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4. 280. Accuracy of genomic prediction of dry matter intake in Dutch Holsteins using sequence variants from meta-analyses

Author

Gredler-Grandl, B., primary, Raymond, B., additional, Schopen, G.C.B., additional, Chitneedi, P.K., additional, Cai, Z., additional, Manzanilla-Pech, C.I.V., additional, Iso-Touru, T., additional, Fischer, D., additional, Bolormaa, S., additional, Chud, T.S., additional, Schenkel, F.S., additional, Wang, Y., additional, Li, C., additional, Hailemariam, D., additional, Villanueva, B., additional, Fernandez, A., additional, Kuehn, C., additional, Sahana, G., additional, Lidauer, M.H., additional, Pryce, J.E., additional, González-Recio, O., additional, Plastow, G., additional, Baes, C.F., additional, Charfeddine, N., additional, de Haas, Y., additional, Veerkamp, R.F., additional, and Bouwman, A.C., additional

Published
2022
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5. 20. Genetically more efficient Australian dairy cows and sheep are higher emitters of methane per unit of food

Author

Sepulveda, B.J., primary, Muir, S.K., additional, Bolormaa, S., additional, MacLeod, I.M., additional, Knight, M.I., additional, Behrendt, R., additional, Marett, L.C., additional, Deighton, M.H., additional, Garner, J.B., additional, Moate, P.J., additional, Wales, W.J., additional, Williams, R.O., additional, Daetwyler, H.D., additional, Cocks, B.G., additional, and Pryce, J.E., additional

Published
2022
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9. Evaluation of updated Feed Saved breeding values developed in Australian Holstein dairy cattle.

Author

Bolormaa, S, MacLeod, IM, Khansefid, M, Marett, LC, Wales, WJ, Nieuwhof, GJ, Baes, CF, Schenkel, FS, Goddard, ME, Pryce, JE, Bolormaa, S, MacLeod, IM, Khansefid, M, Marett, LC, Wales, WJ, Nieuwhof, GJ, Baes, CF, Schenkel, FS, Goddard, ME, and Pryce, JE

Abstract

Although selection for increased milk production traits has led to a genetic increase in body weight (BW), the genetic gain in milk production has exceeded the gain in BW, so gross feed efficiency has improved. Nonetheless, greater gains may be possible by directly selecting for a measure of feed efficiency. Australia first introduced Feed Saved (FS) estimated breeding value (EBV) in 2015. Feed Saved combines residual feed intake (RFI) genomic EBV and maintenance requirements calculated from mature BW EBV. The FS EBV was designed to enable the selection of cows for reduced energy requirements with similar milk production. In this study, we used a reference population of 3,711 animals in a multivariate analysis including Australian heifers (AUSh), Australian cows (AUSc), and overseas cows (OVEc) to update the Australian EBV for lifetime RFI (i.e., a breeding value that incorporated RFI in growing and lactating cows) and to recalculate the FS EBV in Australian Holstein bulls (AUSb). The estimates of genomic heritabilities using univariate (only AUSc or AUSh) to trivariate (including the OVEc) analyses were similar. Genomic heritabilities for RFI were estimated as 0.18 for AUSc, 0.27 for OVEc, and 0.36 for AUSh. The genomic correlation for RFI between AUSc and AUSh was 0.47 and that between AUSc and OVEc was 0.94, but these estimates were associated with large standard errors (range: 0.18-0.28). The reliability of lifetime RFI (a component of FS) in the trivariate analysis (i.e., including OVEc) increased from 11% to 20% compared with the 2015 model and was greater, by 12%, than in a bivariate analysis in which the reference population included only AUSc and AUSh. By applying the prediction equation of the 2020 model, the average reliability of the FS EBV in 20,816 AUSb that were born between 2010 and 2020 improved from 33% to 43%. Previous selection strategies-that is, using the predecessor of the Balanced Performance Index (Australian Profit Ranking index) that did n

Published
2022

10. Sharing of either phenotypes or genetic variants can increase the accuracy of genomic prediction of feed efficiency

Author

Bolormaa, S, MacLeod, IM, Khansefid, M, Marett, LC, Wales, WJ, Miglior, F, Baes, CF, Schenkel, FS, Connor, EE, Manzanilla-Pech, CI, Stothard, P, Herman, E, Nieuwhof, GJ, Goddard, ME, Pryce, JE, Bolormaa, S, MacLeod, IM, Khansefid, M, Marett, LC, Wales, WJ, Miglior, F, Baes, CF, Schenkel, FS, Connor, EE, Manzanilla-Pech, CI, Stothard, P, Herman, E, Nieuwhof, GJ, Goddard, ME, and Pryce, JE

Abstract

BACKGROUND: Sharing individual phenotype and genotype data between countries is complex and fraught with potential errors, while sharing summary statistics of genome-wide association studies (GWAS) is relatively straightforward, and thus would be especially useful for traits that are expensive or difficult-to-measure, such as feed efficiency. Here we examined: (1) the sharing of individual cow data from international partners; and (2) the use of sequence variants selected from GWAS of international cow data to evaluate the accuracy of genomic estimated breeding values (GEBV) for residual feed intake (RFI) in Australian cows. RESULTS: GEBV for RFI were estimated using genomic best linear unbiased prediction (GBLUP) with 50k or high-density single nucleotide polymorphisms (SNPs), from a training population of 3797 individuals in univariate to trivariate analyses where the three traits were RFI phenotypes calculated using 584 Australian lactating cows (AUSc), 824 growing heifers (AUSh), and 2526 international lactating cows (OVE). Accuracies of GEBV in AUSc were evaluated by either cohort-by-birth-year or fourfold random cross-validations. GEBV of AUSc were also predicted using only the AUS training population with a weighted genomic relationship matrix constructed with SNPs from the 50k array and sequence variants selected from a meta-GWAS that included only international datasets. The genomic heritabilities estimated using the AUSc, OVE and AUSh datasets were moderate, ranging from 0.20 to 0.36. The genetic correlations (rg) of traits between heifers and cows ranged from 0.30 to 0.95 but were associated with large standard errors. The mean accuracies of GEBV in Australian cows were up to 0.32 and almost doubled when either overseas cows, or both overseas cows and AUS heifers were included in the training population. They also increased when selected sequence variants were combined with 50k SNPs, but with a smaller relative increase. CONCLUSIONS: The accuracy of RFI G

