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1. Large-scale, multibreed, multitrait analyses of quantitative trait loci experiments: The case of porcine X chromosome

Author

Perez-Enciso, M., Mercade, A., Bidanel, J.P., Geldermann, H., Cepica, S., Bartenschlager, H., Varona, L., Milan, D., and Folch, J.M.

Subjects
Swine -- Genetic aspects, Swine -- Research, Genetic research, Zoology and wildlife conservation
Abstract

A QTL analysis of multibreed experiments (i.e., crossed populations involving more than two founder breeds) offers clear advantages over classical two-breed crosses, among them increased power and a more comprehensive coverage of the total genetic variability in the species. An alternative to designed multibreed crosses is to reanalyze jointly several experiments involving different breeds. We report a multibreed, multitrait QTL analysis of SSCX that involves five different crosses, six breeds, and almost 3,000 genotyped individuals using a truly multibreed strategy to allow for any number of founder breed origins. Traits analyzed were growth, fat thickness, car-cass length, and shoulder and ham weights. Generally, the joint analysis resulted in more significant QTL than the single-experiment analyses. We show that the QTL for fatness, which is highly significant (nominal P < [10.sup.-43]), is of Asiatic origin (Meishan). The next most significant QTL (nominal P < [10.sup.15]) affected ham weight and seems to be segregating only between Large White and the rest of the breeds. A multitrait, multi-QTL analysis suggests that these are two distinct loci. Additionally, a locus segregating only between Iberian and Landrace affects live weight. The advantages of joint, multibreed analyses clearly outweigh their potential risks. Key Words: Fatness, Growth, Pig, Quantitative Trait Locus, Sex Chromosome

Published
2005

7. Large-scale, multibreed, multitrait analyses of quantitative trait loci experiments: The case of porcine X chromosome1

Author

Denis Milan, Luis Varona, Hermann Geldermann, Jean Pierre Bidanel, Josep María Folch, Cepica S, Miguel Pérez-Enciso, H. Bartenschlager, and A. Mercadé

Subjects
Genetics, Live weight, Locus (genetics), Large white, General Medicine, Quantitative trait locus, Biology, Breed, Qtl analysis, Animal Science and Zoology, Genetic variability, X chromosome, Food Science
Abstract

A QTL analysis of multibreed experiments (i.e., crossed populations involving more than two founder breeds) offers clear advantages over classical two-breed crosses, among them increased power and a more comprehensive coverage of the total genetic variability in the species. An alternative to designed multibreed crosses is to reanalyze jointly several experiments involving different breeds. We report a multibreed, multitrait QTL analysis of SSCX that involves five different crosses, six breeds, and almost 3,000 genotyped individuals using a truly multibreed strategy to allow for any number of founder breed origins. Traits analyzed were growth, fat thickness, carcass length, and shoulder and ham weights. Generally, the joint analysis resulted in more significant QTL than the single-experiment analyses. We show that the QTL for fatness, which is highly significant (nominal P < 10 -43 ), is of Asiatic origin (Meishan). The next most significant QTL (nominal P < 10 -15 ) affected ham weight and seems to be segregating only between Large White and the rest of the breeds. A multitrait, multi-QTL analysis suggests that these are two distinct loci. Additionally, a locus segregating only between Iberian and Landrace affects live weight. The advantages of joint, multibreed analyses clearly outweigh their potential risks.

Published
2005

8. Assignment of the troponin C2 fast gene (TNNC2) to porcine chromosome bands 17q2.1· q2.2 by in situ hybridization

Author

Zambonelli, P., Davoli, R., Russo, V., Musilová, P., Antonin Stratil, Rubeš, J., Cepica, S., Zambonelli P., Davoli R., Russo V., Musilova P., Stratil A., Rubes J., and Cepica S.

Subjects
Male, pig, ISH, TNNC2, SSC17, Swine, Animals, macromolecular substances, Muscle, Skeletal, Troponin C, Chromosomes, In Situ Hybridization, Chromosome Banding
Abstract

Assignment of troponin C2, fast (TNNC2) gene to porcine chromosome bands 17q21-q22 by in situ hybridization

Published
2000

11. Length polymorphism in an intron of the porcine osteopontin (SPP1) gene is caused by the presence or absence of a SINE (PRE-1) element

Author

Cepica S, Antonín Stratil, J. Dvořák, and Aleš Knoll

Subjects
Genetics, Polymorphism, Genetic, biology, Swine, Sialoglycoproteins, Molecular Sequence Data, Intron, General Medicine, Molecular biology, Polymerase Chain Reaction, Introns, Pedigree, biology.protein, DNA Transposable Elements, Animals, Animal Science and Zoology, Osteopontin, Sine, Gene
Published
1999

