Your search keyword '"EPENDYMAL CELLS"' showing total 444 results

101. Transporter-mediated L-glutamate elimination from cerebrospinal fluid: possible involvement of excitatory amino acid transporters expressed in ependymal cells and choroid plexus epithelial cells.

Author

Shin-ichi Akanuma, Tatsuhiko Sakurai, Masanori Tachikawa, Yoshiyuki Kubo, and Ken-ichi Hosoya

Subjects

*GLUTAMIC acid, *CEREBROSPINAL fluid, *AMINO acid transport, *EPITHELIAL cells, *CHOROID plexus, *NEUROTRANSMITTERS

Abstract

Background: L-Glutamate (L-Glu) is the major excitatory neurotransmitter in the CNS, and its level in cerebrospinal fluid (CSF) is reported to be increased in neuroexcitatory diseases such as epilepsy. Since L-Glu concentration in the CSF is reported to be lower than that in plasma, it has been proposed that some mechanisms of L-Glu clearance from the CSF operate in the brain. The purpose of this study was to elucidate the major pathway of L-Glu elimination from rat CSF and the transporters responsible. Methods: Protein expression and localization of excitatory amino acid transporters were examined by immunohistochemical analysis using specific antibodies. In vivo elimination of L-Glu from rat CSF was evaluated by intracerebroventricular administration. An L-Glu uptake study by using primary-cultured rat ependymal cells and isolated rat choroid plexus was performed to characterize L-Glu transport mechanisms. Results: An immunohistochemical analysis has shown that excitatory amino acid transporter (EAAT) 1 and EAAT3, which are D-aspartate-sensitive and kainate-insensitive L-Glu transporters, are localized on the CSF-side of rat ependymal cells and choroid plexus epithelial cells, respectively. In contrast, the kainate-sensitive L-Glu transporter, EAAT2, is not expressed in these cells. In vivo L-Glu elimination clearance from the rat CSF (189 μL/(min · rat)) was 23-fold higher than the CSF bulk flow rate, indicating that facilitative process(es) are involved in L-Glu elimination from the CSF. The in vivo [³H]L-Glu elimination from the CSF was significantly inhibited by unlabeled L-Glu and D-aspartate, but not kainate. Moreover, unlabeled L-Glu and D-aspartate inhibited [³H]L-Glu uptake by rat ependymal cells and choroid plexus epithelial cells, whereas kainate had little effect. Conclusion: It is suggested that EAAT1 in ependymal cells and EAAT3 in choroid plexus epithelial cells participate in L-Glu elimination from the CSF. [ABSTRACT FROM AUTHOR]

Published

2015

102. Role of non-neuronal cells in body weight and appetite control.

Author

Argente-Arizón, Pilar, Freire-Regatillo, Alejandra, Argente, Jesús, and Chowen, Julie A.

Subjects

NEURONS, BODY weight, APPETITE

Abstract

The brain is composed of neurons and non-neuronal cells, with the latter encompassing glial, ependymal and endothelial cells, as well as pericytes and progenitor cells. Studies aimed at understanding how the brain operates have traditionally focused on neurons, but the importance of non-neuronal cells has become increasingly evident. Once relegated to supporting roles, it is now indubitable that these diverse cell types are fundamental for brain development and function, including that of metabolic circuits, and they may play a significant role in obesity onset and complications. They participate in processes of neurogenesis, synaptogenesis, and synaptic plasticity of metabolic circuits both during development and in adulthood. Some glial cells, such as tanycytes and astrocytes, transport circulating nutrients and metabolic factors that are fundamental for neuronal viability and activity into and within the hypothalamus. All of these cell types express receptors for a variety of metabolic factors and hormones, suggesting that they participate in metabolic function. They are the first line of defense against any assault to neurons. Indeed, microglia and astrocytes participate in the hypothalamic inflammatory response to high fat diet (HFD)-induced obesity, with this process contributing to inflammatory-related insulin and leptin resistance. Moreover, HFD-induced obesity and hyperleptinemia modify hypothalamic astroglial morphology, which is associated with changes in the synaptic inputs to neuronal metabolic circuits. Astrocytic contact with the microvasculature is increased by HFD intake and this could modify nutrient/hormonal uptake into the brain. In addition, progenitor cells in the hypothalamus are now known to have the capacity to renew metabolic circuits, and this can be affected by HFD intake and obesity. Here, we discuss our current understanding of hownon-neuronal cells participate in physiological and physiopathological metabolic control. [ABSTRACT FROM AUTHOR]

Published

2015

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

Author

Stavros eMalas and Elena ePanayiotou

Subjects

Spinal Cord Injuries, Stem Cells, Stem Cell Therapy, ependymal cells, central canal, Physiology, QP1-981

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

104. SVCT2 Vitamin C Transporter Expression in Progenitor Cells of the Postnatal Neurogenic Niche

Author

Patricia ePastor, Pedro eCisternas, Katterine eSalazar, Carmen eSilva-Alvarez, Karina eOyarce, Nery eJara, Francisca eEspinoza, Agustin eMartínez, and Francisco Javier Nualart

Subjects

Brain, Stem Cells, progenitor, vitamin C, ependymal cells, SVCT2, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

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 one-month of postnatal development. Using immunohistochemistry, sodium-vitamin C cotransporter 2 (SVCT2) expression was detected in the subventricular zone and rostral migratory stream. 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 induced their neural differentiation, increased βIII-tubulin and SVCT2 expression, and amplified vitamin C uptake.

Published

2013

105. Protein carbonylation after traumatic brain injury: cell specificity, regional susceptibility, and gender differences.

Author

Lazarus, Rachel C., Buonora, John E., Jacobowitz, David M., and Mueller, Gregory P.

Subjects

*BRAIN injuries, *NEURONS, *GENDER differences (Psychology), *PROTEINS, *CARBONYLATION

Abstract

Protein carbonylation is a well-documented and quantifiable consequence of oxidative stress in several neuropathologies, including multiple sclerosis, Alzheimer׳s disease, and Parkinson׳s disease. Although oxidative stress is a hallmark of traumatic brain injury (TBI), little work has explored the specific neural regions and cell types in which protein carbonylation occurs. Furthermore, the effect of gender on protein carbonylation after TBI has not been studied. The present investigation was designed to determine the regional and cell specificity of TBI-induced protein carbonylation and how this response to injury is affected by gender. Immunohistochemistry was used to visualize protein carbonylation in the brains of adult male and female Sprague–Dawley rats subjected to controlled cortical impact (CCI) as an injury model of TBI. Cell-specific markers were used to colocalize the presence of carbonylated proteins in specific cell types, including astrocytes, neurons, microglia, and oligodendrocytes. Results also indicated that the injury lesion site, ventral portion of the dorsal third ventricle, and ventricular lining above the median eminence showed dramatic increases in protein carbonylation after injury. Specifically, astrocytes and limited regions of ependymal cells adjacent to the dorsal third ventricle and the median eminence were most susceptible to postinjury protein carbonylation. However, these patterns of differential susceptibility to protein carbonylation were gender dependent, with males showing significantly greater protein carbonylation at sites distant from the lesion. Proteomic analyses were also conducted and determined that the proteins most affected by carbonylation in response to TBI include glial fibrillary acidic protein, dihydropyrimidase-related protein 2, fructose-bisphosphate aldolase C, and fructose-bisphosphate aldolase A. Many other proteins, however, were not carbonylated by CCI. These findings indicate that there is both regional and protein specificity in protein carbonylation after TBI. The marked increase in carbonylation seen in ependymal layers distant from the lesion suggests a mechanism involving the transmission of a cerebral spinal fluid-borne factor to these sites. Furthermore, this process is affected by gender, suggesting that hormonal mechanisms may serve a protective role against oxidative stress. [ABSTRACT FROM AUTHOR]

Published

2015

106. The LIM Homeodomain Factor Lhx2 Is Required for Hypothalamic Tanycyte Specification and Differentiation.

Author

Salvatierra, Juan, Lee, Daniel A., Zibetti, Cristina, Duran-Moreno, Maria, Sooyeon Yoo, Newman, Elizabeth A., Hong Wang, Bedont, Joseph L., de Melo, Jimmy, Miranda-Angulo, Ana L., Gil-Perotin, Sara, Garcia-Verdugo, Jose Manuel, and Blackshaw, Seth

Subjects

*HOMEOBOX proteins, *HYPOTHALAMUS, *NEUROGLIA, *CELL differentiation, *NEURAL stem cells, *GENE expression, *IMMUNOPRECIPITATION

Abstract

Hypothalamic tanycytes, a radial glial-like ependymal cell population that expresses numerous genes selectively enriched in embryonic hypothalamic progenitors and adult neural stem cells, have recently been observed to serve as a source of adult-born neurons in the mammalian brain. The genetic mechanisms that regulate the specification and maintenance of tanycyte identity are unknown, but are critical for understanding how these cells can act as adult neural progenitor cells. We observe that LIM (Lin-11, Isl-1, Mec-3)- homeodomain gene Lhx2 is selectively expressed in hypothalamic progenitor cells and tanycytes. To test the function of Lhx2 in tanycyte development, we used an intersectional genetic strategy to conditionally delete Lhx2 in posteroventral hypothalamic neuroepithelium, both embryonically and postnatally. We observed that tanycyte development was severely disrupted when Lhx2 function was ablated during embryonic development. Lhx2-deficient tanycytes lost expression of tanycyte-specific genes, such as Rax, while also displaying ectopic expression of genes specific to cuboid ependymal cells, such as Rarres2. Ultrastructural analysis revealed that mutant tanycytes exhibited a hybrid identity, retaining radial morphology while becoming multiciliated. In contrast, postnatal loss of function of Lhx2 resulted only in loss of expression of tanycyte-specific genes. Using chromatin immunoprecipitation, we further showed that Lhx2 directly regulated expression of Rax, an essential homeodomain factor for tanycyte development. This study identifies Lhx2 as a key intrinsic regulator of tanycyte differentiation, sustaining Rax-dependent activation of tanycyte-specific genes while also inhibiting expression of ependymal cell-specific genes. These findings provide key insights into the transcriptional regulatory network specifying this still poorly characterized cell type. [ABSTRACT FROM AUTHOR]

Published

2014

107. Peroxiredoxin VI oxidation in cerebrospinal fluid correlates with traumatic brain injury outcome.

Author

Manevich, Y., Hutchens, S., Halushka, P.V., Tew, K.D., Townsend, D.M., Jauch, E.C., and Borg, K.

