Your search keyword '"Oliver, Tom"' showing total 4 results

1. European butterfly populations vary in sensitivity to weather across their geographical ranges.

Author

Mills, Simon C., Oliver, Tom H., Bradbury, Richard B., Gregory, Richard D., Brereton, Tom, Kühn, Elisabeth, Kuussaari, Mikko, Musche, Martin, Roy, David B., Schmucki, Reto, Stefanescu, Constantí, van Swaay, Chris, Evans, Karl L., and Borregaard, Michael

Subjects

*BUTTERFLIES, *PHENOLOGY, *SPECIES distribution, *POPULATION dynamics

Abstract

Aim The aim was to assess the sensitivity of butterfly population dynamics to variation in weather conditions across their geographical ranges, relative to sensitivity to density dependence, and determine whether sensitivity is greater towards latitudinal range margins. Location Europe. Time period 1980-2014. Major taxa studied Butterflies. Methods We use long-term (35 years) butterfly monitoring data from > 900 sites, ranging from Finland to Spain, grouping sites into 2° latitudinal bands. For 12 univoltine butterfly species with sufficient data from at least four bands, we construct population growth rate models that include density dependence, temperature and precipitation during distinct life-cycle periods, defined to accommodate regional variation in phenology. We use partial R2 values as indicators of butterfly population dynamics' sensitivity to weather and density dependence, and assess how these vary with latitudinal position within a species' distribution. Results Population growth rates appear uniformly sensitive to density dependence across species' geographical distributions, and sensitivity to density dependence is typically greater than sensitivity to weather. Sensitivity to weather is greatest towards range edges, with symmetry in northern and southern parts of the range. This pattern is not driven by variation in the magnitude of weather variability across the range, topographic heterogeneity, latitudinal range extent or phylogeny. Significant weather variables in population growth rate models appear evenly distributed across the life cycle and across temperature and precipitation, with substantial intraspecific variation across the geographical ranges in the associations between population dynamics and specific weather variables. Main conclusions Range-edge populations appear more sensitive to changes in weather than those nearer the centre of species' distributions, but density dependence does not exhibit this pattern. Precipitation is as important as temperature in driving butterfly population dynamics. Intraspecific variation in the form and strength of sensitivity to weather suggests that there may be important geographical variation in populations' responses to climate change. [ABSTRACT FROM AUTHOR]

Published

2017

2. Mechanisms underpinning community stability along a latitudinal gradient: Insights from a niche-based approach.

Author

Evans LC, Melero Y, Schmucki R, Boersch-Supan PH, Brotons L, Fontaine C, Jiguet F, Kuussaari M, Massimino D, Robinson RA, Roy DB, Schweiger O, Settele J, Stefanescu C, van Turnhout CAM, and Oliver TH

Subjects

Animals, Biodiversity, Bayes Theorem, Europe, Ecosystem, Butterflies

Abstract

At large scales, the mechanisms underpinning stability in natural communities may vary in importance due to changes in species composition, mean abundance, and species richness. Here we link species characteristics (niche positions) and community characteristics (richness and abundance) to evaluate the importance of stability mechanisms in 156 butterfly communities monitored across three European countries and spanning five bioclimatic regions. We construct niche-based hierarchical structural Bayesian models to explain first differences in abundance, population stability, and species richness between the countries, and then explore how these factors impact community stability both directly and indirectly (via synchrony and population stability). Species richness was partially explained by the position of a site relative to the niches of the species pool, and species near the centre of their niche had higher average population stability. The differences in mean abundance, population stability, and species richness then influenced how much variation in community stability they explained across the countries. We found, using variance partitioning, that community stability in Finnish communities was most influenced by community abundance, whereas this aspect was unimportant in Spain with species synchrony explaining most variation; the UK was somewhat intermediate with both factors explaining variation. Across all countries, the diversity-stability relationship was indirect with species richness reducing synchrony which increased community stability, with no direct effects of species richness. Our results suggest that in natural communities, biogeographical variation observed in key drivers of stability, such as population abundance and species richness, leads to community stability being limited by different factors and that this can partially be explained due to the niche characteristics of the European butterfly assemblage., (© 2023 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2023

3. Local adaptation to climate anomalies relates to species phylogeny.

Author

Melero Y, Evans LC, Kuussaari M, Schmucki R, Stefanescu C, Roy DB, and Oliver TH

Subjects

Animal Distribution, Animals, Computer Simulation, Europe, Phylogeography, Adaptation, Physiological genetics, Butterflies genetics, Butterflies physiology, Climate, Ecosystem, Phylogeny

Abstract

Climatic anomalies are increasing in intensity and frequency due to rapid rates of global change, leading to increased extinction risk for many species. The impacts of anomalies are likely to vary between species due to different degrees of sensitivity and extents of local adaptation. Here, we used long-term butterfly monitoring data of 143 species across six European bioclimatic regions to show how species' population dynamics have responded to local or globally-calculated climatic anomalies, and how species attributes mediate these responses. Contrary to expectations, degree of apparent local adaptation, estimated from the relative population sensitivity to local versus global anomalies, showed no associations with species mobility or reproductive rate but did contain a strong phylogenetic signal. The existence of phylogenetically-patterned local adaptation to climate has important implications for forecasting species responses to current and future climatic conditions and for developing appropriate conservation practices., (© 2022. The Author(s).)

Published

2022

4. Environmental drivers of annual population fluctuations in a trans-Saharan insect migrant.

Author

Hu G, Stefanescu C, Oliver TH, Roy DB, Brereton T, Van Swaay C, Reynolds DR, and Chapman JW

Subjects

Africa, Northern, Animals, Computer Simulation, Desert Climate, Europe, Geography, Mediterranean Region, Population Density, Population Dynamics, Seasons, Wind, Animal Migration physiology, Butterflies physiology, Environment

Abstract

Many latitudinal insect migrants including agricultural pests, disease vectors, and beneficial species show huge fluctuations in the year-to-year abundance of spring immigrants reaching temperate zones. It is widely believed that this variation is driven by climatic conditions in the winter-breeding regions, but evidence is lacking. We identified the environmental drivers of the annual population dynamics of a cosmopolitan migrant butterfly (the painted lady Vanessa cardui ) using a combination of long-term monitoring and climate and atmospheric data within the western part of its Afro-Palearctic migratory range. Our population models show that a combination of high winter NDVI (normalized difference vegetation index) in the Savanna/Sahel of sub-Saharan Africa, high spring NDVI in the Maghreb of North Africa, and frequent favorably directed tailwinds during migration periods are the three most important drivers of the size of the immigration to western Europe, while our atmospheric trajectory simulations demonstrate regular opportunities for wind-borne trans-Saharan movements. The effects of sub-Saharan vegetative productivity and wind conditions confirm that painted lady populations on either side of the Sahara are linked by regular mass migrations, making this the longest annual insect migration circuit so far known. Our results provide a quantification of the environmental drivers of large annual population fluctuations of an insect migrant and hold much promise for predicting invasions of migrant insect pests, disease vectors, and beneficial species., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021