12. Assignment of pig alpha-antichymotrypsin (AACT or P12) gene to chromosome region 7q23-q26

Author

Musilova, P., Lahbib Mansais, Yvette, Yerle, Martine, CEPICA, S., STRATIL, A., Coppieters, Wouter, RUBES, J., Laboratoire de Génétique Cellulaire (LGC), Institut National de la Recherche Agronomique (INRA)-Ecole Nationale Vétérinaire de Toulouse (ENVT), Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut National Polytechnique (Toulouse) (Toulouse INP), and Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées

Subjects
cartographie génétique, [SDV]Life Sciences [q-bio]
Abstract

Chantier qualité spécifique "Auteurs Externes" département de Génétique animale : uniquement liaison auteur au référentiel HR-Access; International audience

Published
1995

16. Linkage and QTL mapping for Sus scrofa chromosome 7

Author

Yue, G., primary, Stratil, A., additional, Cepica, S., additional, Schroffel, J., additional, Schroffelova, D., additional, Fontanesi, L., additional, Cagnazzo, M., additional, Moser, G., additional, Bartenschlager, H., additional, Reiner, G., additional, and Geldermann, H., additional

Published
2003
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17. Linkage and QTL mapping for Sus scrofa chromosome 9

Author

Cepica, S., primary, Schröffel, J., additional, Stratil, A., additional, Hojný, J., additional, Pierzchala, M., additional, Kuryl, J., additional, Brunsch, C., additional, Sternstein, I., additional, Davoli, R., additional, Fontanesi, L., additional, Reiner, G., additional, Bartenschlager, H., additional, Moser, G., additional, and Geldermann, H., additional

Published
2003
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19. Linkage and QTL mapping for Sus scrofa chromosome 6

Author

Yue, G., primary, Stratil, A., additional, Kopecny, M., additional, Schroffelova, D., additional, Schroffel, J., additional, Hojny, J., additional, Cepica, S., additional, Davoli, R., additional, Zambonelli, P., additional, Brunsch, C., additional, Sternstein, I., additional, Moser, G., additional, Bartenschlager, H., additional, Reiner, G., additional, and Geldermann, H., additional

Published
2003
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20. Linkage and QTL mapping for Sus scrofa chromosome 4

Author

Cepica, S., primary, Stratil, A., additional, Kopecny, M., additional, Blazkova, P., additional, Schroffel, J., additional, Davoli, R., additional, Fontanesi, L., additional, Reiner, G., additional, Bartenschlager, H., additional, Moser, G., additional, and Geldermann, H., additional

Published
2003
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27. Genome-wide linkage and QTL mapping in porcine F2 families generated from Pietrain, Meishan and Wild Boar crosses.

Author

Geldermann, H., Müller, E., Moser, G., Reiner, G., Bartenschlager, H., Cepica, S., Stratil, A., Kuryl, J., Moran, C., Davoli, R., and Brunsch, C.

Subjects
ANIMAL genetics, SWINE, GENOMES, GENE mapping
Abstract

Copyright of Journal of Animal Breeding & Genetics is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2003
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28. Ontogenetic Development of Creatine Phosphokinase in Skeletal Muscles and Heart from Pigs

Author

Cepica, S. and Jørgensen, P. Fogd

Abstract

Creatine Phosphokinase (CPK) in striated muscles shows only small changes in activity before birth. After birth and during the first month of extrauterine life the activity increases rapidly. The largest increase is seen in muscles with a glycolytic energy metabolism (m. long, dorsi) and the smallest in muscles with an oxydative energy metabolism (m. flexor dig. ped. sup.). The differences between these groups of muscles are statistically significant. In heart tissue the increase in CPK activity is lower, the levels amounting to 40 to 47 % of those in striated muscles.

Published
1977
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29. Regional localization of porcine MYOD1, MYF5, LEP, UCP3 and LCN1 genes

Author

Cepica, S., Yerle, M., Antonin Stratil, Schroffel, J., Redl, B., Laboratoire de Génétique Cellulaire (LGC), Institut National de la Recherche Agronomique (INRA)-Ecole Nationale Vétérinaire de Toulouse (ENVT), Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut National Polytechnique (Toulouse) (Toulouse INP), and Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées

Subjects
ADNC, [SDV.GEN]Life Sciences [q-bio]/Genetics
Abstract

Chantier qualité spécifique "Auteurs Externes" département de Génétique animale : uniquement liaison auteur au référentiel HR-Access; International audience

30. Status of Genome and QTL Mapping in Pigs Data of Hohenheim F2 Families

Author

Geldermann, H., Moser, G., Müller, E., Beeckmann, P., Yue, G., Dragos, M., Bartenschlager, H., Cepica, S., Antonin Stratil, and Schröffel, J.

