Signature of Balancing Selection at the MC1R Gene in Kunming Dog Populations

Guo-dong Wang; Lu-guang Cheng; Ruo-xi Fan; David M. Irwin; Shu-sheng Tang; Jian-guo Peng; Ya-ping Zhang

doi:10.1371/journal.pone.0055469

Abstract

Coat color in dog breeds is an excellent character for revealing the power of artificial selection, as it is extremely diverse and likely the result of recent domestication. Coat color is generated by melanocytes, which synthesize pheomelanin (a red or yellow pigment) or eumelanin (a black or brown pigment) through the pigment type-switching pathway, and is regulated by three genes in dogs: MC1R (melanocortin receptor 1), CBD103 (β-defensin 103), and ASIP (agouti-signaling protein precursor). The genotypes of these three gene loci in dog breeds are associated with coat color pattern. Here, we resequenced these three gene loci in two Kunming dog populations and analyzed these sequences using population genetic approaches to identify evolutionary patterns that have occurred at these loci during the recent domestication and breeding of the Kunming dog. The analysis showed that MC1R undergoes balancing selection in both Kunming dog populations, and that the Fst value for MC1R indicates significant genetic differentiation across the two populations. In contrast, similar results were not observed for CBD103 or ASIP. These results suggest that high heterozygosity and allelic differences at the MC1R locus may explain both the mixed color coat, of yellow and black, and the difference in coat colors in both Kunming dog populations.

Citation: Wang G-d, Cheng L-g, Fan R-x, Irwin DM, Tang S-s, Peng J-g, et al. (2013) Signature of Balancing Selection at the MC1R Gene in Kunming Dog Populations. PLoS ONE 8(2): e55469. https://doi.org/10.1371/journal.pone.0055469

Editor: Yong-Gang Yao, Kunming Institute of Zoology, Chinese Academy of Sciences, China

Received: September 11, 2012; Accepted: December 23, 2012; Published: February 12, 2013

Copyright: © 2013 Wang et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: This work was supported by grants from the National Basic Research Program of China (973 Program, 2013CB835200), National Natural Science Foundation of China (91231108), Chinese Academy of Sciences, and Bureau of Science and Technology of Yunnan Province. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Phenotypic diversity, including body size and coat color, among domestic dogs is overwhelming compared with that observed in their wild ancestors [1], [2], [3]. Morphological polymorphisms selected under domestication provide an excellent resource for unraveling the molecular basis of phenotypic diversity in domestic animals, and gives opportunities to examine the evolutionary patterns generated by artificial selection. The extremely diverse coat colors found in dog breeds is a good case for revealing the power of artificial selection, where the selection was imposed for human needs, and resulted in strong artificial selection and domestication bottlenecks [4].

Melanocytes synthesize pheomelanin (a red or yellow pigment) or eumelanin (a black or brown pigment) in mammals depending upon the genotype of several genes: MC1R (melanocortin receptor 1), ASIP (agouti-signaling protein precursor), and CBD103 (β-defensin 103, also was known as K locus) [3], [5], [6]. MC1R is epistatic to both CBD103 and ASIP [3], [7]. Activated MC1R exclusively produces eumelanin and dominantly causes a uniform black coat, while inhibited MC1R exclusively produces pheomelanin and causes a uniform red or yellow coat [3]. CBD103 and ASIP bind to MC1R competitively and regulate the pigment type-switching pathway. ASIP encodes an extracellular inhibitory ligand of MC1R expressed on melanocytes [8], thus, gain-of-function mutations at ASIP yield the dominant inheritance of a yellow coat, while loss-of-function mutations at ASIP yield the recessive inheritance of a black coat. Conversely, CBD103 is a high affinity ligand of MC1R and competitively inhibits the ability of the ASIP protein to antagonize MC1R signaling [3]. Dogs carrying the dominant allele of CBD103 have a black coat. Previous research has showed that mutations at these three genes can affect the coat color patterns in domesticated dogs [9]. For instance, a SINE insertion in ASIP causes the black-and-tan and saddle tan [10], a CBD103 mutation causes a black coat color [3], and a specific MC1R allele causes the black mask pattern [11].

