Cholinergic neuronotrophic factors: fractionation properties of an extract from selected chick embryonic eye tissues

Growth Factors and Their Application in the Therapy of Hereditary Neurodegenerative Diseases

Hereditary neurodegenerative diseases (hNDDs) such as Alzheimer's, Parkinson's, Huntington's disease, and others are primarily characterized by their progressive nature, severely compromising both the cognitive and motor abilities of patients. The underlying genetic component in hNDDs contributes to disease risk, creating a complex genetic landscape. Considering the fact that growth factors play crucial roles in regulating cellular processes, such as proliferation, differentiation, and survival, they could have therapeutic potential for hNDDs, provided appropriate dosing and safe delivery approaches are ensured. This article presents a detailed overview of growth factors, and explores their therapeutic potential in treating hNDDs, emphasizing their roles in neuronal survival, growth, and synaptic plasticity. However, challenges such as proper dosing, delivery methods, and patient variability can hinder their clinical application.

CNTF and retina

Ciliary neurotrophic factor (CNTF) is one of the most studied neurotrophic factors for neuroprotection of the retina. A large body of evidence demonstrates that CNTF promotes rod photoreceptor survival in almost all animal models. Recent studies indicate that CNTF also promotes cone photoreceptor survival and cone outer segment regeneration in the degenerating retina and improves cone function in dogs with congenital achromotopsia. In addition, CNTF is a neuroprotective factor and an axogenesis factor for retinal ganglion cells (RGCs). This review focuses on the effects of exogenous CNTF on photoreceptors and RGCs in the mammalian retina and the potential clinical application of CNTF for retinal degenerative diseases.

Interactions between developing autonomic neurons and their target tissues

Neurons critically depend on contact with the correct target tissue in order to survive and mature. The number of neurons surviving in a nerve centre directly depends on the size of the peripheral field in innervates. It has been proposed that target tissues release a neurotrophic substance (retrophin) which is internalized by nerve terminals and retrogradely transported to the perikarya where its action results in the survival of appropriate neurons. In the sympathetic nervous system, nerve growth factor probably acts as a retrophin. Similar retrophins must exist for other neuronal systems. In order to identify a parasympathetic retrophin two approaches have been taken. One was to grow appropriate target tissues with radiolabelled amino acids and to determine whether the proteins synthesized and released by these target tissues were retrogradely transported by parasympathetic neurons in vivo. The other approach was to show that a purified neurotrophic factor for the chick ciliary ganglion could be retrogradely transported by parasympathetic neurons. The results have suggested that at least two retrophins are involved in the normal development of the autonomic nervous system: one, nerve growth factor, for the sympathetic nervous system and the other, as yet unnamed, for the parasympathetic system.

The use of ciliary neurotrophic factor to promote recovery after peripheral nerve injury by delivering it at the site of the cell body

Despite a body of evidence showing that various neurotrophic factors support the survival of nerve cells and stimulate axonal outgrowth, doubt remains about their optimal site of application as well as the more compelling question of what clinical benefit, if any, they would confer. Ciliary neurotrophic factor (CNTF) supports the survival of motorneurons in vitro and in vivo. Direct delivery of CNTF to the cell bodies may help reduce the side effects and overcome the problem of rapid systemic clearance. The aim of this study was to establish whether nerve regeneration may be improved upon by the controlled addition of a specific humoral neurotrophic substance (CNTF) at the level of the cell body. Three groups of five adult sheep were used. The first group acted as normal controls. In the second and third groups, the median nerve was divided and repaired using an epineurial suture technique. In the second group, CNTF was supplied into the CSF at the level of C6 by an implanted osmotic pump. In the third group physiological saline was placed in the osmotic pump. The animals underwent comprehensive electrophysiological and isometric tension experiments at six months. All of the animals had reduced electrophysiological, morphometric and isometric tension indices after surgery compared to normal. The CNTF group had better results than the saline group in the following; (1) area and amplitude of the muscle action potential (2) the percentage of tetanus and muscle mass preserved after repair. These differences were only statistically significant for amplitude of the muscle action potential. No statistical difference was found in the morphological indices (fibre diameter, axon diameter, myelin thickness and internodal length) between the CNTF and saline groups. CNTF does not confer a functional benefit when applied at the level of the cell body.

Ciliary neurotrophic factor protects retinal ganglion cells from axotomy-induced apoptosis via modulation of retinal gliain vivo

Adenoviral-mediated transfer of ciliary neurotrophic factor (CNTF) to the retina rescued retinal ganglion cells (RGCs) from axotomy-induced apoptosis, presumably via activation of the high affinity CNTF receptor alpha (CNTFRalpha) expressed on RGCs. CNTF can also activate astrocytes, via its low affinity leukemia inhibitory receptor beta expressed on mature astrocytes, suggesting that CNTF may also protect injured neurons indirectly by modulating glia. Adenoviral-mediated overexpression of CNTF in normal and axotomized rat retinas was examined to determine if it could increase the expression of several glial markers previously demonstrated to have a neuroprotective function in the injured brain and retina. Using Western blotting, the expression of glial fibrillary acid protein (GFAP), glutamate/aspartate transporter-1 (GLAST-1), glutamine synthetase (GS), and connexin 43 (Cx43) was examined 7 days after intravitreal injections of Ad.CNTF or control Ad.LacZ. Compared to controls, intravitreal injection of Ad.CNTF led to significant changes in the expression of CNTFRalpha, pSTAT(3), GFAP, GLAST, GS, and Cx43 in normal and axotomized retinas. Taken together, these results suggest that the neuroprotective effects of CNTF may result from a shift of retinal glia cells to a more neuroprotective phenotype. Moreover, the modulation of astrocytes may buffer high concentrations of glutamate that have been shown to contribute to the death of RGCs after optic nerve transection.

Cytokines that signal through the leukemia inhibitory factor receptor-beta complex in the nervous system

Cytokines that signal through the leukemia inhibitory factor (LIF) receptor, such as LIF and ciliary neuronotrophic factor, have a wide range of roles within both the developing and mature nervous system. They play a vital role in the differentiation of neural precursor cells into astrocytes and can prevent or promote neuronal differentiation. One of the conundrums regarding signalling through the LIF receptor is how it can have multiple, often conflicting roles in different cell types, such as enhancing the differentiation of astrocytes while inhibiting the differentiation of some neuronal cells. Factors that can modulate signal transduction downstream of cytokine signalling, such as "suppressor of cytokine signalling" proteins, which inhibit the JAK/STAT but not the mitogen-activated protein kinase pathway, may therefore play an important role in determining how a given cell will respond to cytokine signalling. This review discusses the general effects of cytokine signalling within the nervous system. Special emphasis is placed on differentiation of neural precursor cells and the role that regulation of cytokine signalling may play in how a given precursor cell responds to cytokine stimulation.

