Characterization of nucleolar localization and exclusion signals in terminal deoxynucleotidyltransferase interacting factor 2/estrogen receptor α-binding protein.

Terminal deoxynucleotidyltransferase interacting factor 2/estrogen receptor α-binding protein (TdIF2/ERBP) is a multifunctional nucleolar protein. The nucleolar localization of TdIF2/ERBP is important for its functions because it promotes ribosomal RNA transcription. However, signal sequences that direct TdIF2/ERBP to the nucleolus are not well characterized. We examined the TdIF2/ERBP sequence using truncation and mutation analyses to determine whether the nucleosome binding and C-terminal domains of TdIF2/ERBP possess nucleolar localization signals (NoLSs). In these domains, four NoLSs that could direct the mCherry protein to the nucleolus were detected. In addition, a short stretch of hydrophobic residues (VLLVL) in the center of TdIF2/ERBP acted as a nucleolar exclusion signal, which reduced the nucleolar accumulation of mCherry-NoLS fusion proteins. These results would contribute to improving the prediction of NoLSs from protein sequences. The short, transferrable localization signals would be valuable tools for understanding the association between localization and functions of nucleolar proteins. Abbreviations TdIF2: terminal deoxynucleotidyltransferase interacting factor 2; ERBP: estrogen receptor α-binding protein; EGFP: enhanced green fluorescent protein; NLS: nuclear localization signal; NoLS: nucleolar localization signal; NoES: nucleolar exclusion signal; DAPI: 4',6-diamidino-2-phenylindole.

Highly Sensitive Measurement of Inositol 1,4,5-Trisphosphate by Using a New Fluorescent Ligand and Ligand Binding Domain Combination.

Based on the results of our previous adenophostin A structure-activity relationship studies, two fluorescent inositol 1,4,5-trisphosphate (IP3 ) receptor ligands, fluorescent adenophostin A (FADA) and fluorescent low-affinity ligand (FLL), were designed. Binding of the fluorescent ligands to the fluorescent IP3 sensor in protein-expressing cells caused FRET. This principle was extended to a cell-free assay system by using the fluorescent IP3 sensor bound to agarose beads. The effect of FLL on the FRET signal was reduced by subsequent addition of IP3 . The IC50 values of IP3 on the FRET signals were 139.7 and 352.1 nm for 30 and 100 nm FLL, respectively. This method allowed quantitative measurement of IP3 concentrations below 10 nm and was applied to measure cytosolic IP3 concentrations in COS-7 cells and to examine the potency of synthesized adenophostin A analogues.

Evaluation of Phototoxicity of Short-Wavelength Laser Light Utilizing PCNA Accumulation.

In recent years, diseases such as age-related macular degeneration and retinal pigment degeneration caused by excessive exposure to short-wavelength visible light have become significant concerns. With the aim of quantitatively evaluating the toxicity of short-wavelength light, proliferating cell nuclear antigen (PCNA) accumulation at the irradiation site was investigated using live cell imaging techniques to irradiate individual living cells with short-wavelength laser light. By examining the dependency of PCNA accumulation on the irradiation site within the cells and their cell cycle, it was observed that PCNA accumulation occurred only when the cell nucleus of cells in the S phase of the cell cycle was irradiated. We investigated the accumulation of PCNA at the laser irradiation site using laser light at wavelengths of 405 nm and 375 nm, with intensities ranging from 0.5 µW to 9.0 µW. The results confirmed an increase in PCNA accumulation with increasing intensity, and a higher accumulation was observed with laser light irradiation at a wavelength of 375 nm compared to 405 nm. By comparing the PCNA accumulation and 24 h cell viability, we demonstrated the feasibility of quantitatively assessing laser light toxicity through the measurement of PCNA accumulation.

A rapid and simple method of evaluating the dimeric tendency of fluorescent proteins in living cells using a truncated protein of importin α as fusion tag.

