SUMMARY: Cytomegalovirus (CMV) is the most frequent infectious cause of developmental disorders of the central nervous system (CNS) in humans. Infection of the CNS stem cells seems to be primarily responsible for the generation of the brain abnormalities. In this study, we evaluated the infectivity of murine CMV (MCMV) in epidermal growth factor (EGF)-responsive CNS stem cells prepared from fetal mouse brains, and studied the effect of infection on growth and differentiation of the stem cells. The CNS stem cells were permissive for MCMV infection, although MCMV replication was slower than in mouse embryonic fibroblasts. MCMV infection inhibited the growth and DNA replication of the stem cells. A clonogenic assay revealed that MCMV infection suppressed generation of colonies from single stem cells. When uninfected stem cells were induced to differentiate, a decrease in expression of the primitive neuroepidermal marker nestin was observed by immunocytochemistry and flow cytometry, whereas expression of neurofilament and glial fibrillary acidic protein (GFAP) were induced. In virus-infected CNS stem cells, nestin expression was retained, whereas the expression of neurofilament was more severely inhibited than that of GFAP in these cells. Two-color flow cytometry showed that differentiated glial precursor cells were preferentially susceptible to MCMV infection. MCMV-infected and uninfected CNS stem cells were transplanted into the neonatal rat brains. The reduced number of infected stem cells were engulfed into the subventricular zone and expressed GFAP, but did not migrate further, in contrast to the uninfected stem cells. These results suggest that suppression of the growth of the CNS stem cells and inhibition of the neuronal differentiation by CMV infection may be primary causes of disorders of brain development in congenital CMV infection. (Lab Invest 2000, 80:1373-1383.
The hypothesis that both activated Kupffer cells and the spleen may be responsible for endotoxin-induced liver injury following partial hepatectomy was investigated. Male rats were divided into a sham group receiving laparotomy alone and three groups receiving a two-thirds hepatectomy; one group was given normal saline (NS) solution as a vehicle control, one group received intravenous gadolinium chloride (GC group) (7 mg/kg body weight) for 2 days before intravenous injection of endotoxin to inhibit Kupffer cell phagocytosis, and the third group simultaneously underwent splenectomy and partial hepatectomy (SH group). As endotoxin, lipopolysaccharide (LPS) (1 mg/kg body weight) was administered intravenously 2 days after surgery. In the GC and SH groups, phagocytic activity was reduced to approximately 40% of that in the sham group. The highest plasma tumor necrosis factor alpha (TNF-alpha) level (8,544 +/- 1,223 pg/mL) was observed in the NS group at 1 hour after LPS administration, and the level was significantly reduced by GdCl3 or splenectomy (P < 0.05). Inhibition of Kupffer cell function and splenectomy attenuated functional and structural liver damage associated with the decreased hepatic infiltration of polymorphonuclear leukocytes (PMNs) and reduced priming of circulating PMNs in the early stage of endotoxemia following partial hepatectomy. Consequently, the 24-hour survival rate of the SH and GC groups was significantly improved to 50% and 80%, respectively (P < .05), while that of the NS group was 12.5%. These findings indicate that the modification of inflammatory mediator generation by splenectomy or inhibition of Kupffer cell function may be beneficial for the prevention of endotoxin-induced liver injury after partial hepatectomy.
Cytomegalovirus (CMV) is the most frequent infectious cause of developmental brain disorders in humans. Here we show the role of innate immune responses caused by natural killer (NK) cells and nitric oxide (NO) derived from brain macrophages during murine CMV (MCMV) infection of the developing brain. Viral replication in the brain of newborn mice was significantly enhanced by administration of anti-asialo-GM1 antibody, specific for NK cells, or L-N6-(1-imminoethyl)-lysine, a specific inhibitor of NO synthase 2 (NOS2). These results suggest that NK cells and NO contribute to the viral clearance from the brain. At 3 days postinfection (dpi) MCMV early antigen (Ag)-positive cells were immunohistochemically detected in the periventricular area, where most of the positive cells were macrophages. At 7 dpi MCMV-Ag was found not only in cells of the periventricular area but also in neurons of the hippocampus and cortex. At 11 dpi MCMV-Ag disappeared from the periventricular area, but persisted in neurons. In the periventricular area, NK cells and NOS2-positive macrophages were associated with MCMV-Ag-positive cells. In contrast, there were very few NK cells and NOS2-positive macrophages around the MCMV-Ag-positive neurons. In situ hybridization for MCMV DNA demonstrated that positive signals were found mostly in the periventricular cells, and rarely in neurons. These results suggest that the innate immune responses are restricted to the virus-replicating cells, and do not affect MCMV-infected neurons. Therefore, evasion of the innate immune responses by MCMV-infected neurons may be an important factor in supporting the viral persistence in the developing brain.
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.
Pin2/TRF1 was independently identified as a telomeric DNA binding protein (TRF1) [1] and as a protein (Pin2) that can bind the mitotic kinase NIMA and suppress its ability to induce mitotic catastrophe [2, 3]. Pin2/TRF1 has been shown to bind telomeric DNA as a dimer [3-7] and to negatively regulate telomere length [8-11]. Interestingly, Pin2/TRF1 levels are regulated during the cell cycle, being increased in late G2 and mitosis and degraded as cells exit from mitosis [3]. Furthermore, overexpression of Pin2/TRF1 induces mitotic entry and then apoptosis [12]. This Pin2/TRF1 activity can be significantly potentiated by the microtubule-disrupting agent nocodazole [12] but is suppressed by phosphorylation of Pin2/TRF1 by ATM; this negative regulation is important for preventing apoptosis upon DNA damage [13]. These results suggest a role for Pin2/TRF1 in mitosis. However, nothing is known about how Pin2/TRF1 is involved in mitotic progression. Here, we describe a surprising physical interaction between Pin2/TRF1 and microtubules in a cell cycle-specific manner. Both expressed and endogenous Pin2/TRF1 proteins were localized to the mitotic spindle during mitosis. Furthermore, Pin2/TRF1 directly bound microtubules via its C-terminal domain. Moreover, Pin2/TRF1 also promoted microtubule polymerization in vitro. These results demonstrate for the first time a specific interaction between Pin2/TRF1 and microtubules in a mitosis-specific manner, and they suggest a new role for Pin2/TRF1 in modulating the function of microtubules during mitosis.