Cytokines which signal through the LIF receptor and their actions in the nervous system

A number of different cytokines, each initially characterized on the basis of very different biological activities, all have very similar signalling pathways and share a similar tertiary structure. These cytokines include leukaemia inhibitory factor, ciliary neuronotrophic factor, oncostatin M, growth-promoting activity and cardiotrophin 1. They all have been found to regulate a number of properties of cells of the developing and mature nervous system in vitro and thus are neuroregulatory cytokines. The actions of these cytokines include regulation of neurotransmitter phenotype, differentiation of neuronal precursor cells both in the peripheral nervous system and in the spinal cord, survival of differentiated neurons, and regulation of development of both astrocytes and oligodendrocytes. In addition, studies in animal models show that these factors can rescue sensory and motor neurons from axotomy-induced cell death, which suggests that they can act as trauma factors for injured neurons. Analysis of the expression patterns of the different neuroregulatory cytokines and their receptors reveals that the receptors are expressed throughout nervous system development and following trauma, whereas the cytokines show temporal and spatial specific expression patterns. This is consistent with the idea that specific cytokines have specific roles in neural development and repair, but that their signalling pathways are shared. The phenotypes of the receptor knockouts show clear deficits in nervous system development, indicating a crucial role for LIF receptor signalling. Knockouts of individual cytokines are less dramatic, but LIF and CNTF knockouts do reveal deficits in maintenance of motor neurons or following trauma. Thus, whereas LIF and CNTF have clear roles in maintenance and following trauma, it is unclear which of the cytokines is involved in nervous system development. In clinical terms, these findings add further support to the use of these cytokines in nervous system trauma and disease.

Trophic action of pharmacological substances with a guanidine group on mouse neuroblastoma cells and chick ganglionic neurons in culture

A series of substances (designated CTQ compounds) with a guanidine group have been synthesized and tested for their ability to promote neuronal survival and neurite outgrowth. Mouse neuroblastoma clonal cell lines grown in serum-containing medium for 10 days as well as primary cultures of embryonic chicken ganglion neurons grown in serum-free defined medium for 1 or 2 days have been used for the experiments. Among the various CTQ compounds (CTQ1-CTQ20) tested, only CTQ8 exerted positive neurotrophic effects on these peripheral neuronal cells. At a concentration of 10(-4) M, CTQ8 enhanced neuritogenesis of neuroblastoma cells. However, the most striking influence of CTQ8 was its promoting effect (6- to 10-fold) on the survival of chicken ciliary and dorsal root ganglionic neurons at concentrations ranging from 10(-3) M to 5 x 10(-4) M.

The cellular and molecular basis of peripheral nerve regeneration

Functional recovery from peripheral nerve injury and repair depends on a multitude of factors, both intrinsic and extrinsic to neurons. Neuronal survival after axotomy is a prerequisite for regeneration and is facilitated by an array of trophic factors from multiple sources, including neurotrophins, neuropoietic cytokines, insulin-like growth factors (IGFs), and glial-cell-line-derived neurotrophic factors (GDNFs). Axotomized neurons must switch from a transmitting mode to a growth mode and express growth-associated proteins, such as GAP-43, tubulin, and actin, as well as an array of novel neuropeptides and cytokines, all of which have the potential to promote axonal regeneration. Axonal sprouts must reach the distal nerve stump at a time when its growth support is optimal. Schwann cells in the distal stump undergo proliferation and phenotypical changes to prepare the local environment to be favorable for axonal regeneration. Schwann cells play an indispensable role in promoting regeneration by increasing their synthesis of surface cell adhesion molecules (CAMs), such as N-CAM, Ng-CAM/L1, N-cadherin, and L2/HNK-1, by elaborating basement membrane that contains many extracellular matrix proteins, such as laminin, fibronectin, and tenascin, and by producing many neurotrophic factors and their receptors. However, the growth support provided by the distal nerve stump and the capacity of the axotomized neurons to regenerate axons may not be sustained indefinitely. Axonal regenerations may be facilitated by new strategies that enhance the growth potential of neurons and optimize the growth support of the distal nerve stump in combination with prompt nerve repair.

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).

Multiple neurotrophic factors including NGF-like activity in nerve regeneration chamber fluids

Silicone nerve regeneration chambers were implanted between the cut ends of the sciatic nerve of adult rats. Neurotrophic activities in cell-free fluids collected from the chambers were determined using bioassays for survival of embryonic chick ciliary and sympathetic neurons in culture. Separation by molecular exclusion HPLC of the components of fluids collected 1, 2 or 3 days after implantation revealed the presence of a multitude of neurotrophic factors differing in their molecular weights, specificity towards the two types of neurons, and time course. Antiserum to nerve growth factor partially blocked sympathetic activity of fluids collected at 1 day. Affinity purified antibody was also effective and completely eliminated bioactivity of HPLC fractions corresponding to the molecular weight of nerve growth factor. The presence in the fluids of 13-18 and 20-32 kD components active towards ciliary neurons is consistent with the release of fibroblast growth factor and ciliary neurotrophic factor respectively. The stimulation of sympathetic neurons by the 13-18 kD material, and also by 4-6 and 7-11 kD components cannot be entirely accounted for by known factors. This study demonstrates that a number of neurotrophic factors, which differ in their specificity towards sympathetic and parasympathetic neurons, are made available to the region of axonal regrowth over the first few days of regeneration. Contrary to earlier reports, nerve growth factor-like activity was shown to be present in nerve regeneration chambers.

Histometric effects of ciliary neurotrophic factor in wobbler mouse motor neuron disease

We investigated the histological effects of ciliary neurotrophic factor on degenerating motor neurons, their axons, and skeletal muscles in 68 wobbler mice with motor neuron disease. Treatment consisted of recombinant rat or human ciliary neurotrophic factor (or a vehicle solution), 1-mg/kg subcutaneous injection, three times per week for 4 weeks after the clinical diagnosis. The number of motor neurons immunoreactive for calcitonin gene-related peptide was higher in mice receiving rat ciliary neurotrophic factor (p < 0.03), although the number of choline acetyltransferase-reactive neurons was the same in both treated and untreated control groups. Treatment did not prevent vacuolar degeneration of motor neurons. In mice treated with human ciliary neurotrophic factor, the percentage of axons undergoing acute axonal degeneration (myelin ovoids) was smaller in the entire C5 ventral root (p < 0.02) and in the musculocutaneous nerve (p < 0.04), and the number of myelinated nerve fibers was 30% higher in both nerves (p < 0.01 and p < 0.04, respectively) than in controls. In ciliary neurotrophic factor-treated mice, the biceps muscle weight was 20% greater, the mean muscle fiber diameter was 30% larger, and the number of atrophied muscle fibers was 75% lower than that in the vehicle-treated wobbler mice (p < 0.001 for all three results). The number of terminal axonal branching points and the mean length of motor end-plates were also higher in the ciliary neurotrophic factor-treated mice (p < 0.001 and p < 0.02, respectively).(ABSTRACT TRUNCATED AT 250 WORDS)

The interleukin-1-induced increase of substance P in sympathetic ganglia is not mediated by ciliary neurotrophic factor

