Fine mapping of quantitative trait loci affecting female fertility in dairy cattle on BTA03 using a dense single-nucleotide polymorphism map.

Druet, Tom; Fritz, Sebastien; Boussaha, Mekki; Ben-Jemaa, Slim; Guillaume, F.; Derbala, David; Zelenika, Diana; Lechner, Doris; Charon, Celine; Boichard, Didier; Gut, Ivo G; Eggen, Andre; Gautier, Mathieu

doi:10.1534/genetics.107.085035

Article (Scientific journals)

Fine mapping of quantitative trait loci affecting female fertility in dairy cattle on BTA03 using a dense single-nucleotide polymorphism map.

Druet, Tom; Fritz, Sebastien; Boussaha, Mekki et al.

2008 • In Genetics, 178 (4), p. 2227-35

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https://hdl.handle.net/2268/10089

DOI
10.1534/genetics.107.085035

PubMed
18430945

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Keywords :

Alleles; Animals; Base Sequence; Cattle/genetics; Chromosomes, Mammalian/genetics; Female; Fertility/genetics; Haplotypes; Heterozygote; Linkage Disequilibrium/genetics; Molecular Sequence Data; Physical Chromosome Mapping; Polymorphism, Single Nucleotide/genetics; Quantitative Trait Loci/genetics

Abstract :

[en] Fertility quantitative trait loci (QTL) are of high interest in dairy cattle since insemination failure has dramatically increased in some breeds such as Holstein. High-throughput SNP analysis and SNP microarrays give the opportunity to genotype many animals for hundreds SNPs per chromosome. In this study, due to these techniques a dense SNP marker map was used to fine map a QTL underlying nonreturn rate measured 90 days after artificial insemination previously detected with a low-density microsatellite marker map. A granddaughter design with 17 Holstein half-sib families (926 offspring) was genotyped for a set of 437 SNPs mapping to BTA3. Linkage analysis was performed by both regression and variance components analysis. An additional analysis combining both linkage analysis and linkage-disequilibrium information was applied. This method first estimated identity-by-descent probabilities among base haplotypes. These probabilities were then used to group the base haplotypes in different clusters. A QTL explaining 14% of the genetic variance was found with high significance (P < 0.001) at position 19 cM with the linkage analysis and four sires were estimated to be heterozygous (P < 0.05). Addition of linkage-disequilibrium information refined the QTL position to a set of narrow peaks. The use of the haplotypes of heterozygous sires offered the possibility to give confidence in some peaks while others could be discarded. Two peaks with high likelihood-ratio test values in the region of which heterozygous sires shared a common haplotype appeared particularly interesting. Despite the fact that the analysis did not fine map the QTL in a unique narrow region, the method proved to be able to handle efficiently and automatically a large amount of information and to refine the QTL position to a small set of narrow intervals. In addition, the QTL identified was confirmed to have a large effect (explaining 13.8% of the genetic variance) on dairy cow fertility as estimated by nonreturn rate at 90 days.

Disciplines :

Animal production & animal husbandry
Genetics & genetic processes

Author, co-author :

Druet, Tom ; Institut Scientifique de Recherche Agronomique - INRA > Département de Génétique Animale > Station de Génétique Quantitative et Appliquée

Fritz, Sebastien

Boussaha, Mekki

Ben-Jemaa, Slim

Guillaume, F.

Derbala, David

Zelenika, Diana

Lechner, Doris

Charon, Celine

Boichard, Didier

More authors (3 more)

Language :

English

Title :

Fine mapping of quantitative trait loci affecting female fertility in dairy cattle on BTA03 using a dense single-nucleotide polymorphism map.

