Development of a genotype‐by‐sequencing immunogenetic assay as exemplified by screening for variation in red fox with and without endemic rabies exposure

Donaldson, Michael E.; Rico, Yessica; Hueffer, Karsten; Rando, Halie M.; Kukekova, Anna V.; Kyle, Christopher J.

doi:10.1002/ece3.3583

Cited by 6 publications

(20 citation statements)

References 92 publications

(142 reference statements)

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“…Adaptation and response to selection in the red fox is therefore of interest not only to wildlife ecology, but also fields including behavioral and evolutionary genetics. The draft red fox genome assembly, which is currently in version 2.2 and known as vv2.2, has already proven valuable for studies of fox behavioral genetics [ 12 ], immunological adaptation [ 13 ], and population diversity [ 14 ].…”

Section: Introductionmentioning

confidence: 99%

Construction of Red Fox Chromosomal Fragments from the Short-Read Genome Assembly

Rando

Farré

Robson

et al. 2018

Genes

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The genome of a red fox (Vulpes vulpes) was recently sequenced and assembled using next-generation sequencing (NGS). The assembly is of high quality, with 94X coverage and a scaffold N50 of 11.8 Mbp, but is split into 676,878 scaffolds, some of which are likely to contain assembly errors. Fragmentation and misassembly hinder accurate gene prediction and downstream analysis such as the identification of loci under selection. Therefore, assembly of the genome into chromosome-scale fragments was an important step towards developing this genomic model. Scaffolds from the assembly were aligned to the dog reference genome and compared to the alignment of an outgroup genome (cat) against the dog to identify syntenic sequences among species. The program Reference-Assisted Chromosome Assembly (RACA) then integrated the comparative alignment with the mapping of the raw sequencing reads generated during assembly against the fox scaffolds. The 128 sequence fragments RACA assembled were compared to the fox meiotic linkage map to guide the construction of 40 chromosomal fragments. This computational approach to assembly was facilitated by prior research in comparative mammalian genomics, and the continued improvement of the red fox genome can in turn offer insight into canid and carnivore chromosome evolution. This assembly is also necessary for advancing genetic research in foxes and other canids.

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Section: Introductionmentioning

confidence: 99%

Construction of Red Fox Chromosomal Fragments from the Short-Read Genome Assembly

Rando

Farré

Robson

et al. 2018

Genes

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“…While the neutral genetic structure of host species can be used to infer relationships with disease maintenance and spread [ 37 , 51 , 52 ], understanding deeper co-evolutionary patterns between hosts and pathogens requires insight into the variation that exists in genes that interact with the reciprocal selective pressures. To this end and building on the data from Goldsmith et al [ 37 ], Donaldson et al [ 53 ] developed a GBS assay to specifically target 116 immunogenetically relevant regions of the red fox genome. Donaldson et al [ 53 ], tested the assay on a small sample size of red foxes from regions with different AR variants and regions without rabies and found 15 F ST -based outlier SNPs that divided the samples into two genetic clusters corresponding to regions with and without AR, similar to the results by Goldsmith et al [ 37 ].…”

Section: Introductionmentioning

confidence: 99%

“…To this end and building on the data from Goldsmith et al [ 37 ], Donaldson et al [ 53 ] developed a GBS assay to specifically target 116 immunogenetically relevant regions of the red fox genome. Donaldson et al [ 53 ], tested the assay on a small sample size of red foxes from regions with different AR variants and regions without rabies and found 15 F ST -based outlier SNPs that divided the samples into two genetic clusters corresponding to regions with and without AR, similar to the results by Goldsmith et al [ 37 ]. In both studies, inferences on the relationship between host genetic clustering and rabies distributions were undermined by either small sample sizes or assessments on regions of the genome unlikely to show patterns of selection from infectious diseases.…”

Section: Introductionmentioning

confidence: 99%

“…In both studies, inferences on the relationship between host genetic clustering and rabies distributions were undermined by either small sample sizes or assessments on regions of the genome unlikely to show patterns of selection from infectious diseases. However, in these studies, red fox genetic structure was more pronounced in the data from the immunogenetic assay [ 53 ] relative to the microsatellite data [ 37 ], suggesting that gene flow was not solely responsible for the observed patterns of genetic structure.…”

Section: Introductionmentioning

confidence: 99%

“…Herein, we build on the work of Goldsmith et al [ 37 ] and Donaldson et al [ 53 ], using the same immunogenetic GBS assay, by increasing the number of red fox sampled per location to better assess frequency differences of genetic variants among the sampled locations and to gain further insight into the role of red fox in AR maintenance in Alaska. We also aimed to put the interrelationships of AR and red foxes in Alaska into context by including red fox from Ontario (Canada) as a potential outgroup.…”

Section: Introductionmentioning

confidence: 99%

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The role of a mechanistic host in maintaining arctic rabies variant distributions: Assessment of functional genetic diversity in Alaskan red fox (Vulpes vulpes)

et al. 2021

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Populations are exposed to different types and strains of pathogens across heterogeneous landscapes, where local interactions between host and pathogen may present reciprocal selective forces leading to correlated patterns of spatial genetic structure. Understanding these coevolutionary patterns provides insight into mechanisms of disease spread and maintenance. Arctic rabies (AR) is a lethal disease with viral variants that occupy distinct geographic distributions across North America and Europe. Red fox (Vulpes vulpes) are a highly susceptible AR host, whose range overlaps both geographically distinct AR strains and regions where AR is absent. It is unclear if genetic structure exists among red fox populations relative to the presence/absence of AR or the spatial distribution of AR variants. Acquiring these data may enhance our understanding of the role of red fox in AR maintenance/spread and inform disease control strategies. Using a genotyping-by-sequencing assay targeting 116 genomic regions of immunogenetic relevance, we screened for sequence variation among red fox populations from Alaska and an outgroup from Ontario, including areas with different AR variants, and regions where the disease was absent. Presumed neutral SNP data from the assay found negligible levels of neutral genetic structure among Alaskan populations. The immunogenetically-associated data identified 30 outlier SNPs supporting weak to moderate genetic structure between regions with and without AR in Alaska. The outliers included SNPs with the potential to cause missense mutations within several toll-like receptor genes that have been associated with AR outcome. In contrast, there was a lack of genetic structure between regions with different AR variants. Combined, we interpret these data to suggest red fox populations respond differently to the presence of AR, but not AR variants. This research increases our understanding of AR dynamics in the Arctic, where host/disease patterns are undergoing flux in a rapidly changing Arctic landscape, including the continued northward expansion of red fox into regions previously predominated by the arctic fox (Vulpes lagopus).

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Passive Immunity in Rabies Prophylaxis

Rupprecht¹,

Yager

Newhouse

2020

Rabies and Rabies Vaccines

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Development of a genotype‐by‐sequencing immunogenetic assay as exemplified by screening for variation in red fox with and without endemic rabies exposure

Cited by 6 publications

References 92 publications

Construction of Red Fox Chromosomal Fragments from the Short-Read Genome Assembly

Construction of Red Fox Chromosomal Fragments from the Short-Read Genome Assembly

The role of a mechanistic host in maintaining arctic rabies variant distributions: Assessment of functional genetic diversity in Alaskan red fox (Vulpes vulpes)

Passive Immunity in Rabies Prophylaxis

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