Transcription through a simple DNA repeat blocks replication elongation.

The influence of d(G)n.d(C)n repeats on plasmid replication in Escherichia coli cells was analyzed using electrophoretic analysis of replication intermediates. These repeats impeded the replication fork in a length- and orientation-dependent manner. Unexpectedly, the replication arrest relied primarily on the repeats' transcription. When the d(C)n sequence served as the transcriptional template, both transcription and replication were blocked. This was true for transcription driven by either bacterial or phage RNA polymerases. We hypothesize that the replication fork halts after it encounters a stalled ternary complex of the RNA polymerase, the DNA template and the r(G)n transcript. This constitutes a novel mechanism for the regulation of replication elongation. The effects of this mechanism on repeat length polymorphism and genome rearrangements are discussed.

Trinucleotide repeats affect DNA replication in vivo.

(CGG)n.(CCG)n and (CTG)n.(CAG)n repeats of varying length were cloned into a bacterial plasmid, and the progression of the replication fork through these repeats was followed using electrophoretic analysis of replication intermediates. We observed stalling of the replication fork within repeated DNAs and found that this effect depends on repeat length, repeat orientation relative to the replication origin and the status of protein synthesis in a cell. Interruptions within repeated DNAs, similar to those observed in human genes, abolished the replication blockage. Our results suggest that the formation of unusual DNA structures by trinucleotide repeats in the lagging-strand template may account for the observed replication blockage and have relevance to repeat expansion in humans.

Mechanisms of triplex-caused polymerization arrest.

Pyrimidine/purine/purine triplexes are known to inhibit DNA polymerization. Here we have studied the mechanisms of this inhibition by comparing the efficiency of Vent DNA polymerase on triplex- and duplex-containing templates at different temperatures, Mg2+concentrations and time intervals with the thermal stability of the corresponding structures. Our results show that triplexes can only be by-passed at temperatures where thermal denaturation initiates, while duplexes, in contrast, are overcome at temperatures where they are quite stable. These results show that DNA polymerase cannot untangle triplex regions within DNA templates and seems to entirely depend on their thermal fluctuations. The high stability of triplexes at physiological temperatures and ambient conditions make them a barrier to polymerization.

Trapping DNA polymerases using triplex-forming oligodeoxyribonucleotides.

Triplexes (triple helices) formed within DNA templates prior to or during DNA synthesis cause DNA polymerase to terminate [Samadashwily et al., EMBO J. 13 (1993) 4975-4983]. Here, we show that triplex-forming oligodeoxyribonucleotides (oligos) efficiently trap DNA polymerases at target DNA sequences within single-stranded (ss) templates. This was observed for all studied DNA polymerases, including Sequenase and the thermophilic Taq and Vent polymerases. The termination rate depends on the fine structure of a triplex, as well as on ambient conditions such as temperature and the concentration of magnesium ions. Inhibition of DNA synthesis was observed not only when triplexes blocked the path of DNA polymerase, but also when a polymerization primer was involved in triplex formation. Escherichia coli ss-binding (SSB) protein helps DNA polymerase overcome the triplex barrier, but with an efficiency dramatically dependent on the triplex configuration. These results describe a novel method for blocking DNA replication at target homopurine-homopyrimidine sequences by means of triplex-forming oligos in direct analogy with similar results during transcription.

Suicidal nucleotide sequences for DNA polymerization.

Studying the activity of T7 DNA polymerase (Sequenase) on open circular DNAs, we observed virtually complete termination within potential triplex-forming sequences. Mutations destroying the triplex potential of the sequences prevented termination, while compensatory mutations restoring triplex potential restored it. We hypothesize that strand displacement during DNA polymerization of double-helical templates brings three DNA strands (duplex DNA downstream of the polymerase plus a displaced overhang) into close proximity, provoking triplex formation, which in turn prevents further DNA synthesis. Supporting this idea, we found that Sequenase is unable to propagate through short triple-helical stretches within single-stranded DNA templates. Thus, DNA polymerase, by inducing triplex formation at specific sequences in front of the replication fork, causes self-termination. Possible biological implications of such 'conformational suicide' are discussed. Our data also provide a novel way to target DNA polymerases at specific sequences using triplex-forming oligonucleotides.

Intramolecular DNA triplexes: unusual sequence requirements and influence on DNA polymerization.

Homopurine-homopyrimidine mirror repeats are known to form intramolecular DNA triplexes in vitro. By probing with chemical agents specific for unusual DNA conformations, we have now demonstrated the formation of intramolecular triplexes consisting of G.G.C and T.A.T base triplets by DNA sequences that are neither homopurine-homopyrimidine nor mirror repeats. This finding significantly enlarges the number of sequences that could form DNA triplexes. The observed triplexes are stable under the conditions that are optimal for DNA polymerases in vitro. We found that triplex formation causes specific termination of DNA polymerization in vitro. This effect is detected for different DNA polymerases and may have implications for the regulation of DNA replication in vivo.

Analysis of sequence specificity of 5-bromodeoxyuridine-induced reversion in cells containing multiple copies of a mutant gpt gene.

For studies on molecular mechanisms of mutagenesis, it would be advantageous to transfer mutant genes with specific alterations into mammalian cells and use the transformed cells in reversion analyses. In the present paper, we describe an efficient method for analyzing reversion events occurring in cells that possess multiple copies of a mutational target gene. This method involves amplification of the chromosomally integrated target genes with the polymerase chain reaction (PCR) and restriction endonuclease digestion of the amplified product. Single reversion events that either create or destroy restriction endonuclease recognition sequences that encompass the site of the original mutation can be identified in a background of 10-20 copies of the gene that retain the mutant sequence. Using this method, we have analyzed revertants induced by 5-bromodeoxyuridine (BrdU) in a Chinese hamster ovary cell line that possesses multiple copies of a mutant bacterial gpt gene containing a specific alteration. The results of this study not only demonstrate the effectiveness of this method for analyzing reversion of a single gene copy in transfectants possessing multiple copies of a mutant target gene, but also demonstrate that the sequence specificity for BrdU-induced mutations is the same in Chinese hamster cells as previously observed with mouse cells.