Min Sup Song

Identification of the miR-106b∼25 microRNA cluster as a proto-oncogenic PTEN-targeting intron that cooperates with its host gene MCM7 in transformation

A microRNA network regulates the tumor suppressor PTEN in prostate cancer. A Malignant Combination The abundance of microRNAs (miRNAs), tiny non–protein-coding RNAs that act as posttranscriptional regulators of gene expression, is frequently altered in cancer; indeed, various miRNAs are thought to act as oncogenes or tumor suppressors. Poliseno et al. investigated the possible role of miRNA regulation of the tumor suppressor PTEN in prostate cancer. They identified miRNAs from several families that targeted the gene encoding PTEN, thereby decreasing PTEN abundance, and showed that the abundance of some of these miRNAs was increased in human prostate cancer. Intriguingly, three PTEN-targeting miRNAs located within an intron of the gene encoding the DNA helicase minichromosome maintenance protein 7 (MCM7), which shows increased abundance in various human cancers, cooperated with MCM7 to transform fibroblasts in vitro and to initiate tumors when overexpressed in the prostates of transgenic mice. Thus, the MCM7 gene locus appears to encode multiple oncogenic elements that cooperate to promote prostate cancer development. PTEN (phosphatase and tensin homolog deleted on chromosome 10) is a tumor suppressor that antagonizes signaling through the phosphatidylinositol 3-kinase–Akt pathway. We have demonstrated that subtle decreases in PTEN abundance can have critical consequences for tumorigenesis. Here, we used a computational approach to identify miR-22, miR-25, and miR-302 as three PTEN-targeting microRNA (miRNA) families found within nine genomic loci. We showed that miR-22 and the miR-106b~25 cluster are aberrantly overexpressed in human prostate cancer, correlate with abundance of the miRNA processing enzyme DICER, and potentiate cellular transformation both in vitro and in vivo. We demonstrated that the intronic miR-106b~25 cluster cooperates with its host gene MCM7 in cellular transformation both in vitro and in vivo, so that the concomitant overexpression of MCM7 and the miRNA cluster triggers prostatic intraepithelial neoplasia in transgenic mice. Therefore, the MCM7 gene locus delivers two simultaneous oncogenic insults when amplified or overexpressed in human cancer. Thus, we have uncovered a proto-oncogenic miRNA-dependent network for PTEN regulation and defined the MCM7 locus as a critical factor in initiating prostate tumorigenesis.

The deubiquitinylation and localization of PTEN are regulated by a HAUSP–PML network

Nuclear exclusion of the PTEN (phosphatase and tensin homologue deleted in chromosome 10) tumour suppressor has been associated with cancer progression. However, the mechanisms leading to this aberrant PTEN localization in human cancers are currently unknown. We have previously reported that ubiquitinylation of PTEN at specific lysine residues regulates its nuclear–cytoplasmic partitioning. Here we show that functional promyelocytic leukaemia protein (PML) nuclear bodies co-ordinate PTEN localization by opposing the action of a previously unknown PTEN-deubiquitinylating enzyme, herpesvirus-associated ubiquitin-specific protease (HAUSP, also known as USP7), and that the integrity of this molecular framework is required for PTEN to be able to enter the nucleus. We find that PTEN is aberrantly localized in acute promyelocytic leukaemia, in which PML function is disrupted by the PML–RARα fusion oncoprotein. Remarkably, treatment with drugs that trigger PML–RARα degradation, such as all-trans retinoic acid or arsenic trioxide, restore nuclear PTEN. We demonstrate that PML opposes the activity of HAUSP towards PTEN through a mechanism involving the adaptor protein DAXX (death domain-associated protein). In support of this paradigm, we show that HAUSP is overexpressed in human prostate cancer and is associated with PTEN nuclear exclusion. Thus, our results delineate a previously unknown PML–DAXX–HAUSP molecular network controlling PTEN deubiquitinylation and trafficking, which is perturbed by oncogenic cues in human cancer, in turn defining a new deubiquitinylation-dependent model for PTEN subcellular compartmentalization.

The tumour suppressor RASSF1A regulates mitosis by inhibiting the APC–Cdc20 complex

The tumour suppressor gene RASSF1A is frequently silenced in lung cancer and other sporadic tumours as a result of hypermethylation of a CpG island in its promoter. However, the precise mechanism by which RASSF1A functions in cell cycle regulation and tumour suppression has remained unknown. Here we show that RASSF1A regulates the stability of mitotic cyclins and the timing of mitotic progression. RASSF1A localizes to microtubules during interphase and to centrosomes and the spindle during mitosis. The overexpression of RASSF1A induced stabilization of mitotic cyclins and mitotic arrest at prometaphase. RASSF1A interacts with Cdc20, an activator of the anaphase-promoting complex (APC), resulting in the inhibition of APC activity. Although RASSF1A does not contribute to either the Mad2-dependent spindle assembly checkpoint or the function of Emi1 (ref. 1), depletion of RASSF1A by RNA interference accelerated the mitotic cyclin degradation and mitotic progression as a result of premature APC activation. It also caused a cell division defect characterized by centrosome abnormalities and multipolar spindles. These findings implicate RASSF1A in the regulation of both APC–Cdc20 activity and mitotic progression.

