Molecular profile of reactive astrocytes--implications for their role in neurologic disease

The use of transplanted glial cells to reconstruct glial environments in the CNS

Transplantation studies have demonstrated that glia-depleted areas of the CNS can be reconstituted by the introduction of cultured cells. Thus, the influx of Schwann cells into glia-free areas of demyelination in the spinal cord can be prevented by the combined introduction of astrocytes and cells of the O-2A lineage. Although Schwann cell invasion of areas of demyelination is associated with destruction of astrocytes, the transplantation of rat tissue culture astrocytes ("type-1") alone cannot suppress this invasion, indicating a role for cells of the O-2A lineage in reconstruction of glial environments. By transplanting different glial cell preparations and manipulating lesions so as to prevent meningeal cell and Schwann cell proliferation it is possible to demonstrate that the behaviour of tissue culture astrocytes ("type-1") and astrocytes derived from O-2A progenitor cells ("type-2") is different. In the presence of meningeal cells, tissue culture astrocytes clump together to form cords of cells. In contrast, type-2 astrocytes spread throughout glia-free areas in a manner unaffected by the presence of meningeal cells or Schwann cells. Thus, progenitor-derived astrocytes show a greater ability to fill glia-free areas than tissue culture astrocytes. Similarly, when introduced into infarcted white matter in the spinal cord, progenitor-derived astrocytes fill the malacic area more effectively than tissue culture astrocytes, although axons do not regenerate into the reconstituted area.

Remyelination of mouse spinal cord axons demyelinated by local injection of lysolecithin

Local injections of lysolecithin are commonly used to produce areas of demyelination in the CNS. For the mouse, the demyelinating initial phase of lesion development has been described previously but the spontaneous repair which follows has not. In this study we describe the morphological sequelae which result from the injection of 2 microliters of 1% lysolecithin into the spinal cord of adult mice. Lesion length was variable, extending 8 mm or more in 33% of lesioned animals. By 7 days after injection very little extracellular myelin debris was detected and remyelination had commenced. Remyelination progressed rapidly so that almost all axons were invested by myelin sheaths by 23 days. Remyelination was accompanied by a prominent astrocytosis. The long lesion length and the rapidity of repair has important implications for studies designed to assess the ability of transplanted myelinogenic cells to migrate towards demyelinating lesions.

Regeneration in the adult mammalian CNS: guided by development

In the past year, the roles and mechanisms of molecules involved in cell survival (glial-derived neurotrophic growth factor), growth cone guidance (netrins and semaphorins), axonal outgrowth and sorting (neural cadherin, polysialylated neural cell adhesion molecules, and L1), and neuronal connectivity (cell adhesion molecules, dystroglycan, and agrin) have been described during development and, to a limited extent, in the mature CNS. Evidence is now emerging that some developmental events, such as the expression of polysialylated neural cell adhesion molecule and L1, are recapitulated during adult CNS regeneration. These results suggest new avenues to address more accurately the challenges of axonal regrowth in the adult mammalian CNS.

Evidence for the role of protein kinase C in astrocyte-induced proliferation of rat cerebromicrovascular endothelial cells

The proliferation of cerebral endothelial cells is a crucial step in neural angiogenesis and is a process responsive to changes in the surrounding environment. Serum-free medium conditioned by rat cortical astrocytes was found to accelerate DNA synthesis, induce transient activation of protein kinase C (PKC), and increase the endogenous phosphorylation of the PKC-specific substrate, the 85 kDa MARCKS protein, in rat cerebromicrovascular endothelial cells (RCEC). The stimulatory factor(s) in astrocyte conditioned media (ACM) were heat- and trypsin-sensitive and found to have an apparent molecular weight greater than 10 kDa. The potent PKC activator, 12-O-tetradecanoyl phorbol 13-acetate (TPA), also stimulated RCEC proliferation, whereas the inhibition of PKC by staurosporine caused a concomitant loss in ACM-induced PKC translocation, MARCKS protein phosphorylation and DNA synthesis. These findings implicate PKC activation as a critical early event in cerebral endothelial cell proliferation triggered by astrocyte-derived mitogen(s).

The inflammatory response system of brain: implications for therapy of Alzheimer and other neurodegenerative diseases

Cultured brain cells are capable of generating many molecules associated with inflammatory and immune functions. They constitute the endogenous immune response system of brain. They include complement proteins and their regulators, inflammatory cytokines, acute phase reactants and many proteases and protease inhibitors. Most of the proteins are made by microglia and astrocytes, but even neurons are producers. Many appear in association with Alzheimer disease lesions, indicating a state of chronic inflammation in Alzheimer disease brain. Such a state can apparently exist without stimulation by peripheral inflammatory mediators or the peripheral immune system. A strong inflammatory response may be autotoxic to neurons, exacerbating the fundamental pathology in Alzheimer disease and perhaps other neurological disorders. Autotoxic processes may contribute to cellular death in chronic inflammatory diseases affecting other parts of the body, suggesting the general therapeutic value of anti-inflammatory agents. With respect to Alzheimer disease, multiple epidemiological studies indicate that patients taking anti-inflammatory drugs or suffering from conditions in which such drugs are routinely used, have a decreased risk of developing Alzheimer disease. In one very preliminary clinical trial, the anti-inflammatory drug indomethacin arrested progress of the disease. New agents directed against the inflammatory processes revealed in studies of Alzheimer disease lesions may have broad therapeutic applications.

The concept of trophic units in the central nervous system

The present paper proposes that trophic interplay among cells may represent the final common pathway for both genetic and environmental influences, and hence new criteria for the understanding of central nervous system (CNS) connectivity can be suggested. In particular, trophic signals may make up the common "language" through which genetic and epigenetic influences mold the CNS during development and the adult life. Furthermore, it will put forward the hypothesis that the developmental trophic interplay among cells leads to the formation of trophic units in the adult brain. A trophic unit is defined as the smallest set of cells, within the CNS, which act in a complementary way to support each other's trophism. The trophic units consist of neurons, glial cells, blood vessels, extracellular matrix (ECM). In particular, ECM gives support to the thin elongated cell processes and gives rise to selective chemical bridges between cell surfaces or between cell surfaces and the extracellular milieu. The trophic unit is a plastic device that not only assures neuronal survival, but also operates to adapt neuronal networks to new tasks by controlling extension of neuronal processes, synapse turnover and ECM characteristics. These plastic responses depend on the interplay of all the elements that constitute the trophic units. The concept of trophic unit may help to understand some features of neurodegenerative diseases, for example, the clustering of tangles in the neocortex and in the entorhinal cortex of Alzheimer's patients [corrected].

Inhibition of inducible nitric oxide synthase mRNA expression by basic fibroblast growth factor in human microglial cells

The effect of basic fibroblast growth factor (bFGF) on inducible nitric oxide synthase (iNOS) mRNA expression in human cultured ramified microglial cells was investigated. Using RT-PCR and Southern blot analysis, we found that bFGF prevented the iNOS gene expression as induced by LPS/TNF alpha. Also, bFGF dose-dependently inhibited nitrite levels in treated cell supernatants. That the early presence of bFGF during LPS/TNF alpha induction was essential indicates that iNOS gene expression can be transcriptionally regulated.

