Acrylamide impairs fast and slow axonal transport in rat optic system

Effects of single and repeated doses of acrylamide on fast and slow axonal transport of radio labeled proteins following the injection of L-[4,5-³H] leucine have been studied in the optic system of male Sprague-Dawley rats. A single dose of acrylamide (100 mg/kg) had no effect, but higher concentrations (200–300 mg/kg) altered the distribution of fast axonally transported materials in optic nerves and optic tracts. Repeated doses of acrylamide (30 mg/kg/day, 5 days per week for 4 weeks) produced degeneration of tibial nerves but spared optic nerves and optic tracts. Fast axonal transport rate in optic axons was reduced by 50% (reduced to 4 mm/h from 8 mm/h) in acrylamide treated animals. Acrylamide also slowed the velocity of slow axonal transport of labeled proteins in optic axons to 1.0 mm per day from 1.3 mm per day. Since acrylamide impaired the rate of both fast and slow axonal transport in the absence of overt morphological damage, it can be concluded that deficit in axonal transport is an important factor in the pathogenesis of axonal degeneration in acrylamide neuropathy.     

Redistribution of proteins of fast axonal transport following administration of beta,beta'-iminodipropionitrile: a quantitative autoradiographic study

Beta,beta'-iminodipropionitrile (IDPN) produces a rearrangement of axoplasmic organelles with displacement of microtubules, smooth endoplasmic reticulum, and mitochondria toward the center and of neurofilaments toward the periphery of the axon, whereas the rate of the fast component of axonal transport is unchanged. Separation of microtubules and neurofilaments makes the IDPN axons an excellent model for study of the role of these two organelles in axonal transport. The cross-sectional distribution of [3H]-labeled proteins moving with the front of the fast transport was analyzed by quantitative electron microscopic autoradiography in sciatic nerves of IDPN-treated and control rats, 6 h after injection of a 1:1 mixture of [3H]-proline and [3H]-lysine into lumbar ventral horns. In IDPN axons most of the transported [3H] proteins were located in the central region with microtubules, smooth endoplasmic reticulum and mitochondria, whereas few or none were in the periphery with neurofilaments. In control axons the [3H]-labeled proteins were uniformly distributed within the axoplasm. It is concluded that in fast axonal transport: (a) neurofilaments play no primary role; (b) the normal architecture of the axonal cytoskeleton and the normal cross-sectional distribution of transported materials are not indispensable for the maintenance of a normal rate of transport. The present findings are consistent with the models of fast transport that envision microtubules as the key organelles in providing directionality and propulsive force to the fast component of axonal transport.     

Components of fast and slow axonal transport in the goldfish optic nerve

The composition of the fast and slow components of axonal transport in the goldfish optic nerve was investigated, using specific radioactive precursors injected into the eye. Tritiated glucosamine and fucose label macromolecules, presumably glycoproteins, which are rapidly transported from the eye to the optic tectum. Material labeled with these precursors is not evident in the slowly transported component. Glucosamine and fucose incorporation are blocked when a protein synthesis inhibitor, acetoxycycloheximide, is injected into the eye concurrently with the precursors. As well as labeling macromolecules, ³H-glucosamine and ³H-N-acetylmannosamine ( a precursor of sialic acids) also label rapidly-transported chloroform-methanol-extractable material which may contain transported glycolipids. Two procedures were used to show that the slow component of axonal transport contains tubulin, a protein characteristic of the microtubules:

• (a) Tracer doses of tritiated colchicine injected into the eye label a wave of radioactivity which moves 0.5 mm/day, the rate of slow axonal transport in the goldfish optic nerve. We believe this wave represents the movement of colchicine which is bound to colchicine-binding protein moving in the slow component of axonal transport.
• (b) Tritiated proline labels a slowly transported protein which is precipitated by vinblastine and has a mobility on polyacrylamide gels comparable to authentic tubulin. These results indicate that the fast and slow components of axonal transport each provide specific chemical substances to the nerve endings.

     

Rapid movement of microtubules in axons

Cytoskeletal and cytosolic proteins are transported along axons in the slow components of axonal transport at average rates of about 0.002-0.1 microm/s. This movement is essential for axonal growth and survival, yet the mechanism is poorly understood. Many studies on slow axonal transport have focused on tubulin, the subunit protein of microtubules, but attempts to observe the movement of this protein in cultured nerve cells have been largely unsuccessful. Here, we report direct observations of the movement of microtubules in cultured nerve cells using a modified fluorescence photobleaching strategy combined with difference imaging. The movements are rapid, with average rates of 1 microm/s, but they are also infrequent and highly asynchronous. These observations indicate that microtubules are propelled along axons by fast motors. We propose that the overall rate of movement is slow because the microtubules spend only a small proportion of their time moving. The rapid, infrequent, and highly asynchronous nature of the movement may explain why the axonal transport of tubulin has eluded detection in so many other studies.     