Enhanced green fluorescent protein (EGFP) and its yellow variant (Venus) are weakly dimeric under physiological conditions. We designed a simple method to evaluate the dimeric tendency of fluorescent proteins in living mammalian cells. A novel single mutation, A206L, interfering with the hydrophobic interactions of the dimer interface in Venus, contributed to its monomerization, and was as effective as the A206K mutation in this assay.

Increase of tear volume in dogs after reunion with owners is mediated by oxytocin.

In humans, tear volume increases during emotional arousal. To our knowledge, no previous studies have investigated the relationship between emotional arousal and tear volume in animals. We performed the Schirmer tear test (STT) and measured tear volume in dogs before and after reunions with owners and familiar non-owners. Tear volume increased significantly during reunion with the owner, but not with a familiar non-owner. When an oxytocin solution was applied to dogs' eyes, the tear volume also increased, suggesting that oxytocin might mediate tear secretion during owner-dog reunions. Finally, human participants rated their impressions on photos of dogs with or without artificial tears and they assigned more positive scores to the photos with artificial tears. These results suggest that emotion-elicited tears can facilitate human-dog emotional connections. VIDEO ABSTRACT.

Validation of a newly generated oxytocin antibody for enzyme-linked immunosorbent assays.

The biological and psychological significance of oxytocin is increasingly recognized; however, reliable assays of oxytocin in biological samples have not been developed. We raised a new oxytocin polyclonal rabbit antibody against synthetic oxytocin. The affinity of antibodies to oxytocin was examined by a radio-immunoassay and compared with that of a previously validated antibody. One antibody showed affinity for oxytocin in the radio-immunoassay. We developed a solid-phase ELISA for oxytocin using this antibody and compared it with existing methods. The newly developed ELISA showed comparable results using urine samples but not using serum samples. These results indicate that the new ELISA is useful for urinary oxytocin; further modifications, such as different extraction methods, are needed for its application to serum oxytocin.

Spontaneous calcium responses of SF2 rat dental epithelial cells stably expressing the calcium sensor G-GECO.

Genetically-encoded calcium indicators such as G-GECO are useful for studying Ca2+ responses during long-term processes. In this study, we employed a lentiviral vector and established a rat dental epithelial cell line that stably expressed G-GECO (SF2-G-GECO). Ca2+ imaging analysis under cell culture conditions revealed that SF2-G-GECO cells exhibited spontaneous Ca2+ responses, which could be classified into the following three major patterns depending on the cell density: localized Ca2+ responses at cell protrusions at a low density, a cell-wide spread of Ca2+ responses at a medium density, and Ca2+ responses in clusters of 3-20 cells at a high density. The P2Y receptor inhibitor suramin (10 µM), the ATP-degrading enzyme apyrase (5 units/mL), and the fibroblast growth factor (FGF) receptor inhibitor FIIN-2 (1 µM) decreased the frequency of spontaneous Ca2+ responses. These results indicate that ATP and FGF are involved in the spontaneous Ca2+ responses. SF2 cells differentiate into ameloblasts via interactions with mesenchymal cells. Therefore, SF2-G-GECO cells are expected to be a useful tool for studying the functions of Ca2+ responses in regulating gene expression during tooth development.

Live cell imaging of micronucleus formation and development.

The micronucleus (MN) test is widely used to biomonitor humans exposed to clastogens and aneugens, but little is known about MN development. Here we used confocal time-lapse imaging and a fluorescent human lymphoblastoid cell line (T105GTCH), in which histone H3 and α-tubulin stained differentially, to record the emergence and behavior of micronuclei (MNi) in cells exposed to MN-inducing agents. In mitomycin C (MMC)-treated cells, MNi originated in early anaphase from lagging chromosome fragments just after chromosome segregation. In γ-ray-treated cells showing multipolar cell division, MN originated in late anaphase from lagging chromosome fragments generated by the abnormal cell division associated with supernumerary centrosomes. In vincristine(VC)-treated cells, MN formation was similar to that in MMC-treated cells, but MNi were also derived from whole chromosomes that did not align properly on the metaphase plate. Thus, the MN formation process induced by MMC, γ-rays, and VC, were strikingly different, suggesting that different mechanisms were involved. MN stability, however, was similar regardless of the treatment and unrelated to MN formation mechanisms. MNi were stable in daughter cells, and MN-harboring cells tended to die during cell cycle progression with greater frequency than cells without MN. Because of their persistence, MN may have significant impact on cells, causing genomic instability and abnormally transcribed genes.

