The evolutionarily conserved centromeric dodeca-satellite DNA has an asymmetric distribution of guanine and cytosine residues resulting in one strand being relatively G-rich. This dodeca-satellite G-strand contains a GGGA-tract that is similar to the homopurine tracts found in most telomeric DNA sequences. Here, we show that the dodeca-satellite G-strand forms intramolecular hairpin structures that are stabilized by the formation of non-Watson-Crick G.A pairs as well as regular Watson-Crick G.C pairs. Special stacking interactions are also likely to contribute significantly to the stability of this structure. This hairpin conformation melts at relatively high temperature, around 75 o C, and is detected under many different ionic and pH conditions. As judged by electron microscopy visualization, these structures can be formed in aβ-DNA environment. Under the same experimental conditions, neither the C-strand nor the double-stranded dodeca-satellite DNA were found to form any unusual DNA strucutre. A protein activity has been detected that preferentially binds to the single-stranded dodeca-satellite C-strand. The biological relevance of these results is discussed in view of the similarities to telometric DNA.