Abstract
The timing of many biological events, including butterfly imago emergence, has advanced under climate change, with the rate of these phenological changes often differing among taxonomic groups. Such inter-taxa variability can lead to phenological mismatches. For example, the timing of a butterfly’s flight period may become misaligned with a key nectar resource, potentially increasing the extinction risk to both species. Here we fit statistical models to field data to determine how the phenology of the marbled white butterfly, Melanargia galathea, and its main nectar source, greater knapweed, Centaurea scabiosa, have changed over recent years at three sites across the UK. We also consider whether topographical diversity affects C. scabiosa’s flowering period. At our focal site, on the species’ northern range limit, we find that over a 13-year period the onset of C. scabiosa’s flowering period has become later whilst there is no obvious trend over time in the onset of M. galathea’s flight period. In recent years, butterflies have started to emerge before their key nectar source was available across most of the site. This raises the intriguing possibility that phenological mismatch could be an unrecognised determinant of range limits for some species. However, the presence of topographical diversity within the site decreased the chance of a mismatch occurring by increasing the length of the flowering period by up to 14 days. We suggest that topographical diversity could be an important component in minimising phenological mismatches under future climate change.
Highlights
Recent climate change has seen the advancement of biological events across many taxonomic groups, including flowering in plants (Fitter and Fitter 2002; Menzel and Fabian 1999), egg laying in birds (Crick et al 1997; Crick and Sparks 1999) and the migration of a wide range of taxonomic groups (Cherry et al 2013; Marra et al 2005)
Model selection suggested that the day of peak abundance, the peak abundance, and the length of the flight period differed among years and sites (Table 1)
There was evidence that the timing and the length of the flowering period differed among years and between study sites (Table 2)
Summary
Recent climate change has seen the advancement of biological events across many taxonomic groups, including flowering in plants (Fitter and Fitter 2002; Menzel and Fabian 1999), egg laying in birds (Crick et al 1997; Crick and Sparks 1999) and the migration of a wide range of taxonomic groups (Cherry et al 2013; Marra et al 2005). Whilst phenological responses to climate change are common, the rates of change can differ across taxonomic groups Differences in the rate or direction of change between interacting species can lead to phenological mismatches, with potential consequences for the abundance, distribution and extinction risk of the interacting species (Fabina et al 2010; Memmott et al.2007; Parmesan 2007; van Asch and Visser 2007). It is necessary to consider the effects of changing conditions on inter-dependent species, including pollinators and their food plants (Visser and Both 2005), when predicting the impacts of climate change and planning appropriate conservation measures. A warming of 1°C could advance the first and the peak appearances of most British butterfly species by 2-10 days (Roy and Sparks 2000), whilst warming of 3°C could advance their appearance by as much as two or three weeks
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