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4. Genetic Studies and Breed Diversity of Kazakh Native Horses: A Comprehensive Review.

Author

Kabylbekova, D., Assanbayev, T. S., Kassymbekova, Shinara, and Kantanen, J.

Subjects
HORSE breeding, ANIMAL science, SUSTAINABILITY, ANIMAL culture, EDUCATION research
Abstract

This comprehensive review analyzes the state of horse breeding in Kazakhstan, examining its historical context, current status, genetic studies, and future prospects. Drawing on historical records, government reports, academic studies, and genetic research, this review provides insights into the genetic diversity of Kazakh native horse breeds. The review traces the historical trajectory of horse breeding, explores its significance for the economy and culture, and discusses current population trends. Genetic studies reveal untapped potential for breed improvement. Kazakhstan's horse breeding faces opportunities for growth and development, requiring efforts to increase the horse population and harness genetic potential for productivity. This review emphasizes the need to preserve the gene pool of Kazakh native horses, ensuring sustainability and cultural significance. [ABSTRACT FROM AUTHOR]

Published
2024

5. Y-chromosomal haplogroups from wild and domestic goats reveal ancient migrations and recent introgressions

Author

Lenstra, J.A., Consortium, VarGoats, Nijman, I.J., Rosen, B.D., Bardou, P., Faraut, T., Cumer, T., Daly, K.G., Zheng, Z., Cai, Y., Asadollahpour, H., Kul, Çınar B., Zhang, W.-Y., E, G., Ayin, A., Bakhtin, M., Balteanu, V.A., Barfield, D., Baird, H., Berger, B., Blichfeldt, T., Boink, G., Bugiwati, S.R.A., Cai, Z., Carolan, S., Clark, E., Cubric-Curik, V., Dagong, M.I.A., Dorji, T., Drew, L., Guo, J., Hallsson, J., Horvat, S., Kantanen, J., Kawaguchi, F., Kazymbet, P., Khayatzadeh, N., Kim, N., Kumar Shah, M., Liao, Y., Martínez, A., Masangkay, J.S., Masaoka, M., Mazza, R., McEwan, J., Milanesi, M., Omar, F.Md., Nomura, Y., Ouchene-Khelifi, N.-A., Pereira, F., Sahana, G., Sasazaki, S., Da Silva, A., Simčič, M., Sölkner, J., Sutherland, A., Tigchelaar, J., Zhang, H., Consortium, Econogene, Ajmone-Marsan, P., Bradley, D.G., Colli, L., Drögemüller, C., Lei, C., Mannen, H., Pompanon, F., Tosser-Klopp, G., Jiang, Y., Veerkamp, R. F., and de Haas, Y.

Subjects
630 Agriculture, 590 Animals (Zoology), 570 Life sciences, biology
Abstract

By its paternal transmission, Y-chromosomal haplotypes are sensitive markers of population history and male-mediated introgression. We used whole-genome sequences (WGSs) of 386 domestic goats from 75 modern breeds and 7 wild goat species generated by the VarGoats goat genome project. Phylogenetic analyses indicated five domestic haplogroups Y1AA, Y1AB, Y1B, Y2A and Y2B. Haplogroup distributions for 180 domestic breeds indicate ancient paternal population bottlenecks during the migration into northern Europe, southern Asia and Africa. Sharing of haplogroups reveals male-mediated introgressions: from Asia into Madagascar and, more recently, into the South-African Boer goat; then from this breed into other southeastern African goats; and from Europe into native Korean and Ugandan goats. This study illustrates the power of the Y-chromosomal variation for the reconstructing the history of domestic species with a wide geographic range.

Published
2023
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9. Geographical contrasts of Y-chromosomal haplogroups from wild and domestic goats reveal ancient migrations and recent introgressions

Author

Nijman, I. J., Rosen, B. D., Bardou, P., Faraut, T., Cumer, T., Daly, K. G., Zheng, Z., Cai, Y., Asadollahpour, H., Kul, B. C., Zhang, W. -Y., Guangxin, E., Ayin, A., Baird, H., Bakhtin, M., Balteanu, V. A., Barfield, D., Berger, B., Blichfeldt, T., Boink, G., Bugiwati, S. R. A., Cai, Z., Carolan, S., Clark, E., Cubric-Curik, V., Dagong, M. I. A., Dorji, T., Drew, L., Guo, J., Hallsson, J., Horvat, S., Kantanen, J., Kawaguchi, F., Kazymbet, P., Khayatzadeh, N., Kim, N., Shah, M. K., Liao, Y., Martinez, A., Masangkay, J., Masaoka, M., Mazza, R., Mcewan, J., Milanesi, M., Omar, F. M., Nomura, Y., Ouchene-Khelifi, N. -A., Pereira, F., Sahana, G., Salavati, M., Sasazaki, S., Da Silva, A., Simcic, M., Solkner, J., Sutherland, A., Tigchelaar, J., Zhang, H., Ajmone-Marsan, P., Bradley, D. G., Colli, L., Drogemuller, C., Jiang, Y., Lei, C., Mannen, H., Pompanon, F., Tosser-Klopp, G., Lenstra, J. A., Kijas, J., Guldbrandtsen, B., Denoyelle, L., Sarry, J., le Talouarn, E., Alberti, A., Orvain, C., Engelen, S., Duby, D., Martin, P., Danchin, C., Duclos, D., Allain, D., Arquet, R., Mandonnet, N., Naves, M., Palhiere, I., Rupp, R., Rezaei, H. R., Foran, M., Stella, A., Del Corvo, M., Crisa, A., Marletta, D., Crepaldi, P., Ottino, M., Randi, E., Mujibi, D. F., Gondwe, T., Benjelloun, B., Taela, M. D. G., Nash, O., Moaeen-ud-Din, M., Visser, C., Goyache, F., Alvarez, I., Amills, M., Sanchez, A., Capote, J., Jordana, J., Pons, A., Balears, I., Molina, A., Mruttu, H. A., Masiga, C. W., Van Tassell, C. P., Reecy, J., Luikart, G., Sikosana, J., Anila, H., Petrit, D., Roswitha, B., Philippe, B., Aziz, F., Christos, P., El-Barody, M. A. A., Pierre, T., Phillip, E., Gordon, L., Albano, B. -P., Stephanie, Z., Michel, T., Georg, E., Horst, B., Eveline, I. -A., Luhken, G., Krugmann, D., Eva-Maria, P., Shirin, L., Katja, G., Christina, P., Jutta, R., Marco, B., Andreas, G., Al Tarrayrah, J., Georgios, K., Olga, K., Katerina, K., Christina, L., Anton, I., Lazlo, F., Gabriele, C., Elisabetta, M., Marco, P., Antonello, C., Tiziana, S., Mario, C., Francesca, F., Stefano, G., Marta, M., Bordonaro, S., Giuseppe, D. U., Fabio, P., Mariasilvia, D. A., Alessio, V., Irene, C., Lorraine, P., Mahamoud, A. -S., Van Cann, L. M., Roman, N., Popielarczyk, D., Ewa, S., Augustin, V., Susana, D., Javier, C., Oscar, C., David, G., Regis, C., Gabriela, O. -R., Glowatzki, M. -L., Okan, E., Inci, T., Evren, K., Mike, B., Trinidad, P., Gabriela, J., Godfrey, H., Stella, D., Louise, W., Martin, T., Sam, J., and Riccardo, S.

