Nerve Terminals Form But Fail to Mature When Postsynaptic Differentiation Is Blocked: In Vivo Analysis Using Mammalian Nerve-Muscle Chimeras

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The Journal of Neuroscience, August 15, 2000, 20(16):6077-6086

Nerve Terminals Form But Fail to Mature When Postsynaptic Differentiation Is Blocked: In Vivo Analysis Using Mammalian Nerve-Muscle Chimeras
Quyen T. Nguyen, Young-Jin Son, Joshua R. Sanes, and Jeff W. Lichtman
Department of Anatomy and Neurobiology, Washington University School of Medicine, St. Louis, Missouri 63110

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

To better understand the role of the postsynaptic cell in the differentiation of presynaptic terminals, we transplanted musclesthat lacked postsynaptic differentiation from mutant mice intonormal adult immunocompatible hosts and attached the host nerveto the grafts. Host motor axons innervated wild-type grafted musclefibers and established normal appearing chimeric neuromuscularjunctions. By repeated in vivo imaging, we found that these synapseswere stably maintained. Results were different when nerves enteredtransplanted muscles derived from mice lacking muscle-specificreceptor tyrosine kinase (MuSK) or rapsyn, muscle-specific componentsrequired for postsynaptic differentiation. Initial steps in presynapticdifferentiation (e.g., formation of rudimentary arbors and vesicleclustering at terminals) occurred when wild-type neurites contactedMuSK- or rapsyn deficient muscle fibers, either in vivo or invitro. However, wild-type terminals contacting MuSK or rapsynmutant muscle fibers were unable to mature, even when the chimeraswere maintained for up to 7 months. Moreover, in contrast to thestability of wild-type synapses, wild-type nerve terminals inmutant muscles underwent continuous remodeling. These resultssuggest that postsynaptic cells supply two types of signals tomotor axons: ones that initiate presynaptic differentiation andothers that stabilize the immature contacts so that they can mature.Normal postsynaptic differentiation appears to be dispensablefor initial stages of presynaptic differentiation but requiredfor presynapticmaturation.

Key words: neuromuscular junction; surgical chimera; postsynaptic differentiation; presynaptic maturation; mammalian; in vivo

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

During development, signals pass between nerve terminals and postsynaptic cells that are necessary for synapse formation andmaturation. Some nerve-derived signals that induce postsynapticdifferentiation have been identified, but there is less informationabout retrograde signals used by postsynaptic cells to organizepresynaptic differentiation. Nonetheless, multiple lines of evidenceindicate that retrograde signals are crucial in regulating thedevelopment of presynaptic neurons (for review, see Fitzsimondsand Poo, 1998; Sanes and Lichtman, 1999). One way to assess howpostsynaptic factors affect nerve terminal differentiation andmaturation is to examine presynaptic development in transgenicanimals that lack key components of the postsynaptic apparatus.At the neuromuscular junction (NMJ), several proteins, includingmuscle-specific receptor tyrosine kinase (MuSK) and rapsyn, havebeen shown to be essential for postsynaptic differentiation (Gautamet al., 1995, 1996; DeChiara et al., 1996; Glass et al., 1996,1997; for review, see Sanes and Lichtman, 1999). MuSK is an essentialpart of the agrin receptor complex in the myotube membrane. Rapsynis a cytoplasmic protein that is closely associated with acetylcholinereceptors (AChRs) and is essential for the aggregation of AChRsafter activation of MuSK by agrin. Accordingly, postsynaptic differentiationis profoundly disrupted in mice lacking rapsyn (Gautam et al.,1995) or MuSK (DeChiara et al., 1996).

At birth, motor axons in MuSK $-$ / $-$ and rapsyn $-$ / $-$ mutant animals show severe abnormalities, including either total absence orsmall size of terminal arborizations and diffuse growth (Gautamet al., 1995, 1996; DeChiara et al., 1996). Because MuSK and rapsynare expressed only in the postsynaptic cell, these results implythat failure of postsynaptic differentiation leads indirectlyto failure of presynaptic differentiation. However, because thesemutants die at birth, it has not been possible to analyze therole of postsynaptic differentiation in the postnatal developmentof nerve terminals. We have used two methods to circumvent neonatallethality, thereby permitting prolonged observation of synapticdifferentiation. As a first step, we studied innervation of myotubesformed in vitro from rapsyn $-$ / $-$ or MuSK $-$ / $-$ myoblasts by wild-typeneurons. Second, we devised a novel in vivo method for generatingchimeric synapses between wild-type axons and mutant muscle fibersby transplanting whole neonatal muscles into immunocompatiblewild-type hosts and allowing innervation of mutant fibers by wild-typehost axons. Because the mutant muscles were in wild-type hosts,we were able to follow their maturation over several months. Bothin vitro and in vivo, we found that presynaptic nerve terminalsinitiated differentiation in the absence of normal postsynapticdifferentiation. However, even when the chimeras were maintainedfor up to 7 months, the motor axons failed to form stable contactswith mutant myotubes, and they did not mature to form complexarborizations. Together, these results suggest that postsynapticcells provide two distinct types of signals that direct presynapticdevelopment: ones to initiate presynaptic differentiation andothers to stabilize presynaptic terminals so they can mature.Although postsynaptic differentiation does not seem necessaryfor the generation of signals to initiate presynaptic differentiation,it seems absolutely essential for the generation of signals tostabilize presynaptic nerve terminals so they canmature.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nerve-muscle cocultures. Methods for preparing nerve-muscle cocultures were modified from those of Lupa et al. (1990) andhave been detailed by Son et al. (1999). Briefly, mononucleatedcells were dissociated from hindlimbs of embryonic day 18 (E18)mouse embryos and plated on collagen-coated wells of a multichamberslide (Nunc, Naperville, IL) using DMEM containing 5% fetal calfserum, 10% horse serum, and 3% chick embryo extract. Three daysafter plating, 10 µM cytosine arabinoside was added to suppressproliferation of undifferentiated cells. One day later, the mediumwas replaced by DMEM containing 5% horse serum and 3% chick embryoextract but no calf serum or cytosine arabinoside. Two days later,after myotubes had formed, neurons were dissociated from E10-E12chick ciliary ganglia and plated on the myotubes. At this time,1.5% chick eye extract was added to the medium. Three days later,tetramethylrhodamine-labeled $alpha$ -bungarotoxin (TRITC-BTX) was addedfor 1 hr to label AChRs, and the cultures were then fixed in 1%paraformaldehyde in PBS. Fixed cultures were stained with mouseanti-SV2 antibody and rabbit anti-neurofilament (Sigma, St. Louis,MO), followed by fluorescein-conjugated goat anti-mouse IgG (Cappel,Durham, NC) and Cascade blue-conjugated goat anti-rabbit IgG (MolecularProbes, Eugene,OR).

Generation of surgical chimeric synapses. Methods for transplantation of muscles were modified from those of Wigston and Sanes(1985) (see Fig. 2A,B). Adult mice were anesthetized (ketamine-xylazine,0.15 ml/20 gm), and a ventral midline incision was made in theneck. The skin was reflected, and the left sternomastoid musclewas removed, leaving a long portion of the nerve to the sternomastoidintact. Neonatal [postnatal day 0 (P0)] mouse pups were anesthetizedwith ice, perfused transcardially with DMEM, and then immersedcompletely in DMEM. The left sternomastoid and cleidomastoid muscles(henceforth referred to as graft) were dissected with their bonyinsertions intact and immediately transferred into the neck ofthe host animal. The distal insertion of the graft was attachedto the sternum of the host with two sutures (9-0 nylon monofilament;Ethicon, Somerville, NJ). Then, the proximal insertion of thegraft was attached via the mastoid process of the temporal boneto the host animal's posterior belly of the digastric muscle withone suture. The host nerve stump to the sternomastoid muscle wasattached to the mastoid process of the temporal bone of the graftwith tissue glue (Nexaband; Veterinary Products Laboratories).Finally, the incision was closed with several sutures (6-0 braidedsilk; Ethicon) and the host animal returned to its cage forrecovery.

