Macromolecular structure of reassembled neurofilaments as revealed by the quick-freeze deep-etch mica method: difference between NF-M and NF-H subunits in their ability to form cross-bridges.

Neurofilament (NF) structure and ability to form cross-bridges were examined by quick-freeze deep-etch mica and low-angle rotary-shadow electron microscopy in NFs purified from bovine spinal cord and reassembled in various combinations of NF subunits. When NFs were reassembled from triplet proteins, NF-L, NF-M and NF-H, they were oriented randomly and often fragmented, but their elongated filaments (12-15 nm wide) and the cross-bridges (4-5 nm wide) connecting them were similar in appearance to those of isolated bovine NFs or in vivo rat NFs. Projections extended from the wall of the core filament in almost the same pattern as the cross-bridges and were the same in width and interval (minimum interval, 20-25 nm) as the cross-bridges. Projections were more conspicuous when core filaments were separated by 60 to 80 nm or more, while cross-bridges were more conspicuous when core filaments were close to each other. Projections or cross-bridges extended bilaterally at intervals of 20 to 25 nm where core filaments expanded and formed a network between filaments which were far from one another. When NFs were reconstructed from NF-L alone, only core filaments appeared, the same width as the filaments of triplet NFs. The core filaments were occasionally in almost direct contact with each other, with no projection or cross-bridge. When NFs were reassembled from NF-M alone or NF-L + NF-M, although NF-M core filaments were shorter and slightly thinner than NF-L + NF-M core filaments, both had projections, and both had cross-bridges, but cross-bridges were less evident. Cross-bridges were almost the same in width as those of triplet NFs, but significantly shorter and much less frequent although the minimum interval was the same, and core filaments were not attached to each other. In contrast, when NFs were reconstituted from NF-H alone or NF-L + NF-H, both had conspicuous projections and cross-bridges, similar to those of triplet NFs. Thus, when NFs contained NF-H, they formed frequent cross-bridges and long projections with extensive peripheral branching. When NFs contained NF-M but no NF-H, they tended to form cross-bridges, and to form projections that were shorter and straighter and without peripheral branching. That is, there appears to be a significant difference between NF-M and NF-H in ability to form cross-bridges and thus in interaction with adjacent NFs.     

Erratum to: How the projection domains of NF-L and α-internexin determine the conformations of NF-M and NF-H in neurofilaments

Making use of a numerical self-consistent field method and polymer brush concepts, we model the solvated corona of neurofilaments (NF) composed of projection domains (unstructured tails) of constituent proteins. Projections are modeled with amino acid resolution. We focus on the importance of the two shortest ones (α-internexin and NF-L) in regulating the conformations of the two longer ones (NF-M and NF-H) in an isolated NF. We take the wild-type NF with no α-internexin as the reference, for which the phosphorylation-induced translocation of M- and H-tails has been examined previously. We demonstrate that a subbrush of L-tails creates an electrostatic potential profile with an approximately parabolic shape. An experimentally relevant (2:1) ratio of L- to α-projections reduces the charge density of the L subbrush and shifts the translocation transition of the H-tails to slightly higher degrees of phosphorylation. Replacing all L-tails by α-projections destroys the substructure of the NF corona and this alters the NF response to the phosphorylation of long tails.     

Phosphorylation of native and reassembled neurofilaments composed of NF-L, NF-M, and NF-H by the catalytic subunit of cAMP-dependent protein kinase.