Subjects
haplogroup, introgresija, domestication, goat, introgression, migration, phylogeography, Y-chromosome, Evolution, MITOCHONDRIAL-DNA, FLOW, Haplotypes/genetics, divje koze, DNA, Mitochondrial, DNA, Mitochondrial/genetics, Behavior and Systematics, BREEDS, Y Chromosome, Goats/genetics, Genetics, Animals, domače koze, Ecology, Evolution, Behavior and Systematics, Phylogeny, udc:575:636.39, kozorogi, Ecology, 630 Agriculture, Goats, Genetic Variation, NETWORKS, DIFFERENTIATION, genetika, Haplotypes, ORIGINS, GENETIC DIVERSITY, 590 Animals (Zoology), 570 Life sciences, biology, Y Chromosome/genetics
Abstract

By their paternal transmission, Y-chromosomal haplotypes are sensitive markers of population history and male-mediated introgression. Previous studies identified biallelic single-nucleotide variants in the SRY, ZFY and DDX3Y genes, which in domestic goats identified four major Y-chromosomal haplotypes, Y1A, Y1B, Y2A and Y2B, with a marked geographical partitioning. Here, we extracted goat Y-chromosomal variants from whole-genome sequences of 386 domestic goats (75 breeds) and seven wild goat species, which were generated by the VarGoats goat genome project. Phylogenetic analyses indicated domestic haplogroups corresponding to Y1B, Y2A and Y2B, respectively, whereas Y1A is split into Y1AA and Y1AB. All five haplogroups were detected in 26 ancient DNA samples from southeast Europe or Asia. Haplotypes from present-day bezoars are not shared with domestic goats and are attached to deep nodes of the trees and networks. Haplogroup distributions for 186 domestic breeds indicate ancient paternal population bottlenecks and expansions during migrations into northern Europe, eastern and southern Asia, and Africa south of the Sahara. In addition, sharing of haplogroups indicates male-mediated introgressions, most notably an early gene flow from Asian goats into Madagascar and the crossbreeding that in the 19th century resulted in the popular Boer and Anglo-Nubian breeds. More recent introgressions are those from European goats into the native Korean goat population and from Boer goat into Uganda, Kenya, Tanzania, Malawi and Zimbabwe. This study illustrates the power of the Y-chromosomal variants for reconstructing the history of domestic species with a wide geographical range.

Published
2022
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12. Microsatellite diversity of the Nordic type of goats in relation to breed conservation: how relevant is pure ancestry?

Author

Lenstra, J.A., Tigchelaar, J., Biebach, I., Hallsson, J.H., Kantanen, J., Nielsen, V.H., Pompanon, F., Naderi, S., Rezaei, H.R., Sæther, N., Ertugrul, O., Grossen, C., Camenisch, G., VosLoohuis, M., van Straten, M., de Poel, E.A., Windig, J., Oldenbroek, K., AboShehada, Mahamoud, Marsan, Paolo Ajmone, Tarrayrah, Jamil Al, Angiolillo, Antonella, Baret, Philip, Baumung, Roswitha, BejaPereira, Albano, Bertaglia, Marco, Bordonaro, Salvatore, Brandt, Horst, Bruford, Mike, Caloz, Régis, Canali, Gabriele, Canon, Javier, Cappuccio, Irene, Carta, Antonello, Cicogna, Mario, Crepaldi, Paola, Dalamitra, Stella, Dobi, Petrit, Dunner, Susana, DʼUrso, Giuseppe, El Barody, M. A. A., England, Phillip, Erhardt, Georg, Ertuğrul, Okan, Glowatzki, MarieLouise, IbeaghaAwemu, Eveline, Strzelec, Ewa, Fadlaoui, Aziz, Fornarelli, Francesca, Garcia, David, Georgoudis, Andreas, Giovenzana, Stefano, Gutscher, Katja, Hewitt, Godfrey, Hoda, Anila, Istvan, Anton, Jones, Sam, Joost, Stéphane, Juma, Gabriela, Karetsou, Katerina, Kliambas, Georgios, Koban, Evren, Krugmann, Daniela, Kutita, Olga, Lazlo, Fesus, Ligda, Christina, Lipsky, Shirin, Luikart, Gordon, Lühken, Gesine, Marilli, Marta, Marletta, Donata, Milanesi, Elisabetta, Negrini, Riccardo, Nijman, Isaäc J., Niznikowski, Roman, ObexerRuff, Gabriela, Papachristoforou, Christos, Pariset, Lorraine, Peter, Marco Pellecchia, Christina, Perez, Trinidad, Pietrolà, Emilio, Pilla, Fabio, Popielarczyk, Dominik, Prinzenberg, MariaEva, Roosen, Jutta, Scarpa, Riccardo, Sechi, Tiziana, Taberlet, Pierre, Taylor, Martin, Togan, Inci, Trommetter, Michel, Valentini, Alessio, Van Cann, Lisette M., Vlaic, Augustin, Wiskin, Louise, and Zundel, Stéphanie

Published
2017
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14. Y-chromosomal haplogroups from wild and domestic goats reveal ancient migrations and recent introgressions

Author

Lenstra, J.A., VarGoats Consortium, Nijman, I.J., Rosen, B.D., Bardou, P., Faraut, T., Cumer, T., Daly, K.G., Zheng, Z., Cai, Y., Asadollahpour, H., Kul, B., Zhang, W.-Y., E, G., Ayin, A., Bakhtin, M., Bâlteanu, V.A., Barfield, D., Baird, H., Berger, B., Blichfeldt, T., Boink, G., Bugiwati, S.R.A., Cai, Z., Carolan, S., Clark, E., Cubric-Curik, Vlatka, Dagong, M.I.A., Dorji, T., Drew, L., Guo, J., Hallsson, J., Horvat, S., Kantanen, J., Kawaguchi, F., Kazymbet, P., Khayatzadeh, N., Kim, N., Kumar Shah, M., Liao, Y., Martínez, A., Masangkay, J. S., Masaoka, M., Mazza, R., McEwan, J., Milanesi, M., Omar, F. Md., Nomura, Y., Ouchene-Khelifi, N.-A., Pereira, F., Sahana, G., Sasazaki, S., Da Silva, A., Simčič, M., Sölkner, J., Sutherland, A., Tigchelaar, J., Zhang, H., Econogene Consortium, Ajmone- Marsan, P., Bradley, D. G., Colli, L., Drögemüller, C., Lei, C., Mannen, H., Pompanon, F., Tosser-Klopp, G., and Jiang, Y.

Subjects
wild and domestic goats, Y-chromosome, haplogroups, migrations, introgressions
Abstract

By its paternal transmission, Y-chromosomal haplotypes are sensitive markers of population history and male-mediated introgression. We used whole-genome sequences (WGSs) of 386 domestic goats from 75 modern breeds and 7 wild goat species generated by the VarGoats goat genome project. Phylogenetic analyses indicated five domestic haplogroups Y1AA, Y1AB, Y1B, Y2A and Y2B. Haplogroup distributions for 180 domestic breeds indicate ancient paternal population bottlenecks during the migration into northern Europe, southern Asia and Africa. Sharing of haplogroups reveals male-mediated introgressions: from Asia into Madagascar and, more recently, into the South-African Boer goat ; then from this breed into other southeastern African goats ; and from Europe into native Korean and Ugandan goats. This study illustrates the power of the Y-chromosomal variation for the reconstructing the history of domestic species with a wide geographic range.

Published
2022

17. Genomic Characterization of Animal Genetic Resources

Author

Ajmone-Marsan, P., Boettcher, P. J., Ginja, C., Kantanen J., Lenstra, J.A, Ajmone-Marsan, P., Boettcher, P. J., Ginja, C., Kantanen J., and Lenstra, J.A

Abstract

Whole genome sequencing and related tools now offer opportunities to evaluate the genetic diversity of livestock populations and individuals more precisely and cost-effectively. This publication guides scientists and other stakeholders in the genomic characterization of animal genetic resources.

Published
2023

18. Genetic diversity and pedigree analysis of the Finnsheep breed

Author

Li, M.-H., Stranden, I., and Kantanen, J.

