The isolation of an attached X chromosome (X^X), consisting of two apparently intact X chromosomes joined at their left telomeres, was previously reported (Hodgkin and Albertson 1995, Genetics 141: 527). In contrast to attached X chromosome constructs in other organisms, and also to X-autosome fusions in C. elegans, this X^X configuration is unstable, frequently breaking down to give an apparently normal X chromosome, or else an X chromosome with a deletion of the left end, or an X chromosome carrying a duplication of the left end. The extent of these deletions and duplications is variable, and they are generated at high frequency (in at least 5% of all X^X oogenic meioses). X^X strains therefore provide a useful source of aberrations in this region of the genome, which contains both a meiotic pairing site and numerator sites for sex determination. It seemed likely that X^X breakage was occurring at meiosis, and might be dependent on the meiotic recombination machinery. To test this hypothesis, X^X was crossed onto a series of meiosis-defective backgrounds (
him-1,
him-3,
him-5,
him-6,
him-8,
him-14,
xnd-1, etc.). X^X breakage, as measured by the production of self-progeny males, was significantly or greatly reduced in most of these backgrounds, indicating that the breakage events are partly or wholly dependent on meiotic recombination. Previous FISH studies using YAC probes indicated that the end junction between the two X chromosomes was symmetrical and involved no deletion. We attempted to clone the junction fragment by single primer PCR, in order to determine its exact structure. However, PCR amplification was not successful, perhaps because the junction may include a substantial stretch of telomere repeats or local rearrangements. Further investigation of the structure and properties of the end junction is in progress.