Interaction of linear homologous DNA duplexes via Holliday junction formation.

Interaction of linear homologous DNA duplexes by formation of Holliday junctions was revealed by electrophoresis and confirmed by electron microscopy. The phenomenon was demonstrated using a model of five purified PCR products of different size and sequence. The double-stranded structure of interacting DNA fragments was confirmed using several consecutive purifications, S1-nuclease analysis, and electron microscopy. Formation of Holliday junctions depends on DNA concentration. A thermodynamic equilibrium between duplexes and Holliday junctions was shown. We propose that homologous duplex interaction is initiated by nucleation of several dissociated terminal base pairs of two fragments. This process is followed by branch migration creating a population of Holliday junctions with the branch point at different sites. Finally, Holliday junctions are resolved via branch migration to new or previously existing duplexes. The phenomenon is a new property of DNA. This type of DNA-DNA interaction may contribute to the process of Holliday junction formation in vivo controlled by DNA conformation and DNA-protein interactions. It is of practical significance for optimization of different PCR-based methods of gene analysis, especially those involving heteroduplex formation.

Holliday junctions are formed in concentrated solutions of purified products of DNA amplification.

Previously, using concentrated solutions of PCR products of five different genes, we described the appearance in these solutions of DNA structures with molecular weights approximately twice greater than that of double-strand (ds) fragments and with even higher molecular weight. Since this phenomenon was shown to be not dependent on the size or sequence of the DNA fragments, we suggested that it is due to interaction of DNA duplexes. The double-sized dsDNA complex containing four polynucleotide strands of two DNA fragments was named a "tetramer". Our present work is devoted to elucidation of peculiarities of tetramer formation and its structure in solutions of a purified PCR product of p53 cDNA. We found that the intensity of tetramer formation depends on the concentration of the PCR product in solution. Three subsequent purifications of the PCR product were performed using DNA-binding matrix, but the tetramers appeared again after every procedure. After purification of PCR product preliminarily treated with S1-nuclease, tetramers appeared again, indicating that these structures are formed from dsDNA fragments. Purification of the tetramers on DNA-binding matrix led to the appearance of the initial dsDNA fragments as the main DNA structure. When electroelution and column filtration by centrifugation were used, the purification procedure was speeded up, and a solution with a higher amount of the tetramer was obtained. Electron microscopy revealed the presence of four-stranded symmetrical structures with crossing chains known as Holliday junctions. Thus, for the first time the ability of homologous dsDNA fragments to interact with the formation of Holliday junctions without participation of cell proteins has been demonstrated.