Trophic regulation of action potential in bullfrog sympathetic neurones.

These experiments tested the hypothesis that the normal electrophysiological properties of mature bullfrog sympathetic ganglion (BFSG) neurones are maintained by the retrograde supply of nerve growth factor-like molecules from peripheral target tissues. Maintenance of these cells in explant culture in the absence of nerve growth factor (NGF) for up to 30 days produced electrophysiological changes that resemble those previously shown to accompany axotomy in vivo. These included (i) an increase in action potential (ap) duration (spike width), (ii) a decrease in the amplitude of the afterhyperpolarization (ahp), which follows the ap, and (iii) a rapidly developing decrease in ahp duration. When murine NGF (2.5 s; 50 ng/mL) was included in the culture medium there was less attenuation of ahp amplitude. Inclusion of affinity-isolated sheep IgG antibodies (0.5 micrograms/mL; raised against murine 2.5 s NGF) in the culture medium promoted a greater reduction in ahp amplitude than was seen in the "control" explants that were maintained in the absence of NGF. By contrast, the decrease in ahp duration that occurred in control explants was neither attenuated by exposure to NGF nor was it enhanced by NGF antibodies. Also, the increase in spike width that was seen in control explants was enhanced both by murine NGF and by NGF antibodies. Although some of the data support the hypothesis that factor(s) with some similarity to NGF may be synthesized by BFSG in vitro, loss of the retrograde transport of such factors does not explain all aspects of the electrophysiological response to target deprivation and (or) axotomy.     

Reduction in nerve growth factor availability leads to a conditioning lesion‐like effect in sympathetic neurons

Axotomized peripheral neurons are capable of regeneration, and the rate of regeneration can be enhanced by a conditioning lesion (i.e., a lesion prior to the lesion after which neurite outgrowth is measured). A possible signal that could trigger the conditioning lesion effect is the reduction in availability of a target‐derived factor resulting from the disconnection of a neuron from its target tissue. We tested this hypothesis with respect to nerve growth factor (NGF) and sympathetic neurons by administering an antiserum to NGF to adult mice for 7 days prior to explantation or dissociation of the superior cervical ganglion (SCG) and subsequently measuring neurite outgrowth. The antiserum treatment dramatically lowered the concentration of NGF in the SCG and increased the rate of neurite outgrowth in both explants and cell cultures. The increase in neurite outgrowth was similar in magnitude to that seen after a conditioning lesion. To determine if exogenous NGF could block the effect of a conditioning lesion, mice were injected with NGF or cytochrome C immediately prior to unilateral axotomy of the SCG, and for 7 days thereafter. A conditioning lesion effect of similar magnitude was seen in NGF‐treated and control animals. While NGF treatment increased NGF levels in the contralateral control ganglion, it did not significantly elevate levels in the axotomized ganglion. The results suggest that the decreased availability of NGF after axotomy is a sufficient stimulus to induce the conditioning lesion effect in sympathetic neurons. While NGF administration did not prevent the conditioning lesion effect, this may be due to the markedly decreased ability of sympathetic neurons to accumulate the growth factor after axotomy. © 2006 Wiley Periodicals, Inc. J Neurobiol, 2006     

Nerve growth factor collaborates with myocyte-derived factors to promote development of presynaptic sites in cultured sympathetic neurons

Nerve growth factor (NGF) acutely modulates synaptic transmission between sympathetic neurons and their cardiac myocyte targets. NGF also has developmental effects in establishing the level of synaptic transmission between sympathetic neurons and myocytes in culture, although little is known about the mechanisms by which NGF influences this synaptic connectivity. Here we report that NGF acts in conjunction with factors produced by cardiac myocytes to promote neuronal contact with the target and the extension of synaptic vesicle-containing growth cones. In conjunction with previously published results showing that NGF has long-term effects on synaptic transmission between sympathetic neurons and myocytes, this work suggests that NGF acts to promote sympathetic neurotransmission by increasing the number of sympathetic fibers establishing target contact. Further, we found that developmental changes in cardiac myocytes led to an increase in the density of synaptic vesicle-containing variocosities along sympathetic fibers, a process regulated by NGF. Thus, as myocytes mature they produce factors that promote the formation of sympathetic presynaptic structures. These results argue that multiple target interactions regulate the extent of synapse formation between sympathetic neurons and cardiac cells and suggest that NGF promotes presynaptic development by increasing neuronal contact with myocyte-derived cell surface or matrix-associated factors.     

