Your search keyword '"DAUGHTER DESIGN"' showing total 7 results

1. Detection of Quantitative Trait Loci Affecting Milk Production Traits on Bovine Chromosome 6 in a Chinese Holstein Population by the Daughter Design.

Author

Chen, H. Y., Zhang, Q., Yin, C. C., Wang, C. K., Gong, W. J., and Mei, G.

Subjects

*MILK yield, *MICROSATELLITE repeats, *CATTLE, *MILKING, *DAIRY industry

Abstract

Fourteen microsatellite markers with a coverage of 63.5 cM on bovine chromosome 6 were selected, and 26 sire families with 2,260 daughters were analyzed for mapping quantitative trait loci (QTL) affecting 5 milk production traits in a Chinese Holstein population. In the analyses across 26 families and within the largest significant families with a one-QTL model fitted, a QTL near BMS470 was detected that affected fat yield at the 5% experiment-wide significance level. When a 2-QTL model was fitted in the across-family analysis, it was found that there might exist 2 QTL affecting the 3 yield traits, although the exact or empirical thresholds for the significance testing were unknown. In all analyses, the results for milk yield and protein yield were generally consistent, which might have resulted from the same genetic background for milk and protein yield. [ABSTRACT FROM AUTHOR]

Published

2006

2. Mapping QTLs on BTA6 affecting milk production traits in a Chinese Holstein population.

Author

Chen Huiyong, Zhang Qin, Wang Chunkao, Shu Juan, Mel Gui, Yin Cengceng, Hu Fang, Xu Jingjing, Gong Weijia, Li Hejun, and Qiu Xiaotian

Subjects

*HOLSTEIN-Friesian cattle, *MILK yield, *MICROSATELLITE repeats, *REGRESSION analysis, *CONFIDENCE intervals, *MATHEMATICAL models

Abstract

A Chinese Holstein population with daughter design was analyzed using 14 microsatellites covering a map distance of 557 cM on chromosome 6 to fine map QTL for five milk production traits. 26 paternal half-sib families with 2356 daughters were involved. Two different approaches, linear regression approach and variance component approach, were employed, with a one-QTL model and two-QTL model fitted. With a one-QTL model, the linear regression approach revealed a QTL near BMS470 with effects on milk yield, fat yield, protein yield, and fat percentage, and another QTL near BMS2460 for protein percentage. The variance component approach confirmed the results of linear regression approach for the three yield traits, with the exception that the QTL for fat yield was mapped to a different position near BMS1242. The 95% confidence intervals resulted from linear regression, obtained by bootstrapping, were generally large, ranging from 31 to 53 cM, whereas the variance component approach revealed very small confidence intervals, calculated by LOD drop-off method, for the three yield traits, only 4-5 cM. With a two-QTL model, both approaches provided strong evidence for the existence of two QTLs for the three yield traits. Along with the QTLs identified in one-QTL model analyses, the linear regression approach revealed a second QTL near BP7 with effects on all the three yield traits, whereas the variance component approach located the second QTL near ILSS035, BMS470, and BP7 for the three traits, respectively. [ABSTRACT FROM AUTHOR]

Published

2005

3. Breeding and Genetics II.

Subjects

*ANIMAL breeding, *ANIMAL genetics, *INBREEDING, *MICROSATELLITE repeats, *POLYMERASE chain reaction

Abstract

Presents abstracts of several studies on animal breeding and genetics. "A Computerized Approach to Minimize Inbreeding of Breeding Plans," by John R. Garbe and Yang Da; "Efficiency of Selection on Multiple QTL in a Crossbred Population," by N. Piyasatian, R. Fernando and J. Dekkers; "Detection and Characterization of Microsatellite Loci Based on PCR," by H. Y. Chung, J. M. Ha, S. J. Oh and S. W. Lee.

