Formation of the neuromuscular junction: molecules and mechanisms

The vertebrate skeletal neuromuscular junction is the site at which motor neurons communicate with their target muscle fibers. At this synapse, as at synapses throughout the nervous system, efficient and appropriate communication requires the formation and precise alignment of specializations for transmitter release in the axon terminal with those for transmitter detection in the postsynaptic cell. Classical developmental studies demonstrate that synapse formation at the neuromuscular junction is a mutually inductive event; neurons induce postsynaptic differentiation in muscle cells and myofibers induce presynaptic differentiation in motor axon terminals. More recent experiments indicate that Schwann cells, which cap axon terminals, also play an active role in the formation and maintenance of the neuromuscular junction. Here, we review recent advances in the identification of molecules mediating such inductive interactions and the mechanisms by which they produce their effects. Although our discussion concerns events at developing neuromuscular junctions, it seems likely that similar molecules and mechanisms may act at neuron-neuron synapses in the peripheral as well as the central nervous system.     

Inhibition of protein tyrosine kinases impairs axon extension in the embryonic optic tract

The role of protein tyrosine kinase (PTK) activity in the development of the retinal projection was examined in vivo by applying inhibitors of cytoplasmic PTKs, herbimycin A and lavendustin A, to intact brain preparations of Xenopus embryos. The inhibitors were present during the period when retinal ganglion cell axons first navigate through the optic tract to reach their target, the optic tectum. A majority of inhibitor-treated retinal axons stalled at the beginning of the optic tract, leading to an 80% reduction in projection length at the highest doses. All inhibitor-treated axons that did extend into the optic tract exhibited normal pathfinding behavior. Tyrosine kinase assays of inhibitor-treated brains demonstrated that at doses at which retinal axon extension was severely impaired, PTK activity, including that of src family proteins, was reduced by 50-60%. Consistent with the in vivo findings, PTK inhibitors reduced neurite outgrowth from cultured retinal neurons by 70-80%. This contrasts with the strong enhancement of outgrowth induced by the same inhibitors in cultured chick ciliary ganglion neurons and suggests that the mediation of outgrowth by PTK activity may vary in different neuronal types. Inhibitor-treated growth cones cultured on laminin were larger than normal, suggesting that tyrosine phosphorylation can modulate growth cone-substrate adhesive interactions. Our results in vivo and in vitro provide complementary evidence that retinal axon outgrowth is inhibited by pharmacological blockers of PTK activity and indicate that inhibitor-sensitive PTKs normally play a role in promoting retinal neurite extension.     

The effects of the Rho-kinase inhibitor Y-27632 on arachidonic acid-, GTPgammaS-, and phorbol ester-induced Ca2+-sensitization of smooth muscle

The atypical low density lipoprotein (LDL) binding proteins (Mr 105 and 130 kDa; p105 and p130) in human aortic medial membranes and cultured human and rat aortic smooth muscle cells (SMC) have recently been identified as the cell adhesion glycoprotein T-cadherin. Although cadherins are generally recognized to be important regulators of morphogenesis, the function of T-cadherin in the vasculature is poorly understood. This study has examined the relationship between expression of T-cadherin and the density and proliferation status of SMC. T-cadherin (p105 and p130) levels in SMC lysates were measured on Western blots using ligand-binding techniques. T-cadherin expression was dependent upon cell density, and maximal levels were achieved at confluency. T-cadherin levels were reversibly modulated by switching cultures between serum-free (upmodulation) and serum-containing (downmodulation) conditions. Platelet-derived growth factor (PDGF)-BB, epidermal growth factor (EGF) or insulin-like growth factor (IGF) elicited a dose- and time-dependent downmodulation that was reversible after transfer of SMC to growth factor-free medium. Our results support the hypothesis that T-cadherin may function as a negative determinant of cell growth.     

