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.     

RETROGRADE AXONAL TRANSPORT OF RAPIDLY MIGRATING PROTEINS IN THE VAGUS AND HYPOGLOSSAL NERVES OF THE RABBIT

—The redistribution of rapidly migrating [³H]leucine-labelled proteins was studied using double ligatures applied to the vagus nerve and single ligatures, applied to the hypoglossal nerves. Rapidly migrating proteins accumulating for 16 h proximal to a distal ligature of the cervical vagus redistributed to give a retrograde accumulation distal to a second ligature. Within 6 h a substantial redistribution occurred indicating a rapid retrograde transport. After 21 h there was a further accumulation with 70 per cent of the labelled material accumulating at the distal end of the isolated nerve segment and 16 per cent accumulating at the proximal end. It was shown that about a half of the retrograde accumulation was dependent on the distal accumulation zone. Rapidly migrating proteins accumulated distal to a ligature applied to the hypoglossal nerve 16 h after labelling of the nerve cell bodies indicating that a rapid retrograde transport of labelled macromolecules occurs from the peripheral parts of the nerve in the tongue. Labelled proteins accumulated proximal to ligatures and transections of both the hypoglossal and vagus nerve when applied 16 h after labelling of the nerve cell bodies, indicating the presence of axonal proteins, migrating at a rate of transport intermediate to that of rapidly and slowly migrating proteins.     

AXONAL TRANSPORT OF S-100 PROTEIN IN MAMMALIAN NERVE FIBRES

Abstract— The brain-specific S-100 protein is a neuronal as well as a glial protein. Neuronal S-100 is a migratory protein from soma to terminal of the hypoglossal, vagus and glossopharyngeal nerves of the rabbit (axonal transport of S-100 protein). There is a distinctive rate of flow for S-100 in the somatic and parasympathetic efferent fibres of such cranial nerves.     

RAPID AXOPLASMIC TRANSPORT OF PROTEINS IN REGENERATING SENSORY NERVE FIBERS

Abstract— Utilizing an in vitro labeling procedure, the proteins carried by rapid axoplasmic transport in normal and regenerating sensory fibers of the rat sciatic nerve were compared. No statistically significant differences were found when the total amount of transported protein was compared in control and sectioned nerves at times from 2 to 76 days following axotomy. Fractionation of labeled proteins on polyacrylamide slab gels enabled the identification of some 25 individual transported proteins. By this criterion, no differences were detectable in the composition of proteins synthesized in the dorsal root ganglia from which sectioned vs control sciatic nerves project. When the electrophoretic distributions of transported proteins from control and sectioned nerves were compared, significant' differences were observed. The appearance and disappearance of two proteins were temporally related to chromatolytic changes in the nerve cell body. In addition, the composition of transported proteins in undamaged control nerves contralateral to the sectioned nerves exhibited changes which were not observed in either normal control nerves or sectioned nerves. Changes in the composition of transported proteins as a function of time following the onset of chromatolysis may be involved in controlling nerve regeneration in sensory nerve fibers.     

RETROGRADE AXONAL TRANSPORT OF RAPIDLY MIGRATING LABELLED PROTEINS AND GLYCOPROTEINS IN REGENERATING PERIPHERAL NERVES

Abstract— The redistribution of rapidly migrating [³H]leucine-labelled proteins and [³H]fucose-labelled glycoproteins was studied in ligated regenerating hypoglossal and vagus nerves of the rabbit. When regenerating and contralateral hypoglossal nerves were ligated 16 h after labelling of the nerve cell bodies, rapidly migrating proteins and glycoproteins accumulated distal to the ligatures indicating a rapid retrograde transport from the peripheral parts of the nerves within 6 h. The retrograde accumulation of both proteins and glycoproteins was greater on the regenerating side than on the contralateral side at both 1 and 5 weeks after a nerve crush. Labelled proteins and glycoproteins also accumulated proximal to the ligatures, indicating a delayed rapid anterograde phase of axonal transport. The accumulation of this phase was also greater on the regenerating side 1 week after a nerve crush for both labelled proteins and glycoproteins. One week after a crush of the cervical vagus nerve, rapidly migrating proteins and glycoproteins redistributed between he crush zone and a proximal ligature applied 16 h after labelling of the nerve cell bodies. A retrograde accumulation occurred distal to the ligature within 6 h, indicating a rapid retrograde transport from the crush zone.     

