Local Control of Acetylcholinesterase Gene Expression in Multinucleated Skeletal Muscle Fibers: Individual Nuclei Respond to Signals from the Overlying Plasma Membrane

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The Journal of Neuroscience, February 1, 2000, 20(3):919-928

Local Control of Acetylcholinesterase Gene Expression in Multinucleated Skeletal Muscle Fibers: Individual Nuclei Respond to Signals from the Overlying Plasma Membrane
Susana G. Rossi, Ana E. Vazquez, and Richard L. Rotundo
Department of Cell Biology and Anatomy, University of Miami School of Medicine, Miami, Florida 33136

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nuclei in multinucleated skeletal muscle fibers are capable of expressing different sets of muscle-specific genes dependingon their locations within the fiber. Here we test the hypothesisthat each nucleus can behave autonomously and responds to signalsgenerated locally on the plasma membrane. We used acetylcholinesterase(AChE) as a marker because its transcripts and protein are concentratedat the neuromuscular and myotendenous junctions. First, we showthat tetrodotoxin (TTX) reversibly suppresses accumulation ofcell surface AChE clusters, whereas veratridine or scorpion venom(ScVn) increase them. AChE mRNA levels are also regulated by membranedepolarization. We then designed chambered cultures that allowapplication of sodium channel agonists or antagonists to restrictedregions of the myotube surface. When a segment of myotube is exposedto TTX, AChE cluster formation is suppressed only on that region.Conversely, ScVn increases AChE cluster formation only where incontact with the muscle surface. Likewise, both the synthesisand secretion of AChE are shown to be locally regulated. Moreover,using in situ hybridization, we show that the perinuclear accumulationof AChE transcripts also depends on signals that each nucleusreceives locally. Thus AChE can be up- and downregulated in adjacentregions of the same myotubes. These results indicate that individualnuclei are responding to locally generated signals for cues regulatinggeneexpression.

Key words: neuromuscular junction; skeletal muscle; gene regulation; muscle differentiation; membrane depolarization; acetylcholinesterase

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Skeletal muscle fibers are large multinucleated cells that arise from the fusion of hundreds or thousands of mononucleatedmyoblasts and in vertebrates can be several centimeters long.These large cells develop morphologically and physiologicallyspecialized regions such as sites of insertion into tendons andbones, the myotendenous junctions, or points of contact with motoneurons,the neuromuscular junctions (NMJs). Different sets of genes areexpressed within the specialized domains and along the lengthof the fibers. Although functional compartmentalization of skeletalmuscle, both in culture and in vivo, has been well establishedby several laboratories including our own (for review, see Halland Ralston, 1989; Cartaud and Changeux, 1993; Hall and Sanes,1993), the mechanisms regulating the expression and repressionof the many muscle-specific genes along the length of the musclefibers are less well understood (Termin and Pette, 1992; Fallonand Hall, 1994; Duclert and Changeux, 1995; Burden and Yarden,1997; Buonanno and Fields, 1999).

Studies on the localized expression of acetylcholinesterase (AChE) transcripts in multinucleated myotubes showed that, oncetranscribed, the mRNAs do not diffuse very far in these structurallycomplex cells (Rotundo, 1990). Studies in adult muscle also showedthat AChE mRNA levels are significantly higher at sites of nerve-musclecontact, suggesting increased local transcription (Jasmin et al.,1993; Legay et al., 1995; Michel et al., 1994). Moreover, oncelocally translated, the AChE protein does not diffuse very far(Rossi and Rotundo, 1992, 1996). We also know that AChE is regulatedat least in part by muscle activity, the spontaneous or nerve-evokeddepolarization of the plasma membrane. Drugs that block membranedepolarization, such as the sodium channel antagonist tetrodotoxin(TTX), inhibit assembly of the collagen-tailed (A₁₂) AChE formthat in turn decreases accumulation of AChE on the cell surface(Rieger et al., 1980; Brockman et al., 1984; Fernandez-Valle andRotundo, 1989). Conversely, sodium channel agonists such as veratridine(Ver) dramatically increase A₁₂ AChE assembly (De La Porte etal., 1984).

Together, these studies indicate that synthesis, targeting, and localization of AChE are compartmentalized and suggest thatsignals generated at the plasma membrane overlying individualnuclei may be responsible for locally regulating AChE expression.To test this hypothesis we developed tissue culture chambers designedto isolate the medium overlying small regions of individual quailmyotubes. Sodium channel agonists or antagonists were then addedto one side of the chamber, and normal medium or medium with anotherdrug were added to the other side. Thus different regions of thesame myotubes were exposed to sometimes opposite acting compounds.Our results show that accumulation of AChE transcripts as wellas protein is locally regulated. This local expression suggeststhat each nucleus must be responding to signals that it receivesfrom the overlying plasma membrane, perhaps through activationof a localized second messenger system, providing one possiblemechanism for the regional differentiation in multinucleated musclefibers.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Preparation of tissue-cultured myotubes and design of chambers. Primary quail myoblasts were cultured in Eagle's Minimal EssentialMedium (EMEM) supplemented with 10% horse serum, 2% chick embryoextract, and 50 µg/ml gentamycin (normal medium). For conventionalcultures, myoblasts were plated on collagen-coated culture dishesand fed on the third and fifth days after plating. To expose differentregions of the same muscle fibers to different media, tissue culturechambers were designed based on the Campenot chambers (Campenot,1987) using 2-cm-diameter plastic or glass rings with a centraldivision made from no. 1 coverslip glass attached using siliconevacuum grease (Corning, Acton, MA) between the side of the divisionand the ring (see Fig. 1A,B). The myoblasts were plated on 2.5-cm-diametercollagen-coated glass coverslips that were lightly scratched with000 steel wool to promote parallel alignment of the myotubes (Rossiand Rotundo, 1992). The chambers were attached to the coverslipsusing silicone grease, with the central glass division placedperpendicular to the fibers. When used, pharmacological agentswere added to either one or both sides of the chambers from days4-6 as described under individual experiments. All cell culturesupplies were obtained from Life Technologies (Gaithersburg, MD),except horse serum, which was purchased from Gemini Bio-Products(Calabasas, CA). Scorpion venom (ScVn) (Androctonus australis),TTX, and Ver were purchased from Sigma (St. Louis,MO).

The following tests were used sequentially to determine the integrity of the sealed partitions. (1) After a partition wasplaced over the cells, medium was added first to one side of thechamber; if the medium leaked to the other side the culture wasdiscarded. (2) After both sides of the chamber were filled, adrop of trypan blue was added to one side, and the cultures werereturned to the incubator; if the dye diffused to the other side,the culture was discarded. (3) The culture chambers that passedthe first two tests were then treated experimentally. Before use,myotubes on one side of the chamber were fed with culture mediumcontaining a trace amount of ¹⁴C-sucrose, and the following day aliquots of medium from eachside of the chamber were counted in a liquid scintillation counter.Cultures that did not pass these tests were discarded. Overall,only 10-25% of the chambers passed thetests.

