Abstract
A major challenge in ecology is to understand how populations are affected by increased climate variability. Here, we assessed the effects of observed climate variability on different organismal groups (amphibians, insects, mammals, herbaceous plants and reptiles) by estimating the extent to which interannual variation in the annual population growth rates (CVλ) and the absolute value of the long‐term population growth rate (|log λ|) were associated with short‐term climate variability. We used empirical data (≥ 20 consecutive years of annual abundances) from 59 wild populations in the Northern Hemisphere, and quantified variabilities in population growth rates and climatic conditions (temperature and precipitation in active and inactive seasons) calculated over four‐ and eight‐year sliding time windows. We observed a positive relationship between the variability of growth rate (CVλ) and the variability of temperature in the active season at the shorter timescale only. Moreover, |log λ| was positively associated with the variability of precipitation in the inactive season at both timescales. Otherwise, the direction of the relationships between population dynamics and climate variability (if any) depended largely on the season and organismal group in question. Both CVλ and |log λ| correlated negatively with species' lifespan, indicating general differences in population dynamics between short‐lived and long‐lived species that were not related to climate variability. Our results suggest that although temporal variation in population growth rates and the magnitude of long‐term population growth rates are partially associated with short‐term interannual climate variability, demographic responses to climate fluctuations might still be population‐specific rather than specific to given organismal groups, and driven by other factors than the observed climate variability.
Highlights
Global climate change is likely to lead to concomitant changes in climate means, variability and extremes, resulting in more variable and unpredictable environments for animal and plant populations
For the five organismal groups considered from the Northern Hemisphere, we found some support for our first hypothesis that climate variability translates into temporal variation in the annual population growth rates (CVλ) and, to a lesser extent, into changes in the absolute value of the long-term population growth rate |log λ|
We detected a positive relationship between CVλ and SD of temperature (SDTemp) across populations in the active season, using a four-year time window only
Summary
Global climate change is likely to lead to concomitant changes in climate means, variability and extremes, resulting in more variable and unpredictable environments for animal and plant populations. Precipitation variability, including precipitation extremes, is predicted to increase in the warmer future climate (IPCC 2014, Pendergrass et al 2017) Such interannual climate variability has the potential to translate into fluctuations in the abundances of wild populations through changes in individuals’ vital rates, such as survival, growth and fecundity (van de Pol et al 2010, Genovart et al 2013, Jenouvrier et al 2015). This link between climate variability and population fluctuations is based on the fact that, for many species, population growth rates are sensitive to shifts in the means of vital rates, and in their variance (Doak et al 2005, Morris et al 2008, Vázquez et al 2015). A major aim in ecology is to determine how climate variability can affect populations (Lawson et al 2015)
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