全基因组eQTL揭示猪11号染色体肉质性状新候选位点

doi:10.3969/j.issn.1674-7968.2024.04.007

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (2565 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要全基因组关联分析(genome-wide association study, GWAS)挖掘了大量猪肉肉质性状关联的遗传变异,但是多数变异的调控机制未知。遗传变异主要通过调控基因表达水平影响复杂性状,通过定位表达数量性状位点(expression quantitative trait locus, eQTL)鉴定基因表达水平相关的遗传变异,有助于阐释变异位点与性状之间的关联。为筛选肉质性状候选基因与位点,本研究以F₂代的19个杂交香猪(Sus scrofa)(大白猪♂×从江香猪♀)个体为试验材料,使用全基因组测序(whole genome sequencing, WGS)和背最长肌组织的RNA-seq数据进行全基因组eQTL分析,在11号染色体上共检测到1 332个cis-eQTLs (P_FDR<0.01)和18 078个trans-eQTLs (P_FDR<1E-12)。对cis-eQTL关联中的eSNP (eQTL-associated SNP)位点进行注释筛选,使用PCR-限制性片段长度多态性(restriction fragment length polymorphism, RFLP)和Sanger测序鉴定了1个位于肉质性状候选eGene (eQTL-associated gene)—线粒体中间肽酶基因(mitochondrial intermediate peptidase, MIPEP) 5'UTR的eSNP位点rs319855910 c.-46C>G,与MIPEP基因表达水平显著相关(P_FDR=8.81E-03)。RNA-seq统计分析发现,rs319855910不同基因型显著影响MIPEP基因表达(P<0.05)。当rs319855910基因型由野生型(CC)突变为纯合突变型(GG)时,MIPEP基因的表达水平显著下调(P<0.05)。进一步分析发现,rs319855910位于转录因子结合序列区域,导致MIPEP基因5'UTR序列结合的转录因子种类和数量发生改变。上述结果表明,rs319855910是一个新的猪肉肉质性状候选位点,能够通过转录因子的结合而调节MIPEP基因表达,从而影响猪的肉质性状。本研究为猪种选育和遗传改良提供基础资料。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	郑韵頔
	冉雪琴
	牛熙
	黄世会
	李升
	王嘉福

关键词 ：猪, 全基因组测序(WGS), 转录组测序, 表达数量性状位点(eQTL), SNP, 肉质性状

Abstract：Genome-wide association study (GWAS) has detected a considerable amount of genetic variants associated with pork meat quality traits, however, the regulatory mechanism of numerous variants are generally unknown. Genetic variants mainly exert effects on complex traits by regulating gene expression levels. Thus, mapping expression quantitative trait locus (eQTL) has identified variants associated with gene expression levels, and will contribute to interpretate the association between variant loci and traits. In order to identify genetic variants/genes correlative with meat traits, this study used 19 hybrid Xiang pigs (Sus scrofa)(Large White pig ♂ × Congjiang Xiang pig ♀) of F₂ generation as tested materials, whole genome sequencing (WGS) and high-throughput RNA sequencing (RNA-seq) data of the pork longissimus muscle tissues were integrated for eQTL analysis. The results showed a total of 1 332 cis-eQTL (P_FDR<0.01) and 18 078 trans-eQTL (P_FDR<1E-12) on chromosome 11. Subsequently, annotation and filtering were conducted on the eQTL-associated single nucleotide polymorphism (eSNP) which identified by cis-eQTL associations, and PCR-restriction fragment length polymorphism (RFLP) and Sanger sequencing were used to verify the candidate eSNP. An eSNP event rs319855910 c.-46C>G located in mitochondrial intermediate peptidase gene (MIPEP) 5'UTR was ultimately identified, and rs319855910 significantly associated with MIPEP gene expression (P_FDR=8.81E-03). Statistical analysis combined with genotype and RNA-seq showed that rs319855910 genotypes significantly affected MIPEP gene expression (P<0.05), and it was observed that significant down-regulation (P<0.05) of MIPEP gene expression when the rs319855910 genotype was mutated from homozygote (CC) to homozygous mutant (GG). Furthermore, the transcription factor binding analysis revealed that rs319855910 was located in the region of transcription factor binding sequences, which could change the binding type or number of 5'UTR sequence with transcription factors. The above results suggested that rs319855910 was a novel candidate locus associated with pork meat quality traits, which could affect gene expression and regulate pork meat quality traits by changing the binding of transcription factors. This study provides basic data for pig breeding and genetic improvement.

