Translating environmental gradients into discontinuous reaction norms via hormone signalling in a polyphenic butterfly

Oostra, Vicencio; Jong, Maaike de; Invergo, Brandon M.; Kesbeke, Fanja; Wende, Franziska; Brakefield, Paul M.; Zwaan, Bas J.

doi:10.1098/rspb.2010.1560

Cited by 82 publications

(159 citation statements)

References 36 publications

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“…Therefore I studied population dependent differences in expression profiles of genes belonging to the circadian clock and the insulin signaling pathway (study III). Also hormones could be likely candidates in driving population dependent divergence, since they sit on key regulatory points in the pathways producing differing phenotypes (Zera 2007, Oostra et al 2010. Additionally, I study whether there are population dependent differences in susceptibility to manipulations of hemolymph JH titers by manipulating them positively or negatively through topical applications (study IV).…”

Section: Aims Of the Thesismentioning

confidence: 99%

Population dependent effects of photoperiod on diapause related physiological traits in an invasive beetle (Leptinotarsa decemlineata)

Lehmann

Lyytinen

Sinisalo

et al. 2012

Journal of Insect Physiology

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Section: Aims Of the Thesismentioning

confidence: 99%

Population dependent effects of photoperiod on diapause related physiological traits in an invasive beetle (Leptinotarsa decemlineata)

Lehmann

Lyytinen

Sinisalo

et al. 2012

Journal of Insect Physiology

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“…Although the genetic, developmental, and hormonal control of seasonal polyphenism are becoming increasingly understood, there are relatively few studies that examine the evolution of the pattern elements of seasonal forms (Rountree and Nijhout 1995;Monteiro et al 2015;Oostra et al 2011). Therefore we asked the following questions: (a) How do wing phenotype elements such as shape and pattern differ between seasonal forms?…”

mentioning

confidence: 99%

Evolutionary Trends in Phenotypic Elements of Seasonal Forms of the Tribe Junoniini (Lepidoptera: Nymphalidae)

Clarke

2017

Diversity and Evolution of Butterfly Wing Patterns

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Seasonal polyphenism in insects is the phenomenon whereby multiple phenotypes can arise from a single genotype depending on environmental conditions during development. Many butterflies have multiple generations per year, and environmentally induced variation in wing color pattern phenotype allows them to develop adaptations to the specific season in which the adults live. Elements of butterfly color patterns are developmentally semiautonomous allowing for detailed developmental and evolutionary changes in the overall color pattern. This developmental flexibility of the color pattern can result in extremely diverse seasonal phenotypes in a single species. In this study, we asked the following questions: (a) How do wing phenotype elements such as shape and pattern vary between seasonal forms? (b) Can this variation be explained phylogenetically? (c) If so, what are the various pattern development strategies used to achieve crypsis in the dry season form? To answer these questions, we used high-resolution images to analyze pattern element variation of 34 seasonally polyphenic butterfly species belonging to the tribe Junoniini (Lepidoptera: Nymphalidae). We show that forewing shape and eyespot size both vary seasonally and that the methods by which phenotype elements change in the dry season forms are different in different clades and may therefore have independent and diverse evolutionary origins.

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“…Titers of 20E measured in the early pupal stage showed small differences between the seasonal form genetic mimics, and 20E injections into the dry season form mimic, which had a natural slower increase of 20E during the pupal stage, showed small (albeit significant) increases in eyespot size toward the phenotype of wet season forms (Koch et al 1996). Later work, however, showed that these 20E titer differences observed between WS and DS form genetic mimics could more readily explain variation in pupal stage duration than eyespot size differences (Oostra et al 2011).…”

Section: Physiological Mechanisms Of Eyespot Plasticitymentioning

confidence: 96%

“…This period shows variation in timing of 20E titers in the seasonal form "genetic mimics" as well as in the actual seasonal forms (Mateus et al 2014;Oostra et al 2011). In particular, titers of 20E are low during the first 24 h (WS) (and 48 h in the DS) after pupation, which is the developmental window believed to be important for eyespot ring differentiation at high temperatures (French and Brakefield 1992;Brunetti et al 2001b).…”

Section: Physiological Mechanisms Of Eyespot Plasticitymentioning

confidence: 99%

Physiology and Evolution of Wing Pattern Plasticity in Bicyclus Butterflies: A Critical Review of the Literature

Monteiro

2017

Diversity and Evolution of Butterfly Wing Patterns

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Phenotypic plasticity refers to the ability of a genotype to develop into different phenotypes in response to environmental cues. In many instances, this ability is an evolved adaptation to enable organisms to adapt to predictable but variable environments in time or space (West-Eberhard MJ, Developmental plasticity and evolution. Oxford Unversity Press, New York, p 794, 2003; Stearns SC, BioScience 39 (7) Here I provide a review of the literature that has explored how environmental variation, in particular seasonal variation, impacts eyespot size in African satyrid butterflies of the genus Bicyclus. Plasticity in eyespot size is undeniably the most conspicuous effect of seasonal variation on the appearance of Bicyclus species, and perhaps because of this, its ecological and physiological bases have been under investigation since 1984 (Brakefield PM, Reitsma N, Ecol Entomol 16:291-303, 1991; Brakefield PM, Larsen TB, Biol J Linn Soc 22:1-12, 1984). Much subsequent research on members of this genus, and in particular on the model species Bicyclus anynana, uncovered, however, many other morphological, behavioral, physiological, and life history traits that are equally impacted by seasons and, in particular, by rearing temperature (Bear A,

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Translating environmental gradients into discontinuous reaction norms via hormone signalling in a polyphenic butterfly

Cited by 82 publications

References 36 publications

Population dependent effects of photoperiod on diapause related physiological traits in an invasive beetle (Leptinotarsa decemlineata)

Population dependent effects of photoperiod on diapause related physiological traits in an invasive beetle (Leptinotarsa decemlineata)

Evolutionary Trends in Phenotypic Elements of Seasonal Forms of the Tribe Junoniini (Lepidoptera: Nymphalidae)

Physiology and Evolution of Wing Pattern Plasticity in Bicyclus Butterflies: A Critical Review of the Literature

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