Nerve growth activities in rat peripheral nerve

A comparative study of the effects of chronic axotomy, crush lesion and re-anastomosis of the rat sural nerve on horseradish peroxidase labelling of primary sensory neurons

Chronic axotomy is detrimental to the incorporation of horseradish peroxidase (HRP) by neurons of the central and peripheral nervous system. Using the rat sural nerve as a model, this study aimed to determine the effects of other types of nerve injury on the peroxidase labelling of dorsal root ganglion (DRG) cells. Compared to the decreased labelling occurring shortly after permanent transection of the sural axons at the ankle, crush injury of the nerve had no effect on the number and size distribution of peroxidase-stained cells. Re-anastomosing the sural nerve to its own distal segment or to the tibial nerve delayed the changes in HRP neuronal labelling, which subsequently were less severe in neurons allowed to reinnervate their own nerve. It also sustained the incorporation of HRP by many large DRG neurons, a function which is lost shortly after these cells are chronically axotomized. Nerve re-anastomosis also prevented the retrograde atrophy of myelinated and unmyelinated nerve fibers which is triggered by permanent transection. Based on the preservation of fiber counts in the sural nerves proximal to the site of surgery, with no evidence of degeneration, our observations possibly reflect alterations in the peroxidase metabolism of DRG neurons depending on the type of axonal injury they sustained and the possibility they had upon regeneration to contact endoneurial tubes and ultimately their original end-organs.

Immature optic nerve glia of rat do not promote axonal regeneration when transplanted into a peripheral nerve

The ability of immature central nervous system (CNS) glia to promote axonal regeneration was studied by grafting segments of embryonic and neonatal rat optic nerves into the sciatic nerves of adult rats. Unexpectedly, very few axons regenerated through these grafts. The majority of the axons bypassed the grafts and were associated with Schwann cells. These results were similar to those obtained with grafts of adult rat optic nerves. The failure of immature CNS glia to promote axonal regeneration under these conditions suggests that they may be less effective than Schwann cells in promoting the regeneration and growth of axons.

Peripheral nerve grafts lacking viable Schwann cells fail to support central nervous system axonal regeneration

Peripheral nerve grafts were implanted bilaterally into the diencephalon of adult hamsters. One graft segment contained both viable Schwann cells and their basal lamina tubes. The Schwann cell population in the second graft segment was killed by freezing prior to implantation. Seven weeks after graft implantations, the extracranial end of each graft segment was exposed, transected and labelled with a fluorescent tracer substance. One week after the labelling procedure each animal was perfused and the diencephalon and midbrain were examined. Ultrastructural analyses of both types of graft demonstrated the persistence of the Schwann cell-derived basal lamina tubes. Retrogradely labelled neurons were found in all cases in which an intact graft remained in place for two months, but were seen in only one case with a frozen graft. Large numbers of myelinated and unmyelinated axons were seen within the intact grafts, but no axons were found in the previously frozen grafts. These results indicate that lesioned CNS axons are able to regenerate vigorously when provided with an environment which includes viable Schwann cells. But, CNS axons regenerate less well, if at all, when Schwann cells are absent. Further, it appears that Schwann cell-derived basal lamina tubes, when isolated from their parent cells, are insufficient to initiate or sustain CNS axonal regeneration.

Differential regulation of mRNA encoding nerve growth factor and its receptor in rat sciatic nerve during development, degeneration, and regeneration: role of macrophages

In newborn rats the levels of nerve growth factor (NGF) mRNA (mRNANGF) and NGF receptor mRNA (mRNA(rec)) in the sciatic nerve were 10 and 120 times higher, respectively, than in adult animals. mRNA(rec) levels decreased steadily from birth, approaching adult levels by the third postnatal week, whereas mRNANGF levels decreased only after the first postnatal week, although also reaching adult levels by the third week. Transection of the adult sciatic nerve resulted in a marked biphasic increase in mRNANGF with time. On the proximal side of the cut, this increase was confined to the area immediately adjacent to the cut; peripherally, a similar biphasic increase was present in all segments. mRNA(rec) levels were also markedly elevated distal to the transection site, in agreement with previous results obtained by immunological methods [Taniuchi, M., Clark, H. B. & Johnson, E. M., Jr. (1986) Proc. Natl. Acad. Sci. USA 83, 4094-4098]. Following a crush lesion (allowing regeneration), the mRNA(rec) levels were rapidly down-regulated as the regenerating nerve fibers passed through the distal segments. Down-regulation of mRNANGF also occurred during regeneration but was slower and not as extensive as that of mRNA(rec) over the time period studied. Changes in mRNANGF and mRNA(rec) occurring in vivo after transection were compared with those observed in pieces of sciatic nerve kept in culture. No difference was found for mRNA(rec). Only the initial rapid increase in mRNANGF occurred in culture, but the in vivo situation could be mimicked by the addition of activated macrophages. This reflects the situation in vivo where, after nerve lesion, macrophages infiltrate the area of the Wallerian degeneration. These results suggest that mRNANGF synthesis in sciatic non-neuronal cells is regulated by macrophages, whereas mRNA(rec) synthesis is determined by axonal contact.

Endogenous chicken nerve growth factor from sheath cells is transported in regenerating nerve

We report the presence of endogenous nerve growth factor (NGF) in chicken peripheral nerve. The molecule has been detected with antibodies to mouse salivary gland NGF, using immunohistochemical and immunoelectrophoretic techniques. Previous studies have shown that these antibodies inhibit the survival activity of extracts of chicken peripheral nerve. The NGF accumulated distal, but not proximal, to a ligature placed on a peripheral sympathetic nerve demonstrating that it was retrogradely transported. This transport was detected in intact nerve fibers as well as in nerves from which the peripheral target had been ablated 6 hr or 7 days previously. The results indicate that avian NGF is present in adult chicken peripheral nerves and that this molecule shares antigenic determinants with the mouse molecule. The results further demonstrate that regenerating neurons retrogradely transport NGF supplied by cells within the peripheral nerve (presumably Schwann). The possibility that these cells also provide NGF to intact neurons is discussed.

