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

Conditioning lesions enhance axonal regeneration of descending brain neurons in spinal-cord-transected larval lamprey

In larval lamprey, with increasing recovery times after a transection of the rostral spinal cord, there is a gradual recovery of locomotor behavior, and descending brain neurons regenerate their axons for progressively greater distances below the transection site. In the present study, spinal cord "conditioning lesions" (i.e., transections) were performed in the spinal cord at 30% body length (BL; normalized distance from the head) or 50% BL. After various "lesion delay times" (D), a more proximal spinal cord "test lesion" (i.e., transection) was performed at 10% BL, and then, after various recovery times (R), horseradish peroxidase was applied to the spinal cord at 20% BL to determine the extent of axonal regeneration of descending brain neurons. Conditioning lesions at 30% BL, lesion delay times of 2 weeks, and recovery times of 4 weeks (D-R = 2-4 group) resulted in a significant enhancement of axonal regeneration for the total numbers of descending brain neurons as well as neurons in certain brain cell groups compared to control animals without conditioning lesions. Experiments with hemiconditioning lesions, which reduce interanimal variability, confirmed that conditioning lesions do significantly enhance axonal regeneration and indicate that axotomy rather than diffusible factors released at the injury site is primarily involved in this enhancement. Results from the present study suggest that conditioning lesions "prime" descending brain neurons via cell body responses and enhance subsequent axonal regeneration, probably by reducing the initial delay and/or increasing the initial rate of axonal outgrowth.

Alterations in geniculate ganglion proteins following fungiform receptor damage

Previous anatomical studies in rat have shown that damage produced to fungiform receptors of the anterior tongue at postnatal age 2 (P2) alters the growth and ramification of primary gustatory axons in the rostral nucleus of the solitary tract (NST). Studies employing artificial rearing (AR) procedures, which functionally deprive rat pups of orochemical stimulation during critical periods of postnatal life, produce similar alterations in the development of primary gustatory axons in the NST. Therefore, orochemical stimulation during rat's early postnatal life is necessary for normal development of primary gustatory axons in the rostral NST. One hypothesis concerning receptor-damage effects and AR effects is that receptor damage during critical periods of development may alter the regulation (i.e. transcription/translation) and/or distribution (i.e. transport) of proteins in geniculate ganglion neurons, thereby affecting growth of primary gustatory axons in the rostral NST. Specific aims of the present experiments were to comprehensively examine electrophoretic profiles of geniculate ganglion proteins following P2 receptor damage and late (> P40) receptor damage. Results show that concentrations of particular geniculate ganglion proteins are differentially altered following P2 receptor damage and late receptor damage, and that early receptor damage and late receptor damage produces distinct effects on the electrophoretic profiles of particular classes of proteins. Between the ages of P7-P38, P2 receptor damage lowers ganglion concentration of an acidic membrane glycoprotein designated as A1, with an apparent M(r) of 64-67 kDa and a pI of 4.8-5.2 P2 receptor damage also lowers ganglion concentrations of GAP-43. P2 receptor damage produces transient decreases in ganglion concentrations of NF-160, NF-200, and 8 additional acidic proteins. Three of these proteins may correspond to peripheral nerve sheath proteins analyzed in previous studies of the sciatic nerve, and one of these proteins may correspond to a 24 kDa growth-associated protein characterized in regenerating optic nerve. The time-course for changes observed in ganglion proteins following P2 damage was consistent with that observed for normal anatomical development of primary gustatory axons in both the lingual epithelium and NST. Receptor damage produced at P40 and later yielded different patterns of changes in geniculate ganglion proteins. Late receptor damage produced a transient increase in ganglion concentrations of NF-160, NF-200, GAP-43 and four additional acidic proteins within the 29-57 kDa M(r) range. Late receptor damage also produced a transient decrease in the concentrations of protein A1 and a 30 kDa protein that was not affected by P2 damage. Therefore, proteins that were preferentially affected by P2 damage may be involved in the regulation of initial axonal growth within the lingual epithelium and NST, as opposed to the structural repair or maintenance of extant axons. Relationships between normal anatomical development in peripheral and central components of primary gustatory axons are discussed in relation to availability of particular cytoskeletal and growth-associated proteins.