Sympathetic neurons synthesize and secrete pro‐nerve growth factor protein

Postmitotic sympathetic neuronal survival is dependent upon nerve growth factor (NGF) provided by peripheral targets, and this dependency serves as a central tenet of the neurotrophic hypothesis. In some other systems, NGF has been shown to play an autocrine role, although the pervasiveness and significance of this phenomenon within the nervous system remain unclear. We show here that rat sympathetic neurons synthesize and secrete NGF. NGF mRNA is expressed in nearly half of superior cervical ganglion sympathetic neurons at embryonic day 17, rising to over 90% in the early postnatal period, and declining in the adult. Neuronal immunoreactivity is reduced when retrograde transport is interrupted by axotomy, but persists in a subpopulation of neurons despite diminished mRNA expression, suggesting that intrinsic protein synthesis occurs. Cultured neonatal neurons express NGF mRNA, which is maintained even when they are undergoing apoptosis. To determine which NGF isoforms are secreted, we performed metabolic labeling and immunoprecipitation of NGF‐immunoreactive proteins synthesized by cultured NGF‐dependent and ‐independent neurons. Conditioned medium contained high molecular weight NGF precursor proteins, which varied depending upon the state of NGF dependence. Mature NGF was undetectable by these methods. High molecular weight NGF isoforms were also detected in ganglion homogenates, and persisted at diminished levels following axotomy. We conclude that sympathetic neurons express NGF mRNA, and synthesize and secrete pro‐NGF protein. These findings suggest that a potential NGF‐sympathetic neuron autocrine loop may exist in this prototypic target‐dependent system, but that the secreted forms of this neurotrophin apparently do not support neuronal survival. © 2003 Wiley Periodicals, Inc. J Neurobiol 38–53, 2003     

Nerve growth factor collaborates with myocyte‐derived factors to promote development of presynaptic sites in cultured sympathetic neurons

Nerve growth factor (NGF) acutely modulates synaptic transmission between sympathetic neurons and their cardiac myocyte targets. NGF also has developmental effects in establishing the level of synaptic transmission between sympathetic neurons and myocytes in culture, although little is known about the mechanisms by which NGF influences this synaptic connectivity. Here we report that NGF acts in conjunction with factors produced by cardiac myocytes to promote neuronal contact with the target and the extension of synaptic vesicle‐containing growth cones. In conjunction with previously published results showing that NGF has long‐term effects on synaptic transmission between sympathetic neurons and myocytes, this work suggests that NGF acts to promote sympathetic neurotransmission by increasing the number of sympathetic fibers establishing target contact. Further, we found that developmental changes in cardiac myocytes led to an increase in the density of synaptic vesicle–containing variocosities along sympathetic fibers, a process regulated by NGF. Thus, as myocytes mature they produce factors that promote the formation of sympathetic presynaptic structures. These results argue that multiple target interactions regulate the extent of synapse formation between sympathetic neurons and cardiac cells and suggest that NGF promotes presynaptic development by increasing neuronal contact with myocyte‐derived cell surface or matrix‐associated factors. © 2000 John Wiley & Sons, Inc. J Neurobiol 43: 460–476, 2000     

Reduction in nerve growth factor availability leads to a conditioning lesion-like effect in sympathetic neurons

Axotomized peripheral neurons are capable of regeneration, and the rate of regeneration can be enhanced by a conditioning lesion (i.e., a lesion prior to the lesion after which neurite outgrowth is measured). A possible signal that could trigger the conditioning lesion effect is the reduction in availability of a target-derived factor resulting from the disconnection of a neuron from its target tissue. We tested this hypothesis with respect to nerve growth factor (NGF) and sympathetic neurons by administering an antiserum to NGF to adult mice for 7 days prior to explantation or dissociation of the superior cervical ganglion (SCG) and subsequently measuring neurite outgrowth. The antiserum treatment dramatically lowered the concentration of NGF in the SCG and increased the rate of neurite outgrowth in both explants and cell cultures. The increase in neurite outgrowth was similar in magnitude to that seen after a conditioning lesion. To determine if exogenous NGF could block the effect of a conditioning lesion, mice were injected with NGF or cytochrome C immediately prior to unilateral axotomy of the SCG, and for 7 days thereafter. A conditioning lesion effect of similar magnitude was seen in NGF-treated and control animals. While NGF treatment increased NGF levels in the contralateral control ganglion, it did not significantly elevate levels in the axotomized ganglion. The results suggest that the decreased availability of NGF after axotomy is a sufficient stimulus to induce the conditioning lesion effect in sympathetic neurons. While NGF administration did not prevent the conditioning lesion effect, this may be due to the markedly decreased ability of sympathetic neurons to accumulate the growth factor after axotomy.     