Substrate-bound nerve growth factor promotes neurite growth in peripheral nerve

Nerve growth factor (NGF), in addition to its well-known effects as a soluble neurite growth-promoting factor, also appears to promote the elongation of neurites when it is adsorbed to tissue culture substrates. Peripheral nerve Schwann cells appear to possess a receptor for NGF on their surfaces which is induced substantially after axotomy. We have found that the adsorption of NGF onto cryostat sections of the distal stump of previously severed sciatic nerve enhances neurite growth over this tissue. This finding, coupled with the two previous observations, suggests that Schwann cell surface NGF receptors serve to bind to NGF-like growth factors so as to provide favorable surfaces for regenerating peripheral nerve axons.

Identification of a peripheral nerve neurite growth-promoting activity by development and use of an in vitro bioassay

The effective regeneration of severed neuronal axons in the peripheral nerves of adult mammals may be explained by the presence of molecules in situ that promote the effective elongation of neurites. The absence of such molecules in the central nervous system of these animals may underlie the relative inability of axons to regenerate in this tissue after injury. In an effort to identify neurite growth-promoting molecules in tissues that support effective axonal regeneration, we have developed an in vitro bioassay that is sensitive to substrate-bound factors of peripheral nerve that influence the growth of neurites. In this assay, neonatal rat superior cervical ganglion explants are placed on longitudinal cryostat sections of fresh-frozen sciatic nerve, and the regrowing axons are visualized by catecholamine histofluorescence. Axons are found to regenerate effectively over sciatic nerve tissue sections. When ganglia are similarly explanted onto cryostat sections of adult rat central nervous system tissue, however, axonal regeneration is virtually absent. We have begun to identify the molecules in peripheral nerve that promote effective axonal regeneration by examining the effect of antibodies that interfere with the activity of previously described neurite growth-promoting factors. Axonal elongation over sciatic nerve tissue was found to be sensitive to the inhibitory effects of INO (for inhibitor of neurite outgrowth), a monoclonal antibody that recognizes and inhibits a neurite growth-promoting activity from PC-12 cell-conditioned medium. The INO antigen appears to be a molecular complex of laminin and heparan sulfate proteoglycan. In contrast, a rabbit antiserum that recognizes laminin purified from mouse Engelbreth-Holm-Swarm (EHS) sarcoma, stains the Schwann cell basal lamina of peripheral nerve, and inhibits neurite growth over purified laminin substrata has no detectable effect on the rate of axonal regeneration in our assay.

Examination of a nerve injury-induced, 37 kDa protein: purification and characterization

Following traumatic injury to the adult rat sciatic nerve the synthesis and accumulation of soluble, extra-cellular, 37 kDa protein is increased. This protein, which accumulates in the extracellular space of the injured nerve, accounts for nearly 5% of the total soluble pool of protein in an injured nerve 3 weeks after injury. 8 weeks after injury, when regeneration is nearly complete, this accumulated pool returns to control levels, yet if regeneration is blocked synthesis of the 37 kDa protein remains high. Recently this 37 kDa protein has been shown to be nearly identical to apolipoprotein E, the protein component of various lipoprotein particles. This finding suggests a role for the 37 kDa protein in cholesterol and lipid transport and metabolism during nerve repair within the nervous system, functions that have been ascribed to apo E in serum. Results are presented here describing the purification of the nerve injury induced 37 kDa protein and the subsequent production of specific rabbit antisera directed against it. By centrifugation analysis in a sucrose gradient, a native mass of 37 kDa was determined, revealing the 37 kDa protein's monomeric, native structure. Additionally injections of [35S]methionine directly into the injured nerve allowed 1) a comparison of 37 kDa synthesis in vivo versus in vitro and 2) an examination of the presence or absence of retrogradely transported 37 kDa protein. The in vitro and in vivo collected material were found to share identical 2-dimensional electrophoretic mobilities, and no appreciable amount of transported 37 kDa protein was found in proximal regions of the injured nerve.

Axonal transport of neuroreceptors: possible involvement in long-term memory

Evidence is presented that neuroreceptors move bidirectionally along axons of neurons through fast axoplasmic transport mechanisms. The retrograde transport of receptor-bound signal molecules from nerve terminals to the perikaryon represents a corridor of information between synapses and the cell body of neurons. It is speculated that this process could be involved in long-term memory.

Peripheral nerve implant effects on survival of retinal ganglion layer cells after axotomy initiated by a penetrating lesion

A lesion paradigm involving a small penetrating incision made through the sclera, choroid and retina of the adult rat eye creates a unique environment for the study of the damaged retina. More specifically, the dependable formation of a small focal retinal lesion makes this an ideal model for the determination of conditions that may stimulate retinal regeneration, wound repair and/or cell survival. Our previous studies have indicated that the placement of a desheathed peripheral nerve implant (PNI) into the lesioned adult rat eye: (1) initiated the rescue of retinal tissue that would normally die due to trauma; and (2) maintained the thickness and organization of most retinal layers adjacent to the lesion site, particularly the retinal ganglion cell layer (RGL). We report in the present work that a more detailed analysis of the RGL revealed a significant increase in the survival of axotomized neurons within this layer in the presence of a PNI over an 8-week post-implantation period. More specifically, there was a 60% loss of control RGL cells axotomized by the lesion 3 weeks previously in contrast to only a 30% loss in those tissues exposed to a PNI. Additional RGL cell size distribution studies point to the fact that the PNI appeared to affect the increased survival of cells greater than or equal to 70 micron2. Also the PNI effect demonstrated a specificity of response when tested against the influence of a tendon or suture implant.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence that endogenous beta nerve growth factor is responsible for the collateral sprouting, but not the regeneration, of nociceptive axons in adult rats

