A conditioning lesion of the peripheral axons of dorsal root ganglion cells accelerates regeneration of only their peripheral axons

Axotomy of the peripheral axon of dorsal root ganglion (DRG) cells is known to result in chromatolysis and changes in protein synthesis in DRG cells. We investigated whether a stimulus produced by peripheral branch axotomy would affect the regenerative properties of both the central and peripheral axon of the DRG cell equally. To examine this question, a conditioning crush lesion was made distally on the sciatic nerve 2 weeks prior to a testing lesion of either the dorsal root or peripheral branch axon near the DRG. Fast axonal transport of radioactive proteins was used to assess regeneration of DRG axons. In the adult rat, leading peripheral branch axons normally regenerate at a rate of 4.4 mm/day. If a conditioning lesion of the sciatic nerve is made 2 weeks before the test lesion, the rate of peripheral branch axonal regeneration increases by 25% to 5.5 mm/day. This effect is not limited to the fastest growing axons in the nerve since a population of more slowly growing axons also exhibits accelerated outgrowth in response to a prior peripheral axotomy. In contrast to this, the fastest growing central branch axons of DRG cells, which normally regenerate at a rate of 2.5 mm/day, are not significantly affected by a prior peripheral axotomy. A population of more slowly growing axons in the dorsal root also does not exhibit accelerated outgrowth in response to a peripheral conditioning lesion. The results of these experiments indicate that changes in the DRG neuron's metabolism induced by prior axotomy of its peripheral axon do not affect the regenerative properties of both axons equally. This raises the possibility that accelerated axonal outgrowth in only one axonal branch results from a differentially regulated supply of proteins to the two axons by the DRG cell body.     

Cytotypic differences in the protein composition of the axonally transported cytoskeleton in mammalian neurons

Many of the structural and functional differences between axons are thought to reflect underlying differences in the biochemical composition and dynamic aspects of the axonal cytoskeleton and cytomatrix. In this study we investigated how the composition of the 2 slow components of axonal transport, SCa and SCb, which convey the cytoskeleton and cytomatrix, differs in axons that are structurally and functionally distinct. For this comparison we analyzed axons of retinal ganglion cells in the optic nerve (ON), axons of dorsal root ganglion (DRG) cells, and axons of ventral motor neurons (VMN) in adult rats. 35S-Methionine-labeled proteins transported with the peak of SCa and SCb were analyzed using high-resolution 2-dimensional polyacrylamide gels (2D-PAGE) and fluorography, and the amounts of major SCa and SCb proteins were quantified. The polypeptide composition of both SCa and SCb was found to be largely similar in DRG and VMN axons, but major qualitative as well as quantitative differences between these axons and ON axons were found. Notable among these were higher ratios of neurofilament protein to tubulin in SCa in DRG and VMN axons compared to ON axons, and significantly larger amounts of 2 microtubule-associated proteins relative to tubulin in SCa of ON axons than in both VMN and DRG axons. Tubulin was the major SCb protein in VMN and DRG axons, but it was not present in SCb in ON axons. Additionally, relatively larger amounts of 2 metabolic enzymes, creatine phosphokinase and nerve-specific enolase, were present in SCb in ON axons than in DRG or VMN axons. The results indicate that significant biochemical heterogeneity among different types of axons can be identified by examining the slow components of axonal transport.     

Altered slow axonal transport and regeneration in a myelin-deficient mutant mouse: the trembler as an in vivo model for Schwann cell-axon interactions

