Functional Differences of miR-125b on the Invasion of Primary Glioblastoma CD133-Negative Cells and CD133-Positive Cells

MicroRNAs (miRNAs) are small noncoding RNAs whose function as modulators of gene expression is crucial for the proper control of cell development, differentiation, and homeostasis. The total number and composition of miRNAs expressed per cell at different stages of development varies widely, and the same miRNA may function differently at different stages of development. In this prospective study, we evaluated the function of miR-125b at different developmental stages of glioblastoma cells, such as primary glioblastoma cells and the corresponding stem cells. CD133 is an important surface marker in glioblastoma stem cells. We found that the upregulation of miR-125b had no effects on the invasion of primary glioblastoma CD133-negative cells but that it could inhibit the invasion of corresponding CD133-positive cells; however, the downregulation of miR-125b also had no effects on the invasion of primary glioblastoma CD133-negative cells but promoted the invasion of CD133-positive cells. Further research into the underlying mechanism demonstrated that the effects of miR-125b on the invasion of glioblastoma CD133-positive cells were associated with the alteration of the expression of MMPs (MMP-2 and MMP-9) and corresponding inhibitors (RECK and TIMP3). Our results demonstrate that miR-125b expression plays an essential role in the invasion of glioblastoma CD133-positive cells but not CD133-negative cells. Therefore, miR-125b may represent a novel target for therapy targeting the invasion of glioblastoma stem cells in the future.     

Presence of pluripotent CD133+ cells correlates with malignancy of gliomas

BackgroundPresence of CD133⁺ cancer stem cells has been demonstrated within glioblastoma multiforme (GBM), the most malignant phenotype of gliomas (WHO grade IV). Since GBM frequently develops from low grade gliomas (WHO grade II) we assessed a possible qualitative or quantitative correlation of CD133⁺ cells and glioma grade to get new insights in gliomagenesis.ResultsThe amount of CD133⁺ cells within the bulk tumor mass, analyzed by immunostaining and Western blotting, showed a clear quantitative correlation with glioma grade (WHO° II, III and IV). Most of CD133⁺ cells were arranged in clusters frequently associated to tumor vessels. Protein analysis revealed high cellular coexpression of CD133 with Musashi-I but not CD34 indicating a neural, i.e. local origin of these cells. In vitro, no differences in stem cell properties concerning self-renewal and multi-lineage differentiation have been found for CD133⁺ cells isolated from gliomas of different grades.ConclusionsThese findings indicate a solely quantitative correlation of glioma grade with the presence of neural CD133⁺ cells within tumors supporting the concept of a CD133⁺ stem cell dependent gliomagenesis.     

Celecoxib enhances radiosensitivity in medulloblastoma-derived CD133-positive cells

Objects

Cyclooxygenase-2 (COX-2), the enzyme that converts arachidonic acid to prostaglandins, is overexpressed in a variety of tumors, including medulloblastoma (MB). CD133, a transmembrane glycoprotein, has been suggested as a marker for cancer stem cells in brain tumors. The aim of the present study was to investigate the role of celecoxib, a selective COX-2 inhibitor, in enhancing the effects of ionizing radiotherapy (IR) on medulloblastoma-derived CD133-positive cells (MB-CD133⁺).

Materials and methods

MB-CD133⁺ were isolated from two medulloblastoma cell lines (Daoy and UW228). Then, they were treated with celecoxib in different concentrations, and cell viability was assessed. The assays of cell survival, soft agar, radiosensitivity, colony formation, and apoptotic activity in MB-CD133⁺ treated with celecoxib alone, radiation alone, or celecoxib combined with radiation were further evaluated.

Results

MB-CD133⁺ showed the self-renew ability to form sphere bodies in vitro and regenerate tumors in vivo. The levels of COX-2 mRNA and protein in MB-CD133⁺ were significantly higher than those in MB-CD133^?. The treatment of 30 μM celecoxib could effectively inhibit the abilities of cell proliferation and colony formation and increase IR-induced apoptosis in treated MB-CD133⁺. Furthermore, in vivo study demonstrated that celecoxib significantly enhanced radiosensitivity in MB-CD133⁺-transplanted grafts. Notably, xenotransplantation analysis demonstrated that the treatment of celecoxib could further suppress the expressions of angiogenic and stemnness-related genes in treated MB-CD133⁺ grafts of SCID mice.

