Tomoko Kojidani

Membrane proteins Bqt3 and -4 anchor telomeres to the nuclear envelope to ensure chromosomal bouquet formation

A screen identifies two more bouquet proteins required for meiotic telomere clustering: Bqt4 anchors the telomeres, whereas Bqt3 protects Bqt4 from degradation.

Two distinct repeat sequences of Nup98 nucleoporins characterize dual nuclei in the binucleated ciliate tetrahymena.

Ciliated protozoa have two functionally distinct nuclei, a micronucleus (MIC) and a macronucleus (MAC) [1]. These two nuclei are distinct in size, transcriptional activity, and division cycle control, proceeding with cycles of DNA replication and nuclear division at different times within the same cell [2, 3]. The structural basis generating functionally distinct nuclei remains unknown. Here, we show that, in Tetrahymena thermophila, the nuclear pore complexes (NPCs) of MIC and MAC are composed of different sets of nucleoporins. Among the 13 nucleoporins identified, Nup98 homologs were of interest because two out of the four homologs were localized exclusively in the MAC and the other two were localized exclusively in the MIC. The two MAC-localizing Nup98s contain repeats of GLFG [4]. In contrast, the two MIC-localizing Nup98s lack the GLFG repeats and instead contain a novel repeat signature of NIFN. Ectopic expression of a chimeric MIC-localizing Nup98 homolog bearing GLFG repeats obstructed the nuclear accumulation of MIC-specific nuclear proteins, and expression of a chimeric MAC-localizing Nup98 homolog bearing NIFN repeats obstructed the nuclear accumulation of MAC-specific nuclear proteins. These results suggest that Nup98s act as a barrier to misdirected localization of nucleus-specific proteins. Our findings provide the first evidence that the NPC contributes to nucleus-selective transport in ciliates.

In vivo evidence for the fibrillar structures of Sup35 prions in yeast cells

Correlative light and electron microscopy provides support for the linear amalgamation of yeast prion proteins.

Artificial induction of autophagy around polystyrene beads in nonphagocytic cells

Autophagy is an intracellular event that acts as an innate cellular defense mechanism to kill invading bacteria such as group A Streptococcus in nonphagocytic epithelial-like cells. The cellular events underlying autophagosome formation upon bacterial invasion remain unclear due to the biochemical complexity associated with uncharacterized bacterial components, and the difficulty of predicting the location as well as the timing of where/when autophagosome formation will take place. To overcome these problems, we monitored autophagosome formation in living nonphagocytic cells by inducing autophagy around artificial micrometer-sized beads instead of bacteria. Beads conjugated with bio-reactive molecules provide a powerful tool for examining biochemical properties in vitro. However, this technique has not been applied to living cells, except for phagocytes, because the beads cannot be easily incorporated into nonphagocytic cells. Here we report that micrometer-sized polystyrene beads coated with transfection reagents containing cationic lipids can be incorporated into nonphagocytic cells, and that autophagy can be efficiently induced around the beads in these cells. Monitoring the process of autophagosome formation for pH-sensitive fluorescent dye (pHrodo)-conjugated beads by fluorescence live cell imaging combined with correlative light and electron microscopy, we found that autophagosomes are formed around the beads after partial breakdown of the endosomal membrane. In addition, the beads were subsequently transferred to lysosomes within a couple of hours. Our findings demonstrate the cellular responses that lead to autophagy in response to pathogen invasion.

