Shiori Meguro

Direct isolation of myofibroblasts and fibroblasts from bleomycin-injured lungs reveals their functional similarities and differences

BackgroundMyofibroblasts play a crucial role in tissue repair. The functional similarities and differences between myofibroblasts and fibroblasts are not fully understood because they have not been separately isolated from a living body. The purpose of this study was to establish a method for the direct isolation of myofibroblasts and fibroblasts from injured lungs by using fluorescence-activated cell sorting and to compare their functions.ResultsWe demonstrated that lineage-specific cell surface markers (lin), such as CD31, CD45, CD146, EpCAM (CD326), TER119, and Lyve-1 were not expressed in myofibroblasts or fibroblasts. Fibroblasts of bleomycin-injured lungs and saline-treated lungs were shown to be enriched in linneg Sca-1high, and myofibroblasts of bleomycin-injured lungs were shown to be enriched in linneg Sca-1low CD49ehigh. Results from in-vitro proliferation assays indicated in-vitro proliferation of fibroblasts but not myofibroblasts of bleomycin-injured lungs and of fibroblasts of saline-treated lungs. However, fibroblasts and myofibroblasts might have a low proliferative capacity in vivo. Analysis of genes for collagen and collagen synthesis enzymes by qRT-PCR showed that the expression levels of about half of the genes were significantly higher in fibroblasts and myofibroblasts of bleomycin-injured lungs than in fibroblasts of saline-treated lungs. By contrast, the expression levels of 8 of 11 chemokine genes of myofibroblasts were significantly lower than those of fibroblasts.ConclusionsThis is the first study showing a direct isolation method of myofibroblasts and fibroblasts from injured lungs. We demonstrated functional similarities and differences between myofibroblasts and fibroblasts in terms of both their proliferative capacity and the expression levels of genes for collagen, collagen synthesis enzymes, and chemokines. Thus, this direct isolation method has great potential for obtaining useful information from myofibroblasts and fibroblasts.

α-Fetoprotein–producing ovarian tumor in a postmenopausal woman with germ cell differentiation

α-Fetoprotein (AFP)-producing ovarian tumors (APOTs) are rarely encountered in postmenopausal women, irrespective of whether they are of the germ cell or non-germ cell type. The APOTs that do occur in postmenopausal women are characterized by variable histologies such as hepatoid carcinoma, yolk sac tumor, and epithelial malignancies, most of which are combined. We herein present a case with APOT, which arose in a 58-year-old, gravida 2, para 2, postmenopausal woman. Preoperatively, the tumor, which was in the right ovary, was found to produce AFP (102768.0 ng/mL). The tumor was evenly composed of glands mimicking secretory endometrial gland or fetal gut accompanied by abundant stroma. Immunohistochemically, these glands were positive for SALL4, glypican-3, and hepatocyte nuclear factor 1β. We considered the present case as an AFP-producing adenocarcinoma with adenofibroma showing germ cell differentiation, but it seemed controversial that this tumor should be designated as a yolk sac tumor of the glandular type. The expression profiles of SALL4, OCT4, glypican-3, and hepatocyte nuclear factor 1β were thought to provide interesting implications to characterize the present case.

Cytomegalovirus Initiates Infection Selectively from High-Level β1 Integrin–Expressing Cells in the Brain

Cytomegalovirus (CMV) is a prevalent pathogen in intrauterine infections that causes congenital anomalies such as CMV encephalitis, which is characterized by the focal areas of reactive gliosis, reactive mononuclear cells, microglial nodules, and ventriculoencephalitis. To elucidate the mechanisms of CMV susceptibility in the developing brain, cell tropism and the infectious dynamics of CMV infection were investigated. We evaluated intraventricular and intravascular infections from the perspective of the distribution of CMV and its receptor (β1 integrin) in the earliest phase of infection. Murine CMV (MCMV) immediate early 1-positive cells were colocalized mainly with meninges and choroid plexus (after intraventricular infection) or with endothelial cells and pericytes (after intravascular infection). Using green fluorescent protein-expressing recombinant MCMV particles and fluorescent microbeads (100 to 300 nm), we revealed that CMV particle size is the primary factor determining the initial CMV distribution. β1 Integrin inhibition using a shRNA and functional blocking antibody significantly reduced MCMV infection. IHC analysis, flow cytometric, and brain slice analyses strongly support that high-level β1 integrin-expressing cells (eg, endothelial cells, pericytes, meninges, choroid plexus, and neural stem progenitor cells) are the first targets of MCMV. Therefore, our data demonstrate that the initial distributions of MCMV particles and β1 integrin determine the distinct pattern of infection in the brain in the acute phase.

