Novel applications of polymerase chain reaction to urinary nucleic acid analysis.

DNA fragments from cells that have died throughout the body not only appear in the bloodstream but also cross the kidney barrier into the urine. The relatively low molecular weight (150-200 bp) of this Transrenal DNA should be considered when deciding on methods of isolation and analysis. In particular, if polymerase chain reaction (PCR) is used for amplification and detection of specific sequences, then the reduction of amplicon size will significantly enhance sensitivity. Detection of DNA mutations is also made more difficult by the presence of a large excess of a wild-type allele. Using K-RAS mutations as an example, two ways around this problem--enriched PCR and stencil-aided mutation analysis-are described, based on selective pre-PCR elimination of wild-type sequences.

Transrenal DNA testing: progress and perspectives.

Transrenal DNA (Tr-DNA) is a recently discovered class of extracellular urinary DNA that originates from cells dying throughout the body. Postapoptotic DNA is known to appear in the circulating plasma, but it is now recognized that a portion of these fragments cross the kidney barrier and appear in urine in the form of 150-200-bp fragments. Tr-DNA containing fetal sequences has been isolated from the urine of pregnant women, tumor-specific mutations have been detected in Tr-DNA from patients with colon and pancreatic tumors, and donor DNA has been found in Tr-DNA isolated from recipient urine. Furthermore, proviral HIV DNA, bacterial and parasite DNA sequences have been detected in Tr-DNA from infected patients. Potential applications of Tr-DNA-based tests cover a very broad area of molecular diagnostics and genetic testing, including prenatal detection of inherited diseases, tumor diagnostics and therapeutic monitoring and detection of infectious agents. The Tr-DNA test is expected to have utility in treatment monitoring, transplantation monitoring, drug development and broad public health screening, where a noninvasive, common-platform diagnostic technology has particular value. This review describes some of the highlights of Tr-DNA technology applications, advantages over existing technologies and potential problems anticipated in test development.

Transrenal DNA as a diagnostic tool: important technical notes.

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.

Apoptosis in the myocardium: much is still expected.

Apoptosis continues to be a controversial concept and subject of debate among scientists regarding its value as the basis for new therapeutic strategies. Today, it is widely accepted that the death of cardiac myocytes under a variety of conditions appears to be apoptotic based on a variety of criteria. However, the significance of these observations and how the insights into apoptotic molecular pathways may provide novel therapeutic targets remains to be determined. It is important to reconsider the pertinent underlying mechanisms of apoptosis regulation, and how these molecular pathways may be viewed in the functioning, intact heart. This knowledge can be applied in pursuit of practical goals in a search for new ways to prevent myocardial damage following such injuries as ischaemia/reperfusion or exposure to cardiotoxic drugs. Although recent literature contains reports of positive findings, there has not yet been a rigorous application of the model of apoptosis in the myocardium, and the potential for development of new therapeutic strategies is not yet understood.