Project description:Entry into mitosis is triggered by mitotic kinases that phosphorylate multiple proteins to induce profound cellular changes including nuclear envelope breakdown, chromosome condensation and spindle assembly. Conversely, mitotic exit requires protein dephosphorylation as cells return to their interphase organization. Protein Phosphatase 2A in complex with its B55/Tws regulatory subunit (PP2A-B55) is known to play a crucial role in this transition. However, the precise events and substrates that it regulates are incompletely understood. We used proteomic approaches in Drosophila to identify proteins that interact with PP2A-B55 and are dephosphorylated in a PP2A-B55 dependent manner. Among several candidates, we identified Otefin (also known as Emerin) as a target of PP2A-B55 in the process of nuclear envelope reformation after mitosis. Emerin is a protein of the inner nuclear membrane that interacts with the DNA-binding protein Barrier-to-Autointegration Factor (BAF) via a LEM domain. Our results indicate that phosphorylation of Emerin at Ser50 and Ser54 near its LEM domain negatively regulates its association with BAF, Lamin and additional Emerin. Using live imaging, we show that dephosphorylation of Emerin at the identified sites determines the timing of nuclear envelope reformation. Genetic rescue experiments indicate that this regulation is required in vivo during embryonic development. Phosphoregulation of the Emerin-BAF complex formation by PP2A-B55 appears as a key event of mitotic exit that is likely to be conserved across species.

Project description:Entry into mitosis is triggered by mitotic kinases that phosphorylate multiple proteins to induce profound cellular changes including nuclear envelope breakdown, chromosome condensation and spindle assembly. Conversely, mitotic exit requires protein dephosphorylation as cells return to their interphase organization. Protein Phosphatase 2A in complex with its B55/Tws regulatory subunit (PP2A-B55) is known to play a crucial role in this transition. However, the precise events and substrates that it regulates are incompletely understood. We used proteomic approaches in Drosophila to identify proteins that interact with PP2A-B55 and are dephosphorylated in a PP2A-B55 dependent manner. Among several candidates, we identified Otefin (also known as Emerin) as a target of PP2A-B55 in the process of nuclear envelope reformation after mitosis. Emerin is a protein of the inner nuclear membrane that interacts with the DNA-binding protein Barrier-to-Autointegration Factor (BAF) via a LEM domain. Our results indicate that phosphorylation of Emerin at Ser50 and Ser54 near its LEM domain negatively regulates its association with BAF, Lamin and additional Emerin. Using live imaging, we show that dephosphorylation of Emerin at the identified sites determines the timing of nuclear envelope reformation. Genetic rescue experiments indicate that this regulation is required in vivo during embryonic development. Phosphoregulation of the Emerin-BAF complex formation by PP2A-B55 appears as a key event of mitotic exit that is likely to be conserved across species.

Project description:Entry into mitosis is triggered by mitotic kinases that phosphorylate multiple proteins to induce profound cellular changes including nuclear envelope breakdown, chromosome condensation and spindle assembly. Conversely, mitotic exit requires protein dephosphorylation as cells return to their interphase organization. Protein Phosphatase 2A in complex with its B55/Tws regulatory subunit (PP2A-B55) is known to play a crucial role in this transition. However, the precise events and substrates that it regulates are incompletely understood. We used proteomic approaches in Drosophila to identify proteins that interact with PP2A-B55 and are dephosphorylated in a PP2A-B55 dependent manner. Among several candidates, we identified Otefin (also known as Emerin) as a target of PP2A-B55 in the process of nuclear envelope reformation after mitosis. Emerin is a protein of the inner nuclear membrane that interacts with the DNA-binding protein Barrier-to-Autointegration Factor (BAF) via a LEM domain. Our results indicate that phosphorylation of Emerin at Ser50 and Ser54 near its LEM domain negatively regulates its association with BAF, Lamin and additional Emerin. Using live imaging, we show that dephosphorylation of Emerin at the identified sites determines the timing of nuclear envelope reformation. Genetic rescue experiments indicate that this regulation is required in vivo during embryonic development. Phosphoregulation of the Emerin-BAF complex formation by PP2A-B55 appears as a key event of mitotic exit that is likely to be conserved across species.

Project description:As a dividing cell exits mitosis and daughter cells enter interphase, many proteins must be dephosphorylated. The protein phosphatase 2A (PP2A) with its B55 regulatory subunit plays a crucial role in this transition, but the identity of its substrates and how their dephosphorylation promotes mitotic exit are largely unknown. We conducted a maternal-effect screen in Drosophila melanogaster to identify genes that function with PP2A-B55/Tws in the cell cycle. We found that eggs that receive reduced levels of Tws and of components of the nuclear envelope (NE) often fail development, concomitant with NE defects following meiosis and in syncytial mitoses. Our mechanistic studies using Drosophila cells indicate that PP2A-Tws promotes nuclear envelope reformation (NER) during mitotic exit by dephosphorylating BAF and suggests that PP2A-Tws targets additional NE components, including Lamin and Nup107. This work establishes Drosophila as a powerful model to further dissect the molecular mechanisms of NER and suggests additional roles of PP2A-Tws in the completion of meiosis and mitosis.

