Evidence for a fast, intrachromosomal conversion mechanism from mapping of nucleotide variants within a homogeneous α-satellite DNA array

Assuming that patterns of sequence variants within highly homogeneous centromeric tandem repeat arrays can tell us which molecular turnover mechanisms are presently at work, we analyzed the a-satellite tandem repeat array DXZI of one human X chromosome. Here we present accurate snapshots from this dark matter of the genome. We demonstrate stable and representative cloning of the array in a P1 artificial chromosome (PAC) library, use samples of higher-order repeats subcloned from five unmapped PACs (120-160 kb) to identify common variants, and show that such variants are presently in a fixed transition state. To characterize patterns of variant spread throughout homogeneous array segments, we use a novel partial restriction and pulsed-field gel electrophoresis mapping approach. We find an older large-scale (35-50 kb) duplication event supporting the evolutionarily important unequal crossing-over hypothesis, but generally find independent variant occurrence and a paucity of potential de novo mutations within segments of highest homogeneity (99.1%-99.3%). Within such segments, a highly nonrandom variant clustering within adjacent higher-order repeats was found in the absence of haplotypic repeats. Such variant clusters are hardly explained by interchromosomal, fixation-driving mechanisms and likely reflect a fast, localized, intrachromosomal sequence conversion mechanism.