Subsets of axonally transported and periaxonal polypeptides are released from regenerating nerve

Differential effects of axotomy on the in vivo synthesis of the stress-inducible and constitutive 70-kDa heat-shock proteins in rat dorsal root ganglia

The purpose of this study was to the test the hypothesis that heat-shock protein expression is upregulated (or induced) in dorsal root ganglia (DRG) following axotomy. To test this hypothesis, DRG or sciatic nerve (SN) proteins were pulse-labelled in vivo with [35S]methionine and the metabolic synthesis of two major 70-kDa heat-shock proteins, the constitutive species (hsc70) and stress-inducible species (hsp68), were analyzed by two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) and fluorography. Results showed that DRG hsp68 expression was absent (or barely detectable) under normal (sham-axotomy) conditions. However, following long-range axotomy (35 mm from DRG), there was a delayed (> 12 h post-axotomy) and transient upregulation of DRG hsp68 metabolic synthesis. Control studies demonstrated that, although DRG hsp68 was upregulated, hsp68 was not induced in SN regions proximal to the crush site. In contrast to DRG hsp68 expression, there was abundant DRG hsc70 synthesis under normal conditions that did not significantly change following axotomy. These results suggest that a specific stress protein response is induced in DRG following axotomy.

Calmodulin and in vitro regenerating frog sciatic nerves: release and extracellular effects

Although calmodulin (CaM) is commonly considered to be an intracellular protein, it has been suggested lately that it is released and exerts functions extracellularly. In the present investigation this was studied in in vitro regenerating adult frog (Rana temporaria) sciatic nerves. Using a multi-compartment incubation chamber, the non-neuronal cells in the outgrowth region of such nerves were radiolabelled with amino acid precursors. Based on immunological criteria, these cells were shown to release CaM. When the nerves were treated with CaM, both the outgrowth of sensory axons and the injury-induced proliferation of non-neuronal cells were partially inhibited. The inhibitory effects occurred even when the incubation medium contained as little as 30 pM CaM. Furthermore, treatment with anti-CaM antibodies resulted in reduced outgrowth, which suggested that during normal conditions extracellular CaM is kept at an optimal concentration. Finally, conditioned medium was found to contain several CaM-binding proteins. The present findings may reflect an earlier unknown function of extracellular CaM in controlling various growth mechanisms in integrated tissues.

Regenerating peripheral axons transport and release low-molecular-mass materials in vitro

The release of radiolabeled material from regenerating frog sciatic nerves was studied using a multicompartment chamber, in which the ganglia and the outgrowth region, respectively, were separated from the rest of the nerve. The nerves were incubated with radioactive amino acids in the ganglionic compartment, and the material transported to and released at the outgrowth region was collected and analyzed. Approximately 10% of the transported radioactivity was released over a 24-h incubation period. Of the released materials, 84% had a molecular mass of < 1,000 daltons [the low-molecular-mass (LM) fraction] as determined by exclusion chromatography. The presence of LM material could not be explained by leakage, nor was it due to intracellular or extracellular degradation of radiolabeled, transported proteins. It was reduced by cold and was shown by the use of vinblastine to be dependent on axonal transport. According to TLC, both the original precursor and metabolites thereof could be detected among the released LM material. The present results demonstrate the existence of a transport system for LM material in peripheral axons. The preferential release of LM over high-molecular-mass material at the outgrowth region suggests that it could serve specific functions during regeneration.

Effects of freezing a segment of peripheral nerve on subsequent protein release and axonal regeneration in the frog

Previous studies in frogs have shown that axons from the proximal stump of a cut nerve will grow toward the distal stump, possibly in response to diffusible trophic factors produced by cells of the nerve sheath. In the present experiments, the synthesis and release of proteins in vitro, from proximal and distal stumps of frog sciatic nerves, were studied 1, 4, and 14 days after nerve section in vivo. Using two-dimensional gel electrophoresis to separate released proteins, a marked increase in the synthesis of two lipoproteins of 37 and 67 kDa was seen, initially in both proximal and distal stumps, but by 14 days these proteins were produced exclusively by the distal stump. To see if the production of these proteins was correlated with subsequent reinnervation of the distal stump, isolated nerve segments were removed from the frogs and either replaced immediately or frozen (to kill sheath cells) and replaced. After 2 weeks, the pattern of newly synthesized proteins released by both the frozen and nonfrozen nerve segments was similar although freezing severely impaired the reinnervation of the nerve segment. These results suggest that although the 37- and 67-kDa lipoproteins may have a role in nerve regeneration, their presence per se is not sufficient to support the reinnervation of a distal stump of a cut peripheral nerve and that additional factors may therefore be required.

