Glial cell line-derived neurotrophic factor and developing mammalian motoneurons: regulation of programmed cell death among motoneuron subtypes.

Because of discrepancies in previous reports regarding the role of glial cell line-derived neurotrophic factor (GDNF) in motoneuron (MN) development and survival, we have reexamined MNs in GDNF-deficient mice and in mice exposed to increased GDNF after in utero treatment or in transgenic animals overexpressing GDNF under the control of the muscle-specific promoter myogenin (myo-GDNF). With the exception of oculomotor and abducens MNs, the survival of all other populations of spinal and cranial MNs were reduced in GDNF-deficient embryos and increased in myo-GDNF and in utero treated animals. By contrast, the survival of spinal sensory neurons in the dorsal root ganglion and spinal interneurons were not affected by any of the perturbations of GDNF availability. In wild-type control embryos, all brachial and lumbar MNs appear to express the GDNF receptors c-ret and GFRalpha1 and the MN markers ChAT, islet-1, and islet-2, whereas only a small subset express GFRalpha2. GDNF-dependent MNs that are lost in GDNF-deficient animals express ret/GFRalpha1/islet-1, whereas many surviving GDNF-independent MNs express ret/GFRalpha1/GFRalpha2 and islet-1/islet-2. This indicates that many GDNF-independent MNs are characterized by the presence of GFRalpha2/islet-2. It seems likely that the GDNF-independent population represent MNs that require other GDNF family members (neurturin, persephin, artemin) for their survival. GDNF-dependent and -independent MNs may reflect subtypes with distinct synaptic targets and afferent inputs.

Cardiotrophin-1, a muscle-derived cytokine, is required for the survival of subpopulations of developing motoneurons.

Developing motoneurons require trophic support from their target, the skeletal muscle. Despite a large number of neurotrophic molecules with survival-promoting activity for isolated embryonic motoneurons, those factors that are required for motoneuron survival during development are still not known. Cytokines of the ciliary neurotrophic factor (CNTF)-leukemia inhibitory factor (LIF) family have been shown to play a role in motoneuron (MN) survival. Importantly, in mice lacking the LIFRbeta or the CNTFRalpha there is a significant loss of MNs during embryonic development. Because genetic deletion of either (or both) CNTF or LIF fails, by contrast, to perturb MN survival before birth, it was concluded that another ligand exists that is functionally inactivated in the receptor deleted mice, resulting in MN loss during development. One possible candidate for this ligand is the CNTF-LIF family member cardiotrophin-1 (CT-1). CT-1 is highly expressed in embryonic skeletal muscle, secreted by myotubes, and promotes the survival of cultured embryonic mouse and rat MNs. Here we show that ct-1 deficiency causes increased motoneuron cell death in spinal cord and brainstem nuclei of mice during a period between embryonic day 14 and the first postnatal week. Interestingly, no further loss was detectable during the subsequent postnatal period, and nerve lesion in young adult ct-1-deficient mice did not result in significant additional loss of motoneurons, as had been previously observed in mice lacking both CNTF and LIF. CT-1 is the first bona fide muscle-derived neurotrophic factor to be identified that is required for the survival of subgroups of developing motoneurons.

Activation of the protease-activated thrombin receptor (PAR)-1 induces motoneuron degeneration in the developing avian embryo.

Several studies have shown that both neuronal and glial cells express functional thrombin receptors as well as prothrombin transcripts. Recently, we (and others) have shown that alpha-thrombin induces apoptotic cell death in different neuronal cell types, including motoneurons, in culture. Thrombin-induced effects on different cells are mediated through the cell surface protease-activated thrombin receptor, PAR-1. Furthermore, it has been shown that, in contrast to thrombin, which induces proteolysis of other proteins besides its receptor, the thrombin receptor agonist peptide, serine-phenylalanine-leucine-leucine-arginine-asparagine-proline (SFLLRNP), is only known to activate this receptor. However, whether activation of the thrombin receptor in vivo affects the development of spinal cord motoneurons is not known. Here, we show that treatment with a synthetic SFLLRNP peptide induced a dose-dependent degeneration and death of spinal motoneurons both in highly enriched cultures and in the developing chick embryo in vivo. However, cotreatment with caspase inhibitors completely abolished SFLLRNP-induced motoneuron death both in vitro and in vivo. These results suggest that developing motoneurons express functionally active PAR-1 whose activation leads to cell death through stimulation of the caspase family of proteins. Our findings also suggest a novel and deleterious role for PAR-like receptors in the central nervous system, different from their previously known functions in the vascular and circulatory system.