Published
2022

15. A conditional multi-trait sequence GWAS discovers pleiotropic candidate genes and variants for sheep wool, skin wrinkle and breech cover traits

Author

Bolormaa, S, Swan, AA, Stothard, P, Khansefid, M, Moghaddar, N, Duijvesteijn, N, van der Werf, JHJ, Daetwyler, HD, MacLeod, IM, Bolormaa, S, Swan, AA, Stothard, P, Khansefid, M, Moghaddar, N, Duijvesteijn, N, van der Werf, JHJ, Daetwyler, HD, and MacLeod, IM

Abstract

BACKGROUND: Imputation to whole-genome sequence is now possible in large sheep populations. It is therefore of interest to use this data in genome-wide association studies (GWAS) to investigate putative causal variants and genes that underpin economically important traits. Merino wool is globally sought after for luxury fabrics, but some key wool quality attributes are unfavourably correlated with the characteristic skin wrinkle of Merinos. In turn, skin wrinkle is strongly linked to susceptibility to "fly strike" (Cutaneous myiasis), which is a major welfare issue. Here, we use whole-genome sequence data in a multi-trait GWAS to identify pleiotropic putative causal variants and genes associated with changes in key wool traits and skin wrinkle. RESULTS: A stepwise conditional multi-trait GWAS (CM-GWAS) identified putative causal variants and related genes from 178 independent quantitative trait loci (QTL) of 16 wool and skin wrinkle traits, measured on up to 7218 Merino sheep with 31 million imputed whole-genome sequence (WGS) genotypes. Novel candidate gene findings included the MAT1A gene that encodes an enzyme involved in the sulphur metabolism pathway critical to production of wool proteins, and the ESRP1 gene. We also discovered a significant wrinkle variant upstream of the HAS2 gene, which in dogs is associated with the exaggerated skin folds in the Shar-Pei breed. CONCLUSIONS: The wool and skin wrinkle traits studied here appear to be highly polygenic with many putative candidate variants showing considerable pleiotropy. Our CM-GWAS identified many highly plausible candidate genes for wool traits as well as breech wrinkle and breech area wool cover.

Published
2021

16. Mutant alleles differentially shape fitness and other complex traits in cattle

Author

Xiang, R, Breen, EJ, Bolormaa, S, Vander Jagt, CJ, Chamberlain, AJ, Macleod, IM, Goddard, ME, Xiang, R, Breen, EJ, Bolormaa, S, Vander Jagt, CJ, Chamberlain, AJ, Macleod, IM, and Goddard, ME

Abstract

Mutant alleles (MAs) that have been classically recognised have large effects on phenotype and tend to be deleterious to traits and fitness. Is this the case for mutations with small effects? We infer MAs for 8 million sequence variants in 113k cattle and quantify the effects of MA on 37 complex traits. Heterozygosity for variants at genomic sites conserved across 100 vertebrate species increase fertility, stature, and milk production, positively associating these traits with fitness. MAs decrease stature and fat and protein concentration in milk, but increase gestation length and somatic cell count in milk (the latter indicative of mastitis). However, the frequency of MAs decreasing stature and fat and protein concentration, increasing gestation length and somatic cell count were lower than the frequency of MAs with the opposite effect. These results suggest bias in the mutations direction of effect (e.g. towards reduced protein in milk), but selection operating to reduce the frequency of these MAs. Taken together, our results imply two classes of genomic sites subject to long-term selection: sites conserved across vertebrates show hybrid vigour while sites subject to less long-term selection show a bias in mutation towards undesirable alleles.

Published
2021

18. Vitamin D deficiency is associated with tuberculosis infection among household contacts in Ulaanbaatar, Mongolia

Author

Gurjav, U., primary, Ankhbat, M., additional, Ganbaatar, G., additional, Batjarga, K., additional, Ochirbat, B., additional, Baigal, D., additional, Jargalsaikhan, B., additional, Munkhjargal, O., additional, Bolormaa, S., additional, Yansanjav, N., additional, Luvsanyandan, N., additional, Dorj, G., additional, Dambaa, N., additional, Bromage, S., additional, and Ganmaa, D., additional

Published
2019
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19. Quantifying the contribution of sequence variants with regulatory and evolutionary significance to 34 bovine complex traits

Author

Xiang, R, van den Berg, I, MacLeod, IM, Hayes, BJ, Prowse-Wilkins, CP, Wang, M, Bolormaa, S, Liu, Z, Rochfort, SJ, Reich, CM, Mason, BA, Vander Jagt, CJ, Daetwyler, HD, Lund, MS, Chamberlain, AJ, Goddard, ME, Xiang, R, van den Berg, I, MacLeod, IM, Hayes, BJ, Prowse-Wilkins, CP, Wang, M, Bolormaa, S, Liu, Z, Rochfort, SJ, Reich, CM, Mason, BA, Vander Jagt, CJ, Daetwyler, HD, Lund, MS, Chamberlain, AJ, and Goddard, ME

Abstract

Many genome variants shaping mammalian phenotype are hypothesized to regulate gene transcription and/or to be under selection. However, most of the evidence to support this hypothesis comes from human studies. Systematic evidence for regulatory and evolutionary signals contributing to complex traits in a different mammalian model is needed. Sequence variants associated with gene expression (expression quantitative trait loci [eQTLs]) and concentration of metabolites (metabolic quantitative trait loci [mQTLs]) and under histone-modification marks in several tissues were discovered from multiomics data of over 400 cattle. Variants under selection and evolutionary constraint were identified using genome databases of multiple species. These analyses defined 30 sets of variants, and for each set, we estimated the genetic variance the set explained across 34 complex traits in 11,923 bulls and 32,347 cows with 17,669,372 imputed variants. The per-variant trait heritability of these sets across traits was highly consistent (r > 0.94) between bulls and cows. Based on the per-variant heritability, conserved sites across 100 vertebrate species and mQTLs ranked the highest, followed by eQTLs, young variants, those under histone-modification marks, and selection signatures. From these results, we defined a Functional-And-Evolutionary Trait Heritability (FAETH) score indicating the functionality and predicted heritability of each variant. In additional 7,551 cattle, the high FAETH-ranking variants had significantly increased genetic variances and genomic prediction accuracies in 3 production traits compared to the low FAETH-ranking variants. The FAETH framework combines the information of gene regulation, evolution, and trait heritability to rank variants, and the publicly available FAETH data provide a set of biological priors for cattle genomic selection worldwide.

