Functional resurveys and models reveal the interplay of plasticity and evolution of Pierid butterflies in response to recent climate change

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The paper synthesizes two functional resurvey projects of Pierid butterflies, combining field-based measurements of recent thermal environments with mechanistic models and comparisons of historical, current, and hypothetical thermal sensitivity traits in larval feeding and adult wing melanization. It reports that in California Colias, evolution of photoperiod-cued plasticity in wing melanization matches the avoidance of thermal stress during warming springs, whereas Colorado Colias shows no evolved plasticity but does show larval evolution that improves tolerance to warm extremes. The authors also model that Washington Pieris larvae experienced shifts in selection toward higher warm-temperature performance, with a key caveat being that inference relies on linking measured thermal histories to modeled thermal sensitivity rather than directly observing all underlying physiological mechanisms over time. This paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

The extent of contemporary evolution, which is mediated by interactions with plasticity, will be an important determinant of biological responses to climate change. We synthesize two functional resurvey projects that, coupled with mechanistic models, evaluate the interplay of plasticity and evolution of Pierid butterfly larval (thermal sensitivity of feeding) and adult (wing melanization) traits over recent decades. We characterize thermal environments over the resurvey periods, which we interface with developmental and (historical, current, and hypothetical) thermal sensitivity traits to examine the implications of evolutionary changes. We find that the evolution of photoperiod-cued plasticity of wing melanization in California Colias is consistent with avoiding thermal stress during warming springs. Plasticity has not evolved for Colorado Colias populations, which have experienced stronger increases in climate means relative to extremes in recent decades. Evolution in Colorado Colias larvae has improved tolerance to warm extremes, whereas evolution in California Colias larvae has broadened thermal sensitivity consistent with capitalizing on expanded seasonal thermal opportunity. Our models predict that Washington Pieris larvae have experienced shifts in the direction of selection to increase performance at warm temperatures. The research highlights the importance of evaluating changes in climate change exposure and sensitivity to understand interacting organismal responses.
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Abstract The extent of contemporary evolution, which is mediated by interactions with plasticity, will be an important determinant of biological responses to climate change. We synthesize two functional resurvey projects that, coupled with mechanistic models, evaluate the interplay of plasticity and evolution of Pierid butterfly larval (thermal sensitivity of feeding) and adult (wing melanization) traits over recent decades. We characterize thermal environments over the resurvey periods, which we interface with developmental and (historical, current, and hypothetical) thermal sensitivity traits to examine the implications of evolutionary changes. We find that the evolution of photoperiod-cued plasticity of wing melanization in California Colias is consistent with avoiding thermal stress during warming springs. Plasticity has not evolved for Colorado Colias populations, which have experienced stronger increases in climate means relative to extremes in recent decades. Evolution in Colorado Colias larvae has improved tolerance to warm extremes, whereas evolution in California Colias larvae has broadened thermal sensitivity consistent with capitalizing on expanded seasonal thermal opportunity. Our models predict that Washington Pieris larvae have experienced shifts in the direction of selection to increase performance at warm temperatures. The research highlights the importance of evaluating changes in climate change exposure and sensitivity to understand interacting organismal responses. Competing Interest Statement The authors have declared no competing interest.

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