Axotomized frog sciatic nerve releases diffusible neurite-promoting factors

Using the bullfrog (Rana catesbeiana) dorsal root ganglia (DRG) and its sciatic nerve (ScN) as a model system, we have previously described neuronal and non-neuronal molecular changes associated with the early regenerative response of DRG neurons to axotomy. Since diffusible molecular factors, released by axotomized ScN, might function to stimulate axon regrowth, we have assayed the ability of ScN-conditioned bath to promote in vitro neurite outgrowth from PC-12 cells. Diffusible ScN proteins were collected by incubating segments of normal or axotomized ScN in a small volume of RPMI media for 4 h (nerve bath). The nerve baths, supplemented with serum, were then added to PC-12 cell cultures to assay for the presence of neurite growth factors released by ScN. Results showed that nerve baths, collected from sham-operated or axotomized ScN, could not induce the differentiation of PC-12 into neurite-bearing cells. Therefore, in all subsequent neurite growth assay experiments, an exogenous source of nerve growth factor (NGF) (50 ng/ml) was added to the nerve baths or unconditioned media to generate and maintain PC-12 neuritic structure. We found that nerve baths, collected from previously axotomized (at least 3 days post-injury) nerve, contained diffusible factors which enhanced PC-12 neurite growth, relative to unconditioned media. No neurite growth factors were observed to be released by sham-operated ScN or 1-day post-axotomized ScN. Further experiments were conducted to identify the diffusible neurite growth factors released from axotomized ScN. We showed that the release (if any) of endogenous diffusible NGF or laminin from axotomized nerve could not have accounted for the facilitation of neurite growth. Analysis of radiolabelled ScN proteins by two-dimensional polyacrylamide gel could not have accounted for the facilitation of neurite growth. Analysis of radiolabelled ScN proteins by two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) showed that the relative abundance of two diffusible proteins (M(r) approximately 35 and 70 kDa) in the nerve bath was directly correlated with the ability of the nerve bath to facilitate PC-12 neurite growth.

Extracellular proteins of goldfish optic tectum labeled by intraocular injection of 3H-proline

A prominent group of soluble glycoproteins with a molecular weight of 30K-40K and pI 5.0-5.6 was detected in various parts of the goldfish brain as well as in the optic nerves. Since these proteins are readily liberated from the tissue, we have designated them exoglycoproteins (X-GPs). The X-GPs in the optic tectum were found to be labeled after intraocular injection of radioactive tracers, in a manner consistent with the labeling of proteins transported in the optic axons. However, the labeling of X-GPs was blocked by intracranial injection of a protein synthesis inhibitor, whereas the labeling of axonally transported proteins was unaffected. This shows that the X-GPs can be synthesized locally within the brain. Nevertheless, when protein synthesis in the retina was blocked, the labeling of the X-GPs in the tectum was prevented, like the labeling of axonally transported proteins. Thus precursors for the synthesis of X-GPs can be derived from materials transported in the optic axons. This synthesis can occur in nonneuronal cells, as indicated by the incorporation of labeled amino acid into X-GPs in optic nerves directly exposed to the label. The synthesis of X-GPs was increased in regenerating nerves, suggesting that these proteins may play a role in regeneration. Partial amino acid sequencing of the proteins showed that they are identical to the proteins previously identified as "ependymins," which have been implicated in neuronal plasticity. There are minor differences in amino acid sequence among some individual spots.

Growth cones of regenerating adult sciatic sensory axons release axonally transported proteins

Labelled, rapidly transported axonal proteins were shown to be released from adult frog sciatic sensory neurons, regenerating in vitro after a crush injury. The spatial distribution of the transported, released proteins could accurately be resolved by culturing the nerve on nitrocellulose paper, which trapped the released proteins. The release was located to the crush and to the entire outgrowth region. When regeneration was inhibited by adenosine, the release was limited to the crush site, implying that the release was linked to the growing axons. Other experiments suggested that the release emanated from growth cones. Furthermore, two-dimensional electrophoretical analysis of both fast axonally transported and of released proteins showed that the latter represented a selection of the transported protein species.

