Abstract

The instability of chromosome fragile sites is implicated as a causative factor in several human diseases, including cancer [for common fragile sites (CFSs)] and neurological disorders [for rare fragile sites (RFSs)]. Previous studies have indicated that problems arising during DNA replication are the underlying source of this instability. Although the role of replication stress in promoting instability at CFSs is well documented, much less is known about how the fragility of RFSs arises. Many RFSs, as exemplified by expansion of a CGG trinucleotide repeat sequence in the fragile X syndrome-associated <i>FRAXA</i> locus, exhibit fragility in response to folate deficiency or other forms of "folate stress." We hypothesized that such folate stress, through disturbing the replication program within the pathologically expanded repeats within <i>FRAXA</i>, would lead to mitotic abnormalities that exacerbate locus instability. Here, we show that folate stress leads to a dramatic increase in missegregation of <i>FRAXA</i> coupled with the formation of single-stranded DNA bridges in anaphase and micronuclei that contain the <i>FRAXA</i> locus. Moreover, chromosome X aneuploidy is seen when these cells are exposed to folate deficiency for an extended period. We propose that problematic <i>FRAXA</i> replication during interphase leads to a failure to disjoin the sister chromatids during anaphase. This generates further instability not only at <i>FRAXA</i> itself but also of chromosome X. These data have wider implications for the effects of folate deficiency on chromosome instability in human cells.