Choline acetyltransferase activity is increased in combined cultures of spinal cord and muscle cells from mice

Scalable, optically-responsive human neuromuscular junction model reveals convergent mechanisms of synaptic dysfunction in familial ALS

Neuromuscular junctions (NMJs) are specialized synapses that mediate communication between motor neurons and skeletal muscles and are essential for movement. The degeneration of this system can lead to symptoms observed in neuromuscular and motor neuron diseases. Studying these synapses and their degeneration has proven challenging. Prior NMJ studies heavily relied upon the use of mouse, chick, or isolated primary human cells, which have demonstrated limited fidelity for disease modeling. To enable the study of NMJ dysfunction and model genetic diseases, we, and others, have developed methods to generate human NMJs from pluripotent stem cells (PSCs), embryonic stem cells, and induced pluripotent stem cells. However, published studies have highlighted technical limitations associated with these complex in vitro NMJ models. In this study, we developed a robust PSC-derived motor neuron and skeletal muscle co-culture method, and demonstrated its sensitivity in modeling motor neuron disease. Our method spontaneously and reproducibly forms human NMJs. We developed multiwell-multielectrode array (MEA) parameters to quantify the activity of PSC-derived skeletal muscles, as well as measured the electrophysiological activity of functional human PSC-derived NMJs. We further leveraged our method to morphologically and functionally assess NMJs from the familial amyotrophic lateral sclerosis (fALS) PSCs, C9orf72 hexanucleotide (G4C2)n repeat expansion (HRE), SOD1 A5V , and TDP43 G298S to define the reproducibility and sensitivity of our system. We observed a significant decrease in the numbers and activity of PSC-derived NMJs developed from the different ALS lines compared to their respective controls. Furthermore, we evaluated a therapeutic candidate undergoing clinical trials and observed a variant-dependent rescue of functionality of NMJs. Our newly developed method provides a platform for the systematic investigation of genetic causes of NMJ neurodegeneration and highlights the need for therapeutic avenues to consider patient genotype.

Creating stem cell-derived neuromuscular junctions in vitro

Recent development of novel therapies has improved mobility and quality of life for people suffering from inheritable neuromuscular disorders. Despite this progress, the majority of neuromuscular disorders are still incurable, in part due to a lack of predictive models of neuromuscular junction (NMJ) breakdown. Improvement of predictive models of a human NMJ would be transformative in terms of expanding our understanding of the mechanisms that underpin development, maintenance, and disease, and as a testbed with which to evaluate novel therapeutics. Induced pluripotent stem cells (iPSCs) are emerging as a clinically relevant and non‐invasive cell source to create human NMJs to study synaptic development and maturation, as well as disease modeling and drug discovery. This review will highlight the recent advances and remaining challenges to generating an NMJ capable of eliciting contraction of stem cell‐derived skeletal muscle in vitro. We explore the advantages and shortcomings of traditional NMJ culturing platforms, as well as the pioneering technologies and novel, biomimetic culturing systems currently in use to guide development and maturation of the neuromuscular synapse and extracellular microenvironment. Then, we will explore how this NMJ‐in‐a‐dish can be used to study normal assembly and function of the efferent portion of the neuromuscular arc, and how neuromuscular disease‐causing mutations disrupt structure, signaling, and function.

Modeling the neuromuscular junction in vitro: an approach to study neuromuscular junction disorders

The neuromuscular junction (NMJ) is a specialized structure that works as an interface to translate the action potential of the presynaptic motor neuron (MN) in the contraction of the postsynaptic myofiber. The design of appropriate experimental models is essential to have efficient and reliable approaches to study NMJ development and function, but also to generate conditions that recapitulate distinct features of diseases. Initial studies relied on the use of tissue slices maintained under the same environment and in which single motor axons were difficult to trace. Later, MNs and muscle cells were obtained from primary cultures or differentiation of progenitors and cocultured as monolayers; however, the tissue architecture was lost. Current approaches include self-assembling 3D structures or the incorporation of biomaterials with cells to generate engineered tissues, although the incorporation of Schwann cells remains a challenge. Thus, numerous investigations have established different NMJ models, some of which are quite complex and challenging. Our review summarizes the in vitro models that have emerged in recent years to coculture MNs and skeletal muscle, trying to mimic the healthy and diseased NMJ. We expect our review may serve as a reference for choosing the appropriate experimental model for the required purposes of investigation.

A compartmentalized microfluidic neuromuscular co-culture system reveals spatial aspects of GDNF functions

Bidirectional molecular communication between the motoneuron and the muscle is vital for neuromuscular junction (NMJ) formation and maintenance. The molecular mechanisms underlying such communication are of keen interest and could provide new targets for intervention in motoneuron disease. Here, we developed a microfluidic platform with motoneuron cell bodies on one side and muscle cells on the other, connected by motor axons extending through microgrooves to form functional NMJs. Using this system, we were able to differentiate between the proximal and distal effects of oxidative stress and glial-derived neurotrophic factor (GDNF), demonstrating a dying-back degeneration and retrograde transmission of pro-survival signaling, respectively. Furthermore, we show that GDNF acts differently on motoneuron axons versus soma, promoting axonal growth and innervation only when applied locally to axons. Finally, we track for the first time the retrograde transport of secreted GDNF from muscle to neuron. Thus, our data suggests spatially distinct effects of GDNF – facilitating growth and muscle innervation at axon terminals and survival pathways in the soma.