Interleukin-1 (IL-1) induction of substance P (SP) in cultured sympathetic ganglia requires a soluble intermediate molecule that is present in IL-1 conditioned medium (IL-1CM). One of the required intermediates is leukemia inhibitory factor (LIF; Shadiack et al., J Neurosci 13:2601-2609, 1993). In the present study we have examined the possibility that ciliary neurotrophic factor (CNTF) is another intermediate involved in the IL-1 induction of sympathetic SP. CNTF mimics the action of IL-1CM by raising both SP and choline acetyltransferase activity--actions that are blocked by a specific neutralizing antiserum for CNTF. However, IL-1CM and CNTF differ in their response to depolarizing agents: while KCl (40 mM) blocks the action of IL-1CM (and LIF), it enhances the action of CNTF. Furthermore, neither CNTF bioactivity nor CNTF protein is detected in IL-1CM. Neutralizing antiserum to CNTF fails to block the action of either IL-1 or IL-1CM, suggesting that neither a soluble nor a membrane-bound form of the molecule is active in direct response to IL-1 action. While Northern blots confirm the presence of both CNTF and CNTF receptor mRNA in neonatal ganglia, neither culturing nor IL-1 treatment alters these mRNA levels. These data taken together suggest that while CNTF is present and possibly active in sympathetic ganglia, it is not a mediator of the IL-1 induction of SP.

Target-derived molecules that influence the development of neurons in the avian ciliary ganglion

The developing avian ciliary ganglion has been a particularly amenable system for the identification, isolation, and characterization of putative target-derived molecules that mediate retrograde interactions. To date a number of biochemically distinct activities that regulate neuronal survival, transmitter phenotype, and chemosensitivity of ciliary ganglion neurons have been identified. Of these, only two survival-promoting molecules have been purified to homogeneity: ciliary neurotrophic factor and a related molecule, growth-promoting activity. A somatostatin-inducing activity found in cultured choroid cells is very likely to be chick activin A. Other molecules that regulate acetylcholine and acetylcholine receptor expression comigrate on a gel filtration column at a molecular weight of 50-60 kD, but they have yet to be isolated. Once molecules that mimic retrograde influences are identified, a number of criteria must be met before their physiological significance can be established. These criteria are (1) availability of the molecule from the target at the appropriate time in development; (2) ability of the neurons to respond to the molecule at the appropriate time in development; (3) demonstration that blocking the activity or availability of the molecule is able to block the target-derived developmental change expressed in the neurons. Of the molecules that are thought to retrogradely influence ciliary neuron development, only growth-promoting activity is known to meet criteria 1 and 2, and experiments are currently underway to test whether inhibition of growth-promoting activity in vivo will exacerbate normal cell death.

Cell blotting and isoelectric focusing of neuroblastoma-derived heparin-binding neurotrophic activities: detection of basic fibroblast growth factor protein and mRNA

Neuroblastoma cells have been shown to contain growth factors, which may be involved in the regulation of cell proliferation and/or differentiation. We have examined whether human IMR-32 neuroblastoma cells store factors with a capacity to promote neuron survival and differentiation. Heparin affinity chromatography, cell blotting, and isoelectric focusing of IMR-32 cell extracts revealed multiple neurotrophic activities at molecular weights of 16.8, 24.1, 39.0, 45.3, 52.3 and isoelectric points of 4.0, 5.0, 8.3, 9.0. Immunocytochemistry, immunoblotting, and radio-immunoassay with specific antibodies suggests that one neurotrophic activity is immunologically identical with basic fibroblast growth factor (bFGF). This assumption is supported by Northern blot analysis, which shows a 6.0 kb bFGF transcript.

Specific in vitro biological activity of snake venom myotoxins

Some snake venoms contain toxins that are reported to be selective for damaging muscle. This specificity can be used to design experiments intended to eliminate muscle. We studied the small myotoxins and fractions IV and V of Bothrops nummifer venom to evaluate their direct effect on cultured muscle cells, neurons, macrophages, and a fibroblast cell line. The small myotoxins, at 100 micrograms/ml for 2 h, had no effect in vitro, contrary to the in vivo applications. Fractions IV and V were both myotoxic and, at 100 micrograms/ml, destroyed all cell types. However, at 10 micrograms/ml the effects of fraction IV were more selective for muscle. Vacuolation of the sarcoplasmic reticulum and T-tubules was first seen in the poisoned muscles, without initial lesions in the nuclei, sarcolemma, mitochondria, and rough endoplasmic reticulum. Fractions IV and V have different toxic activity in cells other than muscles and are a mixture of two basic proteins (i and ii). Protein ii is predominant in fraction IV and protein i is predominant in fraction V. The toxic effects may be mediated by the formation of nonspecific ionic pores in the sarcolemma and/or T-tubule muscle membrane.

Preparation and biological properties of native and recombinant ciliary neurotrophic factor

CNTF (ciliary neurotrophic factor), purified from rabbit sciatic nerves by a relatively simple procedure, is bioactive in tissue culture at low picomolar concentration and appears as a doublet on polyacrylamide gel electrophoresis (PAGE). In these nerves, CNTF accounts for more than one-half of the survival-promoting activity on ciliary neurons. The concentration of CNTF in rabbit sciatic nerves is estimated to be 5 nmol/kg, more than 1000 times higher than would seem to be required to support neurons if the neurotrophic factor were homogeneously distributed. With recombinant DNA technology, rat CNTF has been synthesized in Escherichia coli, purified without denaturating agents, and found to be bioactive at a slightly lower concentration than CNTF extracted from rabbit sciatic nerves. After radioiodination, CNTF retains biological activity but is not specifically internalized and retrogradely transported in motor and sensory axons. In peripheral nerves, ciliary neurotrophic factor differs biologically from nerve growth factor (NGF) by its much higher tissue concentration and apparent lack of internalization by peripheral nerve axons.

Expression cloning of neurotrophic factors using Xenopus oocytes

We have explored the potential for cloning novel neurotrophic factor cDNAs via assay of neurotrophic activities following expression in Xenopus oocytes. In this report, we describe the successful application of the method to tract rat ciliary neurotrophic factor (CNTF) activity from mRNA purified from cultured cells and from mRNA synthesized by in vitro transcription of a cDNA library. Rat C6 glioma cells, which had been previously shown to have CNTF-like activity (Westermann et al., 1988), were used as source material. We tested protein extracts of C6 cells using an in vitro assay of primary neurons from the chick ciliary ganglion (CCG assay) and detected a CNTF-like activity. RNA isolated from C6 cells was shown to direct the synthesis of the activity following microinjection into Xenopus oocytes and one-step fractionation of Xenopus extract. C6 mRNA was size-fractionated, and fractions encoding CNTF-like activity were cloned into a lambda phage vector at a site distal to a T7 promoter. Synthetic RNA transcribed from total library DNA was injected into Xenopus oocytes, and a CNTF-like activity in the oocyte extract was detected by the CCG assay. Further fractionation of library clones narrowed the presence of the clone encoding the CNTF-like activity to a pool containing 20,000 members. The presence of a full-length CNTF cDNA clone in this pool and partial clones in other pools was confirmed by Polymerase Chain Reaction (PCR) using oligonucleotides from the rabbit CNTF cDNA (Lin et al., 1989) as primers.(ABSTRACT TRUNCATED AT 250 WORDS)