A key role has not yet been identified for beta nerve growth factor (NGF) in the growth responses that continue to be expressed in the sensory neurons of adult animals. We have now examined the effects of daily administration to adult rats (and in a few experiments, mice) of antiserum to NGF on (i) the collateral sprouting of undamaged nociceptive nerves that occurs into denervated adjacent skin and (ii) the regeneration of cutaneous sensory axons that occurs after they are damaged. The results were unexpected. All collateral sprouting was prevented and that already in progress was halted; sprouting resumed when treatment was discontinued. In contrast, the reestablishment, and even enlargement, of cutaneous nerve fields by regenerating axons was unaffected by anti-NGF treatment, even after dorsal rhizotomy was done to eliminate any central trophic support. In denervated skin, regenerating and collaterally sprouting axons utilized the same cellular pathways to establish functionally identical fields, thus displaying apparently identical growth behaviors, yet anti-NGF treatment clearly distinguished between them. We suggest that endogenous NGF is responsible for the collateral sprouting of nociceptive axons, probably reflecting an ongoing function of NGF in the regulation of their fields. This demonstration in the adult sensory system of a defined role for NGF in nerve growth could apply to nerve growth factors generally in the adult nervous system. The regeneration, however, of nociceptive axons (and nonnociceptive one) is not dependent on NGF.

Selective reinnervation of distal motor stumps by peripheral motor axons

Random matching of regenerating axons with Schwann tubes in the distal nerve stump is thought to contribute to the often poor results of peripheral nerve repair. Motor axons would be led to sensory end organs and sensory axons to motor end plates; both would remain functionless. However, the ability of regenerating axons to differentiate between sensory and motor environments has not been adequately examined. The experiments reported here evaluated the behavior of regenerating motor axons when given equal access to distal sensory and motor nerve stumps across an unstructured gap. "Y"-shape silicon chambers were implanted within the rat femoral nerve with the proximal motor branch as axon source in the base of the Y. The distal sensory and motor branches served as targets in the branches of the Y, and were placed 2 or 5 mm from the axon source. After 2 months for axon regeneration, horseradish peroxidase was used to label the motoneurons projecting axons into either the motor or the sensory stump. Equal numbers of motoneurons were labeled from the sensory and motor stumps at 2 mm, but significantly more motoneurons were labeled from the motor stump at 5 mm. (P = 0.016). This finding is consistent with selective reinnervation of the motor stump. Augmentation of this phenomenon to produce specific reunion of individual motor axons could dramatically improve the results of nerve suture.

Cyclophosphamide treatment used to manipulate the immune response for the production of monoclonal antibodies

After immunization with a complex mixture of antigens, a considerable bias toward obtaining monoclonal antibodies to immunodominant determinants exists. By selectively killing antigen-stimulated lymphocytes, the cytotoxic drug cyclophosphamide can be used to manipulate the bias of the normal immune response. Cyclophosphamide has been used to tolerize mice to one set of antigens followed by immunization with a similar but slightly different set of antigens. This approach yields an enhanced frequency of antibodies that distinguish the two sets of antigens. Cyclophosphamide treatment has also allowed us to produce monoclonal antibodies to weakly immunogenic glycosaminoglycans and to obtain a high frequency of apparently anti-idiotypic antibodies.

Transport of endogenous nerve growth factor in the proximal stump of sectioned nerves

Immunohistochemistry has been used to demonstrate the presence of nerve growth factor (NGF)-like immunoreactivity in normal and sectioned mouse sciatic nerves. In normal nerves, immunoreactive material was not visible unless a silk ligature had previously been applied to constrict the nerves, and only then in the segment of nerve immediately distal to the ligation. Immunoreactivity was visible as early as 2 h after application of the ligature. When nerves were sectioned prior to ligation to prevent the transport of material from nerve terminals within innervated tissues, the NGF-like immunoreactivity continued to accumulate. This accumulation also occurred when a portion of the proximal stump from sectioned nerves was removed from the animal and placed in culture. Quantitative estimate of NGF concentrations with a sensitive immunoassay showed that the amount of NGF present within a segment of the proximal stump of sectioned nerves more than doubled in a 24 h period. The findings indicate that NGF is produced by cells within sectioned nerves, and further suggest that in the normal intact nerve at least a proportion of the NGF being transported derives from these cells.

Changes of nerve growth factor synthesis in nonneuronal cells in response to sciatic nerve transection

The intact sciatic nerve contains levels of nerve growth factor (NGF) that are comparable to those of densely innervated peripheral target tissues of NGF-responsive (sympathetic and sensory) neurons. There, the high NGF levels are reflected by correspondingly high mRNANGF levels. In the intact sciatic nerve, mRNANGF levels were very low, thus indicating that the contribution of locally synthesized NGF by nonneuronal cells is small. However, after transection an increase of up to 15-fold in mRNANGF was measured in 4-mm segments collected both proximally and distally to the transection site. Distally to the transection site, augmented mRNANGF levels occurred in all three 4-mm segments from 6 h to 2 wk after transection, the longest time period investigated. The augmented local NGF synthesis after transection was accompanied by a reexpression of NGF receptors by Schwann cells (NGF receptors normally disappear shortly after birth). Proximal to the transection site, the augmented NGF synthesis was restricted to the very end of the nerve stump that acts as a "substitute target organ" for the regenerating NGF-responsive nerve fibers. While the mRNANGF levels in the nerve stump correspond to those of a densely innervated peripheral organ, the volume is too small to fully replace the lacking supply from the periphery. This is reflected by the fact that in the more proximal part of the transected sciatic nerve, where mRNANGF remained unchanged, the NGF levels reached only 40% of control values. In situ hybridization experiments demonstrated that after transection all nonneuronal cells express mRNANGF and not only those ensheathing the nerve fibers of NGF-responsive neurons.