Preparation of adult spinal cord motor neuron cultures under serum-free conditions

Spinal cord motor neuron cultures are an important tool for the study of mechanisms involved in motor neuron survival, degeneration and regeneration, volatile anesthetic-induced immobility, motor neuron disorders such as amyotrophic lateral sclerosis or spinal muscular atrophy as well as in spinal cord injury. Embryonic spinal cord motor neurons derived from rats have been successfully cultured; unfortunately, the culture of adult motor neurons has been problematic due to their short-term survival. Recently, by using a cocktail of target-derived factors, neurotrophins (brain-derived neurotrophic factor and glial cell line-derived neurotrophic factor) and a permeable cyclic adenosine monophosphate analog, we have established a reproducible protocol for long-term cultures of healthy and functional adult motor neurons (Exp Neurol 220:303-315, 2009). Here, we now describe in detail the steps that we used for the optimization of the process of isolation and maintenance of adult rat ventral horn motor neurons in vitro.

Embryonic motoneuron-skeletal muscle co-culture in a defined system

This paper describes a significant biotechnological advancement by creating a minimalist serum-free defined system to co-culture rat mammalian nerve and muscle cells in order to form functional neuromuscular junctions. To date, all the known in vitro nerve and muscle co-culture models use serum containing media; and while functional neuromuscular junctions (NMJ) are described, they failed to detail or quantify the minimum factors needed to recreate the NMJ in vitro. In this work, we demonstrate the development of a defined motoneuron and muscle co-culture system resulting in the formation of NMJs including: 1) a new culture technique, 2) a novel serum-free medium formulation and 3) a synthetic self-assembled monolayer (SAM) substrate N-1 [3-(trimethoxysilyl) propyl] diethylenetriamine (DETA). We characterized the culture by morphology, immunocytochemistry, electrophysiology and videography. This model system provides a better understanding of the minimal growth factor and substrate interactions necessary for NMJ formation and provides a basic system that can be utilized for nerve-muscle tissue engineering, regenerative medicine and development of limb prosthetics.

Differentiation of cholinergic neurons and physiological role of ciliary neurotrophic factor (CNTF)

Seven types of mRNA that differed in the 5'-non-coding region were identified for choline acetyltransferase of mouse spinal cord. These mRNAs were produced by differential splicing of pre-mRNAs transcribed from three different promoter regions. Two murine cholinergic cell lines, NS20Y and NG108-15, expressed M-type mRNA most abundantly. Using these cell lines, promotor activity in choline acetyltransferase gene was analyzed by transient assay of a reporter gene. The result indicated that there was promoter activity in the region upstream of the M-type exon and enhancer activity in the intron downstream of the M-type exon, and that this region regulated neuron-specific expression of choline acetyltransferase activity. In contrast, R-type mRNA was exclusively expressed in cultured superior cervical ganglion cells and was markedly increased by ciliary neurotrophic factor (CNTF). To analyse the physiological role of CNTF, we constructed and screened a cDNA library from human sciatic nerves and isolated two types of cDNAs for human CNTF. Sequence analysis revealed that one type of cDNA corresponded to the normal mRNA, while the other type contained a 4 bp stretch insertion within the coding region, which caused frameshift from 39th amino acid with a stop codon 24 amino acids downstream. Analysis of genomic DNA for CNTF showed that there was a point mutation from G to A in the intron of the mutated allele, which created a new splice acceptor site and generated a new mRNA species with 4 bp insertion.(ABSTRACT TRUNCATED AT 250 WORDS)

Evolution of the IL-6/class IB cytokine receptor family in the immune and nervous systems

It has been suggested that the cytokine receptor has a structure similar to immunoglobulin and this structural similarity has raised the possibility that they have evolved from a common ancestral molecule. In the early 1970s, it was discovered that developing sympathetic neurons could switch from an adrenergic to cholinergic phenotype. The search for a diffusible factor responsible for this eventually led to the identification of leukemia inhibitory factor (LIF). Cholinergic differentiation factor (CDF)/LIF has turned out to belong to the IL-6/class IB cytokine family. In this article we further speculate on a plausible molecular pathway for the IL6/class IB receptor family in the immune and nervous systems. We think that the evolution of the IL-6/class IB receptor family may have occurred in at least two major steps. Firstly, binding subunits of an IL-6 receptor and for a CDF/LIF receptor evolved and secondly, a third binding subunit of a CNTF receptor evolved. Our evolutional consideration predicts that the binding subunits generally determine the specificity of the receptors and it is possible that novel members of the cytokine family and their receptors exist in the nervous system.