LSL 60101, a selective ligand for imidazoline I2 receptors, on glial fibrillary acidic protein concentration

The concentration of the astrocytic marker, glial fibrillary acidic protein (GFAP) was quantitated by immunoblotting (Western blotting) in the rat brain after treatment with the novel ligand for imidazoline I2 receptors LSL 60101 [2-(2-benzofuranyl)imidazole] and its 6-methoxy derivative LSL 60125. Chronic (7-21 days), but not acute (1 day) or short-term (3 days), treatment with LSL 60101 (10 mg/kg i.p.) markedly increased (44-49%) GFAP immunoreactivity in the rat cerebral cortex. In contrast, chronic (7 days) treatment with LSL 60125 (10 mg/kg i.p.) did not significantly modify GFAP concentrations. In vitro, both drugs displayed moderate high affinity and high selectivity for imidazoline I2 receptors versus alpha 2-adrenoceptors; however, only chronic treatment with LSL 60101 (10 mg/kg i.p.) but not with LSL 60125 (10 mg/kg i.p.) was associated with an up-regulation of imidazoline I2 receptors. These data indicate that glial imidazoline I2 receptors may have a direct physiological function related to GFAP expression and that LSL 60101 could be a good tool for the study of the implication of these receptors on astrocyte activation and neuronal regeneration.

The unique characteristics of inflammatory responses in mouse brain are acquired during postnatal development

The kinetics of leukocyte recruitment during acute inflammation in adult mouse brain differ from the stereotyped response occurring in non-CNS tissues; neutrophil recruitment is minimal and monocyte recruitment occurs after a 48 h delay. One aspect of the CNS microenvironment which may contribute to restricted leukocyte recruitment is the highly differentiated nature of resident CNS macrophages, the microglia. Thus we studied the inflammatory response to intracerebral injections of endotoxin in neonates in which microglia are less differentiated and resemble more closely macrophages of non-CNS tissues. Mice injected with endotoxin on the day of birth exhibited both neutrophil and monocyte recruitment to the parenchyma, but the response differed from that occurring in non-CNS tissues such as skin. Leukocyte recruitment was very slow, the mononuclear phagocyte response peaking 14 days after endotoxin injection. This sluggish inflammatory response was reminiscent of that previously described in fetal wounds. However, when endotoxin was injected into brains of 7-day-old neonates the inflammatory response resembled that seen in non-CNS tissues; i.e. prolific neutrophil recruitment and a brisk mononuclear phagocyte response. Thus the unusual inflammatory cell kinetics are a property of the mature CNS microenvironment; all signals necessary to support typical leukocyte recruitment are present in the brain by 7 days of age but the brain becomes able to restrict leukocyte immigration during subsequent postnatal development. Developmental changes in the host response to identical inflammatory challenges suggest a window during which the brain may be particularly vulnerable to inflammatory bystander damage.

A role for ciliary neurotrophic factor as an inducer of reactive gliosis, the glial response to central nervous system injury

Within the central nervous system (CNS) ciliary neurotrophic factor (CNTF) is expressed by astrocytes where it remains stored as an intracellular protein; its release and function as an extracellular ligand are thought to occur in the event of cellular injury. We find that overexpression of CNTF in transgenic mice recapitulates the glial response to CNS lesion, as does its injection into the uninjured brain. These results demonstrate that CNTF functions as an inducer of reactive gliosis, a condition associated with a number of neurological diseases of the CNS.

Neuropathogenic actions of cytokines assessed in transgenic mice

Cytokines are potent biological response modifiers that exhibit a spectrum of cellular actions. These factors have been implicated as important mediators of physiologic and possibly pathophysiologic processes within the CNS. Targeting the expression of cytokines to specific tissues in transgenic mice has provided a powerful approach to the investigation of complex cellular responses at a localized level and also recapitulated more closely the expression of these mediators as found in pathogenetic processes. This review will focus on the recent application of transgenic technology to achieve the specific cerebral expression of cytokines. The targeting of cytokine gene expression to astrocytes in transgenic mice has provided new and dramatic insights into the CNS pathobiology of these host-response molecules. Specifically: (1) transgenic expression of the cytokines IL-6, IL-3 and IFN-alpha in the CNS results in the development of acute (high expression) or chronic progressive (low expression) CNS disease associated with a spectrum of clinical, physiologic and pathologic manifestations; (2) although the clinical, cellular and molecular phenotype produced by the cerebral expression of the various cytokines showed some overlap, the differences were more prominent reflecting the unique actions of each cytokine; (3) these transgenic models which recapitulate many of the structural and functional impairments seen in human neurodegenerative diseases, highlight the point that cytokines, which normally function as primary regulators of the host response, also have the potential to mediate significant injury in the CNS. Therefore, these transgenic models have provided a valuable tool for advancing our understanding of the CNS pathobiology of cytokines and will no doubt offer a unique resource for the development and testing of therapies aimed at abrogating the toxic actions of these important mediators.

Interferon-gamma and lipopolysaccharide reduce cAMP responses in cultured glial cells: reversal by a type IV phosphodiesterase inhibitor

The aim of the present study was to determine whether two classical macrophage activators, bacterial lipopolysaccharide (LPS) and interferon-gamma (IFN-gamma) could affect the accumulation of the second messenger cAMP in cultured rat microglia and astrocytes. Purified microglia and astrocyte secondary cultures obtained from the neonatal rat were grown for 3 days in basal medium Eagle (BME) + 10% fetal calf serum (FCS). Exposure of microglia to LPS resulted into a dose- and time-dependent decrease in the accumulation of cAMP induced by receptor-mediated (isoproterenol or prostaglandin E2) or direct (forskolin) activation of adenylate cyclase. The inhibitory effect of LPS was rapid (a 10 min preincubation was sufficient to approach a maximal effect), occurred at low doses (IC50 = 1.2 ng/ml), and was not abrogated by pertussis toxin. A selective inhibitor of type IV phosphodiesterase (rolipram, 100 nM) prevented the effect of LPS on cAMP accumulation, while inhibitors of other forms of phosphodiesterase were unable to do so. IFN-gamma (100 u/ml) also caused a depression of the evoked cAMP accumulation in microglia after a 10 min preincubation, and its effect was prevented by rolipram, as in the case of LPS. Astrocytes differed from microglia in that LPS (1-100 ng/ml) did not inhibit the accumulation of cAMP induced by either isoproterenol or forskolin; on the other hand, IFN-gamma did have an inhibitory effect (though less pronounced than in microglia) that could be prevented by rolipram.(ABSTRACT TRUNCATED AT 250 WORDS)

Cytokine regulation of astrocyte function: in-vitro studies using cells from the human brain

