52 research outputs found
Analysis of North American Rheumatoid Arthritis Consortium data using a penalized logistic regression approach
We applied a penalized regression approach to single-nucleotide polymorphisms in regions on chromosomes 1, 6, and 9 of the North American Rheumatoid Arthritis Consortium data. Results were compared with a standard single-locus association test. Overall, the penalized regression approach did not appear to offer any advantage with respect to either detection or localization of disease-associated polymorphisms, compared with the single-locus approach
Dealing with missing phase and missing data in phylogeny-based analysis
We recently described a new method to identify disease susceptibility loci, based on the analysis of the evolutionary relationships between haplotypes of cases and controls. However, haplotypes are often unknown and the problem of phase inference is even more crucial when there are missing data. In this work, we suggest using a multiple imputation algorithm to deal with missing phase and missing data, prior to a phylogeny-based analysis. We used the simulated data of Genetic Analysis Workshop 15 (Problem 3, answer known) to assess the power of the phylogeny-based analysis to detect disease susceptibility loci after reconstruction of haplotypes by a multiple-imputation method. We compare, for various rates of missing data, the performance of the multiple imputation method with the performance achieved when considering only the most probable haplotypic configurations or the true phase. When only the phase is unknown, all methods perform approximately the same to identify disease susceptibility sites. In the presence of missing data however, the detection of disease susceptibility sites is significantly better when reconstructing haplotypes by multiple imputation than when considering only the best haplotype configurations
Efficiency of multiple imputation to test for association in the presence of missing data
The presence of missing data in association studies is an important problem, particularly with high-density single-nucleotide polymorphism (SNP) maps, because the probability that at least one genotype is missing dramatically increases with the number of markers. A possible strategy is to simply ignore the missing data and only use the complete observations, and, consequently, to accept a significant decrease of the sample size. Using Genetic Analysis Workshop 15 simulated data on which we removed some genotypes to generate different levels of missing data, we show that this strategy might lead to an important loss in power to detect association, but may also result in false conclusions regarding the most likely susceptibility site if another marker is in linkage disequilibrium with the disease susceptibility site. We propose a multiple imputation approach to deal with missing data on case-parent trios and evaluated the performance of this approach on the same simulated data. We found that our multiple imputation approach has high power to detect association with the susceptibility site even with a large amount of missing data, and can identify the susceptibility sites among a set of sites in linkage disequilibrium
The impact of genomic selection on genetic diversity and genetic gain in three French dairy cattle breeds
International audienceAbstractBackgroundIn France, implementation of genomic evaluations in dairy cattle breeds started in 2009 and this has modified the breeding schemes drastically. In this context, the goal of our study was to understand the impact of genomic selection on the genetic diversity of bulls from three French dairy cattle breeds born between 2005 and 2015 (Montbéliarde, Normande and Holstein) and the factors that are involved.MethodsWe compared annual genetic gains, inbreeding rates based on runs of homozygosity (ROH) and pedigree data, and mean ROH length within breeds, before and after the implementation of genomic selection.ResultsGenomic selection induced an increase in mean annual genetic gains of 50, 71 and 33% for Montbéliarde, Normande and Holstein bulls, respectively, and in parallel, the generation intervals were reduced by a factor of 1.7, 1.9 and 2, respectively. We found no significant change in inbreeding rate for the two national breeds, Montbéliarde and Normande, and a significant increase in inbreeding rate for the Holstein international breed, which is now as high as 0.55% per year based on ROH and 0.49% per year based on pedigree data (equivalent to a rate of 1.36 and 1.39% per generation, respectively). The mean ROH length was longer for bulls from the Holstein breed than for those from the other two breeds.ConclusionsWith the implementation of genomic selection, the annual genetic gain increased for bulls from the three major French dairy cattle breeds. At the same time, the annual loss of genetic diversity increased for Holstein bulls, possibly because of the massive use of a few elite bulls in this breed, but not for Montbéliarde and Normande bulls. The increase in mean ROH length in Holstein may reflect the occurrence of recent inbreeding. New strategies in breeding schemes, such as female donor stations and embryo transfer, and recent implementation of genomic evaluations in small regional breeds should be studied carefully in order to ensure the sustainability of breeding schemes in the future
