Effect of a Single Dose of β,β''-Iminodipropionitrile In Vivo on the Properties of Neurofilaments In Vitro: Comparison with the Effect of Iminodipropionitrile Added Directly to Neurofilaments In Vitro

The biochemical properties of neurofilaments isolated from control and iminodipropionitrile-treated rats were compared with regard to autophosphorylation capacity, hydrolysis of ATP, and the formation of a viscous gel between filaments. Both preparations exhibited a similar polypeptide composition, and no covalent cross-linking between neurofilament subunits was induced by iminodipropionitrile in vivo. An ATPase activity, systematically present in all preparations, was unaffected by the administration of iminodipropionitrile to the rats. Conversely, the autophosphorylation of neurofilament subunits in vitro was significantly higher in preparations from iminodipropionitrile-treated rats than from control animals, with a marked increase of the phosphorylation of a high molecular weight neurofilament-associated protein. Iminodipropionitrile provoked a higher gelation capacity of neurofilaments as measured in vitro, with a lower critical concentration for the preparation from treated animals. A similar increased interaction was obtained with millimolar concentrations of iminodipropionitrile added to bovine neurofilaments in vitro, involving likely neurofilament-associated molecules, because the effect of the drug was lost after their extraction by 0.8 M KCl. These results support the hypothesis that iminodipropionitrile interferes with the neurofilament networks through a preferential interaction with the neurofilament-associated proteins, resulting in a change in their properties and consequently in an increased capacity of interaction between the polymers.     

Characterization of neurofilament-associated protein kinase activities from bovine spinal cord

1. A neurofilament-enriched preparation from bovine spinal cord contains endogenous protein kinases that phosphorylate high, middle, and low molecular weight neurofilament subunits (NF-H, NF-M, and NF-L), as well as certain other endogenous and exogenous substrates. 2. Most of this associated kinase activity can be separated from the neurofilament subunits and the bulk of the protein by extraction of the neurofilament preparation with 0.8 M KCl. Assays using specific exogenous substrates, activators, and inhibitors for known kinases reveal significant levels of Ca2(+)-calmodulin-dependent, cyclic nucleotide-dependent, Ca2(+)-phosphatidylserine diglyceride-dependent, and regulator-independent kinase activities in the high-salt extract. 3. Fractionation of the salt extract on a gel filtration column resolves a regulator-independent kinase activity identified by its ability to phosphorylate purified NF-M. This preparation can phosphorylate all three neurofilament proteins either in purified form or in the assembled form, as well as alpha-casein. Only the regulator-independent kinase activity in this fraction is responsible for the phosphorylation of neurofilament proteins. 4. While this partially purified kinase activity does not show a strong substrate specificity between the three neurofilament subunits, the phosphorylation pattern it produces upon incubation with salt-extracted neurofilaments is similar to the regulator-independent phosphorylation pattern found in the original neurofilament preparation and, thus, represents a useful starting point for the further purification of this neurofilament-associated kinase activity.     

A Molecular Mechanism for the Induction of Neurofilament Bundling by Aluminum Ions

A1 induces neurofibrillary tangles in the perikaryon of neurons in vivo and in culture. The effect of A1 ions complexed with maltol, a plant-derived ligand of A1, on purified neurofilament preparations was studied in vitro. The binding of A1 to the arm-like projections of the high (H)- and medium (M)-molecular-weight neurofilament subunits causes a conformational change of the molecule (intrafilamentous reaction), characterized by an altered migration on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). In addition, A1 compounds strongly stimulate the interaction between neurofilaments (interfilamentous reaction). The possibility that phosphate groups of the H and M sidearms are involved in binding A1 ions is discussed with regard to the migration on SDS-PAGE of dephosphorylated neurofilaments incubated with A1 compounds and the alteration by A1 ions of neurofilament phosphorylation in vitro by the associated kinase. Immunoblotting analysis of neurofilaments in cultivated neurons intoxicated with A1 compounds revealed a similar A1-dependent alteration of the neurofilament subunit conformation. This result suggest that the mechanism of A1-induced bundling of neurofilaments derived from in vitro studies might be involved in the formation of tangles in situ.     

