FAST AXOPLASMIC TRANSPORT OF ACETYLCHOLINESTERASE IN MAMMALIAN NERVE FIBRES

Abstract— Acetylcholinesterase (acetylcholine acetyl-hydrolase, EC 3.1.1.7) is carried down mammalian nerve fibres by the fast axoplasmic transport system. This conclusion was derived from experiments involving the ligation of cat sciatic nerves at two sites placed 83.5 mm apart. The enzyme accumulated in segments of nerve proximal to the upper ligation in a linear fashion over a period of at least 20 h. At approximately 5 h the accumulation of enzyme ceased in the nerve segment proximal to the distal ligation within the isolated length of nerve, an observation indicating that the portion of AChE free to move within the isolated nerve had been depleted during this period of time. The freely moving fraction of AChE was estimated to be 15% of the total enzyme activity present in the nerve (10% in the proximo-distal direction and 5% in the retrograde direction). The rate of AChE downflow (as estimated from the intercept of the curve plotting accumulation with the line denoting when depletion started) was 431 mm/day within a 95% confidence interval of 357–543 mm/day. In view of the variability, our results demonstrated that AChE was being carried by the fast axoplasmic transport system, which in earlier studies was estimated to have a characteristic rate close to 410 mm/day.
An accumulation of AChE was also found on the distal side of the ligations that represented a movement of AChE in the distal-proximal direction in the fibres. This retrograde transport was smaller in amount (about one-half) than the proximo-distal rate of transport, or close to 220 mm/day. The rate of AChE transport was discussed in relation to the 'transport filament' hypothesis of fast axoplasmic transport.     

Axonal Transport Reversal of Acetylcholinesterase Molecular Forms in Transected Nerve

Reversal of anterograde rapid axonal transport of four molecular forms of acetylcholinesterase (AChE) was studied in chick sciatic nerve during the 24-h period following a nerve transection. Reversal of AChE activity started ～1 h after nerve transection, and all the forms of the enzyme, except the monomeric ones, showed reversal of transport. The quantity of enzyme activity reversed 24 h after transection was twofold greater than that normally conveyed by retrograde transport. We observed no leakage of the enzyme at the site of the nerve transection and no reversal of AChE activity transport in the distal segment of the severed nerve, a result indicating that the material carried by retrograde axonal transport cannot be reversed by axotomy. Thus, a nerve transection induces both quantitative and qualitative changes in the retrograde axonal transport, which could serve as a signal of distal injury to the cell body. The velocity of reverse transport, measured within 6 h after transection, was found to be 213 mm/day, a value close to that of retrograde transport (200 mm/day). This suggests that the reversal taking place in severed sciatic nerve is similar to the anterograde-to-retrograde conversion process normally occurring at the nerve endings.     

RELATIONSHIP BETWEEN THE RATE OF AXOPLASMIC TRANSPORT AND SUBCELLULAR DISTRIBUTION OF ENZYMES INVOLVED IN THE SYNTHESIS OF NOREPINEPHRINE

The net rate of proximo-distal transport of tyrosine hydroxylase, dopamine β-hydroxylase, DOPA decarboxylase and choline acetyltransferase was determined by measuring the accumulation of these enzymes proximal to a ligature of the rat sciatic nerve. The rate of accumulation was constant for at least 12 h. For the enzymes involved in the biosynthesis of norepinephrine the rate of transport was correlated to their subcellular distribution and a close correlation between these two parameters was found. Dopamine β-hydroxylase, an enzyme mainly localized in the particulate fraction of the sciatic nerve, showed the fastest rate of transport (1·94 mm/h) whereas DOPA decarboxylase, exclusively located in the high-speed supernatant fluid, gave the slowest (0·63 mm/h) rate of transport. Tyrosine hydroxylase, predominantly located in the non-particulate fraction of the sciatic nerve was transported much slower (0·75 mm/h) than dopamine β-hydroxylase but still significantly (P < 0.005) faster than DOPA decarboxylase. The subcellular distribution of dopamine β-hydroxylase in ganglia did not differ significantly (0·45 > P > 0·40) from that in the sciatic nerve, but in nerve endings a greater proportion of dopamine β-hydroxylase was localized in particulate fractions. Tyrosine hydroxylase and DOPA decarboxylase were found exclusively in the non-particulate fractions of ganglia. In the nerve endings of the effector organs a small but consistent portion of tyrosine hydroxylase was found in particulate fractions, whereas DOPA decarboxylase was exclusively localized in the high-speed supernatant fluid.     

