The genomic footprint of climate adaptation in <i>Chironomus riparius</i>

Waldvogel, Ann‐Marie; Wieser, Andreas; Schell, Tilman; Patel, Simit; Schmidt, Hanno; Hankeln, Thomas; Feldmeyer, Barbara; Pfenninger, Markus

doi:10.1111/mec.14543

Cited by 61 publications

(100 citation statements)

References 106 publications

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“…Similar to our finding of a dominating effect of mean annual temperature on landscape genetic connectivity, temperature was associated with the highest number of SNPs under putative selection in P. vittatum . Our results are consistent with other studies that have reported (via EAA and outlier tests) a key role of temperature in driving adaptive genetic differentiation in insects (e.g., Dudaniec et al, ; Feng et al, ; Waldvogel et al, ), and in other systems (e.g., trees: Jordan, Hoffmann, Dillon, & Prober, ; vertebrates: Manthey & Moyle, ; marine invertebrates: Xuereb, Kimber, Curtis, Bernatchez, & Fortin, ).…”

Section: Discussionsupporting

confidence: 93%

Detection of environmental and morphological adaptation despite high landscape genetic connectivity in a pest grasshopper (Phaulacridium vittatum)

2019

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Widespread species that exhibit both high gene flow and the capacity to occupy heterogeneous environments make excellent models for examining local selection processes along environmental gradients. Here we evaluate the influence of temperature and landscape variables on genetic connectivity and signatures of local adaptation in Phaulacridium vittatum, a widespread agricultural pest grasshopper, endemic to Australia. With sampling across a 900‐km latitudinal gradient, we genotyped 185 P. vittatum from 19 sites at 11,408 single nucleotide polymorphisms (SNPs) using ddRAD sequencing. Despite high gene flow across sites (pairwise FST = 0.0003–0.08), landscape genetic resistance modelling identified a positive nonlinear effect of mean annual temperature on genetic connectivity. Urban areas and water bodies had a greater influence on genetic distance among sites than pasture, agricultural areas and forest. Together, FST outlier tests and environmental association analysis (EAA) detected 242 unique SNPs under putative selection, with the highest numbers associated with latitude, mean annual temperature and body size. A combination of landscape genetic connectivity analysis together with EAA identified mean annual temperature as a key driver of both neutral gene flow and environmental selection processes. Gene annotation of putatively adaptive SNPs matched with gene functions for olfaction, metabolic detoxification and ultraviolet light shielding. Our results imply that this widespread agricultural pest has the potential to spread and adapt under shifting temperature regimes and land cover change.

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Section: Discussionsupporting

confidence: 93%

Detection of environmental and morphological adaptation despite high landscape genetic connectivity in a pest grasshopper (Phaulacridium vittatum)

2019

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“…This temperature is just below the upper sustainable temperature limit of the species, as inferred from previous experiments and presented a priori a substantial selection pressure (Foucault, Wieser, Waldvogel, Feldmeyer, et al, ; Nemec et al, ). This may be particularly true for this rather cold adapted, Northern population (Waldvogel et al, ). Apart from the experimental temperatures, rearing conditions regarding food availability, air humidity, etc., were a priori kept as selectively lenient as possible.…”

Section: Methodsmentioning

confidence: 95%

“…Whole genome pool‐sequencing was carried out on an Illumina MySeq with 250 bp paired end reads. Reads were trimmed using the wrapper tool autotrim (Waldvogel et al, ) that integrates trimmomatic (Bolger, Lohse, & Usadel, ) for trimming and fastQC (Andrews, ) for quality control. The trimmed reads were then mapped on the latest C. riparius reference genome (Schmidt et al, ) using the BWA mem algorithm (Li & Durbin, ).…”

Section: Methodsmentioning

confidence: 99%

“…Nemec, Patel, Nowak, and Pfenninger () showed that population growth rate (PGR, a composite fitness measure of several phenotypic fitness traits, see below) varied among five natural C. riparius populations sampled across a climatic gradient in Europe when subjected to three temperature treatments in a full factorial common garden experiment. In a recent study, it has been shown that populations of C. riparius from across the species range are indeed adapted to their locale climate and that the genetic basis of this adaptation involves many loci across the genome (Waldvogel et al, ). Additionally, an experimental evolution indicated that such an adaptive phenotypic reaction to temperature treatments may be extremely rapid in this species (Foucault, Wieser, Waldvogel, Feldmeyer, & Pfenninger, ).…”