The thickness of the myelin sheath in normal myelinated nerve is proportional to the diameter of the axon. In the demyelinating mutant mouse, Trembler, not only is the thickness of the myelin sheath reduced, but the caliber of associated axons is smaller. This correlation suggests that the interaction between axons and Schwann cells may affect the shape and function of axons as well as properties of myelin. Since axonal diameter depends in part on the cytoskeleton and its movement with slow axonal transport, we have compared the properties of slow transport in the sciatic nerve of control and Trembler mice. Studies of the sciatic nerve of normal mice showed that the rates for proteins moving in slow component a (SCa) and slow component b (SCb) are similar to those previously measured in rat. In Trembler mice, tubulin was transported significantly faster than in control mice, with a rate of 1.73 mm/d for Trembler compared to 1.56 mm/d in the control. In contrast, the rate for neurofilament proteins was significantly slower in the Trembler (1.15 mm/d compared to 1.38 mm/d in the control). The majority of proteins in SCb were also transported slower in Trembler than control: actin and calmodulin were transported at 2.29 mm/d as compared to 2.73 mm/d in control, while spectrin and clathrin were transported at 2.01 and 2.43 mm/d, respectively, as compared to 2.54 mm/d in control. The importance of slow axonal transport in regeneration has been suggested by the clear correlation between the rates of regeneration and the rates of SCb. Therefore, we evaluated regeneration of motor axons in Trembler mice to determine whether the regenerative response was affected by deficient Schwann cells. A slower regeneration rate was found in the Trembler (1.7 mm/d) motor axon when compared to the control (2.29 mm/d), but elongation of fibers in regeneration began after a shorter delay in the Trembler (1.6 d) than in control (2.5 d). Thus, deficient Schwann cells and poor myelination appear to affect both quantitative and qualitative properties of slow axonal transport. These changes lead to alterations in the morphological and physiological properties of affected axons.     

Axonal transport of the cytoskeleton in regenerating motor neurons: constancy and change

We have examined slow axonal transport in regenerating motor neurons of the rat sciatic nerve. Using SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) we previously found that the slow component is the vehicle for the axonal cytoskeletal proteins, i.e. the neurofilament triplet proteins, tubulin and actin. When these proteins are pulse-labeled by injecting [3H]- or [35S]-amino acids into the spinal cord, they are transported distally in the nerve as two distinguishable waves of radioactivity, SCa and SCb. In normal motor neurons, the neurofilament triplet proteins and the tubulin are transported in SCa at an average velocity of 1.7 mm/day; the less heavily labeled SCb which moves at 2-5 mm/day is the primary vehicle for actin. We now find that during regeneration the velocity of SCa is unchanged in the region of the axon between the cell body and the lesion, but the amount of labeled neurofilament triplet and associated tubulin transported in the axon is decreased in neurons which had been labeled 20 days post-lesion. In contrast, the labeling of the slowly transported proteins moving ahead of the neurofilament triplet is greater in regenerating nerves than in controls. On the basis of our findings, we propose that in motor axons the normal supply of cytoskeletal protein, which is continuously transported in the slow component, is sufficient to support regeneration. Nevertheless, the neuron cell body can alter the supply of these cytoskeletal proteins so as to enhance its regenerative capacity.     

Alterations in slow transport kinetics induced by estramustine phosphate, an agent binding to microtubule-associated proteins.

Estramustine phosphate (EP) disassembles microtubules by binding to microtubule-associated proteins (MAPs) rather than tubulin. In this study, EP-induced alterations of MAP integrity caused a unique form of axonal atrophy in rats. Initially, EP-induced axonal atrophy occurred in both proximal and distal axons of the sciatic nerve, characterized by an increase in neurofilament packing density, associated with a decrease in axonal area. In chronic exposure, distal axonal atrophy was associated with decreased numbers of microtubules, while the neurofilament number remained unaltered for the myelin spiral length. Continued exposure caused enlargement of proximal axons associated with an increase in neurofilament content. Correlative slow transport studies done at two different times, 7 and 14 days after [35S] methionine injection showed that EP retards the transport of cytoskeletal proteins migrating with both components of slow transport (SCa and SCb). However, there was a differential effect on SCb which showed progressive slowing along the nerve while the rate of SCa stayed relatively constant. In this model, the early occurring distal axonal atrophy can best be explained by reduced cytoskeletal components, particularly those traveling in SCb. Later in the course of intoxication, a relatively constant rate of SCa permitted continuous transport of neurofilament triplets, accounting for unaltered numbers of neurofilaments in distal axons with increased packing density. This model of axonal atrophy is unique because spacing of neurofilaments, not numbers determined axon size. Furthermore, EP-induced dissociation of the SCa and SCb kinetics suggests that MAPs play a role in the orderly, cohesive migration of slow transport components, essential for the normal organization of cytoskeleton.     

