Your search keyword '"Phillimore, Albert"' showing total 11 results

1. Dissecting the Contributions of Plasticity and Local Adaptation to the Phenology of a Butterfly and Its Host Plants

Author

Phillimore, Albert B., Stålhandske, Sandra, Smithers, Richard J., and Bernard, Rodolphe

Published

2012

2. Predicting a change in the order of spring phenology in temperate forests

Author

Roberts, Adrian M.I., Tansey, Christine, Smithers, Richard J., and Phillimore, Albert B.

Subjects

species interactions, climate change, growing degree‐day, forcing, plasticity, shade, chilling, Primary Research Article, prediction, Primary Research Articles, phenology

Abstract

The rise in spring temperatures over the past half‐century has led to advances in the phenology of many nontropical plants and animals. As species and populations differ in their phenological responses to temperature, an increase in temperatures has the potential to alter timing‐dependent species interactions. One species‐interaction that may be affected is the competition for light in deciduous forests, where early vernal species have a narrow window of opportunity for growth before late spring species cast shade. Here we consider the Marsham phenology time series of first leafing dates of thirteen tree species and flowering dates of one ground flora species, which spans two centuries. The exceptional length of this time series permits a rare comparison of the statistical support for parameter‐rich regression and mechanistic thermal sensitivity phenology models. While mechanistic models perform best in the majority of cases, both they and the regression models provide remarkably consistent insights into the relative sensitivity of each species to forcing and chilling effects. All species are sensitive to spring forcing, but we also find that vernal and northern European species are responsive to cold temperatures in the previous autumn. Whether this sensitivity reflects a chilling requirement or a delaying of dormancy remains to be tested. We then apply the models to projected future temperature data under a fossil fuel intensive emissions scenario and predict that while some species will advance substantially others will advance by less and may even be delayed due to a rise in autumn and winter temperatures. Considering the projected responses of all fourteen species, we anticipate a change in the order of spring events, which may lead to changes in competitive advantage for light with potential implications for the composition of temperate forests.

Published

2015

3. Temporal shifts and temperature sensitivity of avian spring migratory phenology:A phylogenetic meta-analysis

Author

Usui, Takuji, Butchart, Stuart H.M., and Phillimore, Albert

Subjects

migratory phenology, arrival date plasticity, climate change, plasticity, bird migration timing

Abstract

There are wide reports of advances in the timing of spring migration of birds over time and in relation to rising temperatures, though phenological responses vary substantially within and among species. An understanding of the ecological, life-history and geographic variables that predict this intra- and inter-specific variation can guide our projections of how populations and species are likely to respond to future climate change.Here, we conduct phylogenetic meta-analyses addressing slope estimates of the timing of avian spring migration regressed on (i) year and (ii) temperature, representing a total of 413 species across five continents. We take into account slope estimation error and examine phylogenetic, ecological and geographic predictors of intra- and inter-specific variation.We confirm earlier findings that on average birds have significantly advanced their spring migration time by 2.1 days decade-1 and 1.2 days ºC-1. We find that over time and in response to warmer spring conditions short-distance migrants have advanced spring migratory phenology by more than long-distance migrants. We also find that larger bodied species show greater advance over time compared to smaller bodied species. Our results did not reveal any evidence that interspecific variation in migration response is predictable on the basis of species’ habitat or diet. We detected a substantial phylogenetic signal in migration time in response to both year and temperature, suggesting that some of the shifts in migratory phenological response to climate are predictable on the basis of phylogeny. However, we estimate high levels of species and spatial variance relative to phylogenetic variance, which is consistent with plasticity in response to climate evolving fairly rapidly and being more influenced by adaptation to current local climate than by common descent. On average, avian spring migration times have advanced over time and as spring has become warmer. While we are able to identify predictors that explain some of the true among-species variation in response, substantial intra- and inter-specific variation in migratory response remains to be explained.

