Plasticity in resource choice: a time-limited butterfly prioritizes apparency over quality

Steck, Meredith; Zambre, Amod; Snell‐Rood, Emilie C.

doi:10.1016/j.anbehav.2022.11.012

Cited by 2 publications

(1 citation statement)

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“…Although tyrosine is not an abundant amino acid, relatively speaking, in Pieris hostplants it and other amino acids do vary among species and cultivars, seasonally and even among tissue types (Gomes & Rosa, 2001 ; Kumar et al., 2017 ; Oliveira et al., 2008 ; Shawon et al., 2018 ) and fitness proxies such as larval growth rates and adult size, and even feeding behaviors and resource assimilation strategies, can be affected by host plant attributes (Chen et al., 2004 ; Hwang et al., 2008 ; Slansky & Feeny, 1977 ). Furthermore, hostplant choice behaviors in female cabbage white butterflies can be quite sophisticated (Jaumann & Snell‐Rood, 2017 ; Steck et al., 2023 ). Thus despite being crucifer specialists (i.e.…”

Section: Discussionmentioning

confidence: 99%

Resource‐based trade‐offs and the adaptive significance of seasonal plasticity in butterfly wing melanism

Stoehr,

Glaenzer,

VanWanzeele

et al. 2024

Ecology and Evolution

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Phenotypic plasticity is the ability of an organism to alter its phenotype in response to environmental cues. This can be adaptive if the cues are reliable predictors of impending conditions and the alterations enhance the organism's ability to capitalize on those conditions. However, since traits do not exist in isolation but as part of larger interdependent systems of traits (phenotypic integration), trade‐offs between correlated plastic traits can make phenotypic plasticity non‐ or maladaptive. We examine this problem in the seasonally plastic wing melanism of a pierid (Order Lepidoptera, Family Pieridae) butterfly, Pieris rapae L. Several wing pattern traits are more melanized in colder than in warmer seasons, resulting in effective thermoregulation through solar absorption. However, other wing pattern traits, the spots, are less melanized during colder seasons than in warmer seasons. Although spot plasticity may be adaptive, reduced melanism of these spots could also be explained by resource‐based trade‐offs. Theory predicts that traits involved in resource‐based trade‐offs will be positively correlated when variation among individuals in resource acquisition is greater than variation among individuals in resource allocation strategies, and negatively correlated when variation in allocation is greater than variation in acquisition. Using data from both field studies and laboratory studies that manipulate dietary tyrosine, a melanin precursor, we show that when allocation to thermoregulatory melanism (ventral hindwing, and basal dorsal fore‐ and hindwing “shading”) varies substantially this trait is negatively correlated with spot melanism. However, when there is less variation in allocation to thermoregulatory melanism we find these traits to be positively correlated; these findings are consistent with the resource‐based trade‐off hypothesis, which may provide a non‐ or maladaptive hypothesis to explain spot plasticity. We also show that increased dietary tyrosine results in increased spot melanism under some conditions, supporting the more general idea that melanism may involve resource‐based costs.

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