Project description:The integrity of the nuclear envelope (NE) is essential to maintain the structural stability of the nucleus. Rupture of the NE has been frequently observed in cancer cells, especially in the context of mechanical challenges, such as physical confinement and migration. However, spontaneous NE rupture events have also been described, without any obvious physical challenges to the cell. The molecular mechanism(s) of these spontaneous NE rupture events remain to be explored. Here, we show that DNA damage and subsequent ATR activation can lead to NE rupture. Upon DNA damage, Lamin A/C is phosphorylated in an ATR-dependent manner, leading to changes in lamina assembly and, ultimately, NE rupture. In addition, we show that cancer cells with intrinsic DNA repair defects undergo frequent events of DNA damage-induced NE rupture, which renders them extremely sensitive to further NE perturbations. Exploiting this NE vulnerability could provide a new angle to complement traditional, DNA damage-based chemotherapy.

Project description:The integrity of the nuclear envelope (NE) is essential to maintain the structural stability of the nucleus. Rupture of the NE has been frequently observed in cancer cells, especially in the context of mechanical challenges, such as physical confinement and migration. However, spontaneous NE rupture events have also been described, without any obvious physical challenges to the cell. The molecular mechanism(s) of these spontaneous NE rupture events remain to be explored. Here, we show that DNA damage and subsequent ATR activation can lead to NE rupture. Upon DNA damage, Lamin A/C is phosphorylated in an ATR-dependent manner, leading to changes in lamina assembly and, ultimately, NE rupture. In addition, we show that cancer cells with intrinsic DNA repair defects undergo frequent events of DNA damage-induced NE rupture, which renders them extremely sensitive to further NE perturbations. Exploiting this NE vulnerability could provide a new angle to complement traditional, DNA damage-based chemotherapy.

Project description:In animals, mitosis involves the breakdown of the nucleus. The reassembly of a nucleus after mitosis requires the reformation of the nuclear envelope around a single mass of chromosomes. This process requires Ankle2 (also known as LEM4 in humans) which interacts with PP2A and promotes the function of Barrier-to-Autointegration Factor (BAF). Upon dephosphorylation, BAF dimers cross-bridge chromosomes and bind lamins and transmembrane proteins of the reassembling nuclear envelope. How Ankle2 functions in mitosis is incompletely understood. Using a combination of approaches in Drosophila, along with structural modeling, we provide several lines of evidence that suggest that Ankle2 is a regulatory subunit of PP2A, explaining how it promotes BAF dephosphorylation. In addition, we discovered that Ankle2 interacts with the endoplasmic reticulum protein Vap33, which is required for Ankle2 localization at the reassembling nuclear envelope during telophase. We identified the interaction sites of PP2A and Vap33 on Ankle2. Through genetic rescue experiments, we show that the Ankle2/PP2A interaction is essential for the function of Ankle2 in nuclear reassembly and that the Ankle2/Vap33 interaction also promotes this process. Our study sheds light on the molecular mechanisms of post-mitotic nuclear reassembly and suggests that the endoplasmic reticulum is not merely a source of membranes in the process, but also provides localized enzymatic activity.

Project description:Topoisomerase 1 (Top1) removes supercoils from DNA during replication and transcription, is critical for mitotic progression to the G1 phase, and ensures DNA topology. Tyrosyl-DNA phosphodiesterase 1 (TDP1) mediates the removal of trapped Top1-DNA covalent complexes (Top1ccs). Here, we identify CDK1-dependent phosphorylation of TDP1 at S61 residue during mitosis. TDP1 defective for S61 phosphorylation (TDP1S61A) is trapped on the mitotic chromosomes, triggering DNA damage and mitotic defects. Moreover, we show that Top1cc repair in mitosis occurs via MUS81-dependent mitotic DNA repair mechanism. Replication stress (RS) induced by Camptothecin (CPT) or Aphidicolin (APH) leads to TDP1S61A enrichment at common fragile sites (CFSs), which over-stimulates MUS81-dependent chromatid breaks, anaphase bridges, and micronuclei, ultimately culminating in 53BP1 nuclear bodies in the G1-phase. Our findings provide a new insight into the cell cycle-dependent regulation of TDP1 dynamics forthe repair of trapped Top1ccs during mitosis that prevents genomic instability following RS.