Mice used as donors were derived from matings between heterozygous MuSK+/ $-$ (DeChiara et al., 1996) or rapsyn+/ $-$ (Gautam etal., 1995) mice. Homozygous mutants were readily identified atbirth because they were nearly (rapsyn $-$ / $-$ ) or completely (MuSK $-$ / $-$ )immobile, but genotypes were confirmed in each case by PCR. Littermates(wild-type, MuSK+/ $-$ , or rapsyn+/ $-$ ) were used ascontrols.

To assess the possibility that host-derived myoblasts contributed to the graft, we performed two sets of control experiments.In one, we transplanted control muscles into ROSA-26 mice (TheJackson Laboratory, Bar Harbor, ME). These mice express cytoplasmic $beta$ -galactosidase in nearly all tissues, including muscles (Zambrowiczet al., 1997). This combination allowed us to seek any host-derivedfibers (blue appearing) in wild-type grafts. Second, we prepareda set of grafts using RNZ mice (Pin et al., 1997) as hosts. Inthese mice, an MRF4 promoter drives expression of nuclear-localized $beta$ -galactosidase specifically in muscles. In these chimeras, contaminatinghost myonuclei would be detectable in the graft with the nuclearlocalization of the reaction product, providing greater sensitivityfor detecting small numbers of host myoblasts incorporated intopredominantly wild-type musclefiber.

In vivo imaging. Four to 6 weeks after transplantation, the innervation of control or mutant muscle fibers by wild-type hostaxons was assessed in vivo using the low-light level fluorescencemicroscopy methods described by Lichtman et al. (1987) and vanMier and Lichtman (1994). Host mice were anesthetized as aboveand mechanically ventilated. A ventral midline incision was madein the neck under sterile conditions, and the submandibular glandand fat pad were retracted to expose the muscle graft. The presenceof AChRs was assessed by application of TRITC-BTX (5 µM, 15 minin lactated ringer), and the presence of nerve terminals was assessedby application of 10 µM 4-di-2-Asp (Molecular Probes) for 1 minin lactated ringer. After each view, the neck incisions were suturedclosed (6-0 silk; Ethicon), and the mice returned to their cageto recover. Each of the grafts was viewed two or three times,with 3-5 d betweenviews.

Histological methods. To visualize presynaptic and postsynaptic specializations at high resolution, mice were killed withpentobarbital and transcardially perfused first with lactatedRinger's solution (25°C) and then with 2% paraformaldehyde inPBS (16°C). A ventral neck incision was made, the salivary glandsand fat pad were retracted to expose the graft, and an additional2% paraformaldehyde solution was applied for 30 min. The musclewas then dissected and pinned at resting length on a Sylgard-coateddish and rinsed with PBS (15 min, 25°C), immersed in 0.1 M glycine(1 hr, 25°C), and then rinsed with PBS. To stain for AChRs, muscleswere incubated in 5 µM TRITC-BTX (in the dark, 2 hr). To stainthe nerve terminals, muscles were then incubated in blocking solution(4% BSA and 0.5% Triton X-100 in PBS, 3 hr on a continuous agitator).Incubation with primary antibodies against neurofilament (1:200;SMI312, Sternberger) or synaptophysin (1:500; A. Czernik and P.Greengard, Rockefeller University, New York, NY) was done in blockingsolution (4-12 hr on a continuous agitator). Muscles were thenwashed in PBS and incubated with FITC-conjugated secondary antibodiesdissolved in blocking solution for 1 hr, washed, and mounted onglass slides and coverslipped with an antifade agent (Vectorshield;Vector Laboratories, Burlingame,CA).

For lacZ staining, mice were killed with pentobarbital and transcardially perfused with 2% paraformaldehyde and 0.1% glutaraldehydein PBS, pH 7.4, and then rinsed with PBS. Mouse torsos includinghead and neck were then stripped of skin and immersed in stainingsolution containing 2 mM 4-chloro-5-bromo-3-indolyl- $beta$ -galactosidase(X-gal; dissolved in DMSO), 5 mM potassium ferricyanide, 5 mMpotassium ferrocyanide, and 2 mM MgCl₂ in PBS for 12-24 hr at37°C. After staining, tissues were rinsed in PBS, and sternomastoidmuscle or grafts were dissected and mounted on glass slides andcoverslipped.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Initial presynaptic differentiation in the absence of postsynaptic differentiation

Our aim was to generate synapses between wild-type axons and neonatal muscle fibers under conditions that permit monitoringbeyond the perinatal period. To this end, myoblasts from rapsyn+/ $-$ , rapsyn $-$ / $-$ , MuSK +/ $-$ , and MuSK $-$ / $-$ littermates were cultured.After myotubes had formed, neurons dissociated from chick ciliaryganglia were added to the culture. Ciliary neurons were used inthese experiments because they are easier to isolate and culturethan spinal motor neurons (Bixby and Reichardt, 1985, 1987; Roleet al., 1985), extend neurites that recognize synaptic sites onskeletal muscle fibers (Covault et al., 1987), and form cholinergicsynapses on striatedmuscles.

After 3 d in coculture, differentiation of nerve-muscle contacts was assayed by labeling postsynaptic AChRs, axonal neurofilaments,and synaptic vesicles. In control cultures, ~26% (122 of 471)of nerve-muscle contacts showed signs of differentiation in thatthe neurites formed a small array of neurofilament-poor, SV2-richbranches (Fig. 1A,B,I,J). Approximately 73% of these differentiatedcontacts were found overlying high-density AChRs (Fig. 1C,K),whereas the remaining 27% of the contacts were on AChR-poor membranes.As discussed previously, the remaining 74% of nerve-muscle contactslacked both presynaptic and postsynaptic differentiation (Burgesset al., 1999; Son et al., 1999). In these cases, the neuritesand myotubes may not have been in close contact, or contacts mayhave been newly formed and not yet differentiated. A similar degreeof presynaptic differentiation, as evidenced by neurofilament-poor,SV2-rich branches, was seen in cocultures with rapsyn $-$ / $-$ and MuSK $-$ / $-$ myotubes [26% (73 of 281) in cultures from three animals of contactsin rapsyn $-$ / $-$ cocultures and 22% (66 of 302) in cultures from threeanimals of contacts in MuSK $-$ / $-$ cocultures; Fig. 1E,F,M,N]. Thus,by immunohistochemical appearance, the initial steps of presynapticdifferentiation appear to proceed normally, i.e., at the samerate (Fig. 1Q), in the absence of postsynaptic differentiation,because all of the differentiated nerve-muscle contacts in cocultureswith mutant muscle fibers occurred on AChR-poor membranes (Fig.1G,O).

