Peripheral nerve extract promotes long-term survival and neurite outgrowth in cultured spinal cord neurons

The hypothesis that peripheral, skeletal muscle tissue contains a trophic factor supporting central neurons has recently been investigated in vitro by supplementing the culture medium of spinal cord neurons with muscle extracts and fractions of extract. We extended these studies asking whether or not a trophic factor is present in peripheral nerves, the connecting link between muscle and central neurons via which factors may be translocated from muscle to neurons by the retrograde transport system. Lumbar, 8-day-old chick spinal cords were dissociated into single cells and then cultured in the presence of peripheral nerve extract. Cytosine arabinoside was added to inhibit proliferation of nonneuronal cells. In the presence of nerve extract, spinal cord neurons survived for more than a month, extended numerous neurites, and showed activity of choline acetyltransferase. In the absence of extract, neurons attached and survived for a few days but then died subsequently in less than 10 days. Neurite outgrowth did not occur in the absence of extract. Withdrawal of extract from the medium of established neuronal cultures caused progressive loss of both cells and neurites. Other tissues also contained neuron supporting activity but less than that found in nerve extract. These studies indicate that peripheral nerves contain relatively high levels of spinal cord neuron-directed trophic activity, suggesting translocation of neurotrophic factor from muscle to central target neurons. The neurotrophic factor has long-term (weeks) effects, whereas short-term (days) survival is factor independent.     

Neurite Outgrowth-Promoting Factors in Extracts of Denervated Chick Skeletal Muscle

1. An extract of denervated skeletal muscle contained activity for promotion of neurite outgrowth from telencephalic neurons, as well as that from neurons in the spinal cord. A factor responsible for the activity was characterized in cultures of dissociated neurons.2. The factor acted on neurons only when they were attached to the surface of culture dishes. Since treatments with proteases and lectins reduced the outgrowth-promoting activity, the factor was thought to be a glycoprotein.3. Among the monoclonal antibodies raised against the partially purified extract, five antibodies were found to inhibit the activity for spinal and telencephalic neurons. The most potent antibody, 4D2a, recognized mainly a 63-kD protein and other minor proteins in the extract. Although the 63-kD protein was confirmed to be chick serum albumin by analysis of amino acid sequence, the purified albumin exhibited no activity.4. From these observations, the factor was found to be a glycoprotein recognized by the neutralizing antibody as one of the minor components of the extract. This factor exhibits its activity in a substrate-bound form but not in a diffusible one.     

Isolation of muscle derived stem cells from rat and its smooth muscle differentiation [corrected

We investigated whether stem cells (MDSC) from primary cultures of rat skeletal muscle can differentiate into the smooth muscle lineage in response to vascular endothelial growth factor (VEGF) and coculture with bladder smooth muscle cells. The MDSC were isolated from gastrocnemius muscle biopsies of normal 3-6 week-old Sprague-Dawley rats and purified by the preplate technique. Cells that took approximately 6 days to adhere to the collagen-coated flasks were termed late preplate (LP) cells, and were used in all the experiments. The early plate (EP) cells (pp1-pp4) contained some myogenic cells but were mostly fibroblasts (< 15% desmin+ cells) whereas the LP cells (pp5-pp6) were highly purified muscle-derived cells (pp6) (> 90% desmin+ cells). The muscle-derived stem cells (LP cells) were CD34+ or Sca-1+, CD45- and desmin+ by immunohistochemical staining. After two days of co-culture with bladder smooth muscle cells, about 25% of the muscle-derived stem cells were positive for alpha-smooth muscle actin (alpha-SMA)+. RT-PCR for alpha-SMA was positive in the VEGF stimulated MDSC, but negative in the absence of VEGF. In conclusion, rat muscle-derived stem cells exhibited stem cell properties (CD34+ or Sca-1+), and were not of hematogeous (CD45-) but of myogenic origin (desmin+). RT-PCR of alpha-SMA was positive in the VEGF stimulated muscle-derived stem cells.     

