Spatiotemporal expression patterns of slit and robo genes in the rat brain.

Diffusible chemorepellents play a major role in guiding developing axons toward their correct targets by preventing them from entering or steering them away from certain regions. Genetic studies in Drosophila revealed a repulsive guidance system that prevents inappropriate axons from crossing the central nervous system midline; this repulsive system is mediated by the secreted extracellular matrix protein Slit and its receptors Roundabout (Robo). Three distinct slit genes (slit1, slit2, and slit3) and three distinct robo genes (robo1, robo2, rig-1) have been cloned in mammals. However, to date, only Robo1 and Robo2 have been shown to be receptors for Slits. In rodents, Slits have been shown to function as chemorepellents for several classes of axons and migrating neurons. In addition, Slit can also stimulate the formation of axonal branches by some sensory axons. To identify Slit-responsive neurons and to help analyze Slit function, we have studied, by in situ hybridization, the expression pattern of slits and their receptors robo1 and robo2, in the rat central nervous system from embryonic stages to adult age. We found that their expression patterns are very dynamic: in most regions, slit and robo are expressed in a complementary pattern, and their expression is up-regulated postnatally. Our study confirms the potential role of these molecules in axonal pathfinding and neuronal migration. However, the persistence of robo and slit expression suggests that the couple slit/robo may also have an important function in the adult brain.     

Dynamic changes in glypican-1 expression in dorsal root ganglion neurons after peripheral and central axonal injury

Glypican-1, a glycosyl phosphatidyl inositol (GPI)-anchored heparan sulphate proteoglycan expressed in the developing and mature cells of the central nervous system, acts as a coreceptor for diverse ligands, including slit axonal guidance proteins, fibroblast growth factors and laminin. We have examined its expression in primary sensory dorsal root ganglion (DRG) neurons and spinal cord after axonal injury. In noninjured rats, glypican-1 mRNA and protein are constitutively expressed at low levels in lumbar DRGs. Sciatic nerve transection results in a two-fold increase in mRNA and protein expression. High glypican-1 expression persists until the injured axons reinnervate their peripheral targets, as in the case of a crushed nerve. Injury to the central axons of DRG neurons by either a dorsal column injury or a dorsal root transection also up-regulates glypican-1, a feature that differs from most DRG axonal injury-induced genes, whose regulation changes only after peripheral and not central axonal injury. After axonal injury, the cellular localization of glypican-1 changes from a nuclear pattern restricted to neurons in noninjured DRGs, to the cytoplasm and membrane of injured neurons, as well as neighbouring non-neuronal cells. Sciatic nerve transection also leads to an accumulation of glypican-1 in the proximal nerve segment of injured axons. Glypican-1 is coexpressed with robo 2 and its up-regulation after axonal injury may contribute to an altered sensitivity to axonal growth or guidance cues.     

Expression analysis of neuroleukin, calmodulin, cortactin, and Rho7/Rnd2 in the intact and injured mouse brain

Subtracted cDNA libraries from the mouse developing inferior colliculus were previously constructed between postnatal day (P) 6 and 10. In the P10-P6 subtracted library, neuroleukin, calmodulin I, cortactin, and Rho7 were identified. The goal of the present study was to analyze their distribution, at the mRNA and protein levels, in both the adult and the developing mouse brain. The four molecules showed a wide expression throughout the brain, with a neuronal-enriched localization in structures such as the cortex, the hippocampus, the cerebellum, and the inferior colliculus. The level of expression of their corresponding mRNAs increased during brain postnatal development. The expression of these molecules was also investigated 2 weeks after a mechanical lesion in the adult cerebral cortex. Neuroleukin and cortactin were found to be expressed by reactive astrocytes, while there were no changes in the expression of calmodulin and Rho7. The expression of neuroleukin, calmodulin, cortactin, and Rho7 is discussed in the context of their putative role in the maturation of the brain and in the axonal regeneration process.     

The astrocytic lineage marker calmodulin-regulated spectrin-associated protein 1 (Camsap1): phenotypic heterogeneity of newly born Camsap1-expressing cells in injured mouse brain

