Antibodies to neurofilament protein and other brain proteins reveal the innervation of peripheral organs

Monoclonal and polyclonal antibodies to neurofilament proteins, neuron-specific enolase, glial fibrillary acidic protein and S-100 have been used to demonstrate nerves, ganglion cells and the supportive glial system of the innervation of various organs. The female genitalia, the urinary tract, the respiratory system, the pancreas, the heart and the skin of several mammalian species, including rat, mouse, guinea pig, cat, pig, monkey and man were fixed in para-benzoquinone and portions of each organ were snap frozen. Serial or free-floating thick cryostat sections were stained using indirect immunofluorescence and peroxidase anti-peroxidase immunocytochemistry. In addition, the newly described and highly sensitive immunogold-silver staining technique was used on Bouin's-fixed and wax-embedded tissues. Antibodies to neurofilament proteins seemed to react with neuronal structures in all the species studied. Alternately stained serial sections showed a similar distribution of neurofilament proteins and neuron-specific enolase-containing nerves. Neuron-specific enolase staining had a diffuse appearance and was found to be highly variable, indicating that the neuron-specific enolase content might be related to the physiological state of the nerves and ganglion cells, whereas antibodies to neurofilament protein gave a consistently intense and very clear picture of the ganglion cells and nerve fibres. Antibodies to S-100 stained supportive elements of the peripheral nervous system in all tissues examined, whereas antibodies to glial fibrillary acidic protein were more selective.     

Microtubule-associated proteins bind specifically to the 70-kDa neurofilament protein

Morphological and biochemical evidence have suggested that the components of the neuronal cytoskeleton, microtubules and neurofilaments (NF), interact with each other. Microtubule-associated proteins (MAPs) are plausible candidates for mediating some of these interactions and have been shown to bind to neurofilaments, as well as induce the formation of a viscous complex between neurofilaments and microtubules. By binding 32P-labeled MAPs to neurofilament proteins, which were transferred electrophoretically to nitrocellulose, we determined that, of the three neurofilament subunits, only the core NF70 subunit bound MAPs. The binding to electrophoretically transferred NF70 was specific, saturable, and reversible. Binding parameters were estimated by binding 32P-labeled MAPs to purified NF70 immobilized on nitrocellulose. Approximately 1 mol of MAPs bound per 45 +/- 15 mol of NF70 with an approximate Kd approximately 2.0 +/- 0.9 X 10(-7) M (n = 8). Reassembled filaments in suspension were used to confirm the specific binding. Tubulin and NF70 apparently bind to different sites on MAPs.     

Aromatic hydrocarbon 1,2-diacetylbenzene cross-links neurofilament and other proteins

Here we explored the mechanisms of secretory phospholipase A2 (sPLA2) and glutamate (glu) in neuronal signalling and cell damage. Rats or primary neuronal cultures were treated with MK-801 and injected with/exposed to sPLA2 or glu. MK-801 partially inhibited sPLA2- and glu-induced neuronal death as well as [3H]arachidonic acid release. The involvement of cytosolic PLA2 (cPLA2) and plateletactivating factor (PAF) in sPLA2 or glu signalling was explored by treating cells with the selective cPLA2 inhibitor, AACOCF3, PAF-acetyl hydrolase (PAF-AH) or the presynaptic PAF-receptor antagonist, BN52021. AACOCF3 blocked sPLA2- and glu-induced neuronal death by 26 and 77%, respectively. PAF-AH ameliorated sPLA2 as well as glu neurotoxicity by 31 and 47%, whereas BN52021 inhibited sPLA2 induced neurotoxicity by 11% but did not significantly protect against glu-induced neurotoxicity. Expression in neurons of early response genes in response to sPLA2 or glu was further examined. An up-regulation of COX-2, c-fos, and c-jun, but not COX-1, was observed at earlier time points after rat striatal injection of glu as compared to sPLA2 injection. Moreover we treated neuronal cells with COX-2 inhibitors and found that neuronal cell death after sPLA2 and glu exposure was inhibited by 35 and 33%, respectively. Thus sPLA2 activates a neuronal signalling cascade that includes activation of cPLA2, AA-release, production of PAF and induction of COX-2. Hence sPLA2 and glu signalling are overlapping, but not identical. Cytosolic PLA2 may primarily drive glutamatergic neurotransmission, whereas PAF plays a more crucial role in sPLA2 neuronal signalling.
Acknowledgements:   Supported by EPSCoR grant NSF/LEQSF(2001-04)-RII-01 from the National Science Foundation.     

