Tobias Otto scite author profile

Preface Cancer is characterized by uncontrolled proliferation resulting from aberrant activity of various cell cycle proteins; therefore, cell cycle regulators are considered attractive targets in cancer therapy. Intriguingly, animal models demonstrated that some of these proteins are not essential for proliferation of non-transformed cells and development of most tissues. In contrast, many cancers are uniquely dependent on these proteins and are hence selectively sensitive to their inhibition. After decades of research on the physiological functions of cell cycle proteins and their relevance for cancer, this knowledge recently translated into the first approved cancer therapeutic targeting of a direct regulator of the cell cycle. Here, we review the role of cell cycle proteins in cancer, the rationale for targeting them in cancer treatment and results of clinical trials, as well as future therapeutic potential of various inhibitors. We focus only on proteins that directly regulate cell cycle progression. Cyclin-dependent kinases with transcriptional functions, as well as PARP inhibitors, which are highly successful in targeting BRCA1/BRCA2-mutant tumours, are not covered by this review.

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Stabilization of N-Myc Is a Critical Function of Aurora A in Human Neuroblastoma

Otto

et al. 2009

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In human neuroblastoma, amplification of the MYCN gene predicts poor prognosis and resistance to therapy. In a shRNA screen of genes that are highly expressed in MYCN-amplified tumors, we have identified AURKA as a gene that is required for the growth of MYCN-amplified neuroblastoma cells but largely dispensable for cells lacking amplified MYCN. Aurora A has a critical function in regulating turnover of the N-Myc protein. Degradation of N-Myc requires sequential phosphorylation by cyclin B/Cdk1 and Gsk3. N-Myc is therefore degraded during mitosis in response to low levels of PI3-kinase activity. Aurora A interacts with both N-Myc and the SCF(Fbxw7) ubiquitin ligase that ubiquitinates N-Myc and counteracts degradation of N-Myc, thereby uncoupling N-Myc stability from growth factor-dependent signals.

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MYCN regulates oncogenic MicroRNAs in neuroblastoma

Schulte

Horn

Otto

et al. 2007

Intl Journal of Cancer

242

188

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MYCN amplification is a common feature of aggressive tumour biology in neuroblastoma. The MYCN transcription factor has been demonstrated to induce or repress expression of numerous genes. MicroRNAs (miRNA) are a recently discovered class of short RNAs that repress translation and promote mRNA degradation by sequence-specific interaction with mRNA. Here, we sought to analyse the role of MYCN in regulation of miRNA expression. Using a miRNA microarray containing 384 different miRNAs and a set of 160 miRNA real-time PCR assays to validate the microarray results, 7 miRNAs were identified that are induced by MYCN in vitro and are upregulated in primary neuroblastomas with MYCN amplification. Three of the seven miRNAs belong to the miR-106a and miR-17 clusters, which have previously been shown to be regulated by c-Myc. The miR-17-92 polycistron also acts as an oncogene in haematopoietic progenitor cells. We show here that miR-221 is also induced by MYCN in neuroblastoma. Previous studies have reported miR-221 to be overexpressed in several other cancer entities, but its regulation has never before been associated with Myc. We present evidence of miRNA dysregulation in neuroblastoma. Additionally, we report miRNA induction to be a new mechanism of gene expression downregulation by MYCN. ' 2007 Wiley-Liss, Inc.

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Tobias Otto

Cell cycle proteins as promising targets in cancer therapy

Stabilization of N-Myc Is a Critical Function of Aurora A in Human Neuroblastoma

MYCN regulates oncogenic MicroRNAs in neuroblastoma

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