Assays of cell surface and total and secreted AChE activity: analysis of AChE forms. Conventional quail muscle cultures werewashed three times with 2 ml HBSS, and cell surface AChE activitywas assayed by addition of 800 µl buffer/substrate solution perdish consisting of 0.6 mM unlabeled acetylcholine in PBS, pH 7.4,and 0.1 µCi ³H-acetylcholine (New England Nuclear, Boston, MA) (specific activity73.7 mCi/mmol) (Rotundo and Fambrough, 1980). This cell surfaceAChE assay measures only the active enzyme localized on the externalsurface of the muscle fibers. After a 30 min incubation, 200 µlaliquots of the buffer/substrate solution were removed from eachculture dish, and the ³H-acetate produced was counted. Cell surface AChE was assayedin the chamber cultures using the same protocol except that thebuffer/substrate solution was divided between the two microchambers,and each side was counted separately. In addition, special doublechambers were designed to assay cell surface AChE activity. Thesame myotubes were divided by three glass partitions, the centralone as before plus one on each side separated by capillary tubesto form microchambers on each side of the central division. Thesemicrochambers were filled with medium plus 5 µM TTX or 20 nM ScVnas described inResults.

To measure total AChE activity and to determine the proportions of individual AChE oligomeric forms, conventional cultureswere extracted by scraping the cells into 500 µl/dish borate extractionbuffer (20 mM borate buffer, pH 9.0, 1.0 M NaCl, 0.5% Triton X-100,5 mM EDTA, 0.5% BSA, 2 mM benzamidine, 5 mM n-ethyl maleimide,0.7 mM bacitracin) as described previously (Rossi and Rotundo,1992). After centrifugation, the supernatants were either assayedfor total AChE activity or the AChE oligomeric forms were determinedby velocity sedimentation on 5-20% sucrose gradients centrifugedfor 17 hr at 40,000 rpm in a Beckman SW 41TI rotor. Enzyme activitywas assayed using a modification of the radiometric method ofJohnson and Russell (1975) as described previously (Rotundo, 1984b).

To determine the relative rates of AChE secretion, cultures were rinsed three times with HBSS followed by 10 min incubationwith 10 µM diisopropylfluorophosphate (DFP) in HBSS to irreversiblyinhibit all AChE activity. The cultures were rinsed with HBSSto remove unreacted DFP, 350 µl of modified defined medium (Bottensteinand Sato, 1979) was added to each side of the chambers, and thecultures were returned to the incubator for 7 hr. Modified definedmedium consisted of EMEM containing 5 mg/ml BSA, 20 µg/ml conalbumin,5 µg/ml porcine insulin, 50 µg/ml fibronectin, 100 µM putrescine,20 nM progesterone, and 30 nM selenium. At 1 hr intervals, 5 µlaliquots of medium were removed from each culture and kept onice until they were assayed for AChEactivity.

Immunofluorescence localization and quantitation of cell surface AChE clusters. Cell surface clusters of AChE were visualizedby indirect immunofluorescence (Rossi and Rotundo, 1992, 1993).All incubations were performed in PBS, pH 7.4, containing 10%horse serum (PBS/HS) using 20 µg/ml of anti-avian AChE mAb 1A2(Rotundo, 1984a) for 30 min, followed by 10 µg/ml of fluorescein-conjugatedrabbit anti-mouse IgG (Cappel, West Chester, PA). The cultureswere then fixed with 4% paraformaldehyde in PBS and incubatedwith 1 µg/ml Hoechst 33342 in PBS to stain the nuclei. To measurethe lengths of differentiated myotubes, fixed cultures were permeabilizedwith 0.1% Triton X-100 in PBS, rinsed, and stained with tetramethylrhodamineisothiocyanate (TRITC)-phalloidin (Molecular Probes, Eugene, OR)and Hoechst 33342. Chambers were mounted in bicarbonate-buffered90% glycerol containing 1 mg/ml phenylenediamine and viewed witha 40× objective on a Zeiss Universal microscope equipped forepifluorescence.

AChE clusters per nucleus on individual myotubes (conventional cultures) or over the divided fiber (chamber cultures) werequantified as previously described (Rossi and Rotundo, 1992).At least three cultures were analyzed for each experimental group,and 10 randomly selected fields per culture were counted usinga 40× oil immersion objective. The total number of nuclei in myotubesthat were counted as well as the total number of AChE clustersassociated with those myotubes are indicated for each experiment.Results are expressed as the mean and SE of at least three culturespergroup.

Quantitation of AChE mRNA expression by RNase protection assay. Total RNA from muscle cultures grown on 60 mm culture disheswas isolated after the rapid isolation technique described inSambrook et al. (1989), with minor modifications of the volumesto allow extraction using 1.5 ml microfuge tubes. A 302 nucleotidefragment of quail AChE cDNA, starting 46 nucleotides upstreamfrom the ATG translation start site, was subcloned in pGEM-4Zin both orientations. The plasmids were linearized with HindIIIand used as in vitro transcription templates to produce eitherantisense ³²P-labeled probe using ( $alpha$ -³²P)UTP (specific activity: 800 Ci/mmol; Dupont NEN, Wilmington,DE) or unlabeled sense transcript for use as a standard. The RNAsamples were hybridized overnight at 45°C and digested using 6U RNaseONE (Promega, Madison, WI) per 10 µg of RNA for 60 minat 25°C following the manufacturer's recommended protocol. Thedigests were ethanol-precipitated and electrophoresed on denaturingpolyacrylamide urea gels, and the protected RNA was quantitatedusing a Molecular Dynamics PhosphorImager. The absolute amountsof AChE mRNA protected were determined by comparison with knownamounts of sense RNA standards assayed in parallel and analyzedusing the Image Quantsoftware.

Localization of AChE mRNA by in situ hybridization. Digoxigenin-labeled probes were prepared using the DNA labeling kit fromBoehringer Mannheim (Indianapolis, IN) following the manufacturer'srecommended protocol. For detection of AChE transcripts, a 2443bp fragment of quail AChE cDNA, containing 663 bp of 3' codingregion and 1784 bp of 3' untranslated sequence, served as a template.This probe hybridizes to two bands on Northern blots of totalRNA from tissue-cultured quail muscle corresponding to the 5.0and 5.5 kb transcripts. The control for background hybridizationconsisted of digoxigenin-labeled probe prepared from the parentalpGEM-4Z plasmid (Promega) linearized using EcoRI.

