Monomer-polymer equilibria in the axon: direct measurement of tubulin and actin as polymer and monomer in axoplasm

Assembly and exchange of intermediate filament proteins of neurons: neurofilaments are dynamic structures

We have explored the dynamics of intermediate filament assembly and subunit exchange using fluorescently labeled neurofilament proteins and a fluorescence resonance energy transfer assay. Neurofilaments (NFs) are assembled from three highly phosphorylated proteins with molecular masses of 180 (NF-H), 130 (NF-M), and 66 kD (NF-L) of which NF-L forms the structural core. The core component, NF-L, was stoichiometrically labeled at cysteine 321 with fluorescein, coumarin, or biotin-maleimide to produce assembly-competent fluorescent or biotinylated derivatives, respectively. Using coumarin-labeled NF-L as fluorescence donor and fluorescein-labeled NF-L as the fluorescence acceptor, assembly of NF filaments was induced by rapidly raising the NaCl concentration to 170 mM, and the kinetics was followed by the decrease in the donor fluorescence. Assembly of NF-L subunits into filaments does not require nucleotide binding or hydrolysis but is strongly dependent on ionic strength, pH, and temperature. The critical concentration of NF-L, that concentration that remains unassembled at equilibrium with fully formed filaments, is 38 micrograms/ml or 0.6 microM. Under physiological salt conditions NF-L filaments also undergo extensive subunit exchange. Kinetic analysis and evaluation of several possible mechanisms indicate that subunit exchange is preceded by dissociation of subunits from the filament and generation of a kinetically active pool of soluble subunits. Given the concentration of NF-L found in nerve cells and the possibility of regulating this pool, these results provide the first information that intermediate filaments are dynamic structures and that NF-L within the NF complex is in dynamic equilibrium with a small but kinetically active pool of unassembled NF-L units.

Copurification of kinesin polypeptides with microtubule-stimulated Mg-ATPase activity and kinetic analysis of enzymatic properties

Determination of kinetic properties for kinesin adenosine triphosphatase (ATPase), a proposed motor for transport of membranous organelles, requires adequate amounts of kinesin with a consistent level of enzymatic activity. A purification procedure is detailed that produces approximately 2 mg of kinesin at up to 96% purity from 800 g of bovine brain. This protocol consists of a microtubule affinity step using 5'-adenylylimidodiphosphate (AMP-PNP); followed by gel filtration, ion exchange, and hydroxylapatite chromatography; and then sucrose density gradient centrifugation. The microtubule-activated ATPase activity of kinesin coeluted with kinesin polypeptides throughout the purification. Highly purified kinesin had a Vmax of 0.31 mumol/min/mg in the presence of microtubules, with a Km for ATP of 0.20 mM. The kinetic constants obtained in these studies compare favorably with physiological levels of ATP and microtubules. Variations in buffer conditions for the assay were found to affect ATPase activity significantly. A study of the ability of kinesin to utilize a variety of cation-ATP complexes indicated that kinesin is a microtubule-stimulated Mg-ATPase, but kinesin is able to hydrolyze Ca-ATP, Mn-ATP, and Co-ATP as well as Mg-ATP in the presence of microtubules. In the absence of microtubules, Ca-ATP appears to be the best substrate. Studies with several inhibitors of ATPases determined that vanadate inhibited kinesin ATPase at the lowest concentrations of inhibitor, but significant inhibition of the ATPase also occurred with submillimolar concentrations of AMP-PNP. Other inhibitors of kinesin include N-ethylmaleimide, adenosine diphosphate (ADP), pyrophosphate, and tripolyphosphate. Further characterization of the kinetic properties of the kinesin ATPase is important for understanding the molecular mechanisms for transport of membranous organelles along microtubules.

A model for slow axonal transport and its application to neurofilamentous neuropathies

A model for slow axonal transport is developed in which the essential features are reversible binding of cytoskeletal elements and of soluble cytosolic proteins to each other and to motile elements such as actin microfilaments. Computer simulation of the equations of the model demonstrate that the model can account for many of the features of the SCa and SCb waves observed in pulse experiments. The model also provides a unified explanation for the increase and decrease of neurofilament transport rates observed in various toxicant-induced neuropathies.