Subjects

*BRAIN injury treatment, *BRAIN injuries, *PATIENTS, *CEREBROSPINAL fluid, *PEROXIREDOXINS, *HEALTH outcome assessment, *BIOMARKERS, *DISEASE progression, *HOSPITAL admission & discharge

Abstract

Abstract: Traumatic brain injury (TBI) patients would benefit from the identification of reliable biomarkers to predict outcomes and treatment strategies. In our study, cerebrospinal fluid (CSF) from patients with severe TBI was evaluated for oxidant stress-mediated damage progression after hospital admission and subsequent ventriculostomy placement. Interestingly, substantial levels of peroxiredoxin VI (Prdx6), a major antioxidant enzyme normally found in astrocytes, were detected in CSF from control and TBI patients and were not associated with blood contamination. Functionally, Prdx6 and its associated binding partner glutathione S-transferase Pi (GSTP1-1, also detected in CSF) act in tandem to detoxify lipid peroxidation damage to membranes. We found Prdx6 was fully active in CSF of control patients but becomes significantly inactivated (oxidized) in TBI. Furthermore, significant and progressive oxidation of “buried” protein thiols in CSF of TBI patients (compared to those of nontrauma controls) was detected over a 24-h period after hospital admission, with increased oxidation correlating with severity of trauma. Conversely, recovery of Prdx6 activity after 24h indicated more favorable patient outcome. Not only is this the first report of an extracellular form of Prdx6 but also the first report of its detection at a substantial level in CSF. Taken together, our data suggest a meaningful correlation between TBI-initiated oxidation of Prdx6, its specific phospholipid hydroperoxide peroxidase activity, and severity of trauma outcome. Consequently, we propose that Prdx6 redox status detection has the potential to be a biomarker for TBI outcome and a future indicator of therapeutic efficacy. [Copyright &y& Elsevier]

Published

2014

108. Ventriculomegaly associated with ependymal gliosis and declines in barrier integrity in the aging human and mouse brain.

Author

Shook, Brett A., Lennington, Jessica B., Acabchuk, Rebecca L., Halling, Meredith, Sun, Ye, Peters, John, Wu, Qian, Mahajan, Amit, Fellows, Douglas W., and Conover, Joanne C.

Subjects

*AGING, *BRAIN, *NEURODEGENERATION, *MAGNETIC resonance imaging of the brain, *HISTOLOGY, *NEURAMINIDASE, *ADHERENS junctions, *LABORATORY mice

Abstract

Age-associated ventriculomegaly is typically attributed to neurodegeneration; however, additional factors might initiate or contribute to progressive ventricular expansion. By directly linking postmortem human MRI sequences with histological features of periventricular tissue, we show that substantial lateral ventricle surface gliosis is associated with ventriculomegaly. To examine whether loss of ependymal cell coverage resulting in ventricle surface glial scarring can lead directly to ventricle enlargement independent of any other injury or degenerative loss, we modeled in mice the glial scarring found along the lateral ventricle surface in aged humans. Neuraminidase, which cleaves glycosidic linkages of apical adherens junction proteins, was administered intracerebroventricularly to denude areas of ependymal cells. Substantial ependymal cell loss resulted in reactive gliosis rather than stem cell-mediated regenerative repair of the ventricle lining, and the gliotic regions showed morphologic and phenotypic characteristics similar to those found in aged humans. Increased levels of aquaporin-4, indicative of edema, observed in regions of periventricular gliosis in human tissue were also replicated in our mouse model. 3 D modeling together with volume measurements revealed that mice with ventricle surface scarring developed expanded ventricles, independent of neurodegeneration. Through a comprehensive, comparative analysis of the lateral ventricles and associated periventricular tissue in aged humans and mouse, followed by modeling of surface gliosis in mice, we have demonstrated a direct link between lateral ventricle surface gliosis and ventricle enlargement. These studies highlight the importance of maintaining an intact ependymal cell lining throughout aging. [ABSTRACT FROM AUTHOR]

Published

2014

109. The Lactate Receptor HCA

Author

Alena, Hadzic, Teresa D, Nguyen, Makoto, Hosoyamada, Naoko H, Tomioka, Linda H, Bergersen, Jon, Storm-Mathisen, and Cecilie, Morland

Subjects

lactate, choroid plexus, GPR81, HCA1, ependymal cells, Brain, tela choroidea, Fibroblasts, Article, Cerebral Ventricles, Receptors, G-Protein-Coupled, Mice, Inbred C57BL, Mice, fibroblasts, Choroid Plexus, Animals, Humans, HCAR1, Lactic Acid, dorsal third ventricle, Cerebrospinal Fluid, Third Ventricle

Abstract

The volume, composition, and movement of the cerebrospinal fluid (CSF) are important for brain physiology, pathology, and diagnostics. Nevertheless, few studies have focused on the main structure that produces CSF, the choroid plexus (CP). Due to the presence of monocarboxylate transporters (MCTs) in the CP, changes in blood and brain lactate levels are reflected in the CSF. A lactate receptor, the hydroxycarboxylic acid receptor 1 (HCA1), is present in the brain, but whether it is located in the CP or in other periventricular structures has not been studied. Here, we investigated the distribution of HCA1 in the cerebral ventricular system using monomeric red fluorescent protein (mRFP)-HCA1 reporter mice. The reporter signal was only detected in the dorsal part of the third ventricle, where strong mRFP-HCA1 labeling was present in cells of the CP, the tela choroidea, and the neuroepithelial ventricular lining. Co-labeling experiments identified these cells as fibroblasts (in the CP, the tela choroidea, and the ventricle lining) and ependymal cells (in the tela choroidea and the ventricle lining). Our data suggest that the HCA1-containing fibroblasts and ependymal cells have the ability to respond to alterations in CSF lactate in body–brain signaling, but also as a sign of neuropathology (e.g., stroke and Alzheimer’s disease biomarker).

Published

2020

110. DNGR-1-tracing marks an ependymal cell subset with damage-responsive neural stem cell potential.

Author

Frederico, Bruno, Martins, Isaura, Chapela, Diana, Gasparrini, Francesca, Chakravarty, Probir, Ackels, Tobias, Piot, Cécile, Almeida, Bruna, Carvalho, Joana, Ciccarelli, Alessandro, Peddie, Christopher J., Rogers, Neil, Briscoe, James, Guillemot, François, Schaefer, Andreas T., Saúde, Leonor, and Reis e Sousa, Caetano

Subjects

*CENTRAL nervous system, *NEURAL stem cells, *CENTRAL nervous system injuries, *CEREBROSPINAL fluid, *SPINAL cord, *EMBRYOLOGY

Abstract

Cells with latent stem ability can contribute to mammalian tissue regeneration after damage. Whether the central nervous system (CNS) harbors such cells remains controversial. Here, we report that DNGR-1 lineage tracing in mice identifies an ependymal cell subset, wherein resides latent regenerative potential. We demonstrate that DNGR-1-lineage-traced ependymal cells arise early in embryogenesis (E11.5) and subsequently spread across the lining of cerebrospinal fluid (CSF)-filled compartments to form a contiguous sheet from the brain to the end of the spinal cord. In the steady state, these DNGR-1-traced cells are quiescent, committed to their ependymal cell fate, and do not contribute to neuronal or glial lineages. However, trans-differentiation can be induced in adult mice by CNS injury or in vitro by culture with suitable factors. Our findings highlight previously unappreciated ependymal cell heterogeneity and identify across the entire CNS an ependymal cell subset wherein resides damage-responsive neural stem cell potential. [Display omitted] • DNGR-1 is expressed early in mouse embryogenesis in a subset of ventricular progenitors • DNGR-1 tracing shows that those progenitors give rise to a subset of ependymal cells • DNGR-1-traced ependymal cells have latent regenerative potential • DNGR-1-traced ependymal cells can be mobilized by local injury Frederico et al. show that embryonic DNGR-1 expression marks a population of ventricular progenitors committed to an ependymal cell subset yet endowed with damage-responsive neural stem cell potential in adulthood. Trans-differentiation can by induced in vitro with appropriate factors or in vivo after CNS injury. [ABSTRACT FROM AUTHOR]

Published

2022

111. The lactate receptor HCA1 is present in the choroid plexus, the tela choroidea, and the neuroepithelial lining of the dorsal part of the third ventricle

Author

Hadzic, Alena, Nguyen, Teresa D., Hosoyamada, Makoto, Tomioka, Naoko H., Bergersen, Linda H., Storm-Mathisen, Jon, Morland, Cecilie, Hadzic, Alena, Nguyen, Teresa D., Hosoyamada, Makoto, Tomioka, Naoko H., Bergersen, Linda H., Storm-Mathisen, Jon, and Morland, Cecilie

Abstract

The volume, composition, and movement of the cerebrospinal fluid (CSF) are important for brain physiology, pathology, and diagnostics. Nevertheless, few studies have focused on the main structure that produces CSF, the choroid plexus (CP). Due to the presence of monocarboxylate transporters (MCTs) in the CP, changes in blood and brain lactate levels are reflected in the CSF. A lactate receptor, the hydroxycarboxylic acid receptor 1 (HCA1), is present in the brain, but whether it is located in the CP or in other periventricular structures has not been studied. Here, we investigated the distribution of HCA1 in the cerebral ventricular system using monomeric red fluorescent protein (mRFP)-HCA1 reporter mice. The reporter signal was only detected in the dorsal part of the third ventricle, where strong mRFP-HCA1 labeling was present in cells of the CP, the tela choroidea, and the neuroepithelial ventricular lining. Co-labeling experiments identified these cells as fibroblasts (in the CP, the tela choroidea, and the ventricle lining) and ependymal cells (in the tela choroidea and the ventricle lining). Our data suggest that the HCA1-containing fibroblasts and ependymal cells have the ability to respond to alterations in CSF lactate in body–brain signaling, but also as a sign of neuropathology (e.g., stroke and Alzheimer’s disease biomarker).

Published

2020

112. Cell fate control in the developing central nervous system.

Author

Guérout, Nicolas, Li, Xiaofei, and Barnabé-Heider, Fanie

Subjects

*CELL determination, *CENTRAL nervous system physiology, *PROGENITOR cells, *CELL proliferation, *OLIGODENDROGLIA, *NEUROLOGICAL disorders

Abstract

Abstract: The principal neural cell types forming the mature central nervous system (CNS) are now understood to be diverse. This cellular subtype diversity originates to a large extent from the specification of the earlier proliferating progenitor populations during development. Here, we review the processes governing the differentiation of a common neuroepithelial cell progenitor pool into mature neurons, astrocytes, oligodendrocytes, ependymal cells and adult stem cells. We focus on studies performed in mice and involving two distinct CNS structures: the spinal cord and the cerebral cortex. Understanding the origin, specification and developmental regulators of neural cells will ultimately impact comprehension and treatments of neurological disorders and diseases. [Copyright &y& Elsevier]

Published

2014

113. Analysis of brain nuclei accessible to ghrelin present in the cerebrospinal fluid.

Author

Cabral, A., Fernandez, G., and Perello, M.