Published

2017

4. Estimating the ability of plants to plastically track temperature-mediated shifts in the spring phenological optimum

Author

Tansey, Christine, Hadfield, Jarrod, and Phillimore, Albert

Subjects

forcing, plasticity, citizen science, chilling, photoperiod, phenology, space-for-time, local adaptation

Abstract

One consequence of rising spring temperatures is that the optimum timing of key life history events may advance. Where this is the case, a population’s fate may depend on the degree to which it is able to track a change in the optimum timing either via plasticity or via adaptation. Estimating the effect that temperature change will have on optimum timing using standard approaches is logistically challenging, with the result that very few estimates of this important parameter exist. Here we adopt an alternative statistical method that substitutes space for time to estimate the temperature-sensitivity of the optimum timing of 22 plant species based on >200,000 spatiotemporal phenological observations from across the UK. We find that first leafing and flowering dates are sensitive to forcing (spring) temperatures, with optimum timing advancing by 3 days°C-1 and plastic responses to forcing between -3 and -8 days°C-1. Chilling (autumn/winter) temperatures and photoperiod tend to be important cues for species with early and late phenology respectively. For most species we find that plasticity is adaptive and for seven species plasticity is sufficient to track geographic variation in the optimum phenology. For four species we find that plasticity is significantly steeper than the optimum slope that we estimate between forcing temperature and phenology, and we examine possible explanations for this countergradient pattern, including local adaptation.

Published

2017

5. Estimating the ability of plants to plastically track temperature-mediated shifts in the spring phenological optimum.

Author

Tansey, Christine J., Hadfield, Jarrod D., and Phillimore, Albert B.

Subjects

EFFECT of temperature on plants, TEMPERATURE measurements, PHENOTYPIC plasticity, GLOBAL temperature changes, PHENOLOGY

Abstract

One consequence of rising spring temperatures is that the optimum timing of key life-history events may advance. Where this is the case, a population's fate may depend on the degree to which it is able to track a change in the optimum timing either via plasticity or via adaptation. Estimating the effect that temperature change will have on optimum timing using standard approaches is logistically challenging, with the result that very few estimates of this important parameter exist. Here we adopt an alternative statistical method that substitutes space for time to estimate the temperature sensitivity of the optimum timing of 22 plant species based on >200 000 spatiotemporal phenological observations from across the United Kingdom. We find that first leafing and flowering dates are sensitive to forcing (spring) temperatures, with optimum timing advancing by an average of 3 days °C−1 and plastic responses to forcing between −3 and −8 days °C−1. Chilling (autumn/winter) temperatures and photoperiod tend to be important cues for species with early and late phenology, respectively. For most species, we find that plasticity is adaptive, and for seven species, plasticity is sufficient to track geographic variation in the optimum phenology. For four species, we find that plasticity is significantly steeper than the optimum slope that we estimate between forcing temperature and phenology, and we examine possible explanations for this countergradient pattern, including local adaptation. [ABSTRACT FROM AUTHOR]

Published

2017

6. Winter chilling speeds spring development of temperate butterflies.

Author

Stålhandske, Sandra, Gotthard, Karl, Leimar, Olof, and Phillimore, Albert

Subjects

COLD-blooded animals, SPRING

Abstract

Understanding and predicting phenology has become more important with ongoing climate change and has brought about great research efforts in the recent decades. The majority of studies examining spring phenology of insects have focussed on the effects of spring temperatures alone., Here we use citizen-collected observation data to show that winter cold duration, in addition to spring temperature, can affect the spring emergence of butterflies. Using spatial mixed models, we disentangle the effects of climate variables and reveal impacts of both spring and winter conditions for five butterfly species that overwinter as pupae across the UK, with data from 1976 to 2013 and one butterfly species in Sweden, with data from 2001 to 2013., Warmer springs lead to earlier emergence in all species and milder winters lead to statistically significant delays in three of the five investigated species. We also find that the delaying effect of winter warmth has become more pronounced in the last decade, during which time winter durations have become shorter., For one of the studied species, Anthocharis cardamines (orange tip butterfly), we also make use of parameters determined from previous experiments on pupal development to model the spring phenology. Using daily temperatures in the UK and Sweden, we show that recent variation in spring temperature corresponds to 10-15 day changes in emergence time over UK and Sweden, whereas variation in winter duration corresponds to 20 days variation in the south of the UK versus only 3 days in the south of Sweden., In summary, we show that short winters delay phenology. The effect is most prominent in areas with particularly mild winters, emphasising the importance of winter for the response of ectothermic animals to climate change. With climate change, these effects may become even stronger and apply also at higher latitudes. [ABSTRACT FROM AUTHOR]

Published

2017

7. Temporal shifts and temperature sensitivity of avian spring migratory phenology: a phylogenetic meta-analysis.

Author

Usui, Takuji, Butchart, Stuart H. M., Phillimore, Albert B., and Sheldon, Ben

Subjects

BIRD phylogeny, CLIMATE change, CLIMATOLOGY, BIRDS, BIRD migration, EFFECT of temperature on birds

