Noninvasive Prenatal Diagnosis by Targeted Massively Parallel Sequencing of Maternal Plasma

The presence of fetal DNA in the cell-free plasma of pregnant women was first reported in 1997. This discovery has facilitated the development of noninvasive prenatal diagnosis. The coexistence in maternal plasma of a minor population of fetal DNA among a major background of maternal DNA has posed challenges for extending noninvasive prenatal diagnostic applications that require analytical information beyond the detection of fetus-specific DNA sequences. The recent availability of massively parallel sequencing has enhanced the precision of DNA quantification to an unprecedented level. Our group has demonstrated the application of massively parallel sequencing in noninvasive prenatal diagnosis of chromosomal aneuploidies, as well as genome-wide fetal whole genome sequencing and mutational profiling. While the current costs of massively parallel sequencing are relatively expensive, targeted massively parallel sequencing may enhance the cost-effectiveness compared with the non-targeted approach because it increases the proportion of informative data from the regions-of-interest.;In the first part of this thesis, I have demonstrated the feasibility of targeted massively parallel sequencing in maternal plasma DNA. In this proof-of-principle study, hybridization-based target enrichment was used to enrich exons on chromosome X. Plasma DNA libraries with and without target enrichment were analyzed by massively parallel sequencing. For the targeted regions, the mean sequencing depth of the enriched samples was 213-fold higher than that of the non-enriched samples. Maternal and fetal DNA molecules were enriched to similar extents within the targeted regions. With target enrichment, the detection rate of fetus-specific alleles within the targeted regions increased from 3.5% to 95.9%.;In the second part of this thesis, I have demonstrated the potential application of targeted massively parallel sequencing of plasma DNA for noninvasive prenatal diagnosis of trisomy 21 using an allelic ratio approach. Targeted sequencing was used to enrich single nucleotide polymorphism loci on chr7, chr13, chr18 and chr21. The targeted sequencing data showed that the ratio between fetus-specific and shared alleles increased by approximately 2-fold on chr21 in a paternally-derived trisomy 21 case, and decreased by approximately 11% on chr21 for maternally-derived trisomy 21 cases. I have also used computer simulation to determine the impact of fractional fetal DNA concentration, number of informative alleles and sequencing depth on the detection accuracy.;In the third part of this thesis, I have demonstrated the feasibility of targeted massively parallel sequencing of maternal plasma DNA for noninvasive prenatal diagnosis of monogenic diseases. Targeted sequencing was used to enrich the beta-globin gene region in two families undergoing prenatal diagnosis for beta-thalassemia. Parental haplotypes of the beta-globin gene region were deduced via digital polymerase chain reaction. Relative haplotype dosage analysis was performed successfully to determine the beta-thalassemic status for the fetuses, including one family in which the parents had similar haplotype structures in the disease-causing region.