Fast and slow phases of axoplasmic flow in ventral root nerve fibres

Cytoplasmic mechanisms of axonal and dendritic growth in neurons

The structural mechanisms responsible for the gradual elaboration of the cytoplasmic elongation of neurons are reviewed. In addition to discussing recent work, important older work is included to inform newcomers to the field how the current perspective arose. The highly specialized axon and the less exaggerated dendrite both result from the advance of the motile growth cone. In the area of physiology, studies in the last decade have directly confirmed the classic model of the growth cone pulling forward and the axon elongating from this tension. Particularly in the case of the axon, cytoplasmic elongation is closely linked to the formation of an axial microtubule bundle from behind the advancing growth cone. Substantial progress has been made in understanding the expression of microtubule-associated proteins during neuronal differentiation to stiffen and stabilize axonal microtubules, providing specialized structural support. Studies of membrane organelle transport along the axonal microtubules produced an explosion of knowledge about ATPase molecules serving as motors driving material along microtubule rails. However, most aspects of the cytoplasmic mechanisms responsible for neurogenesis remain poorly understood. There is little agreement on mechanisms for the addition of new plasma membrane or the addition of new cytoskeletal filaments in the growing axon. Also poorly understood are the mechanisms that couple the promiscuous motility of the growth cone to the addition of cytoplasmic elements.

Electrophoretic analysis of axonally transported proteins in rabbit vagus nerve

Proteins synthesized in the nodose ganglia of rabbits were radiolabeled with 35S-methionine and the proteins present in the vagus nerve, at various times later, were analyzed by SDS (sodium dodecyl sulfate)-polyacrylamide gel electrophoresis. Three major groups of proteins were transported as waves of radioactivity within the nerve at rates of 15-17 mm/h, 12-15 mm/day, and 25-30 mm/day. The front of the fastest wave was composed of two proteins only, of apparent molecular weights 21,000 and 24,000. These were followed after a delay by a number of proteins of higher molecular weight, traveling at the same fast rate. The 25-mm/day wave contained several proteins including a major one of molecular weight 43,000 while the 12-mm/day wave was composed entirely of two proteins of molecular weights 54,000 and 56,000. These groups of slowly transported proteins are therefore similar to those transported much more slowly in other mammalian nerves, with the exception that no proteins with molecular weight similar to the neurofilament proteins could be detected. We have confirmed the dependence of slow transport for both groups of proteins on contact between cell body and axon and suggest that it may be a general phenomenon in all mammalian nerves.

Routing of transported materials in the dorsal root and nerve fiber branches of the dorsal root ganglion

After injection of the L7 dorsal root ganglion with 3H-leucine, fast axoplasmic transport carries some 3--5 x more labeled materials down the sensory fibers branches entering the sciatic nerve as compared to the dorsal root fiber branches of the neurons. Freeze-substitution preparations taken from the two sides of the lumbar seventh dorsal root ganglia of cats and monkeys showed little difference in the histograms of nerve fiber diameters of the sensory nerve fiber branch of these neurons as compared to the dorsal root fiber branches. A similar density of microtubules and of neurofilaments in the dorsal root and sensory nerve fiber branches over a wide range of fiber diameters was found in electron micrograph preparations. In the absence of an anatomical difference in the fibers to account for the asymmetrical outflow, a functional explanation based on the transport filament model was advanced.

The influence of supraspinal impulse activity on the intra-axonal transport of acetylcholine, choline acetyltransferase and acetylcholinesterase in rat motor neurons

The effect of supraspinal impulse activity upon the intra-axonal transport of acetylcholine (ACh), ACh esterase (AChE) and cholineacetyltransferase (CAT) in rat sciatic nerve has been studied. A decreased inpulse activity was obtained by spinal cord transsection (SCT) in the thoracic region 18 h, 6 days or 20 days before killing the rats. An increased neuronal activity was obtained by exercising the rats in a commercial rodent treadmill a couple of hours per day for 14 days. The amounts of substances which had accumulated in the sciatic nerve segments relative to a nerve crush performed 12 or 18 h. earlier were used to calculate the intra-axonal transport. The amounts of proximo-distal transported ACh decreased markedly with time after the SCT, while the proximo-distal transport of AChE-activity increased. Physical exercise appeared to increase ACh-transport. Thus, input to motor pericarya from supraspinal centers may regulate intra-axonal transport from the cell body of motor neurons into their axons.

