The Reactive Astrocyte

Ultrasonically actuated neural probes for reduced trauma and inflammation in mouse brain

Electrical neural recordings measured using direct electrical interfaces with neural tissue suffer from a short lifespan because the signal strength decreases over time. The inflammatory response to the inserted microprobe can create insulating tissue over the electrical interfaces, reducing the recorded signal below noise levels. One of the factors contributing to this inflammatory response is the tissue damage caused during probe insertion. Here, we explore the use of ultrasonic actuation of the neural probe during insertion to minimize tissue damage in mice. Silicon neural microprobes were designed and fabricated with integrated electrical recording sites and piezoelectric transducers. The microprobes were actuated at ultrasonic frequencies using integrated piezoelectric transducers. The microprobes were inserted into mouse brains under a glass window over the brain surface to image the tissue surrounding the probe using two-photon microscopy. The mechanical force required to penetrate the tissue was reduced by a factor of 2-3 when the microprobe was driven at ultrasonic frequencies. Tissue histology at the probe insertion site showed a reduced area of damage and decreased microglia counts with increasing ultrasonic actuation of the probes. Two-photon imaging of the microprobe over weeks demonstrated stabilization of the inflammatory response. Recording of electrical signals from neurons over time suggests that microprobes inserted using ultrasound have a higher signal-to-noise ratio over an extended time period.

A simple method for implanting free-floating microdevices into the nervous tissue

Objective. Free-floating implantable neural interfaces are an emerging powerful paradigm for mapping and modulation of brain activity. Minuscule wirelessly-powered devices have the potential to provide minimally-invasive interactions with neurons in chronic research and medical applications. However, these devices face a seemingly simple problem-how can they be placed into nervous tissue rapidly, efficiently and in an essentially arbitrary location?Approach. We introduce a novel injection tool and describe a controlled injection approach that minimizes damage to the tissue.Main results.To validate the needle injectable tool and the presented delivery approach, we evaluate the spatial precision and rotational alignment of the microdevices injected into agarose, brain, and sciatic nerve with the aid of tissue clearing and MRI imaging. In this research, we limited the number of injections into the brain to four per rat as we are using microdevices that are designed for an adult head size on a rat model. We then present immunohistology data to assess the damage caused by the needle.Significance. By virtue of its simplicity, the proposed injection method can be used to inject microdevices of all sizes and shapes and will do so in a fast, minimally-invasive, and cost-effective manner. As a result, the introduced technique can be broadly used to accelerate the validation of these next-generation types of electrodes in animal models.

Chronically Implanted Microelectrodes Cause c-fos Expression Along Their Trajectory

When designing electrodes and probes for brain–machine interfaces, one of the challenges faced involves minimizing the brain-tissue response, which would otherwise create an environment that is detrimental for the accurate functioning of such probes. Following the implantation process, the brain reacts with a sterile inflammation response and resulting astrocytic glial scar formation, potentially resulting in neuronal cell loss around the implantation site. Such alterations in the naïve brain tissue can hinder both the quality of neuronal recordings, and the efficacy of deep-brain stimulation. In this study, we chronically implanted a glass-supported polyimide microelectrode in the dorsolateral striatum of Sprague–Dawley rats. The effect of high-frequency stimulation (HFS) was investigated using c-fos immunoreactivity techniques. GFAP and ED1 immunohistochemistry were used to analyze the brain-tissue response. No changes in c-fos expression were found for either the acute or chronic stimulus groups; although a c-fos expression was found along the length of the implantation trajectory, following chronic implantation of our stiffened polyimide microelectrode. Furthermore, we also observed the formation of a glial scar around the microelectrode, with an accompanying low number of inflammation cells. Histological and statistical analysis of NeuN-positive cells did not demonstrate a pronounced “kill zone” with accompanying neuronal cell death around the implantation site, neither on the polymer side, nor on the glass side of the PI-glass probe.

Thyroid Hormone and Astrocyte Differentiation

Thyroid hormones (THs) have important contributions to the development of the mammalian brain, targeting its actions on both neurons and glial cells. Astrocytes, which constitute about half of the glial cells, characteristically undergo dramatic changes in their morphology during development and such changes become necessary for the proper development of the brain. Interestingly, a large number of studies have suggested that THs play a profound role in such morphological maturation of the astrocytes. This review discusses the present knowledge on the mechanisms by which THs elicit progressive differentiation and maturation of the astrocytes. As a prelude, information on astrocyte morphology during development and its regulations, the role of THs in the various functions of astrocyte shall be dealt with for a thorough understanding of the subject of this review.

Response of brain tissue to chronically implanted neural electrodes

Chronically implanted recording electrode arrays linked to prosthetics have the potential to make positive impacts on patients suffering from full or partial paralysis. Such arrays are implanted into the patient's cortical tissue and record extracellular potentials from nearby neurons, allowing the information encoded by the neuronal discharges to control external devices. While such systems perform well during acute recordings, they often fail to function reliably in clinically relevant chronic settings. Available evidence suggests that a major failure mode of electrode arrays is the brain tissue reaction against these implants, making the biocompatibility of implanted electrodes a primary concern in device design. This review presents the biological components and time course of the acute and chronic tissue reaction in brain tissue, analyses the brain tissue response of current electrode systems, and comments on the various material science and bioactive strategies undertaken by electrode designers to enhance electrode performance.

Astrocytes in cerebral ischemic injury: morphological and general considerations

Asrocytic responses constitute one of the earliest and most prominent changes in the CNS following ischemic injury. Astrocytes are known to carry out critical functions such as maintenance of ionic homeostasis, prevention of excitotoxicity, scavenging free radicals, provision of nutrients and growth factors, promotion of neovascularization, and support of synaptogenesis and neurogenesis that potentially may influence the outcome of ischemic injury. This article reviews ischemia-associated alterations in astrocytes and their potential significance. Interactions with neurons, microglia, and endothelial cells are also considered. This article highlights the critical role of astrocytes in the CNS response to ischemic injury.

Persistent neocortical astrogliosis in adult wistar rats following prenatal ethanol exposure

Timed pregnant wistar rats were divided randomly into groups A and B (n=6) each and C (n=4). Group A received a daily ethanol dose of 5.8 g/kg body weight per day, at 16.00 h on days 9-12th of gestation by intragastric intubations. Group B was pair-fed along with the treated rats and received an isocaloric solution of sucrose to substitute for the ethanol in the experimental group, for the same duration, while group C received standard chow and water ad libitum. The adult offsprings at 42 days of age, (n=10) from each group were sacrificed by whole body perfusion-fixation, after anaesthesia by an overdose of pentothal intraperitoneally. Specimens of neocortical samples were processed routinely for paraffin embedding and sections of 6 microm thickness stained for neurohistology. Another set of specimens was cryosectioned at -23 degrees C after cryoprotection in 30% sucrose/PBS and evaluated for GFAP immunohistochemistry. The study showed a distortion of the microanatomy of the neocortex in the treatment group A, particularly of layer V pyramidal neurons, which revealed mostly pyknotic pyramidal neurons with broken dendrites, collapsed cell bodies, obliterated nuclei and nucleoli. No differences were found between the brains from rats in groups B and C. There were widespread focal areas of reactive astrogliosis, more prominent within the layer V. Astrocytes demonstrated highly stained GFAP-positive immunoreactivity with heavy fibrillary processes in the neocortex of group A offsprings compared to the controls. The sub-pial regions were, however, sparse. In conclusion, this study confirms the hypothesis that microanatomical and microchemical changes following prenatal ethanol exposure persist into adulthood in rats.

The pathology of human spinal cord injury: defining the problems

This article reviews the pathology of human spinal cord injury (SCI), focusing on potential differences between humans and experimental animals, as well as on aspects that may have mechanistic or therapeutic relevance. Importance is placed on astrocyte and microglial reactions. These cells carry out a myriad of functions and we review the evidence that supports their beneficial or detrimental effects. Likewise, vascular responses and the role of inflammation and demyelination in the mechanism of SCI are reviewed. Lastly, schwannosis is discussed, highlighting its high frequency and potential role when designing therapeutic interventions. We anticipate that a better understanding of the pathological responses in the human will be useful to investigators in their studies on the pathogenesis and therapy of SCI.