Subjects
food and beverages
Abstract

Three informative F2 families (by use of European Wild boar (W), Pietrain (P) and Meishan (M)), each with more than 300 animals, were genotyped for evenly spaced marker loci and recorded for more than 100 quantitative traits. Linkage and QTL mapping data for 8 chromosomes are presented (74, 76 and 75 mapped loci in families WxP, MxP and WxM, resp). Linkage maps gave evidence of heterogeneity in recombination between sexes and families. The male to female recombination ratio were 1.19 (WxP), 1.35 (MxP) and 1.27 (WxM). Several QTLs were mapped for performance traits of growth, carcass and meat quality. These QTLs are located on different chromosomes and influenced by families. Larger effects were found on chromosome 6 and 7, and e.g. up to 60% of the phenotypic F2 variance for meat quality traits was associated with chromosome 6. Candidate genes are proposed for some of the QTL intervals. The subsequent QTL mapping use a combined strategy of genome-wide marker mapping with a positional candidate gene approach in order to identify genes which are significant for breeding.

31. Large-scale, multibreed, multitrait analyses of quantitative trait loci experiments: The case of porcine X chromosome

Author

Miguel Perez-Enciso, Mercadé A, Jp, Bidanel, Geldermann H, Cepica S, Bartenschlager H, Varona L, Milan D, Jm, Folch, Station de Génétique Quantitative et Appliquée (SGQA), Institut National de la Recherche Agronomique (INRA), Laboratoire de Génétique Cellulaire (LGC), Institut National de la Recherche Agronomique (INRA)-Ecole Nationale Vétérinaire de Toulouse (ENVT), Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut National Polytechnique (Toulouse) (Toulouse INP), and Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées

Subjects
Male, Likelihood Functions, Genotype, Models, Genetic, Swine, QTL, [SDV]Life Sciences [q-bio], Body Weight, Quantitative Trait Loci, X CHROMOSOME, Breeding, FATNESS, Adipose Tissue, Animals, Body Fat Distribution, GROWTH, Female, PIGS, ComputingMilieux_MISCELLANEOUS
Abstract

A QTL analysis of multibreed experiments (i.e., crossed populations involving more than two founder breeds) offers clear advantages over classical two-breed crosses, among them increased power and a more comprehensive coverage of the total genetic variability in the species. An alternative to designed multibreed crosses is to reanalyze jointly several experiments involving different breeds. We report a multibreed, multitrait QTL analysis of SSCX that involves five different crosses, six breeds, and almost 3,000 genotyped individuals using a truly multibreed strategy to allow for any number of founder breed origins. Traits analyzed were growth, fat thickness, carcass length, and shoulder and ham weights. Generally, the joint analysis resulted in more significant QTL than the single-experiment analyses. We show that the QTL for fatness, which is highly significant (nominal P10(-43)), is of Asiatic origin (Meishan). The next most significant QTL (nominal P10(-15)) affected ham weight and seems to be segregating only between Large White and the rest of the breeds. A multitrait, multi-QTL analysis suggests that these are two distinct loci. Additionally, a locus segregating only between Iberian and Landrace affects live weight. The advantages of joint, multibreed analyses clearly outweigh their potential risks.

33. Assignment<FOOTREF>[sup 1] </FOOTREF> of the troponin C2 fast gene (TNNC2) to porcine chromosome bands 17q2.1→q2.2 by in situ hybridization.

Author

Zambonelli, P., Davoli, R., Russo, V., Musiiová, P., Stratil, A., Rubeš, J., and Cepica, S.

Subjects
FLUORESCENCE in situ hybridization, GENE mapping, STRIATED muscle, TROPOMYOSINS, CALCIUM ions, HUMAN chromosomes
Abstract

The article discusses the localization of troponin C2 fast gene (TNNC2) to porcine chromosome bands 17q2.1->q2.2 by in situ hybridization. Contraction in striated muscle is regulated by the calcium-ion-sensitive complex of the three troponins (C, I, and T) and the fibrous protein tropomyosin. Troponin-C occurs in two distinct isoforms, fast skeletal troponin C is expressed exclusively in fast-twitch skeletal muscle (TNNC2), and slow or cardiac troponin-C (TNNC1) is expressed in both cardiac and slow-twitch skeletal muscle. In human, the TNNC2 gene has been mapped to chromosome 20q12->q13.11.