Phosphorylation of neurofilament-L protein (NF-L) by the catalytic subunit of cAMP-dependent protein kinase (A-kinase) inhibits the reassembly of NF-L and disassembles filamentous NF-L. The effects of phosphorylation by A-kinase on native neurofilaments (NF) composed of three distinct subunits: NF-L, NF-M, and NF-H, however, have not yet been described. In this paper, we examined the effects of phosphorylation of NF proteins by A-kinase on both native and reassembled filaments containing all three NF subunits. In the native NF, A-kinase phosphorylated each NF subunit with stoichiometries of 4 mol/mol for NF-L, 6 mol/mol for NF-M, and 4 mol/mol for NF-H. The extent of NF-L phosphorylation in the native NF was nearly the same as that of purified NF-L. However, phosphorylation did not cause the native NFs to disassemble into oligomers, as was the case for purified NF-L. Instead, partial fragmentation was detected in sedimentation experiments and by electron microscopic observations. This is probably not due to the presence of the three NF subunits in NF or to differences in phosphorylation sites because reassembled NF containing all three NF subunits were disassembled into oligomeric forms by phosphorylation with A-kinase and the phosphorylation by A-kinase occurred at the head domain of NF-L whether NF were native or reassembled. Disassembling intermediates of reassembled NF containing all three NF subunits were somewhat different from disassembling intermediates of NF-L. Thinning and loosening of filaments was frequently observed preceding complete disassembly. From the fact that the thinning was also observed in the native filaments phosphorylated by A-kinase, it is reasonable to propose the native NF is fragmented through a process of thinning that is stimulated by phosphorylation in the head domain of the NF subunits.     

Interaction between neurofilaments and mitochondria in cultured cells of the rat hippocampus

Interaction between neurofilaments and mitochondria was studied on the model of cultured hippocampal cells of newborn rats. A treatment by specific toxins -iminodipropionitril or hexanedione resulted in a disintegration and translocation of neurofilaments in the cultured neurons. These effects were accompanied by a considerable decrease in dimensions of mitochondria, an increase in their elongation coefficient, a noticeable increase in spatial density of these organelles, and their translocation within the perinuclear layer of cytoplasm. The role of neurofilaments in the intraneuronal distribution of mitochondria and modifications of their functional state is discussed. The neurofilament system is supposed to considerably influence the processes of division, growth, and translocation of the mitochondria.Neirofiziologiya/Neurophysiology, Vol. 27, No. 1, pp. 3–10, January–February, 1995.     

Phosphorylation and assembly of nicotinic acetylcholine receptor subunits in cultured chick muscle cells

The assembly of the nicotinic acetylcholine receptor (AChR), an oligomeric cell surface protein, was studied in cultured muscle cells. To measure this process, the incorporation of metabolically labeled alpha-subunit into oligomeric AChR was monitored in pulse-chase experiments, either by the shift of this subunit from the unassembled (5 S) to the assembled (9 S) position in sucrose density gradients, or by its coprecipitation with antisera specific for the delta-subunit. We have found that AChR assembly is initiated 15-30 min after subunit biosynthesis and is completed within the next 60 min. The alpha-subunit is not overproduced, as all detectable pulse-labeled alpha-subunit can be chased into the oligomeric complex, suggesting that AChR assembly in this system is an efficient process. The rate of AChR assembly is decreased by metabolic inhibitors and by monensin, an ionophore that impairs the Golgi apparatus. We have observed that the gamma- and delta-subunits of AChR are phosphorylated in vivo. The delta-subunit is more highly phosphorylated in the unassembled than in the assembled state, indicating that its phosphorylation precedes assembly and that its dephosphorylation is concomitant with AChR assembly. These findings suggest that subunit assembly occurs in the Golgi apparatus and that phosphorylation/dephosphorylation mechanisms play a role in the control of AChR subunit assembly.     

The C-Terminal Domains of NF-H and NF-M Subunits Maintain Axonal Neurofilament Content by Blocking Turnover of the Stationary Neurofilament Network

Newly synthesized neurofilaments or protofilaments are incorporated into a highly stable stationary cytoskeleton network as they are transported along axons. Although the heavily phosphorylated carboxyl-terminal tail domains of the heavy and medium neurofilament (NF) subunits have been proposed to contribute to this process and particularly to stability of this structure, their function is still obscure. Here we show in NF-H/M tail deletion [NF-(H/M)^tailΔ] mice that the deletion of both of these domains selectively lowers NF levels 3–6 fold along optic axons without altering either rates of subunit synthesis or the rate of slow axonal transport of NF. Pulse labeling studies carried out over 90 days revealed a significantly faster rate of disappearance of NF from the stationary NF network of optic axons in NF-(H/M)^tailΔ mice. Faster NF disappearance was accompanied by elevated levels of NF-L proteolytic fragments in NF-(H/M)^tailΔ axons. We conclude that NF-H and NF-M C-terminal domains do not normally regulate NF transport rates as previously proposed, but instead increase the proteolytic resistance of NF, thereby stabilizing the stationary neurofilament cytoskeleton along axons.     

