Thrombospondin-4 contributes to spinal cord injury-induced changes in nociception

BACKGROUND

Our previous data have indicated that nerve injury-induced up-regulation of thrombospondin-4 (TSP4) proteins in dorsal spinal cord plays a causal role in neuropathic pain state development in a spinal nerve ligation model. To investigate whether TSP4 proteins also contribute to the development of centrally mediated changes in nociception after spinal cord injury (SCI), we investigated whether SCI induced TSP4 dysregulation, and if so, whether this change correlated with changes in nociception in a T9 spinal cord contusion injury model.

METHODS

Behavioural sensitivity to mechanical, thermal stimuli and locomotor function recovery were tested blindly in SCI or sham rats post-injury. Intrathecal antisense or mismatch control oligodeoxynucleotides were used to treat SCI rats with nociceptive hyperreflexia, and Western blots were used to measure TSP4 protein levels in dorsal spinal cord samples.

RESULTS

SCI induced below-level hindpaw hypersensitivity to stimuli. TSP4 protein levels are up-regulated in dorsal spinal cord of SCI rats with nociceptive hyperreflexia, but not in SCI rats without nociceptive hyperreflexia. There was no significant difference in motor function recovery post-injury between SCI rats with or without nociceptive hyperreflexia. Intrathecal treatment with TSP4 antisense, but not mismatch control, oligodeoxynucleotides led to reversal of injury-induced TSP4 up-regulation and nociceptive hyperreflexia in SCI rats.

CONCLUSIONS

SCI leads to TSP4 up-regulation in lumbar spinal cord that may play a critical role in mediating centrally mediated behavioural hypersensitivity. Blocking this pathway may be helpful in management of SCI-induced changes in nociception.

Analysis of collateral projections with a double retrograde labeling technique

A method is described whereby collateral innervation by a single cell type may be determined by double retrograde labeling with horseradish peroxidase (HRP) and tritiated bovine serum albumin ([(3)H]BSA). The projections from the entorhinal area to the hippocampal formation were analyzed as a model system, since layer III pyramidal cells project bilaterally to the hippocampus. Following HRP injections into the hippocampus of one side, and [(3)H]BSA injections into the opposite hippocampus, double labeled cells were found in layer III of the entorhinal cortex. These doubly labeled cells could best be viewed in plastic embedded material, whereas frozen sections were found to be inadequate for clearly distinguishing between silver grains and HRP reaction product.

Zn(2+) induces permeability transition pore opening and release of pro-apoptotic peptides from neuronal mitochondria

Rapid entry of Ca(2+) or Zn(2+) kills neurons. Mitochondria are major sites of Ca(2+)-dependent toxicity. This study examines Zn(2+)-initiated mitochondrial cell death signaling. 10 nm Zn(2+) induced acute swelling of isolated mitochondria, which was much greater than that induced by higher Ca(2+) levels. Zn(2+) entry into mitochondria was dependent upon the Ca(2+) uniporter, and the consequent swelling resulted from opening of the mitochondrial permeability transition pore. Confocal imaging of intact neurons revealed entry of Zn(2+) (with Ca(2+)) to cause pronounced mitochondrial swelling, which was far greater than that induced by Ca(2+) entry alone. Further experiments compared the abilities of Zn(2+) and Ca(2+) to induce mitochondrial release of cytochrome c (Cyt-c) or apoptosis-inducing factor. In isolated mitochondria, 10 nm Zn(2+) exposures induced Cyt-c release. Induction of Zn(2+) entry into cortical neurons resulted in distinct increases in cytosolic Cyt-c immunolabeling and in cytosolic and nuclear apoptosis-inducing factor labeling within 60 min. In comparison, higher absolute [Ca(2+)](i) rises were less effective in inducing release of these factors. Addition of the mitochondrial permeability transition pore inhibitors cyclosporin A and bongkrekic acid decreased Zn(2+)-dependent release of the factors and attenuated neuronal cell death as assessed by trypan blue staining 5-6 h after the exposures.

Disruption of inhibition in area CA1 of the hippocampus in a rat model of temporal lobe epilepsy

Previous studies have revealed a loss of neurons in layer III of the entorhinal cortex (EC) in patients with temporal lobe epilepsy. These neurons project to the hippocampus and may activate inhibitory interneurons, so that their loss could disrupt inhibitory function in the hippocampus. The present study evaluates this hypothesis in a rat model in which layer III neurons were selectively destroyed by focal injections of the indirect excitotoxin, aminooxyacetic acid (AOAA). Inhibitory function in the hippocampus was assessed by evaluating the discharge of CA1 neurons in response to stimulation of afferent pathways in vivo. In control animals, stimulation of the temporo-ammonic pathway leads to heterosynaptic inhibition of population spikes generated by subsequent stimulation of the commissural projection to CA1. This heterosynaptic inhibition was substantially reduced in animals that had received AOAA injections 1 mo previously. Stimulation of the commissural projection also elicited multiple population spikes in CA1 in AOAA-injected animals, and homosynaptic inhibition in response to paired-pulse stimulation of the commissural projection was dramatically diminished. These results suggest a disruption of inhibitory function in CA1 in AOAA-injected animals. To determine whether the disruption of inhibition occurred selectively in CA1, we assessed paired-pulse inhibition in the dentate gyrus. Both homosynaptic inhibition generated by paired-pulse stimulation of the perforant path, and heterosynaptic inhibition produced by activation of the commissural projection to the dentate gyrus appeared largely comparable in AOAA-injected and control animals; thus abnormalities in inhibitory function following AOAA injections occurred relatively selectively in CA1. Electrolytic lesions of the EC did not cause the same loss of inhibition as seen in animals with AOAA injections, indicating that the loss of inhibition in CA1 is not due to the loss of excitatory driving of inhibitory interneurons. Also, electrolytic lesions of the EC in animals that had been injected previously with AOAA had little effect on the abnormal physiological responses in CA1, suggesting that most alterations in inhibition in CA1 are not due to circuit abnormalities within the EC. Comparisons of control and AOAA-injected animals in a hippocampal kindling paradigm revealed that the duration of afterdischarges elicited by high-frequency stimulation of CA3, and the number of stimulations required to elicit kindled seizures were comparable. Taken together, our results reveal that the selective loss of layer III neurons induced by AOAA disrupts inhibitory function in CA1, but this does not create a circuit that is more prone to at least one form of kindling.

