Identification of genetic variation in the swine toll-like receptors and development of a porcine TLR genotyping array

Background

Toll-like receptors (TLR) are crucial in innate immunity for the recognition of a broad range of microbial pathogens and are expressed in multiple cell types. There are 10 TLR genes described in the pig genome.

Results

With a twofold objective i.e. to catalogue genetic variants in porcine TLR genes and develop a genotyping array for genetic association studies on immune-related traits, we combined targeted sub-genome enrichment and high-throughput sequencing to sequence the 10 porcine TLR genes in 266 pigs from 10 breeds and wild boars using a DNA-pooling strategy. We identified 306 single nucleotide variants across the 10 TLR and 11 populations, 87 of which were novel. One hundred and forty-seven positions i.e. six stop-gains and 141 non-synonymous substitutions were predicted to alter the protein sequence. Three positions were unique to a single breed with alternative allele frequencies equal to or higher than 0.5. We designed a genotyping array for future applications in genetic association studies, with a selection of 126 variants based on their predicted impact on protein sequence. Since TLR4, TLR7 and TLR9 were underrepresented in this selection, we also included three variants that were located in the 3′UTR of these genes. We tested the array by genotyping 214 of the 266 sequenced pigs. We found that 93 variants that involved the 10 TLR genes were polymorphic in these animals. Twelve of these variants were novel. Furthermore, seven known variants that are associated with immune-related phenotypes are present on the array and can thus be used to test such associations in additional populations.

Conclusions

We identified genetic variations that potentially have an impact on the protein sequence of porcine TLR. A genotyping array with 80 non-synonymous, 10 synonymous and three 3′UTR polymorphisms in the 10 TLR genes is now available for association studies in swine populations with measures on immune-related traits.

Toll-like receptors (TLR) are a family of innate immunity receptors, which are expressed in many cell types, including macrophages, dendritic cells, keratinocytes or even sperm cells. Each TLR recognizes a specific range of microbial pathogens and informs the cell to initiate an immune response. While cell-surface TLR (TLR1, TLR2, TLR4, TLR5, TLR6 and TLR10) recognize non-nucleic acid molecules, intracellular TLR (TLR3, TLR7, TLR8 and TLR9) detect nucleic acids. TLR are relatively large proteins. In swine, the sizes of cell surface and intra-cellular TLR proteins range from 785 to 856 and from 905 to 1050 amino acids, respectively (see Additional file 1). Cell-surface TLR are highly polymorphic, especially in the ectodomains that recognize the pathogens, which allows the organism to broaden the catalogue of molecules that it can recognize. In the pig, 10 TLR genes (TLR1 to TLR10) have been described and unambiguously mapped to seven genomic regions on chromosomes (chr) 1, 8, 10, 13, 15 and X. TLR1, TLR6 and TLR10 cluster within a 56-kb interval on chr 8 and TLR7 and TLR8 map within a 62-kb region on chr X (see Additional file 1). Genetic and functional approaches have linked several porcine missense single nucleotide polymorphisms (SNPs) that are located within TLR genes to immune traits. TLR1, TLR5 and TLR6 are related to antibody responses after vaccination against Erysipelothrix rhusiopathiae or Actinobacillus pleuropneumoniae, [1]. TLR2 is associated with the incidence of pneumonia caused by Mycoplasma hyopneumoniae [2]. TLR5 is associated with the expression of IL-2, IL-10 and TLR5, itself, in peripheral blood mononuclear cells (PBMC), which suggests the presence of a regulatory variant near TLR5 [3]. Reporter assays have also linked missense SNPs that are located within TLR2 and TLR5 to a differential reactivity to Salmonella enterica [4] and within TLR3 to different responses to stimulation by poly(A:C), a synthetic acid that emulates viral infection [5]. Among the 10 porcine TLR genes, TLR4 has by far the largest number of reported genotype:phenotype associations. Missense SNPs within TLR4 are linked to the expression of IFNG, TNFA, IL-2, IL-4 and IL-6 in PBMC as well as to the presence of lesions in the lung [6] and the expression of TLR2, TLR4 itself, TNFA and IL-1β upon lipopolysaccharide stimulation in pulmonary alveolar macrophages [7]. Moreover, porcine TLR4 is also associated with Salmonella typhimurium fecal shedding [8]. In spite of all these reports, the impacts of TLR on most of the health conditions that are relevant to pig breeding remain unexplored.