Published
2000
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34. The porcine ATPase, Ca++ transporting, plasma membrane 1 (ATP2B1) gene maps to chromosome band 5q23

Author

Stanislav Čepica, Vincenzo Russo, S Kubícková, Roberta Davoli, Justyna Anna Milc, Paolo Zambonelli, Jiri Rubes, Zambonelli P., Milc J., Davoli R., Russo V., Kubickova S., Rube J., and Cepica S.

Subjects
porcine ATPase, Swine, Calcium-Transporting ATPases, ATP2B1, Biology, pig, FISH, ATP2B1, SSC5, Ca++ transporting, Cell membrane, FISH, Genetics, medicine, Animals, Atpase ca, Gene map, Cell Membrane, Chromosome Mapping, General Medicine, Molecular biology, Cell biology, medicine.anatomical_structure, Chromosome Band, Membrane, Animal Science and Zoology
Abstract

The porcine ATPase, Ca++ transporting, plasma membrane 1 (ATP2B1) gene maps to chromosome band 5q23

Published
2001

35. Linkage and QTL mapping for Sus scrofa chromosome 6

Author

Roberta Davoli, D. Schröffelova, Paolo Zambonelli, H. Bartenschlager, Gerald Reiner, Antonín Stratil, I. Sternstein, J. Schröffel, H. Geldermann, C. Brunsch, Gen Hua Yue, J. Hojny, Gerhard Moser, M. Kopecny, Stanislav Čepica, Yue G., Stratil A., Kopecny M., Schroffelova D., Schroffel Jr. J., Hojny J., Cepica S., Davoli R., Zambonelli P., Brunsch C., Sternstein I., Moser G., Bartenschlager H., Reiner G., and Geldermann H.

Subjects
Genetics, food and beverages, Locus (genetics), General Medicine, Biology, Quantitative trait locus, musculoskeletal system, Stress resistance, pig, linkage map, chromosome 6, Food Animals, Genetic variation, Animal Science and Zoology, Carcass composition, Allele, tissues
Abstract

Linkage maps have been constructed for Sus scrofa chromosome 6 (SSC6) based on 17 markers, of which 10 were used in all three F 2 families of Wild Boar (W), Meishan (M) and Pietrain (P) crosses. The coverage of the linkage maps of SSC6 was almost complete. All loci were ordered identically in the families, but two intervals (RYR1-A1BG-EAH, S0146-S0003-SW824) differed from published maps. Major quantitative trait loci (QTLs) for meat quality, stress resistance and carcass composition explaining up to 59% of F 2 phenotypic variance have been mapped in the M x P and W x P families centred on the segregating RYR1 T and C alleles. In the W x M family, which was homozygous for the RYR1 C allele, no QTL effects for meat quality and stress-resistance, but moderate effects for carcass composition have been observed in this region. These findings indicate further loci closely linked with the RYR1 or/and further alleles at the RYR1 locus, involved in the variation of carcass and growth traits.

36. Porcine ubiquitin-like 5 (UBL5) gene: genomic organization, polymorphisms, mRNA cloning, splicing variants and association study.

Author

Masopust M, Weisz F, Bartenschlager H, Knoll A, Vykoukalová Z, Geldermann H, and Cepica S

Subjects
Animals, Cloning, Molecular, Female, Gene Order, Male, Promoter Regions, Genetic, Genetic Association Studies, Genome, Polymorphism, Genetic, RNA Splicing, RNA, Messenger, Swine genetics, Ubiquitins genetics
Abstract

