Locating multiple interacting quantitative trait loci with the zero-inflated generalized poisson regression
(2010) In Statistical Applications in Genetics and Molecular Biology 9(1).- Abstract
We consider the problem of locating multiple interacting quantitative trait loci (QTL) influencing traits measured in counts. In many applications the distribution of the count variable has a spike at zero. Zero-inflated generalized Poisson regression (ZIGPR) allows for an additional probability mass at zero and hence an improvement in the detection of significant loci. Classical model selection criteria often overestimate the QTL number. Therefore, modified versions of the Bayesian Information Criterion (mBIC and EBIC) were successfully used for QTL mapping. We apply these criteria based on ZIGPR as well as simpler models. An extensive simulation study shows their good power detecting QTL while controlling the false discovery rate. We... (More)
We consider the problem of locating multiple interacting quantitative trait loci (QTL) influencing traits measured in counts. In many applications the distribution of the count variable has a spike at zero. Zero-inflated generalized Poisson regression (ZIGPR) allows for an additional probability mass at zero and hence an improvement in the detection of significant loci. Classical model selection criteria often overestimate the QTL number. Therefore, modified versions of the Bayesian Information Criterion (mBIC and EBIC) were successfully used for QTL mapping. We apply these criteria based on ZIGPR as well as simpler models. An extensive simulation study shows their good power detecting QTL while controlling the false discovery rate. We illustrate how the inability of the Poisson distribution to account for over-dispersion leads to an overestimation of the QTL number and hence strongly discourages its application for identifying factors influencing count data. The proposed method is used to analyze the mice gallstone data of Lyons et al. (2003). Our results suggest the existence of a novel QTL on chromosome 4 interacting with another QTL previously identified on chromosome 5. We provide the corresponding code in R.
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- author
- Erhardt, Vinzenz ; Bogdan, Malgorzata LU and Czado, Claudia
- publishing date
- 2010
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- count data, model selection criteria, quantitative trait loci, zero inflated Poisson regression
- in
- Statistical Applications in Genetics and Molecular Biology
- volume
- 9
- issue
- 1
- article number
- 26
- publisher
- Berkeley Electronic Press
- external identifiers
-
- scopus:77954373006
- pmid:20597852
- ISSN
- 2194-6302
- DOI
- 10.2202/1544-6115.1545
- language
- English
- LU publication?
- no
- id
- 45fb5c69-a1eb-4cab-8ca9-e947b2344077
- date added to LUP
- 2023-12-08 09:25:07
- date last changed
- 2024-02-04 19:22:15
@article{45fb5c69-a1eb-4cab-8ca9-e947b2344077, abstract = {{<p>We consider the problem of locating multiple interacting quantitative trait loci (QTL) influencing traits measured in counts. In many applications the distribution of the count variable has a spike at zero. Zero-inflated generalized Poisson regression (ZIGPR) allows for an additional probability mass at zero and hence an improvement in the detection of significant loci. Classical model selection criteria often overestimate the QTL number. Therefore, modified versions of the Bayesian Information Criterion (mBIC and EBIC) were successfully used for QTL mapping. We apply these criteria based on ZIGPR as well as simpler models. An extensive simulation study shows their good power detecting QTL while controlling the false discovery rate. We illustrate how the inability of the Poisson distribution to account for over-dispersion leads to an overestimation of the QTL number and hence strongly discourages its application for identifying factors influencing count data. The proposed method is used to analyze the mice gallstone data of Lyons et al. (2003). Our results suggest the existence of a novel QTL on chromosome 4 interacting with another QTL previously identified on chromosome 5. We provide the corresponding code in R.</p>}}, author = {{Erhardt, Vinzenz and Bogdan, Malgorzata and Czado, Claudia}}, issn = {{2194-6302}}, keywords = {{count data; model selection criteria; quantitative trait loci; zero inflated Poisson regression}}, language = {{eng}}, number = {{1}}, publisher = {{Berkeley Electronic Press}}, series = {{Statistical Applications in Genetics and Molecular Biology}}, title = {{Locating multiple interacting quantitative trait loci with the zero-inflated generalized poisson regression}}, url = {{http://dx.doi.org/10.2202/1544-6115.1545}}, doi = {{10.2202/1544-6115.1545}}, volume = {{9}}, year = {{2010}}, }