Expression of GAP-43 in normal and regenerating nerves in the frog

A polyclonal antiserum to chicken, growth-associated protein-43 (GAP-43), raised in rabbit, was shown to recognize a molecule with similar properties to GAP-43 in frogs. Using this antiserum, GAP-43 immunoreactivity was shown to be present throughout the brain and white matter of the spinal cord of larval frogs, but became restricted to specific regions in the adult frog central nervous system. In the peripheral nervous system, GAP-43 was present in normal tadpole and adult axons. After cutting the adult sciatic nerve, GAP-43 slowly disappeared from axons in the distal stump, but appeared in Schwann cells and other (uncharacterized) cells. The constitutive expression of GAP-43 in the adult frog sciatic nerve may be related to the phenomenon of remodelling of motor end-plates, which is known to occur throughout life in frogs.

Effects of protein kinase inhibitors on regeneration in vitro of adult frog sciatic sensory axons

The effects of protein kinase inhibitors on regeneration in vitro of adult frog sciatic sensory axons were tested. Regeneration of crush-injured nerves for 8 days in serum-free medium was inhibited by staurosporine (100 nM) and H-7 (100 microM), which are both known to inhibit protein kinase C. With the use of a compartmented culture system it could be shown that H-7 exerted both local (outgrowth region) and central (ganglia) effects, the latter being more pronounced. The local effects could be due to reduction of Schwann cell proliferation by H-7. Immunohistochemistry demonstrated the presence of protein kinase C in neuronal cell bodies but not in axonal processes. Proliferation of Schwann cells was accompanied by increased protein kinase C immunoreactivity at the site of injury. H-7 caused a selective inhibition in the incorporation of radioactive phosphate into one 74 kDa protein of both ganglia and nerve but also a more general decrease in protein labelling. The results show that protein phosphorylations, possibly mediated by protein kinase C, are involved in regeneration-related mechanisms operating at both local and central levels in the adult frog sciatic sensory axons.

A fast axonally transported protein of the frog sciatic sensory axons undergoes similar qualitative changes during regeneration in vitro and in vivo

The adult frog sciatic sensory neurons have been shown to regenerate in vitro. If a crush injury is made at the beginning of culture, regeneration starts after 3.4 days and proceeds at a rate of approximately 0.8 mm/day for several days. Two-dimensional gel electrophoresis was used to study the patterns of radiolabeled, fast axonally transported proteins during the first 7 days of regeneration. Interest was focused on one protein, referred to as rrp31 (regeneration-related protein 31), which changed in apparent pI from 4.9 to 5.3 when the outgrowth of new fibers started. The change was noticeable 3 days after injury and became prominent during day 5 of culturing. By day 7 the pI changed again, this time toward the original value. The in vitro results were supported by experiments in vivo. In this case the change occurred earlier, with a peak only 3 days after injury, after which the pI decreased. If adenosine at 1 mM was included in the culturing medium, the outgrowth of sensory axons was inhibited in a nontoxic way, and the pI changes of rrp31 were prevented. The temporal nature of the pI changes suggests a role for rrp31 in the initiation of the regeneration process.

Axotomy accelerates slow component b of axonal transport

Because the integrity of an axon depends on the supply of proteins synthesized in the cell body, we examined the effect of axotomy on the transport of structural proteins in rat motor axons, and the effect of altered transport on the rate of outgrowth after a subsequent testing axotomy. To examine the axonal transport of structural proteins, we labeled newly synthesized proteins with 35S-methionine 7 days after a "conditioning" lesion of the sciatic nerve, and removed the nerve 7-21 days later for SDS-PAGE. Tubulin, actin, calmodulin, and the 68-kD light neurofilament protein (NF-L) were identified by fluorography and removed for liquid scintillation counting. The fastest moving structural proteins were carried by slow component b (SCb) of axonal transport, which advanced 20% faster in conditioned axons: 4.2 versus 3.5 mm/day (p less than 0.01). NF-L was not accelerated, indicating that the motor for subcomponent a (SCa) of slow axonal transport was unaffected by axotomy. To measure outgrowth distances, the testing lesions was made 7 days after the conditioning lesion, and growth cones were located by the fast transport method 3 or 9 days later. The regression analysis of outgrowth distance on time showed that sprouts elongated 25% faster in conditioned axons: 4.0 versus 3.2 mm/day (p less than 0.001). These accelerated sprouts were formed too far from the spinal cord to contain SCb proteins that were synthesized after axotomy. Because the rate of outgrowth correlated closely with the rate of SCb in outgrowing sprouts (McQuarrie and Jacob, J. Comp. Neurol. 305:139-147, 1991), we conclude that SCb is accelerated throughout the length of the axon by 7 days after axotomy.