Visualization of aberrant perinuclear microtubule aster organization by microtubule-destabilizing agents.

To analyze aberrant spindle formation by microtubule-targeting drugs, live cell imaging was performed using multi-fluorescent human MDA-MB-435 cells in which several spindle components were visualized. Time-lapse images revealed that nocodazole and vinblastine induced additional perinuclear asters at the onset of mitosis. These results imply that these drugs stimulate the microtubule-organizing activity, despite their microtubule-destabilizing properties.

Effects of full-length human amelogenin on the differentiation of dental epithelial cells and osteoblastic cells.

BACKGROUND AND OBJECTIVE: Amelogenins are major components of extracellular matrix proteins in developing teeth, and regulate the growth of enamel crystals. They also function as signaling molecules in cell differentiation. This study aimed to determine the biological effects of amelogenins on the differentiation of HAT-7 dental epithelial cells and MC3T3-E1 pre-osteoblastic cells using full-length recombinant human amelogenin (rh-AMEL). DESIGN: rh-AMEL was expressed in a mammalian cell line (Expi293F™) and was purified by DDK agarose beads. Effects of rh-AMEL on differentiation were evaluated by Mineralization and Alkaline phosphatase (ALP) activity using Alizarin Red S staining and colorimetric substrate p-nitrophenol, respectively. RESULTS: Western blotting and silver staining confirmed the successful purification of rh-AMEL. Mineralization and ALP activity in HAT-7 cells were significantly higher after treatment with 4 µg/mL rh-AMEL, but not after treatment with Emdogain® (EMD). In MC3T3-E1 cells, on the other hand, rh-AMEL showed biphasic effects on differentiation. Treatment with low concentrations of rh-AMEL (0.001-0.1 µg/mL) and EMD (0.01-1 µg/mL) increased mineralization and ALP activity in MC3T3-E1 cells, whereas treatment with high concentrations of rh-AMEL (4 µg/mL) and EMD (100 µg/mL) had the opposite effect. CONCLUSION: High concentrations of rh-AMEL and EMD decreased the differentiation of MC3T3-E1 cells. By contrast, a high concentration of rh-AMEL, but not that of EMD, promoted the differentiation of HAT-7 cells. This study demonstrates that the effects of rh-AMEL on cell differentiation differ between HAT-7 and MC3T3-E1 cells, and suggests that different regions on AMEL may induce the differentiation of these cell types.

Construction of three quadruple-fluorescent MDA435 cell lines that enable monitoring of the whole chromosome segregation process in the living state.

Mitotic events from prophase to telophase are defined by morphology or movement of chromatin, nuclear envelope, centrosomes and spindles. Live-cell imaging is useful for characterizing the whole chromosome segregation process in the living state. In this study, we constructed three quadruple-fluorescent MDA435 cell lines in which chromatin, kinetochores, nuclear envelope and either inner centromere, microtubules or centrosomes/spindles were differentially visualized with cyan, green, orange and red fluorescent proteins (ECFP, EGFP, mKO and DsRed). Each mitotic stage of the individual cells could be identified by capturing live-cell images without the requirement of fixing or staining steps. In addition, we obtained four-color time-lapse images of one cell line, MDA-Auro/imp/H3/AF, from prophase to metaphase and from early anaphase to telophase. These quadruple-fluorescent cell lines will be useful for precisely analyzing the mitotic events from prophase through to telophase in single cells in the future.

[Advances in methods for analyzing IP3 signaling and understanding of coupled Ca2+ and IP3 oscillations].

