Human centromeres are composed of large tandem arrays of repetitive alpha satellite DNA, which are often sites of aberrant rearrangement in cancers ( Mitelman et al., 1997 ; Padilla- Nash et al., 2001 ). To date, annotation of the human centromere repetitive sequences remains incomplete, greatly hindering in-depth functional studies of these regions essential for chromosome segregation. In order to monitor sister chromatid exchange happening at the centromere (C-SCE) due to recombination and mutagenic events, I have applied the Chromosome-Orientation Fluorescence in situ Hybridization (CO-FISH) technique to centromeres (Cen-CO-FISH) in human cells. This hybridization-based method involves (1) the incorporation of nucleotide analogs through a single round of replication, (2) enzymatic digestion of the newly synthesized DNA strand and (3) subsequent hybridization of single-stranded probes, in absence of a denaturation step. The resulting signal allows to differentially label each sister chromatid based on the 5'-3' directionality of the DNA and to score aberrant staining patterns indicative of C-SCE. The Cen-CO-FISH method applied to human centromeres revealed that human centromeres indeed undergo recombination in cycling cells resulting in C-SCE, and centromere instability is enhanced in cancer cell lines and primary cells undergoing senescence (Giunta and Funabiki, 2017). Here, I present the detailed protocol of the preparation, experimental procedure and data acquisition for the Cen-CO-FISH method in human cells. It also includes a conceptual overview of the technique, with examples of representative images and scoring guidelines. The Cen-CO-FISH represents a valuable tool to facilitate exploration of centromere repeats.
Keywords: Fluorescence in situ hybridization; Alpha satellite; CO-FISH; Centromere; Genome stability; Recombination; Repetitive DNA; Sister chromatid exchange.
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