Key words： Pig Whole genome sequencing (WGS) RNA-seq Expression quantitative trait locus (eQTL) SNP Meat quality trait

收稿日期: 2023-03-24

ZTFLH:

S828.8+9

基金资助:国家自然科学基金(31960641); 贵州省科技创新人才团队项目(黔科合平台人才[2019] 5615); 贵州省“百”层次创新型人才培养项目(黔科合人才[2016]4012); 贵州省科技支撑计划(黔科合支撑[2017]2585; 黔科合支撑[2017]2987); 贵州省农业农村厅生猪产业高质量发展计划[202208-5]

通讯作者: *jfwang@gzu.edu.cn

引用本文:

郑韵頔, 冉雪琴, 牛熙, 黄世会, 李升, 王嘉福. 全基因组eQTL揭示猪11号染色体肉质性状新候选位点[J]. 农业生物技术学报, 2024, 32(4): 807-819.
ZHENG Yun-Di, RAN Xue-Qin, NIU-Xi, HUANG Shi-Hui, LI Sheng, WANG Jia-Fu. Genome-wide eQTL Reveals Novel Candidate Loci for Meat Quality Traits on Chromosome 11 in Pigs (Sus scrofa). 农业生物技术学报, 2024, 32(4): 807-819.

链接本文:

https://journal05.magtech.org.cn/Jwk_ny/CN/10.3969/j.issn.1674-7968.2024.04.007 或 https://journal05.magtech.org.cn/Jwk_ny/CN/Y2024/V32/I4/807