The in situ hybridization procedure for tissue-cultured myotubes described by Horovitz et al. (1989) was followed with minormodifications. Quail muscle cultures grown on 35 mm dishes (conventionalcultures) or chamber cultures grown on collagen-coated coverslipswere fixed for 30 min at 4°C with freshly prepared 4% paraformaldehydein PBS, pH 7.4. Cultures were washed for 10 min in PBS and acetylatedfor 10 min at room temperature in a solution of 0.15 ml aceticanhydride in 50 ml 0.1 M triethanolamine, pH 8. Cultures werethen rinsed three times in 2× SSC and prehybridized at 55°C for4 hr or overnight in 50% formamide, 1% SDS, 10 mM DTT, 10% dextransulfate, 1 M NaCl, 100 µg/ml freshly denatured salmon sperm DNA,and 100 µg/ml yeast RNA. The prehybridization buffer was removed,and a 20 µl drop of hybridization solution consisting of prehybridizationbuffer plus 0.1 ng/µl of freshly denatured digoxigenin-labeledDNA probe was placed in the middle of the culture, covered witha coverslip, and hybridized overnight at 55°C. Cultures were thenrinsed with 2× SSC and washed consecutively at 55°C for 30 minin 50% formamide with 2× SSC, 50% formamide with 1× SSC, and atroom temperature with gentle agitation for 30 min in 1× SSC. Thehybridized digoxigenin-labeled probe was detected using alkalinephosphatase-conjugated anti-digoxigenin antibody from BoehringerMannheim at a concentration of 2 U/ml following the manufacturer'ssuggested procedure except that incubations with the first antibodywere performed for 1 hr. Color developing was stopped in all samplesat the same time after 12 hr, and the cultures were rinsed brieflyin PBS. Nuclei were stained using 1 µg/ml Hoechst 33342 in PBSfor 20 min. Cultures were washed for 10 min in PBS and then mountedby placing a 40 µl drop of mounting medium (0.1% phenylenediamineand 20 mM bicarbonate buffer, pH 9, in 90% glycerol) in the middleof the dish andcoverslipped.

Quantitation of AChE mRNA+ nuclei. Precise quantitation of AChE mRNA was always by RNase protection assay; however, in someexperiments we needed to determine the relative distribution ofAChE transcripts in different regions of the same fibers. To dothis, combined images of Hoechst-stained nuclei and dark-purpleprecipitate indicative of AChE mRNA in situ hybridization werecollected to quantify total number of myotube nuclei and the numberof myotube nuclei that had perinuclear in situ hybridization staining.The myotube nuclei that had perinuclear in situ hybridizationstaining are referred to as AChE mRNA+ nuclei throughout thisstudy. Images of seven different fields from each of three dishesper experimental condition were collected in each experiment.The fields were randomly selected from different areas of eachdish, making sure the whole dish was sampled. Images were capturedusing a Princeton Instruments Micro Max camera mounted on a ZeissUniversal microscope equipped for epifluorescence. A combinationof epifluorescence and transmitted illumination was used to colocalizenuclei and the in situ alkaline phosphatase staining. The resultingimages were analyzed and quantified using Metamorph software (UniversalImaging, West Chester,PA).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Establishment of parallel myotubes in divided chamber cultures

Myoblasts plated on lightly scratched collagen-coated glass coverslips continue to proliferate normally with a strong tendencyto align with the microscopic grooves in the substratum at thetime of fusion. This results in confluent muscle cultures withvirtually all of the myotubes lined up in parallel and ensuresthat approximately equal portions of the fibers will be exposedin each side of the chambers (Fig. 1). When the glass partitionswere sealed over the newly formed myotubes on day 4, the myotubescontinued to differentiate, organized a normal myofibrillar apparatus(Fig. 2), and initiated spontaneous contractions around day 5of culture. The fibers passing under the glass partition exhibitedspontaneous contractions on both sides, indicating that the barrierdid not disrupt the normal functioning of the cells. The musclecultures remained healthy for as long as 5 d after placement ofthe glass partition, at which time the strong spontaneous contractionsusually resulted in detachment of the cells from the coverslips.

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Figure 1. Design of culture chambers to isolate regions of individual myotubes. Myoblasts were plated on scratched collagen-coated glass coverslips and grown in normal medium until they were completely differentiated before the chamber partitions were placed. A, Diagram of a culture chamber showing orientation of the myotubes relative to the partition and retaining ring. B, Photograph of an actual chamber culture after placement of the partition across the myotubes. Scale bar, 1 cm. The drugs were usually added to one side of the chamber, and the other side served as control. Leakage from one side of the chamber to the other was detected by adding ¹⁴C-sucrose to one side. C, Combined transmitted light/epifluorescence photomicrograph of myotubes stained with Hoechst 33342 to highlight the myonuclei showing that the fibers have grown undisturbed under the glass partition (central part, arrowhead). Scale bar, 100 µm.

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Figure 2. Glass/grease partition does not perturb myotube differentiation. Chambers were placed on top of 4-d-old cultures for 2 d as detailed in Materials and Methods. Without removing the chambers, cultures were fixed, treated with 0.1% Triton X-100 for 10 min, and labeled with TRITC-phalloidin for 1 hr. Pictures were taken using a 10× objective (A) to show that the glass partition (between arrows) is located on top of myotubes as in Figure 1. Photomicrographs using a 40× oil immersion objective (B, C) show details of the myofibrillar apparatus from a region of a myotube located outside the glass partition as a control (B), and from a region of a myotube located under the glass partition (C) showing that the synthesis and assembly of this complex protein structure is unaffected.

The lengths of the myotubes running beneath the partition in the chamber cultures were measured using a calibrated eyepiecemicrometer and a 10× objective. Cultures were fixed, permeabilizedwith 0.1% Triton X-100, and incubated with TRITC-phalloidin (MolecularProbes) to stain the myofibrillar apparatus and with Hoechst 33342to label nuclei, facilitating identification and tracing of individualfibers. At least 15 myotubes were measured from each of threecultures. The average length of the myotubes extending beneaththe chamber partitions was 1.8 ± 0.1 mm. The observation thata normal myofibrillar apparatus develops in the regions of myotubebeneath the glass partitions indicates that the chambered culturesdo not interfere with the normal metabolic processes of the musclefibers.

AChE expression is regulated by membrane depolarization

Studies from several laboratories have shown that synthesis and assembly of AChE are regulated by the activity state of themuscle (Koenig and Vigny, 1978; Brockman et al., 1984; Rubin,1985; Fernandez-Valle and Rotundo, 1989). For example, sodiumchannel antagonists such as TTX suppress A₁₂ AChE assembly andcell surface AChE accumulation (Rieger et al., 1980; Koenig etal., 1982; Brockman et al., 1984; Rubin, 1985; Fernandez-Valleand Rotundo, 1989), whereas sodium channel agonists such as Verincrease it (De La Porte et al., 1984; Rubin et al., 1985). Twoother sodium channel agonists, ScVn (Sigma) and brevetoxin (BvTx)(kindly provided by Dr. D. Baden), were tested in our experimentswith the same results as Ver. In the present studies, we usedScVn because unlike Ver it is a hydrophilic molecule and actsfrom the outside of the cells. Veratridine is membrane permeableand therefore its effect is not limited to one side of thechamber.