Published
2019

20. Accuracy of imputation to whole-genome sequence in sheep

Author

Bolormaa, S, Chamberlain, AJ, Khansefid, M, Stothard, P, Swan, AA, Mason, B, Prowse-Wilkins, CP, Duijvesteijn, N, Moghaddar, N, van der Werf, JH, Daetwyler, HD, MacLeod, IM, Bolormaa, S, Chamberlain, AJ, Khansefid, M, Stothard, P, Swan, AA, Mason, B, Prowse-Wilkins, CP, Duijvesteijn, N, Moghaddar, N, van der Werf, JH, Daetwyler, HD, and MacLeod, IM

Abstract

BACKGROUND: The use of whole-genome sequence (WGS) data for genomic prediction and association studies is highly desirable because the causal mutations should be present in the data. The sequencing of 935 sheep from a range of breeds provides the opportunity to impute sheep genotyped with single nucleotide polymorphism (SNP) arrays to WGS. This study evaluated the accuracy of imputation from SNP genotypes to WGS using this reference population of 935 sequenced sheep. RESULTS: The accuracy of imputation from the Ovine Infinium® HD BeadChip SNP (~ 500 k) to WGS was assessed for three target breeds: Merino, Poll Dorset and F1 Border Leicester × Merino. Imputation accuracy was highest for the Poll Dorset breed, although there were more Merino individuals in the sequenced reference population than Poll Dorset individuals. In addition, empirical imputation accuracies were higher (by up to 1.7%) when using larger multi-breed reference populations compared to using a smaller single-breed reference population. The mean accuracy of imputation across target breeds using the Minimac3 or the FImpute software was 0.94. The empirical imputation accuracy varied considerably across the genome; six chromosomes carried regions of one or more Mb with a mean imputation accuracy of < 0.7. Imputation accuracy in five variant annotation classes ranged from 0.87 (missense) up to 0.94 (intronic variants), where lower accuracy corresponded to higher proportions of rare alleles. The imputation quality statistic reported from Minimac3 (R2) had a clear positive relationship with the empirical imputation accuracy. Therefore, by first discarding imputed variants with an R2 below 0.4, the mean empirical accuracy across target breeds increased to 0.97. Although accuracy of genomic prediction was less affected by filtering on R2 in a multi-breed population of sheep with imputed WGS, the genomic heritability clearly tended to be lower when using variants with an R2 ≤ 0.4. CONCLUSIONS: The mean imputat

Published
2019

21. Comparing allele specific expression and local expression quantitative trait loci and the influence of gene expression on complex trait variation in cattle

Author

Khansefid, M, Pryce, JE, Bolormaa, S, Chen, Y, Millen, CA, Chamberlain, AJ, Vander Jagt, CJ, Goddard, ME, Khansefid, M, Pryce, JE, Bolormaa, S, Chen, Y, Millen, CA, Chamberlain, AJ, Vander Jagt, CJ, and Goddard, ME

Abstract

BACKGROUND: The mutations changing the expression level of a gene, or expression quantitative trait loci (eQTL), can be identified by testing the association between genetic variants and gene expression in multiple individuals (eQTL mapping), or by comparing the expression of the alleles in a heterozygous individual (allele specific expression or ASE analysis). The aims of the study were to find and compare ASE and local eQTL in 4 bovine RNA-sequencing (RNA-Seq) datasets, validate them in an independent ASE study and investigate if they are associated with complex trait variation. RESULTS: We present a novel method for distinguishing between ASE driven by polymorphisms in cis and parent of origin effects. We found that single nucleotide polymorphisms (SNPs) driving ASE are also often local eQTL and therefore presumably cis eQTL. These SNPs often, but not always, affect gene expression in multiple tissues and, when they do, the allele increasing expression is usually the same. However, there were systematic differences between ASE and local eQTL and between tissues and breeds. We also found that SNPs significantly associated with gene expression (p < 0.001) were likely to influence some complex traits (p < 0.001), which means that some mutations influence variation in complex traits by changing the expression level of genes. CONCLUSION: We conclude that ASE detects phenomenon that overlap with local eQTL, but there are also systematic differences between the SNPs discovered by the two methods. Some mutations influencing complex traits are actually eQTL and can be discovered using RNA-Seq including eQTL in the genes CAST, CAPN1, LCORL and LEPROTL1.

