Journal
ECOLOGY
Volume 90, Issue 8, Pages 2223-2232Publisher
WILEY
DOI: 10.1890/08-1498.1
Keywords
East Anglia, UK; flight ability; gene x environment interaction; Glanville fritillary butterfly; Melitaea cinxia; metabolism; migration; mobility; reaction norm; respirometry; single nucleotide polymorphism (SNP); telemetry
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Funding
- Academy of Finland [213457, 211173]
- U.S. National Science Foundation [EF-0412651]
- Biotechnology and Biological Sciences Research Council (BBSRC), United Kingdom
- Academy of Finland (AKA) [211173, 211173] Funding Source: Academy of Finland (AKA)
- BBSRC [BBS/E/C/00004970] Funding Source: UKRI
- Biotechnology and Biological Sciences Research Council [BBS/E/C/00004179, BBS/E/C/00004970] Funding Source: researchfish
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Dispersal is a key life-history trait, especially in species inhabiting fragmented landscapes. The process of dispersal is affected by a suite of morphological, physiological, and behavioral traits, all of which have a more or less complex genetic basis and are affected by the prevailing environmental conditions. To be able to identify genetic and phenotypic effects on dispersal, movements have to be recorded over relevant spatial and temporal scales. We used harmonic radar to track free-flying Glanville fritillary butterflies (Melitaea cinxia) released in the field and reconstructed their flight tracks for several hours. Flight track lengths for individual butterflies ranged from tens of meters to several kilometers. Butterflies were most mobile at midday and in intermediate temperatures. Flight metabolic rate (MR), measured prior to the tracking, explained variation in mobility at all scales studied. One-third of the variation in the distance moved in one hour could be attributed to variation in flight MR. Heterozygous individuals at a single nucleotide polymorphism in the phosphoglucose isomerase (Pgi) gene moved longer distances in the morning and at lower ambient temperatures than homozygous individuals. A similar genotype x temperature interaction was found to affect the metabolic rate. Our results establish connections from molecular variation in a single gene to flight physiology and movement behavior at the landscape level. These results indicate a fitness advantage to the heterozygous genotype in low temperatures and suggest a mechanism by which varying environmental conditions maintain genetic polymorphism in populations.
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