Subjects
Sheep -- Genetic aspects, Animal breeding -- Genetic aspects, Zoology and wildlife conservation
Abstract

Genetic diversity in the Finnsheep breed was analyzed by quantifying the demographic trends, the depth of known pedigree, effective population size, and the amount of inbreeding, as well as identifying candidate rams within the current population for future breeding and conservation purposes. Pedigree records of 148,833 animals with a pedigree completeness coefficient [greater than or equal to] 0.60 and born from 1989 to 2006 were used to estimate the parameters. Mean inbreeding coefficient increased by 0.10% (P < 0.001) and 0.15% (P < 0.001) per annum in all animals and breeding (i.e., reproducing) animals, respectively. Average relationship coefficients among rams, among ewes, and between rams and ewes in breeding animals increased over time and reached 1.67, 1.45, and 1.46% in the 2005 cohort, respectively. The average for breeding rams was above the other 2 averages in almost all birth years. The observed generally low average relationship coefficients between rams and ewes indicate that no extra restrictions on the use of the breeding animals are needed in the near future. Average generation interval was 2.85 yr in the studied period, and the effective population size was estimated to be 119 and 122 using different methods. Relationship coefficients of rams with other breeding rams and rams with breeding ewes are suggested to aid in situ and ex situ conservation decisions on maintaining genetic diversity of Finnsheep. Key words: effective population size, Finnsheep, genetic diversity, inbreeding, pedigree analysis

Published
2009

20. VarGoats project : a dataset of 1159 whole-genome sequences to dissect Capra hircus global diversity

Author

Denoyelle, L., Talouarn, E., Bardou, P., Colli, L., Alberti, A., Danchin, C., Del Corvo, M., Engelen, S., Orvain, C., Palhiere, I., Rupp, R., Sarry, J., Salavati, M., Amills, M., Clark, E., Crepaldi, P., Faraut, T., Masiga, C. W., Pompanon, F., Rosen, B. D., Stella, A., Van Tassell, C. P., Tosser-Klopp, G., Kijas, J., Guldbrandtsen, B., Kantanen, J., Duby, D., Martin, P., Duclos, D., Allain, D., Arquet, R., Mandonnet, N., Naves, M., Carolan, S., Foran, M., Crisa, A., Marletta, D., Ottino, M., Randi, E., Benjelloun, B., Lenstra, H., Moaeen-ud-Din, M., Reecy, J., Goyache, F., Alvarez, I., Capote, J., Jordana, J., Pons, A., Martinez, A., Molina, A., Rosen, B., Drogemuller, C., Luikart, G., Mruttu, H. A., Gondwe, T., Sikosana, J., Taela, M. D. G., Nash, O., Agence Nationale de la Recherche (France), Région Occitanie / Pyrénées-Méditerranée, Ministère de l’Enseignement supérieur et de la Recherche (France), Biotechnology and Biological Sciences Research Council (UK), Bill & Melinda Gates Foundation, Department for International Development (UK), Center for Tropical Studies and Conservation (US), University of Edinburgh, Scottish Government's Rural and Environment Science and Analytical Services, Laboratoire d'Ecologie Alpine (LECA ), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA), Génétique Physiologie et Systèmes d'Elevage (GenPhySE ), Ecole Nationale Vétérinaire de Toulouse (ENVT), Institut National Polytechnique (Toulouse) (Toulouse INP), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut National Polytechnique (Toulouse) (Toulouse INP), Université de Toulouse (UT)-Université de Toulouse (UT)-École nationale supérieure agronomique de Toulouse (ENSAT), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Système d'Information des GENomes des Animaux d'Elevage (SIGENAE), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Università cattolica del Sacro Cuore [Piacenza e Cremona] (Unicatt), Génomique métabolique (UMR 8030), Genoscope - Centre national de séquençage [Evry] (GENOSCOPE), Université Paris-Saclay-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université d'Évry-Val-d'Essonne (UEVE)-Centre National de la Recherche Scientifique (CNRS), Institut de l'élevage (IDELE), Università cattolica del Sacro Cuore [Milano] (Unicatt), The Roslin Institute, Biotechnology and Biological Sciences Research Council (BBSRC), Centre for Tropical Livestock Genetics and Health [Edimburgh] (CTLGH), Centre for Research in Agricultural Genomics (CRAG), Università degli Studi di Milano = University of Milan (UNIMI), Tropical Institute of Development Innovations (TRIDI), USDA Agricultural Research Service [Beltsville, Maryland], USDA-ARS : Agricultural Research Service, Consiglio Nazionale delle Ricerche [Milano] (CNR), CSIRO Agriculture and Food (CSIRO), Unité de Recherches Zootechniques (URZ), APIS-GENE, Occitanie region, Ministere de l'Enseignement superieur, de la Recherche et de l'Innovation, United States Agency for International Development (USAID), CGIAR:OPP1127286, ACTIVEGOAT & CAPRISNP projects, UK Research & Innovation (UKRI) : BBS/OS/GC/000012F, ANR-10-INBS-0009,France-Génomique,Organisation et montée en puissance d'une Infrastructure Nationale de Génomique(2010), ANR-11-INBS-0003,CRB-Anim,Réseau de Centres de Ressources Biologiques pour les animaux domestiques(2011), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-École nationale supérieure agronomique de Toulouse [ENSAT]-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)-Université d'Évry-Val-d'Essonne (UEVE), University of Milan, and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Centre National de la Recherche Scientifique (CNRS)-Université d'Évry-Val-d'Essonne (UEVE)

Subjects
[SDV.BIO]Life Sciences [q-bio]/Biotechnology, [SDV]Life Sciences [q-bio], Short Communication, Single-nucleotide polymorphism, 610 Medicine & health, Biology, QH426-470, Genome, SF1-1100, Domestication, Animals, Domestication, Genetic Variation, Genomics, Goats, Genome, Genome-Wide Association Study, 03 medical and health sciences, Capra hircus, Genetics, Animals, Indel, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Genetic association, 2. Zero hunger, 0303 health sciences, Genetic diversity, [SDV.BA.MVSA]Life Sciences [q-bio]/Animal biology/Veterinary medicine and animal Health, Settore AGR/17 - ZOOTECNICA GENERALE E MIGLIORAMENTO GENETICO, 630 Agriculture, Goats, 0402 animal and dairy science, Genetic Variation, 04 agricultural and veterinary sciences, General Medicine, Genomics, 15. Life on land, 040201 dairy & animal science, Animal culture, Evolutionary biology, 570 Life sciences, biology, 590 Animals (Zoology), Animal Science and Zoology, Reference genome, Genome-Wide Association Study
Abstract