Slow Axonal Transport Impairment of Cytoskeletal Proteins in Streptozociti-Induced Diabetic Neuropathy

The impairment of slow axonal transport of cytoskeletal proteins was studied in the sciatic nerves of streptozocin-diabetic rats. [35S]Methionine was unilaterally injected into the fourth lumbar ganglion and spinal cord, to label the sensory and motor axons, respectively, and then the polymerized elements of the cytoskeleton and the corresponding soluble proteins were analyzed separately. In addition, the pellet/supernatant ratio for tubulin and actin was also assessed. Our results indicate that the velocity of slow component a (SCa) of axonal transport, particularly that of neurofilaments, was strongly reduced (by 60%) in sensory axons. At the same time, a decreased pellet/supernatant ratio of tubulin, possibly owing to a depolymerization of stable microtubules, was also observed. The transport of slow component b (SCb) of axonal transport was also impaired, but the extent of this impairment could not be precisely evaluated. In contrast, motor axons showed little or no impairment of both SCa and SCb at the time studied, a result suggesting a delayed development of the neuropathy in motor axons.     

Axotomy accelerates slow component b of axonal transport

Because the integrity of an axon depends on the supply of proteins synthesized in the cell body, we examined the effect of axotomy on the transport of structural proteins in rat motor axons, and the effect of altered transport on the rate of outgrowth after a subsequent testing axotomy. To examine the axonal transport of structural proteins, we labeled newly synthesized proteins with ³⁵ S-methiomine 7 days after a “conditioning” lesion of the sciatic nerve, and removed the nerve 7–21 days later for SDS-PAGE. Tubulin, actin, calmodulin, and the 68-kD light neurofilament protein (NF-L) were identified by fluorography and removed for liquid scintillation counting. The fastest moving structural proteins were carried by slow component b (SCb) of axonal transport, which advanced 20% faster in conditioned axons: 4.2 versus 3.5 mm/day (p < 0.01). NF-L was not accelerated, indicating that the motor for subcomponent a (SCa) of slow axonal transport was unaffected by axotomy. To measure outgrowth distances, the testing lesion was made 7 days after the conditioning lesion, and growth cones were located by the fast transport method 3 or 9 days later. The regression analysis of outgrowth distance on time showed that sprouts elongated 25% faster in conditioned axons: 4.0 versus 3.2 mm/day (p < 0.001). These accelerated sprouts were formed too far from the spinal cord to contain SCb proteins that were synthesized after axotomy. Because the rate of outgrowth correlates closely with the rate of SCb in outgrowing sprouts (McQuarrie and Jacob, J. Comp. Neurol. 305:139–147, 1991), we conclude that SCb is accelerated throughout the length of the axon by 7 days after axotomy.     

Axonal transport of calmodulin: a physiologic approach to identification of long-term associations between proteins

Calmodulin is a soluble, heat-stable protein which has been shown to modulate both membrane-bound and soluble enzymes, but relatively little has been known about the in vivo associations of calmodulin. A 17,000-dalton heat-stable protein was found to move in axonal transport in the guinea pig visual system with the proteins of slow component b (SCb; 2 mm/d) along with actin and the bulk of the soluble proteins of the axon. Co-electrophoresis of purified calmodulin and radioactively labeled SCb proteins in two dimensional polyacrylamide gel electrophoresis (PAGE) demonstrated the identity of the heat-stable SCb protein and calmodulin on the basis of pI, molecular weight, and anomalous migration in the presence of Ca2+-chelating agents. No proteins co-migrating with calmodulin in two-dimensional PAGE could be detected among the proteins of slow component a (SCa; 0.3 mm/d, microtubules and neurofilaments) or fast component (FC; 250 mm/d, membrane-associated proteins). We conclude that calmodulin is transported solely as part of the SCb complex of proteins, the axoplasmic matrix. Calmodulin moves in axonal transport independent of the movements of microtubules (SCa) and membranes (FC), which suggests that the interactions of calmodulin with these structures may represent a transient interaction between groups of proteins moving in axonal transport at different rates. Axonal transport has been shown to be an effective tool for the demonstration of long-term in vivo protein associations.     