Multiple mRNA species of choline acetyltransferase from rat spinal cord

A cDNA library directed by a specific primer was constructed from the rat spinal cord and screened with 32P-labeled rat choline acetyltransferase cDNA which was recently isolated in this laboratory. Sequence analysis of 29 clones indicated that there are four types of cDNA (R1-, R2-, N1- and M-types). The nucleotide sequences in these cDNAs were identical in the coding region and the first 38 bp of the 5'-noncoding region, but differed in the 5'-noncoding region upstream of -38 bp. The R1-type was identical to the cDNA previously cloned from the rat spinal cord. The M and N1-type cDNAs both had sequences homologous to that of the cDNA previously obtained from the mouse spinal cord. Polymerase chain reaction analysis confirmed the presence of these 4 types of mRNA and found another type (N2-type) of transcript. The numbers of cDNA clones isolated and the relative amounts of polymerase chain reaction products for each type of mRNA suggested that the most abundant transcript was M-type. Sequencing of the genomic clone containing the 5'-region of choline acetyltransferase mRNA revealed that these five types of mRNA species were transcribed from three different promoter regions and produced by differential splicing of the 5'-noncoding exons.

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.

The use of the optical disector to estimate the total number of neurons in the developing chick lateral motor column: effects of purified growth factors

Competition between neurons for limited amounts of trophic factors is believed to be the basis for large-scale neuronal death during the normal development of the vertebrate nervous system. In this study, an unbiased stereological counting method, an optical disector/Cavalieri combination, was used to estimate the total number of motor neurons in the lateral motor column of the developing chick and to assess the effects of four growth factors on neuronal numbers. The total number of neurons in lateral motor columns at embryonic day 6 (E6), E8, E10 and E12 were 18,747 +/- 1,369 (mean +/- SD), 15,037 +/- 1,816, 10,245 +/- 940, and 8,802 +/- 797, respectively. Daily exposure from E6 to E9 to three of the growth factors (basic fibroblast growth factor, bFGF; leukemia inhibitory factor, LIF; nerve growth factor, NGF) had no effect on total neuron number at E10. However, exposure to ciliary neurotrophic factor (CNTF) from E6 to E9 significantly increased (P less than 0.05) the number of neurons in the lateral motor column (13,610 +/- 725, compared with 10,058 +/- 204 in normal saline controls). These results are in agreement with previous reports of large scale neuronal death in the developing chick lumbar lateral motor column between E6 and E12 and confirm that exposure to growth factors such as CNTF can mitigate the course of normal ontogenetic cell death. The optical disector/Cavalieri combination is an efficient method for counting neurons: on average, following sectioning and staining, less than 30 min was required to estimate the total number of motor neurons in a lateral motor column with a coefficient of error of approximately 10%.

Effects of basic fibroblast growth factor on survival and choline acetyltransferase development of spinal cord neurons

To investigate the biological role of basic fibroblast growth factor (bFGF) for the development of the spinal cord we studied the in vitro and in vivo effects of this protein on survival and choline acetyltransferase (ChAT)-activity of embryonic chick and rat spinal cord neurons. In vitro, bFGF (ED50 1-2.8 ng/ml) supported the survival of embryonic neurons from the ventral part of the rat spinal cord (ventral spinal cord, vsc), including motoneurons. Addition of bFGF (100 ng/ml) increased the ChAT-activity in embryonic chick vsc cultures to 150% as compared to untreated cultures (100%). The effect of bFGF was dose-dependent. In vivo-application of bFGF resulted in a similar increase of ChAT-activity in chick spinal cord. Since bFGF stimulates the ChAT-activity of spinal cord neurons in vivo and in vitro we therefore conclude that this protein may have a physiological function for the transmitter development of cholinergic spinal cord neurons.

Role of fibronectin in the inhibitory effect of TGF-beta on choline acetyltransferase activity in co-cultures of spinal cord neurons and myotubes

We have recently shown that the enhanced expression of choline acetyltransferase (ChAT) activity in co-cultures of spinal cord motoneurons and muscle cells was blocked by transforming growth factor-beta (TGF-beta) (Dev. Brain Res., 57, 129-137, 1990). This study was performed to investigate the role of fibronectin in this effect. TGF-beta increased fibronectin level about 2-fold in extracellular matrix of spinal cord cells and skeletal myotubes in culture. Addition of a synthetic polypeptide that competitively inhibits fibronectin binding to its cell surface receptor recovered the TGF-beta-induced suppression of ChAT activity in co-cultures. The polypeptide did not affect ChAT activity in cultures of spinal cord cells alone or in co-cultures without TGF-beta. These results indicate that TGF-beta inhibits the stimulation of ChAT activity in spinal cord neurons in co-culture through a change in the composition and/or amount of fibronectin in the extracellular matrix at neuromuscular contacts.

