Pig QTL Database

Release 56
(Apr 24, 2025)

. . . from browsing trait ontology

References

On trait: Teat number

Arakawa A, Okumura N, Taniguchi M, Hayashi T, Hirose K, Fukawa K, Ito T, Matsumoto T, Uenishi H, Mikawa S (2015). Genome-wide association QTL mapping for teat number in a purebred population of Duroc pigs Animal genetics,46(5):571-5. [see all QTL by this paper]
Bidanel, J P; Rosendo, A; Iannuccelli, N; Riquet, J; Gilbert, H; Caritez, J C; Billon, Y; Amigues, Y; Prunier, A; Milan, D (2008). Detection of quantitative trait loci for teat number and female reproductive traits in Meishan x Large White F2 pigs Animal: an international journal of animal bioscience,813-20. [see all QTL by this paper]
Bovo S, Ballan M, Schiavo G, Ribani A, Tinarelli S, Utzeri V J, Dall'Olio S, Gallo M, Fontanesi L (2021). Single-marker and haplotype-based genome-wide association studies for the number of teats in two heavy pig breeds References,52(4):440-450. [see all QTL by this paper]
C. Rodriguez, A. Tomas, E. Alves, O. Ramirez, M. Arque, G. Munoz, C. Barragan, L. Varona, L. Silio, M. Amills, J.L. Noguera (2005). QTL mapping for teat number in an Iberian-by-Meishan pig intercross Animal Genetics,36: 490-496. [see all QTL by this paper]
Cassady JP, Johnson RK, Pomp D, Rohrer GA, Van Vleck LD, Spiegel EK, Gilson KM. (2001). Identification of quantitative trait loci affecting reproduction in pigs. J Anim Sci,Mar;79(3):623-33.. [see all QTL by this paper]
Chalkias H, Jonas E, Andersson LS, Jacobson M, de Koning DJ, Lundeheim N, Lindgren G (2017). Identification of novel candidate genes for the inverted teat defect in sows using a genome-wide marker panel Journal of applied genetics,58(2):249-259. [see all QTL by this paper]
Deng M, Qiu Z, Liu C, Zhong L, Fan X, Han Y, Wang R, Li P, Huang R, Zhao Q (2024). Genome-wide association analysis revealed new QTL and candidate genes affecting the teat number in Dutch Large White pigs Animal Genetics,55(2):206-216. [see all QTL by this paper]
Ding, Nengshui; Guo, Yuanmei; Knorr, Christoph; Ma, Junwu; Mao, Huirong; Lan, LÃ¼tao; Xiao, Shijun; Ai, Huashui; Haley, Chris S; (2009). Genome-wide QTL mapping for three traits related to teat number in a White Duroc x Erhualian pig resource population. BMC genetics, 10: 6. [see all QTL by this paper]
Duijvesteijn N, Veltmaat JM, Knol EF, Harlizius B (2014). High-resolution association mapping of number of teats in pigs reveals regions controlling vertebral development BMC genomics,15: 542. [see all QTL by this paper]
Fang F, Li J, Guo M, Mei Q, Yu M, Liu H, Legarra A, Xiang T (2022). Genomic evaluation and genome-wide association studies for total number of teats in a combined American and Danish Yorkshire pig populations selected in China Journal of animal science,100(7):skac174. [see all QTL by this paper]
G. Yue, J. Schröffel Jr., G. Moser, H. Bartenschlager, G. Reiner, H, Geldermann (2003). Linkage and QTL mapping for Sus scrofa chromosome 12. J Anim Breed Genet,120(1) 95-102. [see all QTL by this paper]
Guo, Y-M; Lee, G J; Archibald, A L; Haley, C S (2008). Quantitative trait loci for production traits in pigs: a combined analysis of two Meishan x Large White populations. Animal genetics,39 (5): 486-95. [see all QTL by this paper]
H. Geldermann, E. Muller, G. Moser, G. Reiner, H. Bartenschlager, S. Cepica, A. Stratil, J. Kuryl, C. Moran, R. Davoli and C. Brunsch (2003). Genome-wide linkage and QTL mapping in porcine F2 families. J Anim Breed Genet,120:363-393. [see all QTL by this paper]