Project description:Replication stress (RS) can lead to the formation of DNA double strand breaks (DSBs) and threatens genomic stability. Homologous recombination (HR) pathway is essential to prevent RS and repairs associated DSBs. Upon excessive RS or HR deficiency, DSBs can persist in mitosis, wherein DNA damage response and DSB repair are inhibited. Thus, the fate of DSBs remaining or arising in mitosis remains poorly understood. Here we unwind two distinct roles of the polymerase theta (Polθ) in the maintenance of genomic stability. First, by mass spectrometry and foci screening we show that, in interphase, Polθ interacts with HR proteins and its recruitment to IR-induced DSBs is highly dependent of HR pathway. Secondly, we identify a novel role of the Polθ in counteracting the deleterious effect of DSBs in mitosis. Contrariwise to its interphase recruitment, Polθ recruitment to mitotic DSBs is HR-independent and triggered by mitotic kinases activities. In response to RS or HR deficiency, Polθ localizes to DSBs throughout mitosis and forms nuclear bodies in the G1 daughter cells. In addition, Polθ localizes to centromeres and acentric fragments and activates the mitotic checkpoint. Conversely, Polθ deficiency leads to premature anaphase onset, resulting in an accumulation of mitotic abnormalities. Strikingly, the specific inhibition of Polθ in mitosis kills HR-deficient cells, identifying mitotic Polθ function as its key role in maintaining genome integrity. Our results pinpoint to the mitotic Polθ-mediated replication stress response pathway as a unique vulnerability of cancer cells, with great potential for further investigation.

Project description:Mitosis in eukaryotes involves reorganization of the nuclear envelope (NE) and microtubule-organizing centres (MTOCs). During male gametogenesis in Plasmodium, the causative agent of malaria, mitosis is exceptionally rapid and highly divergent. Within 8 min, the haploid male gametocyte genome undergoes three replication cycles (1N to 8N), while maintaining an intact NE. Axonemes assemble in the cytoplasm and connect to a bipartite MTOC-containing nuclear pole (NP) and cytoplasmic basal body, producing eight flagellated gametes. The mechanisms coordinating NE remodelling, MTOC dynamics, and flagellum assembly remain poorly understood. We identify the SUN1-ALLAN complex as a novel mediator of NE remodelling and bipartite MTOC coordination during Plasmodium male gametogenesis. SUN1, a conserved NE protein, localizes to dynamic loops and focal points at the nucleoplasmic face of the spindle poles. ALLAN, a divergent allantoicase, has a location like that of SUN1, and these proteins form a unique complex, detected by live-cell imaging, ultrastructural expansion microscopy, and interactomics. Deletion of either SUN1 or ALLAN genes disrupts nuclear MTOC organization, leading to basal body mis-segregation, defective spindle assembly, and impaired spindle microtubule kinetochore attachment, but axoneme formation remains intact. Ultrastructural analysis revealed nuclear and cytoplasmic MTOC miscoordination, producing aberrant flagellated gametes lacking nuclear material. These defects block development in the mosquito and parasite transmission, highlighting the essential functions of this complex.

Project description:The influence of mono-ubiquitylation of histone H2B (H2Bub) on transcription via nucleosome reassembly has been widely documented. Recently, it has also been shown that H2Bub promotes recovery from replication stress; however, the underling molecular mechanism remains unclear. Here, we show that H2B ubiquitylation coordinates activation of the intra-S replication checkpoint and chromatin re-assembly, in order to limit fork progression and DNA damage in the presence of replication stress. In particular, we show that the absence of H2Bub affects replication dynamics (enhanced fork progression and reduced origin firing), leading to γH2A accumulation and increased hydroxyurea sensitivity. Further genetic analysis indicates a role for H2Bub in transducing Rad53 phosphorylation. Concomitantly, we found that a change in replication dynamics is not due to a change in dNTP level, but is mediated by reduced Rad53 activation and destabilization of the RecQ helicase Sgs1 at the fork. Furthermore, we demonstrate that H2Bub facilitates the dissociation of the histone chaperone Asf1 from Rad53, and nucleosome reassembly behind the fork is compromised in cells lacking H2Bub. Taken together, these results indicate that the regulation of H2B ubiquitylation is a key event in the maintenance of genome stability, through coordination of intra-S checkpoint activation, chromatin assembly and replication fork progression. S.cerevisiae oligonucleotide microarrays were provided by Affymetrix (S.cerevisiae Tiling 1.0R, P/N 900645). BrdU and proteins ChIP-chip analyses were carried out as described (Fachinetti et al., M Cell, 2010).

