Experimental panencephalitis induced in suckling mice by parainfluenza I (6/94) virus. III. Ultrastructural studies.

Intracerebral inoculation of newborn mice with Parainfluenza I (6/94) virus produces a chronic panencephalitis. Electron microscopic studies were carried out over 125 days of the infection. Productive infection of choroidal and ependymal epithelial cells was seen from postinoculation days 2nd to the 8th. Fusion of adjacent choroid and ependymal cells resulted in giant cell formation. Completed virions were seen adsorbed to circulating macrophages and these cells replicated intracytoplasmic nucleocapsids. Neuronal infection was evident on the 3rd postinoculation day, was widespread by the 6th day postinoculation and persisted to the 35th day postinoculation. Nucleocapsid alignment and budding from neuronal plasma membranes was never seen. An initially intense mononuclear cell infiltrate subsided by the 35th day but residual inflammation persisted throughout the study. Late in the course of the infection, vacuolation of the neuropil and a periventricular and deep cerebral spongiform change was seen which could not be directly associated with local viral replication. These ultrastructural findings are correlated with prior light microscopic, virological and immunofluorescent studies of the infection and compared to other experimental models of myxovirus central nervous system infections.     

Astrocytes generated from patient induced pluripotent stem cells recapitulate features of Huntington's disease patient cells

ABSTRACT: BACKGROUND: Huntington's Disease (HD) is a devastating neurodegenerative disorder that clinically manifests as motor dysfunction, cognitive impairment and psychiatric symptoms. There is currently no cure for this progressive and fatal disorder. The causative mutation of this hereditary disease is a trinucleotide repeat expansion (CAG) in the Huntingtin gene that results in an expanded polyglutamine tract. Multiple mechanisms have been proposed to explain the preferential striatal and cortical degeneration that occurs with HD, including noncell- autonomous contribution from astrocytes. Although numerous cell culture and animal models exist, there is a great need for experimental systems that can more accurately replicate the human disease. Human induced pluripotent stem cells (iPSCs) are a remarkable new tool to study neurological disorders because this cell type can be derived from patients as a renewable, genetically tractable source for unlimited cells that are difficult to acquire, such as neurons and astrocytes. The development of experimental systems based on iPSC technology could aid in the identification of molecular lesions and therapeutic treatments. RESULTS: We derived iPSCs from a father with adult onset HD and 50 CAG repeats (F-HD-iPSC) and his daughter with juvenile HD and 109 CAG repeats (D-HD-iPSC). These disease-specific iPSC lines were characterized by standard assays to assess the quality of iPSC lines and to demonstrate their pluripotency. HD-iPSCs were capable of producing phenotypically normal, functional neurons in vitro and were able to survive and differentiate into neurons in the adult mouse brain in vivo after transplantation. Surprisingly, when HD-iPSCs were directed to differentiate into an astrocytic lineage, we observed the presence of cytoplasmic, electron clear vacuoles in astrocytes from both F-HD-iPSCs and D-HD-iPSCs, which were significantly more pronounced in D-HD-astrocytes. Remarkably, the vacuolation in astrocytes was observed under basal culture conditions without additional stressors and increased over time. Importantly, the vacuolation phenotype has also been observed in peripheral blood lymphocytes from individuals with HD. Together, these data suggest that vacuolation may be a phenotype associated with HD. CONCLUSIONS: We have generated a unique in vitro system to study HD pathogenesis using patient-specific iPSCs. The astrocytes derived from patient-specific iPSCs exhibit a vacuolation phenotype, a phenomenon previously documented in primary lymphocytes from HD patients. Our studies pave the way for future mechanistic investigations using human iPSCs to model HD and for high-throughput therapeutic screens.     