Characterization of the fast and slow components of axonal transport in retinal ganglion cells

The constituent proteins of the fast (110–150 mm/day) and slow (1.5–2 mm/day) components of axonal transport in the retinal ganglion cells of the rabbit were investigated. The fast and slow components were labelled by intraocular injection of (³H)- and (¹⁴C)-leucine, respectively. Subcellular fractionation of the optic nerve and tract and subsequent gel electrophoresis of the fractions showed that most of the soluble proteins moved with the slow phase of axonal transport, whereas only some of the soluble proteins were transported with the rapid phase. Extraction of the microsomal fraction with triton X-100 resulted in the solubilization of highly labelled proteins belonging to the rapid phase. These proteins showed a relatively low electrophoretic mobility.     

Axotomy accelerates slow component b of axonal transport.

Because the integrity of an axon depends on the supply of proteins synthesized in the cell body, we examined the effect of axotomy on the transport of structural proteins in rat motor axons, and the effect of altered transport on the rate of outgrowth after a subsequent testing axotomy. To examine the axonal transport of structural proteins, we labeled newly synthesized proteins with 35S-methionine 7 days after a "conditioning" lesion of the sciatic nerve, and removed the nerve 7-21 days later for SDS-PAGE. Tubulin, actin, calmodulin, and the 68-kD light neurofilament protein (NF-L) were identified by fluorography and removed for liquid scintillation counting. The fastest moving structural proteins were carried by slow component b (SCb) of axonal transport, which advanced 20% faster in conditioned axons: 4.2 versus 3.5 mm/day (p less than 0.01). NF-L was not accelerated, indicating that the motor for subcomponent a (SCa) of slow axonal transport was unaffected by axotomy. To measure outgrowth distances, the testing lesions was made 7 days after the conditioning lesion, and growth cones were located by the fast transport method 3 or 9 days later. The regression analysis of outgrowth distance on time showed that sprouts elongated 25% faster in conditioned axons: 4.0 versus 3.2 mm/day (p less than 0.001). These accelerated sprouts were formed too far from the spinal cord to contain SCb proteins that were synthesized after axotomy. Because the rate of outgrowth correlated closely with the rate of SCb in outgrowing sprouts (McQuarrie and Jacob, J. Comp. Neurol. 305:139-147, 1991), we conclude that SCb is accelerated throughout the length of the axon by 7 days after axotomy.     

Axonal isoforms of myosin-I

We have examined spinal motor neurons in Sprague-Dawley rats to further characterize a mechanoenzyme, myosin-Igamma (myr4), which is found in high concentration during axon tract formation in neonates. We raised an antibody to myr4 and made riboprobes for in situ hybridization. Myr4 mRNA was abundant in spinal cord motor neurons (particularly during axon regrowth). Nerves undergoing Wallerian degeneration (from a crush 7 days earlier) showed anti-myr4 labeling of the axolemma and SER--after microtubules, neurofilaments, and F-actin had already been degraded--which is consistent with a described lipid-binding domain in the tail region of myosin-Is. Newly synthesized myr4 was carried in axons by the slow component (SC) of axonal transport at 1-8 mm/day, whereas, none was carried by the fast component (FC). We conclude that SC delivers myr4 to the cytoplasmic surfaces of stationary axonal membranes (SER and axolemma). This positioning would anchor the tail domain of myr4 and leave the catalytic head domain free to interact with F-actin.     

SLOW AXONAL TRANSPORT OF LABELLED PROTEINS IN SENSORY FIBRES OF RABBIT VAGUS NERVE

Both rapid (415 mm/day) and slow (24 mm/day) rates of axonal transport of proteins were found in sensory fibres of rabbit vagus nerve after injection of [³H]leucine into the nodose ganglion in vivo. The slow phase of transport was dependent on contact between the cell bodies and the nerve trunk, and did not continue under in vivro conditions. The results suggest some difference between the mechanisms of fast and slow transport.     

Drag of the Cytosol as a Transport Mechanism in Neurons

Axonal transport is typically divided into two components, which can be distinguished by their mean velocity. The fast component includes steady trafficking of different organelles and vesicles actively transported by motor proteins. The slow component comprises nonmembranous materials that undergo infrequent bidirectional motion. The underlying mechanism of slow axonal transport has been under debate during the past three decades. We propose a simple displacement mechanism that may be central for the distribution of molecules not carried by vesicles. It relies on the cytoplasmic drag induced by organelle movement and readily accounts for key experimental observations pertaining to slow-component transport. The induced cytoplasmic drag is predicted to depend mainly on the distribution of microtubules in the axon and the organelle transport rate.     