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Figure 1. Nerve-muscle cocultures. A-P, Fluorescent photomicrographs of nerve-muscle cocultures showing terminal differentiation of neurites as evidenced by the presence of SV2 staining (A, E, I, M) in neurofilament-poor (B, F, J, N) areas of the nerve terminals. Twenty-six percent of nerve-muscle contacts in control cocultures (A, B, I, J) showed signs of differentiation in that the neurites formed a small array of neurofilament-poor, SV2-rich branches. Approximately 73% of these differentiated contacts were found overlying high-density AChRs labeling with TRITC-BTX (C, K), whereas the remaining 27% of the contacts were on AChR-poor membranes. A similar degree of presynaptic differentiation as evidenced by neurofilament-poor, SV2-rich branches was seen in cocultures with MuSK $-$ / $-$ (E, F) and rapsyn $-$ / $-$ (M, N) myotubes. All of these differentiated nerve-muscle contacts in cocultures with mutant muscle fibers occurred on AChR-poor membranes (G, O). D, H, L, P, Superimposition of presynaptic and postsynaptic staining for SV2 (pseudocolored green), neurofilament (pseudocolored blue), and AchRs (peudocolored red) for control and mutant cocultures. Scale bar, 5 µm. Q, Column graph showing that the level of nerve terminal differentiation is similar in the control and mutant muscle fiber cocultures.

Generating chimeric synapses in vivo

To assess whether the differentiated contacts between wild-type axons on mutant muscle fibers progress to form the complexbranching pattern characteristic of mature neuromuscular synapsesin vivo, we needed a way to generate contacts between wild-typemotor axons and neonatal muscle fibers under conditions that permitmonitoring over long periods in living animals. To this end, wetransplanted whole sternomastoid muscles from P0 donors into theneck of wild-type adult hosts (Fig. 2A; for details, see Materialsand Methods). The host sternomastoid muscle was removed, the graftwas sutured in its place, and the host's cut nerve stump was affixedto the transplant. The use of adult hosts ensured greater availabilityof host motor neurons to innervate transplanted muscle fibers,because axotomy in neonatal animals has been shown to cause massivemotor neuron death (Kashihara et al., 1987; Pollin et al., 1991;Snider et al., 1992; Li et al., 1998). Because the rapsyn andMuSK mutants were generated from 129 ES cells and maintained ina mixed C57Bl6-129J background, F1 offspring of C57Bl6-129J matingswere used as hosts to ensure immunocompability and thus obviatethe need for immunosuppression after transplantation. The rationaleis that each F1 offspring will have all the alleles of both C57Bl6and 129J lines, including those responsible for tissue histocompability.Preliminary experiments confirmed that grafts were rapidly rejectedby immunoincompatible hosts (data not shown). When immunocompatiblehosts were used, the grafts survived for many months, and hostaxons grew into the graft muscle.

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Figure 2. Transplantation method. A, Schematic of transplantation method showing a sternomastoid muscle from a P0 mouse (arrow) transplanted into the neck of an adult mouse whose own sternomastoid muscle has been removed. B-D, Wild-type muscle grafted into a ROSA-26 host 4 weeks after transplantation. B, Dissected neck of a ROSA mouse whose own left sternomastoid muscle has been replaced with a wild-type muscle graft (arrow) 1 month after transplantation. C, Nearly all cell types in the ROSA mice, including skeletal muscle fibers, express cytoplasmic $beta$ -galactosidase and turn blue with X-gal staining. D, In contrast, wild-type (wt) muscle fibers grafted into ROSA-26 hosts remain completely clear. E, F, Wild-type muscle grafted into an RNZ host. E, Muscle fibers in the RNZ mice express nuclear localized $beta$ -galactosidase, and thus the myonuclei in these mice turn blue with X-gal staining. F, In contrast, wild-type muscle fibers grafted into the RNZ mice show complete absence of blue myonuclei. These results indicate that there has been no fusion of host precursor cells with muscle fibers in the graft. Scale bar (B-E), 100 µm.

Grafted muscles remain free of host myoblasts after transplantation

To determine whether muscle fibers in the graft were entirely derived from the donor, control muscles were grafted into transgenichosts that expressed $beta$ -galactosidase either in the cytoplasm ofall cells (ROSA-26 mice) or specifically in nuclei of muscle fibers(RNZ mice). Transplantation into the ROSA-26 hosts allowed forthe detection of any host-derived cells in the graft, includingSchwann cells, whereas transplantation into the RNZ hosts alloweddetection of host-derived myonuclei with maximal sensitivity.Four weeks after transplantation, we saw no evidence of lacZ stainingin muscle fiber cytoplasm (n = 3 grafts into ROSA hosts) or myonuclei(n = 2 grafts into RNZ hosts) of the grafts, despite the factthat adjacent host muscles were intensely lacZ-positive (Fig.2B-F). This result indicates that muscle transplants are not populatedby host muscle cell progenitors after transplantation using thisprotocol. In contrast, host Schwann cells did invade the grafts,because at least half the Schwann cells near the neuromuscularjunctions of transplanted muscle fibers into ROSA-26 hosts wereblue (data not shown). This result is consistent with the observationthat neonatal terminal Schwann cells undergo apoptosis when theirassociated axons degenerate (Trachtenberg and Thompson, 1996),as must have occurred in these transplants causing replacementby host Schwann cells during or after reinnervation by hostaxons.

Host axons reoccupy original synaptic sites in transplanted wild-type muscles

At the time of transplantation, neuromuscular junctions in the control donor (P0) muscle were arranged in a band approximatelymidway along the length of the muscle fibers (Fig. 3A). In oneset of control transplants, we determined the fate of former synapticsites in the absence of innervation. Five days after transplantation,before the host nerve had entered the muscle, TRITC-BTX stainingshowed that the transplanted muscle fibers maintained the originalendplate band (Fig. 3B). Similar results were obtained at longerperiods (10 d; Fig. 3C) in transplants kept denervated by deflectingthe host nerve into adjacent host musculature. However AChR-richplaques remained small and poorly differentiated in the aneuralmuscles compared with normal innervated muscles of the same age,suggesting that postsynaptic differentiation had slowed. A smallsubset of fibers showed multiple patches of AChR clusters alongtheir length (data not shown), suggesting that these fibers hadformed from satellite cells after the degeneration of the transplantedmuscle fibers. Eventually these uninnervated grafts showed signsof extensive necrosis (i.e., fatty change). Thus, in the absenceof reinnervation, the control grafts did not survive, and thepostsynaptic specialization did not continue to mature.

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Figure 3. Stability of postsynaptic AChRs after transplantation. Photomicrographs show the AChR staining pattern with TRITC-BTX in sternomastoid muscles. A, At the time of transplantation, the NMJs (arrows) in the P0 muscle were arranged in a small cuff known as an endplate band (area between white lines) approximately midway along the length of the muscle. B, C, Five to 10 d after denervation or transplantation into a host where the host nerve was deflected from the graft, the NMJs in the muscle still maintain their tight distribution in an endplate band midway along the length of the muscle. D, After transplantation and attachment of the host nerve stump (28 weeks after transplantation for this particular graft), host axons innervate muscle fibers approximately midway along the length of the graft, forming an endplate band. Scale bars: A-C, 20 µm; D, 100 µm.

Results were quite different in grafts to which the host nerve stump was attached. The grafted muscles were larger when examined1-7 months after transplantation than they had been when the graftwas made. The majority of muscle fibers (>90%) in the successfulgrafts (10 of 13) did not appear to have degenerated and regenerated,because they did not have central nuclei. Muscle fiber necrosisand regeneration attributable to ischemia have been shown to occurwithin the first week after free grafting (Carlson and Gutmann,1975), and regenerating muscle fibers have been shown to retaincentral nuclei for up to 6 months (Schmalbruch, 1976). The lowlevel of ischemia-induced muscle fiber degeneration in the graftsis likely related to the small cross-sectional diameter of theneonatal mouse sternomastoid muscle used for transplantation (Wigstonand Sanes, 1985).

