Distant microglial and astroglial activation secondary to experimental spinal cord lesion

This paper analysed whether glial responses following a spinal cord lesion is restricted to a scar formation close to the wound or they might be also related to widespread paracrine trophic events in the entire cord. Spinal cord hemitransection was performed in adult rats at the thoracic level. Seven days and three months later the spinal cords were removed and submitted to immunohistochemistry of glial fibrillary acidic protein (GFAP) and OX42, markers for astrocytes and microglia, as well as of basic fibroblast growth factor (bFGF), an astroglial neurotrophic factor. Computer assisted image analysis was employed in the quantification of the immunoreactivity changes. At the lesion site an increased number of GFAP positive astrocytes and OX42 positive phagocytic cells characterized a dense scar formation by seven days, which was further augmented after three months. Morphometric analysis of the area and microdensitometric analysis of the intensity of the GFAP and OX42 immunoreactivities showed reactive astrocytes and microglia in the entire spinal cord white and gray matters 7 days and 3 months after surgery. Double immunofluorescence demonstrated increased bFGF immunostaining in reactive astrocytes. The results indicated that glial reaction close to an injury site of the spinal cord is related to wounding and repair events. Although gliosis constitutes a barrier to axonal regeneration, glial activation far from the lesion may contribute to neuronal trophism and plasticity in the lesioned spinal cord favoring neuronal maintenance and fiber outgrowth.     

Growth-associated protein-43 and ephrin B3 induction in the brain of adult SIV-infected rhesus macaques

Understanding the mechanisms of neuronal regeneration and repair in the adult central nervous system is a vital area of research. Using a rhesus lentiviral encephalitis model, we sought to determine whether recovery of neuronal metabolism after injury coincides with the induction of two important markers of synaptodendritic repair: growth-associated protein-43 (GAP-43) and ephrin B3. We examined whether the improvement of neuronal metabolism with combined anti-retroviral therapy (cART) after simian immunodeficiency virus (SIV) infection in rhesus macaques involved induction of GAP-43, also known as neuromodulin, and ephrin B3, both implicated in axonal pathfinding during neurodevelopment and regulation of synapse formation, neuronal plasticity, and repair in adult brain. We utilized magnetic resonance spectroscopy to demonstrate improved neuronal metabolism in vivo in adult SIV-infected cART animals compared to untreated and uninfected controls. We then assessed levels of GAP-43, ephrin B3, and synaptophysin, a pre-synaptic marker, in three brain regions important for cognitive function, cortex, hippocampus, and putamen, by quantitative real-time RT-PCR and immunohistochemistry. Here we demonstrate that (1) GAP-43 mRNA and protein are induced with SIV infection, (2) GAP-43 protein is higher in the hippocampus outer molecular layer in SIV-infected animals that received cART compared to those that did not, and (3) activated microglia and infiltrating SIV-infected macrophages express abundant ephrin B3, an important axonal guidance molecule. We propose a model whereby SIV infection triggers events that lead to induction of GAP-43 and ephrin B3, and that short-term cART results in increased magnitude of repair mechanisms especially in the hippocampus, a region known for high levels of adult plasticity.     

Relationship of calpain-mediated proteolysis to the expression of axonal and synaptic plasticity markers following traumatic brain injury in mice

