Waiting in the wings: what can we learn about gene co-option from the diversification of butterfly wing patterns?

Jiggins, Chris D.; Wallbank, Richard W. R.; Hanly, Joseph J.

doi:10.1098/rstb.2015.0485

Cited by 72 publications

(47 citation statements)

References 72 publications

(120 reference statements)

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“…I have reviewed our understanding of wing patterning based on genetic crossing experiments, but have not considered in detail the developmental basis for pattern diversity, which has recently been reviewed elsewhere (Jiggins et al 2017).…”

Section: Discussionmentioning

confidence: 99%

What Can We Learn About Adaptation from the Wing Pattern Genetics of Heliconius Butterflies?

Jiggins

2017

Diversity and Evolution of Butterfly Wing Patterns

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Heliconius wing patterns are an adaptive trait under strong selection in the wild. They are also amenable to genetic studies and have been the focus of evolutionary genetic analysis for many years. Early genetic studies characterised a large number of Mendelian loci with large effects on wing pattern elements in crossing experiments. The recent application of molecular genetic markers has consolidated these studies and led to recognition that a huge range of allelic variation at just a few major loci controls patterns across most of the Heliconius radiation. Some of these loci consist of tightly linked components that control different aspects of the phenotype and can be separated by occasional recombination. More recent quantitative analyses have also identified minor-effect loci that influence the expression of these major loci.Studies of a single locus polymorphism in Heliconius numata provide an example of a 'supergene', in which a single major locus controls segregation of a variable phenotype. This supports 'Turner's Sieve' hypothesis for the evolution of supergenes, whereby sequential linked mutations arise at the same locus. In addition, inversion polymorphisms are associated with wing pattern variation in wild populations, which reduce recombination across the supergene locus. This provides direct evidence that the architecture and organisation of genomes can be shaped by natural selection. There is also evidence that patterns of dominance of the alleles at this locus have also been shaped by natural selection. Mimicry therefore provides a case study of how natural selection shapes the genetic control of adaptive variation.Keywords Mimicry • Heliconius • Convergent evolution • Input-output gene • Developmental pathway • Adaptive radiation A major research effort in evolutionary biology is devoted to determining the molecular changes in DNA sequences that control adaptive phenotypic changes. By identifying the number and identity of genes controlling traits, and the relative

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Section: Discussionmentioning

confidence: 99%

What Can We Learn About Adaptation from the Wing Pattern Genetics of Heliconius Butterflies?

Jiggins

2017

Diversity and Evolution of Butterfly Wing Patterns

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“…Major morphological transitions and innovations are considered first with articles on the origins of animal multicellularity from a classical perspective by Cavalier-Smith [52] and illustrating the impact of genomics by Babonis & Martindale [20] and an article on the evolution of land plants by Harrison [53]; the major transition that created the unique mammalian middle ear is discussed by Tucker [46]. The next section focuses on diversification and modifications of morphology as exemplified by tetrapod limbs by Saxena et al [54], flowers by Pam Soltis and co-workers [55], cranial shape in birds by Abzhanov and co-workers [45] and wing coloration patterns in butterflies by Jiggins et al [56]. The last section considers the relatively recent evolution of genetically determined morphological variation within a single species owing to either natural selection, using as examples, cavefish (article by Krishnan & Rohner [57]) and stickleback (article by Piechel & Marques [58]) or artificial selection, using dogs as an example (article by Elaine Ostrander and co-workers [59]) and ends with the article on developmental plasticity by Xu & Zhang [49].…”

Section: The Organization Of This Theme Issuementioning

confidence: 99%

“…Several articles in the issue provide examples where the evolution of morphological diversity has been found to involve cis-regulatory regions. The stunning coloured patterns of the wings of the different species of Heliconius butterflies provide outstanding examples in which a gene is expressed in a new context and takes on a completely new function [56]. Striking examples of changes in cis-regulatory regions underlying morphological diversity are also found in natural populations of stickleback [58].…”