Binding of brain spectrin to the 70-kDa neurofilament subunit protein

Brain spectrin, or fodrin, a major protein of the subaxolemmal cytoskeleton, associates specifically in in vitro assays with the 70-kDa neurofilament subunit (NF-L) and with glial filaments from pig spinal cord. As an initial approach to the identification of the fodrin-binding proteins, a crude preparation of neurofilaments was resolved by electrophoresis on SDS/polyacrylamide gels and then transferred to nitrocellulose paper, which was 'blotted' with 125I-fodrin. A significant binding of fodrin was observed on polypeptides of 70 kDa, 52 kDa and 20 kDa. These polypeptides were further purified and identified respectively as the NF-L subunit of neurofilaments, the glial fibrillary acidic protein (GFP) and the myelin basic protein. The binding of fodrin to NF-L was reversible and concentration-dependent. The ability of the pure NF-L and GFP to form filaments was used to quantify their association with fodrin. a) The binding of fodrin to reassembled NF-L was saturable with a stoichiometry of 1 mol fodrin bound/50 +/- 10 mol NF-L and an apparent dissociation constant Kd = 4.3 x 10(-7) M. b) The binding involved the N-terminal domain of the polypeptide chain derived from the [2-(2-nitrophenylsulfenyl)-3-methyl-3'-bromoindolenine] cleavage of NF-L. c) Binding occurred optimally at physiological pH (6.8-7.2) and salt concentrations (50 mM). d) Interestingly, calmodulin, a Ca2+-binding protein, which has been shown to bind to fodrin, was found to reinforce the binding of fodrin to the NF-L, at Ca2+ physiological concentrations. The binding of fodrin to pure neurofilaments was not affected by the presence of the 200-kDa (NF-H) and the 160-kDa (NF-M) subunits. The apparent dissociation constant for the binding of fodrin to NF-L in the pure NF was 1.0 x 10(-6) M with 1 mol fodrin bound/80 +/- 10 mol NF-L. Moreover, the binding of fodrin to GFP, demonstrated in blot assays, was confirmed by cosedimentation experiments. The apparent dissociation constant Kd for the fodrin binding was 2.8 x 10(-7) M and the maximum binding was 1 mol fodrin/55 +/- 10 mol GFP.     

Phosphorylation of neurofilament proteins by protein kinase C

The low molecular mass (70 kDa) subunit of neurofilaments (NF-L) contains at least three phosphorylation sites in vivo and is phosphorylated by multiple kinases in a site-specific manner [(1987) J. Neurochem. 48, S101; Sihag, R.K. and Nixon, R.A. submitted]. In this study, we observed that the three subunits of neurofilament proteins from retinal ganglion cell neurons are substrates for purified mouse brain protein kinase C. Two-dimensional alpha-chymotryptic phosphopeptide map analyses of the NF-L subunit demonstrated that protein kinase C phosphorylates four polypeptide sites, two of which incorporate phosphate when retinal ganglion cells are pulse-radiolabeled with [32P]orthophosphate in vivo.     

