Your search keyword '"EPENDYMAL CELLS"' showing total 250 results

201. A tale of two cousins: Ependymal cells, quiescent neural stem cells and potential mechanisms driving their functional divergence.

Author

Stratton JA, Shah P, Sinha S, Crowther E, and Biernaskie J

Subjects

Brain cytology, Brain metabolism, Cell Division genetics, Cell Lineage genetics, Ependyma metabolism, Epithelial Cells cytology, Epithelial Cells metabolism, Gene Regulatory Networks genetics, Homeostasis genetics, Humans, Neural Stem Cells cytology, Neuroglia cytology, Neuroglia metabolism, Stem Cell Niche genetics, Cell Proliferation genetics, Ependyma cytology, Neural Stem Cells metabolism, Neurogenesis genetics

Abstract

Recent work has suggested that stem cells exhibit far greater heterogeneity than initially thought. Indeed, their dynamic nature and shared traits with surrounding niche cells have made prospective identification of adult neural stem cells (NSCs) challenging. Refined fate mapping strategies and single-cell omics techniques have begun to clarify functionally distinct states within the adult NSC pool, the molecular signatures that govern these states, and the functional contributions/interactions with neighboring cells within the subventricular niche. Ependymal cells are the epithelial cells which line the ventricular system and reside in the same niche as NSCs. Our own work has revealed that, despite sharing similar embryonic origins with NSCs and close geographic proximity, ependymal cells are transcriptionally distinct and fail to exhibit stem cell function in vivo, even following injury. Intriguingly, comparison of ependymal cells with qNSCs revealed transcriptional signatures that are largely overlapping, suggesting that post-transcriptional regulation might underlie their divergent phenotypes. Additional analysis of ependymal versus qNSC gene regulatory network activation supports this notion. This Viewpoint summarizes the historical confusion regarding the identity of NSCs within the lateral ventricle niche and describes recent work that provides greater appreciation for the diverse functional states within the NSC niche., (© 2019 Federation of European Biochemical Societies.)

Published

2019

202. Effect of Differently Polarized Macrophages on Proliferation and Differentiation of Ependymal Cells from Adult Spinal Cord.

Author

Ma Y, Deng M, and Liu M

Subjects

Animals, Bone Marrow Cells metabolism, Coculture Techniques, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Spinal Cord cytology, Spinal Cord metabolism, Cell Differentiation physiology, Cell Proliferation physiology, Ependyma cytology, Ependyma metabolism, Macrophage Activation physiology, Tumor Necrosis Factor-alpha deficiency

Abstract

Ependymal cells (EpCs) are a kind of multi-potent stem cells in the central canal of adult spinal cord, which proliferate following spinal cord injury (SCI). Although they can differentiate into functional neurons in vitro , EpC progeny differentiate mainly into astrocytes after SCI, and the mechanism remains unclear. The present study aimed to explore whether neuroinflammation induced by classically activated macrophages (M1) or alternatively activated macrophages (M2) had an effect on EpC proliferation and/or differentiation. EpCs were isolated from intact spinal cord of adult mice and co-cultured with M1 or M2, respectively, in vitro . EpC proliferation was detected using a Cell Counting Kit-8 (CCK8) assay and Ki67 staining. Expression of Sox2 (SRY-box 2) in EpCs derived from different groups was detected by immunofluorescence and western blotting. Also explored was whether the mitogen activated protein kinase (MAPK) signaling pathway was involved in EpC proliferation. Immunofluorescence staining of βIII-tubulin and MAP2 were performed to assess the differentiation direction of EpCs in different culture conditions. Immunofluorescence and western blotting assays showed much more Sox2-positive EpCs in the group EpCs-M1 than the group EpCs-M2 in vitro ( p  < 0.01). The percentage of EpCs with positive Sox2 staining was decreased after tumor necrosis factor α (TNFα) antibody was added into the medium of EpCs-M1. Correspondingly, fewer Sox2-positive staining cells were observed in the central canal of TNFα-deficient mice with SCI. M1 co-culture promoted EpC proliferation significantly, which could be downregulated by Sox2 gene silencing ( p  < 0.01). Interestingly, M1 regulated the expression of Sox2 through the MAPK signaling pathway, especially the activation of ERK and p38 kinase. Co-culture in M2 conditioned medium obviously increased the proportion of βIII-tubulin-positive cells ( p  < 0.01). Small amounts of MAP2-positive neurons could be detected on day 7 in the M2 group and the control group. M1 conditioned medium could promote EpC proliferation in response to SCI through the TNFα-MAPK-Sox2 signaling pathway; M2 conditioned medium favors EpCs differentiating toward neurons.

Published

2019

203. Evidence Supporting a Role for the Blood-Cerebrospinal Fluid Barrier Transporting Circulating Ghrelin into the Brain.

Author

Uriarte M, De Francesco PN, Fernandez G, Cabral A, Castrogiovanni D, Lalonde T, Luyt LG, Trejo S, and Perello M

Subjects

Animals, Antibodies metabolism, Cerebral Ventricles metabolism, Ghrelin administration & dosage, Ghrelin cerebrospinal fluid, Male, Mice, Inbred C57BL, Orexins metabolism, Blood-Brain Barrier metabolism, Cerebrospinal Fluid metabolism, Ghrelin blood

Abstract

The stomach-derived hormone ghrelin mainly acts in the brain. Studies in mice have shown that the accessibility of ghrelin into the brain is limited and that it mainly takes place in some circumventricular organs, such as the median eminence. Notably, some known brain targets of ghrelin are distantly located from the circumventricular organs. Thus, we hypothesized that ghrelin could also access the brain via the blood-cerebrospinal fluid (CSF) barrier, which consists of the choroid plexus and the hypothalamic tanycytes. Using systemic injection of ghrelin or fluorescent-ghrelin in mice, we found that cells of the blood-CSF barrier internalize these molecules. In time-response studies, we found that peripherally injected fluorescent-ghrelin quickly reaches hypothalamic regions located in apposition to the median eminence and more slowly reaches the periventricular hypothalamic parenchyma, adjacent to the dorsal part of the third ventricle. Additionally, we found that CSF ghrelin levels increase after the systemic administration of ghrelin, and that central infusions of either an anti-ghrelin antibody, which immuno-neutralizes CSF ghrelin, or a scrambled version of ghrelin, which is also internalized by cells of the blood-CSF barrier, partially impair the orexigenic effect of peripherally injected ghrelin. Thus, current evidence suggests that the blood-CSF barrier can transport circulating ghrelin into the brain, and that the access of ghrelin into the CSF is required for its full orexigenic effect.

Published

2019

204. RNA Profiling of the Human and Mouse Spinal Cord Stem Cell Niches Reveals an Embryonic-like Regionalization with MSX1 + Roof-Plate-Derived Cells.

Author

Ghazale H, Ripoll C, Leventoux N, Jacob L, Azar S, Mamaeva D, Glasson Y, Calvo CF, Thomas JL, Meneceur S, Lallemand Y, Rigau V, Perrin FE, Noristani HN, Rocamonde B, Huillard E, Bauchet L, and Hugnot JP

Subjects

Animals, Embryonic Stem Cells cytology, Ependymoglial Cells cytology, Ependymoglial Cells metabolism, Female, Humans, MSX1 Transcription Factor genetics, MSX1 Transcription Factor metabolism, Male, Mice, Mice, Transgenic, Microscopy, Fluorescence, Middle Aged, Neural Stem Cells cytology, Neural Stem Cells metabolism, RNA metabolism, Spinal Cord cytology, Stem Cell Niche, Stem Cells cytology, Young Adult, Embryonic Stem Cells metabolism, Gene Expression Profiling methods, Gene Expression Regulation, Developmental, RNA genetics, Spinal Cord metabolism, Stem Cells metabolism

Abstract

Anamniotes, rodents, and young humans maintain neural stem cells in the ependymal zone (EZ) around the central canal of the spinal cord, representing a possible endogenous source for repair in mammalian lesions. Cell diversity and genes specific for this region are ill defined. A cellular and molecular resource is provided here for the mouse and human EZ based on RNA profiling, immunostaining, and fluorescent transgenic mice. This uncovered the conserved expression of 1,200 genes including 120 transcription factors. Unexpectedly the EZ maintains an embryonic-like dorsal-ventral pattern of expression of spinal cord developmental transcription factors (ARX, FOXA2, MSX1, and PAX6). In mice, dorsal and ventral EZ cells express Vegfr3 and are derived from the embryonic roof and floor plates. The dorsal EZ expresses a high level of Bmp6 and Gdf10 genes and harbors a subpopulation of radial quiescent cells expressing MSX1 and ID4 transcription factors., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2019

205. Ependymal Cells Require Anks1a for Their Proper Development.

Author

Park S, Lee H, Lee J, Park E, and Park S

Subjects

Animals, Animals, Newborn, Cell Count, Cell Differentiation, Chromosomes, Artificial, Bacterial genetics, Glial Fibrillary Acidic Protein metabolism, Mice, Transgenic, Up-Regulation, Adaptor Proteins, Signal Transducing metabolism, Ependyma cytology, Ependyma growth & development

Abstract

Ependymal cells constitute the multi-ciliated epithelium, which lines the brain ventricular lumen. Although ependymal cells originate from radial glial cells in the perinatal rodent brain, the exact mechanisms underlying the full differentiation of ependymal cells are poorly understood. In this report, we present evidence that the Anks1a phosphotyrosine binding domain (PTB) adaptor is required for the proper development of ependymal cells in the rodent postnatal brain. Anks1a gene trap targeted LacZ reporter analysis revealed that Anks1a is expressed prominently in the ventricular region of the early postnatal brain and that its expression is restricted to mature ependymal cells during postnatal brain development. In addition, Anks1a-deficient ependymal cells were shown to possess type B cell characteristics, suggesting that ependymal cells require Anks1a in order to be fully differentiated. Finally, Anks1a overexpression in the lateral wall of the neonatal brain resulted in an increase in the number of ependymal cells during postnatal brain development. Altogether, our results suggest that ependymal cells require Anks1a PTB adaptor for their proper development.

Published

2019

206. The Trp73 Mutant Mice: A Ciliopathy Model That Uncouples Ciliogenesis From Planar Cell Polarity.

Author

Marques MM, Villoch-Fernandez J, Maeso-Alonso L, Fuertes-Alvarez S, and Marin MC

Abstract

p73 transcription factor belongs to one of the most important gene families in vertebrate biology, the p53-family. Trp73 gene, like the other family members, generates multiple isoforms named TA and DNp73, with different and, sometimes, antagonist functions. Although p73 shares many biological functions with p53, it also plays distinct roles during development. Trp73 null mice (p73KO from now on) show multiple phenotypes as gastrointestinal and cranial hemorrhages, rhinitis and severe central nervous system defects. Several groups, including ours, have revisited the apparently unrelated phenotypes observed in total p73KO and revealed a novel p73 function in the organization of ciliated epithelia in brain and trachea, but also an essential role as regulator of ependymal planar cell polarity. Unlike p73KO or TAp73KO mice, tumor-prone Trp53 -/- mice (p53KO) do not present ependymal ciliary or planar cell polarity defects, indicating that regulation of ciliogenesis and PCP is a p73-specific function. Thus, loss of ciliary biogenesis and epithelial organization might be a common underlying cause of the diverse p73KO-phenotypes, highlighting Trp73 role as an architect of the epithelial tissue. In this review we would like to discuss the data regarding p73 role as regulator of ependymal cell ciliogenesis and PCP, supporting the view of the Trp73 -mutant mice as a model that uncouples ciliogenesis from PCP and a possible model of human congenital hydrocephalus.