Distinct neurotrophic factors from skeletal muscle and the central nervous system interact synergistically to support the survival of cultured embryonic spinal motor neurons

Motor neurons isolated from 6-day-old embryonic chick spinal cords require muscle extract for survival in culture; however, it was found, that some motor neurons, identified by retrograde labeling with rhodamine, will survive in mixed spinal cell cultures in the absence of the extract. The motor neuron survival-promoting activity produced by spinal cells is soluble and differs from the factor present in muscle extract, the two activities acting in a synergistic manner: the spinal cell activity potentiated that of muscle to decrease its ED50 by an order of magnitude, the motor neuronal survival (30%) seen in the presence of both factors being more than the sum of their individual activities. This synergism was shown to be restricted to the action of the spinal cell factor on motor neurons, no effect of the factor being noted with sympathetic neurons. As a series of defined growth and survival factors present in the central nervous system (nerve growth factor, brain-derived neurotrophic factor, acidic and basic fibroblast growth factors) had no effect on motor neuron survival, we conclude that the molecule responsible for the motor neuron survival-promoting activity of the spinal cells is a previously undefined factor.     

Acetylcholine synthesis by chick spinal cord neurons in dissociated cell culture

Acetylcholine (ACh) synthesis was examined in cultures of chick spinal cord cells to follow the development of the cholinergic neurons. The cells, prepared from 4-day-old embryonic chick spinal cords, were grown either alone in dissociated cell cultures (SC cultures) or with chick myotubes (SC-M cultures). ACh synthesis was measured by incubating the cultures in [³Hcholine and using high-voltage paper electrophoresis to quantitate the amount of [³H]ACh present in cell extracts prepared from the labeled cultures. The amount of [³H]ACh synthesized in SC-M cultures was strictly proportional to the number of spinal cord cells used to prepare the cultures, and was linear with the time of incubation in [³H]choline for periods up to 1 hr. Maximal rates of synthesis were observed with [³H]choline concentrations in excess of 100 μM. Such rates for 1-week-old SC-M cultures were approximately 10–20 pmoles of [³H]ACh/hr/10⁵ spinal cord cells. Studies on the stability of the intracellular [³H]ACh revealed the presence of a major pool with a half-time of 20–30 min. A second, small pool decayed more rapidly. No detectable [³H]ACh was spontaneously released from the cells, suggesting that most of the decay represented intracellular degradation. Development of cholinergic neurons as monitored by [³H]ACh synthesis continued over a 2-week period in SC-M cultures and paralleled general cell growth. When examined at 1 week, SC-M cultures had about a 50% greater capacity for [³H]ACh synthesis and 60% more choline acetyltransferase activity than did SC cultures. No difference was observed in the stability of the [³H]ACh formed for the two types of cultures at 1 week, and no further difference was observed in the rates of [³H]ACh synthesis at 2 weeks. Growth of SC cultures in medium containing different amounts of chick embryo extract (2–10%) or in medium with fetal calf serum (10%) instead of extract produced only small differences in the measured rates of [³H]ACh synthesis. Thus chick spinal cord cells can undergo some of the early stages of cholinergic development in cell culture without sustained contact with skeletal myotubes, one of the normal postsynaptic target cells for the cholinergic neuron population. No absolute requirement for muscle factors was revealed under these conditions, although such factors may have been provided by other cell types in the spinal cord population or may have been present in other additions to the culture medium.     

Choline acetyltransferase activity of spinal cord cell cultures increased by co-culture with muscle and by muscle-conditioned medium