Proteolysis of the neurofilament 68 kDa protein explains several previously described brain proteins of unique composition and high acidity

Neurofilaments follow the structural principles of non-neuronal intermediate filaments but contain additional sequences which are carboxyterminally located and increase in length between triplet proteins (68 kDa, 160 kDa and 200 kDa). The tailpiece domain has been sequenced in the case of the porcine 68 kDa protein. It has a unique amino acid composition. Within 106 residues there are only 12 different amino acid types, and glutamic acid accounts for 46% of the sequence. Examination of the literature on highly acidic brain proteins leads us to the proposal that microglutamic acid-rich protein, Glu-50, macroglutamic protein, as well as some unusual components of the S100 class, are most likely proteolytic degradation products of the neurofilament 68 kDa protein.     

Degradation of neurofilament proteins by purified human brain cathepsin D

Abstract: Cathepsin D (CD) was purified to homogeneity from postmortem human cerebral cortex. Incubation of CD with human neurofilament proteins (NFPs) prepared by axonal flotation led to the rapid degradation of the 200,000, 160,000, and 70,000 NFP subunits (200K, 160K, and 70K) which had been separated by one-or two-dimensional sodium dodecyl sulfate-polyacrylámide gel electrophoresis (SDS-PAGE). Degradation was appreciable at enzyme activity-to-substrate protein ratios that were two-to threefold lower than those in unfractionated homogenates from cerebral cortex. Quantitative measurements of NFPs separated by PAGE revealed that, at early stages of digestion, the 160K NFP was somewhat more rapidly degraded than the 70K subunit while the 200K NFP had an intermediate rate of degradation. At sufficiently high enzyme concentrations, all endogenous proteins in human NF preparations were susceptible to the action of CD. Human brain CD also degraded cytoskeletal proteins in NF preparations from mouse brain with a similar specificity. To identify specific NFP breakdown products, antisera against each of the major NFPs were applied to nitrocellulose electroblots of NFPs separated by two-dimensional SDS-PAGE. In addition to detecting the 200K, 160K, and 70K NFP in human NF preparations, the antisera also detected nonoverlapping groups of polypeptides resembling those in NF preparations from fresh rat brain. When human NF preparations were incubated with CD, additional polypeptides were released in specific patterns from each NFP subunit. Some of the immuno-cross-reactive fragments generated from NFPs by CD comigrated on two-dimensional gels with polypeptides present in unincubated preparations. These results demonstrate that NFPs and other cytoskel-etal proteins are substrates for CD. The physiological significance of these findings and the possible usefulness of analyzing protein degradation products for establishing the action of proteinases in vivo are discussed.     

Purification and degradation of purified neurofilament proteins by the brain calcium-activated neutral proteases

The effect of the three forms (CANP1, CANP2 & CANP3) of calf brain calcium activated neutral protease (CANP) on the hydrolysis of purified neurofilament triplet proteins was investigated. It was observed that: each of the purified neurofilament proteins, was hydrolyzed slowly by CANP2 whereas the hydrolysis of 150 KDa and 68 kDa proteins by CANP1 & CANP3 was rapid; when assembled neurofilaments were used as a substrate, again differences in the rate and extent of degradation of the triplet proteins by the three proteases were observed. For example, little cleavage of the 68 kDa protein by CANP2 and CANP3 was noted whereas 210 kDa and 150 kDa proteins remained largely intact. CANP1 degraded the 150 kDa and 68 kDa proteins more rapidly than 210 kDa protein, where only a slight effect was noted. These data provide further proof of the existence of three different forms of CANP in the brain, and indications of the resistance of 210 kDa protein to proteolysis which may be compatible with its proposed special role in crossbridge formation.     

