Axoplasmic transport

Subcellular fractionation of rapidly transported axonal material in olfactory nerve: evidence for a size- dependent molecule separation during transport

[(3)H]Leucine applied to the olfactory mucosae of garfish pike results in rapid precursor uptake, incorporation into proteins and export of labeled protein by axoplasmic transport. The resulting characteristic isotope distributions along the nerve have been subjected to subcellular fractionation. More label is found associated with the particulete fraction obtained from the most rapidly moving profile region than from the regions produced by more slowly moving material. The smaller material tends to separate from the larger molecular complexes by trailing behind. The results are discussed in relation to the transport mechanism.

Simulation of axoplasmic transport

We have analysed a kinetic model of axonal transport by simulating experimental tracer profiles. The existence of three phases of axoplasmic transport is assumed: fast anterograde, slow anterograde and retrograde. Each phase has its characteristic velocity. Transported materials are postulated to shift between these phases. Also catabolism and sequestration of material is allowed for in our model. Thus, we have set up equations which contain axonal transport, diffusion and cross-over terms. The rate constants of material shifts were determined by computer fitting to experimental data. Best-fitted values of the rate constants for transfer of material between the fast and slow phases were both 2 X 10(-5) sec-1, while the rate constants for transfer between the fast and retrograde phases were both 1 X 10(-5) sec-1. The rate constant of material loss from the slow phase to the extracellular space was 1 X 10(-6) sec-1. The material shift between the slow and retrograde phases was negligibly small. These data show that there is exchange of material between the fast and slow phases and between the fast and retrograde phases. However, there is no significant exchange between the slow and retrograde phases. Diffusion was found to have only a minor effect on the profiles. The velocity of the fast anterograde track in cold-blooded animals was predicted to be around 200 mm/day, or, in other words, to be close to experimentally observed values of the fast anterograde component of axonal transport.

Is intracellular acetylcholinesterase involved in the processing of peptide neurotransmitters?

The evidence that acetylcholinesterase may be a peptidase with a role in the processing of the precursors of some neuropeptides is briefly summarized. The proposition that the rate of processing and not the synthesis of the precursor may be the limiting step in the provision of neuropeptides to the nerve terminal will also be evaluated.

A paradigm for axonal transport

Axonal transport has been extensively studied for a period of 20-30 years, but there is still no general consensus concerning the mechanism by which this transport process operates. An important development in this regard is the recent studies in the physical biochemistry group in the Department of Biochemistry at Monash University where it has been demonstrated that ordered flows may be generated spontaneously in polymer systems under non-equilibrium conditions. The new phenomenon exhibits many novel features, particularly with respect to polymer transport, which bear marked similarity to the behaviour of components in axonal transport. This article sets out to essentially bring to the attention of those in the neurosciences some of the properties of ordered structured flows in polymer solutions. These properties may generate a different view in the understanding of the mechanism of axonal transport.

Axonal transport of the molecular forms of acetylcholinesterase in chick sciatic nerve

Acetylcholinesterase (AChE) polymorphism was studied in the sciatic nerve of 4-week-old Leghorn chicks, by sucrose gradient sedimentation analysis. Four main AChE molecular forms were found with sedimentation coefficients of 5S, 7.5S, 11.5S and 20S respectively. Axonal transport of each of these forms was investigated on the basis of the enzyme accumulation kinetics measured on both sides of nerve transections and of the enzyme redistribution kinetics in nerve segments isolated in vivo. After nerve transection, 11.5S and 20S forms accumulated faster in the anterograde than in the retrograde direction and also much faster than 5S and 7.5S forms in the anterograde direction. Retrograde accumulations of 5S and 7.5S were faint or negligible. In addition, 1 h after nerve cutting, the accumulation rates for 11.5S and 20S forms (but not for 5S and 7.5S) fell, in both directions, to about one-third of their initial values, probably owing to reversal of axonal transport at the axotomy site. Local protein synthesis inhibition by cycloheximide did not affect the accumulation of 11.5S and 20S in front of a transection, at least during the first hours, but reduced that of 5S and 7.5S by about 40%. In isolated nerve segments in vivo, the rapidly mobile fraction of AChE was estimated to constitute 23% of the total enzyme activity present in the nerve, 14% of it moving in an anterograde and 9% in a retrograde direction. A small amount of 11.5S molecules (approx. 20%) was in rapid transit (two-thirds in the anterograde and one-third in the retrograde direction), whereas almost all the 20S--about 90%--migrated rapidly (two-thirds forwards and one-third backwards). Anterograde velocities of 408 +/- 94 and 411 +/- 161 mm/day respectively were estimated for the 11.5S and 20S forms. Their respective retrograde velocities were 175 +/- 85 and 145 +/- 107 mm/day. Assuming that the totality of 5S and 7.5S molecules are moving in the anterograde direction, their accumulation rates were consistent with the average anterograde velocities of 2.9 +/- 1.3 and 5.1 +/- 1.4 mm/day, respectively.

