Jinhong Shi

Therapeutic Effect of Human Umbilical Cord Mesenchymal Stem Cells on Neonatal Rat Hypoxic-Ischemic Encephalopathy

The therapeutic potential of umbilical cord blood mesenchymal stem cells has been studied in several diseases. However, the possibility that human umbilical cord Whartons jelly‐derived mesenchymal stem cells (hUCMSCs) can be used to treat neonatal hypoxic–ischemic encephalopathy (HIE) has not yet been investigated. This study focuses on the potential therapeutic effect of hUCMSC transplantation in a rat model of HIE. Dermal fibroblasts served as cell controls. HIE was induced in neonatal rats aged 7 days. hUCMSCs labeled with Dil were then transplanted into the models 24 hr or 72 hr post‐HIE through the peritoneal cavity or the jugular vein. Behavioral testing revealed that hUCMSC transplantation but not the dermal fibroblast improved significantly the locomotor function vs. vehicle controls. Animals receiving cell grafts 24 hr after surgery showed a more significant improvement than at 72 hr. More hUCMSCs homed to the ischemic frontal cortex following intravenous administration than after intraperitoneal injection. Differentiation of engrafted cells into neurons was observed in and around the infarct region. Gliosis in ischemic regions was significantly reduced after hUCMSC transplantation. Administration of ganglioside (GM1) enhanced the behavioral recovery on the base of hUCMSC treatment. These results demonstrate that intravenous transplantation of hUCMSCs at an early stage after HIE can improve the behavior of hypoxic–ischemic rats and decrease gliosis. Ganglioside treatment further enhanced the recovery of neurological function following hUCMSC transplantation.

Identification of neonatal rat hippocampal radial glia cells in vitro

The role of radial glia cells (RGCs) as neural progenitors and as guides for migrating neurons is well established, whereas their precise contribution to adult hippocampal neurogenesis remains less understood. To precisely study the properties of hippocampal RGCs under normal conditions in vitro, here we acquired the hippocampal RGCs of postnatal 1 d rats under adherent conditions in vitro, identified their astroglia and stem/progenitor properties. We found that the neonatal rat hippocampal RGCs had longer processes than the RGCs from fetal cerebral cortices, and these cells could be double-labeled by BLBP, GFAP, Vimentin with Nestin and expressed some stem/progenitor genes, these cells also presented multiple differentiation potentialities, albeit the ability of gliogenesis far exceeded the neurogenesis under normal culture conditions in vitro. Taken together, we acquired and identified some properties of the RGCs from neonatal rat hippocampi in vitro.

Cortical Endogenic Neural Regeneration of Adult Rat after Traumatic Brain Injury

Focal and diffuse neuronal loss happened after traumatic brain injury (TBI). With little in the way of effective repair, recent interest has focused on endogenic neural progenitor cells (NPCs) as a potential method for regeneration. Whether endogenic neural regeneration happened in the cortex of adult rat after TBI remains to be determined. In this study, rats were divided into a sham group and a TBI group, and the rat model of medium TBI was induced by controlled cortical impact. Rats were injected with BrdU at 1 to 7 days post-injury (dpi) to allow identification of differentiated cells and sacrificed at 1, 3, 7, 14 and 28 dpi for immunofluorescence. Results showed nestin+/sox-2+ NPCs and GFAP+/sox-2+ radial glial (RG)-like cells emerged in peri-injured cortex at 1, 3, 7, 14 dpi and peaked at 3 dpi. The number of GFAP+/sox-2+ cells was less than that of nestin+/sox-2+ cells. Nestin+/sox-2+ cells from posterior periventricle (pPV) immigrated into peri-injured cortex through corpus callosum (CC) were found. DCX+/BrdU+ newborn immature neurons in peri-injured cortex were found only at 3, 7, 14 dpi. A few MAP-2+/BrdU+ newborn neurons in peri-injured cortex were found only at 7 and 14 dpi. NeuN+/BrdU+ mature neurons were not found in peri-injured cortex at 1, 3, 7, 14 and 28 dpi. While GFAP+/BrdU+ astrocytes emerged in peri-injured cortex at 1, 3, 7, 14, 28 dpi and peaked at 7 dpi then kept in a stable state. In the corresponding time point, the percentage of GFAP+/BrdU+ astrocytes in BrdU+ cells was more than that of NPCs or newborn neurons. No CNP+/BrdU+ oligodendrocytes were found in peri-injured cortex. These findings suggest that NPCs from pPV and reactive RG–like cells emerge in peri-injured cortex of adult rats after TBI. It can differentiate into immature neurons and astrocytes, but the former fail to grow up to mature neurons.

