Your search keyword '"Lehnert Sigrid A"' showing total 7 results

1. Nutrition-Gene Interactions (Post-Genomics) : Changes in gene expression through nutritional manipulations

Author

Harper, Gregory S., Lehnert, Sigrid A., Greenwood, Paul L., Makkar, Harinder P.S., editor, and Viljoen, Gerrit J., editor

Published

2005

2. In silico validation of pooled genotyping strategies for genomic evaluation in Angus cattle.

Author

Alexandre, Pâmela A., Reverter, Antonio, Lehnert, Sigrid A., Porto-Neto, Laercio R., and Dominik, Sonja

Abstract

In this study, we aimed to assess the value of genotyping DNA pools as a strategy to generate accurate and cost-effective genomic estimated breeding values (GEBV) of sires in multi-sire mating systems. In order to do that, we used phenotypic records of 2,436 Australian Angus cattle from 174 sires, including yearling weight (YWT; N = 1,589 records), coat score (COAT; N = 2,026 records), and Meat Standards Australia marbling score (MARB; N = 1,304 records). Phenotypes were adjusted for fixed effects and age at measurement and pools of 2, 5, 10, 15, 20, and 25 animals were explored. Pools were created either by phenotype or at random. When pools were created at random, 10 replicates were examined to provide a measure of sampling variation. The relative accuracy of each pooling strategy was measured by the Pearson correlation coefficient between the sire’s GEBV with pooled progeny and the GEBV using individually genotyped progeny. Random pools allow the computation of sire GEBV that are, on average, moderately correlated (i.e., r > 0.5 at pool sizes [PS] ≤ 10) with those obtained without pooling. However, for pools assigned at random, the difference between the best and the worst relative accuracy obtained out of the 10 replicates was as high as 0.41 for YWT, 0.36 for COAT, and 0.61 for MARB. This uncertainty associated with the relative accuracy of GEBV makes randomly assigning animals to pools an unreliable approach. In contrast, pooling by phenotype allowed the estimation of sires’ GEBV with a relative accuracy ≥ 0.9 at PS < 10 for all three phenotypes. Moreover, even with larger PS, the lowest relative accuracy obtained was 0.88 (YWT, PS = 20). In agreement with results using simulated data, we conclude that pooling by phenotype is a robust approach to implementing genomic evaluation using commercial herd data, and PS larger than 10 individuals can be considered. [ABSTRACT FROM AUTHOR]

Published

2020

3. Pooled genotyping strategies for the rapid construction of genomic reference populations.

Author

Alexandre, Pâmela A, Porto-Neto, Laercio R, Karaman, Emre, Lehnert, Sigrid A, and Reverter, Antonio

Subjects

CATTLE herding, GENETIC correlations, GENOTYPES, ANIMAL genetics, BEEF cattle

Abstract

The growing concern with the environment is making important for livestock producers to focus on selection for efficiency-related traits, which is a challenge for commercial cattle herds due to the lack of pedigree information. To explore a cost-effective opportunity for genomic evaluations of commercial herds, this study compared the accuracy of bulls' genomic estimated breeding values (GEBV) using different pooled genotype strategies. We used ten replicates of previously simulated genomic and phenotypic data for one low (t1) and one moderate (t2) heritability trait of 200 sires and 2,200 progeny. Sire's GEBV were calculated using a univariate mixed model, with a hybrid genomic relationship matrix (h-GRM) relating sires to: 1) 1,100 pools of 2 animals; 2) 440 pools of 5 animals; 3) 220 pools of 10 animals; 4) 110 pools of 20 animals; 5) 88 pools of 25 animals; 6) 44 pools of 50 animals; and 7) 22 pools of 100 animals. Pooling criteria were: at random, grouped sorting by t1, grouped sorting by t2, and grouped sorting by a combination of t1 and t2. The same criteria were used to select 110, 220, 440, and 1,100 individual genotypes for GEBV calculation to compare GEBV accuracy using the same number of individual genotypes and pools. Although the best accuracy was achieved for a given trait when pools were grouped based on that same trait (t1: 0.50–0.56, t2: 0.66–0.77), pooling by one trait impacted negatively on the accuracy of GEBV for the other trait (t1: 0.25–0.46, t2: 0.29–0.71). Therefore, the combined measure may be a feasible alternative to use the same pools to calculate GEBVs for both traits (t1: 0.45–0.57, t2: 0.62–0.76). Pools of 10 individuals were identified as representing a good compromise between loss of accuracy (~10%–15%) and cost savings (~90%) from genotype assays. In addition, we demonstrated that in more than 90% of the simulations, pools present higher sires' GEBV accuracy than individual genotypes when the number of genotype assays is limited (i.e. 110 or 220) and animals are assigned to pools based on phenotype. Pools assigned at random presented the poorest results (t1: 0.07–0.45, t2: 0.14–0.70). In conclusion, pooling by phenotype is the best approach to implementing genomic evaluation using commercial herd data, particularly when pools of 10 individuals are evaluated. While combining phenotypes seems a promising strategy to allow more flexibility to the estimates made using pools, more studies are necessary in this regard. [ABSTRACT FROM AUTHOR]

