Yuntao Xia Ph.D. , Maria Katz M.Sc. , Dhruva Chandramohan Ph.D. , Elan Bechor Ph.D. , Benjamin Podgursky M.Sc. , Michael Hoxie B.S. , Qinnan Zhang Ph.D. , Willy Chertman M.D. , Jessica Kang B.S. , Edwina Blue B.S. , Justin Chen B.S. , Justin Schleede Ph.D. , Nathan R. Slotnick M.D., Ph.D. , Xiaoli Du Ph.D. , Robert Boostanfar M.D. , Eric Urcia M.Sc. , Barry Behr Ph.D. , Jacques Cohen Ph.D. , Noor Siddiqui M.Sc.
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Abstract
Objective
To validate the performance of our laboratory-developed whole-genome screening assay within clinical preimplantation genetic testing environments.
Design
Perform a laboratory-developed whole-genome assay on both cell lines and trophectoderm biopsies, subsequently employing the next-generation sequencing procedure to reach a sequencing depth of 30X. Adhere to the Genome Analysis Toolkit best practices for accuracy, sensitivity, specificity, and precision calculations by comparing samples with references. Our assay was then applied to cell lines and biopsies harboring known pathogenic variants, aiming to ascertain these changes solely from the next-generation sequencing data, independent of parental genome information.
Settings
Clinical laboratory.
Patients
Coriell cell lines and research embryos with known chromosomal or genetic variants. Research trophectoderm biopsies from a couple that are heterozygous carriers for distinct variants in the same autosomal recessive gene (HOGA1).
Intervention
Not applicable.
Main Outcome Measures
Accuracy, sensitivity, specificity, and precision were assessed by comparing the samples to their references. For samples with known variants, we calculated our sensitivity to detecting established variants. For the research embryos, noncarrier, carrier, and compound heterozygous states of inherited HOGA1 variants were distinguished independently of parental samples.
Results
Amplification of DNA from cell lines and embryos yielded success rates exceeding 99.9% and 98.2%, respectively, although maintaining an accuracy of >99.9% for aneuploidy assessment. The accuracy (99.99%), specificity (99.99%), sensitivity (98.0%), and precision (98.1%) of amplified genome in the bottle (reference NA12878) and embryo biopsies were comparable to results on genomic DNA, including mitochondrial heteroplasmy. Using our assay, we achieved >99.99% sensitivity when examining samples with known chromosomal and genetic variants. This encompassed pathogenic CFTR, BRCA1, and other variants, along with uniparental isodisomies and microdeletions such as DiGeorge syndrome. Our research study identified noncarrier, carrier, and compound heterozygous states within trophectoderm biopsies while simultaneously screening for 1,300 other severe monogenic diseases.
Conclusion
To our knowledge, this is the first clinical validation of whole-genome embryo screening. In this study, we demonstrated high accuracy for aneuploidy calls (>99.9%) and genetic variants (99.99%), even in the absence of parental genomes. This assay demonstrates advancements in genomic screening and an extended scope for testing capabilities in the realm of preimplantation genetic testing.
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