Biological activity of a new neuronal growth factor from injured peripheral nerve

Neuregulin-1 isoform induces mitogenesis, KCa and Ca2+ currents in PC12 cells. A comparison with sciatic nerve conditioned medium

Neuregulin-1 (NRG-1) is an active component found in sciatic nerve conditioned medium (CM). NRG-1 is a growth and differentiation factor shown to have an effect on neuritogenesis and survival of neural cells. PC12 cells chronically treated with NRG-1 (beta1 isoform) show an increase in proliferation under low-serum condition (2.5% fetal bovine serum and 1.25% horse serum) and serum deprivation, without visible morphological changes. NRG-1 and CM treatments of PC12 cells induced an increase of voltage-activated Ca2+ currents and large-conductance calcium-activated K+ currents (KCa). AG825, a specific inhibitor for erbB2 receptor, abolishes KCa current, though Ca2+ currents were not inhibited. These results showed that NRG-1 is capable of inducing functional changes but is not sufficient on its own to have an effect on cell morphology.

A real-time quantitative PCR comparative study between rat optic and sciatic nerves: determination of neuregulin-1 mRNA levels

Injured axons from peripheral nervous system (PNS) possess the ability to regenerate. In contrast, regeneration of injured axons does not occur in the central nervous system (CNS) or occurs to a limited extent. Previous works have shown that rat sciatic nerve conditioned medium (CM) produced PC12 cells neuronal-like differentiation and neurite outgrowth. In the present work, we compared the expression of neuregulin-1s (NRG-1s) from rat sciatic and optic nerves as members of the PNS and CNS, respectively. Sciatic nerve CM showed a higher neurotrophic activity on PC12 cells than rat optic nerve CM. RT-PCR analysis verified the presence of all three types of NRG-1 mRNAs and their receptors in both types of nerves. Real-time quantitative PCR (QPCR) assays showed that the relative expression levels of all three types of NRG-1 mRNAs were higher in optic nerves than in sciatic nerves. Eleven-day cultured optic nerves showed an increased in NDF and SMDF when compared to freshly isolated optic nerves, whereas GGF decreased. However, 11-day-cultured sciatic nerves only showed an increase in SMDF mRNA. Western blots corroborated the differences in NRG-1 expression profile for both types of nerves and their CMs. Incubation of both CMs with the anti-pan-NRG-1 antibody showed that the neurotrophic activity of the optic nerve CM increased, whereas the sciatic nerve CM remained unchanged. These results indicated that different NRG-1 levels are expressed upon nerve degeneration and the balance between those levels and other neurotrophic factors could have an important role on nerve regeneration.

Ionic currents in PC12 cells differentiated into neuron-like cells by a cultured-sciatic nerve conditioned medium

The present work deals with the identification of the ionic currents found in PC12 cells differentiated into neuron-like cells by a 9-11-day cultured-sciatic nerve conditioned medium (CM). PC12 whole-cell currents were measured after chronic exposure to CM. The results obtained in these CM-treated cells reveal that the functional expression of Ca(2+) currents is increased, that Na+ currents are not affected, and that a transient K+ current and a K+ delayed rectifier (K+ dr) current are increased. The combination of nifedipine and omega-conotoxin GVIA (omega-CgTX) does not block completely the increased functional expression of the Ca(2+) current. The remaining current is blocked by omega-agatoxin TK indicating that P/Q-type channels are additionally contributing to the increase in Ca(2+) current. NGF-treated PC12 cells, used as positive controls, confirm that NGF increases the expression of voltage-dependent Na+ currents and of Ca(2+) currents. In addition, we found that NGF also increases a K+ dr-type current in these cells. The results obtained with the CM might be due to a molecule or a mixture of molecules released into the medium by the 9-11-day cultured sciatic nerves.

Neuregulin found in cultured-sciatic nerve conditioned medium causes neuronal differentiation of PC12 cells

The present work deals with the search and identification of the molecule or combination of molecules, present in a medium conditioned by cultured rat-sciatic nerves (CM), able to cause neuronal differentiation of PC12 cells. The molecular mass range of the active fraction, as well as the thermostability and heparin affinity of the active component found in previous work, all characteristics shared with neuregulin (NRG) family members, led us to search for a NRG protein in the CM. Nerves were previously cultured for 8 days and the CM collected every 24 h, the following 3 days. The CM was concentrated (30,000 NMWL) and fractionated by quaternary ammonium chromatography and Cibacron blue affinity chromatography. The most active fraction B1.2 was further characterized by heparin affinity chromatography, size exclusion HPLC, Western blotting and immunoprecipitation. Results reveal abundance of NRG mRNA in the cultured nerves, presence of a 54 kDa NRG protein in the CM that increases along fractionation, and progressive diminution of fraction B1.2 differentiation activity on PC12 cells by gradual removal of the NRG protein by immunoprecipitation. The abundance of Schwann cells and the lack of axons in the cultured nerves suggest Schwann cells as the main NRG source, to which fibroblasts and perineurial cells might contribute.

