Hierarchical modeling of haplotype effects based on a phylogeny

Selle, Maria Lie; Steinsland, Ingelin; Lindgren, Finn; Brajkovic, Vladimir; Čubrić-Ćurik, Vlatka

doi:10.1101/2020.01.31.928390

Cited by 5 publications

(5 citation statements)

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“…IBD mapping, in turn, can be seen as a generalization of linkage mapping that uses IBD among pairs of people who are not closely related rather than only among close relatives. Our method is also closely related to haplotype mapping, and in particular approaches to haplotype mapping that estimate tree-like structures to describe relatedness among sets of haplotypes (Liu et al, 2001;Morris, 2005;Selle et al, 2021). Finally, our method adds to a tradition of methods for identifying trait-involved loci that are explicitly tree-based (Templeton et al, 1987;McPeek and Strahs, 1999;Larribe et al, 2002;Morris et al, 2002;Zöllner and Pritchard, 2005;Minichiello and Durbin, 2006;Mailund et al, 2006;Tachmazidou et al, 2007;Kimmel et al, 2008;Wu, 2008;Besenbacher et al, 2009;Zhang et al, 2012;Burkett et al, 2013;Thompson and Kubatko, 2013;Thompson et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

“…Tree-based approaches to quantitative trait locus (QTL) mapping-in which a trait is tested for association with a tree or set of trees describing genetic variation in a region-have been proposed several times and shown to provide some advantages (Templeton et al, 1987;McPeek and Strahs, 1999;Larribe et al, 2002;Morris et al, 2002;Zöllner and Pritchard, 2005;Minichiello and Durbin, 2006;Mailund et al, 2006;Tachmazidou et al, 2007;Kimmel et al, 2008;Wu, 2008;Besenbacher et al, 2009;Zhang et al, 2012;Burkett et al, 2013;Thompson and Kubatko, 2013;Thompson et al, 2016), as have approaches to haplotype-based mapping that leverage awareness of tree-like relatedness patterns among sets of haplotypes (Liu et al, 2001;Morris, 2005;Selle et al, 2021). At the same time, explicitly tree-based approaches have until recently been limited by difficulties in estimating locus-level trees at scale.…”

Section: Introductionmentioning

confidence: 99%

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Tree-based QTL mapping with expected local genetic relatedness matrices

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Fan

et al. 2023

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Understanding the genetic basis of complex phenotypes is a central pursuit of genetics. Genome-wide Association Studies (GWAS) are a powerful way to find genetic loci associated with phenotypes. GWAS are widely and successfully used, but they face challenges related to the fact that variants are tested for association with a phenotype independently, whereas in reality variants at different sites are correlated because of their shared evolutionary history. One way to model this shared history is through the ancestral recombination graph (ARG), which encodes a series of local coalescent trees. Recent computational and methodological breakthroughs have made it feasible to estimate approximate ARGs from large-scale samples. Here, we explore the potential of an ARG-based approach to quantitative-trait locus (QTL) mapping, echoing existing variance-components approaches. We propose a framework that relies on the conditional expectation of a local genetic relatedness matrix given the ARG (local eGRM). Simulations show that our method is especially beneficial for finding QTLs in the presence of allelic heterogeneity. By framing QTL mapping in terms of the estimated ARG, we can also facilitate the detection of QTLs in understudied populations. We use local eGRM to identify a large-effect BMI locus, the \textit{CREBRF} gene, in a sample of Native Hawaiians in which it was not previously detectable by GWAS because of a lack of population-specific imputation resources. Our investigations can provide intuition about the benefits of using estimated ARGs in population- and statistical-genetic methods in general.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tree-based QTL mapping with expected local genetic relatedness matrices

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Schraiber

Fan

et al. 2023

Preprint

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“…It uses the same key underlying linear algebra routines as standard genetic evaluation software [25,[71][72][73], and enables both full Bayesian analysis with fast and very accurate approximate algorithm [74] or even faster empirical Bayesian analysis. We have used the R-INLA package extensively for standard quantitative genetic studies [75][76][77], accounting for selection [78], spatial modelling of plant and tree trials [79] and for modelling of phenotypes on phylogeny [80]. While the R-INLA package is fast for models with a sparse structure (time-series, spatial regions or points and pedigree), it does not fare well for genomic models that have dense a structure [32,33].…”