The expression of CNTF message and immunoreactivity in the central and peripheral nervous system of the rat

We have examined the temporal and spatial expression of ciliary neurotrophic factor (CNTF) and its messenger RNA (mRNA) by immunocytochemistry and Northern blot analysis. Specific CNTF-like (CNTF-IR) immunoreactivity and CNTF message were detected primarily in sciatic nerve, spinal cord, and optic nerve sections in the adult rat. In the sciatic nerve immunostaining was localized primarily to the Schwann cell cytoplasm. Schwann cells in the dorsal root ganglion and in the spinal motor roots were immunoreactive for CNTF but no CNTF immunoreactivity was detected in Schwann cells associated with unmyelinated sympathetic fibers in the superior cervical ganglion. CNTF-IR was first detected in sciatic nerve sections on postnatal day 8 and increased in intensity until reaching adult levels by postnatal day 21. In the adult rat, optic nerve staining was confined to astrocyte-like cells and their projections, and this pattern of immunoreactivity was first apparent at postnatal day 8. Double labelling experiments suggest that a GFAP-positive cell in the optic nerve synthesizes CNTF. In the spinal cord, CNTF-IR was seen only in white matter non-neuronal cells at all ages studied. Branched oligodendrocyte-like cells appeared stained and the staining was first apparent at postnatal day 8. The data, therefore, suggest that myelinating Schwann cells produce CNTF and demonstrate the presence of CNTF and its messenger RNA at the appropriate time period in tissues previously defined as having biological responses to CNTF.

Immunolocalization of ciliary neuronotrophic factor in adult rat sciatic nerve

Two rabbit polyclonal antibodies were raised against synthetic peptides corresponding to residue numbers 45-59 and 181-200 of rat ciliary neuronotrophic factor (CNTF). The resulting antibodies were purified by affinity chromatography and both purified antibodies reacted by enzyme-linked immunoassay (ELISA) and immunoblotting with rat sciatic nerve CNTF. The anti-CNTF peptide antibodies were used to immunostain sections of adult rat sciatic nerve, previously known as the richest tissue source of CNTF. By light microscopy both antibodies appeared to stain exclusively Schwann cells and axons and both did so with the same pattern of specific staining. Immunostaining was eliminated by absorption of the anti-peptide antibodies with either their corresponding peptide or with purified rat nerve CNTF or by using purified nonspecific IgG. Schwann cells were stained and in semi-thin sections this staining appeared to be in the Schwann cell cytoplasm. Axons could be stained in addition to Schwann cells providing higher concentrations of antibodies were used. Epineurial, endoneurial and endothelial cells appeared unstained. Since all Schwann cells and axons appear to contain CNTF and since CNTF is known to act in vitro to support sensory and sympathetic ganglionic and motor neurons, we suggest that Schwann cells may normally provide CNTF to those neurons contributing axons to the peripheral nerve.

Molecular mechanisms for generation of neural diversity and specificity: roles of polypeptide factors in development of postmitotic neurons

Development of postmitotic neurons is influenced by two groups of polypeptide factors. Neurotrophic factors promote neuronal survival both in vivo and in vitro. Neuronal differentiation factors influence transmitter phenotypes without affecting neuronal survival. The list of neurotrophic factors is increasing partly because certain growth factors and cytokines have been shown to possess neurotrophic activities and also because new neurotrophic factors including new members of the nerve growth factor (NGF) family have been identified at the molecular level. In vitro assays using recombinant neurotrophic factors and distributions of their mRNAs and proteins have indicated that members of a neurotrophic gene family may play sequential and complementary roles during development and in the adult nervous system. Most of the receptors for neurotrophic factors contain tyrosine kinase domains, suggesting the importance of tyrosine phosphorylation and subsequent signal transduction for their effects. Molecules such as LIF (leukemia inhibitory factor) and CNTF (ciliary neurotrophic factor) have been identified as neuronal differentiation factors in vitro. At the moment, however, it remains to be determined whether or not the receptors for a group of neuronal differentiation factors constitute a gene family or contain domains of kinase or phosphatase activity. Synergetic combinations of neurotrophic and neuronal differentiation factors as well as their receptors may contribute to the generation of neural specificity and diversity.

Differential effects on sensory nerve processes and behavioral alterations in the rat after treatment with antibodies to nerve growth factor

Published work on the effects of antibodies to nerve growth factor (ANTI-NGF) treatment on rats has shown an increase in the number of unmyelinated central processes of dorsal root ganglia (DRG) neurons (31). This increase is interpreted to be sprouting of the central projections of the DRG neurons. To test for sprouting of the peripheral DRG projections, we quantitated the number of peripheral DRG processes in the peripheral nerves of ANTI-NGF-treated compared to untreated rats, following selective surgery to eliminate motor and sympathetic nerve fibers. We report the numbers of peripheral DRG processes in an NGF-deprived environment decrease by 48% compared to untreated controls and the decrease is selective for the unmyelinated fiber population. Since the majority of the unmyelinated population is nociceptive, two nociceptive behavioral measures, one reflexive (tail flick) and one nonreflexive (paw or skin pinch), were performed and demonstrated decreased responses in the ANTI-NGF-treated compared to untreated and preimmune-treated rats. These data suggest a directional effect, primarily on the unmyelinated sensory population which results in altered nociceptive behavior, induced by the suppression of one endogenous factor, NGF. Furthermore, it is important to note that the centrally directed sensory processes project to a central nervous system environment and the peripherally directed processes are in a peripheral nervous system environment. Thus, a single molecule may have different effects on directional growth of a neuronal population that may be related to the interactions available in the substrate of the environment.

A ciliary neuronotrophic factor from peripheral nerve and smooth muscle which is not retrogradely transported

We have found that a CNTF-like molecule which supports ciliary and sympathetic neurons is not retrogradely transported in either sympathetic or parasympathetic nerves. The factor has an apparent Mr of 21 kDa, a pI of 4.9, and is present in peripheral nerves and smooth muscle of the chick. Our experiments indicate that CNTF-like activity does not accumulate on the distal side of ligated chick expansor nerves. In contrast, there is a clear accumulation of NGF. The activity further differs from NGF in that it is not removed from a smooth muscle of the chick wing by innervating sympathetic fibers. Transection of these fibers does not lead to an accumulation of ciliary activity in the expansor secundariorum muscle, suggesting that neurons do not actively deplete the muscle of factor by retrograde transport. Finally, recombinant CNTF or semi-purified preparations of CNTF-like activity labelled with 125I were not transported to the ciliary ganglion of chicks following injection of biologically active material into the eye. Our results suggest either that endogenous CNTF does not act as a survival factor in vivo, or that retrograde transport is not a property inherent to all neuronotrophic molecules.