Subjects

*CEREBROSPINAL fluid, *CELL nuclei, *GHRELIN receptors, *LOCUS coeruleus, *BRAIN anatomy, *PEPTIDE hormones, *GENE expression

Abstract

Highlights: [•] Cerebrospinal fluid ghrelin reaches most brain areas expressing ghrelin receptors. [•] Ependymal cells are able to uptake ghrelin present in the cerebrospinal fluid. [•] Ghrelin uptake in ependymal cells occurs in a ghrelin receptor-independent manner. [ABSTRACT FROM AUTHOR]

Published

2013

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

Author

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

Subjects

*URIC acid, *CARRIER proteins, *LABORATORY mice, *CARDIOVASCULAR diseases risk factors, *BRAIN physiology, *CEREBROSPINAL fluid

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. [ABSTRACT FROM AUTHOR]

Published

2013

115. FoxJ1-expressing cells contribute to neurogenesis in forebrain of adult rats: Evidence from in vivo electroporation combined with piggyBac transposon.

Author

Devaraju, Karthikeyan, Barnabé-Heider, Fanie, Kokaia, Zaal, and Lindvall, Olle

Subjects

*DEVELOPMENTAL neurobiology, *ELECTROPORATION, *TRANSPOSONS, *GENE expression, *ASTROCYTES, *STROKE, *LABORATORY rats

Abstract

Abstract: Ependymal cells in the lateral ventricular wall are considered to be post-mitotic but can give rise to neuroblasts and astrocytes after stroke in adult mice due to insult-induced suppression of Notch signaling. The transcription factor FoxJ1, which has been used to characterize mouse ependymal cells, is also expressed by a subset of astrocytes. Cells expressing FoxJ1, which drives the expression of motile cilia, contribute to early postnatal neurogenesis in mouse olfactory bulb. The distribution and progeny of FoxJ1-expressing cells in rat forebrain are unknown. Here we show using immunohistochemistry that the overall majority of FoxJ1-expressing cells in the lateral ventricular wall of adult rats are ependymal cells with a minor population being astrocytes. To allow for long-term fate mapping of FoxJ1-derived cells, we used the piggyBac system for in vivo gene transfer with electroporation. Using this method, we found that FoxJ1-expressing cells, presumably the astrocytes, give rise to neuroblasts and mature neurons in the olfactory bulb both in intact and stroke-damaged brain of adult rats. No significant contribution of FoxJ1-derived cells to stroke-induced striatal neurogenesis was detected. These data indicate that in the adult rat brain, FoxJ1-expressing cells contribute to the formation of new neurons in the olfactory bulb but are not involved in the cellular repair after stroke. [Copyright &y& Elsevier]

Published

2013

116. SVCT2 vitamin C transporter expression in progenitor cells of the postnatal neurogenic niche.

Author

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

Subjects

VITAMIN C, PROGENITOR cells, STEM cells, CELL proliferation, CELL differentiation, SODIUM cotransport systems, NEURAL cell adhesion molecule

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. [ABSTRACT FROM AUTHOR]

Published

2013

117. Ependymal cells and neurodegenerative disease: outcomes of compromised ependymal barrier function.

Author

Nelles DG and Hazrati LN

Abstract

Within the central nervous system, ependymal cells form critical components of the blood-cerebrospinal fluid barrier and the cerebrospinal fluid-brain barrier. These barriers provide biochemical, immunological and physical protection against the entry of molecules and foreign substances into the cerebrospinal fluid while also regulating cerebrospinal fluid dynamics, such as the composition, flow and removal of waste from the cerebrospinal fluid. Previous research has demonstrated that several neurodegenerative diseases, such as Alzheimer's disease and multiple sclerosis, display irregularities in ependymal cell function, morphology, gene expression and metabolism. Despite playing key roles in maintaining overall brain health, ependymal barriers are largely overlooked and understudied in the context of disease, thus limiting the development of novel diagnostic and treatment options. Therefore, this review explores the anatomical properties, functions and structures that define ependymal cells in the healthy brain, as well as the ways in which ependymal cell dysregulation manifests across several neurodegenerative diseases. Specifically, we will address potential mechanisms, causes and consequences of ependymal cell dysfunction and describe how compromising the integrity of ependymal barriers may initiate, contribute to, or drive widespread neurodegeneration in the brain., (© The Author(s) 2022. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2022

118. Recent advances in understanding cell type transitions during dorsal neural tube development.

Author

Kalcheim C and Rekler D

Abstract

The vertebrate neural tube is a representative example of a morphogen-patterned tissue that generates different cell types with spatial and temporal precision. More specifically, the development of the dorsal region of the neural tube is of particular interest because of its highly dynamic behavior. First, early premigratory neural crest progenitors undergo an epithelial-to-mesenchymal transition, exit the neural primordium, and generate, among many derivatives, most of the peripheral nervous system. Subsequently, the dorsal neural tube becomes populated by definitive roof plate cells that constitute an organizing center for dorsal interneurons and guide axonal patterning. In turn, roof plate cells transform into dorsal radial glia that contributes to and shapes the formation of the dorsal ependyma of the central nervous system. To form a normal functional spinal cord, these extraordinary transitions should be tightly regulated in time and space. Thus far, the underlying cellular changes and molecular mechanisms are only beginning to be uncovered. In this review, we discuss recent results that shed light on the end of neural crest production and delamination, the early formation of the definitive roof plate, and its further maturation into radial glia. The last of these processes culminate in the formation of the dorsal ependyma, a component of the stem cell niche of the central nervous system. We highlight how similar mechanisms operate throughout these transitions, which may serve to reveal common design principles applicable to the ontogeny of epithelial tissues., Competing Interests: The authors declare that they have no competing interests.No competing interests were disclosed.No competing interests were disclosed.No competing interests were disclosed., (Copyright: © 2022 Kalcheim C et al.)

Published

2022

119. A simple method to obtain pure cultures of multiciliated ependymal cells from adult rodents.

Author

Grondona, J., Granados-Durán, P., Fernández-Llebrez, P., and López-Ávalos, M.

Subjects

*EPITHELIUM, *CELL culture, *BRAIN physiology, *IMMUNOGLOBULINS, *FLOW cytometry, *NEUROGLIA, *LABORATORY rodents

Abstract

Ependymal cells form an epithelium lining the ventricular cavities of the vertebrate brain. Numerous methods to obtain primary culture ependymal cells have been developed. Most of them use foetal or neonatal rat brain and the few that utilize adult brain hardly achieve purity. Here, we describe a simple and novel method to obtain a pure non-adherent ependymal cell culture from explants of the striatal and septal walls of the lateral ventricles. The combination of a low incubation temperature followed by a gentle enzymatic digestion allows the detachment of most of the ependymal cells from the ventricular wall in a period of 6 h. Along with ependymal cells, a low percentage (less than 6 %) of non-ependymal cells also detaches. However, they do not survive under two restrictive culture conditions: (1) a simple medium (alpha-MEM with glucose) without any supplement; and (2) a low density of 1 cell/µl. This purification method strategy does not require cell labelling with antibodies and cell sorting, which makes it a simpler and cheaper procedure than other methods previously described. After a period of 48 h, only ependymal cells survive such conditions, revealing the remarkable survival capacity of ependymal cells. Ependymal cells can be maintained in culture for up to 7-10 days, with the best survival rates obtained in Neurobasal supplemented with B27 among the tested media. After 7 days in culture, ependymal cells lose most of the cilia and therefore the mobility, while acquiring radial glial cell markers (GFAP, BLBP, GLAST). This interesting fact might indicate a reprogramming of the cell identity. [ABSTRACT FROM AUTHOR]

Published

2013

120. Ectopic ependymal cells in striatum accompany neurogenesis in a rat model of stroke

Author

Danilov, A.I., Kokaia, Z., and Lindvall, O.

Subjects

*ECTOPIC tissue, *EPENDYMA, *DEVELOPMENTAL neurobiology, *LABORATORY rats, *STROKE, *NEURAL stem cells

Abstract

Abstract: Stroke-induced neurogenesis originates from a neural stem cell (NSC) niche in subventricular zone (SVZ). In mice, NSCs are concentrated in a so-called “neurogenic spot” in the lateral angle area of SVZ. We aimed to identify the “neurogenic spot” in the rat SVZ and to characterize the cellular changes in the ependymal cell compartment in this area at different time points after middle cerebral artery occlusion. The majority of ependymal cells outlining the ventricular wall did not proliferate, and their numbers in the “neurogenic spot” declined at 6 and 16weeks after stroke. Cells with the ultrastructural properties of ependymal cells were detected in the adjacent striatum. The number of these ectopic ependymal cells (EE cells) correlated positively with the magnitude of lateral ventricular enlargement and negatively with the ependymal cell number in the “neurogenic spot”. EE cells were found along blood vessels, accumulated in the pericyst regions, and participated in scar formation but did not incorporate BrdU. We provide the first evidence for the occurrence of EE cells in the ischemic striatum following stroke. [Copyright &y& Elsevier]

Published

2012

121. Constitutive expression of ciliary neurotrophic factor in mouse hypothalamus.

Author

Severi, Ilenia, Carradori, Maria Rita, Lorenzi, Teresa, Amici, Adolfo, Cinti, Saverio, and Giordano, Antonio

Subjects

*CILIARY neurotrophic factor, *ASTROCYTES, *LABORATORY mice, *CONFOCAL microscopy, *CYTOKINES, *IMMUNOHISTOCHEMISTRY

Abstract

Ciliary neurotrophic factor (CNTF) is a potent survival molecule for a large number of neuronal and glial cells in culture; its expression in glial cells is strongly upregulated after a variety of nerve tissue injuries. Exogenously administered CNTF produces an anorectic effect via activation of hypothalamic neurons and stimulates neurogenesis in mouse hypothalamus. To determine whether CNTF is produced endogenously in the hypothalamus, we sought cellular sources and examined their distribution in adult mouse hypothalamus by immunohistochemistry. CNTF immunoreactivity (IR) was predominantly detected in the ependymal layer throughout the rostrocaudal extension of the third ventricle, where numerous ependymocytes and tanycytes exhibited specific staining. Some astrocytes in the grey matter of the anterior hypothalamus and in the median eminence of the hypothalamic tuberal region were also positive. Stimulation of cells bearing CNTF receptor α (CNTFRα) induces specific activation of the signal transducer and activator of transcription 3 (STAT3) signalling system. Treatment with recombinant CNTF and detection of the nuclear expression of phospho-STAT3 (P-STAT3) showed that CNTF-producing ependymal cells and tanycytes were intermingled with, or very close to, P-STAT3-positive, CNTFRα-bearing cells. A fraction of CNTF-producing ependymal cells and tanycytes and some median eminence astrocytes also exhibited P-STAT3 IR. Thus, in normal adult mice the ependyma of the third ventricle is both a source of and a target for CNTF, which may play hitherto unknown roles in hypothalamic function in physiological conditions. [ABSTRACT FROM AUTHOR]

Published

2012

122. Gap junction-mediated calcium waves define communication networks among murine postnatal neural progenitor cells.

Author

Lacar, Benjamin, Young, Stephanie Z., Platel, Jean‐Claude, and Bordey, Angélique

Subjects

*POSTNATAL care, *NEUROGENETICS, *ASTROCYTES, *ELECTROPORATION, *BLOOD vessels, *CONNEXINS, *MOLECULAR structure