Conclusions

Celecoxib presents the potential of radiosensitizing effect in MB-derived cancer stem cells. Therefore, it should be warranted in future trials to enhance the radiotherapeutic effects in MB patients.     

Mobilization of CD133+CD34− cells in healthy individuals following whole‐body acupuncture for spinal cord injuries

Acupuncture can alleviate symptoms of spinal cord injuries (SCI). The underlying mechanism, however, is unknown. We hypothesized that stem cells could be mobilized by acupuncture. Therefore, we enrolled 14 healthy study participants using acupuncture points for the treatment of SCI. The frequency of CD133 and CD34 cells in peripheral blood and the serum concentrations of matrix metalloproteinase (MMP)‐9, brain‐derived neurotrophic factor (BDNF), nerve growth factor (NGF), and interleukin‐6 were determined before and after acupuncture (<1 hr, 24 hr, and 48 hr). CD133⁺34^? cells were doubled 48 hr after acupuncture, with concomitant decreases in BDNF and MMP‐9 levels. Interleukin‐6 remained below detectable levels, eliminating a stress‐induced cell release. Individuals acupunctured on control counterpoints showed no changes in CD133⁺ cells. Our results indicate that acupuncture for SCI can mobilize human CD133⁺34^? cells. © 2009 Wiley‐Liss, Inc.     

Enhanced cell growth and tumorigenicity of rat glioma cells by stable expression of human CD133 through multiple molecular actions

CD133 (Prominin‐1/AC133) is generally treated as a cell surface marker found on multipotent stem cells and tumor stem‐like cells, and its biological function remains debated. Genetically modified rat glioma cell lines were generated by lentiviral gene delivery of human CD133 into rat C6 glioma cells (hCD133⁺‐C6) or by infection of C6 cells with control lentivirus (mock‐C6). Stable hCD133 expression promoted the self‐renewal ability of C6‐formed spheres with an increase in the expression of the stemness markers, Bmi‐1 and SOX2. Akt phosphorylation, Notch‐1 activation, and Notch‐1 target gene expression (Hes‐1, Hey1 and Hey2) were increased in hCD133⁺‐C6 when compared to mock‐C6. The inhibition of Akt phosphorylation, Notch‐1 activation, and Hes‐1 in hCD133⁺‐C6 cells effectively suppressed their clonogenic ability, indicating that these factors are involved in expanding the growth of hCD133⁺‐C6. An elevated expression of GTPase‐activating protein 27 (Arhgap27) was detected in hCD133⁺‐C6. A decline in the invasion of hCD133⁺‐C6 by knockdown of Arhgap27 expression indicated the critical role of Arhgap27 in promoting cell migration of hCD133⁺‐C6. In vivo study further showed that hCD133⁺‐C6 formed aggressive tumors in vivo compared to mock‐C6. Exposure of hCD133⁺‐C6 to arsenic trioxide not only reduced Akt phosphorylation, Notch‐1 activation and Hes‐1 expression in vitro, but also inhibited their tumorigenicity in vivo. The results show that C6 glioma cells with stable hCD133 expression enhanced their stemness properties with increased Notch‐1/Hes‐1 signaling, Akt activation, and Arhgap27 action, which contribute to increased cell proliferation and migration of hCD133⁺‐C6 in vitro, as well as progressive tumor formation in vivo.     

