Browsing by Subject "ATAC-seq"

Uterine leiomyoma (also known as myoma) is the most common neoplasia in women during reproductive age and it represents a burden for public health care. Approximately 70% of Caucasian women develop myomas, although only 25% of cases are symptomatic. The genetic background of myomas varies significantly and the most common genetic causes are mutations in genes Mediator complex subunit 12 (MED12), Fumarate hydratase (FH) or YEATS Domain containing 4 (YEATS4) , rearrangements affecting the High Mobility Group AT-hook 2 (HMGA2), and deletions in COL4A5/6 locus. MED12 mutations represent the most common genetic alteration in myomas, being present in approximately 70% of cases. Genome organization comprises different levels of complexity, spanning from regulation of individual genes to changes in the architecture of large portions of chromosomes. Literature offers massive evidence of changes in genome organization among different cell types and between several tumor and related healthy cells, but information about these changes in myoma is lacking. The aim of this study is to determine the main features of genome organization in myomas belonging to the aforementioned five genetic subclasses, in order to identify which are the underlying common pathways that are dysregulated in the neoplasia. This is achieved by mapping regions of open chromatin in myomas and related my-ometrium samples with ATAC-seq. Sample’s clustering seems not to be individual-dependent, while tumors belonging to FH, YEATS4 and COL4A5/6 subclasses form distinct clusters, unlike MED12 and HMGA2 subclasses. Six open chromatin regions located within genes were identified in 19/25 tumors and not in myometrium. Seven myometrium-specific open chromatin regions were identified in 21/25 myometria and in less than 10 tumors. As expected, Gene Ontology enrichment analysis revealed that myomas belonging to FH subclass are characterized by deregulation of metabolic pathways. Many of the identified genes in the open chromatin regions have been linked to other tumors in previous studies. Tumor-specific open chromatin regions locate within oncogenes, while myometrium-specific ones are found in proximity of tumor suppressor genes, suggesting a biological role in myomagenesis for these genes. Further investigation on the identified genes (e.g. transcriptional regulation, gene expression and protein level) and addi-tional studies on chromatin architecture are needed to fully unravel the mechanism of myomagenesis.