Altered spectrum of retrogradely transported axonal proteins in p-bromophenylacetylurea neuropathy

The composition of retrogradely transported axonal proteins was examined by acrylamide gel electrophoresis and gel autoradiography in the experimental neuropathy induced in rats by p-bromophenylacetylurea (BPAU). Protein composition was normal during the early phase of retrograde transport but showed significant abnormalities during a later phase. The early phase consisted of proteins collected distal to a mid-thigh ligature of sciatic nerve between 15 and 24 hours after injection of [³⁵S] methionine into lumbar ventral horn of the spinal cord. In terms of their relative labeling and electrophoretic mobility, these proteins were almost identical in experimental and control rats. Most of the labeled protein bands were also identical in the later phase, collected between 24 and 48 hours, but there were some consistent omissions and additions. Present in controls but missing in BPAU treated rats were three bands at 42, 41, and 25 KDa. In contrast, 4 bands (63, 56, 50, 26 KDa) were more prominent in the experimental rats than in controls. We suspect abnormal post-translational modification or proteolysis of rapidly transported proteins in the terminal or preterminal portion of the neurons exposed to BPAU. This abnormality, in addition to a previously reported premature processing of transported organelles, may underlie the development of peripheral neuropathy.     

Qualitative analysis of proteins rapidly transported in ventral horn motoneurons and bidirectionally from dorsal root ganglia

Two-dimensional electrophoresis has allowed a higher-resolution comparison of rapid transport in ventral horn motoneurons and bidirectionally in dorsal root sensory neurons. Dorsal root ganglia 8 and 9, or hemisected spinal cords, from frog were selectively exposed in vitro to 35S-methionine. Transported, labelled proteins that accumulated in 3 mm segments proximal to ligatures on dorsal roots and spinal nerves or sciatic nerves were subjected to two-dimensional gel electrophoresis. Comparisons were made of fluorographic patterns from dried gels. Sixty-five species of proteins were found to be rapidly transported in both bifurcations of dorsal root sensory neurons. No abundant species of protein was rapidly transported in dorsal roots that was not also found in spinal nerves. A comparison of proteins rapidly transported in the sciatic nerve from ventral horn motoneurons with those from dorsal root sensory neurons yielded 50 common species of polypeptides. At most four minor species were possibly transported only in ventral horn motoneurons. An overall comparison indicates that at least 45 species of proteins, including all of the more abundantly transported ones, were consistently common to both dorsal root bifuractions and to ventral horn motoneurons. This appears to be the case despite the very different functions carried out by motoneurons and sensory neurons.     

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.     

Characterization of proteins transported at different rates by axoplasmic flow in the dorsal root afferents of rats

Proteins synthesized by soma located in L₄ dorsal root ganglia and supplied to the axonal branches extending centrally in the dorsal root and peripherally towards the sciatic nerve were analyzed for radioactivity following injections of [³H] leucine into the L₄ dorsal root ganglia. All proteins located in the dorsal root and sciatic nerve were analyzed by SDS acrylamide gel electrophoresis at various times post injection. The differences in radioactivity between the dorsal root and sciatic nerve proteins were mainly quantitative and not qualitative, with many proteins of various molecular weight ranges being transported into both segments. Generally, it appears that in both axonal branches the high molecular weight proteins are transported at the highest rate, medium weights slower and low molecular weight proteins slowest. More proteins of high and low molecular weights are transported into the dorsal root whereas more of those of medium molecular weight are transported towards the sciatic nerve.     