Abstract

There are wide reports of advances in the timing of spring migration of birds over time and in relation to rising temperatures, though phenological responses vary substantially within and among species. An understanding of the ecological, life-history and geographic variables that predict this intra- and interspecific variation can guide our projections of how populations and species are likely to respond to future climate change., Here, we conduct phylogenetic meta-analyses addressing slope estimates of the timing of avian spring migration regressed on (i) year and (ii) temperature, representing a total of 413 species across five continents. We take into account slope estimation error and examine phylogenetic, ecological and geographic predictors of intra- and interspecific variation., We confirm earlier findings that on average birds have significantly advanced their spring migration time by 2·1 days per decade and 1·2 days °C−1. We find that over time and in response to warmer spring conditions, short-distance migrants have advanced spring migratory phenology by more than long-distance migrants. We also find that larger bodied species show greater advance over time compared to smaller bodied species. Our results did not reveal any evidence that interspecific variation in migration response is predictable on the basis of species' habitat or diet., We detected a substantial phylogenetic signal in migration time in response to both year and temperature, suggesting that some of the shifts in migratory phenological response to climate are predictable on the basis of phylogeny. However, we estimate high levels of species and spatial variance relative to phylogenetic variance, which is consistent with plasticity in response to climate evolving fairly rapidly and being more influenced by adaptation to current local climate than by common descent., On average, avian spring migration times have advanced over time and as spring has become warmer. While we are able to identify predictors that explain some of the true among-species variation in response, substantial intra- and interspecific variation in migratory response remains to be explained. [ABSTRACT FROM AUTHOR]

Published

2017

8. Passerines may be sufficiently plastic to track temperature-mediated shifts in optimum lay date.

Author

Phillimore, Albert B., Leech, David I., Pearce‐Higgins, James W., and Hadfield, Jarrod D.

Subjects

*PASSERIFORMES, *CLIMATE change, *BIOLOGY, *PHENOLOGY, *SPATIAL variation

Abstract

Projecting the fates of populations under climate change is one of global change biology's foremost challenges. Here, we seek to identify the contributions that temperature-mediated local adaptation and plasticity make to spatial variation in nesting phenology, a phenotypic trait showing strong responses to warming. We apply a mixed modeling framework to a Britain-wide spatiotemporal dataset comprising >100 000 records of first egg dates from four single-brooded passerine bird species. The average temperature during a specific time period (sliding window) strongly predicts spatiotemporal variation in lay date. All four species exhibit phenological plasticity, advancing lay date by 2-5 days °C−1. The initiation of this sliding window is delayed further north, which may be a response to a photoperiod threshold. Using clinal trends in phenology and temperature, we are able to estimate the temperature sensitivity of selection on lay date ( B), but our estimates are highly sensitive to the temporal position of the sliding window. If the sliding window is of fixed duration with a start date determined by photoperiod, we find B is tracked by phenotypic plasticity. If, instead, we allow the start and duration of the sliding window to change with latitude, we find plasticity does not track B, although in this case, at odds with theoretical expectations, our estimates of B differ across latitude vs. longitude. We argue that a model combining photoperiod and mean temperature is most consistent with current understanding of phenological cues in passerines, the results from which suggest that each species could respond to projected increases in spring temperatures through plasticity alone. However, our estimates of B require further validation. [ABSTRACT FROM AUTHOR]

Published

2016

9. Similarities in butterfly emergence dates among populations suggest local adaptation to climate.

Author

Roy, David B., Oliver, Tom H., Botham, Marc S., Beckmann, Bjorn, Brereton, Tom, Dennis, Roger L. H., Harrower, Colin, Phillimore, Albert B., and Thomas, Jeremy A.