Abstract

In the postnatal neurogenic niche, two populations of astrocyte-like cells (B cells) persist, one acting as neural progenitor cells (NPCs, B1 cells) and one forming a structural boundary between the neurogenic niche and the striatum (B2 cells, niche astrocytes). Despite being viewed as two distinct entities, we found that B1 and B2 cells express the gap junction protein connexin 43 and display functional coupling involving 50-60 cells. Using neonatal electroporation to label slowly cycling radial glia-derived B1 cells, which send a basal process onto blood vessels, we further confirmed dye coupling between NPCs. To assess the functionality of the coupling, we used calcium imaging in a preparation preserving the three-dimensional architecture of the subventricular zone. Intercellular calcium waves were observed among B cells. These waves travelled bidirectionally between B1 and B2 cells and propagated on blood vessels. Inter-B-cell calcium waves were absent in the presence of a gap junction blocker but persisted with purinergic receptor blockers. These findings show that privileged microdomains of communication networks exist among NPCs and niche astrocytes. Such functional coupling between these two cell types suggests that niche astrocytes do not merely have a structural role, but may play an active role in shaping the behavior of NPCs. [ABSTRACT FROM AUTHOR]

Published

2011

123. Six3 is required for ependymal cell maturation.

Author

Lavado, Alfonso and Oliver, Guillermo

Subjects

*CELL migration, *NEUROGLIA, *GENE expression, *DEVELOPMENTAL neurobiology, *EPENDYMA

Abstract

Ependymal cells are part of the neurogenic niche in the adult subventricular zone of the lateral ventricles, where they regulate neurogenesis and neuroblast migration. Ependymal cells are generated from radial glia cells during embryonic brain development and acquire their final characteristics postnatally. The homeobox gene Six3 is expressed in ependymal cells during the formation of the lateral wall of the lateral ventricles in the brain. Here, we show that Six3 is necessary for ependymal cell maturation during postnatal stages of brain development. In its absence, ependymal cells fail to suppress radial glia characteristics, resulting in a defective lateral wall, abnormal neuroblast migration and differentiation, and hydrocephaly. [ABSTRACT FROM AUTHOR]

Published

2011

124. Early fetal development of the human cerebellum.

Author

Kwang Ho Cho, Rodríguez-Vázquez, Jose Francisco, Ji Hyun Kim, Abe, Hiroshi, Murakami, Gen, and Hwan Cho, Baik

Subjects

*FETAL development, *HISTOLOGY, *HUMAN embryo physiology, *MESENCEPHALON, CEREBELLUM anatomy

Abstract

Early cerebellum development in humans is poorly understood. The present study histologically examined sections from 20 human embryos and fetuses at 6 weeks (12-16 mm crown-rump length (CRL); 4 specimens), 7-9 weeks (21-39 mm CRL; 8 specimens), 11-12 weeks (70-90 mm CRL; 4 specimens) and 15-16 weeks (110-130 mm CRL; 4 specimens). During 7-9 weeks (approximate CRL 28 mm), the rhombic lip (a pair of thickenings of the alar plate) protruded dorsally, bent laterally, extended ventrolaterally and fused with the medially located midbrain. During that process, the primitive choroid plexus appeared to become involved in the cerebellar hemisphere to form a centrally located eosinophilic matrix. At that stage, the inferior olive had already developed in the thick medulla. Thus, the term 'bulbo-pontine extension' may represent an erroneous labeling of a caudal part of the rhombic lip. The cerebellar vermis developed much later than the hemisphere possibly from a midline dark cell cluster near the aqueduct. In the midline area after 12 weeks (80 mm CRL), the growing bilateral hemispheres seem to provide mechanical stress such as rotation and shear that cause the development of several fissures much deeper than those on the hemisphere. The rapidly growing surface germinal layer may be a minor contributor to this vermian fissure formation. The vermian fissures seem to enable inside involvement of the surface germinal cells, and to induce cytodifferentiation of the vermis. Consequently, in the early stages, it appears that the cerebellar hemisphere and vermis develop independently of each other. [ABSTRACT FROM AUTHOR]

Published

2011

125. Hypoxia upregulates the expression of the O-linked N-acetylglucosamine containing epitope H in human ependymal cells

Author

Arvanitis, Leonidas D., Vassiou, Katerina, Kotrotsios, Anastasios, and Sgantzos, Markos N.

Subjects

*HYPOXEMIA, *GLUCOSAMINE, *GENE expression, *EPITOPES, *EPENDYMA, *MONOCLONAL antibodies, *LABORATORY mice, *ASTROCYTES

Abstract

Abstract: Epitope H contains an O-linked N-acetylglucosamine (O-GlcNAc) residue in a specific conformation and/or environment recognized by mouse IgM monoclonal antibody H (mabH). Epitope H is present in several types of cells and in several polypeptides outside the CNS. Previous results have shown that in the adult human brains, epitope H is confined mostly to a minority of fibrous astrocytes, and it is greatly upregulated in the reactive astrocytes. Post-translational modification with O-GlcNAc occurs on many proteins involved in several cell processes, such as cell cycle progression, apoptosis, proteasome degradation pathways, and modulation of cellular function in response to nutrition and stress. Hypoxia is one of the major causes of cellular stress. Therefore, in this study, we used the mAbH and the indirect immunoperoxidase method to investigate the expression of epitope H in ependymal cells in brains of persons who died with signs of hypoxic encephalopathy. The results of the present study showed that practically all ependymal cells showed cytoplasmic staining for epitope H in supranuclear cytoplasm in the brain of two premature neonates and in ten infants who died with signs of hypoxic encephalopathy. However, the overwhelming majority of ependymal cells of the nine human embryos taken from legal abortions, ranging from 26 days until 13 weeks of gestational age, and of the ten infants’ brains without any sign of hypoxic encephalopathy remained negative. Only occasionally did the ependymal cells show weak cytoplasmic staining in some foci. In addition, the reactive astrocytes in the hypoxic brains showed strong cytoplasmic staining, confirming previous results. [Copyright &y& Elsevier]

Published

2011

126. Proliferation, migration and differentiation of ependymal region neural progenitor cells in the brainstem after hypoglossal nerve avulsion.

Author

Fagerlund, Michael, Jaff, Nasren, Danilov, Alexandre I., Peredo, Inti, Brundin, Lou, and Svensson, Mikael

Subjects

*CELL proliferation, *CELL migration, *CELL differentiation, *EPENDYMA, *NEURONS, *BRAIN stem, *HYPOGLOSSAL nerve, *AVULSION fractures

Abstract

Purpose: Cells in the ependymal region in the adult central nervous system (CNS) have been found to possess neural progenitor cell (NPC) like features including capacity for generating new neurons and glia in response to injury and inflammatory disease. Whether these cells are activated after a peripheral nerve injury has not previously been extensively evaluated. Methods: We investigate the possible activation and effect of NPCs in the ependymal region in the immediate vicinity to the hypoglossal nucleus in the brainstem using two models of injuries, hypoglossal nerve transection and nerve avulsion after which the proliferation, migration and differentiation of ependymal regional NPCs were evaluated. Results: We showed that: (i) immunoreactivity for Sox2 was detected in cells in the ependymal region of the brainstem and that BrdU/Sox2-positive cells were observed after avulsion, but not after transection injury; (ii) avulsion induces re-expression of nestin in the ependymal layer as well as induced NPC migration from the ependymal layer; (iii) the chemokine SDF-1α (a marker for migrating cells) was upregulated ipsilateral to the nerve injury; (iiii) the NPCs migrating differentiated only into GFAP-positive astrocytes in the hypoglossal nucleus. Conclusion: These results suggest that nerve avulsion injury induces in parallel with the retrograde "axon reaction" activation of endogenous NPCs in the ependymal region and further suggest that these cells could be involved in repair and neuroregeneration after injury within the brainstem. [ABSTRACT FROM AUTHOR]

Published

2011

127. Distribution of EFHC1 or Myoclonin 1 in mouse neural structures

Author

Léon, Christine, de Nijs, Laurence, Chanas, Grazyna, Delgado-Escueta, Antonio V., Grisar, Thierry, and Lakaye, Bernard

Subjects

*ANIMAL models in epilepsy research, *LABORATORY mice, *NEURAL stem cells, *GENE expression, *IMMUNOGLOBULIN G, *NEURAL development, *GENETIC mutation, *MESSENGER RNA

Abstract

Summary: EFHC1, a gene mutated in juvenile myoclonic epilepsy, encodes EFHC1, a protein with three DM10 domains and one EF-hand motif. We recently demonstrated that this molecule is a microtubule-associated protein (MAP) implicated in neuronal migration. Because some controversies persist about the precise localization in the CNS, we studied the neuroanatomical distribution of EFHC1 in mature and developing mouse brain. In the adult, low mRNA expression was detected in several brain structures such as cortex, striatum, hippocampus and cerebellum. At E16, EFHC1 mRNA was shown to be expressed in cortex and not only in cells lining ventricles. Using a purified polyclonal antibody, EFHC1 staining was observed in all cortical layers, in piriform cortex, in hippocampus and in Purkinje cells of cerebellum. In the cortex, the majority of EFHC1 positive cells correspond to neurons, however some glial cells were also stained. In agreement with a previous study, we demonstrated strong EFHC1 expression in cilia of ependymal cells lining cerebral ventricles. Moreover, at E16, the protein was observed at the borders of brain ventricles, in choroid plexus, but also, although to a lesser extent, in piriform and neocortex. In these latter structures, the pattern of expression seems to correspond to the extensions of the radial glia fibers as demonstrated by BLBP immunostaining. Finally, we confirmed that EFHC1 was also expressed and co-localized with the mitotic spindle of neural stem cells. These results confirm that EFHC1 is a protein with a likely low expression level in mouse brain but detectable both in adult and embryonic brain supporting our previous data and hypothesis that EFHC1 could play an important role during brain development. As discussed, this opens the door to a new conceptual approach viewing some idiopathic generalized epilepsies as developmental diseases instead of classical channelopathies. [Copyright &y& Elsevier]

Published

2010

128. FoxJ1-dependent gene expression is required for differentiation of radial glia into ependymal cells and a subset of astrocytes in the postnatal brain.