Impaired axonal regeneration in acrylamide intoxication

Acrylamide is a neurotoxin known to impair regeneration of axons following nerve crush and to produce structurally abnormal regenerating sprouts. To investigate the mechanism of these abnormalities, protein synthesis and fast axonal transport were studied in acrylamide-intoxicated and control rats 2 weeks after sciatic nerve crush. Using an in vitro preparation of sciatic nerve-dorsal root ganglion, there was no difference in ganglion ³H-leucine incorporation between the two groups. In these preparations of sensory axons, as well as in motor axons studied in vivo, a smaller proportion of rapidly transported radioactivity was carried beyond the crush in the acrylamide-regenerating nerves compared to the control-regenerating nerves. Correlative ultrastructural studies demonstrated that this difference reflected the impaired outgrowth of the acrylamide-regenerating nerves, rather than an abnormality in fast transport. The acrylamide-treated sprouts often developed swellings filled with whorls of neurofilaments; in addition, many sprouts ended in massively enlarged growth cones containing membranous organelles. EM autoradiography showed labeled, rapidly transported organelles accumulated in the neurofilamentous whorls, and therefore suggested that these organelles might be “trapped” or impeded in passage through these regions. However, there was no evidence that the growth cones received insufficient amounts of transported protein; in fact, the distended endings were densely labeled and apparently “ballooned” by transported organelles. These results suggest that acrylamide intoxication does not impair regeneration by diminishing the delivery of rapidly transported materials to the growing tip. Rather, the marked distention of the growth cones is interpreted as the morphological consequence of continued delivery of rapidly transported organelles into sprouts unable to utilize them in outgrowth.     

A COMPARISON OF AXONALLY TRANSPORTED PROTEINS IN THE RAT SCIATIC NERVE BY IN VITRO AND IN VIVO TECHNIQUES

An in vitro system for studying fast axonal transport in mammalian nerves has been developed. The viability of in vitro nerve preparations was established on the basis of three criteria: electron microscopy, electrical properties, and the activities of two marker enzymes, 5'-nucleotidase and total ATPase. The specific activity of transported proteins was greater using the in vitro procedure, and the level of locally incorporated radioactivity lower, when compared to in vivo transport experiments. Separation of solubilized transported proteins on polyacrylamide gels in the presence of sodium dodecyl sulfate showed that a large number of polypeptides are transported. Using a double label procedure which employed L-[³H]methionine and L-[³⁵S]methionine, proteins transported in vitro and in vivo were compared. No differences in the electrophoretic distribution of transported proteins from the two systems was seen. The major component of transported proteins electrophoresed with an apparent molecular weight of 105,000 ± 24,000. Using the in vitro system, transported proteins were compared to those labelled locally in either Schwann cells or cells of the dorsal root ganglion. Large differences in the labelling patterns were observed in both comparisons. We conclude that in vitro procedures provide a valid means of studying rapid axoplasmic transport. The proteins carried by rapid axoplasmic transport differ from those synthesized in either the Schwann cells of the sciatic nerve or the cells of the dorsal root ganglion.     

RAPID AXONAL TRANSPORT IN VITRO IN THE SCIATIC SYSTEM OF THE FROG OF FUCOSE-, GLUCOSAMINE- AND SULPHATE-CONTAINING MATERIAL

—An in vitro system from the frog has been used to study fast axonal transport of glycoproteins. The migration of [³H]fucose-, [³H]glucosamine- and [³⁵S]sulphate-labelled material was followed from the dorsal ganglia, along the sciatic nerve towards the gastrocnemius muscle. The distribution in different subcellular fractions, effect of cycloheximide and transport kinetics did not differ very much between fucose- and glucosamine-incorporation into the nerve. Cycloheximide blocked the synthesis of TCA-insoluble radioactivity, which was transported at a rate of 60–90 mm per day at 18°C, more effectively than the synthesis of stationary proteins in the ganglia. About 10 per cent of the TCA-insoluble and transported radioactivity was extracted by chloroform-methanol (2:1, v/v) and might be glycolipids and the rest glycoproteins. Results suggest that TCA-soluble activity, which was recovered in the nerve, originated in part from labelled macromolecules consumed along the axons. The rapidly transported TCA-insoluble radioactivity was 85 per cent particulate and mainly associated with structures sedimenting in the microsomal fraction. [³⁵S]Sulphate-labelled TCA-insoluble material was resistant towards chloroform-methanol (2:1, v/v) extraction and rapidly transported from the ganglia into the nerve. The synthesis was inhibited by cycloheximide. The material, probably proteoglycans, represented a quantitatively minor part of transported glycoproteins.     

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.     

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.     