Subjects

BUTTERFLIES, INSECT populations, INSECT adaptation, CLIMATE change, BIOLOGICAL fitness of insects

Abstract

Phenology shifts are the most widely cited examples of the biological impact of climate change, yet there are few assessments of potential effects on the fitness of individual organisms or the persistence of populations. Despite extensive evidence of climate-driven advances in phenological events over recent decades, comparable patterns across species' geographic ranges have seldom been described. Even fewer studies have quantified concurrent spatial gradients and temporal trends between phenology and climate. Here we analyse a large data set (~129 000 phenology measures) over 37 years across the UK to provide the first phylogenetic comparative analysis of the relative roles of plasticity and local adaptation in generating spatial and temporal patterns in butterfly mean flight dates. Although populations of all species exhibit a plastic response to temperature, with adult emergence dates earlier in warmer years by an average of 6.4 days per °C, among-population differences are significantly lower on average, at 4.3 days per °C. Emergence dates of most species are more synchronised over their geographic range than is predicted by their relationship between mean flight date and temperature over time, suggesting local adaptation. Biological traits of species only weakly explained the variation in differences between space-temperature and time-temperature phenological responses, suggesting that multiple mechanisms may operate to maintain local adaptation. As niche models assume constant relationships between occurrence and environmental conditions across a species' entire range, an important implication of the temperature-mediated local adaptation detected here is that populations of insects are much more sensitive to future climate changes than current projections suggest. [ABSTRACT FROM AUTHOR]

Published

2015

10. Inferring local processes from macro-scale phenological pattern: a comparison of two methods.

Author

Phillimore, Albert B., Proios, Konstantinos, O'Mahony, Naiara, Bernard, Rodolphe, Lord, Alexa M., Atkinson, Sian, Smithers, Richard J., and Gibson, David

Subjects

*PHENOLOGY, *TEMPERATURE, *PLANT species, *ANIMAL species, *MACROECOLOGY, *BIOLOGICAL adaptation, *CLIMATE change

Abstract

Understanding the processes responsible for macro-scale spatial and temporal phenological patterns is a critical step in developing predictive phenological models. While phenological responses may involve the integration of multiple environmental cues, the spring phenology of many plant and animal species appears to be especially sensitive to temperature., As a result of the success of citizen science schemes in mobilizing amateur naturalists, for some parts of the world, there now exist extensive data sets of phenological timings, spanning many species, locations and years. In macroecology, two types of models - time windows and growing degree-days - are widely used to predict phenology on the basis of temperature., Here, we compare the performance of the two methods in predicting spatiotemporal variation in the timing of Quercus robur first leafing. The methods agree on the time at which leafing becomes sensitive to temperature and provide weak support for a delay in initiation of thermal sensitivity with increasing latitude due to a day-length requirement. Both methods explain c. 50% of the variation in first dates and identify plasticity, rather than local adaptation, as the major cause of spatial covariation between temperature and phenology. For a 1°C rise in spring temperatures we predict that a plastic response of first leafing will give rise to an advance of about seven days., Synthesis: Time-window and growing degree-day methods provide remarkably congruent insights into the processes underpinning geographic variation in Quercus robur first leafing dates. We find that a spatially invariant plastic response to temperature dominates spatiotemporal phenological variation, which means that it may be reasonable to substitute space for time to project how this species will respond to climate change. This study demonstrates the contribution that top-down macroecological approaches can make to our understanding of the processes that give rise to intraspecific phenological variation. [ABSTRACT FROM AUTHOR]

Published

2013

11. Differences in spawning date between populations of common frog reveal local adaptation.

Author

Phillimore, Albert B., Hadfield, Jarrod D., Jones, Owen R., and Smithers, Richard J.

Subjects

*SPAWNING, *POPULATION dynamics, *PHENOTYPIC plasticity, *RANA temporaria, *ANALYSIS of covariance

Abstract

Phenotypic differences between populations often correlate with climate variables, resulting from a combination of environment- induced plasticity and local adaptation. Species comprising populations that are genetically adapted to local climatic conditions should be more vulnerable to climate change than those comprising phenotypically plastic populations. Assessment of local adaptation generally requires logistically challenging experiments. Here, using a unique approach and a large dataset (>50,000 observations from across Britain), we compare the covariation in temperature and first spawning dates of the common frog (Rana temporaria) across space with that across time. We show that although all populations exhibit a plastic response to temperature, spawning earlier in warmer years, between-population differences in first spawning dates are dominated by local adaptation. Given climate change projections for Britain in 2050-2070, we project that for populations to remain as locally adapted as contemporary populations will require first spawning date to advance by ∼21-39 days but that plasticity alone will only enable an advance of ∼5-9 days. Populations may thus face a microevolutionary and gene flow challenge to advance first spawning date by a further ∼16-30 days over the next 50 years. [ABSTRACT FROM AUTHOR]

Published

2010