A real-time PCR assay for DNA-methylation using methylation-specific blockers.

DNA methylation-based biomarkers have been discovered that could potentially be used for the diagnosis of cancer by detection of circulating, tumor-derived DNA in bodily fluids. Any methylation detection assay that would be applied to these samples must be capable of detecting small amounts of tumor DNA in the presence of background normal DNA. We have developed a real-time PCR assay, called HeavyMethyl, that is well suited for this application. HeavyMethyl uses methylation-specific oligonucleotide blockers and a methylation-specific probe to achieve methylation-specific amplification and detection. We tested the assays on unmethylated and artificially methylated DNA in order to determine the limit of detection. After careful optimization, our glutathione-S-transferase pi1 and Calcitonin assays can amplify as little as 30 and 60 pg of methylated DNA, respectively, and neither assay amplifies unmethylated DNA. The Calcitonin assay showed a highly significant methylation difference between normal colon and colon adenocarcinomas, and methylation was also detected in serum DNA from colon cancer patients. These assays show that HeavyMethyl technology can be successfully employed for the analysis of very low concentrations of methylated DNA, e.g. in serum of patients with tumors.

Effects of benzo[a]pyrene DNA adducts on Escherichia coli DNA polymerase I (Klenow fragment) primer-template interactions: evidence for inhibition of the catalytically active ternary complex formation.

Benzo[a]pyrene diol epoxide (B[a]PDE) adducts are strong blocks of DNA replication in vitro, allowing the rare incorporation of a nucleotide across from the lesion and negligibly small extent of further bypass. To study the mechanistic details of this process, a gel-retardation assay was used to measure the dissociation constants for the binding of DNA polymerase I (Klenow fragment) (KF) to the primer-templates containing a (+)-trans- or (+)-cis-B[a]P-N(2)-dG adduct. When the primer was terminated one nucleotide before the adduct, the presence of a (+)-trans-B[a]P-N(2)-dG adduct did not affect the binding while a (+)-cis-B[a]P-N(2)-dG adduct caused a slight decrease in affinity. The presence of any dNTP decreased the affinity of KF to the modified primer-templates. (In contrast, a strong increase of the affinity to unmodified primer-templates was observed in the presence of the next correct dNTP.) Limited protease digestion experiments indicated that a closed ternary complex of KF with the modified primer-templates was not detectable in the presence of any dNTP, whereas it was clearly observed with unmodified template in the presence of the next correct nucleotide. These findings suggest that these adducts may interfere with the conformational change to the catalytically active closed ternary complex and/or cause significant destabilization of this complex. When the primers extended to the position across from the adduct, the affinity of KF was significantly decreased irrespective of the identity of the base across from the adduct, possibly explaining the low bypass of the lesion. Interestingly, the stability of these DNA-polymerase complexes correlated with nucleotide insertion kinetics for the unmodified and (+)-trans-B[a]PDE-modified templates.

Polyamide nucleic acid targeted to the primer binding site of the HIV-1 RNA genome blocks in vitro HIV-1 reverse transcription.

We report here that polyamide nucleic acid (PNA) as well as a polyamide nucleic acid-DNA chimera complementary to the primer binding site of the HIV-1 genome can completely block priming by tRNA3Lys and consequently the in vitro initiation of reverse transcription by HIV-1 RT. Conventional heating and cooling is not required for annealing PNA analogs to the complementary nucleotide sequence as effective blockage of reverse transcription results from their invasion in the duplex region of preprimed U5-PBS HIV-1 RNA template-primer and was seen even at ambient temperature. Further, the extension of the initiated nascent (-) strand DNA can also be blocked by inclusion of another PNA, targeted to upstream sequences in the U5 region of the viral RNA. Interestingly, a PNA chimera having only two DNA nucleotides annealed with the U5-PBS RNA is recognized as a bonafide primer by HIV-1 RT, as the 3'OH end of the chimeric molecule is extended by the enzyme in the presence of dNTPs. A significant observation was that RNA/PNA or RNA/(PNA-DNA) hybrids were entirely resistant to the RNase H activity of HIV-1 RT. Furthermore, PNA invasion into the RNA/DNA hybrid completely prevented the cleavage of the RNA strand, suggesting that the RNase H activity of HIV-1 RT which was required in reverse transcription may also be inhibited by the PNA oligomer. These observations suggest that oligomeric PNAs targeted to various critical regions of the viral genome are likely to have strong therapeutic potential for interrupting multiple steps involved in the replication of HIV-1 and warrant serious investigation especially in the area of an effective delivery system.