The role of neuronal plasticity and repair on the final functional outcome following traumatic brain injury (TBI) remains poorly understood. Moreover, the relationship of the magnitude of post-traumatic secondary injury and neurodegeneration to the potential for neuronal repair has not been explored. To address these questions, we employed Western immunoblotting techniques to examine how injury severity affects the spatial and temporal expression of markers of axonal growth (growth-associated protein GAP-43) and synaptogenesis (pre-synaptic vesicular protein synaptophysin) following either moderate (0.5 mm, 3.5 M/s) or severe (1.0 mm, 3.5 M/s) lateral controlled cortical impact traumatic brain injury (CCI-TBI) in young adult male CF-1 mice. Moderate CCI increased GAP-43 levels at 24 and 48 h post-insult in the ipsilateral hippocampus relative to sham, non-injured animals. This increase in axonal plasticity occurred prior to maximal hippocampal neurodegeneration, as revealed by de Olmos silver staining, at 72 h. However, moderate CCI-TBI did not elevate GAP-43 expression in the ipsilateral cortex where neurodegeneration was extensive by 6 h post-TBI. In contrast to moderate injury, severe CCI-TBI failed to increase hippocampal GAP-43 levels and instead resulted in depressed GAP-43 expression in the ipsilateral hippocampus and cortex at 48 h post-insult. In regards to injury-induced changes in synaptogenesis, we found that moderate CCI-TBI elevated synaptophysin levels in the ipsilateral hippocampus at 24, 48, 72 h and 21 days, but this effect was not present after severe injury. Together, these data highlights the adult brain's ability for axonal and synaptic plasticity following a focal cortical injury, but that severe injuries may diminish these endogenous repair mechanisms. The differential effects of moderate versus severe TBI on the post-traumatic plasticity response may be related to the calpain-mediated proteolytic activity occurring after a severe injury preventing increased expression of proteins required for plasticity. Supporting this hypothesis is the fact that GAP-43 is a substrate for calpain along with our data demonstrating that calpain-mediated degradation of the cytoskeletal protein, alpha-spectrin, is approximately 10 times greater in ipsilateral hippocampal tissue following severe compared to moderate CCI-TBI. Thus, TBI severity has a differential effect on the injury-induced neurorestorative response with calpain activation being one putative factor contributing to neuroregenerative failure following severe CCI-TBI. If true, then calpain inhibition may lead to both neuroprotective effects and an enhancement of neuronal plasticity/repair mechanisms post-TBI.     

Failure to express GAP-43 leads to disruption of a multipotent precursor and inhibits astrocyte differentiation

The nervous system-specific protein GAP-43 is significantly upregulated in neurons and glia that are differentiating. In P19 EC cells that do not express GAP-43, neurogenesis is inhibited; many immature neurons apoptose and the survivors do not mature morphologically. Here we show that the initial defect is in an early precursor with characteristics of a neural stem cell, which failed to respond normally to retinoic acid (RA). As a consequence, its progeny had altered cell fates: In addition to the neuronal defects previously reported, RC1-labeled radial glia failed to exit the cell cycle, accumulated, and failed to acquire GFAP immunoreactivity. However, leukemia inhibitory factor (LIF) could stimulate GFAP expression suggesting that astrocytes not derived from radial glia are less affected by absence of GAP-43. Differentiation of radial glia-derived astrocytes was also inhibited in glial cultures from GAP-43 (-/-) cerebellum, and in GAP-43 (-/-) telencephalon in vivo, differentiation of astrocytes derived from both radial and nonradial glia lineages were both affected: In the glial wedge, GFAP-labeled radial glia-derived astrocytes were reduced consistent with the interpretation that they may be unable to deflect GAP-43 (-/-) commissural axons toward the midline. At the midline, both radial and nonradial glia-derived astrocytes were also decreased although it fused normally. The results demonstrate that GAP-43 expressed in multipotent precursors is required for appropriate cell fate commitment, and that its absence affects astrocyte as well as neuronal differentiation.     

GAP-43 gene expression during development: persistence in a distinctive set of neurons in the mature central nervous system

GAP-43 is a rapidly transported axonal protein most prominently expressed in regenerating and developing nerves. However, the low level persistence of GAP-43 in the adult CNS where growth and regenerative capacity are minimal may additionally indicate a role for this molecule in neuronal remodeling. Previous studies have revealed GAP-43 immunoreactivity in neurites throughout many regions of the CNS. To identify the CNS neurons that express GAP-43 at different stages of development, we utilized in situ hybridization and immunocytochemistry; the latter was performed with an antibody that recognizes GAP-43 immunoreactivity in both perikarya and neurites. In the perinatal period GAP-43 is expressed in all neurons. Subsequently its expression becomes progressively restricted such that by maturity most neurons no longer express detectable levels, although GAP-43 expression is still moderately high in the adult entorhinal cortex, and strikingly high in the adult hippocampus and olfactory bulb. In light of current notions about the function of GAP-43, it is tempting to speculate that this anatomy denotes neurons engaged in structural remodeling and functional plasticity.     