Author

Jacquet, Benoit V., Salinas-Mondragon, Raul, Huixuan Liang, Therit, Blair, Buie, Justin D., Dykstra, Michael, Campbell, Kenneth, Ostrowski, Lawrence E., Brody, Steven L., and Ghashghaei, H. Troy

Subjects

*GENE expression, *CELL differentiation, *ASTROCYTES, *NEUROGLIA, *TRANSCRIPTION factors, *NEURAL stem cells

Abstract

Neuronal specification occurs at the periventricular surface of the embryonic central nervous system. During early postnatal periods, radial glial cells in various ventricular zones of the brain differentiate into ependymal cells and astrocytes. However, mechanisms that drive this time- and cell-specific differentiation remain largely unknown. Here, we show that expression of the forkhead transcription factor FoxJ1 in mice is required for differentiation into ependymal cells and a small subset of FoxJ1+ astrocytes in the lateral ventricles, where these cells form a postnatal neural stem cell niche. Moreover, we show that a subset of FoxJ1+ cells harvested from the stem cell niche can self-renew and possess neurogenic potential. Using a transcriptome comparison of FoxJ1-null and wild-type microdissected tissue, we identified candidate genes regulated by FoxJ1 during early postnatal development. The list includes a significant number of microtubule-associated proteins, some of which form a protein complex that could regulate the transport of basal bodies to the ventricular surface of differentiating ependymal cells during FoxJ1-dependent ciliogenesis. Our results suggest that time- and cell-specific expression of FoxJ1 in the brain acts on an array of target genes to regulate the differentiation of ependymal cells and a small subset of astrocytes in the adult stem cell niche. [ABSTRACT FROM AUTHOR]

Published

2009

129. The ependymal route for insulin-like growth factor-1 gene therapy in the brain

Author

Hereñú, C.B., Sonntag, W.E., Morel, G.R., Portiansky, E.L., and Goya, R.G.

Subjects

*SOMATOMEDIN, *BRAIN diseases, *EPENDYMA, *DRUG administration, *CYTOMEGALOVIRUS diseases, *NEUROPHARMACOLOGY, *ANIMAL disease models, *CEREBROSPINAL fluid, *IMMUNOFLUORESCENCE, *LABORATORY mice, *GENE therapy

Abstract

Abstract: I.c.v. administration of the peptide insulin-like growth factor-1 (IGF-1) has been shown to be an effective neuroprotective strategy in the brain of different animal models, a major advantage being the achievement of high concentrations of IGF-1 in the brain without altering serum levels of the peptide. In order to exploit this therapeutic approach further, we used high performance recombinant adenoviral (RAd) vectors expressing their transgene under the control of the potent mouse cytomegalovirus immediate early (mCMV) promoter, to transduce brain ependymal cells with high efficiency and to achieve effective release of transgenic IGF-1 into the cerebrospinal fluid (CSF). We constructed RAd vectors expressing either a chimeric green fluorescent protein fused to HSV-1 thymidine kinase (TK/GFP)fus, or the cDNA encoding rat IGF-1, both driven by the mCMV promoter. The vectors were injected into the lateral ventricles of young rats and chimeric GFP expression in brain sections was assessed by fluorescence microscopy. The ependymal cell marker vimentin was detected by immunofluorescence and nuclei were labeled with the DNA dye 4′,6-diamidino-2-phenylindole. Blood and CSF samples were drawn at different times post–vector injection. In all cerebral ventricles, vimentin immunoreactive cells of the ependyma were predominantly transduced by RAd-(TK/GFP)fus, showing nuclear and cytoplasmic expression of the transgene. For tanycytes (TK/GFP)fus expression was evident in their cytoplasmic processes as they penetrated deep into the hypothalamic parenchyma. I.c.v. injection of RAd-IGF-1 induced high levels of IGF-1 in the CSF but not in serum. We conclude that the ependymal route constitutes an effective approach for implementing experimental IGF-1 gene therapy in the brain. [Copyright &y& Elsevier]

Published

2009

130. Aquaporin-4 maintains ependymal integrity in adult mice

Author

Li, X., Kong, H., Wu, W., Xiao, M., Sun, X., and Hu, G.

Subjects

*AQUAPORINS, *CEREBROSPINAL fluid, *AMINO acid metabolism, *GAP junctions (Cell biology), *GENE expression, *TRANSGENIC mice, *IMMUNOHISTOCHEMISTRY

Abstract

Abstract: Ependymal cells form the walls of the ventricles, and take part in the production of cerebrospinal fluid (CSF). Aquaporin-4 (AQP4), a predominant water channel of the brain, is restricted to basolateral plasma membranes of ependymal cells. The highly polarized expression of AQP4 suggests it may be involved in maintaining the structural and functional integrity of the ependyma. This hypothesis was validated by using adult AQP4 knockout mice generated by our laboratory [Fan Y, Zhang J, Sun XL, Gao L, Zeng XN, Ding JH, Cao C, Niu L, Hu G (2005) Sex- and region-specific alterations of basal amino acid and monoamine metabolism in the brain of aquaporin-4 knockout mice. J Neurosci Res 82:458–464]. Histological analysis showed disorganized ependymal layer of the lateral ventricle and aqueduct in AQP4-deficiency mice. A majority (92.7%) of null mice displayed reduced lateral ventricular volume, while a small fraction (7.3%) had enlarged or normal ventricular size with a narrow aqueduct. Immunohistochemistry demonstrated that AQP4 deletion resulted in decreased expression of gap junction protein connexin43 in the ependymal cells. Electron microscopy confirmed junctional complex absence at basolateral membranes of ependymocytes. Moreover, AQP4 knockout mice showed decreased CSF production and increased brain water content compared with wild-type mice. These results highlight a key role of AQP4 in maintaining the structure and function of the ependyma. In addition, variable profiles of ventricle system in adult AQP4 null mice indicate functional AQP4 polymorphisms. [Copyright &y& Elsevier]

Published

2009

131. Strain differences of cerebral ventricles in mice: Can the MRL/MpJ mouse be a model for hydrocephalus?

Author

Hino, Keisuke, Otsuka, Saori, Ichii, Osamu, Hashimoto, Yoshiharu, and Kon, Yasuhiro

Abstract

The article presents a study on the differences of cerebral ventricles of mice strains to determine the possibility of a new hydrocephalic model mouse. Strains from five inbred mice, including MRL/MpJ, BALB/c, and DBA/2, were investigated by histological techniques that examines strain volume and surface area of lateral ventricles. The study notes that MRL/MpJ mouse has greater volume of cerebral ventricles compared to other strains, suggesting it as a potential model for hydrocephalus.

Published

2009

132. Identification of a discrete subpopulation of spinal cord ependymal cells with neural stem cell properties.

Author

Stenudd, Moa, Sabelström, Hanna, Llorens-Bobadilla, Enric, Zamboni, Margherita, Blom, Hans, Brismar, Hjalmar, Zhang, Shupei, Basak, Onur, Clevers, Hans, Göritz, Christian, Barnabé-Heider, Fanie, and Frisén, Jonas

Abstract

Spinal cord ependymal cells display neural stem cell properties in vitro and generate scar-forming astrocytes and remyelinating oligodendrocytes after injury. We report that ependymal cells are functionally heterogeneous and identify a small subpopulation (8% of ependymal cells and 0.1% of all cells in a spinal cord segment), which we denote ependymal A (EpA) cells, that accounts for the in vitro stem cell potential in the adult spinal cord. After spinal cord injury, EpA cells undergo self-renewing cell division as they give rise to differentiated progeny. Single-cell transcriptome analysis revealed a loss of ependymal cell gene expression programs as EpA cells gained signaling entropy and dedifferentiated to a stem-cell-like transcriptional state after an injury. We conclude that EpA cells are highly differentiated cells that can revert to a stem cell state and constitute a therapeutic target for spinal cord repair. [Display omitted] • Troy expression defines a subpopulation of spinal cord ependymal (EpA) cells • EpA cells harbor the in vitro stem cell capacity of the adult spinal cord • EpA cells dedifferentiate and acquire stem cell properties after spinal cord injury • EpA cells self-renew while generating astrocytes and oligodendrocytes after injury Stenudd et al. identify a subpopulation of ependymal cells defined by Troy expression, EpA cells, that contains the in vitro stem cell capacity of the spinal cord. These cells dedifferentiate to self-renewing stem cells after spinal cord injury and generate scar-forming astrocytes as well as oligodendrocytes. [ABSTRACT FROM AUTHOR]

Published

2022

133. X-Ray Exposure Induces Apoptosis of Some Proliferative Epidermal Cells Following Traumatic Spinal Cord Injury in Adult Rats.

Author

Wang, Xu, Sun, Zhengyi, Wang, Jing, Nan, Guoxin, Ma, Yanchao, Wang, Shuanke, Xia, Yayi, and Zhang, Youcheng

Subjects

*LANGERHANS cells, *APOPTOSIS, *CELL death, *SPINAL cord injuries, *CELL proliferation, *CELL growth

Abstract

We investigated whether X-ray radiation induced apoptosis of the proliferative ependymal cells (ECs) in adult rats with spinal cord injury (SCI) and the effect of X-ray radiation on the proliferative activities of ECs. A rat model with SCI was developed and used to determine the proliferation and apoptosis of ECs in the spinal cords after X-ray exposure. TUNEL assay and BrdU incorporation were used to detect apoptosis and proliferation respectively. We found that there were few TUNEL-positive cells in proliferative ependymal zone (EZ) after SCI except at the epicenter, and approximately half of the irradiated ECs became TUNEL-positive. However, these radiated ECs did not lose their proliferative activity until 1 week later and started to decrease rapidly after 1 week. The observation suggested that only part of ECs were sensitive to radiation and the nonsensitive cells continued their mitosis process. These findings indicated that X-ray exposure of the rats with SCI in early stage induced apoptosis of the proliferative ECs and partially inhibited their proliferative activities. [ABSTRACT FROM AUTHOR]

Published

2009

134. Cells of adult brain germinal zone have properties akin to hair cells and can be used to replace inner ear sensory cells after damage.

Author

Dongguang Wei, Levic, Snezana, Liping Nie, Wei-qiang Gao, Petit, Christine, Jones, Edward G., and Yamoah, Ebenezer N.