Published

2004

4. Breeding and Genetics II.

Subjects

*ANIMAL breeding, *ANIMAL genetics, *INBREEDING, *MICROSATELLITE repeats, *POLYMERASE chain reaction

Abstract

Presents abstracts of several studies on animal breeding and genetics. "A Computerized Approach to Minimize Inbreeding of Breeding Plans," by John R. Garbe and Yang Da; "Efficiency of Selection on Multiple QTL in a Crossbred Population," by N. Piyasatian, R. Fernando and J. Dekkers; "Detection and Characterization of Microsatellite Loci Based on PCR," by H. Y. Chung, J. M. Ha, S. J. Oh and S. W. Lee.

Published

2004

5. Breeding and Genetics II.

Subjects

*ANIMAL breeding, *ANIMAL genetics, *INBREEDING, *MICROSATELLITE repeats, *POLYMERASE chain reaction

Abstract

Presents abstracts of several studies on animal breeding and genetics. "A Computerized Approach to Minimize Inbreeding of Breeding Plans," by John R. Garbe and Yang Da; "Efficiency of Selection on Multiple QTL in a Crossbred Population," by N. Piyasatian, R. Fernando and J. Dekkers; "Detection and Characterization of Microsatellite Loci Based on PCR," by H. Y. Chung, J. M. Ha, S. J. Oh and S. W. Lee.

Published

2004

6. Quantitative Trait Loci Affecting Milk Yield and Protein Percentage in a Three-Country Brown Swiss Population

Author

Johann Sölkner, Alison M. Friedmann, M. Soller, Alessandro Bagnato, E. Lipkin, A. Rossoni, Christian Maltecca, Luca Fontanesi, Ivica Medugorac, Vincenzo Russo, M. Dolezal, F. Schiavini, Bagnato A., Schiavini F., Rossoni A., Maltecca C., Dolezal M., Medugorac I., Sölkner J., Russo V., Fontanesi L., Friedman A., Soller M., and Lipkin E.

Subjects

Male, QTL, Genetic Linkage, Quantitative Trait Loci, Population, Quantitative trait locus, Biology, Animal science, Genetics, Animals, Lactation, education, SELECTIVE MILK DNA POOLING, Allele frequency, Alleles, Dairy cattle, education.field_of_study, Sire, Chromosome Mapping, food and beverages, MILK PRODUCTION, DNA, Milk Proteins, Breed, Milk, Trait, Cattle, Female, Animal Science and Zoology, Brown Swiss, DAIRY CATTLE, DAUGHTER DESIGN, Microsatellite Repeats, Food Science

Abstract

Quantitative trait loci (QTL) mapping projects have been implemented mainly in the Holstein dairy cattle breed for several traits. The aim of this study is to map QTL for milk yield (MY) and milk protein percent (PP) in the Brown Swiss cattle populations of Austria, Germany, and Italy, considered in this study as a single population. A selective DNA pooling approach using milk samples was applied to map QTL in 10 paternal half-sib daughter families with offspring spanning from 1,000 to 3,600 individuals per family. Three families were sampled in Germany, 3 in Italy, 1 in Austria and 3 jointly in Austria and Italy. The pools comprised the 200 highest and 200 lowest performing daughters, ranked by dam-corrected estimated breeding value for each sire-trait combination. For each tail, 2 independent pools, each of 100 randomly chosen daughters, were constructed. Sire marker allele frequencies were obtained by densitometry and shadow correction analyses of 172 genome-wide allocated autosomal markers. Particular emphasis was placed on Bos taurus chromosomes 3, 6, 14, and 20. Marker association for MY and PP with a 10% false discovery rate resulted in nominal P-values of 0.071 and 0.073 for MY and PP, respectively. Sire marker association tested at a 20% false discovery rate (within significant markers) yielded nominal P-values of 0.031 and 0.036 for MY and PP, respectively. There were a total of 36 significant markers for MY, 33 for PP, and 24 for both traits; 75 markers were not significant for any of the traits. Of the 43 QTL regions found in the present study, 10 affected PP only, 8 affected MY only, and 25 affected MY and PP. Remarkably, all 8 QTL regions that affected only MY in the Brown Swiss, also affected MY in research reported in 3 Web-based QTL maps used for comparison with the findings of this study (http://www.vetsci.usyd.edu.au/reprogen/QTL_Map/; http://www.animalgenome.org/QTLdb/cattle.html; http://bovineqtl.tamu.edu/). Similarly, all 10 QTL regions in the Brown Swiss that affected PP only, affected only PP in the databases. Thus, many QTL appear to be common to Brown Swiss and other breeds in the databases (mainly Holstein), and an appreciable fraction of QTL appears to affect MY or PP primarily or exclusively, with little or no effect on the other trait. Although QTL information available today in the Brown Swiss population can be utilized only in a within family marker-assisted selection approach, knowledge of QTL segregating in the whole population should boost gene identification and ultimately the implementation and efficiency of an individual genomic program.