Progressive axonopathy: an inherited neuropathy of boxer dogs. An immunocytochemical study of the axonal cytoskeleton

The distribution of the major axonal cytoskeletal proteins has been determined in lumbar ventral roots and spinal cord of dogs with progressive axonopathy, an inherited neuropathy of boxer dogs. The three neurofilament proteins, and beta-tubulin, actin and fodrin were localized using immunocytochemistry. The majority of swollen axons in the nerve roots contained excessive, disorientated neurofilaments. In about 5% of such fibres the peripheral filaments in the axoplasm were orientated circumferentially and such zones were deficient in tubulin. Many, but not all, spheroids contained increased amounts of actin, often with internal areas of more intense staining. Similar findings were present in axonal swellings in the CNS, although their contents were more variable. The distribution of axonal fodrin in CNS and PNS appeared unaltered. The perikarya of many motor neurons in the spinal cord and brain stem contained phosphorylated neurofilaments. The results support previous suggestions that defects in slow axonal transport are involved in the pathogenesis of this disease.

Immunoelectron microscopic localization of actin in neurites of cultured embryonic chick dorsal root ganglia: actin is a component of granular, microtubule-associated crossbridges

Axons have been shown to contain substantial quantities of actin distributed along their length. However, the general lack of information on the structure and organizational state of this protein in axons has made it difficult to assign it a functional role. In the present study, we used electron microscopic immunocytochemistry (immunogold labeling) on neurites from cultured embryonic chick dorsal root ganglia to: (1) determine the distribution of actin in neurites: (2) identify actin-containing structures; and (3) reveal whether or not actin is associated preferentially with microtubules. Results show that actin is present throughout neurites but is organized primarily into short filaments that are localized almost exclusively to granular, microtubule-associated crossbridges. We propose that these short actin filaments are part of the framework of a supramolecular 'carrier complex' for the slow component b polypeptides. In addition, actin-containing crossbridges are often closely associated with the surfaces of membrane-bound organelles. This suggests that actin and microtubule-associated crossbridges are involved somehow in fast axonal transport, although the nature of their participation in this process still needs to be resolved.

Subcellular localization of functionally differentiated microtubules in squid neurons: regional distribution of microtubule-associated proteins and beta-tubulin isotypes

The subcellular localization of microtubule proteins in the neurons of squid (Doryteuthis bleekeri) was immunologically studied using monoclonal antibodies against the microtubule proteins. We found that (1) the squid neurons contained three kinds of high-molecular-weight microtubule-associated proteins [MAP A of approximately 300 kilodaltons (kD), MAP B of 260 kD, and axolinin of 260 kD] and two kinds of beta-tubulin isotypes (beta 1 and beta 2); (2) the cell body of the squid giant neuron contained MAP A, MAP B, and the two beta-tubulin isotypes (beta 1 and beta 2); (3) axolinin and the beta 1 isotype were present exclusively in the peripheral axoplasm of the giant axon; and (4) a small amount of axolinin, MAP A, and the beta 1 isotype was found in the insoluble aspect of the central axoplasm, whereas the soluble aspect of the central axoplasm contained an abundant amount of MAP A along with the modified form of the beta 1 isotype. The regional difference of the distribution of the microtubule protein components may explain the differences in stability among axonal microtubules. Microtubules in the soluble aspect of the central axoplasm are sensitive to any treatment with colchicine, cold temperature, and high ionic strength but those both in the insoluble aspect of the central axoplasm and in the peripheral axoplasm are highly insensitive to the treatment.

Dynamic instability of native microtubules from squid axons is rare and independent of gliding and vesicle transport

Dynamic instability characterizes the steady-state behavior of microtubules in vitro whereby polymer mass remains constant, while individual microtubules in the population may either grow or shrink. Video-enhanced contrast light microscopy was used to directly observe dynamic length changes in native, MAP-containing microtubules from squid axoplasm. We wanted to determine whether dynamic instability characterizes the steady-state behavior of axoplasmic microtubules in vitro. The lengths of a representative population of over 400 microtubules were analyzed. "Dynamic" microtubules were found to represent about 2% of the population. This observation is different from that described for cultured cells or microtubules assembled from PC-purified tubulin where most microtubules were either growing or shrinking.