Subjects

*HAIR cells, *INNER ear, *BRAIN, *HEARING disorders, *NEURODEGENERATION

Abstract

Auditory hair cell defect is a major cause of hearing impairment, often leading to spiral ganglia neuron (SGN) degeneration. The cell loss that follows is irreversible in mammals, because inner ear hair cells (HCs) have a. limited capacity to regenerate. Here, we report that in the adult brain of both rodents and humans, the ependymal layer of the lateral ventricle contains cells with proliferative potential, which share morphological and functional characteristics with HCs. In addition, putative neural stem cells (NSCs) from the subventricular zone of the lateral ventricle can differentiate into functional SGNs. Also important, the NSCs can incorporate into the sensory epithelia, demonstrating their therapeutic potential. We assert that NSCs and edendymal cells can undergo an epigenetic functional switch to assume functional characteristics of HCs and SGNs. This study suggests that the functional plasticity of renewable cells and conditions that promote functional reprogramming can be used for cell therapy in the auditory setting. [ABSTRACT FROM AUTHOR]

Published

2008

135. Ultrastructural evidence that ependymal cells are infected in experimental scrapie.

Author

Fournier, Jean-Guy, Adjou, Karim, Grigoriev, Vladimir, and Deslys, Jean-Philippe

Subjects

*SCRAPIE, *PRION diseases in animals, *CELL membranes, *NEUROLOGICAL disorders, *PUBLIC health research

Abstract

During the last stage of infection in the experimental scrapie-infected hamster model, light microscopy reveals typical immunostaining of PrPsc in the subependymal region and at the apical ependymal cell borders. Whereas the subependymal immuno-staining is known to originate from extracellular amyloid filaments and residual membranes of astrocytes as constituents of plaque-like structures, the ultrastructural correlate of the supraependymal PrPsc staining remains uncertain. To decipher this apical PrPsc immunopositivity and subsequently the ependymocyte–scrapie agent interaction, we employed highly sensitive immuno-electron microscopy for detecting PrPsc in 263K scrapie-infected hamster brains. The results revealed the supraependymal PrPsc signal to be correlated not only with extracellular accumulation of amyloid filaments, but also with three distinct ependymal cell structures: (1) morphologically intact or altered microvilli associated with filaments, (2) the ependymal cell cytoplasm in proximity of apical cell membrane, and (3) intracytoplasmic organelles such as endosomes and lysosomal-like structures. These findings suggest a strong ependymotrope feature of the scrapie agent and recapitulate several aspects of the cell–prion interaction leading to the formation and production of PrPsc amyloid filaments. Our data demonstrate that in addition to neurons and astrocytes, ependymocytes constitute a new cellular target for the scrapie agent. In contrast, the absence of PrPsc labeling in choroid plexus and brain vascular endothelial cells indicates that these cells are not susceptible to the infection and may inhibit passage of the infectious agent across the blood–brain barrier. [ABSTRACT FROM AUTHOR]

Published

2008

136. Subventricular Zone-Mediated Ependyma Repair in the Adult Mammalian Brain.

Author

Jie Luo, Shook, Brett A., Daniels, Stephen B., and Conover, Joanne C.

Subjects

*BRAIN, *EPENDYMA, *NEURAL stem cells, *REGENERATION (Biology), *CELLS, *ADULTS, *MAMMALS

Abstract

The subventricular zone (SVZ) of the adult mouse brain is a narrow stem cell niche that lies along the length of the lateral wall of the lateral ventricles. The SVZ supports neurogenesis throughout adulthood; however, with increasing age, the ventral SVZ deteriorates and only the dorsolateral SVZ remains neurogenic. Associated with the elderly dorsolateral SVZ, we reported previously an increased number of astrocytes interposed within the adjacent ependymal lining. Here, we show that astrocytes integrated within the ependyma are dividing, BrdU-labeled astrocytes that share cellular adherens with neighboring ependymal cells. By tracking BrdU-labeled astrocytes over time, we observed that, as they incorporated within the ependyma, they took on antigenic and morphologic characteristics of ependymal cells, suggesting a novel form of SVZ-supported "regenerative" repair in the aging brain. A similar form of SVZ-mediated ependyma repair was also observed in young mice after mild ependymal cell denudation with low dosages of neuraminidase. Together, this work identifies a novel non-neuronal mechanism of regenerative repair by the adult SVZ. [ABSTRACT FROM AUTHOR]

Published

2008

137. c-Myb Is Required for Neural Progenitor Cell Proliferation and Maintenance of the Neural Stem Cell Niche in Adult Brain.

Author

MALATERRE, JORDANE, MANTAMADIOTIS, THEO, DWORKIN, SEBASTIAN, LIGHTOWLER, SALLY, QING YANG, RANSOME, MARK I., TURNLEY, ANN M., NICHOLS, NANCY R., EMAMBOKUS, NIKLA R., FRAMPTON, JON, and RAMSAY, ROBERT G.

Subjects

CELL proliferation, NEURAL stem cells, NEURONS, HOMEOSTASIS, CELL division, DEVELOPMENTAL neurobiology

Abstract

Ongoing production of neurons in adult brain is restricted to specialized neurogenic niches. Deregulated expression of genes controlling homeostasis of neural progenitor cell division and/or their microenvironment underpins a spectrum of brain pathologies. Using conditional gene deletion, we show that the proto-oncogene c-myb regulates neural progenitor cell proliferation and maintains ependymal cell integrity in mice. These two cellular compartments constitute the neurogenic niche in the adult brain. Brains devoid of c-Myb showed enlarged ventricular spaces, ependymal cell abnormalities, and reduced neurogenesis. Neural progenitor cells lacking c-Myb showed a reduced intrinsic proliferative capacity and reduction of Sox-2 and Pax-6 expression. These data point to an important role for c-Myb in the neurogenic niche of the adult brain. [ABSTRACT FROM AUTHOR]

Published

2008

138. Endogenous brain Na pumps, brain ouabain-like substance and the α2 isoform in salt-dependent hypertension

Author

Van Huysse, James W.

Subjects

*HYPERTENSION, *ADENOSINE triphosphatase, *PHYSIOLOGICAL control systems, *PATHOLOGICAL physiology

Abstract

Abstract: An endogenous ouabain-like substance (OLS) plays a critical role in the etiology of experimental models of human hypertension induced by a high salt diet. Early on, evidence for a role of this Na, K-ATPase inhibitor in blood pressure regulation was provided mainly by correlations of blood pressure with the levels of circulating Na, K-ATPase inhibitor. However, over the past decade, numerous studies have shown that endogenous Na pump inhibitors in the brain mediate salt-dependent hypertension in a variety of experimental models, including Dahl salt-sensitive (Dahl-S) and spontaneously hypertensive (SHR) rats on a high-salt diet. Other forms of hypertension that are known to be mediated by endogenous ouabain-like substances include steroid/salt- (e.g., DOCA-salt) and ACTH-induced hypertension. Even when exogenous ouabain is peripherally administered and/or the plasma ouabain/OLS level is increased in rats, the resulting hypertension is of CNS origin. After peripheral ouabain administration, ouabain levels increase in the plasma and the inhibitor subsequently accumulates in the brain. The ensuing hypertension is abolished by the intracerebroventricular (icv) administration of an anti-ouabain antibody (but not by the same antibody dose given iv), by discrete excitotoxic lesions in the brain or by ganglionic blockade, demonstrating that the response is neurally mediated. The pressor response to stimuli that increase the brain OLS (high salt diet, icv sodium) or to icv ouabain is abolished by icv losartan, demonstrating that the brain OLS activates the brain renin-angiotensin system (RAS) downstream. There are three isoforms of the catalytic α subunit of the Na, K-ATPase in the brain and cardiovascular system (α1, α2 and α3), but it is not known which brain isoform(s) mediate the hypertensive effects of circulating/CNS ouabain. Preliminary studies in gene-targeted mice suggest that the α2 isoform plays a critical role. [Copyright &y& Elsevier]

Published

2007

139. Cyclophosphamide-induced agenesis of cerebral aqueduct resulting in hydrocephalus in mice.

Author

Prakash, Singh, Gajendra, and Mahedra Singh, Sukh

Subjects

*HYDROCEPHALUS, *TERATOGENIC agents, *BRAIN diseases, *BRAIN, *MICE

Abstract

The present work was undertaken to reveal the mechanism of cerebral aqueduct agenesis found to result in hydrocephalus following intrauterine exposure to model teratogen, cyclophosphamide, in murine fetuses. A single dose of 10-mg/kg body weight cyclophosphamide was injected intaperitoneally to pregnant mice on day 10, 11 or 12 of gestation. Fetuses were collected through abdominal incision on day 18 and studied for various malformations of brain and cranium including hydrocephalus. Incomplete development and failure of canalization of the cerebral aqueduct were detected when serial sections of brain in coronal and transverse planes were studied under the microscope. Biotechnological investigations such as % DNA fragmentation, % viable cell count and cell proliferation assay were carried out on brain cells for further studies. Agenesis and non-canalization of the cerebral aqueduct resulted in increased pressure of CSF, which led to rupture of the aqueduct complicated by leakage and accumulation of CSF in brain substance forming a cavity containing CSF parallel and lateral to the unopened part of the cerebral aqueduct. Incomplete development along with non-canalization of the cerebral aqueduct resulted in blockage of CSF flow through the ventricles that manifest as internal hydrocephalus. External hydrocephalus on the other hand was detected where the CSF accumulated in the cavity formed inside the brain substance and established communication with the CSF in the subarachnoid space. Cyclophosphamide induced inhibition of mitosis and cell differentiation of ependymal cells reflecting a decreased % viable cell count and cell proliferation assay along with augmentation of apoptosis of brain cells quantified as increased % DNA fragmentation count, which were identified as the contributing factors underlying the agenesis and incomplete development of the cerebral aqueduct. The study also suggests that cell survival, proliferation, migration or differentiation of ependymal cells might have been affected, and we speculate that CSF may have an inducing role in the development and canalization of the cerebral aqueduct. [ABSTRACT FROM AUTHOR]

Published

2007

140. The secretory ependymal cells of the subcommissural organ: Which role in hydrocephalus?

Author

Meiniel, Annie

Subjects

*EPENDYMA, *HYDROCEPHALUS, *CEREBROSPINAL fluid, *HOMEOSTASIS

Abstract

Abstract: Ependyma in the central nervous system gives rise to several specialized cell types, including the secretory ependymal cells located in the subcommissural organ. These elongated cells show large cisternae in their cytoplasm, which are filled with material secreted into the cerebrospinal fluid and toward the leptomeningeal spaces. A specific secretion of the subcommissural organ was named SCO-spondin, regarding its marked homology with developmental proteins of the thrombospondin superfamily (presence of thrombospondin type 1 repeats). The ependymal cells of the subcommissural organ and SCO-spondin secretion are suspected to play a crucial role in cerebrospinal fluid flow and/or homeostasis. There is a close correlation between absence of the subcommissural organ and hydrocephalus in rat and mouse strains exhibiting congenital hydrocephalus, and in a number of mice transgenic for developmental genes. The ependymal cells of the subcommissural organ are under research as a key factor in several developmental processes of the central nervous system. [Copyright &y& Elsevier]

Published

2007

141. Developmental changes in the expression of ATP7A during a critical period in postnatal neurodevelopment

Author

Niciu, M.J., Ma, X.-M., El Meskini, R., Ronnett, G.V., Mains, R.E., and Eipper, B.A.