Nuclear localization of barrier-to-autointegration factor is correlated with progression of S phase in human cells

Barrier-to-autointegration factor (BAF) is a conserved metazoan protein that plays a critical role in retrovirus infection. To elucidate its role in uninfected cells, we first examined the localization of BAF in both mortal and immortal or cancerous human cell lines. In mortal cell lines (e.g. TIG-1, WI-38 and IMR-90 cells) BAF localization depended on the age of the cell, localizing primarily in the nucleus of >90% of young proliferating cells but only 20-25% of aged senescent cells. In immortal cell lines (e.g. HeLa, SiHa and HT1080 cells) BAF showed heterogeneous localization between the nucleus and cytoplasm. This heterogeneity was lost when the cells were synchronized in S phase. In S-phase-synchronized populations, the percentage of cells with predominantly nuclear BAF increased from 30% (asynchronous controls) to ∼80%. In HeLa cells, RNAi-induced downregulation of BAF significantly increased the proportion of early S-phase cells that retained high levels of cyclin D3 and cyclin E expression and slowed progression through early S phase. BAF downregulation also caused lamin A to mislocalize away from the nuclear envelope. These results indicate that BAF is required for the integrity of the nuclear lamina and normal progression of S phase in human cells.

Inner nuclear membrane protein Ima1 is dispensable for intranuclear positioning of centromeres.

Inner nuclear membrane (INM) proteins play a role in spatial organization of chromosomes within the nucleus. In the fission yeast Schizosaccharomyces pombe, Sad1, an INM protein of the conserved SUN‐domain family, plays an active role in moving chromosomes along the nuclear membranes during meiotic prophase. Ima1 is another conserved INM protein recently identified. A previous study claimed that Ima1 is essential for mitotic cell growth, linking centromeric heterochromatin to the spindle‐pole body. However, we obtained results contradictory to the previously proposed role for Ima1: Ima1 was dispensable for mitotic cell growth or centromere positioning. This discrepancy was attributed to incorrect ima1 deletion mutants used in the previous study. Our results show that Ima1 collaborates with two other conserved INM proteins of the LEM‐domain family that are homologous to human Man1 and Lem2. Loss of any one of three INM proteins has no effect on mitotic cell growth; however, loss of all these proteins causes severe defects in mitotic cell growth and nuclear membrane morphology. Considering that all three INM proteins interact with Sad1, these results suggest that Ima1, Lem2 and Man1 play at least partially redundant roles for nuclear membrane organization.

Biased assembly of the nuclear pore complex is required for somatic and germline nuclear differentiation in Tetrahymena

Ciliates have two functionally distinct nuclei, a somatic macronucleus (MAC) and a germline micronucleus (MIC) that develop from daughter nuclei of the last postzygotic division (PZD) during the sexual process of conjugation. Understanding this nuclear dimorphism is a central issue in ciliate biology. We show, by live‐cell imaging of Tetrahymena, that biased assembly of the nuclear pore complex (NPC) occurs immediately after the last PZD, which generates anterior‐posterior polarized nuclei: MAC‐specific NPCs assemble in anterior presumptive MACs but not in posterior presumptive MICs. MAC‐specific NPC assembly in the anterior nuclei occurs much earlier than transport of Twi1p, which is required for MAC genome rearrangement. Correlative light‐electron microscopy shows that addition of new nuclear envelope (NE) precursors occurs through the formation of domains of redundant NE, where the outer double membrane contains the newly assembled NPCs. Nocodazole inhibition of the second PZD results in assembly of MAC‐specific NPCs in the division‐failed zygotic nuclei, leading to failure of MIC differentiation. Our findings demonstrate that NPC type switching has a crucial role in the establishment of nuclear differentiation in ciliates.

Inner nuclear membrane protein Lem2 augments heterochromatin formation in response to nutritional conditions

