Project description:Centrosome amplification is a common feature of human tumors, but whether this is a cause or a consequence of human cancer remains unclear. Here, we report the creation of a mouse model in which centrosome number can be persistently increased in the absence of additional genetic defects. We show that extra centrosomes increase tumor initiation in a mouse model of intestinal neoplasia. Most importantly, we demonstrate that supernumerary centrosomes are sufficient to drive development of spontaneous tumors in multiple tissues. Tumors with centrosome amplification exhibit frequent mitotic errors and possess complex karyotypes, recapitulating a common feature of human cancer. Together, our data support a direct causal relationship between centrosome amplification, genomic instability and tumor development. The sequences in this dataset result from random whole-genome DNA sequencing of spontaneous T- cell lymphomas, B-cell lymphomas, squamous cell carcinomas and one sarcoma from doxycycline-treated Plk4 mice.

Project description:Centrosome amplification is sufficient to promote spontaneous tumorigenesis in mammals

Project description:Centrosomes are microtubule-organizing centers that facilitate bipolar mitotic spindle assembly and chromosome segregation. Recognizing that centrosome amplification is a common feature of aneuploid cancer cells, we tested whether supernumerary centrosomes are sufficient to drive tumor development. To do this, we constructed and analyzed mice in which centrosome amplification can be induced by a Cre-recombinase-mediated increase in expression of Polo-like kinase 4 (Plk4). Elevated Plk4 in mouse fibroblasts produced supernumerary centrosomes and enhanced the expected mitotic errors, but proliferation continued only after inactivation of the p53 tumor suppressor. Increasing Plk4 levels in mice with functional p53 produced centrosome amplification in liver and skin, but this did not promote spontaneous tumor development in these tissues or enhance the growth of chemically induced skin tumors. In the absence of p53, Plk4 overexpression generated widespread centrosome amplification, but did not drive additional tumors or affect development of the fatal thymic lymphomas that arise in animals lacking p53. We conclude that, independent of p53 status, supernumerary centrosomes are not sufficient to drive tumor formation.

Project description:Centrosome amplification is a common feature of many cancer cells, and it has been previously proposed that centrosome amplification can drive genetic instability and so tumorigenesis. To test this hypothesis, we generated Drosophila lines that have extra centrosomes in approximately 60% of their somatic cells. Many cells with extra centrosomes initially form multipolar spindles, but these spindles ultimately become bipolar. This requires a delay in mitosis that is mediated by the spindle assembly checkpoint (SAC). As a result of this delay, there is no dramatic increase in genetic instability in flies with extra centrosomes, and these flies maintain a stable diploid genome over many generations. The asymmetric division of the larval neural stem cells, however, is compromised in the presence of extra centrosomes, and larval brain cells with extra centrosomes can generate metastatic tumors when transplanted into the abdomens of wild-type hosts. Thus, centrosome amplification can initiate tumorigenesis in flies.

Project description:Centrosome amplification is frequent in cancer, but the underlying mechanisms remain unclear. Here we report that disruption of the Kruppel-like factor 14 (KLF14) gene in mice causes centrosome amplification, aneuploidy and spontaneous tumorigenesis. Molecularly, KLF14 functions as a transcriptional repressor of Plk4, a polo-like kinase whose overexpression induces centrosome overduplication. Transient knockdown of KLF14 is sufficient to induce Plk4-directed centrosome amplification. Clinically, KLF14 transcription is significantly downregulated, whereas Plk4 transcription is upregulated in multiple types of cancers, and there exists an inverse correlation between KLF14 and Plk4 protein expression in human breast and colon cancers. Moreover, KLF14 depletion promotes AOM/DSS-induced colon tumorigenesis. Our findings reveal that KLF14 reduction serves as a mechanism leading to centrosome amplification and tumorigenesis. On the other hand, forced expression of KLF14 leads to mitotic catastrophe. Collectively, our findings identify KLF14 as a tumour suppressor and highlight its potential as biomarker and therapeutic target for cancer.

Project description:While aneuploidy is found in more than 90% of solid tumors, it is unclear whether aneuploidy is the cause or the consequence of tumorigenesis. Different mouse models deficient in centrosomal or spindle checkpoint proteins that induce aneuploidy show either a promotion or a decrease in tumorigenesis depending on the tissues and the types of oncogenic stimuli. To investigate the effects of aneuploidy in skin development and tumorigenesis, we used Plk4 over-expression (Plk4OE) during epidermal development to assess centrosome amplification and aneuploidy. We found that PLK4OE in the developing epidermis induced centrosome amplification and multipolar divisions, consequently led to p53 stabilization and apoptosis of epidermal progenitors. This delayed epidermal stratification and induced lethal skin barrier defect in 50% of the mice. Plk4 transgene expression was shutdown postnatally in the surviving mice and PLK4OE mice never developed spontaneous skin tumors. Concomitant Plk4OE and P53 deletion (PLK4OE/p53cKO) rescued the defects in differentiation and stratification. Unexpectedly, p53 deletion did not rescue the apoptosis or eventual elimination of the cells overexpressing PLK4 and presenting multiple centrosomes. Remarkably, the short term presence of cells with supernumerary centrosomes postnatally was sufficient to generate aneuploidy and triggered spontaneous skin cancers with complete penetrance. These results reveal for the first time that aneuploidy induced by centrosome amplification, even if transient, can trigger tumorigenesis.

Project description:Centrosome abnormalities are a typical hallmark of human cancers. However, the origin and dynamics of such abnormalities in human cancer are not known. In this study, we examined centrosomes in Barrett's esophagus tumorigenesis, a well-characterized multistep pathway of progression, from the premalignant condition to the metastatic disease. This human cancer model allows the study of sequential steps of progression within the same patient and has representative cell lines from all stages of disease. Remarkably, centrosome amplification was detected as early as the premalignant condition and was significantly expanded in dysplasia. It was then present throughout malignant transformation both in adenocarcinoma and metastasis. The early expansion of centrosome amplification correlated with and was dependent on loss of function of the tumor suppressor p53 both through loss of wild-type expression and hotspot mutations. Our work shows that centrosome amplification in human tumorigenesis can occur before transformation, being repressed by p53. These findings suggest centrosome amplification in humans can contribute to tumor initiation and progression.

Project description:Centrosome amplification triggers tumorigenesis in p53 deficient epidermis

Project description:This study shows that the TLR4/MyD88 pathway in intestinal mesenchymal cells promotes intestinal carcinogenesis in the APCmin mouse model.

Project description:Centrosome amplification induces proliferation arrest and cell invasion. The fate of centrosome amplification cells are studied here.