Red fox genome assembly identifies genomic regions associated with tame and aggressive behaviours

Kukekova, Anna V.; Johnson, Jennifer L.; Xiang, Xueyan; Feng, Shaohong; Liu, Shi Ping; Rando, Halie M.; Kharlamova, Anastasiya V.; Herbeck, Yury; Serdyukova, Natalia A.; Xiong, Zijun; Beklemischeva, Violetta; Koepfli, Klaus Peter; Гулевич, Р. Г.; Vladimirova, Anastasiya V.; Hekman, Jessica P.; Perelman, Polina L.; Graphodatsky, Alexander S.; O’Brien, Stephen J.; Wang, Xiaozhu; Clark, Andrew G.; Acland, Gregory M.; Trut, Lyudmila N.; Zhang, Guojie

doi:10.1038/s41559-018-0611-6

Cited by 117 publications

(143 citation statements)

References 123 publications

Supporting

Mentioning

137

Contrasting

Unclassified

Order By: Relevance

“…generation time (corresponding to 1.33 × 10 -9 mutations per year) to calculate the divergence time between retrocopies and corresponding parental genes (T = K s /2λ). Thus, a further phylogenetic analysis, by comparing the other genomes such as the gray wolf and the red fox(Gopalakrishnan et al, 2017;Kukekova et al, 2018), would be helpful to validate dog-specific or Canini-specific candidate retrogenes. Consistent with previous studies in other mammals(Marques et al, 2005;Pan & Zhang, 2009), fish(Fu et al, 2010), and plant(Wang et al, 2006), this result confirmed that retrotransposition could play significant roles in both genome remolding and lineage or species differentiation.Interestingly, we detected 14 intact retrogenes with K s values of 0 which might be indicative of very recent retrogenes.…”

supporting

confidence: 83%

Analysis of new retrogenes provides insight into dog adaptive evolution

Gao

Adetula

et al. 2019

Ecology and Evolution

View full text Add to dashboard Cite

The origin and subsequent evolution of new genes have been considered as an important source of genetic and phenotypic diversity in organisms. Dog breeds show great phenotypic diversity for morphological, physiological, and behavioral traits. However, the contributions of newly originated retrogenes, which provide important genetic bases for dog species differentiation and adaptive traits, are largely unknown. Here, we analyzed the dog genome to identify new RNA‐based duplications and comprehensively investigated their origin, evolution, functions in adaptive traits, and gene movement processes. First, we totally identified 3,025 retrocopies including 476 intact retrogenes, 2,518 retropseudogenes, and 31 chimerical retrogenes. Second, selective pressure along with ESTs expression analysis showed that most of the intact retrogenes were significantly under stronger purifying selection and subjected to more functional constraints when compared to retropseudogenes. Furthermore, a large number of retrocopies and chimerical retrogenes that occurred approximately 22 million years ago implied a burst of retrotransposition in the dog genome after the divergence time between dog and its closely related species red fox. Interestingly, GO and pathway analyses showed that new retrogenes had expanded in glutathione biosynthetic/metabolic process which likely provided important genetic basis for dogs' adaptation to scavenge human waste dumps. Finally, consistent with the results in human and mouse, a significant excess of functional retrogenes movement on and off the X chromosome in the dog confirmed a general pattern of gene movement process in mammals which was likely driven by natural selection or sexual antagonism. Together, these results increase our understanding that new retrogenes can reshape the dog genome and provide further exploration of the molecular mechanisms underlying the dogs' adaptive evolution.

show abstract

supporting

confidence: 83%

Analysis of new retrogenes provides insight into dog adaptive evolution

Gao

Adetula

et al. 2019

Ecology and Evolution

View full text Add to dashboard Cite

show abstract

“…http://dx.doi.org/10.1101/228544 doi: bioRxiv preprint first posted online Dec. 4, 2017; heterozygosity and increased divergence between populations which was identified in the 157 analysis of re-sequenced genomes (34 (35,36). In our exonic SNP data, GRM3 has a C to G change causing a Wnt4 in the fox had more than one SNP with significant allele frequency changes.…”

mentioning

confidence: 93%

Genomic responses to selection for tame/aggressive behaviors in the silver fox (Vulpes vulpes)