Aberrant fetal macrophage/microglial reactions to cytomegalovirus infection.

Congenital cytomegalovirus (CMV) infection is the leading viral cause of neurodevelopmental disorders in humans, with the most severe and permanent sequelae being those affecting the cerebrum. As the fetal immune reactions to congenital CMV infection in the brain and their effects on cerebral development remain elusive, our aim was to investigate primitive innate immunity to CMV infection and its effects on cerebral corticogenesis in a mouse model for congenital CMV infection using a precise intraplacental inoculation method.

Effects of intrapulmonary viral tropism and cytokine expression on the histological patterns of cytomegalovirus pneumonia

Pulmonary cytomegalovirus (CMV) infection causes fatal CMV pneumonia (CMVp) in immunocompromised patients; however, the mechanisms underlying CMV‐infection‐induced pulmonary lesion development remain largely unknown. We examined the relationship between CMVp patterns and intrapulmonary viral tropism, including expression of inflammatory cytokines and related molecules. Double immunohistochemistry of CMV antigen and cellular markers showed that epithelial tropism was associated with a diffuse alveolar damage (DAD) pattern (CMVp‐DAD) while stromal tropism was associated with a predominantly interstitial inflammation/fibrosis (IIF) (CMVp‐IIF) or a combination of DAD and IIF (CMVp‐complex). Transforming growth factor (TGF)‐β1 expression was relevant to CMV‐induced tissue injury, and its expression was higher in CMVp‐complex and CMVp‐IIF than in CMVp‐DAD. Expression of integrin β6 (ITGB6), an adhesion molecule and important activator of TGF‐β1 in interstitial pneumonia, was lost in CMV‐infected pneumocytes, especially CMVp‐DAD, whereas CMV‐negative pneumocytes in CMVp‐complex and CMVp‐IIF showed overexpression. Diffuse interleukin (IL)‐8 up‐regulation and strong expression were present in both CMV‐infected pneumocytes and stromal cells only in CMVp‐IIF cases with marked interstitial neutrophilic infiltration. On the basis of viral tropism and the expression of TGF‐β1, ITGB6, and IL‐8, we conclude that CMV‐infected pulmonary cells play an important role in the development of diverse CMVp patterns.

Pathogenesis of developmental anomalies of the central nervous system induced by congenital cytomegalovirus infection

In humans, the herpes virus family member cytomegalovirus (CMV) is the most prevalent mediator of intrauterine infection‐induced congenital defect. Central nervous system (CNS) dysfunction is a distinguishing symptom of CMV infection, and characterized by ventriculoencephalitis and microglial nodular encephalitis. Reports on the initial distribution of CMV particles and its receptors on the blood brain barrier (BBB) are rare. Nevertheless, several factors are suggested to affect CMV etiology. Viral particle size is the primary factor in determining the pattern of CNS infections, followed by the expression of integrin β1 in endothelial cells, pericytes, meninges, choroid plexus, and neural stem progenitor cells (NSPCs), which are the primary targets of CMV infection. After initial infection, CMV disrupts BBB structural integrity to facilitate the spread of viral particles into parenchyma. Then, the initial meningitis and vasculitis eventually reaches NSPC‐dense areas such as ventricular zone and subventricular zone, where viral infection inhibits NSPC proliferation and differentiation and results in neuronal cell loss. These cellular events clinically manifest as brain malformations such as a microcephaly. The purpose of this review is to clearly delineate the pathophysiological basis of congenital CNS anomalies caused by CMV.

Benign and malignant tumor of the uterine body with broccoli sign: MR imaging features for differential diagnosis

The characteristic morphology called broccoli sign combines a stalk and prolapsed tumor and is a useful diagnostic indicator of prolapsed tumor of the uterine body. Magnetic resonance (MR) imaging findings of broccoli sign are common for uterine submucosal leiomyomata but not well described for other tumors of the endometrial cavity, such as endometrial polyp, atypical polypoid adenomyoma, endometrial carcinoma, carcinosarcoma, and adenosarcoma. Both benign and malignant masses of the uterine body can show broccoli sign. The MR imaging features of prolapsed uterine tumor with broccoli sign resemble those of usual uterine body tumors, but the location is different. We describe the MR imaging features of prolapsed uterine tumors with broccoli sign.

