Analyzing complex traits with congenic strains

Shao, Haifeng; Sinasac, David S.; Burrage, Lindsay C.; Hodges, Craig A.; Supelak, Pamela J.; Palmert, Mark R.; Moreno, Carol; Cowley, Allen W.; Jacob, Howard J.; Nadeau, Joseph H.

doi:10.1007/s00335-010-9267-5

Cited by 45 publications

(52 citation statements)

References 49 publications

(88 reference statements)

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“…This time-and labor-intensive effort to identify specific genes is often derailed by the discovery that a single QTL of large effect is in fact caused by multiple loci of small effect located in the same chromosomal region (Legare et al 2000;Mott et al 2000;Cheng et al 2010;Shao et al 2010;Parker et al 2013). An AIL is an improvement over these traditional methods because it merges identification and fine-mapping into a single step, which can often discriminate between loci that are due to single vs. multiple alleles (Darvasi and Soller 1995).…”

Section: Discussionmentioning

confidence: 99%

High-Resolution Genetic Mapping of Complex Traits from a Combined Analysis of F2 and Advanced Intercross Mice

et al. 2014

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Genetic influences on anxiety disorders are well documented; however, the specific genes underlying these disorders remain largely unknown. To identify quantitative trait loci (QTL) for conditioned fear and open field behavior, we used an F 2 intercross (n = 490) and a 34th-generation advanced intercross line (AIL) (n = 687) from the LG/J and SM/J inbred mouse strains. The F 2 provided strong support for several QTL, but within wide chromosomal regions. The AIL yielded much narrower QTL, but the results were less statistically significant, despite the larger number of mice. Simultaneous analysis of the F 2 and AIL provided strong support for QTL and within much narrower regions. We used a linear mixed-model approach, implemented in the program QTLRel, to correct for possible confounding due to familial relatedness. Because we recorded the full pedigree, we were able to empirically compare two ways of accounting for relatedness: using the pedigree to estimate kinship coefficients and using genetic marker estimates of "realized relatedness." QTL mapping using the marker-based estimates yielded more support for QTL, but only when we excluded the chromosome being scanned from the marker-based relatedness estimates. We used a forward model selection procedure to assess evidence for multiple QTL on the same chromosome. Overall, we identified 12 significant loci for behaviors in the open field and 12 significant loci for conditioned fear behaviors. Our approach implements multiple advances to integrated analysis of F 2 and AILs that provide both power and precision, while maintaining the advantages of using only two inbred strains to map QTL.

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Section: Discussionmentioning

confidence: 99%

High-Resolution Genetic Mapping of Complex Traits from a Combined Analysis of F2 and Advanced Intercross Mice

et al. 2014

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“…Sequential IL analysis. This method was proposed by Shao et al (2010) and adjusted to the population used in this study. ILs that share one break-point were selected and used in sequential (two by two) analyses to identify QTLs.…”

Section: Mappingmentioning

confidence: 99%

“…The genome of an IL is composed of a recipient genome contributed by one of the parental strains (Bristol N2) and a short, homozygous segment of the donor genome contributed by CB4856. We first conducted a straightforward bin mapping approach, followed by comparisons to a common reference (N2), and then a sequential pairwise analysis (Shao et al, 2010). These analyses indicate that the genetic architecture of dauer traits is highly complex, with a large number of quantitative trait loci (QTLs) affecting dauer larvae development in growing populations.…”

Section: Introductionmentioning

confidence: 99%

Genetic mapping of variation in dauer larvae development in growing populations of Caenorhabditis elegans

et al. 2013

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In the nematode Caenorhabditis elegans, the appropriate induction of dauer larvae development within growing populations is likely to be a primary determinant of genotypic fitness. The underlying genetic architecture of natural genetic variation in dauer formation has, however, not been thoroughly investigated. Here, we report extensive natural genetic variation in dauer larvae development within growing populations across multiple wild isolates. Moreover, bin mapping of introgression lines (ILs) derived from the genetically divergent isolates N2 and CB4856 reveals 10 quantitative trait loci (QTLs) affecting dauer formation. Comparison of individual ILs to N2 identifies an additional eight QTLs, and sequential IL analysis reveals six more QTLs. Our results also show that a behavioural, laboratory-derived, mutation controlled by the neuropeptide Y receptor homolog npr-1 can affect dauer larvae development in growing populations. These findings illustrate the complex genetic architecture of variation in dauer larvae formation in C. elegans and may help to understand how the control of variation in dauer larvae development has evolved.

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“…52,55 In this model, naturally occurring protective A/J-derived alleles act in protective but context-dependent ways to modify the penetrance, expressivity, and pleiotropy of diet-induced MetS phenotypes on the genetically predisposed C57BL/6J background. Thus in this and other cases, 56 QTLs act as genetic modifiers, with highly non-additive effects and strong dependence on genetic background. Context dependence probably explains the contrast in the prevalence of evidence for modifier effects in genetically heterogeneous populations such as the Resil- 20 From Modified Phenotypes to Modifier Genes Strategies to Identify Genetic Modifiers in Humans Several approaches can be used to study modifier genes directly in human populations, including comparative expression profiling, genome-wide association studies (GWASs), and family-based association analyses.…”

Section: Modifiers Of Complex Traitsmentioning

confidence: 87%

“…Specialized inbred resources such as congenic strains, in which the causal target allele or candidate modifier locus has been transferred to an alternative strain background, 56 can be readily generated to identify genetic modifier effects and map the responsible loci. Genetic transfer can be achieved through selective breeding to isolate the variant on a distinct strain background or by direct genetic engineering of embryonic stem cells or oocytes and subsequent generation of founder mice.…”

Section: Strategies To Identify Genetic Modifiers In Micementioning

confidence: 99%

From Peas to Disease: Modifier Genes, Network Resilience, and the Genetics of Health

Riordan

Nadeau

2017

The American Journal of Human Genetics

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113

107

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Phenotypes are rarely consistent across genetic backgrounds and environments, but instead vary in many ways depending on allelic variants, unlinked genes, epigenetic factors, and environmental exposures. In the extreme, individuals carrying the same causal DNA sequence variant but on different backgrounds can be classified as having distinct conditions. Similarly, some individuals that carry disease alleles are nevertheless healthy despite affected family members in the same environment. These genetic background effects often result from the action of so-called ''modifier genes'' that modulate the phenotypic manifestation of target genes in an epistatic manner. While complicating the prospects for gene discovery and the feasibility of mechanistic studies, such effects are opportunities to gain a deeper understanding of gene interaction networks that provide organismal form and function as well as resilience to perturbation. Here, we review the principles of modifier genetics and assess progress in studies of modifier genes and their targets in both simple and complex traits. We propose that modifier effects emerge from gene interaction networks whose structure and function vary with genetic background and argue that these effects can be exploited as safe and effective ways to prevent, stabilize, and reverse disease and dysfunction.

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Analyzing complex traits with congenic strains

Cited by 45 publications

References 49 publications

High-Resolution Genetic Mapping of Complex Traits from a Combined Analysis of F2 and Advanced Intercross Mice

High-Resolution Genetic Mapping of Complex Traits from a Combined Analysis of F2 and Advanced Intercross Mice

Genetic mapping of variation in dauer larvae development in growing populations of Caenorhabditis elegans

From Peas to Disease: Modifier Genes, Network Resilience, and the Genetics of Health

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