Axonal maturation in development--II. Immunofluorescence study of rat spinal cord and cerebellum with axon-specific neurofilament antibodies

Differential expression and modification of neurofilament triplet proteins during cat cerebellar development

Neurofilament (NF) proteins consist of three subunits of different molecular weights defined as NF-H, NF-M, and NF-L. They are typical structures of the neuronal cytoskeleton. Their immunocytochemical distribution during postnatal development of cat cerebellum was studied with several monoclonal and polyclonal antibodies against phosphorylated or unmodified sites. Expression and distribution of the triplet neurofilament proteins changed with maturation. Afferent mossy and climbing fibers in the medullary layer contained NF-M and NF-L already at birth, whereas NF-H appeared later. Within the first three postnatal weeks, all three subunits appeared in mossy and climbing fibers in the internal granular and molecular layers and in the axons of Purkinje cells. Axons of local circuit neurons such as basket cells expressed these proteins at the end of the first month, whereas parallel fibers expressed them last, at the beginning of the third postnatal month. Differential localization was especially observed for NF-H. Depending on phosphorylation, NF-H proteins were found in different axon types in climbing, mossy, and basket fibers or additionally in parallel fibers. A nonphosphorylated NF-H subunit was exclusively located in some Purkinje cells at early developmental stages and in some smaller interneurons later. A novel finding is the presence of a phosphorylation site in the NF-H subunit that is localized in dendrites of Purkinje cells but not in axons. Expression and phosphorylation of the NF-H subunit, especially, is cell-type specific and possibly involved in the adult-type stabilization of the axonal and dendritic cytoskeleton.

Abnormal perikaryal accumulation of neurofilament light protein in the brain of mice transgenic for the human protein: sequence of postnatal development

Adult mice transgenic for the human form of neurofilament light protein display abnormal perikaryal immunoreactivity for this protein in many regions of the CNS and notably the thalamus. To determine the sequence of development of these anomalies, we have compared normal and transgenic mice of different postnatal ages (P0-P70), using immunocytochemistry with primary antibodies recognizing both murine and human sequence of neurofilament light protein (NR-4) or the human form only (DP5-1-12). In normal mouse brainstem, several nuclei displayed immunoreactive perikarya at P0. The number of these perikarya culminated at P10, followed by a general decrease, some nuclei having lost all perikaryal immunostaining in adults. In transgenic mouse brainstem, the distribution of perikaryal immunoreactivity already resembled at P0 that of P10 in normal mouse, and remained unchanged in adults. Differences between normal and transgenic mice were even more pronounced in the forebrain. Some nuclei of normal mouse basal forebrain that were weakly immunopositive at P10 or P20, but no longer in adults, were already labeled at P0 and remained so or became more intense at later stages in transgenic mice. In the thalamus of normal mouse, perikaryal labeling was faint, confined to a few nuclei, and detected only transiently at P10, whereas in transgenics, it was already observed in some nuclei at P0, increased in intensity and extended to other nuclei at P10, and persisted thereafter. Strongly immunoreactive, inflated perikarya with excentric nuclei were prominent in these thalamic nuclei at P20, and even larger in size at P70. In the cerebral cortex of normal mice, layers II-III and layer V of many cytoarchitectonic areas showed immunoreactive cell bodies at P10, a distribution which became gradually restricted to the parietal cortex in adults. In transgenic mice, immunopositive cortical cell bodies were first detected at P3, filled layers II-III of numerous cortical areas at P10, and then rapidly decreased in number to approach the adult pattern at P20. In the cortex as well as thalamus of P10 transgenic mice, differences between the patterns of cellular staining with clones NR4 and DP5-1-12 antibodies indicated that both the murine and human proteins were accumulated in these neurons. Thus, neurofilament light protein accumulation in the transgenic mouse brain generally involved neurons displaying perikaryal immunoreactivity for the protein at least at some point during normal postnatal development.(ABSTRACT TRUNCATED AT 400 WORDS)

The neurofilament triplet is present in distinct subpopulations of neurons in the central nervous system of the guinea-pig

