TY - UNPB
T1 - Clinical-grade whole genome sequencing-based haplarithmisis enables all forms of preimplantation genetic testing
AU - Janssen, A. E. J.
AU - Koeck, R. M.
AU - Essers, R.
AU - van Dijk, W.
AU - Drusedau, M.
AU - Meekels, J.
AU - Yaldiz, B.
AU - van de Vorst, M.
AU - Cao, P.
AU - de Koning, B.
AU - Hellebrekers, D. M. E. I.
AU - Stevens, S. J. C.
AU - Sun, S. M.
AU - Heijligers, M.
AU - de Munnik, S. A.
AU - van Uum, C. M. J.
AU - Achten, J.
AU - Hamers, L.
AU - Naghdi, M.
AU - Vissers, L. E. L. M.
AU - van Golde, R. J. T.
AU - de Wert, G.
AU - Dreesen, J. C. F. M.
AU - de Die-Smulders, C.
AU - Coonen, E.
AU - Brunner, H. G.
AU - van den Wijngaard, A.
AU - Paulussen, A. D. C.
AU - Zamani Esteki, M.
PY - 2023/12/8
Y1 - 2023/12/8
N2 - High-throughput sequencing technologies have increasingly led to discovery of disease-causing genetic variants, primarily in postnatal multi-cell DNA samples. However, applying these technologies to preimplantation genetic testing (PGT) in nuclear or mitochondrial DNA from single or few-cells biopsied from in vitro fertilised (IVF) embryos is challenging. PGT aims to select IVF embryos without genetic abnormalities. Although genotyping-by-sequencing (GBS)-based haplotyping methods enabled PGT for monogenic disorders (PGT-M), structural rearrangements (PGT-SR), and aneuploidies (PGT-A), they are labour intensive, only partially cover the genome and are troublesome for difficult loci and consanguineous couples. Here, we devised a simple, scalable and universal whole genome sequencing haplarithmisis-based approach enabling all forms of PGT in a single assay. In a comparison to state-of-the-art GBS-based PGT for nuclear DNA (37 embryos, 18 families, 25 indications), shallow sequencing-based PGT (10 embryos, 3 families), and PCR-based PGT for mitochondrial DNA (10 embryos, 2 families), our approach alleviates technical limitations by decreasing whole genome amplification artifacts by 68.4%, increasing breadth of coverage by 4-fold, and reducing wet-lab turn-around-time by 2.5-fold. Importantly, this method enables trio-based PGT-A for aneuploidy origin, an approach we coin PGT-AO, detects translocation breakpoints, and nuclear and mitochondrial single nucleotide variants and indels in base-resolution.
AB - High-throughput sequencing technologies have increasingly led to discovery of disease-causing genetic variants, primarily in postnatal multi-cell DNA samples. However, applying these technologies to preimplantation genetic testing (PGT) in nuclear or mitochondrial DNA from single or few-cells biopsied from in vitro fertilised (IVF) embryos is challenging. PGT aims to select IVF embryos without genetic abnormalities. Although genotyping-by-sequencing (GBS)-based haplotyping methods enabled PGT for monogenic disorders (PGT-M), structural rearrangements (PGT-SR), and aneuploidies (PGT-A), they are labour intensive, only partially cover the genome and are troublesome for difficult loci and consanguineous couples. Here, we devised a simple, scalable and universal whole genome sequencing haplarithmisis-based approach enabling all forms of PGT in a single assay. In a comparison to state-of-the-art GBS-based PGT for nuclear DNA (37 embryos, 18 families, 25 indications), shallow sequencing-based PGT (10 embryos, 3 families), and PCR-based PGT for mitochondrial DNA (10 embryos, 2 families), our approach alleviates technical limitations by decreasing whole genome amplification artifacts by 68.4%, increasing breadth of coverage by 4-fold, and reducing wet-lab turn-around-time by 2.5-fold. Importantly, this method enables trio-based PGT-A for aneuploidy origin, an approach we coin PGT-AO, detects translocation breakpoints, and nuclear and mitochondrial single nucleotide variants and indels in base-resolution.
KW - genetic and genomic medicine
U2 - 10.1101/2023.12.06.23299605
DO - 10.1101/2023.12.06.23299605
M3 - Preprint
BT - Clinical-grade whole genome sequencing-based haplarithmisis enables all forms of preimplantation genetic testing
ER -