Yuko Hayashi

Trichoplein and Aurora A block aberrant primary cilia assembly in proliferating cells

The trichoplein–AurA pathway must suppress primary cilia assembly in order for cells to exit G1.

Ectopic expression of human p53 inhibits entry into S phase and induces apoptosis in the Drosophila eye imaginal disc.

Transgenic flies in which ectopic expression of human p53 was targeted to the Drosophila eye imaginal disc were established. On sectioning of adult fly eyes which displayed a severe rough eye phenotype, most ommatidia were found to be fused and irregular shapes of rabdomeres were observed. In addition, many pigment cells were lost. In the developing eye imaginal disc, photoreceptor cell differentiation was initiated normally despite the ectopic expression of p53. However, expression of p53 inhibited cell cycle progression in eye imaginal disc cells and the S phase zone (the second mitotic wave) behind the morphogenetic furrow was almost completely abolished. Furthermore, expression of p53 induced extensive apoptosis of eye imaginal disc cells, and co-expression of baculovirus P35 in the eye imaginal disc suppressed the p53-induced rough eye phenotype. These results are consistent with the known functions of human p53 and indicate the existence of signaling systems with elements corresponding to human p53 in Drosophila eye imaginal disc cells. Genetic crosses of transgenic flies expressing p53 to a collection of Drosophila deficiency stocks allowed us to identify several genomic regions, deletions of which caused enhancement or suppression of the p53-induced rough eye phenotype. The transgenic flies established in this study should be useful to identify novel targets of p53 and its positive or negative regulators in Drosophila.

Trichoplein controls microtubule anchoring at the centrosome by binding to Odf2 and ninein

The keratin cytoskeleton performs several functions in epithelial cells and provides regulated interaction sites for scaffold proteins, including trichoplein. Previously, we found that trichoplein was localized on keratin intermediate filaments and desmosomes in well-differentiated, non-dividing epithelia. Here, we report that trichoplein is widely expressed and has a major function in the correct localization of the centrosomal protein ninein in epithelial and non-epithelial cells. Immunocytochemical analysis also revealed that this protein is concentrated at the subdistal to medial zone of both mother and daughter centrioles. Trichoplein binds the centrosomal proteins Odf2 and ninein, which are localized at the distal to subdistal ends of the mother centriole. Trichoplein depletion abolished the recruitment of ninein, but not Odf2, specifically at the subdistal end. However, Odf2 depletion inhibited the recruitment of trichoplein to a mother centriole, whereas ninein depletion did not. In addition, the depletion of each molecule impaired MT anchoring at the centrosome. These results suggest that trichoplein has a crucial role in MT-anchoring activity at the centrosome in proliferating cells, probably through its complex formation with Odf2 and ninein.

The keratin-binding protein Albatross regulates polarization of epithelial cells

The keratin intermediate filament network is abundant in epithelial cells, but its function in the establishment and maintenance of cell polarity is unclear. Here, we show that Albatross complexes with Par3 to regulate formation of the apical junctional complex (AJC) and maintain lateral membrane identity. In nonpolarized epithelial cells, Albatross localizes with keratin filaments, whereas in polarized epithelial cells, Albatross is primarily localized in the vicinity of the AJC. Knockdown of Albatross in polarized cells causes a disappearance of key components of the AJC at cell–cell borders and keratin filament reorganization. Lateral proteins E-cadherin and desmoglein 2 were mislocalized even on the apical side. Although Albatross promotes localization of Par3 to the AJC, Par3 and ezrin are still retained at the apical surface in Albatross knockdown cells, which retain intact microvilli. Analysis of keratin-deficient epithelial cells revealed that keratins are required to stabilize the Albatross protein, thus promoting the formation of AJC. We propose that keratins and the keratin-binding protein Albatross are important for epithelial cell polarization.

Identification of trichoplein, a novel keratin filament-binding protein.

