Estimation of allele-specific fitness effects across human protein-coding sequences and implications for disease

A central challenge in human genomics is to understand the cellular, evolutionary, and clinical significance of genetic variants. Here, we introduce a unified population-genetic and machine-learning model, called inear llele- pecific election nferenc ( ), for estimating the fitness effects of all ob...

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Bibliographic Details
Published in:Genome research 2019-08, Vol.29 (8), p.1310-1321
Main Authors: Huang, Yi-Fei, Siepel, Adam
Format: Article
Language:English
Subjects:
Alleles
Autism
Autism Spectrum Disorder - genetics
Autism Spectrum Disorder - metabolism
Autism Spectrum Disorder - pathology
Base Sequence
Central nervous system
Genetic diversity
Genetic Fitness
Genetic Variation
Genetics, Population
Genome, Human
Genomes
Genomics
Humans
Inheritance Patterns
Learning algorithms
Machine Learning
Method
Models, Genetic
Mutation
Negative selection
Neoplasms - genetics
Neoplasms - metabolism
Neoplasms - pathology
Polymorphism, Single Nucleotide
Population genetics
Proteome - genetics
Proteome - metabolism
Reproductive fitness
Selection, Genetic
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Summary:A central challenge in human genomics is to understand the cellular, evolutionary, and clinical significance of genetic variants. Here, we introduce a unified population-genetic and machine-learning model, called inear llele- pecific election nferenc ( ), for estimating the fitness effects of all observed and potential single-nucleotide variants, based on polymorphism data and predictive genomic features. We applied LASSIE to 51 high-coverage genome sequences annotated with 33 genomic features and constructed a map of allele-specific selection coefficients across all protein-coding sequences in the human genome. This map is generally consistent with previous inferences of the bulk distribution of fitness effects but reveals pervasive weak negative selection against synonymous mutations. In addition, the estimated selection coefficients are highly predictive of inherited pathogenic variants and cancer driver mutations, outperforming state-of-the-art variant prioritization methods. By contrasting our estimated model with ultrahigh coverage ExAC exome-sequencing data, we identified 1118 genes under unusually strong negative selection, which tend to be exclusively expressed in the central nervous system or associated with autism spectrum disorder, as well as 773 genes under unusually weak selection, which tend to be associated with metabolism. This combination of classical population genetic theory with modern machine-learning and large-scale genomic data is a powerful paradigm for the study of both human evolution and disease.
ISSN:1088-9051
1549-5469
DOI:10.1101/gr.245522.118