Reactive astrocytes in neonate brain upregulate intermediate filament gene expression in response to axonal injury

We have examined the injury response of astrocytes in the immature hamster brain in this study, focusing on alterations in the expression of glial fibrillary acidic protein (GFAP) and vimentin. In the adult CNS these two type III intermediate filament (IF) proteins have been shown to undergo robust increases in expression in response to axonal injury. Since injury to the immature CNS reportedly elicits less glial scar formation than adult brain injury, we examined the possibility that immature astrocytes respond differently than adult astrocytes to CNS injury with respect to IF gene expression. In situ hybridization using a ³⁵S-labeled cDNA GFAP probe was done on brainstem sections obtained 2,7 and 14 days after unilateral transection of the corticospinal tract in P8 hamster pups. The results indicated that substantial increases in GFAP mRNA were associated with the degenerating portion of the corticospinal tract by 2 days after axotomy and that the levels remained elevated for at least 14 days. Double-label immunofluorescence studies of this material suggested that GFAP as well as vimentin protein levels were also increased in many astrocytes in and around the degenerating corticospinal tract 2–14 days after axotomy. Most of the reactive astocytes in the degenerating regions exhibited increases in GFAP and vimentin immunostaining but some vimentin-negative GFAP-positive reactive astrocytes were also observed, particularly in regions surrounding the actual degenerative zones. The results from these experiments revealed that immature astrocytes have the potential for altering their normal developmental program of GFAP and vimentin expression after injury and mount a response that is qualitatively similar to that of astrocytes after CNS injury in the adult animal.     

Growth-associated protein (GAP-43)-like immunoreactivity in primary and permanent tooth pulp nerve fibers of the cat.

GAP-43-like immunoreactivity in developing and mature incisor and canine tooth pulp nerve fibers in the cat was examined with fluorescence immunohistochemistry and pre-embedding immunogold electron microscopy. As expected, pulpal and periodontal nerve fibers in primary teeth aged 2-3 weeks showed strong immunoreactivity. Double-labeling experiments demonstrated that 50-70% of primary pulpal GAP-43-positive nerve fibers showed CGRP-like immunoreactivity. However, in adult permanent teeth the vast majority of pulpal nerve fibers also displayed intense GAP-43-like immunoreactivity both when surrounding pulpal blood vessels and in the subodontoblast/odontoblast region. There was a high degree (90-95%) of simultaneous expression of GAP-43-like immunoreactivity and CGRP-like immunoreactivity in adult permanent pulps. Immunogold GAP-43 labeling was mainly associated with the cytoplasmic side of axonal membranes. However, occasional examples of immunolabeled Schwann cells were also found. High levels of GAP-43 in normal mature permanent pulpal nerves may facilitate neural plasticity after dental wear or injury.     

Immunohistochemical localization of GAP-43 in rat and human sympathetic nervous system — effects of aging and diabetes

The neuronal 43 kDa growth associated peptide (GAP-43) is expressed in conditions of embryonic growth, axonal regeneration, and, to a limited degree, within the central nervous system as an indicator of synaptic plasticity. Although much is known about the expression of GAP-43 in cultured sympathetic neurons, information concerning the existence, immunolocalization and response of GAP-43 to experimental injury is not available for intact sympathetic ganglia in vivo. In this study we have characterized the in situ distribution and identity of GAP-43 in adult rat and human prevertebral and paravertebral sympathetic ganglia using immunohistochemical and biochemical methods. Antisera to GAP-43 intensely labeled intraganglionic presynaptic axons and synapses terminating on neurons of normal adult rat and human sympathetic ganglia in situ. There was minimal GAP-43 immunoreactivity of principal sympathetic neuron perikarya, proximal dendrites and initial axonal segments. The immunohistologic appearance of GAP-43 was unchanged in the ganglia of aged and diabetic rats and elderly humans, conditions in which presynaptic terminal axons and synapses show evidence of chronic degeneration, regeneration and neuroaxonal dystrophy, an unusual ultrastructural alteration which may represent disordered synaptic plasticity. Radioimmunoassay of ganglionic GAP-43 is comparable in young adult, aged and diabetic rat prevertebral or paravertebral sympathetic ganglia. Double immunolocalization of NPY (which labeled markedly swollen dystrophic axons) and GAP-43 in human sympathetic ganglia using a sequential immunogold-silver/fluorescence technique demonstrated that typical dystrophic axons contain little GAP-43.     

Immunohistochemical localization of GAP-43 in rat and human sympathetic nervous system--effects of aging and diabetes.

