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17 results on '"van der Werf, Julius H.J."'

1. Challenges and strategies for genetic selection of sheep better adapted to harsh environments

Author

Nel, Cornelius L. [0000-0002-3329-4928], Van Der Werf, Julius H.J. [0000-0003-2512-1696], Rauw , Wendy Mercedes [0000-0002-2885-1961], Cloete, Schalk W.P. [0000-0002-4548-5633], Nel, Cornelius L., Van Der Werf, Julius H.J., Rauw , Wendy Mercedes, Cloete, Schalk W.P., Nel, Cornelius L. [0000-0002-3329-4928], Van Der Werf, Julius H.J. [0000-0003-2512-1696], Rauw , Wendy Mercedes [0000-0002-2885-1961], Cloete, Schalk W.P. [0000-0002-4548-5633], Nel, Cornelius L., Van Der Werf, Julius H.J., Rauw , Wendy Mercedes, and Cloete, Schalk W.P.

Abstract

Extensive sheep farming is often associated with small flocks grazing large areas, delivering limited economic returns compared with the revenue of examples such as dairy or intensive beef cattle farming. However, sheep are a popular choice of livestock in challenging environments where few other production systems are viable (Rust and Rust, 2013). Low input, extensive systems make use of the ability of ruminants to metabolize low-quality, high fiber materials that characterize pastoral grazing. By producing wool, meat, and sometimes dairy, extensive sheep production can deliver high-quality output products from a low-quality input that would otherwise have had little value for sustaining mankind. Furthermore, extensive pastoral systems can arguably be excused from some of the criticisms aimed at factory farming (Frank, 1979). Assuming sustainable stocking rates, extensive sheep farming may be favored in terms of the social and environmental concerns around animal production. However, low input systems are also associated with specific challenges. Outside the support of intensive systems, livestock are expected to survive, produce, and reproduce with little assistance from human intervention or shelter. In addition to requiring a high level of independence, they are also more exposed to the environmental elements such as harsh climates, disease, and parasite challenge. These environmental stressors directly affect production, but the implications for health and welfare should also be considered (Dwyer, 2009). Environmental intervention can be effective (Masters et al., 2023) and should aim to ensure the best outcome for animals wherever possible. In the majority of extensive systems, however, opportunities are limited for being either impractical or too expensive. Animals kept in extensive systems should thus possess an ability to adapt and cope with environmental challenges—a concern of animal breeding and genetics. The issue of adaptability has been previously rev

Published
2023

2. Supplemental Material for Mulder et al., 2019

Author

Mulder, Herman A., Lee, Sang Hong, Clark, Sam, Hayes, Ben J., van der Werf, Julius H.J., Mulder, Herman A., Lee, Sang Hong, Clark, Sam, Hayes, Ben J., and van der Werf, Julius H.J.

Abstract

This file contains additional figures., This file contains additional figures.

Published
2019

3. Genetic correlation and heritabilities for purebred and crossbred performance in poultry egg production traits

Author

Wei, Ming and van der Werf, Julius H.J.

Subjects
Inbreeding -- Genetic aspects, Eggs -- Production, Multivariate analysis -- Usage, Poultry -- Genetic aspects, Zoology and wildlife conservation
Abstract

Genetic correlations between purebred and crossbred performance and purebred and crossbred heritabilities were estimated for egg production traits of laying chickens using a multivariate sire model accounting for additive relationships between sires. Two sire lines, denoted lines 1 and 2, were crossed to one dam line to produce crossbred progeny. Records for egg weight, egg specific gravity, and egg number were collected on purebred and crossbred hens. In total, 99 sires in line 1 and 292 sires in line 2 were used in the analysis, each sire producing on average 45 purebred and 105 crossbred daughters. Estimates of purebred heritability in lines 1 and 2 were in range of .54 to .74 for egg number traits, .52 to .91 for egg weight traits, and .41 to .83 for egg specific gravity traits. Estimates of crossbred heritability were .04 to .51 for egg numbers, .23 to .45 for egg weight, and .13 to .31 for egg specific gravity. The sire component in crossbreds differed up to 78% from the sire component in purebreds depending on traits. The estimate of genetic correlation ([r.sub.pc]) between purebred and crossbred performance was .56 to .73 for egg number, .69 to .99 for egg weight, and .72 to .82 for egg specific gravity. Although crossbred parameters were strongly affected by environmental factors, the results tend to agree with the theory that traits with a larger dominance variation and a larger difference between sire components in purebreds and crossbreds show a lower [r.sub.pc]. Because the estimates of [r.sub.pc] were significantly lower than 1 for egg number and egg specific gravity, an optimal selection strategy should combine purebred and crossbred information for crossbred progress. Key Words: Crossbreeding, Egg Production, Genetic Parameters, Multivariate Analysis, Poultry

