Transitions of cancer cells between distinct cell states, which are typically driven by transcription reprogramming, fuel tumor plasticity, metastasis, and therapeutic resistance. Whether the transiti Show more
Transitions of cancer cells between distinct cell states, which are typically driven by transcription reprogramming, fuel tumor plasticity, metastasis, and therapeutic resistance. Whether the transitions between cell states can be therapeutically targeted remains unknown. Here, using the epithelial-to-mesenchymal transition (EMT) as a model, we show that the transcription reprogramming during a cell-state transition induces genomic instability through R-loops and transcription-replication conflicts, and the cell-state transition cannot occur without the ATR kinase, a key regulator of the replication stress response. ATR inhibition during EMT not only increases transcription- and replication-dependent genomic instability but also disrupts transcription reprogramming. Unexpectedly, ATR inhibition elevates R-loop-associated DNA damage at the SNAI1 gene, a key driver of the transcription reprogramming during EMT, triggering ATM- and Polycomb-mediated transcription repression of SNAI1. Beyond SNAI1, ATR also suppresses R-loops and antagonizes repressive chromatin at a subset of EMT genes. Importantly, inhibition of ATR in tumors undergoing EMT reduces tumor growth and metastasis, suggesting that ATR inhibition eliminates cancer cells in transition. Thus, during EMT, ATR not only protects genome integrity but also enables transcription reprogramming, revealing that ATR is a safeguard of cell-state transitions and a target to suppress tumor plasticity. Show less
Familial hypercholesterolemia (FH) is a genetic disease, usually with onset during childhood, characterized by elevated blood LDL cholesterol levels and potentially associated with severe cardiovascul Show more
Familial hypercholesterolemia (FH) is a genetic disease, usually with onset during childhood, characterized by elevated blood LDL cholesterol levels and potentially associated with severe cardiovascular complications. Concerning mutated genes in FH, such as Show less
Hypertrophic cardiomyopathy (HCM) is a genetic disorder characterized by cardiac hypertrophy caused by mutations in sarcomere protein genes. MYBPC3 mutations are reported as a frequent cause of HCM. W Show more
Hypertrophic cardiomyopathy (HCM) is a genetic disorder characterized by cardiac hypertrophy caused by mutations in sarcomere protein genes. MYBPC3 mutations are reported as a frequent cause of HCM. We aimed to identify the gene mutation underlying HCM in an Italian patient and his family composed of 13 relatives. Mutation screening of 658 known mutations was performed using a rapid and efficient mutation detection system based on semiautomated MALDI-TOF mass spectrometry using the Sequenom MassArray System and iPLEX Gold genotyping chemistry. Subsequently, direct sequencing of the coding exons and flanking intronic regions was performed for the most suitable HCM genes (MYBPC3, MYH7, TNNT2, TNNI3, and TPM1) in the index patient. We found a novel MYBPC3 gene mutation: G13999T (Gln689His). No other sarcomere gene mutation was found in this family. This genetic variant, which changes the last amino acid of MYBPC3 exon 21, affects a highly conserved residue. Furthermore, the Gln689His does not appear in public databases and has never been described as a polymorphism. The potential pathogenic role of this novel mutation was underlined by its absence in a sample of healthy subjects (n = 122) from the general Italian population. In summary, a novel MYBPC3 gene mutation has been identified in a patient affected by HCM, whereas it was absent in 244 reference alleles. Show less