Neurotrophic agents prevent motoneuron death following sciatic nerve section in the neonatal mouse

We have examined the ability of different neurotrophic and growth factors to prevent axotomy-induced motoneuron cell death in the developing mouse spinal cord. After postnatal unilateral section of the mouse sciatic nerve, most motoneuron (MN) loss occurs in the lateral motor column of the fourth lumbar segment (L4). Significant axotomy-induced cell death occurred after surgery performed on or before postnatal day (PN) 5. In contrast, no significant cell loss was found when axotomy was performed after PN10. Axotomy on PN2 or PN5 resulted in a 44% loss of L4 motoneurons by 7 days, and a 66% loss of motoneurons by 10 days postsurgery. Implantation of gelfoam presoaked in various neurotrophic factors at the lesion site rescued axotomized motoneurons. Nerve growth factor (NGF), nedurotrophin-4/5 (NT-4/5) and ciliary neurotrophic factor (CNTF) rescued 20%–30% of motoneurons, whereas brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3), and insulin-like growth factor 1 (IGF-1) rescued virtually all motoneurons from axotomy-induced death. By contrast, platelet-derived growth factor (PDGF)-AA, PDGF-AB, basic fibroblast growth factor (bFGF), and interleukin (IL-6) were ineffective on motoneuron survival following axotomy. NGF, BDNF, NT-3, IGF-1, and CNTF also prevented axotomy-induced atrophy of surviving motoneurons. These data show that mouse lumbar motoneurons continue to be vulnerable to axotomy up to about 1 week after birth and that a number of trophic agents, including the neurotrophins, CNTF, and IGF-1, can prevent the death of these neurons following axotomy. Our studies confirm and extend previous reports on the time course of axotomy-induced mouse motoneuron death and the survival promoting effects of neurotrophic factors. 1994 John Wiley & Sons, Inc.     

Regeneration restores some of the altered electrical properties of axotomized bullfrog B-cells

In bullfrog B-type sympathetic neurones axon injury produces substantial changes in somal membrane properties. These include a shortening of action potential afterhyperpolarization (AHP) and an increase in action potential (AP) duration. In the present experiments we compared two injury situations: nerve crush, which was followed by regeneration, and nerve cut, after which regeneration to the original target was prevented, to investigate whether these electrophysiological changes were related to axon regeneration. Both crush and cut injuries produced a similar maximum decrease in AHP duration (to 33 and 30%) by 14 days after axotomy. After nerve crush, AHP duration recovered to within control values by 42 days, while after cut it remained depressed. AHP amplitude decreased to the same extent after nerve crush or cut (to 62 and 58%), but the rate of decrease was slower following crush when compared with cut, and following both types of injury it still remained depressed at 42 and 49 days. Changes in AP duration also took longer to occur following nerve crush, reaching maximal values at 35-42 days, at which time AHP duration had returned to within the normal range. The early reduction in AHP duration and its rapid recovery in regenerating neurones suggests that the current underlying this membrane property is regulated by events associated with axon outgrowth and peripheral reconnection. In contrast, changes in AHP amplitude and AP repolarization appeared to be independent of the occurrence of axon regeneration and remained abnormal at 49 days despite the recovery of AHP duration. These results imply that the electrophysiological changes seen in B-cells following injury are differentially regulated during subsequent regeneration.     

