A Rapid HPLC Method to Separate the Triplet Proteins of Neurofilament

In this article a fast HPLC technique to separate the individual neurofilament proteins is described. Highly pure fractions of the three neurofilament proteins can be obtained. As much as 50 mg of each neurofilament polypeptide can be separated from a crude neurofilament protein preparation in one step in less than 2 h. The short separation time is of importance in minimizing degradation, especially of the 150-kilodalton neurofilament polypeptide.     

The regulatory role of calmodulin in the proteolysis of individual neurofilament proteins by calpain

The in vitro degradation of individual neurofilament proteins by calpain and the effects of calmodulin on this proteolysis were studied. Two major results are reported. First, in the presence of calcium, calmodulin binds to the 200-kD neurofilament protein, but only weakly associates with the 150-kD neurofilament protein. The 70-kD neurofilament protein shows no specific calmodulin-binding. Second, calmodulin inhibits the calpain-mediated degradation of the 200-kD neurofilament protein, but does not alter the hydrolysis of the 150-kD and 70-kD neurofilament proteins. In addition, calmodulin is able to bind to the 200-kD neurofilament protein in the presence of other neurofilament subunits, indicating that calmodulin may play a role in the regulation of the metabolism of the 200-kD neurofilament protein in vivo.     

Phosphorylation Modulates Calpain-Mediated Proteolysis and Calmodulin Binding of the 200-kDa and 160-kDa Neurofilament Proteins

Abstract: The effects of enzymatic dephosphorylation on neurofilament interaction with two calcium-binding proteins, calpain and calmodulin, were examined. Dephosphorylation increased the rate and extent of 200-kDa neurofilament protein proteolysis by calpain. In contrast, dephosphorylation of the 160-kDa neurofilament protein did not alter the rate or extent of calpain proteolysis. However, the calpain-induced breakdown products of native and dephosphorylated 160-kDa neurofilament protein were different. Dephosphorylation did not change the proteolytic rate, extent, or breakdown products of the 68-kDa neurofilament protein. Calmodulin binding to the purified individual 160- and 200-kDa neurofilament proteins was increased following dephosphorylation. These results suggest that phosphorylation may regulate the metabolism and function of neurofilaments by modulating interactions with the calcium-activated proteins calpain and calmodulin.     

Neurofilament functions in health and disease.

Transgenic approaches have recently been used to investigate the functions of neuronal intermediate filaments. Gene knockout studies have demonstrated that neurofilaments are not required for axogenesis and that individual neurofilament proteins play distinct roles in filament assembly and in the radial growth of axons. The involvement of neurofilaments in disease is supported by the discovery of novel mutations in the neurofilament heavy gene from cases of amyotrophic lateral sclerosis and by reports of neuronal death in mouse models expressing neurofilament and alpha-internexin transgenes. However, mouse studies have shown that axonal neurofilaments are not required for pathogenesis caused by mutations in superoxide dismutase and that increasing perikaryal levels of neurofilament proteins may even confer protection in this disease.     

The breakdown of the individual neurofilament proteins by cathepsin D

In a continuing study of proteolysis of CNS proteins by CNS enzymes, neurofilament proteins (210 K, 155 K, 70 K) and desmin were separated, and the breakdown of individual proteins by purified brain cathepsin D was measured and compared to breakdown by plasma thrombin. With both cathepsin D and thrombin, the rate of breakdown of the 70 K protein was the highest, followed by the 155 K, and that of the 210 K was the lowest. With each substrate cathepsin D breakdown was the highest at pH 3; small but significant breakdown could be seen at pH 6. The pattern of intermediate breakdown products depended on pH, with greater amounts of fragments detected at higher pH, and the patterns with the two enzymes were different. We showed that differences exist in cleavage sites and breakdown rates of the neurofilament proteins. The capacity of the cathepsin D present in the tissue to hydrolyze these substrates was high, even at pH close to neutral, and was greatly in excess of that needed for physiological neurofilament turnover.     