A calcium-dependent protease associated with the neural cytoskeleton. Purification and partial characterisation

Calcium-dependent protease activity was found associated with a neurofilament-enriched cytoskeleton isolated from the bovine spinal cord. The protease was extracted from the cytoskeleton by 0.6 M KCl, and purified to apparent homogeneity (3300-fold) by chromatography on organomercurial-Sepharose 4B, casein-Sepharose 4B, and Sepharose CL-6B. A cytosolic calcium-dependent protease was similarly purified from the bovine spinal cord, after the cytosol was fractionated on DEAE-cellulose. Both cytoskeleton-bound and cytosolic enzymes had an apparent molecular mass of 100 kDa as judged by gel filtration, and consisted of two subunits (79 kDa and 20 kDa) upon sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Both enzymes exhibited caseinolytic activity with 0.5 mM Ca2+ and above, and the activity was strongly inhibited by various thiol protease inhibitors. In the presence of 0.1-0.2 mM Ca2+, the 68-kDa and 160-kDa components, and to a lesser extent the 200-kDa component, of the neurofilament triplet polypeptides were degraded by the cytosolic protease, whereas the cytoskeleton-bound protease needed two-fold higher concentration of Ca2+ to degrade the neurofilaments. Nevertheless, the cytoskeleton-bound protease in situ, i.e. before its extraction form the cytoskeleton by 0.6 M KCl, preferentially degraded the 160-kDa component in the presence of 0.1-0.2 mM Ca2+, suggesting that a proper locational relation of this enzyme to the neurofilament structure is a prerequisite to its preference for the 160-kDa component. It appears that a factor or factors involved in such an interaction between the protease and the neurofilament were eliminated during the course of enzyme purification. The glial fibrillary acidic protein was almost insensitive to the proteases purified in the present study.     

Immunochemical Characterization of Antisera to Rat Neurofilament Subunits

Abstract: Antisera raised to the 68,000, 145,000 and 200,000 molecular weight subunits of rat neurofilaments were used for immunochemical staining of polypeptides separated by one- and two-dimensional gel electrophoresis. It was found that each antiserum reacts intensely with its corresponding neurofilament subunit and weakly with the other two subunits. All the antisera also react with a polypeptide of molecular weight 57,000 present in neurofilament-rich preparations from both rat spinal cord and peripheral nerve. This polypeptide is different from either tubulin or vimentin and may represent a neurofilament breakdown product, since it varied in amount from preparation to preparation. The three antisera also reacted with the polypeptide subunits of chicken and goldfish neurofilament despite the considerable difference in molecular weight between these subunits and those of mammalian neurofilament. Key Words: Neurofilaments–Antibodies–Immunochemical. Autilio-Gambetti L. et al. Immunochemical characterization of antisera to rat neurofilament subunits. J. Neurochem. 37, 1260-1265(1981).     

Principal neurofilament-associated protein kinase in squid axoplasm is related to casein kinase I