Comparison of neurite outgrowth induced by intact and injured sciatic nerves: a confocal and functional analysis

Mechanisms regulating axon growth in the peripheral nervous system have been studied by means of an in vitro bioassay, the tissue section culture, in which regenerating neurons are grown on substrata made up of tissue sections. Sections from intact and degenerated sciatic nerves proved to be different in their ability to support neurite outgrowth of embryonic chick sensory neurons from both qualitative and quantitative points of view. On denervated nerve sections, the total length of neurites elaborated per neuron was almost twice that found on intact nerve sections. In addition, confocal microscopy revealed a striking difference between intact and denervated nerve substrata: on denervated nerve sections, neurites grew inside the internal structures of endoneurial Schwann cell tubes, within the underlying tissue sections, whereas on intact nerve sections neurites extended along endoneurial basal laminae but never entered Schwann cell tubes. Perturbation experiments were used to analyze some of the molecular determinants that control neurite outgrowth in this system. Antibodies directed against the beta1-integrin subunit inhibited neurite extension on both normal and degenerated rat sciatic nerve tissue. Strikingly, however, differential inhibition was observed using antibodies directed against extracellular matrix molecules. Anti-laminin-2 (merosin) antibodies drastically reduced both the percentage of growing neurons and the total length of neurites on denervated nerve sections, but they did not modify these parameters on sections of normal nerve. Taken together, these results suggest that laminin-2/merosin promotes neurite outgrowth in peripheral nerve environments but only after Wallerian degeneration, which is when axons are allowed to extend within endoneurial tubes.     

Rac1-dependent actin filament organization in growth cones is necessary for beta1-integrin-mediated advance but not for growth on poly-D-lysine

The activity of filopodia and lamellipodia determines the advance, motility, adhesion, and sensory capacity of neuronal growth cones. The shape and dynamics of these highly motile structures originate from the continuous reorganization of the actin cytoskeleton in response to extracellular signals. The small GTPases, Rac1, Rho, and CDC42, regulate the organization of actin filament structures in nonneuronal cells; yet, their role in growth cone motility and neurite outgrowth is poorly understood. We investigated in vitro the function of Rac1 in neurite outgrowth and differentiation by introducing purified recombinant mutants of Rac1 into primary chick embryo motor neurons via trituration. Endogenous Rac1 was expressed in growth cone bodies as well as in the tips and shafts of filopodia, where it often colocalized with actin filament structures. The introduction of constitutively active Rac1 resulted in an increase in rhodamine-phalloidin staining, presumably from an accumulation of actin filaments in growth cones, while dominant negative Rac1 caused a decrease in rhodamine-phalloidin staining. Nevertheless, both Rac1 mutants retarded growth cone advance, and hence attenuated neurite outgrowth and inhibited differentiation of neurites into axons and dendrites on laminin and fibronectin. In contrast, on poly-D-lysine, neither Rac1 mutant affected growth cone advance, neurite outgrowth, or neurite differentiation despite inducing similar changes in the amount of rhodamine-phalloidin staining in growth cones. Our data demonstrate that Rac1 regulates actin filament organization in neuronal growth cones and is pivotal for beta1 integrin-mediated growth cone advance, but not for growth on poly-D-lysine.     

Regulation of nerve growth mediated by inositol 1,4,5-trisphosphate receptors in growth cones

The inositol 1,4,5-trisphosphate (IP3) receptor (IP3R) acts as a Ca2+ release channel on internal Ca2+ stores. Type 1 IP3R (IP3R1) is enriched in growth cones of neurons in chick dorsal root ganglia. Depletion of internal Ca2+ stores and inhibition of IP3 signaling with drugs inhibited neurite extension. Microinjection of heparin, a competitive IP3R blocker, induced neurite retraction. Acute localized loss of function of IP3R1 in the growth cone induced by chromophore-assisted laser inactivation resulted in growth arrest and neurite retraction. IP3-induced Ca2+ release in growth cones appears to have a crucial role in control of nerve growth.     