Sympathetic neurons synthesize and secrete pro-nerve growth factor protein

Postmitotic sympathetic neuronal survival is dependent upon nerve growth factor (NGF) provided by peripheral targets, and this dependency serves as a central tenet of the neurotrophic hypothesis. In some other systems, NGF has been shown to play an autocrine role, although the pervasiveness and significance of this phenomenon within the nervous system remain unclear. We show here that rat sympathetic neurons synthesize and secrete NGF. NGF mRNA is expressed in nearly half of superior cervical ganglion sympathetic neurons at embryonic day 17, rising to over 90% in the early postnatal period, and declining in the adult. Neuronal immunoreactivity is reduced when retrograde transport is interrupted by axotomy, but persists in a subpopulation of neurons despite diminished mRNA expression, suggesting that intrinsic protein synthesis occurs. Cultured neonatal neurons express NGF mRNA, which is maintained even when they are undergoing apoptosis. To determine which NGF isoforms are secreted, we performed metabolic labeling and immunoprecipitation of NGF-immunoreactive proteins synthesized by cultured NGF-dependent and -independent neurons. Conditioned medium contained high molecular weight NGF precursor proteins, which varied depending upon the state of NGF dependence. Mature NGF was undetectable by these methods. High molecular weight NGF isoforms were also detected in ganglion homogenates, and persisted at diminished levels following axotomy. We conclude that sympathetic neurons express NGF mRNA, and synthesize and secrete pro-NGF protein. These findings suggest that a potential NGF-sympathetic neuron autocrine loop may exist in this prototypic target-dependent system, but that the secreted forms of this neurotrophin apparently do not support neuronal survival.     

The Death Programme in Cultured Sympathetic Neurones Can Be Suppressed at the Posttranslational Level by Nerve Growth Factor, Cyclic AMP, and Depolarization

We have examined whether sympathetic neurones that have lost the potential to be rescued by protein and RNA synthesis inhibitors after a period of nerve growth factor (NGF) deprivation are irreversibly committed to die. We found that 15 h after withdrawal of NGF from 7-day cultures of neonatal rat superior cervical ganglion neurones, 50% of the neurones lost the potential to be rescued by cycloheximide but that NGF rescued most of the neurones. By 22 h after NGF withdrawal, only 10% of the neurones were rescued by inhibition of macromolecular synthesis with cycloheximide, puromycin, or actinomycin D, but as many as 60-80% of the neurones were rescued by NGF. This is after the time at which a DNA "ladder," consistent with cell death by apoptosis, was first detected (18 h). As long as 27 h of NGF withdrawal was required before 50% of the neurones lost the potential to be rescued by NGF. The survival-promoting agent 8-(4-chlorophenylthio)cyclic AMP (CPTcAMP) or depolarization with 50 mM KCl (HK) rescued neurones with kinetics similar to those of NGF, and rescue by all three agents did not require protein synthesis. Thus, NGF, CPTcAMP, and HK can rescue neurones deprived of NGF at much later times than either protein or RNA synthesis inhibitors by acting at the posttranslational level, a finding suggesting that initiation of the cell death programme in sympathetic neurones is not an irreversible step.     

NGF receptor-mediated reduction in axonal NGF uptake and retrograde transport following sciatic nerve injury and during regeneration.

Injury to the rat sciatic nerve leads to the induction of nerve growth factor (NGF) receptors on the denervated Schwann cells and their disappearance on the regenerating axons of the axotomized, normally NGF-sensitive sensory and sympathetic neurons. This disappearance in the axonal expression and retrograde transport of NGF receptors is associated with a similarly dramatic reduction in the axonal uptake and retrograde transport of NGF following axotomy and during regeneration. In view of the massive NGF synthesis occurring in the injured nerve, these results suggest that, while sensory and sympathetic neurons are the primary targets of NGF in the normal peripheral nervous system, the denervated Schwann cells may become its primary target in the aftermath of nerve injury.     

Nerve growth factor acutely potentiates synaptic transmission in vitro and induces dendritic growth in vivo on adult neurons in airway parasympathetic ganglia

Elevated levels of nerve growth factor (NGF) and NGF-mediated neural plasticity may have a role in airway diseases such as asthma and chronic obstructive pulmonary disease (COPD). Although NGF is known to affect sensory and sympathetic nerves, especially during development, little is known regarding its effect on parasympathetic nerves, especially on adult neurons. The purpose of this study was to analyze the acute and chronic effects of NGF on the electrophysiological and anatomical properties of neurons in airway parasympathetic ganglia from adult guinea pigs. Using single cell recording, direct application of NGF caused a lasting decrease in the cumulative action potential afterhyperpolarization (AHP) and increased the amplitude of vagus nerve-stimulated nicotinic fast excitatory postsynaptic potentials. Neuronal responsiveness to nicotinic receptor stimulation was increased by NGF, which was blocked by the tyrosine kinase inhibitor, K-252a, implicating neurotrophin-specific (Trk) receptors. Neurotrophin-3 and brain-derived neurotrophic factor had no effect on the synaptic potentials, AHP, or nicotinic response; inhibition of cyclooxygenase with indomethacin inhibited the effect of NGF on the cumulative AHP. Forty-eight hours after in vivo application of NGF to the trachealis muscle caused an increase in dendritic length on innervating neurons. These results are the first to demonstrate that NGF increases the excitability of lower airway parasympathetic neurons, primarily through enhanced synaptic efficacy and changes to intrinsic neuron properties. NGF also had dramatic effects on the growth of dendrites in vivo. Such effects may indicate a new role for NGF in the regulation of parasympathetic tone in the diseased or inflamed lower airways.     