Published
1995

4. Animal model estimation of additive and dominance variances in egg production traits of poultry

Author

Wei, Ming and van der Werf, Julius H.J.

Subjects
Animal models in research -- Usage, Eggs -- Production, Poultry research -- Analysis, Zoology and wildlife conservation
Abstract

An animal model analysis was used to estimate simultaneously additive |Mathematical Expression Omitted~ and dominance |Mathematical Expression Omitted~ variances for egg production traits within three White Leghorn lines. The data consisted of information for three generations on egg number (EN) produced at 18 to 25 (EN1), 26 to 65 (EN2), and 18 to 65 wk of age (EN3); egg weight (EW) measured at 30 to 35 (EW1) and 40 to 45 wk (EW2); and egg specific gravity (ESG) measured at 30 to 35 (ESG1) and 40 to 45 wk (ESG2). A transformation was used for EN2 and EN3 because of a skewed distribution. In total, 813 sires, 2,575 dams, and 28,649 daughters were involved in the analyses. Three genetic models (sire-dam, additive, and dominance) were compared in estimating heritability (|h.sup.2~). The sire-dam model underestimated |h.sup.2~ because it ignored animal relationships. The |h.sup.2~ estimates from the additive model were approximately 9 to 52% higher for EN and 2 to 18% higher for EW and ESG than those from the dominance model. The differences between the |h.sup.2~ estimates from the additive and dominance models were increased for larger dominance variance |Mathematical Expression Omitted~. Ratios of |Mathematical Expression Omitted~ to total variance were high for EN (10 to 20%) and low for EW and ESG (1 to 13%). Ratios of |Mathematical Expression Omitted~ to total genetic variance for EN1, EN2, EN3, EW1, EW2, ESG1, and ESG2 were 18 to 36, 29 to 43, 29 to 56, 1 to 26, 3 to 8, 20 to 27, and 2 to 14%, respectively. The results on dominance were in good agreement with heterosis and inbreeding depression for these egg production traits described previously.

Published
1993

6. Sensitivity of the breeding values for growth rate and worm egg count to environmental worm burden in Australian Merino sheep

Author

Hollema, Baukje L., Bijma, Piter, van der Werf, Julius H.J., Hollema, Baukje L., Bijma, Piter, and van der Werf, Julius H.J.

Abstract

The objective of this study was to explore the sensitivity of breeding values for growth rate and worm egg count (WEC, cube root transformed) to environmental worm burden, measured as the average WEC for each contemporary group (CGWEC). Growth rate and WEC were measured on 7,818 naturally infected Merino lambs in eight flocks across Australia, linked through common use of AI sires. Through bivariate analysis, genetic correlations of 0.55 ± 0.23 and 0.30 ± 0.16 were found for growth rate and WEC between low and high CGWEC, respectively. In a second analysis, breeding values for growth rate and WEC were regressed on CGWEC with a random regression model. The heritability for growth rate varied from 0.23 to 0.16 from low to high CGWEC, and the heritability for WEC varied from 0.25 to 0.36. Results suggest that breeding values for both growth rate and WEC are sensitive to environmental worm burden. Animals expressed less genetic variation for growth rate and more genetic variation for WEC in high CGWEC than in low CGWEC. This form of genotype-by-environment interaction should therefore be considered in genetic evaluation of both growth rate and WEC, to increase the efficiency of selection for animals that are more parasite resistant and more resilient to environmental worm challenge.