Protein synthesis at synaptic sites on dendrites

Studies over the past 20 years have revealed that gene expression in neurons is carried out by a distributed network of translational machinery. One component of this network is localized in dendrites, where polyribosomes and associated membranous elements are positioned beneath synapses and translate a particular population of dendritic mRNAs. The localization of translation machinery and mRNAs at synapses endows individual synapses with the capability to independently control synaptic strength through the local synthesis of proteins. The present review discusses recent studies linking synaptic plasticity to dendritic protein synthesis and mRNA trafficking and considers how these processes are regulated. We summarize recent information about how synaptic signaling is coupled to local translation and to the delivery of newly transcribed mRNAs to activated synaptic sites and how local translation may play a role in activity-dependent synaptic modification.

Glycoprotein synthesis at the synapse: fractionation of polypeptides synthesized within isolated dendritic fragments by concanavalin A affinity chromatography

The synthesis of glycosylated proteins at postsynaptic sites was evaluated by combining metabolic labeling of isolated pinched-off dendritic fragments (synaptodendrosomes) with glycoprotein isolation by Con A affinity chromatography. Three major labeled proteins were detected (apparent molecular weights of 128, 42 and 19 kDa) along with seven minor polypeptides. Treatment of the glycoprotein fraction with N-glycosidase F led to shift in the apparent molecular weight of the bands. Also, label incorporation into glycoprotein species was blocked by tunicamycin. Thus, the three prominent polypeptides and most of the minor components of this fraction corresponded to bona fide N-glycoproteins. Incubation of synaptodendrosomes with cycloheximide also inhibited label incorporation into the isolated glycoproteins, indicating that the labeling resulted from local de novo synthesis. Subcellular fractionation revealed that the labeled glycoproteins were present in soluble and particulate fractions, mainly microsomes and synaptic membranes, and one of the species (42 kDa) appeared in the incubation medium, indicating secretion. In addition, these glycoproteins were dissimilarly distributed in several brain regions, and were expressed differentially during development, reaching their highest level of synthesis during the period of synaptogenesis. These results provide evidence for local dendritic synthesis of particular glycoprotein components of the synapse.

Protein synthesis at the synapse: developmental changes, subcellular localization and regional distribution of polypeptides synthesized in isolated dendritic fragments

This study evaluated local protein synthesis in subcellular fractions of pinched-off dendrites (synaptodendrosomes) from different brain regions and at different developmental ages. Synaptodendrosomes were labeled with [35S]methionine and newly synthesized proteins were characterized by SDS-PAGE and phosphorimaging. The same set of approximately 30 cycloheximide-sensitive labeled bands was observed in synaptodendrosomes isolated from different brain regions, although the relative enrichment of some individual bands varied. Labeling of several major proteins was developmentally regulated, revealing three different patterns of variation. Subcellular fraction studies revealed that at least 10 labeled bands were enriched in synaptic junctions.

A cellular mechanism for targeting newly synthesized mRNAs to synaptic sites on dendrites

Long-lasting forms of activity-dependent synaptic plasticity involve molecular modifications that require gene expression. Here, we describe a cellular mechanism that mediates the targeting newly synthesized gene transcripts to individual synapses where they are locally translated. The features of this mechanism have been revealed through studies of the intracellular transport and synaptic targeting of the mRNA for a recently identified immediate early gene called activity-regulated cytoskeleton-associated protein Arc. Arc is strongly induced by patterns of synaptic activity that also induce long-term potentiation, and Arc mRNA is then rapidly delivered into dendrites after episodes of neuronal activation. The newly synthesized Arc mRNA localizes selectively at synapses that recently have been activated, and the encoded protein is assembled into the synaptic junctional complex. The dynamics of trafficking of Arc mRNA reveal key features of the mechanism through which synaptic activity can both induce gene expression and target particular mRNA transcripts to the active synapses.

Selective targeting of newly synthesized Arc mRNA to active synapses requires NMDA receptor activation

Newly synthesized Arc mRNA is selectively targeted to synapses that have experienced particular patterns of activity. Here, we demonstrate that the targeting requires NMDA receptor activation. Arc expression was induced by an electroconvulsive seizure, and the newly synthesized mRNA was then targeted to synaptic sites by activating the perforant path projections to the dentate gyrus. When micropipette electrodes containing NMDA receptor antagonists (MK801 or APV) were positioned in the dentate gyrus during the stimulation period, newly synthesized Arc mRNA was transported into dendrites but did not localize in the activated lamina; instead, the mRNA remained diffusely distributed. AMPA receptor antagonists (CNQX) blocked targeting of Arc mRNA in a small region, and mGluR antagonists (MCPG) did not affect localization. These results demonstrate that NMDA receptor activation is required for the targeting of Arc mRNA to active synapses.

Differential mRNA localization in astroglial cells in culture

Messenger RNA (mRNA) targeting to specific subcellular domains has been studied extensively in many cell types, and there is increasing evidence suggesting that mRNA sorting also occurs in astrocytes. As a step toward developing strategies to evaluate the signals that govern mRNA sorting in astrocytes, the authors studied the subcellular distribution of several representative mRNAs, poly(A) RNA and ribosomal RNA, in process-bearing (type-2) astroglial cells in culture. Nonradioactive in situ hybridization analysis revealed a gradual increase in the expression of glial fibrillary acidic protein (GFAP) mRNA as type-2 astrocytes differentiated in culture. In mature cells, labeling was present in both cell bodies and processes. GFAP mRNA labeling was granular in nature and was particularly concentrated at branch points and at the tips of the processes. Unlike GFAP mRNA, vimentin, beta-tubulin, and beta- and gamma-actin mRNAs were mainly confined to the cell bodies, with only occasional labeling seen in the processes. Nonradioactive and radioactive in situ hybridization analysis of poly(A) and ribosomal RNA, respectively, revealed labeling in cell bodies and processes of immature and differentiated astrocytes. Treatment with nocodazole, a microtubule depolymerizing agent, resulted in a substantial reduction of GFAP mRNA labeling in the processes, whereas treatment with cytochalasin D, a microfilament-disrupting agent, did not alter GFAP mRNA distribution. The results indicate that cultured type-2 astrocytes have the capacity to sort mRNAs to different subcellular domains and that the localization of GFAP mRNA to astrocyte processes requires intact microtubules.