Participation of astrocytes in central nervous system pathophysiology is likely to involve cytokines, both as stimulators and mediators of astrocyte function. We have used highly enriched human astrocyte cultures as an experimental tool to investigate the influence of cytokines on adhesion molecule expression and synthesis of mediators that are probably important in immune and inflammatory reactions involving the nervous system and in cerebral tissue repair. The response of astrocytes to interferon-gamma mainly resulted in increased expression of major histocompatibility complex antigens and co-stimulatory molecules (intercellular adhesion molecule-1, LFA-1 alpha) which mediate astrocyte-T-cell interactions. Another co-stimulatory molecule, B7, was neither expressed nor inducible by IFN-gamma and other cytokines. TNF-alpha and IL-1 beta were more efficient in stimulating synthesis of immunoregulatory and proinflammatory cytokines (IL-6, IL-8 and colony-stimulating factors), cytokine antagonists (TNF-alpha soluble receptors), or cytokines with a possible neuroprotective role (leukemia inhibitory factor); they also increased expression of some co-stimulatory molecules (intercellular adhesion molecule-1 and vascular cell adhesion molecule-1). Transforming growth factor-beta 1 was a strong inducer of leukemia inhibitory factor, but did not affect either major histocompatibility complex/co-stimulatory molecule expression or cytokine synthesis. Thus, different cytokines activate distinct functional programs in astrocytes, which may play a specific role in different brain diseases or at different stages of the same disease. It was additionally observed that the response of human astrocytes to cytokines (in particular the inducible synthesis of certain cytokines) varied greatly depending on the presence or absence of neurons in the culture system. This finding suggests that neuronal-glial interactions may be implicated in determining the activation threshold of astrocytes to inflammatory cytokines.

HIV-gp120 activates large-conductance apamin-sensitive potassium channels in rat astrocytes

Central nervous system (CNS) involvement usually occurs in individuals infected with human immunodeficiency virus type 1 (HIV-1). Evidence is now accumulating that neurons and astrocytes may be functionally compromised by exposure to viral components or cellular factors released from HIV-1-infected macrophages and/or microglia. We have previously reported that the HIV coat protein gp120 stimulates Na+/H+ exchange in primary cultured rat astrocytes, which, ultimately, results in the activation of a K+ conductance. In this report we characterize the electrophysiological and biophysical properties of the channels responsible for the gp120-induced increase in K+ conductance. These K+ channels had a relatively large unitary conductance (147 pS), were not gated by voltage, were sensitive to changes in H+ concentration at their cytosolic face, were specifically inhibited by apamin, and were insensitive to charybdotoxin and tetraethylammonium. The activation of these channels by gp120 is referable to cellular alkalinization subsequent to Na+/H+ exchange stimulation; gp120 failed to activate these K+ channels in the absence of external Na+ or in the presence of amiloride, an inhibitor of Na+/H+ exchange. Subsequent K+ loss from the astrocyte into the restricted extracellular space surrounding neurons can then lead to neuronal depolarization, activation of voltage-sensitive Ca2+ channels, and, eventually, cell death. Thus abnormal activation of astrocyte K+ channels by gp120 may contribute to the CNS pathophysiology associated with HIV-1 infection.

beta-Amyloid precursor protein-deficient mice show reactive gliosis and decreased locomotor activity

In several pedigrees of early onset familial Alzheimer's disease (FAD), point mutations in the beta-amyloid precursor protein (APP) gene are genetically linked to the disease. This finding implicates APP in the pathogenesis of Alzheimer's disease in these individuals. To understand the in vivo function of APP and its processing, we have generated an APP-null mutation in mice. Homozygous APP-deficient mice were viable and fertile. However, the mutant animals weighed 15%-20% less than age-matched wild-type controls. Neurological evaluation showed that the APP-deficient mice exhibited a decreased locomotor activity and forelimb grip strength, indicating a compromised neuronal or muscular function. In addition, four out of six homozygous mice showed reactive gliosis at 14 weeks of age, suggesting an impaired neuronal function as a result of the APP-null mutation.

Induction of MMP9 (92 kDa gelatinase) activity and expression of tissue inhibitor of metalloproteinase-2 mRNA (TIMP-2) in primitive neuroectodermal cells infected with retrovirus HTLV-I

Matrix-degrading proteases, including metalloproteinases (MMPs) and tissue inhibitors of metalloproteinases (TIMPs), are involved in modulation of the extracellular matrix, which participates in neural cell differentiation, brain morphogenesis and tissue integrity. Metalloproteinases and TIMPs are associated with inflammatory and degenerative processes in the central nervous system and are regulated by cytokines. Human retroviral infections are frequently associated with neurological disturbances. In the present paper, we have studied the changes occurring in human primitive neuroectodermal cells following infection with human T cell lymphotropic virus type 1 (HTLV-I), a retrovirus responsible for HTLV-I-associated myelopathy. Infected neural cells were found to have high metalloproteinase 9 (MMP9-92 kDa gelatinase) activity. MMP9 induction is dependent on HTLV-I infection of neural cells. In addition, soluble factors, especially tumour necrosis factor alpha, secreted by infected cells, act as mediators of induction. HTLV-I infection also induces expression of RNA coding for tissue inhibitor of metalloproteinase 2. These observations indicate that HTLV-I infection selectively modulates the expression of molecules involved in the dynamic equilibrium between the synthesis and degradation of the neural cell matrix and leads to its remodelling, which modifies cell-cell interactions and cellular function.

Meninges play a neurotrophic role in the regeneration of vasopressin nerves after hypophysectomy

Following hypophysectomy the regenerating fibers of magnocellular neurons are known to establish new neurohemal connections with reorganized vasculatures in the median eminence, which lead to establishment of a posterior pituitary-like structure. In order to examine the role of the meninges (the pia mater and the arachnoid) in this regeneration process, we implanted the meningeal tissues obtained from neonatal rat pups into the third ventricle of the adult rats, and then hypophysectomized the host animals. Ten days after hypophysectomy, the meningeal tissue grafts were found to be densely innervated by regenerating vasopressin-immunoreactive fibers. Such fibers had dots and frequently formed large punctuations. On the contrary, few vasopressin fibers were found within the cortical tissue grafts. Further, the exposure of primary hypothalamic cell cultures to the medium conditioned by meningeal cell cultures promoted not only the survival of vasopressin-immunoreactive neurons but also the outgrowth and aborization of the neurites. The survivals of cortical and cerebellum neurons in culture were also promoted by the conditioned medium. These findings raise the possibility that the meninges play an important role in the axonal regeneration process after hypophysectomy.

Macrophage inflammatory protein 1-alpha mRNA expression in an immortalized microglial cell line and cortical astrocyte cultures

Macrophage inflammatory protein 1 (MIP-1) is a recently characterized inflammatory and chemokinetic cytokine. Proinflammatory stimuli have been shown to induce expression of MIP-1 by macrophages. We hypothesized that microglia and astrocytes express MIP-1 alpha because of their many immunologic similarities to macrophages. MIP-1 alpha mRNA was examined with quantitative reverse transcription and polymerase chain reaction in an immortalized mouse microglial cell line (BV-2) and in mouse cortical astrocyte cultures. We found that in both the BV-2 microglial cell line and in astrocyte cultures, MIP-1 alpha mRNA was strongly induced by lipopolysaccharide and the phorbol ester PMA. MIP-1 alpha mRNA was reduced by dBcAMP, interferon-gamma, and PGE1. Dexamethasone decreased MIP-1 alpha mRNA levels in astrocyte cultures, but not in BV-2 microglial cells. Interleukin-1 beta, tumor necrosis factor alpha, and MIP-1 alpha had no effect on MIP-1 alpha mRNA expression. These findings demonstrate that MIP-1 alpha mRNA is expressed by cultured glial cells and is regulated by proinflammatory and anti-inflammatory stimuli. MIP-1 alpha may be expressed by microglia and astrocytes in vivo, and may help modulate cerebral inflammation.