Knockdown of MLC1 in primary astrocytes causes cell vacuolation: a MLC disease cell model

Megalencephalic leukoencephalopathy with subcortical cysts (MLC) is a rare type of leukodystrophy, in the majority of cases caused by mutations in the MLC1 gene. MRI from MLC patients shows diffuse cerebral white matter signal abnormality and swelling, with evidence of increased water content. Histopathology in a MLC patient shows vacuolation of myelin, which causes the cerebral white matter swelling. MLC1 protein is expressed in astrocytic processes that are part of blood- and cerebrospinal fluid-brain barriers. We aimed to create an astrocyte cell model of MLC disease. The characterization of rat astrocyte cultures revealed MLC1 localization in cell-cell contacts, which contains other proteins described typically in tight and adherent junctions. MLC1 localization in these contacts was demonstrated to depend on the actin cytoskeleton; it was not altered when disrupting the microtubule or the GFAP networks. In human tissues, MLC1 and the protein Zonula Occludens 1 (ZO-1), which is linked to the actin cytoskeleton, co-localized by EM immunostaining and were specifically co-immunoprecipitated. To create an MLC cell model, knockdown of MLC1 in primary astrocytes was performed. Reduction of MLC1 expression resulted in the appearance of intracellular vacuoles. This vacuolation was reversed by the co-expression of human MLC1. Re-examination of a human brain biopsy from an MLC patient revealed that vacuoles were also consistently present in astrocytic processes. Thus, vacuolation of astrocytes is also a hallmark of MLC disease.     

Ultrastructure of the central nervous system after prolonged hypoxia

Summary The neuroglial cells and small blood vessels of the central nervous system of the rats under hypoxia for one to 24 days were examined by electron microscopy. In the first week, the astrocytes were moderately swollen, particularly their perivascular processes. The endothelium of small vessels contained an increased number of mitochondria, accompanied by moderate thickening of the basal lamina. From the 7th to 24th days, intracellular edema in the astrocytes and oligodendrocytes became manifest. In the gray matter, the astrocytes exhibited great dilatation of the endoplasmic reticulum (ER) and increased translucency of the cytoplasm. Many astrocytic processes arranged themselves in lamellar whorls which encircled parts of cytoplasm or were wrapped around altered presynaptic terminals. In the white matter, profuse accumulation of the gliofilaments was observed in many astrocytes. The oligodendrocytes of the gray matter displayed marked dilatation of the ER cisternae whereas in the white matter, they frequently contained an increasing number of lipofuscin granules and lysosomes. The pericytes of the small blood vessels were greatly enlarged and contained numerous osmiophilic inclusion bodies.This study was supported by the Dorothy R. Victor Memorial Fund, the Lusyd Wright Hitchcock Memorial Research Fund and the Buswell Foundation.     

The human blood-brain barrier glucose transporter (GLUT1) is a glucose transporter of gray matter astrocytes

Human and monkey brain sections were examined by immunohistochemical light and electron microscopy to determine the distribution of GLUT1, a glucose transporter isoform associated with erythrocytes and endothelial cells of the human blood-brain barrier. Protein immunoblotting of fractionated human brain membranes was performed to determine the distribution of molecular forms of the transporter. GLUT1 staining was abundant in erythrocytes and cerebral endothelium of gray and white matter but was also present diffusely in gray matter neuropil when viewed by light microscopy. Immunoelectron microscopy confirmed the gray matter and vascular localization of GLUT1, with specific GLUT1 staining seen in erythrocytes, gray and white matter endothelial cells, astrocyte foot processes surrounding gray matter blood vessels, and in astrocyte processes adjacent to synaptic contacts. No astrocytic staining was identified in white matter. Astrocyte GLUT1 staining was identified only in mature gray matter regions; undifferentiated regions of preterm (22–23 weeks gestation) cortex had GLUT1 staining only in blood vessels and erythrocytes, as did germinal matrix. Immunoblots of adult human frontal cortex revealed that two forms of GLUT1 (45 and 52 kDa) were present in unfractionated brain homogenates. Immunoblots of vessel-depleted frontal lobe revealed only the 45 kDa form in gray matter fractions, and depleted in membranes prepared from white matter regions. We conclude that the GLUT1 isoform of glucose transporter is present both in endothelium of the blood-brain barrier and in astrocytes surrounding gray matter blood vessels and synapses. Furthermore, the form present in astrocytes is likely to have a lower molecular weight than the form found in cerebral endothelium. The GLUT1 transporter may play an important role not only in astrocyte metabolism, but also in astrocyte-associated pathways supporting neuronal energy metabolism. © 1995 Wiley-Liss, Inc.     

