Filament proteins in rat optic nerves undergoing Wallerian degeneration

Up-regulation of vimentin expression during regeneration in the adult fish brain

In contrast to mammals, the brains of teleost fish exhibit an enormous regenerative capacity following injury. Here, we have examined the potential role of vimentin in this wound healing. Fifteen days after application of a mechanical lesion to the corpus cerebelli in the teleost fish Apteronotus leptoryhnchus, the areal density of vimentin-positive fibres increased significantly at the lesion site and in the remaining ipsilateral molecular layer. This density remained elevated throughout the time period of up to 100 days examined. Based on this spatio-temporal pattern of vimentin up-regulation we propose that this intermediate filament protein is involved in the survival, differentiation, and/or dendritic growth of the new cells that replace damaged cells in the injury zone.

Glial cell reaction to cis-dichlorodiammine platinum treatment in the immature rat cerebellum

In this study we have investigated changes in glial cells of the cerebellum of cis-dichlorodiammine platinum (cisDDP)-treated rats. The expression of S-100 protein and glial fibrillary acidic protein (GFAP), taken as markers of glial cell function, was evaluated using immunocytochemical methods. In parallel, immunoreactivity for calbindin, parvalbumin, and phosphorylated 200-kDa neurofilament protein was observed in Purkinje cells as markers for neuronal integrity and activity. Results showed that, although no difference in the immunostaining of S-100 protein between control and treated animals could be observed, an increase in the frequency of GFAP immunoreactive cells was present in cisDDP-treated rats. In Purkinje cells, immunocytochemical expression of calbindin and parvalbumin was decreased after drug treatment. In addition, following immunoreaction for phosphorylated 200-kDa neurofilament protein, the somata of Purkinje cells, which were negative in control animals, were stained in treated rats. These findings suggest that cisDDP does not significantly interfere with pathways of glial cell activity and that the increased number of GFAP positive astrocytes may be due to an activation of glial cells consequent upon neuronal death.

Transient immunohistochemical labelling of rat retinal axons during Wallerian degeneration by a monoclonal antibody to neurofilaments

Immunohistochemical labelling with the monoclonal antibody SMI32 to non-phosphorylated epitopes on neurofilament proteins of high molecular weight class was low in rat central optic fibers of controls. After unilateral transection of optic nerve, a strong, transient increase of labelling with SMI32 occurred in degenerating fibers of optic tract at 2 and 4 days, which then declined at 8 and remained low at 21 days. Consequently, immunostaining with SMI32 may serve as a positive marker for degenerating fibers in rat optic system.

Astrocytic messenger RNA responses to striatal deafferentation in male rat

This investigation describes the schedule and regional distribution of astrocytic responses in striatum following deafferentation by unilateral frontal cortex ablation. In the ipsilateral deafferented striatum, glial fibrillary acidic protein and clusterin (sulfated glycoprotein-2) messengerRNA showed peak elevations by 10 days postlesioning (Northern blots). Vimentin messengerRNA responded faster, with a transient elevation by three days postlesioning. The messengerRNA for glial fibrillary acidic protein, clusterin and vimentin returned toward control levels by 27 days postlesioning. However, the neuronal marker growth-associated protein messengerRNA, was decreased at all postlesion times. By in situ hybridization, the increased glial fibrillary acidic protein messengerRNA and clusterin messengerRNA signals were localized mainly to the dorsal half of the ipsilateral deafferented striatum and followed the same schedule as found by Northern blots. Glial fibrillary acidic protein messengerRNA was widely diffused in the dorsal striatum and was excluded from fascicles of the internal capsule; a similar distribution was found for glial fibrillary acidic protein-immunopositive astrocytes. While clusterin messengerRNA signal showed a distinct clustering, its immunoreactivity appeared as deposits in the deafferented striatal neuropil; Western blots confirmed the immunocytochemical results. By in situ hybridization, vimentin messengerRNA was mostly localized to the cortical wound cavity dorsal to the deafferented striatum and overlapped the distribution of vimentin-immunopositive cells. These findings suggest a coordination of striatal astrocytic messengerRNA responses with the degeneration of corticostriatal afferents. We also compared these same parameters with those from published reports on the hippocampus after deafferenting lesions. Certain astrocyte molecular responses to deafferentation are detected about five days earlier in the hippocampus than in the striatum. This different schedule in response to decortication may pertain to differences in synaptic remodeling in the hippocampus vs striatum.

Coexpression of vimentin and glial fibrillary acidic protein in glial cells of the adult rat pineal gland

In the present work, coexpression of vimentin (VIM) and glial fibrillary acidic protein (GFAP) is demonstrated in the glial cells of the adult rat pineal gland. Serial consecutive Epon semithin sections (0.5 microns thick) were alternately immunostained for VIM and GFAP. GFAP positive cells and processes were found in the proximal region of the pineal gland, near the pineal stalk. Most of these cells were also immunostained for VIM in adjacent semithin sections. The significance of the coexpression VIM-GFAP and the restricted location of GFAP positive cells is discussed in relation with the maturation of pineal glial cells.

Gliosis during optic fiber regeneration in the goldfish: an immunohistochemical study

Antisera directed against the 48 kDa and 50 kDa cytoskeletal antigens were used to examine changes in the astroglial fabric of the goldfish visual pathways following optic nerve crush. Several major observations are described. First, an optic nerve crush lesion in these animals appears to be devoid of glial cells for at least the first month after surgery. As a corollary, regenerating axons that grow across the lesion may do so over an aglial substrate. Once the axons cross the lesion, their growth is confined to the astroglial domains of the proximal nerve stump. In the optic nerve, gliosis comprises hypertrophy of astrocytic processes such that the open framework characterizing the normal nerve is obscured. In addition, during regeneration, optic nerve glia express large amounts of the 50 kDa cytoskeletal protein, which they ordinarily express at only minimal levels. In the optic tract, gliosis is reflected in a markedly increased expression of the 50 kDa protein as well as an apparent increase in the number and complexity of glial processes. In addition, optic tract glia begin to express the 48 kDa antigen during regeneration. This protein is ordinarily confined for the most part to the optic nerve and is not seen in the tract glia. Finally, no obvious changes were seen in the glia of the optic tectum. These results demonstrate many points of similarity between gliosis in the goldfish and in mammals. However, in some particulars the two responses differ, and it is possible that these differences are related to the differing ability of central axons to regenerate in the two groups of organisms.

