Non-invasive prenatal diagnosis of fetal trisomy 21 using cell-free fetal DNA in maternal blood

Evaluation of extraction methods for methylated cell-free fetal DNA from maternal plasma

PURPOSE

Recently, fetal placenta-specific epigenetic regions (FSERs) have been identified for quantification of cell-free fetal DNA (cff-DNA) for non-invasive prenatal testing (NIPT). The aim of this study was to evaluate the efficiencies of a column-based kit and magnetic bead-based kit for quantification of methylated FSERs from maternal plasma.

METHODS

Maternal plasma was extracted from normal pregnant women within the gestational age of 10~13 weeks (n = 24). Total cell-free DNA (cf-DNA) was extracted using a column-based kit and magnetic bead-based kit from the plasma of the same pregnant woman, respectively. Methylated FSERs were enriched from the extracted total cf-DNA using a methyl-CpG-binding domain-based protein method. The four FSERs were simultaneously quantified by multiplex real-time polymerase chain reaction.

RESULTS

Methylated FSERs were detected in all samples extracted from both kits. However, the amplification of FSERs showed significant differences in the extraction efficiency of methylated FSERs between the two extraction methods. The Ct values of methylated FSERs extracted using the column-based kit were significantly lower than those obtained using the magnetic bead-based kit (P < 0.001 for all FSERs). The quantity of methylated FSERs was significantly higher for extracted DNA using the column-based kit than that extracted using the magnetic bead-based kit (P < 0.001 for all FSERs). Time and cost for the process of extraction were similar for the column kit and magnetic bead-based kit.

CONCLUSIONS

Our findings demonstrate that the column-based kit was more effective than the magnetic bead-based kit for isolation of methylated FSERs from maternal plasma as assessed by FSER detection.

Combined detection of α-fetoprotein and free β-human chorionic gonadotropin in screening for trisomy 21 and management of cases in the moderate risk value range

Down syndrome is the most common cause of prenatal chromosomal abnormalities, and prenatal serum screening is an effective method for decreasing the birth prevalence of children with Down syndrome. The aim of the present study was to observe the effect of duplex screening and investigate the treatment of cases under specific conditions. The medians of free β-human chorionic gonadotropin (HCG) and α-fetoprotein (AFP) were calculated and compared with those embedded in the 2T software. The detection and false-positive rates were analyzed under different conditions, and the distribution of Down syndrome cases was investigated in different risk ranges. Finally, suitable recommendations for further diagnostic investigation were provided according to the status of each individual. The medians of free β-HCG and AFP were found to differ from the corresponding medians embedded in the 2T software (P<0.01), and on the basis of a 5% false-positive rate, the detection rate would increase from 63.6 to 67.8% when compared with medians embedded in the 2T software, indicating we should establish our own medians of free β-HCG and AFP. In addition, residual cases (risk value <1/300) with relevant Down syndrome indications mainly concentrated at risk values between 1/1,000 and 1/300, and partial residual screening cases were verified through diverse methods. These findings indicated that different laboratories should establish their own medians; furthermore, what is classed as moderate risk is extremely important in screening for Down syndrome and reasonable recommendations may be offered under different conditions.

A Pilot Study of Noninvasive Prenatal Diagnosis of Alpha- and Beta-Thalassemia with Target Capture Sequencing of Cell-Free Fetal DNA in Maternal Blood

AIMS

Thalassemia is a dangerous hematolytic genetic disease. In south China, ∼24% Chinese carry alpha-thalassemia or beta-thalassemia gene mutations. Given the fact that the invasive sampling procedures can only be performed by professionals in experienced centers, it may increase the risk of miscarriage or infection. Thus, most people are worried about the invasive operation. As such, a noninvasive and accurate prenatal diagnosis is needed for appropriate genetic counseling for families with high risks. Here we sought to develop capture probes and their companion analysis methods for the noninvasive prenatal detection of deletional and nondeletional thalassemia.

MATERIALS AND METHODS

Two families diagnosed as carriers of either beta-thalassemia gene or Southeast Asian deletional alpha-thalassemia gene mutation were recruited. The maternal plasma and amniotic fluid were collected for prenatal diagnosis. Probes targeting exons of the genes of interest and the highly heterozygous SNPs within the 1Mb flanking region were designed. The target capture sequencing was performed with plasma DNA from the pregnant woman and genomic DNA from the couples and their children. Then the parental haplotype was constructed by the trios-based strategy. The fetal haplotype was deduced from the parental haplotype with a hidden Markov model-based algorithm.

RESULTS

The fetal genotypes were successfully deduced in both families noninvasively. The noninvasively constructed haplotypes of both fetuses were identical to the invasive prenatal diagnosis results with an accuracy rate of 100% in the target region.