It is commonly assumed that most, if not all, neurons contain the intermediate filament protein class known as the neurofilament protein-triplet. The following study investigated the distribution of neurofilament protein-triplet immunoreactivity in selected regions of the guinea-pig central nervous system using monoclonal antibodies directed against phosphorylation-independent epitopes on the three subunits under optimal tissue processing conditions. Neurofilament protein-triplet immunoreactivity was present in distinct subpopulations of neurons in the cerebellar cortex, neocortex, hippocampal formation, retina, striatum and medulla oblongata. In many of these regions, labelled neurons represented only a small proportion of the total. The selective distribution of this intermediate filament protein class was confirmed in double-labelling experiments using antibodies to the neurofilament protein-triplet in combination with antibodies to other neuronal markers. The distribution of neurofilament protein-triplet immunoreactivity also correlated with the distribution of staining observed with a silver impregnation method based on Bielschowsky. The present results in combination with previous observations have demonstrated that the neurofilament protein-triplet is found in specific subclasses of neurons in different regions of the nervous system. Content of this intermediate filament protein class does not appear to be correlated with neuronal size or length of projection. These results also suggest that the selectivity of staining between neuronal classes observed with classical silver impregnation methods may be due to the presence or absence of the neurofilament protein-triplet. The present results may also provide a new perspective on the basis of the selective vulnerability of neurons in degenerative diseases.

Expression of neurofilament proteins in granule cells of the cerebellum

We have used a panel of monoclonal antibodies directed against the low, middle and high molecular weight subunits of neurofilament triplet, to study their expression in mouse cerebellar granule cells. We demonstrate that in situ such cells only express the 2 lower molecular weight subunits either at various developmental stages or in the adult. The same results were obtained in vitro. This pattern of neurofilament protein expression in adult granule cells is therefore similar to that observed in developing neurons but differs from most neurons in the adult brain. The retention of such 'immature' pattern of neurofilament protein expression throughout adulthood could explain the lack of cytologically identifiable intermediate filaments in these neurons when examined with conventional electron microscopic techniques. It furthermore suggests that various neuronal populations might be characterized by the expression of specific subsets of neuronal intermediate filaments.

Transient modulation of Schwann cell antigens after peripheral nerve transection and subsequent regeneration

Schwann cells within the distal portion of a transected nerve undergo a series of poorly understood events in response to injury and loss of axonal contact. These events may influence the regeneration of PNS neurons. In this study we examined the alteration of antigens located in the basal lamina, plasma membrane and cytoplasm of Schwann cells within the distal nerve stump: (a) after a complete transection of the sciatic nerve, and (b) subsequent to reestablished contact between regenerating axons and dedifferentated Schwann cells separated from contact with neurons. Visualization of laminin and heparan sulphate proteoglycan molecules at various intervals after nerve transection always revealed intact basal lamina channels. In response to loss of axonal contact, vimentin expression by Schwann cells within the distal nerve stump increased, becoming a predominant intermediate filament protein of the cytoskeleton while glial fibrillary acid protein (GFAP) expression decreased. This reversal in the prominence of intermediate filament protein was maintained until the onset of axonal reinnervation, at which point expression of GFAP increased and vimentin decreased. Expression of the Schwann cell plasma membrane associated protein, C4, closely mimicked GFAP expression during axon degeneration and subsequent reinnervation. In the normal uninjured nerve, tissue plasminogen activator (tPA) and S-100 were localized in the region near the Schwann cell-axon interface and the outer Schwann cell plasma membrane. In response to loss of axonal contact, the S-100 and tPA immunoreactivity associated with the Schwann cell-axon interface was lost while that localized around the outer Schwann cell plasma membrane remained unchanged. The results of this study demonstrate that Schwann cells modulate a portion of their antigenic repertoire in response to a loss of axonal contact and after contact with regenerating axons.

Early axonal differentiation in mouse CNS delineated by an antibody recognizing extracted neurofilaments

A monoclonal antibody, C2, raised against chick embryo spinal cord, is shown by a solid phase immunoabsorbent assay to recognize a molecular species associated with neurofilaments extracted from adult mouse and rat brain. As immunoreactivity is lost following pre-treatment with alkaline phosphatase, the antibody probably recognizes a phosphorylated protein. Immunocytochemical staining in fetal mouse indicates that this antigen is expressed selectively in axons from the earliest stages of their development. Neuronal somata tend to show only weak immunoreactivity. The C2 antibody allowed visualization of the spatiotemporal pattern of axonal growth in the retina, neocortex and cerebellum with greater resolution than in previous light microscopic descriptions. The concept that the leading process of some classes of migratory neurons becomes transformed into an axon is supported by the expression of C2 immunoreactivity in radially ascending processes from principle neuron classes in the fetal retina and cerebellum.