Axonal transport reversal of acetylcholinesterase molecular forms in transected nerve

Reversal of anterograde rapid axonal transport of four molecular forms of acetylcholinesterase (AChE) was studied in chick sciatic nerve during the 24-h period following a nerve transection. Reversal of AChE activity started approximately 1 h after nerve transection, and all the forms of the enzyme, except the monomeric ones, showed reversal of transport. The quantity of enzyme activity reversed 24 h after transection was twofold greater than that normally conveyed by retrograde transport. We observed no leakage of the enzyme at the site of the nerve transection and no reversal of AChE activity transport in the distal segment of the severed nerve, a result indicating that the material carried by retrograde axonal transport cannot be reversed by axotomy. Thus, a nerve transection induces both quantitative and qualitative changes in the retrograde axonal transport, which could serve as a signal of distal injury to the cell body. The velocity of reverse transport, measured within 6 h after transection, was found to be 213 mm/day, a value close to that of retrograde transport (200 mm/day). This suggests that the reversal taking place in severed sciatic nerve is similar to the anterograde-to-retrograde conversion process normally occurring at the nerve endings.

Axonal transport and release of transferrin in nerves of regenerating amphibian limbs

Transferrin, a plasma protein required for proliferation of normal and malignant cells, is abundant in peripheral nerves of birds and mammals and becomes more concentrated in this tissue during nerve regeneration. We are testing the hypothesis that this factor is involved in the growth-promoting effect of nerves during the early, avascular phase of amphibian limb regeneration. A sensitive enzyme-linked immunosorbent assay for axolotl transferrin was developed and used to determine whether this protein meets certain criteria expected of the trophic factor(s) from nerves. During limb regeneration adult sciatic nerves greatly increased their content of transferrin, which immunohistochemistry revealed was distributed in both axons and Schwann cells. Using the double ligature method with sciatic nerves in vivo, it was determined that transferrin is carried by fast anterograde axonal transport at all stages of limb regeneration. An approach based on multicompartment organ culture demonstrated that fast-transported transferrin was secreted in physiologically significant amounts at distal ends of regenerating axons. Finally, the concentration of transferrin in the distal region of larval axolotl limb stumps was found to decrease directly and rapidly in response to axotomy. Since transferrin is important for both axonal regeneration and cell cycling, the present data have significance for various aspects of nerve's trophic activity during limb regeneration.

Regeneration of the neurohemal terminals for identified cerebral neurosecretory cells in an insect

The axons of specific neurosecretory cells, L-NSC III, in the brain of the tobacco hornworm, Manduca sexta, were transected during larval-pupal development to study the effects of this type of lesion on these peptidergic neurons and to begin to identify factors that may regulate their regeneration and growth. The two somata of these bilaterally paired neurons produce the prothoracicotropic hormone and are located in the pars intercerebralis. Their axons exit from the contralateral brain lobe via a retrocerebral nerve and pass through the corpus cardiacum before terminating at the glandular corpus allatum. At the corpus allatum, the L-NSC III axons arborize to form the terminal neurohemal organ for prothoracicotropic hormone release. The retrocerebral nerve was severed either in vitro followed by brain transplantation or in situ; in either protocol, the distal axon segments and corpus allatum were removed. The ability of the injured L-NSC III axons to regenerate was assessed immunocytologically by using a monoclonal antibody against the prothoracicotropic hormone. In both treatments, the proximal axon stumps exhibited regenerative growth as early as 1 day after axotomy, and, by the third day, neurites had extended. By the fifth day, the regenerating axons had branched to form terminal varicosities similar to those of a normal neurohemal organ. The regenerated neurohemal structure appeared to be functional, because larvae that had been bilaterally axotomized were able to metamorphose to pupae, a process requiring temporally precise periods of prothoracicotropic hormone release. In addition to the regeneration of the terminal axon structures, several other responses to axotomy and retrocerebral organ excision occurred. These included an apparent accumulation of prothoracicotropic hormone in the axons and regenerating neurohemal-like structure, sprouting of ectopic neurites from the axotomized somata, and a change in shape of the cell bodies from spherical to avoid.

Junction between parent and daughter axons in regenerating myelinated nerve: properties of structure and rapid axonal transport