Project description:Progression through the cell cycle is controlled by regulated and abrupt changes in phosphorylation1. Mitotic entry is initiated by increased phosphorylation of mitotic proteins, a process driven by kinases2, whereas mitotic exit is achieved by counteracting dephosphorylation, a process driven by phosphatases, especially PP2A:B553. Although the role of kinases in mitotic entry is well established, recent data have shown that mitosis is only successfully initiated when the counterbalancing phosphatases are also inhibited4. Inhibition of PP2A:B55 is achieved by the intrinsically disordered proteins ARPP195,6 and FAM122A7. Despite their critical roles in mitosis, the mechanisms by which they achieve PP2A:B55 inhibition is unknown. Here, we report the single-particle cryo-electron microscopy structures of PP2A:B55 bound to phosphorylated ARPP19 and FAM122A. Consistent with our complementary NMR spectroscopy studies, both intrinsically disordered proteins bind PP2A:B55, but do so in highly distinct manners, leveraging multiple distinct binding sites on B55. Our extensive structural, biophysical and biochemical data explain how substrates and inhibitors are recruited to PP2A:B55 and provide a molecular roadmap for the development of therapeutic interventions for PP2A:B55-related diseases.

Project description:Progression through the cell cycle is controlled by regulated and abrupt changes in phosphorylation.1 Mitotic entry is initiated by increased phosphorylation of mitotic proteins, a process driven by kinases,2 while mitotic exit is achieved by counteracting dephosphorylation, a process driven by phosphatases, especially PP2A:B55.3 While the role of kinases in mitotic entry is well-established, recent data have shown that mitosis is only successfully initiated when the counterbalancing phosphatases are also inhibited.4 For PP2A:B55, inhibition is achieved by the two intrinsically disordered proteins (IDPs), ARPP19 (phosphorylation-dependent)6,7 and FAM122A5 (inhibition is phosphorylation-independent). Despite their critical roles in mitosis, the mechanisms by which they achieve PP2A:B55 inhibition is unknown. Here, we report the cryo-electron microscopy structures of PP2A:B55 bound to phosphorylated ARPP19 and FAM122A. Consistent with our complementary NMR spectroscopy studies both IDPs bind PP2A:B55, but do so in highly distinct manners, unexpectedly leveraging multiple distinct binding sites on B55. Our extensive structural, biophysical and biochemical data explain how substrates and inhibitors are recruited to PP2A:B55 and provides a molecular roadmap for the development of therapeutic interventions for PP2A:B55 related diseases.

Project description:Emerin, a conserved LEM-domain protein, is among the few nuclear membrane proteins for which extensive basic knowledge--biochemistry, partners, functions, localizations, posttranslational regulation, roles in development and links to human disease--is available. This review summarizes emerin and its emerging roles in nuclear "lamina" structure, chromatin tethering, gene regulation, mitosis, nuclear assembly, development, signaling and mechano-transduction. We also highlight many open questions, exploration of which will be critical to understand how this intriguing nuclear membrane protein and its "family" influence the genome.

Project description:Many types of cancer cells exhibit abnormal nuclear shapes induced by various molecular changes. However, whether reactive oxygen species (ROS) induce nuclear deformation has not been fully addressed. Here, we show that hydrogen peroxide (H2O2) treatment induced concentration-dependent alterations in nuclear shape that were abolished by pretreatment with the antioxidant N-acetyl-L-cysteine or by catalase overexpression. Interestingly, treatment with H2O2 induced nuclear shape alterations significantly more frequently in mitotic cells than in asynchronous cells, suggesting that H2O2 mainly affects nuclear envelope disassembly and/or reassembly processes. Because protein phosphatase 2 A (PP2A) activity is reported to be involved in nuclear envelope reassembly during mitosis, we investigated the possible involvement of PP2A. Indeed, H2O2 reduced the activity of PP2A, an effect that was mimicked by the PP1 and PP2A inhibitor okadaic acid. Moreover, overexpression of PP2A but not PP1 or PP4 partially rescued H2O2-induced alterations in nuclear shape, indicating that the decrease in PP2A activity induced by H2O2 is specifically involved in the observed nuclear shape alterations. We further show that treatment of mitotic cells with H2O2 induced the mislocalization of BAF (barrier-to-autointegration factor), a substrate of PP2A, during telophase. This effect was associated with Lamin A/C mislocalization and was rescued by PP2A overexpression. Collectively, our findings suggest that H2O2 preferentially affects mitotic cells through PP2A inhibition, which induces the subsequent mislocalization of BAF and Lamin A/C during nuclear envelope reassembly, leading to the formation of an abnormal nuclear shape.

Project description:Sirtuin 2 (SIRT2) is an NAD-dependent deacetylase known to regulate microtubule dynamics and cell cycle progression. SIRT2 has also been implicated in the pathology of cancer, neurodegenerative diseases and progeria. Here, we show that SIRT2 depletion or overexpression causes nuclear envelope reassembly defects. We link this phenotype to the recently identified regulator of nuclear envelope reassembly ANKLE2. ANKLE2 acetylation at K302 and phosphorylation at S662 are dynamically regulated throughout the cell cycle by SIRT2 and are essential for normal nuclear envelope reassembly. The function of SIRT2 therefore extends beyond the regulation of microtubules to include the regulation of nuclear envelope dynamics.

Project description:Replication stress, if not effectively and timely addressed, could result in DNA damage in mitosis. However, it remains unknown the relationship between mitotic DNA damage and other mitotic events such as nuclear envelope (NE) breakdown and reassembly. Here we report that replication stress could generate NE rupture. Rather than de novo formation, the rupture per se is a result of nuclear envelope reassembly defect (NERD) in mitosis. Repair of mitotic DNA damage by DNA polymerase theta (Polθ), a key microhomology-mediated end joining (MMEJ) factor, suppresses NERD. Furthermore, exacerbated NERD is observed in multiple conditions of synthetic lethality, suggesting NERD might be a general consequence of synthetic lethality. In addition, genomic mapping of LADs identifies a population of RESS-LADs (replication stress-sensitive LADs). Replication stress causes the loss of CFSs at RESS-LADs, likely due to the sustained phosphorylation of Lamin A/C at the NE rupture sites. Altogether, our findings establish a novel link between replication stress-induced genome instability and nuclear vulnerability.