The distribution of the neurofilament triplet proteins within individual neurones

The three proteins of the mammalian neurofilament ‘triplet’ were purified from rat sciatic nerve as individual polypeptides. Antibodies were raised in rabbits and in guinea pigs. When tested by the very sensitive immune-blotting technique some of the antibodies proved to be completely specific for the peptide to which they had been raised. Others, however, exhibited weak cross-reactivity with other proteins of the triplet. Cross-reacting IgGs could be removed by appropriate antigen affinity chromatography. Thus a series of rabbit and guinea pig antibodies specific for each of the triplet proteins was obtained. The antibodies were used in immunofluorescence microscopy on cultured rat dorsal root ganglion cells. Only cells with a neuronal morphology were stained by these antibodies, some very strongly and some extremely weakly. When double immunofluorescence was performed it was found that cells stained in an equivalent manner with any combination of antibodies. Neurones which stained strongly with any one antibody could be stained strongly with any other and the converse was true for weakly staining cells. When fine profiles in the growth cones of positive cells were examined it was found that these profiles, representing single or small numbers of neurofilaments, were stained in an identical manner in double immunofluorescence. The results show that the distribution of the three proteins is identical at the level of resolution of the light microscope in rat dorsal root ganglion neurones in tissue culture, and lend support to the supposition that all three triplet polypeptides are contained within each individual neurofilament.     

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.     

Accessibility and cross-linking of native neurofilaments to chemical reagents

Native neurofilaments were submitted to cross-linking reactions with bifunctional reagents (DMA, DMS and DSS) and to chemical reactions with sterically bulky reagents such as EEDQ and DTAF , as well as a glutaraldehyde-activated gel. The 160K and 70K neurofilament proteins reacted slightly more than the 210K neurofilament protein with DMS and DSS. The accessibility of the three neurofilaments to the other chemical reagents was identical. These results were unexpected since neurofilament antibodies seem to react preferentially with 210K protein which is at the periphery of the filament, whereas the 70K protein, which is the backbone of the filament, is probably buried inside the filament. In the same way, it has been shown that the side of the 210K proteins are probably able to cross link the neurofilaments with non covalent and covalent bridges. Using different cross link reagents, we did not observe a characteristic reactivity of the 210K protein towards the different chemicals. We conclude that the three neurofilament proteins are equally exposed to the different sterically bulky reagent and that part of the polypeptide chain of the 70K and the 160K proteins are located at the outside of the filament.     

Microtubule-associated protein 2 within axons of spinal motor neurons: associations with microtubules and neurofilaments in normal and beta,beta'-iminodipropionitrile-treated axons

We have examined the distribution of microtubule-associated protein 2 (MAP2) in the lumbar segment of spinal cord, ventral and dorsal roots, and dorsal root ganglia of control and beta,beta'-iminodipropionitrile- treated rats. The peroxidase-antiperoxidase technique was used for light and electron microscopic immunohistochemical studies with two monoclonal antibodies directed against different epitopes of Chinese hamster brain MAP2, designated AP9 and AP13. MAP2 immunoreactivity was present in axons of spinal motor neurons, but was not detected in axons of white matter tracts of spinal cord and in the majority of axons of the dorsal root. A gradient of staining intensity among dendrites, cell bodies, and axons of spinal motor neurons was present, with dendrites staining most intensely and axons the least. While dendrites and cell bodies of all neurons in the spinal cord were intensely positive, neurons of the dorsal root ganglia were variably stained. The axons of labeled dorsal root ganglion cells were intensely labeled up to their bifurcation; beyond this point, while only occasional central processes in dorsal roots were weakly stained, the majority of peripheral processes in spinal nerves were positive. beta,beta'- Iminodipropionitrile produced segregation of microtubules and membranous organelles from neurofilaments in the peripheral nervous system portion and accumulation of neurofilaments in the central nervous system portion of spinal motor axons. While both anti-MAP2 hybridoma antibodies co-localized with microtubules in the central nervous system portion, only one co-localized with microtubules in the peripheral nervous system portion of spinal motor axons, while the other antibody co-localized with neurofilaments and did not stain the central region of the axon which contained microtubules. These findings suggest that (a) MAP2 is present in axons of spinal motor neurons, albeit in a lower concentration or in a different form than is present in dendrites, and (b) the MAP2 in axons interacts with both microtubules and neurofilaments.     