Keratins 8 and 18 (K8/18) are major components of the intermediate filaments (IFs) of simple epithelia. We report here the identification of a novel protein termed trichoplein. This protein shows a low degree of sequence similarity to trichohyalin, plectin and myosin heavy chain, and is a K8/18-binding protein. Among interactions between trichoplein and various IF proteins that we tested using two-hybrid methods, trichoplein interacted significantly with K16 and K18, and to some extent with K5, K6a, K8 and K14. In in vitro co-sedimentation assays, trichoplein directly binds to K8/18, but not with vimentin, desmin, actin filaments or microtubules. An antibody raised against trichoplein specifically recognized a polypeptide with a relative molecular mass of 61 kDa in cell lysates. Trichoplein was immunoprecipitated using this antibody in a complex with K8/18 and immunostaining revealed that trichoplein colocalized with K8/18 filaments in HeLa cells. In polarized Caco-2 cells, trichoplein colocalized not only with K8/18 filaments in the apical region but also with desmoplakin, a constituent of desmosomes. In the absorptive cells of the small intestine, trichoplein colocalized with K8/18 filaments at the apical cortical region, and was also concentrated at desmosomes. Taken together, these results suggest that trichoplein is a keratin-binding protein that may be involved in the organization of the apical network of keratin filaments and desmosomes in simple epithelial cells.

Defect of Mitotic Vimentin Phosphorylation Causes Microophthalmia and Cataract via Aneuploidy and Senescence in Lens Epithelial Cells

Background: Vimentin, an intermediate filament (IF) protein, is phosphorylated in mitosis. Results: Disruption of vimentin phosphorylation during cell division leads to chromosomal instability (CIN) and premature aging in mouse lens tissue. Conclusion: Our data document the first physiological importance of vimentin phosphorylation during mitosis for organogenesis and tissue homeostasis. Significance: Our data suggest a possible causal relationship between CIN and premature aging. Vimentin, a type III intermediate filament (IF) protein, is phosphorylated predominantly in mitosis. The expression of a phosphorylation-compromised vimentin mutant in T24 cultured cells leads to cytokinetic failure, resulting in binucleation (multinucleation). The physiological significance of intermediate filament phosphorylation during mitosis for organogenesis and tissue homeostasis was uncertain. Here, we generated knock-in mice expressing vimentin that have had the serine sites phosphorylated during mitosis substituted by alanine residues. Homozygotic mice (VIMSA/SA) presented with microophthalmia and cataracts in the lens, whereas heterozygotic mice (VIMWT/SA) were indistinguishable from WT (VIMWT/WT) mice. In VIMSA/SA mice, lens epithelial cell number was not only reduced but the cells also exhibited chromosomal instability, including binucleation and aneuploidy. Electron microscopy revealed fiber membranes that were disorganized in the lenses of VIMSA/SA, reminiscent of similar characteristic changes seen in age-related cataracts. Because the mRNA level of the senescence (aging)-related gene was significantly elevated in samples from VIMSA/SA, the lens phenotype suggests a possible causal relationship between chromosomal instability and premature aging.

The DRE sequence TATCGATA, a putative promoter-activating element for Drosophila melanogaster cell-proliferation-related genes

We have confirmed that the DNA replication-related element (DRE) consisting of an 8-bp palindrome, TATCGATA, and not neighboring sequences, are responsible for activating promoters of the Drosophila melanogaster (Dm) PCNA (proliferating cell nuclear antigen)- and DNA polymerase alpha-encoding genes in both cultured cell and transgenic fly systems. We have so far found 153 copies of DRE in the Dm gene database. 73 of them are concentrated within the 600-bp upstream regions from the transcription start points of 61 genes. Interestingly, many of these genes are involved in either DNA replication, transcription, translation, signal transduction, cell cycle or other putative regulatory functions, and are possibly related to cell proliferation. It seems likely that DRE is an element common to the regulation of cell-proliferation-related genes, although their expression patterns may be different depending on which of regulatory elements other than the DRE are combined.