Paracrine production of nerve growth factor during rat dorsal root ganglion development

Nerve growth factor is a target derived growth factor. In the peripheral nervous system, it is produced by tissues innervated by the sympathetic nervous system and small sensory neurons. In the present study, we tested the hypothesis that an alternate source of nerve growth factor must be available to support dorsal root ganglion neurons before they make connection with the target. Using reverse transcriptase polymerase chain reaction (RT-PCR), we detected nerve growth factor mRNA at embryonic day 12 to 17, but not in adult dorsal root ganglia. In situ hybridization studies revealed positive staining in satellite/supportive cells juxtaposed to dorsal root ganglion neurons. Our study suggests that nerve growth factor from supporting cells may have a paracrine function during development of primary sensory neurons.

Autocrine regulation of neurite outgrowth from PC12 cells by nerve growth factor

The PC12 cell line may be used as a model of NGF-induced neuronal differentiation. Exposure to NGF is accompanied by extension of neurites, cessation of growth and differentiation into cells resembling sympathetic neurons. In this study neurite outgrowth from PC12 cells was induced in serum-free, NGF-free medium conditions. Neurite outgrowth in serum-free conditions was abolished by exposure to anti-NGF antisera. Reverse transcription combined with polymerase chain reaction (RT-PCR) and in situ hybridization of PC12 cells in serum-free medium conditions revealed NGF transcripts. Western blot analysis of these cells revealed tyrosine phosphorylation of the high affinity NGF receptor (TrkA/gp140) and activation of a downstream signal cascade element, ERK-1/MAP kinase. NGF was also detected by a specific enzyme-linked immunoabsorbant assay (ELISA) revealing picogram levels of protein in conditioned medium and cell lysates. Survival of embryonic rat dorsal root ganglion neurons was maintained in cultures grown in this serum-free conditioned medium. This demonstrated that NGF may act as an autocrine or paracrine growth factor for PC12 cell differentiation.

Inhibition of axonal growth from sensory neurons by excess nerve growth factor

Fifteen-day embryonic rat dorsal root ganglion (DRG) neurons were exposed to 1 to 200 ng/ml nerve growth factor (NGF). Maximal neurite outgrowth was obtained with 10 to 20 ng/ml. Neurite outgrowth was reduced to 89% of maximal by increasing NGF to 50 ng/ml, to 66% by 100 ng/ml, and to 18% by 200 ng/ml NGF. Identical effects were seen with mouse 2.5S NGF and recombinant human NGF. Neuron cell counts demonstrated that significant cell death did not occur. In time course experiments, significant inhibition, compared with control, began within 1 hour of adding 200 ng/ml and 3 hours of adding 50 ng/ml NGF. The inhibitory effect of NGF on neurite outgrowth was reversed within 3 hours when DRG were incubated with 5 ng/ml NGF after treatment with 50 or 200 ng/ml NGF medium for 12 hours. The inhibition demonstrated for neurons did not occur in PC12 cells; axonal growth was not inhibited by up to 1,000 ng/ml NGF. Excess brain-derived neurotrophic factor or neurotrophin-3 did not inhibit neurite outgrowth. We conclude that high concentrations of NGF produces specific and reversible arrest of neurite outgrowth from sensory neurons. This observation has important clinical implications, because these inhibitory concentrations have been exceeded when NGF has been administered into the central nervous system of humans and animals.

Neuronal differentiation of PC12 and chick embryo ganglion cells induced by a sciatic nerve conditioned medium: characterization of the neurotrophic activity

The present work deals with the finding and characterization of a neurotrophic factor present in serum-free Dulbecco's modified Eagle's medium in which rat sciatic nerves previously cultured for 9 days were maintained for 24 h. This sciatic nerve conditioned medium (SNCM) produced neuronal differentiation and neurite outgrowth on PC12 cells, as well as survival and differentiation of eight-day old chick embryo dorsal root ganglion (E8-DRG) and ciliary ganglion (E8-CG) neurons. SNCM activity was decreased by dilution, heating and trypsin treatment; it was not inhibited by anti-NGF and anti-bFGF antibodies; and it was not mimicked by CNTF, laminin and fibronectin. By utilizing its neurite-promoting activity on PC12 cells, experiments oriented to purify the factor were carried out. Ultrafiltration, heparin-affinity chromatography and size-exclusion high pressure liquid chromatography (HPLC) were employed. The ability of SNCM to induce PC12 cell, E8-DRG and E8-CG neuronal differentiation, the heparin affinity of the active SNCM protein, and the size-exclusion HPLC elution characteristics of the active protein suggest that the active component of the SNCM is, in all probability, a novel sciatic nerve neurotrophic factor (SNTF).