Synemin isoforms during mouse development: Multiplicity of partners in vascular and neuronal systems

The intermediate filament (IF) synemin gene encodes three IF proteins (H 180, M 150, L 41 kDa isoforms) with overlapping distributions. In the present study we analysed the mRNA and protein expression of each isoform in developing mouse embryos. Synemin M mRNA was present as early as E5 with vimentin and nestin. Synemin H was found later at E9 in the nervous system and mesodermic derivatives concomitantly with angiogenesis, somitogenesis and the migration of neural crest cells. Synemin L appeared later in neurons at E15. Furthermore, the synemin isoforms required different IF partners depending on the cell type to form filamentous structures. In endothelial cells, synemin H/M were found associated with vimentin and were absent in vimentin-null mice. In neurons of the peripheral nervous system of E15 embryos, synemin H/M or L were co-expressed with neurofilament, peripherin and internexin. In adult mice, our data support the existence of different subpopulations of neurons within the dorsal root ganglia: one composed of small neurons containing synemin H/M and peripherin, and another composed of large neurons containing synemin L and neurofilaments. Axons devoid of neurofilaments from mutant mice (NFHLacZ) showed an absence of the L isoform but contained H/M isoforms with peripherin.     

Neurofilament protein triplet immunoreactivity in the dorsal root ganglia of the guinea-pig

Summary Immunoreactivity for the neurofilament protein triplet was investigated in neurons of the dorsal root ganglia of the guinea-pig by using a battery of antibodies. In unfixed tissue, nearly all neurons in these ganglia demonstrated some degree of neurofilament protein triplet immunoreactivity. Large neurons generally displayed intense immunoreactivity, whereas most small to medium-sized neurons showed faint to moderate immunoreactivity. Double-labelling immunofluorescence demonstrated that most antibodies to the individual subunits of the neurofilament protein triplet had the same distribution and intensity of labelling in sensory neurons. Increasing durations of tissue fixation in aldehyde solutions selectively diminished neurofilament protein triplet immunoreactivity in small to medium-sized neurons. Double-labelling with neurofilament protein triplet antibodies in combination with antibodies to other neuronal markers, such as neuron-specific enolase, substance P and tyrosine hydroxylase, showed that tissue processing conditions affect the degree of co-localization of immunoreactivity to the neurofilament protein triplet and to these other neuronal markers. These results indicate that, with a judicious manipulation of the duration of tissue fixation, neurofilament protein triplet immunoreactivity can be used in combination with other neuronal markers to distinguish groups of neurons according to their size and chemical coding.     

Impairment of anterograde and retrograde neurofilament transport after anti-kinesin and anti-dynein antibody microinjection in chicken dorsal root ganglia

The purpose of the present study was to investigate the participation of the motor proteins kinesin and dynein in axonal transport of neurofilaments (NF) in cultured dorsal root ganglia neurons. Therefore, we performed live-recording studies of the green fluorescent protein-tagged neurofilament M (GFP-NF-M) to assay transport processes in neurons. Co-localization studies revealed that GFP-NF-M was capable to build a functional NF network with other NF subunits, including phosphorylated heavy neurofilaments (NF-H-PH). Time-lapse recordings using confocal laser scanning microscopy exhibited fast transport of NF dots in anterograde and retrograde direction through a photobleached gap. Following microinjection of anti-kinesin antibodies or colchicine treatment an impairment of anterograde as well as retrograde NF transport was observed during live-recording experiments. In contrast, microinjection of anti-dynein antibodies only impaired retrograde transport of NF whereas the anterograde movement of GFP-NF-M was unaffected. Treatment of the cells with unspecific antibodies had no effect.     

Routing of transported materials in the dorsal root and nerve fiber branches of the dorsal root ganglion

After injection of the L7 dorsal root ganglion with ³H-leucine, fast axoplasmic transport carries some 3–5 × more labeled materials down the sensory fibers branches entering the sciatic nerve as compared to the dorsal root fiber branches of the neurons. Freeze-substitution preparations taken from the two sides of the lumbar seventh dorsal root ganglia of cats and monkeys showed little difference in the histograms of nerve fiber diameters of the sensory nerve fiber branch of these neurons as compared to the dorsal root fiber branches. A similar density of microtubules and of neurofilaments in the dorsal root and sensory nerve fiber branches over a wide range of fiber diameters was found in electron micrograph preparations. In the absence of an anatomical difference in the fibers to account for the asymmetrical outflow, a functional explanation based on the transport filament model was advanced.     

