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.     

Incorporation of axonally transported glycoproteins into axolemma during nerve regeneration

The insertion of axonally transported fucosyl glycoproteins into the axolemma of regenerating nerve sprouts was examined in rat sciatic motor axons at intervals after nerve crush. [(3)H]Fucose was injected into the lumbar ventral horns and the nerves were removed at intervals between 1 and 14 d after labeling. To follow the fate of the “pulse- labeled” glycoproteins, we examined the nerves by correlative radiometric and EM radioautographic approaches. The results showed, first, that rapidly transported [(3)H]fucosyl glycoproteins were inserted into the axolemma of regenerating sprouts as well as parent axons. At 1 d after delivery, in addition to the substantial mobile fraction of radioactivity still undergoing bidirectional transport within the axon, a fraction of label was already associated with the axolemma. Insertion of labeled glycoproteins into the sprout axolemma appeared to occur all along the length of the regenerating sprouts, not just in sprout terminals. Once inserted, labeled glycoproteins did not undergo extensive redistribution, nor did they appear in sprout regions that formed (as a result of continued outgrowth) after their insertion. The amount of radioactivity in the regenerating nerves decreased with time, in part as a result of removal of transported label by retrograde transport. By 7-14 d after labeling, radioautography showed that almost all the remaining radioactivity was associated with axolemma. The regenerating sprouts retained increased amounts of labeled glycoproteins; 7 or 14 d after labeling, the regenerating sprouts had over twice as much of radioactivity as comparable lengths of control nerves or parent axons. One role of fast axonal transport in nerve regeneration is the contribution to the regenerating sprout of glycoproteins inserted into the axolemma; these membrane elements are added both during longitudinal outgrowth and during lateral growth and maturation of the sprout.     

SYNTHESIS, MIGRATION AND TURNOVER OF PROTEIN IN RETINAL GANGLION CELLS

Abstract— The synthesis, migration and turnover of proteins in retinal ganglion cells of the adult rabbit was studied after intraocular injections of [³H]leucine. It was shown that the isotope was rapidly incorporated into proteins of the retina and some of the proteins were subsequently transported out into the axons of the retinal ganglion cells down to the terminals. This intra-axonal transport of protein occurred at four different velocities; 150, 40, 6-12 and 2 mm/day respectively. The two most rapidly migrating phases of axonal transport were predominantly associated with light particulate fractions and had a relatively rapid turnover in the nerve terminals in the lateral geniculate body. The third phase of axonal transport which had a rate of 6-12 mm/day was possibly associated with the migration of mitochondria. The most slowly migrating proteins in the axon which moved at an average rate of 2 mm/day carried predominantly soluble proteins down to the nerve terminals. A minor part of this phase was metabolized locally in the axon with a half-life of about 14 days. When this slowly migrating phase had reached the nerve terminals in the lateral geniculate body, it was degraded with a half-life of 9-6 days. The different phases of axonal transport were of different magnitudes. As measured from the maximal amount of radioactivity present in the nerve terminals the relative amounts of radioactivity of the four phases were: 1,1 -8,1 -5 and 8-5.     

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.     

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.     

Fast axonal transport in motor nerve regeneration.

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

Axonal transport of class II and III beta-tubulin: evidence that the slow component wave represents the movement of only a small fraction of the tubulin in mature motor axons.

Pulse-labeling studies demonstrate that tubulin synthesized in the neuron cell body (soma) moves somatofugally within the axon (at a rate of several millimeters per day) as a well-defined wave corresponding to the slow component of axonal transport. A major goal of the present study was to determine what proportion of the tubulin in mature motor axons is transported in this wave. Lumbar motor neurons in 9-wk-old rats were labeled by injecting [35S]methionine into the spinal cord 2 wk after motor axons were injured (axotomized) by crushing the sciatic nerve. Immunoprecipitation with mAbs which recognize either class II or III beta-tubulin were used to analyze the distributions of radioactivity in these isotypes in intact and axotomized motor fibers 5 d after labeling. We found that both isotypes were associated with the slow component wave, and that the leading edge of this wave was enriched in the class III isotype. Axotomy resulted in significant increases in the labeling and transport rates of both isotypes. Immunohistochemical examination of peripheral nerve fibers demonstrated that nearly all of the class II and III beta-tubulin in nerve fibers is located within axons. Although the amounts of radioactivity per millimeter of nerve in class II and III beta-tubulin were significantly greater in axotomized than in control nerves (with increases of +160% and +58%, respectively), immunoassay revealed no differences in the amounts of these isotypes in axotomized and control motor fibers. We consider several explanations for this paradox; these include the possibility that the total tubulin content is relatively insensitive to changes in the amount of tubulin transported in the slow component wave because this wave represents the movement of only a small fraction of the tubulin in these motor fibers.     