Treatments of leprosy at the Ryukyu University Hospital

The competence of neurons to regenerate depends on their ability to initiate a program of gene expression supporting growth and on the growth-permissive properties of glial cells in the distal stump of the injured nerve. Most studies on intrinsic molecular mechanisms governing peripheral nerve regeneration have focussed on the lesion-induced expression of proteins promoting growth cone motility, neurite extension, and adhesion. However, little is known about the expression of intrinsic chemorepulsive proteins and their receptors, after peripheral nerve injury and during nerve regeneration. Here we report the effect of peripheral nerve injury on the expression of the genes encoding sema III/coll-1 and its receptor neuropilin-1, which are known to be expressed in adult sensory and/or motor neurons. We have shown that peripheral nerve crush or transection results in a decline in sema III/coll-1 mRNA expression in injured spinal and facial motor neurons. This decline was paralleled by an induction in the expression of the growth-associated protein B-50/GAP-43. As sema III/coll-1 returned to normal levels following nerve crush, B-50/GAP-43 returned to precrush levels. Thus, the decline in sema III/coll-1 mRNA coincided with sensory and motor neuron regeneration. A sustained decline in sema III/coll-1 mRNA expression was found when regeneration was blocked by nerve transection and ligation. No changes were observed in neuropilin-1 mRNA levels after injury to sensory and motor neurons, suggesting that regenerating peripheral neurons continue to be sensitive to sema III/coll-1. Therefore we propose that a decreased expression of sema III/coll-1, one of the major ligands for neuropilin-1, during peripheral nerve regeneration is an important molecular event that is part of the adaptive response related to the success of regenerative neurite outgrowth occurring following peripheral nerve injury.     

Basic fibroblast growth factor enhances the growth of postnatal neostriatal GABAergic neurons in vitro

Basic fibroblast growth factor (bFGF) significantly enhances the short-term survival of embryonic striatal neurons in vitro but has little effect on the outgrowth of striatal cells compared to neurons from other brain regions. Studies in our laboratory have shown that bFGF protects postnatal striatal cells in vitro from NMDA receptor-induced neurotoxicity. We therefore examined the effects of bFGF on the outgrowth of GABA-containing cells taken from the postnatal (Day 1) caudate-putamen and cultured for up to 3 weeks. In control cultures GABAergic neurons formed three populations based on somatic size and developed the cytoarchitectural features characteristic of dendrites, spines, and axons. In the presence of bFGF (6 pM continuously from the day of plating), small- and medium-sized GABAergic neurons showed significant increases compared to untreated controls in axon-like growth (axon length) at 6 days in culture and in both axon- and dendrite-like neurite growth (axon length and branch order, number of primary dendrites, dendrite length, and dendritic branch order) at 13 and 17 days in culture. Large GABAergic neurons were unaffected by treatment with bFGF. Striatal GABAergic neurons exposed to nerve growth factor (10 ng/ml) were not different from untreated controls. Neuron survival was also unaffected by bFGF treatment at all days in culture examined. Other observations suggested that the neurotrophic effects of bFGF were mediated by a direct action of the growth factor on striatal neurons and not glial cells. First, glial cells (identified by the immunohistochemical localization of glial fibrillary acidic protein) were unaffected by bFGF treatment at the low concentration (6 pM) used to enhance neurite growth, but did significantly proliferate at higher concentrations of bFGF (6 nM). Second, immunoreactive bFGF receptor protein was localized predominantly to the somata and processes of striatal neurons and not to glial cells in the cultures. Finally, when neurons from control cultures were briefly exposed (1 to 4 h) to bFGF at concentrations which were neurotrophic, a marked elevation in the immediate early gene protein c-fos was observed by immunohistochemistry in the nuclei of neurons, including GABAergic cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

BAX is required for neuronal death after trophic factor deprivation and during development

Members of the BCL2-related family of proteins either promote or repress programmed cell death. BAX, a death-promoting member, heterodimerizes with multiple death-repressing molecules, suggesting that it could prove critical to cell death. We tested whether Bax is required for neuronal death by trophic factor deprivation and during development. Neonatal sympathetic neurons and facial motor neurons from Bax-deficient mice survived nerve growth factor deprivation and disconnection from their targets by axotomy, respectively. These salvaged neurons displayed remarkable soma atrophy and reduced elaboration of neurities; yet they responded to readdition of trophic factor with soma hypertrophy and enhanced neurite outgrowth. Bax-deficient superior cervical ganglia and facial nuclei possessed increased numbers of neurons. Our observations demonstrate that trophic factor deprivation-induced death of sympathetic and motor neurons depends on Bax.     

