Common fragile sites (cFS) represent chromosomal regions that are prone to breakage after partial inhibition of DNA synthesis. Activation of cFS is associated with various forms of DNA instability in cancer cells, and is thought to be an initiating event in the generation of DNA damage in early-stage tumorigenesis. Only a few cFS have been fully characterized despite the growing interest in cFS instability in cancer genomes. In this study, six-color fluorescence in situ hybridization revealed that FRA2C consists of two cFS spanning 747 kb FRA2Ctel and 746 kb FRA2Ccen at 2p24.3 and 2p24.2, respectively. Both cFS are separated by a 2.8 Mb non-fragile region containing MYCN. Fine-tiling array comparative genomic hybridization of MYCN amplicons from neuroblastoma (NB) cell lines and primary tumors revealed that 56.5% of the amplicons cluster in FRA2C. MYCN amplicons are either organized as double minutes or as homogeneously stained regions in addition to the single copy of MYCN retained at 2p24. We suggest that MYCN amplicons arise from extra replication rounds of unbroken DNA secondary structures that accumulate at FRA2C. This hypothesis implicates cFS in high-level gene amplification in cancer cells. Complex genomic rearrangements, including deletions, duplications and translocations, which originate from double-strand breaks, were detected at FRA2C in different cancers. These data propose a dual role for cFS in the generation of gross chromosomal rearrangements either after DNA breakage or by inducing extra replication rounds, and provide new insights into the highly recombinogenic nature of cFS in the human cancer genome.