Apolipoprotein D expression in human brain reactive astrocytes

Astrocytosis is a hallmark of damage that frequently occurs during aging in human brain. Astrocytes proliferate in elderly subjects, becoming hypertrophic and highly immunoreactive for glial fibrillary acidic protein (GFAP). These cells are one type that actively responds in the repair and reorganization of damage to the neural parenchyma and are a source of several peptides and growth factors. One of these biomolecules is apolipoprotein D (apo D), a member of the lipocalin family implicated in the transport of small hydrophobic molecules. Although the role of apo D is unknown, increments in brain apo D expression have been observed in association with aging and with some types of neuropathology. We have found an overexpression of apo D mRNA in reactive astrocytes by in situ hybridization in combination with immunohistochemistry for apo D in normal aged human brains. The number of double-labeled cells varied according to the cerebral area and the gliosis grade. The possible significance of this increased synthesis of apo D in reactive astrocytes is discussed in relation to the role of apo D in aging and in glial function.

Characterization of cortical astrocytes on materials of differing surface chemistry

The behavior of cortical astrocytes was evaluated on a number of medically relevant materials of differing physicochemical properties. This study describes cell attachment, DNA synthesis, production of extracellular matrix (ECM) proteins, and neuronal interactions of perinatal rat astrocytes in vitro. The number of attached astrocytes initially differed among the materials, decreasing with increasing material hydrophobicity. In contrast, the rate of DNA synthesis increased with increasing material hydrophobicity. With the exception of only one material, astrocytes reached confluence by 12 days in culture on all the materials tested. Furthermore, the expression of characteristic ECM proteins and the fundamental ability of astrocytes to support neuronal attachment and growth was qualitatively identical between populations of astrocytes on different materials. The ability of astrocytes to colonize different surfaces initially was mediated via adsorbed serum proteins, as reducing the capacity of a model surface to adsorb proteins inhibited astrocyte colonization for up to 2 weeks in culture. We propose that astrocytes are relatively insensitive to differences in surface chemistries so long as the proteins necessary for cellular attachment are capable of adsorbing to the material to some extent. It seems likely that the ability of astrocytes to produce and remodel a matrix creates a surface environment that eventually becomes similar regardless of the surface chemistry of the underlying material.

Sequential changes in glial fibrillary acidic protein and gene expression following parasagittal fluid-percussion brain injury in rats

This study documents the regional and temporal patterns of glial fibrillary acidic protein (GFAP) RNA and protein expression after parasagittal fluid-percussion (F-P) brain injury (1.7 to 2.2 atm) in male Sprague-Dawley rats. In situ hybridization was conducted in 28 rats with a 35S-labeled antisense riboprobe to GFAP at 0.5, 2, and 6 hours and 1, 3, and 30 days after traumatic brain injury (TBI) or sham procedures. Immunocytochemical staining of GFAP was conducted in 20 rats at 1, 3, 7, and 30 days after TBI or sham procedures. At 0.5 and 2 hours after TBI, increased GFAP mRNA was restricted to superficial cortical areas underlying the impact site. At 24 hours, increased GFAP mRNA was observed throughout the traumatized hemisphere except within the histopathologically vulnerable lateral parietal cortex and external capsule. Contralateral expression within the hippocampus and cingulate and lateral cortices was also observed. Three days after TBI, GFAP mRNA expression was prominent overlying pial surfaces, in cortical regions surrounding the contusion, and within the hippocampus and lateral thalamus. Immunocytochemical visualization of GFAP at 1 and 3 days demonstrated reactive astrocytes overlying the pial surface, surrounding the cortical contusion, and within ipsilateral white matter tracts, hippocampus, and lateral thalamus. At 30 days, GFAP mRNA and protein expression were present within the deeper cortical layers of the lateral somatosensory cortex and lateral thalamus and throughout ipsilateral white matter tracts. These data demonstrate a complex pattern of GFAP mRNA and protein expression within gray and white matter tracts following F-P brain injury. Patterns of GFAP gene expression may be a sensitive molecular marker for evaluating the global response of the brain to focal injury in terms of progressive neurodegenerative as well as regenerative processes.

Astrocytic regulation of the recovery of extracellular potassium after seizures in vivo

Glial cells are believed to play a major role in the regulation of the extracellular potassium concentration ([K+]o), particularly when the [K+]o is increased. Using ion-selective electrodes, we compared the [K+]o changes in the dentate gyrus of urethane-anaesthetized adult rats in the presence of reactive astrocytes and after reduction of glial function. The regulation of [K+]o in the dentate gyrus was determined by measuring the ceiling level of [K+]o and the half-time of recovery of [K+]o during and after seizures produced by 20 Hz trains of stimulation to the angular bundle. Reactive astrocytes were induced by repeated seizures and their presence was confirmed by a qualitative increase in glial fibrillary acidic protein (GFAP) and vimentin immunoreactivity. To inhibit glial function, fluorocitrate (FC), a reversible metabolic inhibitor, or alpha-aminoadipate (alpha-AA), an irreversible toxin, was injected into the dentate gyrus region, and the regulation of [K+]o was monitored for 8 h or 2 days later, respectively. After alpha-aminoadipate, loss of astrocytes in the dentate gyrus was demonstrated by loss of staining for GFAP. In the presence of reactive astrocytes there was no significant change in the peak [K+]o during seizures or the half-time of recovery of [K+]o after seizures compared to control animals. alpha-Aminoadipate significantly slowed the rate of recovery of [K+]o, but did not change the ceiling [K+]o. Fluorocitrate reversibly decreased the ceiling [K+]o, but also slowed the rate of recovery of [K+]o. Overall our results suggest that normal glial function is required for the recovery of elevated [K+]o after seizures in vivo.

Optic disc and optic nerve of the blind cape mole-rat (Georychus capensis): a proposed model for naturally occurring reactive gliosis

Recent studies of the visual system of animal species that live in a subterranean environment show not only regressive but also progressive morphological features. In this regard the aim of the present investigation is to describe the structural organisation of the eye and optic nerve of the adult Cape mole-rat, with special emphasis on both glial cell population and myelination. The main results are: (a) astrocytes show identical features to those occurring in reactive gliosis; (b) optic fibers vary greatly in diameter; (c) very small axons are myelinated and are often surrounded by a thicker sheath than larger optic fibers; (d) a large onion bulb-like structure composed of optic fibers, glia, and ganglion cells is found within the choriocapillary layer. These results suggest that the Cape mole-rat and probably other subterranean rodents may serve as a model to study spontaneous gliosis as well as mechanisms involved in myelination and degenerative processes.

The vestibular system as a model of sensorimotor transformations. A combined in vivo and in vitro approach to study the cellular mechanisms of gaze and posture stabilization in mammals

To understand the cellular mechanisms underlying behaviours in mammals, the respective contributions of the individual properties characterizing each neuron, as opposed to the properties emerging from the organization of these neurons in functional networks, have to be evaluated. This requires the use, in the same species, of various in vivo and in vitro experimental preparations. The present review is meant to illustrate how such a combined in vivo in vitro approach can be used to investigate the vestibular-related neuronal networks involved in gaze and posture stabilization, together with their plasticity, in the adult guinea-pig. Following first a general introduction on the vestibular system, the second section describes various in vivo experiments aimed at characterizing gaze and posture stabilization in that species. The third and fourth parts of the review deal with the combined in vivo-in vitro investigations undertaken to unravel the physiological and pharmacological properties of vestibulo-ocular and vestibulo-spinal networks, together with their functional implications. In particular, we have tried to use the central vestibular neurons as examples to illustrate how the preparation of isolated whole brain can be used to bridge the gap between the results obtained through in vitro, intracellular recordings on slices and those collected in vivo, in the behaving animal.