The Kunming dog breed was originally developed from the local hybrid dogs by crossing local native dogs with working dogs, such as the German shepherd, in the 1950s in Kunming, China. This hybrid has two stable populations, the Wolf Black (WB) and the Back Black (BB), which were derived from the Kunming dog breed during the past 16 years. Each of these two populations was bred separately by a random mating approach. Both populations have similar body size and behavior, differing only in coat color. Characteristically, males are 65 to 70 cm in height, with females being 60 to 65 cm, and they have body lengths that are slightly larger than their height. WB dogs have black and yellow all over their bodies, while dogs from the BB population have a black back and yellow abdomen and limbs (See Figure 1). These two stable Kunming dog populations provide an excellent resource to examine the evolutionary process that occurs to color genes under recent domestication process. Here, we resequenced and analyzed three coat-color-related genes: MC1R, CBD103, and ASIP in both Kunming dog populations using population genetic approaches. The results of these analyses show that: 1) Balancing selection occurs at the MC1R locus in both Kunming dog populations, but not at the CBD103 or ASIP loci. 2) Significant differences occur between the WB and BB populations at the MC1R locus, but not at the CBD103 or ASIP loci. This work reveals that the mixed color coat of Kunming dogs likely is due to balancing selection, and that the coat color difference between the two Kunming dog populations might be due to a divergence of the genotypes at the MC1R locus.

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Figure 1. Photographs illustrating the differences in coat colors between the two Kunming dog populations.

A) Wolf Black (WB) population. B) Back Black (BB) population. As shown, WB individuals have black and yellow all over their body, while BB individuals have black on their backs and yellow on their abdomen and limbs.

https://doi.org/10.1371/journal.pone.0055469.g001

Materials and Methods

Population Samples and Sequence of MC1R, CBD103, and ASIP

The present study involves two populations of Kunming dogs. The WB population consisted of 44 individuals while the BB population consisted of 54 individuals. Figure 1 illustrates the differences in the coat colors of the two populations. Total genomic DNA was extracted from blood according to a standard phenol–chloroform extraction protocol. Sequences of 954-bp for MC1R, 1540-bp for CBD103, and 1920-bp for ASIP were amplified and resequenced using Sanger technology (Applied Biosystems). All PCR primers and resequencing primers were designed based on the dog reference genome (canfam2) (Table S1). Every nucleotide position of every individual was determined from both strands by at least one read each, and rare variants were confirmed by a second set of independent PCR products. Sequences from the dog reference genome were used as the reference sequence. All of the sequences obtained in the present study have been deposited into GenBank with accession numbers KC332295 - KC332882.

Data Analysis

The haplotype phase of every individual was estimated with the PHASE 2.1 program [12], [13]. Linkage disequilibrium (LD) parameters (D′ and r²) and LD blocks were inferred using the Haploview program [14]. Summary of population genetic parameters, such as Watterson’s theta estimator (θ_W), nucleotide diversity (θπ), haplotype diversity and population genetic analysis were calculated by DNAsp 5.10.01 [15]. Tajima’s D test [16] was performed using coalescent simulation under the assumption of no recombination across the genes, which is the conclusion of the Haploview analysis. Median-joining networks [17] were constructed by Network 4.5.1.6 to infer the haplotype genealogy (http://www.fluxus-engineering.com/). The program ms [18] was used to generate 10,000 independent replicated samples under the assumptions of the demographic history of the Kunming dog populations. We used the F statistic to evaluate the population differentiation according to the methods of [19] with the program GenepopV4 [20] which resulted in values between 0 (no differentiation) and 1 (complete differentiation). An exact G test was used for the statistical analysis. TMHMM 2.0 package (http://www.cbs.dtu.dk/services/TMHMM/) was used to predict the secondary structure of MC1R [21].

Results

Nucleotide Sequence Variation at MC1R, CBD103, and ASIP

To apply a population genetic approach, we resequenced the entire MC1R coding region, the complete CBD103 coding region as well as one intron, and a part of ASIP in 44 Kunming dog individuals that have the WB coat color, and 54 Kunming dog individuals that have the BB coat color. A total of four SNPs (Single Nucleotide Polymorphism) were identified within the 954-bp MC1R sequence, all of which were non-synonymous substitutions (p.Ser90Gly, p.Ala105Thr, p.Pro159Gln, and p.Met264Val, nomenclature was described in http://www.hgvs.org/mutnomen/). Of the SNPs, three result in a change in amino acid properties, with the substitution p.Ser90Gly being from polar to nonpolar, and the substitutions p.Ala105Thr and p.Pro159Gln being from nonpolar to polar. All of these missense mutations had been previously identified in dogs [22], [23]. We identified 29 SNPs from the 1540-bp fragment of CBD103, and 9 SNPs from the 1920-bp fragment of ASIP. For CBD103 and ASIP all of the SNPs are located in introns and untranslated regions (UTR) except for one synonymous mutation found in CBD103 (g.1385C>T). The protein sequence encoded by CBD103 in the Kunming dog is identical to the k^y allele previously reported [3], [24].