Human and mouse cortical astrocytes differ in aquaporin‐4 polarization toward microvessels

Aquaporin‐4 (AQP4), the predominant water channel in the brain, is expressed in astrocytes and ependymal cells. In rodents AQP4 is highly polarized to perivascular astrocytic endfeet and loss of AQP4 polarization is associated with disease. The present study was undertaken to compare the expression pattern of AQP4 in human and mouse cortical astrocytes. Cortical tissue specimens were sampled from 11 individuals undergoing neurosurgery wherein brain tissue was removed as part of the procedure, and compared with cortical tissue from 5 adult wild‐type mice processed similarly. The tissue samples were immersion‐fixed and prepared for AQP4 immunogold electron microscopy, allowing quantitative assessment of AQP4's subcellular distribution. In mouse we found that AQP4 water channels were prominently clustered around vessels, being 5 to 10‐fold more abundant in astrocytic endfoot membranes facing the capillary endothelium than in parenchymal astrocytic membranes. In contrast, AQP4 was markedly less polarized in human astrocytes, being only two to three‐fold enriched in astrocytic endfoot membranes adjacent to capillaries. The lower degree of AQP4 polarization in human subjects (1/3 of that in mice) was mainly due to higher AQP4 expression in parenchymal astrocytic membranes. We conclude that there are hitherto unrecognized species differences in AQP4 polarization toward microvessels in the cerebral cortex.     

Endothelial nitric oxide synthetase (eNOS) in astrocytes: another source of nitric oxide in neocortex.

The distribution of the endothelial form of nitric oxide synthetase (eNOS) was examined in the visual cortex of three species of primate and in the rat using immunocytochemistry. Labeled cells were found in both the gray and white matter. These cells were stellate in appearance and labeled cell processes were seen contacting blood vessels or the pia, suggesting that, by morphological criteria, the cells were astrocytes. All eNOS positive cells were double labeled with an antibody against S100beta. Although all cells were double labeled in the white matter, in the gray matter, some S100beta positive cells did not contain detectable levels of eNOS. eNOS positive astrocytic processes appeared to form prominent and distinctive structures next to neurons, especially in cortical layer IIIC. We postulate that these eNOS-positive structures form astrocytic perisynaptic sheaths on neuronal somas in the cortex. If this is true, then nitric oxide can influence neuronal transmission directly at axosomatic synapses in the cortex. In addition, the presence of eNOS in astrocytes and in their processes that contact blood vessels suggests that the link between local cortical activity and changes in cerebral blood flow could be mediated by astrocytic release of nitric oxide.     

Accelerated glial reactivity to stroke in aged rats correlates with reduced functional recovery.

Following cerebral ischemia, perilesional astrocytes and activated microglia form a glial scar that hinders the genesis of new axons and blood vessels in the infarcted region. Since glial reactivity is chronically augmented in the normal aging brain, the authors hypothesized that postischemic gliosis would be temporally abnormal in aged rats compared to young rats. Focal cerebral ischemia was produced by reversible occlusion of the right middle cerebral artery in 3- and 20-month-old male Sprague Dawley rats. The functional outcome was assessed in neurobehavioral tests at 3, 7, 14, and 28 days after surgery. Brain tissue was immunostained for microglia, astrocytes, oligodendrocytes, and endothelial cells. Behaviorally, aged rats were more severely impaired by stroke and showed diminished functional recovery compared with young rats. Histologically, a gradual activation of both microglia and astrocytes that peaked by days 14 to 28 with the formation of a glial scar was observed in young rats, whereas aged rats showed an accelerated astrocytic and microglial reaction that peaked during the first week after stroke. Oligodendrocytes were strongly activated at early stages of infarct development in all rats, but this activation persisted in aged rats. Therefore, the development of the glial scar was abnormally accelerated in aged rats and coincided with the stagnation of recovery in these animals. These results suggest that a temporally anomalous gliotic reaction to cerebral ischemia in aged rats leads to the premature formation of scar tissue that impedes functional recovery after stroke.     