Astrocyte reactivity in neonatal mice: apparent dependence on the presence of reactive microglia/macrophages

In neonatal mice, an acute injury produced by a stab wound to the cortex results in minimal astrocyte reactivity, as has been observed by others. However, if the source of the stab wound, a piece of nitrocellulose (NC) membrane, were now implanted in the cortex for a period of time (chronic NC implant injury), then extensive astroglial reactivity in the neonatal brain ensues. The astrogliosis is manifested by increased mRNA, protein content, and immunoreactivity for GFAP, and by ultrastructural changes. Given the previous reports that inflammatory cytokines are possible mediators of astrocyte reactivity (e.g., Balasingam et al: J Neurosci 14:846, 1994), we examined the brain parenchyma of neonatal mice following an NC stab or implant injury, with minimal or extensive astrogliosis, respectively, for a possible differential representation of inflammatory cells. A significant correlation (r = 0.87, P < 0.05) was observed between the occurrence of astrogliosis and the presence of reactive microglia/macrophages; no other inflammatory cell type was detected in the brain parenchyma of neonatal mice following NC implant injury. We suggest that reactive microglia/macrophages are required for the evolution of cells into reactive astrocytes following insults to the neonatal brain.

Inhibition of glutamine synthetase reduces ammonia-induced astrocyte swelling in rat

Astrocyte hypertrophy and swelling occur in a variety of pathophysiological conditions, including diseases associated with hyperammonemia. Ammonia is rapidly incorporated into glutamine by glutamine synthetase localized in astrocytes. We tested the hypotheses that (1) 6 h of hyperammonemia (500-600 microM) is adequate for producing astrocyte enlargement, and (2) astrocyte enlargement is attenuated by inhibition of glutamine synthetase with methionine sulfoximine. Pentobarbital-anesthetized rats received an intravenous infusion of either sodium or ammonium acetate after intraperitoneal pretreatment with vehicle, methionine sulfoximine (0.8 mmol/kg) or buthionine sulfoximine (4 mmol/kg), an analogue that does not inhibit glutamine synthetase. Hyperammonemia produced enlarged cortical astrocytes characterized by (1) decreased electron density of cytoplasmic matrix in perikaryon, processes and perivascular endfeet, (2) increased circumference of nuclear membrane, (3) increased numbers of mitochondria and rough and smooth endoplasmic reticulum in perikarya and large processes, and (4) less compact bundles of intermediate filaments. Pretreatment with methionine sulfoximine, but not buthionine sulfoximine, attenuated the decrease in cytoplasmic density and the increase in nuclear circumference; most perivascular endfeet remained as dense as occurred with sodium acetate infusion. However, increased numbers of organelles in expanded perikarya and large processes occurred after methionine sulfoximine treatment with and without ammonium acetate infusion. In separate groups of rats, hyperammonemia produced an increase in cortical tissue water content which was inhibited by methionine sulfoximine, but not buthionine sulfoximine. We conclude that clinically-relevant levels of hyperammonemia can cause astrocyte enlargement within 6 h in vivo characterized by both watery cytoplasm and increased organelles indicative of a cellular metabolic stress and altered astrocyte function. The watery cytoplasm component of astrocyte enlargement depends on glutamine synthesis rather than on ammonium ions per se, and is possibly caused by the osmotic effect accumulated glutamine.

The role of extracellular ionic changes in upregulating the mRNA for glial fibrillary acidic protein following spreading depression

While spreading depression has been shown to be a powerful stimulus in upregulating glial fibrillary acidic protein (GFAP) mRNA expression, the specific physiological signal underlying the upregulation is unknown. During spreading depression, extracellular ionic concentrations are altered markedly. The present study evaluates the role of these changes in extracellular ionic concentrations as potential signals influencing GFAP mRNA expression. Gel foam pledgets saturated with artificial cerebrospinal fluid (CSF) solutions in which [Na+], [Ca2+], [K+] and [H+] were altered one at a time to match concentrations seen in spreading depression were applied to exposed parietal cortex for one hour. Dot and in situ hybridization techniques were used to evaluate GFAP mRNA levels. We found that CSF containing 60 mM KCl produced a dramatic upregulation of GFAP mRNA levels throughout the cerebral cortex of the ipsilateral hemisphere without causing detectable tissue damage. The pattern and time course of the change were similar to those following application of 3 M KCl. Alteration of other ionic species did not affect GFAP mRNA levels. However, the upregulation of GFAP mRNA was not likely due directly to the increased [K+], but rather to the spreading depression that the elevated [K+] induced. This was demonstrated by the finding that the upregulation in GFAP mRNA induced by the potassium exposure was totally blocked by prior administration of MK-801, an NMDA antagonist that blocks spreading depression. These results demonstrate that an upregulation in GFAP mRNA can occur in the absence of degeneration debris and that the initiating events can be related to physiological changes, but that changes in extracellular ionic concentrations are not the likely molecular signals underlying the upregulation.

The possible role of glia in nociceptive processing and hyperalgesia in the spinal cord of the rat

Recent studies have suggested that glia might play a more active role in synaptic function than previously thought. Therefore, the present studies have evaluated the potential role of spinal cord glia in acute nociceptive processing and in the thermal and mechanical hyperalgesia produced by peripheral injury. In the present experiments, we found that: (1) selective inhibition of glia metabolism with intrathecal (i.t.) administration of fluorocitrate (1 nmol) results in a marked, but reversible, attenuation of the persistent thermal and mechanical hyperalgesia produced by intraplantar zymosan (5 mg); (2) selective inhibition of the inducible form of nitric oxide synthase (iNOS) with i.t. aminoguanidine (1 pmol-1 nmol) resulted in a dose-dependent inhibition of the persistent thermal, but not mechanical hyperalgesia produced by intraplantar zymosan (5 mg); (3) i.t. coadministration of interleukin 1 beta (IL1 beta; 10 ng) and interferon gamma (IFN; 1000 U) resulted in expression of the message for iNOS 8 hr after administration assessed using reverse-transcription polymerase chain reaction (RT-PCR) and Southern blot analysis; and (4) i.t. administration of lipopolysaccharide (LPS; 150 micrograms) produced a time-dependent thermal hyperalgesia compared with saline treated-rats (15 microliters). There was no change in mechanical withdrawal thresholds over time following any treatment, except fluorocitrate. We have previously shown that NO plays a significant role in mechanisms of hyperalgesia. In the present experiments we have extended these observations and have now shown a role for iNOS, expressed by glia, in mechanisms of hyperalgesia. These results suggest an unexplored avenue for the development of potential new and novel therapies for pain control.

Electroconvulsive seizures upregulate astroglial gene expression selectively in the dentate gyrus

Previous studies have revealed that kindled seizures induced via chronically implanted electrodes up-regulate the expression of glial fibrillary acidic protein (GFAP), the protein constituent of intermediate filaments in astrocytes. The present study evaluates the consequences of a single electroconvulsive seizure (ECS) on glial gene expression. ECS were induced in mice via externally-placed electrodes. GFAP mRNA levels were evaluated 1, 2, 4, and 6 days post-seizure by in situ hybridization. GFA immunocytostaining was evaluated in a separate series of animals. Following a single ECS, the levels of mRNA for GFAP increased several fold by 1 day and were still substantially elevated at 4 days. The increases occurred primarily in the dentate gyrus despite the fact that the seizures involved widespread brain regions. GFAP mRNA levels were also increased in areas bordering the ventricles, especially in areas immediately adjacent to the dentate gyrus. These results indicate that ECS up-regulates the mRNA for a key structural protein of astrocytes in a manner that is similar to the response that occurs following injury, that this response occurs selectively in a part of the brain that plays a key role in memory function, and that the increase may be due in part to a diffusible substance that also affects glial gene expression in nearby structures.