[Background]: Since their domestication 10,500 years ago, goat populations with distinctive genetic backgrounds have adapted to a broad variety of environments and breeding conditions. The VarGoats project is an international 1000-genome resequencing program designed to understand the consequences of domestication and breeding on the genetic diversity of domestic goats and to elucidate how speciation and hybridization have modeled the genomes of a set of species representative of the genus Capra., [Findings]: A dataset comprising 652 sequenced goats and 507 public goat sequences, including 35 animals representing eight wild species, has been collected worldwide. We identified 74,274,427 single nucleotide polymorphisms (SNPs) and 13,607,850 insertion-deletions (InDels) by aligning these sequences to the latest version of the goat reference genome (ARS1). A Neighbor-joining tree based on Reynolds genetic distances showed that goats from Africa, Asia and Europe tend to group into independent clusters. Because goat breeds from Oceania and Caribbean (Creole) all derive from imported animals, they are distributed along the tree according to their ancestral geographic origin., [Conclusions]: We report on an unprecedented international effort to characterize the genome-wide diversity of domestic goats. This large range of sequenced individuals represents a unique opportunity to ascertain how the demographic and selection processes associated with post-domestication history have shaped the diversity of this species. Data generated for the project will also be extremely useful to identify deleterious mutations and polymorphisms with causal effects on complex traits, and thus will contribute to new knowledge that could be used in genomic prediction and genome-wide association studies., We are grateful to France Génomique “Call for high impact projects” (ANR‐10‐INBS‐09‐08) for selecting our project and providing us the resources to sequence 400 goats. We would like to mention that APIS-GENE funded some WGS sequences through ACTIVEGOAT & CAPRISNP projects. We thank the Occitanie region and the Animal Genetics Division of the French National Institute for Agriculture, Food and Environment (INRAE-GA) for financing the PhD of ET. We thank the Ministère de l'Enseignement supérieur, de la Recherche et de l'Innovation for financing LD. We thank André Eggen (Illumina) for providing chips to genotype 192 animals. We thank the Animal Genetics Division of the French National Institute for Agriculture, Food and Environment (INRAE-GA) for funding VarGoats2 grant, which allowed DNA extraction and genotyping of 384 animals and CRB-Anim, Grant Agreement ANR-11-INBS-0003, (https://crb-anim.fr/) for funding French local breeds sampling. We thank the Italian Goat and Sheep Breeders Association (AssoNaPa) for supporting in sampling. Whole-genome sequencing libraries for the African goats were prepared and sequenced by Edinburgh Genomics and funded via Biotechnology and Biological Sciences Research Council research grant (BBS/OS/GC/000012F) ‘Reference genome and population sequencing of African goats’ awarded to The Roslin Institute. USDA-ARS with funding from USAID funded the collection of samples from Uganda, Tanzania, Malawi, Mozambique and Zimbabwe. EC and MS were partially supported by the Bill & Melinda Gates Foundation and with UK aid from the UK Government’s Department for International Development (Grant Agreement OPP1127286) under the auspices of the Centre for Tropical Livestock Genetics and Health (CTLGH), established jointly by the University of Edinburgh, SRUC (Scotland’s Rural College), and the International Livestock Research Institute. The findings and conclusions contained within are those of the authors and do not necessarily reflect positions or policies of the Bill & Melinda Gates Foundation nor the UK Government.

Published
2021
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21. Adipose gene expression profiles reveal insights into the adaptation of northern Eurasian semi-domestic reindeer (Rangifer tarandus)

Author

Weldenegodguad, M. (Melak), Pokharel, K. (Kisun), Niiranen, L. (Laura), Soppela, P. (Päivi), Ammosov, I. (Innokentyi), Honkatukia, M. (Mervi), Lindeberg, H. (Heli), Peippo, J. (Jaana), Reilas, T. (Tiina), Mazzullo, N. (Nuccio), Mäkelä, K. A. (Kari A.), Nyman, T. (Tommi), Tervahauta, A. (Arja), Herzig, K.-H. (Karl-Heinz), Stammler, F. (Florian), Kantanen, J. (Juha), Weldenegodguad, M. (Melak), Pokharel, K. (Kisun), Niiranen, L. (Laura), Soppela, P. (Päivi), Ammosov, I. (Innokentyi), Honkatukia, M. (Mervi), Lindeberg, H. (Heli), Peippo, J. (Jaana), Reilas, T. (Tiina), Mazzullo, N. (Nuccio), Mäkelä, K. A. (Kari A.), Nyman, T. (Tommi), Tervahauta, A. (Arja), Herzig, K.-H. (Karl-Heinz), Stammler, F. (Florian), and Kantanen, J. (Juha)

Abstract

Reindeer (Rangifer tarandus) are semi-domesticated animals adapted to the challenging conditions of northern Eurasia. Adipose tissues play a crucial role in northern animals by altering gene expression in their tissues to regulate energy homoeostasis and thermogenic activity. Here, we perform transcriptome profiling by RNA sequencing of adipose tissues from three different anatomical depots: metacarpal (bone marrow), perirenal, and prescapular fat in Finnish and Even reindeer (in Sakha) during spring and winter. A total of 16,212 genes are expressed in our data. Gene expression profiles in metacarpal tissue are distinct from perirenal and prescapular adipose tissues. Notably, metacarpal adipose tissue appears to have a significant role in the regulation of the energy metabolism of reindeer in spring when their nutritional condition is poor after winter. During spring, genes associated with the immune system are upregulated in the perirenal and prescapular adipose tissue. Blood and tissue parameters reflecting general physiological and metabolic status show less seasonal variation in Even reindeer than in Finnish reindeer. This study identifies candidate genes potentially involved in immune response, fat deposition, and energy metabolism and provides new information on the mechanisms by which reindeer adapt to harsh arctic conditions.

Published
2021

22. Unfolding of population structure in Baltic sheep breeds using microsatellite analysis

Author

Tapio, M., Miceikiene, I., Tapio, I., Kantanen, J, Grislis, Z., Olsaker, I., L-E Holm, Viinalaas, H., Jeppsson, S., and Eythorsdottir, E.

Subjects
Biological diversity -- Research, Genetic variation -- Research, Sheep -- Genetic aspects, Biological sciences
Abstract

Studies of genetic diversity in domestic animals are based on an evaluation of the genetic variation within breeds and genetic relationship among them. Combining this genetic population with phenotypic and aetiological data would enable formulation of the most informed recommendation for gene resource management.

Published
2005

27. Differentiation of European cattle by AFLP fingerprinting

Author

Negrini, R., Nijman, I. J., Milanesi, E., Moazami-Goudarzi, K., Williams, J. L., Erhardt, G., Dunner, S., Rodellar, C., Valentini, A., Bradley, D. G., Olsaker, I., Kantanen, J., Ajmone-Marsan, P., and Lenstra, J. A.

Published
2007

32. Genetic origin, admixture and population history of aurochs (Bos primigenius) and primitive European cattle

Author

Upadhyay, M R, Chen, W, Lenstra, J A, Goderie, C R J, MacHugh, D E, Park, S D E, Magee, D A, Matassino, D, Ciani, F, Megens, H-J, van Arendonk, J A M, Groenen, M A M, Marsan, P A, Balteanu, V, Dunner, S, Garcia, J F, Ginja, C, Kantanen, J, Sub Physical Oceanography, LS IRAS Tox Algemeen, Sub Veterinary Genetics, LS Ges. van de bouwkunst, dIRAS RA-1, Sub Physical Oceanography, LS IRAS Tox Algemeen, Sub Veterinary Genetics, LS Ges. van de bouwkunst, and dIRAS RA-1

Subjects
Gene Flow, 0301 basic medicine, Genetics, Genetics (clinical), Demographic history, ved/biology.organism_classification_rank.species, Population, Animal Breeding and Genomics, Breeding, Biology, Polymorphism, Single Nucleotide, 03 medical and health sciences, Human population genetics, Life Science, Animals, Fokkerij en Genomica, Domestication, education, Isolation by distance, education.field_of_study, Settore AGR/17 - ZOOTECNICA GENERALE E MIGLIORAMENTO GENETICO, Models, Genetic, Fossils, ved/biology, Taurine cattle, 0402 animal and dairy science, 04 agricultural and veterinary sciences, Aurochs, Zebu, biology.organism_classification, 040201 dairy & animal science, Europe, Bos primigenius, Genetics, Population, 030104 developmental biology, Evolutionary biology, WIAS, Original Article, Cattle, Corrigendum
Abstract

The domestication of taurine cattle initiated ~10 000 years ago in the Near East from a wild aurochs (Bos primigenius) population followed by their dispersal through migration of agriculturalists to Europe. Although gene flow from wild aurochs still present at the time of this early dispersion is still debated, some of the extant primitive cattle populations are believed to possess the aurochs-like primitive features. In this study, we use genome-wide single nucleotide polymorphisms to assess relationship, admixture patterns and demographic history of an ancient aurochs sample and European cattle populations, several of which have primitive features and are suitable for extensive management. The principal component analysis, the model-based clustering and a distance-based network analysis support previous works suggesting different histories for north-western and southern European cattle. Population admixture analysis indicates a zebu gene flow in the Balkan and Italian Podolic cattle populations. Our analysis supports the previous report of gene flow between British and Irish primitive cattle populations and local aurochs. In addition, we show evidence of aurochs gene flow in the Iberian cattle populations indicating wide geographical distribution of the aurochs. Runs of homozygosity (ROH) reveal that demographic processes like genetic isolation and breed formation have contributed to genomic variations of European cattle populations. The ROH also indicate recent inbreeding in southern European cattle populations. We conclude that in addition to factors such as ancient human migrations, isolation by distance and cross-breeding, gene flow between domestic and wild-cattle populations also has shaped genomic composition of European cattle populations.Heredity advance online publication, 28 September 2016; doi:10.1038/hdy.2016.79.