Published

2019

207. Ciliary Beating Compartmentalizes Cerebrospinal Fluid Flow in the Brain and Regulates Ventricular Development.

Author

Olstad, Emilie W., Ringers, Christa, Hansen, Jan N., Wens, Adinda, Brandt, Cecilia, Wachten, Dagmar, Yaksi, Emre, and Jurisch-Yaksi, Nathalie

Subjects

*CEREBROSPINAL fluid, *CILIA & ciliary motion, *CELL compartmentation, *BRAIN physiology, *CEREBRAL ventricles

Abstract

Summary Motile cilia are miniature, propeller-like extensions, emanating from many cell types across the body. Their coordinated beating generates a directional fluid flow, which is essential for various biological processes, from respiration to reproduction. In the nervous system, ependymal cells extend their motile cilia into the brain ventricles and contribute to cerebrospinal fluid (CSF) flow. Although motile cilia are not the only contributors to CSF flow, their functioning is crucial, as patients with motile cilia defects develop clinical features, like hydrocephalus and scoliosis. CSF flow was suggested to primarily deliver nutrients and remove waste, but recent studies emphasized its role in brain development and function. Nevertheless, it remains poorly understood how ciliary beating generates and organizes CSF flow to fulfill these roles. Here, we study motile cilia and CSF flow in the brain ventricles of larval zebrafish. We identified that different populations of motile ciliated cells are spatially organized and generate a directional CSF flow powered by ciliary beating. Our investigations revealed that CSF flow is confined within individual ventricular cavities, with little exchange of fluid between ventricles, despite a pulsatile CSF displacement caused by the heartbeat. Interestingly, our results showed that the ventricular boundaries supporting this compartmentalized CSF flow are abolished during bodily movement, highlighting that multiple physiological processes regulate the hydrodynamics of CSF flow. Finally, we showed that perturbing cilia reduces hydrodynamic coupling between the brain ventricles and disrupts ventricular development. We propose that motile-cilia-generated flow is crucial in regulating the distribution of CSF within and across brain ventricles. Graphical Abstract Highlights • Spatially organized motile cilia with rotational beats create directional CSF flow • Ciliary beating, heartbeat, and locomotion generate distinct components of CSF flow • Joint action of these components balances CSF compartmentalization and dispersion • Disruption of ciliary beating leads to ventricular defects during brain development Olstad et al. show that the cerebrospinal fluid flow dynamics in vivo are controlled by ciliary beating, heartbeat pulsations, and bodily movements. Together, these components balance the compartmentalization and the dispersion of CSF across the brain ventricles. Genetic disruption of ciliary beating leads to ventricular defects during development. [ABSTRACT FROM AUTHOR]

Published

2019

208. Neurogenesis from Neural Stem Cells, Ependymal Cells and Fibroblasts

Author

Devaraju, Karthikeyan

Subjects

adult neurogenesis, FoxJ1, cortical reprogramming, Neurology, Lnk, ependymal cells, stroke, neural stem cells

Abstract

Stroke is a major cause of death and disability around the world. Stroke leads to loss of neurons and also other cells in the brain due to lack of blood supply. Currently no therapies are available to treat stroke-related disability. It has been shown that stroke leads to increased neurogenesis, birth of new neurons, within the brain. This increased neurogenesis is not sufficient to restore lost function. There is a need to develop therapies for neuronal replacement by improving neurogenesis within the brain and / or transplanting neurons. Cortical strokes lead to more disability after stroke as compared to those affecting the striatum, and whether cortical neurogenesis occurs after stroke is controversial. Cell transplantation may be the key to cortical repair after stroke. Reports have identified positive but very few negative regulators of neurogenesis after stroke, and suggested that ependymal cells can also contribute to stroke-induced neurogenesis. Transplantation of neurons generated from different sources such as fetal brain, embryonic stem cells and induced pluripotent stem cells are associated with ethical issues and carry the risk of immune rejection and tumorigenicity. Direct conversion of patient’s own skin cells to neurons could overcome these problems and potentially restore function after transplantation in stroke-damaged brain. In this thesis we have used transgenic models, viral vectors, electroporation-mediated gene delivery and overexpression of transcription factors to demonstrate neurogenesis from neural stem cells, ependymal cells in the lateral ventricular wall and fibroblasts. We show that Lnk, a known inhibitor of hematopoietic stem cell self-renewal, is also expressed in the brain. Overexpression or removal of Lnk expression leads to decreased or increased neurogenesis in vitro respectively. When brain is damaged by stroke there is increased proliferation of neural stem cells in animals without Lnk expression. This was not observed in status epilepticus, a severe form of epilepsy. We determined that upregulation of Stat1/3 after stroke leads to increased Lnk expression. Subsequently Lnk inhibits cellular response to increased IGF1 stimulation after stroke, by decreasing Akt phosphorylation. We have identified Lnk signaling as a novel mechanism of influencing neurogenic response to stroke. We next determined if ependymal cells in lateral ventricular wall of adult rat brain contribute to neurogenesis after stroke. We identified FoxJ1 as a marker of ependymal cells in rats similar to mice, and used FoxJ1 promoter in piggyBac system to genetically label these cells with fluorescent reporter proteins GFP or RFP by electroporation. Tracing the lineage of the labeled cells in intact and stroke-damaged brain, we identified that FoxJ1 expressing cells contribute to olfactory bulb neurogenesis while the striatal neurogenic response was not significant. Thus, FoxJ1 expressing cells probably have only a minor role in repair after stroke. We then tested whether human fetal lung fibroblasts could be directly converted to cortical neurons. We overexpressed sets of transcription factors that are known to be involved in cortical neuron development. We found that overexpression of different sets of these factors in fibroblasts converted them to cortical-like neurons. These neurons expressed markers of cortical neurons and were functional by electrophysiology. In summary, these results raise the possibility that inhibition of Lnk, a negative regulator of neurogenesis from the brain’s own neural stem cells, and intracortical transplantation of cortical neurons directly converted from fibroblasts could be developed into novel therapeutic strategies for stroke in the future. Stroke är en ledande orsak till dödlighet och handikapp i hela världen. Stroke leder till förlust av nervceller och även andra celler i hjärnan på grund av bristande blodtillförsel. För tillfället finns väldigt få möjligheter att behandla funktionshinder relaterade till stroke. Det har visats att stroke leder till ökad neurogenes, nybildning av nervceller i hjärnan. Denna ökade neurogenes är dock förmodligen inte tillräcklig för att återställa förlorad funktion. Därför finns ett behov av att utveckla nya terapier för att ersätta förlorade nervceller genom att förbättra neurogenes i hjärnan och/eller transplantatio av nervceller. Stroke som drabbar kortex leder till svårare handikapp jämfört med de som påverkar striatum , och hurvida kortikal neurogenes sker efter stroke är kontroversiellt . Därför kan celltransplantationkan vara nyckeln till reparation av kortex efter stroke. Tidigare studier har identifierat många positiva men mycket få negativa regulatorer av nybildning av nervceller efter stroke. Det har också föreslagits att ependymala celler kan bidra till stroke-inducerad neurogenes. Nervceller till transplantation kan genereras från olika källor såsom fostrets hjärna, embryonala stamceller och inducerade pluripotenta stamceller. Dessa är dock förknippade med etiskt svåra frågor och har risker associerade med avstötning och uppkomst av cancer. Direkt omvandling av patientens egna hudceller till nervceller, och använda dessa till transplantation, skulle kunna övervinna dessa problem och potentiellt återställa funktionen i stroke-skadad hjärna. I denna avhandling har vi använt transgena modeller, virala vektorer, elektroporation-medierad genleverans och överuttryck av transkriptionsfaktorer för att påvisa neurogenes från neurala stamceller, ependymalceller och fibroblaster. Vi visar att LNK, en känd hämmare av hematopoietiska stamcellers självförnyelse, också uttrycks i hjärnan. Överuttryck eller avlägsnande av Lnk leder till minskad eller ökad neurogenes respektive in vitro. Efter stroke ses en ökad proliferation av neurala stamceller hos djur utan LNK uttryck. Detta observerades dock inte i djur med status eplipeticus , en allvarlig form av epilepsi som också är associerad med ökad neurogenes. Vi visade att uppreglering av STAT1/3 efter stroke leder till ökat Lnk uttryck. Varpå LNK hämmar neurala stamcellers svar på ökad IGF1 stimulering efter stroke, genom att minska AKT fosforylering. Vi har därigenom identifierat LNK signalering som en ny mekanism för att påverka neurogenes efter stroke . Vi undersökte sedan hurvida ependymalceller i ventrikelväggen på vuxna råttor bidrar till neurogenes efter stroke. Vi identifierade FoxJ1 som en markör av ependymala celler i råttor. Vi använde sedan FoxJ1 promotorn och piggyBac systemet för att genetiskt märka dessa celler med fluorescerande reporterproteiner, GFP eller RFP, genom elektroporering. Genom att följa de märkta cellerna i intakt och strokeskadad hjärna, identifierade vi att FoxJ1 uttryckande celler bidrar till neurogenes i luktbulberna men väldigt lite i striatum. Således har FoxJ1 uttryckande celler förmodligen bara en mindre roll i reparation av striatum efter stroke. Vi testade sedan om humana fetala lungfibroblaster kan direkt omvandlas till kortikala nervceller. Vi överuttryckte olika kombinationer av transkriptionsfaktorer som är kända för att vara inblandade i utvecklingen av kortikala nervceller. Vi upptäckte att överuttryck av olika uppsättningar av dessa faktorer i fibroblaster konverterade dem till kortikal-liknande nervceller. Dessa nervceller uttryckte markörer för kortikala nervceller och visades vara funktionella med hjälp av elektrofysiologi. Sammanfattningsvis, visar dessa resultat,att hämning av LNK, en negativ regulator av neurogenes från hjärnans egna neurala stamceller, och intrakortikal transplantation av kortikala nervceller direkt omvandlade från fibroblaster kan utvecklas till nya terapeutiska strategier för stroke i framtiden.

Published

2014

209. Age-Related Changes in Astrocytic and Ependymal Cells of the Subventricular Zone

Author

Capilla González, Vivian, Cebrián Silla, Arantxa, Guerrero-Cazares, Hugo, García Verdugo, José Manuel, and Quiñones-Hinojosa, Alfredo

Subjects

nervous system, aging, astrocytes, ependymal cells, subventricular zone, ultrastructure, neural stem cells

Abstract

Neurogenesis persists in the adult subventricular zone (SVZ) of the mammalian brain. During aging, the SVZ neurogenic capacity undergoes a progressive decline, which is attributed to a decrease in the population of neural stem cells (NSCs). However, the behavior of the NSCs that remain in the aged brain is not fully understood. Here we performed a comparative ultrastructural study of the SVZ niche of 2-month-old and 24-month-old male C57BL/6 mice, focusing on the NSC population. Using thymidine-labeling, we showed that residual NSCs in the aged SVZ divide less frequently than those in young mice. We also provided evidence that ependymal cells are not newly generated during senescence, as others studies suggest. Remarkably, both astrocytes and ependymal cells accumulated a high number of intermediate filaments and dense bodies during aging, resembling reactive cells. A better understanding of the changes occurring in the neurogenic niche during aging will allow us to develop new strategies for fighting neurological disorders linked to senescence.