Ubiquitin-like 5 (UBL5), which is supposed to be involved in regulation of feed intake, energy metabolism, obesity and type 2 diabetes, is located at position 62.1 cM on the pig chromosome 2 region harbouring quantitative trait loci for carcass and meat quality. The 4,354 bp genomic sequence (FR798948) of the porcine gene encompassing the promoter and entire gene was cloned by polymerase chain reaction. Comparative sequencing revealed 13 polymorphisms in noncoding regions. Synthesis of full-length cDNA sequences using rapid amplification of 5' and 3' ends showed three splice variants. Variants 1 and 2 differ in transcription length for the untranslated part of exon 1 with deduced protein of 73 amino acid (aa) residues and 100 % identities between human, mouse and other species. Variant 3, with 4 bp deletion at the 3' end of exon 2, encodes a truncated protein with 28 aa residues. In a Wild boar×Meishan F2 population (n = 334) with 47 recorded traits, loci FR798948:g.2788G>A and FR798948:g.2141T>C were associated at nominal P < 0.05 with fat deposition, growth and fattening and muscling but after adjustment for multiple testing (Benjamini and Hochberg, J R Stat Soc B 57:289-300, 1995) only eight fat deposition traits showed suggestive association with FR798948:g.2788G>A at adjusted P < 0.10. In a Meishan×Large White (MLW) cross (n = 562) with six trait records available, FR798948:g.2141T>C showed suggestive association with growth (adjusted P = 0.0690). As association mapping conducted in the outbred MLW population is more precise than in the three generation F2 population the UBL5 gene tends to be associated with growth rather than with fat accretion.

Published
2014
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37. Association mapping of quantitative trait loci for carcass and meat quality traits at the central part of chromosome 2 in Italian Large White pigs.

Author

Cepica S, Zambonelli P, Weisz F, Bigi M, Knoll A, Vykoukalová Z, Masopust M, Gallo M, Buttazzoni L, and Davoli R

Subjects
Animals, Body Weight, Breeding, Female, Hydrogen-Ion Concentration, Male, MyoD Protein genetics, Phenotype, Polymorphism, Single Nucleotide, Chromosome Mapping methods, Food Quality, Meat analysis, Quantitative Trait Loci, Swine genetics
Abstract

Association mapping of the central part of porcine chromosome 2 harboring QTLs for carcass and meat quality traits was performed with 17 gene-tagged SNPs located between 44.0 and 77.5 Mb on a physical map (Sscrofa10.2) in Italian Large White pigs. For the analyzed animals records of estimated breeding values for average daily gain, back fat thickness, lean cuts, ham weight, feed conversion ratio, pH1, pHu, CIE L*, CIE a*, CIE b* and drip loss were available. A significant QTL for fat deposition (adjusted P=0.0081) and pH1 (adjusted P=0.0972) to MYOD1 at position 44.4 Mb and a QTL for growth and meatiness (adjusted P=0.0238-0.0601) to UBL5 at position 68.9 Mb were mapped. These results from association mapping are much more accurate than those from linkage mapping and facilitate further search for position candidate genes and causative mutations needed for application of markers through marker assisted selection., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published
2013
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38. Association analyses of porcine SERPINE1 reveal sex-specific effects on muscling, growth, fat accretion and meat quality.

Author

Weisz F, Bartenschlager H, Knoll A, Mileham A, Deeb N, Geldermann H, and Cepica S

Subjects
Amino Acid Substitution, Animals, Chromosomes, Mammalian genetics, Cloning, Molecular, Fats metabolism, Gene Frequency, Male, Phenotype, Polymerase Chain Reaction, Sequence Analysis, DNA, Swine growth & development, Chromosome Mapping, Genetic Association Studies, Meat standards, Polymorphism, Single Nucleotide, Serpin E2 genetics, Swine genetics
Abstract

The serpin peptidase inhibitor, clade E (nexin, plasminogen activator inhibitor type 1), member 1 (SERPINE1) gene encodes plasminogen activator inhibitor type 1 (PAI), which is the major physiological inhibitor of tissue-type and urokinase-type plasminogen activators and plays a role in obesity and insulin resistance in women but not in men. We detected SNP FN396538:g.566G>A in intron 3 and a non-synonymous substitution NM&#95;213910:c.612A>G in exon 3 (p.Ile159Val) and mapped the gene to position 8.4 cM on the linkage map of chromosome 3. Association analyses were conducted on the 12th-15th generation of the Meishan × Large White (MLW) cross (n = 565), with records for weight at the end of test, lifetime daily gain, test time daily gain, loin depth and backfat depth, as well as on a European wild boar × Meishan (W × M) F(2) population (n = 333) with 47 traits recorded for carcass composition and meat quality. Analyses performed across the entire MLW population or in the male animals did not show any trait significantly associated with the loci studied. In female animals, both SNPs were associated with loin depth at nominal P < 0.05 with adjusted P values equal to 0.051 (g.566) and 0.057 (c.612). Differences between homozygotes were up to 0.65 SD. In the entire W × M population and female animals, SERPINE1 was significantly associated at adjusted P < 0.05 in descending order with muscling, growth and fat accretion and in male animals with meat quality (R-value). In the studied populations, allele effects were in opposite directions, which implies that the SNPs are markers that are in linkage disequilibrium with a causative mutation., (© 2011 The Authors, Animal Genetics © 2011 Stichting International Foundation for Animal Genetics.)