Lipoprotein uptake by neuronal growth cones in vitro

Macrophages that rapidly enter injured peripheral nerve synthesize and secrete large quantities of apolipoprotein E. This protein may be involved in the redistribution of lipid, including cholesterol released during degeneration, to the regenerating axons. To test this postulate, apolipoprotein E-associated lipid particles released from segments of injured rat sciatic nerve and apolipoprotein E-containing lipoproteins from plasma were used to determine whether sprouting neurites, specifically their growth cones, possessed lipoprotein receptors. Pheochromocytoma (PC12) cells, which can be stimulated to produce neurites in vitro, were used as a model system. Apolipoprotein E-containing lipid particles and lipoproteins, which had been labeled with fluorescent dye, were internalized by the neurites and their growth cones; the unmetabolized dye appeared to be localized to the lysosomes. The rapid rate of accumulation in the growth cones precludes the possibility of orthograde transport of the fluorescent particles from the PC12 cell bodies. Thus, receptor-mediated lipoprotein uptake is performed by the apolipoprotein B,E(LDL) (low density lipoprotein) receptors, and in the regenerating peripheral nerve apolipoprotein E may deliver lipids to the neurites and their growth cones for membrane biosynthesis.

Neuronal growth factors from tumours of Von Recklinghausen neurofibromatosis

Explants of 21 neurofibromas from 16 patients with Von Recklinghausen neurofibromatosis (NF-I) plus tumour tissue from 5 comparison patients and normal tissue from one of the NF-I patients were assayed for neuronal growth factor(s) using dissociated embryonic sensory neurons from chick embryo. Twenty-one of 21 neurofibroma explants released detectable quantities of neuronal growth factors, but only 2 of 8 non-neurofibroma tissue explants released activity. While antiserum to mouse nerve growth factor (NGF) fractionally inhibited neurite outgrowth induced by some of the neurofibromas, overall differences between assays containing antibody and controls reached statistical significance in 3 cases; in one case, explants of a separate tumour from the same patient had no detectable NGF-like activity. These data support the hypothesis that local release of neuronal growth factors in neurofibromas are responsible for neurites observed within these tumours. Further evidence that endoneurial tissue of peripheral nerve is a rich source of heterogeneous neuronal growth facts has been provided by these studies.

Glial patterns during early development of antennal lobes of Manduca sexta: a comparison between normal lobes and lobes deprived of antennal axons

The synaptic neuropil of the olfactory (antennal) lobe of the moth Manduca sexta is subdivided into histologically conspicuous structures called glomeruli that are typical of olfactory systems in vertebrates and invertebrates. Each glomerulus consists of the highly branched neuritic arbors of both primary olfactory axons and antennal-lobe neurons, bounded by a nearly complete envelope of glial cells. We have studied events occurring during the first half of metamorphic adult development. The first signs of organization of the neuropil into glomeruli are changes in glial cells. Prior to the ingrowth of olfactory axons from the antenna, glial cells form a continuous border around the neuropil. When olfactory axons begin to reach the lobe, glial cells embark on a stereotyped series of changes: the border becomes disrupted, glial cells begin to proliferate and extend processes into the outer regions of the neuropil, and some glial cells migrate toward the center of the neuropil. Shortly thereafter, glomeruli emerge from the neuropil, delineated by glial cells. If, however, afferent axons are prevented from ever reaching the antennal lobe, glomeruli never develop and the glial cells remain almost entirely restricted to a thick layer bordering the neuropil. Thus sensory axons have a direct influence not only on neuronal but also on glial differentiation. Our results lead us to suggest that the glial cells may be in a position to act as intermediaries in developmental interactions between sensory axons and antennal-lobe neurons.

Rat astrocytes and Schwann cells in culture synthesize nerve growth factor-like neurite-promoting factors

Neurite-promoting activity in feeding medium conditioned by rat astrocytes and Schwann cells in culture was examined. The conditioned medium (CM) from both types of glial cultures stimulated extensive neurite outgrowth from embryonic chick dorsal root ganglia (DRG) as well as pheochromocytoma (PC12) cells. Both the DRG and PC12 cells also produce neurite outgrowth in the presence of nerve growth factor (NGF). With the DRG, the neurite growth rates observed with the glial cell CM were identical to growth rates seen with NGF. Although anti-NGF antibody did not inhibit the neurite outgrowth produced by either of the glial CM, a nerve growth factor radioreceptor assay did detect an NGF-like molecule in both CM. Since the extensive neurite outgrowth stimulated by the glial CM was not mimicked by pure laminin alone, we conclude that the glial neurite promoting factors are distinct from laminin.

Sympathetic neuronotrophic activity in the pulp of the cat canine tooth

Extracts of these dental pulps from adult cats contained a non-dialysable agent or agents which could support neurone survival and neurite development for at least three days in neurone-enriched cultures of sympathetic ganglion cells from 11-day chick embryos. The neurone survival-promoting activity differed from nerve growth factor (NGF) in that: (1) anti-mouse NGF serum did not inhibit it; (2) nearly all ganglionic neurones survived in optimum concentrations of pulp extract, whereas only about 35 per cent were supported by NGF; and (3) cell bodies of NGF-supported neurones were markedly larger than in neurones supported by pulp extracts. The neuronotrophic activity in individual dental pulps was highly variable among different cats, but similar between mandibular canines from the same animal. Smaller pulps had higher concentrations of trophic activity than larger ones. Gingival tissue and the anterior belly of the disgastric muscle contained little neuronotrophic activity.