Axonal Transport of Polyamines in Intact and Regenerating Axons of the Rat Sciatic Nerve

The axonal transport of putrescine or its polyamine derivatives spermidine or spermine is a subject of some debate. We investigated this question by injecting [3H]putrescine into the lumbar spinal cord of the rat and measuring the accumulation of radioactivity central to ligatures placed on intact and regenerating sciatic nerves. In normal nerves, approximately twice as much radioactivity built up proximal to these ligatures 2 or 3 days after injection than at more distal ligatures used to control for accumulation of radioactivity which might be due to tissue damage alone. In regenerating nerves the amount of radioactivity accumulating at the ligature was approximately five times that at the distal ligature and two to three times greater than in intact nerves. The identity of the radioactivity in regenerating nerves, determined on an amino acid analyzer, was found to be primarily spermidine and an unknown compound that migrated as a frontal elution peak. Autoradiographic analysis showed that the radioactivity was largely confined to axons, but a significant amount of the silver grains was associated with Schwann cells and myelin sheaths surrounding labeled axons in both intact and regenerating nerves. The data indicate that polyamine derivatives of putrescine are transported axonally in rat sciatic nerves, and some of this transported material accumulates in Schwann cells surrounding the labeled axons. These processes are apparently augmented during regeneration of the injured axons.     

TRANSPORT AND TURNOVER OF NEUROHYPOPHYSIAL PROTEINS OF THE RAT

Axonal transport and turnover rate of proteins in the supraoptico-neurohypo-physial tract were studied after injection of ³⁵S cysteine into the region of the supraoptic nucleus. The proximo-distal migration of labelled proteins from the nerve cell bodies to the axon terminals in the neurohypophysis was followed by measuring the radioactivity of neurohypophysial proteins at various time intervals (4 h to 30 days) after isotope injection. A rapidly transported phase of proteins with a minimal transport rate of approximately 60 mm/day was demonstrated. An accumulation of protein-bound radioactivity was also observed in the neural lobe at 9 days after isotope injection, representing slowly transported proteins (0-5 mm/day). In addition, an intermediate phase of axonal transport (1-5 mm/day) was found. Fractionation of neurohypophysial proteins by polyacrylamide gel disc electrophoresis revealed that a predominating portion of the radioactivity was recovered in a single protein component (fraction A) at 4 h as well as at 30 days after isotope injection. This protein component was shown to be a constituent both of the rapid and the slow phase of axonal transport. With time an increasing amount of radioactivity was found in another protein component (fraction B), which reached a maximum at 14 days after injection and then remained fairly constant up to 30 days. When the turnover rates of neurohypophysial proteins were estimated, a half-life of 1-2 days and 8 days was calculated for the rapidly and slowly transported proteins, respectively.     

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.     

Axonal Transport of Choline Lipids in Normal and Regenerating Rat Sciatic Nerve

Abstract: Biochemical methods were used to study the time course of transport of choline phospholipids (labeled by the injection of [³H]choline into the ventral horn of the lumbar spinal cord) in rat sciatic nerve. Autoradiographic methods were used to localize the transported lipid within motor axons. Transported phospholipid, primarily phosphatidylcholine, present in the nerve at 6 h, continued to accumulate over the following 12 days. No discrete waves of transported lipid were observed (a small wave of radioactive phospholipid moving at the high rate would have been missed); the amounts of radioactive lipid increased uniformly along the entire sciatic nerve. In light-microscope autoradiographs, a class of large-caliber axons, presumably motor axons, retained the labeled lipid. Some lipid, even at 6 h, was seen within the myelin sheaths. Later, the labeling of the myelin relative to axon increased. The continued accumulation of choline phospholipids in the axons probably signifies their prolonged release from cell bodies and their retention in various axonal membranes, including the axolemma. The build-up of these phospholipids in myelin probably represents their transfer from the axons to the myelin sheaths surrounding them. When nerves are crushed and allowed to regenerate for 6 or 12 days, choline phospholipids transported during these times enter the regenerating nerve. In light and electron microscope autoradiographs, transported lipid was seen to be localized primarily in the regenerating axons. However, grains overlay the adjacent Schwann cell cytoplasm, indicating transported lipids were transferred from the regenerating axons to the associated Schwann cells. In addition, some cells not associated with growing axons were labeled, suggesting that phosphatidylcholine and possibly acetylcholine, carried to the regenerating axons by axonal transport, were actively metabolized in the terminal, with released choline label being used by other cells. These results demonstrate that axonal transport supplies mature and growing axons and their glial cells with choline phospholipids.     

