Spring weather conditions influence breeding phenology and reproductive success in sympatric bat populations

Linton, Danielle M.; Macdonald, David W.

doi:10.1111/1365-2656.12832

Cited by 45 publications

(69 citation statements)

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“…The dependence of breeding parameters on environmental conditions has previously been shown both in capital breeders (e.g. Hamel et al., , ) and income breeders, including our two study species (Linton & Macdonald, ). Bat populations are likely to be sensitive to weather conditions experienced during the breeding season (Jones et al.…”

Section: Discussionsupporting

confidence: 67%

“…The timing of ovulation and fertilization and the duration of the gestation period are influenced by spring weather conditions (Racey & Swift, ). In our study system, parturition typically occurs during late May to mid‐June in M. daubentonii and 1–2 weeks later in M. nattereri (Linton & Macdonald, ). Juveniles become volant and are weaned at 5–6 weeks of age.…”

Section: Methodsmentioning

confidence: 98%

“…Transition to pregnancy happens in the early spring period. Transition between pregnancy and lactation happens when females give birth in late May/June (Linton & Macdonald, ).…”

Section: Methodsmentioning

confidence: 99%

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Live fast, don't die young: Survival–reproduction trade‐offs in long‐lived income breeders

Culina

Linton

Pradel

et al. 2019

Journal of Animal Ecology

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Trade‐offs between survival and reproduction are at the core of life‐history theory, and essential to understanding the evolution of reproductive tactics as well as population dynamics and stability. Factors influencing these trade‐offs are multiple and often addressed in isolation. Further problems arise as reproductive states and survival in wild populations are estimated based on imperfect and potentially biased observation processes, which might lead to flawed conclusions.In this study, we aimed at elucidating trade‐offs between current reproduction (both pregnancy and lactation), survival and future reproduction, including the specific costs of first reproduction, in long‐lived, income breeding small mammals, an under‐studied group.We developed a novel statistical framework that encapsulates the breeding life cycle of females, and accounts for incomplete information on female pregnancy and lactation and imperfect and biased recapture rates. We applied this framework to longitudinal data on two sympatric, closely related bat species (Myotis daubentonii and M. nattereri).We revealed the existence of several, to our knowledge previously unknown, trends in survival and breeding of these closely related, sympatric species and detected remarkable differences in their age and costs of first reproduction, as well as their survival–reproduction trade‐offs.Our results indicate that species with this type of life history exhibit a mixture of patterns expected for long‐lived and short‐lived animals, and between income and capital breeders. Thus, we call for more studies to be conducted in similar study systems, increasing our ability to fully understand the evolutionary origin and fitness effects of trade‐offs and senescence.

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Section: Discussionsupporting

confidence: 67%

Section: Methodsmentioning

confidence: 98%

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Live fast, don't die young: Survival–reproduction trade‐offs in long‐lived income breeders

Culina

Linton

Pradel

et al. 2019

Journal of Animal Ecology

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“…In comparison with other mammals of a similar body size, hibernating bats are exceptionally long‐lived (Munshi‐South & Wilkinson, ; Wilkinson & Munshi‐South, ). With their low annual reproductive output (Linton & Macdonald, ), bats’ population dynamics are driven mainly by adult mortality (Fleischer et al, ). Consequently, information on survival of hibernating bats which are, as bats in general, of high conservation concern (Habitats Directive 92/43/EEC, 1992) is of particular importance in times of global climate change with an expected increase in temperatures, changed precipitation patterns, and a higher frequency of extreme weather events, which all may affect seasons differently (IPCC, ).…”

Section: Introductionmentioning

confidence: 99%

“…In comparison with other mammals of a similar body size, hibernating bats are exceptionally long-lived (Munshi-South & Wilkinson, 2010;Wilkinson & Munshi-South, 2002). With their low annual reproductive output (Linton & Macdonald, 2018), bats' population dynamics are driven mainly by adult mortality (Fleischer et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Differences in seasonal survival suggest species‐specific reactions to climate change in two sympatric bat species

