Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia

Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia

Abstract Background Next-generation sequencing of individuals with genetic diseases often detects candidate rare variants in numerous genes, but determining which are causal remains challenging. We hypothesized that the spatial distribution of missense variants in protein structures contains informa...

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Main Authors: R. Michael Sivley, Jonathan H. Sheehan, Jonathan A. Kropski, Joy Cogan, Timothy S. Blackwell, John A. Phillips, William S. Bush, Jens Meiler, John A. Capra
Format: Article
Language:English
Published: BMC 2018-01-01
Series:BMC Bioinformatics
Online Access:http://link.springer.com/article/10.1186/s12859-018-2010-z
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spelling doaj-921b6605636e476a9b2c86243d77a6f22020-11-25T00:41:11ZengBMCBMC Bioinformatics1471-21052018-01-0119111010.1186/s12859-018-2010-zThree-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial PneumoniaR. Michael Sivley0Jonathan H. Sheehan1Jonathan A. Kropski2Joy Cogan3Timothy S. Blackwell4John A. Phillips5William S. Bush6Jens Meiler7John A. Capra8Department of Biomedical Informatics, Vanderbilt UniversityDepartment of Biochemistry and Center for Structural Biology, Vanderbilt UniversityDepartment of Medicine, Vanderbilt UniversityDepartment of Pediatrics, Vanderbilt UniversityDepartment of Medicine, Vanderbilt UniversityDepartment of Pediatrics, Vanderbilt UniversityDepartment of Quantitative and Population Health Sciences, Case Western Reserve UniversityDepartment of Chemistry and Center for Structural Biology, Vanderbilt UniversityDepartment of Biological Sciences, Vanderbilt Genetics Institute, and Center for Structural Biology, Vanderbilt UniversityAbstract Background Next-generation sequencing of individuals with genetic diseases often detects candidate rare variants in numerous genes, but determining which are causal remains challenging. We hypothesized that the spatial distribution of missense variants in protein structures contains information about function and pathogenicity that can help prioritize variants of unknown significance (VUS) and elucidate the structural mechanisms leading to disease. Results To illustrate this approach in a clinical application, we analyzed 13 candidate missense variants in regulator of telomere elongation helicase 1 (RTEL1) identified in patients with Familial Interstitial Pneumonia (FIP). We curated pathogenic and neutral RTEL1 variants from the literature and public databases. We then used homology modeling to construct a 3D structural model of RTEL1 and mapped known variants into this structure. We next developed a pathogenicity prediction algorithm based on proximity to known disease causing and neutral variants and evaluated its performance with leave-one-out cross-validation. We further validated our predictions with segregation analyses, telomere lengths, and mutagenesis data from the homologous XPD protein. Our algorithm for classifying RTEL1 VUS based on spatial proximity to pathogenic and neutral variation accurately distinguished 7 known pathogenic from 29 neutral variants (ROC AUC = 0.85) in the N-terminal domains of RTEL1. Pathogenic proximity scores were also significantly correlated with effects on ATPase activity (Pearson r = −0.65, p = 0.0004) in XPD, a related helicase. Applying the algorithm to 13 VUS identified from sequencing of RTEL1 from patients predicted five out of six disease-segregating VUS to be pathogenic. We provide structural hypotheses regarding how these mutations may disrupt RTEL1 ATPase and helicase function. Conclusions Spatial analysis of missense variation accurately classified candidate VUS in RTEL1 and suggests how such variants cause disease. Incorporating spatial proximity analyses into other pathogenicity prediction tools may improve accuracy for other genes and genetic diseases.http://link.springer.com/article/10.1186/s12859-018-2010-z
collection DOAJ
language English
format Article
sources DOAJ
author R. Michael Sivley
Jonathan H. Sheehan
Jonathan A. Kropski
Joy Cogan
Timothy S. Blackwell
John A. Phillips
William S. Bush
Jens Meiler
John A. Capra
spellingShingle R. Michael Sivley
Jonathan H. Sheehan
Jonathan A. Kropski
Joy Cogan
Timothy S. Blackwell
John A. Phillips
William S. Bush
Jens Meiler
John A. Capra
Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia
BMC Bioinformatics
author_facet R. Michael Sivley
Jonathan H. Sheehan
Jonathan A. Kropski
Joy Cogan
Timothy S. Blackwell
John A. Phillips
William S. Bush
Jens Meiler
John A. Capra
author_sort R. Michael Sivley
title Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia
title_short Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia
title_full Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia
title_fullStr Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia
title_full_unstemmed Three-dimensional spatial analysis of missense variants in RTEL1 identifies pathogenic variants in patients with Familial Interstitial Pneumonia
title_sort three-dimensional spatial analysis of missense variants in rtel1 identifies pathogenic variants in patients with familial interstitial pneumonia
publisher BMC
series BMC Bioinformatics
issn 1471-2105
publishDate 2018-01-01
description Abstract Background Next-generation sequencing of individuals with genetic diseases often detects candidate rare variants in numerous genes, but determining which are causal remains challenging. We hypothesized that the spatial distribution of missense variants in protein structures contains information about function and pathogenicity that can help prioritize variants of unknown significance (VUS) and elucidate the structural mechanisms leading to disease. Results To illustrate this approach in a clinical application, we analyzed 13 candidate missense variants in regulator of telomere elongation helicase 1 (RTEL1) identified in patients with Familial Interstitial Pneumonia (FIP). We curated pathogenic and neutral RTEL1 variants from the literature and public databases. We then used homology modeling to construct a 3D structural model of RTEL1 and mapped known variants into this structure. We next developed a pathogenicity prediction algorithm based on proximity to known disease causing and neutral variants and evaluated its performance with leave-one-out cross-validation. We further validated our predictions with segregation analyses, telomere lengths, and mutagenesis data from the homologous XPD protein. Our algorithm for classifying RTEL1 VUS based on spatial proximity to pathogenic and neutral variation accurately distinguished 7 known pathogenic from 29 neutral variants (ROC AUC = 0.85) in the N-terminal domains of RTEL1. Pathogenic proximity scores were also significantly correlated with effects on ATPase activity (Pearson r = −0.65, p = 0.0004) in XPD, a related helicase. Applying the algorithm to 13 VUS identified from sequencing of RTEL1 from patients predicted five out of six disease-segregating VUS to be pathogenic. We provide structural hypotheses regarding how these mutations may disrupt RTEL1 ATPase and helicase function. Conclusions Spatial analysis of missense variation accurately classified candidate VUS in RTEL1 and suggests how such variants cause disease. Incorporating spatial proximity analyses into other pathogenicity prediction tools may improve accuracy for other genes and genetic diseases.
url http://link.springer.com/article/10.1186/s12859-018-2010-z
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