An immunofluorescence microscopical study of the neurofilament triplet proteins, vimentin and glial fibrillary acidic protein within the adult rat brain

A collection of antibodies specific to different intermediate filament proteins were applied to frozen sections of adult rat brains. The relative distribution of these proteins was then studied using double label immunofluorescence microscopy. Antibodies specific to each of the neurofilament "triplet" proteins (of approximate molecular weight 68 K, 145 K and 200 K) stained exclusively neuronal structures. The distribution of these three antigens was in general identical, except that certain neurofilament populations such as those in the dendrites and cell bodies of pyramidal cells of the hippocampus and cerebral cortex, contained relatively little if any 200 K protein. Some neurone populations, such as the granule cells of the cerebellar cortex, could not be visualized by neurofilament antibodies, indicating that neurofilaments may not be essential for function of all neurones in vitro. Antibodies to GFA and vimentin stained an entirely different population of processes, none of which stained with any of the neurofilament antibodies. Vimentin antibody stained sheath material around the brain, a monolayer of ependymal cell bodies lining the ventricles, fibrous material associated within the choroid plexus, the walls of blood vessels and capillaries, and the processes of cells in certain regions. GFA antibody stained a second layer of sheath material under the vimentin layer, and numerous processes visible throughout the brain. Some specific populations of GFA-positive processes proved to stain also with vimentin. These included the processes of Golgi "epithelial" cells (Bergmann glial fibres), those of certain astrocytes in bundles of myelinated fibers. In addition, some processes apparently derived from ependymal cells proved to stain for both vimentin and GFA, whilst other could only be reliably visualized by vimentin alone. These results are discussed in terms of the previously described morphological characteristics of the various cell types of the brain.     

Neurofilament Proteins in Cultured Chromaffin Cells

Antibodies were raised against the 200-kd, 145-kd, and 68-kd subunits of a rat neurofilament preparation. Immunoblots showed that each antibody was specific for its antigen and that it did not cross-react with any of the two other neurofilament polypeptides. Use of the three antibody preparations to stain bovine chromaffin cells in culture by the indirect immunofluorescence technique indicated that the three neurofilament polypeptides are present in chromaffin cells maintained in culture for 3 or 7 days. The three anti-neurofilament antibodies labelled the cells in a similar pattern: very thin filaments specifically localized around the nucleus were observed whereas neurites and growth cones, developed by cultured chromaffin cells, were generally not stained. Some fibroblasts were present in our cultures but they were never stained by any of the neurofilament antibodies. This indicated that the antibodies used do not react with vimentin, the major intermediate filament protein found in fibroblasts. The three neurofilament antibodies were also used to immunoprecipitate specifically three proteins of molecular weights 210 kd, 160 kd, 70 kd from solubilized extracts of cultured chromaffin cells that were radiolabelled with [35S]methionine. These proteins correspond in molecular weight to the neurofilament triplet found in bovine brain. Finally, the presence of neurofilaments in freshly isolated chromaffin cells was tested by immunoblotting using the 68-kd antibody. A 70-kd protein was specifically stained by this antibody, suggesting that neurofilaments are not only present in cultured chromaffin cells but also in the adrenal gland in vivo. It is concluded from these results that chromaffin cells contain completely assembled neurofilaments. This additional neuronal property again illustrates that chromaffin cells are closely related to neurons and therefore represent an attractive model system for the study of functional aspects of adrenergic neurons.     

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.     

