TY - JOUR
T1 - Prioritization of genes driving congenital phenotypes of patients with de novo genomic structural variants
AU - Middelkamp, Sjors
AU - Vlaar, Judith M.
AU - Giltay, Jacques
AU - Korzelius, Jerome
AU - Besselink, Nicolle
AU - Boymans, Sander
AU - Janssen, Roel
AU - De La Fonteijne, Lisanne
AU - Van Binsbergen, Ellen
AU - Van Roosmalen, Markus J.
AU - Hochstenbach, Ron
AU - Giachino, Daniela
AU - Talkowski, Michael E.
AU - Kloosterman, Wigard P.
AU - Cuppen, Edwin
N1 - Publisher Copyright:
© 2019 The Author(s).
PY - 2019/12/4
Y1 - 2019/12/4
N2 - Background: Genomic structural variants (SVs) can affect many genes and regulatory elements. Therefore, the molecular mechanisms driving the phenotypes of patients carrying de novo SVs are frequently unknown. Methods: We applied a combination of systematic experimental and bioinformatic methods to improve the molecular diagnosis of 39 patients with multiple congenital abnormalities and/or intellectual disability harboring apparent de novo SVs, most with an inconclusive diagnosis after regular genetic testing. Results: In 7 of these cases (18%), whole-genome sequencing analysis revealed disease-relevant complexities of the SVs missed in routine microarray-based analyses. We developed a computational tool to predict the effects on genes directly affected by SVs and on genes indirectly affected likely due to the changes in chromatin organization and impact on regulatory mechanisms. By combining these functional predictions with extensive phenotype information, candidate driver genes were identified in 16/39 (41%) patients. In 8 cases, evidence was found for the involvement of multiple candidate drivers contributing to different parts of the phenotypes. Subsequently, we applied this computational method to two cohorts containing a total of 379 patients with previously detected and classified de novo SVs and identified candidate driver genes in 189 cases (50%), including 40 cases whose SVs were previously not classified as pathogenic. Pathogenic position effects were predicted in 28% of all studied cases with balanced SVs and in 11% of the cases with copy number variants. Conclusions: These results demonstrate an integrated computational and experimental approach to predict driver genes based on analyses of WGS data with phenotype association and chromatin organization datasets. These analyses nominate new pathogenic loci and have strong potential to improve the molecular diagnosis of patients with de novo SVs.
AB - Background: Genomic structural variants (SVs) can affect many genes and regulatory elements. Therefore, the molecular mechanisms driving the phenotypes of patients carrying de novo SVs are frequently unknown. Methods: We applied a combination of systematic experimental and bioinformatic methods to improve the molecular diagnosis of 39 patients with multiple congenital abnormalities and/or intellectual disability harboring apparent de novo SVs, most with an inconclusive diagnosis after regular genetic testing. Results: In 7 of these cases (18%), whole-genome sequencing analysis revealed disease-relevant complexities of the SVs missed in routine microarray-based analyses. We developed a computational tool to predict the effects on genes directly affected by SVs and on genes indirectly affected likely due to the changes in chromatin organization and impact on regulatory mechanisms. By combining these functional predictions with extensive phenotype information, candidate driver genes were identified in 16/39 (41%) patients. In 8 cases, evidence was found for the involvement of multiple candidate drivers contributing to different parts of the phenotypes. Subsequently, we applied this computational method to two cohorts containing a total of 379 patients with previously detected and classified de novo SVs and identified candidate driver genes in 189 cases (50%), including 40 cases whose SVs were previously not classified as pathogenic. Pathogenic position effects were predicted in 28% of all studied cases with balanced SVs and in 11% of the cases with copy number variants. Conclusions: These results demonstrate an integrated computational and experimental approach to predict driver genes based on analyses of WGS data with phenotype association and chromatin organization datasets. These analyses nominate new pathogenic loci and have strong potential to improve the molecular diagnosis of patients with de novo SVs.
KW - Copy number variants
KW - Driver genes
KW - Intellectual disability
KW - Multiple congenital anomalies
KW - Neurodevelopmental disorders
KW - Position effects
KW - Structural variation
KW - Topologically associating domains
KW - Transcriptome sequencing
KW - Whole-genome sequencing
UR - http://www.scopus.com/inward/record.url?scp=85076001768&partnerID=8YFLogxK
U2 - 10.1186/s13073-019-0692-0
DO - 10.1186/s13073-019-0692-0
M3 - Article
C2 - 31801603
AN - SCOPUS:85076001768
SN - 1756-994X
VL - 11
JO - Genome Medicine
JF - Genome Medicine
IS - 1
M1 - 79
ER -