Effects of repetitive conditioning crush lesions on regeneration of the rat sciatic nerve

The effect of repetitive conditioning lesions was tested on regeneration of the rat sciatic nerve. The nerve was conditioned by crush lesions one, two or three times with an interval of 2 or 4 days between each successive lesion. Axonal elongation was measured 3 days after a final test crush lesion. Two conditioning lesions stimulated axonal elongation more than one, while a third conditioning lesion had no further effect on axonal outgrowth. However, if the number of conditioning lesions were varied within a constant conditioning interval, outgrowth after the test lesion was the same. This suggests that the conditioning interval and not the number of conditioning lesions determined the outgrowth after a test lesion. When the conditioning lesion(s) and the test lesion were made at the same place, outgrowth was longer than if the lesions were spatially separated. Incorporation of [3H]thymidine in the regenerated nerve segment showed that proliferation of non-neuronal cells was initiated by each lesion. By counting the number of cell nuclei this proliferation was shown to correspond to an increase of cells in the regenerating nerve. It is therefore possible that the greater number of non-neuronal cells in the distal nerve segment accounts for the enhanced conditioning lesion effect in nerves where the conditioning and test lesions are made at the same place.

The initial period of peripheral nerve regeneration and the importance of the local environment for the conditioning lesion effect

The aim of this study was to investigate the early period of neurite outgrowth in the regenerating rat sciatic nerve and to determine if the non-neuronal cells were important for the conditioning lesion effect. Regeneration distance was evaluated with the pinch-reflex test 6 h to 5 days after a test crush lesion. The regeneration velocity accelerated during approximately 3 days, whereupon outgrowth continued with a constant velocity. In unconditioned nerves the initial delay was 2.8 h and the constant rate of regeneration was 3.2 mm/day. In nerves with a distal conditioning lesion the initial delay was 2.4 h and the rate of regeneration increased by 52%. When the test crush was applied at the same place as the conditioning crush the initial delay was 1.9 h and the rate of regeneration increased by 61%. The conditioning lesion effect was not influenced by the distance between the cell body and the conditioning crush lesion. Furthermore, the conditioning lesion effect could not be expressed if conditioned axons grew into a freeze injured nerve section. Incorporation of [3H]thymidine increased in the regenerating nerve segment. The increase occurred earlier if this segment had been subjected to a conditioning crush lesion. The results of these experiments showed that peripheral neurites start to regenerate within a few hours after an injury, suggesting that growth cone formation is independent of the cell body reaction. A conditioning crush lesion increases the regeneration velocity and its acceleration, and the conditioning lesion effect cannot be expressed in the absence of living Schwann and other non-neuronal cells.

Nerve growth factor and neuronal cell death

The regulation of neuronal cell death by the neuronotrophic factor, nerve growth factor (NGF), has been described during neural development and following injury to the nervous system. Also, reduced NGF activity has been reported for the aged NGF-responsive neurons of the sympathetic nervous system and cholinergic regions of the central nervous system (CNS) in aged rodents and man. Although there is some knowledge of the molecular structure of the NGF and its receptor, less is known as to the mechanism of action of NGF. Here, a possible role for NGF in the regulation of oxidant--antioxidant balance is discussed as part of a molecular explanation for the known effects of NGF on neuronal survival during development, after injury, and in the aged CNS.

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.

Axonal transport reductions in acute experimental allergic encephalomyelitis: qualitative analysis of the optic nerve

In order to determine if changes in axonal transport were different in adult animals with acute experimental allergic encephalomyelitis (EAE), in comparison to juvenile animals with chronic EAE, the effects of this acute demyelinating disorder on axonal transport were examined in the optic nerves of adult strain-13 guinea pigs. Utilizing autoradiographic analysis of silver grain counts, both the fast and slow components of orthograde transport were studied at intervals of thirty minutes, three hours, one day and three days after tritiated leucine injection into the vitreous cavity. In order to determine the contribution of fiber loss in acute EAE, optic nerve fiber density was analyzed from electron micrographs of normal and demyelinated nerves. Animals with acute EAE had a decrease in radioactivity at the lamina retinalis and lamina choroidalis after thirty minutes and three hours, and at the lamina scleralis and foci of demyelination after one and three days. A 16% loss of fibers did not account for as much as a 74% reduction in radioactivity with acute EAE. The global reductions in axonal transport observed in acute EAE animals may contribute to their progressive deterioration and eventual demise by lack of delivery of tubulo-vesicular materials for synaptic transmission, axolemmal proteins for electrogenesis and neurofilamentary components of the cytoskeleton. Moreover, they are unlike the increase of fast axonal transport associated with recovery of physiologic function characteristic of animals with the chronic form of the disease.