Calmodulin-regulated spectrin-associated protein 1 (Camsap1) has been recognized as a new marker for astrocytic lineage cells and is expressed on mature astrocytes in the adult brain (Yamamoto et al. [2009] J. Neurosci. Res. 87:503–513). In the present study, we found that newly born Camsap1-expressing cells exhibited regional heterogeneity in an early phase after stab injury of the mouse brain. In the surrounding area of the lesion site, Camsap1 was expressed on quiescent astrocytes. At 3 days after injury, Camsap1 immunoreactivity was upregulated on glial fibrillary acidic protein-immunoreactive (GFAP-ir) astrocytes. Some of these astrocytes incorporated bromodeoxyuridine (BrdU) together with re-expression of the embryonic cytoskeleton protein nestin. In the neighboring region of the lesion cavity, Camsap1 was expressed on GFAP-negative cells. At 3 days after injury, GFAP-ir astrocytes were absent around the lesion cavity. At this stage, NG2-ir cells immunopositive for Camsap1 and immunonegative for GFAP were distributed in border of the lesion cavity. By 10 days, Camsap1 immunoreactivity was exclusively detected on GFAP-ir reactive astrocytes devoid of NG2 immunoreactivity. BrdU pulse-chase labeling assay suggested the differentiation of Camsap1+/NG2+ cells into Camsap1+/GFAP+ astrocytes. In the subependymal zone of the lateral ventricle, Camsap1-ir cells increased after injury. Camsap1 immunoreactivity was distributed on ependymal and subependymal cells bearing various astrocyte markers, and BrdU incorporation was enhanced on such Camsap1-ir cells after injury. These results suggest that newly born reactive astrocytes are derived from heterogeneous Camsap1-expressing cells in the injured brain.     

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

Exposure of the adult rat brain parenchyma to zinc induces an increase in the intracerebral expression of the metal-binding protein, metallothionein, which is normally confined to astrocytes, ependymal cells, choroid plexus epithelial cells, and brain endothelial cells. Metallothionein is expressed only in diminutive amounts in astrocytes of the neonatal rat brain, which could imply that neonatal rats are devoid of the capacity to detoxify free metals released from a brain wound. In order to examine the influence of a brain injury on the expression of metallothionein in the neonatal brain, PO rats were subjected to a localized freeze lesion of the neocortex of the right temporal cortex. This lesion results in a disrupted blood-brain interface, leading to extravasation of plasma proteins. From 16 h, reactive astrocytosis, defined as an increase in the number and size of cells expressing GFAP and vimentin, was observed surrounding the neocortical lesion site. Astrocytes and pial cells situated adjacent to the area of injury also became positively stained for metallothionein. At 3–6 days post-lesion, the highest level of reactive astrocytes expressing metallothionein was observed. Neo-Timm staining revealed that histochemically reactive zinc had disappeared from the lesion site. Extracellular albumin and metallolhionein-positive astrocytes were absent approximately 2 weeks after the lesion, whereas reactive astrocytosis was still observed. These results show that a lesion of the neonatal rat brain induces a transient expression of metallothionein in reactive astrocytes, probably as a response to metals released from the site of the brain injury. © 1995 Wiley-Liss, Inc.     

SC1/hevin and reactive gliosis after transient ischemic stroke in young and aged rats

SC1 is a member of the SPARC family of glycoproteins that regulate cell-matrix interactions in the developing brain. SC1 is expressed in astrocytes, but nothing is known about the expression in the aged or after stroke. We found that after focal striatal ischemic infarction in adult rats, SC1 increased in astrocytes surrounding the infarct and in the glial scar, but in aged rats, SC1 was lower at the lesion edge. Glial fibrillary acidic protein (GFAP) also increased, but it was less prominent in reactive astrocytes further from the lesion in the aged rats. On the basis of their differential expression of several molecules, 2 types of reactive astrocytes with differing spatiotemporal distributions were identified. On Days 3 and 7, SC1 was prevalent in cells expressing markers of classic reactive astrocytes (GFAP, vimentin, nestin, S100β), as well as apoliprotein E (ApoE), interleukin 1β, aggrecanase 1 (ADAMTS4), and heat shock protein 25 (Hsp25). Adjacent to the lesion on Days 1 and 3, astrocytes with low GFAP levels and a "starburst" SC1 pattern expressed S100β, ApoE, and Hsp32 but not vimentin, nestin, interleukin 1β, ADAMTS4, or Hsp25. Neither cell type was immunoreactive for NG2,CC-1, CD11b, or ionized calcium-binding adapter-1. Their differing expression of inflammation-related and putatively protective molecules suggests different roles for starburst and classic reactive astrocytes in the early glial responses to ischemia.     

