Background: Cell-free DNA from dying cells recently has been discovered in human blood plasma. In experiments performed on animals and humans, we examined whether this cell-free DNA can cross the kidney barrier and be used as a diagnostic tool.
Methods: Mice received subcutaneous injections of either human Raji cells or purified 32P-labeled DNA. DNA was isolated from urine and analyzed by measurement of radioactivity, agarose gel electrophoresis, and PCR. In humans, the permeability of the kidney barrier to polymeric DNA was assessed by detection in urine of sequences that were different from an organism bulk nuclear DNA.
Results: In the experiments on laboratory animals, we found that ∼0.06% of injected DNA was excreted into urine within 3 days in a polymeric form and that human-specific Alu sequences that passed through the kidneys could be amplified by PCR. In humans, male-specific sequences could be detected in the urine of females who had been transfused with male blood as well as in DNA isolated from urine of women pregnant with male fetuses. K-ras mutations were detected in the urine of patients with colon adenocarcinomas and pancreatic carcinomas.
Conclusions: The data suggest that the kidney barrier in rodents and humans is permeable to DNA molecules large enough to be analyzed by standard genetic methodologies.
It is well documented that plasma contains DNA from tissues throughout the body, including developing fetuses, and tumors. A portion of this DNA crosses the kidney barrier and appears in urine (i.e., transrenal DNA). However, molecular, cellular, and physiological mechanisms of the circulating DNA phenomenon and renal clearance are in an early phase of investigation. Here, we discuss possible forms of circulating DNA, factors affecting representation of different tissues and genomic sequences in plasma DNA, possible mechanisms of renal DNA clearance, and technical problems encountered in DNA isolation from urine. We suggest that apoptotic cells are an important source of DNA in both plasma and urine. Further analysis of the data has led us to propose that a significant portion of circulating DNA can be represented in apoptotic bodies.
A small portion of DNA from apoptotic cells escapes complete degradation, appears in blood as oligonucleosomal-size fragments, is excreted in the urine, and can be used for diagnostic purposes. More detailed study revealed that transrenal DNA (Tr-DNA) belongs to a relatively low molecular-weight (150-250 bp) fraction, thereby requiring more careful attention to methods employed for purification and analysis. For example, here it is demonstrated that the QIAamp blood kit purifies primarily high molecular-weight DNA from serum, whereas the Guanidine/Promega Wizard Resin (GITC/WR) method purifies primarily low molecular-weight DNA. As a result, sensitivity in detection of K-RAS mutations in serum of patients with colorectal tumors is significantly higher with DNA isolated with the GITC/WR method than with the QIAamp kit. Amplicon size is also extremely important in analysis of Tr-DNA, because the shorter the amplicon, the higher is the sensitivity of biomarker detection in Tr-DNA. One hundred fifty-seven and 87 bp amplicons were employed for detection of mutant K-RAS in DNA isolated from 0.1 mL of urine obtained from 15 patients with pancreatic cancer. Mutant K-RAS was found in Tr-DNA of 3 and 10 patients with the long and short amplicons, respectively. The sensitivity and specificity of detection of mutant sequences are reduced in the presence of high excess of a respective wild-type allele, but they can be significantly increased through application of enriched polymerase chain reaction (PCR), peptide nucleic acid (PNA) clamped PCR, and/or stencil-aided mutation analysis (SAMA), based on selective pre-PCR elimination of wild-type sequences.
Isotachophoresis is an electrophoretic method of separation of charged substances. The method is characterized by a discontinuous buffer system, constant velocity of separated molecules, and the distribution of separated components in the form of narrow concentrated bands located one right after another. As a rule, isotachophoresis is not used for the separation of nucleic acids because the mobility of polynucleotides in this system does not depend on their size. However, this circumstance proved to be very useful for the quantitative isolation of heterogeneous DNA fragments from biological fluids, for gene diagnostics of cancer in particular. The proposed method of agarose gel isotachophoresis of DNA has been used for the isolation of blood DNA and its successful PCR analysis.
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