Cytomegalovirus (CMV) is the most frequent infectious cause of developmental brain disorders and also causes brain damage in immunocompromised individuals. Although the brain is one of the main targets of CMV infection, little is known about the neuropathogenesis of the brain disorders caused by CMV in humans because of the limitations in studying human subjects. Murine CMV (MCMV) is similar to human CMV (HCMV) in terms of genome structure, pattern of gene expressions, cell tropism and infectious dynamics. In mouse models, it has been shown that neural stem/progenitor cells are the most susceptible to CMV infection in developing brains. During brain development, lytic infection tends to occur in immature glial cells, presumably causing structural disorders of the brain. In the prolonged phase of infection, CMV preferentially infects neuronal cells. Infection of neurons may tend to become persistent by evasion of immune reactions, anti-apoptotic effects and neuron-specific activation of the e1-promoter, presumably causing functional neuronal disorders. It has also been shown that CMV infection in developing brains may become latent in neural immature cells. Brain disorders may occur long after infection by reactivation of the latent infection.
dThe Wnt/-catenin pathway promotes proliferation of neural progenitor cells (NPCs) at early stages and induces neuronal differentiation from NPCs at late stages, but the molecular mechanisms that control this stage-specific response are unclear. Pin1 is a prolyl isomerase that regulates cell signaling uniquely by controlling protein conformation after phosphorylation, but its role in neuronal differentiation is not known. Here we found that whereas Pin1 depletion suppresses neuronal differentiation, Pin1 overexpression enhances it, without any effects on gliogenesis from NPCs in vitro. Consequently, Pin1-null mice have significantly fewer upper layer neurons in the motor cortex and severely impaired motor activity during the neonatal stage. A proteomic approach identified -catenin as a major substrate for Pin1 in NPCs, in which Pin1 stabilizes -catenin. As a result, Pin1 knockout leads to reduced -catenin during differentiation but not proliferation of NPCs in developing brains. Importantly, defective neuronal differentiation in Pin1 knockout NPCs is fully rescued in vitro by overexpression of -catenin but not a -catenin mutant that fails to act as a Pin1 substrate. These results show that Pin1 is a novel regulator of NPC differentiation by acting on -catenin and provides a new postphosphorylation signaling mechanism to regulate developmental stage-specific functioning of -catenin signaling in neuronal differentiation. N eurons are generated from neural stem/progenitor cells (NPCs) during brain development. Recently, it has been emerging that an array of extracellular factors, including Wnt, platelet-derived growth factor, vascular endothelial growth factor, and bone morphogenic proteins, trigger signaling cascades leading to activation of downstream transcription factors to regulate neuronal differentiation from NPCs (6,16,18,22,23,33,51,68,86,91). However, little is known about how these signaling pathways are integrated to control the highly ordered events of neuronal differentiation to generate neurons in different layers or subregions of the brain during development.A well-established key signaling pathway in neurogenesis is the Wnt/-catenin pathway (13,16,18,22,46,62). For example, overexpression of constitutively active -catenin in NPCs induces neurogenesis and increases cortical size (12,23,90). Similarly, overexpression of Wnt3 increases neurogenesis in cortical progenitor cells (26, 43) and adult hippocampal stem/progenitor cells (34). Conversely, ablation of -catenin inhibits neurogenesis, leading to reduced brain size (23, 90). Finally, activation of the Wnt/-catenin pathway leads to the formation of -catenin-TCF complexes to transactivate Wnt target genes, including many proneural transcription factors (25,30,48,79). Significantly, the in vivo function of Wnt/-catenin signaling in neuronal differentiation depends on the developmental stage during brain development. It appears to promote proliferation of early NPCs (expansion phase) but induces neuronal differentiation of NPCs in the la...
Disordered migration and loss of virus-infected neuronal cells in developing mouse brains infected with murine cytomegalovirus
Microcephaly is the most prominent symptom of the developmental brain abnormalities induced by congenital cytomegalovirus (CMV) infection. To investigate the effect of CMV infection on neuronal migration in developing brains, mouse embryos on one side of uteri received, on day 15.5 of gestation (E15.5), an injection of murine CMV (MCMV) into the cerebral ventricles, and the embryos on the other side of the uteri were injected with minimum essential medium (MEM). Labeling with 5-bromo-2-deoxyuridine (BrdU) was accomplished by intraperitoneal injection of BrdU 6 h later. Disturbance of the neuronal migration and loss of neurons were observed postnatally in the brains of MCMV-infected mice, which were identified by immunohistochemical staining of viral antigen. Double staining of BrdU-labeled and viral antigen-positive cells in brains on the 7th postnatal day showed that the migration of BrdU-single-labeled cells, mainly localized in cerebral layers II-III, mostly preceded that of the viral antigen-positive cells. However, about 7.5% of the cells observed were double-labeled, especially in the layers III-IV, and a few double-stained cells were markedly disturbed in migration. In the brains of offspring labeled with BrdU 72 h after infection with MCMV on E15.5, most of the double-stained cells were seen around the ventricular and subventricular zones. These findings suggest that a disturbance of neuronal migration in addition to neuronal loss may play a crucial role in the development of microcephaly in congenital CMV infection in humans.
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