Axotomy-induced alterations in the synthesis and transport of neurofilaments and microtubules in dorsal root ganglion cells

Changes in the synthesis and axonal transport of neurofilament (NF) proteins and tubulin were examined after various selective axotomies of adult rat DRG cells. For axonal transport studies, DRGs were labeled by microinjection of 35S-methionine 14 d after axonal injuries, and nerves were retrieved 7 or 14 d after labeling. Slowly transported proteins were examined by quantitative PAGE/fluorography. After distal peripheral nerve crush (50-55 mm from the DRG), the cytoskeleton that entered undamaged regions of peripheral branch DRG axons by slow axonal transport differed from normal, while the cytoskeleton that entered dorsal root axons did not. Specifically, smaller-than-normal ratios of labeled NF protein/tubulin were transported in peripheral DRG axons after distal peripheral nerve crush. This change was almost entirely due to a selective decrease in the output of labeled NF proteins rather than to an increase in the amount of tubulin transported with NF proteins. Since the efficiency of axonal regeneration is known to be lower after cut injury than after nerve crush, we compared the effect of cut versus crush axotomy of peripheral DRG axons on cytoskeletal protein output. A more substantial reduction in the labeled NF/tubulin transport resulted in peripheral DRG axons if the distal sciatic nerve was cut rather than crushed but, even under these axotomy conditions, the labeled NF/tubulin ratios in dorsal root axons were not reduced. Peripheral cut axotomy did result in a lag in the advance of the labeling peak of the NF/microtubule protein wave in dorsal root axons, suggesting either that these proteins were delayed in exiting the cell body or that a slowing of the rate of their transport occurred. Pulse-labeling DRGs in vitro using 35S-methionine, and analysis of labeled proteins by 2-dimensional PAGE-fluorography demonstrated that the incorporation of radioactivity into NF proteins was significantly reduced, while the labeling of tubulins was unchanged 14 d after distal peripheral axotomy. In contrast to the results of peripheral axotomy, dorsal root crushes made close to the DRG (2-3 mm) or considerably distal (at the CNS entry zone 28-30 mm from the DRG) did not produce detectable changes in the amount of labeled NF or tubulin transport in central or peripheral branch axons. These findings indicate that the down-regulation of NF production/output that is exhibited at 14 d after peripheral branch axotomy is not present after central branch injury.(ABSTRACT TRUNCATED AT 400 WORDS)     

Electrical stimulation of intact peripheral sensory axons in rats promotes outgrowth of their central projections

A lesion of a peripheral nerve before a second injury (conditioning lesion, CL), enhances peripheral and central regeneration of dorsal root ganglion (DRG) axons. This effect is mediated by elevated neuronal cAMP. Here we wanted to investigate whether electrical stimulation (ES) of an intact nerve, which has been shown to accelerate peripheral axon outgrowth, is also effective in promoting axon regeneration of injured DRG axons in vitro and of the central DRG axons in vivo and, whether this effect is mediated by elevation of cAMP. For the in vitro assay, the intact sciatic nerve of adult rats was stimulated at 20 Hz for 1 h, 7 days before harvest and primary culture of DRG neurons on a growth permissive substrate. In the in vivo study, the central axons of the lumbosacral DRGs were cut in the Th8 dorsal column, and the sciatic nerve was either cut or left intact, and subjected to 1 h ES at 20 Hz or 200 Hz. In vitro, ES increased neurite outgrowth 4-fold as compared to non-stimulated DRG neurons. In vivo, ES at 20 Hz significantly increased axon outgrowth into the central lesion site as compared to the Sham control. The 20 Hz ES was as effective as the CL in increasing axon outgrowth into the lesion site but not in promoting axonal elongation even though 20 Hz ES increased intracellular cAMP levels in DRG neurons as effectively as the CL. Thus elevation of cAMP may account for the central axonal outgrowth after ES and a CL.     

Maturation and aging of the axonal cytoskeleton: biochemical analysis of transported tubulin.

Changes in solubility and axonal transport of tubulin during maturation and aging have been investigated using sciatic motor fibers of rats at 4, 7, 14, 30, and 80 weeks of age. One to six weeks after injection of L-[35S]methionine into the spinal cord, labeled cytoskeletal proteins in consecutive segments of the sciatic nerve and the ventral roots were fractionated into soluble and insoluble forms by extraction in 1% Triton at low temperature. In 4-week-old rats, the two forms of tubulin were transported coordinately in a single wave with the average rate of 2 mm/day. At 7 weeks of age, two components in tubulin transport were observed to develop, possibly reflecting the maturation of the axonal cytoskeleton. The slower main component (1.5 mm/day) contained most of the insoluble form together with the neurofilament proteins and the faster component (3 mm/day) was enriched in the soluble form. Though significantly different in composition, the two components correspond to slow component a (SCa) and slow component b (SCb) originally defined in the optic system. A progressive decrease in transport rates of both SCa and SCb was observed with rats at 14, 30, and 80 weeks of age. In addition, there was a large decrease in the proportion of insoluble tubulin during the course of transport in animals older than 30 weeks. This loss of the insoluble form seems to be accounted for partly by the proteolytic degradation of the severely retarded SCa proteins. Changes in axonal transport of tubulin may thus reflect age-related changes in dynamics and turnover of the axonal cytoskeleton.     