Spreading depression and reverberatory seizures induce the upregulation of mRNA for glial fibrillary acidic protein

The present study evaluates the relative roles of seizure activity and spreading depression in upregulating glial fibrillary acidic protein (GFAP) mRNA expression. Stimulating electrodes were placed bilaterally in the angular bundle, and recording electrodes were placed bilaterally in the dentate gyrus of adult rats. Intense electrographic seizures were induced by delivering stimulus trains through one stimulating electrode. In some cases, spreading depression accompanied the seizures, while in other cases, the seizures occurred in the absence of spreading depression. Animals were killed 24 h following the last stimulus train, and the forebrains were prepared for quantitative in situ hybridization. Seizure activity and spreading depression led to significant increases in GFAP mRNA levels in the hippocampal formation. Seizure activity alone (without spreading depression) induced a 4-fold increase in GFAP mRNA levels in the hilus and molecular layer of the dentate gyrus and in stratum lacunosum-moleculare of the hippocampus. When seizure activity was accompanied by spreading depression, there was a 10-fold increase in GFAP mRNA levels in these same regions. Regional differences within the hippocampal formation in glial cell response were evident. While GFAP mRNA levels in stratum lacunosum-moleculare of the hippocampus were upregulated by seizure activity and spreading depression, levels in hippocampal stratum radiatum of the hippocampus remained unchanged. The results suggest that abnormal neuronal activity can influence glial cell gene expression and that spreading depression is a stronger signal than seizure activity in upregulating GFAP mRNA levels.

Immunohistochemical localization of glutathione peroxidase in infarcted human brain

This is the first report which demonstrates the presence of glutathione peroxidase in the autopsied brain of 5 patients without cerebral infarction and 21 patients with cerebral infarction by the indirect enzyme-labeled antibody technique with monoclonal antibody to human glutathione peroxidase. In 2 out of 5 patients without cerebral infarction, a weak reaction for glutathione peroxidase was demonstrated both in neurons and glia. In 6 patients who had died within 5 days after stroke, no staining was observed in infarcted brain tissue except in macrophages. In all 15 patients who had died more than 6 days after stroke, however, a reaction for glutathione peroxidase was demonstrated in the cytoplasm of glial cells in the marginal area around the infarction, and there was a patchy reaction in the cytoplasm of macrophages in the core lesion. These results suggest that glutathione peroxidase in glial cells of the marginal area around the infarction may play a protective role against lipid peroxidation after cerebral infarction, or alternatively, may be involved in the healing process after ischemia.

Glial response to neuronal activity: GFAP-mRNA and protein levels are transiently increased in the hippocampus after seizures

We have recently demonstrated that electrically induced seizures lead to dramatic increases in mRNA for GFAP in areas in which seizures occur. The present study evaluates the time course of the changes in the GFAP-mRNA levels after seizures and the relationship between these changes and GFAP protein levels to understand the role of neuronal activity in regulating glial gene expression. GFA protein and mRNA levels were measured in hippocampi from rats in which seizures were induced by: (1) 50-Hz stimulus trains delivered 12 times over the course of 1 day via indwelling electrodes implanted chronically in the CA3 region of the hippocampus; and (2) intraperitoneal injections of pentylenetetrazol. In the case of the electrically induced seizures, we also compared the glial response in animals that had never experienced a seizure with the response in animals that previously had been kindled but had not experienced a seizure for 30 days. Electrically induced seizures led to rapid transient increases in GFAP-mRNA levels in the hippocampus ipsi- and contralateral to the stimulation. GFAP-mRNA increased about five-fold 1 day after the end of seizure activity and returned to near-control levels by 4 days. There were no detectable increases in GFA protein at 1 day but by 2 days GFA protein levels had increased about two-fold. GFA protein levels remained elevated until 4 days poststimulation and then began to decrease. The responses were similar when seizures were induced in kindled animals, except that the GFAP protein levels remained elevated for somewhat longer.(ABSTRACT TRUNCATED AT 250 WORDS)

Chronic nicotine treatment counteracts nigral cell loss induced by a partial mesodiencephalic hemitransection: an analysis of the total number and mean volume of neurons and glia in substantia nigra of the male rat

This study combines immunocytochemical and stereological methods for the first time to obtain unbiased estimates of the number of cells in the entire substantia nigra and their respective mean volume. Nicotine, delivered by subcutaneously implanted osmotic pumps (0.125 mg/kg/h, 14 days) to male Sprague-Dawley rats with a partial unilateral mesodiencephalic lesion, caused a significant counteraction of the lesion-induced reduction in total number of nigral tyrosine hydroxylase-like immunoreactive neurons counterstained with Cresyl Violet compared with saline treated control animals. The number of Nissl stained neurons without tyrosine hydroxylase-like immunoreactivity was not affected by the lesion nor by nicotine. The numbers of non-neuronal glial fibrillary acidic protein-like immunoreactive cells counterstained with Cresyl Violet and smaller cells seen after Cresyl Violet staining alone, possibly representing microglia, were increased by the lesion but not affected by nicotine. No nicotine-induced effects were found on the number of nigral cells located contralateral to the lesion. The lesion-induced reduction in the mean volume of the nigral cells showing tyrosine hydroxylase-like immunoreactivity, as determined with the stereological rotator method, was not affected by nicotine. These findings suggest that continuous nicotine infusion exerts protective effects on lesioned nigroneostriatal dopamine systems and that these protective effects are selective for the nigral dopamine neurons not affecting other populations of neurons or non-neuronal cells. This neuroprotective effect might lead to new therapeutic strategies in clinical neurodegenerative disorders such as Parkinson's Disease.

Radiation-induced astrocytic and microglial responses in mouse brain

The aim of this study was to investigate the responses of astrocytes and microglia to whole brain irradiation. Levels of glial fibrillary acidic protein (GFAP), which is a marker for astrocytes, were measured by ELISA in irradiated brains taken at varying time points after irradiation. GFAP levels were increased between 120 and 180 days after single doses of 20-45 Gy radiation, but not after lower doses (2 or 8 Gy). The increases in GFAP levels were confirmed by Western blot analysis and immunohistochemical staining which showed that the number of GFAP-positive astrocytes was increased, as was their staining intensity. Coincidently with the increase in astrocyte staining, there was an increase in the number and the intensity of microglial cell staining for Mac I antigen. Autoradiography of brain tissue following in vivo administration of [3H]thymidine showed an increased number of labelled cells during the same time period. The radiation-induced astrocytic and microglial responses that follows brain irradiation is indicative of reactive gliosis and inflammation occurring during the latent period up to the onset of late radiation-induced injury. This gliosis increases with radiation dose. The possibility that gliosis may participate in modifying postirradiation injury in the brain is discussed.

Induction of cortical spreading depression with potassium chloride upregulates levels of messenger RNA for glial fibrillary acidic protein in cortex and hippocampus: inhibition by MK-801

The present study evaluates the time course and spatial extent of changes in GFAP mRNA expression following the induction of spreading depression. Spreading depression was elicited by applying filterpaper pledgets soaked in KCl (3 M) to exposed parietal cortex for ten minutes. Animals were killed 1.5, 3, 6, 12, 24, 48, 96 and 192 h post-KCl application, and the forebrains were prepared for quantitative in situ hybridization. The KCl treatment led to a many-fold increase in GFAP mRNA content in the ipsilateral hippocampus and neocortex and, to a lesser extent, in the contralateral hippocampus, but did not affect GFAP mRNA levels in the contralateral cortex or in the thalamus. The time course of increased expression of GFAP mRNA in the hippocampus differed markedly from that of the cortex. In the hippocampus, GFAP mRNA levels rose rapidly to a maximum at 24 h post-exposure, then fell rapidly. In the cortex, levels rose more slowly and did not reach a maximum until 4 days post-exposure. Analysis of GFAP mRNA levels by dot blot hybridization using samples from a separate set of animals killed at one and 4 days following the KCl exposure confirmed both the upregulation in GFAP mRNA levels and the regional time course differences. Intraperitoneal injection of MK-801, a non-competitive NMDA antagonist which prevents spreading depression, blocked the upregulation of GFAP mRNA in both the hippocampus and the cortex, as demonstrated by both in situ and dot blot hybridization. The results suggest that the physiological changes accompanying spreading depression have a powerful influence on glial cell gene expression.