The neuronal 43 kDa growth associated peptide (GAP-43) is expressed in conditions of embryonic growth, axonal regeneration, and, to a limited degree, within the central nervous system as an indicator of synaptic plasticity. Although much is known about the expression of GAP-43 in cultured sympathetic neurons, information concerning the existence, immunolocalization and response of GAP-43 to experimental injury is not available for intact sympathetic ganglia in vivo. In this study we have characterized the in situ distribution and identity of GAP-43 in adult rat and human prevertebral and paravertebral sympathetic ganglia using immunohistochemical and biochemical methods. Antisera to GAP-43 intensely labeled intraganglionic presynaptic axons and synapses terminating on neurons of normal adult rat and human sympathetic ganglia in situ. There was minimal GAP-43 immunoreactivity of principal sympathetic neuron perikarya, proximal dendrites and initial axonal segments. The immunohistologic appearance of GAP-43 was unchanged in the ganglia of aged and diabetic rats and elderly humans, conditions in which presynaptic terminal axons and synapses show evidence of chronic degeneration, regeneration and neuroaxonal dystrophy, an unusual ultrastructural alteration which may represent disordered synaptic plasticity. Radioimmunoassay of ganglionic GAP-43 is comparable in young adult, aged and diabetic rat prevertebral or paravertebral sympathetic ganglia. Double immunolocalization of NPY (which labeled markedly swollen dystrophic axons) and GAP-43 in human sympathetic ganglia using a sequential immunogold-silver/fluorescence technique demonstrated that typical dystrophic axons contain little GAP-43.     

Brain tissue damage and regeneration monitored by β-amyloid precursor protein in experimental laser-induced interstitial thermotherapy

To study whether neuronal regeneration occurs after laserinduced interstitial thermotherapy (LITT) of the brain, we examined lesions and their margins in adult Lewis rats with histological and immunohistochemical methods. We used the Bodian stain and antibodies against β-amyloid precursor protein (APP), which has been associated with trophic effects in neural regeneration and against heat-shock protein 72 (HSP 72) and neurofilament 68 (NF 68). The glial reaction was monitored with antibodies against glial fibrillary acidic protein (GFAP) and apolipoprotein E (Apo E). β-Amyloid precursor protein showed a distinct temporal profile in areas of lesion margins thought to be associated with neurite sprouting and regeneration. Axonal accumulation of APP started 1 h after LITT and reached a maximum after 3 days. Heat-shock protein 72 was weakly positive in isolated marginal neurons in the early postoperative period. Subsequent to GFAP expression, Apo E immunoreactivity was detected in reactive astrocytes but not in profiles thought to be axonal sprouts. The results showed that margins of LITT-induced lesions contain profiles which resemble sprouting neurites and are similar to those found after injury or ischemia but with differences in the time course of reactive proteins.     

Response of rat cerebral cortical astrocytes to freeze- or cobalt-induced injury: an immunocytochemical and gap-FRAP study

Astrocytic response in the immediate vicinity of freeze- and cobalt-induced lesions has been examined at the light and ultrastructural level. However, the temporal and spatial distribution of astrocytic reactivity throughout the rat cerebral cortex, using glial fibrillary acidic protein (GFAP) immunolabeling, has not been examined. The first purpose of this study was to establish the chronological distribution of astrocytic reactivity, as measured by changes in GFAP immunoreactivity, following freeze- or cobalt-induced injury to the rat cerebral cortex. Cobalt metal also has been proposed to have a direct effect on astrocytes and has been shown to stimulate in vitro astrocytes to become reactive. The second purpose of this report was to determine if cobalt had an effect on in vitro astrocytic gap junctional dye coupling as measured by fluorescence recovery after laser-photobleaching (gap-FRAP). Although the chronological development of the increased GFAP immunoreactivity was different for the freeze- and cobalt-induced lesions, astrocytes initially showed an increase in GFAP immunoreactivity in the region surrounding these lesions. This initial response was followed by a spread of increased GFAP immunoreactivity throughout certain regions of the ipsilateral cerebral hemisphere and then by a restriction of the increased immunolabeling to the lesion site. Cobalt also had a direct effect on in vitro astrocytes as demonstrated by the inhibition of astrocytic gap junctional dye coupling. Based on gap-FRAP analysis, cobalt significantly blocked fluorescence recovery (2.5%) as compared to the fluorescence recovery in control astrocytes (26%). It is proposed that the initial increase in GFAP immunoreactivity may be due to decreased gap junctional activity.     