Project description:Chromosome replication and transcription occur within a complex nuclear milieu whose functional subdomains are only beginning to be mapped out. The nuclear envelope (NE) generally interacts with heterochromatic regions of the genome that are inherently difficult to replicate. Here we delineate compositionally and functionally distict domains of the fission yeast NE, focusing on the NE regions specifically enriched for the inner NE protein, Bqt4, or the conserved lamin interacting domain protein, Lem2. Bqt4 is relatively mobile around the NE and acts in two capacities. First, Bqt4 is required for tethering two key heterochromatic regions, the chromosome termini and the mat locus, to the NE specifically while these regions are undergoing DNA replication. This positioning is required for robust replication and heterochromatin assembly in the wake of the replication fork. Second, Bqt4 mobilizes a subset of Lem2 molecules around the NE, where Lem2/Bqt4 promote pericentric heterochromatin maintenance. Opposing Bqt4-dependent Lem2 mobility are factors that stabilize Lem2 at its most abundant localization site beneath the centrosome, where Lem2 plays a crucial role in kinetochore maintenance. Our data prompt a model in which Bqt4-rich nuclear subdomains are ‘safe zones’ in which collisions between transcription and replication are averted and heterochromatin is reassembled faithfully following replication.

Project description:Animal cells dismantle their nuclear envelope (NE) at the beginning and reconstruct it at the end of mitosis. This process is closely coordinated with spindle pole organization: poles enlarge at mitotic onset and reduce in size as mitosis concludes. The significance of this coordination remains unknown. Here, we demonstrate that Aurora A maintains a pole-localized protein NuMA in a dynamic state during anaphase. Without Aurora A activity, NuMA shifts from a dynamic to a solid state and abnormally accumulates at the poles, causing the segregated chromosome sets to bend around the NuMA-enriched poles. NuMA localization at the poles relies on interactions with dynein/dynactin, its coiled-coil domain, and an intrinsically disordered region (IDR). Mutagenesis experiments revealed that cation- interactions within IDR are key for NuMA pole localization, while glutamine residues trigger the solid-state transition of NuMA upon Aurora A inhibition. We propose that maintaining the proper material properties of the spindle poles is a key step in choreographing accurate organization of the nucleus and genome post-mitosis.

Project description:The nuclear pore complex (NPC) is a cornerstone of eukaryotic cell functionality, orchestrating the nucleocytoplasmic shuttling of macromolecules. Here, we report that PNET1, a transmembrane nucleoporin conserved between humans and plants, is a dynamic, adaptable NPC component, exclusively expressed in actively dividing cells. PNET1's selective integration is crucial for rapid cell growth in highly proliferative meristem and callus tissues in plants, as well as in lung cancer tissues in humans. We demonstrated that PNET1 acts as a pivotal tuner to coordinate mitotic disassembly and post-mitotic reassembly of the NPC during cell cycle. PNET1 hyper-phosphorylation disrupts its interaction with NPC scaffold, promoting NPC disintegration and nuclear membrane breakdown to trigger mitosis. Nascent, unphosphorylated PNET1 restores NPC interactions and recruits NPC scaffold for its reassembly during nuclear membrane rebuilding in daughter cells, continuing the cycle. Our findings reveal a previously uncharted mechanism that ensures rapid cell proliferation via exploiting an on-demand nucleoporin.