Cyclic AMP elevates tubulin expression without increasing intrinsic axon growth capacity

Exposing rat dorsal root ganglion (DRG) neurons to dibutyryl cAMP (db-cAMP) enables central branches to regenerate in the spinal cord by nullifying the ability of CNS myelin to inhibit elongation. A conditioning lesion (CL) promotes similar regeneration of central branches in the spinal cord by increasing neuronal cAMP levels. It is a matter of speculation whether any of the other effects of a CL are triggered by elevated cAMP. We found that like a CL, intraganglionic injection of db-cAMP increases the expression of growth-associated tubulin isotypes. However, unlike a CL, db-cAMP does not increase the velocity at which tubulin is delivered to the tips of growing axons by slow component b (SCb). db-cAMP also fails to increase intrinsic axon growth capacity enough to raise the rate of regeneration of peripheral branches in the sciatic nerve or enable central branches to elongate long distances in an environment free of all CNS inhibitors of elongation (i.e., a peripheral nerve graft transplanted into the spinal cord at the site of dorsal column transection). Thus, the increase in cAMP induced by a CL induces some, but not all, of the changes that may be necessary to increase intrinsic axon growth capacity.     

Transport of cytoskeletal elements from parent axons into regenerating daughter axons

The kinetics of slow axonal transport in newly regenerating axonal sprouts were compared with those in nonelongating axons. The slowly transported cytoskeletal proteins of ventral motor axons were prelabeled by microinjection of 35S-methionine into the spinal cord. Pulse-labeled slow transport "waves" were observed as they progressed from the surviving "parent" axon stumps (located proximal to a crush lesion) into regenerating "daughter" axon sprouts (located distal to the lesion). Prelabeled cytoskeletal elements of the parent axons were transported into daughter axons, to become distributed into 2 transport waves, "a" and "b." The rate and composition of these waves corresponded to the slow transport subcomponents, SCa and SCb. The shapes of the "a" and "b" waves suggested that the cytoskeletal elements had been reorganized at the junction between the parent and daughter axons. This hypothesis was supported by quantitative analyses of the transport distribution for individual radiolabeled cytoskeletal proteins (actin, spectrin, a 58-67 kDa group that includes microtubule-associated proteins, calmodulin, and tubulin). Specifically, during the first week of outgrowth, the amounts of radiolabeled calmodulin and 58-67 kDa proteins were greater in daughter axons than in nonregenerating control axons. These results support Paul Weiss's "conservative" model of axonal regeneration, which holds that the preexisting transported cytoskeletal elements that continually maintain axonal structure can also provide the cytoskeletal elements required for axonal regeneration. In addition, the results elucidate some of the reorganizational changes in cytoskeletal elements that occur when these are recruited from the parent axon to form daughter axons.     

Axonal transport of actin: Slow component b is the principal source of actin for the axon

Axonally transported proteins were studied in guinea pig retinal ganglion cells using the standard radioisotopic labeling procedure. Two slowly moving groups of proteins were identified in guinea pig retinal ganglion cells. The more slowly moving group of proteins, designated slow component a (SCa) was transported at 0.2-0.5 mm/day. Five polypeptides contained greater than 75% of the total radioactivity transported in SCa. Two of these polypeptides correspond to the subunits of tubulin, while the other three correspond to the slow component triplet. The other slowly moving group of proteins, which is designated slow component b (SCb), was transported at approximately 2 mm/day. Twenty labeled polypeptides were identified in SCb. The major labeled polypeptides transported in SCb differ from those transported in SCa. One of the polypeptides transported in SCb co-migrates with skeletal muscle actin in SDS-polyacrylamide slab gels. This polypeptide behaved identically to skeletal muscle actin on DNaseI affinity columns. Since DNaseI is a highly specific affinity ligand for actin, we conclude that the labeled SCb polypeptide which comigrates with actin in SDS-gels is actin. Between 1.4 and 5.7% of the total radioactivity transported in SCb is attributable to action. Detailed comparison of the distribution of total radioactivity in the optic axons with the distribution of radioactive actin in the optic axons at post-injection times between 6 and 77 days showed that actin was transported specifically in SCb, and not in SCa. Furthermore, analyses of the proteins transported in the fast component of guinea pig retinal ganglion cells by DNaseI affinity chromatography failed to reveal an actin-like moiety. Slow component a, SCb and the fast component are the major components of axonal transport in guinea pig retinal ganglion cells. Thus, in these neurons, actin is transported principally and possibly only in SCb. Guinea pig retinal ganglion cell axons project principally to the lateral geniculate nucleus and superior colliculus. The fate of actin axonally transported to the region of the axon terminals was studied by determining the kinetics by which radioactivity associated with actin accumulates and then decays in the superior colliculus. The results of these studies indicate that labeled actin has a half-life in the superior colliculus of approximately 28 days.     