CD133 cells from human umbilical cord blood reduce cortical damage and promote axonal growth in neonatal rat organ co-cultures exposed to hypoxia

To evaluate the effect of CD133⁺ cells (endothelial progenitor cells) on the hypoxia-induced suppression of axonal growth of cortical neurons and the destruction of blood vessels (endothelial cells), we used anterograde axonal tracing and immunofluorescence in organ co-cultures of the cortex and the spinal cord from 3-day-old neonatal rats. CD133⁺ cells prepared from human umbilical cord blood were added to the organ co-cultures after hypoxic insult, and axonal growth, vascular damage and apoptosis were evaluated. Anterograde axonal tracing with 1,1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine perchlorate was used to analyze axonal projections from the cortex to the spinal cord. Immunolabeling co-cultured tissues of the cortex and the spinal cord were used to investigate the effect of CD133⁺ cells on the survival of blood vessels and apoptosis in the brain cortex. Hypoxia remarkably suppressed axonal growth in organ co-cultures of the cortex and the spinal cord, and this suppression was significantly restored by the addition of CD133⁺ cells. CD133⁺ cells also reduced the hypoxia-induced destruction of the cortical blood vessels and apoptosis. CD133⁺ cells had protective effects on hypoxia-induced injury of neurons and blood vessels of the brain cortex in vitro. These results suggest that CD133⁺ cell transplantation may be a possible therapeutic intervention for perinatal hypoxia-induced brain injury.     

Type 1 collagen as a potential niche component for CD133‐positive glioblastoma cells

Cancer stem cells are thought to be closely related to tumor progression and recurrence, making them attractive therapeutic targets. Stem cells of various tissues exist within niches maintaining their stemness. Glioblastoma stem cells (GSCs) are located at tumor capillaries and the perivascular niche, which are considered to have an important role in maintaining GSCs. There were some extracellular matrices (ECM) on the perivascular connective tissue, including type 1 collagen. We here evaluated whether type 1 collagen has a potential niche for GSCs. Imunohistochemical staining of type 1 collagen and CD133, one of the GSCs markers, on glioblastoma (GBM) tissues showed CD133‐positive cells were located in immediate proximity to type 1 collagen around tumor vessels. We cultured human GBM cell lines, U87MG and GBM cells obtained from fresh surgical tissues, T472 and T555, with serum‐containing medium (SCM) or serum‐free medium with some growth factors (SFM) and in non‐coated (Non‐coat) or type 1 collagen‐coated plates (Col). The RNA expression levels of CD133 and Nestin as stem cell markers in each condition were examined. The Col condition not only with SFM but SCM made GBM cells more enhanced in RNA expression of CD133, compared to Non‐coat/SCM. Semi‐quantitative measurement of CD133‐positive cells by immunocytochemistry showed a statistically significant increase of CD133‐positive cells in Col/SFM. In addition, T472 cell line cultured in the Col/SFM had capabilities of sphere formation and tumorigenesis. Type 1 collagen was found in the perivascular area and showed a possibility to maintain GSCs. These findings suggest that type 1 collagen could be one important niche component for CD133‐positive GSCs and maintain GSCs in adherent culture.     

CD133+ glioblastoma stem-like cells induce vascular mimicry in vivo

Glioblastoma is one of the most angiogenic malignancy, the neoplastic vessels of which are likely to arise by angiogenesis and vasculogenesis. An alternative mechanism of tumor vasculature is described, termed vasculogenic mimicry, by which highly aggressive tumor cells can form vessel-like structures themselves, by virtue of their high cellular plasticity. Evidence suggests that cancer stem cells acquire a multi-potent plastic phenotype and show vasculogenic potential. In this study, we report that glioblastoma stem-like cells (GSCs) can form vasculogenic mimicry in tumor xenografts and express pro-vascular molecules. We isolated GSCs from resected human glioblastoma tissues and demonstrated their stemness, differentiation, and in vivo tumor-initiating potential. Through a limiting dilution assay, CD133+ (CD133(+)-GSC) and CD133- (CD133(-)-GSC) subpopulation of GSCs were obtained. Orthotopic xenotransplantation study revealed that these two subpopulations of GSCs shared similar efficacy in tumor formation but showed distinct intratumor vasculature. In comparison with CD133(-)-GSC, a highly vascularized anaplastic tumor, mimicking vasculogenic mimicry, was found in CD133(+)-GSC-derived tumor xenografts. Subsets of CD133(+)-GSC but not CD133(-)-GSC were capable of vascular smooth muscle-like cell differentiation, in vitro and in vivo. In tumor xenografts, endothelium-associated CD31 gene was detected in implanted CD133(-)-GSC and exclusively dispersed within the tumor tissues. Although the detailed action mechanisms required further investigation, this study demonstrated the vasculogenic capacity of brain GSCs and their cellular plasticity. The results of expression of pro-vascular molecules and differentiation of vascular-like cells suggest that GSCs may contribute to form vessel-like structures and provide a blood supply for glioblastoma cells.     