Currently, targeted sub-genome enrichment in combination with high-throughput sequencing is enhancing research in the field of genetics and, particularly, the identification of genetic variation. We captured and sequenced a sub-exome that consisted of 10 taste receptors, 191 genes from the appetite-reward pathways and the TLR from pools of genomic DNA (gDNA). Here, we describe the identification of genetic variation in the porcine TLR genes. We hypothesized that variations that alter the protein sequences of TLR may shape innate immunity and affect disease resistance. The aim of our study was twofold, i.e. (1) to map coding variants in the porcine TLR genes and predict their allelic frequencies in several pig populations and their impact on protein sequence; and (2) based on this information, to develop a genotyping array with a set of variants that tag the 10 TLR genes for future applications in association studies for immune-related traits.

To select the target regions, we considered the 49 non-redundant exons from the 22 transcripts annotated for the 10 porcine TLR genes (www.ensembl.org), including the coding sequences and untranslated regions (UTR). Each TLR has one single reference RefSeq (http://www.ncbi.nlm.nih.gov/books/NBK21091) transcript. RefSeq transcripts include 30 of the 49 exons and display the longest coding sequences, which fully encompass the coding sequences of the alternative transcripts. In addition, most of the alternative transcripts share an identical coding sequence and protein product and only differ in the UTR. Overall, the 22 transcripts span 32,278 base pairs (bp) of exonic sequence, of which 26,706 are coding sequences and 5572 are UTR (see Additional file 1). For the design of Agilent’s SureSelect Target Enrichment baits, 31 genomic positions that fully encompass all TLR exons (coding sequences and UTR) of the 22 transcripts were retrieved via Ensembl’s Biomart [9] (see Additional file 2).

Genomic DNA (gDNA) samples from 266 pigs belonging to 10 breeds (Large White, Landrace, Pietrain, Duroc, Iberian, Majorcan Black, Bazna, Mangalitza, Meishan and Vietnamese) and wild boars were combined into 14 per-breed pools (see Additional file 3) using semi-equal amounts of gDNA that was quantified using a NanoDrop™ spectrophotometer. Meishan and Vietnamese samples were pooled together in an Asian pool. Specialized professionals from each institution that provided animal material obtained all blood samples and tissues following standard routine monitoring procedures and guidelines. No animal experiment was performed within this research.

Genomic DNA pools were subjected to target enrichment and library preparation according to Agilent’s SureSelect protocol for Illumina multiplexed paired-end sequencing. A detailed description of all the methods is available in Additional file 4. The libraries were then sequenced on two sequencing lanes using an Illumina HiSeq 2000 sequencer, which produced 2 × 100 bp read pairs, following the manufacturer’s instructions (see Additional file 4). Reads were mapped to the porcine reference genome (Sscrofa10.2) with the GEM toolkit [10] and BFAST read aligner [11]. Only the reads that were unambiguously mapped to a unique genomic location were kept for further analysis. GATK 3.1 [12] was used for variant calling (see Additional file 4). Functional predictions were added using snpEff [13] based on the Sscrofa10.2.69 database, which classifies variants according to their impact on protein sequence as High (H), Moderate (M), Low (L) or Modifier variants (see Additional file 5). M variants were further classified as deleterious (Mdel) or tolerated (Mtol) according to SIFT scores (see Additional file 3) using snpSift [14] and the Ensembl’s Variant Effect Predictor (VEP) tool [15]. Variants were considered novel if they were not annotated in the porcine dbSNP version 138 using the VEP tool [15]. The proportion of reads that carried each allele was used to estimate the frequency of the alternative allele (pAAF).