Fast axonal transport in motor nerve regeneration

This report describes the fast axonal transport of [³H]-leucine-labeled proteins in regenerating rat sciatic motor nerves. A normal rate of fast transport (383 ± 33 mm/day) was present in the regenerating sprouts, as well as in the central stumps. The rapidly transported proteins passed the level of axotomy without impediment, and accumulated in the endings of the regenerating sprouts, as shown by electron microscope autoradiography. In addition, transported proteins accumulated in terminal neuromas. The relative amount of protein-incorporated radioactivity in the crest of fast transport in the regenerating nerves was increased compared to control nerves. These results are interpreted to suggest that the mechanism of fast transport is the same in regenerating sprouts as in normal axons; during regeneration fast transport appears to add newly synthesized materials to the growing tip.     

Bidirectional axonal transport of 16S acetylcholinesterase in rat sciatic nerve

Axonal transport of the 16S Molecular form of acetylcholinesterase (16S-AChE) in doubly ligated rat sciatic nerves was studied by means of velocity sedimentation analysis on sucrose gradients. This form of AChE was selectively confined to motor, and not to sensory, fibers in the sciatic nerve, where it represented 3--4% of total AChE. Its activity increased linearly with time (4--20 hr) in nerve segments (7 mm) proximal to the central ligature (4.5 mU/24hr) and distal to the peripheral ligature (2.0 mU/24 hr). From the linear rates of accumulation of 16S-AChE, we conclude that the enzyme is conveyed by anterograde and retrograde axonal transport at velocities close to those previously defined for the movement of total AChE (410 mm/day, anterograde; 220 mm/day, retrograde). The transport of AChE molecular forms, other than the 16S form, could not be resolved presumably due to their presence in blood as well as at extraaxonal sites. The present findings are consistent with the view that in rat sciatic nerve most, if not all, of the small portion of total AChE (approximately 3%) which is transported may be accounted for by 16S-AChE.     

Axonal Transport Characteristics of Gangliosides in Sensory Axons of Rat Sciatic Nerve

The distribution of axonally transported gangliosides and glycoproteins along the sciatic nerve was examined from 3 h to 4 weeks following injection of[3H]glucosamine into the fifth lumbar dorsal root ganglion of adult rats. Incorporation of labeled precursor into these glycoconjugates reached a maximal level in the ganglion within 6 h. Outflow patterns of radioactivity for glycoproteins showed a well-defined crest with a transport rate of approximately 330 mm/day. In contrast, the crest of transported gangliosides was continuously attenuated, implying a significant deposition along the axon, and an alternative method of calculating velocity was required. Analysis of accumulation of labeled material at double ligatures demonstrated both anterograde and retrograde transport of glycoproteins and gangliosides and allowed for the calculation of an anterograde transport rate of about 270 mm/day for each. Additional evidence of ganglioside transport is provided in that the TLC pattern of transported radioactive gangliosides accumulating at a ligature is significantly different from the pattern seen in the dorsal root ganglion or following intraneural administration of the labeled precursor. These data indicate that gangliosides are transported at the same rapid rate as glycoproteins but are subject to a more extensive exchange with stationary material than are glycoproteins.     

Fast axonal transport in motor nerve regeneration.