Inhibition of p42 and p44 Mitogen-Activated Protein Kinase Activity by PD98059 Does Not Suppress Nerve Growth Factor-Induced Survival of Sympathetic Neurones

Abstract: Nerve growth factor (NGF) induces persistent p42 and p44 mitogen-activated protein kinase (MAPK) activity in sympathetic neurones in parallel to its survival-promoting activity. To investigate whether these MAPK activities are necessary for NGF-induced survival, we have inhibited NGF-stimulated p42/p44 MAPK activity over extended periods using the compound 2-(2'-amino-3'-methoxyphenyl)-oxanaphthalen-4-one (PD98059). Despite attaining up to 95% inhibition of p42/p44 MAPK activity in cultures treated with NGF and PD98059, neuronal survival is maintained undiminished, although a decrease in the density of the neuritic network is observed. Because p21Ras activity is essential for NGF-induced survival, we conclude that p21Ras-linked activities other than p42 and p44 MAPKs are responsible for mediating NGF-dependent survival of rat sympathetic neurones.     

Involvement of Leukemia Inhibitory Factor in the Increases in Galanin and Vasoactive Intestinal Peptide mRNA and the Decreases in Neuropeptide Y and Tyrosine Hydroxylase mRNA in Sympathetic Neurons After Axotomy

Abstract: In response to axonal injury, noradrenergic sympathetic neurons of the adult superior cervical ganglion (SCG) alter their neurotransmitter phenotype. These alterations include increases in the levels of the neuropeptides, galanin, vasoactive intestinal peptide (VIP), and substance P (SP) and a decrease in the catecholamine biosynthetic enzyme tyrosine hydroxylase (TH). Previous studies have indicated that after axotomy in vivo, leukemia inhibitory factor (LIF) plays an important role in increasing the contents of galanin and VIP in the SCG. In the present study, by examining the time courses of the changes in LIF and neuropeptide mRNA and by using LIF null mutant mice, we have determined that LIF alters neuropeptide content in part by increasing levels of peptide mRNA. In addition, LIF also makes a small contribution to the axotomy-induced down-regulation of mRNA encoding TH and neuropeptide Y, both of which are normally expressed at high levels in the SCG. Finally, by using a LIF-blocking antiserum, this cytokine was found to regulate SP expression in an in vitro axonal injury model. Thus, after axotomy, a single factor, LIF, participates in the down-regulation of peptides/proteins involved in normal neurotransmission and the up-regulation of a group of neuropeptides normally not present in the SCG that may be involved in regeneration.     

Fast axonal transport in central nervous system and peripheral nervous system axons following axotomy

After axotomy, changes in the composition of fast axonally transported proteins ( FTP ) within the peripheral nervous system (PNS) axons have been reported. The most significant and reproducible changes involved polypeptides found within the molecular weight range of 31.0 to 14.5 kilodaltons ( Bisby , 1980). We wished to determine whether similar changes following axotomy occur in axons of the central nervous system (CNS). Intracranial axotomy of the left optic tract was performed stereotaxically in rats. Six days post axotomy 50 muCi 35[S]-methionine was injected into the vitreous body of both eyes. FTP were isolated within the optic nerves 2 h after isotope injection. The nerve segments were processed for SDS-PAGE, fluorography, and compared to similarly prepared fluorographs of normal and eight day post-axotomy sciatic nerve segments. The labelling of 5 major polypeptide bands (S1, MW congruent to 28,000; S2a , MW congruent to 25,000; S2b , MW congruent to 23,000; T1, MW congruent to 20,200; and T2, MW congruent to 17,000) was studied by laser densitometry. Band S2b showed a highly significant (p less than 0.001) increase in concentration, while bands S1 and T1 demonstrated highly significant decreases in concentration following axotomy of the sciatic nerve. In contrast, after axotomy of the retinal ganglion cell axons the only significant change was a decrease (p less than 0.05) in T1. We suggest that failure of CNS axons to respond similarly to PNS axons following axotomy may be related to the failure of CNS axons to regenerate.