Activity of the enzyme choline acetyltransferase (CAT), which mediates the synthesis of the neurotransmitter, acetylcholine, was increased up to 20- fold in spinal cord (SC) cells grown in culture with muscle cells for 2 wk. This increase was directly related to the duration of co-culture as well as to the cell density of both the SC and muscle involved and was not affected by the presence of the acetylcholine receptor blocking agent, α-bungarotoxin. Glutamic acid decarboxylase (GAD) activity was often markedly decreased in SC-muscle cultures while the activities of acetylcholinesterase and several other enzymes were little changed. Increased CAT activity was also observed when SC cultures were maintained in medium which had been conditioned by muscle cells or by undifferentiated cells from embryonic muscle. Muscle-conditioned medium (CM) did not affect the activities of SC cell GAD or acetylcholinesterase. Dilution or concentration of the CM directly affected its ability to increase SC CAT activity , as did the duration and timing of exposure of the SC cells to the CM. The medium could be conditioned by muscle cells in the presence or absence of serum, and remained effective after dialysis or heating to 58 degrees C. Membrane filtration data were consistent with the conclusion that the active material(s) in CM had a molecular weight in excess of 50,000 daltons. We conclude that large molecular weight material that is released by muscle cells is capable of producing a specific increase in CAT activity of SC cells.     

Rescue of motoneurons from cell death by a purified skeletal muscle polypeptide: effects of the ChAT development factor, CDF

Rat skeletal muscle contains a 22 kd polypeptide that increases the level of choline acetyltransferase (ChAT) activity in cultures of embryonic rat spinal cord neurons and has been purified to homogeneity. The application of this factor, ChAT development factor or CDF, to developing chick embryos during the period of naturally occurring motoneuron cell death significantly increased the survival of motoneurons but did not affect the survival of dorsal root ganglion neurons or sympathetic preganglionic neurons (column of Terni). These results provide the first demonstration that an isolated, skeletal muscle-derived molecule can selectively enhance the survival of motoneurons in vivo and suggest that CDF may function in vivo to regulate the survival and development of motoneurons.     

Multiple Neurotrophic Factors from Skeletal Muscle: Demonstration of Effects of Basic Fibroblast Growth Factor and Comparisons with the 22-Kilodalton Choline Acetyltransferase Development Factor

Extracts of skeletal muscle contain chromatographically distinct molecules that enhance the cholinergic development of cultured embryonic rat spinal cord neurons. We have recently purified a 20-22 kilodalton anionic polypeptide choline acetyltransferase (ChAT) development factor (CDF) from rat skeletal muscle extracts that stimulates the development of ChAT activity in rat spinal cord cultures. The maximum increase in the level of ChAT activity achieved by this factor, however, is less than that achieved by the addition of the crude extract. We now show that muscle extract also contains mitogenic activity that is immunologically related to basic fibroblast growth factor (bFGF) and also that recombinant bFGF stimulates ChAT development in rat spinal cord cultures. bFGF, however, differs from CDF in its physiochemical, chromatographic, and immunological properties and by its action on nonneuronal cells. Individually, CDF and bFGF each enhance the level of ChAT activity in rat spinal cord cultures two- to threefold after 2 days of treatment. However, their combined actions result in a five- to sixfold enhancement of ChAT activity, suggesting that they are affecting cholinergic development through different means. The demonstration that extracts of rat skeletal muscle contain two biochemically and immunologically distinct polypeptides, with additive effects on cultured embryonic spinal cord neurons, provides additional evidence for the involvement of multiple target-derived neurotrophic factors in the regulation of cholinergic development.     

A neurite-promoting factor from muscle supports the survival of cultured chicken spinal motor neurons.

During embryonic development, spinal motor neurons require muscle-derived trophic factors for their survival and growth. We have recently isolated a protein from muscle that is not laminin but that still stimulates neurite outgrowth from embryonic neurons in culture. In the present study, we investigated whether this protein, which we refer to as muscle-derived neurite-promoting factor (NPF), could also promote the survival and growth of motor neurons in culture. Spinal motor neurons were isolated from 6-day-old chicken embryos by a metrizamide step-gradient centrifugation protocol. Most large cells (putative motor neurons) were found in the upper metrizamide fraction (0%-6.8% interface; fraction I). Motor neurons were identified by increased specific activity of choline acetyltransferase (CAT) and by their propensity to transport retrogradely either wheat germ agglutinin-horseradish peroxidase or the fluorescent dye, 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine per chlorate (diI), when those substances were injected into the target field. Labeled motor neurons were 2.6-fold enriched in fraction I and the specific CAT activity was 4.4-fold increased in fraction I as compared to unfractionated cells. When motor neurons were grown on muscle-derived NPF, the protein supported the survival of at least 21% of the neurons for as long as 6 days in culture. The protein showed no significant effect on either CAT specific activity or on high-affinity choline uptake by neurons. There was a substantial increase from 21% to 38% of the survival of motor neurons when a combination of muscle-derived NPF and laminin was used as the substrate. Muscle-derived NPF also promoted the survival of sensory neurons and sympathetic neurons in culture. Our results demonstrate that a neurite-promoting protein derived from muscle promotes both the survival and the outgrowth of neurites from cultured spinal motor neurons as well as from sensory and sympathetic neurons.     