This report describes the fast transport of [3H]-leucine-labeled proteins in regenerating rat sciatic motor nerves. A normal rate of fast transport (383 +/- 33 mm/day) was present in the regenerating sprouts, as well as in the central stumps. The rapidly transported proteins passed the level of axotomy without impediment, and accumulated in the endings of the regenerating sprouts, as shown by electron microscope autoradiography. In addition, transported proteins accumulated in terminal neuromas. The relative amount of protein-incorporated radioactivity in the crest of transport in the regenerating nerves was increased compared to control nerves. These results are interpreted to suggest that the mechanism of fast transport is the same in regenerating nerves was increased compared to control nerves. These results are interpreted to suggest that the mechanism of fast transport is the same in regenerating sprouts as in normal axons; during regeneration fast transport appears to add newly synthesized materials to the growing tip.     

A Rapid Anterograde Axonal Transport of Carboxypeptidase H in Rat Sciatic Nerves

Abstract: Using the highly sensitive HPLC-fluorophotometry technique, anterograde and retrograde axonal transport of carboxypeptidase H (CPH), a putative pro-hormone processing enzyme that removes a basic amino acid from the C-terminus of a precursor peptide, was measured 12–72 h after double ligations of rat sciatic nerves. CPH-like activity in rat sciatic nerves was 60-fold lower than that in the pituitary gland. CPH-like enzyme activity was rapidly accumulated in the proximal segment and peaked 48 h after ligation. The axonal flow was 100 mm/day, indicating that CPH in rat sciatic nerves is rapidly transported to the nerve terminals as an active form. The properties of the enzyme were similar to those of CPH in the brain: The pH optimum is at 5.5, and the molecular mass is ∼50 kDa. These results suggest that active CPH in the PNS is transported by a rapid anterograde axonal flow and may play a role in converting proneuropeptides to active neuropeptides under the axonal transport.     

Retrograde Axonal Transport of Locally Synthesized Phosphoinositides in the Rat Sciatic Nerve

Although autoradiography has demonstrated local incorporation of [3H]inositol into axonal phospholipids after intraneural injection, retrograde axonal transport of phosphatidylinositol has only been demonstrated after injection of lipid precursor into the cell body regions (L4 and L5 dorsal root ganglia) of the sciatic nerve. We now report the retrograde axonal transport of inositol phospholipids synthesized locally in the axons. Following microinjection of myo-[3H]inositol into the rat sciatic nerve (50-55 mm distal to L4 and L5 dorsal root ganglia), a time-dependent accumulation of 3H label occurred in the dorsal root ganglia ipsilateral to the injection site. The ratio of dpm present in the ipsilateral dorsal root ganglia to that in the contralateral dorsal root ganglia was not significantly different from unity between 2 and 8 h following isotope injection but increased to 10-12-fold between 24 and 72 h following precursor injection. By 24 h following precursor injection, the ipsilateral/contralateral ratio of the water-soluble label in the dorsal root ganglia still remained approximately 1.0, whereas the corresponding ratio in the chloroform/methanol-soluble fraction was approximately 20. The time course of appearance of labeled lipids in the ipsilateral dorsal root ganglia after injection of precursor into the nerve at various distances from the dorsal root ganglia indicated a transport rate of at least 5 mm/h. Accumulation of label in the dorsal root ganglia could be prevented by intraneural injection of colchicine or ligation of the sciatic nerve between the dorsal root ganglia and the isotope injection site. These results demonstrate that inositol phospholipids synthesized locally in the sciatic nerve are retrogradely transported back to the nerve cell bodies located in the dorsal root ganglia.     