Published
2018

22. Genome variants associated with RNA splicing variations in bovine are extensive shared between tissues

Author

Xiang, R, Hayes, BJ, Vander Jagt, CJ, MacLeod, IM, Khansefid, M, Bowman, PJ, Yuan, Z, Prowse-Wilkins, CP, Reich, CM, Mason, BA, Garner, JB, Marett, LC, Chen, Y, Bolormaa, S, Daetwyler, HD, Chamberlain, AJ, Goddard, ME, Xiang, R, Hayes, BJ, Vander Jagt, CJ, MacLeod, IM, Khansefid, M, Bowman, PJ, Yuan, Z, Prowse-Wilkins, CP, Reich, CM, Mason, BA, Garner, JB, Marett, LC, Chen, Y, Bolormaa, S, Daetwyler, HD, Chamberlain, AJ, and Goddard, ME

Abstract

BACKGROUND: Mammalian phenotypes are shaped by numerous genome variants, many of which may regulate gene transcription or RNA splicing. To identify variants with regulatory functions in cattle, an important economic and model species, we used sequence variants to map a type of expression quantitative trait loci (expression QTLs) that are associated with variations in the RNA splicing, i.e., sQTLs. To further the understanding of regulatory variants, sQTLs were compare with other two types of expression QTLs, 1) variants associated with variations in gene expression, i.e., geQTLs and 2) variants associated with variations in exon expression, i.e., eeQTLs, in different tissues. RESULTS: Using whole genome and RNA sequence data from four tissues of over 200 cattle, sQTLs identified using exon inclusion ratios were verified by matching their effects on adjacent intron excision ratios. sQTLs contained the highest percentage of variants that are within the intronic region of genes and contained the lowest percentage of variants that are within intergenic regions, compared to eeQTLs and geQTLs. Many geQTLs and sQTLs are also detected as eeQTLs. Many expression QTLs, including sQTLs, were significant in all four tissues and had a similar effect in each tissue. To verify such expression QTL sharing between tissues, variants surrounding (±1 Mb) the exon or gene were used to build local genomic relationship matrices (LGRM) and estimated genetic correlations between tissues. For many exons, the splicing and expression level was determined by the same cis additive genetic variance in different tissues. Thus, an effective but simple-to-implement meta-analysis combining information from three tissues is introduced to increase power to detect and validate sQTLs. sQTLs and eeQTLs together were more enriched for variants associated with cattle complex traits, compared to geQTLs. Several putative causal mutations were identified, including an sQTL at Chr6:87392580 within the 5th exon

Published
2018

23. Multi-breed genomic prediction using Bayes R with sequence data and dropping variants with a small effect

Author

van den Berg, I, Bowman, PJ, MacLeod, IM, Hayes, BJ, Wang, T, Bolormaa, S, Goddard, ME, van den Berg, I, Bowman, PJ, MacLeod, IM, Hayes, BJ, Wang, T, Bolormaa, S, and Goddard, ME

Abstract

BACKGROUND: The increasing availability of whole-genome sequence data is expected to increase the accuracy of genomic prediction. However, results from simulation studies and analysis of real data do not always show an increase in accuracy from sequence data compared to high-density (HD) single nucleotide polymorphism (SNP) chip genotypes. In addition, the sheer number of variants makes analysis of all variants and accurate estimation of all effects computationally challenging. Our objective was to find a strategy to approximate the analysis of whole-sequence data with a Bayesian variable selection model. Using a simulated dataset, we applied a Bayes R hybrid model to analyse whole-sequence data, test the effect of dropping a proportion of variants during the analysis, and test how the analysis can be split into separate analyses per chromosome to reduce the elapsed computing time. We also investigated the effect of imputation errors on prediction accuracy. Subsequently, we applied the approach to a dataset that contained imputed sequences and records for production and fertility traits for 38,492 Holstein, Jersey, Australian Red and crossbred bulls and cows. RESULTS: With the simulated dataset, we found that prediction accuracy was highly increased for a breed that was not represented in the training population for sequence data compared to HD SNP data. Either dropping part of the variants during the analysis or splitting the analysis into separate analyses per chromosome decreased accuracy compared to analysing whole-sequence data. First, dropping variants from each chromosome and reanalysing the retained variants together resulted in an accuracy similar to that obtained when analysing whole-sequence data. Adding imputation errors decreased prediction accuracy, especially for errors in the validation population. With real data, using sequence variants resulted in accuracies that were similar to those obtained with the HD SNPs. CONCLUSIONS: We present an efficient

Published
2017

24. Multiple-trait QTL mapping and genomic prediction for wool traits in sheep

Author

Bolormaa, S, Swan, AA, Brown, DJ, Hatcher, S, Moghaddar, N, van der Werf, JH, Goddard, ME, Daetwyler, HD, Bolormaa, S, Swan, AA, Brown, DJ, Hatcher, S, Moghaddar, N, van der Werf, JH, Goddard, ME, and Daetwyler, HD

Abstract

BACKGROUND: The application of genomic selection to sheep breeding could lead to substantial increases in profitability of wool production due to the availability of accurate breeding values from single nucleotide polymorphism (SNP) data. Several key traits determine the value of wool and influence a sheep's susceptibility to fleece rot and fly strike. Our aim was to predict genomic estimated breeding values (GEBV) and to compare three methods of combining information across traits to map polymorphisms that affect these traits. METHODS: GEBV for 5726 Merino and Merino crossbred sheep were calculated using BayesR and genomic best linear unbiased prediction (GBLUP) with real and imputed 510,174 SNPs for 22 traits (at yearling and adult ages) including wool production and quality, and breech conformation traits that are associated with susceptibility to fly strike. Accuracies of these GEBV were assessed using fivefold cross-validation. We also devised and compared three approximate multi-trait analyses to map pleiotropic quantitative trait loci (QTL): a multi-trait genome-wide association study and two multi-trait methods that use the output from BayesR analyses. One BayesR method used local GEBV for each trait, while the other used the posterior probabilities that a SNP had an effect on each trait. RESULTS: BayesR and GBLUP resulted in similar average GEBV accuracies across traits (~0.22). BayesR accuracies were highest for wool yield and fibre diameter (>0.40) and lowest for skin quality and dag score (<0.10). Generally, accuracy was higher for traits with larger reference populations and higher heritability. In total, the three multi-trait analyses identified 206 putative QTL, of which 20 were common to the three analyses. The two BayesR multi-trait approaches mapped QTL in a more defined manner than the multi-trait GWAS. We identified genes with known effects on hair growth (i.e. FGF5, STAT3, KRT86, and ALX4) near SNPs with pleiotropic effects on wool traits. CONCL

Published
2017

25. Genome-wide comparative analyses of correlated and uncorrelated phenotypes identify major pleiotropic variants in dairy cattle