Neurofilament phosphorylation in neuronal perikarya following axotomy: a study of rat spinal cord with ventral and dorsal root transection

Rat spinal cord was stained by indirect immunofluorescence with 11 neurofilament monoclonal antibodies that recognize phosphorylated epitopes. All monoclonals were axon-specific in this location. The large motoneurons containing bundles of neurofilaments did not stain and the pattern remained unchanged after transection of the sciatic nerve in the thigh. With nine monoclonals, stained motoneurons were observed in the ventral horns 3 days, 5 days, 1 week, and 2 weeks after transection of the ventral roots close to the spinal cord. The abnormal motoneurons were typically scattered among normal (i.e., nonstained) cells. Even in animals showing the most severe reaction, the whole motoneuron population at the site of rhizotomy was not affected, stained and nonstained perikarya often coexisting side by side. Stained motoneurons were no longer observed 3 weeks after ventral root transection. Changes in neuronal immunoreactivity were also observed after dorsal root transection. However, a different population was affected, i.e., middle-sized neurons in dorsal horns and at the base of ventral horns. With two monoclonals (A9 and D21), cell bodies remained negative following all operations. It is concluded that axotomy in proximity of the cell body may induce certain neurofilament phosphorylation events in motor neuron perikarya, whereas other phosphorylation events remain confined to the axons under these experimental conditions. The absence of changes after transection of the sciatic nerve in the thigh suggests that neurofilament phosphorylation is a reaction to cell injury rather than a cellular event related to nerve regeneration.

Early and late appearance of neurofilament phosphorylation events in nerve regeneration

Neurofilament phosphorylation in regenerating rat sciatic nerve was studied by indirect immunofluorescence with monoclonal antibodies reacting with phosphorylated epitopes of the 2 large polypeptides of the neurofilament protein triplet (NF 150K, NF 200K). One group of antibodies decorated axons early in the process. In fact, no differences were seen in double labeled sections between these antibodies and polyclonal neurofilament antibodies as to their reactivity with the distal stump of transected sciatic nerves. Another group stained axons after they had completed their elongation, i.e., after they had reached the distal part of the denervated sciatic nerve. In general, the epitopes recognized by antibodies in this group appeared more sensitive to phosphatase digestion as compared to the first group. Furthermore, there was a good correlation between the thickness of the regenerated axons and staining with these monoclonal antibodies. Thick axons (like those observed in normal nerves) were stained, while bundles of thin axons remained unstained. Monoclonal II32 stained regenerated axons in a remarkable segmental pattern. With this antibody, continuous decoration of the axons was still not observed 7 weeks after transection, the longest follow-up period in this study. We suggest that some neurofilament phosphorylation events may contribute to the stabilization of the axonal cytoskeleton and that abnormalities persist in regenerated axons as to the extent of neurofilament phosphorylation.

Expression of neurofilament immunoreactivity in developing rat cerebellum in vitro and in vivo

The developmental expression of neurofilaments immunoreactivity was examined in frozen sections and in primary cultures of rat cerebellum by immunocytochemistry with a series of monoclonal antibodies and with a polyclonal antibody. In tissue sections immunocytochemical staining with all the antibodies used was observed in basket cells where adult-like appearance could be detected by 14 days of age and adult-level intensity was achieved by about 25 days. Granule cells remained unstained. Intense staining appeared in cerebellar white matter as early as 7 days after birth. In contrast, neurofilaments immunoreactivity was detected in cultured granule cells from 7-day-old cerebellum. Only polyclonal antibodies reacting with the highly conserved middle alpha-helical domain of the neurofilament subunits were reactive in culture. Staining could be detected in the nerve cell bodies from the first day after plating; thereafter staining intensity increased and was also distributed in neurite extensions. We conclude that unlike their counterparts in vivo cultured embryonic granule cells can express certain neurofilaments immunoreactivity.

Multiple phosphorylated variants of the high molecular mass subunit of neurofilaments in axons of retinal cell neurons: characterization and evidence for their differential association with stationary and moving neurofilaments