The mean depth for each pool ranged from 3498 to 4794 uniquely mapped sequence reads per bp position (depth) (see Additional file 3). By considering all the pools together, 29,163 bp (90.3 % of the initial target) of the TLR exonic sequences were covered with a depth greater than 1000. This threshold was set in order to accurately calculate pAAF for each breed-pool. Only TLR4 was poorly sequenced with only 41 % of its exons sequenced above that depth (see Additional file 1). Capture baits could be designed for the complete TLR4 gene but some segments (exon 1, exon 2 and the proximal portion of exon 3) displayed perfect homology to the unmapped genomic contig JH118734.1 that harbors ENSSSCG00000024231, a TLR paralog predicted by Ensembl’s genebuild pipeline. Since the corresponding reads could not be uniquely mapped, they were excluded from further analysis. After read mapping, 306 single nucleotide variants (SNV) were called, among which 87 were not annotated in the porcine dbSNP (version 143) and were thus considered novel SNV (Table 1) and (see Additional file 6). Six SNV (in TLR1, TLR8 and TLR10) were predicted to create a premature stop-codon and thus their impact was classified as high (Table 1). One hundred and forty-one non-synonymous SNV were classified as moderate impact variants (45 Mdel and 96 Mtol) (Table 1). The remaining 159 SNV, including 152 synonymous and seven start codon gains (Table 1) were classified as low impact variants. As already described in humans [16], cell-surface porcine TLR had a larger number of variants that included stop-gain and non-synonymous variants (ranging from 13.3 in TLR2 to 19.3 per kb of exonic sequence in TLR1) than intracellular TLR for which the number of variants ranged from 4.9 in TLR7 to 9.3 in TLR8 (Table 1 and Fig. 1). Premature stop codons that abolish the toll/interleukin-1 receptor (TIR) domain, which is responsible for signal transduction, will generate TLR that fail to recognize the pathogen-associated molecular patterns on the cells. Nonetheless, these stop-gain variants in cell-surface TLR genes are relatively common in humans and it is generally considered that they are tolerated because of functional redundancy between various TLR [16]. In agreement to previous studies in swine [17], TLR1 had the highest level of variability with 54 SNV that did not have a uniform distribution i.e. 24 (17 protein-changing and seven silent) SNV were located between residues 500 and 565 within the leucine-rich repeat ectodomain responsible for binding pathogen ligands (Fig. 2).

Normalized number of variants for each TLR gene and variant type. The normalized number of variants indicates the number of variants for every 1000 of exonic sequence. TLR4 is not included because of poor sequencing quality

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Variant distribution along the porcine TLR1 protein. Dark grey vertical bars indicate the number of stop-gain and non-synonymous coding variants. Light grey vertical bars indicate the number of synonymous coding variants. Each position bin includes 10 % (79.6) of the TLR1 amino acids. The dark grey horizontal boxes show the leucine-rich repeats (LRR), the cysteine-rich flanking region (CRFR) and the toll/interleukin-1 receptor (TIR) domains of the TLR1 protein. Black stars represent the four stop-gains identified in TLR1

Full size image

When all the variants were considered across the 11 pig populations, the Asian and Landrace pools displayed the largest levels of genetic diversity whereas it was lowest for the Majorcan Black pool (Table 2). However, these data should be taken with caution because the number of animals varied within each breed-pool. Still these results are not surprising, since the Asian pool included two breeds (Meishan and Vietnamese) and thus, was expected to harbor more genetic diversity, and also Asian and European Sus scrofa split around 0.8–1.6 million years ago and are in fact considered as two different subspecies [18]. Since the reference pig genome sequence is derived from a western breed (Duroc) animal, more differences are expected when comparing Asian pig sequences to this reference sequence. In addition, three SNV were present in only one breed and with a pAAF higher than 0.5 in that breed. Two of these breed-specific variants, including a Mdel in TLR8, were detected in the Asian pool (Table 2) and (see Additional file 6).