Immunohistochemical staining for glial fibrillary acidic protein (GFAP) after deafferentation or ischemic infarction in rat visual system: features of reactive and damaged astrocytes

Immunohistochemical staining for glial fibrillary acidic protein (GFAP) is standard for visualization of reactive astrocytes in tissue sections, whereas various forms of astrocytic damage remain to be described in detail. In this study we tested differences in GFAP labeling in reactive astrocytes and in glial cells damaged by ischemia and edema. Studies were performed in the anatomically well defined visual system of rat. Basic staining patterns for GFAP were established in subcortical visual nuclei and visual cortex. In the first model, deafferentation of visual centers was performed by unilateral optic nerve lesion, and characteristic changes of GFAP labeling in reactive astrocytes were studied at 0.5, 1, 1.5, 2, 4, 8 and 21 days after lesion. Initial changes were seen in the deafferented superior colliculus at 1 day after deafferentation with a diffuse increase and stellate types of reactive cells formed at 2-8 days. In the second model, small ischemic infarcts were produced in the visual cortex of rats using the method of photochemically-induced thrombosis. GFAP labeling with a polyclonal antiserum was massively enhanced in the infarct at 4 hr. Characteristic morphological changes in damaged astrocytes were seen which were also identified in experiments with simulated global ischemia. In the surround of the infarct, swelling of astrocytes also caused increased labeling. At 3-4 days infarction typical reactive astrocytes surrounded the lesioned area. In conclusion, these immunohistochemical studies on GFAP in rat visual system allow for the following classifications. (a) Normal astrocytes vary in labeling at different anatomical localizations. (b) Reactive astrocytes show enhanced labeling and larger cell-size within an interval of 1-2 days after lesion. (c) Astrocytes damaged by ischemia reveal increased labeling of disintegrating cellular elements within hours after a lesion. (d) Swollen astrocytes undergo enhanced labeling in areas with vasogenic edema.

Reactive astroglia-neuron relationships in the human cerebellar cortex: a quantitative, morphological and immunocytochemical study in Creutzfeldt-Jakob disease

In order to investigate the role of neuron-glia interactions in the response of astroglial to a non-invasive cerebellar cortex injury, we have used two cases of the ataxic form of Creutzfeldt-Jakob disease (CJD) with distinct neuronal loss and diffuse astrogliosis. The quantitative study showed no changes in cell density of either Purkinje or Bergmann glial cells in CJ-1, whereas in the more affected CJ-2 a loss of Purkinje cells and an increase of Bergmann glial cells was found. The granular layer in both CJD cases showed a similar loss of granule cells (about 60%) in parallel with the significant increase in GFAP+ reactive astrocytes. GFAP immunostaining revealed greater reactivity of Bergmann glia in CJ-2 than in CJ-1, as indicated by the thicker glial processes and the higher optical density. Granular layer reactive astrocytes were regularly spaced. In both CJD cases there was strict preservation of the spatial arrangement of all astroglial subtypes--Fañanas cells, Bergmann glia and granular layer astrocytes. Reactive Fañanas and Bergmann glial cells and microglia/macrophages expressed vimentin, while only a few vimentin+ reactive astrocytes were detected in the granular layer. Karyometric analysis showed that the increase in nuclear volume in reactive astroglia was directly related with the level of glial hypertrophy. The number of nucleoli per nuclear section was constant in astroglial cells of human controls and CJD, suggesting an absence of polyploidy in reactive astroglia. Ultrastructural analysis revealed junctional complexes formed by the association of macula adherens and gap junctions. In the molecular layer numerous vacant dendritic spines were ensheathed by lamellar processes of reactive Bergmann glia. Our results suggest that quantitative (neuron/astroglia ratio) and qualitative changes in the interaction of neurons with their region-specific astroglial partners play a central role in the astroglial response pattern to the pathogenic agent of CJD.

Transient cortical astrogliosis induced by alcohol exposure during the neonatal brain growth spurt in rats

The astrocyte response to central nervous system injury induced by neonatal alcohol exposure was evaluated using radioimmunoassay and immunocytochemistry of glial fibrillary acidic protein (GFAP). Rat pups were exposed to alcohol on postnatal days 4 through 9 via artificial rearing. Alcohol solutions were administered as one of the following treatments: 10.2% (v/v) in two feedings (4.5 g/kg/day), 5.1% (v/v) in four feedings (4.5 g/kg/day), or 2.5% (v/v) in 12 feedings (6.6 g/kg/day), producing mean blood alcohol concentrations (BACs) of approximately 300, 180, and 50 mg/dl, respectively. Littermates were included as gastrostomy controls (GC) and suckle controls (SC). On postnatal day 10, GFAP concentration increased as a function of BAC, and the 10.2% alcohol treatment significantly and dramatically increased GFAP in the cortex (325% of SC). GFAP immunocytochemistry revealed frequent loci of heavily labeled reactive astrocytes surrounding small cortical blood vessels in the 10.2% group. In addition, a generalized increase in GFAP immunoreactivity was present in the deep layers of the cortex in all alcohol groups, marked by astrocytic fibrillary hypertrophy and increased density. Three-dimensional counts in layer V of parietal cortex using confocal microscopy indicated that the density of GFAP-labeled astrocytes of the 10.2% group was twice that of controls. The layer V gliosis was observable even at low BACs, while gliosis around the vasculature occurred only with high BACs. By postnatal day 15, the astroglial effects were no longer evident. These transient astroglial reactions likely constitute an important aspect of cortical pathophysiology resulting from binge alcohol exposure during the brain growth spurt of the third trimester equivalent.

Neuropathologic changes in the gerbil brain after chronic hypoperfusion

BACKGROUND AND PURPOSE

An animal model has been developed to elucidate the pathological changes in brain cytoskeletal proteins during chronic hypoperfusion.

METHODS

Newly designed coiled clips were placed around both carotid arteries of Mongolian gerbils (n = 10) to cause stenosis without occlusion. Those gerbils showing impaired learning ability by the passive avoidance paradigm were killed for neuropathologic study after 12 weeks.

RESULTS

The brains showed ventricular dilatation, cortical atrophy, and rarefaction of the white matter. Immunoreactivity to anti-microtubule-associated protein 2 antibody in the cerebral cortex and the hippocampus was diminished, indicating dendritic changes of neurons. In the thalamic axonal regions, staining with anti-neurofilament 200K protein antibody was increased, suggesting increased amounts of neurofilament proteins or increased phosphorylation of the protein. Increased immunoreactivity to anti-glial fibrillary acidic protein antibody was observed in a wedge-shaped configuration, corresponding to the border zone of perfusion by small vessels.

CONCLUSIONS

These findings suggest that changes in the cytoskeletal proteins in dendrites, axons, and glial cells may cause neuronal death under conditions of chronic cerebral hypoperfusion.

Gliosis in human brain: relationship to size but not other properties of astrocytes

Gliosis is the most frequent and therefore important neurocellular reaction to brain insult occurring in diseases ranging from AIDS to infarction. Neuropathological diagnosis of gliosis is based on morphological changes of brain glial cells. Changes commonly agreed to reflect gliosis are qualitative increases in size, number and glial fibrillary acidic protein (GFAP) immunoreactivity of astrocytes. These parameters were morphometrically quantified in brain tissues of 22 individuals who died with 7 diseases and statistically compared to the extent of gliosis independently determined by 3 qualified observers. The data indicate that the extent of gliosis correlated with the increase in size of astrocytes in white matter (p = 0.67) and this relationship was statistically significant (P = 0.0006). In contrast, the extent of gliosis was not correlated with the density of astrocytes nor the intensity of GFAP staining.