Section: Recurring Themes (A) Genomic Changes Underlying Origins Of Mmentioning

confidence: 99%

“…There are an increasing number of genome-wide analyses aiming to identify differences in gene expression in developing organs of different organisms, including, for example, comparisons between mouse, chimpanzee and human (reviewed in [66]). Interpretation of positional information may often involve fine-tuning morphogenesis and the spatial coordination of various cell activities such as movement, adhesiveness and proliferation to produce for example the specific shapes of the bird cranium [45] or the bones in vertebrate limb digits [54] or the scale structure in Heliconius butterflies [56]. At first sight, the dissection of how such complex processes are fine-tuned seems very daunting but recent work has shown that morphogenesis can proceed-apparently spontaneously-given the right conditions.…”

Section: (B) Homologymentioning

confidence: 99%

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Perspectives on the history of evo-devo and the contemporary research landscape in the genomics era

Tickle

Urrutia

2017

Phil. Trans. R. Soc. B

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A fundamental question in biology is how the extraordinary range of living organisms arose. In this theme issue, we celebrate how evolutionary studies on the origins of morphological diversity have changed over the past 350 years since the first publication of the Philosophical Transactions of The Royal Society . Current understanding of this topic is enriched by many disciplines, including anatomy, palaeontology, developmental biology, genetics and genomics. Development is central because it is the means by which genetic information of an organism is translated into morphology. The discovery of the genetic basis of development has revealed how changes in form can be inherited, leading to the emergence of the field known as evolutionary developmental biology (evo-devo). Recent approaches include imaging, quantitative morphometrics and, in particular, genomics, which brings a new dimension. Articles in this issue illustrate the contemporary evo-devo field by considering general principles emerging from genomics and how this and other approaches are applied to specific questions about the evolution of major transitions and innovations in morphology, diversification and modification of structures, intraspecific morphological variation and developmental plasticity. Current approaches enable a much broader range of organisms to be studied, thus building a better appreciation of the origins of morphological diversity. This article is part of the themed issue ‘Evo-devo in the genomics era, and the origins of morphological diversity’.

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“…Are there possibilities that the NGP was broken? The wing pattern of a mimicry butterfly, Heliconius sp., might be considered (Jiggins et al 2017) a possible example of such a situation. Under this consideration, several questions are raised: How was the NGP deconstructed in Heliconius butterflies?…”

Section: Macro-evolvability Of the Ngpmentioning

confidence: 99%

Camouflage Variations on a Theme of the Nymphalid Ground Plan

Suzuki

2017

Diversity and Evolution of Butterfly Wing Patterns

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Lepidopteran camouflage patterns offer sophisticated and captivated examples of morphological evolution. Previous studies focused on how and why camouflage patterns are modulated at the microevolutionary level and determined, for instance, the adaptive role of camouflage patterns in avoiding predator attacks. However, less attention has been paid to the macroevolution of camouflage, including the evolutionary paths leading to the origination of leaf mimicry patterns. To understand the deep origins and evolvability of camouflage patterns, a key principle comes from a highly conserved ground plan (termed the nymphalid ground plan; NGP). The ground plan generates a variety of morphological forms, while it maintains its own type. This review introduces several seminal studies that used NGP-known features to reveal the macroevolutionary aspects of lepidopteran camouflage patterns, providing a roadmap for further understanding this biological phenomenon. The following core themes are discussed: (1) how complex camouflage patterns evolved (macroevolutionary pathways), (2) what kind of flexible mechanisms facilitate the origin of such complex patterns (macro-evolvability), and (3) how such complex patterns are tightly integrated through the coupling and uncoupling of ancestral developmental mechanisms (body plan character map). These approaches will provide new research lines for studying the evolution of camouflage patterns and the underlying flexibility of the NGP.

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Waiting in the wings: what can we learn about gene co-option from the diversification of butterfly wing patterns?

Cited by 72 publications

References 72 publications

What Can We Learn About Adaptation from the Wing Pattern Genetics of Heliconius Butterflies?

What Can We Learn About Adaptation from the Wing Pattern Genetics of Heliconius Butterflies?

Perspectives on the history of evo-devo and the contemporary research landscape in the genomics era

Camouflage Variations on a Theme of the Nymphalid Ground Plan

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