All of the control grafts had an endplate band and fascicles of axons terminating near the middle of the muscle around thesite of the original intramuscular nerve (Fig. 3D). In these grafts,only a few muscle fibers (<10%) had synaptic sites at the endof the graft near the site of entry of the host nerve stump tothe graft. No synapses were observed at the end of the graft thatwas opposite the site the nerve stump entry. A possible explanationfor this pattern of innervation is that a small percentage ofmuscle fibers had been damaged during surgery and had degenerated;regenerating muscle fibers have been shown to be capable of formingNMJs in ectopic locations as well as at the original synapticsites (Womble, 1986). In contrast, reinnervation of the othertransplanted muscle fibers by host axons occurred by reoccupationof original synaptic sites, presumably guided by persistent cuesin the graft, for example, in cells of the perineurium, or inthe basal lamina or plasmalemma of musclefibers.

Synapses between host axons and wild-type muscle fibers become mature, stable, and functional

At the time of grafting (P0), the wild-type neuromuscular junctions were simple and small (Fig. 4A). Most of these junctionalsites consisted of oval concentrations of AChRs (plaques) in themuscle plasmalemma with two or more overlying unmyelinated motoraxons, each of which sets down several boutons on the receptorplaque. In contrast, each NMJ in normal adult mice is composedof an AChR-rich region arranged in a complex branching pattern,and a single myelinated motor axon terminates in a branching patternthat precisely overlies the receptor branching pattern (Fig. 4B).

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Figure 4. Comparison of NMJs from wild-type P0, adult, and transplanted muscle fibers. A, At P0, nerve terminals (A1, immunolabeled with antibodies against neurofilament and synaptophysin) have small bouton-like endings overlying a plaque-like area of high AChR density (A2, labeled with TRITC-BTX; A3, overlay of nerve terminal pattern on AChR pattern). B, By 4-6 weeks postnatally in mice, each muscle fiber receives innervation from a single myelinated axon whose arbors show extensive branching (B1). The postsynaptic AChR cluster underlying the presynaptic nerve terminals also shows breaking apart of the original plaque to form a high, branched structure (B2). The presynaptic nerve terminals and the postsynaptic AChR clusters correspond exactly in their branching pattern (B3). C, Four weeks to 10 months after transplantation, wild-type muscle fibers are also innervated by a single axon. The overall size of the NMJs in transplanted muscle fibers is smaller compared with normal adult NMJs, probably because of the fact that the neonatal graft was placed in a full sized adult host, and thus the muscle fibers themselves do not lengthen and are consequently smaller than their age-matched nontransplanted counterparts. The presynaptic (C1) and postsynaptic (C2) components of the NMJs in wild-type transplanted muscle fibers exactly oppose each other (C3) and show the branching morphology similar to that seen in normal nontransplanted NMJs. The difference in presynaptic arbor width between B1 and C1 reflects variability in antibody staining for synaptophysin and does not reflect differences in presynaptic structure between wild-type adult and wild-type transplants. Scale bar: A, C, 5 µm; B, 12.5 µm.

Four weeks after transplantation of control P0 muscles into wild-type adult hosts, each muscle fiber also showed a singleAChR-rich region in a branched configuration that was overlainby a single myelinated axon with similarly branched terminal endings(Fig. 4C). Thus, control P0 muscle grafts can differentiate normal-appearingpostsynaptic receptor distributions, and adult motor axons havethe ability to form structurally mature NMJs on these transplantedneonatal musclefibers.

In normal adult mice, NMJs show little branch addition or retraction over days or months (Lichtman et al., 1987; Balice-Gordonand Lichtman, 1990). To determine whether the junctions on transplantedmuscles were also stable over time, we viewed identified NMJsstained with vital presynaptic and postsynaptic markers usinglow-light level fluorescent microscopy in living mice. We foundthat, as in normal adult muscles, the receptor distribution andnerve terminal branching pattern on individual muscle fibers remainedunchanged over time (Fig. 5). Stimulation of the host muscle nervesupplying grafted wild-type muscles with a suction electrode elicitedbrisk and forceful contractions in all four transplants tested,indicating that the innervation was functional. Taken together,these results indicate that wild-type P0 muscle fibers survivethe heterochronic transplant procedure and become functionallyinnervated by wild-type host motor axons. Furthermore, these chimericsynapses are stably maintained over time, similar to wild-typecontrol NMJs.

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Figure 5. Innervation of control muscles by host axons is stable over time. Stability of heterochronic NMJs on transplanted wild-type muscle fibers viewed in vivo over 5 d are shown. A, On day 0, host presynaptic nerve terminals (labeled with the vital mitochondrial dye 4-di-2-Asp, green) innervating grafted muscle fibers overlie postsynaptic AChR clusters (labeled with TRITC-BTX, red). Presynaptic nerve terminals overlie areas of AChR clusters with precise correspondence (the red and green pseudocolors of the AChRs and nerve terminals combine to give yellow). B, Five days later, the presynaptic and postsynaptic components of the NMJ still retained their close association and are unchanged from day 0. Scale bar, 25 µm.

Contacts on MuSK $-$ / $-$ or rapsyn $-$ / $-$ muscle fibers show postsynaptic and presynaptic abnormalities

We transplanted muscles from MuSK- or rapsyn-deficient neonates into wild-type adult host mice. Even 7 months after innervationof the mutant muscle fibers by wild-type axons, the postsynapticabnormalities seen in mutant neonates (Gautam et al., 1995; DeChiaraet al., 1996) persisted in both MuSK-deficient (n = 3) and rapsyn-deficient(n = 6) muscles: only three mutant muscle fibers of hundreds examined(see below) bore clustered receptors on their surfaces. This maintainedabsence of receptor clusters indicates that rapsyn and MuSK donot merely facilitate or accelerate postsynaptic differentiationbut are absolutely essential for it to occur. These chimeric nerve-musclecontacts were therefore suitable for testing the dependence ofpresynaptic maturation on postsynaptic differentiation

Immunohistochemical labeling of axons and nerve terminals in rapsyn $-$ / $-$ transplants showed that host axons often ran parallelto the length of the muscle fibers. There were occasional clustersof nerve terminal boutons on the surface of the fibers (Fig. 6B,C),but these were typically smaller than those seen in wild-typeP0 muscles and markedly less differentiated than nerve terminalsin control transplants (compare Figs. 6B,C and 4C1). Rather, thenerve terminals resembled immature terminals in rapsyn mutantsat birth (Fig. 6A; Gautam et al., 1995). The degree of terminalmaturation did not appear to change from 3 weeks to 7 months aftertransplantation. The presynaptic structure of host axons in theMuSK-deficient grafts after transplantation (Fig. 6E,F) was alsosimilar to that seen in MuSK $-$ / $-$ mutants at birth (Fig. 6D) andin the rapsyn $-$ / $-$ chimeras described above: nearly all motor axonsterminated in sparse clusters of boutons on the surface of themuscle fibers that were less differentiated than nerve terminalsin control transplants (compare Figs. 6E,F and 4C1).