Section: The Limitations Of This Study and Future Possibilitiesmentioning

confidence: 99%

Spatial modelling improves genetic evaluation in smallholder breeding programs

et al. 2020

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Background Breeders and geneticists use statistical models to separate genetic and environmental effects on phenotype. A common way to separate these effects is to model a descriptor of an environment, a contemporary group or herd, and account for genetic relationship between animals across environments. However, separating the genetic and environmental effects in smallholder systems is challenging due to small herd sizes and weak genetic connectedness across herds. We hypothesised that accounting for spatial relationships between nearby herds can improve genetic evaluation in smallholder systems. Furthermore, geographically referenced environmental covariates are increasingly available and could model underlying sources of spatial relationships. The objective of this study was therefore, to evaluate the potential of spatial modelling to improve genetic evaluation in dairy cattle smallholder systems. Methods We performed simulations and real dairy cattle data analysis to test our hypothesis. We modelled environmental variation by estimating herd and spatial effects. Herd effects were considered independent, whereas spatial effects had distance-based covariance between herds. We compared these models using pedigree or genomic data. Results The results show that in smallholder systems (i) standard models do not separate genetic and environmental effects accurately, (ii) spatial modelling increases the accuracy of genetic evaluation for phenotyped and non-phenotyped animals, (iii) environmental covariates do not substantially improve the accuracy of genetic evaluation beyond simple distance-based relationships between herds, (iv) the benefit of spatial modelling was largest when separating the genetic and environmental effects was challenging, and (v) spatial modelling was beneficial when using either pedigree or genomic data. Conclusions We have demonstrated the potential of spatial modelling to improve genetic evaluation in smallholder systems. This improvement is driven by establishing environmental connectedness between herds, which enhances separation of genetic and environmental effects. We suggest routine spatial modelling in genetic evaluations, particularly for smallholder systems. Spatial modelling could also have a major impact in studies of human and wild populations.

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“…It would also still be subject to computational constraints on the number of haplotypes and, in the case of the tree-informed prior, to caveats about local phylogeny in recombinant systems. Nonetheless, it would be interesting to apply our allele-based inference approach to QTL in non-experimental populations and to compare it with emerging haplotype-based, phylogeny-informed association approaches designed for these populations (Selle et al 2020). This allelic perspective may provide new insight into the genetic architecture of QTL that is not revealed by the variant-based approaches commonly used in non-experimental populations.…”

Section: Applying the Allele-based Approach In Other Populationsmentioning

confidence: 99%

“…This defines a prior distribution over the allelic series that is informed by a tree, p(M|T). In this way, our approach is similar to other models that include phylogenetic information; for example, by modeling distributional "changepoints" on a tree (Azim Ansari and Didelot 2016), or by using phylogenetic distance as an input for a distance-dependent CRP (Cybis et al 2018), among others (Zhang et al 2012;Thompson and Kubatko 2013;Behr et al 2020;Selle et al 2020). In particular, Azim Ansari and Didelot (2016) specify a prior distribution over the allelic series by defining the prior probability that each branch of a tree is functionally mutated with respect to a phenotype (in their case, a categorical trait).…”

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Inferring the Allelic Series at QTL in Multiparental Populations

2020

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Multiparental populations (MPPs) are experimental populations in which the genome of every individual is a mosaic of known founder haplotypes. These populations are useful for detecting quantitative trait loci (QTL) because tests of association can leverage inferred founder haplotype descent. It is difficult, however, to determine how haplotypes at a locus group into distinct functional alleles, termed the allelic series. The allelic series is important because it provides information about the number of causal variants at a QTL and their combined effects. In this study, we introduce a fully-Bayesian model selection framework for inferring the allelic series. This framework accounts for sources of uncertainty found in typical MPPs, including the number and composition of functional alleles. Our prior distribution for the allelic series is based on the Chinese restaurant process, a relative of the Dirichlet process, and we leverage its connection to the coalescent to introduce additional prior information about haplotype relatedness via a phylogenetic tree. We evaluate our approach via simulation and apply it to QTL from two MPPs: the Collaborative Cross (CC) and the Drosophila Synthetic Population Resource (DSPR). We find that, although posterior inference of the exact allelic series is often uncertain, we are able to distinguish biallelic QTL from more complex multiallelic cases. Additionally, our allele-based approach improves haplotype effect estimation when the true number of functional alleles is small. Our method, Tree-Based Inference of Multiallelism via Bayesian Regression (TIMBR), provides new insight into the genetic architecture of QTL in MPPs.

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Hierarchical modeling of haplotype effects based on a phylogeny

Cited by 5 publications

References 67 publications

Tree-based QTL mapping with expected local genetic relatedness matrices

Tree-based QTL mapping with expected local genetic relatedness matrices

Spatial modelling improves genetic evaluation in smallholder breeding programs

Inferring the Allelic Series at QTL in Multiparental Populations

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