Axoplasmic transport in the toad Bufo marinus

The rate and course of axoplasmic transport from the eighth dorsal root ganglion cell bodies into the sciatic nerve of the toad Bufo marinus were studied. Concentrated tritiated proline was hydraulically injected into a surgically exposed dorsal root ganglion of animals maintained at 19 +/- 0.5 degrees C. At postinjection intervals of 1, 6, and 10 h, the animals were sacrificed and the dorsal root, ganglion, and sciatic nerve were removed bilaterally. The dorsal roots and peripheral nerves were cut into 3 mm segments measured from the ganglion. In some experiments all tissues were prepared for liquid scintillation counting techniques. In others the ganglion and every fifth 3 mm nerve segment were fixed in Bouin's fixative for radioautography, and the remaining tissue segments were prepared for liquid scintillation counting methods. Scintillation counts (counts/min) of consecutive segments along the labeled nerve were plotted against distance (mm) for each animal. Examination of these profiles showed a peak of radioactivity in the injected ganglion for each animal that was followed distally by an abrupt drop in the adjacent segments of the nerve. Radioactivity remained relatively stable in subsequent segments forming a plateau and then dropped to baseline levels forming a wavefront in the distal portion of the peripheral nerves of the 6 and 10 h toads. Movement of this wavefront during the 6 to 10 h time interval provided evidence for an axoplasmic flow rate of about 120 mm/day. Radioautographs of the ganglion and representative segments along the sciatic nerve were examined with both bright- and dark-field microscopy. Accumulations of silver grains were observed overlying the injected ganglion cell bodies and labeled axons of the nerve. Values for the number of silver grains/unit area were obtained from dark-field radioautographs of the nerve segments through the use of a computer-microscope system. The relative amount of radioactivity present in the axons was thereby demonstrated. Radioautographic data confirmed the axoplasmic flow rate of about 120 mm/day determined by liquid scintillation counting methods for the bulk of radioactive materials transported at this fast rate. In addition, the evaluation of radioautographic data suggests that an even faster flow rate of 185-215 mm/day may exist for a small portion of the labeled materials transported in the axon.

Slow axonal transport or proteins; blockade by interruption of contact between cell body and axon

The influence of ligation and colchicine treatment on the axonal transport of slowly migrating [3H]leucine-labelled proteins was studied in the vagus nerve of the rabbit. Two days after [3H]leucine labelling of the dorsal motor nucleus of the vagus nerve, ligation or local application of 60 mM colchicine immediately blocked the further progression of slowly migrating proteins distal to the site of treatment. Application of 50-100 mug colchicine to the nerve cell bodies 2 days after labelling blocked the transport of slowly migrating proteins within the next 24 h. It is suggested that contact between nerve cell body and the axon is necessary for the maintenance of the slow transport of proteins in these nerves.

Intraaxonal and extraaxonal transport of 125I-tetanus toxin in early local tetanus

The distribution of radioactivity in the sciatic nerve, the spinal ganglia, the ventral roots and the spinal cord was studied by means of histoautoradiography after injection of 125I-labelled tetanus toxin into gastrocnemius muscles of cats. In the sciatic nerve the major part of the radioactivity was found in the epineurium, but some axons also contained radioactivity. In the ventral root the radioactivity was strictly confined to a few axons; no radioactivity was found in other parts of the ventral root. In the spinal cord the radioactivity was confined to a few motoneurones where it was found in the soma as well as in the dendrites. Transient cooling of the ventral roots prevented the ascent of radioactivity into the spinal cord. Colchicine and vinblastine, after local application to the sciatic nerve, reduced the amount of radioactivity found in the ventral roots and in the spinal cord. However, the same effect was also obtained but to a lesser degree with lumicolchicine. It is concluded that the intraaxonal compartment is involved in the neural ascent of tetanus toxin into the spinal cord.

Low temperature slowing and cold-block of fast axoplasmic transport in mammalian nerves in vitro

