Parallel evolution of gene classes, but not genes: Evidence from Hawai'ian honeycreeper populations exposed to avian malaria

Cassin‐Sackett, Loren; Callicrate, Taylor; Fleischer, Robert C.

doi:10.1111/mec.14891

Cited by 29 publications

(26 citation statements)

References 131 publications

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“…In the case of the amphibian study, RNAseq data after experimental infection revealed the role of MHC super-types in eliciting a massive immune response in dying versus surviving leopard frogs, and directional selection in response to fungal infection was implicated in the reduction of MHC diversity in a related species (see Savage et al 2016Savage et al , 2017. For honeycreepers, genomic analyses identified candidate loci that may facilitate survival after malarial infection in the amakihi (see Cassin-Sackett et al 2018). In the special issue we include one example based on the genomic context of susceptibility of the Tasmanian devil to facial tumours (Hohenlohe et al this issue).…”

Section: The Meeting and Discussionmentioning

confidence: 99%

Conservation of adaptive potential and functional diversity

2019

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The conservation of adaptive potential to enable populations and species to respond to environmental change is one of the cornerstones of conservation genetics. To date, however, most work has by necessity focused on neutral markers and demographic questions. Now, with the rapid development of genomic technologies, we have new tools with which to address this essential but poorly understood aspect of conservation strategy. This was the motivation for a meeting on this subject held at Durham University in November 2017 that generated papers for this special issue. In this brief introduction we summarise the presentations and discussions that took place over the course of the meeting, and provide some initial conclusions together with ideas about the way forward.

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Section: The Meeting and Discussionmentioning

confidence: 99%

Conservation of adaptive potential and functional diversity

2019

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“…If knowledge of causal alleles is available, then one must demonstrate that a given site has been under repeated and independent selection in each replicate pair (Lee & Coop, 2017, 2019. Typically, these analyses are undertaken comparing individual replicate pairs (e.g., Roda et al, 2013b;Lamichhaney et al, 2017;Cassin-Sackett et al, 2019), although some studies detect broad, or 'global' outliers by comparing the aggregate of all populations within each ecotype (e.g., Jones et al, 2012;Kautt et al, 2012). In the absence of repeated selection on the same allele or gene, parallelism can be manifested at the functional level, such that different genes under selection participating in the same predicted biological function contribute to the pattern of phenotypic parallelism in a system.…”

Section: Genotypic Parallel Evolutionmentioning

confidence: 99%

“…In the absence of repeated selection on the same allele or gene, parallelism can be manifested at the functional level, such that different genes under selection participating in the same predicted biological function contribute to the pattern of phenotypic parallelism in a system. It is frequently asked whether predicted biological functions are consistently enriched across independent populations (Smith & Rausher, 2011;Kowalko et al, 2013;Roda et al, 2013b;Perreault-Payette et al, 2017;Cassin-Sackett et al, 2019). These analyses can inform us about how genotypically parallel a system is at different scales of divergence, so we can also view genotypic parallel evolution as broad-sense or narrow-sense ( Figure 1).…”

Section: Genotypic Parallel Evolutionmentioning

confidence: 99%

“…These results suggest that adaptation in S. lautus could be rather flexible and redundant at lower levels of organization (the nucleotide site and gene), and only parallel at the level of the biological function. Parallelism at the biological function level might be common within nature (e.g., Smith & Rausher, 2011;Kowalko et al, 2013;Roda et al, 2013b;Laporte et al, 2015;Perreault-Payette et al, 2017;Cassin-Sackett et al, 2019) given that there are fewer biological functions than there are genes or nucleotide sites (Tenaillon et al, 2012;Tiffin & Ross-Ibarra, 2014). In this regard, our study is rather conservative as we have only defined narrow-sense parallelism in function when the function was separately enriched in at least all nine, or eight population pairs.…”

Section: Genotypic Parallelismmentioning

confidence: 99%

“…The evolution of similar phenotypes within the same environment can arise via independent and repeated selection on the same nucleotide site or gene (reviewed in Wood et al, 2005;Christin et al, 2010;Stern, 2013). Similar phenotypes can also arise by selection on entirely different genes, although often from the same functional pathway (e.g., Smith & Rausher, 2011;Kowalko et al, 2013;Roda et al, 2013b;Laporte et al, 2015;Perreault-Payette et al, 2017;Cassin-Sackett et al, 2019). Here, different genetic routes are able to produce similar phenotypic outcomes across populations, even though selection does not act upon the same allele or gene.…”

Section: Introductionmentioning

confidence: 99%

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Phenotypic and genotypic parallel evolution in parapatric ecotypes ofSenecio

James

Wilkinson

Bernal

et al. 2020

Preprint

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7The independent and repeated adaptation of populations to similar environments often results 8 in the evolution of similar forms. This phenomenon creates a strong correlation between 9 phenotype and environment and is referred to as 'parallel evolution.' However, there is 10 ongoing debate as to when we should call a system either phenotypically or genotypically 11 'parallel.' Here, we suggest a novel and simple framework to quantify parallel evolution at 12 the genotypic and phenotypic levels. We apply this framework to coastal ecotypes of an 13 Australian wildflower, Senecio lautus. Our findings show that S. lautus populations 14 inhabiting similar environments have evolved strikingly similar phenotypes. These 15 phenotypes have arisen via mutational changes affecting common biological functions but 16 occurring in different genes. Our work not only provides a common framework to study the 17

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