A cytoskeletal extract of pure axoplasm, highly enriched with neurofilaments (ANF), was prepared from the giant axon of the squid. This ANF preparation also contained potent kinase activities which phosphorylated the Mr greater than 400,000 (high molecular weight) and Mr 220,000 squid neurofilament protein subunits. High salt (1 M) extraction of this ANF preparation solubilized most of the neurofilament proteins and kinase activities and gel filtration on an AcA 44 column separated these two components. The neurofilaments eluted in the void volume of the column while the kinase activities eluted in the 17-44-kDa range of the column. Two major kinase activities were measured in this peak of activity. One of these strongly phosphorylated the phosphate acceptor peptide Leu-Arg-Arg-Ala-Ser-Leu-Gly (Kemptide) and was completely inhibited by the selective inhibitor of cAMP-dependent kinase Thr-Thr-Tyr-Ala-Asp-Phe-Ile-Ala-Ser-Gly-Arg-Thr-Gly-Arg-Arg-Asn-Ala-Ile- NH2 (Wiptide). Since addition of cAMP did not stimulate activity, this suggested that this kinase was a free catalytic subunit of cAMP-dependent kinase associated with the neurofilaments. The second kinase activity most effectively phosphorylated alpha-casein, and this activity was not affected by Wiptide. The alpha-casein phosphorylating activity (ANF kinase) was the principal activity responsible for neurofilament protein phosphorylation, and was not inhibited by various inhibitors against second messenger regulated kinases, suggesting it was related to the casein kinase family. Four lines of evidence indicate ANF kinase was similar to casein kinase I. These were: 1) the apparent molecular weight determined by gel filtration and the chromatographic elution profile on phosphocellulose column corresponded to casein kinase I; 2) heparin, an inhibitor of casein kinase II at 2-5 micrograms/ml, stimulated both ANF kinase and purified casein kinase I at these concentrations, while CKI-7, a relatively selective inhibitor of casein kinase I, inhibited ANF kinase in a comparable dose-response fashion; 3) purified casein kinase I strongly phosphorylated both ANF protein subunits (like ANF kinase) whereas casein kinase II was relatively ineffective; and 4) tryptic peptide maps of the HMW and Mr 220,000 neurofilament proteins after phosphorylation by ANF kinase or purified casein kinase I showed similar 32P-peptide patterns.     

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.     

Partial purification of neurofilament subunits from bovine brains and studies on neurofilament assembly

The 200,000-dalton neurofilament subunit (P200) and the 160,000-dalton (P160) and 78,000-dalton (P78) neurofilament subunits were partially purified from bovine brain. Intact neurofilaments were prepared by high- speed and sucrose-zone centrifugation. The crude neurofilament was solubilized in 8 M urea solution containing pyridine, formic acid, and 2-mercaptoethanol. The solubilized neurofilament was purified by carboxymethyl (CM) cellulose column and hydroxylapatite column chromatography. The P200 was purified as separate from P160 and P78, but the P160 and P78 subunits were copurified on CM cellulose, hydroxylapatite, Bio-Gel A150m, and Sephadex G-150 column chromatography. Electron microscopy of these purified neurofilament subunits revealed the P200 subunit as a globular structure, and the P160 and P78 subunits as a rod-shaped structure extending up to 120 nm with a 8- to 12-nm width. In the presence of 200 mM KCl, 15 mM MgCl2, and 1 mM ATP, the purified subunits assembled into long filaments. Under the assembly condition, P160 and P78 subunits elongated up to 500 nm, but the longer filament formation required the presence of P200 subunits. The filaments formed in vitro were of two types: long straight filaments and intertwined knobby-type filaments. From these results, we have suggested that P160 and P78 form the neurofilament backbone structure and P200 facilitates the assembly of the backbone units into longer filaments.     

Characterization of mammalian neurofilament subunits by circular dichroism

Critical steps in the disassembly and reassembly of neurofilaments, the intermediate filaments of neurons, have been investigated. Bovine neurofilament subunits (Mr 210 000, 160 000 and 70 000) were purified by urea-polyacrylamide gel electrophoresis and renatured by dialysis against several non-denaturing buffers. The quality of the protein renaturation was measured by circular dichroism. The spectra of renatured neurofilament subunits were interpreted in terms of secondary structure and this showed that the solubilization of proteins in guanidine-HCl buffers is more suitable than in urea buffer for a good recovery of a filamentous structure. Furthermore, it is shown that (i) the three neurofilament subunits exhibit specific CD spectra, with shapes reminiscent of those obtained for the alpha/beta class of proteins and that (ii) there is good correlation between CD spectra, the state of renaturation and the ability of the proteins to assemble into filamentous structures. We conclude that CD studies of neurofilament proteins should help in understanding the numerous variables affecting the disassembly and reassembly of neurofilaments.     