Two classes of actin microfilaments are associated with the inner cytoskeleton of axons

The distribution and length of actin microfilaments (MF) was determined in axoplasm extruded from the giant axons of the squid (Loligo pealeii). Extruded axoplasm that was separated from the axonal cortex contains approximately 92% of the total axonal actin, and 60% of this actin is polymerized (Morris, J., and R. Lasek. 1984. J. Cell Biol. 98:2064-2076). Localization of MF with rhodamine-phalloidin indicated that the MF were organized in fine columns oriented longitudinally within the axoplasm. In the electron microscope, MF were surrounded by a dense matrix and they were associated with the microtubule domains of the axoplasm. The surrounding matrix tended to obscure the MF which may explain why MF have rarely been recognized before in the inner regions of the axon. The axoplasmic MF are relatively short (number average length of 0.55 micron). Length measurements of MF prepared either in the presence or absence of the actin-filament stabilizing drug phalloidin indicate that axoplasm contains two populations of MF: stable MF (number average length of 0.79 micron) and metastable MF (number average length of 0.41 micron). Although individual axonal MF are much shorter than axonal microtubules, the combined length of the total MF is twice that of the total microtubules. Apparently, these numerous short MF have an important structural role in the architecture of the inner axonal cytoskeleton.

Microtubule stability in severed axons

We examined severed axons of cat sympathetic nerves and severed neurites of cultured chick sensory neurons for evidence of extensive microtubule depolymerization. Cat sympathetic fibres fixed at various times after severing were cross-sectioned for electron microscopy from both cut ends. The number density of microtubules was determined at various times after severing for matched proximal and distal regions equidistant from cut ends. These data show that the number density of microtubules was nearly identical in proximal and distal fragments at 10, 20 and 60 min and at distances between 10 and 50 micron from the cut ends. In chick sensory neurites the microtubule array was examined in longitudinal sections. In order to define objectively a normal microtubule array, the distance between 100 microtubule pairs was measured in seven control neurites, giving a mean distance (+/- S.D.) of 33 nm +/- 19 nm. A normal array of microtubules was defined as having microtubules within 52 nm of their nearest lateral neighbour. Among 11 neurites at times from 1 to 15 min after transection, the mean distance from the cut tip to the first microtubule was 1.3 micron in proximal fragments and 0.5 micron in distal fragments. The mean distance to the normal microtubule array was 2.8 micron in proximal fragments and 2.1 micron in distal fragments. There was no trend or pattern with respect to the times after severing that the neurite was fixed and the amount of microtubule depolymerization. Our results show no evidence for stabilization of axonal/neurite microtubules by capping structures at their ends. We conclude that microtubule instability is unlikely to play a role in the response of axons to axotomy.

Morphology of freeze-substituted myelinated axon in mouse peripheral nerves

In order to clarify the in situ shape of axons, the entire shape of freeze-substituted axons (FS axons) was compared with that of chemically-fixed axons (CF axons) using the serial semi-thin section method coupled with rapid freezing technique. Mouse saphenous nerves were rapidly frozen by being contacted against a pure copper block cooled to 4 K by liquid helium. At the internode, the FS axons showed a cylindrical outline while the CF axons showed a polygonal contour. At regions near the node of Ranvier, both FS and CF axons showed a cog-wheel contour, and at the node they became circular and highly attenuated. These findings indicated that the axons, at the internode, were artifactually distorted during chemical fixation and that the in situ shape of myelinated axons was characterized by the cylindrical internodal segment, the distorted juxtaparanodal segment and the attenuated nodal segment. The physiological meanings of the entire shape of axons were discussed with special reference to the molecular mechanism of slow axonal transport and membrane excitation.