Synthesis and assembly of the synaptic cleft protein S-laminin by cultured cells.

S-laminin, a homologue of the B1 chain of laminin, is concentrated in a subset of basal laminae (BLs), including the BL at the skeletal neuromuscular junction and bears an adhesive site for motoneuron-like cells. Here, we have begun to characterize the native form of the protein. We show that several muscle- and glia-like cell lines synthesize and secrete S-laminin as well as the A, B1, and B2 subunits of the conventional laminin trimer. Experiments using subunit-specific antibodies showed that S-laminin is complexed with the A and B2 subunits of laminin but not with B1, suggesting that S-laminin replaces B1 to form a novel laminin-like trimer. Comparison of material precipitated by different antibodies provided evidence for two immunochemically distinct forms of S-laminin, both of which associate with B2 and A-like subunits. Analysis of tunicamycin-treated cells indicated that N-linked glycosylation is required neither for the selective association of S-laminin with B2 and A subunits nor for the distinction between two forms of S-laminin. Finally, a full-length S-laminin cDNA was constructed and transfected into muscle and non-muscle cells. S-laminin was detected intracellularly in both cell types, in extracellular matrix of muscle cells, and in two immunochemically distinct forms. Thus, the cDNA contains sufficient information to permit assembly, secretion, and post-translational modification of S-laminin.     

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.     

Neurofilament proteins NF-L, NF-M and NF-H in brain of patients with Down syndrome and Alzheimer's disease

Summary. Neurofilaments (NFs) are integral constituents of the neuron playing a major role in brain development, maintenance, regeneration and the pattern of expression for NFs suggests their contribution to plasticity of the neuronal cytoskeleton and creating and maintaining neuronal architecture. Using immune-histochemical techniques the altered expression of NFs in Down syndrome (DS) and Alzheimer's disease (AD) has been already published but as no corresponding systematic immune-chemical study has been reported yet, we decided to determine proteins levels of three NFs in several brain regions of DS and AD brain. We evaluated immunoreactive NF-H, NF-M and NF-L levels using Western blotting in brain regions temporal, occipital cortex and thalamus of patients with DS (n = 9), AD (n = 9) and controls (n = 12). We found significantly increased NF-H in temporal cortex (controls: means 0.74 ± 0.39 SD; DS: means 3.01 ± 2.18 SD) of DS patients and a significant decrease of NF-L in occipital cortex of DS and AD patients (controls: means 1.19 ± 0.86 SD; DS: means 0.35 ± 0.20; AD: 0.20 ± 0.11 SD). We propose that the increase of NF-H in temporal cortex of DS brain is due to neuritic sprouting as observed in immune-histochemical studies. The increase may not be caused by the known accumulation of NFs in plaques, tangles or Lewy bodies due to our solubilization protocol. The decrease of NF-L in occipital cortex of DS and AD patients may well be reflecting neuronal loss. Altogether, however, we suggest that NFs are not reliable markers for neuronal death, a hallmark of both neurodegenerative diseases, in DS or AD. The increase of NF-H in DS or the decrease of NF-L in DS and AD leaves the other NFs unchanged, which points to dysregulation in DS and AD and raises the question of impaired structural assembly of neurofilaments. Received July 19, 2000 Accepted July 28, 2000     

Interactions of annexins with the mu subunits of the clathrin assembly proteins

A number of biochemical and genetic studies have suggested that certain annexins play important roles in the endocytic pathway, possibly involving the generation, localization, or fusion of endocytic compartments. In a yeast two-hybrid screen for proteins that interact with the N-terminal domain of annexin A2 we identified the mu2 subunit of the clathrin assembly protein complex AP-2. The interaction depended upon two copies of a Yxx phi amino acid sequence motif (Y = tyrosine, x = variable residue, phi = bulky, hydrophobic residue) in the annexin that is also characteristic of the binding site for mu2 on the cytoplasmic domains of transmembrane receptors. The interaction between mu2 and full-length annexin A2 was demonstrated in vitro to be direct, to require calcium, and to be functional in the sense that annexin A2 was able to recruit the mu2 to immobilized lipids. Examination of other annexins and mu subunits demonstrated that annexin A2 also binds the mu1 subunit of the AP-1 complex, that annexin A6 binds mu1 and mu2, and that annexin A1 binds only mu1. We propose that annexins can "masquerade" as transmembrane receptors when they are attached to membranes in the presence of calcium and that they might therefore function to initiate calcium-regulated coated pit formation at the cell surface or on intracellular organelles.     