Lesional accumulation of CD8<Superscript>+</Superscript> cells in sciatic nerves of experimental autoimmune neuritis rats

Experimental autoimmune neuritis (EAN) is a well-known animal model of human demyelinating polyneuropathies. Macrophages are the major immune cells in peripheral nerves and may exert tissue-damage or tissue-protective activity during EAN. While considered to define a subpopulation of T lymphocytes, CD8 expression has been found on certain macrophages that show cytotoxic effects. Here we have studied the spatiotemporal accumulation of CD8⁺ cells in sciatic nerves of EAN rats. A robust accumulation of CD8⁺ cells was observed in the sciatic nerves of EAN rats, which was positively correlated with the severity of neurological signs in EAN. Moreover, double-labelling experiments showed that the major cellular sources of CD8 were reactive macrophages. Therefore, our data here suggest a pathological role of CD8⁺ macrophages in EAN, which makes CD8⁺ macrophage a potential therapeutic target for EAN.     

CD133基因表达与人脑胶质瘤恶性程度相关性分析

目的探讨人脑胶质瘤组织中胶质瘤干细胞标志物CD133的表达与肿瘤恶性程度的关系。方法应用实时荧光定量PCR方法检测75例不同病理级别胶质瘤组织及4例正常脑组织中CD133基因的表达情况，并与肿瘤病理级别进行相关性分析；同时采用免疫组化法检测35例肿瘤组织和2例正常脑组织中CD133的表达情况，在蛋白表达水平予以验证。结果CD133在基因转录水平和蛋白表达水平具有良好的相关性。CD133在正常脑组织中未见表达，在各级别胶质瘤中均有表达，且差异有显著性（P〈0．01）；CD133表达量与肿瘤的恶性程度呈正相关（P〈0．01）。结论检测胶质瘤CD133表达水平有助于评价肿瘤的生物学行为，并为针对肿瘤干细胞的靶向治疗提供参考依据。     

Human Umbilical Cord Blood CD45<Superscript>+</Superscript> Pan-Hematopoietic Cells Induced a Neurotherapeutic Effect in Mice with Traumatic Brain Injury: Immunophenotyping,Comparison of Maternal and Neonatal Parameters,and Immunomodulation

Human umbilical cord blood (HUCB) transplantation has become an alternative cell therapy for hematological and oncological malignancies in the clinic and is considered for neurological disorders. The heterogeneity in the content of the different stem and progenitor cells composing HUCB mononuclear cells (MNC) may influence their engraftment and neurotherapeutic effect. We hypothesized that CD45 pan-hematopoietic marker expression is heterogeneous in MNC, and therefore, CD45⁺ subpopulation enrichment for neurotherapy may provide a tool to overcome cellular variance in different HUCB units. We employed an immunomagnetic separation method to isolate and characterize HUCB CD45⁺ pan-hematopoietic subpopulation and to investigate whether the vaginal or cesarean deliveries influence their neurotherapeutic effect in a traumatic brain injury (TBI) mouse model. Adult C57BL/6J male mice were subjected to moderate TBI and intravenously xenotransplanted with 1?×?10⁶ CD45⁺ cells derived from either vaginal or cesarean HUCB units. A large heterogeneity in the expression of CD45 marker in MNC, both in vaginal and cesarean HUCB units, was found, regardless of the number of live births. A higher expression of hematopoietic markers was found in the CD45⁺ subpopulation while low expressional levels of typical mesenchymal markers were detected. Neurotherapeutic effects, evaluated with an established neurological severity score and novel object recognition test, indicated improved functional motor and memory recovery and found independent of delivery type. Cytokine analysis in extracts of TBI brain cortices indicated an acute immunomodulatory effect by HUCB CD45⁺ subpopulation upon xenotransplantation. These results may provide insights to CD45 marker as a predictor of HUCB units’ quality for neurotherapy in TBI.     