Published
2012
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39. Four genes located on a SSC2 meat quality QTL region are associated with different meat quality traits in Landrace × Chinese-European crossbred population.

Author

Cepica S, Ovilo C, Masopust M, Knoll A, Fernandez A, Lopez A, Rohrer GA, and Nonneman D

Subjects
Animals, Cloning, Molecular, Fats metabolism, Gene Frequency, Glucose metabolism, Male, Phenotype, Polymerase Chain Reaction, Sus scrofa growth & development, Chromosome Mapping, Genetic Association Studies, Meat standards, Polymorphism, Single Nucleotide, Quantitative Trait Loci, Sus scrofa genetics
Abstract

Several quantitative trait loci (QTL) for different meat quality traits have been localized on the q arm of porcine chromosome 2 at position 55-78 cM. Association analyses were performed in a commercial Landrace × Chinese-European (LCE) crossbred population (n = 446) slaughtered at approximately 127 kg and an average age of 198 days with records for performance (growth, fat and meat accretion) and meat quality [intramuscular fat (IMF), Minolta L*, Minolta a*, Minolta b* and pH at 45 m]. Polymorphisms within positional candidate genes cloned from homologous regions on human chromosome 19, ubiquitin-like 5 (UBL5- AM950288:g.566G>A), resistin (RETN- AM157180:g.1473A>G causing substitution p.Ala36Thr), insulin receptor (INSR- AM950289:g.589T>C) and complement factor D (adipsin) (CFD- AM950287:g. 306C>T) were located at positions 62.1, 64.0, 68.0 and 70.7 cM respectively on the current USDA USMARC map of porcine chromosome 2 and had the following allele frequencies in the LCE: UBL5 566G - 0.57; RETN 1473G - 0.84; INSR 589C - 0.70; and CFD 306C - 0.73. The effects of alleles within the candidate genes on the recorded traits were estimated using an animal model. Significant effects (P < 0.05) were found for pH(45) in m. semimembranosus (m. sm.) (UBL5), IMF (RETN) and Minolta L* (RETN, CFD). Differences between phenotypic means of homozygotes at UBL5, RETN and either RETN or CFD explained 0.34 SD for pH(45) in m. sm., 0.47 SD for IMF and 0.68 SD for Minolta L* respectively. Suggestive effects (P < 0.10) on IMF (UBL5, CFD), Minolta a* (INSR, CFD) and Minolta b* (INSR) were also observed. Our results support the localization of further QTL for meat quality traits in this region and suggest that there are several genes affecting different meat quality traits., (© 2011 The Authors, Animal Genetics © 2011 Stichting International Foundation for Animal Genetics.)

Published
2012
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40. Porcine insulin receptor substrate 4 (IRS4) gene: cloning, polymorphism and association study.

Author

Masopust M, Vykoukalová Z, Knoll A, Bartenschlager H, Mileham A, Deeb N, Rohrer GA, and Cepica S

Subjects
Animals, Base Sequence, Body Weights and Measures, Chromosome Mapping, Cloning, Molecular, DNA Primers genetics, Genome-Wide Association Study, Linear Models, Molecular Sequence Data, Polymerase Chain Reaction, Sequence Analysis, DNA, Sequence Homology, Insulin Receptor Substrate Proteins genetics, Phenotype, Polymorphism, Single Nucleotide genetics, Swine genetics
Abstract

Using PCR and inverse PCR techniques we obtained a 4,498 bp nucleotide sequence FN424076 encompassing the complete coding sequence of the porcine insulin receptor substrate 4 (IRS4) gene and its proximal promoter. The 1,269 amino acid porcine protein deduced from the nucleotide sequence shares 92% identity with the human IRS4 and possesses the same domains and the same number of tyrosine phosphorylation motifs as the human protein. We detected substitution FN424076:g.96C

Published
2011
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41. Porcine NAMPT gene: search for polymorphism, mapping and association studies.