The paralysé mouse mutant: a new animal model of anterior horn motor neuron degeneration.

The survival and morphometric characteristics of lumbar spinal motoneurons were examined in the paralysé mouse mutant. Affected (par/par) mice can be first recognized at approximately postnatal day (PN) 7 to 8 and are characterized by their smaller-than-normal body size, a progressive generalized muscle weakness, and lack of coordination. Mutant mice die by PN16-18, when they have become almost completely paralyzed. Previously, we have shown that this mutation involves alteration of several developmental aspects of the neuromuscular system. However, whether ventral (or anterior) horn motoneurons degenerate and die during the course of the disease was unknown. We report here that at the time the mutant phenotype can be first identified (i.e. approximately PN8), lumbar motoneuron numbers in the lateral motor column of the spinal cord of paralysé mice were not significantly different from those of control littermates. In contrast, by PN14, there was a significant (30 to 35%) decrease in motoneuron numbers in mutant compared to control mice. Furthermore, motoneuron (nuclear and soma) sizes were significantly decreased in the mutants at both stages examined, i.e. PN8 and PN14. These results show that the paralysé mutation involves atrophy and subsequent death of anterior horn motoneurons. Together with the rapid progression and the severity of the disease, these results suggest that the paralysé mouse may represent a good animal model for studying early-onset human motor neuron diseases such as spinal muscular atrophy.

Characterization of spinal motoneuron degeneration following different types of peripheral nerve injury in neonatal and adult mice.

Experimental lesions have been used widely to induce motoneuron (MN) degeneration as a model to test the ability of different trophic molecules to prevent lesion-induced alterations. However, the morphological mechanisms of spinal MN death following different types of lesions is not clear at the present time. In this study, we have characterized the morphological characteristics of MN cell death by examining DNA fragmentation and the ultrastructural and light microscopic morphological features of MNs following different types of spinal nerve injury (i.e., axotomy and avulsion) in the developing and adult mouse. In neonatal mice, axotomy induced cell death as well as the atrophy of MNs that survived the injury. DNA fragmentation could be detected by using the terminal deoxynucleotidyl transferase (TUNEL) method during the cell death process following neonatal axotomy, whereas TUNEL labeling was not observed following either neonatal or adult avulsion. However, with the exception of TUNEL labeling, the morphological characteristics of MN death following neonatal axotomy and avulsion were similar, and both resembled most closely the form of programmed cell death termed cytoplasmic or type 3B, which exhibits similarities as well as differences with currently accepted definitions of apoptosis. By contrast, adult avulsion resulted in a type of degeneration that resembled necrosis more closely. However, even there, the morphology was mixed, showing characteristics of both apoptosis and necrosis. These results indicate that the mode of MN degeneration is complex and is related to developmental age and type of lesion.

Pigment epithelium-derived factor promotes the survival and differentiation of developing spinal motor neurons.

Pigment epithelium-derived factor (PEDF) is a member of the serine protease inhibitor (serpin) superfamily that has been shown previously to promote the survival and/or differentiation of rat cerebellar granule neurons and human retinoblastoma cells in vitro. However, in contrast to most serpins, PEDF has no inhibitory activity against any known proteases, and its described biological activities do not appear to require the serpin-reactive loop located toward the carboxy end of the polypeptide. Because another serpin, protease nexin-1, has been shown to promote the in vivo survival and growth of motor neurons, the authors investigated the potential neurotrophic effects of PEDF on spinal cord motor neurons in highly enriched cultures and in vivo after injury. Here, it is shown that native bovine and recombinant human PEDF promoted the survival and differentiation (neurite outgrowth) of embryonic chick spinal cord motor neurons in vitro in a dose-dependent manner. A truncated form of PEDF that lacks approximately 62% of the carboxy end of the polypeptide comprising the homologous serpin-reactive loop also exhibited neurotrophic activities similar to those of the full-length protein. Furthermore, the data here showed that PEDF was transported retrogradely and prevented the death and atrophy of spinal motor neurons in the developing neonatal mouse after axotomy. These results indicate that PEDF exerts trophic effects on motor neurons, and, together with previous reports, these findings suggest that this protein may be useful as a pharmacologic agent to promote the development and maintenance of motor neurons. J. Comp. Neurol. 412:506-514, 1999. Published 1999 Wiley-Liss, Inc.

