Project description:By using co-immunoprecipitation (Co-IP) assays with LBR-GFP-expressing mitotic cell extracts followed by MS, we identified the tether protein which linked the mitochondria and ER together in mitosis.

Project description:Plk1 is a key mitotic kinase that localizes to distinct subcellular structures to promote accurate mitotic progression. Plk1 recruitment depends on direct interaction between polo-box domain (PBD) on Plk1 and PBD binding motif (PBD BM) on the interactors. However, recent study showed that PBD BM alone is not enough for stable binding between CENP-U and Plk1 highlighting the complexity of the interaction which warrants further investigation. An important interactor for Plk1 during mitosis is the checkpoint protein BubR1. Plk1 bound to BubR1 via PBD interaction with pT620 phosphorylates BubR1 S676/T680 to promote BubR1-PP2A/B56 interaction. The BubR1-PP2A/B56 complex counteracts the destablizing effect on kinetochore-microtubule attachments by mitotic kinases to promote mitotic progression. Here we show that Plk1 phosphorylates T600/T608 on BubR1 and the double phosphorylation is critical for BubR1-Plk1 interaction. A similar mechanism for Plk1-Bub1 interaction also exists indicating a general principle for Plk1 kinetochore recruitment through self-priming. Mechanistically preventing BubR1 T600/T608 phosphorylation impairs chromosome congression and checkpoint silencing by reducing Plk1 and PP2A/B56 binding to BubR1. Increasing the binding affinity towards Plk1 and PP2A/B56 in BubR1 through protein engineering bypasses the requirement of T600/T608 phosphorylation for mitotic progression. These results reveal a new layer of regulation for accurate mitotic progression.

Project description:Polo-like kinase 1 (PLK1) protects against genome instability by ensuring timely and accurate mitotic cell division, and its activity is tightly regulated throughout the cell cycle. Although the pathways that initially activate PLK1 in G2 are well-characterized, the factors that directly regulate PLK1 in mitosis remain poorly understood. Here, we identify that human PLK1 activity is sustained by the DNA damage response kinase Checkpoint kinase 2 (Chk2) in mitosis. Chk2 directly phosphorylates PLK1 T210, a residue on its T-loop whose phosphorylation is essential for full PLK1 kinase activity. Loss of Chk2-dependent PLK1 activity causes increased mitotic errors, including chromosome misalignment, chromosome missegregation, and cytokinetic defects. Moreover, Chk2 deficiency increases sensitivity to PLK1 inhibitors, suggesting that Chk2 status may be an informative biomarker for PLK1 inhibitor efficacy. This work demonstrates that Chk2 sustains mitotic PLK1 activity and protects genome stability through discrete functions in interphase DNA damage repair and mitotic chromosome segregation.

Project description:CCCTC-binding factor (CTCF), a conserved and essential regulator of genome architecture bearing a unique complement of 11 zinc fingers (ZFs), has been reported to remain associated with chromatin throughout mitosis and has thus been proposed to act as a bookmark to ensure rapid reestablishment of chromatin structure after cell division. However, little is known about how CTCF is regulated during mitosis. Using a phospho-specific antibody, we found that phosphorylation of CTCF threonine 431, contained within an atypical ZF linker unique to vertebrate CTCF, is highly enriched in mitotic cells and that this phosphorylated form of CTCF is preferentially localized to mitotic chromosomes. We show that T431 mutations abolish the association of CTCF with mitotic chromatin, arguing that T431 phosphorylation is necessary for CTCF mitotic retention. Furthermore, mutation of the CTCF paralog BORIS to accommodate phosphorylation at the residue corresponding to CTCF T431 induces mitotic retention of BORIS. Our data support previous work demonstrating mitotic retention of CTCF and provide new insight into how CTCF remains associated with chromatin during mitosis. Furthermore, our results indicate that phosphorylation of ZF linkers is not exclusively associated with dissociation of ZF-containing proteins from DNA during mitosis.

Project description:Cell cycle progression into mitosis induce cellular rearrangements such as mitotic spindle formation, Golgi fragmentation, and nuclear envelope breakdown. Like certain retroviruses, nuclear delivery of HPV16 genomes is facilitated by these processes during entry into host cells by tethering of the viral DNA to mitotic chromosomes through the minor capsid protein L2. However, the mechanism of delivery onto and tethering to the condensed chromosomes is barely understood on a mechanistic level. To date it is unclear, which cellular proteins facilitate this process in interaction with L2 or how this process is regulated. Here, we discovered that HPV16 minor capsid protein L2 is phosphorylated during entry upon mitosis onset on conserved residues within the chromosome-binding region (CBR) that is responsible for nuclear import. The crucial L2 phosphorylations occurred sequentially by the master mitotic kinases CDK1 and PLK1. L2 phosphorylation, thus, not only regulated timely delivery of HPV16 vDNA to mitotic chromatin at mitosis onset, but also likely resulted in a conformational switch in L2 that allowed engagement of cellular proteins for this purpose. In summary, our work demonstrates for the first time a crucial role of mitotic kinases for nuclear entry of a DNA virus and provides important insights into the molecular mechanism of pathogen import into the nucleus during mitosis.