Published

2014

210. Les cytokines inflammatoires modulent la prolifération et la différenciation in vitro des cellules souches/progénitrices de la moelle épinière

Author

Vaugeois, Alexandre and Fernandes, Karl J.L.

Subjects

Cellules épendymaires, Neurosphere, Moelle épinière, Spinal cord injury, Cytometrie en flux, Cellules souches neurales, Fluorescent activated cell sorting, Spinal Cord, Neuroinflammation, Neuro-inflammation, Neural stem cell, Ependymal cells, Traumatisme médullaire, Cytokines, Neurosphères

Abstract

La moelle épinière (MÉ) est essentielle pour relier les informations motrices et sensorielles entre le cerveau et la périphérie. Malheureusement, elle peut facilement être endommagée suite à un traumatisme médullaire (TM) ou des pathologies comme la sclérose en plaques. Chez les vertébrés inférieurs, tels les amphibiens, la MÉ lésée se régénère via ses cellules souches endogènes, alors que celle des mammifères démontre une très faible habileté régénératrice post-traumatique. Des travaux récents ont démontré que la MÉ des mammifères contient des cellules souches neurales latentes correspondant aux cellules épendymaires du canal central. D’autres études ont prouvé qu’à la suite d’un TM, les cellules souches épendymaires (cSÉ) prolifèrent, migrent vers le site de la lésion et se différencient principalement en cellules gliales. Promouvoir la régénération de la MÉ endommagée via la modulation des cellules souches endogènes devient donc une voie thérapeutique intéressante. Isolant des cellules souches/progénitrices de la MÉ via la culture de neurosphères (NS), nos études in vitro, en présence de cytokines inflammatoires ou de milieu conditionné auxmacrophages, suggèrent que la réponse inflammatoire influence fortement la prolifération et la différentiation des cSÉ. Dans l’objectif de définir le programme génétique relié à l’activation des cSÉ de la MÉ, nous avons débuté l’élaboration d’un protocole d’isolement des cSÉ à l’aide d’un modèle de souris transgénique., The spinal cord is essential to link motor and sensory information between the brain and its periphery. However, it can be easily damaged following a traumatic injury or hit by pathology such as multiple sclerosis. In lower vertebrates, such as amphibians, the spinal cord has the ability to regenerate its endogenous stem cells, contrary to mammals that have a very limited capacity of post-traumatic regeneration. Recent works have shown that mammalian spinal cord contains quiescent neural stem corresponding to the ependymal cells localized in the central canal. Following spinal cord injury, ependymal stem cells proliferate, migrate towards the injury site and mainly differentiate into glial cells. Promoting spinal cord regeneration through modulation of its endogenous stem cells can be an interesting therapeutic solution. Isolating the spinal cord stem/progenitor cells through neurosphere culture in presence of inflammatory cytokines and conditioned macrophages media, our in vitro studies suggest that neuro-inflammatory response modulate proliferation and differentiation of spinal cord stem/progenitor cells. In order to define the genetic program related to ependymal stem cell activation, we have started the establishment of an experimental protocol for ependymal stem cell isolation with a transgenic mouse model.

Published

2013

211. Adult spinal cord ependymal layer: a promising pool of quiescent stem cells to treat spinal cord injury

Author

Elena Panayiotou and Stavros Malas

Subjects

Pathology, medicine.medical_specialty, Ependymal Cell, Physiology, medicine.medical_treatment, stem cell therapy, lcsh:Physiology, Mini Review Article, Injury Site, central canal, stem cells, Physiology (medical), medicine, Neuronal degeneration, Spinal cord injury, lcsh:QP1-981, business.industry, ependymal cells, Stem-cell therapy, Spinal cord, medicine.disease, Oligodendrocyte, medicine.anatomical_structure, spinal cord injuries, Stem cell, business

Abstract

Spinal cord injury is a major health burden and currently there is no effective medical intervention. Research performed over the last decade revealed that cells surrounding the central canal of the adult spinal cord and forming the ependymal layer acquire stem cell properties either in vitro or in response to injury. Following spinal cord injury activated ependymal cells generate progeny cells which migrate to the injury site but fail to produce the appropriate type of cells in sufficient number to limit the damage, rendering this physiological response mainly ineffective. Research is now focusing on the manipulation of ependymal cells to produce cells of the oligodendrocyte lineage which are primarily lost in such a situation leading to secondary neuronal degeneration. Thus, there is a need for a more focused approach to understand the molecular properties of adult ependymal cells in greater detail and develop effective strategies for guiding their response during spinal cord injury.

Published

2013

212. Molekulare Charakterisierung des kinocilien-spezifischen wdr16-Promoters

Author

Vincent, Franklin Christopher and Stehle, Thilo (Prof. Dr.)

Subjects

Ependymine , Zilie, Ependymal cells, Ependymalzellen , wdr16 , Sox5 , Promoter , Lentivirus

Abstract

In this thesis I have characterized the promoter of the rat orthologue of wdr16, a gene the product of which is only present in kinocilia bearing cells such as brain ependymal cells , but absent from all other cells. The orthologs of the wdr16 gene are especially suited as a paradigm for the analysis of kinocilia-specific promoters. They exhibit a special form of shared synteny, in which wdr16 lies in ‘‘head-to-head’’ orientation to stx 8, the gene of syntaxin 8. Therefore, the sequence between wdr16 and stx8 was taken for finding the transcriptions factor binding site and the corresponding transcription factor which regulates the wdr16 promoter. Since the transcription of wdr16 is upregulated in ependymal primary cultures at the time of differentiation and kinocilia formation, this culture system was well suited for the characterization of the wdr16 promoter as a prototype for kinocilia-specific promoters. The results identified Sox5 as the transcription factor, which positively regulates the promoter of the wdr16 gene. In this work, I have narrowed down to 10 base pairs the promoter binding site within the 766 base pair promoter region. The deletion of these 10 base pairs reduced the promoter strength by about 65%. The involvement of Sox5 shown in the present thesis may well be the first evidence of Sox5 participation in kinocilia-specific gene expression. In dieser Dissertation habe ich den Promotor des Rattenorthologen von wdr16 charakterisiert, eines Gens, dessen Produkt nur in Kinocilien-tragenden Zellen - wie den Ependymzellen des Gehirns - vorkommt, aber in allen anderen Zellen fehlt. Die Orthologen des wdr16-Gens eignen sich beispielhaft für die Analyse Kinocilien-spezifischer Promotoren. Sie weisen eine spezielle Form der gemeinsamen Syntänie auf, in welcher wdr16 in Kopf an Kopf-Orientierung zum Syntaxin 8-Gen stx8 liegt. Deshalb wurde die zwischen wdr16 und stx8 liegende Sequenz verwendet, um den Transkriptionsfaktor-Bindungsort und den zugehörigen Transkriptionsfaktor aufzufinden, der den wdr16-Promotor reguliert. Da die Transkription von wdr16 in Primärkulturen von Ependymzellen bei der Differenzierung und der Kinocilienbildung hochreguliert ist, war dieses Kultursystem gut zur Charakterisierung des wdr16-Promotors als Prototyp Kinocilien-spezifischer Promotoren geeignet. Diese Untersuchungen ergaben die Identifizierung von Sox5 als den Transkriptionsfaktor, der den Promotor des wdr16-Gens positiv reguliert. In dieser Arbeit habe ich den Transkriptionsfaktor-Bindungsort in der 766 Basenpaare umfassenden Promotorregion auf 10 Basenpaare eingeengt. Deletion dieser 10 Basenpaare verringerte die Stärke des Promotors um ungefähr 65 %. Die in vorliegender Dissertation gezeigte Beteiligung von Sox5 ist sehr wahrscheinlich der erste Hinweis auf die Beteiligung von Sox5 an Kinocilien-spezifischer Genexpression.

Published

2013

213. Svct2 vitamin c transporter expression in progenitor cells of the postnatal neurogenic niche

Author

Francisco Nualart, Pedro Cisternas, Agustin Martínez, Carmen Silva-Alvarez, Karina Oyarce, Katterine Salazar, Patricia Pastor, Nery Jara, and Francisca Espinoza

Subjects

Rostral migratory stream, brain, ependymal cells, vitamin C, Subventricular zone, progenitor, Biology, Neural stem cell, lcsh:RC321-571, Cell biology, niche, Cellular and Molecular Neuroscience, SVCT2, medicine.anatomical_structure, Neuroblast, stem cells, Neurosphere, Precursor cell, Immunology, medicine, Original Research Article, Stem cell, Progenitor cell, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Neuroscience

Abstract

Known as a critical antioxidant, recent studies suggest that vitamin C plays an important role in stem cell generation, proliferation and differentiation. Vitamin C also enhances neural differentiation during cerebral development, a function that has not been studied in brain precursor cells. We observed that the rat neurogenic niche is structurally organized at day 15 of postnatal development, and proliferation and neural differentiation increase at day 21. In the human brain, a similar subventricular niche was observed at 1-month of postnatal development. Using immunohistochemistry, sodium-vitamin C cotransporter 2 (SVCT2) expression was detected in the subventricular zone (SVZ) and rostral migratory stream (RMS). Low co-distribution of SVCT2 and βIII-tubulin in neuroblasts or type-A cells was detected, and minimal co-localization of SVCT2 and GFAP in type-B or precursor cells was observed. Similar results were obtained in the human neurogenic niche. However, BrdU-positive cells also expressed SVCT2, suggesting a role of vitamin C in neural progenitor proliferation. Primary neurospheres prepared from rat brain and the P19 teratocarcinoma cell line, which forms neurospheres in vitro, were used to analyze the effect of vitamin C in neural stem cells. Both cell types expressed functional SVCT2 in vitro, and ascorbic acid (AA) induced their neural differentiation, increased βIII-tubulin and SVCT2 expression, and amplified vitamin C uptake.

Published

2013

214. Axons take a dive: Specialized contacts of serotonergic axons with cells in the walls of the lateral ventricles in mice and humans.

Author

Tong, Cheuk Ka, Tong, Cheuk Ka, Cebrián-Silla, Arantxa, Paredes, Mercedes F, Huang, Eric J, García-Verdugo, Jose Manuel, Alvarez-Buylla, Arturo, Tong, Cheuk Ka, Tong, Cheuk Ka, Cebrián-Silla, Arantxa, Paredes, Mercedes F, Huang, Eric J, García-Verdugo, Jose Manuel, and Alvarez-Buylla, Arturo

Abstract

In the walls of the lateral ventricles of the adult mammalian brain, neural stem cells (NSCs) and ependymal (E1) cells share the apical surface of the ventricular-subventricular zone (V-SVZ). In a recent article, we show that supraependymal serotonergic (5HT) axons originating from the raphe nuclei in mice form an extensive plexus on the walls of the lateral ventricles where they contact E1 cells and NSCs. Here we further characterize the contacts between 5HT supraependymal axons and E1 cells in mice, and show that suprependymal axons tightly associated to E1 cells are also present in the walls of the human lateral ventricles. These observations raise interesting questions about the function of supraependymal axons in the regulation of E1 cells.

Published

2014

215. Morphological aspects of migration of lymphocytes with broad cytoplasm through the ependymal cell of the mammalian vascular plexus

Author

Shakhlamov, V. A. and Bitner, E. G.