Haplotype Structure Analysis

Haplotypes identified for the three gene loci are shown in tables S2 to S4. For MC1R, three haplotypes (M1, M2, and M3) were inferred in our populations, M1 was different from M3 for each SNP, while M2 was identical to M1 for the first 3 SNPs and identical to M3 at the last SNP. Interestingly, high heterozygosity was observed at the MC1R locus in both Kunming dog populations, compared with ASIP and CBD103, being 52.27% in the WB population and 48.15% in the BB population. Both Kunming dog populations had all three kinds of haplotypes. We identified 6 haplotypes (C1 to C6) in the resequenced region of CBD103 and 2 haplotypes (A1 and A2) in the resequenced region of ASIP. LD analysis showed that each of the three genes were located in their own LD blocks (Figures S1–S3) in both populations. Further evidence for strong LD was provided by the four-gamete test [25], which reveals no recombination events for the three gene loci in our populations. We constructed median-joining networks [17] to study the genealogy of the haplotypes at the MC1R and CBD103 loci. A median-joining network was not employed for ASIP as it has only two haplotypes. The topologies of the median-joining networks showed that MC1R presented two haplotypes (M1∶47%; M3∶42%) that are separated by relatively long-branch lengths, whereas CBD103 presented only one major haplotype (C1), which represented 73% of the haplotypes (Figure 2). Divergent haplotypes at MC1R in each population might indicate the effect of balancing selection, or of demographic factors such as bottlenecks, population fusions, and/or founder effects.

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Figure 2. Median-joining networks showing the genealogy of MC1R (A) and CBD103 (B) haplotypes in two Kunming dog populations.

Each node in the network represents a different haplotype, and the size of each circle is proportional to the haplotype frequency. Circles are color-coded according to population (Black: BB population; Grey: WB population). The number of nucleotide differences between the haplotypes is shown on the branches of the network.

https://doi.org/10.1371/journal.pone.0055469.g002

Evidence for Balancing Selection at MC1R in both Kunming Dog Populations

To determine whether balancing selection occurs at the MC1R locus in the two Kunming dog populations, we calculated the nucleotide diversity by means of θ_W [26] and θπ [27]. These two nucleotide diversity measures should be equal under a neutral model [16], however, our calculated θπ value was much larger than the θ_W value at the MC1R locus for both Kunming dog populations, with the θπ values being 2.43 and 2.35 times larger than the θ_W values in the WB and BB populations, respectively (see Table 1). The potential influence of artificial selection was further examined using the Tajima’s D test, which statistically compares the differences between θ_W and θπ [16]. At the MC1R locus, Tajima’s D value were significantly positive in both Kunming dog populations (one-tail test, see Table 1), although this may be underestimated as there are only four segregating sites [28], whereas no such pattern was observed for the CBD103 and ASIP loci.

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Table 1. Polymorphism statistics and neutral tests in the Kunming dog populations.