Accumulation of the inhibitory receptor EphA4 may prevent regeneration of corticospinal tract axons following lesion

Abstract We have examined the expression of Eph receptors and their ephrin ligands in adult rat spinal cord before and after lesion. Neurons in adult motor cortex express EphA4 mRNA, but the protein is undetectable in uninjured corticospinal tract. In contrast, after dorsal column hemisection EphA4 protein accumulates in proximal axon stumps. One of the ligands for EphA4, ephrinB2, is normally present in the grey matter flanking the corticospinal tract but after injury is markedly up-regulated in astrocytes in the glial scar. The result is that, after a lesion, corticospinal tract axons bear high levels of EphA4 and are surrounded to front and sides by a continuous basket of cognate inhibitory ephrin ligand. We suggest that a combination of EphA4 accumulation in the injured axons and up-regulation of ephrinB2 in the surrounding astrocytes leads to retraction of corticospinal axons and inhibition of their regeneration in the weeks after a spinal lesion.     

Expression of growth inhibitory factor (metallothionein-III) mRNA and protein following excitotoxic immature brain injury

The balance between trophic factors and inhibitory molecules is likely to determine the outcome of neural tissue damage. The growth inhibitory factor (GIF), a member of the metallothionein family of proteins named metallothionein-III (MT-III), has been suggested to play an important role in tissue repair after adult brain injury. Because no information is available on this factor in relation to immature brain damage, we examined the chronological changes of GIF (MT-III) mRNA and protein following excitotoxic lesions to the postnatal day 9 brain using in situ hybridization and immunocytochemical techniques. We observed a significant decrease of neuronal GIF (MT-III) mRNA and protein levels between 4 and 24 hours postinjury and an increase in glial GIF (MT-III) levels. Double immunocytochemical techniques showed GIF (MT-III) and GFAP positive astrocytes from 2-4 hours postinjury. From 3 days postinjury strongly reactive astrocytes expressed strong levels of both GIF (MT-III) mRNA and protein, which were maintained in the glial scar formed at longer times. These results show the expression of an inhibitory molecule by postnatal reactive astrocytes. Glial GIF (MT-III) expression may play an important role in the tissue reconstruction after immature brain damage.     

Induction of TGF-beta-inducible gene-h3 (betaig-h3) by TGF-beta1 in astrocytes: implications for astrocyte response to brain injury

Transforming growth factor (TGF)-beta-inducible gene-h3 (betaig-h3) product is a secreted protein that is induced by TGF-beta in several cell types and implicated in various tissue pathologies. The aims of this study were to determine the effect of TGF-beta1 on betaig-h3 expression in cultured astrocytes and to examine whether betaig-h3 is expressed in the brain after traumatic injury. The results showed that betaig-h3 mRNA and protein increased in response to TGF-beta1 in U87 human astrocytoma cells and mouse cortical astrocytes. Treatment with other cytokines, including tumor necrosis factor-alpha and fibroblast growth factor-2, did not enhance the expression of betaig-h3 in astrocytes. betaig-h3 was significantly expressed in reactive astrocytes at the site of a stab wound in the cerebral cortex of adult rats. These results provide an insight into understanding a novel role for betaig-h3 protein in the response of astrocytes to brain injury.     

Expression of L1 and PSA during sprouting and regeneration in the adult hippocampal formation

The objective of the present study was to evaluate the expression of polysialic acid (PSA) and the cell adhesion molecule L1 during axonal regeneration and sprouting after injury to the adult rat brain. All animals received a complete lesion of the fimbria-fornix (FF). Grafts of nerve growth factor (NGF)- or β-galactosidase (βGal)-producing fibroblasts were placed in the FF lesion cavity and induced septohippocampal cholinergic regeneration or sympathetic tyrosine hydroxylase (TH)-positive sprouting, respectively. Cholinergic regeneration was evaluated from 2 to 8 weeks following grafting of NGF-producing fibroblasts in the FF lesion cavity. In the graft area, choline acetyltransferase (ChAT)-positive fibers expressed L1 and PSA. Once cholinergic axons reached the hippocampal formation (HF), they no longer expressed L1 or PSA. Eight weeks after a lesion of the FF and transplantation of βGal-producing fibroblasts, TH-positive fibers sprouted in the denervated HF and expressed L1 but not PSA. At the zone of reactive gliosis, PSA but not L1 expression was increased following a lesion of the FF and transplantation of NGF- or βGal-producing fibroblasts. In animals that received a graft of NGF-producing fibroblasts in the FF lesion cavity, numerous ChAT-positive axons were observed along these areas rich in PSA and reactive astrocytes. Taken together, these results suggest that the expression of PSA and L1 is upregulated on regenerating cholinergic axons during axonal elongation and downregulated upon target innervation. In contrast, TH-positive fibers that sprout in the denervated HF express and maintain their expression of L1. Finally, the expression of PSA in the area of reactive gliosis may contribute to a permissive environment for axonal regrowth. J. Comp. Neurol. 399:1–19, 1998. © 1998 Wiley-Liss, Inc.     