Antagonistic Roles of Neurofilament Subunits NF-H and NF-M Against NF-L in Shaping Dendritic Arborization in Spinal Motor Neurons

Dendrites play important roles in neuronal function. However, the cellular mechanism for the growth and maintenance of dendritic arborization is unclear. Neurofilaments (NFs), a major component of the neuronal cytoskeleton, are composed of three polypeptide subunits, NF-H, NF-M, and NF-L, and are abundant in large dendritic trees. By overexpressing each of the three NF subunits in transgenic mice, we altered subunit composition and found that increasing NF-H and/or NF-M inhibited dendritic arborization, whereas increasing NF-L alleviated this inhibition. Examination of cytoskeletal organization revealed that increasing NF-H and/or NF-M caused NF aggregation and dissociation of the NF network from the microtubule (MT) network. Increasing NF-H or NF-H together with NF-M further reduced NFs from dendrites. However, these changes were reversed by elevating the level of NF-L with either NF-H or NF-M. Thus, NF-L antagonizes NF-H and NF-M in organizing the NF network and maintaining a lower ratio of NF-H and NF-M to NF-L is critical for the growth of complex dendritic trees in motor neurons.     

Interactions between mitochondrial bioenergetics and cytoplasmic calcium in cultured cerebellar granule cells

The mitochondrion has moved to the center stage in the drama of the life and death of the neuron. The mitochondrial membrane potential controls the ability of the organelle to generate ATP, generate reactive oxygen species and sequester Ca(2+) entering the cell. Each of these processes interact, and their deconvolution is far from trivial. The cultured cerebellar granule cell provides a model in which knowledge gained from studies on isolated mitochondria can be applied to study the role played by the organelles in the maintenance of Ca(2+) homeostasis in the cell under resting, stimulated and pathophysiological conditions. In particular, mitochondria play a complex role in the response of the neuron to excitotoxic stimulation of NMDA and AMPA-kainate selective glutamate receptors. One goal of research in this area is to provide clues as to possible ways in which modulators of mitochondrial function may be used as neuroprotective agents, since mitochondrial Ca(2+) accumulation seems to play a key role in glutamate excitotoxicity.     

Assembly Properties of Amino- and Carboxyl-Terminally Truncated Neurofilament NF-H Proteins with NF-L and NF-M in the Presence and Absence of Vimentin

Abstract: To understand the assembly characteristics of the high-molecular-weight neurofilament protein (NF-H), carboxyl- and amino-terminally deleted NF-H proteins were examined by transiently cotransfecting mutant NF-H constructs with the other neurofilament triplet proteins, low- and middle-molecular-weight neurofilament protein (NF-L and NF-M, respectively), in the presence or absence of cytoplasmic vimentin. The results confirm that NF-H can coassemble with vimentin and NF-L but not with NF-M into filamentous networks. Deletions from the amino-terminus show that the N-terminal head is necessary for the coassembly of NF-H with vimentin, NF-L, or NF-M/vimentin. However, headless NF-H or NF-H from which the head and a part of the rod is removed can still incorporate into an NF-L/vimentin network. Deletion of the carboxyl-terminal tail of NF-H shows that this region is not essential for coassembly with vimentin but is important for coassembly with NF-L into an extensive filamentous network. Carboxyl-terminal deletion into the α-helical rod results in a dominant-negative mutant, which disrupts all the intermediate filament networks. These results indicate that NF-L is the preferred partner of NF-H over vimentin and NF-M, the head region of NF-H is important for the formation of NF-L/NF-H filaments, and the tail region of NF-H is important to form an extensive network of NF-L/NF-H filaments.     