Hernandez S C, Finlayson H A, Ashworth C J, Haley C S, Archibald A L (2014). A genome-wide linkage analysis for reproductive traits in F2 Large White × Meishan cross gilts Animal genetics,45(2):191-7. [see all QTL by this paper]
Hirooka H, de Koning DJ, Harlizius B, van Arendonk JA, Rattink AP, Groenen MA,Brascamp EW, Bovenhuis H. (2001). A whole-genome scan for quantitative trait loci affecting teat number in pigs. J Anim Sci,Sep;79(9):2320-6.. [see all QTL by this paper]
Holl, J W; Cassady, J P; Pomp, D; Johnson, R K (2004). A genome scan for quantitative trait loci and imprinted regions affecting reproduction in pigs. J Anim Sci,82 (12): 3421-9. [see all QTL by this paper]
Hong Y, Ye J, Dong L, Li Y, Yan L, Cai G, Liu D, Tan C, Wu Z (2021). Genome-Wide Association Study for Body Length, Body Height, and Total Teat Number in Large White Pigs Frontiers in Genetics,12: 650370. [see all QTL by this paper]
King AH, Jiang Z, Gibson JP, Haley CS, Archibald AL. (2003). Mapping quantitative trait loci affecting female reproductive traits on porcinechromosome 8. Biol Reprod.,Jun;68(6):2172-9. Epub 2003 Jan 22.. [see all QTL by this paper]
Lee J, Lee S, Park JE, Moon SH, Choi SW, Go GW, Lim D, Kim JM (2019). Genome-wide association study and genomic predictions for exterior traits in Yorkshire pigs Journal of animal science,97(7):2793-2802. [see all QTL by this paper]
Li Y, Pu L, Shi L, Gao H, Zhang P, Wang L, Zhao F (2021). Revealing New Candidate Genes for Teat Number Relevant Traits in Duroc Pigs Using Genome-Wide Association Studies Animals,11(3):806. [see all QTL by this paper]
Lisheng Zhou, Weimin Zhao, Yanfeng Fu, Xiaomin Fang, Shouwen Ren, Jun Ren (2019). Genome-wide detection of genetic loci and candidate genes for teat number and body conformation traits at birth in Chinese Sushan pigs animal genetics,Sept 2. [see all QTL by this paper]
Liu Z, Li H, Zhong Z, Jiang S (2022). A Whole Genome Sequencing-Based Genome-Wide Association Study Reveals the Potential Associations of Teat Number in Qingping Pigs Animals : an open access journal from MDPI,12(9):1057. [see all QTL by this paper]
Lopes MS, Bastiaansen JW, Harlizius B, Knol EF, Bovenhuis H (2014). A genome-wide association study reveals dominance effects on number of teats in pigs PloS one,9(8): e105867. [see all QTL by this paper]
M. Dragos-Wendrich, G. Moser, H. Bartenschlager, G. Reiner, H. Geldermann (2003). Linkage and QTL mapping for Sus scrofa chromosome 10. J Anim Breed Genet,120(1): 82-88. [see all QTL by this paper]
Moscatelli G, Dall'Olio S, Bovo S, Schiavo G, Kazemi H, Ribani A, Zambonelli P, Tinarelli S, Gallo M, Bertolini F, Fontanesi L (2020). Genome-wide association studies for the number of teats and teat asymmetry patterns in Large White pigs Anim Genet,51(4):595-600. [see all QTL by this paper]
Niu N, Wang H, Shi G, Liu X, Liu H, Liu Q, Yang M, Wang L, Zhang L (2021). Genome scanning reveals novel candidate genes for vertebral and teat number in the Beijing Black Pig Animal Genetics,52(5):734-738. [see all QTL by this paper]
NoskovÃ¡ A, Mehrotra A, Kadri NK, Lloret-Villas A, Neuenschwander S, Hofer A, Pausch H (2023). Comparison of two multi-trait association testing methods and sequence-based fine mapping of six additive QTL in Swiss Large White pigs BMC Genomics,24(1): 192. [see all QTL by this paper]
P. Beeckmann, G. Moser, H. Bartenschlager, G. Reiner, and H. Geldermann (2003). Linkage and QTL mapping for Sus scrofa chromosome 8. J Anim Breed Genet,120(1); 66-73. [see all QTL by this paper]