Cortical astrocytes activated by basic fibroblast growth factor secrete molecules that stimulate differentiation of mesencephalic dopaminergic neurons

In reactive gliosis, astrocytes undergo morphological and biochemical changes which can be mimicked in vitro by treatment with bFGF (basic fibroblast growth factor) or cAMP. To investigate the influence of activated cortical astrocytes on central nervous system (CNSD) neurons, we studied the effect of the supernatant from bFGF-treated astrocytes on the development of dopaminergic neurons from rat mesencephalon. Conditioned medium of untreated astrocytes stimulated dopamine uptake of mesencephalic cultures. After activation of astrocytes with bFGF this effect was greatly enhanced. It was significantly more potent than stimulating effects of other neurotrophic factors. The supernatant of these astrocytes increased the biochemical differentiation but not the survival of dopaminergic neurons in our cell culture system. Trypsin digestion and gel chromatography revealed that the activity was due to one or several proteins with molecular mass above 5 kDa. We excluded the participation of several factors known to be produced by astrocytes or that are neurotrophic for substantia nigra cultures. In particular, we provide evidence that bFGF, BDNF, NT-3, Il-1, Il-6, S100 beta and alpha 2-macroglobulin were not involved in the effect of the conditioned medium. In vitro stimulation of astrocytes therefore triggers the expression of currently uncharacterized factors which influence the biochemical differentiation of mesencephalic dopaminergic neurons, the cells that degenerate in Parkinson's disease.

Localization of mu class glutathione-S-transferase in the forebrains of neonatal and young rats: implications for astrocyte development

The Yb (Mu class) isoform of glutathione-S-transferase has recently been localized in ependymal cells, subependymal cells, and astrocytes in the forebrains of rats 3 weeks to adult in age. It was not known, however, at what age Mu might first be observed during postnatal development and whether the first cells in which it was found would be immature astrocytes or some less differentiated glial precursor cell, if the latter were present in vivo. Tissue sections from the forebrains of neonatal to 16 day old rats were immunostained with antibodies against Mu. In neonates Mu was observed in vimentin-positive cells and their processes adjacent to the lateral ventricles, and in the corpus striatum. The colocalization with vimentin suggested that these were subependymal cells and radial glia. In the corpus striatum the radial glia, while still vimentin-positive, rapidly lost Mu from their radial cell processes, whereas the cell-bodies remained Mu-positive. During the first postnatal week the Mu-positive, glial-fibrillary-acidic-protein (GFAP)-positive cell bodies of immature astrocytes appeared in the corpus striatum. The earliest Mu-positive cells in the immature white matter of the corpus callosum were vimentin-positive and had striking longitudinal processes that also were vimentin- and Mu-positive. Like the processes of radial glia, the longitudinal processes lost their Mu-immunoreactivity, only later and more gradually. Mu-positive, GFAP-positive cells appeared later in the corpus callosum than in the corpus striatum.(ABSTRACT TRUNCATED AT 250 WORDS)

Macrophages and astroglial interactions in repair to brain injury

The response to brain injury appears to involve a well-coordinated interaction between microglia, extrinsic macrophages and glial cells. The proliferation of glial cells at the site of the injury appears necessary to reseal the brain. Most data support the view that glial cell (and fibroblast and endothelial cell) proliferation is driven by IL-1-like factors liberated by the invaded macrophages. Although less well established, most data, including our own suggest that glial cells contribute to the neutrotrophic response found after brain injury. In vitro evidence suggests that glial cell-mediated production of neurotrophic factors may also depend, like glial cell proliferation, on actions of interleukins (e.g., IL-1) at the site of the injury. Moreover, evidence of in vivo experiments, showing that immunosuppressants inhibit the glial response and that inhibition of glial proliferation suppresses the neurotrophic response are in line with this view. Restoration of the damaged brain site may also be compatible with the lack of T and B cell infiltration at the lesioned site. Factors such as prostaglandins and TGF-beta released from glial cells may be involved in controlling and counteracting a threatening immune attack. In conclusion, tissue repair in the brain appears to be centered around regulatory properties of glial cell proliferation, enhancement of neuronal growth and inhibition of a local immune response.

Transient ischemia stimulates glial fibrillary acid protein and vimentin gene expression in the gerbil neocortex, striatum and hippocampus

Astrocytic activation plays a major role in homeostatic maintenance of the central nervous system in response to neuronal damage. To assess the reactivity of astrocytes in transient cerebral ischemia of the gerbil, we studied the levels of glial fibrillary acidic protein (GFAP) and its mRNA. GFAP mRNA increased by 4 h after carotid artery occlusion, reached peak levels by 72 h with a 12-fold increase over control and then started declining as early as 96 h postischemia. An examination of the specific regions of the brain revealed an increase in GFAP mRNA associated with the forebrain, midbrain, hippocampus and striatum. GFAP mRNA in the non-ischemic cerebellum however, remained expressed at constitutively low levels. Immunoblot analysis with anti-GFAP antibodies demonstrated a 2- to 3-fold increase in the protein after 24 and 48 h of reperfusion. Pretreatment with pentobarbital and 1-(5'-oxohexyl)-3-methyl-7-propyl xanthine (HWA 285), the drugs that have been shown to protect against ischemic damage, prevented the increase in GFAP mRNA in the cortex following ischemic injury. Forebrain ischemia also induced vimentin mRNA and protein quantities by 12 h of reperfusion in the cortex. The levels of c-fos and preproenkephalin mRNA increased rapidly within 1 h after ischemic injury, demonstrating a temporal difference in mRNA changes following ischemia. These results indicate that an increase in GFAP and vimentin, the two glial intermediate filament proteins in the area of the ischemic lesion may be associated with a glial response to injury.

Astrogliosis in von Economo's and postencephalitic Parkinson's diseases supports probable viral etiology

A marked generalized astrogliosis was observed in the frontal and temporal white matter from a case of von Economo's disease and another of postencephalitic Parkinson's disease, which areas were otherwise devoid of any other demonstrable microscopic lesions. No similar astrocytic reaction of any severity was observed in the same areas in a number of other brain diseases or controls, except when other kinds of lesions were present in the same section, with reactive astrocytes being present within the primary or defining lesion or immediately close by. The marked astrogliosis in von Economo's and postencephalitic Parkinson's diseases in areas "distant" from the primary lesions seeming to indicate extensive pathological involvement, added to the strong qualitative and quantitative similarity of this reaction to that observed in concurrently studied cases of encephalitides caused by the human immunodeficiency virus, lend further factual support to the hypothesis of a viral etiology, albeit unspecified, in both von Economo's and postencephalitic Parkinson's diseases.

The compensatory 'rebound' of reactive astrogliosis: glial fibrillary acidic protein immunohistochemical analysis of reactive astrogliosis after a puncture wound to the brain of rats with portocaval anastomosis

This study was designed to compare the degree of reactive astrogliosis occurring around a puncture wound in the brain of normal rats and at different intervals after a similar puncture wound in rats with a portocaval anastomosis. The gliosis was evaluated by the number of astrocytes, the thickness of their processes and the intensity of the glial fibrillary acidic protein immunoreactivity. After the puncture wound in the brain of rats with a portocaval anastomosis, the gliosis varied at different intervals being: (1) decreased at 10 days, (2) markedly increased at 5 weeks and (3) significantly decreased at 8, 12, and 16 weeks. These findings suggest that 5 weeks after portocaval anastomosis, an active proliferation of the metabolically altered astrocytes occurs with heightened synthesis of glial fibrillary acidic protein in the period of adaptive compensation, the so-called compensatory 'rebound'. At 8 weeks or more after portocaval anastomosis, these altered astrocytes were considered to be in the phase of decompensation and incapable of maintaining the reactive response which occurred in normal rats. The compensatory rebound and decompensatory 'decline' illustrate the dynamic plasticity of the reactive astrogliosis.