Inner nuclear membrane proteins interact with chromosomes in the nucleus and are important for chromosome activity. Lem2 and Man1 are conserved members of the LEM‐domain nuclear membrane protein family. Mutations of LEM‐domain proteins are associated with laminopathy, but their cellular functions remain unclear. Here, we report that Lem2 maintains genome stability in the fission yeast Schizosaccharomyces pombe. S. pombe cells disrupted for the lem2+ gene (lem2∆) showed slow growth and increased rate of the minichromosome loss. These phenotypes were prominent in the rich culture medium, but not in the minimum medium. Centromeric heterochromatin formation was augmented upon transfer to the rich medium in wild‐type cells. This augmentation of heterochromatin formation was impaired in lem2∆ cells. Notably, lem2∆ cells occasionally exhibited spontaneous duplication of genome sequences flanked by the long‐terminal repeats of retrotransposons. The resulting duplication of the lnp1+ gene, which encodes an endoplasmic reticulum membrane protein, suppressed lem2∆ phenotypes, whereas the lem2∆ lnp1∆ double mutant showed a severe growth defect. A combination of mutations in Lem2 and Bqt4, which encodes a nuclear membrane protein that anchors telomeres to the nuclear membrane, caused synthetic lethality. These genetic interactions imply that Lem2 cooperates with the nuclear membrane protein network to regulate genome stability.

BAF is a cytosolic DNA sensor that leads to exogenous DNA avoiding autophagy.

Significance Rapid detection of invasion of exogenous materials and subsequent responses are important for living organisms to survive hazards, such as pathogen infection. Understanding cellular responses against exogenous DNA provides clues not only for controlling pathogen infections that bring exogenous DNA into host cells, but also for designing efficient DNA delivery vectors for transgene expression. Here, by monitoring the invasion of exogenous DNA-coated polystyrene beads into living cells, we show that barrier-to-autointegration factor detects exogenous DNA immediately after its appearance at endosome breakdown and plays a role in DNA avoiding autophagy. These findings provide new insights into the mechanisms by which a cell detects and responds to exogenous double-stranded DNA. Knowledge of the mechanisms by which a cell detects exogenous DNA is important for controlling pathogen infection, because most pathogens entail the presence of exogenous DNA in the cytosol, as well as for understanding the cell’s response to artificially transfected DNA. The cellular response to pathogen invasion has been well studied. However, spatiotemporal information of the cellular response immediately after exogenous double-stranded DNA (dsDNA) appears in the cytosol is lacking, in part because of difficulties in monitoring when exogenous dsDNA enters the cytosol of the cell. We have recently developed a method to monitor endosome breakdown around exogenous materials using transfection reagent-coated polystyrene beads incorporated into living human cells as the objective for microscopic observations. In the present study, using dsDNA-coated polystyrene beads (DNA-beads) incorporated into living cells, we show that barrier-to-autointegration factor (BAF) bound to exogenous dsDNA immediately after its appearance in the cytosol at endosome breakdown. The BAF+ DNA-beads then assembled a nuclear envelope (NE)-like membrane and avoided autophagy that targeted the remnants of the endosome membranes. Knockdown of BAF caused a significant decrease in the assembly of NE-like membranes and increased the formation of autophagic membranes around the DNA-beads, suggesting that BAF-mediated assembly of NE-like membranes was required for the DNA-beads to evade autophagy. Importantly, BAF-bound beads without dsDNA also assembled NE-like membranes and avoided autophagy. We propose a new role for BAF: remodeling intracellular membranes upon detection of dsDNA in mammalian cells.

Interphase adhesion geometry is transmitted to an internal regulator for spindle orientation via caveolin-1.

Despite theoretical and physical studies implying that cell-extracellular matrix adhesion geometry governs the orientation of the cell division axis, the molecular mechanisms that translate interphase adhesion geometry to the mitotic spindle orientation remain elusive. Here, we show that the cellular edge retraction during mitotic cell rounding correlates with the spindle axis. At the onset of mitotic cell rounding, caveolin-1 is targeted to the retracting cortical region at the proximal end of retraction fibres, where ganglioside GM1-enriched membrane domains with clusters of caveola-like structures are formed in an integrin and RhoA-dependent manner. Furthermore, Gαi1–LGN–NuMA, a well-known regulatory complex of spindle orientation, is targeted to the caveolin-1-enriched cortical region to guide the spindle axis towards the cellular edge retraction. We propose that retraction-induced cortical heterogeneity of caveolin-1 during mitotic cell rounding sets the spindle orientation in the context of adhesion geometry.