Published
2016
Full Text
View/download PDF

40. Microsatellite diversity of the Nordic type of goats in relation to breed conservation: how relevant is pure ancestry?

Author

Lenstra, J A, Tigchelaar, J, Biebach, Iris, Econogene Consortium, Hallsson, J H, Kantanen, J, Nielsen, V H, Pompanon, F, Naderi, S, Rezaei, H R, Saether, N, Ertugrul, O, Grossen, Christine, Camenisch, Glauco, Vos-Loohuis, M, van Straten, M, de Poel, E A, Windig, J, Oldenbroek, K, University of Zurich, and Lenstra, J A

Subjects
10127 Institute of Evolutionary Biology and Environmental Studies, 570 Life sciences, biology, 590 Animals (Zoology), 1103 Animal Science and Zoology, 3403 Food Animals
Published
2017

41. Microsatellite diversity of the Nordic type of goats in relation to breed conservation: How relevant is pure ancestry?

Author

Lenstra, J. A., Biebach, I., Hallsson, J. H., Kantanen, J., Nielsen, V. H., Pompanon, F., Naderi, S., Rezaei, H. R., Sæther, N., Ertugrul, O., Grossen, C., Camenisch, G., Vos-Loohuis, M., van Straten, M., de Poel, E. A., Windig, J., Oldenbroek, K., LS IRAS Tox Algemeen, Biochemisch laboratorium, dIRAS RA-1, and dCSCA AVR

Subjects
Diversity, Goats, Microsatellite, Conservation
Abstract

In the last decades, several endangered breeds of livestock species have been re-established effectively. However, the successful revival of the Dutch and Danish Landrace goats involved crossing with exotic breeds and the ancestry of the current populations is therefore not clear. We have generated genotypes for 27 FAO-recommended microsatellites of these landraces and three phenotypically similar Nordic-type landraces and compared these breeds with central European, Mediterranean and south-west Asian goats. We found decreasing levels of genetic diversity with increasing distance from the south-west Asian domestication site with a south-east-to-north-west cline that is clearly steeper than the Mediterranean east-to-west cline. In terms of genetic diversity, the Dutch Landrace comes next to the isolated Icelandic breed, which has an extremely low diversity. The Norwegian coastal goat and the Finnish and Icelandic landraces are clearly related. It appears that by a combination of mixed origin and a population bottleneck, the Dutch and Danish Land-races are separated from the other breeds. However, the current Dutch and Danish populations with the multicoloured and long-horned appearance effectively substitute for the original breed, illustrating that for conservation of cultural heritage, the phenotype of a breed is more relevant than pure ancestry and the genetic diversity of the original breed. More in general, we propose that for conservation, the retention of genetic diversity of an original breed and of the visual phenotype by which the breed is recognized and defined needs to be considered separately.

Published
2017

42. Maternal and paternal genealogy of Eurasian taurine cattle (Bos taurus)

Author

Kantanen, J., Edwards, C.J., Bradley, D.G., Viinalass, H., Thessler, S., Ivanova, Z., Kiselyova, T., Cinkulov, M., Popov, R., Stojanovic, S., Ammosov, I., and Vilkki, J.

Subjects
Mitochondrial DNA -- Research, Cattle -- Genetic aspects, Biological diversity -- Research, Y chromosome -- Research, Haplotypes -- Analysis, Biological sciences
Published
2009

43. Reduced genetic structure of north Ethiopian cattle revealed by Y-chromosome analysis

Author

Li, M.H., Zerabruk, M., Vangen, O., Olsaker, I., and Kantanen, J.

Subjects
Y chromosome -- Analysis, Y chromosome -- Structure, Gene flow -- Analysis, Cattle -- Genetic aspects, Biological sciences
Abstract

Five Y-chromosome microsatellite markers from seven north Ethiopian cattle populations is analysed to assess the paternal gene pool and to explore the mechanisms behind the genetic structure. It is found that there is common but limited strong male-mediated gene flow among paternal origin of the north Ethiopian cattle populations.

Published
2007

44. Rumen microbial community composition varies with diet and host, but a core microbiome is found across a wide geographical range

Author

Henderson, G., Cox, F., Ganesh, S., Jonker, A., Young, W., Janssen, P. H., Abecia, Leticia, Angarita, E., Aravena, P., Arenas, G. N., Ariza, C., Kelly, W. J., Guan, L. L., Miri, V. H., Hernandez-Sanabria, E., Gomez, A. X. I., Isah, O. A., Ishaq, S., Kim, S.-H., Klieve, A., Kobayashi, Y., Parra, D., Koike, S., Kopecny, J., Kristensen, T. N., O'Neill, B., Krizsan, S. J., LaChance, H., Lachman, M., Lamberson, W. R., Lambie, S., Lassen, J., Muñoz, C., Leahy, S. C., Lee, S. S., Leiber, F., Lewis, E., Ospina, S., Lin, B., Lira, R., Lund, P., Macipe, E., Mamuad, L. L., Murovec, B., Mantovani, H. C., Marcoppido, G. A., Márquez, C., Martin, C., Martínez-Fernández, Gonzalo, Ouwerkerk, D., Martínez, M. E., Mayorga, O. L., McAllister, T. A., McSweeney, C., Newbold, C. Jamie, Mestre, L., Minnee, E., Mitsumori, M., Mizrahi, I., Molina, I., Muenger, A., Nsereko, V., O'Donovan, M., Okunade, S., Pereira, L. G. R., Pinares-Patino, C., Pope, P. B., Bannink, A., Poulsen, M., Rodehutscord, M., Rodriguez, T., Attwood, G. T., Saito, K., Sales, F., Sauer, C., Shingfield, K. J., Shoji, N., Simunek, J., Zambrano, R., Stojanović -Radić, Z., Stres, B., Sun, X., Swartz, J., Ávila, J. M., Tan, Z. L., Tapio, I., Taxis, T. M., Tomkins, N., Ungerfeld, E., Zeitz, J., Valizadeh, R., Van Adrichem, P., van Hamme, J., Van Hoven, W., Waghorn, G., Avila-Stagno, J., Wallace, R. J., Wang, M., Waters, S. M., Keogh, K., Zhou, M., Witzig, M., Wright, A.-D. G., Yamano, H., Yan, T., Yáñez Ruiz, David R., Yeoman, C. J., Zhou, H. W., Zou, C. X., Zunino, P., Barahona, R., Batistotti, M., Bertelsen, M. F., Jami, E., Brown-Kav, A., Carvajal, A. M., Cersosimo, L., Chaves, A. V., Church, J., Clipson, N., Cobos-Peralta, M. A., Cookson, A. L., Cravero, S., Carballo, O. C., Jelincic, J., Crosley, K., Cruz, Gustavo, Cucchi, M. C., De La Barra, R., De Menezes, A. B., Detmann, E., Dieho, K., Dijkstra, J., Dos Reis, W. L. S., Dugan, M. E. R., Kantanen, J., Ebrahimi, S. H., Eythórsdóttir, E., Fon, F. N., Fraga, M., Franco, F., Friedeman, C., Fukuma, N., Gagić , D., Gangnat, I., Grilli, D. J., European Commission, and De Menezes, AB

