Immunohistochemical differences between neurofilaments in perikarya, dendrites and axons : Immunofluorescence study with antisera raised to neurofilament polypeptides (200K, 150K, 70K) isolated by anion exchange chromatography

Neurofilament (NF) proteins (70K, 150K and 200K D) were isolated from 2 M urea extracts of bovine spinal cord by anion exchange chromatography. Antisera to the individual NF polypeptides were produced in rabbits and affinity-purified on Sepharose columns prepared with their own antigen. The NF antisera were completely absorbed by their own antigen at protein concentrations that did not decrease the staining when the absorption was conducted with the heterologous NF antigens. Partial absorption (decrease in immunofluorescence titer) occurred at higher concentrations of the heterologous antigens. Cross-reactivity between the polypeptides of the NF triplet could not be detected by double immunodiffusion. The antisera formed immunoprecipitin lines only when reacted with their own antigen. Conversely, cross-reactivity was demonstrated by the immune blotting procedure. Anti-70K stained all three NF polypeptides. Anti-200K and anti-150K stained both 200K and 150K but not 70K, the main reaction being with their own antigen. The antisera were rendered monospecific by adsorption of the common antigenic determinants on Sepharose columns prepared with the heterologous NF antigens. The localization of the NF proteins was studied by immunofluorescence on cryostat sections of rat brain, cerebellum, spinal cord and posterior root ganglia. All NF antisera (anti-70K, anti-150K and anti-200K) stained axons including Purkinje cell baskets with identical pattern. Spinal cord motor neurons, posterior root ganglia neurons and pyramidal neurons in the cerebral cortex stained with anti-70K and anti-200K. No staining of neuronal perikarya and dendrites was observed with anti-150K. Aluminium-induced neurofibrillary tangles in rabbit spinal cord stained with anti-70K and anti-200K. The tangles were not decorated by anti-150K. It is concluded that a marked difference exists in the concentration of 150K depending on the location, i.e., cell body or axon; or, alternatively, that 150K undergoes modification of antigenic sites within the axon so that it may not be recognized immunologically as a component of the neurofilament within perikarya and dendrites.     

Study of the 10-nm-filament fraction isolated during the standard microtubule preparation.

The cold non-depolymerizable fractions obtained during the standard procedure for the isolation of microtubules from ox brain stem-cerebral hemispheres and spinal cord have been studied. The cerebral-hemisphere preparation was composed of 10-nm filaments but also contained large amounts of membranes. The polypeptide content included tubulin, microtubule-associated proteins and minor proteins corresponding to the neurofilament triplet of proteins of mol.wt. 210 000, 160 000 and 70 000 respectively. The brain-stem preparation contained more 10-nm filaments than membranes. The polypeptide content consisted of the neurofilament triplet (35%), tubulin (30%) and minor proteins. In contrast, the spinal-cord preparation was mainly composed of 10-nm filaments, free of membranes and containing essentially the neurofilament protein triplet (64%). These filaments appeared very similar to the peripheral-nervous-system neurofilaments described by several authors. Since the best neurofilament from the central nervous system often contained less than 15% of the neurofilament protein triplet, our spinal-cord preparation is an improvement on the usual neurofilament preparation. This simple and rapid method gave large amounts of 10-nm filaments (100 mg per 100 g of spinal cord) characterized by the absence of membranous material, a low content of tubulin and the 50 000-mol.wt.-protein component, and a high content of neurofilament peptides. Thus, the presence of tubulin in 10-nm filament preparations seems to be related to the contaminant membranous material and not to be linked to the interaction in vitro of tubulin or microtubules with neurofilaments, as has been suggested previously.     