Neuromuscular development in the avian paralytic mutant crooked neck dwarf (cn/cn): further evidence for the role of neuromuscular activity in motoneuron survival.

Neuromuscular transmission and muscle activity during early stages of embryonic development are known to influence the differentiation and survival of motoneurons and to affect interactions with their muscle targets. We have examined neuromuscular development in an avian genetic mutant, crooked neck dwarf (cn/cn), in which a major phenotype is the chronic absence of the spontaneous, neurally mediated movements (motility) that are characteristic of avian and other vertebrate embryos and fetuses. The primary genetic defect in cn/cn embryos responsible for the absence of motility appears to be the lack of excitation-contraction coupling. Although motility in mutant embryos is absent from the onset of activity on embryonic days (E) 3-4, muscle differentiation appears histologically normal up to about E8. After E8, however, previously separate muscles fuse or coalesce secondarily, and myotubes exhibit a progressive series of histological and ultrastructural degenerative changes, including disarrayed myofibrils, dilated sarcoplasmic vesicles, nuclear membrane blebbing, mitochondrial swelling, nuclear inclusions, and absence of junctional end feet. Mutant muscle cells do not develop beyond the myotube stage, and by E18-E20 most muscles have almost completely degenerated. Prior to their breakdown and degeneration, mutant muscles are innervated and synaptic contacts are established. In fact, quantitative analysis indicates that, prior to the onset of muscle degeneration, mutant muscles are hyperinnervated. There is increased branching of motoneuron axons and an increased number of synaptic contacts in the mutant muscle on E8. Naturally occurring cell death of limb-innervating motoneurons is also significantly reduced in cn/cn embryos. Mutant embryos have 30-40% more motoneurons in the brachial and lumbar spinal cord by the end of the normal period of cell death. Electrophysiological recordings (electromyographic and direct records form muscle nerves) failed to detect any differences in the activity of control vs. mutant embryos despite the absence of muscular contractile activity in the mutant embryos. The alpha-ryanodine receptor that is genetically abnormal in homozygote cn/cn embryos is not normally expressed in the spinal cord. Taken together, these data argue against the possibility that the mutant phenotype described here is caused by the perturbation of a central nervous system (CNS)-expressed alpha-ryanodine receptor. The hyperinnervation of skeletal muscle and the reduction of motoneuron death that are observed in cn/cn embryos also occur in genetically paralyzed mouse embryos and in pharmacologically paralyzed avian and rat embryos. Because a primary common feature in all three of these models is the absence of muscle activity, it seems likely that the peripheral excitation of muscle by motoneurons during normal development is a major factor in regulating retrograde muscle-derived (or muscle-associated) signals that control motoneuron differentiation and survival.

Exogenous heat shock cognate protein Hsc 70 prevents axotomy-induced death of spinal sensory neurons.

Elevation of intracellular heat shock protein (Hsp)70 increases resistance of cells to many physical and metabolic insults. We tested the hypothesis that treatment with Hsc70 can also produce that effect, using the model of axotomy-induced neuronal death in the neonatal mouse. The sciatic nerve was sectioned and in some animals purified bovine brain Hsc70 was applied to the proximal end of the nerve immediately thereafter and again 3 days later. Seven days postaxotomy, the surviving sensory neurons of the lumbar dorsal root ganglion (DRG) and motoneurons of the lumbar ventral spinal cord were counted to assess cell death. Axotomy induced the death of approximately 33% of DRG neurons and 50% of motoneurons, when examined 7 days postinjury. Application of exogenous Hsc70 prevented axotomy-induced death of virtually all sensory neurons, but did not significantly alter motoneuron death. Thus, Hsc70 may prove to be useful in the repair of peripheral sensory nerve damage.

Naturally occurring and axotomy-induced motoneuron death and its prevention by neurotrophic agents: a comparison between chick and mouse.