Figure 3 illustrates the effects of TTX and ScVn on the expression of AChE forms. In TTX-treated cultures, the A₁₂ collagen-tailedAChE form is reduced to <25% of the A₁₂ form in control cultures,whereas there was little or no change in the globular G₂/G₁ orG₄ forms. In ScVn-treated cultures, the A₁₂ form increased to200% of controls with a 40% decrease in the G₂/G₁ and little effecton the G₄. Similar results were obtained using Ver and BvTx. TheA₁₂ forms in Ver- and BvTx-treated cultures were 264 and 158%,respectively, compared with untreated control cultures. At thesame time, G₂/G₁ forms in Ver- and BvTx-treated cultures were46 and 80% of the G₂/G₁ forms in control cultures. Thus the membrane-impermeantsodium channel agonist scorpion toxin is as effective as the morecommonly used membrane-permeant Ver in increasing expression ofA₁₂ AChE while decreasing the levels of the globular G₂/G₁ forms.

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Figure 3. Expression of AChE oligomeric forms in muscle cultures treated with TTX or ScVn. Four-day-old conventional muscle cultures were incubated for 48 hr in either normal medium (A) or medium containing 5 µM TTX (B) or 2 nM ScVn (C). On day 6, AChE was extracted, and the oligomeric forms were analyzed by velocity sedimentation on sucrose gradients. There is a slight increase in G2/G1 globular forms in the presence of TTX and a 50% decrease in the presence of ScVn, suggesting that the newly synthesized enzyme decreases. In contrast, the collagen-tailed (A₁₂) AChE form, which predominates in all surface clusters (Rossi and Rotundo, 1992), is decreased by >50% in the presence of TTX and doubled in the presence of ScVn, indicating that changes in membrane depolarization mediated by agonists or antagonists of the voltage-dependent sodium channels can regulate AChE expression.

Local secretion of AChE is regulated by membrane depolarization

Myotubes normally secrete most of their newly synthesized AChE into the culture medium (Rotundo and Fambrough, 1980), andthe relative proportions secreted are influenced in part by membranedepolarization (Fernandez-Valle and Rotundo, 1989). To determinewhether local membrane depolarization could regulate the amountof AChE released into the medium, we measured the rates of AChEsecretion in TTX- or ScVn-treated sides of chamber cultures relativeto the control side. Enzyme activity was measured in aliquotsof medium sampled every hour for 7 hr, and the resulting activitieswere plotted as percentage of untreated control side. Figure 4shows that the rate of AChE secretion on the TTX-treated sideis increased 1.48-fold relative to the control side, whereas theratio of the ScVn side to control is 0.24. Thus, regions of themyotubes exposed to TTX increase their secretion of AChE intothe surrounding medium, whereas secretion by regions exposed toScVn is decreased. These results show that the local rate of AChEsecretion depends on signals originating on the overlying regionof membrane.

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Figure 4. Compartmentalized regulation of AChE secretion in muscle. Chamber cultures were treated with TTX or ScVn on one side and normal medium on the other from days 4 to 6. The cultures were then DFP-treated to inhibit all AChE and returned to the incubator for 7 hr in defined medium with or without sodium channel agonist or antagonist. At hourly intervals, 5 µl aliquots of the medium were taken from each side of the chamber to measure newly synthesized secreted AChE activity. Individual values were normalized by expressing them as percentage of the maximum value of the control (untreated) side of each chamber culture. Each plot consists of serial samples from a single culture chamber, and the experiment was repeated twice with identical results.

Cell surface assay of AChE activity shows local accumulation of the enzyme

Although most of the newly synthesized AChE in tissue-cultured myotubes is secreted into the medium, a small fraction alsobecomes attached to the cell surface (Rotundo and Fambrough, 1980).To determine whether local membrane depolarization could regulatethe amount of newly synthesized AChE externalized by the myotubes,we measured the relative amounts of enzyme accumulated on thecell surface. Cell surface AChE activity was assayed on myotubestreated from days 4 to 6 with either 5 µM TTX or 20 nMM ScVn asdescribed in Materials and Methods. The results, presented inTable 1, show that cell surface AChE activity in conventional35 mm dishes was increased in the presence of ScVn and decreasedin the presence of TTX. Cell surface AChE activity on TTX-treatedmyotubes was 63% of ScVn-treated cultures.


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Table 1. Cell surface AChE activity on myotubes is regulated by membrane depolarization

Double chambers were then designed to measure cell surface AChE activity on small, 1-mm-wide regions of the myotubes as describedin Materials and Methods. TTX was added to one microchamber andScVn to the other from days 4 to 6 in culture, and cell surfaceAChE activity was measured in each microchamber. Cell surfaceAChE activity on the TTX-treated side was 82 ± 1 cpm, whereasthe ScVn-treated side was 149 ± 5 cpm. Cell surface AChE activityon the TTX-treated region was 55% of the activity on the ScVn-treatedside, measured as an average of three chambers. Thus, like theconventional cultures, cell surface AChE activity assayed in thedouble chambers showed increased accumulation restricted to regionsof the myotubes exposed to ScVn, whereas activity was decreasedon regions exposed to TTX. These results (Table 1) indicate thatlocalized opening of the sodium channels results in increasedcell surface AChE activity only on the exposed region of the membrane,whereas inhibition of membrane depolarization locally decreasesitsaccumulation.

Regulation of AChE cluster formation by local membrane depolarization

To determine whether the formation of AChE clusters over individual nuclei could be regulated by locally generated signals,TTX or ScVn was added to one side of the chambers, and normalmedium was added to the other from days 4 to 6 in culture. Thecultures were then incubated with mAb 1A2 to label cell surfaceAChE and with Hoechst 33342 to stain the nuclei. Parallel setsof conventional coverslip cultures were treated with TTX or ScVnfrom days 4 to 6 or fed with normal medium until day 6 (controls).See Figure 5A-D for examples of AChE clusters localized over thenuclei. Quantitation of AChE clusters per nucleus for each groupshowed that cluster formation was suppressed by TTX and increasedby ScVn only in those fiber regions exposed to the drug, indicatingthat the accumulation of cell surface AChE over individual nucleiis dependent on the response of the nucleus to signals generatedon the overlying plasma membrane. These results are summarizedin Table 2.

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Figure 5. Regulation of cell surface AChE cluster formation on conventional and divided myotubes. Conventional myotube cultures grown on collagen-coated coverslips were incubated in complete medium with or without TTX or ScVn from days 4 to 6. For divided myotube cultures, TTX or ScVn in complete medium was added to one side of the chamber and complete medium alone to the other side from days 4 to 6. The cultures were then labeled with mAb 1A2 to localize cell surface AChE clusters and Hoechst 33342 to stain the nuclei, and the numbers of nuclei and AChE clusters were quantitated (see Materials and Methods and Table 2). A, C, Clusters of AChE visualized by indirect immunofluorescence. B, D, Underlying nuclei stained with Hoechst 33342. A, B and C, D are the same fields viewed through their respective filters. Scale bar, 25 µm. E, The results of quantitation are expressed as the ratio of AChE clusters per nucleus on the experimental side of the myotubes to the control side. Open bars, Conventional cultures; hatched bars, chamber cultures. Quantitation of AChE clusters per nucleus for each group showed that cluster formation was suppressed by TTX and increased by ScVn in the conventional cultures and in the chamber cultures only on those fiber regions exposed to the drug, indicating that the clustering of AChE over individual nuclei is dependent on signals generated on the overlying plasma membrane.