Nuclear PTEN regulates the APC-CDH1 tumor suppressive complex in a phosphatase-independent manner

PTEN is a frequently mutated tumor suppressor gene that opposes the PI3K/AKT pathway through dephosphorylation of phosphoinositide-3,4,5-triphosphate. Recently, nuclear compartmentalization of PTEN was found as a key component of its tumor-suppressive activity; however its nuclear function remains poorly defined. Here we show that nuclear PTEN interacts with APC/C, promotes APC/C association with CDH1, and thereby enhances the tumor-suppressive activity of the APC-CDH1 complex. We find that nuclear exclusion but not phosphatase inactivation of PTEN impairs APC-CDH1. This nuclear function of PTEN provides a straightforward mechanistic explanation for the fail-safe cellular senescence response elicited by acute PTEN loss and the tumor-suppressive activity of catalytically inactive PTEN. Importantly, we demonstrate that PTEN mutant and PTEN null states are not synonymous as they are differentially sensitive to pharmacological inhibition of APC-CDH1 targets such as PLK1 and Aurora kinases. This finding identifies a strategy for cancer patient stratification and, thus, optimization of targeted therapies. PAPERCLIP:

Role of the tumor suppressor RASSF1A in Mst1-mediated apoptosis.

Mammalian sterile 20-like kinase 1 (Mst1) is activated by both caspase-mediated cleavage and phosphorylation in response to apoptotic stimuli, including Fas ligation. Here, we examined the possible role of the tumor suppressor RASSF1A in Mst1 activation and Mst1-mediated apoptosis induced by death receptor signaling. Immunoprecipitation and immunofluorescence analyses revealed that Mst1 was associated with RASSF1A in cultured mammalian cells, with both proteins colocalizing to microtubules throughout the cell cycle. Whereas purified recombinant RASSF1A inhibited the kinase activity of purified recombinant Mst1 in vitro, overexpression of RASSF1A increased the kinase activity of Mst1 in intact cells, suggesting that regulation of Mst1 by RASSF1A in vivo involves more than the simple association of the two proteins. Both the activation of Mst1 and the incidence of apoptosis induced by Fas ligation were markedly reduced in cells depleted of RASSF1A by RNA interference and were increased by restoration of RASSF1A expression in RASSF1A-deficient cells. Moreover, the stimulatory effect of RASSF1A overexpression on Fas-induced apoptosis was inhibited by depletion of Mst1. These findings indicate that RASSF1A facilitates Mst1 activation and thereby promotes apoptosis induced by death receptor signaling.

The tumour suppressor RASSF1A promotes MDM2 self‐ubiquitination by disrupting the MDM2–DAXX–HAUSP complex

The tumour suppressor p53, which accumulates in response to DNA damage and induces cell‐cycle arrest and apoptosis, has a key function in the maintenance of genome integrity. Under normal conditions, the antiproliferative effects of p53 are inhibited by MDM2, a ubiquitin ligase that promotes p53 ubiquitination and degradation. MDM2 is also self‐ubiquitinated and degraded. Here, we show that the tumour suppressor RASSF1A regulates G1–S cell‐cycle progression in a p53‐dependent manner by promoting MDM2 self‐ubiquitination and preventing p53 degradation. Importantly, RASSF1A associates with MDM2 and death‐domain‐associated protein (DAXX) in the nucleus, thereby disrupting the interactions between MDM2, DAXX, and the deubiquitinase, HAUSP, and enhancing the self‐ubiquitin ligase activity of MDM2. Moreover, RASSF1A partially contributes to p53‐dependent checkpoint activation at early time points in response to DNA damage. These findings reveal a new and important function for RASSF1A in regulating the p53–MDM2 pathway.

Skp2 regulates the antiproliferative function of the tumor suppressor RASSF1A via ubiquitin-mediated degradation at the G1-S transition.

The tumor suppressor RASSF1A is inactivated in many human cancers and is implicated in regulation of microtubule stability, cell cycle progression and apoptosis. However, the precise mechanisms of RASSF1A action and their regulation remain unclear. Here we show that Skp2, an oncogenic subunit of the Skp1–Cul1–F–box ubiquitin ligase complex, interacts with, ubiquitinates, and promotes the degradation of RASSF1A at the G1–S transition of the cell cycle. This Skp2-dependent destruction of RASSF1A requires phosphorylation of the latter on serine-203 by cyclin D–cyclin-dependent kinase 4. Interestingly, mutation of RASSF1A-phosphorylation site Ser203 to alanine results in a delay in cell cycle progression from G1 to S phase. Moreover, enforced expression of Skp2 abolishes the inhibitory effect of RASSF1A on cell proliferation. Finally, the delay in G1–S progression after Skp2 removal is normalized by depletion of RASSF1A. These findings suggest that the Skp2-mediated degradation of RASSF1A plays an important role in cell proliferation and survival.

