Author
Listed:
- Maxat Kulmanov
- Robert Hoehndorf
Abstract
Predicting the phenotypes resulting from molecular perturbations is one of the key challenges in genetics. Both forward and reverse genetic screen are employed to identify the molecular mechanisms underlying phenotypes and disease, and these resulted in a large number of genotype–phenotype association being available for humans and model organisms. Combined with recent advances in machine learning, it may now be possible to predict human phenotypes resulting from particular molecular aberrations. We developed DeepPheno, a neural network based hierarchical multi-class multi-label classification method for predicting the phenotypes resulting from loss-of-function in single genes. DeepPheno uses the functional annotations with gene products to predict the phenotypes resulting from a loss-of-function; additionally, we employ a two-step procedure in which we predict these functions first and then predict phenotypes. Prediction of phenotypes is ontology-based and we propose a novel ontology-based classifier suitable for very large hierarchical classification tasks. These methods allow us to predict phenotypes associated with any known protein-coding gene. We evaluate our approach using evaluation metrics established by the CAFA challenge and compare with top performing CAFA2 methods as well as several state of the art phenotype prediction approaches, demonstrating the improvement of DeepPheno over established methods. Furthermore, we show that predictions generated by DeepPheno are applicable to predicting gene–disease associations based on comparing phenotypes, and that a large number of new predictions made by DeepPheno have recently been added as phenotype databases.Author summary: Gene–phenotype associations can help to understand the underlying mechanisms of many genetic diseases. However, experimental identification, often involving animal models, is time consuming and expensive. Computational methods that predict gene–phenotype associations can be used instead. We developed DeepPheno, a novel approach for predicting the phenotypes resulting from a loss of function of a single gene. We use gene functions and gene expression as information to prediction phenotypes. Our method uses a neural network classifier that is able to account for hierarchical dependencies between phenotypes. We extensively evaluate our method and compare it with related approaches, and we show that DeepPheno results in better performance in several evaluations. Furthermore, we found that many of the new predictions made by our method have been added to phenotype association databases released one year later. Overall, DeepPheno simulates some aspects of human physiology and how molecular and physiological alterations lead to abnormal phenotypes.
Suggested Citation
Maxat Kulmanov & Robert Hoehndorf, 2020.
"DeepPheno: Predicting single gene loss-of-function phenotypes using an ontology-aware hierarchical classifier,"
PLOS Computational Biology, Public Library of Science, vol. 16(11), pages 1-22, November.
Handle:
RePEc:plo:pcbi00:1008453
DOI: 10.1371/journal.pcbi.1008453
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References listed on IDEAS
- Yun-Ching Chen & Christopher Douville & Cheng Wang & Noushin Niknafs & Grace Yeo & Violeta Beleva-Guthrie & Hannah Carter & Peter D Stenson & David N Cooper & Biao Li & Sean Mooney & Rachel Karchin, 2014.
"A Probabilistic Model to Predict Clinical Phenotypic Traits from Genome Sequencing,"
PLOS Computational Biology, Public Library of Science, vol. 10(9), pages 1-11, September.
- Ross N. W. Kettleborough & Elisabeth M. Busch-Nentwich & Steven A. Harvey & Christopher M. Dooley & Ewart de Bruijn & Freek van Eeden & Ian Sealy & Richard J. White & Colin Herd & Isaac J. Nijman & Fr, 2013.
"A systematic genome-wide analysis of zebrafish protein-coding gene function,"
Nature, Nature, vol. 496(7446), pages 494-497, April.
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