Author

Cepica S, Bartenschlager H, Ovilo C, Zrůstová J, Masopust M, Fernández A, López A, Knoll A, Rohrer GA, Snelling WM, and Geldermann H

Subjects
Animals, Body Fat Distribution, Chromosome Mapping, Energy Metabolism, Female, Haplotypes genetics, Introns genetics, Male, Meat standards, Microsatellite Repeats, Muscle Development, Promoter Regions, Genetic, Sus scrofa growth & development, Genetic Association Studies methods, Linkage Disequilibrium genetics, Nicotinamide Phosphoribosyltransferase genetics, Polymorphism, Single Nucleotide genetics, Sus scrofa genetics
Abstract

NAMPT encodes an enzyme catalysing the rate-limiting step in NAD biosynthesis. The extracellular form of the enzyme is known as adipokine visfatin. We detected SNP AM999341:g.669T>C (referred to as 669T>C) in intron 9 and SNP FN392209:g.358A>G (referred to as 358A>G) in the promoter of the gene. RH mapping linked the gene to microsatellite SW944. Linkage analysis placed the gene on the current USDA – USMARC linkage map at position 92 cM on SSC9. Association analyses were performed in a wild boar × Meishan F2 family (W × M), with 45 traits recorded (growth and fattening, fat deposition, muscling, meat quality, stress resistance and other traits), and in a commercial Landrace × Chinese-European (LCE) synthetic population with records for 15 traits (growth, fat deposition, muscling, intramuscular fat, meat colour and backfat fatty acid content). In the W × M, SNP 669T>C was associated with muscling, fat deposition, growth and fattening, meat quality and other traits and in the LCE with muscling, meat quality and backfat fatty acid composition. In the W × M, SNP 358A>G was associated with muscling, fat deposition, growth and other traits. After correction for multiple testing, the NAMPT haplotypes were associated in the W × M with, in descending order, muscling (q = 0.0056), growth (q = 0.0056), fat deposition (q = 0.0109), fat-to-meat ratio (q = 0.0135), cooling losses (q = 0.0568) and longissimus pHU (q = 0.0695). The SNPs are hypothesized to be in linkage disequilibrium with a causative mutation affecting energy metabolism as a whole rather than fat metabolism alone.

Published
2010
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42. Genome-wide mapping of quantitative trait loci for fatness, fat cell characteristics and fat metabolism in three porcine F2 crosses.

Author

Geldermann H, Cepica S, Stratil A, Bartenschlager H, and Preuss S

Subjects
Animals, Chromosomes, Mammalian genetics, Female, Genetic Linkage, Genetic Markers, Male, Pedigree, Quantitative Trait, Heritable, Adipocytes metabolism, Adiposity genetics, Chromosome Mapping methods, Crosses, Genetic, Lipid Metabolism genetics, Quantitative Trait Loci genetics, Sus scrofa genetics
Abstract

Background: QTL affecting fat deposition related performance traits have been considered in several studies and mapped on numerous porcine chromosomes. However, activity of specific enzymes, protein content and cell structure in fat tissue probably depend on a smaller number of genes than traits related to fat content in carcass. Thus, in this work traits related to metabolic and cytological features of back fat tissue and fat related performance traits were investigated in a genome-wide QTL analysis. QTL similarities and differences were examined between three F2 crosses, and between male and female animals., Methods: A total of 966 F2 animals originating from crosses between Meishan (M), Pietrain (P) and European wild boar (W) were analysed for traits related to fat performance (11), enzymatic activity (9) and number and volume of fat cells (20). Per cross, 216 (MxP), 169 (WxP) and 195 (WxM) genome-wide distributed marker loci were genotyped. QTL mapping was performed separately for each cross in steps of 1 cM and steps were reduced when the distance between loci was shorter. The additive and dominant components of QTL positions were detected stepwise by using a multiple position model., Results: A total of 147 genome-wide significant QTL (76 at P<0.05 and 71 at P<0.01) were detected for the three crosses. Most of the QTL were identified on SSC1 (between 76-78 and 87-90 cM), SSC7 (predominantly in the MHC region) and SSCX (in the vicinity of the gene CAPN6). Additional genome-wide significant QTL were found on SSC8, 12, 13, 14, 16, and 18. In many cases, the QTL are mainly additive and differ between F2 crosses. Many of the QTL profiles possess multiple peaks especially in regions with a high marker density. Sex specific analyses, performed for example on SSC6, SSC7 and SSCX, show that for some traits the positions differ between male and female animals. For the selected traits, the additive and dominant components that were analysed for QTL positions on different chromosomes, explain in combination up to 23% of the total trait variance., Conclusions: Our results reveal specific and partly new QTL positions across genetically diverse pig crosses. For some of the traits associated with specific enzymes, protein content and cell structure in fat tissue, it is the first time that they are included in a QTL analysis. They provide large-scale information to analyse causative genes and useful data for the pig industry.

Published
2010
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43. Mapping of QTL on chromosome X for fat deposition, muscling and growth traits in a wild boar x Meishan F2 family using a high-density gene map.

