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17 results on '"de Koning, Dirk-Jan"'

1. Optimal design of genetic studies of gene expression with two-color microarrays in outbred crosses

Author

Lam, Alex C., Fu, Jingyuan, Jansen, Ritsert C., Haley, Chris S., and de Koning, Dirk-Jan

Subjects
Gene expression -- Research, Phenotype -- Identification and classification, Allelomorphism -- Identification and classification, Chromosome mapping -- Methods, Biological sciences
Abstract

Combining global gene-expression profiling and genetic analysis of natural allelic variation (genetical genomics) has great potential in dissecting the genetic pathways underlying complex phenotypes. Efficient use of microarrays is paramount in experimental design as the cost of conducting this type of study is high. For those organisms where recombinant inbred lines are available for mapping, the 'distant pair design' maximizes the number of informative contrasts over all marker loci. Here, we describe an extension of this design, named the 'optimal pair design,' for use with [F.sub.2] crosses between outbred lines. The performance of this design is investigated by simulation and compared to several other two-color microarray designs. We show that, for a given number of microarrays, the optimal pair design outperforms all other designs considered for detection of expression quantitative trait loci (eQTL) with additive effects by linkage analysis. We also discuss the suitability of this design for outbred crosses in organisms with large genomes and for detection of dominance.

Published
2008

2. Genomewide rapid association using mixed model and regression: a fast and simple method for genomewide pedigree-based quantitative trait loci association analysis

Author

Aulchenko, Yurii S., de Koning, Dirk-Jan, and Haley, Chris

Subjects
Quantitative trait loci -- Properties, Genomes -- Properties, Genetic markers -- Evaluation, Genetic research -- Methods, Biological sciences
Abstract

For pedigree-based quantitative trait loci (QTL) association analysis, a range of methods utilizing within-family variation such as transmission-disequilibrium test (TDT)-based methods have been developed. In scenarios where stratification is not a concern, methods exploiting between-family variation in addition to within-family variation, such as the measured genotype (MG) approach, have greater power. Application of MG methods can be computationally demanding (especially for large pedigrees), making genomewide scans practically infeasible. Here we suggest a novel approach for genomewide pedigree-based quantitative trait loci (QTL) association analysis: genomewide rapid association using mixed model and regression (GRAMMAR). The method first obtains residuals adjusted for family effects and subsequently analyzes the association between these residuals and genetic polymorphisms using rapid least-squares methods. At the final step, the selected polymorphisms may be followed up with the full measured genotype (MG) analysis. In a simulation study, we compared type 1 error, power, and operational characteristics of the proposed method with those of MG and TDT-based approaches. For moderately heritable (30%) trails in human pedigrees the power of the GRAMMAR and the MG approaches is similar and is much higher than that of TDT-based approaches. When using tabulated thresholds, the proposed method is less powerful than MG for very high heritabilities and pedigrees including large sibships like those observed in livestock pedigrees. However, there is little or no difference in empirical power of MG and the proposed method. In any scenario, GRAMMAR is much faster than MG and enables rapid analysis of hundreds of thousands of markers.

Published
2007

3. Mapping of multiple quantitative trait loci affecting bovine spongiform encephalopathy

Author

Zhang, Chi, de Koning, Dirk-Jan, Hernandez-Sanchez, Jules, Haley, Chris S., Williams, John L., and Wiener, Pamela

Subjects
Bovine spongiform encephalopathy -- Genetic aspects, Chromosome mapping, Genetic variation, Quantitative trait loci, Biological sciences
Abstract

A whole-genome scan was conducted to map quantitative trait loci (QTL) for BSE resistance or susceptibility. Cows from four half-sib families were included and 173 microsatellite markers were used to construct a 2835-cM (Kosambi) linkage map covering 29 autosomes and the pseudoautosomal region of the sex chromosome. Interval mapping by linear regression was applied and extended to a multiple-QTL analysis approach that used identified QTL on other chromosomes as cofactors to increase mapping power. In the multiple-QTL analysis, two genome-wide significant QTL (BTA17 and X/[Y.sub.ps]) and four genome-wide suggestive QTL (BTA1, 6, 13, and 19) were revealed. The QTL identified here using linkage analysis do not overlap with regions previously identified using TDT analysis. One factor that may explain the disparity between the results is that a more extensive data set was used in the present study. Furthermore, methodological differences between TDT and linkage analyses may affect the power of these approaches.

Published
2004

4. On the detection of imprinted quantitative trait loci in experimental crosses of outbred species

Author

de Koning, Dirk-Jan, Bovenhuis, Henk, and van Arendonk, Johan A.M.