Microtubule reassembly from nucleating fragments during the regrowth of amputated neurites

We have proposed that stable microtubule (MT) fragments that resist depolymerization may serve as nucleating elements for the local control of MT dynamics in the axon (Heidemann, S. R., M. A. Hamborg, S. J. Thomas, B. Song, S. Lindley, and D. Chu, 1984, J. Cell Biol., 99:1289-1295). Here we report evidence that supports this proposal in studies on the role of MTs in the regrowth of neurites from the distal segments of amputated chick sensory neurites. Amputated neurites collapse to "beads" of axoplasm that rapidly regrow (Shaw, G., and D. Bray, 1977, Exp. Cell Res., 104:55-62). We examined both unarrested regrowth and regrowth after MT disassembly by either cold (-5 degrees C for 2 h) or nocodazole (0.1 microgram/ml for 15-20 min). In all these cases regrowth occurred at 3.5-4.5 micron/min with no delay times other than the times to reach 37 degrees C or rinse out the nocodazole. Electron micrographs of untreated beads show many MTs of varying lengths, while those of cold- and nocodazole-treated beads show markedly shorter MTs. The robust regrowth of neurites from beads containing only very short MTs argues against unfurling of intact MTs from the bead into the growing neurite. Electron micrographs of cold-treated beads lysed under conditions that cause substantial MT depolymerization in untreated intact neurites show persistent MT fragments similar to those in unlysed cold-treated beads. We interpret this as evidence that the MT fragments in cold-treated beads are somehow distinct from the majority of the MT mass that had depolymerized. Collapsed neurites treated with a higher dose of nocodazole (1.0 microgram/ml for 15-20 min) were completely devoid of MTs and regrew only after a 15-20 min delay in two cases but never regrew in 11 other cases. We found that MTs did not return in beads treated with 1.0 microgram/ml nocodazole even 30 min after removal of the drug. It was unlikely that the inability of these beads to reassemble MTs was due to incomplete removal of nocodazole in that a much higher dose (20 micrograms/ml nocodazole) could be quickly rinsed from intact neurites. Beads treated with 1.0 microgram/ml nocodazole could, however, be stimulated to reassemble MTs and regrow neurites by treatment with taxol. We conclude that the immediate, robust regrowth of neurites from collapsed beads of axoplasm requires MT nucleation sites to support MT reassembly.(ABSTRACT TRUNCATED AT 400 WORDS)

Diabetic rat serum has an increased capacity to inhibit brain microtubule formation in vitro

The assembly of pig brain microtubule proteins was measured in vitro in the presence of serum from control rats and rats that had been rendered diabetic with 50 mg/kg streptozotocin 14 d previously. Control serum inhibited total microtubule assembly and increased the lag time before assembly commenced. Serum from diabetic animals was significantly more potent in both respects. The effect on lag time was reproduced in a predominantly albumin-containing fraction of serum that had been fractionated by affinity chromatography. Glycosylation of rat albumin in vitro led to an increase in its ability to increase polymerization lag time, but the concentration of albumin required was greater than that found in the serum fractions. The results indicate that diabetic serum contains factors that can adversely affect microtubule formation and that part of this effect may be caused by the presence of glycosylated albumin. This phenomenon may underlie some of the complications associated with diabetes.

Restricted diffusion of tyrosine hydroxylase and phenylethanolamine N-methyltransferase from digitonin-permeabilized adrenal chromaffin cells

Tyrosine hydroxylase [TyrOHase; tyrosine 3-monooxygenase; L-tyrosine,tetrahydropteridine:oxygen oxidoreductase (3-hydroxylating), EC 1.14.16.2] and phenylethanolamine N-methyltransferase, EC 2.1.1.28) are involved in catecholamine biosynthesis and are considered soluble proteins. However, they may actually be localized on the surface of the chromaffin granule. We have used the detergent digitonin to permeabilize the plasma membrane of cultured adrenal chromaffin cells to investigate the subcellular localization of TyrOHase and PMTase. A digitonin titration of the release of proteins and catecholamines revealed the existence of at least three subcellular compartments that are distinguished by their digitonin sensitivity: (i) soluble proteins, which were released upon treatment of the cells with low digitonin concentrations (5 microM), (ii) a "digitonin-sensitive" cytoplasmic protein pool, which required higher concentrations of digitonin for release (10 microM) and included TyrOHase and PMTase, and (iii) the chromaffin granule, which was insensitive to digitonin. Analysis of the rates of release of all of these proteins revealed that the rate of TyrOHase and PMTase release was slower at 10 microM than at 40 microM digitonin, while the rates of release of the other proteins were similar at both concentrations and varied in proportion to their respective sizes. Treatment with cytoskeletal disrupting agents had no effect on TyrOHase or PMTase efflux. These data suggest that TyrOHase and PMTase are in a detergent-labile association in the cell. This is consistent with the concept that TyrOHase and PMTase may be localized on the surface of the chromaffin granule.