Cholesterol is a component of the rapid phase of axonal transport

Twenty-two-day-old rats were injected intraocularly with [3H]acetate and killed between 1 hr and 35 days later. Cholesterol was isolated from the retinas, optic tracts, lateral geniculate bodies, and superior colliculi. Within the retina, radioactivity was rapidly incorporated into cholesterol with maximal labeling present one hour after injection. Transported labeled cholesterol (contralaterally corrected for systemic background labeling) was present in the superior colliculus by three hours. Radioactive cholesterol accumulated in all visual structures throughout the 35-day period, but the rate of accumulation was maximal at about the time of arrival of the initial pulse of radioactivity. Colchicine treatment of the retina blocked transport of cholesterol but not its synthesis by the retina. The results indicate that cholesterol is rapidly transported in the visual system and also released from the retina for a prolonged period after its synthesis.

The short term accumulation of axonally transported organelles in the region of localized lesions of single myelinated axons

Myelinated axons were isolated from the sciatic nerve of Xenopus laevis and were subjected to localized (less than 30 microns wide) lesions. In axons which were bathed in a 0.12 M potassium glutamate solution there was very little local reaction to the lesion and optically-detectable particles undergoing axoplasmic transport accumulated immediately adjacent to, and mostly distal to, the lesion. Preparations fixed for electron microscopy at times up to 3 h following the lesion showed that the axoplasmic changes about the lesion were asymmetrical. Large organelles predominated on the distal side of the lesion; these were mostly dense lamellar bodies (DLB) with mean dimensions, as determined from thin sections, of 0.48 by 0.19 microns. Multivesicular bodies, mitochondria, and a variety of smaller membrane bounded bodies also appeared in the particle accumulation distal to the lesion. Analysis of these results led to the conclusion that DLB were transported up to the lesion and represent the majority of the optically detectable particles which are transported in the retrograde direction. Small vesicles and tubules were the commonest structures which accumulated proximal to the lesion. The time course of this accumulation was consistent with the hypothesis that these structures are particulate bodies which move in the orthograde direction at about 1.5 microns/s. Incidental findings which are also of significance to the study of axonal transport were: large particulate material may reverse its direction of movement at an axonal obstruction, and organelles which accumulate on either side of a lesion do so in rows which are associated with microtubules.

Bidirectional axonal transport of free glycine in identified neurons R3--R14 of Aplysia

The axonal transport of 3H-amino acids was studied in the axons of identified neurons R3--R14 in the parietovisceral ganglion (PVG) of the mollusc Aplysia. The PVG was incubated (3--24 hr) in media containing physiological concentrations of single 3H-amino acids while the isolated nerve was superfused with plain or chemically altered media. The nerve was then sliced into sequential segments for biochemical analyses or fixed for autoradiography. 3H-glucine was transported at 70 mm/day in 6X greater quantities than other amino acids which were transported at less than 40 mm/day. In the 3H-glycine experiments, greater than 80% of the label transported into the nerve remained as free glycine, comigrating with glycine in thin-layer chromatographs. In autoradiographs of sections 4 mm from the ganglion-nerve barrier, greater than 50% of the silver grains were over R3--R14 axons which occupy less than 10% of the nerve cross-sectional area. EM autoradiographs confirmed that grains were within R3--R14 and not in surrounding glia. The selective transport of glycine was inhibited by Hg2+, by vinblastine and Nocodazole, and by low Ca2+ media. Autoradiographs of vinblastine-treated nerves showed a drastic reduction in label over R3--R14 and other axons. Label was also transported retrogradely; this transport rate was similar to the orthograde rate, but 5--10 times less label moved retrogradely. Autoradiographs showed that the retrograde label was localized to R3--R14 axons. This report clearly demonstrates the rapid, selective, and bidirectional transport of a free amino acid and provides further evidence that glycine may be used as a neurochemical messenter by neurons R3--R14.