Regenerative specificity of motor axons when reinnervation is partially suppressed

We asked whether regenerating hindlimb motor axons would innervate inappropriate hindlimb regions if competition from appropriate innervation were prevented. The three ventral roots that innervate the hindlimb in the bullfrog (Rana catesbeiana) tadpole were transected, and the two more rostral roots were ligated to prevent regeneration. The most caudal root, which primarily supplies more distal limb musculature in unoperated tadpoles, was left free to regenerate. The specificity of regeneration was assessed by retrogradely labeling spinal motoneurons with HRP placed in the ventral thigh, a region that receives most of its innervation from the ligated roots. Despite the lack of competition from appropriate innervation, the regenerating root did not provide substantial innervation to proximal limb musculature. The same result was obtained in tadpoles operated upon at stages when regeneration of motor axons is specific and in tadpoles at stages when regenerating motor axons do not reinnervate their appropriate targets (Farel and Bemelmans, 1986), although the mechanisms in each case are likely different.     

Effect of multiple dorsal rhizotomies on calcitonin gene-related peptide-like immunoreactivity in the lumbosacral dorsal spinal cord of the cat: a radioimmunoassay analysis

Calcitonin gene-related peptide-like immunoreactivity (CGRP-LI) was measured by radioimmunoassay in the cat lumbosacral dorsal spinal cord following unilateral dorsal rhizotomy of 5 consecutive dorsal roots. The dorsal rhizotomies greatly reduced but did not eliminate the CGRP-LI from the ipsilateral rhizotomized segments. The amount of CGRP-LI remaining in the rhizotomized segments was greatest in the most caudal segment (846 +/- 311 pmoles/g tissue) and decreased below 300 pmoles/g tissue in the remaining segments. When these values were compared to the intact contralateral side, the percent CGRP remaining ranged from 65% in the sacral segments to less than 20% in the lumbar segments. Rostral to the rhizotomized segments there was a gradual return of CGRP-LI to control levels within 3 segments. Small diameter primary afferent fibers are the only known source of CGRP within the dorsal spinal cord. These results suggest that the most likely origin of the CGRP that remained in the rhizotomized lumbar segments was the rostrally and caudally projecting branches of ipsilateral primary afferents that entered the spinal cord through intact dorsal roots caudal and rostral to the transected roots. These results support the hypothesis that small diameter primary afferents project several segments in the cat spinal cord.     

Formation of the peripheral nervous system during tail regeneration in urodele amphibians: ultrastructural and immunohistochemical studies of the origin of the cells.

In the regenerating newt tail, epimorphic regeneration--which recapitulates morphologically normal embryonic development--proceeds along a rostrocaudal differentiation gradient. Innervation of the new myomeres results from the spinal roots of segments rostral to the amputation plane and from ventral roots emerging from the lateroventral region of the regenerating spinal cord, in which motor neurons are differentiating. Electron microscopy and an indirect immunofluorescence study with anti-glial fibrillary acid protein (GFAP) confirm that the ventrolateral part of the regenerated ependymal tube gives rise to cells of the ventral root sheath and the spinal ganglia. Anti-GFAP and anti-neurofilament antibodies showed that ependymoglial cells and Schwann cells may play a role in neuronal pathfinding by helping guide and stabilize pioneering axons as they extend toward the myomeres. The carbohydrate epitope NC-1 is expressed in the spinal cord, in sheath cells of the spinal ganglia and in the non-myelin-forming Schwann cells of the peripheral nervous system. L1, a Ca++ independent neural cell adhesion molecule, was detected in the axonal compartments of the regenerating spinal cord, on immature and/or non-myelin-forming Schwann cells within the peripheral nervous system (PNS), and on nerve fibers within the regenerate. These immunohistochemical observations collectively support the hypothesis that Schwann cells already present in the blastema could be involved in organizing neural pathways.     

Axonal transport of class II and III beta-tubulin: evidence that the slow component wave represents the movement of only a small fraction of the tubulin in mature motor axons.