Author

Cepica S, Bartenschlager H, and Geldermann H

Subjects
Animals, Chromosome Mapping, Female, Genetic Linkage, Genetic Markers, Male, Microsatellite Repeats, Muscle Development, Swine anatomy & histology, Swine growth & development, Body Fat Distribution, Quantitative Trait Loci, Swine genetics, X Chromosome
Abstract

Quantitative trait loci (QTL) for fat deposition, growth and muscling traits have been previously mapped on the basis of low-density linkage maps in a wild boar x Meishan F2family to the chromosome X region flanked by SW2456 and SW1943. Improved QTL resolution was possible using data for F2 animals with a marker density of 2.7 cM distance in the SW2456 to SW1943 region, including AR, SERPINA7 and ACSL4 as candidate genes. The resolution of the QTL scan was increased substantially, as evidenced by the higher F-ratio values for all QTL. Maxima of F-ratio values for fat deposition, muscling and growth traits were 28.6, 18.2 and 16.5 respectively, and those QTL positions accounted for 7.9%, 5.0% and 4.5% of the F2 phenotypic variance (VF2) respectively. QTL for fatness and growth and for most muscling traits mapped near ACSL4, with the exception of the QTL for ham traits that mapped proximally, in the vicinity of AR. An analysis performed separately for F2 male animals showed the predominant QTL affecting fat deposition traits (up to 13.6% VF2) near AR and two QTL for muscling traits (up to 9.9% VF2) mapped close to ACSL4. In the F2 female animals, QTL affecting muscling (up to 12.1% VF2) mapped at ACSL4 and SW2456, and QTL for fat deposition (10% VF2) and growth (up to 10.5% VF2) mapped at ACSL4.

Published
2007
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45. Linkage and RH mapping of the porcine adiponectin gene on chromosome 13.

Author

Cepica S, Masopust M, Knoll A, and Rohrer GA

Subjects
Adiponectin, Animals, Base Sequence, DNA Primers, Molecular Sequence Data, Sequence Analysis, DNA, Sequence Homology, Chromosome Mapping, Chromosomes, Mammalian genetics, Intercellular Signaling Peptides and Proteins genetics, Radiation Hybrid Mapping, Sus scrofa genetics
Published
2005
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46. Linkage mapping of the MC3R gene to porcine chromosome 17.

Author

Civánová K, Knoll A, Rohrer GA, and Cepica S

Subjects
Animals, Base Sequence, DNA Primers, Gene Frequency, Molecular Sequence Data, Sequence Analysis, DNA, Chromosome Mapping, Chromosomes, Mammalian genetics, Receptor, Melanocortin, Type 3 genetics, Sus scrofa genetics
Published
2004
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49. QTL alleles on chromosome 7 from fatty Meishan pigs reduce fat deposition.

Author

Yue G, Beeckmann P, Moser G, Müller E, Bartenschlager H, Cepica S, Schröffel J, Stratil A, and Geldermann H

Subjects
Alleles, Animals, Animals, Wild anatomy & histology, Animals, Wild genetics, Chromosome Mapping, Female, Hybridization, Genetic, Least-Squares Analysis, Male, Microsatellite Repeats, Models, Genetic, Species Specificity, Swine anatomy & histology, Swine genetics, Adiposity genetics, Quantitative Trait Loci, Sus scrofa anatomy & histology, Sus scrofa genetics
Abstract

For detecting QTL in the whole swine genome, 1068 pigs from three F2 populations constructed by crossing European Wild boar and Pietrain (W x P), Meishan and Pietrain (M x P), and Wild Boar and Meishan (W x M) were genotyped for genetic markers evenly spaced at approximately 20 cM intervals. AQTL analysis was performed using a least-squares method. Here the results of the QTL analysis on the porcine chromosome 7 are presented. QTL for carcass composition (e.g. head weight, carcass length, backfat depth, abdominal fat and bacon meat) were mapped in the chromosomal region CYPA/CYPD-TNFB-S0102 in M x P and W x M, but not in W x P. The QTL explained 5.3%-27.2% of the F2 phenotypic variance in the two F2 populations. Most traits affected by the mapped QTL were related to carcass fatness. The mode of gene action of QTL was additive. Surprisingly, in contrast to the parental phenotype, the QTL alleles from fatty Meishan were associated with thinner backfat than Pietrain and Wild Boar alleles, suggesting that the genome of the fatty Meishan pig contains genes which can reduce fat content of carcass substantially.

Published
2003
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