Inositol 1,4,5-trisphosphate (IP3) is an important intracellular messenger produced by phospholipase C via the activation of G-protein-coupled receptor- or receptor-tyrosine-kinase-mediated pathways, and is involved in numerous responses to hormones, neurotransmitters, and growth factors through the releases of Ca2+ from intracellular stores via IP3 receptors. IP3-mediated Ca2+ signals often exhibit complex spatial and temporal organizations, such as Ca2+ oscillations. Recently, new methods have become available to measure IP3 concentration ([IP3]) using AlphaScreen technology, fluorescence polarization, and competitive ligand binding assay (CFLA). These methods are useful for the high throughput screening in drug discovery. Calcium ions generate versatile intracellular signals such as Ca2+ oscillations and waves. Fluorescent sensors molecules to monitor changes in [IP3] in single living cells are crucial to study the mechanism for the spatially and temporally regulated Ca2+ signals. In particular, FRET-based IP3 sensors are useful for the quantitative monitoring intracellular [IP3], and allowed to uncovered the oscillatory IP3 dynamics in association with Ca2+ oscillations. A mathematical model of coupled Ca2+ and IP3 oscillations predicts that Ca2+ oscillations are the result of modulation of the IP3 receptor by intracellular Ca2+, and that the period is modulated by the accompanying IP3 oscillations. These model predictions have also been confirmed experimentally. At present, however, usefulness of FRET-based IP3 sensors are limited by their relatively small change in fluorescence. Development of novel IP3 sensors with improve dynamic range would be important for understanding the regulatory mechanism of Ca2+ signaling and for in vivo IP3 imaging.

Effect of 1,25-dihydroxyvitamin D3 on spontaneous calcium responses in rat dental epithelial SF2 cells revealed by long-term imaging.

Genetically encoded calcium indicators (GECIs) are suitable for long-term imaging studies. In this study, we employed a highly sensitive GECI, G-GECO, and achieved efficient gene delivery with an adenoviral vector. The adenoviral vector allowed us to express G-GECO in more than 80% of cells. More than 80% of G-GECO-expressing cells showed an ATP-induced increase in fluorescence intensity due to Ca2+ release from intracellular stores and subsequent Ca2+ entry. The fluorescence intensity of these cells was increased more than 2-fold by stimulation with 10 µM ATP. We applied long-term imaging (for ~10 h) to monitor Ca2+ responses in SF2, a rat dental epithelial cell line, in culture conditions. SF2 cells showed intermittent rises in the intracellular Ca2+ concentration in the presence of 100 nM 1,25-dihydroxyvitamin D3. Many of these Ca2+ responses began at a specific location in the cytoplasm and spread throughout the entire cytoplasm. The combination of efficient gene delivery with an adenoviral vector and long-term imaging with a highly sensitive GECI enabled detection of intermittent Ca2+ responses that occur only 3-10 times/h/100 cells. This method could be useful to study the effects of Ca2+ responses for regulating longterm processes, such as gene expression, cell migration, and cell division, in many cell types.

Clinical and genetic characteristics of patients with autoimmune thyroid disease with anti-islet autoimmunity.

In contrast to the large number of studies on autoimmunity against the thyroid gland in patients with type 1 diabetes mellitus, little is known about the anti-islet autoimmune status in patients with autoimmune thyroid diseases (AITDs). We therefore studied the anti-islet autoimmune status in patients with AITD and the clinical and genetic characteristics of AITD patients with anti-islet autoimmunity. The positivity and titer of glutamic acid decarboxylase antibody (GAD Ab) were studied in 866 Japanese patients with AITD (546 with Graves disease and 320 with Hashimoto thyroiditis), 221 patients with thyroid disease of nonautoimmune origin, and 282 control subjects. The clinical characteristics and genotypes of HLA-DRB1, DQB1, and CTLA4 were compared between AITD patients with and without GAD Ab. The prevalence of GAD Ab was significantly higher in AITD patients than in control subjects (5.8% vs 2.1%, P = .01), particularly in Graves disease (7.1% vs 2.1%, P = .0019). The prevalence of diabetes mellitus was significantly higher in AITD patients with GAD Ab than in those without (40.0% vs 10.1%, P < .0001), particularly in those with a high titer of GAD Ab (high vs low titer: 64% vs 16%, P = .001) and also in those positive for insulinoma-associated antigen 2 (IA-2) Ab (IA-2 positive vs negative: 75.0% vs 31.3%, P = .016). The AITD patients with GAD Ab were characterized by younger age at onset of diabetes, lower body mass index, higher hemoglobin A(1c) level, and higher frequency of insulin therapy than those without GAD Ab. The frequency of the DRB1*0405-DQB1*0401 haplotype was significantly higher in AITD patients with GAD Ab than in those without GAD Ab and control subjects. A single nucleotide polymorphism (rs3087243) of CTLA4 was significantly associated with AITD, but not with positivity of GAD Ab. These results indicate that patients with AITD, and in particular Graves disease, are prone to develop ß-cell autoimmunity and insulin-requiring diabetes, particularly those with a high titer of GAD Ab and/or positive for both GAD and IA-2 Ab. Glutamic acid decarboxylase Ab positivity in AITD patients was associated with HLA, conferring susceptibility to type 1 diabetes mellitus.