Rate of Movement and Composition of Rapidly Transported Proteins in Regenerating Olfactory Nerve

In a previous study, three successive groups of regenerative fibers, growing initially at 5.8, 2.1, and 0.8 mm/day, were observed in the regenerating garfish olfactory nerve. In the present study, fast axonal transport in the most rapidly regenerating axons (phase I and II) has been examined. Rapid transport in phase I fibers occurs at a velocity of 208 +/- 9 mm/day at 23 degrees, a rate identical to that measured in intact nerves. This first phase of regenerating fibers represents only 3 to 5% of the original axonal population, but each fiber appears to contain 6 to 16 times more transported radioactivity than an axon in an intact nerve. Subcellular distribution of rapidly moving material in phase I and II fibers was closely related to the distribution obtained in intact nerves. Small but significant differences indicate a shift of the transported radioactivity from a heavier to a light axonal membranous fraction. This shift might be characteristic of the immature membrane of a growing axon. The polypeptide distribution of transported radioactivity was also very similar to that of a normal nerve, with most of the radioactivity associated with high-molecular-weight polypeptides.     

Polypeptides in Frog and Rat: Evolutionary Changes in Rapidly Transported and Abundant Nerve Proteins

Abstract: Dorsal root ganglion (DRG) neurons from rat and frog were labeled in vitro with [³⁵S]methionine, and the newly synthesized, rapidly transported proteins were collected at ligatures on the sciatic nerves. The proteins were extracted and separated by two-dimensional polyacrylamide gel electrophoresis. Exposure of x-ray film to dried gels allowed comparison of the labeled, rapidly transported proteins from frog and rat. The gel staining patterns of abundant proteins in the sciatic nerves were also compared. Triolets of gels were examined: one gel from frog, one from rat, and one from frog plus rat combined. Among the transported proteins, some (including A2, A17 and/or A18, B6, B14_a-i, C1, C22, and some members of Al_a-i and B3_a-g) co-migrated on the gels, suggesting that these proteins have been well conserved during evolution. The gel staining patterns of abundant proteins in the sciatic nerves also show some similarities: two forms of actin, serum albumin, and α- and β-tubulin are each in identical positions on the frog and rat gels. Other sciatic nerve and rapidly transported proteins had similar, but not identical, positions on the gels. A number of the rat and frog proteins had no obvious counterpart. We have calculated the magnitude of expected changes in charge and molecular weight of proteins due to accumulation of point mutations during evolution. We conclude that many of the differences between rat and frog protein patterns on the two-dimensional gels could be the result of such point mutations, but we cannot rule out radical changes in polypeptide sequence or abundance between frog and rat for some of these proteins.     

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.     

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 “lwavecrest” 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.     

Protein Synthesis and Axonal Transport During Nerve Regeneration

Abstract— Protein synthesis and axonal transport have been studied in regenerating peripheral nerves. Sciatic nerves of bullfrogs were unilaterally crushed or cut. The animals were killed 1, 2, or 4 weeks later, and 8th and 9th dorsal root ganglia removed together with sciatic nerves and dorsal roots. The ganglia were selectively labeled in vitro with [³⁵S]-methionine. Labeled proteins, in dorsal root ganglia and rapidly transported to ligatures placed on the sciatic nerves and dorsal roots, were analyzed by two-dimensional polyacryl-amide gel electrophoresis. Qualitative analysis of protein patterns revealed no totally new proteins synthesized or rapidly transported in regenerating nerves. However, quantitative comparison of regenerating and contralateral control nerves revealed significant differences in abundance for some of the proteins synthesized in dorsal root ganglia, and for a few of the rapidly transported proteins. Quantitative analysis of rapidly transported proteins in both the peripheral processes (spinal nerves) and central processes (dorsal roots) revealed similar changes despite the fact that the roots were undamaged. The overall lack of drastic changes seen in protein synthesis and transport suggests that the neuron in its program of normal maintenance synthesizes and supplies most of the materials required for axon regrowth.     