Podoplanin-positive myofibroblasts: a pathological hallmark of pleuroparenchymal fibroelastosis

Pathological differential diagnoses of pleuroparenchymal fibroelastosis (PPFE) include usual interstitial pneumonia (UIP) and pulmonary apical cap (PAC); however, there are no specific immunostaining makers to distinguish between these diseases. We performed immunohistochemistry using several pleural mesothelial cell‐related markers, including cytokeratin‐5/6, CAM5.2, WT‐1, calretinin, desmin and podoplanin, for PPFE (n = 4), UIP (n = 10) and PAC (n = 3) lung sections. Among the examined markers, in PPFE and PAC lungs podoplanin commonly showed positivity for spindle cells both in thickened pleura and subpleural fibroelastosis lesions; these cells were also stained with α‐smooth muscle actin, a marker of myofibroblasts. However, even in elastic fibre‐rich cases, UIP lungs did not show such podoplanin‐positive myofibroblasts in pleura/subpleura and fibroblastic foci. These findings were also verified using immunofluorescence. By contrast, immunohistochemically as well as morphologically, the difference between PPFE and PAC was not apparent. The presence of podoplanin‐positive myofibroblasts could be a pathological hallmark of PPFE, suggesting a pathogenic process distinct from UIP but common to PAC.

Phenotypic characterization of perivascular myoid cell neoplasms, using myosin 1B, a newly identified human pericyte marker

Our aims were to identify pericyte-specific markers for the analysis of formalin-fixed, paraffin-embedded human tissue samples, and to characterize perivascular myoid cell neoplasms phenotypically. Previously identified pericyte markers failed to distinguish pericytes from other cellular types, such as vascular smooth muscle cells (vSMCs) and fibroblasts, in immunohistochemistry analysis. However, we compared gene expression profiles between pericytes, vSMCs, and fibroblasts, and performed human skin vasculature immunohistochemistry analysis, which led to the identification of myosin 1B (MYO1B) as a novel pericyte marker. Afterward, we investigated the expression levels of MYO1B and h-caldesmon (h-CD) in perivascular myoid cell neoplasms, angioleiomyomas (n=28), glomus tumors (n=23), and myopericytomas (n=3). Angioleiomyomas were shown to contain MYO1B-negative and h-CD-positive (MYO1B-hCD+) tumor cells, with vSMC features. Glomus tumors were predominantly composed of the MYO1B+hCD+ tumor cells, with the intermediate features between pericytes and vSMCs, whereas MYO1B+hCD- tumor cells with pericytic features and/or the MYO1B-hCD+ tumor cells with vSMC features were frequently found in these tumors. The perivascular concentric pattern of 2 myopericytoma cases was composed of MYO1B+hCD+ tumor cells, whereas that of one myopericytoma contained MYO1B-hCD+ tumor cells. These results indicate that the ability to distinguish between these cell types may allow us to understand the differentiation and origin of perivascular myoid cell neoplasms. This is the first study to identify cell properties of perivascular myoid cell neoplasms by using a pericyte-specific marker with considerably lower expression in vSMCs and fibroblasts.

Intracerebroventricular and Intravascular Injection of Viral Particles and Fluorescent Microbeads into the Neonatal Brain

In the study on the pathogenesis of viral encephalitis, the infection method is critical. The first of the two main infectious routes to the brain is the hematogenous route, which involves infection of the endothelial cells and pericytes of the brain. The second is the intracerebroventricular (ICV) route. Once within the central nervous system (CNS), viruses may spread to the subarachnoid space, meninges, and choroid plexus via the cerebrospinal fluid. In experimental models, the earliest stages of CNS viral distribution are not well characterized, and it is unclear whether only certain cells are initially infected. Here, we have analyzed the distribution of cytomegalovirus (CMV) particles during the acute phase of infection, termed primary viremia, following ICV or intravascular (IV) injection into the neonatal mouse brain. In the ICV injection model, 5 µl of murine CMV (MCMV) or fluorescent microbeads were injected into the lateral ventricle at the midpoint between the ear and eye using a 10-µl syringe with a 27 G needle. In the IV injection model, a 1-ml syringe with a 35 G needle was used. A transilluminator was used to visualize the superficial temporal (facial) vein of the neonatal mouse. We infused 50 µl of MCMV or fluorescent microbeads into the superficial temporal vein. Brains were harvested at different time points post-injection. MCMV genomes were detected using the in situ hybridization method. Fluorescent microbeads or green fluorescent protein expressing recombinant MCMV particles were observed by fluorescent microscopy. These techniques can be applied to many other pathogens to investigate the pathogenesis of encephalitis.