Induction of Jun-like immunoreactivity in astrocytes in gerbil hippocampus with ischemic tolerance

In order to evaluate the potential involvement of immediate early genes in ischemic tolerance, we examined Fos- and Jun-related protein immunoreactivity in gerbil brain. Two minutes of preconditioning ischemia or sham operation was followed by 3-min ischemia 3 days later. The animals were sacrificed after 4 h to 7 days of survival. Fos immunoreactivity was seen in dentate hilar neurons 4 h after 3-min ischemia regardless of preconditioning. Jun immunoreactivity increased in dentate granule cells 4 h after 3-min ischemia without preconditioning. Prominent Jun immunoreactivity was induced in astrocytes in the CA1 region of the gerbils with ischemic tolerance. The result suggests that Jun may contribute to the ischemic tolerance by inducing changes in gen expression in astrocytes.

Macrophages, microglia, and astrocytes are rapidly activated after crush injury of the goldfish optic nerve: a light and electron microscopic analysis

Several matrix and adhesion molecules in fish optic nerve, which are constitutively expressed, are increased during axonal regeneration and are primarily associated with nonneuronal cells (W.P. Battisti, Y. Shinar, M. Schwartz, P. Levitt, and M. Murray [1992] J. Neurocytol. 21:557-573). The current study examines the reactions of specific cell types to optic nerve crush and axonal regeneration. The goldfish optic nerve contains macroglia and microglia as well as a population of monocyte-derived cells (granular macrophages) unique to goldfish. Two cell types were OX-42 positive (granular macrophages and microglia), indicating monocyte lineage, each with a distinct morphology and distribution within the nerve. Within hours of the optic nerve crush, the number of OX-42-labeled cell profiles increased near the crush site, remained elevated during the time axons were elongating, and then declined. Microglia, but not granular macrophages, were phagocytically active. Astrocytes are readily identified in the normal optic nerve, but they exhibited marked morphologic changes within hours of injury, which is consistent with the contribution these cells make to the altered environment. Oligodendroglia could not be reliably identified in regenerating optic nerves until myelin was formed. A comparison of the distribution of OX-42-labeled cells with that of transforming growth factor beta-1 (TGF-beta 1) and tenascin suggests that these molecules are expressed by granular macrophages. Tenascin staining may be additionally associated with astrocytes and/or microglia. The rapid response of these nonneuronal cells to injury, their rapid phagocytic activity, and the secretion of growth-promoting factors by these cells likely contributes to the environment that supports robust regeneration by optic axons in the goldfish.

Early association of reactive astrocytes with senile plaques in Alzheimer's disease

The fibrillar beta-amyloid protein (A beta) plaques of Alzheimer's disease (AD) are associated with reactive astrocytes and dystrophic neurites and have been suggested to contribute to neurodegenerative events in the disease. We recently reported parallel in vitro and in situ findings, suggesting that the adoption of a reactive phenotype and the colocalization of astrocytes with plaques in AD may be mediated in large part by aggregated A beta. Thus, A beta-mediated effects on astrocytes may directly affect disease progression by modifying the degenerative plaque environment. Alternatively, plaque-associated reactive astrocytosis may primarily represent a glial response to the neural injury associated with plaques and not significantly contribute to AD pathology. To investigate the validity of these two positions, we examined the differential colocalization of reactive astrocytes and dystrophic neurites with plaques. Hippocampal sections from AD brains--ranging in neuropathology from mild to severe--were triple-labeled with antibodies recognizing A beta protein, reactive astrocytes, and dystrophic neurites. We observed not only plaques containing both or neither cell type, but also plaques containing (1) reactive astrocytes but not dystrophic neurites and (2) dystrophic neurites but not reactive astrocytes. The relative proportion of plaques colocalized with reactive astrocytes in the absence of dystrophic neurites is relatively high in mild AD but significantly decreases over the course of the disease, suggesting that plaque-associated astrocytosis may be an early and perhaps contributory event in AD pathology rather than merely a response to neuronal injury. These data underscore the potentially significant contributions of reactive astrocytosis in modifying the plaque environment in particular and disease progression in general.

Cryogenic spinal cord injury induces astrocytic gene expression of insulin-like growth factor I and insulin-like growth factor binding protein 2 during myelin regeneration

To study injury-induced astrocytic responses associated with regrowth of axons and regeneration of myelin, the method of Collins and colleagues was used to make focal cryogenic lesions in spinal cords of adult rats (Collins et al.: J Neuropathol Exp Neurol 45: 742-757, 1986). The duration of cryogenic injury (CI), the size of the cryode, and its temperature were chosen to destroy all myelin sheaths and axons without producing cavities or hemorrhages. Messenger RNA and peptide distributions of insulin-like growth factor I (IGF-I), IGF-I receptor (IGFR-I), IGF binding protein 2 (IGFBP-2), glial fibrillary acidic protein (GFAP), and myelin basic protein (MBP) were studied 3-56 days after CI by in situ hybridization and immunocytochemistry. At 3 days, vimentin-positive, GFAP-negative astrocyte-like cells in the lesion expressed IGF-I mRNA and peptide and 7 days after CI, both were expressed by typical GFAP-positive, hypertrophic astrocytes, many of which also were vimentin-positive. Levels of IGF-I, IGFBP-2, and GFAP mRNA and peptide were higher in lesion astrocytes after 14 days. They attained maximum levels at 21-28 days before declining to near control levels at 56 days. Decreasing relative levels of oligodendroglial MBP mRNA were found in and around lesions 7-14 days after CI; subsequently, rising levels accompanied remyelination. At 28 and 56 days after CI, some transferrin-positive, oligodendroglia-like cells also were immunostained by anti-IGFR-I. Our findings suggest that early astrocytic production of IGF-I and IGFBP-2 may be involved in the myelin regeneration which occurs in this model of spinal cord injury.

Indicator expression directed by regulatory sequences of the glial fibrillary acidic protein (GFAP) gene: in vivo comparison of distinct GFAP-lacZ transgenes

An increase in the expression of the glial fibrillary acidic protein (GFAP) gene by astrocytes appears to constitute a crucial component of the brain's response to injury because it is seen in many different species and features prominently in diverse neurological diseases. Previously, we have used a modified GFAP gene (C-339) to target the expression of beta-galactosidase (beta-gal) to astrocytes in transgenic mice (Mucke et al.; New Biol 3:465-474 1991). To determine to what extent the in vivo expression of GFAP-driven fusion genes is influenced by intragenic GFAP sequences, the E. coli lacZ reporter gene was either placed downstream of approximately 2 kb of murine GFAP 5' flanking region (C-259) or ligated into exon 1 of the entire murine GFAP gene (C-445). Transgenic mice expressing C-259 versus C-445 showed similar levels and distributions of beta-gal activity in their brains. Exclusion of intragenic GFAP sequences from the GFAP-lacZ fusion gene did not diminish injury-induced upmodulation of astroglial beta-gal expression or increase beta-gal expression in non-astrocytic brain cells. These results demonstrate that 2 kb of murine GFAP 5' flanking region is sufficient to restrict transgene expression primarily to astrocytes and to mediate injury-responsiveness in vivo. This sequence therefore constitutes a critical target for mediators of reactive astrocytosis. While acute penetrating brain injuries induced focal increases in beta-gal expression around the lesion sites in C-259, C-445, and C-339 transgenic mice, infection of C-339 transgenic mice with scrapie led to a widespread upmodulation of astroglial beta-gal expression. Hence, GFAP-lacZ transgenic mice can be used to monitor differential patterns of astroglial activation in vivo. These and related models should facilitate the assessment of strategies aimed at the in vivo manipulation of GFAP expression and astroglial activation.

