Your search keyword '"Nirea, Kahsay G"' showing total 4 results

1. Strategies for implementing genomic selection in family-based aquaculture breeding schemes: double haploid sib test populations

Author

Nirea Kahsay G, Sonesson Anna K, Woolliams John A, and Meuwissen Theo HE

Subjects

Animal culture, SF1-1100, Genetics, QH426-470

Abstract

Abstract Background Simulation studies have shown that accuracy and genetic gain are increased in genomic selection schemes compared to traditional aquaculture sib-based schemes. In genomic selection, accuracy of selection can be maximized by increasing the precision of the estimation of SNP effects and by maximizing the relationships between test sibs and candidate sibs. Another means of increasing the accuracy of the estimation of SNP effects is to create individuals in the test population with extreme genotypes. The latter approach was studied here with creation of double haploids and use of non-random mating designs. Methods Six alternative breeding schemes were simulated in which the design of the test population was varied: test sibs inherited maternal (Mat), paternal (Pat) or a mixture of maternal and paternal (MatPat) double haploid genomes or test sibs were obtained by maximum coancestry mating (MaxC), minimum coancestry mating (MinC), or random (RAND) mating. Three thousand test sibs and 3000 candidate sibs were genotyped. The test sibs were recorded for a trait that could not be measured on the candidates and were used to estimate SNP effects. Selection was done by truncation on genome-wide estimated breeding values and 100 individuals were selected as parents each generation, equally divided between both sexes. Results Results showed a 7 to 19% increase in selection accuracy and a 6 to 22% increase in genetic gain in the MatPat scheme compared to the RAND scheme. These increases were greater with lower heritabilities. Among all other scenarios, i.e. Mat, Pat, MaxC, and MinC, no substantial differences in selection accuracy and genetic gain were observed. Conclusions In conclusion, a test population designed with a mixture of paternal and maternal double haploids, i.e. the MatPat scheme, increases substantially the accuracy of selection and genetic gain. This will be particularly interesting for traits that cannot be recorded on the selection candidates and require the use of sib tests, such as disease resistance and meat quality.

Published

2012

2. Effect of non-random mating on genomic and BLUP selection schemes

Author

Nirea Kahsay G, Sonesson Anna K, Woolliams John A, and Meuwissen Theo HE

Subjects

Animal culture, SF1-1100, Genetics, QH426-470

Abstract

Abstract Background The risk of long-term unequal contribution of mating pairs to the gene pool is that deleterious recessive genes can be expressed. Such consequences could be alleviated by appropriately designing and optimizing breeding schemes i.e. by improving selection and mating procedures. Methods We studied the effect of mating designs, random, minimum coancestry and minimum covariance of ancestral contributions on rate of inbreeding and genetic gain for schemes with different information sources, i.e. sib test or own performance records, different genetic evaluation methods, i.e. BLUP or genomic selection, and different family structures, i.e. factorial or pair-wise. Results Results showed that substantial differences in rates of inbreeding due to mating design were present under schemes with a pair-wise family structure, for which minimum coancestry turned out to be more effective to generate lower rates of inbreeding. Specifically, substantial reductions in rates of inbreeding were observed in schemes using sib test records and BLUP evaluation. However, with a factorial family structure, differences in rates of inbreeding due mating designs were minor. Moreover, non-random mating had only a small effect in breeding schemes that used genomic evaluation, regardless of the information source. Conclusions It was concluded that minimum coancestry remains an efficient mating design when BLUP is used for genetic evaluation or when the size of the population is small, whereas the effect of non-random mating is smaller in schemes using genomic evaluation.

Published

2012

3. Assessment of fecal near-infrared spectroscopy to predict feces chemical composition and apparent total-tract digestibility of nutrients in pigs

Author

Nirea, Kahsay G, Pérez de Nanclares, Marta, Skugor, Adrijana, Afseth, Nils K, Meuwissen, Theodorus H E, Hansen, Jon Ø, Mydland, Liv T, and Øverland, Margareth

Subjects

Dietary Fiber, Gastrointestinal Tract, Male, Feces, Spectroscopy, Near-Infrared, Swine, Animals, Digestion, Female, Non Ruminant Nutrition, Animal Feed, Diet

Abstract

Apparent total-tract digestibility (ATTD) of nutrients could be an alternative measure of feed efficiency (FE) when breeding for robust animals that are fed fiber-rich diets. Apparent total-tract digestibility of nutrients requires measuring individual feed intake of a large number of animals which is expensive and complex. Alternatively, ATTD of nutrients and feces chemical composition can be predicted using fecal near-infrared reflectance spectroscopy (FNIRS). The objective of this study was to assess if the feces chemical composition and ATTD of nutrients can be predicted using FNIRS that originate from various pig-experimental datasets. Fecal samples together with detailed information on the feces chemical composition and ATTD of nutrients were obtained from four different pig experiments. Feces near-infrared spectroscopy was analyzed from fecal samples of a complete dataset. The model was calibrated using the FNIRS and reference samples of feces chemical composition and ATTD of nutrients. The robustness and predictability of the model were evaluated by the r(2) and the closeness between SE of calibration (SEC) and SE of cross-validation (SECV). Prediction of the feces chemical components and ATTD of nutrients were successful as SEC and SECV were equivalent. Calibration model was developed to estimate the ATTD of nutrients and fecal chemical composition from the FNIRS and worked well for OM (r(2) = 0.94; SEC = 48.5; SECV = 56.6), CP (r(2) = 0.89; SEC = 18.1; SECV = 18.8), GE (r(2) = 0.92; SEC = 1.2; SECV = 1.4), NDF (r(2) = 0.94; SEC = 55; SECV = 60.2), OM digestibility (r(2) = 0.94; SEC = 5.5; SECV = 6.7), GE digestibility (r(2) = 0.88; SEC = 2.3; SECV = 2.6), and fat digestibility (r(2) = 0.79; SEC = 6, SECV = 6.8). However, the SE of prediction was slightly higher than what has been reported in another study. The prediction of feces chemical composition for fat (r(2) = 0.69; SEC = 11.7, SECV = 12.3), CP digestibility (r(2) = 0.63; SEC = 2.3; SECV = 2.7), and NDF digestibility (r(2) = 0.64, SEC = 7.7, SECV = 8.8) was moderate. We conclude that the FNIRS accurately predicts the chemical composition of feces and ATTD of nutrients for OM, CP, and GE. The approach of FNIRS is a cost-effective method for measuring digestibility and FE in a large-scale pig-breeding programs.

Published

2018

4. Assessment of fecal near-infrared spectroscopy to predict feces chemical composition and apparent total-tract digestibility of nutrients in pigs1

Author

Nirea, Kahsay G, primary, Pérez de Nanclares, Marta, additional, Skugor, Adrijana, additional, Afseth, Nils K, additional, Meuwissen, Theodorus H E, additional, Hansen, Jon Ø, additional, Mydland, Liv T, additional, and Øverland, Margareth, additional

Published

2018