Movement of mitochondria in the axons and dendrites of cultured hippocampal neurons

Mitochondria generate ATP and are involved in the regulation of cytoplasmic calcium levels. It is thought that local demand for mitochondria differs between axons and dendrites. Moreover, it has been suggested that the distribution of both energy need and calcium flux in dendrites changes with patterns of synaptic activation, whereas the distribution of these demands in axons is stable. The present study sought to determine whether there are differences in mitochondrial movements between axons and dendrites that may relate to differences in local mitochondrial demand. We labeled the mitochondria in cultured hippocampal neurons with a fluorescent dye and used time-lapse microscopy to examine their movements. In both axons and dendrites, approximately one-third of the mitochondria were in motion at any one time. In both domains, approximately 70% of the mitochondria moved in the anterograde direction, whereas the remainder moved in the retrograde direction. The velocity of the movements in each direction in each domain ranged from 0.1 microm/sec to approximately 2 microm/sec, and the means and distributions of the velocities were similar. Only one difference in the behavior of mitochondria between axons and dendrites emerged from this analysis. Mitochondria in axons were more likely to move with a consistently rapid velocity than were those in dendrites. As a result, mitochondria in axons tended to travel farther than mitochondria in dendrites. These results suggest that the transport of mitochondria in axons and dendrites is similar despite any differences in mitochondrial demand between the two domains.

Role of microtubules and actin filaments in the movement of mitochondria in the axons and dendrites of cultured hippocampal neurons

The mitochondria in the axons and dendrites of neurons are highly motile, but the mechanism of these movements is not well understood. It has been thought that the transport of membrane-bounded organelles in axons, and perhaps also in dendrites, depends on molecular motors of the kinesin and dynein families. However, recent evidence has suggested that some organelle transport, including that of mitochondria, may proceed along actin filaments as well. The present study sought to determine the extent to which mitochondrial movements in neurons depend on microtubule-based and actin-based transport systems. The mitochondria in cultured hippocampal neurons were labeled with a fluorescent dye and the cells were treated with either nocodazole, a drug that disrupts the microtubule network or cytochalasin D or latrunculin B, drugs which disrupt the actin network. The movement of the mitochondria in the axons and dendrites of neurons after each of these drug treatments was then examined with time-lapse microscopy. Treatment with nocodazole, which depolymerizes microtubules, stopped most mitochondrial movements in both axons and dendrites. Treatment with cytochalasin D, which aggregates actin filaments, also inhibited most movements of mitochondria, but latrunculin B, which depolymerizes actin filaments, had virtually no effect. Together, these data suggest that most of the mitochondrial movements in both axons and dendrites are microtubule-based, but in each domain there may also be some movement along actin filaments.

The unique histopathological responses of the injured spinal cord. Implications for neuroprotective therapy

Tissue destruction at the primary site of a spinal cord injury leads to persistent necrosis that progressively enlarges the lesion. Steroids attenuate this necrotizing process and promote tissue repair even though such anti-inflammatory drugs interfere with wound healing in non-CNS organs. To address this paradox, the spinal cord of rats and mice was crushed extradurally and the effects of the following anti-inflammatory agents studied by light microscopical image analysis: allopurinol, aminoguanidine, indomethacin, a bacterial lipopolysaccharide, naproxen, and pregnenolone. The contribution of Wallerian degeneration to progressive necrosis was studied in a mutant mouse strain (WldS) that is characterized by delayed Wallerian degeneration. In rats, the anti-inflammatory agents selectively attenuated progressive necrosis and encouraged wound healing. In mice, considerable tissue repair occurred without pharmacological intervention; this wound-healing process was delayed in the mutant WldS strain. Since spinal cord injury results in concomitant tissue necrosis and wound healing, a goal of neuroprotective therapy is to regulate the dynamic balance between these destructive and reparative processes.

Genetic dissection of the signals that induce synaptic reorganization

Synaptic reorganization of mossy fibers following kainic acid (KA) administration has been reported to contribute to the formation of recurrent excitatory circuits, resulting in an epileptogenic state. It is unclear, however, whether KA-induced mossy fiber sprouting results from neuronal cell loss or the seizure activity that KA induces. We have recently demonstrated that certain strains of mice are resistant to excitotoxic cell death, yet exhibit seizure activity similar to what has been observed in rodents susceptible to KA. The present study takes advantage of these strain differences to explore the roles of seizure activity vs cell loss in triggering mossy fiber sprouting. In order to understand the relationships between gene induction, cell death, and the sprouting response, we assessed the regulation of two molecules associated with the sprouting response, c-fos and GAP-43, in mice resistant (C57BL/6) and susceptible (FVB/N) to KA-induced cell death. Following administration of KA, increases in c-fos immunoreactivity were observed in both strains, although prolonged induction of c-fos was present only in the hippocampal neurons of FVB/N mice. Mossy fiber sprouting following KA administration was also only observed in FVB/N mice, while induction of GAP-43, a marker associated with mossy fiber sprouting, was not observed in either strain. These results indicate that: (i) KA-induced seizure activity alone is insufficient to induce mossy fiber sprouting; (ii) mossy fiber sprouting may be due to the loss of hilar neurons following kainate administration; and (iii) induction of GAP-43 is not a necessary component of the sprouting response that occurs following KA in mice.

Lamina-specific synaptic activation causes domain-specific alterations in dendritic immunostaining for MAP2 and CAM kinase II

Polyribosomal complexes are selectively localized beneath postsynaptic sites on neuronal dendrites; this localization suggests that the translation of the mRNAs that are present in dendrites may be regulated by synaptic activity. The present study tests this hypothesis by evaluating whether synaptic activation alters the immunostaining pattern for two proteins whose mRNAs are present in dendrites: the dendrite-specific cytoskeletal protein MAP2 and the alpha-subunit of CAMKII. High-frequency stimulation of the perforant path projections to the dentate gyrus, which terminate in a discrete band on the dendrites of dentate granule cells, produced a two-stage alteration in immunostaining for MAP2 in the dendritic laminae. Five minutes of stimulation (30 trains) caused a decrease in MAP2 immunostaining in the lamina in which the activated synapses terminate. After more prolonged periods of stimulation (1-2 hr), there was an increase in immunostaining in the sideband laminae just proximal and distal to the activated band of synapses. The same stimulation paradigm produced a modest increase in immunostaining for alpha-CAMKII in the activated laminae, with no detectable changes in the sideband laminae. The alterations in immunostaining for MAP2 were diminished, but not eliminated, by inhibiting protein synthesis; the increases in CAMKII were not. These findings reveal that patterned synaptic activity can produce domain-specific alterations in the molecular composition of dendrites; these alterations may be caused in part by local protein synthesis and in part by other mechanisms.

