Idiosyncratic development of sensory structures in brains of diapausing butterfly pupae: implications for information processing

Lehmann, Philipp; Nylin, Sören; Gotthard, Karl; Carlsson, Mikael A.

doi:10.1098/rspb.2017.0897

Cited by 26 publications

(10 citation statements)

References 39 publications

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“…We did not detect pulses, or waves of gene expression at the whole-CNS level that are often associated with metamorphosis (61) and neurogenesis (60), although such patterns may be present in specific neuron subtypes or may have been obscured by interindividual variation within our sampling pools. Gross CNS morphology did not change during 6 mo of diapause, a pattern also observed based on fineresolution imaging of brain substructures over time in diapausing butterfly pupae (62). However, the overall signal of development in the transcriptomic data, for example up-regulation of cell fate proteins associated with cell differentiation, and many transcripts associated with neurogenesis, is most consistent with some sort of developmental progression.…”

Section: Cns Transcriptome Trajectories Show Widespread Evolutionarysupporting

confidence: 59%

“…Such an evolutionary innovation would represent an extreme analog of the well-documented phenomenon of substantial variation in the duration of all individual life cycle stages across Insecta ( 65 ). Indeed, the developmental steps during CNS metamorphosis are indistinguishable between direct developing and diapausing pupae of the butterfly Pieris napi ( 62 ). Moreover, measurable morphogenesis seems to occur during diapause in other insects, particularly gonadal development during adult reproductive diapause ( 26 , 28 ).…”

Section: Discussionmentioning

confidence: 99%

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Genome-wide variation and transcriptional changes in diverse developmental processes underlie the rapid evolution of seasonal adaptation

Dowle

Powell

Doellman

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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Many organisms enter a dormant state in their life cycle to deal with predictable changes in environments over the course of a year. The timing of dormancy is therefore a key seasonal adaptation, and it evolves rapidly with changing environments. We tested the hypothesis that differences in the timing of seasonal activity are driven by differences in the rate of development during diapause in Rhagoletis pomonella, a fly specialized to feed on fruits of seasonally limited host plants. Transcriptomes from the central nervous system across a time series during diapause show consistent and progressive changes in transcripts participating in diverse developmental processes, despite a lack of gross morphological change. Moreover, population genomic analyses suggested that many genes of small effect enriched in developmental functional categories underlie variation in dormancy timing and overlap with gene sets associated with development rate in Drosophila melanogaster. Our transcriptional data also suggested that a recent evolutionary shift from a seasonally late to a seasonally early host plant drove more rapid development during diapause in the early fly population. Moreover, genetic variants that diverged during the evolutionary shift were also enriched in putative cis regulatory regions of genes differentially expressed during diapause development. Overall, our data suggest polygenic variation in the rate of developmental progression during diapause contributes to the evolution of seasonality in R. pomonella. We further discuss patterns that suggest hourglass-like developmental divergence early and late in diapause development and an important role for hub genes in the evolution of transcriptional divergence.

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Section: Cns Transcriptome Trajectories Show Widespread Evolutionarysupporting

confidence: 59%

Section: Discussionmentioning

confidence: 99%

Genome-wide variation and transcriptional changes in diverse developmental processes underlie the rapid evolution of seasonal adaptation

Dowle

Powell

Doellman

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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“…Recently, Lehmann et al. () demonstrated that in the butterfly Pieris napi (L.), the sensory structures linked to vision are well developed in pupae in diapause, unlike other cerebral structures. These results, although preliminary, suggest that these structures may play a role in maintaining and terminating diapause (Lehmann et al., ).…”

Section: Pursuing Studies On Diapausementioning

confidence: 99%

“…In insects, neural mechanisms associated with the detection of photoperiodism could be involved in measuring the amount of time elapsed since the onset of diapause (Saunders, 2012). Recently, Lehmann et al (2017a) demonstrated that in the butterfly Pieris napi (L.), the sensory structures linked to vision are well developed in pupae in diapause, unlike other cerebral structures. These results, although preliminary, suggest that these structures may play a role in maintaining and terminating diapause (Lehmann et al, 2017a).…”

Section: Diapause Expression In a Climate Change Contextmentioning

confidence: 99%

“…Recently, Lehmann et al (2017a) demonstrated that in the butterfly Pieris napi (L.), the sensory structures linked to vision are well developed in pupae in diapause, unlike other cerebral structures. These results, although preliminary, suggest that these structures may play a role in maintaining and terminating diapause (Lehmann et al, 2017a). More in-depth exploring of the role of insulin signaling pathway in diapause regulation would also be necessary to better understand diapause termination mechanisms in insects (Sim & Denlinger, 2013).…”

Section: Diapause Expression In a Climate Change Contextmentioning

confidence: 99%

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Diapause research in insects: historical review and recent work perspectives

Tougeron

2019

Entomologia Exp Applicata

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All organisms on Earth have evolved biological rhythms to face alternation of periods of favorable and unfavorable environmental conditions, at various temporal scales. Diapause is a state of seasonal dormancy adapted to recurring periods of adverse environmental conditions and triggered by biotic and abiotic factors that precede the arrival of these conditions. Several monographs already review the mechanisms of diapause expression in arthropods, from initiation to termination phases. Rather than adding another review to the literature on this topic, this paper primarily aims to link past concepts on seasonal strategies with new perspective on diapause research in arthropods. By focusing on insects, I examine the legacy of diapause history research in terrestrial arthropods since antiquity but mostly over the past 3 centuries, its contribution to the understanding of insect seasonal ecology, and I explore some of the reasons why it is still relevant to study diapause. I highlight some of the topical issues on which current work focuses to better understand and integrate arthropod diapause with their ecology, especially in the climate change context and for the provision of ecosystem services.

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