Cancer cells rely on telomerase or the alternative lengthening of telomeres (ALT) pathway to overcome replicative mortality. ALT is mediated by recombination and is prevalent in a subset of human cancers, yet whether it can be exploited therapeutically remains unknown. Loss of the chromatin remodeling protein ATRX associates with ALT in cancers. Here, we show that ATRX loss compromises cell-cycle regulation of the telomeric non-coding RNA TERRA and leads to persistent association of replication protein A (RPA) with telomeres after DNA replication, creating a recombinogenic nucleoprotein structure. Inhibition of the protein kinase ATR, a critical regulator of recombination recruited by RPA, disrupts ALT and triggers chromosome fragmentation and apoptosis in ALT cells. Importantly, the cell death induced by ATR inhibitors is highly selective for cancer cells that rely on ALT, , suggesting that such inhibitors may be useful for treatment of ALT-positive cancers.Cancer cells overcome replicative senescence by activating telomerase or the alternative lengthening of telomeres (ALT) pathway (1-3). ALT is used in ~5-15% of all human Author ManuscriptAuthor Manuscript Author ManuscriptAuthor Manuscript cancers and is prevalent in specific cancer types, including osteosarcoma and glioblastoma (4). Currently, there are no therapies specifically targeting ALT. ALT relies on recombination to elongate telomeres (3), but how the recombinogenic state of ALT telomeres is established remains elusive. In contrast to cancer cells defective for homologous recombination (HR) and susceptible to Poly(ADP-ribose) polymerase (PARP) inhibition (5, 6), ALT-positive cells are HR-proficient (7). Thus, the reliance of ALT on recombination raises an important question as to whether recombination can be exploited in ALT-positive cancers as a means for targeted therapy.Single-stranded DNA (ssDNA) coated by replication protein A (RPA) is a key intermediate in both DNA replication and HR (8). RPA transiently associates with telomeres during DNA replication, but is released from telomeres after S phase (9, 10). The release of RPA may be an important mechanism to suppress HR at telomeres. The association of RPA with telomeres in S phase is facilitated by TERRA, the telomere repeat-containing RNA, which is also present at telomeres during this period (9,(11)(12)(13). To investigate how ALT is established, we determined whether the association of TERRA with telomeres is altered in ALT cells. TERRA colocalized with the telomere-binding protein TRF2 in telomerasepositive HeLa cervical cancer cells ( fig. S1) (9). However, in both HeLa and telomerasepositive SJSA1 osteosarcoma cells ( fig. S24B), the number of TERRA foci declined from S phase to G2 ( Considering that RPA is released from telomeres in G2/M when TERRA is repressed by ATRX (9), we examined whether ATRX is required for the release of RPA. In HeLa cells, numerous small replication-associated RPA foci (type-A RPA foci) were detected in S phase (Fig. S7). As cells progressed from S to ...
Squamous cell carcinomas (SCCs) are aggressive malignancies. Previous report demonstrated that master transcription factors (TFs) TP63 and SOX2 exhibited overlapping genomic occupancy in SCCs. However, functional consequence of their frequent co-localization at super-enhancers remains incompletely understood. Here, epigenomic profilings of different types of SCCs reveal that TP63 and SOX2 cooperatively and lineage-specifically regulate long non-coding RNA (lncRNA) CCAT1 expression, through activation of its super-enhancers and promoter. Silencing of CCAT1 substantially reduces cellular growth both in vitro and in vivo, phenotyping the effect of inhibiting either TP63 or SOX2. ChIRP analysis shows that CCAT1 forms a complex with TP63 and SOX2, which regulates EGFR expression by binding to the super-enhancers of EGFR, thereby activating both MEK/ERK1/2 and PI3K/AKT signaling pathways. These results together identify a SCC-specific DNA/RNA/protein complex which activates TP63/SOX2-CCAT1-EGFR cascade and promotes SCC tumorigenesis, advancing our understanding of transcription dysregulation in cancer biology mediated by master TFs and super-enhancers.
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