Neuron-enriched cultures of adult rat dorsal root ganglia: establishment, characterization, survival, and neuropeptide expression in response to trophic factors

It is unknown whether adult dorsal root ganglion (DRG) neurons require trophic factors for their survival and maintenance of neuropeptide phenotypes. We have established and characterized neuron-enriched cultures of adult rat DRGs and investigated their responses to nerve growth factor (NGF), ciliary neuronotrophic factor (CNTF), pig brain extract (PBE, crude fraction of brain-derived neuronotrophic factor, BDNF), and laminin (LN). DRGs were dissected from levels C1 through L6 and dissociated and freed from myelin fragments and most satellite (S-100-immunoreactive) cells by centrifugation on Percoll and preplating. The enriched neurons, characterized by their morphology and immunoreactivity for neuron-specific enolase, constituted a population representative of the in vivo situation with regard to expression of substance P (SP), somatostatin (SOM), and cholecystokinin-8 (CCK) immunoreactivities. In the absence of trophic factors and using polyornithine (PORN) as a substratum, 60-70% of the neurons present initially (0.5 days) had died after 7 days. LN as a substratum did not prevent a 30% loss of neurons up to day 4.5, but it subsequently maintained DRG neurons at a plateau. This behavior might reflect a cotrophic effect of LN and factors provided by non-neuronal cells, whose proliferation between 4.5 and 7 days could not be prevented by addition of mitotic inhibitors of gamma-irradiation. CNTF, but not NGF, slightly enhanced survival at 7 days on either PORN or LN. No neuronal losses were found in non-enriched cultures or when enriched neurons were supplemented with PBE, indicating that non-neuronal cells and PBE provide factor(s) essential for adult DRG neuron survival. Proportions of SP-, SOM-, and CCK-immunoreactive cells were unaltered under any experimental condition, with the exception of a numerical decline in SP cells in 7-day cultures with LN, but not PORN, as the substratum. Our data, considered in the context of recent in vivo and vitro studies, suggest that a combination of trophic factors or an unidentified factor, rather than the established molecules NGF, CNTF, and BDNF, which address embryonic and neonatal DRG neurons, are required for the in vitro maintenance of adult DRG neurons.

Neuronal growth factors produced by adult peripheral nerve after injury

Dorsal root ganglion neurons from embryonic rats, co-cultured with endoneurial explants from transected, adult rat sciatic nerve, extended neurites in the absence of exogenous nerve growth factor (NGF). The effect was seen with endoneurial explants from normal adult sciatic nerves or from nerves which had been permanently transected up to 51 days prior to explantation. The rate of outgrowth decreased at 5 and 7 days and reached a minimum at 14 days after transection. A second phase of increased neurite-promoting activity appeared in 28-, 35-, 41- and 51-day posttransection tissue. The early phase, but not the late phase, was partially inhibited by antisera to NGF.

The induction of a regenerative propensity in sensory neurons following peripheral axonal injury

Injury of the peripheral axons of primary sensory neurons has been previously shown to increase the probability that the corresponding central axons would grow from the injured spinal cord into a peripheral nerve graft. This phenomenon has been used to investigate the nature of extrinsic cues from injured nerves that enhanced regenerative propensity within sensory neurons. In 13 groups of rats, a segment of the right sciatic nerve was grafted to the dorsal columns of the spinal cord and the left sciatic nerve was subjected to mechanical injury, injection of colchicine or infusion of nerve growth factor. Subsequently, neurons in lumbar dorsal root ganglia with axons growing from the spinal cord into a graft were identified by retrograde perikaryal labelling and compared for the two sides. The aim was to mimic or modify the inductive effect of nerve transaction by alternative or additional manipulation of the nerve. Growth of central axons was less enhanced by peripheral axonal interruption if the length of the proximal stump was increased or if a distal stump was present to permit rapid regeneration. However, the regenerative response following nerve transection was altered little by crushing the proximal stump or injecting it with colchicine or nerve growth factor. It is suggested that sensory neurons are stimulated to regenerate by peripheral axonal injuries that reduce some normal retrograde regulatory influence of Schwann cells.

Accurate reinnervation of motor end plates after disruption of sheath cells and muscle fibers

After injury, regenerating motor axons grow back to form neuromuscular junctions at the original synaptic sites on muscle fibers. The pathways they grow along consist of basement membrane, Schwann cells, and perineurium that remained after degeneration of the original axons. All the factors necessary for directing axons to the original synaptic sites persist in muscles even after disruption of myofibers. The aim of the present experiments was to determine whether structural integrity of nerve sheath cells is required for precise reinnervation in the presence and absence of muscle fiber targets. The region of innervation of the cutaneous pectoris muscle of the frog was briefly frozen to eliminate all living cells from neuromuscular junctions, intramuscular nerve bundles, and from a 1-3-mm length of the nerve trunk. Only extracellular matrices persisted within the frozen region of muscle and nerve. These consisted of the basement membrane sheaths of myofibers, of Schwann cells, and of perineurial cells and the small fragments of disrupted cells that were bound to them. In some preparations new muscle fibers developed within the basement membrane sheaths. Regenerating axons grew through the naked basement membrane sheaths of original Schwann cells, formed numerous branches, and contacted the myofibers precisely at the original synaptic sites. By 5 weeks 75% of the original synaptic sites became reinnervated; the terminals were indistinguishable from those at normal neuromuscular junctions. In contrast, preparations in which all muscle fibers were prevented from regenerating far fewer synaptic sites became reinnervated.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects on the growth of damaged ganglion cell axons after peripheral nerve transplantation in adult hamsters

After transplantation of autologous sciatic nerve segments into the retina of adult hamsters for 1-2 months, retrograde labelling with horseradish peroxidase demonstrated a population of ganglion cells situated peripheral to the graft. If an additional lesion was placed between the insertion of the graft and the optic disc at the same time as transplantation, in addition to labelled cells situated peripheral to the graft, retrograde labelling with horseradish peroxidase demonstrated a population of labelled neurons located between the graft and the optic disc which was not observed in animals without the additional lesion. Since the axons of this population of cells would have to turn around away from their normal course towards the optic disc and travel for about 1.5 mm in order to grow into the graft, it suggests that the peripheral nerve graft might play an active role in attracting and/or guiding damaged ganglion cell axons to grow into it.