Neuronal cell death is an important regressive event during the normal development of the peripheral and central nervous systems of many vertebrate and invertebrate species. Furthermore, when neurons are deprived of their target following axonal injury (axotomy) during embryonic, fetal, or early postnatal development, they undergo massive cell death. Both naturally occurring and axotomy-induced neuronal cell death can be prevented by treatment with growth factors or neurotrophic agents. Naturally occurring cell death of spinal MNs has been extensively studied in both avians and mammals. However, compared with mammals, there is little information on the effects of axotomy in avian species and it is not known whether trophic agents can modify axotomy-induced death in avian MNs. It is also not known whether trophic/growth factors can promote the in vivo survival of mammalian MNs during the period of naturally occurring cell death. We have examined (1) the time course of axotomy-induced death of lumbar spinal MNs in chick and mouse, and (2) the survival-promoting activity of a number of previously characterized growth and trophic factors on both programmed and axotomy-induced MN death in these two species. We show that axotomy performed on, or prior to, E12 in the chick results in a rapid decrease (i.e. 50%) in MN numbers within 3-4 days postsurgery, whereas these cells were able to survive for up to 1 week following axotomy on E14. By contrast, mouse MNs remained vulnerable to axotomy for at least 5 days after birth.(ABSTRACT TRUNCATED AT 250 WORDS)

Altered development of spinal cord in the mouse mutant (Patch) lacking the PDGF receptor alpha-subunit gene.

The platelet-derived growth factor receptor alpha subunit (PDGFR alpha) is expressed by glial precursors, glial cells, and some peripheral neurons during normal rodent development. Its ligands are expressed ubiquitously in neurons, including sensory and motor neurons. Thus, neuronally secreted PDGF-A may play a paracrine role in the development of both glial cells and peripheral neurons. The Patch (Ph) mutation, which is a deletion of the PDGFR alpha, is a homozygous embryonic lethal mutation in the mouse. Previously, several developmental abnormalities, including deficiencies in connective tissues in many organs, aberrant neural crest cell migration, and defects in non-neuronal derivatives of crest cells, have been shown to be associated with the Patch mutation. However, whether and the extent to which motor and sensory neurons are affected by the mutation are not known. Here, we have examined the survival and/or morphological differentiation of spinal motor and sensory (dorsal root ganglion) neurons during the period of naturally occurring cell death, i.e., between E14 and E18, in control and Ph/Ph mice. The results show a 65-70% decrease in motor and sensory neuron numbers in Ph/Ph mice, compared to controls, at all stages examined. Furthermore, motoneurons in Ph/Ph mice were significantly smaller than those in controls. Because of the bidirectional nature of neuron-glial cell interactions, these results suggest that PDGFR alpha plays an important role in glial cell development and, thus, indirectly in neuronal cell development or, alternatively, that PDGF and the PDGFR alpha are directly involved in peripheral neuron survival and development by an autocrine/paracrine mechanism.

Brain-derived neurotrophic factor fails to arrest neuromuscular disorders in the paralysé mouse mutant, a model of motoneuron disease.

Several new neurotrophic factors have been recently identified and shown to prevent motoneuron death in vitro and in vivo. One such agent is brain-derived neurotrophic factor (BDNF). In this study, we tested BDNF on an animal model of early-onset motoneuron disease: the paralysé mouse mutant, characterized by a progressive skeletal muscle atrophy and the loss of 30-35% of spinal lumbar motoneurons between the first and second week post-natal. The results show that subcutaneous injections of 1 or 10 mg/kg BDNF did not have any significant effect in increasing the mean survival time of mutant mice or in preventing the loss of motor function and total body weight in paralysé mice. The weight and choline acetyltransferase activity of specific muscles and the number of motoneurons in the spinal cords were identical in BDNF-treated and placebo-injected paralysé mice. These results suggest that BDNF does not act on the disease process in paralysé mice in the conditions we used. By contrast, BDNF has previously been shown to partially prevent the loss of motor function in the wobbler mouse, a suggested model of later-onset motoneuron disease. Taken together these findings suggest that BDNF acts differently on early and late-onset motoneuron diseases. It is however possible that treatment of paralysé mice with BDNF or combinations of different neurotrophic factors prior to the phenotypical expression of the paralysé mutation may prevent the loss of motor function and motoneurons in mutant mice.