Various sympathetic derived human tumors differ in neurofilament expression. Use in diagnosis of neuroblastoma, ganglioneuroblastoma and pheochromocytoma

We have extended our analysis of human tumors using antibodies specific for each of the five types of intermediate filaments to neuroblastoma, ganglioneuroblastoma, pheochromocytoma, ependymoblastoma, and alveolar soft part sarcoma. Tumor cells in the three cases of neuroblastoma, as well as in the single case of alveolar soft part sarcoma, did not react positively with sera directed against any of the five intermediate filament types. We suppose, therefore, that neuroblastoma at least may be derived from a cell type - possibly present in peripheral neurones - which in vivo has very few or no intermediate filaments. In ganglioneuroblastoma and in pheochromocytoma the tumor cells were positive when tested with antibodies directed against neurofilaments and negative with those directed against other intermediate filament types. The ependymoblastoma was positive when tested with antibodies directed against glial fibrillary acidic protein (GFA) and negative when tested with antibodies against other intermediate filament types. Use of antibodies to the different intermediate filament types appears to be a valid way in which to classify tumors, and so far the data presented here and elsewhere support the hypothesis that tumor cells retain the intermediate filament type typical of their cell of origin. Wider use of these sera would seem particularly useful in cases such as neuroblastoma, rhabdomyosarcoma or lymphoma where diagnosis is currently difficult using conventional histological stains.     

Routing of transported materials in the dorsal root and nerve fiber branches of the dorsal root ganglion.

After injection of the L7 dorsal root ganglion with 3H-leucine, fast axoplasmic transport carries some 3--5 x more labeled materials down the sensory fibers branches entering the sciatic nerve as compared to the dorsal root fiber branches of the neurons. Freeze-substitution preparations taken from the two sides of the lumbar seventh dorsal root ganglia of cats and monkeys showed little difference in the histograms of nerve fiber diameters of the sensory nerve fiber branch of these neurons as compared to the dorsal root fiber branches. A similar density of microtubules and of neurofilaments in the dorsal root and sensory nerve fiber branches over a wide range of fiber diameters was found in electron micrograph preparations. In the absence of an anatomical difference in the fibers to account for the asymmetrical outflow, a functional explanation based on the transport filament model was advanced.     

A monoclonal antibody specific for the 200 K polypeptide of the neurofilament triplet

A mouse monoclonal antibody, designated NF1, was obtained from a cloned hybridoma isolated from a fusion of mouse myeloma Sp2 cells with spleen cells from a BALB/c mouse immunized with a crude neurofilament preparation from porcine spinal cord. NF1 is an IgG1 and recognizes, in immune blotting procedures, only the 200 K neurofilament triplet component. Its neurofilament-specific nature is further revealed by immunofluorescence microscopy studies on frozen tissue sections and various cultured cells. Immunoelectron microscopy studies on cytoskeletons of cultured neurones emphasize the discontinuous display along each neurofilament previously observed with polyclonal antibodies specific for the 200 K component after appropriate but rather cumbersome cross-absorption steps. Use of NF1 on various neuronal cells strongly supports the previous proposal of the existence of certain subpopulations of neurofilament-free neurones and the observation that certain neuronal arrangements, (e.g., those in dendrites of pyramidal cells of the hippocampus), although rich in neurofilaments, probably lack the normal 200 K triplet component. Since NF1 shows a broad cross-species reactivity and is able to react on formaldehyde-fixed tissue, it should be a useful reagent to study differential neurofilament expression and organization in embryonic, adult and pathological tissues.     

Distribution of five peptides, three general neuroendocrine markers, and two synaptic-vesicle-associated proteins in the spinal cord and dorsal root ganglia of the adult and newborn dog: an immunocytochemical study