Published

1992

216. Lysophosphatidic acid receptor 1 signaling initiates neonatal post-hemorrhagic hydrocephalus through ciliated ependymal cell loss

Author

Lummis, Nicole Christine

Subjects

Biology, Pharmaceutical sciences, cilia, ependymal cells, intracranial pressure, lysophosphatidic acid receptors, neonatal, post-hemorrhagic hydrocephalus

Abstract

Lysophosphatidic acid (LPA) is a signaling phospholipid that binds to G protein-coupled receptors designated LPA1-LPA6. It has several activities throughout the body, including modulating cellular survival and migration. LPA circulates in the blood bound to carriers such as albumin, and LPA concentrations are increased during cases of hemorrhage or trauma. In the nervous system, LPA helps modulate development and differentiation, but high concentrations of the lipid are often involved in pathology. Post-hemorrhagic hydrocephalus is one such disorder. Hydrocephalus results from an accumulation of cerebrospinal fluid (CSF) in the brain, which expands the fluid-filled ventricles, causing permanent brain damage. This disorder is often chronic and is treated by invasive neurosurgical procedures which drain excess CSF. Here we provide evidence that LPA, introduced to the CSF in the blood, may be a key mediator of post-hemorrhagic hydrocephalus. Animals were injected with LPA at postnatal day 8 and hydrocephalus was observed by measuring increased ventriculomegaly and intracranial pressure 7 days later. Histology and immunohistochemistry demonstrated that the ciliated ependymal cells which generate CSF flow were heavily disrupted 3-6 hours post-LPA exposure. However, development of hydrocephalus and degeneration of the ependymal monolayer was prevented by knockout of LPA1, and to a lesser extent by LPA3 knockout. Pretreatment with the LPA1 antagonist AM095 also protected LPA-injected animals from developing hydrocephalus, signifying that this is a receptor-mediated phenomenon that could be prevented by timely application of a pharmacological inhibitor. As there are currently no efficacious pharmacological treatments for hydrocephalus patients or methods used to prevent hydrocephalus post-hemorrhage, the identification of LPA1-expressing ependymal cells provides a novel target for therapeutic development.

Published

2018

217. The spinal ependymal zone as a source of endogenous repair cells across vertebrates.

Author

Becker CG, Becker T, and Hugnot JP

Subjects

Animals, Biological Evolution, Humans, Neurogenesis physiology, Ependyma physiopathology, Spinal Cord physiopathology, Spinal Cord Injuries physiopathology, Spinal Cord Regeneration physiology

Abstract

Spinal cord injury results in the loss of neurons and axonal connections. In mammals, including humans, this loss is permanent, but is repaired in other vertebrates, such as salamanders and fishes. Cells in the ependymal niche play a pivotal role for the outcome after injury. These cells initiate proliferation and generate new neurons of different types in regenerating species, but only glial cells, contributing to the glial scar, in mammals. Here we compare the cellular and molecular properties of ependymal zone cells and their environment across vertebrate classes. We point out communalities and differences between vertebrates capable of neuronal regeneration and those that are not. Comparisons like these may ultimately lead to the identification of factors that tip the balance for ependymal zone cells in mammals to produce appropriate neural cells for endogenous repair after spinal cord injury., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

218. Cellular composition and organization of the spinal cord central canal during metamorphosis of the frog Xenopus laevis.

Author

Edwards-Faret G, Cebrián-Silla A, Méndez-Olivos EE, González-Pinto K, García-Verdugo JM, and Larraín J

Subjects

Animals, Cell Count, Cell Proliferation, Cilia ultrastructure, Deoxyuridine analogs & derivatives, Female, Larva, Male, Nerve Regeneration, Neural Stem Cells, Neuroglia physiology, Neuroglia ultrastructure, Spinal Cord growth & development, Metamorphosis, Biological, Spinal Cord cytology, Spinal Cord physiology, Xenopus laevis anatomy & histology, Xenopus laevis physiology

Abstract

Studying the cellular composition and morphological changes of cells lining the central canal during Xenopus laevis metamorphosis could contribute to understand postnatal development and spinal cord regeneration. Here we report the analysis of central canal cells at different stages during metamorphosis using immunofluorescence for protein markers expression, transmission and scanning electron microscopy and cell proliferation assays. The central canal was regionalized according to expression of glial markers, ultrastructure, and proliferation in dorsal, lateral, and ventral domains with differences between larvae and froglets. In regenerative larvae, all cell types were uniciliated, have a radial morphology, and elongated nuclei with lax chromatin, resembling radial glial cells. Important differences in cells of nonregenerative froglets were observed, although uniciliated cells were found, the most abundant cells had multicilia and revealed extensive changes in the maturation and differentiation state. The majority of dividing cells in larvae corresponded to uniciliated cells at dorsal and lateral domains in a cervical-lumbar gradient, correlating with undifferentiated features. Neurons contacting the lumen of the central canal were detected in both stages and revealed extensive changes in the maturation and differentiation state. However, in froglets a very low proportion of cells incorporate 5-ethynyl-2'-deoxyuridine (EdU), associated with the differentiated profile and with the increase of multiciliated cells. Our work showed progressive changes in the cell types lining the central canal of Xenopus laevis spinal cord which are correlated with the regenerative capacities., (© 2018 Wiley Periodicals, Inc.)

Published

2018

219. The KASH-containing isoform of Nesprin1 giant associates with ciliary rootlets of ependymal cells.

Author

Potter C, Razafsky D, Wozniak D, Casey M, Penrose S, Ge X, Mahjoub MR, and Hodzic D

Subjects

Amino Acid Sequence, Animals, Cell Cycle Proteins biosynthesis, Cell Cycle Proteins genetics, Cerebellum cytology, Cytoskeletal Proteins, Ependyma cytology, Mice, Mice, Inbred C57BL, Mice, Transgenic, Nerve Tissue Proteins genetics, Nuclear Proteins genetics, Protein Isoforms biosynthesis, Protein Isoforms genetics, Cerebellum metabolism, Cilia metabolism, Ependyma metabolism, Nerve Tissue Proteins biosynthesis, Nuclear Proteins biosynthesis

Abstract

Biallelic nonsense mutations of SYNE1 underlie a variable array of cerebellar and non-cerebellar pathologies of unknown molecular etiology. SYNE1 encodes multiple isoforms of Nesprin1 that associate with the nuclear envelope, with large cerebellar synapses and with ciliary rootlets of photoreceptors. Using two novel mouse models, we determined the expression pattern of Nesprin1 isoforms in the cerebellum whose integrity and functions are invariably affected by SYNE1 mutations. We further show that a giant isoform of Nesprin1 associates with the ciliary rootlets of ependymal cells that line brain ventricles and establish that this giant ciliary isoform of Nesprin1 harbors a KASH domain. Whereas cerebellar phenotypes are not recapitulated in Nes1g STOP/STOP mice, these mice display a significant increase of ventricular volume. Together, these data fuel novel hypotheses about the molecular pathogenesis of SYNE1 mutations and support that KASH proteins may localize beyond the nuclear envelope in vivo., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

220. FoxJ1 regulates spinal cord development and is required for the maintenance of spinal cord stem cell potential.

Author

Li X, Floriddia EM, Toskas K, Chalfouh C, Honore A, Aumont A, Vallières N, Lacroix S, Fernandes KJL, Guérout N, and Barnabé-Heider F

Subjects

Animals, Ependyma metabolism, Female, Male, Mice, Organogenesis physiology, Spinal Cord metabolism, Spinal Cord Injuries metabolism, Cell Differentiation physiology, Forkhead Transcription Factors metabolism, Gene Expression Regulation genetics, Stem Cells cytology

Abstract

Development of the spinal cord requires dynamic and tightly controlled expression of numerous transcription factors. Forkhead Box protein J1 (FoxJ1) is a transcription factor involved in ciliogenesis and is specifically expressed in ependymal cells (ECs) in the adult central nervous system. However, using FoxJ1 fate-mapping mouse lines, we observed that FoxJ1 is also transiently expressed by the progenitors of other neural subtypes during development. Moreover, using a knock-in mouse line, we discovered that FoxJ1 is essential for embryonic progenitors to follow a normal developmental trajectory. FoxJ1 loss perturbed embryonic progenitor proliferation and cell fate determination, and resulted in formation of adult ECs having impaired stem cell potential and an inability to respond to spinal cord injury in both male and female animals. Thus, our study uncovers unexpected developmental functions of FoxJ1 in cell fate determination of subsets of neural cells and suggests that FoxJ1 is critical for maintaining the stem cell potential of ECs into adulthood., (Copyright © 2018 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2018

221. Wnt/β-catenin signaling regulates ependymal cell development and adult homeostasis.

Author

Xing L, Anbarchian T, Tsai JM, Plant GW, and Nusse R

Subjects

Animals, Axin Protein genetics, Mice, Mice, Transgenic, Neural Stem Cells cytology, Neural Stem Cells metabolism, Neuroglia cytology, Spinal Cord cytology, Wnt Proteins genetics, Wnt Proteins metabolism, beta Catenin genetics, beta Catenin metabolism, Axin Protein metabolism, Cell Proliferation, Neuroglia metabolism, Spinal Cord growth & development, Wnt Signaling Pathway physiology

Abstract

In the adult mouse spinal cord, the ependymal cell population that surrounds the central canal is thought to be a promising source of quiescent stem cells to treat spinal cord injury. Relatively little is known about the cellular origin of ependymal cells during spinal cord development, or the molecular mechanisms that regulate ependymal cells during adult homeostasis. Using genetic lineage tracing based on the Wnt target gene Axin2 , we have characterized Wnt-responsive cells during spinal cord development. Our results revealed that Wnt-responsive progenitor cells are restricted to the dorsal midline throughout spinal cord development, which gives rise to dorsal ependymal cells in a spatially restricted pattern. This is contrary to previous reports that suggested an exclusively ventral origin of ependymal cells, suggesting that ependymal cells may retain positional identities in relation to their neural progenitors. Our results further demonstrated that in the postnatal and adult spinal cord, all ependymal cells express the Wnt/β-catenin signaling target gene Axin2 , as well as Wnt ligands. Genetic elimination of β-catenin or inhibition of Wnt secretion in Axin2-expressing ependymal cells in vivo both resulted in impaired proliferation, indicating that Wnt/β-catenin signaling promotes ependymal cell proliferation. These results demonstrate the continued importance of Wnt/β-catenin signaling for both ependymal cell formation and regulation. By uncovering the molecular signals underlying the formation and regulation of spinal cord ependymal cells, our findings thus enable further targeting and manipulation of this promising source of quiescent stem cells for therapeutic interventions., Competing Interests: The authors declare no conflict of interest., (Copyright © 2018 the Author(s). Published by PNAS.)

Published

2018

222. Axons take a dive

Author

Cheuk Ka Tong, Arantxa Cebrián-Silla, Eric J. Huang, José Manuel García-Verdugo, Mercedes F. Paredes, and Arturo Alvarez-Buylla

Subjects

Ependymal Cell, 1.1 Normal biological development and functioning, Biology, Serotonergic, Article, Lateral ventricles, Developmental Neuroscience, Underpinning research, 2.1 Biological and endogenous factors, human, Aetiology, neural stem cells, Plexus, Neurogenesis, Neurosciences, ependymal cells, Anatomy, Stem Cell Research, Neural stem cell, serotonin, supraependymal axons, adult neurogenesis, nervous system, Neurological, Serotonin, Raphe nuclei, Neuroscience, Developmental Biology

Abstract

In the walls of the lateral ventricles of the adult mammalian brain, neural stem cells (NSCs) and ependymal (E1) cells share the apical surface of the ventricular-subventricular zone (V-SVZ). In a recent article, we show that supraependymal serotonergic (5HT) axons originating from the raphe nuclei in mice form an extensive plexus on the walls of the lateral ventricles where they contact E1 cells and NSCs. Here we further characterize the contacts between 5HT supraependymal axons and E1 cells in mice, and show that suprependymal axons tightly associated to E1 cells are also present in the walls of the human lateral ventricles. These observations raise interesting questions about the function of supraependymal axons in the regulation of E1 cells.