Induction of a neurite-promoting factor in rat brain following injury or deafferentation

Ablation of the entorhinal/occipital cortex in young adult rats caused a several-fold increase in the neurite-promoting activity in extracts of the tissue surrounding the wound and in areas that had been deafferented by the lesion. The time course of induction closely paralleled reactive axon sprouting in the deafferented hippocampus, with maximal levels of neurite-promoting activity reached between 9 and 15 days post-lesion. Aged animals, in which reactive sprouting is deficient, showed no increase in activity by 12 days after deafferentation of the hippocampus. The neurite-promoting activity of brain extracts was non-diffusible, heat-labile, and sensitive to proteolysis. All of the activity bound to diethylaminoethyl (cellulose) and was eluted at 200 mM NaCl. The apparent molecular weight (by gel filtration) of the activity in extracts of uninjured brain was 9-17 kilodaltons, whereas the extracts of injured brain also had peaks or shoulders at 30, 70 and greater than or equal to 200 kilodaltons. These data suggest that the brain neurite-promoting activity resides in one or more proteins. Both the injury-induced and basal activities were different from laminin, nerve growth factor, and polyornithine-bindable neurite-promoting factors. The injury-induced activity was sensitive to repeated freezing and thawing, but this inactivation was reversed by thiol reagents such as glutathione, thioglycerol, and mercaptoethanol. We report a neurite-promoting factor that is induced following brain injury or denervation, and may also be important for reactive axon sprouting after brain injury. The induction of this factor is abnormal in aged animals, as is the reactive sprouting response. The properties of the injury-induced activity distinguish it from the basal activity (found in uninjured brain) and from other characterized neurite-promoting factors.

Isolated satellite cells of a peripheral nerve direct the growth of regenerating frog axons

Frog motor axons regenerate and grow back to reinnervate their targets, the original motor end plates, after a lesion. When the cutaneous pectoris muscle is cut away and a segment of peripheral nerve is placed in the vicinity of regenerating axons they turn and grow toward it. This is in marked contrast to the random pattern of axonal outgrowth seen in the absence of a target. The influence on the direction of axonal growth of motor neurons can be produced by a 1-mm segment of nerve satellite cells over a distance of more than 8 mm. The nerve satellite cells have no influence on the direction of growth of the regenerating axons after all the cells in the nerve segment have been killed, leaving only the Schwann cell basal lamina tubes intact. These results show that the cells in the segment of the nerve trunk contain cues that actively direct the growth of motor neurons. Two possible explanations for this effect might be that the cells act indirectly by influencing the organization of the substructure over which axons regenerate or that the nerve satellite cells release a diffusible substance that acts directly on the regenerating axons.

Peripheral nerve implantation into a penetrating lesion of the eye: stimulation of the damaged retina

A small penetrating incision made through the sclera, choroid and retina of the adult rat eye creates a unique lesion paradigm. More specifically, by one to two weeks after the incision the wound area stabilizes, leaving a clean inflammation-free degeneration gap or 'die-back zone' (200-300 microns wide) between the cut edges of the intact retina. The dependable formation of a small focal retinal lesion makes this an ideal model for the determination of conditions that may stimulate retinal regeneration, wound repair and/or cell survival. In other words, material may be injected or placed into the lesion site and the retina analyzed for responses to such treatments. Accordingly, the placement of a desheathed peripheral nerve implant (PNI) into the lesioned adult rat eye initiated the rescue of retinal tissue that would normally die due to trauma. In addition, the cut edges of the retina just lateral to the PNI actually touched and fused together, thus demonstrating a wound closure or healing phenomenon which was not observed in control situations. Also the thickness and organization of most retinal layers at the site of lesion were maintained at intact control levels in the presence of the PNI. However, controls not containing the PNI exhibited dramatic reductions in total and individual retinal layer thickness for up to approximately 500 microns lateral to the lesion site. Through the use of a double lesion paradigm, it was also determined that the wound repair phenomena could be influenced over a distance by (a) putative diffusable factor(s) elaborated or initiated by the PNI.

Production and transport of endogenous trophic activity in a peripheral nerve following target removal

High concentrations of trophic factor for sympathetic neurones were found in the discrete nerve which innervates the expansor secundariorum muscle of the chicken wing. Mouse nerve growth factor (NGF) was additive with nerve extract in allowing survival of sympathetic neurones. Antiserum to NGF, while inhibiting outgrowth in response to NGF, only partially blocked survival promoted by the nerve extract. In these characteristics, the nerve extract resembled the previously characterized activity of its target organ. However, after surgical removal of the muscle there was no decrease in the concentration of trophic factors in the nerve 7 days later. Likewise sectioning, crushing or removing a piece of nerve 1 cm from the muscle had little effect on trophic levels after muscle removal. Retrograde transport of the activity occurred in the nerve even in the absence of the muscle. Distal to ligatures placed on the nerve stump 24 h earlier, 60% of the trophic activity was inhibited by an antiserum to mouse NGF suggesting that a chicken form of the molecule is present and transported. In culture, cells of the nerve sheath produced trophic factors, and the rate of production increased greatly during the first 24 h of incubation. Two conclusions are made: the major source of trophic activity in the nerve is Schwann cells and at least two molecules are present, one of which is a chicken form of NGF.