The 200-kD subunit of neurofilaments (NF-H) functions as a cross-bridge between neurofilaments and the neuronal cytoskeleton. In this study, four phosphorylated NF-H variants were identified as major constituents of axons from a single neuron type, the retinal ganglion cell, and were shown to have characteristics with different functional implications. We resolved four major Coomassie Blue-stained proteins with apparent molecular masses of 197, 200, 205, and 210 kD on high resolution one-dimensional SDS-polyacrylamide gels of mouse optic axons (optic nerve and optic tract). Proteins with the same electrophoretic mobilities were radiolabeled within retinal ganglion cells in vivo after injecting mice intravitreally with [35S]methionine or [3H]proline. Extraction of the radiolabeled protein fraction with 1% Triton X-100 distinguished four insoluble polypeptides (P197, P200, P205, P210) with expected characteristics of NF-H from two soluble neuronal polypeptides (S197, S200) with few properties of neurofilament proteins. The four Triton-insoluble polypeptides displayed greater than 90% structural homology by two-dimensional alpha-chymotryptic iodopeptide map analysis and cross-reacted with four different monoclonal and polyclonal antibodies to NF-H by immunoblot analysis. Each of these four polypeptides advanced along axons primarily in the Group V (SCa) phase of axoplasmic transport. By contrast, the two Triton-soluble polypeptides displayed only a minor degree of alpha-chymotryptic peptide homology with the Triton-insoluble NF-H forms, did not cross-react with NF-H antibodies, and moved primarily in the Group IV (SCb) wave of axoplasmic transport. The four NF-H variants were generated by phosphorylation of a single polypeptide. Each of these polypeptides incorporated 32P when retinal ganglion cells were radiolabeled in vivo with [32P]orthophosphate and each cross-reacted with monoclonal antibodies specifically directed against phosphorylated epitopes on NF-H. When dephosphorylated in vitro with alkaline phosphatase, the four variants disappeared, giving rise to a single polypeptide with the same apparent molecular mass (160 kD) as newly synthesized, unmodified NF-H. The NF-H variants distributed differently along optic axons. P197 predominated at proximal axonal levels; P200 displayed a relatively uniform distribution; and P205 and P210 became increasingly prominent at more distal axonal levels, paralleling the distribution of the stationary neurofilament network.(ABSTRACT TRUNCATED AT 400 WORDS)

Neurofilament triplet proteins of NB2a/d1 neuroblastoma: posttranslational modification and incorporation into the cytoskeleton during differentiation

Induction of axonal neuritogenesis in NB2a/d1 cells was associated with an increased content of neurofilament proteins (NFPs) by immunoblot analysis. The major NFP subunits in differentiated [NB2a(+)] cells included microheterogenous forms with apparent molecular weights of 200-190 kDa (NFP-H), 143-142 kDa (NFP-M) and 70 kDa (NFP-L) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Only NFP-L was detected in cytoskeletal preparations of undifferentiated [NB2a(-)] cells. All three NFPs of NB2a(+) cells incorporated 32P-orthophosphate in intact cells. A 160/155 kDa NFP-H immunoreactive polypeptide in NB2a(-) and NB2a(+) cells represented a relatively unmodified form of the 200 kDa NFP-H, since dephosphorylation of the 200 kDa NFP-H in vitro with alkaline phosphatase generated the 160/155 kDa forms. Triton-extracted NB2a(+) cells displayed NFP-H immunoreactivity in neurites and occasionally in perikaryal regions at the base of neurites. NFP-M was present throughout the neurites and somata of NB2a(+) cells, and was regularly detected in portions of perikarya in NB2a(-) cells. NFP-L immunoreactivity was distributed throughout the Triton-insoluble cytoskeleton of NB2a(-) and NB2a(+) cells. Immunocytochemical analyses revealed that extensively phosphorylated forms of NFP-H were largely restricted to the neurites of NB2a(+) cells, and less modified forms predominated throughout both perikarya and neurites of NB2a(-) and NB2a(+) cells.

Early and late appearance of neurofilament phosphorylated epitopes in rat nervous system development: in vivo and in vitro study with monoclonal antibodies

Neurofilament phosphorylation in rat nervous system development was studied by indirect immunofluorescence with monoclonal antibodies reacting with phosphorylated epitopes in tissue sections and in primary dissociated cultures. The antibodies either decorated neurofilaments shortly after their appearance or after a considerable delay (from 4 to 9 days in vivo and from 12 to 27 days in vitro), thus suggesting the existence of at least two classes of phosphorylated epitopes. With most antibodies there was a good correlation between in vivo and in vitro findings as to the early or late appearance of phosphorylated epitopes. Monoclonal NE14 was the main exception in that immunoreactivity with this antibody was present in 1-day cultures, while it only occurred 4 days after the first appearance of neurofilaments in vivo. The effect of phosphorylation on neurofilament structure and function remains to be determined. Neurofilament expression is an early phenomenon in ontogeny coinciding with neuronal differentiation. It is possible that late phosphorylation events may stabilize the axonal cytoskeleton following the massive loss of axons that occurs in several fiber tracts during late fetal and neonatal life.