Author

Xiang, R, MacLeod, IM, Bolormaa, S, Goddard, ME, Xiang, R, MacLeod, IM, Bolormaa, S, and Goddard, ME

Abstract

While single nucleotide polymorphisms (SNPs) associated with multiple phenotype have been reported, the knowledge of pleiotropy of uncorrelated phenotype is minimal. Principal components (PCs) and uncorrelated Cholesky transformed traits (CT) were constructed using 25 raw traits (RTs) of 2841 dairy bulls. Multi-trait meta-analyses of single-trait genome-wide association studies for RT, PC and CT in bulls were validated in 6821 cows. Most PCs and CTs had substantial estimates of heritability, suggesting that genes affect phenotype via diverse pathways. Phenotypic orthogonalizations did not eliminate pleiotropy: the meta-analysis achieved an agreement of significant pleiotropic SNPs (p < 1 × 10-5, n = 368) between RTs (416), PCs (466) and CTs (425). From this overlap we identified 21 lead SNPs with 100% validation rate containing two clusters: one consisted of DGAT1 (chr14:1.8 M+), MGST1 (chr5:93 M+), PAEP (chr11:103 M+) and GPAT4 (chr27:36 M+) affecting protein, milk and fat yield and the other included CSN2 (chr6:87 M+), MUC1 (chr3:15.6 M), GHR (chr20:31.2 M+) and SDC2 (chr14:70 M+) affecting protein and milk yield. Combining beef cattle data identified correlated SNPs representing CAPN1 (chr29:44 M+) and CAST (chr 7:96 M+) loci affecting beef tenderness, showing pleiotropic effects in dairy cattle. Our findings show that SNPs with a large effect on one trait are likely to have small effects on other uncorrelated traits.

Published
2017

27. Detailed phenotyping identifies genes with pleiotropic effects on body composition

Author

Bolormaa, S., Hayes, B.J., van der Werf, J.H.J., Pethick, D., Goddard, M.E., Daetwyler, H.D., Bolormaa, S., Hayes, B.J., van der Werf, J.H.J., Pethick, D., Goddard, M.E., and Daetwyler, H.D.

Abstract

Background: Genetic variation in both the composition and distribution of fat and muscle in the body is important to human health as well as the healthiness and value of meat from cattle and sheep. Here we use detailed phenotyping and a multi-trait approach to identify genes explaining variation in body composition traits. Results: A multi-trait genome wide association analysis of 56 carcass composition traits measured on 10,613 sheep with imputed and real genotypes on 510,174 SNPs was performed. We clustered 71 significant SNPs into five groups based on their pleiotropic effects across the 56 traits. Among these 71 significant SNPs, one group of 11 SNPs affected the fatty acid profile of the muscle and were close to 8 genes involved in fatty acid or triglyceride synthesis. Another group of 23 SNPs had an effect on mature size, based on their pattern of effects across traits, but the genes near this group of SNPs did not share any obvious function. Many of the likely candidate genes near SNPs with significant pleiotropic effects on the 56 traits are involved in intra-cellular signalling pathways. Among the significant SNPs were some with a convincing candidate gene due to the function of the gene (e.g. glycogen synthase affecting glycogen concentration) or because the same gene was associated with similar traits in other species. Conclusions: Using a multi-trait analysis increased the power to detect associations between SNP and body composition traits compared with the single trait analyses. Detailed phenotypic information helped to identify a convincing candidate in some cases as did information from other species.

Published
2016

28. Detailed phenotyping identifies genes with pleiotropic effects on body composition

Author

Bolormaa, S, Hayes, BJ, van der Werf, JHJ, Pethick, D, Goddard, ME, Daetwyler, HD, Bolormaa, S, Hayes, BJ, van der Werf, JHJ, Pethick, D, Goddard, ME, and Daetwyler, HD

Abstract

BACKGROUND: Genetic variation in both the composition and distribution of fat and muscle in the body is important to human health as well as the healthiness and value of meat from cattle and sheep. Here we use detailed phenotyping and a multi-trait approach to identify genes explaining variation in body composition traits. RESULTS: A multi-trait genome wide association analysis of 56 carcass composition traits measured on 10,613 sheep with imputed and real genotypes on 510,174 SNPs was performed. We clustered 71 significant SNPs into five groups based on their pleiotropic effects across the 56 traits. Among these 71 significant SNPs, one group of 11 SNPs affected the fatty acid profile of the muscle and were close to 8 genes involved in fatty acid or triglyceride synthesis. Another group of 23 SNPs had an effect on mature size, based on their pattern of effects across traits, but the genes near this group of SNPs did not share any obvious function. Many of the likely candidate genes near SNPs with significant pleiotropic effects on the 56 traits are involved in intra-cellular signalling pathways. Among the significant SNPs were some with a convincing candidate gene due to the function of the gene (e.g. glycogen synthase affecting glycogen concentration) or because the same gene was associated with similar traits in other species. CONCLUSIONS: Using a multi-trait analysis increased the power to detect associations between SNP and body composition traits compared with the single trait analyses. Detailed phenotypic information helped to identify a convincing candidate in some cases as did information from other species.