Vulnerabilities of PTEN–TP53-Deficient Prostate Cancers to Compound PARP–PI3K Inhibition

UNLABELLED Prostate cancer is the most prevalent cancer in males, and treatment options are limited for advanced forms of the disease. Loss of the PTEN and TP53 tumor suppressor genes is commonly observed in prostate cancer, whereas their compound loss is often observed in advanced prostate cancer. Here, we show that PARP inhibition triggers a p53-dependent cellular senescence in a PTEN-deficient setting in the prostate. Surprisingly, we also find that PARP-induced cellular senescence is morphed into an apoptotic response upon compound loss of PTEN and p53. We further show that superactivation of the prosurvival PI3K-AKT signaling pathway limits the efficacy of a PARP single-agent treatment, and that PARP and PI3K inhibitors effectively synergize to suppress tumorigenesis in human prostate cancer cell lines and in a Pten/Trp53-deficient mouse model of advanced prostate cancer. Our findings, therefore, identify a combinatorial treatment with PARP and PI3K inhibitors as an effective option for PTEN-deficient prostate cancer. SIGNIFICANCE The paucity of therapeutic options in advanced prostate cancer displays an urgent need for the preclinical assessment of novel therapeutic strategies. We identified differential therapeutic vulnerabilities that emerge upon the loss of both PTEN and p53, and observed that combined inhibition of PARP and PI3K provides increased efficacy in hormone-insensitive advanced prostate cancer.

Aurora B–Mediated Phosphorylation of RASSF1A Maintains Proper Cytokinesis by Recruiting Syntaxin16 to the Midzone and Midbody

Aurora B is critically involved in ensuring proper cytokinesis and maintaining genomic stability. The tumor suppressor RASSF1A regulates cell cycle progression by regulating mitotic progression, G(1)-S transition, and microtubule stability. We previously reported that both Aurora A and Aurora B phosphorylate RASSF1A, and showed that phosphorylation of RASSF1A by Aurora A blocks the inhibitory function of RASSF1A toward anaphase-promoting complex-Cdc20. However, the role of Aurora B-mediated RASSF1A phosphorylation remains unknown. Here, we show that phosphorylation of RASSF1A on Ser203 by Aurora B during late mitosis has a critical role in regulating cytokinesis. Notably, RASSF1A interacts with Syntaxin16, a member of the t-SNARE family, at the midzone and midbody during late mitosis. Aurora B is required for this interaction and for the subsequent recruitment of Syntaxin16 to the midzone and midbody, a prerequisite for the successful completion of cytokinesis. Furthermore, Aurora B depletion results in a failure of Syntaxin16 to properly localize to the midzone and midbody, a mislocalization that was prevented by overexpression of the phosphomimetic RASSF1A (S203D) mutant. Finally, either depletion of Syntaxin16 or expression of the nonphosphorylatable RASSF1A (S203A) mutant results in cytokinesis defects. Our findings implicate Aurora B-mediated phosphorylation of RASSF1A in the regulation of cytokinesis.

Aurora A Regulates Prometaphase Progression by Inhibiting the Ability of RASSF1A to Suppress APC-Cdc20 Activity

The Aurora (Ipl) kinase family plays important roles in the regulation of mitosis and tumorigenesis. The tumor suppressor RASSF1A controls mitotic progression by regulating anaphase-promoting complex (APC)-Cdc20 activity and microtubule stability, but the mechanism by which this action is regulated has not been previously established. Here, we show that Aurora A and B associate with and phosphorylate RASSF1A on serine 203 in vivo at different times and in different subcellular compartments during mitosis. Notably, both depletion of Aurora A by RNA interference and expression of a nonphosphorylatable RASSF1A (S203A) mutant gene led to a marked delay in prometaphase progression. This is likely because of the failure of RASSF1A to dissociate from Cdc20, constitutive inhibition of APC-Cdc20, and accumulation of mitotic cyclins. In contrast, the delay in prometaphase progression caused by Aurora A depletion was largely normalized by phosphomimetic RASSF1A (S203D). Finally, RASSF1A phosphorylation on serine 203 was up-regulated in Aurora A-overexpressing human tumors. These findings indicate that Aurora A plays a critical role in RASSF1A-APC-Cdc20 regulatory mechanisms that control normal prometaphase progression and that are involved in tumorigenesis. [Cancer Res 2009;69(6):2314-23.