Acrylamide-Induced Increases in Deposition of Axonally Transported Glycoproteins in Rat Sciatic Nerve

The axonal transport of proteins, glycoproteins, and gangliosides in sensory neurons of the sciatic nerve was examined in adult rats exposed to acrylamide via intraperitoneal injection (40 mg/kg of body weight/day for nine consecutive days). The L5 dorsal root ganglion was injected with either [35S]methionine to label proteins or [3H]glucosamine to label, more specifically, glycoproteins and gangliosides. At times ranging from 2 to 6 h later, the sciatic nerve and injected ganglion were excised and radioactivity in consecutive 5-mm segments determined. In both control and acrylamide-treated animals, outflow profiles of [35S]methionine-labeled proteins showed a well defined crest which moved down the nerve at a rate of approximately 340 mm/day. Similar outflow profiles and transport rates were seen for [3H]glucosamine-labeled glycoproteins in control animals. However, in animals treated with acrylamide, the crest of transported labeled glycoprotein was severely attenuated as it moved down the nerve. This finding suggests that in acrylamide-treated animals, axonally transported glycoproteins were preferentially transferred (unloaded or exchanged against unlabeled molecules) from the transport vector to stationary axonal structures. We also examined the clearance of axonally transported glycoproteins distal to a ligature on the nerve. The observed impairment of clearance in acrylamide-treated animals relative to controls is supportive of the above hypothesis. Acrylamide may directly affect the mechanism by which axonally transported material is unloaded from the transport vector. Alternatively, the increased rate of unloading might reflect an acrylamide-induced increase in the demand for axonally transported material.     

Anterograde Axonal Transport of Peptidylglycine α-Amidating Monooxygenase in Rat Sciatic Nerves

Axonal transport of peptidylglycine alpha-amidating monooxygenase (PAM) activity was studied in rat sciatic nerves from 12 to 120 h after double ligations. The anterograde axonal transport increased and reached a plateau between 48 and 72 h and then decreased. The flow rate was 100 mm/day, and the molecular mass of the active entity was 70 kDa, which was determined by gel filtration. In contrast, there was no evidence for significant retrograde axonal transport. Anterograde axonal transport of immunoreactive cholecystokinin, a carboxy-terminal-amidated putative neuropeptide, was also found. These results suggest that PAM is transported by a rapid axonal flow and may play a role as a processing enzyme during transport or in the terminals of rat sciatic nerves.     

Retrograde Axonal Transport of Gangliosides and Glycoproteins in the Motoneurons of Rat Sciatic Nerve

Axonal transport of glycoconjugates was studied in the motoneurons of rat sciatic nerve following injection of [3H]glucosamine into the lumbosacral spinal cord. After varying time intervals, the sciatic nerve was exposed, and two ligatures were tied for collection of materials undergoing anterograde and retrograde transport. Gangliosides and glycoproteins were found to undergo fast anterograde transport, estimated at 284-446 mm/day. Both classes underwent retrograde transport as well, with labeled glycoproteins returning slightly ahead of labeled gangliosides. Only minor quantities of labeled proteoglycans were detected. Purified gangliosides extracted from nerve segments were fractionated according to sialic acid number on diethylaminoethyl-Sephadex; the distributional pattern tended to resemble that of brain gangliosides. The similarity between anterograde and retrograde patterns suggested absence of metabolic changes in gangliosides entering and leaving the axon-nerve terminal structures.     

Transport of muscarinic cholinergic receptors in the sciatic nerve of rat

On the basis of the specific [³H]quinuclidinyl-benzilate binding, the transport of muscarinic cholinergic receptors has been demonstrated in the ventral horn, sciatic nerve and in the 3 mm segments proximal and distal to the ligature of rat sciatic nerves ligated for 24 h (a) without electrolytic lesion, (b) six days after lesion of the spinal ganglia, (c) six days after lesion of the motoric axons, and (d) six days after transection of the sciatic nerve. The distribution of these receptors was also studied in the ventral spinal horn, dorsal root sensory axons, spinal ganglia and sciatic nerve of rabbit.Our results suggest that the receptors are transported in the sciatic nerve of rat. This transport consists of a large anterograde, and a discrete retrograde flow of muscarinic cholinergic receptors. Most of the receptors are possibly synthesized in the motoneuron cell bodies and migrate in the motoric axons; to a lesser extent they may also be synthesized in the cell bodies of the dorsal root ganglia and migrate in the sensory axons of the sciatic nerve.     