In addition to cataloguing genetic variation in porcine TLR genes, an equally important goal of our study was to develop a genotyping array with polymorphisms that tag the 10 TLR genes for future association studies on immune-related traits in the swine. For this purpose, we used the OpenArray^® genotyping technology (Life Technologies), which accommodates 128 SNV assays (see Additional file 4), and we designed 126 assays that targeted the 10 TLR genes and two that targeted the SRY gene (c.135C>G and c.593G>C) [19] for sex determination. Due to limitations in the design that are related to the sequence context, including melting temperature and presence of repeat elements or polymorphisms near the target, we could not assay all the variants that altered TLR proteins. First, we designed assays for all the SNV that were predicted to alter protein sequence (six H, 45 Mdel and 96 Mtol). This yielded 113 successful assays for the 10 TLR. To increase the number of assays, we also included 10 SNV that were predicted to be silent. After this first step, we found that TLR4, TLR7 and TLR9 were poorly represented in the array. Hence, we also included one 3′UTR variant for each of these genes. Then, the array was tested by genotyping 214 of the sequenced animals, instead of all 266 pigs because the amount of DNA was not sufficient to genotype the other 52 animals. Genotyping was performed in a QuantStudioTM 12 K Flex Real-Time PCR System (Life Technologies) and the results were analysed by using both Taqman Genotyper version 1.3 and Symphoni Suite software (Life Technologies) (see Additional file 4). Three of the TLR SNV did not yield high-quality genotypes. For 30 TLR SNV, the alternative allele was not detected, but since the frequency of most of these, including all the H SNV, were low (i.e. 24 had a pAAF lower than 0.01), some may represent real polymorphisms that were present in ungenotyped animals. For 93 TLR SNV, the alternative allele was detected for at least one animal, including 16 Mdel, 64 Mtol, 10 L and three 3′UTR variants (Table 3) and (see Additional file 7). Among these, 12 are novel variants and 81 were previously reported by other groups. Moreover, seven of the 81 already annotated SNV are associated to different immune-related traits as discussed below. Although TLR4 is the most poorly represented gene on the array, it displays three SNV (one Mtol, one synonymous and one 3′UTR), which should, at least partially, tag the gene in genetic association studies. Each sample had on average 21 SNV for which the alternative allele (both in the heterozygous and homozygous states) was detected. In agreement with the findings based on pool sequencing, the largest number of alternative alleles was found for the Meishan animals. In contrast, the Majorcan Black pigs were the least divergent when compared to the reference genome. The 18 rare variants that had allelic frequencies lower than 0.01 were uniformly distributed (one to three variants per animal) across 27 pigs and the breed distribution was in agreement with the sequencing data (data not shown). The frequencies of the alternative allele that were estimated based on genotyping data and the pAAF were highly correlated (Pearson r² = 0.88). To the best of our knowledge, only TLR1, 2, 3, 4, 5 and 6 have been genetically or functionally associated to immune related traits in pigs. Some of the missense variants that are described in the previous reports are present on our genotyping array. More specifically, the following variants were included on the array: rs326791928 and rs321053450 in TLR1, rs81210417, rs81218850 and rs81218851 in TLR5, and rs322825361 in TLR6 which were associated to antibody response after vaccination against bacteria [1] and rs81218811 in TLR2 which was linked to the incidence of pneumonia [2]. Moreover, rs81218851 in TLR5 was also associated to the mRNA expression of IL-2, IL-10 and itself [3]. This new array will contribute to better understand the genetic impact of these variants and other porcine TLR variants on a broader range of immunological traits. This genotyping array is available, by contacting the corresponding author, for collaborative efforts to perform genetic association analyses in swine populations with records on immune-related traits such as infectious disease resistance or auto-immune conditions.

AC and ASa designed the experiment. ASh and AC searched for TLR exonic regions. SD contributed the bioinformatic analysis up to variant calling. AC also contributed to the analyses. AH and PA contributed samples. AC wrote the main text. All authors read and approved the final manuscript.

Acknowledgements

We are grateful to M Amills, J Tibau and V Balteanu for contributing samples. We thank A Castelló for performing gDNA extractions and A Mercade for the genotyping using OpenArray technology. This work was funded by Grants from the Spanish Ministry of Science and Innovation (Project AGL2010-22358-C02-01) and the Spanish Ministry of Economy and Competitiveness (AGL2013-44978-R; CSD2007-00036, IPT-2012-0378-060000). A Clop acknowledges the Ramon y Cajal Fellowship program from the Spanish Ministry of Economy and Competitiveness (RYC-2011-07763). S Derdak is supported by the Parc Científic de Barcelona through the Torres Quevedo subprogram (MICINN) under Grant agreement PTQ-12-05391.

Competing interests

The authors declare that they have no competing interests.

Authors and Affiliations

1. Center for Research in Agricultural Genomics (CRAG) Consorci CSIC-IRTA-UAB-UB, Campus UAB, 08193, Bellaterra, Catalonia, Spain

   Alex Clop & Armand Sanchez

2. Hypor BV, Villa ‘de Körver’, Spoorstraat 69, 5831 CK, Boxmeer, The Netherlands

   Abe Huisman

3. Hendrix-Genetics, Villa ‘de Körver’, Spoorstraat 69, 5831 CK, Boxmeer, The Netherlands

   Pieter van As

4. Ain Shams University, Cairo, Egypt

   Abdoallah Sharaf

5. Centre Nacional d’Anàlisi Genòmica CNAG, Baldiri Reixac 4, 08028, Barcelona, Catalonia, Spain

   Sophia Derdak

6. Departament de Ciència Animal i dels Aliments, Facultat de Veterinària, Universitat Autònoma de Barcelona, 08193, Bellaterra, Catalonia, Spain

   Armand Sanchez

Corresponding author

Correspondence to Alex Clop.

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