Objective: To establish a method for noninvasive fetal cell isolation from maternal blood and prenatal testing of monogenic diseases by a combination of direct sequencing and targeted NGS-based SNP haplotyping from single fetal cells.
Method: Peripheral blood of pregnant women in two families (congenital deafness and ichthyosis) was collected. After density-based separation and immunostaining with multiple biomarkers, candidate fetal cells were identified by high-throughput imagine analysis and picked up by automation. Individual fetal cells were subjected to STR-genotyping to identify their origin. Pathogenic mutations were identified by direct Sanger sequencing, and a combination of targeted NGS and SNP haplotyping using a custom panel. All the results were compared with amniotic fluid DNA.
Results: Fetal trophoblasts were successfully harvested from maternal blood. STR-genotyping confirmed the fetal origin. Direct sequencing of pathogenic genetic mutations in fetal cells showed consistent results with amniotic fluid samples. For congenital deafness family, NGS-based SNP haplotyping also correctly identified the fetal haplotype. This single cell haplotyping method can be used to diagnose various genetic diseases.
Conclusion: We have established a method for noninvasive prenatal testing of monogenic diseases from circulating trophoblast cells. This cell-based NIPT can be further applied to the prenatal diagnosis of various monogenic diseases.
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