Published
2016

31. A marker-derived gene network reveals the regulatory role of PPARGC1A, HNF4G, and FOXP3 in intramuscular fat deposition of beef cattle

Author

RAMAYO CALDAS, Yuliaxis, Fortes, M. R. S., Hudson, N. J., Porto-Neto, L. R., Bolormaa, S., Barendse, W., Kelly, M., Moore, S. S., Goddard, M. E., Lehnert, S. A., Reverter, A., Génétique Animale et Biologie Intégrative (GABI), AgroParisTech-Institut National de la Recherche Agronomique (INRA), Food Futures Flagship - Animal Food and Health Sciences, Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), Facultat de Veterinària, Departament de Ciencia Animal i dels Aliments, Universitat Autònoma de Barcelona [Barcelona] (UAB), Queensland Alliance for Agriculture and Food Innovation, Center for Animal Science, University of Queensland [Brisbane], Victorian Department of Environment and Primary Industries, Univ Melbourne, Sch Land & Environm, Parkville, Vic 3010, Australia, Université Paris Diderot - Paris 7 (UPD7), Victorian Dept Environm & Primary Ind, Bundoora, Vic 3083, Australia, Spanish Ministerio de Educacion [AP2008-01450], European Union [267196], European Project: 267196, Institut National de la Recherche Agronomique (INRA)-AgroParisTech, and Universitat Autònoma de Barcelona (UAB)

Subjects
[SDV]Life Sciences [q-bio], association weight matrix, fat deposition, beef quality, genomewide association study, marbling
Abstract

High intramuscular fat (IMF) awards price premiums to beef producers and is associated with meat quality and flavor. Studying gene interactions and pathways that affect IMF might unveil causative physiological mechanisms and inform genomic selection, leading to increased accuracy of predictions of breeding value. To study gene interactions and pathways, a gene network was derived from genetic markers associated with direct measures of IMF, other fat phenotypes, feedlot performance, and a number of meat quality traits relating to body conformation, development, and metabolism that might be plausibly expected to interact with IMF biology. Marker associations were inferred from genomewide association studies (GWAS) based on high density genotypes and 29 traits measured on 10,181 beef cattle animals from 3 breed types. For the network inference, SNP pairs were assessed according to the strength of the correlation between their additive association effects across the 29 traits. The co-association inferred network was formed by 2,434 genes connected by 28,283 edges. Topological network parameters suggested a highly cohesive network, in which the genes are strongly functionally interconnected. Pathway and network analyses pointed towards a trio of transcription factors (TF) as key regulators of carcass IMF: PPARG-C1A, HNF4G, and FOXP3. Importantly, none of these genes would have been deemed as significantly associated with IMF from the GWAS. Instead, a total of 313 network genes show significant co-association with the 3 TF. These genes belong to a wide variety of biological functions, canonical pathways, and genetic networks linked to IMF-related phenotypes. In summary, our GWAS and network predictions are supported by the current literature and suggest a cooperative role for the 3 TF and other interacting genes including CAPN6, STC2, MAP2K4, EYA1, COPS5, XKR4, NR2E1, TOX, ATF1, ASPH, TGS1, and TTPA as modulators of carcass and meat quality traits in beef cattle.

Published
2014
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32. Non-additive genetic variation in growth, carcass and fertility traits of beef cattle

Author

Bolormaa, S, Pryce, JE, Zhang, Y, Reverter, A, Barendse, W, Hayes, BJ, Goddard, ME, Bolormaa, S, Pryce, JE, Zhang, Y, Reverter, A, Barendse, W, Hayes, BJ, and Goddard, ME

Abstract

BACKGROUND: A better understanding of non-additive variance could lead to increased knowledge on the genetic control and physiology of quantitative traits, and to improved prediction of the genetic value and phenotype of individuals. Genome-wide panels of single nucleotide polymorphisms (SNPs) have been mainly used to map additive effects for quantitative traits, but they can also be used to investigate non-additive effects. We estimated dominance and epistatic effects of SNPs on various traits in beef cattle and the variance explained by dominance, and quantified the increase in accuracy of phenotype prediction by including dominance deviations in its estimation. METHODS: Genotype data (729 068 real or imputed SNPs) and phenotypes on up to 16 traits of 10 191 individuals from Bos taurus, Bos indicus and composite breeds were used. A genome-wide association study was performed by fitting the additive and dominance effects of single SNPs. The dominance variance was estimated by fitting a dominance relationship matrix constructed from the 729 068 SNPs. The accuracy of predicted phenotypic values was evaluated by best linear unbiased prediction using the additive and dominance relationship matrices. Epistatic interactions (additive × additive) were tested between each of the 28 SNPs that are known to have additive effects on multiple traits, and each of the other remaining 729 067 SNPs. RESULTS: The number of significant dominance effects was greater than expected by chance and most of them were in the direction that is presumed to increase fitness and in the opposite direction to inbreeding depression. Estimates of dominance variance explained by SNPs varied widely between traits, but had large standard errors. The median dominance variance across the 16 traits was equal to 5% of the phenotypic variance. Including a dominance deviation in the prediction did not significantly increase its accuracy for any of the phenotypes. The number of additive × additive epistatic e

Published
2015

34. The Genetic Architecture of Climatic Adaptation of Tropical Cattle

Author

Rueppell, O, Porto-Neto, LR, Reverter, A, Prayaga, KC, Chan, EKF, Johnston, DJ, Hawken, RJ, Fordyce, G, Garcia, JF, Sonstegard, TS, Bolormaa, S, Goddard, ME, Burrow, HM, Henshall, JM, Lehnert, SA, Barendse, W, Rueppell, O, Porto-Neto, LR, Reverter, A, Prayaga, KC, Chan, EKF, Johnston, DJ, Hawken, RJ, Fordyce, G, Garcia, JF, Sonstegard, TS, Bolormaa, S, Goddard, ME, Burrow, HM, Henshall, JM, Lehnert, SA, and Barendse, W

Abstract

Adaptation of global food systems to climate change is essential to feed the world. Tropical cattle production, a mainstay of profitability for farmers in the developing world, is dominated by heat, lack of water, poor quality feedstuffs, parasites, and tropical diseases. In these systems European cattle suffer significant stock loss, and the cross breeding of taurine x indicine cattle is unpredictable due to the dilution of adaptation to heat and tropical diseases. We explored the genetic architecture of ten traits of tropical cattle production using genome wide association studies of 4,662 animals varying from 0% to 100% indicine. We show that nine of the ten have genetic architectures that include genes of major effect, and in one case, a single location that accounted for more than 71% of the genetic variation. One genetic region in particular had effects on parasite resistance, yearling weight, body condition score, coat colour and penile sheath score. This region, extending 20 Mb on BTA5, appeared to be under genetic selection possibly through maintenance of haplotypes by breeders. We found that the amount of genetic variation and the genetic correlations between traits did not depend upon the degree of indicine content in the animals. Climate change is expected to expand some conditions of the tropics to more temperate environments, which may impact negatively on global livestock health and production. Our results point to several important genes that have large effects on adaptation that could be introduced into more temperate cattle without detrimental effects on productivity.