Axonal growth during regeneration: a quantitative autoradiographic study

The intraaxonal distribution of labeled glycoproteins in the regenerating hypoglossal nerve of the rabbit was studied by use of quantitative electron microscope autoradiography. 9 d after nerve crush, glycoproteins were labeled by the administration of [3H]fucose to the medulla. The distribution of transported 3H-labeled glycoproteins was determined 18 h later in segments of the regenerating nerve and in the contralateral, intact nerve. At the regenerating tip, the distribution was determined both in growth cones and in non-growth cone axons, 6 and 18 h after labeling. The distribution within the non-growth cone axons of the tips was quite different at 6 and 18 h. At 6 h, the axolemma region contained < 10% of the radioactivity; at 18 h, it contained virtually all the radioactivity. In contrast, the distribution within the growth cones was similar at both time intervals, with 30% of the radioactivity over the axolemmal region. Additional segments of the regenerating nerve also showed a preferential labeling of the axolemmal region. In the intact nerve, 3H-labeled glycoproteins were uniformly distributed. These results suggest that: (a) in this system the labeled glycoproteins reaching the tip of the regenerating axons are inserted into the axolemma between 6 and 18 h after leaving the neuronal perikaryon; (b) at the times studied, there is a fairly constant ratio between glycoproteins reaching the growth cone through axoplasmic transport and glycoproteins inserted into the growth cone axolemma; (c) the axolemma elongates by continuous insertion of membrane precursors at the growth cone; the growth cone then advances, leaving behind an immature axon with a newly formed axolemma; and (d) glycoproteins are preferentially inserted into the axolemma along the entire regenerating axon.     

Organization and slow axonal transport of cytoskeletal proteins under normal and regenerating conditions

The organization of the axonal cytoskeleton was investigated by analyzing the solubility and transport profile of the major cytoskeletal proteins in motor axons of the rat sciatic nerve under normal and regenerating conditions. When extracted with the Triton-containing buffer at low temperature, 50% of tubulin and 30% of actin were recovered in the insoluble form resistant to further depolymerizing treatments. Most of this cold-insoluble form was transported in slow component a (SCa), the slower of the two subcomponents of slow axonal transport, whereas the cold-soluble form showed a biphasic distribution between SCa and SCb (slow component b). Changes in slow transport during regeneration were studied by injuring the nerve either prior to (experiment I) or after (experiment II) radioactive labeling. In experiment I where the transport of proteins synthesized in response to injury was examined, selective acceleration of SCb was detected together with an increase in the relative proportion of this component. In experiment II where the response of the preexisting cytoskeleton was examined, a shift from SCa to SCb of the cold-soluble form was observed. The differential distribution and response of the two forms of tubulin and actin suggest that the cold-soluble form may be more directly involved in axonal transport.     

Melanocortins and fast axonal transport in intact and regenerating sciatic nerve

The effect of ACTH/MSH peptides on fast axonal transport along intact or regenerating sciatic nerve was examined following injection of tritiated leucine into the rat lumbar spinal cord. The rate of fast axonal transport was not significantly changed by treatment with ACTH/MSH(4-10), the ACTH(4-9) analog ORG 2766, hypophysectomy, or adrenalectomy. Fast axonal transport was unchanged in regenerating nerves and in regenerating, ACTH(4-10)-treated nerves. However, treatment with ORG 2766 in dosages of either 1 or 10 micrograms/kg/day IP for seven days significantly reduced (62% and 64%, respectively) the crest height of the fast axonal transport curve of intact sciatic nerve. The results suggest that the reported peptide-induced enhancement of nerve regeneration is not due to changes in the rate of fast axonal transport.     

Proteins transported in slow components a and b of axonal transport are distributed differently in the transverse plane of the axon

The distribution of the proteins migrating with the slow components a (SCa) and b (SCb) of axonal transport were studied in cross-sections of axons with electron microscope autoradiography. Radiolabeled amino acids were injected into the hypoglossal nucleus of rabbits and after 15 d, the animals were killed. Hypoglossal nerves were processed either for SDS-polyacrylamide gel electrophoresis fluorography to identify and locate the two components of slow transport, or for quantitative electron microscope autoradiography. Proteins transported in SCa were found to be uniformly distributed within the cross-section of the axon. Labeled SCb proteins were also found throughout the axonal cross-section, but the subaxolemmal region of the axon contained 2.5 times more SCb radioactivity than any comparable area in the remainder of the axon.     

Calpain-mediated degradation of rapidly and slowly axonally transported proteins in retinal ganglion cells

Labelled axonally transported proteins belonging to four different phases of transport in the retinal ganglion cells of the rabbit were used as substrates in order to study proteolytic degradation in axons and nerve terminals.Proteins of both rapidly and slowly transported phases of axonal transport were easily degraded in small intact pieces of the superior colliculus.Addition of the Ca-dependent neutral protease, calpain, to isolated soluble and membrane fractions from the superior colliculus resulted in an increased rate of degradation of axonally transported components. The effects of calpain was most marked toward components in phases II and V of axonal transport in this system (Karlsson and Sjöstrand, 1971; Willard and Hulebak, 1977). The latter phase contains slowly transported neurofilament and microtubular protein while the former one contains rapidly transported membrane proteins.     

