Environment-mediated morph-linked immune and life-history responses in the aposematic wood tiger moth

1. Warning signals are expected to evolve towards conspicuousness and monomorphism, and thereby hamper the evolution of multiple colour morphs. Here, we test fitness responses to different rearing densities to explain colour polymorphism in aposematic wood tiger moth (Parasemia plantaginis) males. 2...

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Bibliographic Details
Published in:The Journal of animal ecology 2013-05, Vol.82 (3), p.653-662
Main Authors: Nokelainen, Ossi, Lindstedt, Carita, Mappes, Johanna
Format: Article
Language:English
Subjects:
aggregation
Animal and plant ecology
Animal populations
Animal, plant and microbial ecology
Animals
aposematism
Biological and medical sciences
Biological Evolution
Butterflies & moths
colour polymorphism
Ecology
Environment
Evolutionary ecology
Fundamental and applied biological sciences. Psychology
General aspects
Genetic Fitness
immune defence
Immune system
Immunity, Innate
Insecta
Invertebrates
Larva - genetics
Larva - physiology
Life cycles
Male
Melanins - genetics
Melanins - metabolism
Moths - genetics
Moths - growth & development
Moths - immunology
Moths - physiology
Parasemia plantaginis
Pigmentation
Polymorphism
Population Density
Wings, Animal - metabolism
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Summary:1. Warning signals are expected to evolve towards conspicuousness and monomorphism, and thereby hamper the evolution of multiple colour morphs. Here, we test fitness responses to different rearing densities to explain colour polymorphism in aposematic wood tiger moth (Parasemia plantaginis) males. 2. We used larval lines sired by white or yellow adult males selected for small or large melanization patterns of coloration. We reared these selected lines either solitarily (favourable conditions) or in aggregations (challenged conditions), and followed their performance to adult stage. We tested whether differences in larval density affected life-history traits, adult melanin expression, adult morph (white or yellow) survival and immunological responses. 3. We found that the aggregated environment increased mortality of larvae, but decreased larval developmental time and pupa weight. Adult wing melanin pigmentation was dependent on larval melanin expression but not rearing density. We also confirmed that adult wing coloration had a genetic basis (h 2 = 0·42) and was not influenced by larval growth density. Adult yellow males survived better from aggregations in comparison with white males, which may be related to differences in immune defence. White males had better encapsulation ability, whereas yellow males had increased lytic activity of haemolymph in the aggregations. 4. Our main results highlight, that morph-linked immune responses mediated by differential growth density may facilitate the maintenance of colour polymorphism in aposematic species. In nature, risk of diseases and parasites vary spatially and temporally. Therefore, both yellow and white adult morphs can be maintained due to their differential investment in immune defence in heterogeneous environments.
ISSN:0021-8790
1365-2656
DOI:10.1111/1365-2656.12037