Subaxolemmal cytoskeleton in squid giant axon. II. Morphological identification of microtubule- and microfilament-associated domains of axolemma

In the preceding paper (Kobayashi, T., S. Tsukita, S. Tsukita, Y. Yamamoto, and G. Matsumoto, 1986, J. Cell Biol., 102:1710-1725), we demonstrated biochemically that the subaxolemmal cytoskeleton of the squid giant axon was highly specialized and mainly composed of tubulin, actin, axolinin, and a 255-kD protein. In this paper, we analyzed morphologically the molecular organization of the subaxolemmal cytoskeleton in situ. For thin section electron microscopy, the subaxolemmal cytoskeleton was chemically fixed by the intraaxonal perfusion of the fixative containing tannic acid. With this fixation method, the ultrastructural integrity was well preserved. For freeze-etch replica electron microscopy, the intraaxonally perfused axon was opened and rapidly frozen by touching its inner surface against a cooled copper block (4 degrees K), thus permitting the direct stereoscopic observation of the cytoplasmic surface of the axolemma. Using these techniques, it became clear that the major constituents of the subaxolemmal cytoskeleton were microfilaments and microtubules. The microfilaments were observed to be associated with the axolemma through a specialized meshwork of thin strands, forming spot-like clusters just beneath the axolemma. These filaments were decorated with heavy meromyosin showing a characteristic arrowhead appearance. The microtubules were seen to run parallel to the axolemma and embedded in the fine three-dimensional meshwork of thin strands. In vitro observations of the aggregates of axolinin and immunoelectron microscopic analysis showed that this fine meshwork around microtubules mainly consisted of axolinin. Some microtubules grazed along the axolemma and associated laterally with it through slender strands. Therefore, we were led to conclude that the axolemma of the squid giant axon was specialized into two domains (microtubule- and microfilament-associated domains) by its underlying cytoskeletons.

Subaxolemmal cytoskeleton in squid giant axon. I. Biochemical analysis of microtubules, microfilaments, and their associated high-molecular-weight proteins

Using the squid giant axon, we analyzed biochemically the molecular organization of the axonal cytoskeleton underlying the axolemma (subaxolemmal cytoskeleton). The preparation enriched in the subaxolemmal cytoskeleton was obtained by squeezing out the central part of the axoplasm using a roller. The electrophoretic banding pattern of the subaxolemmal cytoskeleton was characterized by large amounts of two high-molecular-weight (HMW) proteins (260 and 255 kD). The alpha, beta-tubulin, actin, and some other proteins were also its major constituents. The 260-kD protein is known to play an important role in maintaining the excitability of the axolemma (Matsumoto, G., M. Ichikawa, A. Tasaki, H. Murofushi, and H. Sakai, 1983, J. Membr. Biol., 77:77-91) and was recently designated "axolinin" (Sakai, H., G. Matsumoto, and H. Murofushi, 1985, Adv. Biophys., 19:43-89). We purified axolinin and the 255-kD protein in their native forms and further characterized their biochemical properties. The purified axolinin was soluble in 0.6 M NaCl solution but insoluble in 0.1 M NaCl solution. It co-sedimented with microtubules but not with actin filaments. In low-angle rotary-shadowing electron microscopy, the axolinin molecule in 0.6 M NaCl solution looked like a straight rod approximately 105 nm in length with a globular head at one end. On the other hand, the purified 255-kD protein was soluble in both 0.1 and 0.6 M NaCl solution and co-sedimented with actin filaments but not with microtubules. The 255-kD protein molecule appeared as a characteristic horseshoe-shaped structure approximately 35 nm in diameter. Furthermore, the 255-kD protein showed no cross-reactivity to the anti-axolinin antibody. Taken together, these characteristics lead us to conclude that the subaxolemmal cytoskeleton in the squid giant axon is highly specialized, and is mainly composed of microtubules and a microtubule-associated HMW protein (axolinin), and actin filaments and an actin filament-associated HMW protein (255-kD protein).