Synaptic clustering of AMPA receptors by the extracellular immediate-early gene product Narp

Narp (neuronal activity-regulated pentraxin) is a secreted immediate-early gene (IEG) regulated by synaptic activity in brain. In this study, we demonstrate that Narp possesses several properties that make it likely to play a key role in excitatory synaptogenesis. Narp is shown to be selectively enriched at excitatory synapses on neurons from both the hippocampus and spinal cord. Overexpression of recombinant Narp increases the number of excitatory but not inhibitory synapses in cultured spinal neurons. In transfected HEK 293T cells, Narp interacts with itself, forming large surface clusters that coaggregate AMPA receptor subunits. Moreover, Narp-expressing HEK 293T cells can induce the aggregation of neuronal AMPA receptors. These studies support a model in which Narp functions as an extracellular aggregating factor for AMPA receptors.

Genetic approaches to neurotrauma research: opportunities and potential pitfalls of murine models

Genetic strategies provide new ways to define the molecular cascades that regulate the responses of the mammalian nervous system to injury. Genetic interventions also provide opportunities to manipulate and control key molecular steps in these cascades, so as to modify the outcome of CNS injury. Most current genetic strategies involve the use of mice, an animal that has not heretofore been used extensively for neurotrauma research. Therefore, one purpose of the present review is to consider how mice respond to neural trauma, focusing especially on recent information that reveals important differences between mice and rats, and between different inbred strains of mice. The second aim of this review is to provide a brief introduction to the opportunities, caveats, and potential pitfalls of studies that use genetically modified animals for neurotrauma research.

Synaptic activation causes the mRNA for the IEG Arc to localize selectively near activated postsynaptic sites on dendrites

Polyribosomal complexes beneath postsynaptic sites on dendrites provide a substrate for local translation of particular mRNAs, but the signals that target mRNAs to synapses remain to be defined. Here, we report that high frequency activation of the perforant path projections to the dentate gyrus causes newly synthesized mRNA for the immediate-early gene (IEG) Arc to localize selectively in activated dendritic segments. Newly synthesized Arc protein also accumulates in the portion of the dendrite that had been synaptically activated. The targeting of Arc mRNA was not disrupted by locally inhibiting protein synthesis, indicating that the signals for mRNA localization reside in the mRNA itself. This novel mechanism through which newly synthesized mRNA is precisely targeted to activated synapses is well suited to play a role in the enduring forms of activity-dependent synaptic modification that require protein synthesis.

No evidence for disruption of normal patterns of mRNA localization in dendrites or dendritic transport of recently synthesized mRNA in FMR1 knockout mice, a model for human fragile-X mental retardation syndrome

Recent studies have revealed that FMRP, the gene product of the fragile-X gene FMR1, is an RNA-binding protein. These and other data have led to the idea that FMRP may play a role in targeting mRNAs for transport to synaptic sites. The present study evaluated whether a null mutation of FMR1 disrupts the patterns of localization of three mRNAs that are present constitutively in dendrites (the mRNAs for MAP2, CAMII kinase and dendrin), or disrupt the rapid dendritic transport of the mRNA for activity-regulated cytoskeletal protein (ARC), coded for by an immediate-early gene. In situ hybridization analyses revealed that the patterns of mRNA localization in dendrites and the dendritic transport of ARC mRNA are indistinguishable from normal in FMR1 knockout mice. These results indicate that FMRP does not play an obligatory role in targeting this set of mRNAs to dendrites, although it might be involved in targeting other dendritic mRNAs yet to be identified.

Mechanisms of motor recovery after subtotal spinal cord injury: insights from the study of mice carrying a mutation (WldS) that delays cellular responses to injury

Partial lesions of the mammalian spinal cord result in an immediate motor impairment that recovers gradually over time; however, the cellular mechanisms responsible for the transient nature of this paralysis have not been defined. A unique opportunity to identify those injury-induced cellular responses that mediate the recovery of function has arisen from the discovery of a unique mutant strain of mice in which the onset of Wallerian degeneration is dramatically delayed. In this strain of mice (designated WldS for Wallerian degeneration, slow), many of the cellular responses to spinal cord injury are also delayed. We have used this experimental animal model to evaluate possible causal relationships between these delayed cellular responses and the onset of functional recovery. For this purpose, we have compared the time course of locomotor recovery in C57BL/6 (control) mice and in WldS (mutant) mice by hemisecting the spinal cord at T8 and evaluating locomotor function at daily postoperative intervals. The time course of locomotor recovery (as determined by the Tarlov open-field walking procedure) was substantially delayed in mice carrying the WldS mutation: C57BL/6 control mice began to stand and walk within 6 days (mean Tarlov score of 4), whereas mutant mice did not exhibit comparable locomotor function until 16 days postoperatively.

INTERPRETATION AND CONCLUSION

(a) The rapid return of locomotor function in the C57BL/6 mice suggests that the recovery resulted from processes of functional plasticity rather than from regeneration or collateral sprouting of nerve fibers. (b) The marked delay in the return of locomotor function in WldS mice indicates that the processes of neuroplasticity are induced by degenerative changes in the damaged neurons. (c) These strains of mice can be effectively used in future studies to elucidate the specific biochemical and physiological alterations responsible for inducing functional plasticity and restoring locomotor function after spinal cord injury.

Differential intracellular sorting of immediate early gene mRNAs depends on signals in the mRNA sequence

This study characterizes the differential targeting of recently synthesized immediate early gene (IEG) mRNAs to neuronal cell bodies versus dendrites and tests the hypothesis that this targeting is based on signals in the encoded proteins. A single electroconvulsive seizure induces the expression of a number of IEG mRNAs in granule cells of the dentate gyrus. Most of these IEG mRNAs remain in the cell body, including two that are characterized in the present study (the mRNAs for NGFI-A and COX-2). In contrast, the mRNA for Arc moved rapidly into dendrites at an apparent rate of approximately 300 micron/hr. Inhibiting protein synthesis with cycloheximide did not disrupt the differential mRNA sorting, demonstrating that the differential targeting of mRNAs is not dependent on translation.