The primary aim of this work was to investigate the properties of rapid axonal transport in regenerating myelinated axons in the sciatic nerve of Xenopus laevis, with particular attention to events at the junction between the proximal, intact axon (the "parent") and the distal, newly formed axon (the "daughter"). Morphological studies indicated that all myelinated axons initiated regeneration and that at least 80% of these axons regenerated at a rate of 1 mm/day or greater (20 degrees C). The ultrastructure of the junctional region was examined at regeneration times between 3 days and 20 weeks. The main qualitative change in the junctional axoplasm over this period was in its content of particulate organelles. At times up to 2 weeks regeneration, the junction contained abnormal numbers of 50 nm diameter vesicles and 10 nm granules. Between 2 and 5 weeks the junction showed in addition a peripheral rim of large membrane-bounded organelles around a central core of microtubules and neurofilaments. At longer times the numbers of large membrane-bounded organelles diminished and all junctions contained prominent accumulations of 10 nm granules. The rate of rapid axonal transport of protein was similar in parent and daughter axons. Compared to the parent axons, a 2-5 times greater amount of protein was deposited to a stationary phase in daughter axons. Specimens of nerve that were subjected to mechanical stress during the removal of the perineurium showed a large accumulation of rapidly transported protein in the region of the crush at regeneration times up to 40 days; some of the accumulated protein was subsequently transported retrogradely. Video microscopy of isolated axons supplied evidence that the transport deficit in mechanically stressed nerve was a partial block of anterograde vesicle transport, plus a reversal of anterograde transport, at the junction of parent with daughter axons. No structural changes were detected in mechanically stressed nerve. The results show that the junction between parent and daughter myelinated axons is a region with distinct morphology at which the dynamics of anterograde axonal transport may change dramatically.

Quantitative analysis of labelled inner retinal proteins in experimental optic neuritis

In order to determine if axonal transport changes in chronic experimental allergic encephalomyelitis (EAE) were due to blockade or increased discharge of fast transported proteins from the inner retina, we examined the presence of pulse labeled proteins in autoradiograms of the optic nerve head, retinal ganglion cell and nerve fiber layers of juvenile strain-13 guinea pigs with chronic EAE and normal controls. Quantitative analysis of silver grains, performed six and twenty-four hours following the intravitreal injection of tritiated leucine, showed a decrease in inner retinal radioactivity in those with EAE, whereas no difference was detected between the two groups after three days. Grain counts within the optic nerve heads of guinea pigs with EAE were reduced at all time intervals studied. These results are consistent with an increase in discharge of fast transported proteins from retinal ganglion cells into optic nerve axons and support our previous observations of increased radioactivity at the foci of optic nerve demyelination.

The release of axonally transported material from an in vitro amphibian sciatic nerve preparation

The rapid axonal transport of a pulse of [35S]methionine-labelled material was used to study the release of transported material from amphibian nerve maintained in vitro. Following creation of a moving pulse of activity in a dorsal root ganglion-sciatic nerve preparation, the ganglion was removed and the nerve placed in a three-compartment tray, the section of nerve in the middle compartment containing no truncated branches (unbranched section). All three compartments were filled with a saline solution that in some studies contained nonradioactive methionine (1.0 mmol/L). Analysis of studies in which nonradioactive methionine was absent revealed that labelled material appeared in the bathing solution of the end compartments that contained truncated branches, but not in the solution of the middle (unbranched) compartment. The quantity of label released in the branched compartments was approximately 6% of that remaining in the corresponding section of nerve following an 18-20 h incubation period. However, when nonradioactive methionine was present, all compartments showed an additional activity in the bathing solution of approximately 10% of that remaining in the nerve. In another study in which a position-sensitive detector of ionizing radiation was used to monitor progress of the pulse, it was found that activity did not enter the bathing solution of a compartment prior to the pulse of activity. It is concluded that in the absence of methionine from the bathing solution, axonally transported material is released only from regions of nerve that contain severed axons; however, the presence of methionine allows transported material to be released from nerve containing intact axons. Ultrafiltration studies and thin-layer chromatography revealed the majority of material released to be of low-molecular weight (less than 30,000 daltons) and not free [35S]methionine.

Effects of a conditioning lesion on bullfrog sciatic nerve regeneration: analysis of fast axonally transported proteins

We have shown that bullfrog sciatic nerves respond to a conditioning lesion similarly to goldfish optic nerve and rat or mouse sciatic nerve; that is, following a crush the rate of regeneration is faster in nerves that have received a conditioning lesion compared to nerves that have not. Also, damaged nerve fibres show initial growth or sprouting earlier in a previously conditioned nerve compared to nerves that have not received a prior conditioning lesion. We have not detected changes in the transport of fast axonally transported proteins with the conditioning lesion paradigm, other than those changes seen in regenerating nerves after receiving a single lesion. However, more label was present in a few fast axonally transported proteins at the lesion site in conditioned nerves compared to non-conditioned nerves, and this difference is not apparently due to increased transport. It seems that changes in fast axonally transported proteins probably do not contribute directly to the mechanism underlying the conditioning lesion effect of higher out growth rates, although some of the fast transported proteins may be involved in functions, possibly at the growing tip of damaged fibres, which promote or result from the conditioning effect.