Expression of choline acetyltransferase activity in a co-culture of spinal cord and skeletal muscle cells is inhibited by myogenic differentiation inhibitors

The effect of myogenic differentiation on the expression of choline acetyltransferase (ChAT) activity in co-cultured spinal cord neurons was studied. ChAT activity in spinal cord cells dissociated from 14-day mouse embryos was markedly increased when co-cultured with skeletal myotubes from 20-day embryos. This enhancement of ChAT activity was not observed in the presence of concanavalin A (ConA) or N-methyl-1-deoxynojirimycin (MDJN) which inhibits myoblast fusion, creatine phosphokinase and acetylcholinesterase activities in muscle cells. ChAT activity in spinal cord neurons cultured alone was unaffected by these agents. The inhibitory effect of ConA and MDJN was reversible, with an almost full recovery of ChAT activity following removal of the agents. Addition of ConA or MDJN after myotube formation exerted little inhibitory effect on ChAT activity. The effects of ConA and MDJN on ChAT activity in co-cultures were comparable to those on creatine phosphokinase and acetylcholinesterase. These observations indicate that the neurotrophic effects of skeletal muscle cells on spinal cord neurons are dependent on the differentiation state of the muscle cells.

Cellular incorporation and localization of fluorescent derivatives of gangliosides, cerebroside and sphingomyelin

Fluorescent dansyl derivatives of 3 natural sphingolipids (gangliosides, cerebroside and sphingomyelin) were shown to be readily taken up by culture cells (HeLa-, MDCK- and primary rat brain cells). A part of the incorporated fluorescent sphingolipids remained associated with the cells after incubation in a culture medium containing serum, showing a cellular integration of these lipids. Microscopical studies indicated a localization of incorporated lipids in distinct subcellular regions; whereas dansyl cerebroside densely stained structures suggestive of the cytoskeleton and the actin filament, dansyl sphingomyelin and dansyl gangliosides were primarily associated with the plasma membrane. The findings are consistent with the current views on the arrangement of sphingolipids in animal cells.

Inhibition by transforming growth factor beta of choline acetyltransferase stimulation in a co-culture of spinal cord and muscle cells from mice

Choline acetyltransferase (CAT) activity increased 11-fold in co-cultures of spinal cord and muscle cells from fetal mice relative to cultures of spinal cord cells alone. The addition of transforming growth factor-beta (TGF-beta) to the medium at 30 pM throughout the culture period inhibited the increase of CAT activity in the co-cultures, but did not affect the activity in cultures of spinal cord cells alone. TGF-beta did not inhibit glutamic acid decarboxylase activity in the co-cultures. Other growth factors such as epidermal growth factor, fibroblast growth factor and beta-NGF had little or no effect on CAT activity. TGF-beta markedly inhibited the fusion of myoblasts to myotubes and the expression of marker enzymes for muscle differentiation. When TGF-beta was included during muscle culture and removed before inoculation with spinal cord cells, myoblasts did not subsequently form myotubes. CAT activity in the spinal cord cells, however, markedly increased in co-cultures with the undifferentiated myoblasts. When TGF-beta was added to the co-cultures after myotube formation was complete, the increase in CAT activity was inhibited according to the length of TGF-beta treatment. These results suggest that TGF-beta inhibits the muscle-induced stimulation of CAT activity by inhibiting the production, secretion and/or action of trophic factors from muscle.

Hormonal regulation of adult sympathetic neurons: the effects of castration on neuropeptide Y, norepinephrine, and tyrosine hydroxylase activity

Previous studies utilizing the hypogastric ganglia (HG) have indicated that gonadal steroids exert organizational and activational effects on noradrenergic biochemistry. Bilateral castration of male rodents at birth prevents the normal maturation of tyrosine hydroxylase (T-OH) activity in the HG; castration during adulthood results in a progressive decline in T-OH activity. Testosterone replacement corrects both the ontogenetic and adult functional alterations in the neurotransmitter-synthesizing enzyme. The present studies in adult male rats extend these previous observations and asked the question whether gonadal steroids regulate the neurotransmitters neuropeptide Y (NPY) and norepinephrine (NE) in the HG. Adult rodents were castrated and ganglia T-OH, NPY, and NE were examined at various time points after surgery. All three indices of sympathetic neuron biochemistry declined following castration, but they exhibited different profiles. It appears that hormones may affect enzyme activity and neurotransmitter pools differently within neurons. Testosterone replacement therapy fully restored T-OH activity, and NPY and NE levels in the HG. These studies extend the activational role of testosterone in regulating sympathetic neuron neurotransmitter and neuropeptide levels as well as neurotransmitter-synthesizing enzymes.

Extracellular matrix: an immunological and biochemical (CAT and TOH activity) survey of in vitro differentiation of isolated amphibian neuroblasts

After neural induction certain cells in the neuroepithelium immediately acquire the property to express certain neural phenotypes (Duprat et al., 1984, 1987). However, the activity of almost all the specific enzymes involved in the biosynthesis of neurotransmitters is considerably higher when neurectodermal cells are cultured with chordamesodermal cells than when they are cultured alone. The stimulating effects of chordamesoderm do not appear to be due to diffusible factors (Duprat et al., 1985b). The present study was designed to investigate the role of extracellular matrix components in neuronal cell differentiation. We showed that the extracellular matrix cannot replace chordamesoderm in stimulating the biochemical differentiation of neuroblasts, although fibronectin and especially laminin stimulate morphological differentiation. We suggest that interaction between neuronal and non-neuronal cells plays an important part in functional biochemical differentiation, whereas the molecules of extracellular matrix are important for morphological differentiation.