Tight junction development between cultured hepatoma cells: Possible stages in assembly and enhancement with dexamethasone

Freeze-fracture and thin-section methods were used to study tight junction formation between confluent H4-II-E hepatoma cells that were plated in monolayer culture in media with and without dexamethasone, a synthetic glucocorticoid. Three presumptive stages in the genesis of tight junctions were suggested by these studies: (1) “formation zones” (smooth P-fracture face ridges deficient in intramembranous particles), apparently matched across a partially reduced extracellular space, develop between adjacent cells; (2) linear strands and aggregates of 9–11 nm particles collect along the ridges of the formation zones. The extracellular space was always reduced when these structures were found matched with pits in gentle E-face depressions; (3) the linear arrays of particles on the ridges associate within the membranes to form the fibrils characteristic of mature tight junctions. The formation zones resemble tight junctions in terms of size, complexity and the patterns of membrane ridges. Although some of the beaded particle specialization may actually be gap junctions, it is unlikely that all can be interpreted in this way. No other membrane structures were detected that could represent developmental stages of tight junctions. Dexamethasone (at 2 × 10^?6 M) apparently stimulated formation of tight junctions. Treated cultures had a greater number of formation zones and mature tight junctions, although no differences in qualitative features of the junctions were noted.     

Post-translational assembly and glycosylation of laminin subunits in parietal endoderm-like F9 cells.

Non-reducing and reducing sodium dodecyl sulphate/polyacrylamide-gel electrophoresis of laminin synthesized in parietal endoderm-like F9 cells demonstrated that only AB1B2 complex goes through intracellular traffic for oligosaccharide side-chain processing and secretion. Glycosylation was not necessary for subunit assembly. Assembly was suggested to proceed through B1B2 to AB1B2. Among the pools of monomer subunits, the B2 pool was smallest.     

Interactions between rho and gamma2 subunits of the GABA receptor

The gamma-aminobutyric acid type C (GABA(C)) receptor is a ligand-gated chloride channel with distinct physiological and pharmacological properties. Although the exact subunit composition of native GABA(C) receptors has yet to be firmly established, there is general agreement that GABA rho subunits participate in their formation. Recent studies on white perch suggest that certain GABA rho subunits can co-assemble with the GABA(A) receptor gamma2 subunit to form a heteromeric receptor with electrophysiological properties that correspond more closely to the native GABA(C) receptor on retinal neurons than any of the homomeric rho receptors. In the present study we examined the interactions among various perch GABA rho and gamma2 subunits. When co-expressed in Xenopus oocytes, the gamma2 subunit co-immunoprecipitated with Flag-tagged perch rho1A, rho1B, and rho2B subunits, but not with the Flag-tagged perch rho2A subunit. Immunocytochemical studies indicated that the membrane surface expression of the gamma2 subunit was detected only when it was co-expressed with perch rho1A, rho1B, or rho2B subunit, but not with the perch rho2A subunit or when expressed alone. In addition, co-immunoprecipitation of perch rho1B and gamma2 subunits was also detected in protein samples of the teleost retina. Taken together, these findings suggest that a heteromeric rho(gamma2) receptor could represent one form of GABA(C) receptor on retinal neurons.     

Biosynthesis and processing of the large and small subunits of succinate dehydrogenase in cultured mammalian cells.

Monospecific polyclonal antisera have been raised to purified bovine heart succinate dehydrogenase and to the individual large and small subunits of this enzyme. These antisera exhibit cross-reactivity with the corresponding polypeptides in rat liver (BRL), pig kidney (PK-15) and bovine kidney (NBL-1) cell lines, and were employed to investigate some of the events involved in the biogenesis of succinate dehydrogenase in the PK-15 cell line. Newly-synthesized forms of the large and small subunits of succinate dehydrogenase were detected in cultured PK-15 and BRL cells labelled with [35S]methionine in the presence of uncouplers of oxidative phosphorylation. In PK-15 cells, the precursor forms of the large and small subunits exhibit Mr values approx. 1000-2000 and 4000-5000 greater than those of the corresponding mature forms. When the uncoupler is removed in pulse-chase experiments, complete conversion of the precursors to the mature forms occurs within 45 min. Studies on the kinetics of processing and stability of the large subunit precursor revealed that reversal of precursor accumulation is rapid, with processing occurring with a half-time of 5-7.5 min, and that the accumulated precursor exhibits long-term stability when PK-15 cells are maintained in the presence of 2,4-dinitrophenol.