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Figure 6. Innervation of rapsyn $-$ / $-$ and MuSK $-$ / $-$ muscle fibers by wild-type host axons. A, High-power photomicrograph showing the small bouton-like nerve terminal endings immunolabeled with antibodies against neurofilament and synaptophysin in rapsyn $-$ / $-$ mutants at P0. B, C, Several months (2.5 and 3 months for these grafts) after transplantation, normal host axons still only terminate in bouton-like endings without further maturating into the complex branching pattern of normal mature nerve terminals or nerve terminals innervating muscle fibers in the wild-type transplants (compare B, C with Fig. 4B1,C1). D, High-power photomicrograph showing the small bouton-like nerve terminal endings in MuSK $-$ / $-$ mutants at P0. E, F, Normal host axons innervating MuSK $-$ / $-$ muscle fibers still terminated in bouton-like endings after 4 months (compare E, F with Fig. 4B1,C1). Scale bar: A-E, 5 µm; F, 10 µm.

Despite their overall similarities, there were two differences between the MuSK and rapsyn mutant muscle transplants. First,whereas axons grew throughout the rapsyn mutant muscles aftertransplantation (Fig. 7A,B), axons in the MuSK $-$ / $-$ grafts formedimmature terminal endings that clustered around the central intramuscularnerve (Fig. 7C,D). Second, whereas no AChR clusters were foundin the rapsyn $-$ / $-$ transplants, three muscle fibers in MuSK $-$ / $-$ transplants(two fibers in one transplant, one fiber in the second transplant,and none in the third transplant) bore a remarkably normal-appearing,high-density AChRs cluster with a complex branching pattern (datanot shown). This observation is especially dramatic and raisesthe possibility of a MuSK-independent pathway for postsynapticdifferentiation (also see Sugiyama et al., 1997; Gautam et al.,1999). We cannot, however, rule out the possibility that it resultsfrom the invasion of the graft by a few host satellite cells,which fused with mutant muscle fibers and supplied them with MuSK.No AChR clusters were ever seen in rapsyn $-$ / $-$ transplants, butrapsyn is needed at a 1:1 stoichiometry with AChRs, whereas asmall number of MuSK molecules may be sufficient to induce postsynapticdifferentiation. Further studies will be needed to evaluate thesealternatives.

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Figure 7. Distribution of host axons in rapsyn $-$ / $-$ and MuSK $-$ / $-$ grafts. A, Low-power photomicrograph showing an example of the innervation pattern of a rapsyn $-$ / $-$ muscle after transplantation into a wild-type host (11 weeks after transplantation). Normal host axons innervating rapsyn $-$ / $-$ muscles terminate far away from the entry point of the intramuscular nerve (asterisk). B, Schematic of rapsyn $-$ / $-$ graft in A, showing that nerve terminal endings (arrows) can be found throughout the length of the graft. (Note: the fragmented appearance of the nerve terminals is attributable to the fact that innervating axons weave between the muscle fibers of the graft and thus disappear from the plane of focus.) C, Low-power photomicrograph showing an example of a MuSK $-$ / $-$ muscle after transplantation into a wild-type host (7 months after transplantation). In contrast to the diffuse innervation pattern of muscles in MuSK $-$ / $-$ mutants at P0, after transplantation, wild-type axons innervating MuSK $-$ / $-$ muscles terminate closely to the entry point of the intramuscular nerve (asterisk). D, Schematic of the MuSK $-$ / $-$ graft shown in C, showing that nerve terminal endings (arrows) are found in a tight cluster near the middle of the graft along its length. Scale bar, 200 µm.

Nerve terminal contacts on MuSK $-$ / $-$ or rapsyn $-$ / $-$ muscle fibers are unstable

In that presynaptic differentiation is initiated at points of axonal contact with rapsyn $-$ / $-$ or MuSK $-$ / $-$ myotubes, the defectsobserved are likely to reflect defects in the maturation processper se. To gain insight into the ways in which maturation fails,we visualized identified synaptic sites multiple times in livinganimals.

In contrast to muscles from normal mice and control transplants, there are no postsynaptic markers that can be vitally labeledin the mutant muscle fibers. Thus, we had to depend on other landmarkssuch as the position of the blood vessels to relocate individualmuscle fibers. In doing the multiple-view experiments in the mutanttransplants, we took extreme care to image nerve terminals onlywhen the blood vessel landmarks themselves are in the same orientationas the initial views. We found that whereas in control transplantsnerve terminals and the postsynaptic AChR sites could be relocatedwith little difficulty over 4-5 d (see Fig. 5), nerve terminalson MuSK $-$ / $-$ -transplanted (Fig. 8) and rapsyn $-$ / $-$ -transplanted (datanot shown) muscles changed greatly during this interval. In MuSKtransplants, although there were contact sites that remained identifiableover a 4 d period (n = 7 sites in two animals), there were alsomany contact sites that were present on the first view but wereno longer present at the second view 4 d later (n = 8 sites intwo animals). In addition, new sites of contact that were notpresent at the first view were seen at the second view (n = 4sites in two animals). Thus, over a 4 d period, ~30% of contactsites in MuSK transplants were maintained, whereas the remaining70% appeared to have either retracted or grown additional terminalendings.

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Figure 8. Multiple views of the same nerve terminal endings in MuSK $-$ / $-$ transplants over 4 d. A, Low-power view of nerve terminals (labeled with the vital dye 4-di-2-Asp) innervating a MuSK $-$ / $-$ graft 14 weeks after transplantation into a wild-type host. Using the stable position of blood vessels (arrowheads) traveling through the graft, the same area on the surface of the graft can be reliably reidentified over several days. C, At higher power, several axonal processes (black arrows) can be seen "innervating" the muscle fibers on the surface of this graft. B, Four days later, the same area on the surface of the MuSK $-$ / $-$ graft seen in A and C can be reidentified using the blood vessels as landmarks. D, Normal axons innervating MuSK $-$ / $-$ muscle fibers appear unstable, because the processes seen on the previous view (C) can no longer be seen 4 d later. E, F, Another example at high power of axonal processes innervating a MuSK $-$ / $-$ graft 14 weeks after transplantation into a wild-type host viewed over a 4 d interval. At day 0 (E), a single axon (white arrowhead) can be seen to give off two terminal branches (black arrowhead). Four days later (F), the two terminals branches previously seen appeared to have retracted, and a new axonal process (white arrow) appeared to have grown into the area. Scale bar: A, B, 20 µm; C, D, 10 µm; E, F, 5 µm.