Published

2019

4. Weighting genomic and genealogical information for genetic parameter estimation and breeding value prediction in tropical beef cattle.

Author

Raidan, Fernanda S S, Porto-Neto, Laercio R, Li, Yutao, Lehnert, Sigrid A, and Reverter, Antonio

Subjects

GENOTYPES, GENOMICS, SINGLE nucleotide polymorphisms, PLANT breeding, NUCLEOTIDES

Abstract

A combined matrix that exploits genealogy together with marker-based information could improve the selection of elite individuals in breeding programs. We present genetic parameters for adaptive and growth traits in beef cattle by exploring linear combinations of pedigree-based (A) and marker-based (G) relationship matrices. We use a data set with 2,111 Brahman (BB) and 2,550 Tropical Composite (TC) cattle with genotypes for 729,068 SNP, and phenotypes for five traits. A weighted relationship matrix (WRM) combining G and A was constructed as WRM = λG + (1 - λ)A. The weight (λ) was explored at values from 0.0 to 1.0, at 0.1 intervals. Additionally, four alternative G matrices, in the WRM, were evaluated according to the selection of SNP used to generate them: 1) Gw: all autosomal SNP with minor allele frequency (MAF) > 1%; 2) Gg: autosomal SNP with MAF > 1% and mapped inside to gene coding regions; 3) Gp: autosomal SNP with MAF > 1% and previously reported to have significant pleiotropic effect in these two populations; and 4) Gc: autosomal SNP with MAF > 1% and with significant correlated effects previously reported in both BB and TC populations. In addition, two A matrices were evaluated: 1) A: all relationships between animals were considered after tracing back known ancestors; and 2) Ad: a distorted A matrix where a random 1% of the off-diagonal nonzero values were set to zero to simulate relationship errors. Five independent Ad matrices were explored each with a different random 1% of relationships masked. Criteria for comparing the resulting WRM included estimates of heritability (h2) and cross-validation accuracy (ACC) of genomic estimated breeding values. The choice of WRM had a greater impact on h2 than on ACC estimates. The 1% errors introduced in pedigree relationships generated large distortion in genetic parameters and ACC estimates. However, employing a λ > 0.7 was an efficient mechanism to compensate for the errors in A. Additionally, although significant (P-value < 0.0001), we found no consistent relationship between the type of SNP used to compute G and h2 or ACC estimates. We devised the optimal value of λ for maximum h2 and ACC at λ = 0.7 suggesting a 70% and 30% weighting to genomic and genealogical information, respectively, as an optimal strategy to compensate for pedigree errors, to improve genetic parameters estimates and lead to more accurate selection decisions. [ABSTRACT FROM AUTHOR]

Published

2018

5. Non-synonymous mutations mapped to chromosome X associated with andrological and growth traits in beef cattle.

Author

de Camargo, Gregório Miguel Ferreira, Porto-Neto, Laercio R., Kelly, Matthew J., Bunch, Rowan J., McWilliam, Sean M., Tonhati, Humberto, Lehnert, Sigrid A., Fortes, Marina R. S., and Moore, Stephen S.

Subjects

BEEF cattle, CHROMOSOMES, BOVINE spongiform encephalopathy, VIRUS diseases in cattle, BRAHMAN, BIOINFORMATICS