Subjects
DNA, Bacterial, Rumen, animal structures, Animal Nutrition, Microorganism, Article, 03 medical and health sciences, Species Specificity, Ruminant, Butyrivibrio, Animals, DNA Barcoding, Taxonomic, Life Science, Microbiome, Phylogeny, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, Multidisciplinary, Bacteria, Geography, biology, 030306 microbiology, Host (biology), Ecology, Genetic Variation, Ruminants, Sequence Analysis, DNA, DNA, Protozoan, 15. Life on land, biology.organism_classification, Archaea, Diervoeding, Diet, Gastrointestinal Microbiome, DNA, Archaeal, Microbial population biology, 13. Climate action, Host-Pathogen Interactions, WIAS, Erratum
Abstract

© 2015 Macmillan Publishers Limited. Ruminant livestock are important sources of human food and global greenhouse gas emissions. Feed degradation and methane formation by ruminants rely on metabolic interactions between rumen microbes and affect ruminant productivity. Rumen and camelid foregut microbial community composition was determined in 742 samples from 32 animal species and 35 countries, to estimate if this was influenced by diet, host species, or geography. Similar bacteria and archaea dominated in nearly all samples, while protozoal communities were more variable. The dominant bacteria are poorly characterised, but the methanogenic archaea are better known and highly conserved across the world. This universality and limited diversity could make it possible to mitigate methane emissions by developing strategies that target the few dominant methanogens. Differences in microbial community compositions were predominantly attributable to diet, with the host being less influential. There were few strong co-occurrence patterns between microbes, suggesting that major metabolic interactions are non-selective rather than specific., We thank Ron Ronimus, Paul Newton, and Christina Moon for reading and commenting on the manuscript. We thank all who provided assistance that allowed Global Rumen Census collaborators to supply samples and metadata (Supplemental Text 1). AgResearch was funded by the New Zealand Government as part of its support for the Global Research Alliance on Agricultural Greenhouse Gases. The following funding sources allowed Global Rumen Census collaborators to supply samples and metadata, listed with the primary contact(s) for each funding source: Agencia Nacional de Investigación e Innovación, Martín Fraga; Alberta Livestock and Meat Agency, Canada, Tim A. McAllister; Area de Ciencia y Técnica, Universidad Juan A Maza (Resolución Proy. N° 508/2012), Diego Javier Grilli; Canada British Columbia Ranching Task Force Funding Initiative, John Church; CNPq, Hilário Cuquetto Mantovani, Luiz Gustavo Ribeiro Pereira; FAPEMIG, Hilário Cuquetto Mantovani; FAPEMIG, PECUS RumenGases, Luiz Gustavo Ribeiro Pereira; Cooperative Research Program for Agriculture Science & Technology Development (project number PJ010906), Rural Development Administration, Republic of Korea, Sang-Suk Lee; Dutch Dairy Board & Product Board Animal Feed, André Bannink, Kasper Dieho, Jan Dijkstra; Ferdowsi University of Mashhad, Vahideh Heidarian Miri; Finnish Ministry of Agriculture and Forestry, Ilma Tapio; Instituto Nacional de Tecnología Agropecuaria, Argentina (Project PNBIO1431044), Silvio Cravero, María Cerón Cucchi; Irish Department of Agriculture, Fisheries and Food, Alexandre B. De Menezes; Meat & Livestock Australia; and Department of Agriculture, Fisheries & Forestry (Australian Government), Chris McSweeney; Ministerio de Agricultura y desarrollo sostenible (Colombia), Olga Lucía Mayorga; Montana Agricultural Experiment Station project (MONB00113), Carl Yeoman; Multistate project W-3177 Enhancing the competitiveness of US beef (MONB00195), Carl Yeoman; NSW Stud Merino Breeders’ Association, Alexandre Vieira Chaves; Queensland Enteric Methane Hub, Diane Ouwerkerk; RuminOmics, Jan Kopecny, Ilma Tapio; Rural and Environment Science and Analytical Services Division (RESAS) of the Scottish Government and the Technology Strategy Board, UK, R. John Wallace; Science Foundation Ireland (09/RFP/GEN2447), Sinead Waters; Secretaría de Agricultura, Ganadería, Desarrollo Rural, Pesca y Alimentación, Mario A. Cobos-Peralta; Slovenian Research Agency (project number J1-6732 and P4-0097), Blaz Stres; Strategic Priority Research Program, Climate Change: Carbon Budget and Relevant Issues (Grant No.XDA05020700), ZhiLiang Tan; The European Research Commission Starting Grant Fellowship (336355—MicroDE), Phil B. Pope; The Independent Danish Research Council (project number 4002-00036), Torsten Nygaard Kristensen; and The Independent Danish Research Council (Technology and Production, project number 11-105913), Jan Lassen. These funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Published
2015
Full Text
View/download PDF

45. Genetic origin, admixture and population history of aurochs (Bos primigenius) and primitive European cattle

Author

Upadhyay, M R, Chen, W, Lenstra, J A, Goderie, C R J, MacHugh, D E, Park, S D E, Magee, D A, Matassino, D, Ciani, F, Megens, H-J, van Arendonk, J A M, Groenen, M A M, Marsan, P A, Balteanu, V, Dunner, S, Garcia, J F, Ginja, C, Kantanen, J, Upadhyay, M R, Chen, W, Lenstra, J A, Goderie, C R J, MacHugh, D E, Park, S D E, Magee, D A, Matassino, D, Ciani, F, Megens, H-J, van Arendonk, J A M, Groenen, M A M, Marsan, P A, Balteanu, V, Dunner, S, Garcia, J F, Ginja, C, and Kantanen, J

Abstract

The domestication of taurine cattle initiated ~10 000 years ago in the Near East from a wild aurochs (Bos primigenius) population followed by their dispersal through migration of agriculturalists to Europe. Although gene flow from wild aurochs still present at the time of this early dispersion is still debated, some of the extant primitive cattle populations are believed to possess the aurochs-like primitive features. In this study, we use genome-wide single nucleotide polymorphisms to assess relationship, admixture patterns and demographic history of an ancient aurochs sample and European cattle populations, several of which have primitive features and are suitable for extensive management. The principal component analysis, the model-based clustering and a distance-based network analysis support previous works suggesting different histories for north-western and southern European cattle. Population admixture analysis indicates a zebu gene flow in the Balkan and Italian Podolic cattle populations. Our analysis supports the previous report of gene flow between British and Irish primitive cattle populations and local aurochs. In addition, we show evidence of aurochs gene flow in the Iberian cattle populations indicating wide geographical distribution of the aurochs. Runs of homozygosity (ROH) reveal that demographic processes like genetic isolation and breed formation have contributed to genomic variations of European cattle populations. The ROH also indicate recent inbreeding in southern European cattle populations. We conclude that in addition to factors such as ancient human migrations, isolation by distance and cross-breeding, gene flow between domestic and wild-cattle populations also has shaped genomic composition of European cattle populations.Heredity advance online publication, 28 September 2016; doi:10.1038/hdy.2016.79.

Published
2017

46. Genetic origin, admixture and population history of aurochs (Bos primigenius) and primitive European cattle

Author

Sub Physical Oceanography, LS IRAS Tox Algemeen, Sub Veterinary Genetics, LS Ges. van de bouwkunst, dIRAS RA-1, Upadhyay, M R, Chen, W, Lenstra, J A, Goderie, C R J, MacHugh, D E, Park, S D E, Magee, D A, Matassino, D, Ciani, F, Megens, H-J, van Arendonk, J A M, Groenen, M A M, Marsan, P A, Balteanu, V, Dunner, S, Garcia, J F, Ginja, C, Kantanen, J, Sub Physical Oceanography, LS IRAS Tox Algemeen, Sub Veterinary Genetics, LS Ges. van de bouwkunst, dIRAS RA-1, Upadhyay, M R, Chen, W, Lenstra, J A, Goderie, C R J, MacHugh, D E, Park, S D E, Magee, D A, Matassino, D, Ciani, F, Megens, H-J, van Arendonk, J A M, Groenen, M A M, Marsan, P A, Balteanu, V, Dunner, S, Garcia, J F, Ginja, C, and Kantanen, J

Published
2017

47. Microsatellite diversity of the Nordic type of goats in relation to breed conservation: How relevant is pure ancestry?