Axonal transport of membranous and nonmembranous cargoes: a unified perspective

Membranous and nonmembranous cargoes are transported along axons in the fast and slow components of axonal transport, respectively. Recent observations on the movement of cytoskeletal polymers in axons suggest that slow axonal transport is generated by fast motors and that the slow rate is due to rapid movements interrupted by prolonged pauses. This supports a unified perspective for fast and slow axonal transport based on rapid movements of diverse cargo structures that differ in the proportion of the time that they spend moving. A Flash feature (http://www.jcb.org/cgi/content/full/jcb.200212017/DC1) accompanies this Mini-Review.     

Studies on the mechanism of axoplasmic transport in the crayfish cord

Following the injection of ³H-leucine into a crayfish ganglion, tritiumlabeled proteins were detected remaining in the ganglion and moving at a slow linear rate caudad along the nerve cord. The rate of movement increased linearly with temperature between 5 and 20°C, but ceased at 3° C. The movement was also blocked for a distance around a colchicine-injected ganglion. Both of these observations would be compatible with the involvement of microtubules in slow axoplasmic transport. However, in both instances normal-appearing microtubules were observed by electron microscopy. Gel electropherograms of the denatured labeled proteins showed that the transported proteins are complex and may correspond to most of the axoplasmic proteins including the microtubules.     

Axonal transport: a quantitative study of retained and transported protein fraction in the cat

The fast axonal transport of proteins was studied in the cat sciatic nerve after injection of [3H]leucine into the spinal ganglion or the ventral horn of the seventh lumbar segment. The amount of transported proteins after ganglion injection was linearly related to the amount of label present at the ganglion. At variable intervals after ganglion or spinal cord injection, the sciatic nerves were sectioned in some experiments. The transport of proteins continued in the peripheral nerve stump in a wavelike manner, but the advancing wave leaves a labeled trail behind. A fraction of this trail corresponds to proteins moving at slower velocities than the velocity of proteins in the wave front. Another fraction of the trail corresponds to molecules retained by the axons. Each nerve segment of 5 mm in length retains 1.5% of the transported proteins, and the profile of retained proteins along the sciatic nerves follows a single exponential function. From the proportion of retained proteins, the concentration of transported proteins at the terminals of branching axons as a function of the branching ratio was estimated. In the case of motor axons innervating the soleus muscle of the cat, the concentration of recently transported proteins at the nerve terminals would be approximately 0.83% of the proteins leaving the spinal cord. This low concentration of transported proteins at the nerve terminals may explain the lability of neuromuscular synapses when axonal transport is decreased or interrupted.     

Tubulin transport in neurons

A question of broad importance in cellular neurobiology has been, how is microtubule cytoskeleton of the axon organized? It is of particular interest because of the history of conflicting results concerning the form in which tubulin is transported in the axon. While many studies indicate a stationary nature of axonal microtubules, a recent series of experiments reports that microtubules are recruited into axons of neurons grown in the presence of a microtubule-inhibitor, vinblastine (Baas, P.W., and F.J. Ahmad. 1993.J. Cell Biol. 120:1427-1437: Ahmad F.J., and P.W. Baas. 1995. J. Cell Sci, 108:2761-2769; Sharp, D.J., W. Yu, and P.W. Baas. 1995. J. Cell Biol, 130:93-103; Yu, W., and P.W. Baas. 1995. J. Neurosci. 15:6827-6833.). Since vinblastine stabilizes bulk microtubule-dynamics in vitro, it was concluded that preformed microtubules moved into newly grown axons. By visualizing the polymerization of injected fluorescent tubulin, we show that substantial microtubule polymerization occurs in neurons grown at reported vinblastine concentrations. Vinblastine inhibits, in a concentration-dependent manner, both neurite outgrowth and microtubule assembly. More importantly, the neuron growth conditions of low vinblastine concentration allowed us to visualize the footprints of the tubulin wave as it polymerized and depolymerized during its slow axonal transport. In contrast, depolymerization resistant fluorescent microtubules did not move when injected in neurons. We show that tubulin subunits, not microtubules, are the primary form of tubulin transport in neurons.     

Drag of the Cytosol as a Transport Mechanism in Neurons

Axonal transport is typically divided into two components, which can be distinguished by their mean velocity. The fast component includes steady trafficking of different organelles and vesicles actively transported by motor proteins. The slow component comprises nonmembranous materials that undergo infrequent bidirectional motion. The underlying mechanism of slow axonal transport has been under debate during the past three decades. We propose a simple displacement mechanism that may be central for the distribution of molecules not carried by vesicles. It relies on the cytoplasmic drag induced by organelle movement and readily accounts for key experimental observations pertaining to slow-component transport. The induced cytoplasmic drag is predicted to depend mainly on the distribution of microtubules in the axon and the organelle transport rate.     