A neurite-promting factor from muscle supports the survival of cultured chicken spinal motor neurons

During embryonic development, spinal motor neurons require muscle-derived trophic factors for their survival and growth. We have recently isolated a protein from muscle that is not laminin but that still stimulates neurite outgrowth from embryonic neurons in culture. In the present study, we investigated whether this protein, which we refer to as muscle-derived neurite-promoting factor (NPF), could also promote the survival and growth of motor neurons in culture. Spinal motor neurons were isolated from 6-day-old chicken embryos by a metrizamide step-gradient centrifugation protocol. Most large cells (putative motor neurons) were found in the upper metrizamide fraction (0%–6.8% interface; fraction I). Motor neurons were identified by increased specific activity of choline acetyltransferase (CAT) and by their propensity to transport retrogradely either wheat germ agglutininhorseradish peroxidase or the fluorescent dye, 1,1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine per chlorate (diI), when those substances were injected into the target field. Labeled motor neurons were 2.6-fold enriched in fraction I and the specific CAT activity was 4.4-fold increased in fraction I as compared to unfractionated cells. When motor neurons were grown on muscle-derived NPF, the protein supported the survival of at least 21% of the neurons for as long as 6 days in culture. The protein showed no significant effect on either CAT specific activity or on high-affinity choline uptake by neurons. There was a substantial increase from 21% to 38% of the survival of motor neurons when a combination of muscle-derived NPF also promoted the survival of sensory neurons and sympathetic neurons in culture. Our results demonstrate that a neurite-promoting protein derived from muscle promotes both the survival and the outgrowth of neurites from cultured spinal motor neurons as well as from sensory and sympathetic neurons.     

Biological studies of a putative avian muscle-derived neurotrophic factor that prevents naturally occurring motoneuron death in vivo

A series of in vivo studies have been carried out using the chick embryo to address several critical questions concerning the biological, and to a lesser extent, the biochemical characteristics of a putative avian muscle-derived trophic agent that promotes motoneuron survival in vivo. A partially purified fraction of muscle extract was shown to be heat and trypsin sensitive and rescued motoneurons from naturally occurring cell death in a dose-dependent fashion. Muscle extract had no effect on mitotic activity in the spinal cord and did not alter cell number when administered either before or after the normal cell death period. The survival promoting activity in the muscle extract appears to be developmentally regulated. Treatment with muscle extract during the cell death period did not permanently rescue motoneurons. The motoneuron survival-promoting activity found in skeletal muscle was not present in extracts from a variety of other tissues, including liver, kidney, lung, heart, and smooth muscle. Survival activity was also found in extracts from fetal mouse, rat, and human skeletal muscle. Conditioned medium derived from avian myotube cultures also prevented motoneuron death when administered in vivo to chick embryos. Treatment of embryos in ovo with muscle extract had no effect on several properties of developing muscles. With the exception of cranial motoneurons, treatment with muscle extract did not promote the survival of several other populations of neurons in the central and peripheral nervous system that also exhibit naturally occurring cell death. Initial biochemical characterization suggests that the activity in skeletal muscle is an acidic protein between 10 and 30 kD. Examination of a number of previously characterized growth and trophic agents in our in vivo assay have identified several molecules that promote motoneuron survival to one degree or another. These include S100β, brain-derived neurotrophic factor (BDNF), neurotrophin 4/5 (NT-4/5), ciliary neurotrophic factor (CNTF), transforming growth factor β (TGFβ), platelet-derived growth factor-AB (PDGF-AB), leukemia inhibitory factor (CDF/LIF), and insulin-like growth factors I and II (IGF). By contrast, the following agents were ineffective: nerve growth factor (NGF), neurotrophin-3 (NT3), epidermal growth factor (EGF), acidic and basic fibroblast growth factors (aFGF, bFGF), and the heparin-binding growth-associated molecule (HB-GAM). Of those agents that were effective, CDF/LIF, IGF-1 and -2, BDNF, and TGF are reported to be expressed in developing or adult muscle. Studies are underway to determine whether the survival activity found in avian muscle extract can be accounted for by one or more of these growth factors. Of all the tissue extracts and purified proteins tested here, only the neurotrophins—NGF, NT-3, and BDNF (but not NT-4/5)—rescured sensory neurons from naturally occurring cell death. © 1993 John Wiley & Sons, Inc.     