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.

Complementary DNAs for choline acetyltransferase from spinal cords of rat and mouse: nucleotide sequences, expression in mammalian cells, and in situ hybridization

Complementary DNA clones containing the entire coding region of choline acetyltransferase (ChAT) were isolated from the spinal cords of rat and mouse. The cDNAs of rat and mouse coded for 640 and 641 amino acids, respectively, and showed 95% mutual homology and 80% homology with the cDNA of porcine ChAT. Northern blot analysis revealed a single band of 4.4 kb in the spinal cord and brain in each species. Introduction of the cDNAs into Chinese hamster ovary cells and neuron-derived cell lines, N1E115 and NG108-15, expressed a high ChAT activity, which was inhibited by a specific ChAT inhibitor. In situ hybridization using the rat cRNA probe revealed specific labeling of the motoneurons in the spinal cord and neurons in various forebrain nuclei of the rat where the existence of cholinergic neurons has been demonstrated immunohistochemically.

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.

Androgen increases the number of cells in fetal mouse spinal cord cultures: implications for motoneuron survival

Androgen effects were studied in organotypic cultures of the E12 fetal mouse lumbosacral spinal cord labeled in utero with [3H]thymidine on E10. Following continuous exposure to androgens for one month in vitro, the number of labeled cells was significantly increased in whole explants, and in hemisected segments in the presence or absence of co-cultured fetal thigh muscle. Because lumbosacral motoneurons undergo their final mitosis predominantly on E10 and thus remain permanently labeled, the results suggest that androgens increase neuronal numbers by directly modulating motoneuron survival rather than stimulating mitosis. These findings demonstrate for the first time that in addition to the well documented role of the muscle target in motoneuron survival, the direct neuronotrophic effects of androgen at the level of the spinal cord must also be considered.

Stimulation of choline acetyltransferase in spinal cord explants by limb mesenchyme

Choline acetyltransferase (ChAT) activity in developing spinal cord explants in vitro is shown to be dependent on the presence of co-cultured immature limb tissue. Frog tadpole spinal cord explants grown on collagen or polylysine expressed stage-appropriate levels of ChAT activity only when in the presence of the limb mesenchyme target. Neither skeletal muscle nor polylysine, both of which enhance neurite growth accompanied by increases in cord protein, were capable of maintaining the level of ChAT activity characteristic of these spinal cords in vivo. The results demonstrate that developmentally significant levels of ChAT can be maintained in vitro under appropriate conditions that may act in part through the maintenance of cholinergic motor neurons.

Comparison of transmitter release properties of embryonic sympathetic neurons growing in vivo and in vitro

The functional behavior of embryonic chick sympathetic neurons was determined by inducing release of [3H]norepinephrine by electrical stimulation of sympathetic neurons growing in the chick heart and in culture, with and without heart cells. A very close correspondence between the functional behavior of neurons developing with the heart cells, either in vivo or in vitro, was demonstrated. For example, the outflow of tritium from [3H]norepinephrine loaded sympathetic neurons of 15-day-old chick heart was about three times more at 10 Hz than at 1 Hz. In contrast, the outflow of tritium from 12-day-old [3H]norepinephrine loaded cultured sympathetic neurons was inversely related to the frequency of stimulation (outflow at 1 Hz was about three time more than at 10 Hz). When neurons were co-cultured with the heart cells, the frequency-outflow relationship reverted to that seen in the intact heart. Electrically-evoked outflow of tritium from the heart was reduced in a concentration-dependent manner by 3-30 nM tetrodotoxin, abolished in 0.25 mM Ca medium, and potentiated by 3 mM tetraethylammonium. In sharp contrast, the outflow evoked by stimulation of cultured neurons was neither blocked by 30-300 nM tetrodotoxin, low Ca, nor potentiated by tetraethylammonium. However, when neurons were co-cultured with heart cells, the evoked outflow was blocked by 30 nM tetrodotoxin and low Ca, and potentiated by tetraethylammonium. Veratrine (10 microM) had very little effect on the outflow from cultured neurons but induced a massive outflow from co-cultures as well as hearts. Neurons grown in a medium conditioned by the heart cells were not sensitive to tetrodotoxin and veratrine. It is implied that cultured sympathetic neurons are endowed mostly with Ca channels, and that the Na channels become functional only when neurons are grown with the target cells. This dramatic alteration in the functional behavior of neurons co-cultured with heart cells indicates that the effector organ has an important role in the development of ionic conductances of sympathetic neurons growing in the body and in culture.

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.

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.

Monoclonal antibodies to and immunoaffinity purification of choline acetyltransferase from bovine brain

Three hybridomas producing monoclonal antibodies to bovine brain choline acetyltransferase (ChAT) have been established by fusion of the spleen cells from a mouse immunized with purified enzyme with myeloma NS-1 cells. All three clones produced IgGl antibodies that reacted with enzyme protein denatured with sodium dodecyl sulfate. By using one of the monoclonal antibodies, a rapid and efficient immunoaffinity purification procedure of bovine ChAT has been established. Immunoblot analysis and immunoaffinity purification indicated that bovine ChAT is a single 68-kilodalton protein. The monoclonal antibodies will offer us a good tool to isolate the cDNA clones encoding ChAT.