Establishment and neurite outgrowth properties of neonatal and adult rat olfactory bulb glial cell lines

Two glial cell types surround olfactory axons and glomeruli in the olfactory bulb (OB) and may influence synapse development and regeneration. OB astrocytes resemble type-1 astrocytes, and OB ensheathing cells resemble non-myelinating Schwann cells. We have produced clonal OB astrocyte and ensheathing cell lines from rat neonatal and adult OB cultures by SV40 large T antigen transduction. These cell lines have been characterized by morphology, growth characteristics, immunophenotype, and ability to promote neurite outgrowth in vitro. Neonatal and adult ensheathing cell lines were found to support higher neurite outgrowth than OB astrocyte lines. Neonatal OB astrocyte lines were of two types, high and low outgrowth support. The low support astrocyte lines express J1 and a chondroitin sulfate-containing proteoglycan as do astrocytes encircling the neonatal glomeruli in vivo. The adult OB astrocyte cell lines supported lower levels of outgrowth than adult ensheathing cell lines. These results are consistent with a positive role for ensheathing cells in OB synapse regeneration, in vivo. Further, based on our results, we hypothesize that ensheathing cells and high-outgrowth astrocytes facilitate axon growth in vivo, while low outgrowth astrocytes inhibit axon growth and may facilitate glomerulus formation.     

The turgor sensor KdpD of Escherichia coli is a homodimer

We show that axon guidance of embryonic hippocampal neurons is promoted by pathways of a decapeptide (RDIAEIIKDI) derived from a neurite outgrowth domain of the gamma1 chain of laminin-1. This guidance is directly dependent on: (1) a concentration difference of the decapeptide between the peptide pathway and its surrounding areas, and (2) the optimal surface geometry of the decapeptide pathway. These results indicate that axon guidance of central neurons may proceed along a preferred substratum pathway without a concentration gradient of the guiding molecule along this pathway, or without a repulsive molecule next to the axon pathway.     

Modulation of neurite branching by protein phosphorylation in cultured rat hippocampal neurons

The control of branching of axons and dendrites is poorly understood. It has been hypothesized that branching may be produced by changes in the cytoskeleton [F.J. Diez-Guerra, J. Avila, MAP2 phosphorylation parallels dendrite arborization in hippocampal neurones in culture, NeuroReport 4 (1993) 412-419; P. Friedrich, A. Aszodi, MAP2: a sensitive cross-linker and adjustable spacer in dendritic architecture, FEBS Lett. 295 (1991) 5-9]. The assembly and stability of microtubules, which are prominent cytoskeletal elements in both axons and dendrites, are regulated by microtubule-associated proteins, including tau (predominantly found in axons) and MAP2 (predominantly found in dendrites). The phosphorylation state of tau and MAP2 modulates their interactions with microtubules. In their low-phosphorylation states, tau and MAP2 bind to microtubules and increase microtubule assembly and/or stability. Increased phosphorylation decreases these effects. Diez-Guerra and Avila [F.J. Diez-Guerra, J. Avila, MAP2 phosphorylation parallels dendrite arborization in hippocampal neurones in culture, NeuroReport 4 (1993) 412-419] found that protein phosphorylation correlates with neurite branching in cultured rat hippocampal neurons, and hypothesized that increased protein phosphorylation stimulates neurite branching. To test this hypothesis, we cultured rat hippocampal neurons in the presence of specific modulators of serine-threonine protein kinases and phosphatases. Inhibitors of several protein kinases, which would be expected to decrease protein phosphorylation, reduced branching. KT5720, an inhibitor of cyclic AMP-dependent protein kinase, and KN62, an inhibitor of Ca(2+)-calmodulin-dependent protein kinases, inhibited branching of both axons and dendrites. Calphostin C and chelerythrine, inhibitors of protein kinase C, inhibited branching of axons but not dendrites. Treatments that would be expected to increase protein phosphorylation, including inhibitors of protein phosphatases (okadaic acid, cyclosporin A and FK506) and stimulators of PKA (SP-cAMPS) or PKC (phorbol 12-myristate 13-acetate), increased dendrite branching. Only FK506 and phorbol 12-myristate 13-acetate stimulated axon branching. A subset of these agents was tested to confirm their effects on protein phosphorylation in this preparation. Okadaic acid, FK506 and SP-cAMPS all increased protein phosphorylation; KT5720 and KN62 decreased protein phosphorylation. On Western blots, the position of MAP2c extracted from cultures exposed to okadaic acid was slightly shifted toward higher molecular weight, suggesting greater phosphorylation, while the position of MAP2c from cultures exposed to KT5720 and KN62 was slightly shifted toward lower molecular weight, suggesting less phosphorylation. We conclude that protein phosphorylation modulates both dendrite branching and axon branching, but with differences in sensitivity to phosphorylation and/or dephosphorylation by specific kinases and phosphatases.     