Molecular cloning and expression of a novel adhesion molecule, SC1

SC1, an integral membrane glycoprotein of 100 kd, is uniquely and transiently expressed on spinal cord motoneurons early in development and appears in peripheral neurons and several other tissues during development. SC1 has been purified by immunoaffinity techniques, and SC1 cDNA clones have been obtained by screening an E4 chick embryo phage expression library with a rabbit polyclonal antibody produced against purified SC1. The deduced protein sequence of 588 amino acids consists of a signal peptide, five immunoglobulin-like domains, a transmembrane region, and a short cytoplasmic tail. The sequence is most similar to MUC18, reported as a tumor progression marker in human melanoma. Transfection of SC1 cDNA into mammalian cells leads to cell surface expression of SC1 antigen and a subsequent increase in cell-cell adhesion. SC1 molecules bind to each other via a homophilic adhesion mechanism, independently of calcium or magnesium ions. SC1 may have a role in lateral motor column formation or neurite growth or fasciculation.     

Developmental discord among markers for cholinergic differentiation: in vitro time courses for early expression and responses to skeletal muscle extract

The effects of skeletal muscle extract on the development of CAT, ACh synthesis, high affinity choline uptake, and AChE activities were studied in dissociated ventral spinal cord cultures prepared from 14-day gestational rat embryos. In the absence of muscle extract, the development of CAT and AChE follow biphasic time courses in which they show initial declines followed by periods of steadily increasing activity. In contrast, ACh synthesis and high affinity choline uptake both gradually increase throughout the entire culture period. The presence of muscle extract both prevents the initial decline of CAT and AChE as well as stimulates the rates of development of all four cholinergic markers; however, the degrees and time courses of stimulation differ markedly. The effects of muscle extract on the kinetic and pharmacological properties of ACh synthesis and choline uptake in rat ventral cord cultures were also investigated. Cells treated with muscle extract for 2 days express both high affinity (Km = 1.6 microM) and low affinity (Km = 22 microM) choline uptake mechanisms. Control cells, on the other hand, express only low affinity uptake at this stage but develop a high affinity uptake mechanism by Day 7. During this time both ACh synthesis and high affinity choline uptake become increasingly sensitive to inhibition by hemicholinium-3. These results demonstrate that skeletal muscle factors enhance the development of cholinergic properties in embryonic spinal cord cultures. However, differences in sensitivity to muscle extract concentration, time courses of development, and degrees of stimulation suggest that these changes may involve distinct cellular mechanisms which are differentially affected by skeletal muscle factors.     