Published

2014

223. Musashi and Plasticity of Xenopus and Axolotl Spinal Cord Ependymal Cells.

Author

Chernoff EAG, Sato K, Salfity HVN, Sarria DA, and Belecky-Adams T

Abstract

The differentiated state of spinal cord ependymal cells in regeneration-competent amphibians varies between a constitutively active state in what is essentially a developing organism, the tadpole of the frog Xenopus laevis , and a quiescent, activatable state in a slowly growing adult salamander Ambystoma mexicanum , the Axolotl. Ependymal cells are epithelial in intact spinal cord of all vertebrates. After transection, body region ependymal epithelium in both Xenopus and the Axolotl disorganizes for regenerative outgrowth (gap replacement). Injury-reactive ependymal cells serve as a stem/progenitor cell population in regeneration and reconstruct the central canal. Expression patterns of mRNA and protein for the stem/progenitor cell-maintenance Notch signaling pathway mRNA-binding protein Musashi (msi) change with life stage and regeneration competence. Msi-1 is missing (immunohistochemistry), or at very low levels (polymerase chain reaction, PCR), in both intact regeneration-competent adult Axolotl cord and intact non-regeneration-competent Xenopus tadpole (Nieuwkoop and Faber stage 62+, NF 62+). The critical correlation for successful regeneration is msi-1 expression/upregulation after injury in the ependymal outgrowth and stump-region ependymal cells. msi-1 and msi-2 isoforms were cloned for the Axolotl as well as previously unknown isoforms of Xenopus msi-2 . Intact Xenopus spinal cord ependymal cells show a loss of msi-1 expression between regeneration-competent (NF 50-53) and non-regenerating stages (NF 62+) and in post-metamorphosis froglets, while msi-2 displays a lower molecular weight isoform in non-regenerating cord. In the Axolotl, embryos and juveniles maintain Msi-1 expression in the intact cord. In the adult Axolotl, Msi-1 is absent, but upregulates after injury. Msi-2 levels are more variable among Axolotl life stages: rising between late tailbud embryos and juveniles and decreasing in adult cord. Cultures of regeneration-competent Xenopus tadpole cord and injury-responsive adult Axolotl cord ependymal cells showed an identical growth factor response. Epidermal growth factor (EGF) maintains mesenchymal outgrowth in vitro , the cells are proliferative and maintain msi-1 expression. Non-regeneration competent Xenopus ependymal cells, NF 62+, failed to attach or grow well in EGF+ medium. Ependymal Msi-1 expression in vivo and in vitro is a strong indicator of regeneration competence in the amphibian spinal cord.

Published

2018

224. Expression of a Novel Ciliary Protein, IIIG9, During the Differentiation and Maturation of Ependymal Cells.

Author

Cifuentes M, Baeza V, Arrabal PM, Visser R, Grondona JM, Saldivia N, Martínez F, Nualart F, and Salazar K

Subjects

Animals, Ependyma cytology, Ependymoglial Cells cytology, Female, Male, Rats, Rats, Sprague-Dawley, Cell Differentiation physiology, Cilia metabolism, Ependyma metabolism, Ependymoglial Cells metabolism, Nerve Tissue Proteins metabolism

Abstract

IIIG9 is the regulatory subunit 32 of protein phosphatase 1 (PPP1R32), a key phosphatase in the regulation of ciliary movement. IIIG9 localization is restricted to cilia in the trachea, fallopian tube, and testicle, suggesting its involvement in the polarization of ciliary epithelium. In the adult brain, IIIG9 mRNA has only been detected in ciliated ependymal cells that cover the ventricular walls. In this work, we prepared a polyclonal antibody against rat IIIG9 and used this antibody to show for the first time the ciliary localization of this protein in adult ependymal cells. We demonstrated IIIG9 localization at the apical border of the ventricular wall of 17-day-old embryonic (E17) and 1-day-old postnatal (PN1) brains and at the level of ependymal cilia at 10- and 20-day-old postnatal (PN10-20) using temporospatial distribution analysis and comparing the localization with a ciliary marker. Spectral confocal and super-resolution Structured Illumination Microscopy (SIM) analysis allowed us to demonstrate that IIIG9 shows a punctate pattern that is preferentially located at the borders of ependymal cilia in situ and in cultures of ependymocytes obtained from adult rat brains. Finally, by immunogold ultrastructural analysis, we showed that IIIG9 is preferentially located between the axoneme and the ciliary membrane. Taken together, our data allow us to conclude that IIIG9 is localized in the cilia of adult ependymal cells and that its expression is correlated with the process of ependymal differentiation and with the maturation of radial glia. Similarly, its particular localization within ependymal cilia suggests a role of this protein in the regulation of ciliary movement.

Published

2018

225. Ventricular and Periventricular Anomalies in the Aging and Cognitively Impaired Brain.

Author

Todd KL, Brighton T, Norton ES, Schick S, Elkins W, Pletnikova O, Fortinsky RH, Troncoso JC, Molfese PJ, Resnick SM, and Conover JC

Abstract

Ventriculomegaly (expansion of the brain's fluid-filled ventricles), a condition commonly found in the aging brain, results in areas of gliosis where the ependymal cells are replaced with dense astrocytic patches. Loss of ependymal cells would compromise trans-ependymal bulk flow mechanisms required for clearance of proteins and metabolites from the brain parenchyma. However, little is known about the interplay between age-related ventricle expansion, the decline in ependymal integrity, altered periventricular fluid homeostasis, abnormal protein accumulation and cognitive impairment. In collaboration with the Baltimore Longitudinal Study of Aging (BLSA) and Alzheimer's Disease Neuroimaging Initiative (ADNI), we analyzed longitudinal structural magnetic resonance imaging (MRI) and subject-matched fluid-attenuated inversion recovery (FLAIR) MRI and periventricular biospecimens to map spatiotemporally the progression of ventricle expansion and associated periventricular edema and loss of transependymal exchange functions in healthy aging individuals and those with varying degrees of cognitive impairment. We found that the trajectory of ventricle expansion and periventricular edema progression correlated with degree of cognitive impairment in both speed and severity, and confirmed that areas of expansion showed ventricle surface gliosis accompanied by edema and periventricular accumulation of protein aggregates, suggesting impaired clearance mechanisms in these regions. These findings reveal pathophysiological outcomes associated with normal brain aging and cognitive impairment, and indicate that a multifactorial analysis is best suited to predict and monitor cognitive decline.

Published

2018

226. A mutation in Ccdc39 causes neonatal hydrocephalus with abnormal motile cilia development in mice.

Author

Abdelhamed Z, Vuong SM, Hill L, Shula C, Timms A, Beier D, Campbell K, Mangano FT, Stottmann RW, and Goto J

Subjects

Animals, Cilia genetics, Cilia metabolism, Mice, Mice, Mutant Strains, Choroid Plexus embryology, Choroid Plexus pathology, Cytoskeletal Proteins genetics, Cytoskeletal Proteins metabolism, Ependyma embryology, Ependyma pathology, Gene Expression Regulation, Developmental, Hydrocephalus embryology, Hydrocephalus genetics, Hydrocephalus pathology

Abstract

Pediatric hydrocephalus is characterized by an abnormal accumulation of cerebrospinal fluid (CSF) and is one of the most common congenital brain abnormalities. However, little is known about the molecular and cellular mechanisms regulating CSF flow in the developing brain. Through whole-genome sequencing analysis, we report that a homozygous splice site mutation in coiled-coil domain containing 39 ( Ccdc39 ) is responsible for early postnatal hydrocephalus in the progressive hydrocephal us ( prh is selectively expressed in embryonic choroid plexus and ependymal cells on the medial wall of the forebrain ventricle, and the protein is localized to the axoneme of motile cilia. The Ccdc39 ependymal cells develop shorter cilia with disorganized microtubules lacking the axonemal inner arm dynein. Using high-speed video microscopy, we show that an orchestrated ependymal ciliary beating pattern controls unidirectional CSF flow on the ventricular surface, which generates bulk CSF flow in the developing brain. Collectively, our data provide the first evidence for involvement of Ccdc39 prh/prh ependymal cells develop shorter cilia with disorganized microtubules lacking the axonemal inner arm dynein. Using high-speed video microscopy, we show that an orchestrated ependymal ciliary beating pattern controls unidirectional CSF flow on the ventricular surface, which generates bulk CSF flow in the developing brain. Collectively, our data provide the first evidence for involvement of Ccdc39 in hydrocephalus and suggest that the proper development of medial wall ependymal cilia is crucial for normal mouse brain development., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

227. Ependymal cells of the mouse brain express urate transporter 1 (URAT1)

Author

Yoshiharu Deguchi, Kimiyoshi Ichida, Makoto Hosoyamada, Makiko Nakamura, Naoko H. Tomioka, Takayuki Morisaki, and Masaru Doshi

Subjects

medicine.medical_specialty, Ependymal Cell, Neurology, Bioinformatics, Neuroprotection, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Developmental Neuroscience, Internal medicine, Medicine, Cilia, Kidney, Hematology, business.industry, Cilium, Research, General Medicine, medicine.disease, Gout, Endocrinology, medicine.anatomical_structure, chemistry, Ependymal cells, Uric acid, URAT1, business

Abstract

Background Elevated uric acid (UA) is commonly associated with gout and it is also a known cardiovascular disease risk factor. In contrast to such deleterious effects, UA possesses neuroprotective properties in the brain and elucidating the molecular mechanisms involved may have significant value regarding the therapeutic treatment of neurodegenerative disease. However, it is not yet fully established how UA levels are regulated in the brain. In this study, we investigated the distribution of mouse urate transporter 1 (URAT1) in the brain. URAT1 is a major reabsorptive urate transporter predominantly found in the kidney. Methods Immunohistochemistry of wild type and URAT1 knockout mouse brain using paraffin or frozen sections and a rabbit polyclonal anti-mouse URAT1 antibody were employed. Results Antibody specificity was confirmed by the lack of immunostaining in brain tissue from URAT1 knockout mice. URAT1 was distributed throughout the ventricular walls of the lateral ventricle, dorsal third ventricle, ventral third ventricle, aqueduct, and fourth ventricle, but not in the non-ciliated tanycytes in the lower part of the ventral third ventricle. URAT1 was localized to the apical membrane, including the cilia, of ependymal cells lining the wall of the ventricles that separates cerebrospinal fluid (CSF) and brain tissue. Conclusion In this study, we report that URAT1 is expressed on cilia and the apical surface of ventricular ependymal cells. This is the first report to demonstrate expression of the urate transporter in ventricular ependymal cells and thus raises the possibility of a novel urate transport system involving CSF.

Published

2013

228. Prolonged but non-permanent expression of a transgene in ependymal cells of adult rats using an adenovirus-mediated transposon gene transfer system.