Published
2014

35. A Multi-Trait, Meta-analysis for Detecting Pleiotropic Polymorphisms for Stature, Fatness and Reproduction in Beef Cattle

Author

Flint, J, Bolormaa, S, Pryce, JE, Reverter, A, Zhang, Y, Barendse, W, Kemper, K, Tier, B, Savin, K, Hayes, BJ, Goddard, ME, Flint, J, Bolormaa, S, Pryce, JE, Reverter, A, Zhang, Y, Barendse, W, Kemper, K, Tier, B, Savin, K, Hayes, BJ, and Goddard, ME

Abstract

Polymorphisms that affect complex traits or quantitative trait loci (QTL) often affect multiple traits. We describe two novel methods (1) for finding single nucleotide polymorphisms (SNPs) significantly associated with one or more traits using a multi-trait, meta-analysis, and (2) for distinguishing between a single pleiotropic QTL and multiple linked QTL. The meta-analysis uses the effect of each SNP on each of n traits, estimated in single trait genome wide association studies (GWAS). These effects are expressed as a vector of signed t-values (t) and the error covariance matrix of these t values is approximated by the correlation matrix of t-values among the traits calculated across the SNP (V). Consequently, t'V-1t is approximately distributed as a chi-squared with n degrees of freedom. An attractive feature of the meta-analysis is that it uses estimated effects of SNPs from single trait GWAS, so it can be applied to published data where individual records are not available. We demonstrate that the multi-trait method can be used to increase the power (numbers of SNPs validated in an independent population) of GWAS in a beef cattle data set including 10,191 animals genotyped for 729,068 SNPs with 32 traits recorded, including growth and reproduction traits. We can distinguish between a single pleiotropic QTL and multiple linked QTL because multiple SNPs tagging the same QTL show the same pattern of effects across traits. We confirm this finding by demonstrating that when one SNP is included in the statistical model the other SNPs have a non-significant effect. In the beef cattle data set, cluster analysis yielded four groups of QTL with similar patterns of effects across traits within a group. A linear index was used to validate SNPs having effects on multiple traits and to identify additional SNPs belonging to these four groups.

Published
2014

36. Selection for complex traits leaves little or no classic signatures of selection

Author

Kemper, KE, Saxton, SJ, Bolormaa, S, Hayes, BJ, Goddard, ME, Kemper, KE, Saxton, SJ, Bolormaa, S, Hayes, BJ, and Goddard, ME

Abstract

BACKGROUND: Selection signatures aim to identify genomic regions underlying recent adaptations in populations. However, the effects of selection in the genome are difficult to distinguish from random processes, such as genetic drift. Often associations between selection signatures and selected variants for complex traits is assumed even though this is rarely (if ever) tested. In this paper, we use 8 breeds of domestic cattle under strong artificial selection to investigate if selection signatures are co-located in genomic regions which are likely to be under selection. RESULTS: Our approaches to identify selection signatures (haplotype heterozygosity, integrated haplotype score and FST) identified strong and recent selection near many loci with mutations affecting simple traits under strong selection, such as coat colour. However, there was little evidence for a genome-wide association between strong selection signatures and regions affecting complex traits under selection, such as milk yield in dairy cattle. Even identifying selection signatures near some major loci was hindered by factors including allelic heterogeneity, selection for ancestral alleles and interactions with nearby selected loci. CONCLUSIONS: Selection signatures detect loci with large effects under strong selection. However, the methodology is often assumed to also detect loci affecting complex traits where the selection pressure at an individual locus is weak. We present empirical evidence to suggests little discernible 'selection signature' for complex traits in the genome of dairy cattle despite very strong and recent artificial selection.

Published
2014

39. Detection of quantitative trait loci in Bos indicus and Bos taurus cattle using genome-wide association studies

Author

Bolormaa, S, Pryce, JE, Kemper, KE, Hayes, BJ, Zhang, Y, Tier, B, Barendse, W, Reverter, A, Goddard, ME, Bolormaa, S, Pryce, JE, Kemper, KE, Hayes, BJ, Zhang, Y, Tier, B, Barendse, W, Reverter, A, and Goddard, ME

Abstract

BACKGROUND: The apparent effect of a single nucleotide polymorphism (SNP) on phenotype depends on the linkage disequilibrium (LD) between the SNP and a quantitative trait locus (QTL). However, the phase of LD between a SNP and a QTL may differ between Bos indicus and Bos taurus because they diverged at least one hundred thousand years ago. Here, we test the hypothesis that the apparent effect of a SNP on a quantitative trait depends on whether the SNP allele is inherited from a Bos taurus or Bos indicus ancestor. METHODS: Phenotype data on one or more traits and SNP genotype data for 10 181 cattle from Bos taurus, Bos indicus and composite breeds were used. All animals had genotypes for 729 068 SNPs (real or imputed). Chromosome segments were classified as originating from B. indicus or B. taurus on the basis of the haplotype of SNP alleles they contained. Consequently, SNP alleles were classified according to their sub-species origin. Three models were used for the association study: (1) conventional GWAS (genome-wide association study), fitting a single SNP effect regardless of subspecies origin, (2) interaction GWAS, fitting an interaction between SNP and subspecies-origin, and (3) best variable GWAS, fitting the most significant combination of SNP and sub-species origin. RESULTS: Fitting an interaction between SNP and subspecies origin resulted in more significant SNPs (i.e. more power) than a conventional GWAS. Thus, the effect of a SNP depends on the subspecies that the allele originates from. Also, most QTL segregated in only one subspecies, suggesting that many mutations that affect the traits studied occurred after divergence of the subspecies or the mutation became fixed or was lost in one of the subspecies. CONCLUSIONS: The results imply that GWAS and genomic selection could gain power by distinguishing SNP alleles based on their subspecies origin, and that only few QTL segregate in both B. indicus and B. taurus cattle. Thus, the QTL that segregate in cur

Published
2013

40. Finding genes for economically important traits: Brahman cattle puberty.

Author

Fortes , M.R.S., Lehnert, S.A., Bolormaa, S., Reich, C., Fordyce, G., Corbet, N.J., Whan, V., Hawken, R.J., Reverter, A., Fortes , M.R.S., Lehnert, S.A., Bolormaa, S., Reich, C., Fordyce, G., Corbet, N.J., Whan, V., Hawken, R.J., and Reverter, A.