Serum influences the differentiation of membrane structure in cultured astrocytes

The membranes of mammalian astrocytic processes apposed to blood vessels or forming the surface of the brain contain high concentrations of a characteristic intramembrane particle aggregate, termed "assemblies." In order to identify developmental processes which contribute to this remarkable regional specialization of membrane structure, we have devised culture conditions which support the differentiation of assemblies in secondary cultures of astrocytes derived from neonatal rat forebrain. We report here that different lots of fetal calf serum vary dramatically in their capacity to support the differentiation of assemblies. Fetal calf serum thus appears to exert two distinct influences on astrocyte development: it promotes the differentiation of type 2 astrocytes from bipotential precursor cells, as shown by others, and it influences the density of assemblies in type 1, flat, GFAP-immunoreactive astrocytes in our secondary cultures. Horse serum and defined media also support the appearance of assemblies in flat, GFAP-immunoreactive astrocytes. The separate effects of serum supplementation upon cell lineage and membrane differentiation have to be carefully considered in studies designed to examine factors influencing astrocytic development in vitro.     

Postnatal development of glial fibrillary acidic protein immunoreactivity in the hamster arcuate nucleus

The postnatal development (from 2 days to 1 year) of glial fibrillary acidic protein (GFAP) immunoreactive cells was studied in the arcuate nucleus of male hamsters. In the first postnatal week, GFAP immunoreactivity was observed in radial glial cells whose cell bodies were located in the ependymal layer. Cell processes of GFAP immunoreactive radial glia crossed the arcuate nucleus and reached the pial surface, where they formed a thin and incomplete external limiting membrane. During the second postnatal week, some immunoreactive cell bodies were also located far from the ependymal layer. Some of these cell bodies presented processes that made contact with the ependymal layer whereas others, probably corresponding to maturing astrocytes, did not show ventricular connections. In the third week, only astrocytes showed GFAP immunoreactive perikarya and their immunoreactive processes reached either the blood vessels to form end-feet, or the basal hypothalamic zone to form the glia limitans. In successive weeks, there was an increase of the amount of GFAP-immunoreactive profiles on the glia limitans and surrounding the arcuate nucleus blood vessels. After the 6th postnatal week we observed some GFAP-immunoreactive cells close to arcuate neurons. The number of these cells increased from the 8th postnatal week. From this age on GFAP immunoreactive astrocytic processes compartimentalized the arcuate nucleus defining several rows of aligned neurons. These results indicate that the cytoarchitectonic organization of GFAP immunoreactive elements and their relationship with neurons, blood vessels and pia is not completed until the first 8 weeks of postnatal life in the arcuate nucleus of the hamster.     

Scrapie inoculation of mice: light and electron microscopy of the superior colliculi

Summary Ultrastructural examination of the superior colliculi of mice intraocularly inoculated with the ME7 strain of scrapie showed vacuolation early in the course of infection. Brains were examined between 85–260 days after monocular inoculation with scrapie. The mean incubation period for the development of clinical disease was 302 days. Vacuolation was seen initially in the contralateral superior colliculus and subsequently in the ipsilateral colliculus. In coded trails light microscopical vacuolation was seen from 218 days but ultrastructural examination showed that sparse vacuoles were inconsistently present in either or both of the ipsilateral and contralateral colliculi from 85 days; frequent vacuoles were seen from 190 days. Scrapie-induced vacuoles were differentiated from vacuoles present in control tissue by the presence of loculation or by a limiting double membrane which showed protrusion or proliferation of the innermost lamella. Vacuolation was seen in neuronal perikarya, myelinated fibres, dendrites and axonal presynaptic terminals. Vacuoles of myelinated fibres were observed within myelin and possibly also in the inner tongue of oligodendroglial cytoplasm. Whorled membrane configurations were also seen. Tubulovesicular particles, 40 nm in diameter, were recognised in two scrapie-infected mice. It is suggested that some scrapie vacuoles arise as a result of incorporation of abnormal membrane into organelles, possibly mitochondria, in neuronal perikarya and neurites and probably also within oligodendroglial cytoplasm and myelin.     