Pulse-labeling studies demonstrate that tubulin synthesized in the neuron cell body (soma) moves somatofugally within the axon (at a rate of several millimeters per day) as a well-defined wave corresponding to the slow component of axonal transport. A major goal of the present study was to determine what proportion of the tubulin in mature motor axons is transported in this wave. Lumbar motor neurons in 9-wk-old rats were labeled by injecting [35S]methionine into the spinal cord 2 wk after motor axons were injured (axotomized) by crushing the sciatic nerve. Immunoprecipitation with mAbs which recognize either class II or III beta-tubulin were used to analyze the distributions of radioactivity in these isotypes in intact and axotomized motor fibers 5 d after labeling. We found that both isotypes were associated with the slow component wave, and that the leading edge of this wave was enriched in the class III isotype. Axotomy resulted in significant increases in the labeling and transport rates of both isotypes. Immunohistochemical examination of peripheral nerve fibers demonstrated that nearly all of the class II and III beta-tubulin in nerve fibers is located within axons. Although the amounts of radioactivity per millimeter of nerve in class II and III beta-tubulin were significantly greater in axotomized than in control nerves (with increases of +160% and +58%, respectively), immunoassay revealed no differences in the amounts of these isotypes in axotomized and control motor fibers. We consider several explanations for this paradox; these include the possibility that the total tubulin content is relatively insensitive to changes in the amount of tubulin transported in the slow component wave because this wave represents the movement of only a small fraction of the tubulin in these motor fibers.     

Neurofilaments of the neurosecretory cells of a snail

Following brief formaldehyde fixation and detergent extraction numerous neurofilaments (NF) were seen in the nervous system of the gastropod snail Helisoma. NF are present in perikarya, axons and release sites of the neurosecretory (NS) cells. The NS neurons and their axons contain actin and microtubules, stain positively with NBD-phallacidin, and react positively to antibodies against mammalian tubulin, myosin and NF. In the perikarya of colchicine treated cells large masses of NF were seen. Extraction of NF from the nervous system was accomplished by a disassembly and reassembly method.     

Altered Axonal Transport of Cytoskeletal Proteins in the Mutant Diabetic Mouse

Polypeptides in the motor axons of the sciatic nerve in 120-day-old normal and diabetic mice C57BL/Ks (db/db) were labeled by injection of [35S]methionine into the ventral horn of the spinal cord. At 8, 15, and 25 days after the injection, the distribution of radiolabeled polypeptides along the sciatic nerve was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Four major radiolabeled polypeptides, tentatively identified as actin, tubulin, and the two lightest subunits of the neurofilament triplet, were studied in both diabetic and control mice. In the diabetic animals, the two polypeptides identified as actin and tubulin showed a reduction of average velocity of migration along the sciatic nerve, resulting in a higher fraction of radioactivity in the proximal part of the sciatic nerve, whereas the front of radioactivity (advancing at maximal velocity) moved at a normal rate. In contrast, both the average and maximal velocities of the two neurofilament subunits were slower in the diabetic mice than in the control mice. These results indicate that the axonal transport of the cytoskeletal proteins is differentially affected in the course of diabetic neuropathy, and may suggest that the impairment concerns mainly the proteins carried by the slowest component of axonal transport.     

Characterization of mammalian neurofilament triplet proteins. Subunit stoichiometry and morphology of native and reconstituted filaments

The three major proteins of mammalian neurofilaments of molecular weights 179,000 (NF1), 129,000 (NF2), and 66,500 (NF3) have been purified to homogeneity by multiple anion-exchange and hydroxylapatite absorption chromatography in 8 M urea. Silver staining of polyacrylamide gels of the purified proteins show single bands. In order to gain further insight into the molecular organization of the neurofilament triplet proteins, the molar stoichiometries and morphologies of native and reconstituted filaments and those isolated from developing brain were studied. Denaturing polyacrylamide gel electrophoresis followed by quantitative dye-binding analysis shows that the molar ratio of the three components in neurofilaments isolated from bovine spinal cord myelinated nerve is 4:2:1 (NF3:NF2:NF1). Comparison of the molar ratios of each component in neurofilaments isolated from rat, bovine, and human brain shows a variation in the ratio of each of these polypeptides and raises questions about the physiological uniqueness of the molar composition of the neurofilament triplet. Reconstitution of the three bovine polypeptides into 10-nm filaments was accomplished under conditions in which the NF3 protein was limiting. Reassembly of 10-nm filaments with varying amounts of NF2 and NF1 indicate that the NF3 homopolymer has a limiting capacity to bind NF2 and NF1 and is saturated at a molar ratio of 2:2:1 (NF3:NF2:NF1). Isolation of the neurofilament complex at various stages of rat brain maturation indicates that NF3 and NF2 are integrated into the neurofilament complex as early as embryonic day 17, while NF1 copurifies with these proteins at postnatal day 16, eventually reaching a molar stoichiometry of 2:2:1 in the adult rat. The molecular stoichiometry of the neurofilament proteins, the differential integration of these proteins during brain development, and the variation of the molar composition between mammalian species suggest accessory roles for the NF2 and NF1 proteins in the neurofilament complex.     