Validation of the reshaped shared epitope HLA-DRB1 classification in rheumatoid arthritis
Recently, we proposed a classification of HLA-DRB1 alleles that reshapes the shared epitope hypothesis in rheumatoid arthritis (RA); according to this model, RA is associated with the RAA shared epitope sequence (72â74 positions) and the association is modulated by the amino acids at positions 70 and 71, resulting in six genotypes with different RA risks. This was the first model to take into account the association between the HLA-DRB1 gene and RA, and linkage data for that gene. In the present study we tested this classification for validity in an independent sample. A new sample of the same size and population (100 RA French Caucasian families) was genotyped for the HLA-DRB1 gene. The alleles were grouped as proposed in the new classification: S(1 )alleles for the sequences A-RAA or E-RAA; S(2 )for Q or D-K-RAA; S(3D )for D-R-RAA; S(3P )for Q or R-R-RAA; and X alleles for no RAA sequence. Transmission of the alleles was investigated. Genotype odds ratio (OR) calculations were performed through conditional logistic regression, and we tested the homogeneity of these ORs with those of the 100 first trio families (one case and both parents) previously reported. As previously observed, the S(2 )and S(3P )alleles were significantly over-transmitted and the S(1), S(3D )and X alleles were under-transmitted. The latter were grouped as L alleles, resulting in the same three-allele classification. The risk hierarchy of the six derived genotypes was the same: (by decreasing OR and with L/L being the reference genotype) S(2)/S(3P), S(2)/S(2), S(3P)/S(3P), S(2)/L and S(3P)/L. The homogeneity test between the ORs of the initial and the replication samples revealed no significant differences. The new classification was therefore considered validated, and both samples were pooled to provide improved estimates of RA risk genotypes from the highest (S(2)/S(3P )[OR 22.2, 95% confidence interval 9.9â49.7]) to the lowest (S(3P)/L [OR 4.4, 95% confidence interval 2.3â8.4])
Rigoletto
De cada obra s'ha digitalitzat un programa sencer. De la resta s'han digitalitzat les parts que són diferents.Director: José Sabate
Meta-analysis of genome-wide association studies for cattle stature identifies common genes that regulate body size in mammals
peer-reviewedH.D.D., A.J.C., P.J.B. and B.J.H. would like to acknowledge the Dairy Futures
Cooperative Research Centre for funding. H.P. and R.F. acknowledge funding
from the German Federal Ministry of Education and Research (BMBF) within the
AgroClustEr âSynbreedâSynergistic Plant and Animal Breedingâ (grant 0315527B).
H.P., R.F., R.E. and K.-U.G. acknowledge the Arbeitsgemeinschaft SĂŒddeutscher
RinderzĂŒchter, the Arbeitsgemeinschaft Ăsterreichischer FleckviehzĂŒchter
and ZuchtData EDV Dienstleistungen for providing genotype data. A. Bagnato
acknowledges the European Union (EU) Collaborative Project LowInputBreeds
(grant agreement 222623) for providing Brown Swiss genotypes. Braunvieh Schweiz
is acknowledged for providing Brown Swiss phenotypes. H.P. and R.F. acknowledge
the German Holstein Association (DHV) and the ConfederaciĂłn de Asociaciones
de Frisona Española (CONCAFE) for sharing genotype data. H.P. was financially
supported by a postdoctoral fellowship from the Deutsche Forschungsgemeinschaft
(DFG) (grant PA 2789/1-1). D.B. and D.C.P. acknowledge funding from the
Research Stimulus Fund (11/S/112) and Science Foundation Ireland (14/IA/2576).
M.S. and F.S.S. acknowledge the Canadian Dairy Network (CDN) for providing the
Holstein genotypes. P.S. acknowledges funding from the Genome Canada project
entitled âWhole Genome Selection through Genome Wide Imputation in Beef Cattleâ and acknowledges WestGrid and Compute/Calcul Canada for providing
computing resources. J.F.T. was supported by the National Institute of Food and
Agriculture, US Department of Agriculture, under awards 2013-68004-20364 and
2015-67015-23183. A. Bagnato, F.P., M.D. and J.W. acknowledge EU Collaborative
Project Quantomics (grant 516 agreement 222664) for providing Brown Swiss
and Finnish Ayrshire sequences and genotypes. A.C.B. and R.F.V. acknowledge
funding from the publicâprivate partnership âBreed4Foodâ (code BO-22.04-011-
001-ASG-LR) and EU FP7 IRSES SEQSEL (grant 317697). A.C.B. and R.F.V.
acknowledge CRV (Arnhem, the Netherlands) for providing data on Dutch and
New Zealand Holstein and Jersey bulls.Stature is affected by many polymorphisms of small effect in humans1. In contrast, variation in dogs, even within breeds, has been suggested to be largely due to variants in a small number of genes2,3. Here we use data from cattle to compare the genetic architecture of stature to those in humans and dogs. We conducted a meta-analysis for stature using 58,265 cattle from 17 populations with 25.4 million imputed whole-genome sequence variants. Results showed that the genetic architecture of stature in cattle is similar to that in humans, as the lead variants in 163 significantly associated genomic regions (P < 5 Ă 10â8) explained at most 13.8% of the phenotypic variance. Most of these variants were noncoding, including variants that were also expression quantitative trait loci (eQTLs) and in ChIPâseq peaks. There was significant overlap in loci for stature with humans and dogs, suggesting that a set of common genes regulates body size in mammals
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