CONCLUSION

Our study demonstrates that the effective noninvasive prenatal diagnosis of alpha-thalassemia and beta-thalassemia can be achieved with the targeted capture sequencing and the haplotype-assisted analysis method.

MeDIP Real-Time qPCR has the Potential for Noninvasive Prenatal Screening of Fetal Trisomy 21

This study aimed to verify the reliability of the 7 tissue differentially methylated regions used in the methylated DNA immunoprecipitation (MeDIP) real- time quantitative polymerase chain reaction (real-time qPCR) based approach of fetal DNA in maternal blood to diagnosis of fetal trisomy 21. Forty pregnant women with high risk pregnancy who were referred after first or second trimester screening tests, were selected randomly. For each sample whole DNA extraction (mother and fetus), fragmentation of DNA, immunoprecipitation of methylated DNA and real- time qPCR using 7 primer pairs was performed. D-value for each sample was calculated using the following formula D = -4.908+ 0.254 X_EP1+ 0.409 X_EP4+ 0.793 X_EP5+ 0.324 X_EP6+ 0.505 X_EP7+ 0.508 X_EP9+ 0.691 X_EP12. In all normal cases, D value was negative, while it was positive in all trisomy cases. Therefore, all normal and trisomy 21 cases were classified correctly which correspond to 100% specificity and 100% sensitivity for this method. The MeDIP real-time qPCR method has provided the opportunity for noninvasive prenatal diagnosis of fetal trisomy 21 to be potentially employed into the routine practice of diagnostic laboratories.

Novel Epigenetic Markers on Chromosome 21 for Noninvasive Prenatal Testing of Fetal Trisomy 21

Until now, fetal placenta-specific epigenetic markers for noninvasive prenatal testing of fetal trisomy 21 (T21) have been identified based only on differences in tissue-specific epigenetic characteristics between placenta and maternal blood, but these characteristics have not been validated in T21 placenta. We aimed to discover novel epigenetic markers on chromosome 21 that show a hypermethylated pattern in fetal placenta compared with blood, regardless of the presence of T21. We performed a high-resolution tiling array analysis of chromosome 21 using the methylated-CpG binding domain protein-based method. We identified 93 epigenetic regions that showed fetal placenta-specific differential methylation patterns; among these, three regions showed fetal placenta-specific methylation patterns in T21 placenta samples. The methylation patterns of these three regions in the array were confirmed by bisulfite direct sequencing. The three regions were detectable in first-trimester maternal plasma. Moreover, a combination of their methylation ratio achieved high diagnostic accuracy for noninvasive prenatal testing of fetal T21 by further statistical analysis. These three novel regions with fetal placenta-specific differential methylation patterns on chromosome 21 were identified irrespective of the presence of T21. Our findings suggest that epigenetic characteristics of markers according to the presence or absence of T21 should be considered in the development of noninvasive prenatal testing of fetal T21 using fetal placenta-specific epigenetic markers.

Disease specific characteristics of fetal epigenetic markers for non-invasive prenatal testing of trisomy 21

Background

Non-invasive prenatal testing of trisomy 21 (T21) is being actively investigated using fetal-specific epigenetic markers (EPs) that are present in maternal plasma. Recently, 12 EPs on chromosome 21 were identified based on tissue-specific epigenetic characteristics between placenta and blood, and demonstrated excellent clinical performance in the non-invasive detection of fetal T21. However, the disease-specific epigenetic characteristics of the EPs have not been established. Therefore, we validated the disease-specific epigenetic characteristics of these EPs for use in non-invasive detection of fetal T21.

Methods

We performed a high-resolution tiling array analysis of human chromosome 21 using a methyl-CpG binding domain-based protein (MBD) method with whole blood samples from non-pregnant normal women, whole blood samples from pregnant normal women, placenta samples of normal fetuses, and placenta samples of T21 fetuses. Tiling array results were validated by bisulfite direct sequencing and qPCR.

Results

Among 12 EPs, only four EPs were confirmed to be hypermethylated in normal placenta and hypomethylated in blood. One of these four showed a severe discrepancy in the methylation patterns of T21 placenta samples, and another was located within a region of copy number variations. Thus, two EPs were confirmed to be potential fetal-specific markers based on their disease-specific epigenetic characteristics. The array results of these EPs were consisted with the results obtained by bisulfite direct sequencing and qPCR. Moreover, the two EPs were detected in maternal plasma.

Conclusions

We validated that two EPs have the potential to be fetal-specific EPs which is consistent with their disease-specific epigenetic characteristics. The findings of this study suggest that disease-specific epigenetic characteristics should be considered in the development of fetal-specific EPs for non-invasive prenatal testing of T21.