Impaired neuronal plasticity in transgenic mice expressing human apolipoprotein E4 compared to E3 in a model of entorhinal cortex lesion

The apolipoprotein E (APOE) epsilon 4 allele is a major risk factor for late-onset familial and sporadic Alzheimer's disease (AD) and is associated with a poor outcome after brain injury. Each apoE isoform is suggested to have differential effects on neuronal repair mechanisms within the CNS. In the present study, APOE genotype influence on the immediate response to injury and subsequent repair process was examined in a line of transgenic APOE mice possessing human APOE gene insertions (epsilon 3 and epsilon 4). Quantification of synaptophysin and GAP-43 immunoreactivity was used to measure the extent of degeneration and regeneration after entorhinal cortex lesion (ECL). Progressive neurodegenerative decline occurred in the ipsilateral dentate gyrus until day 28 post-ECL which was more severe in APOE epsilon 3 mice compared to APOE epsilon 4 mice. By day 90 post-ECL compensatory sprouting and reactive synaptogenesis had taken place in the dentate gyrus of APOE epsilon 3 mice such that GAP-43 and synaptophysin immunoreactivity had returned to prelesion levels. In contrast, APOE epsilon 4 mice displayed significant deficits in synaptophysin and GAP-43 immunostaining compared to the APOE epsilon 3 mice (P < 0.05). Expansion of the inner molecular layer (IML) was used as a measure of the sprouting index from the commissural-associational pathway and by day 90 post-ECL the IML width in APOE epsilon 3 mice had increased by 45% but only 20% in APOE epsilon 4 mice (P < 0.0001). ApoE immunoreactivity was increased within the neuropil and glia to the same extent in APOE epsilon 3 and APOE epsilon 4 mice post-ECL. There was no significant difference in the deposition and clearance of degeneration products between APOE epsilon 3 and epsilon 4 mice post-ECL. These results indicate that neuronal plasticity is impaired in transgenic mice possessing human APOE epsilon 4 alleles compared to APOE epsilon 3. These isoform-specific differences in plasticity may relate to the severity of AD and poor, long-term recovery after head injury in APOE epsilon 4 individuals.     

Early profiles of axonal growth and astroglial response after spinal cord hemisection and implantation of Schwann cell-seeded guidance channels in adult rats

We previously demonstrated that transplantation of Schwann cell-seeded channels promoted the regrowth of injured axons in the adult spinal cord. It is not clear, however, whether injured axons recapitulate the developmental scenarios to accomplish regeneration. In the present study, we investigated the early events associated with axonal regrowth after spinal cord hemisection at the eighth thoracic level and implantation of a Schwann cell-seeded minichannel in adult rats. Animals were sacrificed at postoperative days (PO) 2, 4, 7, and 14. Anterograde tracing with fluoro-ruby showed that regenerating axons grew into the graft prior to PO2 and reached the distal end of the channel at PO7. These axons expressed both embryonic neural cell adhesion molecule (E-NCAM) and growth associated protein-43 (GAP-43). Although the expression of E-NCAM decreased by PO7, that of GAP-43 remained high throughout the first 2 weeks after implantation. A close relation of vimentin-positive astroglia to the growing axons in the host tissue suggested a contact-mediated role of these cells in axon guidance. Aggregation of glial fibrillary acidic protein (GFAP)-positive astrocytes together with the increased expression of chondroitin sulfate proteoglycans (CSPGs) starting at PO7 appeared to inhibit axonal growth at the host-graft interface. Thus, adult regenerating axons and astroglia do express developmentally related molecules that may facilitate axonal growth into a permissive graft at the early phase of injury and regeneration. These results suggest that molecules and astroglia essential to development are both important in influencing axonal regrowth in the adult spinal cord.     