Early Effects of β,β'-Iminodipropionitrile on Tubulin Solubility and Neurofilament Phosphorylation in the Axon

Abstract: To elucidate the role of neurofilaments in microtubule stabilization in the axon, we studied the effects of β,β'-iminodipropionitrile (IDPN) on the solubility and transport of tubulin as well as neurofilament phosphorylation in the motor fibers of the rat sciatic nerve. IDPN is known to impair the axonal transport of neurofilaments, causing accumulation of neurofilaments in the proximal axon and segregation of neurofilaments to the peripheral axoplasm throughout the nerve. Administration of IDPN at various intervals after radioactive labeling of the spinal cord with l -[³⁵S]methionine revealed that transport inhibition occurred all along the nerve within 1–2 days. Transport of cold-insoluble tubulin, which accounts for 50% of axonal tubulin, was also affected. A significant increase in the proportion of cold-soluble tubulin was observed, reaching a maximum at 3 days after IDPN treatment and returning to the control level in the following weeks. Preceding this change in tubulin solubility, a transient decrease in the phosphorylation level of the 200-kDa neurofilament protein was detected in the ventral root using phosphorylation-dependent antibodies. These early changes agreed in timing with the onset of segregation and transport inhibition, suggesting that interaction between neurofilaments and microtubules possibly regulated by phosphorylation plays a significant role in microtubule stabilization.     

Studies on the biosynthesis of neurofilament proteins

To determine whether the triplet polypeptides of neurofilaments arise by degradation of precursor, we studied the biosynthesis of neurofilament polypeptides both in vivo and in cell-free systems. Neurofilament-enriched fractions and polyribosomes were prepared from the same rabbit spinal cord homogenates. At 1 h after intracisternal administration of [34S]methionine, radiolabeled neurofilament proteins were detected in spinal cord homogenates as well as in isolated filaments. When polyribosomes from rabbit spinal cord were allowed to incorporate [35S]methionine into protein, triplet polypeptides were among the proteins labeled. Addition of spinal cord polyribosomes to rabbit reticulocyte lysates led to several cycles of translation of the spinal cord mRNA; the three neurofilament polypeptides were among the proteins synthesized in this system. The results demonstrate that the triplet polypeptides of neurofilaments are synthesized as such in the course of individual translational events and do not arise from degradation of P200 or a larger precursor.     

Regeneration of ventral root axons into dorsal roots as shown by increased acetylcholinesterase activity

Regeneration of ventral root axons of the lumbar seventh (L7) segment into the dorsal L7 roots on the opposite side of cat spinal cord was shown by changes in the levels of acetylcholinesterase (AChE) and pseudocholinesterase (PsChE). Low levels of AChE and PsChE were found in control dorsal roots, but when regenerating ventral root fibers entered the dorsal roots, there was a doubling of AChE activity within 2 weeks. Growth appears to start some time after the first week; this is in accord with earlier evidence based on axoplasmic flow of isotope labeled protein in this experimental preparation. The level of AChE activity in the reinnervated dorsal roots increased continually for about 100 days before reaching a plateau at approximately 20 × control levels. The gradual increase and the plateau of AChE activity is in accord with a maturation of the ventral root fibers which had regenerated into the dorsal roots. PsChE in the dorsal roots changes in parallel with AChE in a ratio of 1:10, suggesting that PsChE may in part be localized in the regenerating axons.     