Publication date :

2008

Journal title :

Genetics

ISSN :

0016-6731

eISSN :

1943-2631

Publisher :

Genetics Society of America, Baltimore, United States - Maryland

Volume :

178

Issue :

Pages :

2227-35

Peer reviewed :

Peer Reviewed verified by ORBi

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since 07 May 2010

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Bibliography

BLOTT, S., J. J. KIM, S. MOISIO, A. SCHMIDT-KUNTZEL, A. CORNET et al., 2003 Molecular dissection of a quantitative trait locus: a phenylalanine-to-tyrosine substitution in the transmembrane domain of the bovine growth hormone receptor is associated with a major effect on milk yield and composition. Genetics 163: 253-266.
CHURCHILL, G. A., and R. W. DOERGE, 1994 Empirical threshold value for quantitative trait mapping. Genetics 138: 963-971.
COHEN-ZINDER, M., E. SEROUSSI, D. M. LARKIN, J. J. LOOR, A. EVERTS-VAN DER WIND et al., 2005 Identification of a missense mutation in the bovine ABCG2 gene with a major effect on the QTL on chromosome 6 affecting milk yield and composition in Holstein cattle. Genome Res. 15: 936-944.
FERNANDO, R., and M. GROSSMAN, 1989 Marked assisted selection using best linear unbiased prediction. Genet. Sel. Evol. 21: 467-477.
GAUTIER, M., R. R. BARCELONA, S. FRITZ, C. GROHS, T. DRUET et al., 2006 Fine mapping and physical characterization of two linked quantitative trait loci affecting milk fat yield in dairy cattle on BTA26. Genetics 172: 425-436.
GAUTIER, M., T. FARAUT, K. MOAZAMI- GOUDARZI, V. NAVRATIL, M. FOGLIO et al., 2007 Genetic and haplotypic structure in 14 European and African cattle breeds. Genetics 177: 1059-1070.
GEORGE, A. W., P. M. VISSCHER and C. S. HALEY, 2000 Mapping quantitative trait loci in complex pedigrees: a two-step variance component approach. Genetics 156: 2081-2092.
GEORGES, M., D. NIELSEN, M. MACKINNON, A. MISHRA, R. OKIMOTO et al., 1995 Mapping quantitative trait loci controlling milk production in dairy cattle by exploiting progeny testing. Genetics 139: 907-920.
GRAPES, L. M., J. C. FIRAT, J. C. DEKKERS, M. F. ROTSCHILD and R. L. FERNANDO, 2006 Optimal haplotype structure for linkage disequilibrium-based fine mapping of quantitative trait loci using identity by descent. Genetics 172: 1955-1965.
GRIGNOLA, F. E., I. HOESCHELE and B. TIER, 1996a Mapping quantitative trait loci in outcross populations via residual maximum likelihood. I. Methodology. Genet. Sel. Evol. 28: 479-490.
GRIGNOLA, F. E., I. HOESCHELE, Q. ZHANG and G. THALLER, 1996b Mapping quantitative trait loci in outcross populations via residual maximum likelihood. II. A simulation study. Genet. Sel. Evol. 28: 491-504.
GRISART, B., W. COPPIETERS, F. FARNIR, L. KARIM, C. FORD et al., 2002 Positional candidate cloning of a QTL in dairy cattle: identification of a missense mutation in the bovine DGAT1 gene with major effect on milk yield and composition. Genome Res. 12: 222-231.
GUILLAUME, F., M. GAUTIER, S. BEN JEMAA, S. FRITZ, A. EGGEN et al., 2007 Refinement of two female fertility QTL using alternative phenotypes in French Holstein dairy cattle. Anim. Genet. 38: 72-74.
JENSEN, J., E. A. MANTYSAARI, P. MADSEN and R. THOMPSON, 1996 Residual maximum likelihood estimation of (co)variance components in multivariate mixed linear models using average information. J. Ind. Soc. Agric. Stat. 49: 215-236.
KHATKAR, M. S., P. C. THOMSON, I. TAMMEN and H. W. RAADSMA, 2004 Quantitative trait loci mapping in dairy cattle: review and meta-analysis. Genet. Sel. Evol. 36: 163-190.