Axonal projections between fetal spinal cord transplants and the adult rat spinal cord: a neuroanatomical tracing study of local interactions

Three neuroanatomical tracers have been employed to map the axonal projections formed between transplants of fetal spinal cord tissue and the surrounding host spinal cord in adult rats. Solid pieces of embryonic day 14 (E14) rat spinal cord were placed into hemisection aspiration cavities in the lumbar spinal cord. Injections of either (1) a mixture of horseradish peroxidase and wheat germ agglutinin- conjugated horseradish peroxidase, (2) Fluoro-Gold, or (3) Phaseolus vulgaris leucoagglutinin (PHA-L) were made into the transplants or the neighboring segments of the host spinal cord at 6 weeks to 14 months post-transplantation. Injections of anterograde and retrograde tracers into the transplants revealed extensive intrinsic projections that often spanned the length of the grafts. Axons arising from the transplants extended into the host spinal cord as far as 5 mm from the host-graft interface, as best revealed by retrograde labeling with Fluoro-Gold. Consistent with these observations, iontophoretic injections of PHA-L into the transplants also produced labeled axonal profiles at comparable distances in the host spinal cord, and in some instances elaborate terminals fields were observed surrounding host neurons. The majority of these efferent fibers labeled with PHA-L, however, were confined to the immediate vicinity of the host-graft boundary, and no fibers were seen traversing cellular partitions between host and transplant tissues. Host afferents to the transplants were also revealed by these tracing methods. For example, the injection of Fluoro-Gold into the grafts resulted in labeling of host neurons within the spinal cord and nearby dorsal root ganglia. In most cases, retrogradely labeled neurons in spinal gray matter were located within 0.5 mm of the graft site, although some were seen as far as 4-6 mm away. The distance and relative density of ingrowth exhibited by host axons into the grafts, however, appeared modest based upon the results of HRP and Fluoro-Gold retrograde labeling. This was further confirmed with the PHA-L anterograde method. Whereas some host fibers were seen extending into the transplants, the majority of PHA-L containing axons formed terminal-like profiles at or within 0.5 mm of the host-graft interface. The comprehensive view of intrinsic connectivity and host-graft projections obtained in these studies indicates that intraspinal grafts of fetal spinal cord tissue can establish a short-range intersegmental circuitry in the injured, adult spinal cord. These observations are consistent with the view that such grafts may contribute to the formation of a functional relay between separated segments of the spinal cord after injury.(ABSTRACT TRUNCATED AT 400 WORDS)

Origin of contralateral reactive gliosis in surgically injured rat cerebral cortex

While reactive gliosis is readily observed close to the site of cerebral injury, astrocyte reactivity can also occur in distant areas either ipsilateral or contralateral to the lesion site. The present experiments were designed to address the origin of contralateral gliosis in adult rats following a cortical stab wound injury. One-month-old rats were subjected to either left cortical stab wound alone, callosotomy alone, callosotomy plus left cortical stab wound, or no surgery; 7 days later, animals were sacrificed. Formalin-fixed, paraffin-embedded sections were obtained and immunostained for GFAP. While untreated controls showed no cortical gliosis, callosotomy alone induced mild bilateral cortical gliosis. Whether or not rats were subjected to a callosotomy, the left cortical stab wound produced identical results: severe ipsilateral cortical gliosis and moderate contralateral gliosis. In all lesion models, both the intensity of GFAP staining and the number of reactive astrocytes were most marked in cortical areas abutting the subarachnoid spaces and decreased gradually into the deeper cortical layers. Our results suggest that the origin of contralateral gliosis in cortical stab injury is more likely due to the release of soluble substance(s) which diffuse to distant areas, rather than the migration of astrocytes through the corpus callosum from the lesion site, or being subsequent to degeneration of neurons which fibers traverse the corpus callosum.

Astrocyte hypertrophy in the Alzheimer's disease hippocampal formation

In Alzheimer's disease (AD), neuritic plaques are often found in the hippocampal dentate gyrus along the boundary between inner and outer molecular layers. The dentate outer molecular layer in AD also exhibits axon sprouting in response to an early loss of entorhinal neurons. The relationship between the laminar arrangement of plaques and the sprouting remains unclear. In experimental entorhinal lesions in the rat, the denervated dentate outer molecular layer demonstrates hypertrophic astrocytes which may provide trophic support for the sprouting response. It is not known whether an equivalent astrocyte response occurs in AD or whether this response is related to the distribution of plaques. We used immunohistochemical staining for glial fibrillary acidic protein (GFAP) to demonstrate reactive astrocytes in the hippocampus in AD patients and age-matched controls. These results were compared to the astrocyte response to an experimental entorhinal lesion in the rat. Quantitative and qualitative analyses demonstrated a significant increase in GFAP-positive hypertrophic astrocytes in the dentate outer molecular layer in AD compared to controls. These astrocytes were randomly distributed within the outer layer and did not parallel the distribution of neuritic plaques. In the entorhinal-lesioned rat, reactive hypertrophied astrocytes also showed a selective distribution within the denervated outer molecular layer. Our results further support the similarity of the hippocampal response in AD and experimental entorhinal lesion but do not explain the laminar distribution of neuritic plaques along the denervated zone.

Vimentin mRNA expression increases after corticospinal axotomy in the adult hamster

We examined changes in vimentin gene expression during Wallerian degeneration after corticospinal axotomy in the adult hamster. Vimentin, which is the product of a type III intermediate filament (IF) gene, is expressed in various cells of mesenchymal origin, including microvascular endothelial cells, microglia and developing astrocytes. While increases in vimentin protein have been observed after various types of central nervous system (CNS) injury, it is not known whether this increase is due to increased vimentin mRNA expression. There is also conflicting evidence as to which cells are expressing increased levels of vimentin. In the present study we used in situ hybridization and double-label immunofluorescence techniques to address these issues. A 35S-labeled vimentin cDNA probe was used for in situ hybridizations of brain stem sections obtained 2, 7 and 14 days after unilateral transection of the corticospinal tract in the caudal medulla of adult hamsters. Autoradiography showed that an increase in vimentin mRNA associated with the degenerating corticospinal tract occurred by 2 days after axotomy and that the levels remained elevated for at least 14 days. Immunoblotting and immunocytochemical studies indicated that vimentin protein levels were increased in the degenerating corticospinal tract. Double-label immunofluorescence revealed many vimentin-positive cells and processes that were also labeled with GFAP antibody. In addition, cells and processes that were vimentin-negative but GFAP-positive were also found in the degenerating tract. We suggest that the reactive cells which possessed both vimentin and GFAP were reactive astrocytes of astroblastic origin while those that expressed only GFAP were derived from mature astrocytes. Other vimentin-positive cells/processes did not label with anti-GFAP and thus were either microglial, endothelial or inflammatory cells. These results demonstrate that an increase in vimentin mRNA occurs during Wallerian degeneration after corticospinal axotomy and that this increase is likely to be due to contributions from more than one cell type.

Transplantation of a temperature-sensitive, nerve growth factor-secreting, neuroblastoma cell line into adult rats with fimbria-fornix lesions rescues cholinergic septal neurons

The HT4 cell line was derived from infection of a mouse neuroblastoma cell line with a retrovirus that encoded the temperature-sensitive (ts) mutant of SV40 large T antigen. At nonpermissive temperature, HT4 cells differentiated with neuronal morphology, expressed neuronal antigens, synthesized nerve growth factor (NGF) mRNA, and secreted biologically active NGF in vitro. We sought to establish whether transplanted HT4 cells expressed class I major histocompatibility complex (MHC) antigens, a partial requirement for recognition by cytotoxic T lymphocytes (CTL), and thus be susceptible to xenograft rejection. Differentiated HT4 cells expressed marginally detectable levels of class I MHC antigens, but demonstrated higher levels of class I MHC expression after treatment with interferon-gamma. However, HT4 cells were resistant to direct lysis by perforin, the pore-forming protein of CTLs, and thus may have potential use in xenograft experiments. To address whether HT4 cells secrete NGF in vivo, HT4 cells were transplanted into adults rats with unilateral fimbria-fornix transections. A ts cell line derived from P4 cerebellum, BT1, that does not differentiate with neuronal phenotype or synthesize NGF in vitro, was transplanted as a control. Six weeks posttransplant. HT4 cells had integrated into host CNS without forming tumors. In BT1 transplants, the number of medial septal acetylcholinesterase (AChE)-positive cells was reduced to 26-39% of the contralateral control side, depending on the rostrocaudal level. In HT4 transplants, the number of cholinergic septal neurons was 58-78% of the contralateral side. This percentage was significantly (P less than 0.005) greater than that seen with BT1 transplants, indicating that transplanted HT4 cells secrete NGF in vivo and rescue cholinergic septal neurons following fimbria-fornix transection.

