Phenological responsiveness to climate differs among four species of <i>Quercus</i> in North America

Gerst, Katharine L.; Rossington, Natalie L.; Mazer, Susan J.

doi:10.1111/1365-2745.12774

Cited by 52 publications

(42 citation statements)

References 74 publications

(132 reference statements)

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“…First event dates are also a poor metric for phenophases that do not have a single uninterrupted period, but stop and restart, such as plants that flower sporadically (Gerst et al. ). Peak event times (e.g., mating displays for mammals, calling times for frogs, peak flowering times for plants) should be more comparable than disparate metrics such as first flowering for plants vs peak spawning activity for fish, although even peaks will not always be comparable across phenologies at different levels of biological organization.…”

Section: Future Directions and Conclusionmentioning

confidence: 99%

Phenology as a process rather than an event: from individual reaction norms to community metrics

Inouye

Ehrlén

Underwood

2019

Ecological Monographs

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Measures of the seasonal timing of biological events are key to addressing questions about how phenology evolves, modifies species interactions, and mediates biological responses to climate change. Phenology is often characterized in terms of discrete events, such as a date of first flowering or arrival of first migrants. We discuss how phenological events that are typically measured at the population or species level arise from distributions of phenological events across seasons, and from norms of reaction of these phenological events across environments. We argue that individual variation in phenological distributions and reaction norms has important implications for how we should collect, analyze, and interpret phenological information. Regarding phenology as a reaction norm rather than one year's specific values implies that selection acts on the phenologies that an individual expresses over its lifetime. To understand how climate change is likely to influence phenology, we need to consider not only plastic responses along the reaction norm but changes in the reaction norm itself. We show that when individuals vary in their reaction norms, correlations between reaction norm elevation and slope make first events particularly poor estimators of population sensitivity to climate change, and variation in slopes can obscure the pattern of selection on phenology. We also show that knowing the shape of the distribution of phenological events across the season is important for predicting biologically important phenological mismatches with climate change. Last, because phenological events are parts of a continuous developmental process, we suggest that the approach of measuring phenology by recording developmental stages of individuals in a population at a single point in time should be used more widely. We conclude that failure to account for phenological distributions and reaction norms may lead to overinterpretation of metrics based on single events, such as commonly recorded first event dates, and may confound meta‐analyses that use a range of metrics. Rather than prescribing a single universal approach to studying phenology, we point out limitations of inferences based on single metrics and encourage work that considers the multivariate nature of phenology and more tightly links data collection and analyses with biological hypotheses.

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Section: Future Directions and Conclusionmentioning

confidence: 99%

Phenology as a process rather than an event: from individual reaction norms to community metrics

Inouye

Ehrlén

Underwood

2019

Ecological Monographs

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“…Plant phenology is strongly driven by climate, and temperature is the most important driver of plant phenology (Lieth, 1974). Climate warming profoundly influences plant phenology (Cleland, Chiariello, Loarie, Mooney, & Field, 2006;Gerst, Rossington, & Mazer, 2017;Godoy et al, 2009;Hovenden, Wills, Schoor, Williams, & Newton, 2008;Novy et al, 2013), and invasive plants track climate warming more closely than native plants (Wolkovich et al, 2013). Aside from climate warming, atmospheric nitrogen (N) deposition is also among the key components of global change (Galloway et al, 2004).…”

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confidence: 99%

Warming delays the phenological sequences of an autumn‐flowering invader

Peng

Yang

Zhou

et al. 2018

Ecology and Evolution

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Phenology can play an important role in driving plant invasions; however, little is known about how climate warming, nitrogen (N) deposition, and invasion stages influence the phenological sequences of autumn‐flowering invaders in a subtropical climate. Accordingly, we conducted an experiment to address the effects of experimental warming, N‐addition, and community types on the first inflorescence buds, flowering, seed‐setting, and dieback of invasive Solidago canadensis. Warming delayed the onset of first inflorescence buds, flowering, seed‐setting, and dieback; N‐addition did not influence these four phenophases; community types influenced the onset of first seed‐setting but not the other phenological phases. Seed‐setting was more sensitive to experimental manipulations than the other phenophases. The onset of first inflorescence buds, flowering, and seed‐setting was marginally or significantly correlated with ramet height but not ramet numbers. Our results suggest that future climate warming might delay the phenological sequences of autumn‐flowering invaders and some phenophases can shift with invasion stages.

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“…However, earlier leaf out or flowering is not consistent across plant classes, related sub-species, or within a single species. For example, trees have not advanced their phenology as much as other plant groups and some flowering forbs vary within genus (Gerst, Rossington, & Mazer, 2017;Root et al, 2003). Flowering among related species of plants may respond differently, with one subspecies blooming earlier and another remaining unchanged as demonstrated in Mertensia and Solidago (Hafdahl & Craig, 2014;Miller-Rushing & Inouye, 2009).…”

Section: Introductionmentioning

confidence: 99%

Evidence of an extreme weather‐induced phenological mismatch and a local extirpation of the endangered Karner blue butterfly

Patterson

Grundel

Dzurisin

et al. 2019

Conservat Sci and Prac

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In 2011, an experiment was undertaken to examine spring synchrony between the endangered Karner blue butterfly (Lycaeides melissa samuelis) (Kbb) and its obligate host plant, wild blue lupine (Lupinus perennis) at Indiana Dunes National Lakeshore (INDU), where the southernmost population of Kbb occurred at the time of this study. From 2012 to 2014, field‐placed Kbb eggs were observed for larvae hatching in conjunction with observations of lupine emergence in oak savanna habitat. In 2012, 61% of Kbb hatched when <5% of lupine had emerged due to an extreme early spring event as compared to subsequent years where temporal overlap was >15% between Kbb and lupine. Laboratory experiments testing the sensitivity of Kbb hatching to warm temperatures during the winter of 2011–2012 confirmed that Kbb eggs were susceptible to temperature‐induced hatching. In the summer of 2012, second generation Kbb larvae feeding on sun‐exposed lupine had higher mortality due to the heat and drought conditions that resulted in earlier plant senescence. Following 2012, Kbb were no longer observed at INDU. This observation illustrates the pressing need for adaptive management strategies that account for extreme weather events brought on by climate change.

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Phenological responsiveness to climate differs among four species of Quercus in North America

Cited by 52 publications

References 74 publications

Phenology as a process rather than an event: from individual reaction norms to community metrics

Phenology as a process rather than an event: from individual reaction norms to community metrics

Warming delays the phenological sequences of an autumn‐flowering invader

Evidence of an extreme weather‐induced phenological mismatch and a local extirpation of the endangered Karner blue butterfly

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