Differential turnover of phosphate groups on neurofilament subunits in mammalian neurons in vivo

The phosphorylation and dephosphorylation of specific proteins was demonstrated directly in the intact vertebrate nervous system in vivo. By exploiting the neurons' ability to segregate a select group of cytoskeletal proteins from most other phosphorylated constituents of the cell by axoplasmic transport, we were able to examine the dynamics of phosphate turnover on neurofilament proteins in mouse retinal ganglion cell neurons simultaneously labeled with [32P]orthophosphate and [3H]proline in vivo. Three [3H]proline-labeled neurofilament protein (NFP) subunits, designated H (160-200 kDa), M (135-145 kDa), and L (68-70 kDa), entered optic axons in a mole:mole ratio similar to that of isolated axonal neurofilaments, supporting the notion that newly synthesized NFPs are transported along axons as assembled neurofilaments. NFP subunits incorporated high levels of 32P before reaching axonal sites at the level of the optic nerve. As neurofilaments were transported along axons, however, many initially incorporated [32P]phosphate groups were removed. Loss of these phosphate groups occurred to a different extent on each subunit. A minimum of 50-60 and 35-40% of the labeled phosphate groups was removed in a 5-day period from the L and M subunits, respectively. By contrast, the H subunit exhibited relatively little or no phosphate turnover during the same period. Dephosphorylation of L in axons is accompanied by a decrease in its net state of phosphorylation; changes in the phosphorylation state of H and M, however, also reflect ongoing addition of phosphates to these polypeptides during axonal transport (Nixon, R.A., Lewis, S.E., and Marotta, C.A. (1986) J. Neurosci., in press). The possibility is raised that dynamic rearrangements of phosphate topography on NFPs represent a mechanism to coordinate interactions of neurofilaments with other proteins as these elements are transported and incorporated into the stationary cytoskeleton along retinal ganglion cell axons.     

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.     

GTP regeneration influences interactions of microtubules, neurofilaments, and microtubule-associated proteins in vitro

Interactions of microtubules, neurofilaments, and microtubule-associated proteins were investigated by turbidity and falling-ball viscometry measurements. We found evidence of endogenous GTPase activity in neurofilaments and microtubule-associated proteins (MAPs) in preparations that do not include urea or heat treatment, respectively. The absence or presence of either adenyl-5'-yl imidodiphosphonic acid or a GTP-regenerating system markedly influenced observed polymerization and gelation characteristics. Most significantly, the apparent viscosity of neurofilament and microtubule samples did not display a biphasic optimal MAP concentration profile when a GTP-regenerating system was operant. Likewise, GTP regeneration promoted the recovery of gelation following mechanical disruption of neurofilament/MAP/microtubule mixtures. These and other observations require some reassessment of proposed roles for microtubule-associated proteins in modulating neurofilament-microtubule interactions in vitro.     

The differential appearance of neurofilament triplet polypeptides in the developing rat optic nerve

The ontogenetic appearance of the individual triplet polypeptides that comprise mammalian neurofilaments was studied in the developing rat optic nerve. Triton-insoluble cytoskeletal preparations from the optic nerves of rats of postnatal ages 1 Day (P1), 6 days (P6), 10 days (P10), 20 days (P20), and 3 months (adult) were analyzed for protein composition by one and two-dimensional gel electrophoresis. Results indicate that at P1, both the 150- and 68-kDa neurofilament subunit proteins are present. The 200-kDa subunit first becomes discernible at P20, but, at this age, it is still present in considerably less quantity than in the adult. Immunocytochemical verification of the presence of neurofilament protein was accomplished by staining tissue sections with specific antibodies against the 150- and the 68-kDa neurofilament subunits using the peroxidase-antiperoxidase technique. Results of the morphological analyses have shown that neurofilaments are not present in quantity until P10, which coincides with the time when the 68-kDa subunit increases in quantity by one dimensional gel analysis. Thus, the 150- and 68-kDa subunits can be detected prior to the appearance of neurofilaments, and the 200-kDa protein is not observed until sometime later. The potential physiological significance of the differential subunit transport is discussed with respect to neuronal differentiation in the developing mammalian CNS.     