The role of Brn-4 in the regulation of neural stem cell differentiation into neurons.

Brn-4, a member of the homeobox family of transcription factors, has previously been implicated in the regeneration and repair of denervated striatum. We investigated the effects of Brn-4 on the differentiation and development of neural stem cells (NSCs) from E16 rat hippocampus. Immunocytochemistry revealed that extracts of deafferented hippocampus promoted neuronal differentiation to a greater extent than extracts from normal hippocampus. Deafferented extracts also promoted maturation of newborn neurons as reflected in changes in cell areas and perimeters, and enhanced Brn-4 expression in MAP-2 positive neurons. Suppression or overexpression of Brn-4 in NSCs markedly decreased or increased neuronal differentiation and maturation of newborn neurons, respectively. These results suggest that Brn-4 expression is required both for neuronal differentiation of NSCs and maturation of newborn neurons, and that there may be some regulatory factors in deafferented hippocampus that can regulate Brn-4 expression in neuronal progenitors. Brn-4 is therefore a potential research target for the development of new therapeutics to promote brain repair.

Characterization and identification of Sox2+ radial glia cells derived from rat embryonic cerebral cortex

During the central nervous system (CNS) development, radial glia cells (RGCs) play at least two essential roles, they contribute to neuronal production and the subsequent guidance of neuronal migration, whereas its precise distribution and contribution to cerebral cortex remains less understood. In this research, we used Vimentin as an astroglial marker and Sox2 as a neural progenitor marker to identify and investigate RGCs in rat cerebral cortex at embryonic day (E) 16.5. We found that the Sox2+ progenitor cells localized in the germinal zone (GZ) of E16.5 cerebral cortex, ~95% Sox2+ cells co-localized with Vimentin+ or Nestin+ radial processes which extended to the pial surface across the cortical plate (CP). In vitro, we obtained RG-like cells from E16.5 cerebral cortex on adherent conditions, these Sox2+ Radial glia (RG)-like cells shared some properties with RGCs in vivo, and these Sox2+ RG-like cells could differentiate into astrocytes, oligodendrocytes and presented the radial glia—neuron lineage differentiation ability. Taken together, we identified and investigated some characterizations and properties of Sox2+ RGCs derived from E16.5 cerebral cortex, we suggested that the embryonic Sox2+ progenitor cells which located in the cortical GZ were mainly composed of Sox2+ RGCs, and the cortex-derived Sox2+ RG-like cells displayed the radial glia—neuron lineage differentiation ability as neuronal progenitors in vitro.

Ectopic neurogenesis in the forebrain cholinergic system-related areas of a rat dementia model.

Lesions to the fimbria fornix (FiFx) plus cingulate bundle (CB), the principal routes of communication of forebrain cholinergic regions, produce lasting impairment of spatial learning and memory in mice. We report that extensive neurogenesis takes place in the FiFx, CB, and basalis magnocellularis following FiFx plus CB transection. Immunofluorescence revealed that nestin-expressing cells were present in all 3 areas following lesion; the majority of nestin-positive cells were also positive for 5-bromo-2-deoxy-uridine, a marker of DNA synthesis. Nestin-positive proliferative cells were almost entirely absent from unlesioned tissue. Neurospheres cultured in vitro from lesioned FiFx displayed the characteristics of neural stem cells--proliferation, expression of embryonic markers, and multipotential differentiation into neurons, astrocytes, and oligodendrocytes. At early stages after transection, a small number of immature and migrating doublecortin-immunopositive neurons were detected in lesioned FiFx, where neuronal cell bodies are normally absent. At later stages, postlesion immature neurons developed into β-tubulin III-positive mature neurons. Lentivirus labeling assay implied that the injury-induced neurogenesis in FiFx may be from local neurogenic astrocytes but not from dentate gyrus. These results demonstrate that insult to cholinergic tracts can stimulate neural stem cell proliferation and neuronal regeneration not only in innervated regions but also in the projection pathways themselves. Ectopic neurogenesis in cholinergic system-related areas provides an additional mechanism for repair of cholinergic innervation following damage.

The dynamic expression of Mash1 in the hippocampal subgranular zone after fimbria-fornix transection.