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.     

Bulk Preparation of CNS Cytoskeleton and the Separation of Individual Neurofilament Proteins by Gel Filtration: Dye-Binding Characteristics and Amino Acid Compositions

Abstract: The three major proteins of mammalian neurofilaments, of molecular weight 70,000, 160,000, and 210,000, have been resolved by sodium dodecyl sulfate (SDS)-polyacrylamide gel eJectrophoresis, and more recently, by ion-exchange chromatography in urea solution. We describe here a method to separate the neurofilament proteins by gel filtration without the use of SDS. A bulk preparation of cytoskeleton from rat spinal cord was first characterized. This preparation was then solubilized in a buffer containing 8 M urea and subjected to gel filtration. Individual neurofilament proteins, in milligram quantities, were harvested following the pooling of appropriate fractions. Gel electrophoresis showed a high degree of homogeneity in each of the three pooled fractions. Dye binding studies demonstrated that the protein of molecular weight 210,000 was relatively underrepresented when stained with Coomassie Blue, while all three neurofilament proteins showed similar dye binding properties with Fast Green. Amino acid analysis indicated that (1) all three neurofilament proteins contained a high content of acidic residues; (2) the molecular weight 210.000 protein contained >8 mol% proline; and (3) no simple oligomeric relationship existed among the neurofilament triplets.     

Metabolic studies in vitro of the CNS cytoskeletal proteins: Synthesis and degradation

General aspects of metabolic features of the most prominent CNS intermediate filament proteins, the 200,000 (200K), 150,000 (150K), and 70,000 (70K) dalton proteins of the neuron, and the glial fibrillary acidic protein (GFAP) have been explored using the incubated spinal cord slice from the rat. Measurement of shortterm uptake of³H-labeled amino acids into the individual proteins separated on polyacrylamide gels revealed that of the three neurofilament proteins, 200K was most metabolically active, 150K was less active, and 70K contained very little incorporated radioactivity. Glial fibrillary acidic protein based on Coomassie blue stain affinity showed less metabolic activity than any of the neurofilament proteins. Those relationships were constant at all ages, but the metabolic activity of all CNS intermediate filaments decreased with age. When Ca²⁺ was present in the medium of the incubated slices, the intermediate filaments were rapidly destroyed, but GFAP was more resistant to degradation than the neurofilament proteins. GFAP and probably the neurofilament proteins also were relatively resistant to Ca²⁺-activated degradative mechanisms in spinal cords of rats at younger ages (15 day) than in those of older animals (10–18 months). It is likely that the Ca²⁺ activated protease is less active in developing animals in which the nerve tracts are still elongating, than in adults. These results suggest that GFAP is less active metabolically and more resistant to degradation than the neurofilament proteins at all stages of maturation, but that metabolic activity of all CNS intermediate filaments decreases with age while the susceptibility to degradation increases.Special Issue dedicated to Dr. Elizabeth Roboz-Einstein.     