This study describes the immunocytochemical distribution of five neuropeptides (calcitonin gene-related peptide [CGRP], enkephalin, galanin, somatostatin, and substance P), three neuronal markers (neurofilament triplet proteins, neuron-specific enolase [NSE], and protein gene product 9.5), and two synaptic-vesicle-associated proteins (synapsin I and synaptophysin) in the spinal cord and dorsal root ganglia of adult and newborn dogs. CGRP and substance P were the only peptides detectable at birth in the spinal cord; they were present within a small number of immunoreactive fibers concentrated in laminae I-II. CGRP immunoreactivity was also observed in motoneurons and in dorsal root ganglion cells. In adult animals, all peptides under study were localized to varicose fibers forming rich plexuses within laminae I-III and, to a lesser extent, lamina X and the intermediolateral cell columns. Some dorsal root ganglion neurons were CGRP- and/or substance P-immunoreactive. The other antigens were present in the spinal cord and dorsal root ganglia of both adult and newborn animals, with the exception of NSE, which, at birth, was not detectable in spinal cord neurons. Moreover, synapsin I/synaptophysin immunoreactivity, at birth, was restricted to laminae I-II, while in adult dogs, immunostaining was observed in terminal-like elements throughout the spinal neuropil. These results suggest that in the dog spinal cord and dorsal root ganglia, peptide-containing pathways complete their development during postnatal life, together with the full expression of NSE and synapsin I/synaptophysin immunoreactivities. In adulthood, peptide distribution is similar to that described in other mammals, although a relative absence of immunoreactive cell bodies was observed in the spinal cord.     

Neuron-like derivatives of cultured F9 embryonal carcinoma cells express characteristics of parietal endoderm cells

Murine F9 embryonal carcinoma cells exposed to retinoic acid and dibutyryl cyclic AMP gradually arborize and acquire a neuron-like morphology in monolayer culture. Whether F9 cells can be induced to differentiate into cells with features specific to neural cells is controversial. We analyzed the intermediate filament content and pericellular matrix proteins of F9 cells after exposing them to retinoic acid, dibutyryl cyclic AMP, and nerve growth factor. In long-term cultures, a great majority of the cells appeared neuron-like, but showed intra- and pericellular laminin and type IV collagen, and frequently cytokeratin filaments as well. Several monoclonal antibodies to neurofilaments did not react with these cells in immunofluorescence or immunoblotting, though they recognize either all or individual mouse neurofilament triplet proteins. Polyclonal antibodies to neurofilament proteins gave a diffuse, nonfibrillar, vinblastine-resistant fluorescence in the morphologically neuron-like cells, but in immunoblotting failed to reveal polypeptides compatible with neurofilament triplet proteins. In long-term cultures, most of the cells appeared to have partially or totally lost the intermediate filaments. This was confirmed with anti-IFA antibodies which normally react with all intermediate filament proteins. The F9-derived cells did not respond to nerve growth factor in any detectable way. We conclude that the morphologically neuron-like derivatives of F9 cells display characteristics of modified parietal endoderm-like cells and do not show unequivocal features of neural cells.     

Protein Synthesis and Rapid Axonal Transport During Regrowth of Dorsal Root Axons

Damage to the sciatic nerve produces significant changes in the relative synthesis rates of some proteins in dorsal root ganglia and in the amounts of some fast axonally transported proteins in both the sciatic nerve and dorsal roots. We have now analyzed protein synthesis and axonal transport after cutting the other branch of dorsal root ganglia neurons, the dorsal roots. Two to three weeks after cutting the dorsal roots, [35S]methionine was used to label proteins in the dorsal root ganglia in vitro. Proteins synthesized in the dorsal root ganglia and transported along the sciatic nerve were analyzed on two-dimensional gels. All of the proteins previously observed to change after sciatic nerve damage were included in this study. No significant changes in proteins synthesized in dorsal root ganglia or rapidly transported along the sciatic nerve were detected. Axon regrowth from cut dorsal roots was observed by light and electron microscopy. Either the response to dorsal root damage is too small to be detected by our methods or changes in protein synthesis and fast axonal transport are not necessary for axon regrowth. When such changes do occur they may still aid in regrowth or be necessary for later stages in regeneration.     

Ultrastructural studies on calcitonin gene-related peptide-, tachykinins- and somatostatin-immunoreactive neurones in rat dorsal root ganglia: Evidence for the colocalization of different peptides in single secretory granules