A multiwire proportional chamber study of axoplasmic transport in frog sciatic nerve involving interruption of somatic supply

A multiwire proportional chamber was used to detect axoplasmic transport in isolated spinal-cord-sciatic nerve preparations in which the nerve cell bodies were exposed to L-[35S]methionine. The detector collected radiation from a series of 6-mm segments of sciatic nerve for consecutive periods of 30 min for the duration of experiments lasting 16--23 h. The radioactivity of each segment showed an initial plateau at background level followed by a rise which was approximately linear through time. Plots of the time at which the rise in radioactivity took place against the position of each segment of the nerve yielded transport velocities for the most rapidly moving label; at room temperature (21--23 degrees C) these were typically 150 mm/24 h. Approximately 1.5 h after the addition of 5 mM colchicine to the bathing solution the slope of the radioactivity-time curve decreased for all segments of the nerve; this indicated that the method satisfactorily detected impaired axoplasmic transport. If the sciatic nerve were severed at the proximal end of the preparation at about 9 h after the radioactive front had been established, the slope of the radioactivity-time curve for each nerve segment subsequently changed abruptly. Plots of the time at which the transition occurred against position in the nerve yielded transport velocities which did not differ statistically from those of the radioactive front. This transition time is thought to indicate the time at which the fastest labelled material left each segment of nerve. In some experiments, an additional change in slope occurred, possibly indicating the departure of the slowest material from each segment.

Axonal transport of 4S RNA in the chick optic system

The axonal transport of tRNA has been investigated in the chick optic system. Chicks were injected with [3H]uridine intraocularly or intracranially and the RNA of the retina, nerve complex, and tecta separated by polyacrylamide gel electrophoresis and then counted. The ratio of tRNA to rRNA specific activities increased with time in both the nerve complex and contralateral tectum. The ratio increased more rapidly in the nerve complex than the tectum. However, no increase was observed in the case of intracranially injected animals. This is consistent with the axonal flow of tRNA. When [methyl-3H]methionine was used as precursor, the preferential labeling of 4S RNA to rRNA which resulted more clearly showed a transport of 4S RNA from the retinal cells to the tectum. In conclusion, it was found that about 40% of the radioactive RNA observed within the optic tectum 4 days after an intraocular injection of [3H]uridine was accounted for by 4S RNA which has flowed from the retina. However, the migration of a methylated RNA molecule of size 4S, but unrelated to rRNA, cannot be entirely eliminated.

Effect of diphtheritic demyelination on axonal transport in the sciatic nerve and subsequent muscle changes in the chicken

Chicken sciatic nerves undergo demyelination following intraneural injection of diphtheria toxin and subsequent atrophy of some muscular cells. Paresis occurs after one week and lasts approximately three weeks; at the height of the lesion C14-leucine was injected into the ventral horn cells of the spinal cord. The axonal transport of fast flowing labelled proteins was followed down the sciatic nerve axons and flow rates at two different times were measured. Muscle cells were stained for succinic dehydrogenase and ATPase; fibre diameters, total protein, and total radioactivity associated with the nerves were also measured. The results showed that the fast flowing labelled proteins accumulated at the demyelination site while the muscle cells supplied by these nerves showed reduction of fibre diameter and evidence of degeneration. Further studies are in progress on slow moving proteins and muscle cells.

Neuronal transport in salamander nerves and its blockade by colchicine

Neuronal transport and the effects of colchicine on it has been studied in salamander spinal nerves. Cholinesterase (ChE) accumulation above the cut region of a nerve at 12.5 degrees C was shown to depend upon two processes. One caused a transient increase which declined to zero by 24 h; the other was explained by axoplasmic transport. At 22 degrees C the transient change was not observed, but the rate of accumulation attributable to transport increased. The Q10 for this transport over the range 12.5 degrees C--22 degrees C is approximately three. The ChE accumulation in the sensory component of the mixed nerve was about equal to that in the motor. The rate of fast axoplasmic transport of labeled leucine was 56 mm/day at 22 degrees C; if ChE moves at the same rate, then only 7% of the total enzyme is carried by fast axoplasmic transport. The transport of ChE was reduced by at least 50% when nerves were bathed in a 75 mM solution of colchicine for 30 min; this treatment is known not to cause subsequent degeneration of these nerves. The rate of slow flow of labeled material after bathing the nerve trunk in tritiated colchicine was found to be approximately 0.5 mm/day.