Host axons innervating rapsyn-deficient muscle fibers were at least as labile as those innervating MuSK $-$ / $-$ muscles. Indeed,contact sites present on the first view were never reidentifiedon the second views 2-4 d later, even though the sites where thenerve terminals were previously observed were unambiguously reidentifiedusing blood vessels as landmarks (n = 30 nerve terminals followedover 2 d and 14 nerve terminals followed over 4 d in two animals).Thus, 100% of synaptic sites in rapsyn transplants appeared toundergo remodeling over intervals of probably <48 hr. This contrastswith control grafts described above in which 73 of 75 NMJs (inthree animals) identified at the first view were reidentified3-5 dlater.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

MuSK and rapsyn are required for postsynaptic differentiation at the NMJ. When mice lacking rapsyn or MuSK were generated,it was found that presynaptic as well as postsynaptic differentiationwere severely compromised (Gautam et al., 1995; DeChiara et al.,1996). In MuSK $-$ / $-$ mice, it was reported that no presynaptic differentiationoccurred at all; motor axons failed to branch or to concentratesynaptic vesicles, and they remained similar to preterminal axons(DeChiara et al., 1996). Using high-power confocal microscopy,we did find some evidence of presynaptic specialization in MuSK $-$ / $-$ mice at birth (Fig. 6D), although these terminals were much smallerand simpler than those of wild-type mice at birth. In rapsyn $-$ / $-$ mice, some presynaptic and postsynaptic differentiation did occur,but both presynaptically and postsynaptically, the defects werestill devastating (Gautam et al., 1995). Because rapsyn and MuSKare both expressed only in the postsynaptic cell, it was hypothesizedthat the presynaptic defects resulted indirectly from lack ofretrograde signals that are normally elaborated as part of theprogram of postsynaptic differentiation. Here, we have used musclesfrom MuSK $-$ / $-$ and rapsyn $-$ / $-$ mice to test this hypothesis. To thisend, we used dissociated cultures and a novel transplantationparadigm to examine genotypically chimeric synapses over a protractedperiod. Surprisingly, initial steps of presynaptic differentiationdid occur in the absence of postsynaptic differentiation: bothin vitro and in vivo, wild-type motor axons generated varicosities,synaptic vesicle clusters, and rudimentary arbors on mutant musclefibers. Thus, although the myotube organizes the initial stepsin presynaptic differentiation, as demonstrated by the invariableapposition of nerve terminals to the myotube surface, these stepsdo not require postsynaptic differentiation. In contrast, evenwhen the chimeric synapses were maintained for up to 7 monthsin vivo, they failed to mature. Furthermore, such endings appearedto undergo continuous remodeling. Thus, postsynaptic differentiationis required to stabilize nerve-muscle contacts, and stability,in turn, may permit maturation of presynaptic nerve terminals.Together, our results suggest that postsynaptic cells providetwo distinct types of signals to their synaptic inputs: some thatorganize early events in presynaptic differentiation and othersthat lead to stabilization and maturation of the nerve terminal.Postsynaptic differentiation seems to be dispensable for initialpresynaptic differentiation but is required for presynapticmaturation.

There are several advantages to studying synaptic development in surgical chimeras. First, because the mutant muscle is transplantedinto a wild-type host, the viability of the animal is not compromisedby lethal mutations. Thus, synapses can be viewed over long intervals,and developmental delay can be distinguished from developmentalblockade. Indeed, the initial failure to detect presynaptic differentiationin MuSK $-$ / $-$ mice (DeChiara et al., 1996) is presumably a consequenceof their neonatal lethality. Second, in situations in which themolecules of interest are present in multiple tissues, concernsabout indirect effects on synapse development arising from thedeletion of these molecules from nonmuscle tissues is circumvented.Third, because the motoneurons arise and extend axons in a normalenvironment, it is possible to isolate the retrograde effectsthat impinge directly onsynapses.

The first aim of our transplant experiments was to evaluate the ability of adult motoneurons to innervate neonatal musclefibers. Neonatal and adult motoneurons show different dependenceon their targets (Kashihara et al., 1987; Pollin et al., 1991;Snider et al., 1992), and neonatal and adult muscles show differentresponses to denervation (Blondet et al., 1986, 1989; RodriguesAde and Schmalbruch, 1995). Such differences, or the mismatchin age between the presynaptic and postsynaptic partners, mighthave affected synapse formation and maintenance. We found, however,that adult wild-type motor neurons have the ability to form functionaland stable synaptic contacts with neonatal wild-type muscle fibers.For the majority of transplanted neonatal muscle fibers, reinnervationby host axons appeared to have occurred by the reoccupation oforiginal synaptic sites, as occurs after reinnervation of adultmuscles. Moreover, the synaptic contact between adult wild-typeaxons and transplanted neonatal muscle fibers is stable over time,similar to that of control NMJs. The ability of adult motor axonsto form mature synapses on an initially immature muscle has interestingclinical implications for free grafts used in reconstructivesurgery.

The second aim of these transplantation experiments was to evaluate postsynaptic development of mutant muscle fibers in anotherwise normal environment. Postsynaptic differentiation ofthe NMJ includes a number of steps that ordinarily occur in postnatallife, after mutants lacking agrin, MuSK, or rapsyn die. Thesesteps, including the $gamma$ to $epsilon$ switch in AChR subunits (Mishina etal., 1986; Gu and Hall, 1988; Missias et al., 1996), the changein channel kinetics (Schuetze and Role, 1987; Villaroel and Sakmann,1996), the phosphorylation of AChRs (Qu et al., 1990) and theincrease in their half-life in the postsynaptic membrane (forreview, see Salpeter and Loring, 1985), the appearance of $alpha$ 7A-and B-integrin isoforms (Martin et al., 1996) and laminin $beta$ 2 (Pattonet al., 1997) in the synaptic basal lamina, the generation ofpostsynaptic folds (Desaki and Uehara, 1987; Marques and Lichtman,2000), and the elimination of multiple innervation (Redfern, 1970;for review, see Jansen and Fladby, 1990), may be mediated by signalingpathways that are independent of agrin, MuSK, or rapsyn. Thus,given enough time, it seemed possible that in mutant muscles,postsynaptic differentiation would cross over to dependence onmolecular cascades different from those associated with agrin,MuSK, or rapsyn. However, we found that with rare exceptions (1%of fibers), no normal NMJs formed on MuSK $-$ / $-$ and rapsyn $-$ / $-$ myotubeseven up to seven months after transplantation. The apparent failureof postsynaptic differentiation to take place even though themuscle fibers were alive for several months confirms the conclusion(Gautam et al., 1995; DeChiara et al., 1996) that rapsyn and MuSKdo not merely accelerate or facilitate postsynaptic differentiationin the wild-type animal, but that, rather, both of these moleculesare absolutely necessary for postsynaptic differentiation to takeplace.

The third and principal aim of our study was to assess presynaptic differentiation in the absence of postsynaptic differentiation.We found that wild-type adult axons innervating transplanted rapsyn-or MuSK-deficient muscle fibers either in vivo or in vitro didproceed through initial steps of presynaptic differentiation,forming some varicosities, vesicle clusters, and rudimentary arbors.In general, these terminals were similar to those of neonatalaxons in the mutant animals at P0. The terminals failed to mature,however, even when they were maintained for months. The persistenceof the presynaptic defect in rapsyn- or MuSK-deficient musclefibers after transplantation suggests that in the absence of thesepostsynaptic molecules, presynaptic nerve terminals are fundamentallyincapable of maturing, rather than merely delayed in their maturation.Because MuSK and rapsyn are drastically different in their structureand function [rapsyn is a cytosolic membrane-associated proteinthat is present in a 1:1 ratio with AChRs (Froehner et al., 1981;LaRochelle and Froehner, 1986; Noakes et al., 1993), whereas MuSKis a transmembrane receptor tyrosine kinase (Valenzuela et al.,1995)], it is likely that the similarity in the presynaptic defectsof axons innervating muscle fibers lacking either of these proteinsresults from failure of a common retrograde signal whose formation,localization, or release requires postsynapticdifferentiation.