Quantitative evaluation of the mode of microtubule transport in Xenopus neurons

Tubulin is synthesized in the cell body and must be delivered to the axon to support axonal growth. However, the exact form in which these proteins, in particular tubulin, move within the axon remains contentious. According to the "polymer transport model", tubulin is transported in the form of microtubules. In an alternative hypothesis, the "short oligomer transport model", tubulin is added to existing, stationary microtubules along the axon. In this study, we measured the translocation of microtubule plus ends in soma segments, the middle of axonal shafts and the growth cone areas, by expressing GFP-EB3 in cultured Xenopus embryonic spinal neurons. We found that none of the microtubules in the three compartments were transported rapidly as would be expected from the polymer transport model. These results suggest that microtubules are stationary in most segments of the axon, thus supporting the model according to which tubulin is transported in non-polymeric form in rapidly growing Xenopus neurons.     

Differential effects of cobalt on the initiation of fast axonal transport

Effects of Co²⁺ on the fast axonal transport of individual proteins were examined in vitro in bullfrog spinal/sciatic nerves.³⁵S-methionine-labeled proteins, fast-transported in control and Co²⁺-treated preparations were separated via two-dimensional gel electrophoresis. While the overall amount of protein transported was reduced, no qualitative differences could be seen when gel fluorographic patterns were compared. Quantitative analyses of the 48 most abundantly transported species revealed two significantly different populations (p < 0.01) differentially sensitive to Co²⁺ and distinguishable to a large extent by molecular weight. Those proteins less sensitive to Co²⁺ ranged from ~20,000 to 35,000 daltons while those more sensitive to Co²⁺ were >~35,000 daltons. The finding that all proteins are affected by Co²⁺ supports the proposal that fast-transported proteins are subject to a common Co²⁺-sensitive, Ca²⁺-requiring step. The observed differential effects are consistent with more than one Ca²⁺-dependent step occurring during the initiation phase of fast transport.This research was supported by a Muscular Dystrophy Association postdoctoral fellowship to G.C.S., and by research grants from NSF (BNS 79-24125) and the National Multiple Sclerosis Society (RG 1296-A-1) to R.H.     

ELECTROPHORETIC CHARACTERIZATION OF LEUCINE-, GLUCOSAMINE- AND FUCOSE-LABELLED PROTEINS RAPIDLY TRANSPORTED IN FROG SCIATIC NERVE

—[³H]Leucine, [³H]glucosamine and [³H]fucose were incorporated in vitro into proteins in frog sciatic ganglia and subsequently transported at a rapid rate along the sciatic nerve towards a ligature, in front of which they accumulated. The synthesis of transported fucose-labelled proteins is closely linked to protein synthesis but is not dependent on RNA synthesis, as judged by effects after incubation for 17 h in the presence of cycloheximide and actinomycin D. Labelled ganglionic as well as transported material were solubilized in sodium dodecyl sulphate and characterized by polyacrylamide gel electrophoresis. The bulk of ganglionic proteins, labelled with any of the precursors used, had molecular weights exceeding 40,000. The radioactivity patterns of leucine- and glucosamine-labelled ganglionic proteins showed similarities with dominant peaks corresponding to molecular weights of about 75,000 and 50,000. The last peak was almost lacking in fucose-labelled ganglionic components. Leucine- and glucosamine labelled-transported proteins exhibited characteristic and similar electrophoretic distributions in contrast to the pattern of fucose-labelled nerve proteins, which was more polydisperse. The most conspicious nerve proteins corresponded to molecular weights of about 75,000 and 18,000. There was a remarkable agreement in the profile of leucine-labelled transported nerve proteins and fucose-labelled ganglionic proteins. In the light of these observations the possibility that glycoproteins constitute a large part of rapidly transported proteins will be discussed.     