Chloride/anion channels in glial cell membranes

At least seven different chloride/anion currents have now been identified in astrocytes, oligodendrocytes/Schwann cells, and microglia. Only for two of these currents is the corresponding gene known. One of these genes is not encoding for a chloride channel, but for a class of mitochondria-like pores also found in cell membranes. Astrocytes and oligodendrocytes differ in their resting properties: astrocytes accumulate chloride but do not have a significant permeability. Oligodendrocytes have a close to passive distribution and a significant permeability. Under certain circumstances, astrocytes can express a resting chloride conductance. Reactive and neoplastic astrocytes as well as astrocytes with an altered shape exhibit a resting conductance. The function of these channels certainly involves volume regulation. Other possible functions are potassium homeostasis, migration, proliferation (in microglia), and involvement in spreading depression waves. Of greatest interest are two phenomena discovered in situ: The ClC-2 channel is only found in astrocytic endfeet near blood capillaries adjacent to neuronal GABA(A) receptors. In the supraoptic nucleus of the hypothalamus, there is an osmosensitive astrocytic taurine release. This released taurine interacts with glycine receptors in neighboring neurons, causing inhibition. It is assumed that with the future availability of more in situ, rather than in vitro, studies, an increased number of such complex interactions between glial cells, neurons, and blood vessels will be discovered.     

Differences in kinetics of human cytomegalovirus cell-free viral release after in vitro infection of human microglial cells, astrocytes and monocyte-derived macrophages.

Microglial cells and astrocytes isolated from human embryonic proencephalon were compared to monocyte-derived macrophages (MDM) for their ability to replicate human cytomegalovirus (HCMV) in vitro. A specific cytopathic effect was observed in microglial cells and astrocytes, but not in MDM. A high percentage of glial cells but a low percentage of MDM expressed immediate-early and late viral antigens. The ability of HCMV-infected microglial cells and astrocytes to release viral particles in their supernatants was significantly higher than that of infected MDM. Human microglial cells and astrocytes at an early stage of development are highly susceptible to HCMV infection.     

Ultrastructure of blood vessels in the ganglionic eminence of premature rabbits with spontaneous germinal matrix hemorrhages

Approximately 20% of preterm rabbit pups develop spontaneous germinal matrix hemorrhages (GMH). To understand better the pathogenesis of GMH we studied the ultrastructure of germinal matrix (GM) blood vessels in rabbits delivered at gestational day 28. Regardless of luminal size, the walls of most GM vessels had the structural characteristics associated with a blood-brain barrier (BBB) and consisted of endothelial cells and pericytes, surrounded by GM cell processes. Endothelial cells ranged from voluminous to attenuated, with some cells containing intracytoplasmic, membrane-bound vacuoles, and luminal as well as abluminal cytoplasmic projections. Some short interendothelial junctions had no puncta adherentia, whereas long ones often possessed intermittent pores. In two animals with GMH, intact endothelial cells were separated by narrow and wide gaps filled with luminal contents that occasionally extended beyond the interendothelial opening. The basal lamina (BL) was ill-defined, thin, often discontinuous and of low electron density. Smooth muscle cells and collagen were not present, which precluded any classification into arteries, capillaries and veins. Germinal matrix cell processes lacking both micro- and intermediate filaments were haphazardly disposed around the blood vessel walls in place of astrocytic endplates. Recent reports indicate that an astrocytic environment may be necessary for the development of the interendothelial tight junctions and BL. The presence of "glial foot" processes that lack ultrastructural characteristics of mature astrocytes suggests that interendothelial junctions and basal laminae in the vessels of the ganglionic eminence may not have the necessary structural and functional potential to withstand the transmural pressures or the pathophysiological influence of hypertension, hyperosmolarity, sepsis, and other factors known to open the BBB and to contribute to GMH.     