Subjects

*COPPER proteins, *ADENOSINE triphosphatase, *CYTOSOL, *PURKINJE cells

Abstract

Abstract: ATP7A is a P-type ATPase that transports copper from cytosol into the secretory pathway for loading onto cuproproteins or efflux. Mutations in Atp7a cause Menkes disease, a copper-deficiency disorder fatal in the postnatal period due to severe neurodegeneration. Early postnatal copper injections are known to diminish degenerative changes in some human patients and mice bearing mutations in Atp7a. In situ hybridization studies previously demonstrated that ATP7A transcripts are expressed widely in the brain. ATP7A-specific antibody was used to study the neurodevelopmental expression and localization of ATP7A protein in the mouse brain. Based on immunoblot analyses, ATP7A expression is most abundant in the early postnatal period, reaching peak levels at P4 in neocortex and cerebellum. In the developing and adult brain, ATP7A levels are greatest in the choroid plexus/ependymal cells of the lateral and third ventricles. ATP7A expression decreases in most neuronal subpopulations from birth to adulthood. In contrast, ATP7A expression increases in CA2 hippocampal pyramidal and cerebellar Purkinje neurons. ATP7A is expressed in a subset of astrocytes, microglia, oligodendrocytes, tanycytes and endothelial cells. ATP7A is largely localized to the trans-Golgi network, adopting the cell-specific and developmentally-regulated morphology of this organelle. The presence of ATP7A in the axons of postnatal, but not adult, optic nerve suggests stage-specific roles for this enzyme. In sum, the precisely-regulated neurodevelopmental expression of ATP7A correlates well with the limited therapeutic window for effective treatment of Menkes disease. [Copyright &y& Elsevier]

Published

2006

142. Ependymal epithelium disruption after vanadium pentoxide inhalation: A mice experimental model

Author

Avila-Costa, María Rosa, Colín-Barenque, Laura, Zepeda-Rodríguez, Armando, Antuna, Silvia B., Saldivar O, Liliana, Espejel-Maya, Guadalupe, Mussali-Galante, Patricia, del Carmen Avila-Casado, Maria, Reyes-Olivera, Alfonso, Anaya-Martinez, Veronica, and Fortoul, Teresa I.

Subjects

*EPITHELIUM, *CELLULAR mechanics, *ELECTRON microscopy, *TOXINS

Abstract

Abstract: The blood–brain barrier (BBB) protects the CNS against chemical insults. Regulation of blood–brain tissue exchange is accomplished by ependymal cells, which possess intercellular tight junctions. Loss of BBB function is an etiologic component of many neurological disorders. Vanadium (V) is a metalloid widely distributed in the environment and exerts potent toxic effects on a wide variety of biological systems. The current study examines the effects of Vanadium pentoxide (V2O5) inhalation in mice ependymal epithelium, through the analysis of the brain metal concentrations and the morphological modifications in the ependymal cells identified by scanning and transmission electron microscopy after 8 weeks of inhalation, in order to obtain a possible explanation about the mechanisms that V uses to enter and alter the CNS. Our results showed that V2O5 concentrations increase from the first week of study, stabilizing its values during the rest of the experiment. The morphological effects included cilia loss, cell sloughing and ependymal cell layer detachment. This damage can allow toxicants to modify the permeability of the epithelium and promote access of inflammatory mediators to the underlying neuronal tissue causing injury and neuronal death. Thus, understanding the mechanisms of BBB disruption would allow planning strategies to protect the brain from toxicants such as metals, which have increased in the atmosphere during the last decades and constitute an important health problem. [Copyright &y& Elsevier]

Published

2005

143. Ependymal damage in a Plasmodium yoelii yoelii lethal murine malaria model

Author

Rivera Fernández, Norma, Colin-Barenque, Laura, Romero Silva, Samanta E., Salas Garrido, Gerardo, Jiménez Rosey, Samantha G., Zepeda Rodríguez, Armando, Romero Romero, Laura P., and Menchaca Gómez, Ángeles

Subjects

Plasmodium yoelii yoelii, Cerebrospinal fluid-brain barrier, 5 - Ciencias puras y naturales::57 - Biología::576 - Biología celular y subcelular. Citología [CDU], Ependymal cells, parasitic diseases, Electron microscopy

Abstract

Malaria continues to be a major global health problem, and over 40% of the world’s population is at risk. Severe or complicated malaria is defined by clinical or laboratory evidence of vital organ dysfunction, including dysfunction of the central nervous system (CNS). The pathogenesis of complicated malaria has not been completely elucidated; however, the development of the multiorgan affection seems to play an important role in the disruption of the blood brain barrier (BBB) that protects the CNS against chemical insults. Historically, the BBB has received more attention in the pathogenesis of malaria than have the cerebrospinal fluid-brain barrier (CSFBB) and ependymal cells. This perspective may be misguided because, in the context of disease or toxicity, the CSFBB is more vulnerable to many foreign invaders than are the capillaries. Given the lack on studies of the damage to the CSFBB and ependymal epithelium in experimental murine malaria, the present study evaluated morphological changes in the ependymal cells of CD-1 male mice infected with lethal Plasmodium yoelii yoelii (Pyy) via histopathology and scanning electron microscopy (SEM). Samples were taken two, four and six days post-infection (PI). No lesions were observed upon the initial infection. By the fourth day PI, fourth ventricle ependymal samples exhibited disruptions and roughened epithelia. More severe injuries were observed at six days PI and included thickened cilia and deep separations between the ependymal intercellular spaces. In some of the analyzed areas, the absence of microvilli and cell layer detachment were observed, and some areas exhibited blebbing surfaces. The ependymal cell lesions observed in the CD1 male mice infected with lethal Pyy seemed to facilitate the paracellular permeability of the CSFBB and consequently promote the access of inflammatory mediators and toxic molecules through the barrier, which resulted in damage to the brain tissue. Understanding the mechanism of ependymal disruption during lethal murine malaria could help to elucidate the local and systemic factors that are involved in the pathogenesis of the disease and may provide essential clues for the prevention and treatment of complicated human malaria.

Published

2020

144. GFAP-immunopositive structures in spiny dogfish, Squalus acanthias, and little skate, Raiaerinacea, brains: differences have evolutionary implications.

Author

Kálmán, M. and Gould, R. M.

Subjects

CELLS, NEUROGLIA, BIOTIN, PLANT products, VITAMIN B complex, MAMMALS

Abstract

GFAP expression patterns were compared between the brains of a spiny dogfish (Squalusacanthias) and a little skate (Raiaerinacea). After anesthesia, the animals were perfused with paraformaldehyde. Serial vibratome sections were immunostained against GFAP using the avidin-biotin method. Spiny dogfish brain contained mainly uniformly-distributed, radially arranged ependymoglia. From GFAP distribution, the layered organization in both the telencephalon and the tectum were visible. In the cerebellum, the molecular and granular layers displayed conspicuously different glial structures; in the former a Bergmann glia-like population was found. No true astrocytes (i.e., stellate-shaped cells) were found. Radial glial endfeet lined all meningeal surfaces. Radial fibers also seemed to form endfeet and en passant contacts on the vessels. Plexuses of fine perivascular glial fibers also contributed to the perivascular glia. Compared with spiny dogfish brain, GFAP expression in the little skate brain was confined. Radial glia were limited to a few areas, e.g., segments of the ventricular surface of the telencephalon, and the midline of the diencephalon and mesencephalon. Scarce astrocytes occurred in every brain part, but only the optic chiasm, and the junction of the tegmentum and optic tectum contained large numbers of astrocytes. Astrocytes formed the meningeal glia limitans and the perivascular glia. No GFAP-immunopositive Bergmann glia-like structure was found. Astrocytes seen in the little skate were clearly different from the mammalian and avian ones; they had a different process system – extra large forms were frequently seen, and the meningeal and perivascular cells were spread along the surface instead of forming endfeet by processes. The differences between Squalus and Raia astroglia were much like those found between reptiles versus mammals and birds. It suggests independent and parallel glial evolutionary processes in amniotes and chondrichthyans, seemingly correlated with the thickening of the brain wall, and the growing complexity of the brain. There is no strict correlation, however, between the replacement of radial ependymoglia with astrocytes, and the local thickness of the brain wall. [ABSTRACT FROM AUTHOR]

Published

2001

145. Distribution of testican expression in human brain.

Author

Marr, Henry S., Basalamah, Mohammad A., Bouldin, Thomas W., Duncan, Andrew W., and Edgell, Cora-Jean S.

Subjects

EXTRACELLULAR matrix, EXTRACELLULAR space, CONNECTIVE tissues, PROTEOGLYCANS, GLYCOPROTEINS, ENDOTHELIUM, IN situ hybridization

Abstract

Testican is a putative extracellular heparan/chondroitin sulfate proteoglycan of unknown function that is expressed in a variety of human tissues at widely different levels but is most abundant in the brain. In mice, testican mRNA has been detected only in brain and it is therefore likely to have an important function in the central nervous system. RNA blot analysis reveals the relative intensity of testican in various regions of the human brain. Levels of testican message are most pronounced in the thalamus, hippocampus, occipital lobe, nucleus accumbens, temporal lobe, and caudate nucleus, with somewhat lower levels in the cerebral cortex, medulla oblongata, frontal lobe, amygdala, putamen, spinal cord, substantia nigra, and cerebellum. In situ hybridization reveals the cellular distribution of the mRNA within these areas to be highest in neurons and in choroid plexus epithelium, and moderately lower in ependymal cells lining the ventricles and in vascular endothelial cells. Testican mRNA is not detected in oligodendrocytes or in most astrocytes. However, astrocytes in regions of reactive gliosis do express testican mRNA. These findings, along with a cysteine-rich pattern similarity to neurocan, brevican, versican, and other proteoglycans found in brain, suggest that testican may be a part of the specialized extracellular matrix of the brain. [ABSTRACT FROM AUTHOR]

Published

2000

146. 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, Hussein, Ripoll, Chantal, Leventoux, Nicolas, Jacob, Laurent, Azar, Safa, Mamaeva, Daria, Glasson, Yael, Calvo, Charles-Félix, Thomas, Jean-Léon, Meneceur, Sarah, Lallemand, Yvan, Rigau, Valérie, Perrin, Florence, Noristani, Harun, Rocamonde, Brenda, Huillard, Emmanuelle, Bauchet, Luc, Hugnot, Jean-Philippe, Hôpital Saint Eloi (CHRU Montpellier), Centre Hospitalier Régional Universitaire [Montpellier] (CHRU Montpellier), Institut des Neurosciences de Montpellier (INM), Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Montpellier (UM), Sorbonne Université (SU), Institut du Cerveau = Paris Brain Institute (ICM), Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Institut National de la Santé et de la Recherche Médicale (INSERM)-CHU Pitié-Salpêtrière [AP-HP], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Sorbonne Université (SU)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Centre interdisciplinaire de recherche en biologie (CIRB), Labex MemoLife, École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Collège de France (CdF (institution))-Ecole Superieure de Physique et de Chimie Industrielles de la Ville de Paris (ESPCI Paris), Université Paris sciences et lettres (PSL)-École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Yale School of Medicine [New Haven, Connecticut] (YSM), Institut Pasteur [Paris] (IP), Cellules Souches et Développement / Stem Cells and Development, Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS), CHU Montpellier, Université de Montpellier (UM), This work was supported by grants from IRP (Switzerland), IRME (France), AFM (France), ANR EU ERANET Neuroniche (J.-P.H.), and ANR Brainwash (J.-L.T., L.J.). H.G. was supported by an AFM PhD fellowship, We thank all Montpellier biocampus facilities for help (RHEM, MRI RIO, RAM) and excellent technical work. We are very grateful to Dr. H Boukhaddaoui (imaging), Dr. C Duperray (cytometry), M. Maistre (laser microdissection facilities, Bordeaux), V. Pantesco (Affymetrix facilities), and M. Goussard/P. Guigue (animals) for providing technical expertise in this work. We warmly thank Prof. Morohashi (Kyushu University, Japan) for anti-Arx antibody. The authors declare that there is no conflict of interest regarding the publication of this article., ANR-17-CE14-0005,BrainWash,Drainage lymphatique, recirculation immunitaire et réparation neuronale après un accident cérébrovasculaire(2017), ANR-16-NEU3-0001,NEURONICHE,Spinal cord repair from endogenous stem cells in the spinal niche(2016), Gestionnaire, Hal Sorbonne Université, Drainage lymphatique, recirculation immunitaire et réparation neuronale après un accident cérébrovasculaire - - BrainWash2017 - ANR-17-CE14-0005 - AAPG2017 - VALID, Spinal cord repair from endogenous stem cells in the spinal niche - - NEURONICHE2016 - ANR-16-NEU3-0001 - ERANET NEURON III - VALID, Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Perrin, Florence, Mécanismes moléculaires dans les démences neurodégénératives (MMDN), Université de Montpellier (UM)-Université Montpellier 2 - Sciences et Techniques (UM2)-Institut National de la Santé et de la Recherche Médicale (INSERM)-École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), CHU Saint-Eloi, Institut des Neurosciences de Montpellier - Déficits sensoriels et moteurs (INM), Institut du Cerveau et de la Moëlle Epinière = Brain and Spine Institute (ICM), Institut National de la Santé et de la Recherche Médicale (INSERM)-CHU Pitié-Salpêtrière [AP-HP], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Sorbonne Université (SU)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-École normale supérieure - Paris (ENS Paris), Yale University School of Medicine, Institut Pasteur [Paris], and Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS)