Blot and culture analysis of neuronotrophic factors in nerve regeneration chamber fluids

The fluid accumulating in silicone nerve regeneration chambers implanted between the cut ends of rat sciatic nerve contains neuronotrophic activities towards embryonic chick ciliary and sympathetic neurons. The blot and culture technique of Carnow et al. was used to determine if part of the neuronotrophic activities is due to ciliary neuronotrophic factor, which supports the survival of both types of neurons in vitro. The technique involves separating the fluid proteins by SDS-polyacrylamide gel electrophoresis, Western transfer, and then culturing of purified neurons on the nitrocellulose blots. After 24 hr surviving neurons are restricted to regions of the blot where neuronotrophic factor is present. Analysis of 1 and 2 day fluids showed that a multitude of factors are present, particularly in the 19-30 kD molecular weight range, with discrete peaks of activity at molecular weights consistent with those reported for ciliary neuronotrophic factor. There were several other peaks of activity present in the fluids in addition to these.

Target dependence of motoneuronal survival: the current status

The concept that target-derived molecules are essential for the maintenance of motoneuronal survival has now received considerable support from different sources. One source of information arises from the target-related motoneuron death that occurs naturally at early developmental stages. Another source of information arises from axotomy-induced motoneuron death in adulthood. During development, the survival of motoneurons is initially target-independent. Its target dependence is expressed at a certain embryonic stage and, subsequently, motoneuronal survival becomes less dependent upon the target. It is not known how the state-switch of motoneurons is induced during development. Also, it is not certain whether naturally occurring motoneuron death during development and axotomy-induced motoneuron death in adulthood are based on the same mechanisms. Axotomy induces injury-associated disturbance in the motoneurons, in addition to elimination of the target-derived trophic supply. At present, there is no direct evidence that axotomy-induced motoneuron death in adulthood results solely from the deprivation of trophic factors from the target. The survival of motoneurons in adulthood appears to be maintained by multiple mechanisms. Some of the tropic factors that are involved in the maintenance of neuronal phenotypic expression are distinct from those involved in the maintenance of neuronal survival. There are multiple target-derived trophic factors for a given neuron.

Characterization of a target-derived neuronal cholinergic differentiation factor

The sympathetic innervation of rat sweat glands undergoes a target-induced switch from a noradrenergic to a cholinergic and peptidergic phenotype during development. Treatment of cultured sympathetic neurons with sweat gland extracts mimics many of the changes seen in vivo. Extracts induce choline acetyltransferase activity and vasoactive intestinal peptide expression in the neurons in a dose-dependent fashion while reducing catecholaminergic properties and neuropeptide Y. The cholinergic differentiation activity appears in developing glands of postnatal day 5 rats and is maintained in adult glands. It is a heat-labile, trypsin-sensitive, acidic protein that does not bind to heparin-agarose. Immunoprecipitation experiments with an antiserum directed against an N-terminal peptide of a cholinergic differentiation factor (CDF/LIF) from heart cells suggest that the sweat gland differentiation factor is not CDF/LIF. The sweat gland activity is a likely candidate for mediating the target-directed change in sympathetic neurotransmitter function observed in vivo.

Mitogenic effect of neurotrophic factors on human IMR 32 neuroblastoma cells

The effect of growth factors with neurotrophic properties on proliferation of the human IMR 32 neuroblastoma (NB) cell line was studied. A colorimetric proliferation assay and an anchorage-dependent cell culture system were used. Basic fibroblast growth factor (bFGF), nerve growth factor (NGF), neurite-inducing factor (NIF), ciliary neurotrophic factor (CNTF), and a cell-free extract from selected embryonic chick eye tissues (CIPE) were assayed for their capacity to control proliferation. Basic FGF, NGF, and CIPE stimulated proliferation of IMR 32 NB cells in serum-containing culture conditions. The NIF and CNTF had no effect. The concentration of bFGF required to induce half-maximal cell growth was 4.6 +/- 1.8 ng/ml, but the half-maximally effective dose of NGF was 7.5 +/- 2.7 ng/ml. In combination these two growth factors were additive within a small concentration range. In serum-free culture conditions bFGF affected both proliferation and cell differentiation by promoting neurite growth and cell aggregate formation. In contrast, NGF induced cell neurite outgrowth only. These results, in conjunction with the evidence that bFGF-like molecules are present, in IMR 32 NB cells may support the notion that NB cells regulate their proliferation by an autocrine mechanism. Basic FGF and NGF, two distinct neurotrophic factors, appear to be involved in the regulation of NB cell proliferation.

Ciliary neurotrophic factor supports target-deprived preganglionic sympathetic spinal cord neurons

Spinal cord neurons in the intermediolateral column (IML) that innervate the adrenal medulla require target-derived factor(s) for their maintenance in vivo. Selective destruction of the adult rat adrenal medulla causes an approximate 25% loss of Nissl-stained IML neurons between spinal cord levels Th 4 weeks after surgery. We have previously suggested that basic fibroblast growth factor (bFGF) and ciliary neurotrophic factor (CNTF) or closely related molecules are present in adrenal chromaffin cells and granules. Basic FGF supplemented in gelfoams to the medullectomized adrenal gland fully prevented IML neuron losses. These results are now extended by demonstrating that (i) CNTF administered in vivo (7.2 micrograms/gelfoam) also rescues IML neurons, and (ii) the rescue effect is abolished by splanchnicotomy, i.e. interruption of axonal pathway from the spinal cord to the adrenal gland. These data would be consistent with CNTF being a retrograde trophic messenger to the spinal cord, but do not exclude the possibility that CNTF mimics or induces the formation of an endogenous trophic factor.

Long-term support by injured brain extract of a subpopulation of ciliary ganglion neurons purified by differential adhesion

Ciliary ganglion neurons and nonneurons can be separated from each other, based on the greater adhesivity of the nonneurons to untreated tissue culture plastic in the presence of serum. When the separation was carried out in the presence of Serum Plus (a commercially available supplemented serum), two populations of neurons were distinguished. Neurons in the first class (50-60% of total) adhered to plastic within 15 min, tended to aggregate into clumps, and were not well supported in long term culture by brain extracts. Neuronal adhesion to plastic was inhibited by heparin but not by chondroitin sulfate. Neurons in the second class did not attach to plastic for up to 90 min (and could thus be purified), were not as prone to aggregation, and were quantitatively supported for long periods (greater than 2 weeks) by the neurotrophic factor(s) present in extracts of injured brain. Although no direct evidence is provided, these populations may correspond to the well characterized ciliary and choroid neurons.