Effects of vanadate on the assembly and disassembly of purified tubulin

Sodium-orthovanadate (100-700 microM) added to purified pig brain microtubule protein (molar ratios 13-90 moles vanadate/mole tubulin) inhibits to a considerable extent the assembly (up to 65%) and the disassembly rates (up to 60%) of microtubules, as determined by turbidimetry. Vanadate added to preformed microtubules did not appreciably alter the turbidity level of the samples, however, the disassembly rates were decreased in the same manner as when vanadate was added prior to polymerization. Microtubule protein kept on ice for 3-6 hours became more susceptible to vanadate than freshly prepared protein. The effect of vanadate was independent of the GTP concentration at which the polymerization assays were performed (0.025 to 1 mM GTP). In the presence of taxol, which increases the rate and extent of microtubule formation, vanadate had no effect on assembly rates. Disassembly was inhibited, however, much less than in the presence of vanadate alone. Electron microscopy and polyacrylamide gel electrophoresis did not reveal differences between microtubules prepared in the presence or in the absence of vanadate. This is consistent with the notion that vanadate does not interfere with the interaction between tubulin and the high-molecular weight microtubule-associated proteins. Apparently vanadate brings about an allosteric change of the microtubule protein(s) resulting in the abnormal polymerization kinetics of tubulin found in our study. The above results may be relevant for studies where the effects of vanadate on intracellular motility are interpreted as being solely due to a specific inhibition of ATPases.

Axonal branch shapes

To distinguish the relative roles of the intrinsic and the extrinsic determinants of axonal branching shapes, a number of key branch parameters were measured under a variety of conditions. Branch shapes of frog and of chick axons were analyzed in tissue culture, and these in vitro patterns were compared with in vivo branch patterns of axons in tadpole tail fins. The shape of a branch junction can be characterized by the sizes of its branch angles. In all cases, branch junctions had only two branches (3 branch angles), and the bifurcation angle between them was usually the smallest. The shape of the branch junction was constant in a wide variety of environments, but the exact branch angles, as well as the numbers of branches per axon and the numbers of axons per neuron, could be modulated by changes in the substrate adhesivity.

Microtubules and caliber of central and peripheral processes of sensory axons

The microtubular content and caliber of sensory axons were studied in the L7 dorsal root, at the distal pole of the L7 spinal ganglion, and in the sural nerve of cats. Calibers of myelinated axons were symmetrical about the ganglion. In contrast, nonmedullated axons were strikingly different; 80% of the population at the root were smaller than 0.4 micron2, whilst just across the ganglion the same group was less than 20%. The microtubule densities of myelinated axons of the root were 11.8 and 6.1 microtubules/micron2 for 3- and 10 microns diameter axons, respectively. Across the ganglion the densities of myelinated axons of equal sizes were 24.2 and 14.4 microtubules/micron2, respectively. These values represent an approximate ratio of 1:2 between central and peripheral microtubule densities. Microtubule densities for nonmedullated axons also decreased with the increase in the cross-sectional area. The densities of root nonmedullated axons ranged between 90 and 10 microtubules/micron2; these were smaller, usually by a factor of three, than the densities of peripheral axons of a similar size (range: 367-44). Contrasting with the differences observed across the ganglion, the microtubular content and caliber of sensory axons seems to be quite uniform along their peripheral course. This is supported by the similar values found in the juxtaganglionic and sural nerves. It is estimated that an axon that contains 90 microtubules/micron2 has 26.7 mg of tubulin per ml of axoplasm in its assembled form, and 3.0 mg/ml if it contains 10 microtubules/micron2; these values are the practical limits of assembled tubulin in axoplasms.(ABSTRACT TRUNCATED AT 250 WORDS)

Proteins transported in slow components a and b of axonal transport are distributed differently in the transverse plane of the axon

The distribution of the proteins migrating with the slow components a (SCa) and b (SCb) of axonal transport were studied in cross-sections of axons with electron microscope autoradiography. Radiolabeled amino acids were injected into the hypoglossal nucleus of rabbits and after 15 d, the animals were killed. Hypoglossal nerves were processed either for SDS-polyacrylamide gel electrophoresis fluorography to identify and locate the two components of slow transport, or for quantitative electron microscope autoradiography. Proteins transported in SCa were found to be uniformly distributed within the cross-section of the axon. Labeled SCb proteins were also found throughout the axonal cross-section, but the subaxolemmal region of the axon contained 2.5 times more SCb radioactivity than any comparable area in the remainder of the axon.