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Table 2. Quantitation of cell surface AChE clusters on conventional and divided myotube cultures treated with TTX or ScVn

The number of AChE clusters in treated versus untreated control cultures can also be expressed as a ratio that more clearlycompares the results of individual experiments. In the presentexperiments, the ratio of AChE clusters per nucleus on TTX-treatedcultures to clusters per nucleus on control cultures is 0.33 ±0.01. A similar ratio, 0.27 ± 0.05, was obtained in chamber cultures,where one side of the chamber was TTX-treated and the other sidewas kept in normal medium. The ratio of AChE clusters per nucleuson ScVn-treated versus control cultures was 1.84 ± 0.40, whereasa similar value, 1.71 ± 0.25, was obtained in chamber cultureswhere one side of the chamber was treated with ScVn and the otherside kept in normal medium. Figure 5E shows the ratios of AChEclusters per nucleus on treated cultures versus control on conventionaland chamber cultures. Note that the magnitude of the effect isessentially the same using conventional cultures and chamber cultures.These results emphasize the magnitude of the differences betweenthe effects of positive and negative regulators on the accumulationof cell surface AChE and its dependence on localsignals.

AChE mRNA levels are regulated by membrane depolarization

To determine whether AChE transcript levels were regulated by muscle activity, tissue-cultured quail myotubes were treatedfrom day 4 to day 6 with TTX, ScVn, or Ver. Untreated controlcultures received normal medium. Total RNA purified from eachdish was assayed by RNase protection assay, electrophoresed ondenaturing polyacrylamide urea gels, and exposed using a phosphorimagerfor quantitation by comparison with known AChE RNA standards (Fig.6). The values are expressed in terms of percentage of controlcells in normal medium (100 ± 12%). AChE mRNA levels are slightlyincreased in the presence of TTX (126 ± 4%), whereas they aresignificantly decreased when ScVn (15 ± 7%) or Ver (27 ± 1%) isadded to the medium. Thus the extent and/or frequency of membranedepolarization affects the levels of AChE mRNA in myotubes.

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Figure 6. Regulation of AChE mRNA levels by membrane depolarization. Conventional quail muscle cultures were incubated from days 4 to 6 in complete medium with or without TTX, ScVn, or Ver, and the AChE transcript levels were measured by RNase protection assay (for details, see Materials and Methods). A, Autoradiogram of PAGE analysis of protected AChE mRNA isolated from control cultures (C) or cultures treated with Ver, ScVn, or TTX. The last four lanes are the protected bands from 10 µg of yeast RNA containing 0, 5, 15, and 50 pg of an in vitro-transcribed synthetic sense AChE transcript used as a standard. B, Quantitation of AChE mRNA levels, expressed as percentage of untreated control cultures. Treatment of cultures with TTX resulted in slightly increased AChE mRNA levels, whereas treatment with Ver or ScVn reduced the transcript levels by 75-90%.

Localization of AChE mRNA in quail muscle cultures

Preliminary in situ hybridization studies in our laboratory using digoxigenin-labeled cDNA probes for AChE transcripts showedthat AChE mRNA is not evenly distributed in the myotubes; ratherit is concentrated around individual nuclei (see Fig. 8A,B). Thisperinuclear localization of AChE mRNA around some but not allof the myonuclei has been described earlier for chicken musclecultures (Tsim et al., 1992) as well as for human muscle cultures(Grubic et al., 1995). Previous studies from our lab using a quantitativePCR assay in adult avian muscle fibers (Jasmin et al., 1993) aswell as studies in adult mammalian muscle (Legay et al., 1995;Michel et al., 1995) have also shown that predominantly specificpopulations of nuclei, the ones at the neuromuscular junction,express higher levels of AChEtranscripts.

To determine whether TTX or ScVn treatments changed the number of nuclei with perinuclear localization of AChE mRNA, quailmuscle cultures were analyzed by in situ hybridization after treatmentwith sodium channel agonists or antagonists from days 4-6. Figure7 shows in situ hybridization analysis of conventional cultures.The intensity of the perinuclear staining specific for AChE aswell as the extent of the perinuclear area labeled varied considerablydepending on the treatment, in agreement with the more quantitativeRNase protection studies. Myotubes treated with TTX increasedthe number of nuclei expressing AChE transcripts, whereas ScVn-treatedcells reduced them. The results of quantifying the number of AChEmRNA+ nuclei in these cultures are summarized in Table 3 (seenext section for additional discussion).

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Figure 7. Membrane depolarization reduces the number of AChE mRNA-positive nuclei in tissue-cultured myotubes. Quail muscle cultures were incubated from days 4 to 6 in the presence or absence of TTX or ScVn and analyzed by in situ hybridization using a digoxigenin-labeled random-primed quail AChE cDNA probe. After development of the reaction product (dark staining), the nuclei were stained with Hoescht 33342, and the photomicrographs were taken with a combination of transmitted and fluorescence illumination to show the close relationship of the in situ hybridization product to the myonuclei. A, Background control using plasmid vector pGEM-4Z DNA probe alone; B, distribution of AChE transcripts in untreated control cultures; C, distribution of AChE transcripts in cultures treated with TTX from days 4 to 6; D, distribution of AChE transcripts in cultures treated with ScVn. Treatment of myotubes with TTX, a sodium channel blocker, increased the number of nuclei expressing AChE transcripts, whereas treatment with ScVn, a sodium channel agonist, reduced the number of nuclei expressing AChE transcripts. Solid arrows, Nuclei with AChE mRNA reaction product counted as positive; open arrows, nuclei counted as negative (see Fig. 8 for a higher power photomicrograph). The large nuclei of the fibroblasts, marked with asterisks in C, are always negative compared with the smaller myonuclei in myotubes. Note that the fibroblasts occupy much of the space between the multinucleated myotubes characterized by their small oval nuclei.