Published

2008

7. A whole genome scan for QTL affecting milk protein percentage in Italian Holstein cattle, applying selective milk DNA pooling and multiple marker mapping in a daughter design

Author

Stefania Dall'Olio, M. Föster, E. Lipkin, Daniele Bigi, Emilio Scotti, F. Schiavini, Vincenzo Russo, Alessandro Bagnato, M. Soller, Luca Fontanesi, F. Canavesi, Marlies Dolezal, Paolo Zambonelli, Roberta Davoli, Ivica Medugorac, Johann Sölkner, Russo V., Fontanesi L., Dolezal M., Lipkin E., Scotti E., Zambonelli P., Dall’Olio S., Bigi D., Davoli R., Canavesi F., Medugorac I., Föster M., Sölkner J., Schiavini F., Bagnato A., and Soller M.

Subjects

Genetic Markers, Male, Candidate gene, Heterozygote, Population, Quantitative Trait Loci, Quantitative trait locus, Biology, Breeding, CANDIDATE GENES, Gene Frequency, Genotype, Genetics, Animals, Selection, Genetic, education, Allele frequency, education.field_of_study, Autosome, Genome, Polymorphism, Genetic, Sire, food and beverages, Chromosome Mapping, General Medicine, DNA, Milk Proteins, Chromosomes, Mammalian, GENOME SCAN, Milk, Phenotype, ITALIAN HOLSTEIN CATTLE, Microsatellite, Animal Science and Zoology, Cattle, Female, DAUGHTER DESIGN, Microsatellite Repeats

Abstract

Summary We report on a complete genome scan for quantitative trait loci (QTL) affecting milk protein percentage (PP) in the Italian Holstein-Friesian cattle population, applying a selective DNA pooling strategy in a daughter design. Ten Holstein-Friesian sires were chosen, and for each sire, about 200 daughters, each from the high and low tails of estimated breeding value for PP, were used to construct milk DNA pools. Sires and pools were genotyped for 181 dinucleotide microsatellites covering all cattle autosomes. Sire marker allele frequencies in the pools were obtained by shadow correction of peak height in the electropherograms. After quality control, pool data from eight sires were used for all subsequent analyses. The QTL heterozygosity estimate was lower than that of similar studies in other cattle populations. Multiple marker mapping identified 19 QTL located on 14 chromosomes (BTA1, 2, 3, 4, 5, 6, 8, 9, 12, 14, 17, 20, 23 and 27). The sires were also genotyped for seven polymorphic sites in six candidate genes (ABCG2, SPP1, casein kappa, DGAT1, GHR and PRLR) located within QTL regions of BTA6, 14 and 20 found in this study. The results confirmed or excluded the involvement of some of the analysed markers as the causative polymorphic sites of the identified QTL. The QTL identified, combined with genotype data of these candidate genes, will help to identify other quantitative trait genes and clarify the complex QTL patterns observed for a few chromosomes. Overall, the results are consistent with the Italian Holstein population having been under long-term selection for high PP.

Published

2012