Vimentin mRNA expression increases after corticospinal axotomy in the adult hamster

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

Developmental expression of glial fibrillary acidic protein and glutamine synthetase mRNAs in normal and jimpy mice

Astrogliosis is a prominent feature in the CNS of the dysmyelinating mutant, jimpy. In the following study the expression of the glial markers, glial fibrillary acidic protein (GFAP) and glutamine synthetase (GS) mRNAs were examined the cerebra of normal and jimpy mice. The relative abundance of GFAP and GS mRNAs increased rapidly in the CNS of normal mice during the first two postnatal weeks. During the third week the content of GFAP and GS mRNA remained constant. The pattern of developmental accumulation of these transcripts in jimpy animals was distinctly different. Levels of GFAP transcripts in 6- and 10-day-old jimpy animals were essentially the same as controls. In 14-day-old animals, however, the content of GFAP mRNA in jimpy had increased dramatically, and was 3-fold greater than that found in normal animals. The levels of GFAP message remained significantly elevated above control values for the life of the animals, approximately 22-24 days. In contrast, no significant difference in GS mRNA content was detected between control and jimpy brain tissue. The results of this study indicated that increased accumulation of GFAP mRNA was significant component of reactive gliosis and that the mechanisms responsible for the induction of GFAP were dissociated from those that regulate GS expression.

Glial changes following an excitotoxic lesion in the CNS--II. Astrocytes

Astrocytes are involved, as are microglia/macrophages [Marty et al. (1991) Neuroscience 45, 529-539], in the formation of a glial scar after CNS lesions. This study was undertaken to follow the time-course of changes in the morphology and distribution of astrocytes that takes place during the formation of a glial scar after kainic acid injection in the rat thalamus. The astrocytes were identified using an antibody raised against glial fibrillary acidic protein (GFAP) and the progression of their reaction to the lesion was followed from 24 h to one year after the kainate injection. Three periods could be distinguished during the evolution of the astrocytic response in the neuron-depleted area. There was an initial appearance of a large number of GFAP+ cells. These cells displayed profound morphological differences from the normal. They were enlarged, round and devoid of processes. These GFAP+ astrocytes disappeared four days after the lesion. This increase of the GFAP+ cells in the neuron-depleted area may be due to cytoskeletal changes and thus an increased exposure of antigenic sites. In a second period between four and 14 days, the only GFAP+ elements present in the neuron-depleted area were long and straight processes. These processes entered the lesioned area from the periphery and seemed to follow axon bundles. Additionally, during the first weeks, the number of reactive astrocytes increased in a small band just around the area of neuronal loss. The third period began after two weeks. The lesioned area became gradually occupied by GFAP+ astrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Coexpression of vimentin and glial fibrillary acidic protein in astrocytes of the adult rat optic nerve

The localization of vimentin (VIM) and glial fibrillary acidic protein (GFAP) was studied immunohistochemically in adult rat optic nerve. Consecutive Epon semithin tissue sections were immunostained respectively for VIM or GFAP. With this method, both antigens were detected in consecutive sections of the same cell. According to our results, most astrocytes in the adult rat optic nerve showed coexpression of VIM and GFAP.

Intermediate filaments in the inner ear of normal and experimentally damaged guinea pigs

The hypothesis that proteins known to occur in glial cells in the central nervous system may be present in inner-ear supporting cells was investigated. Immunocytochemical techniques were used to look for the existence of two classes of intermediate filaments, vimentin and glial fibrillary acidic protein (GFAP), in cellular elements of the inner-ear epithelium in normal and experimentally damaged guinea-pig cochleas. Vimentin is present in two types of supporting cells in the normal organ of Corti: Deiters' cells and inner pillar cells. Differences in intensity and distribution of vimentin immunostaining are observed across the three rows of Deiters' cells. GFAP immunoreactivity was not detected in any supporting-cell type in the organ. Cochlear hair cells were not labeled for either GFAP or vimentin. Following hair-cell destruction by exposure to noise or the administration of aminoglycosides, GFAP and vimentin are not present in phalangeal scars replacing lost hair cells.

Changes in astroglial scar formation in rat optic nerve as a function of development

Although astroglial scar formation is a common response to almost any type of injury to the adult central nervous system, lesions in fetal and neonatal rats have been reported to induce little or no scar formation. To examine this developmental difference further, rats ranging in age from 1 to 65 days postnatal were unilaterally enucleated, a surgical procedure that causes the axons in the optic nerve to degenerate. The optic nerves were processed for light and electron microscopy at times ranging from 7 to 365 days postenucleation. Pronounced and permanent glial scars were formed in every age group examined, including the neonates. However, the time course for removal of the degenerating axonal debris and formation of a compact, debris-free glial scar varied as a function of developmental age. In neonatal rats, a compact glial scar formed in 1-2 weeks whereas 3-5 months were required for compact glial scar formation in juveniles and adults. Changes in cross-sectional area were also associated with optic nerve degeneration and glial scar formation. Whereas lesioned neonatal optic nerves underwent little change in area, there was a substantial decrease in area in the juvenile and adult. Morphometric analysis showed that irrespective of the age of the animal at the time of enucleation, the final area of the compact glial scar was 10-20% of the unlesioned adult control. These results suggest that conflict in the literature over the ability of neonatal astrocytes to form a glial scar may be due to the nature of the lesion or the method of detection since astrocytes in the neonatal rat optic nerve clearly have the capacity to become reactive and form a glial scar.