[1] 李睿, 蔡瑞, 庞卫军. 2022. 多组学生物信息学分析在家畜脂肪沉积研究中的应用研究进展[J]. 中国畜牧杂志, 58(10): 83-90.
(Li R, Cai R, Pang W J.2022. Application and research progress on multi-omics bioinformatics analysis in the fat deposition in livestock[J]. Chinese Journal of Animal Science, 58(10): 83-90.)
[2] 刘先先. 2015. 猪15号染色体上影响背最长肌糖原含量和滴水损失的QTL解析[D]. 硕士学位论文, 江西农业大学, 导师: 麻骏武, pp. 5-6.
(Liu X X, 2015. Untangling QTL for muscle gylcogen content and drip less on porcine chromosome 15[D]. Thesis for M.S., Jiangxi Agricultural University, Supervisor: Ma J W, pp. 5-6.)
[3] 熊信威, 2017. 猪12号染色体上增加肌内脂肪含量的因果基因及其因果突变的鉴别与作用机理研究[D]. 博士学位论文, 江西农业大学, 导师: 黄路生, pp. 31-34.
(Xiong X W, 2017. Identification of the causative gene and mutation for increasing IMF content at SSC12 and its mechanism study[D]. Thesis for Ph.D., Jiangxi Agricultural University, Supervisor: Huang L S, pp. 31-34.)
[4] Bailey T L, Johnson J, Grant C E, et al.2015. The MEME Suite[J]. Nucleic Acids Research, 43(W1): W39-W49.
[5] Barrett J C, Fry B, Maller J, et al.2005. Haploview: Analysis and visualization of LD and haplotype maps[J]. Bioinformatics, 21(2): 263-265.
[6] Carmelo V A O, Kadarmideen H N.2020. Genetic variations (eQTLs) in muscle transcriptome and mitochondrial genes, and trans-eQTL molecular pathways in feed efficiency from Danish breeding pigs[J]. PLOS ONE, 15(9): e0239143.
[7] Cattley S, Arthur J W.2007. BioManager: The use of a bioinformatics web application as a teaching tool in undergraduate bioinformatics training[J]. Briefings in Bioinformatics, 8(6): 457-465.
[8] Chen S, Zhou Y, Chen Y, et al.2018. fastp: An ultra-fast all-in-one FASTQ preprocessor[J]. Bioinformatics, 34(17): i884-i890.
[9] Cingolani P, Platts A, Wang L L, et al.2012. A program for annotating and predicting the effects of single nucleotide polymorphisms, SnpEff: SNPs in the genome of Drosophila melanogaster strain w1118; iso-2; iso-3[J]. Fly, 6(2): 80-92.
[10] Danecek P, Auton A, Abecasis G, et al.2011. The variant call format and VCFtools[J]. Bioinformatics, 27(15): 2156-2158.
[11] De Goede O M, Nachun D C, Ferraro N M, et al.2021. Population-scale tissue transcriptomics maps long non-coding RNAs to complex disease[J]. Cell, 184(10): 2633-2648.
[12] Dong S S, He W M, Ji J J, et al.2021. LDBlockShow: A fast and convenient tool for visualizing linkage disequilibrium and haplotype blocks based on variant call format files[J]. Briefings in Bioinformatics, 22(4): bbaa227.
[13] Drag M, Hansen M B, Kadarmideen H N.2018. Systems genomics study reveals expression quantitative trait loci, regulator genes and pathways associated with boar taint in pigs[J]. PLOS ONE, 13(2): e0192673.
[14] Drag M H, Kogelman L J A, Maribo H, et al.2019. Characterization of eQTLs associated with androstenone by RNA sequencing in porcine testis[J]. Physiological Genomics, 51(10): 488-499.
[15] Durinck S, Spellman P T, Birney E, et al.2009. Mapping identifiers for the integration of genomic datasets with the R/Bioconductor package biomaRt[J]. Nature Protocols, 4(8): 1184-1191.
[16] Eldomery M K, Akdemir Z C, Vögtle F-N, et al.2016. MIPEP recessive variants cause a syndrome of left ventricular non-compaction, hypotonia, and infantile death[J]. Genome Medicine, 8(1): 106.
[17] Eldomery M K, Coban-Akdemir Z, Harel T, et al.2017. Lessons learned from additional research analyses of unsolved clinical exome cases[J]. Genome Medicine, 9(1): 26.
[18] Farries G, Bryan K, McGivney C L, et al.2019. Expression quantitative trait loci in equine skeletal muscle reveals heritable variation in metabolism and the training responsive transcriptome[J]. Frontiers in Genetics, 10: 1215.
[19] Gillies C E, Putler R, Menon R, et al.2018. An eQTL landscape of kidney tissue in human nephrotic syndrome[J]. American Journal of Human Genetics, 103(2): 232-244.
[20] González-Prendes R, Quintanilla R, Cánovas A, et al.2017. Joint QTL mapping and gene expression analysis identify positional candidate genes influencing pork quality traits[J]. Scientific Reports, 7: 39830.