Signals that regulate astroglial gene expression: induction of GFAP mRNA following seizures or injury is blocked by protein synthesis inhibitors

Previous studies have revealed that a single electroconvulsive seizure (ECS) strongly induces glial fibrillary acidic protein (GFAP) expression in astrocytes in the hippocampal dentate gyrus. The signals that trigger this induction are not known, but circumstantial evidence suggests the hypothesis that GFAP expression may be induced as a result of the induction of growth factor expression by dentate granule cells that also occurs as a result of the ECS and other types of seizures. The present study tests one prediction of this hypothesis by evaluating whether increases in GFAP mRNA levels after ECS are blocked by inhibiting protein synthesis at various times after the ECS. We report that the upregulation of GFAP expression following ECS is blocked by protein synthesis inhibitors given 5 min before or up to 12 h after a single ECS. This temporal gradient suggests an intermediate step involving the increased expression of a protein growth factor.

Multiple subcellular mRNA distribution patterns in neurons: a nonisotopic in situ hybridization analysis

Previous studies have established that most of the mRNAs that neurons express are localized in the cell body and very proximal dendrites, whereas a small subset of mRNAs is present at relatively high levels in dendrites. It is not clear, however, whether particular mRNAs have the same subcellular distribution in different types of neurons or whether different types of neurons sort mRNAs in different ways. The present study was undertaken to address these questions. Nonisotopic in situ hybridization techniques were used to define the subcellular localization of representative mRNAs including beta-tubulin, low-molecular-weight neurofilament protein (NF-68), high-molecular-weight microtubule-associated protein (MAP2), growth-associated protein 43 (F1/GAP43), the alpha subunit of calcium/calmodulin-dependent protein kinase II (alpha CaMII kinase), and poly (A+) mRNA. The mRNAs for beta-tubulin, neurofilament 68, and F1/GAP43 were restricted to the region of the cell body and very proximal dendrites in most neurons. In some neuron types, however, labeling for NF-68 extended for considerable distances into dendrites. In some neurons that express MAP2, the mRNA was present at the highest levels in the proximal third to half of the dendritic arbor, whereas in other neurons the highest levels of labeling were in the cell body. In most neurons that express alpha CaMII kinase, the highest levels of the mRNA were in the cell body, but labeling was also present throughout dendrites. However, in a few types of neurons, alpha CaMII kinase mRNA was largely restricted to the cell body. The fact that there are no general rules for mRNA localization that apply to all neuron types implies the existence of neuron type-specific mechanisms that regulate mRNA distribution.

Injury-induced physiological events that may modulate gene expression in neurons and glia

Damage to the brain triggers a host of reactive responses in neurons and glia which are seen at sites of focal injury as well as at sites that are at a distance from the injury. Although many of these responses have been studied extensively, the signals that initiate the different responses have not been fully characterized, and it is still not understood how focal injury affects neurons and glia in distant sites. The present review summarizes recent findings that suggest that physiological events that occur at the time of the injury or during the early postlesion period can play an important and variable role in modulating neuronal and glial responses to injury. We focus on the events that occur in the hippocampal formation following unilateral lesions of the entorhinal cortex - a model system that has been used extensively for studies of cellular responses following focal brain injury. This lesion destroys the cells of origin of a massive excitatory projection to the dentate gyrus and hippocampus proper. Over time, the denervated neurons in the hippocampal formation are almost completely reinnervated as a result of local sprouting of systems that survive the lesion. Thus, this model system has been useful for studying cellular responses to both denervation and reinnervation. We summarize the information that this injury triggers physiological events that can strongly modulate gene expression in neurons and glia, including episodes of spreading depression that occur at the time of the injury, seizures that occur during the early postlesion period, the loss of afferent drive which leads to decreases in postsynaptic activity, and the restoration of activity that occurs in conjunction with reinnervation. We describe recent studies which suggest that some of these physiological events occur to a variable extent in different animals, especially the episodes of spreading depression and the recurrent seizures. Thus, the spatial pattern and temporal dynamics of altered gene expression following this "model" experimental injury may vary from animal to animal. The fact that physiological events strongly modulate the reactive changes in gene expression that occur following injury has important implications for understanding the sequelae of injury, and offers new opportunities for experimental and therapeutic interventions that may improve cellular repair, regeneration, and recovery of function.

Genetic determinants of susceptibility to excitotoxic cell death: implications for gene targeting approaches

Recent studies have sought to identify the genes involved in excitotoxic neurodegeneration. Here we report that certain strains of mice, including strains that are used for gene targeting studies, do not exhibit excitotoxic cell death after kainic acid seizures. Kainic acid produced excitotoxic cell death in the CA3 and CA1 subfields of the hippocampus in 129/SvEMS and FVB/N mice, in the same pattern as described in rats. C57BL/6 and BALB/c mice exhibited excitotoxic cell death only at very high doses of kainate, and then only in a very restricted area, although they exhibited comparable seizures. Hybrids of 129/SvEMS x C57BL/6 mice created using embryonic stem cells from 129/SvEMS mice also did not exhibit excitotoxic cell death. These results demonstrate that C57BL/6 and BALB/c strains carry gene(s) that convey protection from glutamate-induced excitotoxicity. This differential susceptibility to excitotoxicity represents a potential complication for gene targeting studies.

Genetic influences on cellular reactions to brain injury: activation of microglia in denervated neuropil in mice carrying a mutation (Wld(S)) that causes delayed Wallerian degeneration

This study examines the relationship between the appearance of degenerative changes in synaptic terminals and axons and the activation of microglia in denervated neuropil regions of normal mice of the C57BL/6 strain and mutant mice (Wld(S)), in which Wallerian degeneration is substantially delayed. The time course of degenerative changes in synaptic terminals and axons was assessed using selective silver staining. Microglial cells were identified by immunostaining for Mac-1, a monoclonal antibody to the CR3 complement receptor, and by histochemical staining for nucleoside diphosphatase (NDPase). Increased argyrophilia, indicative of degenerative changes, was evident as early as 1 day postlesion in normal mice, but was not seen until 6-8 days in mice with the Wld(S) mutation. Microglial activation in normal C57BL/6 mice was evident by 24 hours postlesion, as evidenced by increased immunostaining for Mac-1, increased histochemical staining for NDPase, and morphological changes indicative of an activated phenotype (short, thick processes). Quantitative evaluation of immunostaining for Mac-1 revealed that peak activation occurred between 2 and 6 days postlesion with a return to a quiescent phenotype by 12 days. In contrast, the microglial response was significantly delayed and prolonged in mice bearing the Wld(S) mutation. Activated microglia were not seen within the deafferented area until 6 to 8 days postlesion and peak activation occurred between 12 and 20 days postlesion. These data suggest that the response of microglia in denervated neuropil zones is triggered by the same types of degenerative changes that cause increased argyrophilia as detected by selective silver staining methods.