One clue to the mechanism underlying the defect in presynaptic maturation in the absence of postsynaptic differentiation isthe observation that host axons innervating rapsyn- or MuSK-deficientmuscle fibers are in constant flux with continuous growth andretraction of terminal endings. Although wild-type axons appearedcapable of some degree of presynaptic differentiation on eitherrapsyn- or MuSK-deficient muscle fibers, such endings underwentcontinuous remodeling after transplantation. These results suggestthat postsynaptic cells provide two types of signals to innervatingaxons: ones to initiate presynaptic differentiation and ones tostabilize immature nerve terminals so they can mature. As demonstratedby the presence of presynaptic differentiation seen in the dissociatedcultures and after transplantation, postsynaptic differentiationdoes not appear to be required for the initiation of nerve terminaldifferentiation. In contrast, the lability of immature presynapticnerve terminals innervating mutant muscle fibers suggests thatpostsynaptic differentiation is required for the stabilizationof immature nerve terminals so they canmature.

The nature of the stabilizing retrograde signals is not yet known. Studies at Caenorhabditis elegans and Drosophila NMJs suggestthat target cell activity influences synaptic structure and function.For example, decreasing muscle activity in C. elegans inducessprouting of motor neurons (Zhao and Nonet, 2000), and changesin postsynaptic receptor density in Drosophila muscle induce correspondingchanges in presynaptic neurotransmitter release (Petersen et al.,1997; Davis and Goodman, 1998). However, physical contact withtarget cells in the absence of any activity can also influencepresynaptic development, because the preferential associationof synaptic vesicle-containing neurites with myotubes was stillobserved when the myotubes were previously fixed with paraformaldehyde(Lupa and Hall, 1989; Lupa et al., 1990). In the present situation,the retrograde signals for nerve terminal stabilization may beeither positive (e.g., anchoring molecules) or negative (e.g.,failure to downregulate signals that promote continued growth).The requirement for postsynaptic differentiation in the stabilizationof synaptic connections implies that postsynaptic dedifferentiationcould lead to presynaptic instability. Indeed, one view of themechanism of naturally occurring synapse elimination is that itis instigated by changes in the postsynaptic cell that includethe same characteristic seen in the mutant muscles studied here:the absence of a high density of postsynaptic AChRs at sites ofsynapse destabilization (for review, see Lichtman and Colman,2000). It is therefore possible that downregulation of MuSK signalingor rapsyn expression within a muscle fiber could elicit synapseloss.

  FOOTNOTES

Received March 23, 2000; revised May 10, 2000; accepted May 19, 2000.