Beneficial effects of insulin-like growth factor-I on wobbler mouse motoneuron disease.

Recombinant human insulin-like growth factor-I (IGF-I) is being considered as a possible therapeutic agent for the treatment of motoneuron diseases like amyotrophic lateral sclerosis. The neurological mutant mouse wobbler, carries an autosomal recessive gene (wr) and has been characterized as a model of lower motoneuron disorders with associated muscle atrophy, denervation and reinnervation. The purpose of the present study was to determine the possible beneficial effect of IGF-I administration in this mouse model. Upon diagnosis at 4 weeks of age, affected mice and their control normal littermates received human recombinant IGF-I (1 mg/kg) or vehicle solution, once a day, for 6 weeks. Body weight and grip strength were evaluated periodically during the treatment period. Mean muscle fiber diameter on biceps brachii sections, choline acetyltransferase activity in muscle extracts, and motoneuron numbers in spinal cord sections were determined. IGF-I treated wobbler mice showed a marked weight increase from 3 to 6 weeks of treatment in comparison with placebo treated mutant mice. At the end of the treatment, grip strength, estimated by dynamometer resistance, was 40% higher in IGF-I treated versus placebo treated animals. Mean muscle fiber diameter which is smaller in wobbler mice than in normal mice was increased in IGF-I treated mutants. However, in this study the muscle choline acetyltransferase activity and the number of spinal cord motoneurons were unchanged. Thus, IGF-I administration mainly results in a significant effect on the behavioral and skeletal muscle histochemical parameters of the wobbler mouse mutant.

Prevention of thrombin-induced motoneuron degeneration with different neurotrophic factors in highly enriched cultures.

Previous reports have shown that neuronal and glial cells express functionally active thrombin receptors. The thrombin receptor (PAR-1), a member of a growing family of protease activated receptors (PARs), requires cleavage of the extracellular amino-terminus domain by thrombin to induce signal transduction. Studies from our laboratory have shown that PAR-1 activation following the addition of thrombin or a synthetic thrombin receptor activating peptide (TRAP) induces motoneuron cell death both in vitro and in vivo. In addition to increasing motoneuron cell death, PAR- 1 activation leads to decreases in the mean neurite length and side branching in highly enriched motoneuron cultures. It has been suggested that motoneuron survival depends on access to sufficient target-derived neurotrophic factors through axonal branching and synaptic contacts. However, whether the thrombininduced effects on motoneurons can be prevented by neurotrophic factors is still unknown. Using highly enriched avian motoneuron cultures, we show here that alone, soluble chick skeletal muscle extracts (CMX), brain-derived neurotrophic factor (BDNF), ciliary neurotrophic factor (CNTF), and glial cell line-derived neurotrophic factor (GDNF) significantly increased motoneuron survival compared to controls, whereas nerve growth factor (NGF) did not have a significant effect on motoneuron survival. Furthermore, cotreatment with muscle-derived agents (i.e., CMX, BDNF, GDNF) significantly prevented the death of motoneurons induced by alpha-thrombin. Yet, non-muscle-derived agents (CNTF and NGF) had little or no significant effect in reversing thrombin-induced motoneuron death. CMX and CNTF significantly increased the mean length of neurites, whereas NGF, BDNF, and GDNF failed to enhance neurite outgrowth compared to controls. Furthermore, CMX and CNTF significantly prevented thrombin-induced inhibition of neurite outgrowth, whereas BDNF and GDNF only partially reversed thrombin-induced inhibition of neurite outgrowth. These findings show differential effects of neurotrophic factors on thrombin-induced motoneuron degeneration and suggest specific overlaps between the trophic and stress pathways activated by some neurotrophic agents and thrombin, respectively.

The role of thrombin-like (serine) proteases in the development, plasticity and pathology of the nervous system.

