Are there three polynucleotide strands in the catalytic centre of DNA polymerases?

Mitochondrial DNA may undergo large-scale rearrangements, thus leading to diseases. The mechanisms of these rearrangements are still the matter of debates. Several lines of evidence indicate that breakpoints are characterized by direct repeats (DR), one of them being eliminated from the normal genome. Analysis of DR showed their skewed nucleotide content compatible with the formation of known triple helices. Here, I propose a novel mechanism involving the formation of triplex structures that result from the dissociation of the [synthesized repeat-DNA polymerase] complex. Upon binding to the homologous sequence, replication is initiated from the primer bound in a triple helix manner. This feature implies the initiation of replication on the double-stranded DNA from the triple helix primer. Hereby, I review evidences supporting this model. Indeed, all short d(G)-rich primers 10 nucleotides long can be elongated on double-stranded DNA by phage, bacterial, reverse transcriptases and eukaryotic DNA polymerases. Mismatches may be tolerated between the primer and its double-stranded binding site. In contrast to previous studies, evidences for the parallel binding of the triple helix to its homologous strand are provided. This suggest the displacement of the non-template strand by the triple helix primer upon binding within the DNA polymerase catalytic centre. Computer modelling indicates that the triple helix primer lies within the major groove of the double helix, with its 3' hydroxyl end nearby the catalytic amino acids. Taken together, I bring new concepts on DNA rearrangements, and novel features of triple helices and DNA polymerases that can bind three polynucleotide strands similar to RNA polymerases.