Section: Introductionmentioning

confidence: 99%

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Genomic processes underlying rapid adaptation of a natural Chironomus riparius population to unintendedly applied experimental selection pressures

Pfenninger

Foucault

2020

Molecular Ecology

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Evolve and Resquence (E&R) studies are a useful tool to study genomic processes during rapid adaptation, e.g., in the framework of adaptive responses to global climate change. We applied different thermal regimes to a natural Chironomus riparius (Diptera) population in an E&R framework to infer its evolutionary potential for rapid thermal adaptation. We exposed two replicates to three temperatures each (14°C, 20°C and 26°C) for more than two years, the experiment thus lasting 22, 44 or 65 generations, respectively. The two higher temperatures presented a priori moderate, respectively strong selection pressures. Life‐cycle fitness tests revealed no appreciable adaptation to thermal regimes but a common adaptation of all six replicates probably due to the rearing conditions, presumably increased larval density and water quality. Genomic analyses showed a strong, genome‐wide selective response in all replicates (mean s of selected SNPs = 0.305). This genomic response was significantly similar at all genomic levels among all replicates (SNPs, 10 kb windows, genes, exons, regions of elevated allele frequency change [REA]). The intersections among the replicates exposed to the same temperature were either insignificant or underrepresented. This confirmed a selective response to identical selection pressure(s), however, not to thermal regime. Genes closest to the SNP with the highest selection coefficient per REA were enriched for GO terms related to ion transport, regulation of transcription and signal transduction, which supported the presumed acting selection pressures. Our study showed the evolutionary potential for rapid adaptation by genome‐wide and probably polygenic selection on standing genetic variation in C. riparius. However, because of the impossibility to accurately predict the acting selective regime in evolutionary experiments, we discuss the sobering perspectives for inferring the evolutionary potential of natural populations with this approach.

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“…Moreover, the integration of experimental investigations with genetics and genomics is possible since the publication of a high‐quality draft genome as reference sequence (Oppold et al, ). Furthermore, important population genetic parameters have been studied, such as the species‐specific spontaneous mutation rate (Oppold & Pfenninger, ), its genomic and transcriptomic basis of niche differentiation (Schmidt, Greshake, Feldmeyer, Hankeln, & Pfenninger, ), demography in European populations (Waldvogel et al, ), and its genomic architecture (Kraemer & Schmidt, ; Oppold et al, ; Zampicinini, Blinov, Cervella, Guryev, & Sella, ). The possibility to easily obtain natural populations from a large distribution range, its capacity to cope with laboratory culture conditions and the availability of genetic and genomic resources makes C. riparius a suitable study organism for many disciplines and research areas.…”

Section: Introductionmentioning

confidence: 99%

Establishing laboratory cultures and performing ecological and evolutionary experiments with the emerging model species Chironomus riparius

Foucault

Wieser

Waldvogel

et al. 2019

J Applied Entomology

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Chironomus riparius is a well‐established model organism in various fields such as ecotoxicology and ecology, and therefore, environmental preferences, ecological interactions and metabolic traits are well‐studied. With the recent publication of a high‐quality draft genome, as well as different population genetic parameters such as mutation and recombination rate, the species can be used as an alternative to the Drosophila models in experimental population genomics or molecular ecology. To facilitate access to this promising experimental model species for a wider range of researchers, we describe experimental methods to first create and sustain long‐term cultures of C. riparius and then use them to perform repeatable and comparable experiments for various research questions.

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The genomic footprint of climate adaptation in Chironomus riparius

Cited by 61 publications

References 106 publications

Detection of environmental and morphological adaptation despite high landscape genetic connectivity in a pest grasshopper (Phaulacridium vittatum)

Detection of environmental and morphological adaptation despite high landscape genetic connectivity in a pest grasshopper (Phaulacridium vittatum)

Genomic processes underlying rapid adaptation of a natural Chironomus riparius population to unintendedly applied experimental selection pressures

Establishing laboratory cultures and performing ecological and evolutionary experiments with the emerging model species Chironomus riparius

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