Author

LS IRAS Tox Algemeen, Biochemisch laboratorium, dIRAS RA-1, dCSCA AVR, Lenstra, J. A., Biebach, I., Hallsson, J. H., Kantanen, J., Nielsen, V. H., Pompanon, F., Naderi, S., Rezaei, H. R., Sæther, N., Ertugrul, O., Grossen, C., Camenisch, G., Vos-Loohuis, M., van Straten, M., de Poel, E. A., Windig, J., Oldenbroek, K., LS IRAS Tox Algemeen, Biochemisch laboratorium, dIRAS RA-1, dCSCA AVR, Lenstra, J. A., Biebach, I., Hallsson, J. H., Kantanen, J., Nielsen, V. H., Pompanon, F., Naderi, S., Rezaei, H. R., Sæther, N., Ertugrul, O., Grossen, C., Camenisch, G., Vos-Loohuis, M., van Straten, M., de Poel, E. A., Windig, J., and Oldenbroek, K.

Published
2017

48. Microsatellite diversity of the Nordic type of goats in relation to breed conservation: how relevant is pure ancestry?

Author

Lenstra, J. A, Tigchelaar, J., Biebach, I., Hallsson, J. H., Kantanen, J., Nielsen, V. H., Pompanon, F., Naderi, S., Rezaei, H. R., Sæther, N., Ertugrul, O., Grossen, C., Camenisch, G., Vos Loohuis, M., van Straten, M., de Poel, E. A., Windig, J., Oldenbroek, K., Abo Shehada, Mahamoud, Ajmone Marsan, Paolo, Tarrayrah, Jamil Al, Angiolillo, Antonella, Baret, Philip, Baumung, Roswitha, Beja Pereira, Albano, Bertaglia, Marco, Bordonaro, Salvatore, Brandt, Horst, Bruford, Mike, Caloz, Régi, Canali, Gabriele, Canon, Javier, Cappuccio, Irene, Carta, Antonello, Cicogna, Mario, Crepaldi, Paola, Dalamitra, Stella, Dobi, Petrit, Dunner, Susana, D'Urso, Giuseppe, El Barody, M. A. A., England, Phillip, Erhardt, Georg, Ertuğrul, Okan, Glowatzki, Marie Louise, Ibeagha Awemu, Eveline, Strzelec, Ewa, Fadlaoui, Aziz, Fornarelli, Francesca, Garcia, David, Georgoudis, Andrea, Giovenzana, Stefano, Gutscher, Katja, Hewitt, Godfrey, Hoda, Anila, Istvan, Anton, Jones, Sam, Joost, Stephane, Juma, Gabriela, Karetsou, Katerina, Kliambas, Georgio, Koban, Evren, Krugmann, Daniela, Kutita, Olga, Lazlo, Fesu, Ligda, Christina, Lipsky, Shirin, Luikart, Gordon, Lühken, Gesine, Marilli, Marta, Marletta, Donata, Milanesi, Elisabetta, Negrini, Riccardo, Nijman, Isaäc J., Niznikowski, Roman, Obexer Ruff, Gabriela, Papachristoforou, Christo, Pariset, Lorraine, Peter, Marco Pellecchia, Christina, Null, Perez, Trinidad, Pietrolà, Emilio, Pilla, Fabio, Popielarczyk, Dominik, Prinzenberg, Maria Eva, Roosen, Jutta, Scarpa, Riccardo, Sechi, Tiziana, Taberlet, Pierre, Taylor, Martin, Togan, Inci, Trommetter, Michel, Valentini, Alessio, Van Cann, Lisette M., Vlaic, Augustin, Wiskin, Louise, Zundel, Stéphanie, Ajmone Marsan, Paolo (ORCID:0000-0003-3165-4579), Canali, Gabriele (ORCID:0000-0001-9244-8184), Negrini, Riccardo (ORCID:0000-0002-8735-0286), Lenstra, J. A, Tigchelaar, J., Biebach, I., Hallsson, J. H., Kantanen, J., Nielsen, V. H., Pompanon, F., Naderi, S., Rezaei, H. R., Sæther, N., Ertugrul, O., Grossen, C., Camenisch, G., Vos Loohuis, M., van Straten, M., de Poel, E. A., Windig, J., Oldenbroek, K., Abo Shehada, Mahamoud, Ajmone Marsan, Paolo, Tarrayrah, Jamil Al, Angiolillo, Antonella, Baret, Philip, Baumung, Roswitha, Beja Pereira, Albano, Bertaglia, Marco, Bordonaro, Salvatore, Brandt, Horst, Bruford, Mike, Caloz, Régi, Canali, Gabriele, Canon, Javier, Cappuccio, Irene, Carta, Antonello, Cicogna, Mario, Crepaldi, Paola, Dalamitra, Stella, Dobi, Petrit, Dunner, Susana, D'Urso, Giuseppe, El Barody, M. A. A., England, Phillip, Erhardt, Georg, Ertuğrul, Okan, Glowatzki, Marie Louise, Ibeagha Awemu, Eveline, Strzelec, Ewa, Fadlaoui, Aziz, Fornarelli, Francesca, Garcia, David, Georgoudis, Andrea, Giovenzana, Stefano, Gutscher, Katja, Hewitt, Godfrey, Hoda, Anila, Istvan, Anton, Jones, Sam, Joost, Stephane, Juma, Gabriela, Karetsou, Katerina, Kliambas, Georgio, Koban, Evren, Krugmann, Daniela, Kutita, Olga, Lazlo, Fesu, Ligda, Christina, Lipsky, Shirin, Luikart, Gordon, Lühken, Gesine, Marilli, Marta, Marletta, Donata, Milanesi, Elisabetta, Negrini, Riccardo, Nijman, Isaäc J., Niznikowski, Roman, Obexer Ruff, Gabriela, Papachristoforou, Christo, Pariset, Lorraine, Peter, Marco Pellecchia, Christina, Null, Perez, Trinidad, Pietrolà, Emilio, Pilla, Fabio, Popielarczyk, Dominik, Prinzenberg, Maria Eva, Roosen, Jutta, Scarpa, Riccardo, Sechi, Tiziana, Taberlet, Pierre, Taylor, Martin, Togan, Inci, Trommetter, Michel, Valentini, Alessio, Van Cann, Lisette M., Vlaic, Augustin, Wiskin, Louise, Zundel, Stéphanie, Ajmone Marsan, Paolo (ORCID:0000-0003-3165-4579), Canali, Gabriele (ORCID:0000-0001-9244-8184), and Negrini, Riccardo (ORCID:0000-0002-8735-0286)

Abstract

In the last decades, several endangered breeds of livestock species have been re-established effectively. However, the successful revival of the Dutch and Danish Landrace goats involved crossing with exotic breeds and the ancestry of the current populations is therefore not clear. We have generated genotypes for 27 FAO-recommended microsatellites of these landraces and three phenotypically similar Nordic-type landraces and compared these breeds with central European, Mediterranean and south-west Asian goats. We found decreasing levels of genetic diversity with increasing distance from the south-west Asian domestication site with a south-east-to-north-west cline that is clearly steeper than the Mediterranean east-to-west cline. In terms of genetic diversity, the Dutch Landrace comes next to the isolated Icelandic breed, which has an extremely low diversity. The Norwegian coastal goat and the Finnish and Icelandic landraces are clearly related. It appears that by a combination of mixed origin and a population bottleneck, the Dutch and Danish Land-races are separated from the other breeds. However, the current Dutch and Danish populations with the multicoloured and long-horned appearance effectively substitute for the original breed, illustrating that for conservation of cultural heritage, the phenotype of a breed is more relevant than pure ancestry and the genetic diversity of the original breed. More in general, we propose that for conservation, the retention of genetic diversity of an original breed and of the visual phenotype by which the breed is recognized and defined needs to be considered separately.