Studies on the Biosynthesis of Intermediate Filament Proteins in the Rat CNS

Abstract: The biosynthesis of brain intermediate filament proteins [neurofilament proteins and glial fibrillary acidic protein (GFA)] was studied with cell-free systems containing either rat spinal cord polysomes (free polysomes or rough microsomes) and rabbit reticulocyte factors or wheat germ homogenate containing spinal cord messenger RNA. The products of translation were isoated by immunoaffinity chromatography and then analyzed by two-dimensional gel electrophoresis (2DGE) followed by fluorography. The free polysome population was found to synthesize two neurofilament proteins (MW 145K, p15.4, and MW 70K, pl 5.3) and three isomers of GFA (α, β, and γ) that differ in isoelectric point. Wheat germ homogenate containing messenger RNA extracted from free cord polysomes synthesized two proteins that comigrated with neurofilament protein standards at 145K 5.4 and 70K 5.3; these proteins were partially purified by neurofilament affinity chromatography. The wheat germ system also synthesized the α, β, and γ isomers of GFA as characterized by immunoaffinity chromatographic purification and comigration with standards in 2DGE analysis. Our data are consistent with the conclusion that synthesis of neurofilament proteins requires multiple messenger RNAs. Also, synthesis of intermediate filament proteins occurs in the free polysome population; detectable amounts of these proteins were not synthcsized by the rough microsomes.     

The structure and development of the rat retina: an immunofluorescence microscopical study using antibodies specific for intermediate filament proteins

Rat retina structure was studied between embryonic day 14 and adult with antibodies specific for vimentin, glial fibrillary acidic protein (GFA) and the proteins of the neurofilament triplet. Vimentin could be detected in radial processes throughout the retina at all stages studied. These processes are believed to correspond, in the developing retina, to ventriculocytes, and in the mature retina to Müller cells. They could not normally be stained with any of the other intermediate filament antibodies employed here. We did find, however, that some older albino rats possessed GFA staining in addition to vimentin in these processes. Since we never saw such staining in the retinae of mature non-albino rats, and the retinae of older albino rats often showed signs of degeneration, we concluded that such GFA expression was most likely pathological. Neurofilament protein-positive processes were first detectable at embryonic day 15 1/2 in the inner regions of the retina, and corresponded to the axons of retinal ganglion cells. Such processes were equivalently displayed with antibodies to 68 K and 145 K protein, but were negative with 200 K protein. Some 68 K and 145 K positive fibers could also be decorated with vimentin antibody at this stage, though at later stages this was not the case. At later development stages more 68 K and 145 K neurofilament positive processes appeared, and after the first post-natal week progressively more of such processes became in addition 200 K positive, so that almost all neurofilament positive fibers in the adult stained for all three proteins. Such fibers, in the mature retina corresponded to 68 K and 145 K positive optic nerve fibers, and the processes of neurones in the inner plexiform layer. All fibers in the mature optic nerve fiber layer, but not all of those in the inner plexiform layer were stainable with 200 K antibodies. At 4 days post-natal we were able to detect 68 K and 145 K protein positive profiles in the outer regions of the developing retina, the prospective outer plexiform layer. Such profiles were always in addition vimentin positive, but negative for 200 K protein. During further development such profiles became ordered into a well defined layer and from about post-natal day 13 all of them began to acquire 200 K protein. They could be identified as the processes of horizontal cells. They continued to express vimentin in addition to the three triplet proteins in the adult, a so far unprecedented situation. We were able to detect neurofilament staining in the mature retina only in the above described regions, the inner and outer nuclear layer and the photoreceptor processes being completely free of staining. GFA was first detected in short processes adjacent to the inner limiting membrane which penetrated the optic nerve fiber layer. Such profiles were first detectable in the eye of the newborn animal, and were invariably identically stainable with vimentin at this age. These profiles could be stained with both vimentin and GFA at all later stages examined, although GFA staining became very much stronger than vimentin staining in some profiles in the adult. The results presented here are discussed in terms of development of the different retinal cell types.     

The intermediate filament complement of the retina: a comparison between different mammalian species

We compared the intermediate filament expression of the various cell types in the fully differentiated neural retina from rat, mouse, rabbit, guinea pig, cow, pig, and cat. Many cell types had an intermediate filament complement conserved across species boundaries, such as Müller cells and retinal ganglion cells. In some species (rabbit, guinea pig, and cow), however, we were unable to visualize GFA (glial fibrillary acidic)-positive retinal astrocytes, although such profiles were clearly visible in the remainder. Horizontal cell staining proved to be extremely species-variable. In rat and mouse the processes of these cells were identically displayed with antibodies to vimentin and all three neurofilament triplet proteins. In cow they decorated with antibodies to vimentin and antibodies to the two lower molecular weight neurofilament proteins alone, whereas in pig, rabbit and guinea pig all three neurofilament proteins but not vimentin were present. Finally cat horizontal cells stained for all three neurofilament proteins, some finer processes being additionally stainable with vimentin. A further surprise was the visualization of profiles positive only for the two lower molecular weight neurofilament proteins in the inner nuclear layer of both rabbit and guinea pig retina but not the other species. The implications of these results will be discussed.     