Characterization of a Schwann cell neurite-promoting activity that directs motoneuron axon outgrowth

Schwann cells support and facilitate axonal growth during development and successful regeneration in the peripheral nerve. In the regenerating rat sciatic nerve, Schwann cells provide a trophic milieu for primary sensory, sympathetic, and motoneurons. We have characterized a neurotrophic activity produced by adult rat sciatic nerve Schwann cells and a spontaneously immortal Schwann cell clone (iSC). This activity elicits neurite outgrowth from chick embryo explants of both CNS and PNS. The iSC activity has been concentrated by cation-exchange chromatography and compared to known neurotrophins in bioassay. Pooled bound fractions elicit neurite outgrowth from sympathetic, ciliary and motoneurons. In collagen matrix cocultures of iSC and E4 ventral horn (before motor axon extension to muscle targets), the iSC activity can direct the initial axonal extension from motoneurons. The data presented suggest that Schwann cell-produced activity may mediate motoneuron axonal extension before contact with their peripheral source of neurotrophin.

Impaired motor axon regeneration in the C57BL/Ola mouse

The delayed Wallerian degeneration which occurs in the C57BL/Ola mouse is associated with impaired motor axon regeneration. Following sciatic nerve crush, recovery of the sciatic functional index was delayed and incomplete when compared with recovery in C57BL/6J mice. After facial nerve crush, recovery of whisker movement in Ola mice was also delayed, and there was a prolonged period of partial recovery, not seen in 6J mice. Regeneration rate of the motor axons was measured by the axonal transport technique in sciatic nerve and was approximately 0.7 mm/d for Ola mice, and 4.0 mm/d for 6J mice. Combining these results from our previous work, we conclude that regeneration of both sensory and motor axons is impaired when Wallerian degeneration does not follow its usual time course after injury.

Enhanced synthesis of brain-derived neurotrophic factor in the lesioned peripheral nerve: different mechanisms are responsible for the regulation of BDNF and NGF mRNA

Nerve growth factor (NGF) and brain-derived neurotrophic factor (BDNF) are molecules which regulate the development and maintenance of specific functions in different populations of peripheral and central neurons, amongst them sensory neurons of neural crest and placode origin. Under physiological conditions NGF is synthesized by peripheral target tissues, whereas BDNF synthesis is highest in the CNS. This situation changes dramatically after lesion of peripheral nerves. As previously shown, there is a marked rapid increase in NGF mRNA in the nonneuronal cells of the damaged nerve. The prolonged elevation of NGF mRNA levels is related to the immigration of activated macrophages, interleukin-1 being the most essential mediator of this effect. Here we show that transsection of the rat sciatic nerve also leads to a very marked increase in BDNF mRNA, the final levels being even ten times higher than those of NGF mRNA. However, the time-course and spatial pattern of BDNF mRNA expression are distinctly different. There is a continuous slow increase of BDNF mRNA starting after day 3 post-lesion and reaching maximal levels 3-4 wk later. These distinct differences suggest different mechanisms of regulation of NGF and BDNF synthesis in non-neuronal cells of the nerve. This was substantiated by the demonstration of differential regulation of these mRNAs in organ culture of rat sciatic nerve and Schwann cell culture. Furthermore, using bioassays and specific antibodies we showed that cultured Schwann cells are a rich source of BDNF- and ciliary neurotrophic factor (CNTF)-like neurotrophic activity in addition to NGF. Antisera raised against a BDNF-peptide demonstrated BDNF-immunoreactivity in pure cultured Schwann cells, but not in fibroblasts derived from sciatic nerve.

