Aya Hashimoto scite author profile

Osteoblastic mineralization occurs during the early stages of bone formation. During this mineralization, hydroxyapatite (HA), a major component of bone, is synthesized, generating hard tissue. Many of the mechanisms driving biomineralization remain unclear because the traditional biochemical assays used to investigate them are destructive techniques incompatible with viable cells. To determine the temporal changes in mineralization-related biomolecules at mineralization spots, we performed time-lapse Raman imaging of mouse osteoblasts at a subcellular resolution throughout the mineralization process. Raman imaging enabled us to analyze the dynamics of the related biomolecules at mineralization spots throughout the entire process of mineralization. Here, we stimulated KUSA-A1 cells to differentiate into osteoblasts and conducted time-lapse Raman imaging on them every 4 hours for 24 hours, beginning 5 days after the stimulation. The HA and cytochrome c Raman bands were used as markers for osteoblastic mineralization and apoptosis. From the Raman images successfully acquired throughout the mineralization process, we found that β-carotene acts as a biomarker that indicates the initiation of osteoblastic mineralization. A fluctuation of cytochrome c concentration, which indicates cell apoptosis, was also observed during mineralization. We expect time-lapse Raman imaging to help us to further elucidate osteoblastic mineralization mechanisms that have previously been unobservable.

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Simple propagation method for resident macrophages by co-culture and subculture, and their isolation from various organs

Ogawa

Tsurutani

Hashimoto

et al. 2019

BMC Immunol

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Background Resident macrophages (Mø) originating from yolk sac Mø and/or foetal monocytes colonise tissues/organs during embryonic development. They persist into adulthood by self-renewal at a steady state, independent of adult monocyte inputs, except for those in the intestines and dermis. Thus, many resident Mø can be propagated in vitro under optimal conditions; however, there are no specific in vitro culture methods available for the propagation of resident Mø from diverse tissues/organs. Results We provided a simple method for propagating resident Mø derived from the liver, spleen, lung, and brain of ICR male mice by co-culture and subculture along with the propagation of other stromal cells of the respective organs in standard culture media and successfully demonstrated the propagation of resident Mø colonising these organs. We also proposed a simple method for segregating Mø from stromal cells according to their adhesive property on bacteriological Petri dishes, which enabled the collection of more than 97.6% of the resident Mø from each organ. Expression analyses of conventional Mø markers by flow cytometry showed similar expression patterns among the Mø collected from the organs. Conclusion This is the first study to clearly provide a practical Mø propagation method applicable to resident Mø of diverse tissues and organs. Thus, this novel practical Mø propagation method can offer broad applications for the use of resident Mø of diverse tissues and organs.

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In situ Raman imaging of osteoblastic mineralization

Hashimoto

Chiu

Sawada

et al. 2014

J Raman Spectroscopy

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Hydroxyapatite (HA) is synthesized at early stages of bone formation by osteoblasts. Nondestructive observation of early stages of osteoblastic mineralization provides crucial information for biological mechanism of bone formation. Raman microscopy serves as an ideal tool to observe the osteoblastic mineralization process because it shows the chemical information of the sample at a minimally invasive level. In addition, HA is a marker for osteoblastic mineralization, and HA Raman signal is strong enough to identify mineralized spots in osteoblasts. In this research, we visualized the distribution of HA in cultured mouse osteoblasts by Raman imaging and observed the location of the mineralized spots in the culture. We monitored HA Raman signal from osteoblast culture for 3 days after administrating the osteogenic differentiation medium and observed Raman signal associated with HA. We identified mineralized spots of KUSA‐A1 by Raman imaging constructed from the distribution of HA Raman signal. We successfully visualized the distribution of the mineralized spots in the culture of KUSA‐A1. We compared our Raman images with Alizarin red S staining assay, which was a conventional method to evaluate the mineralization process. Raman imaging of the KUSA‐A1 culture visualized the mineralized spots more accurately than Alizarin red S staining assay. Raman imaging of HA serves as a powerful tool to identify the mineralized spots in an in vitro culture of osteogenic lineage cells. Copyright © 2014 John Wiley & Sons, Ltd.

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Impairment of endothelial‐mesenchymal transformation during atrioventricular cushion formation in Tmem100 null embryos

Mizuta

Sakabe

Hashimoto

et al. 2014

Developmental Dynamics

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Background: Endothelial-mesenchymal transformation (EndMT) is essential for endocardial cushion formation during cardiac morphogenesis. We recently identified Tmem100 as an endothelial gene indispensable for vascular development. In this study, we further investigated its roles for EndMT during atrioventricular canal (AVC) cushion formation. Results: Tmem100 was expressed in AVC endocardial cells, and Tmem100 null embryos showed severe EndMT defect in the AVC cushions. While calcineurin-dependent suppression of vascular endothelial growth factor (VEGF) expression in the AVC myocardium is important for EndMT, significant up-regulation of Vegfa expression was observed in Tmem100 null heart. EndMT impaired in Tmem100 null AVC explants was partially but significantly restored by the expression of constitutively-active calcineurin A, suggesting dysregulation of myocardial calcineurin-VEGF signaling in Tmem100 null heart. Moreover, Tmem100 null endocardial cells in explant culture did not show EndMT in response to the treatment with myocardium-derived growth factors, transforming growth factor b2 and bone morphogenetic protein 2, indicating involvement of an additional endocardial-specific abnormality in the mechanism of EndMT defect. The lack of NFATc1 nuclear translocation in endocardial cells of Tmem100 null embryos suggests impairment of endocardial calcium signaling. Conclusions: The Tmem100 deficiency causes EndMT defect during AVC cushion formation possibly via disturbance of multiple calcium-related signaling events. Developmental Dynamics 244:31-42, 2015. V C 2014 Wiley Periodicals, Inc.

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Influence of conditioning regimens and stem cell sources on donor-type chimerism early after stem cell transplantation

et al. 2008

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We retrospectively analyzed very early chimerism before and ongoing neutrophil engraftment (days 7, 14, 21, 28) and investigated the influence of conditioning regimens and stem cell sources on donor-type chimerism in 59 Japanese patients who had received allogeneic hematopoietic stem cell transplantation. The percentage of donor-type chimerism increased before engraftment in all patients who achieved engraftment. The average percentage of donor-type chimerism in patients who had received reduced-intensity stem cell transplantation (RIST) with total body irradiation (TBI) was significantly higher than that in patients who had received RIST without TBI (98.8% vs 87.5% on day 21, P<0.01; 99.3% vs 84.3% on day 28, P<0.01). The average percentage of donor-type chimerism after peripheral blood stem cell transplantation was significantly higher than that after bone marrow transplantation on day 7 (81.5% vs 43.1%, P<0.01), and the average percentage of donor-type chimerism after cord blood transplantation was significantly lower on day 14 (55.8% vs 84.8%, P<0.05). Compared with the average percentage of donor-type chimerism in patients who achieved engraftment with each stem cell source, a notable decrease in donor-type chimerism was observed in patients who failed to achieve engraftment. This study suggests that differences in conditioning regimens and stem cell sources should be taken into account when considering donor-type chimerism.

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Aya Hashimoto

Time-lapse Raman imaging of osteoblast differentiation

Simple propagation method for resident macrophages by co-culture and subculture, and their isolation from various organs

In situ Raman imaging of osteoblastic mineralization

Impairment of endothelial‐mesenchymal transformation during atrioventricular cushion formation in Tmem100 null embryos

Influence of conditioning regimens and stem cell sources on donor-type chimerism early after stem cell transplantation

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