Antibodies to different isoforms of the heavy neurofilament protein (NF-H) in normal aging and Alzheimer's disease

Sera of normal controls and of patients with neurological diseases contain antineurofilament antibodies. Recent studies suggest that biochemically and immunologically distinct subclasses of neurofilaments occur in different types of neurons. Alzheimer's disease (AD), the major cause of dementia, is associated with a marked degeneration of brain cholinergic neurons. In the present work we characterized the repertoire and age dependence of antineurofilament antibodies in normal sera and examined whether the degeneration of cholinergic neurons in AD is associated with serum antibodies directed specifically against the neurofilaments of mammalian cholinergic neurons. This was performed by immunoblot assays utilizing neurofilaments from the purely cholinergic bovine ventral root neurons and from the chemically heterogeneous bovine dorsal root neurons. Antibodies to the heavy neurofilament protein NF-H were detected in normal control sera. Their levels were significantly higher in older (aged 70–79) than in younger (aged 40–59) subjects. These antibodies bound similarly to bovine ventral root and dorsal root NF-H and their NF-H specificity was unchanged during aging. In contrast, the levels of IgG in AD sera that are directed against ventral root cholinergic NF-H were higher than those directed against the chemically heterogeneous dorsal root NF-H. Immunoblot experiments utilizing dephosphorylated ventral root and dorsal root NF-H and chymotryptic fragments of these molecules revealed that AD sera contain a repertoire of antimamalian NF-H IgG. A subpopulation of these antibodies binds to phosphorylated epitopes that are specifically enriched in ventral root cholinergic NF-H and that are located on the carboxy terminal domain of this molecule. The level of these anticholinergic NF-H IgG are significantly higher in AD sera than in those of both normal controls and patients with multi-infarct dementia.     

Antisense inhibition of the renin-angiotensin system in brain and peripheral organs

Antisense inhibition is a method of attenuating the target at the gene expression level. There are two main groups of molecular tools for this goal. The first includes the use of short synthetic stretches of DNA-antisense oligodeoxynucleotides. The second tool is the use of vectors (plasmids or viruses) containing the gene of interest subcloned in the antisense orientation, which in the cells produces the antisense RNA. Both antisense DNA and RNA can bind to the complementary sense mRNA and interfere with its translation. Effects are usually short lasting (days) for oligodeoxynucleotides and longer lasting (weeks or months) for vectors. In this article we briefly describe techniques of antisense inhibition in the context of the renin-angiotensin system.     

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.     

Ferritin: a novel mechanism for delivery of iron to the brain and other organs

Traditionally, transferrin has been considered the primary mechanism for cellular iron delivery, despite suggestive evidence for additional iron delivery mechanisms. In this study we examined ferritin, considered an iron storage protein, as a possible delivery protein. Ferritin consists of H- and L-subunits, and we demonstrated iron uptake by ferritin into multiple organs and that the uptake of iron is greater when the iron is delivered via H-ferritin compared with L-ferritin. The delivery of iron via H-ferritin but not L-ferritin was significantly decreased in mice with compromised iron storage compared with control, indicating that a feedback mechanism exists for H-ferritin iron delivery. To further evaluate the mechanism of ferritin iron delivery into the brain, we used a cell culture model of the blood-brain barrier to demonstrate that ferritin is transported across endothelial cells. There are receptors that prefer H-ferritin on the endothelial cells in culture and on rat brain microvasculature. These studies identify H-ferritin as an iron transport protein and suggest the presence of an H-ferritin receptor for mediating iron delivery. The relative amount of iron that could be delivered via H-ferritin could make this protein a predominant player in cellular iron delivery. blood-brain barrier; iron transport; H-ferritin     

Antibodies against structural proteins of carlaviruses in human and other mammals

The study of four isolates of chrysanthemum B-virus (CVB) has shown the virus to have a single 40 Kd structural protein able to dissociate under the definite conditions forming the truncated (for 3 and 6 Kd) polypeptides having preserved their whole antigenic determinants. The human plasma is shown to contain antibodies reacting with the structural protein B-BX and, approximately 10 times weaker with the structural protein of another carlavirus, potato M-virus. Interaction of antibodies with CVB is found to take place due to F(ab)2 fragments. The analogous reaction with the proteins of other plant viruses or retroviruses has never been registered. Antibodies reacting with CVB protein are also present in the plasma of green monkey, rabbit, mouse and goat but in lesser quantities than in human plasma. Two possible explanations are proposed for the presented data, either immunization of mammalians by the protein or peptide containing its antigenic determinant, or the accidental coincidence of CVB antigenic determinant with some viral, bacterial or fungal determinant widespread in mammalians.     