Published
2017

49. Genetic origin, admixture and population history of aurochs (Bos primigenius) and primitive European cattle

Author

Upadhyay, M. R., Chen, W., Lenstra, J. A., Goderie, C. R. J., Machugh, D. E., Park, S. D. E., Magee, D. A., Matassino, D., Ciani, F., Megens, H. J., Van Arendonk, J. A. M., Groenen, M. A. M., Ajmone Marsan, Paolo, Balteanu, V., Dunner, S., Garcia, J. F., Ginja, C., Kantanen, J., Ajmone Marsan, Paolo (ORCID:0000-0003-3165-4579), Upadhyay, M. R., Chen, W., Lenstra, J. A., Goderie, C. R. J., Machugh, D. E., Park, S. D. E., Magee, D. A., Matassino, D., Ciani, F., Megens, H. J., Van Arendonk, J. A. M., Groenen, M. A. M., Ajmone Marsan, Paolo, Balteanu, V., Dunner, S., Garcia, J. F., Ginja, C., Kantanen, J., and Ajmone Marsan, Paolo (ORCID:0000-0003-3165-4579)

Abstract

The domestication of taurine cattle initiated ∼10 000 years ago in the Near East from a wild aurochs (Bos primigenius) population followed by their dispersal through migration of agriculturalists to Europe. Although gene flow from wild aurochs still present at the time of this early dispersion is still debated, some of the extant primitive cattle populations are believed to possess the aurochs-like primitive features. In this study, we use genome-wide single nucleotide polymorphisms to assess relationship, admixture patterns and demographic history of an ancient aurochs sample and European cattle populations, several of which have primitive features and are suitable for extensive management. The principal component analysis, the model-based clustering and a distance-based network analysis support previous works suggesting different histories for north-western and southern European cattle. Population admixture analysis indicates a zebu gene flow in the Balkan and Italian Podolic cattle populations. Our analysis supports the previous report of gene flow between British and Irish primitive cattle populations and local aurochs. In addition, we show evidence of aurochs gene flow in the Iberian cattle populations indicating wide geographical distribution of the aurochs. Runs of homozygosity (ROH) reveal that demographic processes like genetic isolation and breed formation have contributed to genomic variations of European cattle populations. The ROH also indicate recent inbreeding in southern European cattle populations. We conclude that in addition to factors such as ancient human migrations, isolation by distance and cross-breeding, gene flow between domestic and wild-cattle populations also has shaped genomic composition of European cattle populations.

Published
2017

50. Revisiting AFLP fingerprinting for an unbiased assessment of genetic structure and differentiation of taurine and zebu cattle

Author

Utsunomiya, Yuri T., Bomba, Lorenzo, Lucente, Giordana, Colli, Licia, Negrini, Riccardo, Lenstra, Johannes A., Erhardt, Georg, Garcia, José F., Ajmone-Marsan, Paolo, Moazami-Goudarzi, K., Williams, J., Wiener, P., Olsaker, I., Kantanen, J., Dunner, S., Cañón, J., Rodellar, C., Martín-Burriel, I., Valentini, A., Zanotti, M., Holm, L. E., Eythorsdottir, E., Mommens, G., Polygen, Van Haeringen, Nijman, I. J., Dolf, G., Bradley, D. G., Algemeen Onderzoek DGK, LS IRAS Tox Algemeen, Dep Natuurkunde, Faculty of Veterinary Medicine Research Groups, Algemeen Onderzoek DGK, LS IRAS Tox Algemeen, Dep Natuurkunde, Faculty of Veterinary Medicine Research Groups, Universidade Estadual Paulista (Unesp), Univ Cattol Sacro Cuore, Univ Utrecht, and Univ Giessen

Subjects
Genetic Markers, Conservation of Natural Resources, AFLP, Genotype, ved/biology.organism_classification_rank.species, Introgression, Breeding, Genetic differentiation, Revisiting AFLP, Ascertainment bias, Genetic variation, genetic structure, Genetics, Animals, Cluster Analysis, Genetics(clinical), Amplified Fragment Length Polymorphism Analysis, Genetics (clinical), Models, Genetic, Settore AGR/17 - ZOOTECNICA GENERALE E MIGLIORAMENTO GENETICO, biology, ved/biology, Taurine cattle, Genetic Variation, Aurochs, Zebu, biology.organism_classification, humanities, Genetics, Population, Genetic marker, Genetic structure, Amplified fragment length polymorphism, Cattle, Research Article
Abstract

Made available in DSpace on 2014-12-03T13:07:04Z (GMT). No. of bitstreams: 0 Previous issue date: 2014-04-17Bitstream added on 2014-12-03T13:24:33Z : No. of bitstreams: 1 WOS000335177200001.pdf: 750548 bytes, checksum: 075b52b143f984a79a48dec1b9a68ce6 (MD5) Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) Background: Descendants from the extinct aurochs (Bos primigenius), taurine (Bos taurus) and zebu cattle (Bos indicus) were domesticated 10,000 years ago in Southwestern and Southern Asia, respectively, and colonized the world undergoing complex events of admixture and selection. Molecular data, in particular genome-wide single nucleotide polymorphism (SNP) markers, can complement historic and archaeological records to elucidate these past events. However, SNP ascertainment in cattle has been optimized for taurine breeds, imposing limitations to the study of diversity in zebu cattle. As amplified fragment length polymorphism (AFLP) markers are discovered and genotyped as the samples are assayed, this type of marker is free of ascertainment bias. In order to obtain unbiased assessments of genetic differentiation and structure in taurine and zebu cattle, we analyzed a dataset of 135 AFLP markers in 1,593 samples from 13 zebu and 58 taurine breeds, representing nine continental areas.Results: We found a geographical pattern of expected heterozygosity in European taurine breeds decreasing with the distance from the domestication centre, arguing against a large-scale introgression from European or African aurochs. Zebu cattle were found to be at least as diverse as taurine cattle. Western African zebu cattle were found to have diverged more from Indian zebu than South American zebu. Model-based clustering and ancestry informative markers analyses suggested that this is due to taurine introgression. Although a large part of South American zebu cattle also descend from taurine cows, we did not detect significant levels of taurine ancestry in these breeds, probably because of systematic backcrossing with zebu bulls. Furthermore, limited zebu introgression was found in Podolian taurine breeds in Italy.Conclusions: The assessment of cattle diversity reported here contributes an unbiased global view to genetic differentiation and structure of taurine and zebu cattle populations, which is essential for an effective conservation of the bovine genetic resources. Univ Estadual Paulista, Fac Ciencias Agr & Vet, BR-14884900 Jaboticabal, SP, Brazil Univ Cattol Sacro Cuore, Inst Zootech, Piacenza, Italy Univ Cattol Sacro Cuore, BioDNA Biodivers & Ancient DNA Res Ctr, Piacenza, Italy Univ Utrecht, Fac Vet Med, Utrecht, Netherlands Univ Giessen, Inst Anim Breeding & Genet, D-35390 Giessen, Germany Univ Estadual Paulista, Fac Med Vet Aracatuba, BR-16050680 Aracatuba, SP, Brazil Univ Estadual Paulista, Fac Ciencias Agr & Vet, BR-14884900 Jaboticabal, SP, Brazil Univ Estadual Paulista, Fac Med Vet Aracatuba, BR-16050680 Aracatuba, SP, Brazil FAPESP: 11/16643-2 FAPESP: 13/12829-0

Published
2014
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