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Bayesian estimation of genetic regulatory effects in high-throughput reporter assays.

Publication ,  Journal Article
Majoros, WH; Kim, Y-S; Barrera, A; Li, F; Wang, X; Cunningham, SJ; Johnson, GD; Guo, C; Lowe, WL; Scholtens, DM; Hayes, MG; Reddy, TE; Allen, AS
Published in: Bioinformatics
January 15, 2020

MOTIVATION: High-throughput reporter assays dramatically improve our ability to assign function to noncoding genetic variants, by measuring allelic effects on gene expression in the controlled setting of a reporter gene. Unlike genetic association tests, such assays are not confounded by linkage disequilibrium when loci are independently assayed. These methods can thus improve the identification of causal disease mutations. While work continues on improving experimental aspects of these assays, less effort has gone into developing methods for assessing the statistical significance of assay results, particularly in the case of rare variants captured from patient DNA. RESULTS: We describe a Bayesian hierarchical model, called Bayesian Inference of Regulatory Differences, which integrates prior information and explicitly accounts for variability between experimental replicates. The model produces substantially more accurate predictions than existing methods when allele frequencies are low, which is of clear advantage in the search for disease-causing variants in DNA captured from patient cohorts. Using the model, we demonstrate a clear tradeoff between variant sequencing coverage and numbers of biological replicates, and we show that the use of additional biological replicates decreases variance in estimates of effect size, due to the properties of the Poisson-binomial distribution. We also provide a power and sample size calculator, which facilitates decision making in experimental design parameters. AVAILABILITY AND IMPLEMENTATION: The software is freely available from www.geneprediction.org/bird. The experimental design web tool can be accessed at http://67.159.92.22:8080. SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.

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Published In

Bioinformatics

DOI

EISSN

1367-4811

Publication Date

January 15, 2020

Volume

36

Issue

2

Start / End Page

331 / 338

Location

England

Related Subject Headings

  • Software
  • Linkage Disequilibrium
  • Humans
  • Gene Frequency
  • Bioinformatics
  • Bayes Theorem
  • Alleles
  • 49 Mathematical sciences
  • 46 Information and computing sciences
  • 31 Biological sciences
 

Citation

APA
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Majoros, W. H., Kim, Y.-S., Barrera, A., Li, F., Wang, X., Cunningham, S. J., … Allen, A. S. (2020). Bayesian estimation of genetic regulatory effects in high-throughput reporter assays. Bioinformatics, 36(2), 331–338. https://doi.org/10.1093/bioinformatics/btz545
Majoros, William H., Young-Sook Kim, Alejandro Barrera, Fan Li, Xingyan Wang, Sarah J. Cunningham, Graham D. Johnson, et al. “Bayesian estimation of genetic regulatory effects in high-throughput reporter assays.Bioinformatics 36, no. 2 (January 15, 2020): 331–38. https://doi.org/10.1093/bioinformatics/btz545.
Majoros WH, Kim Y-S, Barrera A, Li F, Wang X, Cunningham SJ, et al. Bayesian estimation of genetic regulatory effects in high-throughput reporter assays. Bioinformatics. 2020 Jan 15;36(2):331–8.
Majoros, William H., et al. “Bayesian estimation of genetic regulatory effects in high-throughput reporter assays.Bioinformatics, vol. 36, no. 2, Jan. 2020, pp. 331–38. Pubmed, doi:10.1093/bioinformatics/btz545.
Majoros WH, Kim Y-S, Barrera A, Li F, Wang X, Cunningham SJ, Johnson GD, Guo C, Lowe WL, Scholtens DM, Hayes MG, Reddy TE, Allen AS. Bayesian estimation of genetic regulatory effects in high-throughput reporter assays. Bioinformatics. 2020 Jan 15;36(2):331–338.

Published In

Bioinformatics

DOI

EISSN

1367-4811

Publication Date

January 15, 2020

Volume

36

Issue

2

Start / End Page

331 / 338

Location

England

Related Subject Headings

  • Software
  • Linkage Disequilibrium
  • Humans
  • Gene Frequency
  • Bioinformatics
  • Bayes Theorem
  • Alleles
  • 49 Mathematical sciences
  • 46 Information and computing sciences
  • 31 Biological sciences