AXONAL TRANSPORT OF PHENYLETHANOLAMINE-N-METHYLTRANSFERASE IN TOAD SCIATIC NERVE

—The presence of phenylethanolamine-N-methyltransferase (EC 2.1.1.-) and dopamine-β-hydroxylase (EC 1.14.2.1) activities was demonstrated in the sciatic nerve of the toad, Bufo marinus. The rates of accumulation of phenylethanolamine-N-methyltransferase (PNMT) and dopamine-β-hydroxylase (DBH) proximal to a ligation of the sciatic nerve were studied. DBH accumulated proximal to the ligation at a more than 10-fold faster rate than PNMT. By measuring the rate of loss of enzyme activity distal to a ligation, an estimate of per cent clearance of each enzyme was made. Based on the per cent of enzyme activity free to move, the absolute transport rates for each enzyme were estimated to be: PNMT, 3.6 mm/24 h; DBH, 102 mm/24 h. PNMT activity (89 per cent) was recovered in the soluble fraction of sciatic nerve homogenates with no change occurring in the subcellular distribution of the enzyme proximal to ligations. In contrast, 43 per cent of DBH activity was found in the soluble fraction of sciatic nerve homogenates; but a disproportionate increase in paniculate DBH activity was found proximal to sciatic nerve ligations. Reduction of toad body temperature to 4°C resulted in a complete but totally reversible block of the axonal transport of both PNMT and DBH.     

AUTORADIOGRAPHIC STUDY OF RNA IN NERVE FIBRES OF EMBRYONIC SENSORY GANGLIA CULTURED IN VITRO UNDER NGF STIMULATION

Abstract— The presence and distribution of RNA in nerve fibres was studied by autoradiographic detection of [³H]uridine incorporation in chick embryo sensory nerve cells cultured in vitro under the effect of the Nerve Growth Factor. The presence of RNA in these fibres, free from satellite cells, is demonstrated. The cellular origin of the fibre RNA is, at least in part, proved.     

AXONAL TRANSPORT OF LIPIDS IN THE RABBIT OPTIC SYSTEM

Abstract— Axonal transport of lipids was demonstrated in the rabbit optic system using [2-³H]glycerol and [3-¹⁴C]serine. Following intraocular injection of these precursors, radioactive lipids were detected in the optic tract, superior colliculus and lateral geniculate body over a 31 day period. The bulk of lipid appeared to migrate at a rate equivalent to that of rapidly transported protein which, when combined with a prolonged period of release into the axon, led to a peak of transported radioactivity at 6-10 days for the 3 tissues. The suggestion of a second peak at 17 days indicated the possibility of a smaller slow component, although another interpretation is suggested. Analysis of individual transported lipids revealed [2-³H]glycerol to label phosphoglycerides preferentially and [3-¹⁴C]serine to be an effective precursor for sphingolipids and certain of the phosphoglycerides. [3-¹⁴C]Serine labeled axonally transported proteins to an even greater extent than lipids, revealing the same fast and slow components previously shown with other amino acids.     

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 OF PROTEINS IN THE HYPOTHALAMO-NEUROHYPOPHYSIAL SYSTEM OF THE RAT

—Axonal transport of proteins in the hypothalamo-neurohypophysial system of the rat was studied after a local injection of [³⁵S]cysteine in the region of the supraoptic nucleus. The migration of labelled proteins was followed by measuring the specific radioactivity of the proteins in various parts of the hypothalamo-neurohypophysial tract. Between 2 and 4 h after the isotope injection there was a sharp increase in the protein-bound specific radioactivity of the posterior pituitary lobe, demonstrating that a transport of ³⁵S-labelled proteins had occurred from the supraoptic nucleus to the neurohypophysis. The rate of the transport was 2-3 mm/h. During the first 24 h after the injection a continuous accumulation of labelled material occurred in the neural lobe. Considerable radioactivity could still be recovered 6 days after the isotope injection. Fractionation of the neurohypophysial proteins by polyacrylamide gel electrophoresis revealed that approximately 90 per cent of the radioactivity of the soluble proteins was recovered in a single protein fraction. Labelling of this fraction was not observed until 2 h after isotope injection. The radioactivity increased markedly up to 4 h. It is suggested that this protein component is involved in the neurohypophysial response to osmotic stress since the protein disappeared from the posterior lobe upon dehydration of the rat.     