Subjects
Genetic research -- Methods, Mendel's law -- Models, Biological sciences
Abstract

In this article, the quantitative genetic aspects of imprinted genes and statistical properties of methods to detect imprinted QTL are studied. Different models to detect imprinted QTL and to distinguish between imprinted and Mendelian QTL were compared in a simulation study. Mendelian and imprinted QTL were simulated in an [F.sub.2] design and analyzed under Mendelian and imprinting models. Mode of expression was evaluated against the [H.sub.0] of a Mendelian QTL as well as the [H.sub.0] of an imprinted QTL. It was shown that imprinted QTL might remain undetected when analyzing the genome with Mendelian models only. Compared to testing against a Mendelian QTL, using the [H.sub.0] of an imprinted QTL gave a higher proportion of correctly identified imprinted QTL, but also gave a higher proportion of false inference of imprinting for Mendelian QTL. When QTL were segregating in the founder lines, spurious detection of imprinting became more prominent under both tests, especially for designs with a small number of [F.sub.1] sires.

Published
2002

9. The Genome Architecture of the Collaborative Cross Mouse Genetic Reference Population.

Author

McIntyre, Lauren M. and de Koning, Dirk-Jan

Subjects
*GENOMES, *GENETIC polymorphisms, *LABORATORY mice, *SPECIES hybridization, *X chromosome, *POPULATION genetics
Abstract

The Collaborative Cross Consortium reports here on the development of a unique genetic resource population. The Collaborative Cross (CC) is a multiparental recombinant inbred panel derived from eight laboratory mouse inbred strains. Breeding of the CC lines was initiated at multiple international sites using mice from The Jackson Laboratory. Currently, this innovative project is breeding independent CC lines at the University of North Carolina (UNC), at Tel Aviv University (TAU), and at Geniad in Western Australia (GND). These institutions aim to make publicly available the completed CC lines and their genotypes and sequence information. We genotyped, and report here, results from 458 extant lines from UNC, TAU, and GND using a custom genotyping array with 7500 SNPs designed to be maximally informative in the CC and used a novel algorithm to infer inherited haplotypes directly from hybridization intensity patterns. We identified lines with breeding errors and cousin lines generated by splitting incipient lines into two or more cousin lines at early generations of inbreeding. We then characterized the genome architecture of 350 genetically independent CC lines. Results showed that founder haplotypes are inherited at the expected frequency, although we also consistently observed highly significant transmission ratio distortion at specific loci across all three populations. On chromosome 2, there is significant overrepresentation of WSB/EiJ alleles, and on chromosome X, there is a large deficit of CC lines with CAST/EiJ alleles. Linkage disequilibrium decays as expected and we saw no evidence of gametic disequilibrium in the CC population as a whole or in random subsets of the population. Gametic equilibrium in the CC population is in marked contrast to the gametic disequilibrium present in a large panel of classical inbred strains. Finally, we discuss access to the CC population and to the associated raw data describing the genetic structure of individual lines. Integration of rich phenotypic and genomic data over time and across a wide variety of fields will be vital to delivering on one of the key attributes of the CC, a common genetic reference platform for identifying causative variants and genetic networks determining traits in mammals. [ABSTRACT FROM AUTHOR]

Published
2012
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10. Mapping of Multiple Quantitative Trait Loci Affecting Bovine Spongiform Encephalopathy.

Author

Chi Zhang, de Koning, Dirk-Jan, Hernández-Sánchez, Jules, Haley, Chris S., Williams, John L., and Wiener, Pamela

Subjects
*BOVINE spongiform encephalopathy, *CENTRAL nervous system diseases, *CHROMOSOMES, *GENOMES, *GENETICS, *SEX chromosomes
Abstract

A whole-genome scan was conducted to map quantitative trait loci (QTL) for BSE resistance or susceptibility. Cows from four half-sib families were included and 173 microsatellite markers were used to construct a 2835-cM (Kosambi) linkage map covering 29 autosomes and the pseudoautosomal region of the sex chromosome. Interval mapping by linear regression was applied and extended to a multiple-QTL analysis approach that used identified QTL on other chromosomes as cofactors to increase mapping power. In the multiple-QTL analysis, two genome-wide significant QTL (BTA17 and X/Yps) and four genome-wide suggestive QTL (BTA1, 6, 13, and 19) were revealed. The QTL identified here using linkage analysis do not overlap with regions previously identified using TDT analysis. One factor that may explain the disparity between the results is that a more extensive data set was used in the present study. Furthermore, methodological differences between TDT and linkage analyses may affect the power of these approaches. [ABSTRACT FROM AUTHOR]

Published
2004
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12. Facilitating Discovery: The Role of Society Journals in Collaborative Science.

