Katharina Spath1, Dhruti Babariya2, Michalis Konstantinidis3, Jo Lowndes4, Tim Child5, James A Grifo6, Joanna Poulton7, Dagan Wells2. 1. Nuffield Department of Women's and Reproductive Health, University of Oxford, Oxford, United Kingdom; Juno Genetics, Oxford, United Kingdom. Electronic address: Katharina.spath@junogenetics.com. 2. Nuffield Department of Women's and Reproductive Health, University of Oxford, Oxford, United Kingdom; Juno Genetics, Oxford, United Kingdom. 3. CooperGenomics, Livingston, New Jersey. 4. Oxford Centre for Genomic Medicine, Oxford University Hospitals NHS Foundation Trust, Nuffield Orthopaedic Centre, Oxford, United Kingdom. 5. Nuffield Department of Women's and Reproductive Health, University of Oxford, Oxford, United Kingdom; Oxford Fertility, Fertility Partnership, Oxford, United Kingdom. 6. NYU Fertility Center, New York, New York. 7. Nuffield Department of Women's and Reproductive Health, University of Oxford, Oxford, United Kingdom.
Abstract
OBJECTIVE: To validate and apply a strategy permitting parallel preimplantation genetic testing (PGT) for mitochondrial DNA (mtDNA) disease and aneuploidy (PGT-A). DESIGN: Preclinical test validation and case reports. SETTING: Fertility centers. Diagnostics laboratory. PATIENTS: Four patients at risk of transmitting mtDNA disease caused by m.8993T>G (Patients A and B), m.10191T>G (Patient C), and m.3243A>G (Patient D). Patients A, B, and C had affected children. Patients A and D displayed somatic heteroplasmy for mtDNA mutations. INTERVENTIONS: Embryo biopsy, genetic testing, and uterine transfer of embryos predicted to be euploid and mutation-free. MAIN OUTCOME MEASURES: Test accuracy, treatment outcomes, and mutation segregation. RESULTS: Accuracy of mtDNA mutation quantification was confirmed. The test was compatible with PGT-A, and half of the embryos tested were shown to be aneuploid (16/33). Mutations were detected in approximately 40% of embryo biopsies from Patients A and D (10/24) but in none from Patients B and C (n = 29). Patients B and C had healthy children following PGT and natural conception, respectively. The m.8993T>G mutation displayed skewed segregation, whereas m.3243A>G mutation levels were relatively low and potentially impacted embryo development. CONCLUSIONS: Considering the high aneuploidy rate, strategies providing a combination of PGT for mtDNA disease and aneuploidy may be advantageous compared with approaches that consider only mtDNA. Heteroplasmic women had a higher incidence of affected embryos than those with undetectable somatic mutant mtDNA but were still able to produce mutation-free embryos. While not conclusive, the results are consistent with the existence of mutation-specific segregation mechanisms occurring during oogenesis and possibly embryogenesis.
OBJECTIVE: To validate and apply a strategy permitting parallel preimplantation genetic testing (PGT) for mitochondrial DNA (mtDNA) disease and aneuploidy (PGT-A). DESIGN: Preclinical test validation and case reports. SETTING: Fertility centers. Diagnostics laboratory. PATIENTS: Four patients at risk of transmitting mtDNA disease caused by m.8993T>G (Patients A and B), m.10191T>G (Patient C), and m.3243A>G (Patient D). Patients A, B, and C had affected children. Patients A and D displayed somatic heteroplasmy for mtDNA mutations. INTERVENTIONS: Embryo biopsy, genetic testing, and uterine transfer of embryos predicted to be euploid and mutation-free. MAIN OUTCOME MEASURES: Test accuracy, treatment outcomes, and mutation segregation. RESULTS: Accuracy of mtDNA mutation quantification was confirmed. The test was compatible with PGT-A, and half of the embryos tested were shown to be aneuploid (16/33). Mutations were detected in approximately 40% of embryo biopsies from Patients A and D (10/24) but in none from Patients B and C (n = 29). Patients B and C had healthy children following PGT and natural conception, respectively. The m.8993T>G mutation displayed skewed segregation, whereas m.3243A>G mutation levels were relatively low and potentially impacted embryo development. CONCLUSIONS: Considering the high aneuploidy rate, strategies providing a combination of PGT for mtDNA disease and aneuploidy may be advantageous compared with approaches that consider only mtDNA. Heteroplasmic women had a higher incidence of affected embryos than those with undetectable somatic mutant mtDNA but were still able to produce mutation-free embryos. While not conclusive, the results are consistent with the existence of mutation-specific segregation mechanisms occurring during oogenesis and possibly embryogenesis.
Authors: Marina Di Domenico; Andrea Ballini; Mariarosaria Boccellino; Salvatore Scacco; Roberto Lovero; Ioannis Alexandros Charitos; Luigi Santacroce Journal: J Pers Med Date: 2022-03-24