[21] Gupta S, Stamatoyannopoulos J A, Bailey T L, et al.2007. Quantifying similarity between motifs[J]. Genome Biology, 8(2): R24.
[22] Haas J, Mester S, Lai A, et al.2018. Genomic structural variations lead to dysregulation of important coding and non-coding RNA species in dilated cardiomyopathy[J]. EMBO Molecular Medicine, 10(1): 107-120.
[23] Han X, Gao C, Liu L, et al.2022. Integration of eQTL analysis and GWAS highlights regulation networks in cotton under stress condition[J]. International Journal of Molecular Sciences, 23(14): 7564.
[24] Hirschey M D, Shimazu T, Goetzman E, et al.2010. SIRT3 regulates mitochondrial fatty-acid oxidation by reversible enzyme deacetylation[J]. Nature, 464(7285): 121-125.
[25] Hormozdiari F, Van de Bunt M, Segrè A V, et al.2016. Colocalization of GWAS and eQTL signals detects target genes[J]. American Journal of Human Genetics, 99(6): 1245-1260.
[26] Hu Z L, Park C A, Reecy J M.2022. Bringing the animal QTLdb and CorrDB into the future: Meeting new challenges and providing updated services[J]. Nucleic Acids Research, 50(D1): D956-D961.
[27] Iqbal A, Kim Y S, Kang J M, et al.2015. Genome-wide association study to identify quantitative trait loci for meat and carcass quality traits in Berkshire[J]. Asian-Australasian Journal of Animal Sciences, 28(11): 1537-1544.
[28] Khanal P, Maltecca C, Schwab C, et al.2019. Genetic parameters of meat quality, carcass composition, and growth traits in commercial swine[J]. Journal of Animal Science, 97(9): 3669-3683.
[29] Kim D, Langmead B, Salzberg S L.2015. HISAT: A fast spliced aligner with low memory requirements[J]. Nature Methods, 12(4): 357-360.
[30] Kinsella R J, Kähäri A, Haider S, et al.2011. Ensembl BioMarts: A hub for data retrieval across taxonomic space[J]. Database, 2011: bar030. DOI:10.1093/database/bar030.
[31] Kobayashi M, Takeda K, Narita T, et al.2017. Mitochondrial intermediate peptidase is a novel regulator of sirtuin-3 activation by caloric restriction[J]. FEBS Letters, 591(24): 4067-4073.
[32] Kogelman L J A, Pant S D, Fredholm M, et al.2014. Systems genetics of obesity in an F₂ pig model by genome-wide association, genetic network, and pathway analyses[J]. Frontiers in Genetics, 5: 214.
[33] Lagarrigue S, Martin L, Hormozdiari F, et al.2013. Analysis of allele-specific expression in mouse liver by RNA-Seq: A comparison with cis-eQTL identified using genetic linkage[J]. Genetics, 195(3): 1157-1166.
[34] Lavallée-Adam M, Cloutier P, Coulombe B, et al.2017. Functional 5'UTR motif discovery with LESMoN: Local enrichment of sequence motifs in biological networks[J]. Nucleic Acids Research, 45(18): 10415-10427.
[35] Li H.2011a. Improving SNP discovery by base alignment quality[J]. Bioinformatics, 27(8): 1157-1158.
[36] Li H.2011b. A statistical framework for SNP calling, mutation discovery, association mapping and population genetical parameter estimation from sequencing data[J]. Bioinformatics, 27(21): 2987-2993.
[37] Li H, Durbin R.2010a. Fast and accurate long-read alignment with Burrows-Wheeler transform[J]. Bioinformatics, 26(5): 589-595.
[38] Li M, Li C M, Ye Z C, et al.2020. Sirt3 modulates fatty acid oxidation and attenuates cisplatin-induced AKI in mice[J]. Journal of Cellular and Molecular Medicine, 24(9): 5109-5121.
[39] Li H D, Lund M S, Christensen O F, et al.2010b. Quantitative trait loci analysis of swine meat quality traits[J]. Journal of Animal Science, 88(9): 2904-2912.
[40] Liao Y, Smyth G K, Shi W.2014. featureCounts: An efficient general purpose program for assigning sequence reads to genomic features[J]. Bioinformatics, 30(7): 923-930.
[41] Lionel A C, Costain G, Monfared N, et al.2018. Improved diagnostic yield compared with targeted gene sequencing panels suggests a role for whole-genome sequencing as a first-tier genetic test[J]. Genetics in Medicine, 20(4): 435-443.