There is increasing evidence suggesting that members of the serine protease family, including thrombin, chymotrypsin, urokinase plasminogen activator, and kallikrein, may play a role in normal development and/or pathology of the nervous system. Serine proteases and their cognate inhibitors have been shown to be increased in the neural parenchyma and cerebrospinal fluid following injury to the blood brain barrier. Zymogen precursors of thrombin and thrombin-like proteases as well as their receptors have also been localized in several distinct regions of the developing or adult brain. Thrombin-like proteases have been shown to exert deleterious effects, including neurite retraction and death, on different neuronal and non-neuronal cell populations in vitro. These effects appear to be mediated through cell surface receptors and can be prevented or reversed with specific serine protease inhibitors (serpins). Furthermore, we have recently shown that treatment with protease nexin-1 (a serpin that inhibits thrombin-like proteases) promotes the survival and growth of spinal motoneurons during the period of programmed cell death and following injury. Taken together, these observations suggest that thrombin-like proteases play a deleterious role, whereas serpins promote the development and maintenance of neuronal cells. Thus, changes in the balance between serine proteases and their cognate inhibitors may lead to pathological states similar to those associated with some neurodegenerative diseases such as Alzheimer's disease. The present review summarizes the current state of research involving such serine proteases and speculates on the possible role of these thrombin-like proteases in the development, plasticity and pathology of the nervous system.

Apoptosis in the nervous system: morphological features, methods, pathology, and prevention.

For nearly 70 years apoptosis has been known to be a form of cell death distinct from necrosis as well as an important regressive event during the normal development of the nervous system. For example, in the chick, mouse, rat and human approximately 50% of postmitotic neurons die naturally during embryonic or fetal development. It is generally accepted that neurons die during this period by apoptosis. After the period of naturally occurring cell death, the surviving neurons may undergo degeneration and death due to injury or disease later either during development or in adulthood. Recently, apoptosis has been suggested to be involved in the abnormal neuronal death that occurs following axonal injury or in neurodegenerative diseases such as amyotrophic lateral sclerosis and Alzheimer's. Although little is known about the etiology of these diseases, progress is steadily being made toward understanding their underlying mechanisms. For diseases of spinal motoneurons, during the past two years gene mutations have been identified in patients with familial amyotrophic lateral sclerosis or spinal muscular atrophy. Furthermore, a number of in vitro, in vivo, and mutant animal models have been developed in order to study the factors which control motoneuron survival and/or death. Here, we review the morphological differences between necrotic and apoptotic cell death and some of the methods used to differentiate the two pathways. We also discuss motoneuron cell death during development, following injury and in disease, and its prevention by different agents, including neurotrophic factors.

Calcium influxes and calmodulin modulate the expression and physicochemical properties of acetylcholinesterase molecular forms during development in vivo.

1. Acetylcholinesterase (AcChoE; EC 3.1.1.7) exists in several molecular forms that may be anchored to cell membranes or associated with extracellular matrix. AcChoE bound to lipidic membranes is detergent extractable (DE AcChoE), whereas the enzyme associated with extracellular matrix is high salt soluble (HSS AcChoE). The latter variant is accumulated in synaptic regions by an unknown mechanism. 2. We have suggested previously that depolarization-induced Ca2+ influx is a major factor that modulates AcChoE synthesis in vivo, as well as the conversion of some DE AcChoE to HSS variant. In the present study, we have examined (i) the effects of depolarization-induced skeletal muscle inactivity and ionophore-induced Ca2+ influxes on the expression of AcChoE molecular forms and (ii) the hypothesis that Ca(2+)-dependent calmodulin may be involved in the conversion of at least some forms of DE AcChoE to HSS variant in vivo. 3. Chick embryos were treated in ovo during the early period of nerve-muscle interactions with d-tubocurarine (dTC; a competitive neuromuscular blocking agent) or with decamethonium (dMET; a depolarizing agent). Both dTC and dMET equally and significantly reduced embryonic neuromuscular activity (motility). However, dTC significantly decreased AcChoE overall activity, whereas dMET had virtually no effect on AcChoE expression, compared to controls. 4. Treatment of embryos with the Ca2+ ionophore A23187 significantly increased the total AcChoE activity as well as the DE/HSS ratio of each AcChoE molecular form. However, treatment with N-(6-Aminohexyl)-5-chloro-1-naphthalenesulfonamide (also termed W-7), a calmodulin antagonist, did not alter the total AcChoE activity, but significantly increased the DE/HSS ratio of AcChoE forms. 5. These results support the idea that (i) depolarization and/or Ca2+ influxes, but not muscle contraction, may regulate AcChoE expression in skeletal muscle and (ii) Ca(2+)-dependent calmodulin activation may be involved in the conversion of some DE AcChoE to their HSS variant in vivo.