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Table 3. Quantitation of AChE mRNA+ nuclei in conventional and divided myotube cultures treated with TTX or ScVn

Compartmentalized regulation of AChE mRNA levels by local membrane depolarization

The activity state of the muscle clearly affects the levels of AChE transcripts as well as their distribution around the myonuclei.To determine whether AChE mRNA accumulation around individualnuclei was influenced by signals from the overlying region ofplasma membrane, culture chambers were treated with TTX or ScVnon one side of the division and normal medium on the other sidefrom days 4 to 6. In situ hybridization experiments on chambercultures followed the same procedure described for conventionalcultures. Myotubes that were intact and easily seen to grow underthe division of the chamber and extend from the control side tothe drug-treated side were identified. The total number of nucleiin each side of each of these fibers was counted, and the numberof nuclei that had AChE mRNA accumulations (AChE mRNA+ nuclei)was determined for each side of the same fibers. In this way,the percentage of AChE mRNA+ nuclei could be calculated for eachside of the chambers. For the TTX-treated group, 37% of the nucleiin the control side of the chambers were AChE mRNA+, whereas inthe TTX-treated side 60% of the nuclei were AChE mRNA+. For theScVn-treated group, 31% of the nuclei in the control side wereAChE mRNA+, whereas in the ScVn-treated side the percentage wasmuch lower: only 14% of the nuclei were AChE mRNA+. In a separateseries of experiments, conventional cultures were treated withTTX or ScVn from days 4 to 6 or kept in normal medium as controls.After in situ hybridization and staining of nuclei, the totaland AChE mRNA+ nuclei in seven fields of each of three independentdishes in two separate experiments were counted, and the percentageof AChE mRNA+ nuclei was then calculated. Results from the conventionalcultures were essentially the same as results obtained with thechamber cultures. In the control conventional cultures, 24 and33% (experiments 1 and 2, respectively) of the nuclei were AChEmRNA+. When treated with TTX, the percentage of AChE mRNA+ nucleiincreased to 61 and 66%, respectively, whereas ScVn treatmentdecreased the percentage of AChE mRNA+ nuclei to 16 and 15%. Thetotal number of nuclei counted in each experiment and resultsare summarized in Table 3. Expressing the numbers of RNA+ nucleias percentage of untreated controls (Fig. 8C) allows a bettercomparison of the conventional and chambered cultures and clearlyshows the localized suppressive effects of membrane depolarizationon AChE mRNA expression.

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Figure 8. Local control of AChE mRNA expression in myonuclei underlying regions of plasma membrane exposed to sodium channel agonists or antagonists. Chamber cultures were prepared as described in Materials and Methods, and either TTX or ScVn was added to one side of the chambers from days 4 to 6. Conventional cultures were treated in parallel. A, B, Enlarged segment of two myotubes showing perinuclear distribution of the AChE mRNA in situ hybridization reaction product. The cells were stained as described in the legend to Figure 7. C, The ratio of AChE mRNA+ nuclei to the total number of nuclei in divided myotubes was determined by in situ hybridization (hatched bars). Just as for conventional cultures (open bars), treatment with a sodium channel blocker increases the number of nuclei expressing AChE transcripts, whereas treatment with sodium channel agonist reduced the number of nuclei expressing AChE mRNA. These effects are restricted to nuclei underlying regions of the plasma membrane exposed to the drugs, indicating that each nucleus responds to locally generated signals originating at the overlying plasma membrane.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Studies from several laboratories, including our own, have established that skeletal muscle fibers are highly compartmentalizedwith respect to the expression of several muscle-specific proteinsand genes (for review, see Hall and Ralston, 1989; Cartaud andChangeux, 1993; Duclert and Changeux, 1995). Thus sarcoplasmicproteins synthesized in the vicinity of one myonucleus have alow probability, on average, of diffusing to the vicinity of anothernucleus. Likewise, transcripts expressed by one nucleus have alow probability of translation on the endoplasmic reticulum inthe vicinity of another nucleus. Although the mechanisms underlyingthis compartmentalization are not known, it is likely that simplephysical barriers, such as limits in the volume of cytoplasm surroundinga given nucleus and restrictions in space occupied by the densemyofibrillar apparatus, play as much a role as more highly organizedmechanisms such as interactions of specific transcripts with cytoskeletalelements and localized second messenger systems. Clearly one initialstep in establishing these compartments must involve the establishmentof local patterns of geneexpression.

One possible mechanism for establishing unique patterns of gene expression in different regions of multinucleated skeletalmuscle fibers could depend on the timing of cell fusion or originof myoblasts, giving rise to the myonuclei of the different regionsof the fiber. During skeletal muscle development, nuclei contributedby the earliest myoblasts to fuse tend to be localized in thecentral region of the fibers, whereas nuclei located in the regionof the myotendenous junctions tend to derive from later populationsof myoblasts. This is because myoblasts tend to fuse at the endsof the fibers, and therefore the fibers grow in length by additionto the myotendenous region. This model would suggest that differentpopulations of myoblasts were committed to different patternsof gene expression, with the earlier progenitors giving rise tothe subsynaptic nuclei and later ones giving rise to those inthe extrajunctional regions and later those of the myotendenousjunction.

Another possibility is that the myoblasts fusing with a given muscle fiber are essentially identical with respect to theirrepertoire of expressed genes and that this repertoire becomesmore highly specified depending on where in the fibers the nucleireside. In this model each nucleus would receive information generatedlocally and would alter its expression of specific genes accordingly.Although the muscle phenotype is specified during determinationof the myogenic lineage (Cossu et al., 1996; Molkentin and Olson,1996), this local control of gene expression would constitutemore of a fine tuning of the phenotype, a highly refined mechanismfor mediating plasticity in accord with the physiological demandsimposed on the muscle. At the same time, this type of mechanismwould also facilitate repair of damaged muscle by allowing localfusion of satellite cells wherever needed that in turn would expresswhichever proteins were locally required, like the induction ofnew NMJ-like domains in muscle in vivo by local expression ofthe MuSK kinase domain (Jones et al., 1999).

Acetylcholinesterase is an excellent marker for studying local regulation of gene expression because it is regulated at leastin part by muscle activity, and in adult muscle it is restrictedto specific regions of the fibers such as the neuromuscular andmyotendenous junctions. In noninnervated regions of the fibers,referred to as extrajunctional, expression of AChE is usuallysuppressed (for review, see Massoulié et al., 1993). At the vertebrateneuromuscular junction, for example, AChE protein and transcriptsare more highly expressed than in the neighboring extrajunctionalsegments (Jasmin et al., 1993; Legay et al., 1995; Michel et al.,1994), and in fact the levels drop dramatically outside the 50-to 100-µm-wide region of innervation. Thus compartmental boundariesare narrowly defined in vivo and may reflect the same underlyingmechanisms found in cultured muscle cells. However, the cellularsignals as well as the molecular mechanisms responsible for thedownregulation of AChE in noninnervated regions of the fibers,and the upregulation of the enzyme at the neuromuscular junction,are stillunknown.

To study the compartmentalized regulation of AChE, we adapted the partitioned culture chambers developed by Campenot (1987)to muscle fibers by first growing the myotubes on scratched collagen-coatedcoverslips, which promotes parallel fiber growth, followed byplacement of a glass partition sealed with silicone grease perpendicularto the myotubes (Fig. 1). A successful seal is totally dependenton an even coating of silicone grease on the bottom of the glasspartition and occurs approximately 1 out every 5-10 tries. Oncein place, however, the partition does not perturb the cells anddifferentiation proceeds normally (Fig. 2).

