Abstract
Habitat loss and climate change are rapidly converting natural habitats and thereby increasing the significance of dispersal capacity for vulnerable species. Flight is necessary for dispersal in many insects, and differences in dispersal capacity may reflect dissimilarities in flight muscle aerobic capacity. In a large metapopulation of the Glanville fritillary butterfly in the Åland Islands in Finland, adults disperse frequently between small local populations. Individuals found in newly established populations have higher flight metabolic rates and field-measured dispersal distances than butterflies in old populations. To assess possible differences in flight muscle aerobic capacity among Glanville fritillary populations, enzyme activities and tissue concentrations of the mitochondrial protein Cytochrome-c Oxidase (CytOx) were measured and compared with four other species of Nymphalid butterflies. Flight muscle structure and mitochondrial density were also examined in the Glanville fritillary and a long-distance migrant, the red admiral. Glanville fritillaries from new populations had significantly higher aerobic capacities than individuals from old populations. Comparing the different species, strong-flying butterfly species had higher flight muscle CytOx content and enzymatic activity than short-distance fliers, and mitochondria were larger and more numerous in the flight muscle of the red admiral than the Glanville fritillary. These results suggest that superior dispersal capacity of butterflies in new populations of the Glanville fritillary is due in part to greater aerobic capacity, though this species has a low aerobic capacity in general when compared with known strong fliers. Low aerobic capacity may limit dispersal ability of the Glanville fritillary.
Highlights
Flight is critically important for the fitness of most insects due to its role in reproduction [1,2,3] and dispersal [4,5,6,7]
Variation among Glanville fritillary populations in aerobic capacity Mitochondrial CytOx activity was significantly higher in Glanville fritillaries originating from newly-established populations (11.260.4 mmol O2 per min per mg soluble protein; n = 43) than from old populations (9.160.4 mmol O2 per min per mg soluble protein, n = 28; Fig. 2A; one-way ANOVA, new versus old populations; F1,69 = 5.9; P = 0.016)
Heterozygous individuals for single nucleotide polymorphism (SNP) Pgi_111 (AC) were more frequent in new than old populations (20 versus 3 individuals), whereas there was no difference in the numbers of the AA homozygotes (21 versus 25; Pearson x2 = 12.2, P = 0.002), as expected based on previous studies [4,56]
Summary
Flight is critically important for the fitness of most insects due to its role in reproduction [1,2,3] and dispersal [4,5,6,7]. Bats, and several species of insects, flight performance is highly correlated with indicators of the aerobic capacity of flight muscle, such as mitochondrial respiration, enzyme activities, and mitochondrial size and concentration [13,14,15,16,17,18]. These biochemical indicators are invaluable for assessing aerobic capacity of species that cannot be studied in a laboratory setting, making them useful metrics for studying dispersal ability in nature
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