Author

Suzuki JI, Dezawa M, and Kitada M

Subjects

Animals, Ependyma cytology, Gene Expression, Male, Rats, Rats, Wistar, Adenoviridae genetics, Adenoviridae metabolism, DNA Transposable Elements physiology, Ependyma metabolism, Gene Transfer Techniques, Transgenes physiology

Abstract

Ependymal cells have been considered one of prime targets for gene therapy in the central nervous system as they can secrete proteins directly into the cerebrospinal fluid. In this study, we have explored the probability of permanent exogenous gene expression using a combined adenovirus/transposon system. To this end, we created three adenoviruses; adenovirus #1 containing a CAG promoter-driven enhanced green fluorescent protein tagged with a palmitoylation site (palEGFP), whose DNA sequence was flanked by two different Tol2 ends, #2 containing a human FoxJ1 promoter-driven T2TP transposase, and #3 containing an EF-1 alpha promoter-driven T2TP transposase. We injected these adenoviruses into the lateral ventricles of adult rats to assess the duration of transgene expression, by which adenoviruses selectively infected to ependymal cells because they express the specific receptor. In animals injected with only adenovirus #1, we found palEGFP-expressing ependymal cells 1week after injection, but these cells had disappeared by 2weeks. In animals that received adenoviruses #1 and #2 in combination, despite detecting many palEGFP-expressing ependymal cells within the initial 2weeks, transgene expression in ependymal cells was almost disappeared 1month after injection. In contrast, many palEGFP-expressing astrocytes, oligodendrocytes, and neurons were found near the sites injected with adenoviruses #1 and #3, even 1month after injection. There was no prominent infiltration of immunological cells during the observation period. These findings indicate that an adenovirus-mediated transposon gene transfer system can lead to prolonged, but not permanent, expression of exogenous genes in ependymal cells of adult rats., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

229. The BAF45D Protein Is Preferentially Expressed in Adult Neurogenic Zones and in Neurons and May Be Required for Retinoid Acid Induced PAX6 Expression.

Author

Liu C, Sun R, Huang J, Zhang D, Huang D, Qi W, Wang S, Xie F, Shen Y, and Shen C

Abstract

Adult neurogenesis is important for the development of regenerative therapies for human diseases of the central nervous system (CNS) through the recruitment of adult neural stem cells (NSCs). NSCs are characterized by the capacity to generate neurons, astrocytes, and oligodendrocytes. To identify key factors involved in manipulating the adult NSC neurogenic fate thus has crucial implications for the clinical application. Here, we report that BAF45D is expressed in the subgranular zone (SGZ) of the dentate gyrus, the subventricular zone (SVZ) of the lateral ventricle, and the central canal (CC) of the adult spinal cord. Coexpression of BAF45D with glial fibrillary acidic protein (GFAP), a radial glial like cell marker protein, was identified in the SGZ, the SVZ and the adult spinal cord CC. Quantitative analysis data indicate that BAF45D is preferentially expressed in the neurogenic zone of the LV and the neurons of the adult CNS. Furthermore, during the neuroectoderm differentiation of H9 cells, BAF45D is required for the expression of PAX6, a neuroectoderm determinant that is also known to regulate the self-renewal and neuronal fate specification of adult neural stem/progenitor cells. Together, our results may shed new light on the expression of BAF45D in the adult neurogenic zones and the contribution of BAF45D to early neural development.

Published

2017

230. An ex vivo spinal cord injury model to study ependymal cells in adult mouse tissue.

Author

Fernandez-Zafra T, Codeluppi S, and Uhlén P

Subjects

Aging, Animals, Disease Models, Animal, Mice, Cell Proliferation physiology, Ependyma pathology, Neuroglia pathology, Spinal Cord Injuries pathology

Abstract

Traumatic spinal cord injury is characterized by an initial cell loss that is followed by a concerted cellular response in an attempt to restore the damaged tissue. Nevertheless, little is known about the signaling mechanisms governing the cellular response to injury. Here, we have established an adult ex vivo system that exhibits multiple hallmarks of spinal cord injury and allows the study of complex processes that are difficult to address using animal models. We have characterized the ependymal cell response to injury in this model system and found that ependymal cells can become activated, proliferate, migrate out of the central canal lining and differentiate in a manner resembling the in vivo situation. Moreover, we show that these cells respond to external adenosine triphosphate and exhibit spontaneous Ca 2+ activity, processes that may play a significant role in the regulation of their response to spinal cord injury. This model provides an attractive tool to deepen our understanding of the ependymal cell response after spinal cord injury, which may contribute to the development of new treatment options for spinal cord injury., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

231. A simple strategy for culturing morphologically-conserved rat hypothalamic tanycytes.

Author

De Francesco PN, Castrogiovanni D, Uriarte M, Frassa V, Agosti F, Raingo J, and Perello M

Subjects

Animals, Cells, Cultured, Electrophysiological Phenomena, Endocytosis, Immunohistochemistry, Rats, Sprague-Dawley, Cell Culture Techniques methods, Cell Shape, Ependymoglial Cells cytology, Hypothalamus cytology

Abstract

Hypothalamic tanycytes are specialized bipolar ependymal cells that line the floor of the third ventricle. Given their strategic location, tanycytes are believed to play several key functions including being a selective barrier and controlling the amount of hypothalamic-derived factors reaching the anterior pituitary. The in vitro culture of these cells has proved to be difficult. Here, we report an improved method for the generation of primary cultures of rat hypothalamic tanycytes. Ependymal cultures were derived from tissue dissected out of the median eminence region of 10-day-old rats and cultured in a chemically defined medium containing DMEM:F12, serum albumin, insulin, transferrin and the antibiotic gentamycin. After 7 days in vitro, ∼30% of the cultured cells exhibited morphological features of tanycytes as observed by phase contrast or scanning electron microscopy. Tanycyte-like cells were strongly immuno-reactive for vimentin and dopamine-cAMP-regulated phospho-protein (DARPP-32) and weakly immune-reactive for glial fibrillary acidic protein. Tanycyte-like cells displayed a stable negative resting plasma membrane potential and failed to show spiking properties in response to current injections. When exposed to fluorescent beads in the culture medium, tanycyte-like cells exhibited a robust endocytosis. Thus, the present method effectively yields cultures containing tanycyte-like cells that resemble in vivo tanycytes in terms of morphologic features and molecular markers as well as electrical and endocytic activity. To our knowledge, this is the first protocol that allows the culturing of tanycyte-like cells that can be individually identified and that conserve the morphology of tanycytes in their natural physiological environment.

Published

2017

232. Loss of Mpdz impairs ependymal cell integrity leading to perinatal-onset hydrocephalus in mice.

Author

Feldner A, Adam MG, Tetzlaff F, Moll I, Komljenovic D, Sahm F, Bäuerle T, Ishikawa H, Schroten H, Korff T, Hofmann I, Wolburg H, von Deimling A, and Fischer A

Subjects

Animals, Astrocytes physiology, Cells, Cultured, Epithelial Cells physiology, Gene Deletion, Gene Knockdown Techniques, Humans, Membrane Proteins, Mice, Carrier Proteins genetics, Carrier Proteins metabolism, Disease Models, Animal, Ependyma pathology, Hydrocephalus physiopathology

Abstract

Hydrocephalus is a common congenital anomaly. LCAM1 and MPDZ ( MUPP1 ) are the only known human gene loci associated with non-syndromic hydrocephalus. To investigate functions of the tight junction-associated protein Mpdz, we generated mouse models. Global Mpdz gene deletion or conditional inactivation in Nestin-positive cells led to formation of supratentorial hydrocephalus in the early postnatal period. Blood vessels, epithelial cells of the choroid plexus, and cilia on ependymal cells, which line the ventricular system, remained morphologically intact in Mpdz -deficient brains. However, flow of cerebrospinal fluid through the cerebral aqueduct was blocked from postnatal day 3 onward. Silencing of Mpdz expression in cultured epithelial cells impaired barrier integrity, and loss of Mpdz in astrocytes increased RhoA activity. In Mpdz -deficient mice, ependymal cells had morphologically normal tight junctions, but expression of the interacting planar cell polarity protein Pals1 was diminished and barrier integrity got progressively lost. Ependymal denudation was accompanied by reactive astrogliosis leading to aqueductal stenosis. This work provides a relevant hydrocephalus mouse model and demonstrates that Mpdz is essential to maintain integrity of the ependyma., (© 2017 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2017

233. Inflammatory demyelination induces ependymal modifications concomitant to activation of adult (SVZ) stem cell proliferation.

Author

Pourabdolhossein F, Gil-Perotín S, Garcia-Belda P, Dauphin A, Mozafari S, Tepavcevic V, Manuel Garcia Verdugo J, and Baron-Van Evercooren A

Subjects

Animals, Encephalomyelitis, Autoimmune, Experimental metabolism, Female, Immunohistochemistry methods, Inflammation metabolism, Mice, Inbred C57BL, Neurogenesis, Neuroglia cytology, Adult Stem Cells cytology, Cell Proliferation physiology, Encephalomyelitis, Autoimmune, Experimental pathology, Lateral Ventricles cytology, Neural Stem Cells cytology

Abstract

Ependymal cells (E1/E2) and ciliated B1cells confer a unique pinwheel architecture to the ventricular surface of the subventricular zone (SVZ), and their cilia act as sensors to ventricular changes during development and aging. While several studies showed that forebrain demyelination reactivates the SVZ triggering proliferation, ectopic migration, and oligodendrogenesis for myelin repair, the potential role of ciliated cells in this process was not investigated. Using conventional and lateral wall whole mount preparation immunohistochemistry in addition to electron microscopy in a forebrain-targeted model of experimental autoimmune encephalomyelitis (tEAE), we show an early decrease in numbers of pinwheels, B1 cells, and E2 cells. These changes were transient and simultaneous to tEAE-induced SVZ stem cell proliferation. The early drop in B1/E2 cell numbers was followed by B1/E2 cell recovery. While E1 cell division and ependymal ribbon disruption were never observed, E1 cells showed important morphological modifications reflected by their enlargement, extended cytoskeleton, and reinforced cell-cell junction complexes overtime, possibly reflecting protective mechanisms against ventricular insults. Finally, tEAE disrupted motile cilia planar cell polarity and cilia orientation in ependymal cells. Therefore, significant ventricular modifications in ciliated cells occur early in response to tEAE suggesting a role for these cells in SVZ stem cell signalling not only during development/aging but also during inflammatory demyelination. These observations may have major implications for understanding pathophysiology of and designing therapeutic approaches for inflammatory demyelinating diseases such as MS., (© 2017 Wiley Periodicals, Inc.)

Published

2017

234. Cell- and region-specific expression of depression-related protein p11 (S100a10) in the brain.

Author

Milosevic A, Liebmann T, Knudsen M, Schintu N, Svenningsson P, and Greengard P

Subjects

Animals, Depression metabolism, Female, Image Processing, Computer-Assisted, Immunohistochemistry, In Situ Hybridization, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Annexin A2 biosynthesis, Brain metabolism, S100 Proteins biosynthesis

Abstract

P11 (S100a10), a member of the S100 family of proteins, has widespread distribution in the vertebrate body, including in the brain, where it has a key role in membrane trafficking, vesicle secretion, and endocytosis. Recently, our laboratory has shown that a constitutive knockout of p11 (p11-KO) in mice results in a depressive-like phenotype. Furthermore, p11 has been implicated in major depressive disorder (MDD) and in the actions of antidepressants. Since depression affects multiple brain regions, and the role of p11 has only been determined in a few of these areas, a detailed analysis of p11 expression in the brain is warranted. Here we demonstrate that, although widespread in the brain, p11 expression is restricted to distinct regions, and specific neuronal and nonneuronal cell types. Furthermore, we provide comprehensive mapping of p11 expression using in situ hybridization, immunocytochemistry, and whole-tissue volume imaging. Overall, expression spans multiple brain regions, structures, and cell types, suggesting a complex role of p11 in depression. J. Comp. Neurol. 525:955-975, 2017. © 2016 Wiley Periodicals, Inc., Competing Interests: The authors declare no conflict of interest., (© 2016 The Authors The Journal of Comparative Neurology Published by Wiley Periodicals, Inc.)