Abstract

Background: Previous genome-wide association analyses identified QTL regions in the X chromosome for percentage of normal sperm and scrotal circumference in Brahman and Tropical Composite cattle. These traits are important to be studied because they are indicators of male fertility and are correlated with female sexual precocity and reproductive longevity. The aim was to investigate candidate genes in these regions and to identify putative causative mutations that influence these traits. In addition, we tested the identified mutations for female fertility and growth traits. Results: Using a combination of bioinformatics and molecular assay technology, twelve non-synonymous SNPs in eleven genes were genotyped in a cattle population. Three and nine SNPs explained more than 1% of the additive genetic variance for percentage of normal sperm and scrotal circumference, respectively. The SNPs that had a major influence in percentage of normal sperm were mapped to LOC100138021 and TAF7L genes; and in TEX11 and AR genes for scrotal circumference. One SNP in TEX11 was explained ~13% of the additive genetic variance for scrotal circumference at 12 months. The tested SNP were also associated with weight measurements, but not with female fertility traits. Conclusions: The strong association of SNPs located in X chromosome genes with male fertility traits validates the QTL. The implicated genes became good candidates to be used for genetic evaluation, without detrimentally influencing female fertility traits. [ABSTRACT FROM AUTHOR]

Published

2015

6. Potential GHG emission benefits of Asparagopsis taxiformis feed supplement in Australian beef cattle feedlots.

Author

Ridoutt, Bradley, Lehnert, Sigrid A., Denman, Stuart, Charmley, Edward, Kinley, Robert, and Dominik, Sonja

Subjects

*RUMINANTS, *GREENHOUSE gases, *BEEF cattle, *DIETARY supplements, *FEED utilization efficiency, *RADIATIVE forcing, *FEEDLOTS

Abstract

The red macroalgae Asparagopsis taxiformis has been identified as a promising feed supplement to inhibit enteric methane formation during ruminant livestock production and thereby contribute to GHG emissions reduction. Some studies also suggest improvements to animal weight gain through enhanced feed conversion efficiency. In this study, the potential GHG emissions reduction benefits were assessed from a life cycle perspective and in an actual industry context – the large Australian beef cattle sector, where feed supplementation occurred during feedlot finishing, when farmers have greatest control over animal diets. Seven adoption scenarios were compared to a baseline emissions inventory that was extrapolated to 2030. Feed supplementation with A. taxiformis had the potential to reduce the sector's carbon footprint by 1–4% in 2030, which due to the scale of the industry is a relevant emissions reduction (0.6–2.0 Mt CO 2 e), but modest in relation to the industry's goal of carbon neutrality by 2030. When emissions were assessed using alternative climate metrics that are more sensitive to changes in the rate of methane emission than the GWP100 climate metric (i.e. GWP*, radiative forcing climate footprint), larger potential benefits were found. Considering only the feedlot subsector, the radiative forcing climate footprint reached a plateau under most scenarios, indicating that climate neutrality is realistically achievable for the feedlot subsector within 5 years. That said, concurrent action on CO 2 and N 2 O emissions will be needed, as even steep reductions in methane emissions at the expense of additional long-lived emissions will only achieve a short-term climate benefit and will make long-term climate stabilization more difficult. [Display omitted] • Asparagopsis taxiformis feed ingredient inhibits methane production by beef cattle. • Life cycle GHG emission scenarios were modelled for use in Australian feedlots. • The carbon footprint of Australian beef cattle could be reduced by 1–4% by 2030. • Beef cattle feedlots could become climate neutral from 2024. • Choice of climate metric highly impacts the assessment of benefits. [ABSTRACT FROM AUTHOR]

Published

2022

7. Conceptus-related measurements during the first trimester of bovine pregnancy.

Author

Riding, George A., Lehnert, Sigrid A., French, Andrew J., and Hill, Jonathan R.

Subjects

*CATTLE pregnancy, *BEEF cattle, *AMNIOTIC liquid, *PROTEINS, *GESTATIONAL age

Abstract

In order to determine the variability inherent in conceptus-related measurements in first trimester bovine pregnancies, conceptus and fetometric parameters from beef cattle pregnancies (n = 103) estimated to be between Days 36 and 103 of gestation were examined. During this period, the protein concentration of amniotic fluid ranged between 0.181 and 0.501 mg/mL. The amniotic fluid volume gradually increased from <1 mL at Day 36 to 950 mL at Day 103 (R² = 0.9275) and amniotic compartment dimensions (length, R²= 0.9713; width, R² = 0.9802) increased predictably with fetal growth. Conversely, allantoic fluid protein concentration and volume correlated weakly with fetal age. A significant linear correlation existed between fetal crown rump length (CRL) and crown nose length (R² = 0.9899) confirming that either measurement can be employed in the ultrasonographic estimation of fetal age. The amniotic compartment and fetometric data presented here have both research and clinical value, particularly in relation to fetal development evaluation and pregnancy viability diagnosis. [ABSTRACT FROM AUTHOR]

Published

2008