ANALYSIS OF PROTEINS UNDERGOING AXONAL TRANSPORT IN NIGRO-STRIATAL NEURONS IN THE RAT

Abstract— An analysis of proteins undergoing axonal transport in nigro-striatal neurons, after the stereotaxic injection of [³H]leucine into the substantia nigra of rat brain was performed. As early as 6 h after the injection [³H]proteins appeared in the caudate-putamen. The maximum accumulation was at 5 days and there was still residual protein radioactivity present at 30 days. About 70 per cent of the total radioactive protein in the caudate-putamen was solubilized by homogenization in 0–5%, (v/v) Triton X-100 and remained in the supernatant on centrifuging for 1 h at 100,000 g. The supernatant fraction, when chroma-tographed on a DEAE-cellulose column, was resolved into four protein peaks (A, B. C and D) which were found to be labelled differently as a function of time after the injection of [³H]leucine. Peak A was substantially labelled in a first phase (6–24 h) and reached its maximum in a second phase (5 days). The proteins comprising this peak appeared to undergo both fast and slow axonal transport. Although some labelling in peak B was evident at 6 h, maximal activity did not occur until 5 days. No radioactivity could be detected in peaks C and D at 6 h. Maximal labelling of these two peaks also occurred at 5 days. These data suggest that the proteins of peaks B, C and D were transported primarily by slow axoplasmic flow. The radioactive protein peaks A and B from the second phase of the transport were excluded from a Sephadex G-200 column, pointing to their high molecular weights (13,000–200,000). Peak B. which had the highest specific radioactivity (c.p.m./mg protein) at 5 days, contained a significant level of tyrosine hydroxylase, an important component of dopaminergic neurons.     

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.     

PROTEINS OF AXONAL TRANSPORT: INTERACTION OF RAPIDLY TRANSPORTED PROTEINS WITH LECTINS

Rapidly transported fucose-labelled glycoproteins from the optic system of the rabbit were solubilised with the non-ionic detergent Berol 172. The major labelled components were bound to wheat germ agglutinin or Concanavalin A coupled to Sepharose but not to other lectins or glycoproteins. It was concluded that rapidly transported proteins contain exposed N-acetyl-D-glucosamine     

AXONAL TRANSPORT OF SULFATED GLYCOPROTEINS AND MUCOPOLYSACCHARIDES IN THE GARFISH OLFACTORY NERVE

—Application of ³⁵SO₄ to the olfactory mucosa of the long-nosed garfish is found to label sulfated macromolecules which are transported down the olfactory nerve. The transported molecules pass along the nerve as a discrete peak whose leading edge has a transport velocity of 206 ± 6 mm/day. A large portion of the radioactivity from the peak is deposited along the axon. At 2 days after isotope application 83% of the total nerve radioactivity is in the axons and the remaining 17% has accumulated at the terminals in the olfactory bulb. Characterization of sulfated material in the migrating peak indicates that both sulfated glycoproteins (isolated as glycopeptides) and mucopolysaccharides, including chondroitin sulfate and heparan sulfate, are undergoing transport.     

AXONAL TRANSPORT OF RADIOACTIVITY IN THE GOLDFISH OPTIC SYSTEM FOLLOWING INTRAOCULAR INJECTION OF LABELLED RNA PRECURSORS

After injection of the tritiated RNA precursors [³H]guanosine, [³H]uridine or [³H]orotic acid into the eye of goldfish, labelled TCA-soluble material and RNA appeared to be axonally transported to the contralateral optic tectum. From the time courses of arrival in the tectum,‘average’rates of transport of 6 mm/day for the soluble material and 1·7 mm/day for the RNA were calculated. If the optic nerve was cut after the transported material had arrived in the tectum, about 60 per cent of the TCA-soluble material disappeared by 7 days after the cut, but almost none of the RNA. After a further 8- to 13-day period, the TCA-soluble material had declined by a further 50 per cent from the 7-day value, but the RNA by only 20 per cent. Thus, relatively little RNA was lost when the optic axons degenerated, an observation which suggested that the RNA might be extra-axonal. However, if the optic nerve was crushed before the arrival of the transported material, RNA did not appear in the tectum until the regenerating optic nerve fibres arrived. Therefore, the presence of RNA must be dependent on intact nerve fibres. Moreover, in the earliest stages of regeneration the proportion of transported RNA to TCA-soluble material was considerably higher than normal, suggesting that the regenerating fibres arrived in the tectum already carrying RNA. This implies that the RNA itself was transported in the optic fibres.     

BLOCKADE OF FAST AXONAL TRANSPORT BY DIPHTHERITIC DEMYELINATION IN THE CHICKEN SCIATIC NERVE

Chicken sciatic nerves undergo demyelination following intraneural injection of diphtheria toxin due to a lesion at the site of injection. Paresis occurs after 1 week and lasts for approx 3 weeks; at the height of the lesion we injected [¹⁴C]Ieucine into the ventral horn cells of the spinal cord and followed the axonal transport of fast flowing labelled proteins down the sciatic nerve fibres making measurements of flow rates at two different times. The results showed the fast flowing labelled proteins were blocked at the demyelination site. We measured total protein in the nerves and examined them histologically to confirm the lesion. Further studies are in progress on the post synaptic muscle cells and the impaired nerves.     