In vivo phosphorylation of distinct domains of the 70-kilodalton neurofilament subunit involves different protein kinases

A combination of in vivo and in vitro approaches were used to characterize phosphorylation sites on the 70,000-kilodalton (kDa) subunit of neurofilaments (NF-L) and to identify the protein kinases that are likely to mediate these modifications in vivo. Neurofilament proteins in a single class of neurons, the retinal ganglion cells, were pulse-labeled in vivo by injecting mice intravitreously with [32P]orthophosphate. Radiolabeled neurofilaments were isolated after they had advanced along optic axons, and the individual subunits were separated on sodium dodecyl sulfate-polyacrylamide gels. Two-dimensional alpha-chymotryptic phosphopeptide map analysis of NF-L revealed three phosphorylation sites: an intensely labeled peptide (L-1) and two less intensely labeled peptides (L-2 and L-3). The alpha-chymotryptic peptide L-1 was identified as the 11-kDa segment containing the C terminus of NF-L. The ability of these peptides to serve as substrates for specific protein kinases were examined by incubating neurofilament preparations with [gamma-32P]ATP in the presence of purified cAMP-dependent protein kinase or appropriate activators and/or inhibitors of endogenous cytoskeleton-associated protein kinases. The heparin-sensitive, calcium- and cyclic nucleotide-independent kinase associated with the cytoskeleton selectively phosphorylated L-1 and L-3 but had little, if any, activity toward L-2. When this kinase was inhibited with heparin, cAMP addition to the neurofilament preparation stimulated the phosphorylation of L-2, and addition of the purified catalytic subunit of cAMP-dependent protein kinase induced intense labeling of L-2. At higher labeling efficiencies, the exogenous kinase also phosphorylated L-3 and several sites at which labeling was not detected in vivo; however, L-1 was not a substrate. Calcium and calmodulin added to neurofilament preparations in the presence of heparin modestly stimulated the phosphorylation of L-1 and L-3, but not L-2, and the stimulation was reversed by trifluoperazine. The selective phosphorylation of different polypeptide domains on NF-L by second messenger-dependent and -independent kinases suggests multiple functions for phosphate groups on this protein.     

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.     

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.     

Interactions between neurofilaments and microtubule-associated proteins: a possible mechanism for intraorganellar bridging

Mammalian neurofilaments prepared from brain and spinal cord by either of two methods partially inhibit the in vitro assembly of microtubules. This inhibition is shown to be due to the association of a complex of high molecular weight microtubule-associated proteins (MAP1 and MAP2) and tubulin with the neurofilament. Further analysis of the association reveals a saturable binding of purified brain MAPs to purified neurofilaments with a Kd of 10(-7) M. Purified astroglial filaments neither inhibit microtubule assembly nor show significant binding of MAPs. It is proposed that the MAPs might function as one element in a network of intraorganellar links in the cytoplasm.     

Gene replacement in mice reveals that the heavily phosphorylated tail of neurofilament heavy subunit does not affect axonal caliber or the transit of cargoes in slow axonal transport