Regulation of AChE occurs at several levels in electrically excitable cells. In the present studies we have shown that atleast four separate levels of AChE regulation are controlled atthe local level in multinucleated muscle fibers (Table 4). Secretionis the fate of the majority of newly synthesized AChE moleculesin tissue-cultured muscle (Rotundo and Fambrough, 1980), and thereforethe rate of secretion closely parallels the rate of synthesis.The observation that secretion of AChE is increased in regionsof the myotubes exposed to TTX and reduced in regions treatedwith ScVn implies that the synthesis of the enzyme is regulatedby local membrane activity (Fig. 4). At the same time, the levelsof AChE transcripts are regulated in parallel. Blocking membranedepolarization with TTX results in increased levels of AChE transcripts,whereas chronic membrane depolarization using ScVn results indecreased AChE mRNA only around those nuclei located in the treatedregion (Figs. 7, 8; Table 3). A similar parallel regulation ofnicotinic ACh receptor subunit proteins and transcripts is wellestablished in both birds and mammals (for review, see Hall andSanes, 1993; Duclert and Changeux, 1995).


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Table 4. Summary of effects of scorpion venom and tetrodotoxin on AChE

It is of interest to note the distribution of AChE mRNA in the myotubes (Fig. 7). In most myotubes the AChE transcripts appearas bilateral accumulations at the poles of the oval-shaped myonuclei,which are clearly visible in untreated myotubes. When AChE mRNAlevels are upregulated, as when the cells are treated with TTX,the transcripts appear to fill the myotubes (Fig. 7C), whereaswhen the transcripts are downregulated with ScVn, only a few nucleipresent local accumulations of AChE mRNA (Fig. 7D). Changes inAChE mRNA levels are reflected not only in changes in the absolutelevels of transcripts measured using a sensitive RNase protectionassay (Fig. 6), they are also reflected in changes in the numbersof nuclei that exhibit perinuclear accumulations of AChE mRNA(Fig. 8C). These observations suggest that regulation of the AChEtranscript could be an "on/off" event at individual nuclei withinthe myotubes. This intriguing possibility remains to be testeddirectly.

After synthesis on the rough endoplasmic reticulum and assembly into the globular dimeric and tetrameric AChE forms, a subsetof the catalytic subunits also is assembled with the noncatalyticcollagen-like tail (Rotundo, 1984a). The collagen-like tail isnecessary for attachment of AChE to the extracellular matrix ofmuscle and the formation of cell surface clusters of the enzyme(Rotundo et al., 1997; Peng et al., 1999). The assembly of AChEcatalytic subunits with the collagen-like tail also depends onmembrane depolarization. In denervated muscle, or muscle paralyzedby TTX, the collagen-tailed form is not assembled (for review,see Massoulié et al., 1993). In tissue-cultured muscle, the assemblyof the collagen-tailed form is inhibited in the presence of TTXand enhanced in the presence of Na channel agonists such as Veror ScVn [De La Porte et al. (1984), and Fig. 3]. In the chambercultures, TTX blocks the accumulation of cell surface AChE, whereasScVn increases it (Table 1). As would be predicted by the lackof assembly of the collagen-tailed AChE, TTX also blocks the formationof cell surface AChE clusters (Fig. 5E, Table 2), and in parallelwith the increase of cell surface AChE after treatment with ScVn,there is also an increase in the formation of AChE clusters. Thatthese changes also occur over the small regions of the surfaceof the myotubes that are exposed to the drugs in the chamberedcultures indicates that the area around each nucleus is respondingautonomously to the locally generated signals. The formation ofAChE clusters is especially important because these clusters alsoinclude several other molecular components of the neuromuscularjunction, including the nicotinic acetylcholine receptor and heparansulfate proteoglycan(perlecan).

We have shown that the expression of AChE can be locally controlled in multinucleated skeletal muscle fibers at the levelsof mRNA accumulation, protein synthesis, assembly, secretion,accumulation on the cell surface, and finally in the formationof clusters with other synaptic components. In each case the signalsthat regulate the specific molecular processes can be shown tooriginate on the plasma membrane, because in each case local changesin membrane depolarization are what gave rise to the observedchanges. The changes in membrane depolarization that decreaseAChE transcript levels and increase assembly of the collagen-tailedform of the enzyme are similar to those that occur during normalphysiological activity in the mature fibers, as well as duringspontaneous contraction of muscle that occurs after onset of differentiationin culture. Thus it is likely that similar mechanisms operateto downregulate AChE expression in extrajunctional regions ofmuscle and increase expression of the matrix-bound form of theenzyme in junctional regions of thefibers.

  FOOTNOTES

Received June 3, 1999; revised Nov. 10, 1999; accepted Nov. 11, 1999.

This research was supported by Grant AG05917 from the National Institute on Aging to R.L.R. A.E.V. was a recipient of a minoritypostdoctoral fellowship supplement from the National Instituteon Aging. We thank Julie Bailey for assistance in preparing thechamber cultures during the course of these experiments. We alsothank Dr. Daniel Baden for providing the brevetoxin as part ofa pilot project sponsored by the National Institute of EnvironmentalHealth Sciences Marine and Freshwater Biomedical Sciences Centerat the University of Miami, GrantES05705.
Correspondence should be addressed to Dr. Richard L. Rotundo, Department of Cell Biology and Anatomy (R-124), University ofMiami School of Medicine, 1600 N.W. 10th Avenue, Miami, FL 33136.E-mail: rrotundo{at}miami.edu.