FAST AXONAL TRANSPORT IN VITRO IN THE SCIATIC SYSTEM OF THE FROG

Abstract— An in vitro system from the frog has been used to study fast axonal protein transport. The preparation, which was incubated in a specially made chamber, consisted of the gastrocnemius muscle, the sciatic nerve, the dorsal ganglia and part of the spinal cord. The parts were separated from each other by silicone grease barriers, which made it possible to follow the migration of labelled proteins from the spinal cord and ganglia, along the sciatic nerve, towards the muscle. About 80 per cent of transported proteins in the sciatic nerve originated from the dorsal spinal ganglia and moved antidromically at a rate of 60–90 mm per day at 18°C. The rapidly transported proteins were 90 per cent particulate and mainly associated with structures sedimenting in the microsomal fraction.
The effects of cyclohexirnide showed that the synthesis of rapidly moving proteins and their transport were separate processes. A low concentration of colchicine inhibited the transport when it was present in the medium surrounding the ganglia, but had no effect even at a higher concentration, when it was added to the nerve compartment. The presence of vinblastine at a low concentration in either of the two compartments completely arrested the protein transport. Likewise N-ethylmaleimide or p-chloromercuribenzene sulphonic acid in the nerve medium effectively blocked the fast transport. Results from experiments performed to test the possibility of disto-proximal flow and of transfer of proteins from the muscle to the nerve are discussed.     

TRANSPORT OF CHOLESTEROL IN THE CHICK OPTIC SYSTEM

After injection of radioactive cholesterol into the vitreous humour of chicks, cholesterol is axonally transported along the optic nerve to the contralateral optic tectum. In the optic nerve of young chicks cholesterol is only transported at the slow rate whereas in the sciatic nerve of adult chicks it is transported at both the fast and slow rates. This difference is not due to age or a peculiarity of avian species as the same difference exists in mice. Estimates of the cholesterol content of tissues and the amount of cholesterol transported suggests the existence of small rapidly turning over pools of cholesterol in nerves. Due to its great metabolic stability, cholesterol is a useful and specific marker for slow transport in the optic nerve and thus may prove suitable for the mapping of neuronal projections.     

Protein Synthesis and Rapid Axonal Transport During Regrowth of Dorsal Root Axons

Damage to the sciatic nerve produces significant changes in the relative synthesis rates of some proteins in dorsal root ganglia and in the amounts of some fast axonally transported proteins in both the sciatic nerve and dorsal roots. We have now analyzed protein synthesis and axonal transport after cutting the other branch of dorsal root ganglia neurons, the dorsal roots. Two to three weeks after cutting the dorsal roots, [35S]methionine was used to label proteins in the dorsal root ganglia in vitro. Proteins synthesized in the dorsal root ganglia and transported along the sciatic nerve were analyzed on two-dimensional gels. All of the proteins previously observed to change after sciatic nerve damage were included in this study. No significant changes in proteins synthesized in dorsal root ganglia or rapidly transported along the sciatic nerve were detected. Axon regrowth from cut dorsal roots was observed by light and electron microscopy. Either the response to dorsal root damage is too small to be detected by our methods or changes in protein synthesis and fast axonal transport are not necessary for axon regrowth. When such changes do occur they may still aid in regrowth or be necessary for later stages in regeneration.     

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.     

