sea star: juvenile resource availability does not compensate for a poor larval environment

Richardson

Allen

2023

Mar Biol

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Carryover effects are widespread in nature and can link early-life experiences to the regulation of populations. However, for organisms with complex life cycles, it is unclear whether offspring can overcome negative early-life experiences when provided with abundant post-metamorphic resources. We tested this by rearing larvae of the keystone sea star Asterias forbesi, under high or low food conditions, and then reared the juveniles for 2–3 weeks under one of four food treatments. Larvae reared under low food conditions took longer to reach metamorphosis and settled as smaller juveniles with fewer spines. For early settlers (mean age at settlement = 24.0 d), carryover effects of low larval food significantly reduced post-metamorphic size, mussel consumption and growth. However for late settlers (mean age at settlement = 29.3 d), there were no carryover effects of larval food availability detected post-metamorphosis. The differences between early and late settlers may indicate a trade-off between larval duration and the presence of carryover effects. Our data suggest that carryover effects mediated by body size at settlement could determine post-metamorphic survival, growth, and performance, ultimately impacting the recruitment of this keystone predator.

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“…While life‐history stages can be quite different from each other in terms of morphology, trophic mode and even habitat, phenotypic and genetic correlations between life‐history stages are ecologically and evolutionarily important. For example, larval size and size at metamorphosis are positively correlated in frogs (Relyea, 2001), marine invertebrates (Trackenberg et al, 2020), and insects (Tammaru, 1998; Tammaru et al, 2004). If traits are correlated across stages, an early‐life experience may determine performance later in the life history (i.e., “carry‐over” or “latent’ effects Pechenik, 2006) for example, juvenile body size and/or growth can be affected by temperature (moths, Galarza et al, 2019; sticklebacks, Kim et al, 2018), food availability (mussels, Phillips, 2002; frogs, Warne & Crespi, 2015), and season length (frogs, Prokic et al, 2021; frogs, Szekely et al, 2020; damselflies, Tuzun & Stoks, 2018;) of the larval stage.…”

Section: Introductionmentioning

confidence: 99%

“…While life-history stages can be quite different from each other in terms of morphology, trophic mode and even habitat, phenotypic and genetic correlations between life-history stages are ecologically and evolutionarily important. For example, larval size and size at metamorphosis are positively correlated in frogs (Relyea, 2001), marine invertebrates (Trackenberg et al, 2020), and insects…”

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Mapping the correlations and gaps in studies of complex life histories

Richardson

Marshall

2023

Ecology and Evolution

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For species with complex life histories, phenotypic correlations between life‐history stages constrain both ecological and evolutionary trajectories. Studies that seek to understand correlations across the life history differ greatly in their experimental approach: some follow individuals (“individual longitudinal”), while others follow cohorts (“cohort longitudinal”). Cohort longitudinal studies risk confounding results through Simpson's Paradox, where correlations observed at the cohort level do not match that of the individual level. Individual longitudinal studies are laborious in comparison, but provide a more reliable test of correlations across life‐history stages. Our understanding of the prevalence, strength, and direction of phenotypic correlations depends on the approaches that we use, but the relative representation of different approaches remains unknown. Using marine invertebrates as a model group, we used a formal, systematic literature map to screen 17,000+ papers studying complex life histories, and characterized the study type (i.e., cohort longitudinal, individual longitudinal, or single stage), as well as other factors. For 3315 experiments from 1716 articles, 67% focused on a single stage, 31% were cohort longitudinal and just 1.7% used an individual longitudinal approach. While life‐history stages have been studied extensively, we suggest that the field prioritize individual longitudinal studies to understand the phenotypic correlations among stages.

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Effects of embryo energy, egg size, and larval food supply on the development of asteroid echinoderms

Cited by 5 publications

References 60 publications

Cannibalism of newly metamorphosed juvenile sea stars

Cannibalism of newly metamorphosed juvenile sea stars

Carryover effects in a sea star: juvenile resource availability does not compensate for a poor larval environment

Mapping the correlations and gaps in studies of complex life histories

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