Immunoelectronmicroscopical localization of the three neurofilament triplet proteins along neurofilaments of cultured dorsal root ganglion neurones

Correlated immunofluorescence and electron microscopy was used to study neurofilament expression, organization and structure in cultured neurones of newborn rat dorsal root ganglia. The results extend previous immunofluorescent data subdividing the neurones into two main classes: neurones rich in neurofilaments, expressing all three triplet proteins and neurones without noticeable neurofilaments which cannot be stained positively for any of the triplet proteins. The two classes are identified as the large light cells and small dark cells characteristically found in adult dorsal root ganglia in situ. Further ultrastructural characterization identifies the various subclasses of each major class in the cultures used. Cytoskeletons of neurofilament-rich neurones decorated by antibodies specific for each triplet protein lead to the following model. All three triplet proteins are associated with each individual filament, although the antibodies show a different localization. Whereas the 68K protein seems to form the backbone of the filament, the 200K protein is periodically arranged (repeat approx. 100 nm) in a more peripheral position. The 145 K protein is revealed in a nearly continuous manner along the filament.     

Evolution of homologous domains of cytoplasmic intermediate filament proteins and lamins

The earliest gene duplications in the evolution of the intermediate filament proteins created the ancestors of acidic keratins, basic keratins, nonepithelial intermediate filament proteins, and lamins. Biochemistry and function of cytoplasmic intermediate filaments differ greatly from those of lamins. Cytoplasmic intermediate filament proteins have a different cellular location than lamins, form different types of supramolecular structures, and are missing a protein segment found in lamins; but the data presented here indicate that the cytoplasmic intermediate filaments do not have a common ancestor separate from the ancestor of lamins. In the non-epithelial intermediate filament branch, the ancestor of neurofilament proteins and the common ancestor of desmin, vimentin, and glial fibrillary acidic protein (GFAP) diverged first. By evolutionary criteria, the intermediate filament protein recently discovered in neuronal cells does not belong to the neurofilament family but is more closely related to desmin, vimentin, and GFAP. Sequences of different sub-domains yield different evolutionary trees, possibly indicating existence of sub- domain-specific functions.      

Differential Location of Different Types of Intermediate-Sized Filaments in Various Tissues of the Chicken Embryo

The location of constitutive proteins of different types of intermediate-sized (about 10 mm) filaments (cytokeratin, vimentin, desmin, brain filament protein) was examined in various tissues of 11–20 day chick embryos, using specific antibodies against the isolated proteins and immunofluorescence microscopy on frozen sections and on isolated serous membrane. The tissues studied which contained epithelia were small intestine, gizzard, esophagus, crop, liver, kidney, thymus, mesenteries, and epidermis. The results show that the different intermediate filament proteins, as seen in the same organ, are characteristic of specific lines of differentiation: Cytokeratin filaments are restricted to – and specific for – epithelial cells; vimentin filaments are seen – at this stage of embryogenesis – only in mesenchymal cells, including connective tissue, endothelial and blood cells, and chondrocytes; filaments containing protein(s) related to the subunit protein prepared from gizzard 10 nm filaments (i.e., desmin) are significant only in muscle cells; and intermediate filament protein of brain, most probably neurofilament protein, is present only in nerve cells. We conclude that for most tissues the expression of filaments of cytokeratin, vimentin, desmin, and neurofilament protein is mutually exclusive, and that these protein structures provide useful markers for histochemical and cytochemical differentiation of cells of epithelial, mesenchymal, myogenic, and neurogenic differentiation.     