Functional recovery after cerebellar damage is related to GAP-43-mediated reactive responses of pre-cerebellar and deep cerebellar nuclei

Since brain injuries in adulthood are a leading cause of long-term disabilities, the development of rehabilitative strategies able to impact on functional outcomes requires detailing adaptive neurobiological responses. Functional recovery following brain insult is mainly ascribed to brain neuroplastic properties although the close linkage between neuronal plasticity and functional recovery is not yet fully clarified. The present study analyzed the reactive responses of pre-cerebellar (inferior olive, lateral reticular nucleus and pontine nuclei) and deep cerebellar nuclei after a hemicerebellectomy, considering the great plastic potential of the cerebellar system in physiological and pathological conditions. The time course of the plastic reorganization following cerebellar lesion was investigated by monitoring the Growth Associated Protein-43 (GAP-43) immunoreactivity. The time course of recovery from cerebellar symptoms was also assessed to parallel behavioral and neurobiological parameters. A key role of GAP-43 in neuronal reactive responses was evidenced. Neurons that underwent an axotomy as consequence of the right hemicerebellectomy (neurons of left inferior olive, right lateral reticular nucleus and left pontine nuclei) exhibited enhanced GAP-43 immunoreactivity and cell death. As for the not-axotomized neurons, we found enhanced GAP-43 immunoreactivity only in right pontine nuclei projecting to the spared (left) hemicerebellum. GAP-43 levels augmented also in the three deep cerebellar nuclei of the spared hemicerebellum, indicating the ponto-cerebellar circuit as crucially involved in functional recovery. Interestingly, each nucleus showed a distinct time course in GAP-43 immunoreactivity. GAP-43 levels peaked during the first post-operative week in the fastigial and interposed nuclei and after one month in the dentate nucleus. These results suggest that the earlier plastic events of the fastigial and interposed nuclei were driving compensation of the elementary features of posture and locomotion, while the later plastic events of the dentate nucleus were mediating the recovered ability to flexibly adjust the locomotor plan.     

Changes in localization of synaptophysin following fluid percussion injury in the rat brain

Traumatic brain injuries damage neurons and cause progressing dysfunctions of the brain. Synaptophysin (SYP), a major integral transmembrane protein of synaptic vesicles, provides a molecular marker for the synapse and serves as a functional marker of the brain. This study examined magnitude-dependent changes of SYP in the rat brain 2 days following low, moderate or high fluid percussion injuries and investigated time-dependent changes of SYP in the rat brain with moderate fluid percussion injury 2, 15 and 30 days after trauma using immunohistochemistry and Western blotting. SYP immunoreactivity increased in the lateral cortex and in the subcortical white matter, with increasing magnitude of injury and time after trauma. Increased SYP immunoreactivity was accompanied with degeneration of neuronal cell bodies, their processes and terminals as well as glial cell proliferations. Amounts of SYP measured by Western blotting remained unchanged in brains with moderate fluid percussion within 30 days after trauma. These findings indicate that trauma accumulates SYP at injured sites of neurons without changing SYP contents and that increased SYP immunoreactivity in the cerebral cortex following traumatic injury reflects an inhibition of synaptic vesicle transportation and dysfunction of synapses, thus providing a histological substrate for brain dysfunctions.     

Transient upregulation of NCAM mRNA in astrocytes in response to entorhinal cortex lesions and ischemia

Axonal sprouting and synaptic reorganization play an important role in the adaptation of the CNS to injury. However, the molecular mechanisms underlying this neuronal plasticity are poorly understood. In the present study we used in situ hybridization to examine the expression of NCAM mRNA in normal hippocampus, and in response to entorhinal cortex (EC) lesions and transient global ischemia. Both neurons and astrocytes were labeled by digoxygenin-tagged cRNA probes which recognize all three major NCAM isoforms of the adult CNS. In contrast, NCAM180-specific probes labeled only neurons in the hippocampus. After unilateral EC lesion, a transient and anatomically restricted upregulation of NCAM120/140 mRNA in reactive astrocytes in the denervated molecular layer of the dentate gyrus was observed. This increase was only present 2–4 days after the lesion whereas the GFAP mRNA increase was present up to 30 days postlesion. Following global ischemia a similar, transient increase of NCAM120/140 mRNA labeling of reactive astrocytes was observed; this increase was anatomically restricted to CA1, where neuronal loss occurred. Results suggest that the transient upregulation of NCAM120/140 mRNA in reactive astrocytes shortly after injury might be an important molecular mechanism in the cascade of events underlying neuronal plasticity in the adult CNS.     