Acetylcholine synthesis at the rat neuromuscular junction

Acetylcholine (ACh) synthesis in homogenates of rat soleus muscles had two components. One component, specifically inhibited by bromoacetylcholine (BrACh), had a Km for choline of 0.26 mM; the other, resistant to BrACh, had a Km for choline of 45 mM. The component with a low Km was absent from denervated muscle, and was identical in kinetic terms to ACh synthesising activity in homogenates of sciatic nerve. It is therefore considered choline acetyltransferase (ChAT)-specific. The use of BrACh as a specific inhibitor of ChAT activity allowed the calculation of ACh synthesis at individual motor end-plates in the soleus muscle of the rat: 2.1 X 10(-3) nmol h-1. Since the number of muscle fibres and the number of motor units are known for this muscle, ACh synthesis per motor unit could be calculated: 0.15 nmol h-1. It is concluded that BrACh can be used as a specific inhibitor of ChAT activity in homogenates of skeletal muscle and that its use will obviate the necessity of dividing biopsied muscle or small rodent muscles into neural and aneural segments.

Sprouting and nerve retraction in frog neuromuscular junction during ontogenesis and environmental changes

Based on recent evidence for a physiological remodeling of neuromuscular contacts (Wernig et al.), a morphometric study was performed on axon- and cholinesterase-stained cutaneous pectoris muscle of frog. The aim of this investigation was to separate changes due to aging, growth, and environmental conditions. Within a single muscle, fiber diameters, synaptic lengths, number of intraterminal branches, and lengths of abandoned gutters differ considerably (with coefficients of variation from 40 to 56%). On the other hand, these parameters are correlated and correlations hold when muscle fibers grow during ontogenesis: large muscle fibers bear larger and more complex junctions than small fibers. Obviously there exist growth regulating interactions between muscle fiber and the presynaptic nerve. To dissociate between age- and growth-related changes muscle fibers of equal diameters in frogs of different age are compared. With increase in age there is an additional increase in abandoned gutters, synaptic length, and complexity independent of muscle fiber growth. Possibly, abandoned gutters accumulate with time and synaptic length increases with age as the net outcome of continual synapse remodeling. When freshly caught frogs (October) were compared with frogs kept under laboratory conditions for a period of 16 weeks (which in addition included a change in season) the number of sprouts in a junction increased by about 2, the average length of presynaptic nerve terminals with small circumscribed contacts increased by 30-150 microns, and abandoned gutters tended to be shorter on fibers with large junctions. The hypothesis is discussed that remodeling is "inherent" to nerve terminals whereby sprouting is counterbalanced and reversed by nerve activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Studies of neurotransmitter chemistry of central nervous system neurons in primary tissue culture

Primary tissue culture methods have been applied to various areas of the central nervous system, including cerebral cortex, spinal cord, cerebellum, hippocampus, hypothalamus, striatum, mesencephalon, lower brain stem and retina. Experimental studies in vitro involving central neurotransmission are discussed here. Information gleaned from such studies impacts on neurotransmitter identification, neuronal development, patterns of receptor distribution, peptidergic transmission, transmitter metabolism, synaptogenesis and the regulation of synaptic development.

Low-molecular-weight peptide stimulates cholinergic development in ventral spinal cord cultures

Skeletal muscle extract contains a previously undocumented 1300- to 1500-Da neurotrophic factor. Incubation of ventral spinal cord neurons in the presence of this factor enhances the rate of de novo acetylcholine synthesis two- to threefold over control cells, after 6 days in culture. This effect on cholinergic activity appears to be selective, since incubation with the factor results in only slight elevations of lactate dehydrogenase activity and DNA content, and no increase in the acetylcholinesterase activity. The 1300- to 1500-Da factor is acid-stable and partially sensitive to proteolysis by proteinase K, Staphylococcus aureus V8 protease, and subtilisin, but insensitive to trypsin. These results indicate that the active moiety is a peptide. The importance of peptides as neurotransmitters or neuromodulators is well accepted, but their role in the regulation of neuronal development is not widely appreciated. The present cholinergic neurotrophic peptide is distinct from previously characterized cholinergic trophic factors and represents the first example of a small, target-derived peptide which influences cholinergic development.

Inhibition of acetylcholine receptor synthesis by conditioned medium of electrically stimulated muscle cultures

In previous studies, it has been reported that electrical stimulation of muscle cultures is followed by inhibition of acetylcholine receptor (AChR) synthesis. In the study reported here, we show that even media taken from electrically stimulated muscle cultures are capable of inhibiting receptor synthesis. This inhibition is specific, since the levels of acetylcholinesterase and creatine kinase are not reduced. The electrically stimulated myotubes probably synthesize and release to the medium a protein(s) responsible for reducing AChR synthesis.