AXONAL TRANSPORT OF PROTEIN IN THE OPTIC NERVE OF OCTOPUS VULGARIS, LAM.

Abstract— The presence of an axonal flow of proteins has been investigated in the optic nerve and lobe of Octopus vulgaris up to 5 days after the intraocular injection of [³H]leucine. In each of these regions and in the posterior half of the eye the content of radioactivity has been determined in the TCA-soluble fraction and in the saline-soluble and insoluble protein fractions.
After subtraction of the values of the control side, the concentration of radioactive proteins in the optic nerve and lobe of the injected side was found to increase according to a triphasic pattern. An initial phase of fast increase was followed by a period of essentially steady values and, eventually, by a second phase of less rapid but more prolonged increment. In both regions the per cent of radioactive soluble proteins increased after the completion of the first phase.     

AXOPLASMIC TRANSPORT IN THE OPTIC NERVE AND TRACT OF THE RABBIT

The axonal transport of labelled proteins was studied in the optic system of adult rabbits after an intraocular injection of [³H]Ieucine. It was demonstrated that the precursor was incorporated into protein, which was transported along the axons of the retinal ganglion cells. Intraocularly injected puromycin inhibited protein synthesis in the retina and markedly inhibited the appearance of labelled protein in the optic nerve and tract. It was further demonstrated by intracisternal injection of [³H]leucine that an intraocular injection of puromycin did not affect the local protein synthesis in the optic nerve and tract. Cell fractionation studies of the optic nerve and tract showed that the rapidly migrating component, previously described as moving at an average rate of 110-150 mm/day, was largely associated with the microsomal fraction. About 40 per cent of the total protein-bound radioactivity in this component was found in the microsomal fraction and about 15 per cent was recovered in the soluble protein fraction. Most of the labelled material moving at a rate of 1-5-2 mm/day was soluble protein. The specific radioactivity of this component was about ten times greater than that of the fast one. In the slow component about 50 per cent of the radioactivity was found in the soluble protein fraction and about 10 per cent of the radioactivity was recovered in the microsomal fraction. Radioautography demonstrated incorporated label in the neuropil structures in the lateral geniculate body as early as 4-8 hr after intraocular injection. The labelling of the neuropil increased markedly during the first week, and could be observed after 3 weeks.     

RABBIT SCIATIC NERVE FASCICLE AND''ENDONEURIAL''PREPARATIONS FOR IN VITRO STUDIES OF PERIPHERAL NERVE GLUCOSE METABOLISM

Abstract— Suitable preparations for in vitro studies of the composite glucose and energy metabolism of peripheral nerve axons and Schwann cells have not been available. Methods are described for the preparation and incubation of a defined segment of a rabbit sciatic nerve fascicle, free of epineurial contamination, but with an intact perineurial membrane; removing the perineurium provides in addition an‘endoneurial’preparation. Conditions were selected for incubating each preparation with glucose that maintained stable P-creatine and ATP concentrations and a stable rate of O₂ uptake; under these conditions the preparations retained an unaltered EM appearance during a 2-h incubation. Glucose diffusion into the endoneurial compartment of the fascicle is restricted, possibly by the perineurial membrane, and a higher medium glucose concentration (20 mM) was required to maintain a steady state of energy metabolism in this preparation than in the‘endoneurial’preparation, which was incubated with 5 mwglucose. The‘endoneurial’preparation required 0.50 mm -myoinositol in the medium to prevent a decrease in tissue free myoinositol and a slow decrease in O₂ uptake, which occurred when it was omitted. Under the incubation conditions selected the glucose concentrations in the‘endoneurial’preparation and in the endoneurial compartment of the fascicle were reasonably similar, and the preparations had similar rates of respiration, similar estimated rates of glucose utilization, and similar relative rates of respiration and lactate production. The preparations derive the major fraction of their energy requirements from respiration. Their rates of O₂ uptake are 60% higher than the previous indirect estimate of O₂ uptake in whole rabbit tibial nerve in situ. Constant rates of incorporation of ¹⁴C from [U-¹⁴C]glucose into CO₂ and total lipid were observed in the‘endoneurial’preparation after a 15-min equilibration period. The preparations reported provide suitable tools for in vitro studies of peripheral nerve metabolism not previously available.