Neurofilament phosphorylation in axons and perikarya: immunofluorescence study of the rat spinal cord and dorsal root ganglia with monoclonal antibodies

Rat dorsal root ganglia and spinal cord were stained with 12 monoclonal antibodies reacting with phosphorylated epitopes of two neurofilament proteins (NF 150K and NF 200K). Three monoclonal antibodies were axon-specific in both locations; neuronal perikarya were not stained. Nine monoclonal antibodies stained a subpopulation of neurofilament-positive sensory neurons, as indicated by double labeling experiments with polyclonal antibodies reacting with phosphorylated and dephosphorylated forms of the neurofilament protein triplet. Of these nine antibodies, two stained motor neuron perikarya in the spinal cord, while the remaining seven antibodies were axon-specific in this location. Subpopulations of stained and unstained motor neurons were not observed. With all 12 antibodies, the staining pattern in the lumbar dorsal root ganglia and spinal cord remained unchanged following sciatic nerve crush and ligature. The findings suggest that, in the neurofilament, some phosphorylated epitopes are axon specific, while other phosphorylated epitopes are present in both axons and perikarya. Furthermore, they suggest that differences exist between neuronal populations as to the presence of phosphorylated epitopes in perikaryal neurofilaments. It remains to be seen whether phosphorylation events in perikarya and axons have similar or different effects on neurofilament structure and function.

Non-phosphorylated and phosphorylated neurofilaments in hypothyroid rat cerebellum

Purkinje cell baskets in hypothyroid rat cerebellum were studied with antibodies reacting with phosphorylated or non-phosphorylated neurofilament epitopes. Compared to normal rats, Purkinje cell baskets were fewer in number and less developed in hypothyroid rat cerebellum. However, no differences were observed as to their immunoreactivity with monoclonal antibodies reacting with phosphorylated or non-phosphorylated neurofilament epitopes.

Axonal maturation in development--I. Characterization of monoclonal antibodies reacting with axon-specific neurofilament epitopes

Monoclonal antibodies reacting with the high molecular weight neurofilament polypeptides (NF 150K and NF 200K) were obtained upon immunization with NF 150K and NF 200K isolated from bovine spinal cord by anion exchange chromatography. The five monoclonal antibodies obtained with NF 200K stained only axons. With three monoclonals the reactivity was abolished by digestion with phosphatase and by dilution of the supernatants in sodium potassium phosphate. The nine monoclonal antibodies obtained upon immunization with NF 150K stained both high molecular weight neurofilament polypeptides on immunoblots of bovine and rat spinal cord extracts with the exception of one monoclonal only reacting with the homologous antigen. The antibodies could be divided into two groups, axon-specific and conventional. Conventional antibodies decorated neurofilaments regardless of their location, i.e. axons, perikarya and dendrites. With all these antibodies the immunostaining was not affected by phosphatase digestion of neurofilament protein nor by dilution of the supernatants in sodium potassium phosphate. Axon-specific antibodies reacting with both NF 150K and NF 200K in rat spinal cord only stained the heterologous antigen (NF 200K) in rat optic nerve and sciatic nerve extracts. We suggest that some axon-specific neurofilament antibodies recognize neurofilament modifications other than phosphorylation; or, alternatively that they react with phosphorylated epitopes not accessible to phosphate or to exogenous phosphatases. Furthermore, we suggest that some neurofilament modifications do not occur uniformly throughout the nervous system.

Maturation of a large neurofilament protein (NF 150K) in rat postnatal development

The mammalian neurofilament is made of three neuron-specific proteins with approximate molecular weights of 70 kilodaltons (kDa) (NF 70K), 150 kDa (NF 150K), and 200 kDa (NF 200K) by SDS-PAGE. As previously reported in the rat by Strocchi et al (J Neurochem 39:1132-1141, 1982) and Nixon et al (J Cell Biol 94:150-58, 1982), NF 150K comprises three molecular weight variants with the same isoelectric point. A fourth lower molecular weight and slightly less acidic variant was identified by monoclonal and polyclonal antibodies reacting with the alpha-helical middle domain of NF 150K. With few exceptions, this lower molecular weight variant did not stain with monoclonal antibodies reacting with the peripheral carboxy-terminal domain. Staining with these antibodies was abolished or markedly reduced following neurofilament dephosphorylation. The distribution of the NF 150K variants varied in different regions of the nervous system. The higher molecular weight variant (component a) was less prominent in brain compared to spinal cord, optic nerve, and sciatic nerve. Furthermore, the lower molecular weight variant (component d) was not identified in optic nerve and sciatic nerve. All four variants were identified in brain and spinal cord extracts of newborn rats with monoclonal and polyclonal antibodies reacting with the alpha-helical middle domain of NF 150K. As a general (see Results for exceptions) monoclonal antibodies reacting with the carboxy-terminal region of NF 150K did not stain the variants in newborn rat brain extracts until day 10 when immunoreactivity of component a first appeared. The adult pattern was first observed on postnatal day 15.(ABSTRACT TRUNCATED AT 250 WORDS)