Genetic influences on cellular reactions to CNS injury: the reactive response of astrocytes in denervated neuropil regions in mice carrying a mutation (Wld(S)) that causes delayed Wallerian degeneration

This study compares the reactive changes in astrocytes in denervated neuropil regions in normal mice and in mice carrying the Wld(S) mutation which leads to delayed Wallerian degeneration. In situ hybridization and immunocytochemical techniques were used to define the time course of changes in the levels of glial fibrillary acidic protein (GFAP) and GFAP mRNA in the denervated neuropil of the hippocampus after unilateral aspiration lesions of the entorhinal cortex. In control mice, GFAP mRNA levels increased rapidly in the denervated neuropil to a peak that was about tenfold higher than control at 2-4 days, decreased between 6 and 8 days postlesion, and then increased again to a second peak at 10 days postlesion. Increases in immunostaining for GFAP were evident by 2 days, remained elevated until 12 days postlesion and then decreased slowly. In mice carrying the Wld(S) mutation, the upregulation of GFAP mRNA levels in the denervated laminae was substantially delayed. Strikingly absent was the dramatic increase in labeling at 2-4 days postlesion which was such a prominent feature of the response in control animals. Peak labeling in the denervated laminae was not seen until 10-12 days postlesion. The development of a well-defined band of intensely immunostained and hypertrophied astrocytes in the denervated zone was also delayed in the Wld(S) animals, although there were modest increases in immunostaining as early as 2 days postlesion that were seen throughout the hippocampus ipsilateral to the lesion. These results suggest that degenerative changes in axons and synaptic terminals are the principal trigger for upregulating GFAP expression in the denervated neuropil, although other signals also play a role in the early postlesion response.

High frequency transcranial magnetic stimulation mimics the effects of ECS in upregulating astroglial gene expression in the murine CNS

The present study evaluates the consequences of high frequency (25 hz) trans-cranial magnetic stimulation on the expression of glial fibrillary acidic protein (GFAP) in the murine CNS. Trains of transcranial magnetic stimulation (1-30 trains at 25 Hz, 10 s duration) were delivered to mice via 5-cm diameter round coils. The stimulation produced stimulus-locked motor responses but did not elicit behavioral seizures. GFAP mRNA levels were evaluated 12, 24, 36, 48 h, 4 days, and 8 days following stimulation by in situ hybridization. Following multiple 25 Hz trains, there were dramatic increases in the levels of GFAP mRNA in the hippocampal dentate gyrus; more modest increases were observed in the cerebral cortex. The selective increases in GFAP mRNA in the dentate gyrus were similar to those observed following single electroconvulsive seizures (ECS). These results indicate that trans-cranial magnetic stimulation can be used to modulate astroglial gene expression, inducing the first stage of a reactive response that is similar to what occurs following nervous system injury.

Ultrastructural basis for gene expression at the synapse: synapse-associated polyribosome complexes

This review summarizes what is known about the protein synthetic machinery that is selectively localized beneath postsynaptic sites on the dendrites of CNS neurons. This machinery, made up of polyribosomes and associated membranous cisterns, allows a local synthesis of key proteins at individual postsynaptic sites.

Protein synthesis within dendrites: glycosylation of newly synthesized proteins in dendrites of hippocampal neurons in culture

There is increasing evidence that certain mRNAs are present in dendrites and can be translated there. The present study uses two strategies to evaluate whether dendrites also possess the machinery for protein glycosylation. First, precursor labeling techniques were used to conjunction with autoradiography to visualize glycosyltransferase activities that are characteristic of the rough endoplasmic reticulum (RER) (mannose) or the Golgi apparatus (GA) (galactose and fucose) in dendrites that had been separated from their cell bodies and in intact neurons treated with brefeldin A or low temperature. Second, immunocytochemical techniques were used to define the subcellular distribution of proteins that are considered markers of the RER (ribophorin I) and GA (p58, alpha-mannosidase II, galactosyltransferase, and TGN38/41). Autoradiographic analysis revealed that isolated dendrites incorporated sugar precursors in a tunicamycin-sensitive and protein synthesis-dependent manner. Moreover, when intact neurons were pulse-labeled with 3H-labeled sugars at low temperature or after treatment with brefeldin A, labeling was distributed over proximal and sometimes distal dendrites. Immunolabeling for RER markers was predominantly localized in cell bodies but extended for a considerable distance into dendrites of all neurons. Immunolabeling for GA markers was confined to the cell body in approximately 70% of the neurons, but in 30% of the neurons, the staining extended into proximal and middle dendrites. These results indicate that the machinery for glycosylation extends well into dendrites in many neurons.

Genetic influences on cellular reactions to spinal cord injury: a wound-healing response present in normal mice is impaired in mice carrying a mutation (WldS) that causes delayed Wallerian degeneration

Progressive tissue necrosis is a process unique to the injured mammalian spinal cord which often leads to gradually increasing cavitation and enlargement of the lesion. To evaluate the role of neuronal degeneration in initiating this response, histopathological changes were compared in C57BL and WldS (delayed Wallerian degeneration mutation) mice. The spinal cord was crushed at T8, producing a primary lesion at the site of the trauma and a secondary lesion extending rostrocaudally in the dorsal columns (where long ascending and descending fiber tracts undergo Wallerian degeneration). Cavitation was relatively mild at both sites and developed mainly at the margins of the lesions. In striking contrast to spinal cord injury in rats, progressive necrosis did not occur in mice; instead, the primary and secondary lesion sites became filled in by macrophages and fibroblasts embedded in a well-vascularized collagenous stroma. Quantitative image analysis revealed that the primary lesion decreased dramatically in size and cavitation between 2 and 3 weeks in C57BL, whereas in WldS the reduction in size and cavitation began later (at 4 weeks) and was less complete. The initial development of the secondary lesion began later and its healing was less complete in WldS than C57BL. These results are consistent with the hypothesis that neuronal damage, including Wallerian degeneration, triggers inflammatory responses leading to tissue repair. For this reason, any delay in neuronal degeneration, as in the WldS mutation, results in deficient tissue repair as reflected in the larger size of both primary and dorsal column lesions.