Abstract

Age at puberty is an important component of reproductive performance in beef cattle production systems. Brahman cattle are typically late-pubertal relative to Bos taurus cattle and so it is of economic relevance to select for early age at puberty. To assist selection and elucidate the genes underlying puberty, we performed a genome-wide association study (GWAS) using the BovineSNP50 chip (similar to 54 000 polymorphisms) in Brahman bulls (n = 1105) and heifers (n = 843) and where the heifers were previously analysed in a different study. In a new attempt to generate unbiased estimates of single-nucleotide polymorphism (SNP) effects and proportion of variance explained by each SNP, the available data were halved on the basis of year and month of birth into a calibration and validation set. The traits that defined age at puberty were, in heifers, the age at which the first corpus luteum was detected (AGECL, h(2) = 0.56 +/- 0.11) and in bulls, the age at a scrotal circumference of 26 cm (AGE26, h(2) = 0.78 +/- 0.10). At puberty, heifers were on average older (751 +/- 142 days) than bulls (555 +/- 101 days), but AGECL and AGE26 were genetically correlated (r = 0.20 +/- 0.10). There were 134 SNPs associated with AGECL and 146 SNPs associated with AGE26 (P < 0.0001). From these SNPs, 32 (similar to 22%) were associated (P < 0.0001) with both traits. These top 32 SNPs were all located on Chromosome BTA 14, between 21.95 Mb and 28.4 Mb. These results suggest that the genes located in that region of BTA 14 play a role in pubertal development in Brahman cattle. There are many annotated genes underlying this region of BTA 14 and these are the subject of current research. Further, we identified a region on Chromosome X where markers were associated (P < 1.00E-8) with AGE26, but not with AGECL. Information about specific genes and markers add value to our understanding of puberty and potentially contribute to genomic selection. Therefore, identifying these genes contributing to

Published
2012

41. Finding genes for economically important traits: Brahman cattle puberty.

Author

Fortes, M.R.S., Lehnert, S.A., Bolormaa, S., Reich, C., Fordyce, G., Corbet, N.J., Whan, V., Hawken, R.J., Reverter, A., Fortes, M.R.S., Lehnert, S.A., Bolormaa, S., Reich, C., Fordyce, G., Corbet, N.J., Whan, V., Hawken, R.J., and Reverter, A.

Abstract

Age at puberty is an important component of reproductive performance in beef cattle production systems. Brahman cattle are typically late-pubertal relative to Bos taurus cattle and so it is of economic relevance to select for early age at puberty. To assist selection and elucidate the genes underlying puberty, we performed a genome-wide association study (GWAS) using the BovineSNP50 chip (similar to 54 000 polymorphisms) in Brahman bulls (n = 1105) and heifers (n = 843) and where the heifers were previously analysed in a different study. In a new attempt to generate unbiased estimates of single-nucleotide polymorphism (SNP) effects and proportion of variance explained by each SNP, the available data were halved on the basis of year and month of birth into a calibration and validation set. The traits that defined age at puberty were, in heifers, the age at which the first corpus luteum was detected (AGECL, h(2) = 0.56 +/- 0.11) and in bulls, the age at a scrotal circumference of 26 cm (AGE26, h(2) = 0.78 +/- 0.10). At puberty, heifers were on average older (751 +/- 142 days) than bulls (555 +/- 101 days), but AGECL and AGE26 were genetically correlated (r = 0.20 +/- 0.10). There were 134 SNPs associated with AGECL and 146 SNPs associated with AGE26 (P < 0.0001). From these SNPs, 32 (similar to 22%) were associated (P < 0.0001) with both traits. These top 32 SNPs were all located on Chromosome BTA 14, between 21.95 Mb and 28.4 Mb. These results suggest that the genes located in that region of BTA 14 play a role in pubertal development in Brahman cattle. There are many annotated genes underlying this region of BTA 14 and these are the subject of current research. Further, we identified a region on Chromosome X where markers were associated (P < 1.00E-8) with AGE26, but not with AGECL. Information about specific genes and markers add value to our understanding of puberty and potentially contribute to genomic selection. Therefore, identifying these genes contributing to

Published
2012

43. Evidence for pleiotropism and recent selection in thePLAG1region in Australian Beef cattle

Author

Fortes, M. R. S., primary, Kemper, K., additional, Sasazaki, S., additional, Reverter, A., additional, Pryce, J. E., additional, Barendse, W., additional, Bunch, R., additional, McCulloch, R., additional, Harrison, B., additional, Bolormaa, S., additional, Zhang, Y. D., additional, Hawken, R. J., additional, Goddard, M. E., additional, and Lehnert, S. A., additional

Published
2013
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44. Accuracy of prediction of genomic breeding values for residual feed intake and carcass and meat quality traits in Bos taurus, Bos indicus, and composite beef cattle1

Author

Bolormaa, S., primary, Pryce, J. E., additional, Kemper, K., additional, Savin, K., additional, Hayes, B. J., additional, Barendse, W., additional, Zhang, Y., additional, Reich, C. M., additional, Mason, B. A., additional, Bunch, R. J., additional, Harrison, B. E., additional, Reverter, A., additional, Herd, R. M., additional, Tier, B., additional, Graser, H.-U., additional, and Goddard, M. E., additional

Published
2013
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