Naohiro Katagiri scite author profile

The 5S ribonucleoprotein particle (RNP) complex, consisting of RPL11, RPL5, and 5S rRNA, is implicated in p53 regulation under ribotoxic stress. Here, we show that the 5S RNP contributes to p53 activation and promotes cellular senescence in response to oncogenic or replicative stress. Oncogenic stress accelerates rRNA transcription and replicative stress delays rRNA processing, resulting in RPL11 and RPL5 accumulation in the ribosome-free fraction, where they bind MDM2. Experimental upregulation of rRNA transcription or downregulation of rRNA processing, mimicking the nucleolus under oncogenic or replicative stress, respectively, also induces RPL11-mediated p53 activation and cellular senescence. We demonstrate that exogenous expression of certain rRNA-processing factors rescues the processing defect, attenuates p53 accumulation, and increases replicative lifespan. To summarize, the nucleolar-5S RNP-p53 pathway functions as a senescence inducer in response to oncogenic and replicative stresses.

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RNA content in the nucleolus alters p53 acetylation via MYBBP1A

Kuroda

Murayama

Katagiri

et al. 2011

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A number of external and internal insults disrupt nucleolar structure, and the resulting nucleolar stress stabilizes and activates p53. We show here that nucleolar disruption induces acetylation and accumulation of p53 without phosphorylation. We identified three nucleolar proteins, MYBBP1A, RPL5, and RPL11, involved in p53 acetylation and accumulation. MYBBP1A was tethered to the nucleolus through nucleolar RNA. When rRNA transcription was suppressed by nucleolar stress, MYBBP1A translocated to the nucleoplasm and facilitated p53-p300 interaction to enhance p53 acetylation. We also found that RPL5 and RPL11 were required for rRNA export from the nucleolus. Depletion of RPL5 or RPL11 blocked rRNA export and counteracted reduction of nucleolar RNA levels caused by inhibition of rRNA transcription. As a result, RPL5 or RPL11 depletion inhibited MYBBP1A translocation and p53 activation. Our observations indicated that a dynamic equilibrium between RNA generation and export regulated nucleolar RNA content. Perturbation of this balance by nucleolar stress altered the nucleolar RNA content and modulated p53 activity.

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The nucleolar protein nucleophosmin is essential for autophagy induced by inhibiting Pol I transcription

Katagiri

Kuroda

Kishimoto

et al. 2015

Sci Rep

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Various cellular stresses activate autophagy, which is involved in lysosomal degradation of cytoplasmic materials for maintaining nutrient homeostasis and eliminating harmful components. Here, we show that RNA polymerase I (Pol I) transcription inhibition induces nucleolar disruption and autophagy. Treatment with autophagy inhibitors or siRNA specific for autophagy-related (ATG) proteins inhibited autophagy but not nucleolar disruption induced by Pol I transcription inhibition, which suggested that nucleolar disruption was upstream of autophagy. Furthermore, treatment with siRNA specific for nucleolar protein nucleophosmin (NPM) inhibited this type of autophagy. This showed that NPM was involved in autophagy when the nucleolus was disrupted by Pol I inhibition. In contrast, NPM was not required for canonical autophagy induced by nutrient starvation, as it was not accompanied by nucleolar disruption. Thus, our results revealed that, in addition to canonical autophagy, there may be NPM-dependent autophagy associated with nucleolar disruption.

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Novel Nucleolar Pathway Connecting Intracellular Energy Status with p53 Activation

Kumazawa

Nishimura

Kuroda

et al. 2011

Journal of Biological Chemistry

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In response to a shortage of intracellular energy, mammalian cells reduce energy consumption and induce cell cycle arrest, both of which contribute to cell survival. Here we report that a novel nucleolar pathway involving the energy-dependent nucleolar silencing complex (eNoSC) and Myb-binding protein 1a (MYBBP1A) is implicated in these processes. Namely, in response to glucose starvation, eNoSC suppresses rRNA transcription, which results in a reduction in nucleolar RNA content. As a consequence, MYBBP1A, which is anchored to the nucleolus via RNA, translocates from the nucleolus to the nucleoplasm. The translocated MYBBP1A induces acetylation and accumulation of p53 by enhancing the interaction between p300 and p53, which eventually leads to the cell cycle arrest (or apoptosis). Taken together, our results indicate that the nucleolus works as a sensor that transduces the intracellular energy status into the cell cycle machinery.Intracellular energy balance is important for cell survival. In response to nutrient or environmental stresses that cause reduction in the intracellular energy level, mammalian cells sense the intrinsic energy status and attempt to restore bioenergetic homeostasis through compensatory changes in the regulation of intermediate metabolic processes. One such mechanism is the reduction of ribosome biosynthesis, a major biosynthetic and energy-consuming process in mammalian cells, whereas the other mechanism is the arrest of cell proliferation. The LKB1-AMP-activated protein kinase (AMPK) 3 pathway is reportedly involved in both regulatory processes (1-5). During energy starvation or glucose deprivation, when the cellular AMP/ATP ratio is increased, the LKB1-AMPK pathway is activated. This signaling in turn inhibits the mammalian target of rapamycin (mTOR)/p70 S6 kinase activity that is required for rapid and sustained serum-induced ribosomal biosynthesis (2). In addition to this regulation, AMPK, which is reportedly activated in response to reduced energy level, phosphorylates and activates p53, which leads to G 1 cell cycle arrest (6). Inhibition of mTOR by AMPK and G 1 cell cycle arrest by AMPK via p53 activation suppresses energy expenditure and protects cells from energy deprivation-induced apoptosis (4, 5).On the other hand, a recent study in our laboratory revealed that glucose deprivation also reduces rRNA synthesis, which leads to down-regulation of ribosome biosynthesis in HeLa cells lacking the LKB1-AMPK pathway (7). We found that a novel nucleolar protein, nucleomethylin (NML), forms an energy-dependent nucleolar silencing complex (eNoSC) with SIRT1 and SUV39H1 and functions in this process. Our results suggest that an energy-dependent change in the NAD ϩ /NADH ratio regulates eNoSC, allowing the complex to couple the changing energy status with the level of rRNA transcription by regulating the epigenetic status of rRNA clusters. eNoSC promotes the restoration of energy balance and protects cells from energy deprivation-induced apoptosis (7).With regard to p53 activation, several...

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Gradual reduction in rRNA transcription triggers p53 acetylation and apoptosis via MYBBP1A

Kumazawa

Nishimura

Katagiri

et al. 2015

Sci Rep

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The nucleolus, whose primary function is ribosome biogenesis, plays an essential role in p53 activation. Ribosome biogenesis is inhibited in response to cellular stress and several nucleolar proteins translocate from the nucleolus to the nucleoplasm, where they activate p53. In this study, we analysed precisely how impaired ribosome biogenesis regulates the activation of p53 by depleting nucleolar factors involved in rRNA transcription or rRNA processing. Nucleolar RNA content decreased when rRNA transcription was inhibited. In parallel with the reduced levels of nucleolar RNA content, the nucleolar protein Myb-binding protein 1 A (MYBBP1A) translocated to the nucleoplasm and increased p53 acetylation. The acetylated p53 enhanced p21 and BAX expression and induced apoptosis. In contrast, when rRNA processing was inhibited, MYBBP1A remained in the nucleolus and nonacetylated p53 accumulated, causing cell cycle arrest at the G1 phase by inducing p21 but not BAX. We propose that the nucleolus functions as a stress sensor to modulate p53 protein levels and its acetylation status, determining cell fate between cell cycle arrest and apoptosis by regulating MYBBP1A translocation.

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