Subjects

Resource, Male, [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Ependymoglial Cells, radial glial cells, floor plate, Mice, Transgenic, Mice, Young Adult, transcription factors, [SDV.BBM.GTP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Genomics [q-bio.GN], Animals, Humans, [SDV.NEU] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Stem Cell Niche, lcsh:QH301-705.5, ComputingMilieux_MISCELLANEOUS, Embryonic Stem Cells, ependyma, neural stem cells, MSX1 Transcription Factor, lcsh:R5-920, roof plate, Gene Expression Profiling, Stem Cells, ependymal cells, [SDV.NEU.NB] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Gene Expression Regulation, Developmental, spinal cord, Middle Aged, niche, lcsh:Biology (General), Microscopy, Fluorescence, regionalization, RNA, [SDV.BBM.GTP] Life Sciences [q-bio]/Biochemistry, Molecular Biology/Genomics [q-bio.GN], [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Female, lcsh:Medicine (General), Msx1

Abstract

Summary: 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. : A niche of stem cells is present around the central canal of the adult spinal cord. A better description of cell diversity and genes expressed in this niche may help to use it to promote spinal cord regeneration after lesions. In this article, based on several techniques, Ghazale and colleagues provide a cellular and molecular resource for the adult human and mouse stem cell niches. Keywords: spinal cord, niche, neural stem cells, regionalization, ependyma, ependymal cells, radial glial cells, transcription factors, Msx1, roof plate, floor plate

Published

2019

147. Ependymal and Neural Stem Cells of Adult Molly Fish ( Poecilia sphenops , Valenciennes, 1846) Brain: Histomorphometry, Immunohistochemical, and Ultrastructural Studies.

Author

Mokhtar DM, Sayed RKA, Zaccone G, Albano M, and Hussein MT

Subjects

Animals, Brain, Ependyma, Neuroglia, Neural Stem Cells, Poecilia

Abstract

This study was conducted on 16 adult specimens of molly fish ( Poecilia sphenops ) to investigate ependymal cells (ECs) and their role in neurogenesis using ultrastructural examination and immunohistochemistry. The ECs lined the ventral and lateral surfaces of the optic ventricle and their processes extended through the tectal laminae and ended at the surface of the tectum as a subpial end-foot. Two cell types of ECs were identified: cuboidal non-ciliated (5.68 ± 0.84/100 μm 2 ) and columnar ciliated (EC3.22 ± 0.71/100 μm 2 ). Immunohistochemical analysis revealed two types of GFAP immunoreactive cells: ECs and astrocytes. The ECs showed the expression of IL-1β, APG5, and Nfr2. Moreover, ECs showed immunostaining for myostatin, S100, and SOX9 in their cytoplasmic processes. The proliferative activity of the neighboring stem cells was also distinct. The most interesting finding in this study was the glia-neuron interaction, where the processes of ECs met the progenitor neuronal cells in the ependymal area of the ventricular wall. These cells showed bundles of intermediate filaments in their processes and basal poles and were connected by desmosomes, followed by gap junctions. Many membrane-bounded vesicles could be demonstrated on the surface of the ciliated ECs that contained neurosecretion. The abluminal and lateral cell surfaces of ECs showed pinocytotic activities with many coated vesicles, while their apical cytoplasm contained centrioles. The occurrence of stem cells in close position to the ECs, and the presence of bundles of generating axons in direct contact with these stem cells indicate the role of ECs in neurogenesis. The TEM results revealed the presence of neural stem cells in a close position to the ECs, in addition to the presence of bundles of generating axons in direct contact with these stem cells. The present study indicates the role of ECs in neurogenesis.

Published

2022

148. Hydrocephalus in Nfix -/- Mice Is Underpinned by Changes in Ependymal Cell Physiology.

Author

Harkins D, Harvey TJ, Atterton C, Miller I, Currey L, Oishi S, Kasherman M, Davila RA, Harris L, Green K, Piper H, Parton RG, Thor S, Cooper HM, and Piper M

Subjects

Animals, Cell Physiological Phenomena, Lateral Ventricles, Mice, Neuroglia, Ependyma, Hydrocephalus genetics, NFI Transcription Factors genetics

Abstract

Nuclear factor one X (NFIX) is a transcription factor required for normal ependymal development. Constitutive loss of Nfix in mice ( Nfix -/- ) is associated with hydrocephalus and sloughing of the dorsal ependyma within the lateral ventricles. Previous studies have implicated NFIX in the transcriptional regulation of genes encoding for factors essential to ependymal development. However, the cellular and molecular mechanisms underpinning hydrocephalus in Nfix -/- mice are unknown. To investigate the role of NFIX in hydrocephalus, we examined ependymal cells in brains from postnatal Nfix -/- and control ( Nfix +/+ ) mice using a combination of confocal and electron microscopy. This revealed that the ependymal cells in Nfix -/- mice exhibited abnormal cilia structure and disrupted localisation of adhesion proteins. Furthermore, we modelled ependymal cell adhesion using epithelial cell culture and revealed changes in extracellular matrix and adherens junction gene expression following knockdown of NFIX . Finally, the ablation of Nfix from ependymal cells in the adult brain using a conditional approach culminated in enlarged ventricles, sloughing of ependymal cells from the lateral ventricles and abnormal localisation of adhesion proteins, which are phenotypes observed during development. Collectively, these data demonstrate a pivotal role for NFIX in the regulation of cell adhesion within ependymal cells of the lateral ventricles.

Published

2022

149. Phosphorylation-dependent proteome of Marcks in ependyma during aging and behavioral homeostasis in the mouse forebrain.

Author

Muthusamy N, Williams TI, O'Toole R, Brudvig JJ, Adler KB, Weimer JM, Muddiman DC, and Ghashghaei HT

Subjects

Mice, Animals, Phosphorylation, Myristoylated Alanine-Rich C Kinase Substrate metabolism, Proteome metabolism, Membrane Proteins metabolism, Protein Kinase C metabolism, Homeostasis, Prosencephalon metabolism, Mammals metabolism, Ependyma metabolism, Intracellular Signaling Peptides and Proteins metabolism

Abstract

Ependymal cells (ECs) line the ventricular surfaces of the mammalian central nervous system (CNS) and their development is indispensable to structural integrity and functions of the CNS. We previously reported that EC-specific genetic deletion of the myristoylated alanine-rich protein kinase C substrate (Marcks) disrupts barrier functions and elevates oxidative stress and lipid droplet accumulation in ECs causing precocious cellular aging. However, little is known regarding the mechanisms that mediate these changes in ECs. To gain insight into Marcks-mediated mechanisms, we performed mass spectrometric analyses on Marcks-associated proteins in young and aged ECs in the mouse forebrain using an integrated approach. Network analysis on annotated proteins revealed that the identified Marcks-associated complexes are in part involved in protein transport mechanisms in young ECs. In fact, we found perturbed intracellular vesicular trafficking in cultured ECs with selective deletion of Marcks (Marcks-cKO mice), or upon pharmacological alteration to phosphorylation status of Marcks. In comparison, Marcks-associated protein complexes in aged ECs appear to be involved in regulation of lipid metabolism and responses to oxidative stress. Confirming this, we found elevated signatures of inflammation in the cerebral cortices and the hippocampi of young Marcks-cKO mice. Interestingly, behavioral testing using a water maze task indicated that spatial learning and memory is diminished in young Marcks-cKO mice similar to aged wildtype mice. Taken together, our study provides first line of evidence for potential mechanisms that may mediate differential Marcks functions in young and old ECs, and their effect on forebrain homeostasis during aging., (© 2022. The Author(s), under exclusive licence to American Aging Association.)

Published

2022

150. Single-nucleus RNA sequencing identified cells with ependymal cell-like features enriched in neonatal mice after spinal cord injury.

Author

Ikeda-Yorifuji I, Tsujioka H, Sakata Y, and Yamashita T

Subjects

Animals, Animals, Newborn, Ependyma metabolism, Ependyma pathology, Humans, Mammals, Mice, Sequence Analysis, RNA, Spinal Cord metabolism, Persons with Disabilities, Motor Disorders metabolism, Spinal Cord Injuries pathology

Abstract

The adult mammalian central nervous system has limited regenerative ability, and spinal cord injury (SCI) often causes lifelong motor disability. While regeneration is limited in adults, injured spinal cord tissue can be regenerated and neural function can be almost completely restored in neonates. However, difference of cellular composition in lesion has not been well characterized. To gain insight into the age-dependent cellular reaction after SCI, we performed single-nucleus RNA sequencing, analyzing 4076 nuclei from sham and injured spinal cords from adult and neonatal mice. Clustering analysis identified 18 cell populations. We identified previously undescribed cells with ependymal cell-like gene expression profile, the number of which was increased in neonates after SCI. Histological analysis revealed that these cells line the central canal under physiological conditions in both adults and neonates. We confirmed that they were enriched in the lesion only in neonates. We further showed that these cells were positive for the cellular markers of ependymal cells, astrocytes and radial glial cells. This study provides a deeper understanding of neonate-specific cellular responses after SCI, which may determine regenerative capacity., (Copyright © 2022 Japan Neuroscience Society and Elsevier B.V. All rights reserved.)

Published

2022