P. Beeckmann, J. Schröffel Jr, G. Moser, H. Bartenschlager, G. Reiner, and H. Geldermann (2003). Linkage and QTL mapping for Sus scrofa chromosome 1. J Anim Breed Genet,120(1):1-10. [see all QTL by this paper]
Park J, Do KT, Park KD, Lee HK (2023). Genome-wide association study using a single-step approach for teat number in Duroc, Landrace and Yorkshire pigs in Korea Animal Genetics,54(6):743-751. [see all QTL by this paper]
Rohrer GA. (2000). Identification of quantitative trait loci affecting birth characters andaccumulation of backfat and weight in a Meishan-White Composite resourcepopulation. J Anim Sci,Oct;78(10):2547-53.. [see all QTL by this paper]
Rohrer Gary A, Nonneman Dan J (2017). Genetic analysis of teat number in pigs reveals some developmental pathways independent of vertebra number and several loci which only affect a specific side Genetics, Selection, Evolution : GSE,49(1): 4. [see all QTL by this paper]
S. Cepica, G. Reiner, H. Bartenschlager, G. Moser, H. Geldermann (2003). Linkage and QTL mapping for Sus scrofa chromosome X. J Anim Breed Genet,120(1): 144-151. [see all QTL by this paper]
S. S. Lee, Y. Chen, C. Moran, A. Stratil, G. Reinder, H. Bartenschlager, G. Moser and H. Geldermann (2003). Linkage and QTL mapping for Sus scrofa chromosome 5. J Anim Breed Genet,120(1): 38-44. [see all QTL by this paper]
S. S. Lee, Y. Chen, C. Moran, S. Cepica, G. Reiner, H. Bartenschlager, G. Moser and H. Geldermann (2003). LInkage and QTL mapping for Sus scrofa chromosome 2. J Anim Breed Genet,120(1): 11-19. [see all QTL by this paper]
Sato, S; Atsuji, K; Saito, N; Okitsu, M; Sato, S; Komatsuda, A; Mitsuhashi, T; Nirasawa, K; Hayashi, T; Sugimoto, Y; Kobayashi, (2006). Identification of quantitative trait loci affecting corpora lutea and number of teats in a Meishan x Duroc F2 resource population. J Anim Sci,84 (11): 2895-901. [see all QTL by this paper]
Tan C, Wu Z, Ren J, Huang Z, Liu D, He X, Prakapenka D, Zhang R, Li N, Da Y, Hu X (2017). Genome-wide association study and accuracy of genomic prediction for teat number in Duroc pigs using genotyping-by-sequencing Genetics, Selection, Evolution : GSE,49(1): 35. [see all QTL by this paper]
Tang J, Zhang Z, Yang B, Guo Y, Ai H, Long Y, Su Y, Cui L, Zhou L, Wang X, Zhang H, Wang C, Ren J, Huang L, Ding N (2017). Identification of loci affecting teat number by genome-wide association studies on three pig populations Asian-Australasian journal of animal sciences,30(1): 1-7. [see all QTL by this paper]
Tortereau F, Gilbert H, Heuven HC, Bidanel JP, Groenen MA, Riquet J (2010). Combining two Meishan F2 crosses improves the detection of QTL on pig chromosomes 2, 4 and 6. Genetics, Selection, Evolution : GSE,42: 42. [see all QTL by this paper]
Uzzaman MR, Park JE, Lee KT, Cho ES, Choi BH, Kim TH (2018). Whole-genome association and genome partitioning revealed variants and explained heritability for total number of teats in a Yorkshire pig population Asian-Australasian journal of animal sciences,31(4): 473-479. [see all QTL by this paper]
van Son M, Lopes MS, Martell HJ, Derks MFL, Gangsei LE, Kongsro J, Wass MN, Grindflek EH, Harlizius B (2019). A QTL for Number of Teats Shows Breed Specific Effects on Number of Vertebrae in Pigs: Bridging the Gap Between Molecular and Quantitative Genetics Frontiers in genetics,10: 272. [see all QTL by this paper]
Verardo L L, Lopes M S, Wijga S, Madsen O, Silva F F, Groenen M A M, Knol E F, Lopes P S, GuimarÃ£es S E F (2017). After genome-wide association studies: Gene networks elucidating candidate genes divergences for number of teats across two pig populations Journal of animal science,94(4): 1446-58. [see all QTL by this paper]
