Universal chromosomal microarray analysis reveals high proportion of copy-number variants in low-risk pregnancies.

OBJECTIVES: To evaluate the yield and utility of the routine use of chromosomal microarray analysis (CMA) for prenatal genetic diagnosis in a large cohort of pregnancies with normal ultrasound (US) at the time of genetic testing, compared with pregnancies with abnormal US findings. METHODS: We reviewed all prenatal CMA results in our center between November 2013 and December 2018. The prevalence of different CMA results in pregnancies with normal US at the time of genetic testing ('low-risk pregnancies'), was compared with that in pregnancies with abnormal US findings ('high-risk pregnancies'). Medical records were searched in order to evaluate subsequent US follow-up and the outcome of pregnancies with a clinically relevant copy-number variant (CNV), i.e. a pathogenic or likely pathogenic CNV or a susceptibility locus for disease with > 10% penetrance, related to early-onset disease in the low-risk group. RESULTS: In a cohort of 6431 low-risk pregnancies that underwent CMA, the prevalence of a clinically significant CNV related to early-onset disease was 1.1% (72/6431), which was significantly lower than the prevalence in high-risk pregnancies (4.9% (65/1326)). Of the low-risk pregnancies, 0.4% (27/6431) had a pathogenic or likely pathogenic CNV, and another 0.7% (45/6431) had a susceptibility locus with more than 10% penetrance. Follow-up of the low-risk pregnancies with a clinically significant early-onset CNV revealed that 31.9% (23/72) were terminated, while outcome data were missing in 26.4% (19/72). In 16.7% (12/72) of low-risk pregnancies, an US abnormality was discovered later on in gestation, after genetic testing had been performed. CONCLUSION: Although the background risk of identifying a clinically significant early-onset abnormal CMA result in pregnancies with a low a-priori risk is lower than that observed in high-risk pregnancies, the risk is substantial and should be conveyed to all pregnant women. © 2020 International Society of Ultrasound in Obstetrics and Gynecology.

Single-nucleotide polymorphism-based chromosomal microarray analysis provides clues and insights into disease mechanisms.

OBJECTIVE: Chromosomal microarray analysis (CMA) is the modality of choice for prenatal diagnosis in pregnancy with fetal malformation, as it has a high diagnostic yield for microdeletion/duplication syndromes. The aim of this study was to demonstrate the additional utility of single-nucleotide polymorphism (SNP)-based CMA in diagnosing monogenic diseases, imprinting disorders and uniparental disomy (UPD). METHODS: CMA was performed using Affymetrix CytoScan array, for all indications in 6995 pregnancies, at a tertiary referral hospital from November 2013 to June 2018. We describe four cases that had a CMA result that provided a more comprehensive understanding of the complex genetic mechanisms underlying the clinical presentation. RESULTS: In the first fetus, CMA was performed due to intrauterine growth restriction and revealed a 75 kbp maternally inherited microdeletion encompassing the Bloom syndrome gene (BLM). A diagnosis of Bloom syndrome was made upon identifying a paternally inherited common Ashkenazi founder mutation. In the second case, CMA was performed due to severely abnormal maternal serum analytes and revealed a deletion in 14q32.2q32.31 on the maternally inherited copy, leading to a diagnosis of Kagami-Ogata syndrome, which is an imprinting disorder. In the third case, amniocentesis was performed because of late-onset fetal macrosomia and mild polyhydramnios. CMA detected a deletion encompassing the locus of Prader-Willi/Angelman syndrome. In the fourth case, amniocentesis was performed due to maternal cytomegalovirus seroconversion. Maternal UPD of the entire long arm of chromosome 11 was detected. CONCLUSION: Prenatal CMA, based on oligo and SNP platforms, increases the diagnostic yield and enables a wider spectrum of disorders to be detected through the identification of complex genetic etiologies beyond only copy number variants. Copyright © 2019 ISUOG. Published by John Wiley & Sons Ltd.

Role of late amniocentesis in the era of modern genomic technologies.