Comparative immunohistochemical study of glial filament proteins (glial fibrillary acidic protein and vimentin) in goldfish, octopus, and snail

Glial fibrillary acidic protein (GFAP) and vimentin proteins are known to be component proteins of glial filaments in the CNS of many vertebrates. The nature of the filaments present in the glial cells of the goldfish optic tectum and in the CNS of two members of the Mollusca (Helix pomatia and Octopus vulgaris) were investigated using immunocytochemical localization of monoclonal antibodies to GFAP and vimentin. Immunoblots visualized by the alkaline phosphatase method showed cross-reactive protein bands to GFAP and vimentin antibodies in total brain homogenates of the goldfish, octopus, and snail. Immunofluorescence staining of the goldfish optic tectum showed GFAP immunoreactivity, primarily in the ependymal cell processes. Immunogold labelling at the ultrastructural level verified that GFAP antibodies were bound to glial filaments. Immunolabelling of the optic lobe of Octopus vulgaris and the cerebral ganglia of Helix pomatia suggests that a protein exhibiting antigenic properties similar to GFAP is a component protein in the filaments of the protoplasmic and filamentous glia randomly distributed throughout the CNS. Unlike anti-GFAP antibodies, which stained relatively specific to filaments, vimentin staining in the CNS tissues of the three organisms studied did not appear to be exclusive to filamentous structures. As vimentin protein has been shown, in previous studies as well as our own, to exist in many tissue types, this suggests that it does not appear to be confined to glial filaments but is shared with other subcellular components. The proteins GFAP and vimentin which are thought to be well conserved in vertebrate evolution also appear to be expressed in the nervous system of some lower organisms.

Expression of glial fibrillary acidic protein (GFAP) in goldfish optic nerve following injury

By using an antibody to goldfish glial fibrillary acidic protein (GFAP), the reaction of goldfish optic nerve to injury has been studied by immunoblotting and immunohistochemical methods. Goldfish optic nerve, which normally lacks GFAP immunoreactivity (Nona et al.: Glia, 2:189-200, 1989), expresses GFAP following injury. This immunoreactivity, which is observed as early as 10 days after crush and which is still evident at 30 days after crush, all but disappears by 150 days after crush. Since it is well established that functional restoration of synaptic connections and the recovery of vision takes place in goldfish following optic nerve injury, our results indicate that reactive astrocytes do not represent an impediment to regeneration in goldfish visual system.

Axonal injury in the optic nerve: a model simulating diffuse axonal injury in the brain

A new model of traumatic axonal injury has been developed by causing a single, rapid, controlled elongation (tensile strain) in the optic nerve of the albino guinea pig. Electron microscopy demonstrates axonal swelling, axolemmal blebs, and accumulation of organelles identical to those seen in human and experimental brain injury. Quantitative morphometric studies confirm that 17% of the optic nerve axons are injured without vascular disruption, and horseradish peroxidase (HRP) studies confirm alterations in rapid axoplasmic transport at the sites of injury. Since 95% to 98% of the optic nerve fibers are crossed, studies of the cell bodies and terminal fields of injured axons can be performed in this model. Glucose utilization was increased in the retina following injury, confirming electron microscopic changes of central chromatolysis in the ganglion cells and increased metabolic activity in reaction to axonal injury. Decreased activity at the superior colliculus was demonstrated by delayed HRP arrival after injury. The model is unique because it produces axonal damage that is morphologically identical to that seen in human brain injury and does so by delivering tissue strains of the same type and magnitude that cause axonal damage in the human. The model offers the possibility of improving the understanding of traumatic damage of central nervous system (CNS) axons because it creates reproducible axonal injury in a well-defined anatomical system that obviates many of the difficulties associated with studying the complex morphology of the brain.

Vimentin-GFAP transition in primary dissociated cultures of rat embryo spinal cord

Primary dissociated cultures derived from 15-day-old rat embryo spinal cord with or without dorsal root ganglia (DRG) were grown on polylysine, Primaria and laminin substrates. On polylysine and Primaria substrates, spinal cord neurons formed aggregates connected by bundles of neurites in a distinctive pattern similar to that observed in cultures derived from embryonal rat brain and neonatal rat cerebellum. After 2 days in culture, the number of cells stained with GFAP antibodies progressively increased within the vimentin-positive monolayer surrounding the neuronal aggregates. These astrocytes had the typical appearance of astrocytes in primary dissociated cultures derived from late fetal or early neonatal murine brain, i.e. large flat or stellate cells with thick processes staining equally well with GFAP and vimentin antibodies. Astrocytes found within the neuronal aggregates in 4-5 day cultures were markedly different, i.e. small stellate cells with slender processes forming a delicate mesh throughout the aggregate. These GFAP-positive cells stained only weakly with vimentin antibodies. Spinal cord neurons formed aggregates on laminin substrates but failed to extend neurites and rapidly degenerated. The large flat cells in the surrounding monolayer gradually invaded the aggregates. These cells stained with both GFAP and vimentin antibodies. DRG neurons developed equally well on Primaria and laminin substrates, extending their neurites on the vimentin-positive flat cells forming the monolayer regardless of their reactivity with GFAP antibodies.

Neurite extension on dibutyryl cyclic AMP-stimulated astrocytes

Although both central and peripheral neurons successfully regenerate cut axons along peripheral nerve and other suitable substrates, axonal elongation through the mature central nervous system (CNS) is limited. It has been proposed that the presence of reactive astrocytes formed in response to CNS injury act as a barrier to axonal regeneration. In contrast, in vitro, astrocytes in a flat or unstimulated state have been shown to be a preferred substrate for neurite extension. We have investigated whether induced modifications of astrocytes alter the capacity of these cells to act as a substrate for axonal elongation. Treatment with dibutyryl cyclic AMP (dBcAMP) results in a marked morphological and biochemical change in astrocytes, considered by some to be a model of reactive astrocytosis. Retinal and dorsal root ganglia explants from embryonic mice were cultured on top of untreated glial monolayers and those treated with dBcAMP. The subsequent neuritic growth was measured at 48 h. No difference was found between the groups, indicating that astrocytes are an excellent substrate for axonal growth, even after they develop a stellate shape and high levels of glial fibrillary acidic protein.