Author

McIntyre, Lauren M. and de Koning, Dirk Jan

Subjects
*SCIENCE periodicals, *INFORMATION resources, *RESEARCH
Abstract

The article discusses the role of society-sponsored journals in collaborative science. It recognizes society-sponsored journals as one of the most exciting resources for research. It cites the case of the journal "Genetics" that provides updates on the field. In addition, the article explains the importance data sharing to collaborations.

Published
2012
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13. Genotype Probabilities at Intermediate Generations in the Construction of Recombinant Inbred Lines.

Author

Broman, Karl W., McIntyre, Lauren M., and de Koning, Dirk-Jan

Subjects
*GENETIC research, *GENETIC polymorphisms, *GENOMES, *LABORATORY mice, *GENETIC markers, *HAPLOTYPES
Abstract

The mouse Collaborative Cross (CC) is a panel of eight-way recombinant inbred lines: eight diverse parental strains are intermated, followed by repeated sibling mating, many times in parallel, to create a new set of inbred lines whose genomes are random mosaics of the genomes of the original eight strains. Many generations are required to reach inbreeding, and so a number of investigators have sought to make use of phenotype and genotype data on mice from intermediate generations during the formation of the CC lines (so-called pre-CC mice). The development of a hidden Markov model for genotype reconstruction in such pre-CC mice, on the basis of incompletely informative genetic markers (such as single-nucleotide polymorphisms), formally requires the two-locus genotype probabilities at an arbitrary generation along the path to inbreeding. In this article, I describe my efforts to calculate such probabilities. While closed-form solutions for the two-locus genotype probabilities could not be derived, I provide a prescription for calculating such probabilities numerically. In addition, I present a number of useful quantities, including single-locus genotype probabilities, two-locus haplotype probabilities, and the fixation probability and map expansion at each generation along the course to inbreeding. [ABSTRACT FROM AUTHOR]

Published
2012
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14. High-Resolution Genetic Mapping Using the Mouse Diversity Outbred Population.

Author

Svenson, Karen L., Gatti, Daniel M., Valdar, William, Welsh, Catherine E., Cheng, Riyan, Chesler, Elissa J., Palmer, Abraham A., McMillan, Leonard, Churchill, Gary A., McIntyre, Lauren M., and de Koning, Dirk-Jan

Subjects
*GENE mapping, *GENETIC polymorphisms, *OUTCROSSING (Biology), *CROSS-fertilization (Biology), *LABORATORY mice
Abstract

The JAX Diversity Outbred population is a new mouse resource derived from partially inbred Collaborative Cross strains and maintained by randomized outcrossing. As such, it segregates the same allelic variants as the Collaborative Cross but embeds these in a distinct population architecture in which each animal has a high degree of heterozygosity and carries a unique combination of alleles. Phenotypic diversity is striking and often divergent from phenotypes seen in the founder strains of the Collaborative Cross. Allele frequencies and recombination density in early generations of Diversity Outbred mice are consistent with expectations based on simulations of the mating design. We describe analytical methods for genetic mapping using this resource and demonstrate the power and high mapping resolution achieved with this population by mapping a serum cholesterol trait to a 2-Mb region on chromosome 3 containing only 11 genes. Analysis of the estimated allele effects in conjunction with complete genome sequence data of the founder strains reduced the pool of candidate polymorphisms to seven SNPs, five of which are located in an intergenic region upstream of the Foxo1 gene. [ABSTRACT FROM AUTHOR]

Published
2012
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15. A General Bayesian Approach to Analyzing Diallel Crosses of Inbred Strains.

Author

Lenarcic, Alan B., Svenson, Karen L., Churchill, Gary A., Valdar, William, McIntyre, Lauren M., and de Koning, Dirk-Jan

Subjects
*GENOTYPE-environment interaction, *ANIMAL sexual behavior, *SPECIES hybridization, *HETEROSIS, *EPISTASIS (Genetics)
Abstract