Presence of the betaII isotype of tubulin in the nuclei of cultured mesangial cells from rat kidney

Tubulin has generally been considered to be a cytosolic protein whose only function is to form microtubules. This assumption is supported by a great deal of evidence derived from immunohistochemical studies using antibodies directed against whole tubulin or its component polypeptides alpha- and beta-tubulin. We have re-examined the intracellular distribution of tubulin using monoclonal antibodies specific for the betaI, betaII, betaIII, and betaIV isotypes of beta-tubulin. Our test system is the cultured rat kidney mesangial cell. We have found that betaIII is absent from these cells and that beta1 and betaIV are present in microtubules throughout the cytosol. In contrast, betaII is present largely in the nuclei. Immunoblotting of purified nuclear extracts shows that the betaII-reactive antigen co-migrates with beta-tubulin. Extraction of the cytosol and chromatin suggests that betaII is concentrated in the nucleoli and also in a reticulated network in the rest of the nucleoplasm. An antibody to tyrosinated alpha-tubulin shows that alpha is also present in the nucleoli. Treatment of the cells with fluorescent colchicine shows an accumulation of colchicine in the nucleoli. Finally, fluorescently labeled alphabetaII-tubulin dimers, when microinjected into the cells, enter the nuclei and are concentrated in the nucleoli. These results suggest that the betaII isotype of tubulin is present as an alphabetaII dimer in the nuclei of cultured mesangial cells and suggest the possibility that different tubulin isotypes may have specific functions within the cell.     

Selective solubilization of high-molecular-mass neurofilament subunit during nerve regeneration

A reduction in neurofilament (NF) protein synthesis and changes in their phosphorylation state are observed during nerve regeneration. To investigate how such metabolic changes are involved in the reorganization of the axonal cytoskeleton, we studied the injury-induced changes in the solubility and axonal transport of NF proteins as well as their phosphorylation states in the rat sciatic nerve. In the control nerve, 15-25% of high-molecular-mass NF subunit (NF-H) was recovered in the 1% Triton-soluble fraction when fractionated in the presence of phosphatase inhibitors. After a complete loss of NF proteins distal to the injury site (70-75 mm from the spinal cord) 1 week after injury, NF-H detected in the regenerating sprouts at 2 weeks or later exhibited higher solubility (>50%) and lower C-terminal phosphorylation level than NF-H in the control nerve. Solubility increase was also apparent with L-[35S]methionine-labeled NF-H that was in transit in the proximal axon at the time of injury. The low-molecular-mass subunit remained in the insoluble fraction in both the normal and the regenerating nerves, indicating that selective solubilization of NF-H rather than total filament disassembly occurs during regeneration.     

Preparation of Neurofilament Protein from Guinea Pig Peripheral Nerve and Spinal Cord

Abstract: A simple and rapid method for preparation of enriched neurofilament protein from mammalian peripheral nerve or spinal cord is described. Tissue extracts from guinea pig nerve or spinal cord are fractionated by ammonium sulfate fractionation, chromatography on Sepharose 4B, and precipitation with ethanol. Molecular exclusion chromatography on Sepharose 4B, in which the neurofilament protein elutes quantitatively in the exclusion volume of the column, with little contamination by other proteins, is found to be a highly effective purification step. The protein is found to precipitate in ammonium sulfate fractions over a wide range of salt concentration, from 20 to 80% saturation. It is found to be quantitatively precipitated in 40% v/v ethanol-water. The preparative method described yields 0.25 mg of neurofilament protein per gram of nerve or spinal cord, with a purity of approximately 50%. The three principal neurofilament polypeptides, which have molecular weights by SDS-polyacrylamide gel electrophoresis of 200K, 145K, and 68K, are found to be present in the preparation in a molar ratio of 1:2:6. A variant form of neurofilament protein occurring in approximately 20% of Hartley strain guinea pigs is described, which has the polypeptide composition: 200K, 192K, 145K, 68K.     

