The High Diagnostic Yield of Prenatal Exome Sequencing Followed by 3400 Gene Panel Analysis in 629 Ongoing Pregnancies With Ultrasound Anomalies

Background: The aim of this study was to evaluate the diagnostic yield of routine exome sequencing (ES) in fetuses with ultrasound anomalies. Methods: We performed a retrospective analysis of the ES results of 629 fetuses with isolated or multiple anomalies referred in 2019–2022. Variants in a gene panel consisting of approximately 3400 genes associated with multiple congenital anomalies and/or intellectual disability were analyzed. We used trio analysis and filtering for de novo variants, compound heterozygous variants, homozygous variants, X-linked variants, variants in imprinted genes, and known pathogenic variants. Results: Pathogenic and likely pathogenic variants (class five and four, respectively) were identified in 14.0% (88/629, 95% CI 11.5%–16.9%) of cases. In the current cohort, the probability of detecting a monogenetic disorder was ∼1:7 (88/629, 95% CI 1:8.7–1:5.9), ranging from 1:9 (49/424) in cases with one major anomaly to 1:5 (32/147) in cases with multiple system anomalies. Conclusions: Our results indicate that a notable number of fetuses (1:7) with ultrasound anomalies and a normal chromosomal microarray have a (likely) pathogenic variant that can be detected through prenatal ES. These results warrant implementation of exome sequencing in selected cases, including those with an isolated anomaly on prenatal ultrasound.</p

Warsaw Breakage Syndrome associated DDX11 helicase resolves G-quadruplex structures to support sister chromatid cohesion

Warsaw Breakage Syndrome (WABS) is a rare disorder related to cohesinopathies and Fanconi anemia, caused by bi-allelic mutations in DDX11. Here, we report multiple compound heterozygous WABS cases, each displaying destabilized DDX11 protein and residual DDX11 function at the cellular level. Patient-derived cell lines exhibit sensitivity to topoisomerase and PARP inhibitors, defective sister chromatid cohesion and reduced DNA replication fork speed. Deleting DDX11 in RPE1-TERT cells inhibits proliferation and survival in a TP53-dependent manner and causes chromosome breaks and cohesion defects, independent of the expressed pseudogene DDX12p. Importantly, G-quadruplex (G4) stabilizing compounds induce chromosome breaks and cohesion defects which are strongly aggravated by inactivation of DDX11 but not FANCJ. The DNA helicase domain of DD