Published
2018

17. Using imputed whole-genome sequence data to improve the accuracy of genomic prediction for parasite resistance in Australian sheep

Author

Hans D. Daetwyler, N. Duijvesteijn, John P. Gibson, Nasir Moghaddar, Mohammad Al Kalaldeh, Sang Hong Lee, Iona M. MacLeod, Julius H. J. van der Werf, Al Kalaldeh, Mohammad, Gibson, John, Duijvesteijn, Naomi, Daetwyler, Hans D., MacLeod, Iona, Moghaddar, Nasir, Lee, Sang Hong, and van der Werf, Julius H.J.

Subjects
Genetic Markers, Male, lcsh:QH426-470, [SDV]Life Sciences [q-bio], Quantitative Trait Loci, Sheep Diseases, Genome-wide association study, Single-nucleotide polymorphism, Computational biology, Biology, Quantitative trait locus, nematode resistance, Polymorphism, Single Nucleotide, 03 medical and health sciences, Genetics, Animals, SNP, Genetic Testing, Parasite Egg Count, genotype imputation, Ecology, Evolution, Behavior and Systematics, Disease Resistance, underlying variation, 030304 developmental biology, Genetic association, lcsh:SF1-1100, 2. Zero hunger, Whole genome sequencing, variants, 0303 health sciences, Sheep, Whole Genome Sequencing, Australia, 0402 animal and dairy science, Genetic Variation, 04 agricultural and veterinary sciences, General Medicine, Heritability, 040201 dairy & animal science, lcsh:Genetics, Genetic marker, quantitative trait loci, Female, Animal Science and Zoology, lcsh:Animal culture, mixed-model analysis, Research Article, Genome-Wide Association Study
Abstract

International audience; AbstractBackgroundThis study aimed at (1) comparing the accuracies of genomic prediction for parasite resistance in sheep based on whole-genome sequence (WGS) data to those based on 50k and high-density (HD) single nucleotide polymorphism (SNP) panels; (2) investigating whether the use of variants within quantitative trait loci (QTL) regions that were selected from regional heritability mapping (RHM) in an independent dataset improved the accuracy more than variants selected from genome-wide association studies (GWAS); and (3) comparing the prediction accuracies between variants selected from WGS data to variants selected from the HD SNP panel.ResultsThe accuracy of genomic prediction improved marginally from 0.16 ± 0.02 and 0.18 ± 0.01 when using all the variants from 50k and HD genotypes, respectively, to 0.19 ± 0.01 when using all the variants from WGS data. Fitting a GRM from the selected variants alongside a GRM from the 50k SNP genotypes improved the prediction accuracy substantially compared to fitting the 50k SNP genotypes alone. The gain in prediction accuracy was slightly more pronounced when variants were selected from WGS data compared to when variants were selected from the HD panel. When sequence variants that passed the GWAS -log10(pvalue)\documentclass[12pt]{minimal}\usepackage{amsmath}\usepackage{wasysym}\usepackage{amsfonts}\usepackage{amssymb}\usepackage{amsbsy}\usepackage{mathrsfs}\usepackage{upgreek}\setlength{\oddsidemargin}{-69pt}\begin{document}$$- log_{10} (p\,value)$$\end{document} threshold of 3 across the entire genome were selected, the prediction accuracy improved by 5% (up to 0.21 ± 0.01), whereas when selection was limited to sequence variants that passed the same GWAS -log10(pvalue)\documentclass[12pt]{minimal}\usepackage{amsmath}\usepackage{wasysym}\usepackage{amsfonts}\usepackage{amssymb}\usepackage{amsbsy}\usepackage{mathrsfs}\usepackage{upgreek}\setlength{\oddsidemargin}{-69pt}\begin{document}$$- log_{10} (p\,value)$$\end{document} threshold of 3 in regions identified by RHM, the accuracy improved by 9% (up to 0.25 ± 0.01).ConclusionsOur results show that through careful selection of sequence variants from the QTL regions, the accuracy of genomic prediction for parasite resistance in sheep can be improved. These findings have important implications for genomic prediction in sheep.

Published
2019

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