The chondroitin sulphate proteoglycan brevican is upregulated by astrocytes after entorhinal cortex lesions in adult rats

The chondroitin sulphate proteoglycan brevican is one of the most abundant extracellular matrix molecules in the adult rat brain. It is primarily synthesized by astrocytes and is believed to influence astroglial motility during development and under certain pathological conditions. In order to study a potential role of brevican in the glial reaction after brain injury, its expression was analysed following entorhinal cortex lesion in rats (12 h, 1, 2, 4, 10, 14 and 28 days and 6 months post lesion). In situ hybridization and immunohistochemistry were employed to study brevican mRNA and protein, respectively, in the denervated outer molecular layer of the fascia dentata and at the lesion site. In both regions brevican mRNA was upregulated between 1 and 4 days post lesion. The combination of in situ hybridization with immunohistochemistry for glial fibrillary acidic protein demonstrated that many brevican mRNA-expressing cells are astrocytes. In the denervated zone of the fascia dentata, immunostaining for brevican was increased by 4 days, reached a maximum by 4 weeks and remained detectable up to 6 months post lesion. Electron microscopic immunocytochemistry showed that brevican is a component of the extracellular matrix compartment. At the lesion site a similar time course of brevican upregulation was observed. These data demonstrate that brevican is upregulated in areas of brain damage as well as in areas denervated by a lesion. They suggest a role of brevican in reactive gliosis and are compatible with the hypothesis that brevican is involved in the synaptic reorganization of denervated brain areas.     

MAP2d mRNA is expressed in identified neuronal populations in the developing and adult rat brain and its subcellular distribution differs from that of MAP2b in hippocampal neurones

The brain microtubule-associated protein MAP2 family is composed of high-molecular-weight (MAP2a and MAP2b) and low-molecular-weight (MAP2c and MAP2d) isoforms. The common C-terminal region of HMW MAP2 and MAP2c contains three repeated microtubule-binding domains while MAP2d comprises four repeats. MAP2c mRNA is known to be expressed at high levels in the immature brain. We show that in the brains of rat pups, MAP2c mRNAs are indeed expressed at high levels compared with MAP2d. However, in adult rat brains, MAP2d mRNA levels are higher than MAP2c. In order to identify the neural cells expressing MAP2d, we used in situ hybridization. In vivo, we show that MAP2d mRNA is expressed in well-identified neuronal populations of the brain. In primary cultures of hippocampal neurones, double-labelling experiments confirm that MAP2d is clearly expressed in neurones. We also evaluated in this study the subcellular distribution of the MAP2d mRNAs in cultured hippocampal neurones and we report that in contrast with MAP2b mRNAs, mostly localized in dendrites, MAP2d mRNAs are essentially located in neuronal cell bodies.     

Differential expression of fibroblast growth factor-2 and fibroblast growth factor receptor 1 in a scarring and nonscarring model of CNS injury in the rat

Injury to the adult brain results in abortive axon regeneration and the deposition of a dense fibrous glial scar. Therapeutic strategies to promote postinjury axon regeneration are likely to require antiscarring strategies. In neonatal brain wounds, scar material is not laid down and axons grow across the lesion site, either by de novo growth or regeneration. To achieve the therapeutic goal of recapitulating the nonscarring neonatal response in the injured adult, an understanding of how ontogenic differences in scarring reflect developmental diversities in the trophic response to injury is required. Fibrobast growth factor-2 (FGF-2) expression is developmentally regulated and has been implicated as a regulator of the wounding response of the adult rat central nervous system. We have investigated the expression of FGF-2 and fibroblast growth factor receptor 1 (FGFR1) after penetrating lesions to the cerebral cortex of 5 days post partum (dpp) (nonscarring) and 16 dpp and adult (scarring) rats. In situ hybridization, immunohistochemistry and Western blotting showed robust and sustained increases in FGF-2 and FGFR1 mRNA and protein in reactive astrocytes around the lesion in scarring rats, a response that was attenuated substantially in the nonscarring neonate. These results demonstrate that changes in astrocyte FGF-2 and FGFR1 expression are coincident with the establishment of a mature pattern of glial scarring after injury in the maturing central nervous system, but it is premature to infer a causal relationship without further experiments.     