Axonal regeneration in dorsal spinal roots is accelerated by peripheral axonal transection

Regeneration of crushed axons in rat dorsal spinal roots was measured to investigate the transganglionic influence of an additional peripheral axonal injury. The right sciatic nerve was cut at the hip and the left sciatic nerve was left intact. One week later, both fifth lumbar dorsal roots were crushed and subsequently, regeneration in the two roots was assessed with one of two anatomical techniques. By anterograde tracing with horseradish peroxidase, the maximal rate of axonal regrowth towards the spinal cord was estimated to be 1.0 mm/day on the left and 3.1 mm/day on the right. Eighteen days after crush injury, new, thinly myelinated fibers in the root between crush site and spinal cord were 5-10 times more abundant ipsilateral to the sciatic nerve transection. The central axons of primary sensory neurons regenerate more quickly if the corresponding peripheral axons are also injured.     

Phosphofructokinase in the rat nervous system: regional differences in activity and characteristics of axonal transport

The distribution of phosphofructokinase (PFK) in gray and white matter regions of the rat nervous system was evaluated. Determinations of PFK activity revealed that cell body enriched regions (sensorimotor cortex) had a significantly higher level of activity than axonal regions (sciatic nerve, dorsal roots, and optic nerve). The level of PFK activity was also significantly higher in central axons (optic nerve) than in peripheral axons (sciatic nerve). Differences in PFK activity could be largely attributed to differences in tissue content of the enzyme rather than to differences in the types of PFK isozymes present. Cortex contained significantly larger amounts of PFK relative to total protein than did peripheral nerve. However, purification of PFK revealed that all three of the PFK isozymes, C (86 kd), A (84 kd), and B (80 kd), were present in both cortex and sciatic nerve. Both SDS/PAGE and immunoblotting studies using PFK isozyme-specific antibodies demonstrated that the relative proportions of the three PFK isozymes were similar in cell body and axonal regions of the nervous system. The PFK-C and PFK-A isozymes each comprised about half the total and only small amounts of the PFK-B isozyme were present in both regions. However, immunoprecipitation experiments suggested that quantitatively different proportions of the possible PFK hybrids (tetramers) may be distributed between axonal and cell body regions. The transport of PFK was examined in this study and PFK was identified in slow component b (SCb) of axonal transport. SCb moves at a rate of 2-4 mm/day in rat axons and is known to contain several other enzymes of intermediary metabolism as well as actin. The finding that PFK, the rate limiting enzyme in glycolysis, is present in SCb lends support to the hypothesis that glycolytic enzymes are not freely diffusing proteins in axons but, instead, are present as organized assemblies that have long-term, yet flexible, associations with structural elements of the cytoplasm.     

Diversity in the axonal transport of structural proteins: major differences between optic and spinal axons in the rat