Assays for cholinergic properties in cultured rat Schwann cells

Cultured rat Schwann cells did not contain detectable levels of choline-acetyltransferase (less than 0.5 pmol ACh min-1 mg-1 of protein) or of acetylcholinesterase and nicotinic acetylcholine receptors. After adding Schwann cells to primary rat myotube cultures, the level of cholineacetyl-transferase in the co-cultures increased after three weeks to as high as 5 pmol ACh min-1 mg-1. The activity appearing in co-cultures sedimented at approximately 4S, and was inhibited 50% by 4(1-napthylvinyl)pyridine in the concentration range of 10-50 microM. After treatment of co-cultures with anti rat neural antigen-1 (RAN-1) and complement, 70-80% of the activity was lost, suggesting that it is induced in the Schwann cells. Attempts to obtain the effect by exposure of Schwann cells to medium conditioned by the myotube cultures, or by co-culture with fibroblasts gave levels of activity at or below the limit of detection.

Increase of choline acetyltransferase by colchicine in primary cell cultures of spinal cord

Colchicine (5-10 microM) increased choline acetyltransferase (ChAT) activity 5-10-fold and suppressed acetylcholinesterase (AChE) and glutamate decarboxylase (GAD) activities to 30% and 50%, respectively, of the levels of control cells in mouse spinal cord cells cultured for several days. The synthesis of radiolabeled acetylcholine (ACh) from [14C]choline was also enhanced 4.6-fold, although the uptake of [14C]choline into cells was decreased to 80% of control level. Neither the incorporation of [3H]leucine into protein nor the total amount of protein was increased by colchicine. Vinblastine also increased ChAT activity while cytochalasin B was not effective. Immunochemical titration study revealed that the increase of ChAT activity by colchicine was due to the accumulation of ChAT molecules. Co-culture of spinal cord cells with skeletal muscle markedly stimulated ChAT activity, and the addition of colchicine to the cocultures showed greater than additive effect. These observations indicate that colchicine increases ChAT molecules in a specific manner, that the stimulatory effect of colchicine on ChAT activity is possibly mediated via the interaction with microtubules, and that the increase of ChAT activity is based on a mechanism different from that of co-cultures with skeletal muscle cells.

Neurotrophic effects of hippocampal extracts on medial septal nucleus in vitro

Within peripheral sympathetic and sensory systems, target tissue provides diffusible factors such as nerve growth factor that influence neuronal survival, growth, and differentiation. To determine whether target tissue may exert retrograde effects within the central nervous system, we have used hippocampus as a source of neurotrophic factors and cultured medial septal nucleus explants as a source of neurons that may respond to such factors. Soluble extracts from rat hippocampus enhance cholinergic activity (choline acetyltransferase, choline uptake, acetylcholine synthesis) of the rat medial septal nucleus cultured in serum-free defined medium. The enhancement is dose dependent, relatively specific for hippocampus, and varies with age, reaching a peak in 2- to 3-week-old rat hippocampus. The enhancing activity of the hippocampal extract appears to be mediated by protease-sensitive polypeptide(s) that differ from nerve growth factor in biological and chemical characteristics.

Target influences on [3H]ACh synthesis and release by ciliary ganglion neurons in vitro

The developmental influence of neuron-target interaction upon transmitter synthesis from labeled precursor and the capacity to release labeled transmitter were examined in dispersed cell cultures of embryonic ciliary ganglion neurons by comparing cultures of neurons plated alone and neurons plated upon pectoral myotubes. Of the total ACh synthesized from radiolabeled choline by neurons plated alone, more than half is via a Na+-dependent path, but a larger fraction of the synthesis is Na+ insensitive in culture than in mature neurons in vivo. In addition, at 1 week in culture the neurons lacking target failed to significantly increase ACh synthesis from the labeled choline in response to a previous high [K+]0 depolarization. Synthetic responsiveness to depolarization is a characteristic of mature nerve terminals in this preparation. One week after plating neurons onto myotube cultures, synthesis of ACh from the exogenous precursor is double that of sibling cultures lacking muscle, and prior depolarization with [K+]0 results in an increase in labeled product. Release from the labeled transmitter pool by the neurons with myotubes was also enhanced. [3H]ACh release elicited by depolarization via a Ca2+-dependent mechanism was more than fivefold higher in the cocultures. The influence of coculture with myotubes upon neuronal development is not duplicated by the neurons themselves despite formation of apparent interneuronal synapses (G. Crean, G. Pilar, J. Tuttle, and K. Vaca, 1982, J. Physiol. (London). 331, 87-104), by "fibroblasts" or medium conditioned over myotube cultures. Neurons under these conditions neither increase synthesis of [3H]ACh in response to a prior depolarization nor demonstrate enhanced basal [3H]ACh synthesis and release. Thus, coculture of embryonic ciliary ganglion neurons with a striated muscle target has a somewhat specific inductive effect, enhancing the capacity for neuronal [3H]ACh synthesis and release toward mature levels. This influence of a readily accessible target upon ciliary neuron cholinergic development in vitro may reflect a normal neuromuscular interaction occurring during embryogenesis.