Project description:The goal of this experiment was to assess whether transcription happens during mitosis. For this, we isolated mitotic HeLa cells and treated them with a transcription inhibitor, ActD.

Project description:Chromatin is highly condensed and transcriptionally repressed during mitosis. Although it is established that some general transcription factors are inactivated by phosphorylation at mitosis, many details of mitotic transcriptional repression and its underlying mechanisms are largely unknown. Here, we provide evidence that as cells enter mitosis, genes with transcriptionally engaged RNA Polymerase II (Pol II) can continue transcription until the end of the gene to clear Pol II from mitotic chromatin. Using ChIP-Seq, we find that the transcriptional reinitiation process is globally impaired in early mitosis (prophase/prometaphase), with loss of TFIIB occupancy and nucleosome-free regions at promoters. Pretreatment of nocodazole-arrested mitotic cells with the P-TEFb inhibitor flavopiridol prevents the release of promoter-proximal engaged Pol II. Global nascent RNA sequencing and RNA fluorescence in situ hybridization (FISH) of individual genes demonstrate the existence of transcriptionally engaged Pol II in early mitosis. Chemical and mutational inhibition of P-TEFb in mitosis leads to delays in the progression of cell division. Together, our study reveals a novel mechanism for mitotic transcriptional repression whereby transcriptionally engaged Pol II can progress into productive elongation and finish transcription to allow proper cellular division. ChIP-Seq of Pol II of different forms, TFIIB, H3K4me3 in human HeLa cells at different cell cycle stages. ChIP-Seq of Pol II in HeLa mitotic cells with or without CDK9 inhibitor flavopiridol pretreatment. Nascent RNA-seq in asynchronous and arrested mitotic cells.

Project description:HeLa S3 cells in mitosis were selected by mitotic shake-off using an automated cell shaker (Eliassen et al. 2000, MCB)by Beth Alexander and Myra Hurt at Florida State University. This experiment set contains the complete set of 43K arrays for the first mitotic shake-off experiment described in Whitfield et al.(2002), (Shake).

Project description:Phosphorylation of Ser10 of histone H3 (H3S10p), together with the adjacent dimethylation of Lys9 (H3K9me2), has been proposed to function as a ‘phospho-methyl switch’ to regulate mitotic chromosome dynamics and control peripheral heterochromatin localization (1, 2). Despite of immensely understanding the regulation of H3S10 phosphorylation, how this modification temporarily masks the H3K9me2 mark during mitosis is poorly understood. Herein, we report that the master mitotic kinase Plk1 phosphorylates G9a at Thr1045 (pT1045) in vitro and in vivo at early mitosis. T1045p inhibits G9a catalytic activity, leading to decrease H3K9me2 levels. RNA-sequencing analysis showed that the phospho-mimic T1045 mutant of G9a (T1045E) compromised its repressive activity on several targeted genes, which was confirmed by luciferase reporter assays. Using genome-wide epigenomic technologies, we found that T1045E mutant displayed reduced H3K9me2 level, accompanied with increased chromatin accessibility, compared to the wild-type G9a cells. Finally, we found that T1045 phosphorylation could be removed by the phosphatase PP2A at late mitosis, which inversely reactivated G9a activity on H3K9me2 level, correlated with lower levels of H3S10p. Therefore, our result may provide a mechanistic explanation for ‘phospho-methyl switch’ and highlight the importance of Plk1 and PP2A-mediated dynamic regulation of G9a during mitosis.

Project description:FOXA1 serves as a crucial pioneer transcription factor in developmental processes, and plays a pivotal role as a mitotic bookmarking factor to perpetuate gene expression profiles and maintain cellular identity. During mitosis, the majority of FOXA1 dissociates from specific DNA binding sites and redistributes to non-specific binding sites, however, the regulatory mechanisms governing FOXA1's molecular dynamics in mitosis remain elusive. Here we show that mitotic kinase Aurora B regulates FOXA1's different DNA binding modes and the formation of the biomolecular condensate. Mechanistically, Aurora B kinase phosphorylates FOXA1 at Serine 221 (S221) to disrupt the specific, but not the non-specific, DNA binding. The phosphorylation of S221 also negatively regulates the FOXA1 condensates that require specific DNA binding. Importantly, perturbation of the dynamic phosphorylation impairs accurate gene reactivations and cell proliferation, suggesting that reversible mitotic protein phosphorylation emerges as a fundamental mechanism for the spatiotemporal control of mitotic bookmarking.