Changes in the rate of axonal flow of proteins through the branches of motor and sensory neurocytes during the period of intense growth of the sciatic nerve in rats

14C-glycin was microinjected into the ventral horns of the spinal cord or spinal ganglions. The rate of fast and slow axoplasmic transport of proteins in the axons of motor and sensory neurons was studied by liquid scintillation. Motor fibers of the sciatic nerve manifested a marked decrease (P less than 0.05) in the rate of slow axoplasmatic transport of the labeled protein from 5.25 +/- 0,31 in 2-week-old rats to 3.45 +/- +/- 0.23 mm/day in 4-week-old animals and a significant increase in the rate of fast axoplasmic transport (P less than 0.05) from 99 +/- 13.2 (2-week-old rats) up to 198 +/- 18.9 mm/day (in 4-week-old rats). The two-week-old rats had higher rates (4.5 +/- 0.3 mm/day) of slow axoplasmic transport of the labeled protein in the central and peripheral axons of sensory neurocytes and lower rates of fast axoplasmic transport (126 +/- 14.7 mm/day) as compared with 4-week-old animals (3.75--4.1 +/- 0.25 -- slow transport; 144 +/- 23.34 mm/day -- fast transport). However, the differences described are not significant.     

Anterograde Axonal Transport in Rats During Intoxication with Acrylamide

Abstract: Anterograde axonal transport was examined in sensory nerves of rats intoxicated with a low dose (group I) or a high dose (group II) of acrylamide. After injection of either [³⁵S]methionine and [³H]fucose or [³H]proline into the dorsal root ganglia of the 5th lumbar roots, distribution of protein label was measured in 3-mm segments of the sciatic nerve at intervals of 2 h, 4 h, 10 days, and 26 days. No difference in ganglion incorporation was present at 4 h, and the fast transport velocity of methionine label also remained normal [14.7 ± 1.3 mm/h (mean ± SD) in controls versus 14.6 ± 0.3 mm/h and 15.4 ± 1.2 mm/h in acrylamide group I and II, respectively]. Neither was there any decrease in transport velocity of proline label of slow component b (4.18 ± 0.29 mm/day in controls versus 4.29 ± 0.17 mm/d and 4.22 ± 0.29 mm/day in acrylamide group I and II, respectively). In slow component a, however, a significant reduction in the fractional amount of proline label was found (20.8 ± 4.0% in controls versus 17.6 ± 14.9% and 9.7 ± 5.9% in acrylamide group I and II, respectively). Again no decrease in transport velocity was observed (1.03 ± 0.02 mm/day in controls versus 1.06 ± 0.08 mm/day and 1.07 ± 0.03 mm/day in acrylamide group I and II, respectively), and closer inspection of the activity along the nerve did not reveal any alteration in skewness or ‘peakedness’ of the distribution curve. The reduction in amount of protein carried in the slow axonal transport component in rats with severe acrylamide neuropathy (group II) could be associated with fibre breakdown at a late stage of the neuropathic process. The most important consequence of the study is, however, that in contrast to previous suggestions, during acrylamide intoxication no changes are present in protein incorporation or in anterograde axonal transport which can explain the initial pathological or functional abnormalities of the distal axons.     

TRANSPORT AND TURNOVER OF NEUROHYPOPHYSIAL PROTEINS OF THE RAT

Axonal transport and turnover rate of proteins in the supraoptico-neurohypo-physial tract were studied after injection of ³⁵S cysteine into the region of the supraoptic nucleus. The proximo-distal migration of labelled proteins from the nerve cell bodies to the axon terminals in the neurohypophysis was followed by measuring the radioactivity of neurohypophysial proteins at various time intervals (4 h to 30 days) after isotope injection. A rapidly transported phase of proteins with a minimal transport rate of approximately 60 mm/day was demonstrated. An accumulation of protein-bound radioactivity was also observed in the neural lobe at 9 days after isotope injection, representing slowly transported proteins (0-5 mm/day). In addition, an intermediate phase of axonal transport (1-5 mm/day) was found. Fractionation of neurohypophysial proteins by polyacrylamide gel disc electrophoresis revealed that a predominating portion of the radioactivity was recovered in a single protein component (fraction A) at 4 h as well as at 30 days after isotope injection. This protein component was shown to be a constituent both of the rapid and the slow phase of axonal transport. With time an increasing amount of radioactivity was found in another protein component (fraction B), which reached a maximum at 14 days after injection and then remained fairly constant up to 30 days. When the turnover rates of neurohypophysial proteins were estimated, a half-life of 1-2 days and 8 days was calculated for the rapidly and slowly transported proteins, respectively.