Published

2017

235. Regenerative Potential of Ependymal Cells for Spinal Cord Injuries Over Time.

Author

Li X, Floriddia EM, Toskas K, Fernandes KJL, Guérout N, and Barnabé-Heider F

Subjects

Animals, Cell Self Renewal, Cells, Cultured, Disease Models, Animal, Genes, Reporter, Macrophages immunology, Macrophages metabolism, Mice, Microglia immunology, Microglia metabolism, Neural Stem Cells metabolism, Spinal Cord cytology, Spinal Cord embryology, Spinal Cord metabolism, Spinal Cord Injuries immunology, Spinal Cord Injuries metabolism, Spinal Cord Injuries therapy, Cell Differentiation, Ependyma cytology, Neural Stem Cells cytology, Regeneration, Spinal Cord Injuries pathology

Abstract

Stem cells have a high therapeutic potential for the treatment of spinal cord injury (SCI). We have shown previously that endogenous stem cell potential is confined to ependymal cells in the adult spinal cord which could be targeted for non-invasive SCI therapy. However, ependymal cells are an understudied cell population. Taking advantage of transgenic lines, we characterize the appearance and potential of ependymal cells during development. We show that spinal cord stem cell potential in vitro is contained within these cells by birth. Moreover, juvenile cultures generate more neurospheres and more oligodendrocytes than adult ones. Interestingly, juvenile ependymal cells in vivo contribute to glial scar formation after severe but not mild SCI, due to a more effective sealing of the lesion by other glial cells. This study highlights the importance of the age-dependent potential of stem cells and post-SCI environment in order to utilize ependymal cell's regenerative potential., (Copyright © 2016 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2016

236. p73 is required for ependymal cell maturation and neurogenic SVZ cytoarchitecture.

Author

Gonzalez-Cano L, Fuertes-Alvarez S, Robledinos-Anton N, Bizy A, Villena-Cortes A, Fariñas I, Marques MM, and Marin MC

Subjects

Animals, Ependyma cytology, Lateral Ventricles cytology, Mice, Mice, 129 Strain, Mice, Inbred C57BL, Mice, Knockout, Tumor Protein p73 deficiency, Tumor Protein p73 genetics, Tumor Suppressor Protein p53, Cell Growth Processes physiology, Ependyma physiology, Lateral Ventricles physiology, Neurogenesis physiology, Tumor Protein p73 physiology

Abstract

The adult subventricular zone (SVZ) is a highly organized microenvironment established during the first postnatal days when radial glia cells begin to transform into type B-cells and ependymal cells, all of which will form regenerative units, pinwheels, along the lateral wall of the lateral ventricle. Here, we identify p73, a p53 homologue, as a critical factor controlling both cell-type specification and structural organization of the developing mouse SVZ. We describe that p73 deficiency halts the transition of the radial glia into ependymal cells, leading to the emergence of immature cells with abnormal identities in the ventricle and resulting in loss of the ventricular integrity. p73-deficient ependymal cells have noticeably impaired ciliogenesis and they fail to organize into pinwheels, disrupting SVZ niche structure and function. Therefore, p73 is essential for appropriate ependymal cell maturation and the establishment of the neurogenic niche architecture. Accordingly, lack of p73 results in impaired neurogenesis. Moreover, p73 is required for translational planar cell polarity establishment, since p73 deficiency results in profound defects in cilia organization in individual cells and in intercellular patch orientation. Thus, our data reveal a completely new function of p73, independent of p53, in the neurogenic architecture of the SVZ of rodent brain and in the establishment of ependymal planar cell polarity with important implications in neurogenesis. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 730-747, 2016., (© 2015 Wiley Periodicals, Inc.)

Published

2016

237. DAPT mediates atoh1 expression to induce hair cell-like cells.

Author

Ren H, Guo W, Liu W, Gao W, Xie D, Yin T, Yang S, and Ren J

Abstract

Hearing loss is currently an incurable degenerative disease characterized by a paucity of hair cells (HCs), which cannot be spontaneously replaced in mammals. Recent technological advancements in gene therapy and local drug delivery have shed new light for hearing loss. Atoh1, also known as Math1, Hath1, and Cath1, is a proneural basic helix-loop-helix (bHLH) transcription factor that is essential for HC differentiation. At various stages in development, Atoh1 activity is sufficient to drive HC differentiation in the cochlea. Thus, Atoh1 related gene therapy is the most promising option for HC induction. DAPT, an inhibitor of Notch signaling, enhances the expression of Atoh1 indirectly, which in turn promotes the induction of a HC fate. Here, we show that DAPT cooperates with Atoh1 to synergistically promote HC fate in ependymal cells in vitro and promote hair cell regeneration in the cultured basilar membrane (BM) which mimics the microenvironment in vivo. Taken together, our findings demonstrated that DAPT is sufficient to induce HC-like cells via enhancing of the expression of Atoh1 to inhibit the progression of HC apoptosis and to induce new HC formation.

Published

2016

238. Endogenous neural stem cell responses to stroke and spinal cord injury.

Author

Grégoire CA, Goldenstein BL, Floriddia EM, Barnabé-Heider F, and Fernandes KJ

Subjects

Animals, Brain Ischemia therapy, Ependyma physiopathology, Humans, Spinal Cord Injuries therapy, Stem Cell Niche physiology, Stroke therapy, Brain Ischemia physiopathology, Neural Stem Cells physiology, Spinal Cord Injuries physiopathology, Stroke physiopathology

Abstract

Stroke and spinal cord injury (SCI) are among the most frequent causes of central nervous system (CNS) dysfunction, affecting millions of people worldwide each year. The personal and financial costs for affected individuals, their families, and the broader communities are enormous. Although the mammalian CNS exhibits little spontaneous regeneration and self-repair, recent discoveries have revealed that subpopulations of glial cells in the adult forebrain subventricular zone and the spinal cord ependymal zone possess neural stem cell properties. These endogenous neural stem cells react to stroke and SCI by contributing a significant number of new neural cells to formation of the glial scar. These findings have raised hopes that new therapeutic strategies can be designed based on appropriate modulation of endogenous neural stem cell responses to CNS injury. Here, we review the responses of forebrain and spinal cord neural stem cells to stroke and SCI, the role of these responses in restricting injury-induced tissue loss, and the possibility of directing these responses to promote anatomical and functional repair of the CNS., (© 2015 Wiley Periodicals, Inc.)

Published

2015

239. Current states of endogenous stem cells in adult spinal cord.

Author

Qin Y, Zhang W, and Yang P

Subjects

Animals, Neurogenesis physiology, Ependyma cytology, Neural Stem Cells cytology, Spinal Cord cytology, Stem Cells cytology

Abstract

New neurons are continuously generated throughout life in the subgranular zone in the dentate gyrus of the mammalian hippocampus and in the subventricular zone of the lateral ventricles. With the aid of new methodologies, significant progress has been made in the characterization of endogenous stem cells (ependymal cells) and their development in the adult spinal cord. Recent studies have shed light on essential extrinsic and intrinsic molecular mechanisms that govern sequential steps of neurogenesis in the adult spinal cord. This review discusses the occurrence, origin, and specific makers of ependymal cells; the factors regulating neurogenesis of multipotent ependymal cells; and the implications of ependymal cells in the repair of spinal cord injuries., (© 2014 Wiley Periodicals, Inc.)

Published

2015

240. Ependymal cell differentiation, from monociliated to multiciliated cells.

Author

Delgehyr N, Meunier A, Faucourt M, Bosch Grau M, Strehl L, Janke C, and Spassky N

Subjects

AC133 Antigen, ADP-Ribosylation Factors physiology, Adenylyl Cyclases physiology, Animals, Antigens, CD, Biomarkers, CD24 Antigen, Cell Differentiation, Cells, Cultured, Ependyma physiology, Ependyma surgery, Glycoproteins, Immunohistochemistry, Lateral Ventricles physiology, Lateral Ventricles surgery, Mice, Peptides, Primary Cell Culture methods, Staining and Labeling methods, Tubulin metabolism, Cilia physiology, Ependyma cytology, Ependymoglial Cells cytology, Lateral Ventricles cytology, Neural Stem Cells cytology

Abstract

Primary and motile cilia differ in their structure, composition, and function. In the brain, primary cilia are immotile signalling organelles present on neural stem cells and neurons. Multiple motile cilia are found on the surface of ependymal cells in all brain ventricles, where they contribute to the flow of cerebrospinal fluid. During development, monociliated ependymal progenitor cells differentiate into multiciliated ependymal cells, thus providing a simple system for studying the transition between these two stages. In this chapter, we provide protocols for immunofluorescence staining of developing ependymal cells in vivo, on whole mounts of lateral ventricle walls, and in vitro, on cultured ependymal cells. We also provide a list of markers we currently use to stain both types of cilia, including proteins at the ciliary membrane and tubulin posttranslational modifications of the axoneme., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

241. A knock-in Foxj1(CreERT2::GFP) mouse for recombination in epithelial cells with motile cilia.

Author

Muthusamy N, Vijayakumar A, Cheng G Jr, and Ghashghaei HT

Subjects

Animals, Cell Lineage, Choroid Plexus cytology, Cilia physiology, Epithelial Cells metabolism, Epithelial Cells ultrastructure, Female, Forkhead Transcription Factors biosynthesis, Gene Expression, Gene Knock-In Techniques, Green Fluorescent Proteins biosynthesis, Green Fluorescent Proteins genetics, Integrases genetics, Male, Mice, 129 Strain, Mice, Inbred C57BL, Mice, Transgenic, Recombination, Genetic, Tamoxifen pharmacology, Transcriptional Activation drug effects, Choroid Plexus metabolism, Forkhead Transcription Factors genetics

Abstract

The transcription factor Foxj1 is expressed by cells destined to differentiate into epithelial cells projecting motile cilia into fluid- or air-filled cavities. Here, we report the generation of an inducible knock-in Foxj1(CreERT2::GFP) mouse, which we show reliably induces Cre-mediated recombination for genetic studies in epithelial cells with motile cilia throughout embryonic and postnatal development. Induction during embryonic stages revealed efficient recombination in the epithelial component of the choroid plexus in the developing brain as early as E12.5. Induction during late embryonic stages showed confined recombination not only in the choroid plexus but also in the ventricular walls of the brain. Recombination induced during postnatal periods expanded to include epithelia of the lungs, testis, oviduct, and brain. Using these mice, we confirmed our recent discovery of a perinatally derived neuronal population in the mouse olfactory bulbs, which is derived from the Foxj1 lineage. Our Foxj1(CreERT2::GFP) knock-in mouse will be a powerful tool for studying molecular mechanisms associated with the continuum of cells that form the Foxj1 lineage, and for assessing their physiological significance during development and aging., (Copyright © 2014 Wiley Periodicals, Inc.)

Published

2014

242. Abnormal cilia in a fourth ventricular ependymoma

Author

Ho, K. -L.

Published

1986

243. Ultrastructural observations of spinal cord lesions and blood-brain barrier changes in scrapie-infected mice

Author

Lossinsky, A. S., Moretz, R. C., Carp, R. I., and Wisniewski, H. M.