https://doi.org/10.1371/journal.pone.0055469.t001

Significantly positive values for Tajima’s D can be generated by two processes: 1) balancing selection, and 2) demographic history. To examine whether demographic history played a role in the significant positive values for Tajima’s D at the MC1R locus, we did a demographic simulation that followed the demographic history of Kunming dogs for the three loci [18]. The demographic history of Kunming dog populations can be divided into two stages: a domestication period (Figure 3, A) which underwent a bottleneck early in domestication, and a breeding period which underwent a bottleneck during recent breed creation (Figure 3, B) [29]. According to previous research [30], [31], the dog was domesticated about 15,000 years (t₃ ≈ 3750 generations if we assume 4 years per generation) from several hundred wolves (N₁) whose effective population size was about 10,000 (Ne ≈ 10,000). The Kunming dog breed was created from domesticated dogs about 70 years ago (t₂ ≈ 17 generations), and had a founder population of about 100 (N₂ = 100). The WB and BB Kunming dog populations were generated about 16 years ago (t₁ ≈ 4 generations), and the initial sizes of each population were about 15 (N₃ = 15). At the time our samples were collected, each of the Kunming dog populations had a size of about 100 individuals (N₄ = 100). We have assumed that the population underwent population expansion at t₁ and t₃ and was at a constant size at t₂. All of the parameters are verifiable except N₁ and the growth parameter α. N₁ represents the size of the founder population, which might have been several hundred individuals [31]. Growth parameter α represents the growth rates in the domestication period, but has uncertainty, as we do not know the real number of domesticated dogs that existed in the 1950s. Since we did not have reliable estimates for N₁ and α we therefore did multiple simulations using differing values for N₁ (100, 500, and 1000) and α (98.24, 122.8, and 147.37; representing 5 million, 50 million, and 500 billion individuals in the 1950s, respectively). As shown in Figure 3, the results from all of the simulations show significantly positive Tajima’s D values for MC1R in both Kunming dog populations under the simulated demographic histories. For the different values of N₁, 100, 500, and 1000, the P value of Tajima D test was 0.0016, 0.00071, and 0.0017 in the WB population, and was 0.0065, 0.0041, and 0.0067 in the BB population, respectively. For the different values of α 98.24, 122.8, and 147.37, the P value of Tajima D test was 0.0016, 0.00091, and 0.00071 in the WB population, and was 0.0065, 0.0039, and 0.0043 in the BB population, respectively. In contrast to MC1R, the Tajima’s D values for CBD103 and ASIP were not significantly positive. These analyses suggest that MC1R has undergone balancing selection during the demographic history of both Kunming dog populations.

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Figure 3. Standard coalescent simulations under the neutral model on the genealogy of the Kunming dogs.

The demographic history of the Kunming dog populations can be divided into two stages: domestication and breeding periods. A) The domestication period started ∼15,000 years ago (t₃). Ne represents the effective population size of the wolf population and N₁ represents the size of the founder population of domesticated dogs. Domesticated dog underwent a period of population expansion, represented by the growth parameter α. B) The breeding period for the Kunming dog breeds started ∼70 years ago. N₂ represents the size of the founder population of the Kunming dogs. Both Kunming dog breeds underwent a population size reduction (N3) followed by a period of population expansion (t₁, N₄). C) Standard coalescent simulations under different N₁ (100, 500, and 1000) in the WB population. D) Standard coalescent simulations under different N₁ (100, 500, and 1000) in the BB population. E) Standard coalescent simulations under different growth parameter α (98.24, 122.8, and 147.37) in the WB population. F) Standard coalescent simulations under growth parameter α (98.24, 122.8, and 147.37) in the BB population.

https://doi.org/10.1371/journal.pone.0055469.g003

MC1R, but not CBD103 and ASIP, Show Population Differentiation

To determine whether population differentiation had occurred between the two Kunming dog populations, we analyzed the distribution of the haplotypes for the MC1R and CBD103 loci. Interestingly, at the MC1R locus, M3 was the most abundant haplotype in the WB population, accounting for 55.68% of the sampled chromosomes, while M1 was the most abundant haplotype in the BB population, accounting for 60.19%. However, for CBD103, the same haplotype, C1, was most abundant in both Kunming dog populations, accounting for 61.36% and 82.41% in the WB and BB populations, respectively. The Fst value was calculated for measuring the degree of population differentiation between the WB and BB populations [19], [32] and the results are shown in Table 2. The Fst value for the MC1R locus across the two populations indicates significant genetic differentiation (Fst0.11, P-value0, exact G test), and each SNP of MC1R locus showed a significant signal for population differentiation, ranging from 0.101 (p.Ser90Gly, p.Ala105Thr, and p.Pro159Gln, P-value <0.001) to 0.146 (p.Met264Val, P-value <0.001). In contrast, the Fst value for the CBD103 locus across the two populations did not show a similar result (Fst0.012, P-value = 0.068), and none of the SNPs from CBD103 showed a significant signal for population differentiation.

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Table 2. Summary statistics of population structure.