Phosphorylation of neurofilament proteins by endogenous calcium/calmodulin-dependent protein kinase

A protein fraction containing neurofilaments was prepared from rat brain cytosol by differential centrifugation and gel filtration chromatography. These preparations were enriched for a calcium/calmodulin-dependent kinase activity that phosphorylated endogenous neurofilament proteins. The enzyme incorporated approximately 1 mol PO4/mol of each neurofilament triplet polypeptide. These data suggest that a calmodulin-dependent kinase may mediate some of the effects of calcium on cytoskeletal function by phosphorylation of neurofilament proteins.     

Traumatic brain injury alters the gut-derived serotonergic system and associated peripheral organs

Most efforts to understand the pathology of traumatic brain injury (TBI) have been centered on the brain, ignoring the role played by systemic physiology. Gut-derived serotonin is emerging as a major regulator of systemic homeostasis involving various organs and tissues throughout the body. Here, we shed light on the roles occupied by gut-derived serotonin and its downstream metabolic targets in the systemic pathogenesis of TBI. Male C57BL/6J mice were subjected to a fluid percussion injury (FPI) and RT-qPCR was used to examine mRNA levels in intestine, liver, and adipose tissue. In the intestinal tract, TBI transiently downregulated enteric neuronal markers Chat and Nos1 in the duodenum and colon, and altered colonic genes related to synthesis and degradation of serotonin, favoring an overall serotonin downregulation. There also was a decrease in serotonin fluorescence intensity in the colonic mucosa and reduced circulating blood serotonin levels, with concurrent alterations in serotonin-associated gene expression in downstream tissues after TBI (i.e., upregulation of serotonin receptor Htr2a and dysregulation of genes associated with lipid metabolism in liver and adipose). Levels of commensal bacterial species were also altered in the gut and were associated with TBI-mediated changes in the colonic serotonin system. Our findings suggest that TBI alters peripheral serotonin homeostasis, which in turn may impact gastrointestinal function, gut microbiota, and systemic energy balance. These data highlight the importance of building an integrative view of the role of systemic physiology in TBI pathogenesis to assist in the development of effective TBI treatments.     

Effect of chronic ethanol ingestion on phosphate content of neurofilament proteins and neurofilament associated protein phosphatase in rat spinal cord

Rats were trained to drink alcohol solution by gradually increasing the ethanol content [2.5–15% (v/v)] in drinking water. After 11 months of alcohol (15% v/v) ingestion, animals were guillotined and the spinal cords were used for the preparation of neurofilaments (NF). NF triplet proteins were separated by SDS-PAGE and the phosphate contents of individual components were estimated. Results indicated a significant increase in phosphate content of 200 KD protein in alcohol fed rats (30.19±4.12 mol of phosphate/mole of protein: p<0.001) compared to control group (18.42 ±3.91 mol of phosphate/mole of protein). No significant change in the phosphate content of 150KD and 68KD components of NF were seen in experimental group. Further, the studies on NF associated protein phosphatase activity indicated a significant decrease in phosphatase activity among the alcohol fed rats (14.10±2.5 mU; p<0.001) against NF rich fraction as a substrate, as compared to control (20.15±2.15 mU). While the observed decrease in NF associated protein phosphatase would possibly explain the increase in phosphate content of NF proteins in alcohol fed rats, the precise mechanism of decrease in enzyme activity remains to be elucidated. Nevertheless, the change seen in phosphate content and NF associated protein phosphatase activity as a result of ethanol ingestion would possibly form the biochemical basis of some of the neuropathological changes seen in alcoholics.