Distribution of GAP-43 mRNA in the adult rat brain

Regional distribution of gene expression of the axonal growth-associated protein, GAP-43, was studied in adult rat brains by in situ hybridization autoradiography to determine the features of mature neuronal populations that synthesize GAP-43 protein. Such synthesis appears to correlate with axonal growth during maturation and regrowth after axotomy. In most adult neurons, the sharp decline in GAP-43 gene expression implies a reduced capacity for axonal growth. Neurons capable of extending axonal knobs in the absence of injury may indicate a “plasticity” underlying dynamic processes of interaction between neurons and their synaptic targets. Antisense and sense (control) riboprobes were used on serial sections in the three principal axes, and the magnitude of hybridization signal was examined to determine regional patterns. GAP-43 mRNA levels are pronounced in diverse neuronal groups including the locus coeruleus, raphé nn., dopaminergic nigral and ventral tegmental nn., mitral cells, hippocampal CA₃, inferior olivary n., vagal motor n. and other parasympathetic preganglionic neurons, select thalamic midline and intralaminar nn., several specific nn. of the hypothalamus and basal forebrain, the granular layer of cerebellar cortex, the infragranular neocortex, and the granular olfactory paleocortex; there is substantial range in the magnitude of expression. Regions revealing minimal signal include most thalamic sensory relay nuclei, the granule neurons of the olfactory bulb and dentate gyrus, and the caudate and putamen. Possible concomitants of GAP-43 expression include regulation of ion flux and neurotrans-mitter release. Those neurons with long, extensively dispersed and numerous synaptic connections display the strongest signals and may possess the greatest propensity for continuous growth and turnover of their axon terminals, in contrast to short-axon and specific projection neurons exhibiting minimal levels. These data may enable inferring which populations display normal or experimentally induced axonal growth. © 1993 Wiley-Liss, Inc.     

Lentiviral‐mediated silencing of glial fibrillary acidic protein and vimentin promotes anatomical plasticity and functional recovery after spinal cord injury

In spinal cord injury (SCI), absence of functional recovery and lack of spontaneous axonal regeneration are attributed, among other factors, to the formation of a glial scar that forms both physical and chemical barriers. The glial scar is composed mainly of reactive astrocytes that overexpress two intermediate filament proteins, glial fibrillary acidic protein (GFAP) and vimentin (VIM). To promote regeneration and sprouting of spared axons after spinal cord trauma and with the objective of translation to clinics, we designed an original in vivo gene transfer strategy to reduce glial scar formation after SCI, based on the RNA interference (RNAi)‐mediated inhibition of GFAP and VIM. We first show that direct injection of lentiviral vectors expressing short hairpin RNA (shRNA) against GFAP and VIM in a mouse model of SCI allows efficient and specific targeting of astrocytes. We then demonstrate that the lentiviral‐mediated and stable expression of shGFAP and shVIM leads to a strong reduction of astrogliosis, improves functional motor recovery, and promotes axonal regrowth and sprouting of spared axons. This study thus examplifies how the nonneuronal environment might be a major target within the lesioned central nervous system to promote axonal regeneration (and sprouting) and validates the use of lentiviral‐mediated RNAi in SCI. © 2014 Wiley Periodicals, Inc.     

Adult Nestin-expressing Subependymal Cells Differentiate to Astrocytes in Response to Brain Injury

The adult brain contains a small population of central nervous system (CNS) cells in the subependyma which, like embryonic CNS progenitor cells, express the intermediate filament nestin. In this report, the differentiation capacity in vivo of these cells was analysed following a standardized trauma. Before the trauma, the subependymal cells expressed nestin but not the astrocytic and neuronal differentiation markers glial fibrillary acidic protein (GFAP) and neurofilament respectively. In response to injury, the majority of the subependymal cells coexpressed nestin and GFAP, but never nestin and neurofilament. Furthermore, cells coexpressing nestin and GFAP were found progressively further away from the subependyma and closer to the lesion at later time points after the injury, indicating that these cells migrate towards the lesion. Nestin was in addition re-expressed in reactive astrocytes near the lesion and in non-reactive astrocytes very far from the lesion throughout the ipsilateral cortex. In conclusion, our data indicate that the nestin-positive subependymal cells are an in vivo source for the generation of new astrocytes but not neurons after injury, and that nestin re-expression in astrocytes following traumatic stimuli can be used as a sensitive marker for astroglial activation.