Cancer stem cells (CSC) appear to have increased metastatic potential, but mechanisms underlying this are poorly defined. Here we show that VEGFA induction of Sox2 promotes EMT and tumor metastasis. In breast lines and primary cancer culture, VEGFA rapidly upregulates SOX2 expression, leading to SNAI2 induction, EMT, increased invasion and metastasis. We show Sox2 downregulates miR-452, which acts as a novel metastasis suppressor to directly target the SNAI2 3′-untranslated region (3′-UTR). VEGFA stimulates Sox2- and Slug-dependent cell invasion. VEGFA increases lung metastasis in vivo, and this is abrogated by miR-452 overexpression. Furthermore, SNAI2 transduction rescues metastasis suppression by miR-452. Thus, in addition to its angiogenic action, VEGFA upregulates Sox2 to drive stem cell expansion, together with miR-452 loss and Slug upregulation, providing a novel mechanism whereby cancer stem cells acquire metastatic potential. Prior work showed EMT transcription factor overexpression upregulates CSC. Present work indicates that stemness and metastasis are a two-way street: Sox2, a major mediator of CSC self-renewal, also governs the metastatic process.
BackgroundThe Cancer Atlas project has shown that p53 is the only commonly (96 %) mutated gene found in high-grade serous epithelial ovarian cancer, the major histological subtype. Another general genetic change is extensive aneuploidy caused by chromosomal numerical instability, which is thought to promote malignant transformation. Conventionally, aneuploidy is thought to be the result of mitotic errors and chromosomal nondisjunction during mitosis. Previously, we found that ovarian cancer cells often lost or reduced nuclear lamina proteins lamin A/C, and suppression of lamin A/C in cultured ovarian epithelial cells leads to aneuploidy. Following up, we investigated the mechanisms of lamin A/C-suppression in promoting aneuploidy and synergy with p53 inactivation.ResultsWe found that suppression of lamin A/C by siRNA in human ovarian surface epithelial cells led to frequent nuclear protrusions and formation of micronuclei. Lamin A/C-suppressed cells also often underwent mitotic failure and furrow regression to form tetraploid cells, which frequently underwent aberrant multiple polar mitosis to form aneuploid cells. In ovarian surface epithelial cells isolated from p53 null mice, transient suppression of lamin A/C produced massive aneuploidy with complex karyotypes, and the cells formed malignant tumors when implanted in mice.ConclusionsBased on the results, we conclude that a nuclear envelope structural defect, such as the loss or reduction of lamin A/C proteins, leads to aneuploidy by both the formation of tetraploid intermediates following mitotic failure, and the reduction of chromosome (s) following nuclear budding and subsequent loss of micronuclei. We suggest that the nuclear envelope defect, rather than chromosomal unequal distribution during cytokinesis, is the main cause of aneuploidy in ovarian cancer development.
Transgenic mice carrying multiple copies of a recoverable lambda phage shuttle vector (lambda supF) were constructed for the purpose of studying mutagenesis in a whole animal. Spontaneous mutations in rescued supF target genes from several different lines of transgenic mice were analyzed. One mouse line, 1139, was identified in which the frequency of spontaneous mutations was unusually high (3.15 x 10(-4)), 20-fold higher than in other transgenic mice carrying a similar number of copies of the lambda transgene (approximately 100). Over 75% of the spontaneous mutations from 1139 mice were found to be deletions, whereas mostly point mutations were recovered from the other mice. In 1139 no significant variation among adult tissues has been detected. However, embryonic tissue yielded a 3- to 4-fold lower frequency of mutations, most of which were point mutations rather than deletions. The frequency of mutations at another locus, the hypoxanthine phosphoribosyl transferase gene, was not elevated in fibroblast lines established in culture from the 1139 mice. Overall, these results suggest that the deletion mutagenesis affecting the transgene sequences in 1139 mice is a locus-specific effect occurring during growth and development. The increased mutagenesis could not be explained by the degree of methylation of the transgene sequences, since hypermethylation was seen in both 1139 mice and other mice with a low frequency of shuttle vector mutations. The integrated lambda vector DNA in 1139 mice was mapped to a single site on chromosome 7, but no mechanism for the mutagenesis was suggested by this localization. It is proposed that the lambda DNA may have either integrated into an unstable genomic site or created a newly unstable locus in the process of integration.
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