The classic diallel takes a set of parents and produces offspring from all possible mating pairs. Phenotype values among the offspring can then be related back to their respective parentage. When the parents are diploid, sexed, and inbred, the diallel can characterize aggregate effects of genetic background on a phenotype, revealing effects of strain dosage, heterosis, parent of origin, epistasis, and sex-specific versions thereof. However, its analysis is traditionally intricate, unforgiving of unplanned missing information, and highly sensitive to imbalance, making the diallel unapproachable to many geneticists. Nonetheless, imbalanced and incomplete diallels arise frequently, albeit unintentionally, as by-products of larger-scale experiments that collect F1 data, for example, pilot studies or multiparent breeding efforts such as the Collaborative Cross or the Arabidopsis MAGIC lines. We present a general Bayesian model for analyzing diallel data on dioecious diploid inbred strains that cleanly decomposes the observed patterns of variation into biologically intuitive components, simultaneously models and accommodates outliers, and provides shrinkage estimates of effects that automatically incorporate uncertainty due to imbalance, missing data, and small sample size. We further present a model selection procedure for weighing evidence for or against the inclusion of those components in a predictive model. We evaluate our method through simulation and apply it to incomplete diallel data on the founders and F1's of the Collaborative Cross, robustly characterizing the genetic architecture of 48 phenotypes. [ABSTRACT FROM AUTHOR]

Published
2012
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16. Imputation of Single-Nucleotide Polymorphisms in Inbred Mice Using Local Phylogeny.

Author

Wang, Jeremy R., de Villena, Fernando Pardo-Manuel, Lawson, Heather A., Cheverud, James M., Churchill, Gary A., McMillan, Leonard, McIntyre, Lauren M., and de Koning, Dirk-Jan

Subjects
*GENETIC polymorphisms, *PHYLOGENY, *GENETIC research, *GENOMES, *NUCLEOTIDE sequence
Abstract

We present full-genome genotype imputations for 100 classical laboratory mouse strains, using a novel method. Using genotypes at 549,683 SNP loci obtained with the Mouse Diversity Array, we partitioned the genome of 100 mouse strains into 40,647 intervals that exhibit no evidence of historical recombination. For each of these intervals we inferred a local phylogenetic tree. We combined these data with 12 million loci with sequence variations recently discovered by whole-genome sequencing in a common subset of 12 classical laboratory strains. For each phylogenetic tree we identified strains sharing a leaf node with one or more of the sequenced strains. We then imputed high- and medium-confidence genotypes for each of 88 nonsequenced genomes. Among inbred strains, we imputed 92% of SNPs genome-wide, with 71% in high-confidence regions. Our method produced 977 million new genotypes with an estimated per-SNP error rate of 0.083% in high-confidence regions and 0.37% genome-wide. Our analysis identified which of the 88 nonsequenced strains would be the most informative for improving full-genome imputation, as well as which additional strain sequences will reveal more new genetic variants. Imputed sequences and quality scores can be downloaded and visualized online. [ABSTRACT FROM AUTHOR]

Published
2012
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17. Varying Coefficient Models for Mapping Quantitative Trait Loci Using Recombinant Inbred Intercrosses.

Author

Yi Gong, Fei Zou, McIntyre, Lauren M., and de Koning, Dirk-Jan

Subjects
*GENE mapping, *GENETIC polymorphisms, *GENOTYPE-environment interaction, *LOCUS (Genetics), *LABORATORY mice
Abstract

There has been a great deal of interest in the development of methodologies to map quantitative trait loci (QTL) using experimental crosses in the last 2 decades. Experimental crosses in animal and plant sciences provide important data sources for mapping QTL through linkage analysis. The Collaborative Cross (CC) is a renewable mouse resource that is generated from eight genetically diverse founder strains to mimic the genetic diversity in humans. The recombinant inbred intercrosses (RIX) generated from CC recombinant inbred (RI) lines share similar genetic structures of F2 individuals but with up to eight alleles segregating at any one locus. In contrast to F2 mice, genotypes of RIX can be inferred from the genotypes of their RI parents and can be produced repeatedly. Also, RIX mice typically do not share the same degree of relatedness. This unbalanced genetic relatedness requires careful statistical modeling to avoid false-positive findings. Many quantitative traits are inherently complex with genetic effects varying with other covariates, such as age. For such complex traits, if phenotype data can be collected over a wide range of ages across study subjects, their dynamic genetic patterns can be investigated. Parametric functions, such as sigmoidal or logistic functions, have been used for such purpose. In this article, we propose a flexible nonparametric time-varying coefficient QTL mapping method for RIX data. Our method allows the QTL effects to evolve with time and naturally extends classical parametric QTL mapping methods. We model the varying genetic effects nonparametrically with the B-spline bases. Our model investigates gene-by-time interactions for RIX data in a very flexible nonparametric fashion. Simulation results indicate that the varying coefficient QTL mapping has higher power and mapping precision compared to parametric models when the assumption of constant genetic effects fails. We also apply a modified permutation procedure to control overall significance level. [ABSTRACT FROM AUTHOR]

Published
2012
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