OBJECTIVE: Traditionally, amniocentesis is performed between 17 and 23 weeks of gestation. This enables decisions regarding the course of pregnancy to be made before viability. Less frequently, amniocentesis is performed in the third trimester. Advanced genomic technologies such as chromosomal microarray analysis (CMA) provide more detailed information about the fetus compared with traditional G-banded chromosomal analysis. The aim of this study was to assess the indications for and safety of late amniocentesis, genetic-test results (especially in the context of CMA technology) and outcome of pregnancies that underwent the procedure after 24 weeks. METHODS: Medical records were analyzed retrospectively of all women in whom amniocentesis was performed at a gestational age of 24 + 0 to 38 + 6 weeks, at Hadassah Medical Center, between June 2013 and March 2017. Parameters investigated included indications for late amniocentesis, complications, CMA results and pregnancy outcome. RESULTS: During the study period, 291 women (303 fetuses, 277 singleton and 14 twin pregnancies; in two twin pairs, one fetus was terminated before amniocentesis) underwent late amniocentesis. CMA was performed in all instances of amniocentesis. The most frequent indication was abnormal sonographic finding(s) (204/303 fetuses, 67%). Preterm delivery occurred in 1.7% and 5.1% of pregnancies within the first week and within 1 month following the procedure, respectively. Aneuploidy was detected in nine (3%) fetuses and nine (3%) others had a pathogenic/likely pathogenic copy number variant, suggesting that CMA doubled the diagnostic yield of traditional karyotyping. Maximal diagnostic yield (17.5%) was achieved for the subgroup of fetuses referred with abnormal sonographic findings in two or more fetal anatomical systems. Variants of uncertain significance or susceptibility loci were found in another nine (3%) fetuses. CONCLUSIONS: In pregnancies undergoing late amniocentesis, CMA increased detection rates of fetal abnormalities and had a shorter turnaround time compared with traditional chromosomal analysis; therefore, late amniocentesis may serve as a helpful tool for detecting fetal abnormalities or reassuring parents following late-appearing abnormal sonographic findings. However, CMA may expose findings of uncertain significance, about which the couple should be precounseled. The procedure appears to be safe. Copyright © 2018 ISUOG. Published by John Wiley & Sons Ltd.

A deleterious mutation in the LOXHD1 gene causes autosomal recessive hearing loss in Ashkenazi Jews.

Autosomal recessive nonsyndromic sensorineural hearing loss (ARNSHL) in Ashkenazi Jews, is mainly caused by mutations in the GJB2 and GJB6 genes. Here we describe a novel homozygous mutation of the LOXHD1 gene resulting in a premature stop codon (R1572X) in nine patients of Ashkenazi Jewish origin who had severe-profound congenital non-progressive ARNSHL and benefited from cochlear implants. Upon screening for the mutation among 719 anonymous Ashkenazi-Jews we detected four carriers, indicating a carrier rate of 1:180 Ashkenazi Jews. This is the second reported mutation in the LOXHD1 gene, and its homozygous presence in two of 39 Ashkenazi Jewish families with congenital ARNSHL suggest that it could account for some 5% of the familial cases in this community.

Status of p53 in human cancer cells does not predict efficacy of CHK1 kinase inhibitors combined with chemotherapeutic agents.

DNA damage checkpoints cause cell cycle arrest, allowing DNA repair before resumption of the cell cycle. These checkpoints can be activated through several signaling pathways. Checkpoint activators include p53, checkpoint kinase 1 (CHK1), checkpoint kinase 2 and/or MAPKAP kinase 2 (MK2). Many cancer cells lack p53 activity and, therefore, depend on alternative checkpoint activators to arrest the cell cycle following DNA damage. Inhibition of these pathways is expected to specifically sensitize these p53-deficient cells to DNA damage caused by chemotherapy. Using isogenic p53-proficient and p53-deficient cancer cell lines, we show that inactivation of CHK1, but not MK2, abrogates cell cycle arrest following chemotherapy, specifically in p53-deficient cells. However, we show that CHK1 is required to maintain genome integrity and cell viability, and that p53-proficient cells are no less sensitive than p53-deficient cells to CHK1 inhibition in the presence of DNA damage. Thus, combining CHK1 inhibition with DNA damage does not lead to preferential killing of p53-deficient over p53-proficient cells, and inhibiting CHK1 does not appear to be a promising approach for potentiation of cancer chemotherapy.