Changes in glial fibrillary acidic protein mRNA expression after corticospinal axotomy in the adult hamster

We examined changes in the expression of glial fibrillary acidic protein (GFAP) mRNA during Wallerian degeneration in the corticospinal system of the adult Golden hamster following axotomy. GFAP is the product of a type III intermediate filament (IF) gene that is expressed specifically in mature astrocytes. A well-studied component of a complex response termed reactive astrogliosis that occurs after various types of CNS injury is the increased production of astrocytic processes filled with GFAP-containing IFs. While increased expression of GFAP during reactive astrogliosis has been well established at the protein level, little is known about whether or not changes in GFAP mRNA levels occur after CNS injury. In the present study we used in situ hybridization methods to examine this issue. A 35S-labeled mouse GFAP cDNA probe was used for in situ hybridizations of sections of the brain stem obtained 2, 7, and 14 days after unilateral transections of the corticospinal tract in the caudal medulla. Film as well as emulsion autoradiography showed a dramatic increase in GFAP mRNA labeling associated with the degenerating corticospinal tract. GFAP mRNA levels were already dramatically increased in the injured corticospinal tract by 2 days post axotomy and remained elevated at 14 days. Interestingly, in addition to the robust increase in GFAP mRNA levels specifically associated with the degenerating tract, a diffuse increase in GFAP mRNA labeling was observed throughout the grey matter of the brain stem at 2 days post-axotomy, but not after this time. Immunoblotting and immunocytochemical experiments verified that the increased GFAP mRNA levels in the degenerating corticospinal system were accompanied by an increased expression of the protein. These results demonstrate that an increase in GFAP mRNA levels occurs during Wallerian degeneration in the CNS and suggest that increased expression of the GFAP gene is a major contributor to CNS scarring that results after direct traumatic injury.

Increase in glial fibrillary acidic protein following neural trauma

Immunohistochemical staining and quantitative evaluation of glial fibrillary acidic protein (GFAP) were carried out in a stab wound model of neural trauma in the rat. Increased GFAP staining was detected in reactive cortical astrocytes in the vicinity of the wound at 3, 7, and 30 d following injury. Western blots immunostained for GFAP also demonstrated an increase in GFAP in homogenates from the lesioned cortex, compared to the contralateral control side, on days 3, 7, and 30. Specific activity of GFAP expressed as a ratio of lesion/control values showed a fivefold increase from day 0 to day 7, with no further change on day 30. We conclude that neural trauma elicits a quantitative increase in GFAP in the rat cortex during the first week following injury. This increase correlates with both astrocyte hyperthrophy and proliferation. Thus, specific activity of GFAP is a reliable indicator of the onset and progression of astrogliosis in neural trauma.

Spinal cord repair: is tissue oxygenation an important variable?

We have demonstrated the reliability and feasibility of making PtO2 recordings from graft and host tissue in the injured spinal cord. The data suggest that the oxygen microenvironment of developing graft and host spinal tissue is clearly different from that found in normal spinal tissue or in transplants that have not survived or integrated well. These same constraints seem to apply to cavitation in developing grafts and poorly developed graft/host interfaces. The similarity between these findings and those from previous studies in other fetal vertebrates suggests that oxygen tensions in the spinal cord probably reflect the developmental status of the regenerating tissue. Our future studies will seek to define the relationship between anatomical development of transplant tissue and these functional (PtO2, microvascular development and tissue metabolism) indicators of graft development. These investigations should also provide a background for those later studies which seek to establish the mechanisms by which these relationships come about i.e. oxygen consumption of host/transplant tissue, blood flow to transplants, studies of glycolytic metabolism (2-DG autoradiography), etc. In this way, we can begin to understand the role of tissue metabolism in graft-mediated repair.

Reactive astrogliosis after basic fibroblast growth factor (bFGF) injection in injured neonatal rat brain

Reactive gliosis was revealed by immunocytochemistry using antibodies against the glial fibrillary acidic protein (GFAP) after a stab or an electrolytic lesion administered to the cerebral cortex, corpus callosum, striatum, or hippocampus of a 6-day-old rat. The intensity of the gliosis was about the same in the various structures injured and did not change with the delay of 3, 7, or 20 days between the injury and the sacrifice of the animals. When basic fibroblast growth factor (bFGF) was injected in the lesion locus just after the lesion was performed, it resulted (as soon as 3 days after injury) in a strong astrogliosis that was enhanced after a delay of 7 days, the astrocytes in the lesion area exhibiting enlarged cell processes and intense GFAP-positive immunoreactivity. After a delay of 20 days, the astrocytes were not dispersed any more but packed in three or four layers along the borders of the lesion, thus reducing its extension. This suggests a possible role for bFGF in promoting scar formation following brain injury.

Attenuation of neurotoxicity following anoxia or glutamate receptor activation in EGF- and hippocampal extract-treated neuronal cultures

Neurotoxicity following anoxia or glutamate receptor activation was studied in primary neuronal cultures grown in serum-free, chemically defined CDM R12 medium. Exposure to 1 mM KCN, 0.5 mM kainic acid and 0.5 mM N-methyl-D-aspartate led to progressive neuronal degeneration. This damage was quantified by measuring lactate dehydrogenase released in the culture medium. The toxic effects were observed early during the development of the neuronal culture (from 4 days in vitro on) and seemed to be neuron-specific since astrocyte cultures were not affected. Chronic treatment of the neuronal cultures with epidermal growth factor at 10 ng/ml and hippocampal extract at dil. 1/833 (w/v) induced morphological alterations, increased beta-adrenergic receptor coupled adenylate cyclase activity, increased level of total lactate dehydrogenase activity in the case of epidermal growth factor-treated cultures, and attenuation of lactate dehydrogenase release following exposure to KCN or glutamate receptor agonists. The alterations observed are probably due to the proliferation and differentiation of glial cells in these treated cultures. This suggests that glial cells protect neurons in vitro from degeneration induced by anoxia or glutamate receptor activation.

Astrocyte morphology altered by 1-(5-isoquinolinylsulfonyl) 2-methyl piperazine (H-7) and other protein kinase inhibitors

Studies were conducted to determine if the protein kinase C inhibitor H-7 could block the effects of phorbol-12-myristate-13-acetate (PMA) on astrocyte morphology. Contrary to expectation, H-7 alone was found to induce morphological changes very similar to those elicited by PMA. This effect was shared by two other inhibitors of protein kinase C, H-8 and staurosporine, but not by the cyclic nucleotide-dependent protein kinase inhibitor HA-1004 or the calcium/calmodulin dependent protein kinase inhibitor W-7. Although the morphological effects observed with H-7 resemble those induced by PMA, H-7 did not promote the redistribution of protein kinase C to the membrane or induce the phosphorylation of endogenous proteins like PMA. In addition, the effects of H-7 were still observed in cells depleted of protein kinase C activity which were no longer responsive to treatment with PMA. Cytoskeletal elements appear to be involved in the effect of H-7 on cell shape since this effect is blocked by treatment with colchicine. Activators of the cyclic AMP-dependent protein kinase also alter astrocyte shape, however, while H-7 did cause a slight increase in cyclic AMP levels, it was unlikely that this action is responsible for its effect on morphology. One common action of both H-7 and PMA was to decrease the 32P content of several 20,000 Da proteins. While the mechanism by which H-7 exerts its influence on astrocyte morphology remains to be clarified, be it by the inhibition of protein kinase C or some other mechanism, the results suggest that caution must be used when interpreting the effects of activators and inhibitors of this kinase.