Disruption of the blood-brain interface in neonatal rat neocortex induces a transient expression of metallothionein in reactive astrocytes

Exposure of the adult rat brain parenchyma to zinc induces an increase in the intracerebral expression of the metal-binding protein, metallothionein, which is normally confined to astrocytes, ependymal cells, choroid plexus epithelial cells, and brain endothelial cells. Metallothionein is expressed only in diminutive amounts in astrocytes of the neonatal rat brain, which could imply that neonatal rats are devoid of the capacity to detoxify free metals released from a brain wound. In order to examine the influence of a brain injury on the expression of metallothionein in the neonatal brain, PO rats were subjected to a localized freeze lesion of the neocortex of the right temporal cortex. This lesion results in a disrupted blood-brain interface, leading to extravasation of plasma proteins. From 16 h, reactive astrocytosis, defined as an increase in the number and size of cells expressing GFAP and vimentin, was observed surrounding the neocortical lesion site. Astrocytes and pial cells situated adjacent to the area of injury also became positively stained for metallothionein. At 3-6 days post-lesion, the highest level of reactive astrocytes expressing metallothionein was observed. Neo-Timm staining revealed that histochemically reactive zinc had disappeared from the lesion site. Extracellular albumin and metallothionein-positive astrocytes were absent approximately 2 weeks after the lesion, whereas reactive astrocytosis was still observed. These results show that a lesion of the neonatal rat brain induces a transient expression of metallothionein in reactive astrocytes, probably as a response to metals released from the site of the brain injury.

Altered pattern of immunohistochemical staining for glial fibrillary acidic protein (GFAP) in the forebrain and cerebellum of the mutant spastic rat

The spastic rat is a neurological mutant of the Han-Wistar strain with prominent spasticity, tremor, and ataxia. Neurodegeneration is found in the CA3 sector of the hippocampus and in Purkinje cells of the cerebellum. We examined the forebrain and cerebellum of spastic rats for glial reactions by using immunolabelling for the astrocytic marker, glial fibrillary acidic protein (GFAP). First, a map of the GFAP-distribution was made representing a systematic series of frontal sections in controls. Reactive astrocytes with increased GFAP should occur in the areas with established neuronal degeneration, but they could also demarcate further regions with pathology in this rat strain. Since the baseline levels of GFAP-immunoreactivity differ between brain regions, control rats and clinically normal littermates served as controls to judge relative increases in major structures. In the CA3 sector and hilus of the dorsal hippocampus, a massive gliosis was detected. In the cerebellum, a patchy increase of GFAP labelling in Bergmann glia was found. Further increases of GFAP-labelling in reactive astrocytes occurred in fiber tracts, the ventral thalamic nuclei, medial geniculate nuclei, pontine region and optic layer of the superior colliculus. Inconsistent changes were noted in cortex and pallidum. No defects of glial labelling or malformations in glial architectonics were found. The reactive changes of astroglial cells in hippocampus and cerebellum are in proportion to the neuronal degeneration. The glial reactions in the other brain regions possibly reflect a reaction to fiber degeneration and incipient neuronal degeneration or functional alterations of glial cells in response to neuronal dysfunction.

Induction of focal spongiform neurodegeneration in developmentally resistant mice by implantation of murine retrovirus-infected microglia

FrCasE is a highly neurovirulent murine leukemia virus which causes a noninflammatory spongiform neurodegenerative disease after neonatal inoculation. The central nervous system (CNS) infection is wide-spread, involving several different cell types, whereas the lesions are localized to motor areas of the brain and spinal cord. Inoculation of FrCasE at 10 days of age (P10) results in viremia, but infection of the CNS is restricted and neurological disease is not observed (M. Czub, S. Czub, F. McAtee, and J. Portis, J. Virol. 65:2539-2544, 1991). In this study, we used this developmental resistance to restrict the extent and the distribution of FrCasE in the brain to examine whether the spongiform degeneration is a consequence of infection of cells in proximity to the lesions. Two approaches were used to infect the brain on or after P10. First, mice were inoculated with FrCasE at P10 to induce viremia and then at P17 were subjected to focal CNS injury within brain regions known to be susceptible to virus-induced spongiform degeneration. The injury resulted in local inflammation, glial activation, migration of inflammatory cells into the wound site, and high-level parenchymal infection about the wound site. However, no evidence of spongiform neurodegeneration was observed over a period of 3 months. The second approach involved the implantation of FrCasE-infected microglia into the CNS at > or = P10. This resulted in microglial engraftment and focal CNS infection unilaterally at the implantation sites and bilaterally along white matter tracts of the corpus callosum and pons and in cells of the subventricular layers of the lateral cerebral ventricles. Strikingly, focal spongiform degeneration colocalized with the sites of infection. In contrast to the wounding experiments, the implantation model was not associated with an inflammatory response or significant glial activation. Results of these studies suggest that (i) the developmental resistance of the CNS to infection lies at the blood-brain barrier and can be bypassed by direct introduction into the brain of virus-infected cells, (ii) the neuropathology induced by this virus is a consequence of local effects of the infection and does not appear to require endothelial or neuronal infection, and (iii) elements of the inflammatory response and/or glial activation may modulate the expression of neuropathology induced by neurovirulent retroviruses.

Intrastriatal quinolinic acid injections protect against 6-hydroxydopamine-induced lesions of the dopaminergic nigrostriatal system

We tested the effect of intrastriatal quinolinic acid (QA) injections 2 weeks before subsequent intrastriatal injections of 6-hydroxydopamine (6-OHDA). Levels of DA and its metabolites were measured 2 days and 21 days after lesioning the dopaminergic nigrostriatal system with 6-OHDA. Intrastriatal 6-OHDA injections in the absence of prior treatment of QA significantly decreased dopamine (DA) and its metabolite levels in striatum but not in substantia nigra at day 2, and in striatum and substantia nigra at day 21, a clear indication of a time-dependent retrograde axonal degeneration of substantia nigra cell bodies. Intrastriatal QA injections 2 weeks before subsequent intrastriatal injection of 6-OHDA partially prevented the 6-OHDA-depleting effect on DA and its metabolite levels in both striatum and substantia nigra 21 days after 6-OHDA injection. However, no statistically significant differences were found between QA + 6-OHDA- and 6-OHDA-treated animals at day 2. Our results suggest that intrastriatal QA injections partially prevent the naturally-occurring retrograde axonal degeneration of substantia nigra cell bodies caused by 6-OHDA, and illustrate a target-derived interaction between dopaminergic nerve endings and cell bodies. We suggest that the protective effect found in the QA-injected animals against the neurotoxic action of 6-OHDA is mediated by neurotrophic agents released by activated astroglia.