Limited intravascular coupling in the rodent brainstem and retina supports a role for glia in regional blood flow

Regional synaptic activity induces local increases in perfusion that are coupled to upstream vasodilation and improved blood flow. In the cerebral circulation, it has been proposed that astrocytes mediate the link between the initiating stimulus and local vasodilation through propagated intracellular calcium waves. In the systemic circulation the mechanism by which local vasodilation triggers upstream alterations in blood flow involves electrotonic propagation of hyperpolarization via endothelial gap junctions, although less is known concerning the cerebral circulation. The present study aimed to investigate the extent of coupling in microvessels of the rodent brainstem and retina and the subtypes of intracellular calcium stores that might mediate astrocytic signaling. Within the brainstem, connexins (Cxs) 37 and 40 were restricted to the endothelium of pial vessels and larger penetrating arterioles, whereas astrocytic Cxs30 and 43 were found closely associated with pre- and postsynaptic neurons and nearby microvessels. Within the rat retina, Cxs37 and 40 were expressed in large radiating arterioles, but were not found in smaller vessels on the retinal surface or in the deeper retinal layers. These Cxs were absent from all retinal vessels in mice. Astrocytes, expressing Cxs30 and 43 in the rat, but only Cx43 in the mouse, were found closely associated with superficial, but not deeper blood vessels. Inositol-trisphosphate receptors (IP(3)R) 1 and 2 were expressed within brainstem astrocytes, whereas IP(3)R1 and 3 were expressed within retinal astrocytes. Limited intravascular coupling and the proximity of astrocytic networks to blood vessels supports a role for glia in activity-dependent alterations in central blood flow.     

Astrocytes secrete basal lamina after hemisection of rat spinal cord

Basal lamina is reconstructed over the lesioned surface of the spinal cord. The following experiment (90 rats) studies the ultrastructure of the formation of this membrane and the immunohistochemistry of laminin production (a major secreted component of basal lamina). After hemisection of the spinal cord at T6 animals were prepared for electron microscopy or antilaminin-biotin-avidin-peroxidase incubation. Three-5 days posthemisection, antilaminin reaction product was observed in astrocytes and their processes which faced the lesion, endothelia of blood vessels or pia. Ultrastructurally (3 days), basal lamina was polymerizing as small projections on the surface of astrocytic membranes facing the lesion, endothelia or pia. By 5 days the basal lamina was a single membrane, folded multiple sheets or in swirls. At 6-10 days the antilaminin reaction and the basal lamina (except for duplications) did not differ from normal. Reactive astrocytes secrete laminin for at least 3-5 days after hemisection and form basal lamina on the lesioned surface of the spinal cord after spinal cord hemisection.     

Copper deficiency elicits glial and neuronal response typical of neurodegenerative disorders

Dysregulation of copper homeostasis has been associated with neurodegenerative diseases including Alzheimer's disease, amyotrophic lateral sclerosis (ALS) and prion diseases. The investigation of the role of abnormal copper level in the development of neuropathological damage is essential for the understanding of pathogenetic mechanisms of these neurodegenerative disorders. Using a mouse model of perinatally induced copper deficiency, the present study analysed the response of neuronal and glial cells to copper deficiency from infancy to young adult age. In mice born and maintained after weaning on copper-deficient diet, copper measurements indicated that at 6-8 weeks the copper levels in the brain were decreased by about 80% with respect to controls. In the brain of copper-deficient mice, microglial and astrocytic activation was observed, mostly in the cerebral cortex and thalamus. In addition, small vacuolated globoid cells confined to the subgranular zone of the dentate gyrus were found in the third postnatal week, and larger vacuolar profiles, identified as neuronal vacuoles, were observed in layer V of the cortex after the fourth week. The spatial distribution and temporal onset of vacuolation appeared to be unrelated to those of activated microglia and astrocytes. Nitrotyrosine-positivity was found to reflect the distribution of vacuoles in the cortex. The specific histopathological features here reported, as well as the severity of neurological deficits observed in this murine model of copper deficiency, strongly suggest that some hallmarks of neurodegenerative disorders could be mediated by multifactorial pathogenetic mechanisms that include copper dysregulation.     