Summary Calcitonin gene-related peptide (CGRP)-, tachykinins- and somatostatin-immunoreactive neurones in rat dorsal root ganglia have been studied by means of single and double immunogold labelling techniques. Peptide-immunoreactive neurones are generally B- or C-type cells of small size, with well developed rough endoplasmic reticulum and scanty neurofilaments. In neurones classifiable as A₂-type cells, i.e. larger neurones with a lighter cytoplasm due to the presence of poorly developed Nissl bodies and numerous neurofilaments, only CGRP immunoreactivity was detected. Immunolabelled structures were identified as large (60–100 nm diameter), electron-dense, membranebounded p-type granules. They were observed only in neuronal cell bodies or in the intraganglionic portions of the axons. No granules immunoreactive to the antisera applied in this study were observed in non-neuronal cells. Immunostaining experiments with different combinations of the antisera revealed, in some cells, the presence of double immunolabelled granules; in particular localization of CGRP and tachykinins, CGRP and somatostatin, and tachykinins and somatostatin to single secretory granules was demonstrated. The finding that more than one peptide is localized to the same secretory granule supports the postulate that peptides are co-released upon nerve stimulation providing morphological support for physiological and pharmacological data demonstrating an interaction between different peptides in the modulation of synaptic activity.     

An ultrastructural classification of the neuronal cell bodies of the rat dorsal root ganglion using zinc iodide-osmium impregnation

Summary Zinc iodide-osmium (ZIO) impregnation of rat dorsal root ganglia differentially stained various elements in the neuronal cells, particularly their Golgi bodies. On the basis of this differential ZIO staining dorsal root ganglion neurones have been classified into seven types. The ultrastructure of these is described and the numbers of each type in the L4 dorsal root ganglion have been determined. Prolonged nerve stimulation did not change the relative numbers of the different cell types suggesting that none of the differences between cell types represents differences in their state of activity. The possibility is discussed that differences in morphology may reflect differences in neurotransmitter function.I.R.D. is supported by the Medical Research Council; P.K. thanks the Mental Health Trust for a project grant     

Cross-Linking of Neurofilament Proteins of Rat Spinal Cord In Vivo After Administration of 2,5-Hexanedione

The aliphatic hexacarbons n-hexane, methyl-n-butyl ketone, and 2,5-hexanedione are known to produce a peripheral neuropathy that involves an accumulation of 10-nm neurofilaments above the nodes of Ranvier in the spinal cord and peripheral nerve. In this study, rats were treated with 0.5% 2,5-hexanedione in drinking water for 180 days, and their spinal cord neurofilaments were isolated after development of the neuropathy. Visualization by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a significant reduction in content of the neurofilament triplet proteins in treated animals and the presence of bands migrating at 138K and 260K that were not present in control animals. Analysis of the lanes using immunoblotting procedures and anti-70K, anti-160K, and anti-210K neurofilament antibodies revealed many cross-linked peptides. The 138K band cross-reacted with the anti-160K neurofilament antibody. This suggests that the 138K band is an intramolecular cross-link of the 160K neurofilament subunit. In addition to this peptide, there were numerous high-molecular-weight peptides immunoreactive with all three neurofilament protein antibodies. In addition to cross-linking, there was also a diminished amount of immunoreactive breakdown product of all three neurofilament proteins. This report demonstrates direct evidence of 2,5-hexanedione-induced cross-linking of neurofilament proteins in vivo, which maybe responsible for the accumulation of neurofilament proteins pathognomic of this neuropathy.     

Axoplasmic transport of horseradish peroxidase in single neurons of the dorsal root ganglion studied in vitro by microinjection

Summary The dependence of anterograde axoplasmic transport on cytoskeletal components was investigated using microinjection of horseradish peroxidase (HRP) into the somata of chick dorsal root ganglion cells in vitro. Microinjected HRP was transported anterogradely in the neurites and their branches; this transport was disturbed by colchicine in a drug-dependent and time-dependent manner. Cytochalasin B, a drug that depolymerizes actin, did not inhibit the transport of HRP, despite the formation of local swellings in neurites. The microinjection of polyclonal antibodies directed against tubulin and monoclonal antibodies (mAbs) against 200-kDa neurofilaments disturbed the axoplasmic transport of co-injected HRP, which then exhibited an irregular and discontinuous distribution in the axonal branches. The transport of HRP became discontinuous after the injection of anti-tubulin antibodies and led to the formation of globular deposits of HRP. Polyclonal antibodies against actin and mAbs to 160-kDa and 68-kDa neurofilaments seemed to have no effect on the axoplasmic transport of co-injected HRP. Microinjection of antibodies against tubulin induced formation of perinuclear bundles consisting of cytoskeletal components. The transport of HRP thus appears to be regulated by an intact microtubular system and cross-linker components (200-kDa neurofilaments) of the cytoskeleton. Actin and most intermediate filament proteins do not seem to play an essential role in the transport of HRP.