Differential responses of mitotic spindle pole formation to microtubule-stabilizing agents epothilones A and B at low concentrations.

We previously reported that the microtubule-stabilizing agent docetaxel induced formation of fragile acentrosomal spindle poles but that structurally related paclitaxel did not. In the present study, we examined whether the microtubule-stabilizing agents epothilones A and B, which are structurally similar, affect the centrosome/spindle pole architecture.We investigated mitotic processes in epothilone A or B-treated human MDA-MB-435 cells, in which the centrosomes, spindle poles and mitotic micro-tubules were simultaneously visualized by GFP-Aurora A kinase. Fluorescence microscopy of metaphase cells indicated that several chromosomes were misaligned away from the metaphase plate when treated with IC(50) concentrations of epothilone A or B (4.5 or 2 nM, respectively), suggesting that microtubule dynamics was impaired. Interestingly, epothilone B induced formation of acentro-somal spindle poles, but this effect was not observed for epothilone A. Live-cell imaging showed that aster-like structures ectopically arose around the nuclear envelope at the onset of mitosis in epothilone B-treated cells and that one of these asters became an acentrosomal spindle pole. Aster-like structures also arose in the presence of epothilone A, but they were merged into centro-some-derived spindle poles during prometaphase and completely disappeared until metaphase. These results indicate that the centro-some/spindle pole integrity is strongly affected by epothilone B but is not greatly affected by epothilone A. Our findings show that the two epothilones cause different cellular responses at equipotent concentrations and suggest that they have different mechanisms of activity in cells.

Dynamic behavior of FCHO1 revealed by live-cell imaging microscopy: its possible involvement in clathrin-coated vesicle formation.

The intracellular behavior of human FCHO1 protein was investigated by live-cell imaging microscopy. The fluorescence intensity of green fluorescent protein (GFP)-FCHO1 fluctuated periodically in a perinuclear region approximately every 100 s, reminding us of the periodic fluctuations of clathrin reported in our recent work. The periodicity of FCHO1 was temporally correlated with that of clathrin, suggesting that FCHO1 is involved in clathrin-coated vesicle formation.

Rhythmic cycle of clathrin-coated pit formation at the trans-golgi network in human MDA-MB-435 cells.

We studied the in vivo dynamics of enhanced green fluorescent protein-tagged clathrin light chain a (GFP-CLCa) at the trans-Golgi network (TGN) in MDA-MB-435 cells. The intensity of fluorescence signals of GFP-CLCa periodically increased and decreased at the TGN approximately every 100 s. This suggests that the formation of clathrin-coated pits occurs synchronously and periodically at the TGN.

A multi-fluorescent MDA435 cell line for mitosis inhibitor studies: simultaneous visualization of chromatin, microtubules, and nuclear envelope in living cells.

As a part of our efforts to create a pre-made multi-fluorescent cell library for various cytological assays, we made a triple-fluorescent cell line in which microtubules, chromosomes, and nuclear envelopes were visualized for simultaneous observation of spindle structure and chromosome distribution in living cells. Pilot experiments with microtubule-disturbing drugs showed the advantages of this cell line in mitosis inhibitor studies.