Genetic influences on cellular reactions to spinal cord injury: activation of macrophages/microglia and astrocytes is delayed in mice carrying a mutation (WldS) that causes delayed Wallerian degeneration

Reactive changes in macrophages/microglia and astrocytes were evaluated following spinal cord injury in normal mice of the C57BL/6J strain and in mice carrying a mutation (WldS) which delays the onset of Wallerian degeneration in damaged axons. Crush injuries were produced at the T8 level by using an extradural approach; animals were allowed to survive for 2 days to 12 weeks, and spinal cords were prepared for immunocytochemistry using antibodies against Mac1 and glial fibrillary acidid protein (GFAP). In normal mice, Mac1-positive macrophages accumulated at the injury site by 4 days and immunostaining of these cells peaked at 6-8 days. Cells in the gray matter near the crush site and in the ascending dorsal column also exhibited increased Mac1 staining that was prominent at 1 week and remained high at 2-4 weeks. In mice carrying the WldS mutation, the accumulation of macrophages at the injury site and the increase in immunostaining of these cells were delayed, as were the increases in immunostaining in the gray matter and dorsal columns. Both normal and mutant mice exhibited pronounced increases in glial fibrillary acidic protein immunostaining at the edge of the crush site and for some distance both rostral and caudal to the injury; increased immunostaining was also prominent along the ascending dorsal columns. The center of the crush site, which contained connective tissue, remained completely unstained for GFAP. In normal mice, immunostaining for GFAP reached a peak at 1 week postinjury and then declined. In mice carrying the WldS mutation, increases in GFAP immunostaining did not reach a peak until 2-3 weeks postinjury. These results indicate that activation of macrophages, microglia, and astrocytes is delayed and prolonged in mice carrying the WldS mutation.

Protein synthesis within dendrites: ionic and neurotransmitter modulation of synthesis of particular polypeptides characterized by gel electrophoresis

This study evaluates whether physiological variables differentially affect the local synthesis of protein constituents of synapses in subcellular fractions containing pinched-off dendrites (synaptodendrosomes). Synaptodendrosomes were pulse-labeled in a medium containing 35S-methionine with 3 or 25 mM KCl and in the presence or absence of 0.5 mM EGTA or 10 microM glutamate. Synaptodendrosomes were then subfractionated to prepare synaptic plasma membranes and synaptic junctional complexes. The protein constituents of the synaptic plasma membrane and synaptic junctional complex fractions that were locally synthesized were identified using SDS-PAGE and two-dimensional gel electrophoresis and the extent of labeling of individual bands was analyzed using a Phosphorimager. Analysis of incorporation into individual bands resolved by SDS-PAGE revealed that depolarizing conditions (25 mM KCl) increased the extent of labeling of different bands to a different extent (ranging from 10-70% increases in labeling). Addition of 0.5 mM EGTA decreased the extent of labeling of the same group of bands in both 3 mM KCl and 25 mM KCl conditions. Addition of 10 microM glutamate reduced incorporation especially in the synaptodendrosomes incubated in 25 mM KCl. Two-dimensional gel electrophoresis analyses revealed that the labeled spots that showed differential labeling under the different conditions did not correspond to the most prominent Coomassie-stained spots. These results indicate that the proteins that are synthesized in synaptodendrosomes and regulated by physiological variables are not amongst the more abundant protein constituents of the fractions. Taken together, these results are consistent with the idea that protein synthesis within dendrites may be regulated by synaptic activity.

The role of postlesion seizures and spreading depression in the upregulation of glial fibrillary acidic protein mRNA after entorhinal cortex lesions

Unilateral lesions of the entorhinal cortex have been shown to lead to dramatic increases in GFAP mRNA levels in denervated zones in the hippocampus and dentate gyrus and sometimes (but not always) in nondenervated zones in the contralateral hippocampus and dentate gyrus. The variable distribution of the increases in GFAP mRNA expression suggests that the events which trigger changes in GFAP mRNA levels occur to a variable extent in individual animals. The companion paper characterizes two candidate triggering events: spreading depression (SD) that occurs to a variable extent at the time of the lesion and recurrent seizures that occur during the early postlesion interval. The goal of the present study was to evaluate whether individual differences in the extent or spatial distribution of lesion-induced increases in GFAP mRNA are related to the occurrence of either SD or seizures. We quantified the increases in GFAP mRNA levels in individual animals that had been monitored physiologically to define the incidence of SD and postlesion seizures. The results revealed that the quantitative extent of the increases in GFAP mRNA in denervated zones and was not related to either SD or postlesion seizures. The increases in GFAP mRNA in nondenervated zones also were not related to episodes of spreading depression that occurred at the time of lesion production but were related to the spontaneous seizures that developed during the first 24 h postlesion after the animals had recovered from the surgical anesthesia. Taken together, these data indicate that physiological events that occur during the early postlesion interval can play an important role in determining the pattern and extent of altered cellular gene expression in response to an injury.

The process of reinnervation in the dentate gyrus of adult rats: physiological events at the time of the lesion and during the early postlesion period

Destruction of the entorhinal cortex (EC) triggers a number of cellular and molecular responses in the denervated hippocampus and dentate gyrus. The signals that trigger these changes are not known but could include physiological events that occur during the production of the injury or during the early postlesion period. Of particular interest is whether experimental lesions induce seizures and/or spreading depression (SD), both of which have been shown to dramatically alter neuronal and glial gene expression. In the present study, acute neurophysiological techniques were used to evaluate whether seizures or SD occur during the production of EC lesions. Chronic recording techniques were used to monitor electroencephalographic (EEG) activity during the first 24 h after the injury in order to evaluate the extent of postlesion seizures. One or more episodes of SD occurred in 9 of 13 animals during the production of electrolytic EC lesions. However, hippocampal seizures were not observed except for very brief episodes of seizure activity at the onset of an episode of SD. Chronic recordings of postlesion EEG activity revealed that spontaneous electrographic seizures occurred during the first 24 h postlesion in all animals. The spontaneous electrographic seizures were approximately 30 s in duration and were not accompanied by motor convulsions. The first seizures occurred within several hours after the lesion, and seizures continued to occur periodically (at an average frequency of 0.42 per hour) over the 24-h recording period. Seizures occurred on the side of the brain ipsilateral to the lesion in all animals and occurred on the side contralateral to the lesion in 3 of 5 animals. These results indicate that EC lesions produce physiological events that occur variably in different animals; these processes may account for some of the variability in the cellular responses to this "standardized" injury.