ErbB-4 and neuregulin expression in the adult mouse olfactory bulb after peripheral denervation

ErbB-4 is expressed by the periglomerular and the mitral/tufted cells of the adult mouse olfactory bulb (OB) and in the present work we tested whether this expression is regulated by the olfactory nerve input to the OB. Reversible zinc sulphate lesions of the olfactory mucosa were made in adult mice and the deafferented OB analysed by immunohistochemistry, Western blotting and semiquantitative RT-PCR. Following deafferentation, the expression of erbB-4, erbB-2 and neuregulin-1 (NRG-1) mRNAs in the OB was altered. At early stages (7-14 days) after lesion the levels of expression of olfactory marker protein (OMP), tyrosine hydroxylase (TH), erbB-4 and NRG-1 mRNAs were decreased, whilst expression of erbB-2 increased and that of NRG-2 was not significantly altered. We observed at least two distinct time courses for these expression changes. The lowest amounts of mRNA for erbB-4 and NRG-1 were observed at day 7 after lesion, whilst mRNAs for TH and OMP were lowest at day 14. At day 28 after the lesion, when olfactory receptor neuron axons had reinnervated the olfactory bulb, the expression levels of OMP, TH, erbB-2, erbB-4 and NRG-1 were identical to control values. These results indicate that the expression of erbB-4 mRNA and protein in periglomerular and mitral cells is controlled by peripheral olfactory innervation. The tight correlation in NRG-1 and erbB-4 expression levels also suggests a possible functional link that deserves further exploration.     

Gradients of ephrin-A2 and ephrin-A5b mRNA during retinotopic regeneration of the optic projection in adult zebrafish

Regeneration of optic axons in the continuously growing optic system of adult zebrafish was analyzed by anterograde tracing and correlated with the mRNA expression patterns of the recognition molecules ephrin-A2 and ephrin-A5b in retinal targets. The optic tectum and diencephalic targets are all reinnervated after a lesion. However, the rate of erroneous pathway choices was increased at the chiasm and the bifurcation between the ventral and dorsal brachium of the optic tract compared to unlesioned animals. Tracer application to different retinal positions revealed retinotopic reinnervation of the tectum within 4 weeks after the lesion. In situ hybridization analysis indicated the presence of rostral-low to caudal-high gradients of ephrin-A2 and ephrin-A5b mRNAs in unlesioned control tecta and after a unilateral optic nerve lesion. By contrast, the parvocellular superficial pretectal nucleus showed retinotopic organization of optic fibers but no detectable expression of ephrin-A2 and ephrin-A5b mRNAs. However, a row of cells delineating the terminal field of optic fibers in the dorsal part of the periventricular pretectal nucleus was intensely labeled for ephrin-A5b mRNA and may thus provide a stop signal for ingrowing axons. Ephrin-A2 and ephrin-A5b mRNAs were not detectable in the adult retina, despite their prominent expression during development. Thus, given a complementary receptor system in retinal ganglion cells, expression of ephrin-A2 and ephrin-A5b in primary targets of optic fibers in adult zebrafish may contribute to guidance of optic axons that are continuously added to the adult projection and of regenerating axons after optic nerve lesion.     

The dual response of protein kinase Fyn to neural trauma: early induction in neurons and delayed induction in reactive astrocytes

In the developing central nervous system, a src-related protein-tyrosine kinase fyn participates in the myelination process, neuronal growth, and cytoskeletal organization. In adults, fyn has been implicated in learning and memory formation. To test if fyn expression is modulated by neuronal activity, we performed quantitative in situ hybridization (ISH) using brain sections of the adult rats that had undergone either kainic acid (KA)-induced seizures or neuronal deafferentation (entorhinal cortex lesion, ECL). In the KA model, a few hours after seizure activities, fyn mRNA was elevated in the dentate gyrus (DG) (+45%), cerebral cortex layer III (+35%), and piriform cortex (+25%). Conversely, fyn mRNA consistently decreased in the hippocampal neurons after transection of the major axonal inputs from the entorhinal cortex. Although fyn expression in the brain has been allegedly limited to neurons and oligodendrocytes, we provide in this study the first evidence that fyn mRNA is highly expressed in the astrocytes involved in reactive gliosis. In the KA model, the occurrence of fyn-overexpressing astrocytes increased with the progress of neuronal damage in the CA1 and CA3 regions of the hippocampus. In contrast, fyn-overexpressing astrocytes were not observed in the granular cell layer of dentate gyrus (DG), where neurons were not damaged. Likewise, in the ECL model, the most drastic change in fyn mRNA expression took place at the reactive astrocytes near the stab wound sites, where fyn mRNA levels were doubled 4-10 d after the lesion. Collectively, our data suggest that (i) an early induction of fyn mRNA in neurons is linked to neuronal activity, and (ii) the delayed induction of fyn mRNA in reactive astrocytes near the damaged cells may play novel signaling roles during glial response.