Survey of Intermediate Filament Proteins in Optic Nerve and Spinal Cord: Evidence for Differential Expression

The distribution of intermediate filament proteins in optic nerve and spinal cord from rat, hamster, goldfish, frog, and newt were analyzed by two-dimensional gel electrophoresis. General as well as specific monoclonal and polyclonal antibodies were reacted against putative intermediate filament proteins. In vitro incubations of excised optic nerve in the presence of [35S]methionine distinguished between neuronal and nonneuronal intermediate filament proteins. The proteins of the intermediate filament complex in the two tissues for rat and hamster were similar. The typical neurofilament triplet and glial fibrillary acidic protein (GFAP) were observed. Vimentin was more concentrated in the optic nerve than in the spinal cord. The goldfish, newt, and frog contained neurofilament proteins in the 145-150K range and in the 70-85K range. In addition, predominant neurofilament proteins in the 58-62K molecular-weight range were found in all three species. In contrast to mammalian species, the goldfish, newt, and frog displayed extensive heterogeneity between optic nerve and spinal cord in the expression of both neuronal and nonneuronal intermediate filament proteins. The distinctive presence of low-molecular-weight intermediate filament proteins and their high concentration in the optic nerve and spinal cord of these nonmammalian vertebrates is discussed in terms of neuronal development and regeneration.     

Cytoskeleton-associated plectin: in situ localization, in vitro reconstitution, and binding to immobilized intermediate filament proteins

The association and interaction of plectin (Mr 300,000) with intermediate filaments and filament subunit proteins were studied. Immunoelectron microscopy of whole mount cytoskeletons from various cultured cell lines (rat glioma C6, mouse BALB/c 3T3, and Chinese hamster ovary) and quick-frozen, deep-etched replicas of Triton X-100-extracted rat embryo fibroblast cells revealed that plectin was primarily located at junction sites and branching points of intermediate filaments. These results were corroborated by in vitro recombination studies using vimentin and plectin purified from C6 cells. Filaments assembled from mixtures of both proteins were extensively crosslinked by oligomeric plectin structures, as demonstrated by electron microscopy of negatively stained and rotary-shadowed specimens as well as by immunoelectron microscopy; the binding of plectin structures on the surface of filaments and cross-link formation occurred without apparent periodicity. Plectin's cross-linking of reconstituted filaments was also shown by ultracentrifugation experiments. As revealed by the rotary-shadowing technique, filament-bound plectin structures were oligomeric and predominantly consisted of a central globular core region of 30-50 nm with extending filaments or filamentous loops. Solid-phase binding to proteolytically degraded vimentin fragments suggested that plectin interacts with the helical rod domain of vimentin, a highly conserved structural element of all intermediate filament proteins. Accordingly, plectin was found to bind to the glial fibrillar acidic protein, the three neurofilament polypeptides, and skin keratins. These results suggest that plectin is a cross-linker of vimentin filaments and possibly also of other intermediate filament types.     

Homology and Diversity Between Intermediate Filament Proteins of Neuronal and Nonneuronal Origin in Goldfish Optic Nerve

The predominant intermediate filament proteins of the goldfish optic nerve have molecular weights of 58K. They can be separated into a series of four major isoelectric variants of neuronal (ON1 and ON2) and nonneuronal (ON3 and ON4) origin. The extent of homology between the goldfish 58K intermediate filament proteins themselves and to rat optic nerve vimentin and glial fibrillary acidic protein (GFAP) was investigated. Unlabeled and [32P]orthophosphate-labeled proteins were subjected to partial hydrolysis by V8 protease, chymotrypsin, and CNBr. The results show that the goldfish intermediate filament proteins share with vimentin and GFAP a 40K chymotrypsin-resistant core fragment. Phosphorylated moieties appear to be located outside the core region since they are preferentially cleaved off by chymotrypsin and not found associated with the 40K core. In addition, the goldfish ON proteins contain the antigenic site within the core that is common to most intermediate filaments. V8 or CNBr digestion indicates that many fragments that are common to ON1 and ON2 are clearly distinct from fragments that are common to ON3 and ON4. In addition, structural variability is observed between the goldfish intermediate filament proteins and vimentin and GFAP. The results are discussed in terms of intermediate filament structure and their possible role in nerve growth.     