Identification of 130 kDa cell surface LDL-binding protein from smooth muscle cells as a partially processed T-cadherin precursor

Atypical cell surface lipoprotein-binding proteins of 105 kDa and 130 kDa are present in membranes of vascular smooth muscle cells. We recently identified the 105 kDa protein from human aortic media as T-cadherin, an unusual glycosylphosphatidylinositol (GPI)-anchored member of the cadherin family of cell adhesion proteins. The goal of the present study was to determine the identity of 130 kDa lipoprotein-binding protein of smooth muscle cells. We applied different approaches that included protein sequencing of purified protein from human aortic media, the use of human T-cadherin peptide-specific antisera, and enzymatic treatment of cultured cells with trypsin and GPI-specific phospholipase C. Our results indicate that the 130 kDa protein is a partially processed form of T-cadherin which is attached to the membrane surface of smooth muscle cells via a GPI anchor and contains uncleaved N-terminal propeptide sequence. Our data disclose that, in contrast to classical cadherins, T-cadherin is expressed on the cell surface in both its precursor (130 kDa) and mature (105 kDa) forms.     

Signal transduction in vertebrate growth cones navigating in vivo

Navigating growth cones need signal transduction machinery to amplify and transmit the effects of extracellular signals throughout the growth cone. In culture, many drugs that affect second messengers are known to modulate neurite extension (with different effects on different neurons), and gradients of calcium influx and cyclic nucleotide analogs can cause growth cones to turn. However, it is not clear which of these responses are physiologically relevant, as axons grow through much more complex environments in vivo. The "exposed brain" preparation in Xenopus embryos provides an experimentally tractable system in which it is possible to study growth, pathfinding, and target recognition of retinal growth cones in vivo, while pharmacologically manipulating their signal transduction systems. These growth cones can also be easily studied in explant culture. We describe preliminary results of parallel in vivo and in vitro experiments using an array of drugs that perturb transduction molecules. Surprisingly, calcium ionophores and cyclic nucleotide analogs have no significant effect on retinal axon growth or pathfinding. Several agents including herbimycin A, ML-7, mastoparan, and RHC80267 inhibit retinal axon growth, both in vivo and in vitro, suggesting that tyrosine kinases, myosin, heterotrimeric G-proteins, and diacylglycerol lipase are important for retinal growth cones navigating in the optic pathway.     

Working with avoidant children: a clinical challenge

We examined axon-target interactions in cocultures of embryonic rat trigeminal, dorsal root, nodose, superior cervical ganglia or retina with a variety of native or foreign peripheral targets such as the whisker pad, forepaw, and heart explants. Axon growth into these peripheral target tissues was analyzed by the use of lipophilic tracer DiI. Embryonic day 15 dorsal root and trigeminal axons grew into isochronic normal and foreign cutaneous targets. Both axon populations avoided the same age heart tissue, but grew profusely into younger (embryonic day 13) or older (postnatal) heart explants. In contrast, embryonic day 15 superior cervical or nodose ganglion axons grew heavily into the same age heart and forepaw explants and to a lesser extent into the whisker pad explants. Embryonic day 15 retinal axons grew into all three peripheral targets used in this study. Primary sensory and sympathetic axons, but not retinal axons, formed target-specific patterns in the whisker pad and forepaw explants. DiI-labeling and immunostaining of primary sensory neurons in coculture revealed that these neurons retain their bipolar characteristics, and express class-specific markers such as parvalbumin, calcitonin gene-related peptide and TrkA receptors. In the whisker pad explants, axons positive for all three markers were seen to form patterns around the follicles. Our results indicate that developing peripheral targets can attract and support axon growth from a variety of sources. Whereas neurotrophins play a major role in attracting and supporting survival of subpopulations of sensory neurons, other substrate-bound or locally released molecules must regulate sensory neurite growth into specific peripheral and central targets.     