Neurotrophic activity in the central and peripheral nervous systems of the cat. Effects of injury

Neurotrophic activity for ciliary ganglion neurons in culture was found in both central and peripheral nervous system of the cat. The activity found in extracts of spinal cord supported the survival of 100% of the test neurons during 24 h and was characterized by a slope of -56 +/- 13 in the linear portion of the dose-response curve. Sciatic nerve extract supported the survival of only 60% of the test neurons; it dose-response curve had a slope of -20 +/- 4. Extracts of meninges, spinal rootlets, dorsal root ganglia and muscle supported 100% of the test neurons; two slopes were observed in their dose-response curves, which coincided with those of spinal cord and sciatic nerve dose-response curves. The two different slopes may correspond to two different active molecules, tentatively denominated I and II, having distinct distributions in the assayed tissues. In the spinal cord, both direct injury and deafferentation led to increases in neurotropic activity. In the peripheral nervous system, transections leading to death of dorsal root ganglion neurons or to degeneration of their axons were accompanied by decreases in activity II. Activity I in dorsal roots and dorsal root ganglia was unaffected by injury and may be associated with non-neuronal cells or extracellular matrix components.

Nerve growth factor immunohistochemistry and biological activity in the rat iris

Nerve growth factor (NGF) production in the cultured rat iris was examined using immunohistochemistry and bioassay of irides and conditioned media. NGF immunoreactivity increased steadily with days in culture so that the intensity of staining was maximal after 6 days of culture. The localization was shown to be sensitive to the presence of cross-linking fixatives such as formaldehyde and glutaraldehyde and this effect was only partially alleviated by the use of very high concentrations of antibodies. NGF immunoreactivity was localized in Schwann cells and possibly nerve axons, but with no antigen detectable in smooth muscle fibres. Media conditioned over irides initially supported a high percentage of dissociated sympathetic neurons, but the number supported decreased with time in culture until day 4. Moreover, the use of antibodies to NGF allowed the detection of at least two types of neuronotropic activity, NGF accounting for at least 94% of the total trophic activity present after 4 days of culture. These findings provide support for the proposal that Schwann cells produce NGF and question the accepted hypothesis that the molecule is produced by smooth muscle fibres as a peripheral maintenance factor for sympathetic and sensory nerves. The results also suggest that two survival factors may be involved in the regulation of sympathetic function.

Identification and quantification of mRNA for nerve growth factor in histological preparations

Hybridization histochemistry has been used to detect mRNA for nerve growth factor (NGF) in histological preparations of mouse salivary glands and rat iris using a 32P-labelled cDNA probe and autoradiography. Label was visible over the tubular cells of the male mouse submaxillary gland but not the sublingual gland. A much lower label density was found over the tubular cells of the female submaxillary gland, whereas sections of liver and pancreas were negative. Quantitative autoradiography allowed the detection of low levels of mRNA for NGF in the rat iris which was elevated by prior culture of the tissue. The results provide direct histological evidence for the presence of specific NGF-mRNA in the mouse submaxillary gland and rat iris, with increased levels following culture.

Expression of specific sheath cell proteins during peripheral nerve growth and regeneration in mammals

Protein synthesis in the nerve sheath of injured as well as intact mature and developing sciatic nerves from rat and rabbit was investigated by incubating segments of nerve with [35S]methionine in vitro. The composition of labeled proteins under the different conditions of nerve growth was analyzed by two-dimensional gel electrophoresis and fluorography. The expression of six secreted proteins in rat sciatic nerve with the apparent molecular weights of 70,000 (70 kD), 54,000 (54 kD), 51,000 (51 kD), 39,000 (39 kD), 37,000 (37 kD), and 30,000 (30 kD) was of particular interest because of the correlation of their synthesis and secretion with aspects of nerve growth and regeneration. The synthesis of the 37-kD protein was significantly stimulated during both sciatic nerve development as well as regeneration but not in the intact mature nerve. The expression of this protein appears to be regulated by signal(s) from the axon but not the target. The 70-kD protein was exclusively synthesized in response to axotomy, thus confining its role to some aspect(s) of nerve repair. In contrast, the 54- and 51-kD proteins were expressed in the intact mature nerve sheath. Their synthesis and release was rapidly inhibited upon axotomy but returned to normal or higher levels towards the end of sciatic nerve regeneration, suggesting a role in the maintenance of the integrity of the mature (nongrowing) rat nerve. The 39- and 30-kD proteins were only transiently synthesized within the first week after axotomy. Two proteins with the apparent molecular masses of 70 and 37 kD were synthesized in denervated rabbit sciatic nerve. The similar molecular weights, net charges, and time-courses of induction suggest a homology between these proteins in rabbit and rat, indicating common molecular responses of peripheral nerve sheath cells to axon injury in both mammalian species.

Unmyelinated axons in a muscle nerve. Electron microscopic morphometry of the sternomastoid nerve in normal and sympathectomized rats

In continuation of earlier studies on the innervation of the sternomastoid muscle of the rat, a detailed morphometric analysis was performed on the unmyelinated axons of the nerve, in normal rats and after extensive cervical sympathectomy. In 4 normal rats an average of 314 myelinated and 319 unmyelinated axons were present. 42 days after surgery, the 3 animals showed Horner's syndrome and a highly significant 40% loss of unmyelinated axons. We therefore suggest that 40% of the C-fibers in this nerve are postganglionic sympathetic efferents and that the remaining 60% are type IV fibers, i.e., unmyelinated afferents. Our counts also indicate that part of the Remak bundles of the Schwann cells contain only sympathetic axons, whereas others contain mixed groups of sympathetic and afferent axons. Myelinated nerve fibers were not lost due to sympathectomy. Unexpectedly, the 3 animals analyzed 7-13 days after surgery showed Horner's syndrome but only a 16% loss of unmyelinated axons, which was not even statistically significant. Morphological signs of degeneration and sprouting did not provide any clue, but a possible explanation would be that a transitory sprouting of the remaining afferent C-fibers or Schwann cells occurred.