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.     

Quantitative analysis of microtubule transport in growing nerve processes

In neurons, tubulin is synthesized primarily in the cell body, whereas the molecular machinery for neurite extension and elaboration of microtubule (MT) array is localized to the growth cone region. This unique functional and biochemical compartmentalization of neuronal cells requires transport mechanisms for the delivery of newly synthesized tubulin and other cytoplasmic components from the cell body to the growing axon. According to the polymer transport model, tubulin is transported along the axon as a polymer. Because the majority of axonal MTs are stationary at any given moment, it has been assumed that only a small fraction of MTs translocates along the axon by saltatory movement reminiscent of the fast axonal transport. Such intermittent "stop and go" MT transport has been difficult to detect or to exclude by using direct video microscopy methods. In this study, we measured the translocation of MT plus ends in the axonal shaft by expressing GFP-EB1 in Xenopus embryo neurons in culture. Formal quantitative analysis of MT assembly/disassembly indicated that none of the MTs in the axonal shaft were rapidly transported. Our results suggest that transport of axonal MTs is not required for delivery of newly synthesized tubulin to the growing nerve processes.     

Posttranslational Protein Modification by Polyamines in Intact and Regenerating Nerves

A 150,000-g supernatant from axoplasm of the giant axon of the stellate nerve of the squid and from rat sciatic and goldfish optic nerves was found to be able to incorporate covalently [3H]putrescine and [3H]spermidine into an exogenous protein (N,N'-dimethylcasein). Incorporation of radioactivity was inhibited by CuSO4, a specific inhibitor of transglutaminases, the enzymes mediating these reactions in other tissues. Analysis of pH and temperature range and enzyme kinetics displayed characteristics predicted for transglutaminase-mediated reactions. Transglutaminase activity increased during regeneration of both vertebrate nerves, but greater activity was found in segments of nerve containing no intact axons than in either intact segments or in segments containing regenerating axons. Polyacrylamide gel electrophoresis of endogenous modified proteins (in the absence of N,N'-dimethylcasein) showed labeling of 18-, 46- and 200-kilodalton proteins by both [3H]putrescine and [3H]spermidine. Analysis of the protein-bound radioactivity from intact and regenerating rat sciatic nerves demonstrated it to be predominantly in the form of the parent radioactive polyamine. These experiments demonstrate the covalent modification of proteins by polyamines at low levels in squid axoplasm and at relatively higher levels in rat sciatic and goldfish optic nerves. In the latter two cases, the activity of these modification reactions may be due in part to the modification of axonal proteins, but the majority of the activity occurs in nonneuronal cells of the nerve.     

Phosphorylation of Proteins in Normal and Regenerating Goldfish Optic Nerve

Within 6 h after radiolabeled phosphate was injected into the eye of goldfish, labeled acid-soluble and acid-precipitable material began to appear in the optic nerve and subsequently also in the lobe of the optic tectum, to which the optic axons project. From the rate of appearance of the acid-precipitable material, a maximal velocity of axonal transport of 13-21 mm/day could be calculated, consistent with fast axonal transport group II. Examination of individual proteins by two-dimensional gel electrophoresis revealed that approximately 20 proteins were phosphorylated in normal and regenerating nerves. These ranged in molecular weight from approximately 18,000 to 180,000 and in pI from 4.4 to 6.9. Among them were several fast transported proteins, including protein 4, which is the equivalent of the growth-associated protein GAP-43. In addition, there was phosphorylation of some recognizable constituents of slow axonal transport, including alpha-tubulin, a neurofilament constituent (NF), and another intermediate filament protein characteristic of goldfish optic axons (ON2). At least some axonal proteins, therefore, may become phosphorylated as a result of the axonal transport of a phosphate carrier. Some of the proteins labeled by intraocular injection of 32P showed changes in phosphorylation during regeneration of the optic axons. By 3-4 weeks after an optic tract lesion, five proteins, including protein 4, showed a significant increase in labeling in the intact segment of nerve between the eye and the lesion, whereas at least four others (including ON2) showed a significant decrease. When local incorporation of radiolabeled phosphate into the nerve was examined by incubating nerve segments in 32P-containing medium, there was little or no labeling of the proteins that showed changes in phosphorylation during regeneration. Segments of either normal or regenerating nerves showed strong labeling of several other proteins, particularly a group ranging in molecular weight from 46,000 to 58,000 and in pI from 4.9 to 6.4. These proteins were presumably primarily of nonneuronal origin. Nevertheless, if degeneration of the axons had been caused by removal of the eye 1 week earlier, most of the labeling of these proteins was abolished. This suggests that phosphorylation of these proteins depends on the integrity of the optic axons.