Mash1, a member of the basic helix-loop-helix (bHLH) transcription factor family, has previously been considered essential for neuronal differentiation and specification in the nervous system. In this study, we investigated the expression of Mash1 in the hippocampus after fimbria-fornix (FF) transection. Western blot showed that protein of Mash1 increased significantly and peaked at day 7 after FF transection. Immunofluorescence indicated that after FF transection, more newborn cells differentiated into Mash1 positive cells in the deafferented side than that in the normal side, and we investigated that in the neurogenic area, subgranular zone (SGZ), a part of Mash1 positive cells were NeuN positive, and more Mash1/NeuN double positive neurons were identified in the deafferented side than that in the normal side. Additionally, the number of Mash1/NeuN double positive neurons in SGZ increased significantly and peaked at day 7 after FF transection. In vitro, immunofluorescence revealed that extracts of the deafferented hippocampus promoted neuronal differentiation to a greater extent than extracts from normal hippocampus. Deafferented extracts also enhanced Mash1 expression in MAP-2 positive neurons. This study concludes that after FF transection, Mash1 expression in the deafferented hippocampus increased and might play an important role in inducing local progenitors to differentiate into neurons.

Generation and identification of rat fetal cerebral radial glia-like cells in vitro

The role of radial glia cells (RGCs) as neural progenitors and as guides for migrating neurons is well established, mouse or human-derived radial glia (RG)-like cells in vitro showed some astroglia and stem/progenitor properties like RGCs in vivo, but different species-derived RG-like cells present some different properties. Here we acquired rat-derived RG-like cells on adherent conditions in vitro and then identified their astroglia and stem/progenitor properties. Similarly to the RGCs, the RG-like cells could be double-labeled by brain lipid-binding protein, glial fibrillary acidic protein, vimentin with nestin and expressed some astroglia and stem/progenitor genes; these cells also presented tripotent differentiation potentialities, albeit the ability of gliogenesis far exceeded the neurogenesis in vitro. Taken together, we acquired and identified some properties of rat-derived RG-like cells from fetal cerebral cortices in vitro.

MicroRNA expression profiles of neural stem cells following valproate inducement

Neural stem cells (NSCs) possess self‐renewal and multilineage differentiation ability, thus are considered to be a potential source for cell replacement therapy of many nervous system diseases, such as neurodegenerative diseases. Valproate (VPA), a member of histone deacetylase inhibitor family, is an epigenetic regulator and can promote NSCs to differentiate into neurons, nevertheless, the underlying mechanisms of the process remain unclear. MicroRNAs (miRNAs) exert a crucial part in the posttranscriptional regulation of gene expression. Epigenetic mechanisms involve in the regulation of miRNAs expression. Therefore we speculated that miRNAs may be important factors during the promotion of neuronal differentiation by VPA. Here, after selecting appropriate concentration and treatment time of VPA, we conducted microRNA arrays at 24 h on the treatment of 1 mM VPA or vehicle. After validation, we obtained 5 significantly upregulated miRNAs (miR‐29a‐5p, miR‐674‐5p, miR‐155‐5p, miR‐652‐3p, and miR‐210‐3p) in VPA group compared with control. We predicted the target genes of these miRNAs on the website. Through gene ontology (GO) and pathway analyses, we obtained preliminary comprehension of the function of these genes. The bioinformatics analyses indicated the involvement of them during neurogenesis. In addition, we observed high expression of miR‐210‐3p, miR‐29a‐5p, and miR‐674‐5p in central nervous system, which suggested that they were likely to play crucial roles in neuronal differentiation. We then defined the upregulation of Map2 by transfecting mimic of miR‐674‐5p, which indicated the promotion of miR‐674‐5p on NSCs differentiation. The present study explored the miRNAs potentially mediated the function of VPA on promoting NSCs to differentiate into neurons.

Brain lipid binding protein mediates the proliferation of human glioblastoma cells by regulating ERK1/2 signaling pathway in vitro

Brain lipid binding protein (BLBP) is highly expressed in the radial glial cells (RGCs) of the central nervous system (CNS), in glioblastomas, and, in vitro, in U251 cells. In this report, we have demonstrated that increased BLBP expression in glioblastoma is associated with poor survival and used a double-vector CRISPR/Cas9 lentiviral system to deplete endogenous BLBP from U251 cells, we found that loss of BLBP induced cell growth inhibition and S-phase arrest. Moreover, an increase in P53 and a decrease in p-ERK1/2 were observed after BLBP depletion, suggesting a potential mechanism by which loss of BLBP results in growth inhibition.