Blood vessels expressing CD90 in human and rat brain tumors

Blood vessels in brain tumors, particularly glioblastomas, have been shown to express CD90. CD90⁺ cells in and around blood vessels in cancers including brain tumors have been identified as endothelial cells, cancer stem cells, fibroblasts or pericytes. In this study, we aimed to determine the nature or type(s) of cells that express CD90 in human brain tumors as well as an experimental rat glioma model by double immunofluorescence staining. The majority of CD90⁺ cells in human glioblastoma tissue expressed CD31, CD34 and von Willebrand factor, suggesting that they were endothelial cells. Vasculatures in a metastatic brain tumor and meningioma also expressed CD90. CD90⁺ cells often formed glomeruloid structures, typical of angiogenesis in malignant tumors, not only in glioblastoma but also in metastatic tumors. Some cells in the middle and outer layers of the vasculatures expressed CD90. Similar results were obtained in the rat glioma model. There were cells expressing both α‐smooth muscle actin and CD90 in the middle layer of blood vessels, indicating that smooth muscle cells and/or pericytes may express CD90. CD90⁺ vasculatures were surrounded by tumor‐associated macrophages (TAMs). Thus, in addition to endothelial cells, some other types of cells, such as smooth muscle cells, pericytes and fibroblasts constituting the vasculature walls in brain tumors expressed CD90. Because CD90 has been shown to interact with integrins expressed by circulating monocytes, CD90 might be involved in angiogenesis through recruitment and functional regulation of TAMs in tumors. CD90⁺ vasculatures may also interact with tumor cells through interactions with integrins. Because CD90 was not expressed by vasculatures in normal brain tissue, it might be a possible therapeutic target to suppress angiogenesis and tumor growth.     

The pathological characteristics of glioma stem cell niches

Brain tumor stem cells (BTSC) are predicted to be critical drivers of tumor progression due to their self-renewal capacity and limitless proliferative potential. Recent studies suggest that stem cells are controlled by a particular microenvironment known as a “niche”. We therefore analysed human glioma tissues and found that the CD133⁺ and nestin⁺ niches are perivascularly localized in all glioma tissues. Furthermore, there is a positive correlation between the CD133⁺ niches and CD133⁺ blood vessels, which is similar to the correlation between the nestin⁺ niches and nestin⁺ blood vessels. We demonstrate that both CD133⁺ blood vessels and nestin⁺ blood vessels have an important role in maintaining the structure of the glioma stem cell niche. Moreover, the abundance of CD133⁺ niches and nestin⁺ niches increases significantly as tumor grade increases. These findings provide a new insight into the biology of BTSC and open a new perspective for targeted therapy against the brain tumors.     

Antiviral CD8<Superscript>+</Superscript> T cells cause an experimental autoimmune encephalomyelitis-like disease in naive mice

Major histocompatibility complex class I-restricted CD8⁺ cytotoxic T lymphocytes are involved in the pathogenesis of multiple sclerosis (MS) and both autoimmune, experimental autoimmune encephalomyelitis, and viral, Theiler’s murine encephalomyelitis virus (TMEV) infection, animal models of MS. Following TMEV infection, certain T cell hybridomas, generated from cloned TMEV-induced CD8⁺ T cells, were able to produce clinical signs of disease (flaccid hind limb paralysis) upon adoptive transfer into naive mice. Dual T cell receptors (TCR) are present on the surface of these cells as both Vβ3 and Vβ6 were detected by polymerase chain reaction (PCR) screening and flow cytometry and multiple Vα mRNAs were detected by PCR screening. This is the first demonstration of antiviral CD8⁺ T cells having more than one TCR initiating an autoimmune disease in the natural host of the virus. We hypothesize that this is a potential mechanism for virus-induced autoimmune disease initiated by CD8⁺ T cells.     