Organelle, bead, and microtubule translocations promoted by soluble factors from the squid giant axon

A reconstituted system for examining directed organelle movements along purified microtubules has been developed. Axoplasm from the squid giant axon was separated into soluble supernatant and organelle-enriched fractions. Movement of axoplasmic organelles along MAP-free microtubules occurred consistently only after addition of axoplasmic supernatant and ATP. The velocity of such organelle movement (1.6 micron/sec) was the same as in dissociated axoplasm. The axoplasmic supernatant also supported movement of microtubules along a glass surface and movement of carboxylated latex beads along microtubules at 0.5 micron/sec. The direction of microtubule movement on glass was opposite to that of organelle and bead movement on microtubules. The factors supporting movements of microtubules, beads, and organelles were sensitive to heat, trypsin, AMP-PNP and 100 microM vanadate. All of these movements may be driven by a single, soluble ATPase that binds reversibly to organelles, beads, or glass and generates a translocating force on a microtubule.

Video microscopy of fast axonal transport in extruded axoplasm: a new model for study of molecular mechanisms

The development of AVEC-DIC microscopy and the application of this method to the study of fast axonal transport in isolated axoplasm extruded from the giant axon of the squid Loligo pealei provides a new paradigm for analyzing the intracellular transport of membranous organelles. The size of the axon, the number of transported particles, and the absence of permeability barriers like the plasma membrane in this preparation permit many experiments that are difficult or impossible to perform using other model systems. The use and features of this preparation are described in detail and a number of properties are evaluated for the first time. The process of extrusion is characterized. Particle movement is evaluated both in the interior of extruded axoplasm and along individual fibrils that extend from the periphery of perfused axoplasm. The role of divalent cations, particularly Ca2+, and the effects of elevated Ca2+ on axoplasmic organization and transport are analyzed. A series of pharmacological agents and polypeptides that alter cytoskeletal organization are used to examine the role of microfilaments and microtubules in fast transport. Finally, the effects of depleting ATP and of adding ATP analogues are discussed. The extruded axoplasm preparation is shown to be an invaluable model system for biochemical and pharmacological analyses of the molecular mechanisms of intracellular transport.

Solubility properties of neuronal tubulin: evidence for labile and stable microtubules

The solubility properties of tubulin and microtubules in pure cultures of sympathetic neurons were examined by electron microscopic and biochemical techniques. For morphological analyses, neurons were extracted with Triton X-100 in the presence or absence of 1 mM CaCl2, and the resulting detergent-extracted residues were examined for microtubules. In parallel experiments, the solubility of tubulin was determined under various solution conditions. Detergent-extracted residues of neurons prepared without Ca2+ contained many microtubules. Neurite residues prepared in the presence of Ca2+ also contained microtubules, but at substantially lower numbers than in residues prepared without Ca2+. The biochemical data parallel the morphological observations. Following detergent-extraction under microtubule stabilizing conditions, 30% of the tubulin was detergent-soluble (i.e. unpolymerized), while 70% was detergent-insoluble (i.e. polymerized). A more detailed examination of the solubility properties of tubulin indicated that 62% was detergent-insoluble but soluble in buffers containing mM CaCl2, while 5-8% was detergent and Ca2+-insoluble. A variety of control experiments indicated that non-specific adsorption of tubulin onto detergent-insoluble components of the cultures, assembly of tubulin onto pre-existing microtubules, and incomplete extraction of tubulin from cells contributed minimally to the levels of Ca2+-soluble and insoluble tubulin obtained with the extraction conditions used. These results indicate that (a) the majority of neuronal tubulin is assembled into microtubules which disassemble upon treatment with Ca2+ and (b) a portion of the neuronal tubulin is assembled into microtubules which show the unusual property of Ca2+-stability.