Regulation of putative muscle-derived neurotrophic factors by muscle activity and innervation: in vivo and in vitro studies.

The normal embryonic development of spinal cord motoneurons (MNs) involves the proliferation of precursor cells followed by the degeneration of approximately 50% of postmitotic MNs during the period when nerve-muscle connections are being established. The death of MNs in vivo can be ameliorated by activity blockade and by treatment with muscle extracts. Muscle activity and innervation have been suggested to regulate the availability of putative muscle-derived neurotrophic agent(s), and MNs are thought to compete for limited amounts of these trophic agents during normal development. Thus, activity and innervation are thought to regulate MN survival by modulating trophic factor availability. We have tested this notion by examining MN survival in vivo and ChAT development in spinal cord neurons in vitro following treatments with partially purified muscle extracts from normally active, paralyzed (genetically or pharmacologically), aneural, denervated, slow tonic, and fast-twitch muscles from embryonic and postnatal animals. Extracts from active and chronically inactive embryonic avian and mouse muscles were found to be equally effective in promoting the in vivo survival of MNs in the chick embryo. Similarly, extracts from fast-twitch and slow tonic postnatal avian muscles did not differ in their ability to promote both MN survival in vivo and ChAT activity in vitro. Although aneural and control embryonic muscle extract had similar effects on ChAT development in vitro, aneural muscle extract contained somewhat less MN survival-promoting activity when tested in vivo. By contrast, denervated postnatal muscle extract was more effective in promoting both MN survival in vivo and ChAT activity in vitro than age-matched control muscle extract.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental modulation of physicochemical variants of the tailed asymmetric (16S) acetylcholinesterase by neuromuscular activity and innervation in the mouse embryo.

We have studied the physicochemical properties of acetylcholinesterase (AChE) during embryonic development of normal and functionally impaired mouse skeletal muscle, focusing on the tailed asymmetric (16S) form of the enzyme. The muscle-specific 16S AChE exists in two different variants. One is associated with extracellular matrix and is high-salt soluble (HSS, also termed hydrophilic AChE), whereas the other form is anchored to cell membranes and is detergent extractable (DE, or hydrophobic AChE). Before innervation during normal embryonic development, both hydrophilic and hydrophobic 16S AChE exist in equal amounts. After muscle innervation, there was an increase (amounting three-fold on E18) in the levels of hydrophilic vs. hydrophobic 16S AChE. This alteration of the relative proportions of the two variants of 16S AChE did not occur in chronically inactive muscles either from the mouse mutant, muscular dysgenesis, or from tetrodotoxin-treated mouse embryos. Taken together with previous reports, the present results suggest that postsynaptic membrane depolarization-induced Ca2+ fluxes are important in modulating not only the synthesis of 16S AChE, but also the relative proportions of both physicochemical variants of this molecular form of AChE.

The regulation of motoneuron survival and differentiation by putative muscle-derived neurotrophic agents: neuromuscular activity and innervation.

The chronic blockade of neuromuscular activity is known to promote the survival of developing motoneurons in vivo in the chick, mouse and rat embryo. Increased survival in this situation may reflect an activity-dependent mechanism for the regulation of trophic factor production by target cells. To test this notion, we have examined motoneuron survival in vivo and choline acetyltransferase (ChAT) development in vitro following treatment of chick embryos and rat spinal cord cultures with partially purified skeletal muscle extracts derived from normally active, chronically paralyzed and aneural embryos, and from denervated postnatal chickens. Extracts from active and paralyzed chick embryos were equally effective in promoting motoneuron survival and ChAT activity. Aneural embryonic muscle extracts were slightly less effective in promoting motoneurons survival in vivo, but were not significantly different from control extracts in the in vitro ChAT assay. Denervated postnatal muscle extracts, however, were more effective in enhancing both motoneuron survival and ChAT activity. These data indicate that: (1) the promotion of motoneuron survival in vivo by activity blockade may not be mediated by an up-regulation of trophic factor synthesis in target cells; (2) postnatal innervation may regulate the production of putative muscle-derived neurotrophic factors; and (3) the synthesis or availability of trophic agents may be regulated differently in embryonic and postnatal muscle.