Severe Hyperhomocysteinemia Decreases Respiratory Enzyme and Na<Superscript>+</Superscript>-K<Superscript>+</Superscript> ATPase Activities,and Leads to Mitochondrial Alterations in Rat Amygdala

Severe hyperhomocysteinemia is caused by increased plasma levels of homocysteine (Hcy), a methionine derivative, and is associated with cerebral disorders. Creatine supplementation has emerged as an adjuvant to protect against neurodegenerative diseases, due to its potential antioxidant role. Here, we examined the effects of severe hyperhomocysteinemia on brain metabolism, and evaluated a possible neuroprotective role of creatine in hyperhomocysteinemia, by concomitant treatment with Hcy and creatine (50 mg/Kg body weight). Hyperhomocysteinemia was induced in young rats (6-day-old) by treatment with homocysteine (0.3–0.6 µmol/g body weight) for 23 days, and then the following parameters of rat amygdala were evaluated: (1) the activity of the respiratory chain complexes succinate dehydrogenase, complex II and cytochrome c oxidase; (2) mitochondrial mass and membrane potential; (3) the levels of necrosis and apoptosis; and (4) the activity and immunocontent of Na⁺,K⁺-ATPase. Hcy treatment decreased the activities of succinate dehydrogenase and cytochrome c oxidase, but did not alter complex II activity. Hcy treatment also increased the number of cells with high mitochondrial mass, high mitochondrial membrane potential, and in late apoptosis. Importantly, creatine administration prevented some of the key effects of Hcy administration on the amygdala. We also observed a decrease in the activity and immunocontent of the α1 subunit of the Na⁺,K⁺-ATPase in amygdala after Hcy- treatment. Our findings support the notion that Hcy modulates mitochondrial function and bioenergetics in the brain, as well as Na⁺,K⁺-ATPase activity, and suggest that creatine might represent an effective adjuvant to protect against the effects of high Hcy plasma levels.     

Inhibition of phosphorylated STAT3 by cucurbitacin I enhances chemoradiosensitivity in medulloblastoma-derived cancer stem cells

Introduction

CD133 (PROM1) is a potential marker for cancer stem cells (CSCs), including those found in brain tumors. Recently, medulloblastoma (MB)-derived CD133-positive cells were found to have CSC-like properties and were proposed to be important contributors to tumorigenicity, cancer progression, and chemoradioresistance. However, the biomolecular pathways and therapeutic targets specific to MB-derived CSCs remain unresolved.

Materials and methods

In the present study, we isolated CD133⁺ cells from MB cell lines and determined that they showed increased tumorigenicity, radioresistance, and higher expression of both embryonic stem cell-related and drug resistance-related genes compared to CD133^? cells. Bioinformatics analysis suggested that the STAT3 pathway might be important in MB and CD133⁺ cells. To evaluate the effects of inhibiting the STAT3 pathway, MB-derived CD133^+/? cells were treated with the potent STAT3 inhibitor, cucurbitacin I. Treatment with cucurbitacin I significantly suppressed the CSC-like properties and stemness gene signature of MB-derived CD133⁺ cells. Furthermore, cucurbitacin I treatment increased the apoptotic sensitivity of MB-derived CD133⁺ cells to radiation and chemotherapeutic drugs. Notably, cucurbitacin I demonstrated synergistic effects with ionizing radiation to inhibit tumorigenicity in MB-CD133⁺-inoculated mice.

Results

These results indicate that the STAT3 pathway plays a key role in mediating CSC properties in MB-derived CD133⁺ cells. Targeting STAT3 with cucurbitacin I may therefore represent a novel therapeutic approach for treating malignant brain tumors.