Action of Brefeldin A on Amphibian Neurons: Passage of Newly Synthesized Proteins Through the Golgi Complex Is Not Required for Continued Fast Organelle Transport in Axons

Abstract: The relation between the availability of newly synthesized protein and lipid and the axonal transport of optically detectable organelles was examined in peripheral nerve preparations of amphibia (Rana catesbeiana and Xenopus laevis) in which intracellular traffic from the endo-plasmic reticulum to the Golgi complex was inhibited with brefeldin A (BFA). Accumulation of fast-transported radio-labeled protein or phospholipid proximal to a sciatic nerve ligature was monitored in vitro in preparations of dorsal root ganglia and sciatic nerve. Organelle transport was examined by computer-enhanced video microscopy of single myelinated axons. BFA reduced the amount of radiolabeled protein and lipid entering the fast-transport system of the axon without affecting either the synthesis or the transport rate of these molecules. The time course of the effect of BFA on axonal transport is consistent with an action at an early step in the intrasomal pathway, and with its action being related to the observed rapid (<1 h) disassembly of the Golgi complex. At a concentration of BFA that reduced fast-transported protein by >95%, no effect was observed on the flux or velocity of anterograde or retrograde organelle transport in axons for at least 20 h. Bidirectional axonal transport of organelles was similarly unaffected following suppression of protein synthesis by >99%. The findings suggest that the anterograde flux of transport organelles is not critically dependent on a supply of newly synthesized membrane precursors. The possibilities are considered that anterograde organelles normally arise from membrane components supplied from a post-Golgi storage pool, as well as from recycled retrograde organelles.     

Reversal of axonal transport at a nerve crush.

Abstract— —We have compared retrograde axonal transport of ³H-labeled protein in normal rat motor and sensory axons, and axons which were injured by a distal ligation of the sciatic nerve. After injection of L-[³H]leucine into the vicinity of the neuron cell bodies, labeled protein was transported into the axons. A premature return of protein towards the cell bodies occurred in the injured axons, which we interpret as a reversal of axonal transport occurring at the site of injury. We estimate that reversal of transport occurred within 1.9–2.4 h of the arrival of labeled protein at the injury, and that the minimum velocity of the subsequent retrograde transport was 112–133 mm day^?1. The ability of the injured axons to reverse transport developed about 0.8 h after making the injury. A large fraction of the orthograde transported protein was returned towards the cell body: it is estimated that by 28 h after labeled protein in sensory axons reached the injury, 46% of the³H-labeled protein originally transported to the injury site had been returned. In intact sensory nerves at this time only 15% of the transported protein had returned. It is suggested that axonal injury produces a sudden increase in the return of newly synthesized protein to the cell body, and that this might serve as a signal for chromatolysis.     

Storage and fast transport of noradrenaline, dopamine beta-hydroxylase and neuropeptide Y in dog sciatic nerve axons.

The axonal transport and subcellular distribution of noradrenaline (NA), dopamine beta-hydroxylase (DBH) and neuropeptide Y (NPY) were determined in dog sciatic nerve using an accumulation technique. The results were compared with those obtained by application of the same procedures and methods on the splenic nerve in the same animal species. Evidence was found for the coexistence of NA and NPY in large dense-cored vesicles in dog sciatic nerve axons. After differential centrifugation and isopyenic sucrose density gradient centrifugation of 24 h ligated sciatic nerve pieces NA and NPY equilibrated around 1M sucrose. The DBH activity was dispersed broadly on the gradient. Subsequently, the accumulation of NA, DBH and NPY was studied in proximal and sital segments of 8, 12 and 24 h dog ligated sciatic nerve and inferences were made concerning the axonal transport of these compounds. NA, DBH and NPY displayed a divergent accumulation proximal to the ligation. After 12 h of ligation a transport rate was calculated of 4.8 +/- 1.8 mm/h for NA, of 5.9 +/- 1.5 mm/h for DBH and of 4.9 +/- 2.0 mm/h for NPY. With a correction for the stationary fractions, a similar fast transport rate of approximately 10 to 12 mm/h was proposed for NA, DBH and NPY. The occurrence was shown of a limited retrograde transport of DBH and possibly NPY, but not of NA.