Characterization of choline acetyltransferase-sustaining and survival-promoting activities for parasympathetic neurons in pig lung

A total of 49 tissues from six animal species were screened for substances that would sustain choline acetyltransferase (ChAT) in parasympathetic ciliary neurons in culture. Among these, lungs from several species, particularly pig, contained relatively high concentrations of ChAT-sustaining activity. The bioassay used was one in which embryonic chicken ciliary ganglia were cultured as explants for 3 days with KCl and lung extract. KCl, in the presence of lung extract, sustained high concentrations of choline acetyltransferase activity, but did not maintain enzymatic activity in the absence of lung extract. These effects were dependent on the embryonic age of the ciliary ganglia. Lung extract and KCl would not maintain choline acetyltransferase activity in parasympathetic neurons taken from chickens older than embryonic day 12. In addition to ChAT-sustaining activity, pig lung also contains survival-promoting activity for parasympathetic neurons but not for other neuronal types, including sympathetic or sensory neurons of neural crest or placodal origin. This is a more specific target spectrum than previously reported ciliary survival-promoting factors that have been purified or partially purified and indicates that survival-promoting activities in pig lung are different than those previously observed. Because of the large quantitites that can be obtained, we suggest that pig lung is a preparatively feasible source for possibly novel ciliary neuron ChAT-sustaining and survival-promoting activities for parasympathetic neurons.

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.

Purification of adult rat sciatic nerve ciliary neuronotrophic factor

The ciliary neuronotrophic factor (CNTF), a protein required for the survival of cultured avian embryonic parasympathetic ciliary ganglionic neurons, was recently purified from extracts of selected chick intraocular tissues. Here we report the purification of a mammalian CNTF activity from extracts of adult rat sciatic nerve using a fractionation procedure similar to that employed for isolating chick eye CNTF. About 2 micrograms of CNTF protein can be obtained from each 1.5 g batch of nerve tissue. Like the chick CNTF, the mammalian factor displays trophic activity for dorsal root and sympathetic as well as ciliary ganglionic neurons. The nerve CNTF activity differs from its chick counterpart in molecular weight and chromatographic behavior on ion-exchange columns. Unlike purified nerve growth factor (NGF), nerve CNTF activity is insensitive to anti-NGF antibodies and is unable to support the survival of 8-day chick embryo dorsal root ganglion neurons.

Hippocampal neurotrophic factor: characterization and response to denervation

The rat hippocampus contains an acidic macromolecular neurotrophic factor (NTF) which supports the survival of cultured chick ciliary ganglion cells. Hippocampal NTF increases approximately 2-fold from birth to adulthood with no further change with aging. Disruption of extrinsic inputs to the hippocampus from the entorhinal cortex, locus coeruleus or contralateral hippocampus, but not from the septum, results in an increase in the concentration of NTF in the hippocampus. Destruction of intrinsic hippocampal neurons by kainic acid treatment is accompanied by a large increase in hippocampal NTF, a result consistent with a glial origin for the factor. This conclusion is supported by the finding that a lesion-induced rise in NTF can be suppressed by administration of methotrexate, an inhibitor of gliosis.

Growth patterns of primary cultures dissociated from 3-day-old chick embryos: morphological and biochemical comparisons

Cultures were prepared by dissociating 3-day-old whole chick embryos and plating the dispersed cells on poly-L-lysine-coated dishes in Dulbecco's Modified Eagle's Medium with 10% fetal calf serum. By 48 hr in culture, aggregates and neuritic sprouting were observed. Long neuritic bundles connecting cell aggregates were evident by 4 days in culture. Consistent patterns throughout the lifespan of the cultures were contacts between neurites, and flat isolated cells, presumptively glial, emerged. Throughout the lifespan of the cultures, the cholinergic cell population was characterized histochemically by the method of Karnovsky and Roots and biochemically by assaying choline acetyltransferase. By 4 days in culture, all aggregates showed light cholinesterase-positive staining; however, with days in culture, several aggregates had no staining, and some positive-stained aggregates were interconnected with other aggregates showing only spotted positive staining. Choline acetyltransferase activity showed a developmental profile in agreement with the histological findings. The early presence of choline acetyltransferase activity is taken as indication of the early commitment of cholinergic neurons.

A simple, objective method to measure the activity of factors that promote neuronal survival

The activity of factors that promote short-term neuron survival (neurotrophic or neuronotrophic factors) can be quickly and objectively determined by measuring the incorporation of radiolabelled leucine or methionine during the 24 h duration of the assay. Other types of radiolabelled small molecules, such as choline or 2-deoxyglucose, can also be used but their signal/noise ratios are not as favorable under the optimal assay culture conditions. The neuronotrophic titers determined by amino acid uptake are the same as those estimated by microscopic counting of live and dead neurons.

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.

Neuronotrophic factors for mammalian brain neurons: injury induction in neonatal, adult and aged rat brain

Tissue from neonatal, adult and aged Sprague-Dawley rat brain contained low levels of survival promoting activity for embryonic neurons from various rat brain regions. This basal neuronotrophic activity was 2-fold higher in adult and 4-fold higher in aged rat brain, with respect to that in neonatal brain. Tissue extracts also contained 4-fold higher levels of neuronotoxic activity in adult and aged than in neonatal brain. Ablation of the occipital/entorhinal cortex caused a 3-fold increase in neuronotrophic activity in the tissue surrounding the wound in neonates and 4-fold in adult and aged brain, with respect to the basal levels. Maximal activities occurred at 3 days, 6 days and 15 days postlesion in neonatal, adult and aged tissue respectively, and subsequently returned to basal levels. Neuronotoxic activity was not induced following injury. The slower neuronotrophic response to injury in older animals may be one of the determinant factors of the slower recovery from brain damage observed in aging.

Electrophoretic similarity of the ciliary ganglion survival factors from different tissues and species

The survival of dissociated ciliary ganglion neurons is promoted by extracts of several different embryonic and adult tissues from two species. The survival-promoting activity in each of these extracts survives exposure to sodium dodecyl sulfate (SDS) and sulfhydryl-reducing agent and can, therefore, be subjected to SDS-polyacrylamide gel electrophoresis. Upon electrophoresis, the survival-promoting activity is recovered in a discrete peak at an apparent molecular weight of approximately 21,800 for all of the tissues examined. These results suggest that a similar molecule in each of these different tissues and species may be responsible for their ability to promote the survival of ciliary ganglion nerve cells in culture.

Differential morphologic effects of two fractions from fetal calf muscle on cultured chick ciliary ganglion cells

An extract of fetal calf striated muscle was found to support the survival, growth and differentiation of chick ciliary ganglion neurons in dissociated cell culture. The active material was precipitated in a single fraction by 35-60% ammonium sulfate. When this active fraction was passed over a concanavalin A-Sepharose column, only a portion of the activity was bound to the column and could be eluted by high salt. Both the bound and unbound fractions supported long-term neuronal survival and enhanced the neurons' capacity for acetylcholine synthesis. The two active fractions induced distinctly different morphologies in the cultures. The bound, salt-eluted fraction resulted in the extension of long, narrow multiply branched neurites with frequent varicosities, but it failed to support non-neuronal survival. The unbound, flow-through fraction caused the neurons to extend processes which aligned with each other and with the non-neuronal cells in dense networks. Striated muscle may thus possess the capacity to send more than one signal to modulate the development as well as maintain the survival of motor neurons.