Altered plasma membranes in experimental scrapie

Summary The status spongiosus in the cerebral cortex of mice affected with two different strains of scrapie virus corresponded to focally swollen perikaryal cytoplasm of nerve cells and astrocytes, to swollen neuronal and astrocytic processes and to membrane-bounded vacuoles within pre- and postsynaptic neuronal terminals. The swollen cytoplasm contained uniformly dispersed, finely granulo-filamentous material. A few enlarged dendrites were filled with fragments of membranes or 350 Å wide vesicular and tubular structures suggestive of virus particles. Ruptured plasma membranes and curled fragments of membranes were seen around cleared cytoplasmic regions and within membrane-bounded vacuoles. Neurons or astrocytes that lined affected cells or processes frequently showed similar changes. Confluence of swollen cells or processes occurred after dissolution of their adjacent plasma membranes. Astrocytes reacted to the injury by proliferation whereas nerve cells degenerated. The findings are compared to those seen in other subacute spongiform virus encephalopathies, i. e., mink encephalopathy, Kuru and Creutzfeldt-Jakob disease. The characteristic vacuolar degeneration of nerve cells in these diseases which is associated with fragmentation and accumulation of plasma membranes is discussed with reference to the peculiar properties of the scrapie virus.This investigation was supported in part by United States Public Health Research Grant NS-09053 from the National Institute of Neurological Diseases and Stroke, National Institutes of Health, Bethesda, Maryland.     

Ischemia-induced apoptosis in primary cultures of astrocytes.

Astrocytes participate in a wide variety of important physiological processes and pathological insults, including ischemia. Information on the mechanism of astroglial injury and death during ischemic insult, however, is scarce. In this study, we investigated the mode of astrocytic cell death using an in vitro ischemic model. Cultured astrocytes exhibited several distinct morphological and biochemical features of apoptosis under ischemia. At 4 h of ischemia, Annexin V staining demonstrated an early commitment of some astrocytes to apoptosis. Condensed nuclei became visible from 4 h and the number increased with ischemic incubation time. Electron microscopy showed compacted and segregated chromatin along the edges of nuclear membranes. The number of TUNEL-positive nuclei and the degree of DNA laddering increased with ischemic incubation. Caspase-3, but not caspase-1, activity was increased in ischemia-injured astrocytes. Swollen mitochondria and vacuoles found in some cells with chromatin condensation indicated that these apoptotic-like cells might die of necrosis. The results imply that astrocytes are capable of undergoing apoptosis without the presence of other cell types, such as neurons. Ischemia can induce apoptosis in astrocytes contributing to the pathogenesis of ischemic injury in the CNS.     

Freeze-fracture ultrastructure of the perinodal astrocyte and associated glial junctions

Freeze-fracture examination of nodes of Ranvier from adult rat optic nerve demonstrates the presence of astrocytic processes at the majority of nodes of Ranvier. Astrocytic processes often run along the entire length of the nodal gap, although they do not necessarily encircle the entire nodal circumference. The E- and P-fracture faces and the cross-fractured cytoplasm of these astrocytes (termed 'perinodal astrocytes') were examined. The cytoplasm of perinodal astrocytes contains 10-nm filaments. The P-faces of perinodal astrocytic membranes are characterized by orthogonal arrays of intramembranous particles ('assemblies'), with a center-to-center periodicity of approximately equal to 6 nm. Complementary orthogonally arranged pits are observed on the E-faces of the astrocytic membranes. The density of these arrays in perinodal astrocytic membranes is similar to that in parenchymal astrocytic membranes, but is substantially lower than that at pericapillary astrocytic membranes. In addition, gap junctions are present between astrocytes, and between astrocytes and paranodal oligodendroglial layers. These findings indicate that astrocytic processes comprise an important structural component of central nodes of Ranvier, and provide a morphological basis for a possible astrocytic role in nodal function.