Detection limits of different approaches in behavioral teratology, and correlation of effects with neurochemical parameters

Five laboratories collaborated in the evaluation of detection limits of different testing concepts in behavioral teratology. In one laboratory, rat dams were treated by gavage with five doses of methylmercury (0.0, 0.25, 0.05, 0.5, and 5.0 mg/kg/day). The treatment period was restricted to days 6 to 9 of gestation. The usual reproduction parameters were assessed in the dams. The offspring (88-99 per group) were subjected to a routine developmental and behavioral testing battery. After completion of these tests, random samples of the animals were further investigated in four other laboratories using the following techniques: auditory startle habituation, visual discrimination and figure-8 activity monitor; wheel-shaped activity monitor and spatial alternation operant conditioning; two-compartment locomotor activity, passive avoidance and male ultrasonic vocalization during sexual behavior; assays of the weight of different brain areas, their glial fibrillary acidic (GFA) protein and S-100 protein concentration. The following dose-dependent effects were noted in ascending dose sensitivity order: delayed vaginal opening; increased and more variable passiveness in spatial alternation; impaired swimming behavior, increased GFA protein concentration in the cerebellar vermis; increased auditory startle amplitude, decreased intertrial interval pokes in the visual discrimination test, increased percentage of visits in passive area of figure-8 activity monitor, increased path iteration frequencies and decreased local activity in the wheel-shaped activity monitor, decreased locomotor activity in the two-compartment monitor, increased cerebellar vermis weight, and decreased S-100 protein in the hippocampus. Therefore, this study showed comparable sensitivities for the behavioral testing battery, for some automated multiparametric test systems and for the neurochemical assays.

Ca2+-mediated degradation of central nervous system (CNS) proteins: topographic and species variation

Incubation of homogenates of rat, rabbit, and bovine spinal cord and of bovine brain white and gray matter in the presence of calcium (5 mM) produced an extensive degradation of the neurofilament triplet proteins (NFP; 200 K, 150 K, and 69 K). The breakdown products of the NFPs were identified by immunoblot. The glial fibrillary acidic protein (GFAP), microtubular proteins (MTP), and myelin proteins were also degraded. The 150 K NFP was more susceptible than the other NFPs. The extent of calcium-mediated degradation was slightly greater with rat spinal cord than the others. Bovine brain white matter had more activity than gray, which had no appreciable degradative activity. The breakdown was prevented by both EGTA and leupeptin but a similar concentration of MgCl2 (5 mM) had no effect. These results suggest that NFPs are degraded by a Ca2+-activated neutral proteinase in the central nervous system (CNS) of several species. The lesser activity in gray matter suggests that the enzyme is enriched in axons, myelin, and/or oligodendroglial cells.

Irreversible effects of dichloromethane on the brain after long term exposure: a quantitative study of DNA and the glial cell marker proteins S-100 and GFA

Two astroglial proteins S-100 and GFA, as well as DNA, were quantitatively determined in different regions of the gerbil brain after continuous long term exposure to moderate concentrations of dichloromethane. The intention of the experiment was to expose three groups of animals at three different solvent concentrations (210, 350, or 700 ppm) for three months. Because of the high mortality rate, however, the 700 ppm experiment was terminated after seven weeks. In the 350 ppm experiment half the exposed animals died and the exposure period was terminated after ten weeks. After the exposure period, the surviving gerbils in the 350 ppm exposure group and those from the 210 ppm group were allowed a postexposure solvent free period of four months. After exposure to 350 ppm, increased concentrations of the two astroglial proteins were found in the frontal and sensory motor cerebral cortex, compatible with astrogliosis in these regions. Exposure to 350 ppm and 210 ppm decreased the concentrations of DNA in the hippocampus. Moreover, after exposure at 350 ppm, DNA concentrations were also decreased in the cerebellar hemispheres. These results indicate a decreased cell density in these brain regions, probably due to cell loss. The neurotoxic effects were not found to correlate with the endogenous formation of carbon monoxide.

Response of astrocytes in the visual system to Wallerian degeneration: an immunohistochemical analysis of laminin and glial fibrillary acidic protein (GFAP)

Eye removal in adult rats resulted in an increase in immunohistochemical staining with antibodies to glial fibrillary acidic protein in the optic nerve, optic tract, and primary visual nuclei. Astrocytes along the primary visual pathway did not stain with antibodies to laminin in response to eye removal. There was an increase in laminin immunoreactivity associated with blood vessels along the injured pathway. These blood vessels were also shown to have an increased size. The lack of laminin induction in astrocytes along the path of degenerating optic axons may be responsible in part for the inability of axons to regenerate in the primary visual system.

Co-expression of glial fibrillary acidic protein- and vimentin-type intermediate filaments in human astrocytomas

The expression of intermediate filament (IF) proteins was studied in 71 cases of malignant human astrocytoma and in 17 cases of reactive gliosis, using immunocytochemical techniques with polyclonal and monoclonal antibodies to glial fibrillary acidic protein (GFAP) and vimentin. In all cases of astrocytoma, varying in degree of malignancy from grade I to grade IV, co-expression of GFAP and vimentin was found. No change in vimentin- or GFAP-IF expression with increasing anaplasia was seen. In addition astrocytic cells in reactive gliosis showed simultaneous expression of GFAP and vimentin. The intracellular distribution of these IF proteins differed. Vimentin was found to be located in a more juxta-nuclear position, whereas GFAP immunoreactivity showed a more intense staining of the cellular processes. Astrocytes in reactive gliosis behaved more or less like neoplastic cells. However, thin cell processes of reactive astrocytes in the cortex and superficial white matter only contained GFAP immunoreactivity. Simultaneous expression of GFAP and vimentin and their proportion in malignant and reactive glial cells are discussed in the light of earlier reports on the IF content of glial cells during development and maturation, in which vimentin precedes GFAP-expression. The existence of two separate (functional) IF systems in astroglia is suggested.