[42] Liu C, Joehanes R, Ma J, et al.2022. Whole genome DNA and RNA sequencing of whole blood elucidates the genetic architecture of gene expression underlying a wide range of diseases[J]. Scientific Reports, 12(1): 20167.
[43] Liu Y, Liu X, Zheng Z, et al.2020. Genome-wide analysis of expression QTL (eQTL) and allele-specific expression (ASE) in pig muscle identifies candidate genes for meat quality traits[J]. Genetics, Selection, Evolution, 52(1): 59.
[44] Liu S, Won H, Clarke D, et al.2022. Illuminating links between cis-regulators and trans-acting variants in the human prefrontal cortex[J]. Genome Medicine, 14: 133.
[45] Liu X, Zhang J, Xiong X, et al.2021. An integrative analysis of transcriptome and GWAS data to identify potential candidate genes influencing meat quality traits in pigs[J]. Frontiers in Genetics, 12: 748070.
[46] Mahboobi R, Fallah F, Yadegar A, et al.2022. Expression analysis of miRNA-155 level in Helicobacter pylori related inflammation and chronic gastritis[J]. Iranian Journal of Microbiology, 14(4): 495-502.
[47] McKenna A, Hanna M, Banks E, et al.2010. The genome analysis toolkit: A MapReduce framework for analyzing next-generation DNA sequencing data[J]. Genome Research, 20(9): 1297-1303.
[48] Mountjoy E, Schmidt E M, Carmona M, et al.2021. An open approach to systematically prioritize causal variants and genes at all published human GWAS trait-associated loci[J]. Nature Genetics, 53(11): 1527-1533.
[49] Nicolae D L, Gamazon E, Zhang W, et al.2010. Trait-associated SNPs are more likely to be eQTLs: Annotation to enhance discovery from GWAS[J]. PLOS Genetics, 6(4): e1000888.
[50] Ota M, Nagafuchi Y, Hatano H, et al.2021. Dynamic landscape of immune cell-specific gene regulation in immune-mediated diseases[J]. Cell, 184(11): 3006-3021.
[51] Petretto E, Mangion J, Dickens N J, et al.2006. Heritability and tissue specificity of expression quantitative trait loci[J]. PLOS Genetics, 2(10): e172.
[52] Porter L C, Franczyk M P, Pietka T, et al.2018. NAD+-dependent deacetylase SIRT3 in adipocytes is dispensable for maintaining normal adipose tissue mitochondrial function and whole body metabolism[J]. American Journal of Physiology. Endocrinology and Metabolism, 315(4): E520-E530.
[53] Purcell S, Neale B, Todd-Brown K, et al.2007. PLINK: A tool set for whole-genome association and population-based linkage analyses[J]. American Journal of Human Genetics, 81(3): 559-575.
[54] Rantalainen M, Lindgren C M, Holmes C C.2015. Robust linear models for cis-eQTL analysis[J]. PLOS ONE, 10(5): e0127882.
[55] Rio D C, Ares M, Hannon G J, et al.2010. Purification of RNA using TRIzol (TRI reagent)[J]. Cold Spring Harbor Protocols, 2010(6): pdb.prot5439.
[56] Robinson M D, McCarthy D J, Smyth G K.2010a. edgeR: A bioconductor package for differential expression analysis of digital gene expression data[J]. Bioinformatics, 26(1): 139-140.
[57] Robinson M D, Oshlack A.2010b. A scaling normalization method for differential expression analysis of RNA-seq data[J]. Genome Biology, 11(3): R25.
[58] Scott A J, Chiang C, Hall I M.2021. Structural variants are a major source of gene expression differences in humans and often affect multiple nearby genes[J]. Genome Research, 31(12): 2249-2257.
[59] Shabalin A A.2012. Matrix eQTL: Ultra fast eQTL analysis via large matrix operations[J]. Bioinformatics, 28(10): 1353-1358.
[60] Shen W K, Chen S Y, Gan Z Q, et al.2023. AnimalTFDB 4.0: A comprehensive animal transcription factor database updated with variation and expression annotations[J]. Nucleic Acids Research, 51(D1): D39-D45.
[61] Shi T, Wang F, Stieren E, et al.2005. SIRT3, a mitochondrial sirtuin deacetylase, regulates mitochondrial function and thermogenesis in brown adipocytes[J]. The Journal of Biological Chemistry, 280(14): 13560-13567.
[62] Sun W.2012. A statistical framework for eQTL mapping using RNA-seq data[J]. Biometrics, 68(1): 1-11.
