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Long-term phenological trends, species accumulation rates, aphid traits and climate: five decades of change in migrating aphids

Bell, James R.; Alderson, Lynda; Izera, Daniela; Kruger, Tracey; Parker, Sue; Pickup, Jon; Shortall, Chris R.; Taylor, Mark S.; Verrier, Paul; Harrington, Richard

Authors

Lynda Alderson

Daniela Izera

Tracey Kruger

Sue Parker

Jon Pickup

Chris R. Shortall

Mark S. Taylor

Paul Verrier

Richard Harrington



Contributors

Bell, James R.
Other

Alderson, Lynda
Other

Izera, Daniela
Other

Kruger, Tracey
Other

Parker, Sue
Other

Pickup, Jon
Other

Shortall, Chris R.
Other

Taylor, Mark S.
Other

Verrier, Paul
Other

Harrington, Richard
Other

Abstract

Aphids represent a significant challenge to food production. The Rothamsted Insect Survey (RIS) runs a network of 12·2-m suction-traps throughout the year to collect migrating aphids. In 2014, the RIS celebrated its 50th anniversary. This paper marks that achievement with an extensive spatiotemporal analysis and the provision of the first British annotated checklist of aphids since 1964.
Our main aim was to elucidate mechanisms that advance aphid phenology under climate change and explain these using life-history traits. We then highlight emerging pests using accumulation patterns.
Linear and nonlinear mixed-effect models estimated the average rate of change per annum and effects of climate on annual counts, first and last flights and length of flight season since 1965. Two climate drivers were used: the accumulated day degrees above 16 °C (ADD16) indicated the potential for migration during the aphid season; the North Atlantic Oscillation (NAO) signalled the severity of the winter before migration took place.
All 55 species studied had earlier first flight trends at rate of β = −0·611 ± SE 0·015 days year−1. Of these species, 49% had earlier last flights, but the average species effect appeared relatively stationary (β = −0·010 ± SE 0·022 days year−1). Most species (85%) showed increasing duration of their flight season (β = 0·336 ± SE 0·026 days year−1), even though only 54% increased their log annual count (β = 0·002 ± SE <0·001 year−1).
The ADD16 and NAO were shown to drive patterns in aphid phenology in a spatiotemporal context. Early in the year when the first aphids were migrating, the effect of the winter NAO was highly significant. Further into the year, ADD16 was a strong predictor. Latitude had a near linear effect on first flights, whereas longitude produced a generally less-clear effect on all responses. Aphids that are anholocyclic (permanently parthenogenetic) or are monoecious (non-host-alternating) were advancing their phenology faster than those that were not.
Climate drives phenology and traits help explain how this takes place biologically. Phenology and trait ecology are critical to understanding the threat posed by emerging pests such as Myzus persicae nicotianae and Aphis fabae cirsiiacanthoidis, as revealed by the species accumulation analysis.

Citation

Bell, J. R., Alderson, L., Izera, D., Kruger, T., Parker, S., Pickup, J., Shortall, C. R., Taylor, M. S., Verrier, P., & Harrington, R. (2015). Long-term phenological trends, species accumulation rates, aphid traits and climate: five decades of change in migrating aphids. Journal of Animal Ecology, 84(1), 21-34. https://doi.org/10.1111/1365-2656.12282

Journal Article Type Article
Acceptance Date Aug 8, 2014
Online Publication Date Aug 14, 2014
Publication Date 2015-01
Deposit Date Feb 9, 2024
Journal Journal of Animal Ecology
Print ISSN 0021-8790
Electronic ISSN 1365-2656
Publisher Wiley
Peer Reviewed Peer Reviewed
Volume 84
Issue 1
Pages 21-34
DOI https://doi.org/10.1111/1365-2656.12282
Public URL https://keele-repository.worktribe.com/output/722539
Publisher URL https://besjournals.onlinelibrary.wiley.com/doi/10.1111/1365-2656.12282


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