Dr. Vazquez's present address: Department of Otolaryngology, University of Miami School of Medicine, Miami, FL33136.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Bottenstein JE, Sato GH (1979) Growth of a rat neuroblastoma cell line in serum-free supplemented medium. Proc Natl Acad Sci USA 76:514-517[Abstract/Free Full Text].
Brockman SK, Younkin LH, Younkin SG (1984) The effect of spontaneous electromechanical activity on the metabolism of acetylcholinesterase in cultured embryonic rat myotubes. J Neurosci 4:131-140[Abstract].
Buonanno A, Fields RD (1999) Gene regulation by patterned electrical activity during neural and skeletal muscle development. Curr Opin Neurobiol 9:110-120[ISI][Medline].
Burden S, Yarden Y (1997) Neurogulins and their receptors: a versatile signaling module in organogenesis and oncogenesis. Neuron 18:847-855[ISI][Medline].
Campenot RB (1987) Local control of neurite sprouting in cultured sympathetic neurons by nerve growth factor. Brain Res 465:293-301[Medline].
Cartaud J, Changeux JP (1993) Post-transcriptional compartmentalization of acetylcholine receptor biosynthesis in the subneural domain of muscle and electrocyte junctions. Eur J Neurosci 5:191-202[ISI][Medline].
Cossu G, Tajbakhsh S, Buckingham M (1996) How is myogenesis initiated in the embryo? Trends Genet 12:218-223[ISI][Medline].
De La Porte S, Vigny M, Massoulié J, Koenig J (1984) Action of veratridine on acetylcholinesterase in cultures of rat muscle cells. Dev Biol 106:450-456[ISI][Medline].
Duclert A, Changeux JP (1995) Acetylcholine receptor gene expression at the developing neuromuscular junction. Physiol Rev 75:339-368[Free Full Text].
Fallon JR, Hall ZW (1994) Agrin and dystroglycan: building synapses together. Trends Neurosci 17:469-473[ISI][Medline].
Fernandez-Valle C, Rotundo RL (1989) Regulation of acetylcholinesterase synthesis and assembly by muscle activity: effects of tetrodotoxin. J Biol Chem 264:14043-14049[Abstract/Free Full Text].
Grubic Z, Komel R, Walker WF, Miranda AF (1995) Myoblast fusion and innervation with rat motor nerve alter distribution of acetylcholinesterase and its mRNA in cultures of human muscle. Neuron 14:317-327[ISI][Medline].
Hall ZW, Ralston E (1989) Nuclear domains in muscle cells. Cell 59:771-772[ISI][Medline].
Hall ZW, Sanes JR (1993) Synaptic structure and development: the neuromuscular junction. Cell/Neuron Rev [Suppl] 72:99-121.
Horovitz O, Spitsberg V, Salpeter MM (1989) Regulation of acetylcholine receptor synthesis at the level of translation in rat primary muscle cells. J Cell Biol 108:1817-1822[Abstract/Free Full Text].
Jasmin BJ, Lee RK, Rotundo RL (1993) Compartmentalization of acetylcholinesterase mRNA and enzyme at the vertebrate neuromuscular junction. Neuron 11:467-477[ISI][Medline].
Johnson CD, Russell RL (1975) A rapid, simple radiometric assay for cholinesterase, suitable for multiple determinations. Anal Biochem 64:229-238[ISI][Medline].
Jones G, Moore CH, Hashemolhosseini S, Brenner HR (1999) Constitutively active MuSK is clustered in the absence of agrin and induces ectopic postsynaptic-like membranes in skeletal muscle fibers. J Neurosci 19:3376-3383[Abstract/Free Full Text].
Koenig J, Vigny M (1978) Neural induction of the 16S acetylcholinesterase in muscle cell cultures. Nature 271:75-77[Medline].
Koenig J, Oren M, Malone MA (1982) Establishment of neuromuscular contacts in cultures of rat embryonic cells: effects of tetrodotoxin on maturation of muscle fibers and on formation and maintenance of acetylcholinesterase and acetylcholine receptor clusters. Dev Neurosci 5:314-325[ISI][Medline].
Legay C, Huchet M, Massoulié J, Changeux JP (1995) Developmental regulation of acetylcholinesterase transcripts in the mouse diaphragm: alternative splicing and focalization. Eur J Neurosci 7:1803-1809[ISI][Medline].
Massoulié J, Pezzementi L, Bon S, Krejci E, Vallette FM (1993) Molecular and cellular biology of cholinesterases. Prog Neurobiol 41:31-91[ISI][Medline].
Michel RN, Vu CQ, Tetzlaff W, Jasmin BJ (1994) Neural regulation of acetylcholinesterase mRNAs at mammalian neuromuscular synapses. J Cell Biol 127:1061-1069[Abstract/Free Full Text].
Molkentin JD, Olson EN (1996) Combinatorial control of muscle development by basic helix-loop-helix and MADS-box transcription factors. Proc Natl Acad Sci USA 93:9366-9373[Abstract/Free Full Text].
Peng HB, Xie H, Rossi SG, Rotundo RL (1999) Acetylcholinesterase clustering at the neuromuscular junction involves perlecan and dystroglycan. J Cell Biol 145:911-921[Abstract/Free Full Text].
Rieger F, Koenig J, Vigny M (1980) Spontaneous contractile activity and the presence of the 16S form of acetylcholinesterase in rat muscle cells in culture. Dev Biol 76:358-365[ISI][Medline].
Rossi SG, Rotundo RL (1992) Cell surface acetylcholinesterase molecules on multinucleated myotubes are clustered over the nucleus of origin. J Cell Biol 119:1657-1667[Abstract/Free Full Text].
Rossi SG, Rotundo RL (1993) Localization of "non-extractable" acetylcholinesterase to the vertebrate neuromuscular junction. J Biol Chem 268:19152-19159[Abstract/Free Full Text].
Rossi SG, Rotundo RL (1996) Transient interactions between collagen-tailed acetylcholinesterase and sulfated proteoglycans prior to immobilization on the extracellular matrix. J Biol Chem 271:1979-1987[Abstract/Free Full Text].
Rotundo RL (1984a) Purification and properties of the membrane-bound form of acetylcholinesterase from chicken brain. Evidence for two distinct polypeptide chains. J Biol Chem 259:13186-13194[Abstract/Free Full Text].
Rotundo RL (1984b) Asymmetric acetylcholinesterase is assembled in the Golgi apparatus. Proc Natl Acad Sci USA 81:479-483[Abstract/Free Full Text].
Rotundo RL (1990) Nucleus-specific translation and assembly of acetylcholinesterase in multinucleated muscle cells. J Cell Biol 110:715-719[Abstract/Free Full Text].
Rotundo RL, Fambrough DM (1980) Synthesis, transport and fate of acetylcholinesterase in cultured chick embryo muscle cells. Cell 22:583-594[ISI][Medline].
Rotundo RL, Rossi SG, Anglister L (1997) Transplantation of quail collagen-tailed acetylcholinesterase molecules onto the frog neuromuscular synapse. J Cell Biol 136:367-374[Abstract/Free Full Text].
Rubin LL (1985) Increases in muscle Ca²⁺ mediate changes in acetylcholinesterase and acetylcholine receptors caused by muscle contraction. Proc Natl Acad Sci USA 82:7121-7125[Abstract/Free Full Text].
Rubin LL, Chalfin NA, Adamo A, Klymbowsky MW (1985) Cellular and secreted forms of acetylcholinesterase in mouse muscle cultures. J Neurochem 45:1932-1940[ISI][Medline].
Sambrook J, Fritsh EF, Maniatis T (1989) In: Molecular cloning: a laboratory manual. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.
Termin A, Pette D (1992) Changes in myosin heavy-chain isoform synthesis of chronically stimulated rat fast-twitch muscle. Eur J Biochem 204:569-573[ISI][Medline].
Tsim KWK, Greenberg I, Rimer M, Randall WR, Salpeter MM (1992) Transcripts for acetylcholine esterase show distribution differences in cultured chick muscle cells. J Cell Biol 118:1201-1212[Abstract/Free Full Text].

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