Neuronotrophic activity for ciliary ganglion neurons. Induction following injury to the brain of neonatal, adult, and aged rats

The induction of neuronotrophic activity following injury to the brain of neonatal, adult, and aged Sprague-Dawley rats was compared using an improved in vitro assay. The maximal levels of activity in tissue surrounding the wound were reached at 3, 10-15, and about 15 days postlesion in neonatal, adult, and aged animals, respectively. Tissue neuronotrophic levels were always much lower in neonatal animals relative to the older animals. Accumulation of neuronotrophic activity in the gelfoam placed into the wound cavities in neonatal and adult animals lagged behind the levels in tissue by 4-5 days, suggesting that either the neuronotrophic factor itself or the cells which produce it are transferred from the tissue into the gelfoam. Relatively little activity accumulated in the gelfoam taken from aged Sprague-Dawley rats, and this observation was confirmed in aged Fischer rats. Aged animals seem to be unable to produce or release one of a number of neuronotrophic factors in response to injury.

Promotion of neurite outgrowth and cell survival in dissociated fetal rat retinal cultures by a fraction derived from a brain extract

We have reported previously that a fraction (BE) derived from a pig brain extract stimulated neurite outgrowth and cell survival from fetal rat retinal explants. The BE effects were dose dependent and could not be altered by NGF or its antiserum. In the present study we have observed that under similar culture conditions BE was also capable of stimulating neurite outgrowth and cell survival from fetal rat dissociated retinal cells. More specifically, the neurite-promoting activity of BE was found to be dose dependent over a concentration range of 0-50 micrograms/ml with a half-maximal response between 5 and 10 mg/ml. The ability of BE to stimulate neurite outgrowth was also age-related. There was a progressive decrease in the BE-mediated response between fetal day 17 and the second neonatal day. Viable process bearing cells could also be maintained in culture for at least two weeks in the presence of BE (25 micrograms/ml). In contrast, after 1 day in culture control cells began to rapidly degenerate and by days 3-5 no process-bearing cells were observed. The BE was found to exert its action primarily through a soluble factor(s) in the culture medium. However, we also report evidence for a substrate bound component of the BE which may aid in the attachment and/or neurite outgrowth phenomena.

Torpedo electromotor system development: developmentally regulated neuronotrophic activities of electric organ tissue

Explant cultures of electric lobe from 45-60 mm stage Torpedo embryos and both ganglionic and dissociated cell cultures prepared from 8-day chick ciliary ganglia have been used to determine whether the electric organs of Torpedo marmorata contain developmentally regulated neuronotrophic activity. Electric lobe explants were evaluated by measuring their neurone density, choline acetyltransferase (CAT0, and low salt, Triton X-100-soluble protein contents. Addition of soluble extracts prepared from the electric organs of late stage embryos (85-105 mm) to standard medium results in the maintenance of nearly theoretical neurone densities in electric lobe explants during a 7-day culture period. Soluble electric organ extracts from early embryonic stages (42-59 mm) do not increase neurone density relative to control cultures but cause an elevation in the CAT content of the explants over control values. On the basis of this analysis it is concluded (1) that late embryonic stage and adult electric organs contain neuronotrophic activity that allows electromotor neurones to survive in vitro and (2) that activity increases rapidly in the electric organs between the 59 nd 72 mm stages of development at a time when rapid increases in postsynaptic membrane markers in the electric organs occur and when peripheral synaptogenesis begins. The activity of late stage embryonic electric organs is heat stable and lost on dialysis. Using ciliary ganglion explants and evaluating both the initial fibre outgrowth and the CAT content after 4 days in vitro, trophic activity is found to be maximal at early embryonic stages (45-55 mm) and to decline thereafter. It is shown that the decline in activity is not due to an increase in toxicity. Using established dissociated ganglionic cell survival assays the specific activity of neuronotrophic factors allowing survival is constant between the 45 and 73 mm stages in the electric organs and then rapidly declines, but activity per electric organ increases rapidly between the 45 and 73 mm stages and then remains at a constant level. The use of poly-dl-ornithine substrates coated with heart-conditioned medium for the cell survival assay results in up to tenfold increase in the trophic titre of the electric organ extracts. The neuronotrophic activity supporting survival of ciliary motorneurones present in embryonic electric organs is heat labile and retained on dialysis. It is concluded that developing electric organs contain at least two neuronotrophic factors that have different properties and are differently regulated. Both factors may contribute during development to bringing naturally occurring electromotor neurone cell death to an end.

Neuronotrophic and neurite-promoting factors: effects on early postnatal chromaffin cells from rat adrenal medulla

Adrenal chromaffin cells from early postnatal rats maintained in culture have previously been shown to grow neuritic processes and survive better in the presence of nerve growth factor (NGF). In the present study we have quantitated the effects on chromaffin cell (postnatal day (D) 8) survival and neurite outgrowth of: NGF, ciliary neuronotrophic factor (CNTF), activities contained in various types of conditioned media (CM), and various substrata (laminin, fibronectin and polyornithine-binding neurite-promoting factor from RN 22 Schwannoma cells - PNPF). At saturating concentrations CNTF (50 ng/ml) and C6 glioma cell CM, (50-fold concentrated) supported survival over the 4-day culture period of all the chromaffin cells present in culture 2 h after seeding. NGF (50 ng/ml) and the non-concentrated CMs from primary Schwann cell and astrocytes as well as Schwannoma and C6 glioma cell cultures, achieved the maintenance of only about half the number of cells above the baseline survival as compared to CNTF and the concentrated C6-CM. These results are compatible with two subsets of D8 chromaffin cells, one only supported by CNTF and the concentrated CM and the other supported by either NGF or CNTF. Either NGF or CNTF elicited neurite outgrowth from 15-20% of the surviving cells. Combination of maximal doses of NGF and CNTF caused a small increase in neurite recruitment beyond that elicited by either factor alone. Low doses of CNTF added to the effect of NGF, shifting the NGF titration curve by about 4-fold. Neurite outgrowth was also induced by the concentrated, but not the unconcentrated C6-CM. Laminin, fibronectin and PNPF did not affect the fibronectin and PNPF did not affect the recruitment of neurites as compared to a polyornithine substratum unless the cultures were supplemented with a neuronotrophic factor and carried for 7 days. However, even before showing effects on neurite recruitment these substrata affected various neuritic performances, such as length, neurite numbers and endings per cell.

An analysis of peripheral neuronal survival factors present in muscle

Extracts of bovine heart, rat heart, and rat skeletal muscle were chromatographically separated and the fractions tested for their ability to maintain the survival of dissociated sympathetic, parasympathetic, and sensory neurones. Bovine heart contained at least five, rat heart at least six, and rat skeletal muscle at least four active components differing in their physicochemical properties and their target selectivity. Bovine and rat heart appeared to contain at least two components in common. The differences in active components found in the three tissues are consistent with a complex and perhaps tissue-specific system regulating neuronal survival.