Non-glial specificities of immunocytochemistry for the glial fibrillary acidic protein (GFAP). Triple expression of GFAP, vimentin and cytokeratins in papillary meningioma and metastasizing renal carcinoma

In an extensive immunocytochemistry study for glial fibrillary acidic protein (GFAP) of human neuropathological biopsy or autopsy tissue specimens examined for diagnostic or research purposes, rare non-glial specificities of the GFAP immunostain were observed: Schwann cells of some small nerves in salivary gland, renal capsule, and in epidural fat adjacent to a metastatic carcinoma, Schwann and satellite cells in a spinal ganglion invaded by tumor, chondrocytes of epiglottic cartilage, few cells of a malignant pleomorphic adenoma of salivary gland, most cells of a recurrent papillary meningioma with areas similar to the hemangiopericytic variant, and many cells of a renal carcinoma metastatic to brain; the primary renal tumor had been operated 4 years earlier and focally contained some GFAP-positive cells. To ascertain the specificity of such unexpected immunoreactivities for GFAP and to exclude possible crossreactivities with other intermediate filament (IF) proteins, a panel of different antibodies was used for immunocytochemistry with the peroxidase-antiperoxidase (polyclonal antisera) or labeled biotin-avidin (monoclonal antibodies) techniques: two monoclonal and four polyclonal anti-GFAP, three monoclonal and one polyclonal anti-cytokeratins (CK), and two monoclonal anti-vimentin (VIM) antibodies. Triple expression of GFAP, VIM and CK was found in the papillary meningioma (in patterns suggesting frequent co-localization), in the metastatic carcinoma (in patterns suggesting little co-localization), and in the pleomorphic adenoma (only few GFAP-positive cells). Co-expression of GFAP and VIM was seen in epiglottic chondrocytes and reactive astroglia; another metastatic carcinoma was labeled only for CKs. In the light of previous reports on non-glial specificities of the GFAP immunostain, and of the consistency of our immunostaining results obtained by all monospecific anti-GFAP antibodies as well as the lack of immunocytochemically evident crossreactivity with other IF proteins, authentic GFAP production by some rare non-glial tissues and tumors is suggested.

The role of post-traumatic mitosis in elevation of anaerobic metabolism enzyme (lactic acid dehydrogenase) activity in degenerating central and peripheral nerve

Glial and Schwann cells undergo marked biochemical and morphological alterations following axonal injury. In the present experiments, the extent of enzyme activity associated with anaerobic (LDH, lactic dehydrogenase) vs aerobic (SDH, succinic dehydrogenase) respiration was assessed distal to the site of nerve fiber injury. Studies were performed in rat central (optic) and peripheral (sciatic) nerves at 2, 7 and 14 days postoperatively (d.p.o.). In sciatic nerves, LDH activity rose 3-fold in traumatized (vs unoperated control) nerve tissue between 2 and 7 d.p.o. and remained elevated at 14 d.p.o. SDH activity in traumatized nerve was equal to that in unoperated nerve at 7 d.p.o., but decreased at 14 d.p.o. LDH activity in optic nerve at 2 d.p.o. was equivalent to that in control nerve, but rose approximately two-fold by 7 d.p.o. However, unlike peripheral nerve, activity in traumatized optic nerve decreased to control levels at 14 d.p.o. SDH activity in traumatized optic nerve remained unchanged at any timepoint examined. Taken in concert, these data are consistent with the hypothesis that there is an overall shift in CNS glial and Schwann cell metabolism from aerobic to anaerobic respiration following nerve injury. Additional studies were performed to determine if this shift requires prior Schwann or glial cell mitosis. Administration of mitotic inhibitor (AraC, cytosine arabinofuranoside) inhibited post-traumatic elevations in LDH activity in optic, but not peripheral nerve. No significant effect of the drug on axonal degeneration (as assessed by saxitoxin binding) was observed.

Glial fibrillary acidic (GFA) protein in vertebrates: immunofluorescence and immunoblotting study with monoclonal and polyclonal antibodies

We report a comparative immunofluorescence and immunoblotting study of GFA protein, the subunit of glial filaments, in nonmammalian vertebrates. The study was conducted with polyclonal antibodies raised to human and shark antigen and with monoclonal antibodies isolated from mice immunized with chicken and bovine antigen. With the exception of cyclostomes, glial filaments appeared remarkably conserved in vertebrate phylogeny, both with respect to the molecular weight and immunoreactivity of their protein subunit. In most species, the antibodies decorated a single band in brain, spinal cord, and optic nerve extracts by the immunoblotting procedure. This band had the same molecular weight in the different CNS regions. With the exception of the turtle, species differences in the molecular weight of the band were not greater than those observed among mammalian vertebrates (human, bovine, and rat). However, there were some exceptional findings in fish. In goldfish and trout brain and spinal cord extracts, the antibodies decorated with the same intensity two bands. In accordance with previous immunofluorescence findings, goldfish optic nerve extracts were negative by the immunoblotting procedure. In four fishes (sea bass, tautog, trout, and scup), optic nerves reacted with the antibodies. However, the band decorated by the antibodies was higher in molecular weight than that obtained from brain and spinal cord extracts. Glial fibers were demonstrated by immunofluorescence in the brain, spinal cord, optic nerve, and retina of most species studied. In amphibia immunofluorescent structures were comparatively few, probably accounting for the negative results by immunoblotting. A comparative immunohistological study of the cerebellum showed the presence of perpendicular glial fibers in the molecular layer of most species examined. Birds and amphibia were different in this respect. Bergmann glia in chicken were GFA negative. In the frog and the toad, immunofluorescent fibers in the molecular layer of the cerebellum were haphazardly oriented. Ependymal radial glia was GFA-negative in the cerebellum of subavian vertebrates. Antisera raised in rabbit to shark GFA protein reacted with the same bovine GFA fragments recognized by polyclonal and monoclonal antibodies raised to human and bovine antigens, respectively, i.e., 30-kDa N-bromosuccinimide fragment (tryptophan cleavage); 35-kDa 2-nitro-5-thiocyanobenzoic acid fragment (cysteine cleavage); 18-kDa cyanogen bromide fragment (methionine cleavage). Conversely, the chicken GFA monoclonal antibodies selected for this study only reacted with noncleaved protein.

