Prediction and identification of recurrent genomic rearrangements that generate chimeric chromosomes in Saccharomyces cerevisiae.
Kim Palacios-FloresAlejandra CastilloCarina UribeJair García-SoteloMargareta BoegeGuillermo DávilaMargarita FloresRafael PalaciosLucia MoralesPublished in: Proceedings of the National Academy of Sciences of the United States of America (2019)
Genomes are dynamic structures. Different mechanisms participate in the generation of genomic rearrangements. One of them is nonallelic homologous recombination (NAHR). This rearrangement is generated by recombination between pairs of repeated sequences with high identity. We analyzed rearrangements mediated by repeated sequences located in different chromosomes. Such rearrangements generate chimeric chromosomes. Potential rearrangements were predicted by localizing interchromosomal identical repeated sequences along the nuclear genome of the Saccharomyces cerevisiae S288C strain. Rearrangements were identified by a PCR-based experimental strategy. PCR primers are located in the unique regions bordering each repeated region of interest. When the PCR is performed using forward primers from one chromosome and reverse primers from another chromosome, the break point of the chimeric chromosome structure is revealed. In all cases analyzed, the corresponding chimeric structures were found. Furthermore, the nucleotide sequence of chimeric structures was obtained, and the origin of the unique regions bordering the repeated sequence was located in the expected chromosomes, using the perfect-match genomic landscape strategy (PMGL). Several chimeric structures were searched in colonies derived from single cells. All of the structures were found in DNA isolated from each of the colonies. Our findings indicate that interchromosomal rearrangements that generate chimeric chromosomes are recurrent and occur, at a relatively high frequency, in cell populations of S. cerevisiae.
Keyphrases
- cell therapy
- saccharomyces cerevisiae
- high frequency
- copy number
- high resolution
- stem cells
- mesenchymal stem cells
- dna damage
- single cell
- dna repair
- induced apoptosis
- transcranial magnetic stimulation
- genome wide
- dna methylation
- risk assessment
- single molecule
- bone marrow
- mass spectrometry
- cell death
- human health
- climate change
- signaling pathway