Investigations of slow axonal transport reveal variation in both protein composition and the rate of movement. However, these studies involve a variety of nerve preparations in different species, and most lack the resolution needed to determine the kinetics of identified proteins. We have compared the axonal transport of slow-transported proteins in retinal ganglion cells and spinal motor neurons of young rats. Nine proteins that contribute to axonal structures were examined: the neurofilament triplet (NFT), alpha and beta tubulin, actin, fodrin, calmodulin, and clathrin. Axonally transported proteins were pulse-labeled by intraocular or intracord injections of 35S-methionine. After allowing sufficient time for labeled slow-component proteins to enter the spinal or optic nerves, consecutive 2-3 mm nerve segments were subjected to SDS-PAGE. Fluorographs were used as templates for locating the gel regions containing the above polypeptides, and the radioactivity in these regions was measured by liquid-scintillation spectrometry. In retinal ganglion cells, the peak of tubulin labeling advanced at 0.36 mm/d in association with the NFT and fodrin. The cotransport of tubulin and the NFT identified this complex as the slower subcomponent of slow transport, termed slow component a (SCa) and representing the movement of the microtubule-neurofilament network. The peaks of actin and calmodulin labeling were cotransported at 2.3 mm/d in near-register with peaks of fodrin and clathrin labeling. These 4 proteins, moving ahead of the NFT, identified this complex as SCb--the faster subcomponent of slow transport, which represents the movement of the cytoplasmic matrix and microtrabecular lattice. Both subcomponents had the same composition and rate as that reported for the optic axons of guinea pigs and rabbits, establishing a basic mammalian pattern. In spinal motor axons, the SCa tubulin peak advanced at 1.3 mm/d, and the SCb actin and calmodulin peaks were cotransported at 3.1 mm/d. Unlike optic axons, SCa in motor axons was more heavily labeled than SCb, and included labeled peaks of actin, clathrin, and calmodulin moving in register with the SCa tubulin peak. Actin was the most heavily labeled of these SCb proteins moving with SCa, and it left a higher plateau of radioactivity behind the advancing SCa peak. The SDS-PAGE labeling pattern for SCb did not differ from that seen in optic axons, except that some tubulin was found to form a peak that advanced in register with the actin and calmodulin peaks.(ABSTRACT TRUNCATED AT 400 WORDS)     

Inflammation near the nerve cell body enhances axonal regeneration

Although crushed axons in a dorsal spinal root normally regenerate more slowly than peripheral axons, their regeneration can be accelerated by a conditioning lesion to the corresponding peripheral nerve. These and other observations indicate that injury to peripheral sensory axons triggers changes in their nerve cell bodies that contribute to axonal regeneration. To investigate mechanisms of activating nerve cell bodies, an inflammatory reaction was provoked in rat dorsal root ganglia (DRG) through injection of Corynebacterium parvum. This inflammation enhanced regeneration in the associated dorsal root, increasing 4-fold the number of regenerating fibers 17 d after crushing; peripheral nerve regeneration was not accelerated. A milder stimulation of dorsal root regeneration was detected after direct injection of isogenous macrophages into the ganglion. It is concluded that changes favorable to axonal regeneration can be induced by products of inflammatory cells acting in the vicinity of the nerve cell body. Satellite glial cells and other unidentified cells in lumbar DRG were shown by thymidine radioautography to proliferate after sciatic nerve transection or injection of C. parvum into the ganglia. Intrathecal infusion of mitomycin C suppressed axotomy-induced mitosis of satellite glial cells but did not impede axonal regeneration in the dorsal root or the peripheral nerve. Nevertheless, the similarity in reactions of satellite glial cells during 2 processes that activate neurons adds indirect support to the idea that non-neuronal cells in the DRG might influence regenerative responses of primary sensory neurons.     

Slow transport rates of cytoskeletal proteins change during regeneration of axotomized retinal neurons in adult rats

To investigate cytoskeletal changes associated with axonal regrowth from damaged nerve cells in the mammalian CNS, we examined the slow transport of axonal proteins during the regeneration of adult rat retinal ganglion cell (RGC) axons. Although normally such RGC axons do not regrow after injury in the CNS, they can extend several centimeters when their nonneuronal environment is changed by replacing the optic nerve (ON) with a grafted segment of peripheral nerve (PN). Proteins transported in axons of RGCs from intact control and PN-grafted animals were labeled by an intraocular injection of 35S-methionine and examined 4-60 days later by SDS PAGE. During RGC regeneration into PN grafts, the transport rate of tubulin and neurofilament increased twofold, whereas that of actin decreased to nearly one third of its normal rate. Thus, in these regenerating RGC axons, all three major cytoskeletal proteins were largely transported within a single rate component rather than in the two separate components (SCa and SCb) normally observed in the intact ON. Furthermore, the 200 kDa neurofilament protein (NF-H) was persistently detected in Western blots during periods of active regeneration, a finding that contrasts with the late appearance of the NF-H during the developmental growth of retinal axons. The changes in slow transport observed during RGC regeneration in adult rats may reflect growth-associated responses of mature CNS neurons during periods of active axonal extension.     