Axonal Polypeptides Cross-Reactive with Antibodies to Neurofilament Proteins

Antibodies were prepared to mammalian CNS neurofilament proteins (NFPs) and the antibody specificities were compared using a sensitive immunoblotting method. This procedure was used to detect and characterize cross-reactive proteins and their degradation products in neurofilament preparations. NFPs were prepared by axon flotation. Rabbits were immunized with 200,000, 140,000, and 70,000 NFPs (200K, 140K, and 70K) that had been electrophoretically purified by polyacrylamide gel electrophoresis (PAGE). By immunohistofluorescence it was shown that all antisera stained similar filamentous structures in rat cerebellar neurons. By use of a horseradish peroxidase-conjugated indirect antibody procedure, however, differences were detected in the cross-reactivities of the antisera to rat NFPs, separated by PAGE and electrophoretically transferred to nitrocellulose membranes. Each antiserum exhibited strong binding to the homologous NFP and, thus, was suitable for the detection of cross-reactive polypeptides and proteolytic degradation products derived exclusively from the individual NFPs. Anti-200K, anti-140K, or anti-70K was applied to overloaded two-dimensional nitrocellulose blots of NFPs prepared by axon flotation. Each of the three sera detected a group of unique nonoverlapping polypeptides, some of which were identified as NFP degradation products. A different group of polypeptides was cross-reactive with antiserum to purified glial fibrillary acidic protein. The immunostaining of polypeptides on nitrocellulose was far more sensitive for detecting NFP degradation products than was staining polyacrylamide gels with Coomassie blue. Titers for the antisera were two to three orders of magnitude higher with the immunoblotting procedure than with immunohistologic methods. The sensitivity and the specificity of the described methods suggest their usefulness for examining proteolytic cleavage products of NFPs under a variety of conditions.     

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.     

Processing of neurofilament proteins from perikaryal to axonal type

In previous studies, neuronal cell bodies, excised by hand from bovine spinal ganglia, were analyzed and heterogeneous intermediate and high molecular weight neurofilament proteins that differed in electrophoretic mobility from their axonal counterparts were demonstrated (1, 2). In the present experiment, intermediate and high molecular weight neurofilament proteins of the axonal type were treated with alkaline phosphatase, and neurofilament proteins enriched in perikaryal type proteins were labeled with³²P. Results showed that neurofilament proteins were phosphorylated after their translation, in the perikarya and the proximal portion of the axon, and suggested that phosphorylation was responsible for the differences between axonal and perikaryal neurofilament proteins.Special Issue dedicated to Prof. Holger Hydén.     

Dephosphorylation of neurofilament proteins enhances their susceptibility to degradation by calpain.

The degradation of phosphorylated and dephosphorylated neurofilament proteins by the Ca2+-activated neutral proteinase calpain was studied. Neurofilaments were isolated from bovine spinal cord, dephosphorylated by alkaline phosphatase (from Escherichia coli) and radioiodinated with [125I]-Bolton-Hunter reagent. The radioiodinated neurofilament proteins (untreated and dephosphorylated) were incubated in the presence and absence of calpain from rabbit skeletal muscle, and the degradation rates of large (NF-H), mid-sized (NF-M) and small (NF-L) neurofilament polypeptides were analysed by SDS/polyacrylamide-gel electrophoresis and autoradiography. The degradation of dephosphorylated neurofilament proteins occurred at a higher rate, and to a greater extent, than did that of the phosphorylated (untreated) neurofilament proteins. The dephosphorylated high-molecular-mass neurofilament (NF-HD) was proteolyzed 6 times more quickly than the untreated NF-H. The degradation rate of the NF-M and NF-L neurofilament proteins was also enhanced after dephosphorylation, but less than that of NF-H. This indicates that the dephosphorylation of neurofilament proteins can increase their sensitivity to calpain degradation.     

Inhibition of Melatonin Biosynthesis Induces Neurofilament Hyperphosphorylation with Activation of Cyclin-dependent Kinase 5

Decreased level of melatonin and hyperphosphorylation of neurofilament proteins have been reported in Alzheimer’s disease (AD). However, the direct evidence linking melatonin and neurofilament phosphorylation is still lacking. Here, we investigated the effect of inhibiting melatonin biosynthesis on phosphorylation of neurofilament proteins and the involvement of cyclin-dependent kinase 5 (cdk-5) in rats. We observed that injection of haloperidol, a specific inhibitor of 5-hydroxyindole-O-methyltransferase, resulted in significantly decreased level of serum melatonin with a concomitantly increased phosphorylation of neurofilament proteins and activation of cdk-5 in rats. Exogenous supplementation of melatonin partially arrested the hyperphosphorylation of neurofilament and the activation of cdk-5. These results suggest that inhibition of melatonin biosynthesis may activate cdk-5 and thus induces Alzheimer-like hyperphosphorylation of neurofilament proteins. S. Wang and L. Zhu contributed equally to this paper.     