1) Fast axoplasmic transport in mammalian nerve in vitro was studied using an isotope labeling technique. The rate of outflow in cat sciatic nerve fibers of 410 mm/day in vitro was reduced at temperatures below 38 degrees C with a Q10 of 2.0 in the range 38-18 degrees C and a Q10 of 2.3 at 38-13 degrees C. 2) At a temperature of 11 degrees C a partial failure of transport occurred. At temperatures below 11 degrees C a complete block of fast axoplasmic transport occurred, a phenomenon termed "cold-block." No transport at all was seen over the temperature range of 10-0 degrees C for times lasting up to 48 hr. 3) Transport was resumed after a period of cold-block lasting up to 22 hr when the nerves were brought back to a temperature of 38 degrees C. Some deleterious effects due to cold-block were seen in the recovery phase as indicated by a reduction in crest amplitude, change in its form, and slowed rate. 4) The approximately P level (combined ATP and creatine phosphate) remained near control level in nerves kept at low or cold-block temperatures for times as long as 64 hr. The reduction in fast axoplasmic transport rate seen at low temperatures for times up to 22 hr was therefore considered due to a decrease in the utilization of ATP, a concept in accord with the "transport filament" model proposed to account for fast axoplasmic transport. 5) The sloping of the front of the crest over the temperature range of 18-13 degrees C suggests an additional factor at the lower temperatures. A disassembly of microtubules is discussed as a possible explanation of the cold-block phenomenon.

Differential transport of protein in axons: comparison between the sciatic nerve and dorsal columns of cats

Fast axoplasmic transport was studied in dorsal root ganglion cells of the cat. Proteins carried in the fast axoplasmic flow were labeled after an intraganglionic injection of (L)-[4,5-(3)H]leucine. The rate of transport was 380 +/- 26 mm/day in both the central and peripheral branches of the bifurcating axons that arise from cells of the dorsal root ganglion. The amount of radioactivity transported centrally, through the dorsal roots into the spinal cord, was about 50% of that moving peripherally, through the sensory fibers of the sciatic nerve. Labeled material appears to be transported principally in a bound form, as 70-80% of the radioactivity was insoluble in 0.01 M potassium phosphate buffer at pH 7.4. With multiple extractions, a fractionation procedure was developed by which 94-96% of the total transported radioactivity could be solubilized. The proteins carried by fast axoplasmic transport through the dorsal columns and through the sciatic nerve were compared by electrophoresis of extracted fractions on Na dodecyl sulfate-polyacrylamide gels. Different patterns of radioactivity are seen in the electrophoretograms, suggesting that the cells of the dorsal root ganglion may possess the ability to commit different proteins to transport through two branches of a single bifurcating axon.

Rate of fast axoplasmic transport in mammalian nerve fibres

1. Fast axoplasmic transport in mammalian nerve fibres was determined by the presence of a crest of activity in the sciatic nerve after injection of [(3)H]leucine into the L7 dorsal root ganglion or the L7 motoneurone region in the ventral horn region of the spinal cord. After incorporation into proteins by the cell bodies, a rate of transport close to 410 mm/day was found for cat sensory nerves. A closely similar rate was found in the motor and sensory sciatic nerve fibres of the monkey, dog, rabbit, goat and rat. In the longer nerves where longer downflow times were possible, there was no decrement of rate with distance, or presence of later appearing crests of activity indicative of multiple fast transport systems.2. The rate of fast transport found in the long L7 dorsal roots of the rhesus monkey was the same as that in the corresponding length of sciatic nerve and the same fast rate was shown by the crest of activity ascending in the dorsal columns of the spinal cord.3. Labelled activity was found present inside myelinated nerve fibres ranging in diameter from 3 to 23 mum in nerve segments taken at the forward part of the crest suggesting that the rate of fast axoplasmic transport is independent of fibre diameter.

Rapid axonal transport of sulfated mucopolysaccharide proteins

When sulfur-35-labeled sodium sulfate is injected intraocularly in the goldfish, labeled sulfated mucopolysaccharides rapidly appear in the contra-lateral optic tectum of the brain, demonstrating the axonal flow of sulfated mucopolysaccharides. The transport rate is the same as that observed for proteins labeled after intraocular injection of tritiated proline. Treatment of the sulfur-35-labeled material with precipitants and enzymes reveals the presence of substances with properties similar to those of heparan sulfate (the major component) and chondroitin sulfate. Dermatan sulfate was not detected.

Metabolic dependence of fast axoplasmic transport in nerve

Fast axoplasmic transport, shown in cat sciatic nerves by a crest of labeled activity after injection of the L7 ganglion with [(3)H]-leucine or [ (3)H]-lysine, was stopped within 15 minutes after death of the animals by bleeding. If the sciatic nerves were removed from the animals and placed in a chamber supplied with oxygen at 38 degrees centigrade, fast transport was sustained. Transport was rapidly blocked in similar in vitro preparations when the nerves were kept in a nitrogen environment. Fast axoplasmic transport is closely dependent upon oxibdative metabolism.