Experimental diabetic neuropathy: similar changes of slow axonal transport and axonal size in different animal models

Analysis of slow axonal transport in sciatic and primary visual systems of BB rats with spontaneous diabetes of 2.5-3.5 months duration revealed a delay in transport of the neurofilament (NF) subunits, tubulin, actin, and the 60, 52, and 30 kDa polypeptides in both systems. The polypeptides examined were not affected uniformly. Rather, the transport of the 60, 52, and 30 kDa polypeptides and the rapidly moving component of tubulin, all constituents of the slow component b (SCb) of axonal transport, appeared to be more severely delayed than the transport of polypeptide constituents of the slow component a (SCa), such as NF and the slow-moving tubulin. Transport was not impaired in diabetic BB rats maintained normoglycemic with optimal doses of insulin. A 52 kDa polypeptide constituent of SCb was identified as neuron-specific enolase, and the 30 and 60 kDa polypeptides are likely to be aldolase and pyruvate kinase; all 3 are glycolytic enzymes. Morphometric analysis revealed that the cross-sectional area of sciatic axons was increased proximally at the level of the motor roots and decreased distally at the level of the tibial nerve. The changes in slow transport and caliber observed in central and peripheral axonal systems of diabetic BB rats are virtually identical to those previously described in rats with streptozotocin-induced diabetes, another model of insulin-dependent diabetes. In both models, the alterations of axonal caliber are likely to be secondary to the impairment of axonal transport.(ABSTRACT TRUNCATED AT 250 WORDS)     

Constitutive expression of GAP-43 correlates with rapid, but not slow regrowth of injured dorsal root axons in the adult rat

It has been postulated that the neuronal growth-associated protein GAP-43 plays an essential role in axon elongation. Although termination of developmental axon growth is generally accompanied by a decline in expression of GAP-43, a subpopulation of dorsal root ganglion (DRG) neurons retains constitutive expression of GAP-43 throughout adulthood. Peripheral nerve regeneration occurring subsequent to injury of the peripheral axon branches of adult DRG neurons is accompanied by renewed elevation of GAP-43 expression. Lesions of DRG central axon branches in the dorsal roots are also followed by some regenerative growth, but little or no increase in GAP-43 expression above the constitutive level is observed. To determine whether dorsal root axon regeneration occurs only from neurons which constitutively express GAP-43, we have used retrograde fluorescent labeling to identify those DRG neurons which extend axons beyond a crush lesion of the dorsal root. Only GAP-43 immunoreactive neurons supported axon regrowth of 7 mm or greater within the first week. At later times, axon regrowth is seen to occur from neurons both with and without GAP-43 immunoreactivity. We conclude that regeneration of injured axons within the dorsal root is not absolutely dependent on the presence of GAP-43, but that expression of GAP-43 is correlated with a capacity for rapid growth.     

Fate of GAP-43 in ascending spinal axons of DRG neurons after peripheral nerve injury: delayed accumulation and correlation with regenerative potential.

Proteins characteristic of growing axons often fail to be induced or transported along axons that have been interrupted far from their cell bodies in the adult mammalian CNS. Here, we inquire whether long axons in the mammalian CNS can support efficient axonal transport and deposition of one such protein, GAP-43, when the protein is induced in neuron cell bodies. We have used immunocytochemistry to follow the fate of GAP-43 in dorsal column axons ascending the rat spinal cord from dorsal column axons ascending the rat spinal cord from dorsal root ganglion (DRG) neurons, after synthesis of the protein is induced in these cells by peripheral nerve injury. Sciatic nerve lesions do lead to an accumulation of GAP-43 in dorsal column axons derived from the lumbar DRG. However, in distal segments of these CNS axons, accumulation of GAP-43 is apparent only after a delay of 1-2 weeks, in contrast to its rapid accumulation in axon segments within the PNS environment, suggesting that deposition and stabilization of GAP-43 can be limited by local, posttranslational regulation. GAP-43 immunoreactivity subsides to control levels within 8 weeks after crush lesions that permit peripheral axon regeneration, but remains robust 8 weeks after resection lesions that prevent peripheral regeneration. Accumulation of GAP-43 in cervical dorsal column axons after peripheral nerve injury is closely correlated with the ability of these axons to respond to local cues capable of eliciting axon growth (Richardson and Verge, 1986).