The COOH-terminal tail of mammalian neurofilament heavy subunit (NF-H), the largest neurofilament subunit, contains 44-51 lysine-serine-proline repeats that are nearly stoichiometrically phosphorylated after assembly into neurofilaments in axons. Phosphorylation of these repeats has been implicated in promotion of radial growth of axons, control of nearest neighbor distances between neurofilaments or from neurofilaments to other structural components in axons, and as a determinant of slow axonal transport. These roles have now been tested through analysis of mice in which the NF-H gene was replaced by one deleted in the NF-H tail. Loss of the NF-H tail and all of its phosphorylation sites does not affect the number of neurofilaments, alter the ratios of the three neurofilament subunits, or affect the number of microtubules in axons. Additionally, it does not reduce interfilament spacing of most neurofilaments, the speed of action potential propagation, or mature cross-sectional areas of large motor or sensory axons, although its absence slows the speed of acquisition of normal diameters. Most surprisingly, at least in optic nerve axons, loss of the NF-H tail does not affect the rate of transport of neurofilament subunits.     

Characterization of two proteolytically derived soluble polypeptides from the neurofilament triplet components NFM and NFH.

We have purified to homogeneity the regions derived by chymotryptic digestion of the ox neurofilament polypeptides NFH and NFM; the regions, called M1 and M2, are thought to form part of the projecting sidearms of mammalian neurofilaments [Chin, Eagles & Maggs (1983) Biochem. J. 215, 239-252]. They were isolated and purified under non-denaturing conditions and showed no tendency to interact with each other in solution. The Mr values obtained by sedimentation are approx. 61,000 for M1 and 42,000 for M2, considerably lower than the values obtained by SDS/polyacrylamide-gel electrophoresis. These Mr values were unchanged in the presence of 6 M-guanidine hydrochloride, suggesting that the regions exist as monomers in solution. Both M1 and M2 are highly phosphorylated, and there is only a slight change in the sedimentation value upon dephosphorylation. Dephosphorylation of M1 with alkaline phosphatase was more than 90% efficient but was never absolute. Dephosphorylation of M2 was complete. Both M1 and M2 bind Ca2+; in the case of M1, this binding is phosphorylation-dependent. M1 also binds cytochrome c, and dephosphorylation affects binding. In similar conditions, neurofilaments bind at least twice their own mass of cytochrome c, owing to their opposite net charges. No interactions were observed between native or dephosphorylated M1 and M2, and intact neurofilaments under a wide variety of conditions. These results are discussed in terms of the possible roles that neurofilament sidearms might play and throw doubt upon their supposed function of rigidly cross-linking neurofilaments together within the axoplasm of neurons.     

The molecular morphology of bovine heart mitochondrial NADH----ubiquinone reductase. Native disulfide-linked subunits and rotenone-induced conformational changes

Bovine heart mitochondrial NADH----ubiquinone reductase (complex I), contains two disulfide-linked subunits of 75 and 33 kDa as revealed by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis with beta-mercaptoethanol omitted from preparation of the sample for the first dimension. Two unidentified polypeptides (110-115 and 69 kDa) are also found in disulfide linkage with the two complex I subunits. The 110-115-kDa polypeptide appears to be pyridine dinucleotide transhydrogenase by several criteria including selective precipitation with an antibody raised to the purified transhydrogenase. The two disulfide-linked subunits were also found in a product cross-linked for 2 min with dithiobis (succinimidyl propionate) (DSP) along with five other complex I subunits of 53-57, 42, 24-27, 17-18, and 12.5-15.5 kDa (Gondal, J.A., and Anderson, W.M. (1985) J. Biol. Chem. 260, 5931-5935) indicating that these seven subunits lie within 11-12 A of each other at one or more points in space in the enzyme's interior. Cross-linking of complex I with DSP for 2 min in the presence of 1 microM rotenone yielded a cross-linked product consisting of the two natural disulfide-linked subunits and the 110-115- and 69-kDa polypeptides. This suggests that rotenone induces a conformational change in the enzyme that moves the seven DSP cross-linked subunits away from each other and outside the 11-12 A bridging distance of DSP. This alteration in conformation may be communicated to iron-sulfur center N-2 within the hydrophobic outer shell of the enzyme to prevent electron transfer to its natural electron acceptor, ubiquinone. A model of rotenone action based upon these observations is presented.