An immunofluorescence study of neurofilament protein expression by developing hippocampal neurons in tissue culture

We have studied the development of intermediate filament proteins in the neurons found in hippocampal cell cultures using single and double label immunofluorescence with both monoclonal and polyclonal antibodies. Neurons in these cultures are known to differentiate in a manner similar to their counterparts in situ: in particular they develop axonal and dendritic processes which differ from each other in form, in ultrastructure, and in synaptic polarity. During the first days in culture, developing neurons could not be stained with antibodies against any of the neurofilament proteins, although many cells reacted with anti-vimentin. Later in the first week, antibody staining revealed clearly filamentous staining for the L (68 000 daltons) and the M (145 000 daltons) neurofilament subunits, though M reactivity was much stronger at this earlier stage of development. Some neurofilament positive profiles in many cells could also be stained with vimentin, though the vimentin immunoreactivity became progressively less pronounced during further development, and disappeared after about two weeks in culture. Also at about two weeks in vitro we noted the first appearance of neurofilament H protein (200 000 daltons) immunoreactivity, which was localized to a subset of long neurites which could be identified on morphological grounds as axons. These processes lacked staining for microtubule associated protein 2 (MAP2), a dendritic marker. They tended to be close to islands of glial cells, suggesting that H induction may require complex neuron-glial interactions. These results are consistent with the suggestion that H protein immunoreactivity is a marker for axonal outgrowth. In addition to obvious filamentous staining, we were able to localize neurofilament antigens to an interesting class of small ring-like structures, found increasingly frequently as the cultures aged. We also present evidence that tyrosinated alpha-tubulin is present both within dendrites and axons of neurons in these cultures.     

Differential location of different types of intermediate-sized filaments in various tissues of the chicken embryo.

The location of constitutive proteins of different types of intermediate-sized (about 10 mm) filaments (cytokeratin, vimentin, desmin, brain filament protein) was examined in various tissues of 11--20 day chick embryos, using specific antibodies against the isolated proteins and immunofluorescence microscopy on frozen sections and on isolated serous membrane. The tissues studied which contained epithelia were small intestine, gizzard, esophagus, crop, liver, kidney, thymus, mesenteries, and epidermis. The results show that the different intermediate filament proteins, as seen in the same organ, are characteristic of specific lines of differentiation: Cytokeratin filaments are restricted to--and specific for--epithelial cells; vimentin filaments are seen--at this stage of embryogenesis--only in mesenchymal cells, including connective tissue, endothelial and blood cells, and chondrocytes; filaments containing protein(s) related to the subunit protein prepared from gizzard 10 nm filaments (i.e., desmin) are significant only in muscle cells; and intermediate filament protein of brain, most probably neurofilament protein, is present only in nerve cells. We conclude that for most tissues the expression of filaments of cytokeratin, vimentin, desmin, and neurofilament protein is mutually exclusive, and that these protein structurees provide useful markers for histochemical and cytochemical differentiation of cells of epithelial, mesenchymal, myogenic, and neurogenic differentiation.     

Calcium-Activated Proteolysis of Neurofilament Proteins in the Squid Giant Neuron

The phosphorylation and proteolysis of squid neurofilament proteins by endogenous kinase and calcium-activated protease activities, respectively, were studied. When axoplasm was incubated in the presence of [gamma-32P]ATP, most of the phosphate was incorporated into two neurofilament proteins: a 220-kilodalton (NF-220) and a high-molecular-weight (HMW) protein. When this phosphorylated axoplasm was subjected to endogenous calcium-activated proteolysis, two significant phosphorylated fragments were generated, i.e., a soluble 110K fragment and a pelletable 100K fragment. Immunochemical and other analyses suggest that the pelletable 100K fragment contains the common helical neurofilament rod region and that the soluble 110K protein is the putative side arm of the NF-220. In contrast, neither the HMW or the NF-220 was detected in the region of the stellate ganglion which contains the cell bodies of the giant axon. However, this region did contain a number of proteins that were sensitive to calcium-activated proteolysis and reacted with a monoclonal intermediate filament antibody. This intermediate filament antibody reacts with most of the axoplasmic proteins that copurify with neurofilaments, i.e., in the order of their intermediate filament antibody staining intensity, a 60K, 65K, 220K, and 74K protein. In the cell body preparation, the intermediate filament antibody labeled, in order of their staining intensity, a 65K, 60K, 74K, and 180K protein. In both the axoplasmic and cell body preparations, endogenous calcium-activated proteolysis generated characteristic fragments that could be labeled with the anti-intermediate filament antibody.     