KHATKAR, M. S., P. C. THOMSON, I. TAMMEN, J. A. CAVANAGH, F. W. NICHOLAS et al., 2006 Linkage disequilibrium on chromosome 6 in Australian Holstein-Friesian cattle. Genet. Sel. Evol. 38: 463-477.
KHATKAR, M. S., K. R. ZENGER, M. HOBBS, R. J. HAWKEN, J. A. CAVANAGH et al., 2007 A primary assembly of a bovine haplotype block map based on a 15,036-single-nucleotide polymorphism panel genotyped in Holstein-Friesian cattle. Genetics 176: 763-772.
KIM, J. J., and M. GEORGES, 2002 Evaluation of a new fine-mapping method exploiting linkage disequilibrium: a case study analysing a QTL with major effect on milk composition on bovine chromosome 14. Asian-Aust. J. Anim. Sci. 15: 1250-1256.
KNOTT, S. A., J. M. ELSEN and C. S. HALEY, 1996 Methods for multiple marker mapping of quantitative trait loci in half-sib populations. Theor. Appl. Genet. 93: 71-80.
MEUWISSEN, T. H., and M. E. GODDARD, 2000 Fine mapping of quantitative trait loci using linkage disequilibria with closely linked marker loci. Genetics 155: 421-430.
MEUWISSEN, T. H., and M. E. GODDARD, 2001 Prediction of identity by descent probabilities from marker-haplotypes. Genet. Sel. Evol. 33: 605-634.
MEUWISSEN, T. H., and M. E. GODDARD, 2004 Mapping multiple QTL using linkage disequilibrium and linkage analysis information and multitrait data. Genet. Sel. Evol. 36: 261-279.
MEUWISSEN, T. H., A. KARLSEN, S. LIEN, I. OLSAKER and M. E. GODDARD, 2002 Fine mapping of a quantitative trait locus for twinning rate using combined linkage and linkage disequilibrium mapping. Genetics 161: 373-379.
MISZTAL, I., T. TSURUTA, T. STRABEL, B. AUVRAY, T. DRUET, 2002 BLUPF90 and related programs (BGF90). 7th World Congress on Genetics Applied to Livestock Production, Montpellier, France, Communication no. 28-07.
NEZER, C., C. COLLETTE, L. MOREAU, B. BROUWERS, J. J. KIM et al., 2003 Haplotype sharing refines the location of an imprinted quantitative trait locus with major effect on muscle mass to a 250-kb chromosome segment containing the porcine IGF2 gene. Genetics 165: 277-285.
OLSEN, H. G., S. LIEN, M. GAUTIER, H. NILSEN, A. ROSETH et al., 2005 Mapping of a milk production quantitative trait locus to a 420-kb region on bovine chromosome 6. Genetics 169: 275-283.
PONG-WONG, R., A. W. GEORGE, J. A. WOOLLIAMS and C. S. HALEY, 2001 A simple and rapid method for calculating identity-by-descent matrices using multiple markers. Genet. Sel. Evol. 33: 453-471.
QIAN, D., and L. BECKMANN, 2002 Minimum-recombinant haplotyping in pedigrees. Am. J. Hum. Genet. 70: 1434-1445.
RIQUET, J., W. COPPIETERS, N. CAMBISANO, J. J. ARRANZ, P. BERZI et al., 1999 Fine-mapping of quantitative trait loci by identity by descent in outbred populations: application to milk production in dairy cattle. Proc. Natl. Acad. Sci. USA 96: 9252-9257.
VANRADEN, P. M., and G. R. WIGGANS, 1991 Derivation, calculation, and use of national animal model information. J. Dairy Sci. 74: 2737-2746.
WINDIG, J. J., and T. H. E. MEUWISSEN, 2004 Rapid haplotype reconstruction in pedigrees with dense marker maps. J. Anim. Breed. Genet. 121: 26-39.
YTOURNEL, F., H. GILBERT and D. BOICHARD, 2007 Concordance between IBD probabilities and linkage disequilibrium. 58th Annual Meeting of the European Association of Animal Production, Dublin, Ireland.
ZHAO, H. H., R. L. FERNANDO and J. C. DEKKERS, 2007 Power and precision of alternate methods for linkage disequilibrium mapping of quantitative trait loci. Genetics 175: 1975-1986.