Published

1987

244. A glioependymal cyst of the cerebellopontine angle: Immunohistochemical and ultrastructural studies

Author

Ho, K. -L. and Chason, J. L.

Published

1987

245. The adult spinal cord harbors a population of GFAP-positive progenitors with limited self-renewal potential.

Author

Fiorelli R, Cebrian-Silla A, Garcia-Verdugo JM, and Raineteau O

Subjects

Adult Stem Cells metabolism, Animals, Glial Fibrillary Acidic Protein, Mice, Mice, Transgenic, Multipotent Stem Cells metabolism, Neural Stem Cells metabolism, Neuroglia cytology, Neuroglia metabolism, Spinal Cord metabolism, Adult Stem Cells cytology, Cell Differentiation physiology, Multipotent Stem Cells cytology, Nerve Tissue Proteins metabolism, Neural Stem Cells cytology, Spinal Cord cytology

Abstract

Adult neural stem cells (aNSCs) of the forebrain are GFAP-expressing cells that are intercalated within ependymal cells of the subventricular zone (SVZ). Cells showing NSCs characteristics in vitro can also be isolated from the periaqueductal region in the adult spinal cord (SC), but contradicting results exist concerning their glial versus ependymal identity. We used an inducible transgenic mouse line (hGFAP-CreERT2) to conditionally label GFAP-expressing cells in the adult SVZ and SC periaqueduct, and directly and systematically compared their self-renewal and multipotential properties in vitro. We demonstrate that a population of GFAP(+) cells that share the morphology and the antigenic properties of SVZ-NSCs mostly reside in the dorsal aspect of the central canal (CC) throughout the spinal cord. These cells are non-proliferative in the intact spinal cord, but incorporate the S-phase marker EdU following spinal cord injury. Multipotent, clonal YFP-expressing neurospheres (i.e., deriving from recombined GFAP-expressing cells) were successfully obtained from both the intact and injured spinal cord. These spheres however showed limited self-renewal properties when compared with SVZ-neurospheres, even after spinal cord injury. Altogether, these results demonstrate that significant differences exist in NSCs lineages between neurogenic and non-neurogenic regions of the adult CNS. Thus, although we confirm that a population of multipotent GFAP(+) cells co-exists alongside with multipotent ependymal cells within the adult SC, we identify these cells as multipotent progenitors showing limited self-renewal properties., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

246. PTB deficiency causes the loss of adherens junctions in the dorsal telencephalon and leads to lethal hydrocephalus.

Author

Shibasaki T, Tokunaga A, Sakamoto R, Sagara H, Noguchi S, Sasaoka T, and Yoshida N

Subjects

Animals, Hydrocephalus genetics, Mice, Mice, 129 Strain, Mice, Inbred C57BL, Mice, Knockout, Neural Stem Cells ultrastructure, Polypyrimidine Tract-Binding Protein genetics, Telencephalon abnormalities, Adherens Junctions ultrastructure, Hydrocephalus etiology, Polypyrimidine Tract-Binding Protein physiology, Telencephalon embryology

Abstract

Polypyrimidine tract-binding protein (PTB) is a well-characterized RNA-binding protein and known to be preferentially expressed in neural stem cells (NSCs) in the central nervous system; however, its role in NSCs in the developing brain remains unclear. To explore the role of PTB in embryonic NSCs in vivo, Nestin-Cre-mediated conditional Ptb knockout mice were generated for this study. In the mutant forebrain, despite the depletion of PTB protein, neither abnormal neurogenesis nor flagrant morphological abnormalities were observed at embryonic day 14.5 (E14.5). Nevertheless, by 10 weeks, nearly all mutant mice succumbed to hydrocephalus (HC), which was caused by a lack of the ependymal cell layer in the dorsal cortex. Upon further analysis, a gradual loss of adherens junctions (AJs) was observed in the ventricular zone (VZ) of the dorsal telencephalon in the mutant brains, beginning at E14.5. In the AJs-deficient VZ, impaired interkinetic nuclear migration and precocious differentiation of NSCs were observed after E14.5. These findings demonstrated that PTB depletion in the dorsal telencephalon is causally involved in the development of HC and that PTB is important for the maintenance of AJs in the NSCs of the dorsal telencephalon.

Published

2013

247. GEMC1 is a critical regulator of multiciliated cell differentiation

Author

Terré, Berta, Piergiovanni, Gabriele, Segura-Bayona, Sandra, Gil-Gómez, Gabriel, Youssef, Sameh A, Attolini, Camille Stephan-Otto, Wilsch-Bräuninger, Michaela, Jung, Carole, Rojas, Ana M, Marjanović, Marko, Knobel, Philip A, Palenzuela, Lluís, López-Rovira, Teresa, Forrow, Stephen, Huttner, Wieland B, Valverde, Miguel A, de Bruin, Alain, Costanzo, Vincenzo, Stracker, Travis H, LS Pathobiologie, dPB RMSC, LS Pathobiologie, dPB RMSC, Ministerio de Economía y Competitividad (España), Instituto de Salud Carlos III, European Commission, Associazione Italiana per la Ricerca sul Cancro, European Research Council, Association for International Cancer Research, Fondazione Telethon, Fondazione Giovanna Ciani, Fundación 'la Caixa', and Swiss National Science Foundation

Subjects

0301 basic medicine, Candidate gene, Cellular differentiation, Regulator, Cell Cycle Proteins, Hair cells, Germline, Mice, Hidrocefàlia, Growth Disorders, Mice, Knockout, Genetics, General Neuroscience, Cilium, NOTCH SIGNALING CONTROLS, Cell Differentiation, Articles, Esterilitat, Penetrance, Aparell respiratori, 3. Good health, Cell biology, ALZHEIMERS-DISEASE, TRANSCRIPTION FACTORS, hydrocephaly, cilia, ciliopathy, infertility, transcription, EPENDYMAL CELLS, Motile cilium, REDUCED GENERATION, CENTRIOLE BIOGENESIS, MUCOCILIARY CLEARANCE DISORDER, Biology, General Biochemistry, Genetics and Molecular Biology, MULTIPLE MOTILE CILIA, 03 medical and health sciences, Cèl·lules acústiques, medicine, Humans, Animals, FUNCTIONAL GENOMICS, Molecular Biology, General Immunology and Microbiology, Geminin, DNA-REPLICATION, Respiratory organs, medicine.disease, Ciliopathy, 030104 developmental biology, Carrier Proteins

Abstract

Terré, Berta et al., The generation of multiciliated cells (MCCs) is required for the proper function of many tissues, including the respiratory tract, brain, and germline. Defects in MCC development have been demonstrated to cause a subclass of mucociliary clearance disorders termed reduced generation of multiple motile cilia (RGMC). To date, only two genes, Multicilin (MCIDAS) and cyclin O (CCNO) have been identified in this disorder in humans. Here, we describe mice lacking GEMC1 (GMNC), a protein with a similar domain organization as Multicilin that has been implicated in DNA replication control. We have found that GEMC1‐deficient mice are growth impaired, develop hydrocephaly with a high penetrance, and are infertile, due to defects in the formation of MCCs in the brain, respiratory tract, and germline. Our data demonstrate that GEMC1 is a critical regulator of MCC differentiation and a candidate gene for human RGMC or related disorders., We thank the Ministerio de Economía y Competitividad (MINECO) for funding to TS (BFU2012‐39521) and MAV (SAF2012‐38140; Fondo de Investigación Sanitaria (RD12/0042/0014); FEDER Funds); G.G.‐G. is supported by ISCIII (PI13/00864); V.C. is funded by the Associazione Italiana per Ricerca sul Cancro (AIRC), the European Research Council (ERC) consolidator grant (614541), the Association for International Cancer Research (AICR) (13‐0026), the Giovanni Armenise Award to V.C., the Epigen Progetto Bandiera (4.7) and the Fondazione Telethon (GGP13071); G.P. was supported by AIRC Borsa: Fondazione Giovanna Ciani Rif. 16444; S.S.B. was supported by a fellowship from Fundació La Caixa; P.A.K. was supported by an Early Postdoc Mobility Fellowship from the Swiss National Science Foundation; and B.T. was supported by a Severo Ochoa FPI Fellowship (MINECO). IRB Barcelona is a Severo Ochoa Award of Excellence Recipient (MINECO).

248. Inflammatory demyelination induces ependymal modifications concomitant to activation of adult ( SVZ) stem cell proliferation

Author

Pourabdolhossein, F., Gil-Perotin, S., Garcia-Belda, P., Dauphin, A., Mozafari, S., Vanja Tepavcevic, Garcia Verdugo, J. M., and Evercooren, A. B. -V

Subjects

nervous system, B1 cells, inflammatory demyelination, ependymal cells, subventricular zone, tEAE

Abstract

Ependymal cells (E1/E2) and ciliated B1cells confer a unique pinwheel architecture to the ventricular surface of the subventricular zone (SVZ), and their cilia act as sensors to ventricular changes during development and aging. While several studies showed that forebrain demyelination reactivates the SVZ triggering proliferation, ectopic migration, and oligodendrogenesis for myelin repair, the potential role of ciliated cells in this process was not investigated. Using conventional and lateral wall whole mount preparation immunohistochemistry in addition to electron microscopy in a forebrain-targeted model of experimental autoimmune encephalomyelitis (tEAE), we show an early decrease in numbers of pinwheels, B1 cells, and E2 cells. These changes were transient and simultaneous to tEAE-induced SVZ stem cell proliferation. The early drop in B1/E2 cell numbers was followed by B1/E2 cell recovery. While E1 cell division and ependymal ribbon disruption were never observed, E1 cells showed important morphological modifications reflected by their enlargement, extended cytoskeleton, and reinforced cell-cell junction complexes overtime, possibly reflecting protective mechanisms against ventricular insults. Finally, tEAE disrupted motile cilia planar cell polarity and cilia orientation in ependymal cells. Therefore, significant ventricular modifications in ciliated cells occur early in response to tEAE suggesting a role for these cells in SVZ stem cell signalling not only during development/aging but also during inflammatory demyelination. These observations may have major implications for understanding pathophysiology of and designing therapeutic approaches for inflammatory demyelinating diseases such as MS.

249. Axons take a dive: Specialized contacts of serotonergic axons with cells in the walls of the lateral ventricles in mice and humans

Author

Ck, Tong, Cebrián-Silla A, Mf, Paredes, Eric Huang, Jm, García-Verdugo, and Alvarez-Buylla A

Subjects

adult neurogenesis, nervous system, ependymal cells, human, neural stem cells, serotonin, supraependymal axons

Abstract

In the walls of the lateral ventricles of the adult mammalian brain, neural stem cells (NSCs) and ependymal (E1) cells share the apical surface of the ventricular-subventricular zone (V-SVZ). In a recent article, we show that supraependymal serotonergic (5HT) axons originating from the raphe nuclei in mice form an extensive plexus on the walls of the lateral ventricles where they contact E1 cells and NSCs. Here we further characterize the contacts between 5HT supraependymal axons and E1 cells in mice, and show that suprependymal axons tightly associated to E1 cells are also present in the walls of the human lateral ventricles. These observations raise interesting questions about the function of supraependymal axons in the regulation of E1 cells.

250. Molecular Characterization of an Aquaporin cDNA from Brain: Candidate Osmoreceptor and Regulator of Water Balance

Author

Jung, Jin Sup, Bhat, Ratan V., Preston, Gregory M., Guggino, William B., Baraban, Jay M., and Agre, Peter

Published

1994