Elevated levels of total (maternal and fetal) beta-globin DNA in maternal blood from first trimester pregnancies with trisomy 21.

BACKGROUND: Elevated levels of circulating fetal DNA have been observed in maternal plasma when a trisomy 21 fetus is confirmed. However, these studies have been limited to pregnancies carrying a male fetus. We sought to quantify total (fetal and maternal) DNA from dried blood spots (DBS) for use as an additional factor in multi-parameter prenatal screening for aneuploidy. METHODS: Maternal DBS were obtained from the NICHD-sponsored multi-center cohort (BUN) study. Seventeen confirmed trisomy 21 (mean gestational age 12.23 +/- 0.77 weeks) cases were each matched by gestational age to euploid controls (n = 30). DNA was extracted and quantitative PCR was performed to measure four non-chromosome 21 loci, including glyceraldehyde-3-phosphate dehydrogenase (GAPDH) (12p13), beta-globin (11p15.5), beta-actin (7p15-12) and p53 (17p13.1). RESULTS: Beta-globin DNA levels were significantly elevated (P = 0.003) in 13 of 17 trisomy 21 cases (4.08 +/- 1.78 Geq/ml x 10(5)) compared with matched controls (2.35 +/- 1.84 Geq/ml x 10(5)). Following conversion of beta-globin concentrations into multiples of the median (MoM), MoM for trisomy 21 cases was 2.8 compared with 1.0 in euploid cases. No significant differences in levels of circulating GAPDH, beta-actin and p53 sequences were detected. CONCLUSIONS: This work demonstrates differential levels of circulating beta-globin DNA in maternal blood of euploid and trisomy 21 cases. Sequence-specific quantification could provide an additional measure to improve non-invasive methods of prenatal screening to detect trisomy 21 using dried blood. Beta-globin in particular is an attractive biomarker that could contribute to enhance multiple serum parameter testing in the first trimester.

Quantity versus quality: optimal methods for cell-free DNA isolation from plasma of pregnant women.

PURPOSE: Methods to isolate cell-free fetal DNA from maternal plasma are critical in developing noninvasive fetal DNA testing strategies. Given that plasma consists of heterogeneous DNA-size fragments in a complex mix of proteins, recovery and analysis of this DNA are understandably inefficient. To facilitate recovery, we performed qualitative and quantitative analysis of DNA isolated from maternal plasma. METHODS: DNA isolated from maternal blood (n = 15) was compared using five different DNA isolation protocols: two conventional, two column-based, and one magnetic-bead based. Purity and concentration of DNA recovered were determined with a NanoDrop spectrophotometer. Real-time polymerase chain reaction quantification of the beta-globin and DYS1 loci was performed to determine total and fetal-specific genome equivalents, respectively. RESULTS: DNA quality and quantity were different among the five methods tested. Although purity and concentration of total DNA were greatest with the conventional boiling-lysis approach, correct detection of a male fetus was achieved in only 62.5% of cases. DNA isolation using the magnetic beads yielded the highest quantity of total DNA (2018.83 +/- 4.09 GEq/mL), with 100% fetal DNA detection. CONCLUSIONS: Optimal plasma DNA recovery protocols must take into account DNA purity and concentration. We confirm that the magnetic-beads method provides a fast, simple, sensitive, and specific approach to purify plasma DNA. The resulting high-quality DNA facilitates efficient examination of fetal DNA sequences.

Cell-free fetal DNA and intact fetal cells in maternal blood circulation: implications for first and second trimester non-invasive prenatal diagnosis.

Both intact fetal cells as well as cell-free fetal DNA are present in the maternal circulation and can be recovered for non-invasive prenatal genetic diagnosis. Although methods for enrichment and isolation of rare intact fetal cells have been challenging, diagnosis of fetal chromosomal aneuploidy including trisomy 21 in first- and second-trimester pregnancies has been achieved with a 50-75% detection rate. Similarly, cell-free fetal DNA can be reliably recovered from maternal plasma and assessed by quantitative PCR to detect fetal trisomy 21 and paternally derived single gene mutations. Real-time PCR assays are robust in detecting low-level fetal DNA concentrations, with sensitivity of approximately 95-100% and specificity near 100%. Comparing intact fetal cell versus cell-free fetal DNA methods for non-invasive prenatal screening for fetal chromosomal aneuploidy reveals that the latter is at least four times more sensitive. These preliminary results do not support a relationship between frequency of intact fetal cells and concentration of cell-free fetal DNA. The above results imply that the concentration of fetal DNA in maternal plasma may not be dependent on circulating intact fetal cells but rather be a product of growth and cellular turnover during embryonic or fetal development.