Isolation and characterisation of a diverse family of Arabidopsis two and three-fingered C2H2 zinc finger protein genes and cDNAs

The motor nerve transplantation (MNT) technique is used to transfer an intact nerve into a denervated muscle by harvesting a neurovascular pedicle of muscle containing motor endplates from the motor endplate zone of a donor muscle and implanting it into a denervated muscle. Thirty-six adult New Zealand White rabbits underwent reinnervation of the left long peroneal (LP) muscle (fast twitch) with a motor nerve graft from the soleus muscle (slow twitch). The right LP muscle served as a control. Reinnervation was assessed using microstimulatory single-fiber electromyography (SFEMG), alterations in muscle fiber typing and grouping, and isometric response curves. Neurofilament antibody was used for axon staining. The neurofilament studies provided direct evidence of nerve growth from the motor nerve graft into the adjacent denervated muscle. Median motor endplate jitter was 13 microsec preoperatively, and 26 microsec at 2 months, 29.5 microsec at 4 months, and 14 microsec at 6 months postoperatively (p < 0.001). Isometric tetanic tension studies showed a progressive functional recovery in the reinnervated muscle over 6 months. There was no histological evidence of aberrant reinnervation from any source outside the nerve pedicle. Isometric twitch responses and adenosine triphosphatase studies confirmed the conversion of the reinnervated LP muscle to a slow-type muscle. Acetylcholinesterase studies confirmed the presence of functioning motor endplates beneath the insertion of the motor nerve graft. It is concluded that the MNT technique achieves motor reinnervation by growth of new nerve fibers across the pedicle graft into the recipient muscle.     

Cooperative mechanisms between leg joints of Carausius morosus II. Motor neuron activity and influence of conditional bursting interneuron

The activity of the motor neuron pools of the protractor coxae muscle and of the thoracic part of the depressor trochanteris muscle during forward walking in the stick insect was investigated, and a spiking local interneuron, able to produce "endogenous bursting" and innervating both motor neuron pools, was identified. Extracellular recordings of the motor neurons innervating the protractor and the thoracic depressor of front, middle, and rear legs, respectively, were made with oil-hook electrodes from the peripheral nerves nl2c and nl4a while the animals were walking on a styrofoam treadwheel. The corresponding leg movements were registered and phase histograms were created with the software Spike2. Intracellular recordings were made in the neuropile of the metathoracic ganglion with glass electrodes filled with the dye Lucifer yellow. In all three legs measured (front, middle, and rear), both motor neuron pools increased their activity during the swing movement. The increase in the activity of the protractor motor neurons started at the end of the stance approximately 100 ms before reaching the posterior extreme position (PEP), and the activity of the large-sized depressor motor neurons increased as soon as the tarsus was lifted at the PEP. A local spiking interneuron was identified that excited both motor neuron pools. In 4 of 23 recordings the interneuron started to burst in synchrony with protractor and thoracic depressor motor neurons. During bursting a depolarizing stimulus reinforced and a hyperpolarizing stimulus inhibited the activity of both motor neuron pools. Thus we conclude that the thoracic part of the depressor trochanteris muscle might be a component of the neuromuscular system that shapes the swing movement. The two proximal joints, subcoxal and coxa-trochanter, connected mechanically via the thoracic part of the depressor trochanteris muscle, are also connected neurally by segmental and intersegmental spiking interneurons (this paper) and by nonspiking local interneurons (see companion paper).