Similar polypeptide composition of fast-transported proteins in rat motor and sensory axons

SDS-polyacrylamide gel electrophoresis was used to characterize labeled proteins transported in rat motor and sensory axons after application of 3H-leucine to the neuron cell bodies. Two types of experiments were performed: first, transported protein accumulating proximal to a ligature placed on the sciatic nerve was analyzed; second, the segment of sciatic nerve nearest to the "wavecrest" of transported protein travelling down the nerve was analyzed. In both cases, no significant differences in peak position or amplitude were found in gels containing labeled proteins from motor or sensory axons. This may mean that the majority of fast-transported protein is involved in an axonal function common to the two types of neuron.

Inhibition of the rapid movement of optically detectable axonal particles colchicine and vinblastine

The rapid saltatory motion of intra-axonal particles detected by dark-field microscopy in myelinated axons isolated from sciatic nerves of adult Xenopus laevis was inhibited by colchicine or vinblastine at a concentration of larger than or equal to 0.1 mM. Both the predominant somatopetal transport and the somatofugal transport of these round particles were inhibited. The reduction in numbers of moving particles was apparent first in the juxtanodal portions of the isolated axons within about 1 h. No particles could be detected moving by 3-5 h after application of the colchicine or vinblastine. During the phase of partial inhibition, those particles that were still progressing along the axon did so at apparently normal velocities while they were in motion, but remained stationary increasingly frequently and for progressively longer periods. Colchicine or vinblastine at a concentration of less than or equal to 10 micronM caused no observable inhibition within 4 h of application. Colchicine at a concentration of larger than or equal to 10 mM caused local accumulation of round particles, and vinblastine at a concentration of larger than or equal to 2.5 mM caused fragmentation of rod-shaped organelles, believed to be mitochondria. Electron microscopy of nerve fibers treated with 5 mM colchicine showed a progressive loss of microtubules from the axoplasm, such that approximately 70% of the microtubules had disappeared after 4h.

Selective uptake and transport of label within three identified neuronal systems after injection of 3H-GABA into the pigeon optic tectum: an autoradiographic and Golgi study

After injection of tritiated gamma-aminobutyric acid (GABA) into the pigeon optic tectum and thalamus it was possible to correlate certain aspects of the autoradiographic labeling pattern with observations made from Golgi material. Three neuronal, GABA specific systems were identified both from the uptake of the amino acid and from the subsequent and bidirectional in tracellular transport of labe. The first system derives from cell bodies within sublayer IIi the axons of which could be selectively labelled throughout their course within layer I and to the areas of termination within the pretectum and ventral thalamus. The radially ascending dendrites and axon collaterals of these neurons arbourised within sublayer IIf, and could be labelled in a retrograde fashion after tectal or thalamic injections. The second system was represented by small perikarya within sublayer IIc with locally and superficially directed dendrites and with a radially and deep directed axon from which an extensive axon collateral system arose. It was found possible to label these perikarya either directly or indirectly after tangential tectal injections which preferentially labelled the axons and terminals of these neurons within the deeper regions of the tectal cortex and resulted in the retrograde axonal movement of label to theoverlying cell bodies. A third system was found within sublayer IId, was horizontally organized and from a correlation with degeneration, other autoradiographic and Golgi preparations thought to be mainly dendritic in nature. The biochemical and anatomical implications of specific GABA uptake and subsequent transport of label are discussed and a model of the tectal cortex, based on the three proposed inhibitory systems and their relation to a number of tectal afferent inputs, considered.

Areal differences in the laminar distribution of thalamic afferents in cortical fields of the insular, parietal and temporal regions of primates

A cytoarchitectonic parcellation has been made of the cortex of the insula and of the adjoining parts of the temporal and parietal lobes in rhesus and squirrel monkeys. In conjunction with this, the intracortical distribution of the thalamo-cortical fibers has been studied by the autoradiographic tracing technique. There is a systematic change in the density, laminar distribution and general character of the intracortical thalamic afferent plexus which seems to follow, in particular, the progressive differentiation of cortical layering that occurs in moving from insular through granular to homotypical cortex. In the dysgranular and granular insular areas in which cortical lamination is indistinct, the thalamic plexus as demonstrated autoradiographically is sparse and extends through much of layers III and IV. In the granular cortex (areas 3b and AI), the thalamic plexus is densest and coarsest; it fills all of layers IV and IIIB and extends into layer IIIA. In the "second" and "third" sensory areas, such as the second somatic sensory and many of the auditory fields, the density of the plexus and its coarseness diminish slightly and the deeper half of layer IV becomes free of terminals. In the homotypical cortex, the plexus becomes sparser, finer and strictly confined to layer IIIB. In many areas there are additional indications of thalamic terminations in deeper layers. Where layers V and VI are not divided into sublaminae (e.g.,in areas 3b and AI) there is labeling of the superficial half of layer VI. Where layers V and VI become subdivided in the homotypical cortex, the auditory and adjacent fields were only observed in cases in which the magnocellular nucleus of the medial geniculate body was involved by the injection of isotope. The boundaries of the cortical projection fields of individual thalamic nuclei, as determined autoradiographically, are remarkably sharp and invariably coincide with a sharp architectonic boundary or with a zone of maximal cytoarchitectonic change. Zones of apparent architectonic transition never showed overlap of thalamic afferents emanating from more than one nucleus. These results raise for discussion the significance of architectonic structure in relation to cortical connectivity and have a bearing upon those studies that have attempted to relate the terminals of thalamic afferents to particular classes of cortical neuron.