This project was supported by grants from National Institutes of Health and the Muscular Dystrophy Association (J.W.L.) andthe Bakewell NeuroImagingFund.
Correspondence should be addressed to Dr. Jeff W. Lichtman, Department of Anatomy and Neurobiology, Washington UniversitySchool of Medicine, Box 8108, 660 South Euclid, St. Louis, MO.E-mail: jeff{at}thalamus.wustl.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Balice-Gordon RJ, Lichtman JW (1990) In vivo visualization of the growth of pre- and postsynaptic elements of neuromuscular junctions in the mouse. J Neurosci 10:894-908[Abstract].
Bixby JL, Reichardt LF (1985) The expression and localization of synaptic vesicle antigens at neuromuscular junctions in vitro. J Neurosci 11:3070-3080[Abstract].
Bixby JL, Reichardt LF (1987) Effects of antibodies to neural cell adhesion molecule (N-CAM) on the differentiation of neuromuscular contacts between ciliary ganglion neurons and myotubes in vitro. Dev Biol 119:363-372[Web of Science][Medline].
Blondet B, Rieger F, Gautron J, Pincon-Raymond M (1986) Difference in the ability of neonatal and adult denervated muscle to accumulate acetylcholinesterase at the old sites of innervation. Dev Biol 117:13-23[Web of Science][Medline].
Blondet B, Rieger F, Verdiere-Sahugue M (1989) Activity-independent modulation of acetylcholine receptor levels in rat skeletal muscle following neonatal denervation. Neurosci Lett 102:273-278[Web of Science][Medline].
Burgess RW, Nguyen QT, Son YJ, Lichtman JW, Sanes JR (1999) Alternatively spliced isoforms of nerve- and msucle-derived agrin: their role at the neuromuscular junction. Neuron 23:33-44[Web of Science][Medline].
Carlson BM, Gutmann E (1975) Regeneration in free grafts of normal and denervated muscles in the rat: morphology and histochemistry. Anat Rec 183:46-62.
Covault J, Cunningham JM, Sanes JR (1987) Neurite outgrowth on cryostat sections of innervated and denervated skeletal muscle. J Cell Biol 105:2479-2488[Abstract/Free Full Text].
Davis GW, Goodman CS (1998) Synapse-specific control of synaptic efficacy at the terminals of a single neuron. Nature 392:82-86[Medline].
DeChiara TM, Bowen DC, Valenzuela DM, Simmons MV, Poueymirou WT, Thomas S, Kinetz E, Compton DL, Rojas E, Park JS, Smith C, DiStefano PS, Glass DJ, Burden SJ, Yancopoulos GD (1996) The receptor tyrosine kinase MuSK is required for neuromuscular junction formation in vivo. Cell 85:501-512[Web of Science][Medline].
Desaki J, Uehara Y (1987) Formation and maturation of subneural apparatuses at neuromuscular junctions in postnatal rats: a scanning and transmission electron miscroscopical study. Dev Biol 119:390-401[Web of Science][Medline].
Fitzsimonds RM, Poo MM (1998) Retrograde signaling in the development and modification of synapses. Physiol Rev 78:143-170[Abstract/Free Full Text].
Froehner SC, Gulbrandsen V, Hyman C, Jeng AY, Neubig RR, Cohen JB (1981) Immunofluorescence localization at the mammalian neuromuscular junction of the Mr 43,000 protein of Torpedo postsynaptic membranes. Proc Natl Acad Sci USA 78:5230-5234[Abstract/Free Full Text].
Gautam M, Noakes PG, Mudd J, Nichol M, Chu GC, Sanes JR, Merlie JP (1995) Failure of postsynaptic specialization to develop at neuromuscular junctions of rapsyn-deficient mice. Nature 377:232-236[Medline].
Gautam M, Noakes PG, Moscoso L, Rupp F, Scheller RH, Merlie JP, Sanes JR (1996) Defective neuromuscular synaptogenesis in agrin-deficient mutant mice. Cell 85:525-535[Web of Science][Medline].
Gautam M, DeChiara TM, Glass DJ, Yancopoulos GD, Sanes JR (1999) Distinct phenotypes of mutant mice lacking agrin, MuSK, or rapsyn. Brain Res Dev Brain Res 114:171-178[Medline].
Glass DJ, Bowen DC, Stitt TN, Radziejewski C, Bruno J, Ryan TE, Gies DR, Shah S, Mattsson K, Burden SJ, DiStefano PS, Valenzuela DM, DeChiara TM, Yancopoulos GD (1996) Agrin acts via a MuSK receptor complex. Cell 85:513-523[Web of Science][Medline].
Glass DJ, Apel ED, Shah S, Bowen DC, DeChiara TM, Stitt TN, Sanes JR, Yancopoulos GD (1997) Kinase domain of the muscle-specific receptor tyrosine kinase (MuSK) is sufficient for phosphorylation but not clustering of acetylcholine receptors: required role for the MuSK ectodomain? Proc Natl Acad Sci USA 94:8848-8853[Abstract/Free Full Text].
Gu Y, Hall ZW (1988) Immunological evidence for a change in subunits of the acetylcholine receptor in developing and denervated rat muscle. Neuron 1:117-125[Web of Science][Medline].
Jansen JK, Fladby T (1990) The perinatal reorganization of the innervation of skeletal muscle in mammals. Prog Neurobiol 34:39-90[Web of Science][Medline].
Kashihara YM, Kuno M, Miyata Y (1987) Cell death of axotomized motoneurons in neonatal rats, and pits prevention by peripheral reinnervation. J Physiol (Lond) 386:135-148[Abstract/Free Full Text].
LaRochelle WJ, Froehner SC (1986) Determination of the tissue distributions and relative concentrations of the postsynaptic 43-kDa protein and the acetylcholine receptor in Torpedo. J Biol Chem 261:5270-5274[Abstract/Free Full Text].
Li L, Houenou LJ, Wu W, Lei M, Prevette DM, Oppenheim RW (1998) Characterization of spinal motoneuron degeneration following different types of peripheral nerve injury in neonatal and adult mice. J Comp Neurol 396:158-168[Web of Science][Medline].
Lichtman JW, Colman H (2000) Synapse elimination and indelible memory. Neuron 25:269-278[Web of Science][Medline].
Lichtman JW, Magrassi L, Purves D (1987) Visualization of neuromuscular junctions over periods of several months in living mice. J Neurosci 7:1215-1222[Abstract].
Lupa MT, Hall ZW (1989) Progressive restriction of synaptic vesicle protein to the nerve terminal during development of the neuromuscular junction. J Neurosci 9:3937-3945[Abstract].
Lupa MT, Gordon H, Hall ZW (1990) A specific effect of muscle cells on the distribution of presynaptic proteins in neuritis and its absence in a C2 muscle cell variant. Dev Biol 142:31-43[Web of Science][Medline].
Marques MJ, Conchello JA, Lichtman JW (2000) From plaque to pretzel: fold formation and acetylcholine receptor loss at the developing neuromuscular junction. J Neurosci 20:3663-3675[Abstract/Free Full Text].
Martin PT, Kaufman SJ, Kramer RH, Sanes JR (1996) Synaptic integrins in developing, adult and mutant muscle: selective association of $alpha$ 1, $alpha$ 7A, and $alpha$ 7B integrins with the neuromuscular junction. Dev Biol 174:743-754.
Mishina M, Takai T, Imoto K, Noda M, Takahashi T, Numa S, Methfessel C, Sakmann B (1986) Molecular distinction between fetal and adult forms of muscle acetylcholine receptor. Nature 321:406-411[Medline].
Missias AC, Chu GC, Klocke BJ, Sanes JR, Merlie JP (1996) Maturation of the acetylcholine receptor in skeletal muscle: regulation of the AChR gamma-to-epsilon switch. Dev Biol 179:223-238[Web of Science][Medline].
Noakes PG, Phillips WD, Hanley TA, Sanes JR, Merlie JP (1993) 43K protein and acetylcholine receptors colocalize during the initial stages of neuromuscular synapse formation in vivo. Dev Biol 155:275-280[Web of Science][Medline].
Patton BL, Miner JH, Chiu AY, Sanes JR (1997) Localization, regulation and function of laminins in the neuromuscular system of developing, adult and mutant mice. J Cell Biol 139:1507-1521[Abstract/Free Full Text].
Petersen SA, Fetter RD, Noordermeer JN, Goodman CS, DiAntonio A (1997) Genetic analysis of glutamate receptors in Drosophila reveals a retrograde signal regulating presynaptic transmitter release. Neuron 19:237-248.
Pin CL, Ludolph DC, Cooper ST, Klocke BJ, Merlie JP, Konieczny SF (1997) Distal regulatory elements control MRF4 gene expression in early and late myogenic cell populations. Dev Dyn 208:299-312[Web of Science][Medline].
Pollin MM, McHanwell S, Slater CR (1991) The effect of age on motor neurone death following axotomy in the mouse. Development 112:83-89[Abstract].
Qu ZC, Moritz E, Huganir RL (1990) Regulation of tyrosine phosphorylation of the nicotinic acetylcholine receptor at the rat neuromuscular junction. Neuron 4:367-378[Web of Science][Medline].
Redfern PA (1970) Neuromuscular transmission in newborn rats. J Physiol (Lond) 209:701-709[Abstract/Free Full Text].
Rodrigues Ade C, Schmalbruch H (1995) Satellite cells and myonuclei in long-term denervated rat muscles. Anat Rec 243:430-437[Medline].
Role LW, Matossian VR, O'Brien RJ, Fischbach GD (1985) On the mechanism of acetylcholine receptor accumulation at newly formed synapses on chick myotubes. J Neurosci 5:2197-2204[Abstract].
Salpeter MM, Loring RH (1985) Nicotinic acetylcholine receptors in vertebrate muscle: properties, distribution and neural control. Prog Neurobiol 25:297-325[Web of Science][Medline].
Sanes JR, Lichtman JW (1999) Development of the vertebrate neuromuscular junction. Annu Rev Neurosci 22:389-442[Web of Science][Medline].
Schuetze SM, Role LW (1987) Developmental regulation of nicotinic acetylcholine receptors. Annu Rev Neurosci 10:403-457[Web of Science][Medline].
Schmalbruch H (1976) The morphology of regeneration of skeletal muscles in the rat. Tissue Cell 8:673-692[Web of Science][Medline].
Snider WD, Elliott JL, Yan Q (1992) Axotomy-induced neuronal death during development. J Neurobiol 23:1231-1246[Web of Science][Medline].
Son YJ, Patton BL, Sanes JR (1999) Induction of presynaptic differentiation in cultured neurons by extracellular matrix components. Eur J Neurosci 11:3457-3467[Web of Science][Medline].
Sugiyama JE, Glass DJ, Yancopoulos GD, Hall ZW (1997) Laminin-induced acetylcholine receptor clustering: an alternative pathway. J Cell Biol 139:181-191[Abstract/Free Full Text].
Trachtenberg JT, Thompson WJ (1996) Schwann cell apoptosis at developing neuromuscular junctions is regulated by glial growth factor. Nature 379:174-177[Medline].
Valenzuela DM, Stitt TN, DiStefano PS, Rojas E, Mattsson K, Compton DL, Nunez L, Park JS, Stark JL, Gies DR (1995) Receptor tyrosine kinase specific for the skeletal muscle lineage: expression in embryonic muscle, at the neuromuscular junction, and after injury. Neuron 15:573-584[Web of Science][Medline].
van Mier P, Lichtman JW (1994) Regenerating muscle fibers induce directional sprouting from nearby nerve terminals: studies in living mice. J Neurosci 14:5672-5686[Abstract].
Villaroel A, Sakmann B (1996) Calcium permeability increase of endplate channels in rat muscle during postnatal development. J Physiol (Lond) 496:331-338[Abstract/Free Full Text].
Wigston DJ, Sanes JR (1985) Selective reinnervation of intercostal muscles transplanted from different segmental levels to a common site. J Neurosci 5:1208-1221[Abstract].
Womble MD (1986) The clustering of acetylcholine receptors and formation of neuromuscular junctions in regenerating mammalian muscle grafts. Am J Anat 176:191-205[Web of Science][Medline].
Zambrowicz BP, Imamoto A, Fiering S, Herzenberg LA, Kerr WG, Soriano P (1997) Disruption of overlapping transcripts in the ROSA beta geo 26 gene trap strain leads to widespread expression of beta-galactosidase in mouse embryos and hematopoietic cells. Proc Natl Acad Sci USA 94:3789-3794[Abstract/Free Full Text].
Zhao H, Nonet ML (2000) A retrograde signal is involved in activity-dependent remodeling at a C. elegans neuromuscular junction. Development 127:1253-1266[Abstract].

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