Verardo L L, Silva F F, Varona L, Resende M D V, Bastiaansen J W M, Lopes P S, Guimarães S E F (2014). Bayesian GWAS and network analysis revealed new candidate genes for number of teats in pigs Journal of applied genetics,56(1):123-32. [see all QTL by this paper]
Verardo LL, Silva FF, Lopes MS, Madsen O, Bastiaansen JWM, Knol EF, Kelly M, Varona L, Lopes PS, Guimarães SEF (2016). Revealing new candidate genes for reproductive traits in pigs: combining Bayesian GWAS and functional pathways Genetics, Selection, Evolution : GSE,48(1): 9. [see all QTL by this paper]
Wada Y, Akita T, Awata T, Furukawa T, Sugai N, Inage Y, Ishii K, Ito Y,Kobayashi E, Kusumoto H, Matsumoto T, Mikawa S, Miyake M, (2000). Quantitative trait loci (QTL) analysis in a Meishan x Gottingen crosspopulation. Animal Genetics,Dec;31(6):376-84.. [see all QTL by this paper]
Wang L, Zhang Y, Zhang T, Zhang L, Yan H, Liu X, Wang L (2017). Genotyping by sequencing reveals a new locus for pig teat number Animal Genetics,48(4): 470-472. [see all QTL by this paper]
Wei J, Sun J, Pan Y, Cao M, Wang Y, Yuan T, Guo A, Han R, Ding X, Yang G, Yu T, Ding R (2024). Revealing genes related teat number traits via genetic variation in Yorkshire pigs based on whole-genome sequencing BMC genomics,25(1): 1217. [see all QTL by this paper]
Xu RX, Wei N, Wang Y, Wang GQ, Yang GS, Pang WJ (2014). Association of Novel Polymorphisms in Lymphoid Enhancer Binding Factor 1 (LEF-1) Gene with Number of Teats in Different Breeds of Pig Asian-Australasian journal of animal sciences,27(9): 1254-62. [see all QTL by this paper]
Xu Z, Lin Q, Cai X, Zhong Z, Teng J, Li B, Zeng H, Gao Y, Cai Z, Wang X, Shi L, Wang X, Wang Y, Zhang Z, Lin Y, Liu S, Yin H, Bai Z, Wei C, Zhou J, Zhang W, Zhang X, Shi S, Wu J, Diao S, Liu Y, Pan X, Feng X, Liu R, Su Z, Chang C, Zhu Q, Wu Y, The PigGTEx Consortium, Zhou Z, Bai L, Li K, Wang Q, Pan Y, Xu Zhong, Peng X, Mei S, Mo D, Liu X, Zhang H, Yuan X, Liu Y, Liu G, Su G, Sahana G, Lund MS, Ma L, Xiang R, Shen X, Li P, Huang R, Ballester M, Piazuelo DC, Amills M, Clop A, Mortensen PK, Fredholm M, Tang G, Li M, Li X, Ding X, Li J, Chen Y, Zhang Q, Zhao Y, Zhao F, Fang L, Zhang Z (2024). Integrating large-scale meta-GWAS and PigGTEx resources to decipher the genetic basis of 232 complex traits in pigs. bioRxiv,. [see all QTL by this paper]
Yang L, Li X, Zhuang Z, Zhou S, Wu J, Xu C, Ruan D, Qiu Y, Zhao H, Zheng E, Cai G, Wu Z, Yang J. (2023). Genome-Wide Association Study Identifies the Crucial Candidate Genes for Teat Number in Crossbred Commercial Pigs Animals : an open access journal from MDPI,13(11):1880. [see all QTL by this paper]
Yang R, Guo X, Zhu D, Tan C, Bian C, Ren J, Huang Z, Zhao Y, Cai G, Liu D, Wu Z, Wang Y, Li N, Hu X (2021). Accelerated deciphering of the genetic architecture of agricultural economic traits in pigs using a low-coverage whole-genome sequencing strategy GigaScience,10(7):giab048. [see all QTL by this paper]
Zhang, J; Xiong, Y; Zuo, B; Lei, M; Jiang, S; Li, F; Zheng, R; Li, J; Xu, D (2007). Detection of quantitative trait loci associated with several internal organ traits and teat number trait in a pig population. Journal of genetics and genomics (Yi chuan xue bao),34 (4): 307-14. [see all QTL by this paper]
Zhuang Z, Ding R, Peng L, Wu J, Ye Y, Zhou S, Wang X, Quan J, Zheng E, Cai G, Huang W, Yang J, Wu Z (2020). Genome-wide Association Analyses Identify Known and Novel Loci for Teat Number in Duroc Pigs Using Single-Locus and Multi-Locus Models BMC Genomics,21(1):344. [see all QTL by this paper]