Extracts of skeletal muscle increase neurite outgrowth and cholinergic activity of fetal rat spinal motor neurons

A soluble extract of rat skeletal muscle increased neurite outgrowth and cholinergic activity of dissociated ventral spinal neurons in culture. The effects were concentration-dependent, saturable, and labile in the presence of heat or trypsin. The morphological enhancement was produced only by skeletal muscle extract and decreased with developmental age, whereas the cholinergic enhancement was produced by extracts of cerebral cortex and cardiac and skeletal muscle and did not change with age. These changes were specific for ventral cord neurons, but no species specificity was observed with respect to the muscle source or the neuronal target.

Regulation of choline acetyltransferase in primary cell cultures of spinal cord by neurotransmitter L-norepinephrine

Neurotransmitter L-norepinephrine increased up to 8-fold the activity of choline acetyltransferase (CAT), the enzyme responsible for the synthesis of acetylcholine, in mouse spinal cord cells in culture grown for several days. The increase of CAT activity by L-norepinephrine was mediated by a beta-adrenergic receptor in the same manner as the response of intracellular cyclic AMP. Derivatives of cyclic AMP caused an increase of CAT activity to the level similar to that of L-norepinephrine. A cyclic AMP phosphodiesterase inhibitor, 3-isobutyl-1-methyl xanthine (IBMX), enhanced the elevation of CAT activity by L-norepinephrine. These results indicate that L-norepinephrine stimulated the synthesis of CAT molecules via the action of cyclic AMP. The pretreatment of cells with 5-fluoro-2'-deoxyuridine (FdU) markedly diminished the numbers of satellite cells and, in parallel, the responses of CAT activity to L-norepinephrine. The increase of cyclic AMP by L-norepinephrine was also reduced by pretreatment of the cells with FdU. In contrast, co-cultures of spinal cord with heart muscle markedly (30-fold) stimulated CAT activity both with and without pretreatment of FdU. The addition of L-norepinephrine and co-cultures with heart muscle showed an additive effect. These observations indicate that the stimulatory effect of L-norepinephrine on CAT activity is mostly, if not only, mediated via the interaction with satellite cells, and that the increase of CAT activity by L-norepinephrine is based on a mechanism different from that of co-cultures with heart muscle cells.

Nervous system-specific protein D2 associated with neurite outgrowth in nerve cell cultures

Dissociated cerebral cells from fetal rat brain were grown in culture for various periods. After 12 days in culture the nervous system-specific surface membrane protein D2 reached both maximal specific concentration and maximal amount. Moreover, most of this D2 protein was in the perinatal form with high electrophoretic mobility. The amount of perinatal D2 protein possibly followed the amount of neurites in this system. D2 protein was also found in 2 neuroblastoma C-1300 clones: Neuro 2a and NB 41A3. By addition of gangliosides, Neuro 2a cells could be induced to differentiate and form processes, and D2 protein was significantly increased. However, in both differentiated and undifferentiated neuroblastoma cells D2 protein was present in the adult form with slow electrophoretic mobility. NB 41A3 cells were unaffected by gangliosides and D2 protein was not changed. Thus ganglioside treatment of Neuro 2a tumor cells was followed by a cellular response only partly similar to developmental events concomitant to differentiation of primary cells.

Spinal cord neuronotrophic factors (SCNTFs): I. Bioassay of schwannoma and other conditioned media

We present a procedure for the dissociation and growth in serum-free defined culture medium of 4-day chick embryo lumbar spinal cord (LC4) neurons. LC4 neurons will not survive for even 24 h without the addition of trophic supplements (putative spinal cord neuronotrophic factors, SCNTFs). Serum-free medium conditioned over chick embryo heart and skeletal muscle, mouse Schwann and rat RN22 Schwannoma cell cultures were found to contain SCNTF activity which could be quantitated using a convenient neuronal survival bioassay. RN22 conditioned medium also contains polyornithine-binding neurite promoting factors (PNPFs) which can be physically separated from SCNTF. When SCNTF and PNPF were presented to LC4 neurons individually or in combination (i) SCNTF, but not PNPF, supported neuronal survival whereas (ii) PNPF, but not SCNTF, induced neurite production. When LC4 neurons were grown in SCNTF alone, nearly all of them exhibited a flattened, circular, 'fried-egg' morphology. The subsequent addition of PNPF caused these cells to extend long neurites with characteristic terminal growth-cone-like structures.

Increase in choline acetyltransferase activity in surgically isolated postganglionic parasympathetic neurones of the urinary bladder of adult rats

In the urinary bladder of adult male rats the choline acetyltransferase activity in postganglionic neurones isolated from the central nervous system was shown to increase markedly and rapidly following section of the contralateral postganglionic neurones. The enzyme activity of the operated bladder was 32% of the control 3 days postoperatively, while at the last observation, 25 days postoperatively, it was 86%. As judged from additional studies on totally denervated bladders and on totally decentralized bladders the increase found in the enzyme activity was not due to ingrowth of nerves from outside or to unspecific acetylcholine synthesis neither was it due to increase in bladder wall tension or to increase in tissue mass.