Wang

Pipes

Trut

et al. 2017

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Also, empirical pedigree calculations have long been used to understand genetic models of human diseases (13) and are increasingly used in natural populations to understand the genetic basis of quantitative trait variation, fitness consequences of inbreeding, and much more (14). To date, empirical pedigrees and gene dropping approaches have been rarely used to study the temporal spread and loss of individual alleles (15)(16)(17)(18).Here, we combine genomic data with a known population pedigree to describe and predict allele frequency change at many loci in an exhaustively sampled free-living population of Florida Scrub-Jays (Aphelocoma coerulescens) at Archbold Biological Station. Intensive study since 1969 has resulted in lifetime fitness measures for thousands of individuals on an extensive pedigree.…”

mentioning

confidence: 99%

mentioning

confidence: 99%

Allele frequency dynamics in a pedigreed natural population

Chen

Jurić

Cosgrove

et al. 2018

Preprint

Self Cite

View full text Add to dashboard Cite

A central goal of population genetics is to understand how genetic drift, natural selection, and gene flow shape allele frequencies through time. However, the actual processes underlying these changes -variation in individual survival, reproductive success, and movement -are often difficult to quantify. Fully understanding these processes requires the population pedigree, the set of relationships among all individuals in the population through time. Here, we use extensive pedigree and genomic information from a long-studied natural population of Florida Scrub-Jays (Aphelocoma coerulescens) to directly characterize the relative roles of different evolutionary processes in shaping patterns of genetic variation through time. We performed gene dropping simulations to estimate individual genetic contributions to the population and model drift on the known pedigree. We found that observed allele frequency changes are generally well predicted by accounting for the different genetic contributions of founders. Our results show that the genetic contribution of recent immigrants is substantial, with some large allele frequency shifts that otherwise may have been attributed to selection actually due to gene flow. We identified a few SNPs under directional short-term selection after appropriately accounting for gene flow. Using models that account for changes in population size, we partitioned the proportion of variance in allele frequency change through time. Observed allele frequency changes are primarily due to variation in survival and reproductive success, with gene flow making a smaller contribution. This study provides one of the most complete descriptions of short-term evolutionary change in allele frequencies in a natural population to date. An evolving natural population is essentially a vast pedigree, with genetic material transmitted down this pedigree following the laws of Mendelian inheritance (except in rare cases of meiotic drive). We often cannot directly observe the actual processes underlying genetic change. Instead, population genetic studies typically rely on current day patterns of genetic variation -or, if temporal samples are available, the variation in allele frequencies through time -to make inferences about the effects of genetic drift, natural selection, and gene flow in driving evolutionary change. However, these evolutionary mechanisms can be precisely understood in terms of the differential genetic contributions of individuals to the population pedigree over time, combined with the stochasticity of Mendelian segregation.Knowledge of the population pedigree allows us to trace expected individual genetic contributions, i.e., the expected number of copies of a neutral allele contributed by a given individual, to the population in future generations. Individual genetic contributions can be estimated analytically (1-3) or via gene dropping simulations, i.e., simulations of Mendelian transmission of alleles down their pedigree of descendants (4). The long-term genetic contribution of an indi...

show abstract

Red fox genome assembly identifies genomic regions associated with tame and aggressive behaviours

Cited by 117 publications

References 123 publications

Analysis of new retrogenes provides insight into dog adaptive evolution

Analysis of new retrogenes provides insight into dog adaptive evolution

Genomic responses to selection for tame/aggressive behaviors in the silver fox (Vulpes vulpes)

Allele frequency dynamics in a pedigreed natural population

Contact Info

Product

Resources

About