Changes in protein content of goldfish optic nerve during degeneration and regeneration following nerve crush

After the goldfish optic nerve was crushed, the total amount of protein in the nerve decreased by about 45% within 1 week as the axons degenerated, began to recover between 2 and 5 weeks as axonal regeneration occurred, and had returned to nearly normal by 12 weeks. Corresponding changes in the relative amounts of some individual proteins were investigated by separating the proteins by two-dimensional gel electrophoresis and performing a quantitative analysis of the Coomassie Brilliant Blue staining patterns of the gels. In addition, labelling patterns showing incorporation of [3H]proline into individual proteins were examined to differentiate between locally synthesized proteins (presumably produced mainly by the glial cells) and axonal proteins carried by fast or slow axonal transport. Some prominent nerve proteins, ON1 and ON2 (50-55 kD, pI approximately 6), decreased to almost undetectable levels and then reappeared with a time course corresponding to the changes in total protein content of the nerve. Similar changes were seen in a protein we have designated NF (approximately 130 kD, pI approximately 5.2). These three proteins, which were labelled in association with slow axonal transport, may be neurofilament constituents. Large decreases following optic nerve crush were also seen in the relative amounts of alpha- and beta-tubulin, which suggests that they are localized mainly in the optic axons rather than the glial cells. Another group of proteins, W2, W3, and W4 (35-45 kD, pI 6.5-7.0), which showed a somewhat slower time course of disappearance and were intensely labelled in the local synthesis pattern, may be associated with myelin. A small number of proteins increased in relative amount following nerve crush. These included some, P1 and P2 (35-40 kD, pIs 6.1-6.2) and NT (approximately 50 kD, pI approximately 5.5), that appeared to be synthesized by the glial cells. Increases were also seen in one axonal protein, B (approximately 45 kD, pI approximately 4.5), that is carried by fast axonal transport, as well as in two axonal proteins, HA1 and HA2 (approximately 60 and 65 kD respectively, pIs 4.5-5.0), that are carried mainly by slow axonal transport. Other proteins, including actin, that showed no net changes in relative amount (but presumably changed in absolute amount in direct proportion to the changes in total protein content of the nerve), are apparently distributed in both the neuronal and nonneuronal compartments of the nerve.

Tissue calcium levels in CaCl2-induced myelopathy

CaCl2-induced myelopathy was produced in rats by the application of a solution of CaCl2 to exposed leptomeninges of lumbosacral spinal cord. Equal lengths of remote cervical and lumbar cord were removed at intervals following Ca2+ application. The total Ca2+ in tissue from lumbar cord was significantly elevated over autologous cervical cord and homologous lumber controls after after 2 h. The maximum Ca2+ increase in lumbar cord was 3.9-fold that of homogolous control and was reached by 8 h post Ca2+ application. The time course for the elevation of Ca2+ as measured by atomic absorption spectrophotometry, resembles that found in spinal cord following direct physical trauma. These findings as well as similar changes in morphology and neural proteins from previous studies suggest that Ca2+ is involved in and may potentiate the degeneration of axons and myelin via Ca2+-activated neutral proteinases.

Cellular origin and biosynthesis of rat optic nerve proteins: a two-dimensional gel analysis

High resolution 2DGE (two-dimensional gel electrophoresis) was used to characterize neuronal and glial proteins of the rat optic nerve, to examine the phases of intraaxonal transport with which the neuronal proteins are associated, and to identify the ribosomal populations on which these proteins are synthesized. Neuronal proteins synthesized in the retinal ganglion cells were identified by injecting the eye with L-[35S]methionine, followed by 2DGE analysis of fast and slow axonally transported proteins in particulate and soluble fractions. Proteins synthesized by the glial cells were labeled by incubating isolated optic nerves in the presence of L-[35S]methionine and then analyzed by 2DGE. A number of differences were seen between filamentous proteins of neurons and glia. Most strikingly, proteins in the alpha- and beta-tubulin region of the 2D gels of glial proteins were distinctly different than was observed for axonal proteins. As expected, neurons but not glia expressed neurofilament proteins, which appeared among the slow axonally transported proteins in the particulate fraction; significant amounts of the glial filamentous protein, GFA, were also labeled under these conditions, which may have been due to transfer of amino acids from the axon to the glial compartment. The fast axonally transported proteins contained relatively large amounts of high-molecular-weight acidic proteins, two of which were shown to comigrate (on 2DGE) with proteins synthesized by rat CNS rough microsomes; this finding suggests that rough endoplasmic reticulum may be a major site of synthesis for fast transported proteins. In contrast, the free polysome population was shown to synthesize the principal components of slow axonal transport, including tubulin subunits, actin, and neurofilament proteins.

Appearance and distribution of neurofilament immunoreactivity in iris nerves

We have used antiserum raised against neurofilament (NF) protein and indirect immunofluorescence techniques to visualize neuronal structures in rodent, cat, and cow irides. In the adult rat iris a large population of nerve fibers with a nonautonomic distribution show NF-like immunoreactivity. In whole mounts, smooth fluorescent fibers were seen in a fine-meshed plexus from the sphincter margin to the ciliary processes. Superimposed, a sparse pattern of thick meandering axon bundles were seen. Electroblotting and peroxidase immunochemical staining techniques unequivocally showed the presence of all three NF polypeptides in the adult rat iris. Adult mouse irides showed a somewhat sparser pattern of NF-positive nerves than that of the rat. Adult guinea pig irides contained irregular NF-positives fibers and few axon bundles. In cryostat-sectioned cat iris numerous irregularly distributed individual fibers were found, whereas in similarly sectioned cow iris thick NF-positive axon bundles were more numerous. By embryonic day 18 numerous sparse NF-positive axons were seen, and the subsequent gradual increase in both axons in bundles and fine-meshed plexuses of individual fibers produced an appearance similar to that in the adult by 6 days of postnatal age. One week after grafting of irides to the anterior eye chamber, most NF-positive nerves had disappeared from the iris grafts. Sympathetic and parasympathetic denervation of the irides did not influence the distribution of the NF-positive iris nerves. Five days after electrothermal lesion of the trigeminal nerve just distal to its ganglion a large proportion of the NF-positive nerves had disappeared from the iris. All perikarya in the parasympathetic ciliary and most perikarya in the superior cervical sympathetic and in the trigeminal sensory ganglion showed NF immunoreactivity. The present report shows a way to visualize nonautonomic nerve populations in stretch-prepared as well as sectioned irides by immunofluorescence techniques using an antiserum to neurofilament protein.