Functional enhancement of intrastriatal dopamine-containing grafts by the co-transplantation of sciatic nerve tissue in 6-hydroxydopamine-lesioned rats

Peripheral nerve "bridges" demonstrate the ability to facilitate axonal growth and regenerate adult and fetal central nervous system tissue. The purpose of this study was to determine if co-grafted peripheral nerve tissue could enhance the ability of fetal dopamine (DA) cell transplants to reinnervate host striatum that had been denervated unilaterally. Male Fisher-344 rats were unilaterally lesioned with 6-hydroxydopamine to eliminate the nigrostriatal DA pathway. A total of 31 rats demonstrated a pattern of rotation indicative of a greater than 98% depletion in DA. Rats were kept as nongrafted controls (n = 6), grafted with sciatic nerve (PN) minces (n = 6), grafted with fetal ventral mesencephalon (VM; n = 10), or co-grafted with VM and PN minces (n = 9). All groups were then tested for changes in apomorphine-induced rotational behavior. The PN control group showed no significant differences in rotation when compared to pregrafting levels and to the lesioned nongrafted group. Both the VM-grafted group and the VM-PN co-grafted group showed significant (P less than 0.01, one-way ANOVA) decreases in rotations beginning at 1.5 weeks postgrafting. There was a progressive decrease in rotations up to 12 weeks, the last test point examined. Interestingly, the co-graft group revealed a significantly greater decrease in rotation (P less than 0.05) than the VM group beginning at 5 weeks and continuing out to the 12-week test point. Histological and immunocytochemical studies showed good survival of both PN and VM grafts. The augmented recovery could not be accounted for by increased DA cell survival or host brain DA reinnervation in the co-graft group. Taken together, these findings suggest that PN tissue enhances the ability of fetal VM grafts to reinnervate host brain.

Delayed wallerian degeneration in sciatic nerves of C57BL/Ola mice is associated with impaired regeneration of sensory axons

Wallerian degeneration is delayed following sciatic nerve crush in C57BL/Ola mice. Compared to C57BL/6J mice, regeneration of sensory axons is significantly slowed in the Ola mice, but reinnervation does eventually occur. We conclude that Wallerian degeneration is a prerequisite for normal sensory axon regeneration following a crush injury to peripheral nerve.

P0 mRNA expression in cultures of Schwann cells and neurons that lack basal lamina and myelin

Schwann cells of the peripheral nervous system depend on the presence of both axons and basal lamina to achieve a myelinating phenotype. Furthermore, removal of axonal influence results in the cessation of myelination and down-regulation of myelin protein expression by Schwann cells. Here we examine whether both axons and basal lamina are required by Schwann cells for the expression of mRNA encoding the major myelin glycoprotein, P0. Cultures of Schwann cells and neurons obtained from dorsal root ganglia of 15 day embryonic rat pups were grown for up to 20 days in vitro under conditions that either allowed or prohibited basal lamina and myelin formation. These cultures were assayed for the expression of P0 mRNA by using an S1 nuclease-protection assay. After 20 days in vitro, the cultures that did not assemble basal lamina and that were incapable of myelin formation expressed P0 mRNA at a level which was comparable to that seen in identically aged, myelinating cultures. Both the myelinating and nonmyelinating cultures demonstrated an appreciable increase in P0 mRNA when compared to the starting embryonic dorsal root ganglia Schwann cells. The latter had a low, but detectable, level of mRNa for this myelin glycoprotein. The cultures that were devoid of basal lamina and myelin showed a clear increase in P0 mRNA by 11-15 days in culture. This increase in expression depended on the presence of neurons/neurites, since Schwann cells which were grown in neuron-depleted cultures expressed little, if any, P0 mRNA. In contrast to the levels of P0 mRNA, the nonmyelinating cultures had a significantly lower amount of P0 glycoprotein than did the cultures which assemble myelin. This suggests that the nonmyelinating Schwann cells regulate the level of this glycoprotein at the translational and/or the posttranslational level. The data presented here suggest that myelin protein mRNA expression and myelin assembly by Schwann cells are separable events, with the former depending on one or more neuronal/axonal factors.

Kinetics of production of a novel growth factor after peripheral nerve injury

In response to transection injury, the distal segment of sciatic nerve produces a soluble factor which stimulates neurite outgrowth from 15 day embryonic rat dorsal root ganglion (DRG) neurons, and PC12 cells. This activity enhances survival of large sensory neurons, promotes myelination and has been designated SN. The expression of SN, undetectable in the perineurium and proximal segments, occurs solely in the endoneurium distal to the site of permanent transection. When the distal portion is removed immediately after transection, homogenized and the supernatant tested, there is little neurite promoting activity in the normal nerve. For the first 10 days after transection the major soluble factor present in the distal segment is NGF. The amount of neurite promoting activity increases after 10 days and appears to plateau at 30-35 days while the proportion that is inhibited by anti-NGF decreases. In a competitive receptor binding assay, SN does not compete with 125I-NGF for receptors on either DRG or PC12 cells. Separation using polyacrylamide-agarose followed by HPLC demonstrates that SN migrates with polypeptides of molecular weights 17.2 and 19.1 kDa.