Increase in neuronotrophic activity during the period of smooth muscle innervation

The expansor secundariorum is a unique smooth muscle of the avian wing that receives a dense sympathetic innervation and contains high concentrations of survival factors for sympathetic neurons. In the present study it has been possible to simultaneously examine the appearance of the neuronotrophic activity and the arrival of nerve fibres during the period of innervation. The results show that catecholamine containing nerve fibres can first be detected within the muscle on the fourteenth day of incubation (stage 40) followed by a rapid increase in the density of fibres during the next few days until the adult pattern is reached shortly before hatch. Biochemical estimation of the innervation process by measurement of dopamine beta-hydroxylase activity was supported by the histochemical findings. Estimation of neuronotrophic activity revealed that muscle from stage 40 embryos contains only low levels of activity which increases rapidly as innervation proceeds and further, that this increase in neuronotrophic activity was directly correlated with the dopamine beta-hydroxylase activities. Possible mechanisms regulating this dramatic increase in the specific activity of trophic factors are discussed.

Regulation of sympathetic trophic factors in smooth muscle

The level and nature of trophic activity present in the chicken expansor secundariorum muscle has been shown to be altered by denervation. This muscle receives a dense, sympathetic innervation and contains high concentrations of trophic factors, which were found to be immunologically and functionally distinct from mouse Nerve Growth Factor. In young birds, denervation increased the number of neurons which could be supported by muscle extract. This difference was apparent with regard to E8 to E16 sympathetic neurons. Innervated but not denervated extract was additive with NGF in promoting neurite outgrowth. In contrast, when extracts of denervated and innervated muscle from mature birds were examined, no difference was seen in the number of neurons supported by each extract. However when the denervated and innervated extracts from mature birds were combined more neurons were supported than by a saturating dose of either extract alone. Furthermore, muscle from mature birds responded to denervation only between 2 and 9 days, whereas in young birds the effect was apparent for at least 3 weeks. Analysis of intact, control muscles during the first 8 weeks posthatch demonstrated that the number of neurons that could be supported by the individual extracts varied with the age of the bird. It is concluded that denervation does not in all instances lead to an increase in trophic activity, but does produce a change in the nature of the activity present, such that a different neuronal subpopulation may be supported.(ABSTRACT TRUNCATED AT 250 WORDS)

Parasympathetic neurotrophic activity in the rat iris: determination after different denervations

The iris of the adult rat contains one or several neurotrophic factors that enhance the survival of dissociated parasympathetic neurons (from the embryonic chick ciliary ganglion) in culture. To assay survival activity, iris homogenates were serially diluted with culture medium and the percentage of neurons surviving for 2 days in a collagen matrix in culture determined. The extract induced survival curves that were similar for denervated and normal irides. Similarly no differences in fibre outgrowth from cultured whole ciliary ganglia were found. The results suggest that the apparent level of parasympathetic growth factor(s) is not under strict control of the innervation of the iris.

NGF-dependent and -independent growth of neurites from sympathetic ganglion cells of the aged human in a serum-free culture

Small pieces of tissue isolated from abdominal sympathetic ganglia in aged male patients were cultured in a chemically defined, serum-free medium. The growth of neurites from pieces of ganglia in cultures with and without 50 ng/ml mouse 2.5S nerve growth factor (NGF) was compared. The NGF stimulated significantly greater regeneration of neurites, causing the growth of long fibers from the ganglion pieces. Many short neurites grew, even in the absence of the NGF, but these were generally short, except for long neurites generated in several nerve cells. A method was devised for the evaluation of NGF-dependent growth of neurites in the culture. The rate of the NGF-dependent growth of neurites, which was calculated by the difference in the total lengths of the NGF-dependent neurites between 2- and 4-day-old cultures, was approximately 160 micron/day. The results indicate that although the growth of neurites from some sympathetic nerve cells of the aged human become independent of the NGF, most of the nerve cells remain dependent on the NGF, even in the stage of senescence.

AChE-positive fiber growth after hippocampal fimbria transection and peripheral nerve homogenate implantation

Gelfoam treated with peripheral nerve homogenate was implanted into a site of hippocampal fimbria transection in the adult rat to assess whether the homogenate might enhance growth of AChE-positive fibers into the lesion site and whether the fiber growth might be directed to the implants. Homogenate was prepared from intact peripheral nerve and in a few cases from degenerated nerve. Some implants were encased in Silastic. Homogenate was also injected into the denervated hippocampus. The major finding was that AChE-positive fiber growth was associated with regions of high astroglial cell content in preference to the relatively hypocellular implants. No clear differences in AChE fiber sprouting into the lesion site, fiber growth into implants, or hippocampal reinnervation were noted between homogenate and saline-treated animals.

Neuronotrophic factors: effects on central cholinergic regeneration in vivo

To determine if neurotrophic factors (NTFs) which either support the survival (CNTF) or promote neuritic outgrowth (PNPF) of peripheral cholinergic neurons in vitro affect central cholinergic regeneration in vivo, NTFs were administered intracerebrally to rats after injury to septohippocampal fibers. Choline acetyltransferase activity within intrahippocampal iris implants was used as an index of cholinergic innervation. CNTF stimulated cholinergic sprouting while PNPF was ineffective under our experimental conditions, suggesting that the effects of other NTFs in vivo may be mediated by enhanced neuronal survival after injury rather than increased axonal sprouting.

Central nervous system-directed neuronotrophic activity present in red blood cells

A new neuronotrophic factor has been identified in extracts of vertebrate red blood cells. The factor supports the survival in culture of neurons from vertebrate central nervous systems, and does not support the survival of several peripheral ganglionic neurons. The active molecule appears to be a slightly acidic protein of 30,000-100,000 daltons.