Spread of a neurotropic coronavirus to spinal cord white matter via neurons and astrocytes

Mouse hepatitis virus strain JHM (MHV-JHM) causes a chronic encephalomyelitis in susceptible mice, with histological evidence of demyelination in the spinal cord. After intranasal inoculation, virus spreads retrogradely to several brain structures along neuroanatomic projections to the main olfactory bulb. In the absence of experimental intervention, mice become moribund before the spinal cord is infected. In this study, infusions of anti-MHV neutralizing monoclonal antibodies were administered to protect mice from the MHV-JHM-induced acute encephalitis and to allow survival until virus spread to the spinal cord. Under these conditions, virus was observed to enter specific layers (primarily laminae V to VII) in the gray matter of the upper spinal cord, consistent with transneuronal spread. While the brain structures which are the sources for virus spread to the spinal cord cannot be determined with certainty, the ventral reticular nucleus is likely to be important since it is consistently and extensively labeled in all mice and receives projections from subsequently infected areas of the spinal cord. After initial entry into the gray matter, virus rapidly spread to the white matter of the spinal cord. During the early stages of this process, extensive infection of astrocytes was noted, suggesting that cell-to-cell spread via these glial cells is an important part of this process. Reports from other laboratories using cultured cells strongly suggested that astrocytes serve as important regulators of oligodendrocyte function and, by extrapolation, have a major role in vivo in the processes of both demyelination and remyelination. Thus, our results not only outline the probable pathway used by MHV-JHM to infect the white matter of the spinal cord but also, with the assumption that infection of astrocytes leads to subsequent dysfunction, raise the possibility that infection of these cells contributes to the demyelinating process.

Astrocytic reaction after graded spinal cord compression in rats: immunohistochemical studies on glial fibrillary acidic protein and vimentin

The relation between the degree of spinal cord compression and the extent of early posttraumatic reaction of astrocytes was investigated in rats using the blocking-weight technique to induce a spinal cord compression at the level of the Th8-9. Immunohistochemistry was used to detect changes in the expression of glial fibrillary acidic protein (GFAP) and vimentin up to 24 h after injury. A mild compression, which did not cause any measurable neurological deterioration, induced a mild increase of GFAP immunoreactivity at 4 h and a more marked and widespread immunoreactivity at 24 h. The greatest increase of GFAP immunoreactive astrocytes occurred in rats with moderate compression of the cord causing reversible paraparesis and in animals with severe compression leading to paraplegia. The increase of GFAP immunoreactivity was present already 4 h after injury in virtually all the segments investigated (Th5-6-Th11-12) and was most marked at 24 h. Vimentin immunoreactivity of control rats was present in the ependymal cells of the central canal, the leptomeninges, and walls of a few intramedullary vessels. Occasional astrocytes were stained. In rats surviving 24 h after moderate and severe compression vimentin immunoreactivity was increased in the walls of intramedullary blood vessels including capillaries of one rostral and one caudal segment. Many macrophages with immunoreactivity appeared and occasional glial cells with astrocyte shape were stained. This investigation shows that within 24 h after compression of the spinal cord a widespread astrocyte reaction occurs. Even a mild compression that does not produce any signs of motor dysfunction can induce widespread astrocyte alterations in the spinal cord. This astrocyte response is more marked in rats with more severe compression leading to more pronounced neurological deterioration. The increase in vimentin immunoreactivity of blood vessels is more localized and occurs in moderate and severe compression of the cord.

Royal Society of Tropical Medicine and Hygiene Meeting at Manson House, London, 19 May 1994. Trypanosomiasis and the nervous system. Pathology and immunology

Damage to the nervous system occurs in both African and American trypanosomiases, but it differs considerably in form and extent in each disease, and with different strains and disease stages. With Trypanosoma brucei infections there is a progressive central nervous system (CNS) pathology which involves the meninges, choroid, blood-brain barrier, and immunopathological changes including perivascular infiltrations, astrocyte activation and alterations in the cytokine/mediator network. These changes underly the altered behaviour in the late or secondary disease stages, prevalent in the chronic gambian form, characterized by hypersomnia leading, if untreated or if treatment is followed by reactive changes, to coma and death. T. cruzi infections can be divided into 3 stages; acute, intermediate and chronic. Each stage has a different neurological involvement. In the acute stage the parasite produces direct destructive and inflammatory changes in the CNS which can be life-threatening, but which normally resolve, giving way to an intermediate period with effective parasite suppression and little or no perpetuation in the nervous system. The chronic stage is characterized by alteration to a progressive peripheral neuroimmunopathology, with autoimmune destruction of many nerve components, especially the autonomic innervation of the heart and gut.

Synaptotrophic effects of human amyloid beta protein precursors in the cortex of transgenic mice

The amyloid precursor protein (APP) is involved in Alzheimer's disease (AD) because its degradation products accumulate abnormally in AD brains and APP mutations are associated with early onset AD. However, its role in health and disease appears to be complex, with different APP derivatives showing either neurotoxic or neurotrophic effects in vitro. To elucidate the effects APP has on the brain in vivo, cDNAs encoding different forms of human APP (hAPP) were placed downstream of the neuron-specific enolase (NSE) promoter. In multiple lines of NSE-hAPP transgenic mice neuronal overexpression of hAPP was accompanied by an increase in the number of synaptophysin immunoreactive (SYN-IR) presynaptic terminals and in the expression of the growth-associated marker GAP-43. In lines expressing moderate levels of hAPP751 or hAPP695, this effect was more prominent in homozygous than in heterozygous transgenic mice. In contrast, a line with several-fold higher levels of hAPP695 expression showed less increase in SYN-IR presynaptic terminals per amount of hAPP expressed than the lower expressor lines and a decrease in synaptotrophic effects in homozygous compared with heterozygous offspring. Transgenic mice (2-24 months of age) showed no evidence for amyloid deposits or neurodegeneration. These findings suggest that APP may be important for the formation/maintenance of synapses in vivo and that its synaptotrophic effects may be critically dependent on the expression levels of different APP isoforms. Alterations in APP expression, processing or function could contribute to the synaptic pathology seen in AD.

Immunocytochemical expression of the blood-brain barrier glucose transporter (GLUT-1) in neural transplants and brain wounds

The present study examined the immunocytochemical expression of the blood-brain barrier glucose transporter (GLUT-1) in a series of fetal neocortical transplants, autonomic tissue transplants, and stab wounds to the rat brain. GLUT-1 is one of a family of different glucose transporters and is found exclusively on barrier-type endothelial cells. In the brain it is responsible for the regulated facilitative diffusion of glucose across the blood-brain barrier. This investigation is the first to determine if this important molecule is altered during the process of angiogenesis that occurs following neural transplantation procedures or direct brain injury. Beginning in late fetal brain, e.g., E18 and continuing into maturity, GLUT-1 was strongly and exclusively expressed on normal cerebral vessels. In solid fetal central nervous system (CNS) transplants up to around 3 weeks postoperative, GLUT-1 was only weakly expressed, particularly as exemplified by colloidal gold immunostaining when compared with the host. At later times examined, up to 15 months postoperative, GLUT-1 immunoexpression was comparable with the normal adjacent brain. In autonomic tissue transplants, where the vessels do not have a blood-brain barrier, as expected, GLUT-1 was not expressed. In stab wounds, at 1 week there was extensive gliosis, and the injured vessels appeared fragmented and collapsed but still expressed GLUT-1, although to a somewhat lesser extent than normal brain. Between 3 and 6 weeks, GLUT-1 was expressed on tortuous vessels and in apparently fibrillar processes in the wound vicinity with a similar pattern to astrocyte (GFAP) reactivity. These results suggest the occurrence of a down-regulation of GLUT-1 in early transplants, perhaps related to reduced glycolytic activity or transient ischemia, or possibly due to the utilization of alternative energy sources. That GLUT-1 expression was not entirely lost in stab wounds to the mature brain suggests that the protein may be more labile in fetal or perinatal brain than in the adult and may not be affected by direct injury. Coupled with previous transplantation studies that have shown reduced neuronal glycolysis and potential barrier alterations, the reduction of GLUT-1 activity within nearly the identical time frame could indicate a relatively early critical period in cellular metabolism following transplantation of CNS tissue.