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.     

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.     

Stable interaction between G-actin and neurofilament light subunit in dopaminergic neurons

Excessive accumulation of neurofilaments in the cell bodies and proximal axons of motor neurons is a major pathological hallmark of motor neuron diseases. In this communication we provide evidence that the neurofilament light subunit (68 kDa) and G-actin are capable of forming a stable interaction. Cytochalasin B, a cytoskeleton disrupting agent that interrupts actin-based microfilaments, caused aggregation of neurofilaments in cultured mesencephalic dopaminergic neurons, suggesting a possible interaction between neurofilaments and actin; which was tested further by using crosslinking reaction and affinity chromatography techniques. In the cross-linking experiment, G-actin interacted with individual neurofilament subunits and covalently cross-linked disuccinimidyl suberate, a homobifunctional cross-linking reagent. Furthermore, G-actin was extensively cross-linked to the light neurofilament subunit with this reagent. The other two neurofilament subunits showed no cross-linking to G-actin. Moreover, neurofilament subunits were retained on a G-actin coupled affinity column and were eluted from this column by increasing salt concentration. All three neurofilament subunits became bound to the G-actin affinity column. However, a portion of the 160 and 200 kDa neurofilament subunits did not bind to the column, and the remainder of these two subunits eluted prior to the 68 kDa subunit, suggesting that the light subunit exhibited the highest affinity for G-actin. Moreover, neurofilaments demonstrated little or no binding to F-actin coupled affinity columns. The phosphorylation of neurofilament proteins with protein kinase C reduced its cross-linking to G-actin. The results of these studies are interpreted to suggest that the interaction between neurofilaments and actin, regulated by neurofilament phosphorylation, may play a role in maintaining the structure and hence the function of dopaminergic neurons in culture.     

High-performance liquid chromatographic analysis of phlorotannins from the brown alga Fucus vesiculosus

Separating individual compounds by HPLC represents an effective method for the detection and quantification of phenolic compounds and has been widely utilised. However, phlorotannins are commonly quantified using colorimetric methods, as the total amount of the whole compound group. In the present paper the separation of a set of individual soluble phlorotannins from the phenolic crude extract of Fucus vesiculosus was achieved by HPLC with UV photodiode array detection. Different gradient programs for reversed- and normal-phase HPLC methods were developed and tested. Normal-phase (NP) conditions with a silica stationary phase and a mobile phase with a linear gradient of increasing polarity were found to separate 16 individual components of the phenolic extract. The suitability of the NP-HPLC method for mass spectrometric application was preliminarily tested. Sample preparation was found to be a critical step in the analysis owing to the rapid oxidation of phlorotannins; ascorbic acid was used as an antioxidant.     

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 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.     

A mathematical model for assessing changes in neurofilament protein levels in neurites and cell bodies of differentiating neuroblastoma cells

A mathematical model which allows the calculation of the level of neurofilament protein in the cell body (x) and in the neurites (y) of differentiating SK-N-SH cells is presented. The model considers the changes in cell number (proliferating cells) and the number of cells with neurites (differentiating cells). It takes into account the fact that (i) when cells are cultured in differentiating conditions, an increase in cell number is initially observed and (ii) in a non-synchronized population of differentiating cells, the length of neurite extended by individual cells varies within the population. Total neurofilament protein levels in a population of cells were measured by enzyme-linked immunoabsorbant assay and application of the model to the data allowed values for x and y to be calculated. The validity of the model is supported by the fact that the predicted total neurofilament protein levels are highly correlated with the experimentally derived neurofilament protein levels. The model should be of use in temporal studies of cytoskeletal proteins involved in neuronal growth/differentiation and also in studies in which the system is a target of toxic insult.