Purification of the chick eye ciliary neuronotrophic factor

Dissociated 8-day chick embryo ciliary ganglionic neurons will not survive for even 24 h in culture without the addition of specific supplements. One such supplement is a protein termed the ciliary neuronotrophic factor (CNTF) which is present at very high concentrations within intraocular tissues that contain the same muscle cells innervated by ciliary ganglionic neurons in vivo. We describe here the purification of chick eye CNTF by a 2 1/2-day procedure involving the processing of intraocular tissue extract sequentially through DE52 ion-exchange chromatography, membrane ultrafiltration-concentration, sucrose density gradient ultracentrifugation, and preparative sodium dodecyl sulfate-polyacrylamide gradient electrophoresis. An aqueous extract of the tissue from 300 eyes will yield about 10-20 micrograms of biologically active, electrophoretically pure CNTF with a specific activity of 7.5 X 10(6) trophic units/mg protein. Purified CNTF has an Mr of 20,400 daltons and an isoelectric point of about 5, as determined by analytical gel electrophoresis. In addition to supporting the survival of ciliary ganglion neurons, purified CNTF also supports the 24-h survival of cultured neurons from certain chick and rodent sensory and sympathetic ganglia. CNTF differs from mouse submaxillary nerve growth factor (NGF) in molecular weight, isoelectric point, inability to be inactivated by antibodies to NGF, ability to support the in vitro survival of the ciliary ganglion neurons, and inability to support that of 8-day chick embryo dorsal root ganglionic neurons. Thus, CNTF represents the first purified neuronotrophic factor which addresses parasympathetic cholinergic neurons.

Neurite-promoting factors and extracellular matrix components accumulating in vivo within nerve regeneration chambers

The outgrowth of neurites from cultured neurons can be induced by the extracellular matrix glycoproteins, fibronectin and laminin, and by polyornithine-binding neurite-promoting factors (NPFs) derived from culture media conditioned by Schwann, or other cultured cells. We have examined the occurrence of fibronectin, laminin and NPFs during peripheral nerve regeneration in vivo. A previously established model of peripheral nerve regeneration was used in which a transected rat sciatic nerve regenerates through a silicone chamber bridging a 10 mm interstump gap. The distribution of fibronectin and laminin during regeneration was assessed by indirect immunofluorescence. Seven days after nerve transection the regenerating structure within the chamber consisted primarily of a fibrous matrix which stained with anti-fibronectin but not anti-laminin. At 14 days, cellular outgrowths from the proximal and distal stumps (along which neurites grow) had entered the fibronectin-containing matrix, consistent with a role of fibronectin in promoting cell migration. Within these outgrowths non-vascular as well as vascular cells stained with anti-fibronectin and anti-laminin. Within the degenerated distal nerve segment, cell characteristic of Bungner bands (rows of Schwann cells along which regenerating neurites extend) stained with anti-fibronectin and laminin. The fluid surrounding the regenerating nerve was found to contain NPF activity for cultured ciliary ganglia neurons which markedly increased during the period of neurite growth into the chamber. In previous studies using this particular neurite-promoting assay, laminin but to a much lesser extent fibronectin also promoted neurite outgrowth.(ABSTRACT TRUNCATED AT 250 WORDS)

Neurite-promoting activities for embryonic spinal neurons and their developmental changes in the chick

Spinal motoneurons may depend upon muscle-derived factors for axon outgrowth and stabilization at two principal stages of their development: during the initial invasion of the differentiating muscle masses in the embryo and during the perinatal regression of multiple innervation. Using a bioassay involving the measurement of neurite outgrowth from 4.5-day embryonic chick spinal neurons in dissociated cell culture, neurite-promoting activities were detected both in medium conditioned over embryonic chicken myotubes in vitro (embryonic muscle-conditioned medium) and in soluble extracts of chick leg muscle prepared 3-5 days after hatching (postnatal muscle extract). The molecules responsible for these two activities had physicochemical properties that distinguished them both from each other and from some other reported neurite-promoting factors. The factor in embryonic muscle-conditioned medium, although active on uncoated tissue culture wells, bound with only low affinity to tissue culture plastic under cell culture conditions. It was inactivated by incubation with trypsin, and was essentially found only in media conditioned by muscle and liver cells. The factor in PNME, on the other hand, bound to plastic culture wells and was found in extracts of a variety of tissues. Its concentration in postnatal leg muscle was developmentally regulated: the specific activity increased approximately 10-fold between hatching and Day 3 (maximum value: 3200 units/mg protein) and then fell back to nearly its original levels by Day 7. Evidence is presented that the observed effects of these two neurite-promoting factors did not result from differential survival in vitro of different cell subpopulations. Possible roles for the two active factors during motoneuron development are discussed.

Effects of corticosterone on chick embryonic retinal cells in culture

Corticosterone has been shown to affect several patterns of glial cell and neuronal development. We have previously reported that exogenously administered corticosterone preferentially accumulated into the retinas of 8-day-old chick embryos. Moreover, we observed that it affects muscarinic cholinergic binding. Thus, we investigated the effect of different concentrations of corticosterone on retinal cells in culture. Retinas were dissected from 8-day-old embryos, dissociated and cells plated on salt-precipitated collagen. At day 5, cultures were treated with corticosterone (from 10(-9) M to 10(-7) M) for 24 h. Controls received either Dulbecco's Modified Eagle Medium (DMEM) plus 10% fetal calf serum (FCS) or DMEM only. Results show that the main effect of the hormone was inhibition of neuronal process outgrowth. Also cell aggregation, flat cell proliferation and confluency are altered in hormone-treated cultures. All these effects are reversible and can be attributed to hormone effect and not to serum deprivation.

Chemically defined requirements for the survival of cultured 8-day chick embryo ciliary ganglion neurons

We have previously demonstrated that both peripheral and central neurons from embryonic chick and newborn mouse can be maintained in a serum-free defined culture medium containing the appropriate neuronotrophic agent and the N1 supplement consisting of insulin, transferrin, putrescine, progesterone and selenite. In the present studies we have examined the short-term survival requirements of 8-day embryonic chick ciliary ganglion (CG) neurons. By comparing CG neuronal survival in our standard culture medium, Eagle's Basal Medium (EBM), with several other commercially available basal media, we have established that CG neurons also have specific requirements for pyruvate, serine and iron (Fe3+), in addition to their trophic factor (Ciliary Neuronotrophic Factor, CNTF) and the N1 supplement. The data suggest the existence of 3 subsets of CG neurons differing in their essential needs, namely: (1) those supported by glucose in the absence of pyruvate, (2) those requiring exogenous pyruvate but not serine or Fe3+, and (3) those which need pyruvate, serine and Fe3+. The minimal effective concentration of pyruvate could be decreased by a factor of 50 in the concurrent presence of serine and Fe3+. Serine was also a limiting element in the survival of some of these CG neurons. The Fe3+ concentration required by the same neurons was considerably diminished with the availability of transferrin, perhaps reflecting an increased Fe3+ transmembrane transport efficiency. Insulin was found to be the only N1 ingredient required for the survival of CG neurons. Insulin was a constant requirement for all 3 subsets of CG neurons, even when cultured in the total absence of glucose (but presence of pyruvate).