Astroglial and microglial reactions in the gerbil hippocampus with induced ischemic tolerance

Preconditioning of the brain with sublethal ischemia protects against neuronal damage following subsequent longer periods of ischemia (ischemic tolerance). In this study, we investigated astroglial and microglial reactions in the hippocampus following ischemia in a gerbil model of ischemic tolerance. Two minutes of forebrain ischemia (preconditioning ischemia) or sham operation was followed by 3 min of ischemia (second ischemia) 3 days later. The brains were perfusion-fixed after 4 h, 1 day, 2 days, and 7 days. Paraffin sections were used for the visualization of astrocytes by immunostaining against glial fibrillary acidic protein (GFAP) and for the visualization of microglia by histochemical staining with isolectin-B4 from Griffonia simplicifolia. The preconditioning ischemia induced a moderate increase in astroglial and microglial staining. Two days after the second ischemia, GFAP staining further increased in astrocytes in the hippocampus with ischemic tolerance. In the CA1 region of the hippocampus without ischemic tolerance, in contrast, microglial activation with increased staining and morphological changes was pronounced. After 7 days, neuronal destruction resulted in the CA1 region without tolerance, where hypertrophic reactive astroglia and reactive microglia with phagocytic transformation accumulated intensely. However, the ischemic preconditioning prevented the CA1 neuronal damage and the activation of microglia was subsiding after 7 days. Thus, activation of glial cells occurred in a graded fashion in response to different degrees of neuronal injury. Astroglial but not microglial activation may have implications in neuronal survival in ischemic tolerance.(ABSTRACT TRUNCATED AT 250 WORDS)

Beta-amyloid-induced changes in cultured astrocytes parallel reactive astrocytosis associated with senile plaques in Alzheimer's disease

One neuropathological characteristic of Alzheimer's disease is an abundance of reactive astrocytes, particularly in association with senile plaques. Neither the factor(s) responsible for initiating the reactive astrocytosis nor the effects of this event on disease progression are known. We investigated the possibility that beta-amyloid protein, the primary constituent of plaques, contributes to reactive astrocytosis by comparing results derived from both culture studies and immunohistochemical analyses of Alzheimer brain tissue. We report that beta-amyloid peptides, in an aggregation-dependent manner, rapidly induce a reactive phenotype in cultured rat astrocytes. Reactive morphological changes are accompanied by increased immunoreactivities for glial fibrillary acidic protein and basic fibroblast growth factor. Although toxic to other types of central nervous system cells, aggregated beta-amyloid peptides do not significantly decrease astrocyte viability. Rather, the processes of cultured astrocytes envelop aggregated deposits of beta-amyloid peptide. In Alzheimer brain, the processes of reactive astrocytes were also observed to engulf beta-amyloid deposits. Similar to the in vitro findings, the astrocytic response was associated only with beta-amyloid plaques exhibiting an aggregated structure. Further, the plaque-associated reactive astrocytes showed enhanced immunoreactivities for glial fibrillary acidic protein and basic fibroblast growth factor. These data suggest that beta-amyloid which has assembled into beta-sheet fibrils significantly contributes to the reactive astrocytosis characteristic of Alzheimer's disease. Thus, in addition to its hypothesized direct effects on neuronal viability, beta-amyloid may also influence disease progression indirectly via reactive astrocytosis.

Proliferative astrocytes may express fibronectin-like protein in the hippocampus of epileptic rats

Kainic acid treatment, a model of temporal lobe epilepsy, induces in CA3-CA4 fields of hippocampal complex a neuronal degeneration associated with glial hypertrophy and proliferation. After treatment with kainate, fibronectin (an extracellular matrix protein) immunoreactivity increases in CA3-CA4. Fibronectin antibodies stain proliferative cells (simultaneously labelled by [3H]thymidin) of astrocytic type (double-immunostained by GFAP antibodies). This result constitutes the first direct demonstration of astroglial fibronectin expression in vivo. In the molecular layer of kainate-treated rats there is an axon-terminal degeneration of association-fibers. This is associated with a transient hypertrophy of resident astrocytes but not with any glial proliferation. Reactive astrocytes do not express (or faintly) fibronectin immunoreactivity in this layer. Since fibronectin is involved in astroglial proliferation in vitro, the present observations suggest that astrocytes contribute in vivo to the astroglial proliferation by an autocrin mechanism.

Localization of vitronectin- and fibronectin-receptors on cultured human glioma cells

Utilizing a human astrocyte-derived glioma cell line, we have demonstrated the presence of a vitronectin receptor, alpha v beta 3, and a fibronectin receptor, alpha 5 beta 1, on the surface of the cells spreading on the respective adhesion molecules by immunohistochemical analyses. By phase-contrast microscopy, these receptors were found to be expressed predominantly in the focal contact-like area, suggesting that they were involved in the spreading of the cells upon contact with these adhesion molecules. Interestingly, they appeared to have differential functions and roles as integrins as evidenced by different time-dependent distribution profiles on the cell surface in the serum-containing medium. Furthermore, both vitronectin and fibronectin seem to have chemotactic effects onto the glioma cells as observed in a Boyden chamber study. Although these receptors are not expected to be present on the surface of astrocytes under physiological conditions, they may be expressed thereon and involved in gliosis when the cerebral vasculature is traumatized and, thereby, blood proteins, including vitronectin and fibronectin, come into contact with the astrocytes.

Immunocytochemical distribution of the brain glucose transporter (GLUT 1) in experimental gliosis

The present study has examined the immunocytochemical expression of the blood-brain barrier glucose transporter GLUT 1 as compared with GFAP in models of experimental gliosis. In neocortical grafts, gliosis was prominent at the graft-host interface mostly associated with blood vessels. Consecutive sections examined for anti-GLUT 1 showed that the protein was distributed in nearly an identical pattern to the anti-GFAP, staining fibrillar processes and all vessels and also appeared extracellularly. In stab wounds, GLUT 1 immunoexpression was similar to GFAP reactivity and stained injured vessels and glial-like processes that were reminiscent of astrocytic end-feet. Normal glial cells and processes in unaffected neuropil, however, were never stained. This report suggests that GLUT 1 protein may be upregulated in non-endothelial components, such as reactive astroglia or possibly microglia, that are associated with injured or angiogenic vessels.

