Aberrant expression of microRNAs (miRNAs) and the enzymes that control their processing have been reported in multiple biological processes including primary and metastatic tumours1–6, but the mechanisms governing this are not clearly understood. Here we show that TAp63, a p53 family member, suppresses tumorigenesis and metastasis, and coordinately regulates Dicer and miR-130b to suppress metastasis. Metastatic mouse and human tumours deficient in TAp63 express Dicer at very low levels, and we found that modulation of expression of Dicer and miR-130b markedly affected the metastatic potential of cells lacking TAp63. TAp63 binds to and transactivates the Dicer promoter, demonstrating direct transcriptional regulation of Dicer by TAp63. These data provide a novel understanding of the roles of TAp63 in tumour and metastasis suppression through the coordinate transcriptional regulation of Dicer and miR-130b and may have implications for the many processes regulated by miRNAs.
Highlights d Oncogenic KRAS promotes an immune-suppressive profile in CRC d IRF2 is a key downstream target of oncogenic KRASmediating immune suppression d IRF2 suppresses MDSC migration and infiltration by targeting the CXCL3-CXCR2 axis d Enforced IRF2 expression or CXCR2 inhibition overcomes anti-PD1 resistance in CRC
Summary
Synthetic and collateral lethality have provided conceptual frameworks to identify cancer-specific vulnerabilities1–3. Here, we explored an approach to identify potential synthetic lethal interactions through screening mutually exclusive deletion patterns in cancer genomes. We sought to identify ‘synthetic essential’ genes, which might be occasionally deleted in some cancers but almost always retained in the context of a specific tumor suppressor deficiency, and posited that such synthetic essential genes would be therapeutic targets in cancers harboring specific tumor suppressor deficiencies. In addition to known synthetic lethal interactions, this approach uncovered the chromatin helicase DNA-binding factor CHD1 as a putative synthetic essential gene in PTEN-deleted cancers. In PTEN-deleted prostate and breast cancers, functional analysis showed that CHD1 depletion profoundly and specifically suppressed cell proliferation, survival and tumorigenic potential. Mechanistically, functional PTEN stimulates GSK3β-mediated phosphorylation of CHD1 degron domains, which promotes CHD1 degradation via β-TrCP-mediated ubiquitination-proteasome pathway. Conversely, PTEN deficiency results in CHD1 protein stabilization, which in turn engages the H3K4me3 mark to activate transcription of the pro-tumorigenic TNFα/NF-κB gene network. Together, this study identifies a novel PTEN pathway in cancer and provides a framework for the discovery of trackable targets in cancers harboring specific tumor suppressor deficiencies.
The role of p63 in cancer has been an area of intense debate and controversy. Is TP63 (which encodes p63) a tumour suppressor gene or an oncogene? This debate is partly due to the complexity of the gene. There are several p63 isoforms — some with tumour suppressive functions and others with oncogenic functions. In this Opinion article, we focus on the recent advances in understanding p63 biology and its roles in cancer. In this regard, we discuss the role of p63 in multiple stem cell compartments, ageing, in the response to DNA damage and in DNA repair. Finally, we highlight the importance of understanding the interactions between all three p53 family members and the potential impact of this knowledge on cancer therapy and regenerative medicine.
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