In vitro binding of [14C]2,5-hexanedione to rat neuronal cytoskeletal proteins

2,5-Hexanedione (2,5-HD) induces central-peripheral axonpathy characterized by the accumulation of 10-nm neurofilaments proximal to the nodes of Ranvier and a Wallerian-type degeneration. It has been postulated that neurofilament crosslinking may be involved in the production of this axonopathy. A potential initiating event in this neurotoxic process may be the direct binding of 2,5-HD to neurofilament and microtubule proteins. In this study, the in vitro binding of [¹⁴C]2,5-HD to neurofilament and microtubule proteins was examined. Neurofilament proteins isolated from rat spinal cord or microtubule proteins isolated from rat brain were incubated in the presence of 2,5-HD at concentrations ranging 25 to 500 mM. Quantitative analysis of sodium dodecyl sulfate (SDS) polyacrylamide gels revealed a dose- and time-dependent binding of 2,5-HD to both neurofilament proteins and microtubule proteins. Expressed as pmol 2,5-HD bound per g protein, the observed relative binding was MAP2>NF160>NF200>NF68>tubulin. These data demonstrate the direct binding of 2,5-HD to cytoskeletal proteins including both neurofilaments and microtubules.     

Spontaneous and Experimental Neuritis and the Distribution of the Myelin Protein P2 in the Nervous System

The P2 contents of nervous tissues from the human, rabbit, guinea pig, and Lewis rat were measured by radioimmunoassay. The ventral spinal roots contained more P2 than any other tissue. Human dorsal roots and peripheral nerves contained 41-65% of the amount in human ventral roots. Human olfactory and optic nerves and brain contained 1.1-2.7%, spinal cord, 2.8%, cranial nerve VIII, 11%, and cerebral grey matter, 0%. The relative amounts in the rabbit nervous system were similar except that the spinal cord contained 20% of the amount in the ventral roots. Qualitative estimates in the guinea pig showed that the spinal roots and peripheral nerves contained more P2 than the spinal cord, and that none was present in the brain. In the Lewis rat, P2 could be detected in the spinal roots and peripheral nerves but not in the CNS. The distribution of P2 in the human nervous system parallels the incidence and severity of lesions in acute polyradiculoneuritis. It also explains the absence of any lesions in the CNS when experimental allergic neuritis is induced in the Lewis rat.     

Binding specificities of purified porcine brain alpha- and beta-tubulin subunits and of microtubule-associated proteins 1 and 2 examined by electron microscopy and solid-phase binding assays

In this study, the molecular interaction of separated alpha- and beta-tubulin with purified microtubule-associated protein 1 (MAP 1) and MAP 2 was studied using electron microscopy and solid-phase binding assays with 125I-radiolabeled proteins. Electron microscopy of proteins recovered from sodium dodecyl sulfate polyacrylamide gels and subsequently incubated in various combinations under conditions promoting tubulin polymer formation revealed that both subunits have binding sites for MAP 1 as well as MAP 2. Overlays of nitrocellulose-transblotted MAPs with electrophoretically separated tubulin subunits eluted from gels confirmed these results. In overlays of nitrocellulose-immobilized tubulin subunits with gel-eluted MAP 2, self-association of MAP 2, but no binding to tubulin was detected. However, overlays with MAP 1 and MAP 2 purified under nondenaturing conditions revealed binding of both MAPs to beta-tubulin. In addition, these experiments demonstrated binding of both MAPs to MAP 2 and to the neurofilament proteins NF 70, NF 150 and NF 200. It is concluded that both alpha- and beta-tubulin possess binding sites for MAP 1 as well as MAP 2, but that the accessibility and/or binding affinity of these sites are strongly dependent on the tertiary structure of proteins. The demonstrated in vitro binding of MAP 1 and MAP 2 to all three neurofilament proteins as well as to MAP 2 confirms their presumed role as cytoskeletal linking proteins.