Relationship between injury-induced astrogliosis, laminin expression and axonal sprouting in the adult rat brain

Lesion-induced regenerative sprouting of CNS axons is accompanied by structural and metabolic changes of astrocytes. In order to evaluate the effects of these astrocytic changes on axonal regeneration, we investigated the spatio-temporal relationship of gliosis, laminin expression and axonal sprouting in the postcommissural fornix of the adult rat. Using immunocytochemical methods we observed (1) a perilesional area with a transient lack of astrocytes and axons, (2) the reappearance of reactive astrocytes followed by the ingrowth of sprouting fibres and finally an increase in laminin-immunoreactivity, (3) the absence of lesion-induced laminin-expression in reactive astrocytes and (4) the formation and long-lasting (at least 28 months) persistence of a dense plexus of laminin-immunopositive blood vessels at the site of transection and in the proximal and distal stumps. These data indicate that astrogliosis is permeable for regrowing axons and that injury-induced axonal sprouting in the transected postcommissural fornix may be mediated by laminin-independent mechanisms.

Modifications of glial metabolism of glutamate after serotonergic neuron degeneration in the hippocampus of the rat

We have investigated the role of serotonergic neurons on the astrocytes catabolism of glutamate by analyzing glutamine synthetase (GS) and glutamate dehydrogenase (GDH) expression in the hippocampus after the degeneration of serotonergic neurons by a specific neurotoxin (5,7-DHT). 5,7-DHT caused reactive gliosis with hypertrophy (increase in glial fibrillary acidic protein (GFAP) expression) but not proliferation of astrocytes. Glutamate metabolism appeared preferentially regulated by a control of GDH expression rather than GS since the expression of GDH was specifically and significantly induced in the hippocampus whereas the level of GS remained unchanged. The inhibition of serotonin synthesis (by para-chlorophenylalanine (p-CPA) administration) produced no significant increase of GDH level. This suggests that serotonin is not the principal factor involved in this control of GDH expression.

Astrocyte and microglial motility in vitro is functionally dependent on the hyaluronan receptor RHAMM

RHAMM (Receptor for Hyaluronic Acid Mediated Motility) has been identified as a receptor for the extracellular matrix component hyaluronan (HA) and was recently shown to be essential for the locomotion of normal and transformed peripheral cells. Until now the potential role of RHAMM in the motility of neural-derived cells has not been investigated. Here, we report that cultured primary astrocytes, astrocyte cell lines, and microglia express this receptor and exhibit RHAMM-dependent motility. Immunocytochemical localization of RHAMM showed that it was often present as aggregates at the periphery of cells in contact with one another or concentrated on protruding processes of isolated cells. Glial cells contained 50 and 72 kDa forms of RHAMM, and both of these forms were found to have HA binding capacity. Time lapse imaging of cell locomotion revealed a significant inhibition of motility and process elongation by neutralizing anti-RHAMM antibodies and by peptides corresponding to the HA binding domains of RHAMM. These results demonstrate that RHAMM serves a role in glial cell locomotion in vitro and provide the basis for investigations of the motile behavior of glial cells in vivo after CNS injury.

Increased monoamine oxidase B activity in plaque-associated astrocytes of Alzheimer brains revealed by quantitative enzyme radioautography

The aetiology and pathogenesis of Alzheimer's disease are currently poorly understood, but symptomatic disease is associated with amyloid plaques, neurofibrillary tangles, neuronal loss and numerous alterations of neurotransmitter systems in the CNS. Monoamine oxidase type B is known to be increased in Alzheimer diseased brains. The distribution and abundance of catalytic sites for monoamine oxidases A and B in post mortem human brains of 11 Alzheimer disease cases and five age-matched controls were investigated by quantitative enzyme radioautography. Using tritiated monoamine oxidase inhibitors (Ro41-1049 and lazabemide)--as high affinity substrates selective for monoamine oxidases A and B, respectively--it was found that monoamine oxidase B activity increased up to three-fold exclusively in temporal, parietal and frontal cortices of Alzheimer disease cases compared with controls. This increase was restricted to discrete patches (approximately 185 microns in diameter) which occupied approximately 12% of the cortical areas examined. In other brain regions (hippocampal formation >> caudate-putamen > cerebellum), patches of [3H]lazabemide-enriched binding were less abundant. [3H]Ro41-1049 binding (i.e. monoamine oxidase A) was unchanged in all tissues of diseased versus control brains. The monoamine oxidase B-enriched patches in all cortical regions correlated, in their distribution and frequency, with glial fibrillary acidic protein-immunoreactive clusters of astrocytes. Diffuse and mature beta-amyloid-immunoreactive senile plaques as well as patches of high density binding of [3H]PK-11195--a high-affinity ligand for peripheral-type (mitochondrial) benzodiazepine binding sites in microglia/macrophages--were found throughout Alzheimer diseased cortices. The up-regulation of monoamine oxidase B in plaque-associated astrocytes in Alzheimer's disease--in analogy to its proposed role in neurodegenerative disorders such as Parkinson's disease--might, indirectly, be a potential source of cytotoxic free radicals. Lazabemide, a selective reversible monoamine oxidase B inhibitor, is currently under clinical evaluation for the treatment of Parkinson's and Alzheimer's diseases. We conclude that enzyme radioautography with [3H]lazabemide is a reliable high resolution assay for plaque-associated astroglioses in Alzheimer's disease. Its clinical diagnostic utility for positron emission tomography or single photon emission computer tomography studies is being investigated.

Ischemia-induced cellular redistribution of the astrocytic gap junctional protein connexin43 in rat brain

The distribution and levels of the astrocytic gap junction protein, connexin43 (Cx43) was analyzed in various regions of brain as a function of time after neuronal loss and consequent reactive gliosis induced by bilateral carotid occlusion in rats. In the striatum 2 days after induction of ischemia, immunostaining intensity for Cx43 increased in animals exhibiting mild to moderate striatal damage, whereas areas of reduced staining surrounded by elevated levels of Cx43 immunoreactivity were observed in animals with severe ischemic damage. Immunolabelling of glial cell bodies was evident in ischemic, but not normal, striatum. Similar, though less dramatic, changes were seen at 7 days post-ischemia. Compared with the fine punctate pattern of Cx43 staining seen in normal striatum, ischemic striatal areas contained large aggregates of punctate profiles. In the hippocampus, increased immunostaining was seen at 2 and 7 days post-ischemia and, unlike normal hippocampus, neurons in the CA3 pyramidal cell layer were surrounded by a network of Cx43-immunoreactive puncta at the latter survival time. Immuno-EM analysis of ischemic tissue revealed numerous immunolabelled gap junctions among astrocytic processes in the vicinity of degenerating neurons and elevated levels of intracellular Cx43 immunoreactivity in astrocytic processes and cell bodies. No differences in protein levels or phosphorylation states of Cx43 were detected in either hippocampus or striatum by Western blot analyses of ischemic and control tissue. These results suggest that astrocytes respond to an ischemic insult by reorganizing their gap junctions, that the qualitative nature of their response is dependent on the severity of neuronal damage or loss, and that a pool of Cx43 normally undetectable by immunohistochemistry may contribute to the ischemia-induced elevations of immunolabelling for this protein.