Electrophysiologic study of cultured neurons dissociated from spinal cords and dorsal root ganglia of fetal mice

Spontaneously occurring action potentials and postsynaptic potentials were recorded intracellularly from mouse spinal cord (SC) neurons and dorsal root ganglion (DRG) neurons in mixed SC and DRG cell cultures. In some SC cells, excitatory postsynaptic potentials were evoked by electrical stimulation of a nearby SC or DRG cell. SC and DRG neurons had distinguishing morphologic and electrophysiologic properties. SC neurons usually were elliptical or stellate and had several branched processes whereas DRG cells were most commonly round and had on the average only one process, but occasionally 3 or 4. Calculations from cell measurements revealed that SC neurons had less soma surface area and more process surface area than DRG cells, with a similar total surface area for each class. Lower resting membrane potentials were recorded from SC neurons, but when the capability for action potential generation was tested at comparable steady membrane potentials, most SC and less than half of DRG neurons fired repetitively to electrical stimulation. During the depolarizing and repolarizing phases of SC cell action potentials the rates of change of membrane potential were lower than for DRG cells, which had rapidly rising action potentials and a markedly negative afterpotential. An initially delayed repolarization phase was characteristic of the DRG cell action potential. Cell cultures were prepared by trypsin dissociation of spinal cords with attached spinal ganglia from fetuses of 10, 11, 12, 13, 14, and 17 days gestational age. Cell cultures grown on plastic or collagen were studied electrophysiologically at times from 16 to 94 days.     

Regulation of neurotransmitter synthesis: from neuron to gene.

We are interested in the molecular mechanisms of the regulation of neurotransmitter related gene expression by neurotrophic factors and neuronal activity. Previous work has shown that conditioned medium of muscle cells induces choline acetyltransferase (CAT) activity and represses tyrosine hydroxylase, dopamine-beta-hydroxylase and aromatic L-amino acid decarboxylase (AADC) activities in cultured sympathetic neurons. Here, we show that a new muscle-derived cell line secretes two factors which induce CAT activity in spinal cord cultures; one of those is related to LIF, a CAT inducing factor for sympathetic neurons. Preliminary data are presented on the structure of the human AADC and CAT genes. Putative promoter regions have been coupled to reporter genes; transient transfection experiments will allow us to determine the promoter elements responsible for the regulation by neurotrophic factors. We also summarize the distribution of AADC-immunoreactive cells in rat and cat brain, which will be used as a reference for the study of the specificity of expression of AADC promoter in transgenic mice.     

Development of substance P receptors on rat motoneurons in vitro.

Experiments were performed to examine the influence of interneuronal interactions on the expression of neurotransmitter receptors by developing mammalian CNS neurons. Receptors for the neuropeptide, substance P (SP), were assayed on embryonic rat motoneurons and other spinal cord neurons developing in vitro by the binding of 125I-SP to live neurons. Scatchard analysis showed the presence of high-affinity binding sites, and binding competition assays using SP, neurokinin A, or neurokinin B indicated that the high-affinity 125I-SP binding sites on these neurons were type NK1 tachykinin receptors, or SP receptors (SPRs). Neurons in the spinal cords of rats at Embryonic Day 14 displayed no SPRs. Cell-surface SPRs were detected on spinal cord neurons within 24 hr after they were placed in culture, however, and the level of 125I-SP binding increased for several days. SPRs were assayed on spinal motoneurons that had been identified by retrograde labeling with a fluorescent tracer, isolated in high purity by fluorescence-activated cell sorting (FACS), and maintained in culture. Motoneurons grown in isolation from other neurons developed SPRs in vitro along the same time course as neurons in heterogeneous spinal cord cultures. These results show that rat spinal motoneurons can express SPRs early in their development, and they suggest that the initial expression of SPRs by developing motoneurons does not require interaction with other neurons.     

Developmental changes in unique cell surface antigens of chick embryo spinal motoneurons and ganglion cells