Inhibition and stimulation of rapid axonal transport in vitro by sulfhydryl blockers

The effects of sulfhydryl blocking agents have been studied on the rapid axonal transport in vitro of [3H]leucine-labelled proteins in the frog sciatic nerve. The transport was inhibited in the presence of low concentrations of N-ethylmaleimide (NEM) (greater than or equal to 10(-5) M), p-chloromercuribenzene sulfonic acid (PCMBS) (greater than 10(-5) M) or ions of heavy metals, Cd2+ (greater than or equal to 5 X 10(-5) M), Hg2+ (greater than or equal to 5 X 10(-6) M) and Cu2+(greater than or equal to 10(-4) M). Both the amount and the rate of transported radioactivity were reduced. Transport inhibiting concentrations of these agents also inhibited the binding of colchicine in rat brain or frog nerve supernatants. The amount of transported proteins was increased at an unchanged transport rate by a very low concentration of NEM (10(-6) M), PCMBS (10(-6) M) and Cd2+ (10(-6)M), which did not affect the binding of colchicine. The present results suggest that stimulation of axonal transport can be achieved through an interaction with sulfhydryl groups.

Release of acetylcholinesterase into the perfusate from the ox adrenal gland

Increasing the potassium ion concentration of Tyrode’s solution perfusing an isolated ox adrenal gland leads to a release of acetylcholinesterase activity into the perfusate. The amount of enzyme activity released by added potassium is much reduced if calcium ions are omitted from the perfusion fluid. The activity of acetylcholinesterase secreted into the perfusate was confined to a single isoenzyme which is identical with the only soluble isoenzyme present in splanchnic nerve trunks and with one of the five soluble isoenzymes in the adrenal medulla.

Axonal transport of RNA during regeneration of the optic nerves of goldfish

The distribution of radioactive RNA and RNA precursors in the goldfish optic tecta following intraocular injection of 3H-uridine has been studied during various stages of optic nerve regeneration. 3H-uridine was injected into the posterior chamber of the right eye 17, 30, or 60 days after both optic nerves were crushed. Five were sacrificed at time intervals ranging from 0.5 to 21 days after injection. One day prior to sacrificing, 14C-proline was also injected into the right eye as a marked of fast axonal protein transport. Seventeen to 23 days after crushing, the approximate time of nerve reconnection, the amount of radioactive RNA appearing in the left optic tectum was increased by more than ten times control values. Approximately 30 days after crushing the nerve, when the reconnected nerve is maturing, RNA values were still elevated, but significantly decreased from the earlier stage. By 60 days after crushing the optic nerve, the amounts of RNA in the left tectum was close to normal. Evidence suggesting that, at least, some of the radioactive RNA in the tectum originated from RNA transported along optic axons rather than from RNA synthesized locally in the tectum was provided by autoradiographic experiments. Autoradiograms of paraffin sections taken from the goldfish optic tecta after the intraocular injection of 3H-uridine showed a distribution of grains in a linear pattern, suggesting a distribution over the incoming fibers during the reconnection stage of regeneration. Electron microsocpic autoradiography of glutaraldehyde fixed epoxy sections confirmed that a significant number of grains (shown to be 3H-RNA) were, in fact, over regenerating optic axons. Intracranial injection of 3H-uridine, during the same stage of regeneration, on the other hand, resulted in a distribution of grains, specifically over cell perikaprya. These experiments suggest that during the reconnection phase of nerve regeneration, large amounts of RNA may be carried within regenerating optic axons as they enter the optic tectum.