Subcellular distribution of axonally transported adenylate cyclase: effect of nerve constriction and comparison with acetylcholinesterase

Abstract: Despite several studies indicating that cyclic nucleotides and their associated enzymes are present in peripheral nerves, their role in neuronal function remains unknown. One possible role is that of a modulating influence in the processes associated with axonal growth and maintenance, and in axonal regeneration. This study has used the frog sciatic nerve as a preparation for investigating the subcellular distribution of neuronai adenylate cyclase activity in normal and crush-injured nerves. The experiments have focused primarily on the axonal transport of adenylate cyclase activity and its subcellular redistribution at the site of constriction. The adenylate cyclase activity measurements were also compared with similar measurements of acetylcholinesterase distribution. Adenylate cyclase activity in normal sciatic nerves increased in the segment proximal to a nerve constriction over time, but did not increase distal to the constriction. Subcellular fractionation of the accumulating activity indicated that the majority of axonally transported enzyme was associated with microsomal organelles; however, an additional transported component was found in the nuclear/mitochondrial fraction. The transport velocities of these two components were different. The microsomal activity appeared to be transported with Group I proteins, while the nuclear/mitochondrial activity was transported with Group II. Rapidly transported Group I proteins have been suggested to be destined principally for the axolemma or the agranular reticu-lum, and the more slowly transported Group II proteins to be associated with intracellular organelles, including synaptic structures. Thus, axonally transported adenylate cyclase activity may have more than one functional role in peripheral nerve. The association of both adenylate cyclase and Protein I, an endogenous substrate for cyclic AMP, with Group II transport offers the intriguing possibility of a structural correspondence. Adenylate cyclase activity in Group I, however, did not appear to be transported with organelles which also contained acetylcholinesterase. The two enzymes, in terms of both velocity of transport and susceptibility to retrograde transport, were handled differently by the neuron. The subcellular distribution of adenylate cyclase activity in an isolated nerve segment was also found to change over time. Microsomal activity decreased, while nuclear/mitochondrial activity transiently increased and then also decreased. This may offer some indication of the morphological location of adenylate cyclase and its potential involvement in Wallerian degeneration and nerve regeneration, particularly in view of recent reports concerning the importance of local injury-induced changes to the initiation of nerve regeneration. We have proposed a dynamic association between axonal calcium and cyclic AMP concentration, which provides a method for membrane renewal or degradation in the intact axon and may offer a molecular basis for the structural reorganization occurring in the proximal segment of an injured nerve.     

Characterization of proteins transported at different rates by axoplasmic flow in the dorsal root afferents of rats.

Proteins synthesized by soma located in L4 dorsal root ganglia and supplied to the axonal branches extending centrally in the dorsal root and peripherally towards the sciatic nerve were analyzed for radioactivity following injections of [3H] leucine into the L4 dorsal root ganglia. All proteins located in the dorsal root and sciatic nerve were analyzed by SDS acrylamide gel electrophoresis at various times post injection. The differences in radioactivity between the dorsal root and sciatic nerve proteins were mainly quantitative and not qualitative, with many proteins of various molecular weight ranges being transported into both segments. Generally, it appears that in both axonal branches the high molecular weight proteins are transported at the highest rate, medium weights slower and low molecular weight proteins slowest. More proteins of high and low molecular weights are transported into the dorsal root whereas more of those of medium molecular weight are transported towards the sciatic nerve.     

Proteins of axonal transport: investigation of solubility characteristics and behaviour in gel filtration

Rapid axonal transport of proteins in retinal ganglion cells of the rabbit was studied following intraocular injections of labelled amino acids. Approximately 10% of the transported radioactivity was found in the supernatant following homogenization and high-speed centrifugation of the nerve terminal region. Relatively simple manipulations with ionic strength, pH and the presence of a chelating agent could solubilize an equivalent amount of radioactivity from the pellet. Lithium diiodosalicylate solubilized most rapidly transported membrane proteins. Gel filtration of readily soluble rapidly transported radioactivity gave a main macromolecular radioactive peak with an approximate mol. wt. of 500,000 dalton as determined on Sephadex G-200. However, gel filtration on Sepharose CL-6B gave a mol. wt. of about 160,000 for the same radioactive peak. SDS polyacrylamide gel electrophoresis of rapidly transported soluble proteins and fractions derived from these proteins via gel filtration and ion exchange chromatography revealed in all cases a very complex picture of labelled polypeptides. Thus rapid axonal transport of soluble proteins in this system seems to involve many different macromolecules.