Homosynaptic and heterosynaptic changes in driving of dentate gyrus interneurons after brief tetanic stimulation in vivo

This study addressed changes in interneuron driving in the dentate gyrus (DG) of urethane-anaesthetized rats in response to tetanic stimulation of the perforant path (PP) or the converging dentate commissural pathway (CP). Using an extracellular tungsten electrode, we recorded from putative interneurons in the DG that fired to stimulation of both the PP and the CP. Conditioning trains (400 Hz, 17.5 ms) were delivered to each pathway individually and to the two pathways together. The primary measure of synaptic drive was the latency of interneuron discharge. High-intensity PP tetany, CP tetany, and paired tetany consistently reduced firing latency to CP driving (P < .05 for all three), indicating an LTP-like increase in synaptic activation through the CP. High-intensity PP tetany decreased latency to PP driving in only two of seven cases. Heterosynaptic changes occurred frequently in individual experiments. Activity-mediated adjustments in synaptic driving of inhibitory interneurons could play a role in normal physiological function.

The process of reinnervation in the dentate gyrus of adult rats: gene expression by neurons during the period of lesion-induced growth

Neurons in the hippocampal dentate gyrus are extensively reinnervated following the destruction of their normal inputs from the ipsilateral entorhinal cortex (EC). The present study evaluates gene expression by dentate granule neurons and the neurons giving rise to the sprouting connections during the period of synapse growth. Adult male rats were prepared for in situ hybridization at 2, 4, 6, 8, 10, 12, 14, 20, and 30 days following unilateral EC lesions. Sections were hybridized using 35S-labeled cRNA probes for mRNAs that encode proteins thought to be important for neuronal structure and/or synapse function, including (1) mRNAs that are normally present in dendrites--the mRNAs for the high molecular weight microtubule-associated protein 2 (MAP2) and the alpha-subunit of calcium/calmodulin-dependent protein kinase II (CAMII kinase), (2) mRNAs that are upregulated in neurons that are regenerating their axons (T alpha 1 tubulin and F1/GAP43) and (3) mRNAs for proteins that are the principal constituents of neurofilaments and microtubules (the low molecular weight neurofilament protein NF68 and beta-tubulin). Although there were small changes in the levels of labeling for the mRNAs that are normally present in dendrites, there were no dramatic increases in the levels of any of the mRNAs either in dentate granule cells or in neurons giving rise to the reinnervating fibers at any postlesion interval. These results indicate that neurons in mature animals can substantially remodel their synaptic terminals and their dendrites in the absence of large-scale changes in gene expression (at least as measured by steady-state mRNA levels at various time points).

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.

mRNA distribution within dendrites: relationship to afferent innervation

The majority of neuronal mRNAs are confined to cell bodies, but a few mRNAs are present at high levels in dendrites. Here we report an initial analysis of the relationship between afferent innervation and the distribution of mRNA within dendritic fields. In situ hybridization techniques were used to compare the subcellular distribution of dendritic mRNAs in principal neurons of the hippocampal formation in vivo. The mRNA encoding the alpha subunit of calcium/calmodulin dependent protein kinase II (CAMII kinase) was present at high levels throughout the layers that contain the dendrites of hippocampal pyramidal cells and dentate granule cells. In contrast, the mRNA encoding the high molecular weight microtubule-associated protein MAP2 had a more limited distribution. In the dentate gyrus, labeling for MAP2 was present in a discrete band in the lamina containing proximal dendrites and decreased to low levels in laminae containing distal dendrites. This laminar pattern resembles the distinct terminations of the commissural/associational projection (high MAP2 labeling) and the entorhinal projection (lower MAP2 labeling) upon dendrites of granule cells. To determine if the differential distribution of dendritic mRNAs was regulated by either the presence or activity of afferents, we evaluated mRNA distribution in the dentate molecular layer following (1) removal of the entorhinal input by lesions of the entorhinal cortex or (2) prolonged delivery of potentiating stimulation to entorhinal afferents. Denervation led to modest decreases in the levels of mRNAs for both CAMII and MAP2 but did not lead to detectable alterations in mRNA distribution. Also, prolonged stimulation did not lead to detectable alterations in MAP2 or CAMII mRNA distribution although such stimulation clearly elevated the expression of mRNA for glial fibrillary acidic protein (GFAP).

Targeting of mRNAs to subsynaptic microdomains in dendrites

Recent studies have revealed that a heterogeneous population of mRNAs is present in neuronal dendrites (including mRNAs that encode proteins involved in intracellular signaling), that different types of neurons have different assortments of dendritic mRNAs, and that the levels of some dendritic mRNAs are up-regulated by activity. These findings reinforce and extend the hypothesis that the localization of mRNA in dendrites provides a means of synthesizing proteins locally that are important for synaptic function.

Cholinergic sprouting is blocked by repeated induction of electroconvulsive seizures, a manipulation that induces a persistent reactive state in astrocytes

Previous studies have demonstrated that some of the molecular and morphological changes that are characteristic of reactive astrocytes are induced following seizures. This discovery provides the means to experimentally modify the time course and extent of reactive changes in astrocytes following injury and so explore how these reactive changes modulate other events in the injured nervous system. The present study evaluates whether superinduction of a reactive state in astrocytes alters one form of postlesion synaptic reorganization (the sprouting of cholinergic projections in the dentate gyrus after destruction of the entorhinal cortex). Cholinergic sprouting after entorhinal cortex lesions was evaluated in control mice and in mice that experienced electroconvulsive seizures (ECS) from the day of surgery until 12 days postlesion. Animals were prepared for acetylcholinesterase (AChE) histochemistry at 2, 4, 6, 8, 10, 12, 14, and 30+ days postlesion. Quantitative densitometric analyses revealed that the increase in AChE staining that is indicative of cholinergic sprouting was essentially eliminated in the animals that experienced daily ECS. These results indicate that the induction of electroconvulsive seizures during the postinjury period disrupts at least one form of postlesion synaptic reorganization that would otherwise occur. This disruption of synaptic reorganization may be a consequence of the induction of a persistent reactive state in astrocytes.

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.