The monoclonal antibody technique was used to investigate neuronal heterogeneity and its developmental changes in the chick embryo trunk especially at the thoracic level. We report here four monoclonal antibodies (called SC 1, SC 2, SC 3, and SC 4) that bound to cell surface antigens. These antigens appeared to be proteins or glycoproteins because of their susceptibility to trypsin. In the spinal cord, antibody SC 3 stained all cells, but antibody SC 1 specifically stained motoneurons and ventral epithelial cells. The staining of motoneurons by antibody SC 1 was transient. It appeared at early stages (stage 16-17; Hamburger and Hamilton), but decreased markedly in intensity at older stages (stage 30-31). Antibody SC 2 did not stain cells in the spinal cord. It stained only neurons in the dorsal root and sympathetic ganglia. Antibody SC 4 stained only cells derived from the neural crest at the early stages (stage 16-20). At later stages, it stained a wider population of cells, including sensory neurons, Schwann cells, and cells in the central nervous system. In the dorsal root ganglion, antibodies SC 1 and SC 2 stained only neuronal cells whereas antibodies SC 3 and SC 4 stained both neuronal and glial cells. The dorsal root ganglionic antigens recognized by these antibodies were not expressed concurrently but appeared in a developmental sequence. Staining with antibodies SC 3 and SC 4 appeared first, then SC 1, and finally SC 2. Among these four antigens, the antigens common to both neuronal and glial cells appeared earlier than the neuron specific antigens. Thus, our monoclonal antibodies revealed heterogeneities in cell surface neuronal molecules and their transient and sequential appearance during embryonic development.     

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.     

Cell Survival Characteristics and Choline Acetyltransferase Activity in Motor Neurone-Enriched Cultures from Chick Embryo Spinal Cord

The effect of muscle extract on cell survival and choline acetyltransferase (ChAT) activity in cultures of enriched cholinergic neurones from 7-day chick embryo spinal cord was examined. When neurones were grown on hydrated collagen gels, considerable cell survival and ChAT activity were obtained even in the absence of tissue extract. These parameters were stimulated twofold in the presence of skeletal muscle extract but not liver or skin extracts. The cholinergic neurotrophic activity was found to be heat- and trypsin-sensitive, nondialysable, and to act in the virtual absence of glial cells. These data are consistent with a retrogradely acting motor neurone trophic activity.     

A muscle-derived substrate-bound factor that promotes neurite outgrowth from neurons of the central and peripheral nervous systems

The development and survival of spinal motor neurons depends upon muscle-derived trophic factors. Some circumstantial evidence suggested to us that the regulatory subunit of cyclic adenosine 3':5'-monophosphate-dependent protein kinase (cAMP-dPK)-type II might be involved in neuritic outgrowth from spinal neurons. In the present study, we tested a commercial preparation of cAMP-dPK for neurite-promoting activity. Commercial cAMP-dPK-type II from skeletal and cardiac muscles elicited a significant neurite outgrowth from cultured embryonic chicken neurons when the enzyme preparation was bound to polylysine-coated substrata; type I cAMP-dPK from skeletal muscle was ineffective. Neither cAMP-dPK-type I nor -type II had a significant effect on the survival of spinal neurons in culture. Type II cAMP-dPK also stimulated neurite outgrowth from chicken cerebral hemisphere neurons, dorsal root ganglionic neurons, ciliary ganglionic neurons, and rat sympathetic ganglionic neurons in culture. The neurite-promoting activity appears to reside in a contaminant of the preparation since neither the purified regulatory nor catalytic subunits of cAMP-dPK-type II had an effect on neurite outgrowth per se from cultured neurons and since neurite-promoting activity did not correlate with [3H]cAMP binding or cAMP-dependent kinase activity. The neurite-promoting protein was then partially purified from commercial cAMP-dPK-type II by gel filtration on Sephadex G-200 followed by ion-exchange chromatography on DE-52 cellulose. Sodium dodecyl sulfate gel electrophoresis of the active protein peak revealed a major protein band (MW 50 kDa) and several minor bands (e.g., MW 200 kDa, 52 kDa, 45 kDa). Also, immunoblot analysis and immunoprecipitation revealed that the partially purified neurite-promoting protein was distinct from laminin, heparan sulfate proteoglycan, nerve growth factor, neural cell adhesion molecule, and fibronectin. Furthermore, the neurite-promoting activity was not diminished by treatment with heparinase nor was it bound to heparin conjugated to Sepharose. Our results demonstrate that a protein unrelated to laminin or its associated macromolecules and which copurifies with the type II cAMP-dPK of striated muscle stimulates neurite outgrowth from neurons of the central and peripheral nervous systems.