https://doi.org/10.1371/journal.pone.0055469.t002

Discussion

The pigmentation system of domestic dogs has undergone strong artificial selection yielding a high diversity of coat colors, with variation in the quantity, quality, and regional distributions. The pigment type-switching pathway, including the MC1R, ASIP, and CBD103 gene loci, is a good model to research the influences of artificial selection. Here, we resequenced these three gene loci and applied population genetic approaches to identify the signature of artificial selection in two Kunming dog populations. For the MC1R locus, the resequenced region identified four previously known non-synonymous mutations, two of which have previously been reported to be associated with specific coat colors in dog populations: p.Ser90Gly is partially correlated with a black/brown coat [33], while having at least one copy of the p.Met264Val mutation, and not being homozygous for p.(Trp306*), was associated with the presence of a melanistic mask [11]. No nonsense mutations (p.(Trp306*)) were found in our populations, which is consistent with previous research as the homozygous p.(Trp306*) mutation causes a recessive pheomelanic phenotype [33], a trait that does not appear in either Kunming dog population. The protein sequence of CBD103 coming from our population is identical to the k^y allele previously reported, and not the 3-bp deletion allele (CBD103^ΔG23) that is associated with a black coat [3], [24] and is in accordance with the observation that none of the Kunming dogs have a black coat. The resequenced region of ASIP did not include the region that encodes the substitution of R96C, a substitution that accounts for the recessive inheritance of a uniform black coat [34].

The divergent haplotypes and statistically significant positive Tajima’s D value suggests that MC1R might have undergone balancing selection or was influenced by demographic factors in both Kunming dog populations [35], [36], [37], [38]. To distinguish between these alternatives, we reconstructed the demographic history of the Kunming dog populations, which has been the characterized in previous research [29], [30], [31] and through records of breeding history. For each simulation of demographic history, we generated 10,000 independently replicated samples, calculated the nucleotide diversity, and conducted the Tajima’s D test. In brief, all simulation results strongly suggest that balancing selection, and not demographic history of either the domesticated dog or the Kunming breed, better explains the observed high nucleotide diversity at the MC1R locus, but not at the CBD103 or ASIP loci. The most common reason for balancing selection is heterozygote advantage, a phenomena which has been well described for genes such as beta-hemoglobin [39], major histocompatibility complex-human leukocyte antigen (MHC-HLA) [40], and glucose-6-phosphate dehydrogenase (G6PD) [41]. Here, high heterozygosity at the MC1R locus in the Kunming dog populations is consistent with the mixture of yellow and black in the coat color of the Kunming dog.

Additional analyses showed that quite different haplotype distributions exist at the MC1R locus in the WB and BB populations, although both populations have a high heterozygosity caused by balancing selection. M3 was the main haplotype in the WB population while M1 was the main haplotype in the BB population. As shown in Table 2, clearly there is a significantly larger Fst value for the MC1R locus, compared to CBD103, revealing a significant difference between the WB and the BB populations. These results suggest that MC1R accounts for the coat color difference between these two populations and that the different compositions of the MC1R haplotypes might be responsible for the among-population differentiation in coat color patterns between the two Kunming dog populations. The results of TMHMM analysis showed that the p.Met264Val is located in the presumptive fourth-extracellular domain of MC1R, a region that contains important ligand binding sites [42], and that p.Ser90Gly and p.Ala105Thr are located in the second transmembrane domain, which is also involved in ligand binding [42], [43], [44], [45], [46], [47]. Variation in the sequences of these ligand-binding sites between the two Kunming dog populations may lead to differences in ligand-binding ability, and in turn, to differences in coat color.

Supporting Information

Figure S1.

Linkage disequilibrium pattern of MC1R .

https://doi.org/10.1371/journal.pone.0055469.s001

(EPS)

Figure S2.

Linkage disequilibrium pattern for CBD103 .

https://doi.org/10.1371/journal.pone.0055469.s002

(EPS)

Figure S3.

Linkage disequilibrium pattern for ASIP .

https://doi.org/10.1371/journal.pone.0055469.s003

(EPS)

Table S1.

Sequences of primer for PCR and resequencing of MC1R and CBD103 , and ASIP .

https://doi.org/10.1371/journal.pone.0055469.s004

(DOC)

Table S2.

Summary of the differences in sequences, and haplotype distributions, for MC1R in the 98 Kunming dog individuals.

https://doi.org/10.1371/journal.pone.0055469.s005

(DOC)

Table S3.

Summary of the differences in sequences, and haplotype distributions, for CBD103 in the 98 Kunming dog individuals.

https://doi.org/10.1371/journal.pone.0055469.s006

(DOC)

Table S4.

Summary of the differences in sequences, and haplotype distributions, for ASIP in the 98 Kunming dog individuals.

https://doi.org/10.1371/journal.pone.0055469.s007

(DOC)

Acknowledgments

We thank Wei-wei Zhai and three anonymous reviewers for helpful comments and suggestions.

Author Contributions

Conceived and designed the experiments: GDW YPZ. Performed the experiments: LGC RXF. Analyzed the data: GDW. Contributed reagents/materials/analysis tools: LGC SST JGP. Wrote the paper: GDW DMI YPZ.

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