58,000 dalton intermediate filament proteins of neuronal and nonneuronal origin in the goldfish visual pathway

A group of proteins in the goldfish optic nerve with a molecular weight of 58K daltons was analyzed by two-dimensional gel electrophoresis. Results show that the proteins are differentially phosphorylated and found exclusively in a cytoskeletal-enriched fraction. The proteins from this fraction can be reconstituted into typical intermediate filament structures, as shown by electron microscopy. Two components which are of neuronal origin are transported within the slow phase of transport. The 58K proteins are the most abundant proteins in the optic nerve, and they are distinct from actin and tubulin. It was concluded that they are intermediate filament proteins. Cytoskeletal preparations of rat spinal cord, rat optic nerve, and goldfish optic nerve were compared by one-dimensional gel electrophoresis. The rat spinal cord contains glial fibrillary acidic protein (GFAP), and the rat optic nerve contains vimentin and GFAP, in addition to the neurofilament triplet. A typical mammalian neurofilament triplet is not detected in the goldfish optic nerve, while the major cytoskeletal constituent is a 58K band which coelectrophoreses with vimentin in the rat optic nerve by one-dimensional gel electrophoresis.

Changes in myelin and axonal proteins in CaCl2-induced myelopathy in rat spinal cord

Calcium-induced myelopathy was produced in rats by dripping 1.0 ml of a 10% solution of CaCl2 at pH 7.4 upon exposed spinal cord. Changes in spinal cord proteins were examined following application of calcium. Analysis of proteins by SDS-PAGE revealed progressive losses of neurofilament, microtubular, and glial filament proteins over a period of 8 hours to 5 days. Large losses of myelin proteins were also evident. The protein alterations observed correlate well with ultrastructural changes and resemble those previously found with physical trauma. These observations indicate that Ca2+ plays a pivotal role, possibly by activating proteinase(s), in the degeneration of axons and myelin sheath in both Ca2+-induced myelopathy and spinal cord injury.

Astrocyte cell lineage. V. Similarity of astrocytes that form in the presence of dBcAMP in cultures to reactive astrocytes in vivo

The relationship between astrocytes forming in the presence of dibutyryl cyclic AMP (dBcAMP) in culture and reactive astrocytes responding to a cerebral cortex stab wound was investigated using computerized image analysis (Zeiss IBAS 1) and immunocytochemical staining. The diameters of the nuclei of astrocytes in primary cultures of newborn mouse neopallial cells were compared to those of the nuclei of normal and reactive astrocytes in histological sections of mouse cerebral cortex. We found that the nuclei of astrocytes that formed in the presence of dBcAMP in cultures are significantly larger than those of spontaneously occurring small stellate astrocytes in culture and of normal astrocytes of the cerebral cortex in vivo but corresponded more closely to the nuclei of reactive astrocytes in the area surrounding a stab wound in the cerebral cortex. Large stellate cells formed in the presence of dBcAMP had vimentin and an increase in GFP-containing intermediate filaments. Formation of reactive astrocytes in vivo is also associated with an increase in both vimentin and GFP-containing intermediate filaments. These observations indicate a closer relationship of astrocytes formed in the presence of dBcAMP in cultures to the reactive astrocytes in the cerebral cortex than to normal astrocytes. We propose, therefore, that the large stellate astrocytes that form in the presence of dBcAMP be referred to as reactive astrocytes in culture.

Masking of epitopes in tissue sections. A study of glial fibrillary acidic (GFA) protein with antisera and monoclonal antibodies

Antisera to chicken brain antigen (CBA) isolated by hydroxyapatite chromatography from 8 M urea extracts following repeated extractions with phosphate buffer selectively decorate neurofilaments (NF) in neuronal perikarya, dendrites and axons. The antisera also reacted with GFA protein, the astrocyte-specific intermediate filament protein, as indicated by the adsorption of NF immunoreactivity following passage of the antisera through columns prepared with purified GFA protein. Moreover, the antisera stained the polypeptides of the NF triplet (70 kd, 150 kd, 200 kd) and GFA protein by the immunoblotting procedure. Monoclonal antibodies selectively decorating NF in tissue sections were isolated from a fusion of mouse myeloma cells with spleen cells of mice immunized with CBA. By the immunoblotting procedure the antibodies decorated the 150 kd NF polypeptide and GFA protein. No staining of glial filaments or any other structure on tissue sections was also observed with antibodies derived from another fusion strongly reacting with GFA protein on immunoblots. All antibodies (monoclonal and polyclonal) appeared to react with the same region of the GFA polypeptide as indicated by immunoblots of cleavage products.

Formation of 10-nanometer filaments from the 150K-dalton neurofilament protein in vitro

In the present study we report self-assembly of individual neurofilament (NF) triplet proteins (70K, 150K, and 200K daltons) isolated by anion exchange chromatography from bovine spinal cord. Formation of smooth 10-nm filaments by both NF 150K and NF 70K is shown. Optimal conditions for NK 150K filament formation were incubation in 100 mM MES, 0.2 M NaCl, 1 mM DTT, 0.5 mM EGTA, pH 6.5, at 37 degrees C for 24 hr. Under the same assembly conditions, NF 200K formed 7-nm coiled structures. These thin filaments were similar to those formed by NF 70K and 150K under less than optimal conditions. Our results indicate that NF 150K is an integral part of the filament (self-assembly of NF 70K was previously demonstrated by others). We suggest that the optimal conditions resulting in the formation of a 10-nm 200K homopolymer remain to be determined and that the thin coiled structures formed by all three NF proteins are protofilaments that coalesce to form a double helical 10-nm filament.