Antagonistic regulation of the Drosophila PCNA gene promoter by DREF and Cut

The gene promoter of Drosophila proliferating cell nuclear antigen (dPCNA) contains several transcriptional regulatory elements, such as upstream regulatory element (URE), DNA replication‐related element (DRE, 5′‐TATCGATA), and E2F recognition sites. In the present study, a yeast one‐hybrid screen using three tandem repeats of DRE in dPCNA promoter as the bait allowed isolation of a cDNA encoding Cut, a Drosophila homolog of mammalian CCAAT‐displacement protein (CDP)/Cux. Electrophoretic mobility shift assays showed that Cut bound to both DRE and the sequence 5′‐AATCAAAC in URE, with much higher affinity to the former. Measurement of dPCNA promoter activity by transient luciferase expression assays in Drosophila S2 cells after an RNA interference for Cut or DREF showed DREF activates the dPCNA promoter while Cut functions as a repressor. Chromatin immunoprecipitation assays in the presence or absence of 20‐hydroxyecdysone further showed both DREF and Cut proteins to be localized in the genomic region containing the dPCNA promoter in S2 cells, especially in the Cut case upon induction of differentiation. These results indicate that Cut functions as a transcriptional repressor of dPCNA gene by binding to the promoter region in the differentiated state, while DREF binds to DRE to promote expression of dPCNA during cell proliferation.

Identification of CFDD (Common Regulatory Factor for DNA Replication and DREF Genes) and Role of Its Binding Site in Regulation of the Proliferating Cell Nuclear Antigen Gene Promoter

The Drosophila proliferating cell nuclear antigen (PCNA) gene promoter contains at least three transcriptional regulatory elements, the URE (upstream regulatory element), DRE (DNA replication-related element), and E2F recognition sites. In nuclear extracts of Drosophila Kc cells, we detected a novel protein factor(s), CFDD (common regulatory factor for DNA replication and DREF genes) that appeared to recognize two unique nucleotide sequences (5′-CGATA and 5′-CAATCA) and bind to three sites in the PCNA gene promoter. These sites were located at positions −84 to −77 (site 1), −100 to −93 (site 2) and −134 to −127 (site 3) with respect to the transcription initiation sites. Sites 2 and 3 overlapped with DRE and URE, respectively, and the 5′-CGATA matched with the reported recognition sequence of BEAF-32 (boundary element-associated factor of 32 kDa). Detailed analyses of CFDD recognition sequences and experiments with specific antibodies to DREF (DRE-binding factor) and BEAF-32 suggest that CFDD is different from DREF, UREF (URE-binding factor) and BEAF-32. A UV cross-linking experiment revealed that polypeptides of ∼76 kDa in the nuclear extract interact directly with the CFDD site 1 sequence. Transient expression assays of chloramphenicol acetyltransferase (CAT) in Kc cells transfected with PCNA promoter-CAT fusion genes carrying mutations in CFDD site 1 and examination of lacZ expression from PCNA promoter-lacZ fusion genes carrying mutations in site 1, introduced into flies by germ line transformation, revealed that CFDD site 1 plays an important role for the promoter activity both in cultured cells and in living flies. In addition to the PCNA gene, multiple CFDD sites were found in promoters of the DNA polymerase α and DREF genes, and CFDD binding to the DREF promoter was confirmed. Therefore, CFDD may play important roles in regulation ofDrosophila DNA replication-related genes.

Palmitoylation of ERBIN is required for its plasma membrane localization

LAP (leucine‐rich repeats (LRR) and PSD‐95/Dlg/ZO‐1 (PDZ)) family proteins, including Scribble, LET‐413, ERBIN, Densin‐180 and Lano, are involved in the regulation of cell polarity. The LRR domains of LAP proteins were reported to mediate their basolateral membrane localization and to be essential for their function. To further dissect the mechanism of the plasma membrane localization of ERBIN, we introduced various mutants of ERBIN into cultured cells and observed the intracellular localization. When an LRR domain mutant lacking amino acid residues 1–32 at the amino (N) terminal region was over‐expressed in cells, the mutant did not localize at the plasma membrane, but localized in the cytoplasm. We found that cysteines 14 and 16 at the N‐terminal region of ERBIN are in vivo palmitoylated. Over‐expressed mutants in which cysteine 14 and/or cysteine 16 were changed to serines did not localize at the plasma membrane, indicating that the palmitoylation of ERBIN is necessary for its plasma membrane localization. The over‐expressed 1–196 amino acids fragment of ERBIN, which lacked the latter half of LRR, was palmitoylated but did not localize at the plasma membrane. These results suggest that both palmitoylation and LRR are required for the plasma membrane localization of ERBIN.