The immunological relatedness of neurofilament proteins of higher vertebrates

We prepared intermediate filaments from the nervous system of several different species, representing mammals, birds and reptiles. These were examined using a panel of polyclonal and monoclonal antibodies originally raised against pig or rat neurofilament proteins. All species studied possessed a single major protein of apparent molecular weight between 68 K and 75 K immunologically related to the lowest molecular weight rat and pig neurofilament protein. All birds and mammals possessed two proteins immunologically related respectively to the pig and rat middle and high molecular weight neurofilament proteins. These data show that the neurofilament triplet proteins represent an evolutionarily conserved three member protein family in birds and mammals, and allow us to suggest a new nomenclature for these three homologous proteins: "H" for the heaviest subunit, "M" for the middle subunit and "L" for the lightest subunit. We found that many monoclonal antibodies stained both the H- and M-proteins of all mammalian and avian species examined, suggesting a close immunological relatedness between these two proteins. The reptiles examined appeared to have only one high molecular weight protein, which was immunologically related to both of the high molecular weight mammalian and avian neurofilament proteins. We also noted a curious situation in neurofilament preparations derived from cows. Both the highest and the middle cow neurofilament proteins were stained by all antibodies which were specific solely for the high molecular weight protein in other species.     

An isoelectric variant of the 150,000-dalton neurofilament polypeptide. Evidence that phosphorylation state affects its association with the filament

A soluble isoelectric variant of the 150,000-dalton neurofilament protein was isolated from bovine brain by treating a partially purified filament preparation with a low-ionic-strength high-pH buffer. The protein (S150) had similar peptide maps to the neurofilament component of the same molecular weight (NF150) and was recognized by a polyclonal antibody made against the NF150 polypeptide. However, only half the anti-NF150 activity could be removed with the S150 protein. In addition, the S150 protein had a higher isoelectric point than the NF150 protein. Phosphate analysis indicated that the S150 protein was considerably lessened in phosphate content, which could account for the higher isoelectric point of the protein. It appears, therefore, that the S150 protein may be a precursor of NF150 or the result of phosphatase activity during the isolation procedure. Assembly studies showed that the S150 protein, unlike the NF150 protein, could not assemble with the 70-kDa neurofilament protein, indicating that the phosphate groups which were removed are important in the association of this protein to the neurofilament. When filaments containing all three triplet neurofilament polypeptides or those composed of the 70- and 150-kDa neurofilament proteins were subjected to acid phosphatase, a soluble fraction was obtained, which contained isoelectric variants with higher pI values than the NF150 polypeptide. Only unmodified NF150 protein was found in the insoluble fraction. These results support the argument that removal of phosphate groups results in the dissociation of this protein from the filament.     

Differential spatial and temporal expression of two type III intermediate filament proteins in olfactory receptor neurons

Olfactory receptor neurons (ORNs) do not express the typical neuronal intermediate filament proteins (IFPs), the neurofilament triplet proteins. Immunocytochemical evidence shows that ORNs coexpress vimentin and peripherin but distribute them differently. Specifically, ORNs contain vimentin in dendrites, cell bodies, and axons, but not in terminals in glomeruli; peripherin is present in axons, but excluded from dendrites, cell bodies, and terminal glomeruli. In adult rats, ORN axon fascicles are variably stained with antisera for peripherin; in juvenile rats, staining of fascicles is uniform. Staining with antibody to vimentin is uniform in both adult and juvenile ORN axon fascicles. The unusual pattern of IFP expression and intracellular sorting may have implications for the unique plastic and regenerative capacities of these neurons.