Cells in neonatal rat hypothalamus primary culture--an immunofluorescence study

Hypothalami from 1 day neonatal rats were dissociated and cultured for 4-16 days. Using immunofluorescence and antisera against neurofilament (NF) peptides, glial fibrillary acidic protein (GFAP), galactocerebroside and fibronectin we have distinguished neurons, astrocytes, oligodendrocytes and fibroblast-like cells in culture. Astrocytes initially grew as islets of 15-30 cells which dispersed as the culture aged. These cells, together with fibronectin-reactive flat cells, formed a monolayer upon which ovoid and process-bearing cells grew after 4 days in culture. Neurofilament-positive neurons constituted 5-10% of the total cell population. In maturing cultures the number of neurons decreased and fibroblasts increased. Oligodendrocytes represented less than 1% of total cell population. These studies emphasize the necessity of using the complementary techniques of morphology and immunocytochemistry for the characterization of hypothalamic neural cells in vitro.

Purification of a calcium-activated neutral proteinase from bovine brain

A calcium-activated neutral proteinase (CANP) resolved into three components has been partially purified from bovine brain. The method of isolation has resulted in 22,000, 7,100, and 8,000-fold purification for CANP I, II and III respectively. All three fractions require Ca2+ for activation. The characterization of the purified CANP I has shown that it is activated by 250 microM Ca2+ and the enzyme loses its activity when incubated in the presence of Ca2+ without substrate. Mg2+ is ineffective. The enzyme degrades neurofilament triplet proteins, tubulin and casein efficiently. The myelin basic protein is hydrolyzed after longer incubation. Bovine serum albumin and histones are unaffected. The enzyme is active at pH 5.5 to 9.0 with optimum between pH 7.5 and 8.5. It has a Km of 1.8 X 10(-7) M for the 69,000 dalton neurofilament protein. The enzyme is inhibited by sulphydryl blocking reagents and also by EGTA, leupeptin and E-64c. The SDS-PAGE analysis of the enzyme fractions has shown a major band at 66-68,000 daltons and two minor bands at 60,000 and 48-50,000 daltons for CANP I; a major band at 48-50,000 daltons and a minor band at 30-32,000 daltons for CANP II and a predominant doublet at 30-32,000 daltons with a minor band at 48-50,000 daltons for CANP III. The degradation of neurofilament proteins suggests that the CANP(s) may be involved in the turnover of these proteins.

Monoclonal antibodies to glial fibrillary acidic protein. 1. Characterization

Mouse hybridomas producing antibodies to glial fibrillary acidic protein (GFAP) have been cloned and their immunoglobulins characterized biochemically, immunochemically and immunocytochemically. Immunoaffinity columns were prepared using cyanogen bromide activated sepharose 4R and the antibodies of the C9 clone. A protein giving a single band in the 50-55 kd range was thus isolated from aqueous extracts of bovine brain. The clone yields antibodies which are, on the basis of these studies, specific for GFAP. The antibody belongs to the class IgG1 and has been applied to human tissues, both frozen sections and sections embedded in paraffin wax following fixation in formaldehyde. The results show that the antibody may be of assistance in the classification of human brain tumors.

Degradation of cytoskeletal proteins in experimental spinal cord injury

Spinal cord injury was produced in rats by dropping a 10 g weight from 30 cm upon dura-invested exposed spinal cord. Examination of the fine structure of the traumatic lesion (15 min to 30 min) revealed granular degeneration of axons and occasional loosening of myelin lamellae. Older lesions (4 to 72 hours) showed degeneration of axons and vesiculation of myelin. At 15 minutes there is more loss of neurofilament proteins than of myelin proteins. Substantial decreases in the neurofilament and myelin proteins were observed at 30 minutes and the losses were even greater 2-72 hours after injury. This indicates that degeneration of axons may precede degradation of the myelin sheath and also that increased proteinase(s) activity, possibly activated by calcium, mediates the traumatic axonolysis and myelinolysis in experimental spinal cord trauma.

Vimentin in the central nervous system. A study of the mesenchymal-type intermediate filament-protein in Wallerian degeneration and in postnatal rat development by two-dimensional gel electrophoresis

Intermediate filament proteins were identified by two-dimensional gel electrophoresis in urea extracts of rat optic nerves undergoing Wallerian degeneration and in cytoskeletal preparations of rat brain and spinal cord during postnatal development. The glial fibrillary acidic (GFA) protein and vimentin were the major optic nerve proteins following Wallerian degeneration. Vimentin was a major cytoskeletal component of newborn central nervous system (CNS) and then progressively decreased until it became barely identifiable in mature brain and spinal cord. The decrease of vimentin occurred concomitantly with an increase in GFA protein. A protein with the apparent molecular weight of 61,000 and isoelectric point of 5.6 was identified in both cytoskeletal preparations of brain and spinal cord, and in urea extracts of normal optic nerves. The protein disappeared together with the polypeptides forming the neurofilament triplet in degenerated optic nerves.

Isolation of neurofilament proteins and of immunologically active neurofilament degradation products from extracts of brain, spinal cord and sciatic nerve

This paper reports the isolation by immunoaffinity chromatography of neurofilament proteins from 1 mM sodium phosphate buffer extracts of brain, spinal cord and sciatic nerve in four mammalian species: human, bovine, rabbit and rat. Antisera were prepared against degraded chicken neurofilament proteins as previously described. The main polypeptides isolated in the fraction tightly attached to the column and eluted at pH 2.9 were at 72 and at approx. 150 kdaltons. In rat and rabbit the approx. 150-kdalton neurofilament polypeptide was apparently smaller compared with bovine and human as indicated by comigration experiments on sodium dodecyl sulfate polyacrylamide gel electrophoresis. The 200-kdalton neurofilament polypeptide was less tightly attached to the immunoaffinity column and was preferentially eluted at pH 6.0 in 5 M urea. Variable amounts of degraded products were also present in most purified preparations. Degradation was markedly increased by the omission of EDTA in the extraction and column buffers. In the rat, degraded proteins isolated on the immunoaffinity column in the absence of EDTA were at 68 and 55 kdaltons.