Reusch

Gampe

Scheuerlein

et al. 2019

Ecology and Evolution

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Long‐lived animals with a low annual reproductive output need a long time to recover from population crashes and are, thus, likely to face high extinction risk, if the current global environmental change will increase mortality rates. To aid conservation of those species, knowledge on the variability of mortality rates is essential. Unfortunately, however, individual‐based multiyear data sets that are required for that have only rarely been collected for free‐ranging long‐lived mammals. Here, we used a five‐year data set comprising activity data of 1,445 RFID‐tagged individuals of two long‐lived temperate zone bat species, Natterer's bats ( Myotis nattereri ) and Daubenton's bats ( Myotis daubentonii ), at their joint hibernaculum. Both species are listed as being of high conservation interest by the European Habitats Directive. Applying mixed‐effects logistic regression, we explored seasonal survival differences in these two species which differ in foraging strategy and phenology. In both species, survival over the first winter of an individual's life was much lower than survival over subsequent winters. Focussing on adults only, seasonal survival patterns were largely consistent with higher winter and lower summer survival but varied in its level across years in both species. Our analyses, furthermore, highlight the importance of species‐specific time periods for survival. Daubenton's bats showed a much stronger difference in survival between the two seasons than Natterer's bats. In one exceptional winter, the population of Natterer's bats crashed, while the survival of Daubenton's bats declined only moderately. While our results confirm the general seasonal survival pattern typical for hibernating mammals with higher winter than summer survival, they also show that this pattern can be reversed under particular conditions. Overall, our study points toward a high importance of specific time periods for population dynamics and suggests species‐, population‐, and age class‐specific responses to global climate change.

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Climate Change and Insectivore Ecology

Vafidis

Smith

Thomas

2019

Encyclopedia of Life Sciences

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The impacts of climate change on natural populations are only beginning to be understood. Although some important changes are already occurring, in the future these are predicted to be more substantial and of greater ecological significance. Insects are a key taxonomic group for understanding the ecological impacts of climate change, due to their responsiveness to environmental change and importance as food for other organisms. Insects are highly sensitive to rising temperatures, changes in rainfall patterns and erratic weather conditions, driving rapid short‐term variations in their abundance, mobility, distribution and phenology. Such variations represent changes in their availability as prey to insectivores, a diverse range of insect‐eating animals that include mammals, fish, amphibians, reptiles and birds. The impacts of these changes on the ecology of insectivores are complex and include population increases or decreases, broad‐scale shifts in distribution, and changes in behavioural traits such as foraging strategy, investment in parental care, and the timing of breeding and migration. Although some insectivorous species are able to respond to – and even benefit from – climate change, those that fail to respond appropriately may struggle to reproduce, disperse and survive, leading to population decline and ultimately, to extinction. Key Concepts Insects are a key taxonomic group in most terrestrial and freshwater ecosystems, providing an important trophic resource for insectivores. Climate change is already causing major shifts in the distribution, phenology, behaviour, abundance and diversity of insect populations, with complex consequences for insectivores. Climate change may benefit some insectivores by increasing food availability and providing more suitable conditions for reproduction. Specific benefits to insectivores include earlier parturition, faster development of juveniles and range expansion. Warmer temperatures may also cause negative impacts on insectivores, through more frequent and intense heat waves and reduced water availability in arid environments. The negative impacts are expected to be more severe for taxa that are less able to disperse or migrate to escape unfavourable conditions, and thus less able to shift range to track the changing conditions. The timing of biological events (phenology) will be affected – primarily by advancing the dates at which insects become active in spring and extending the length of the active season of insects in temperate and boreal regions. Important gaps in our knowledge remain, for example despite the large biomass and species richness of insects in the tropics the impacts of climate change on tropical insectivores remain largely unknown.

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Spring weather conditions influence breeding phenology and reproductive success in sympatric bat populations

Cited by 45 publications

References 48 publications

Live fast, don't die young: Survival–reproduction trade‐offs in long‐lived income breeders

Live fast, don't die young: Survival–reproduction trade‐offs in long‐lived income breeders

Differences in seasonal survival suggest species‐specific reactions to climate change in two sympatric bat species

Climate Change and Insectivore Ecology

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