[63] Tian J, Keller M P, Broman A T, et al.2016. The dissection of expression quantitative trait locus hotspots[J]. Genetics, 202(4): 1563-1574.
[64] Tian Y, Soupir A, Liu Q, et al.2021. Novel role of prostate cancer risk variant rs7247241 on PPP1R14A isoform transition through allelic TF binding and CpG methylation[J]. Human Molecular Genetics, 31(10): 1610-1621.
[65] Vialle R A, De Paiva Lopes K, Bennett D A, et al.2022. Integrating whole-genome sequencing with multi-omic data reveals the impact of structural variants on gene regulation in the human brain[J]. Nature Neuroscience, 25(4): 504-514.
[66] Võsa U, Claringbould A, Westra H-J, et al.2021. Large-scale cis- and trans-eQTL analyses identify thousands of genetic loci and polygenic scores that regulate blood gene expression[J]. Nature genetics, 53(9): 1300-1310.
[67] Wang K, Li M, Hakonarson H.2010. ANNOVAR: Functional annotation of genetic variants from high-throughput sequencing data[J]. Nucleic Acids Research, 38(16): e164.
[68] Wang L, Lu P, Yin J, et al.2022. Case report: Rare novel MIPEP compound heterozygous variants presenting with hypertrophic cardiomyopathy, severe lactic acidosis and hypotonia in a Chinese infant[J]. Frontiers in Cardiovascular Medicine, 9: 1095882.
[69] Wang Y, Ning C, Wang C, et al.2019. Genome-wide association study for intramuscular fat content in Chinese Lulai black pigs[J]. Asian-Australasian Journal of Animal Sciences, 32(5): 607-613.
[70] Wang Z, Shang P, Li Q, et al.2017. iTRAQ-based proteomic analysis reveals key proteins affecting muscle growth and lipid deposition in pigs[J]. Scientific Reports, 7: 46717.
[71] Wang H, Wang X, Li M, et al.2023. Genome-wide association study reveals genetic loci and candidate genes for meat quality traits in a four-way crossbred pig population[J]. Frontiers in Genetics, 14: 1001352.
[72] Wong J H, Shigemizu D, Yoshii Y, et al.2019. Identification of intermediate-sized deletions and inference of their impact on gene expression in a human population[J]. Genome Medicine, 11(1): 44.
[73] Xu K, Jin L, Xiong M.2017. Functional regression method for whole genome eQTL epistasis analysis with sequencing data[J]. BMC Genomics, 18(1): 385.
[74] Yao C, Joehanes R, Johnson A D, et al.2017. Dynamic role of trans regulation of gene expression in relation to complex traits[J]. American Journal of Human Genetics, 100(4): 571-580.
[75] Ye S, Li J, Zhang Z.2020. Multi-omics-data-assisted genomic feature markers preselection improves the accuracy of genomic prediction[J]. Journal of Animal Science and Biotechnology, 11(1): 109.
[76] Yuan Z, Sunduimijid B, Xiang R, et al.2021. Expression quantitative trait loci in sheep liver and muscle contribute to variations in meat traits[J]. Genetics, Selection, Evolution, 53(1): 8.
[77] Zeng B, Lloyd-Jones L R, Montgomery G W, et al.2019. Comprehensive multiple eQTL detection and its application to GWAS interpretation[J]. Genetics, 212(3): 905-918.
[78] Zha C W, Liu K Y, Wu J, et al.2023. Combining genome-wide association study based on low-coverage whole genome sequencing and transcriptome analysis to reveal the key candidate genes affecting meat color in pigs[J]. Animal Genetics, 54(3): 295-306.
[79] Zhao Y, Chen S, Yuan J, et al.2023. Comprehensive analysis of the lncRNA-miRNA-mRNA regulatory network for intramuscular fat in pigs[J]. Genes, 14(1): 168.
[80] Zhou X, Cai X.2021. Joint eQTL mapping and inference of gene regulatory network improves power of detecting both cis- and trans-eQTLs[J]. Bioinformatics, 38(1): 149-156.
[81] Zhu Z, Zhang F, Hu H, et al.2016. Integration of summary data from GWAS and eQTL studies predicts complex trait gene targets[J]. Nature Genetics, 48(5): 481-487.
[82] Zhuang Z, Wu J, Xu C, et al.2022. The genetic architecture of meat quality traits in a crossbred commercial pig population[J]. Foods, 11(19): 3143.