1 School of Biological Sciences, Queen Mary, University of London, London, E1 4NS, UK
2 Department of Physiology, Gower Street, University College London, London, WC1E 6BT, UK
* Author for correspondence (e-mail: r.ashworth{at}ucl.ac.uk)
Accepted 8 August 2005
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Summary |
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Key words: Activity dependent, Muscle development, Acetylcholine, Calcium, Sarcomere, Zebrafish
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Introduction |
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In mature muscle, calcium acts as a messenger linking excitation events at the membrane with downstream effects, such as contraction, ATP production and transcription (Berchtold et al., 2000). Muscle cells are capable of generating calcium signals early in their development, even in the absence of innervation (Bakker et al., 1996
; Ferrari and Spitzer, 1999
; Flucher and Andrews, 1993
; Lorenzon, et al., 1997
). Indeed nerve-independent calcium signals have a role in somite maturation and myofibrillogenesis (De Deyne, 2000
; Li et al., 2004
). While myocytes and nerve-muscle cocultures remain an excellent model for examining signalling at a cellular level, only analysis in vivo permits the examination of nerve generated calcium signals in muscle cells subjected to the full range of developmental cues. The contribution of nerve activated calcium signals to muscle fibre development in intact embryos remains undefined. Here we use the zebrafish embryo as an in vivo model to address the role of activity dependent signals, acetylcholine and calcium, in later stages of muscle development.
The zebrafish embryo is an important organism for the study of vertebrate muscle development (Brennan et al., 2002; Stickney et al., 2000
). The anatomical development of the early neuromuscular system in the zebrafish embryo has been well described (Fig. 1). The earliest movements of the zebrafish embryo (side to side coiling of the tail) at 17 hours post-fertilisation (hpf) are an external indication that nerve-muscle contact has occurred (Kimmel et al., 1995
; Saint-Amant and Drapeau 1998
). Activity-dependent muscle contractions are generated from the outset via cholinergic activation (Melancon et al., 1997
). Analysis of zebrafish mutants (ache and twister) has also implicated cholinergic neurotransmission in slow muscle fibre formation and degeneration (Behra et al., 2002
; Lefebvre et al., 2004
). The intracellular signalling mechanisms that are activated in neurotransmitter-regulated muscle development are unknown. We set out to address the activation of intracellular messengers downstream of acetylcholine and their potential role in regulating muscle development. In mature muscle, acetylcholine mediates its effects via acetylcholine receptor (AChR) induced increase in intracellular calcium. The zebrafish embryo has proved extremely useful for imaging intracellular calcium signals in situ (Ashworth, 2004
). In the present study we characterize the generation of the earliest endogenous activity-dependent calcium signals in the muscle fibres of intact zebrafish embryos and investigate their role in muscle development. Inhibition of acetylcholine and ryanodine receptors revealed a role for activity-dependent signalling pathways in the regulation of myofibril bundling, sarcomere length and fibre length in slow muscle fibres. Taken together these results reveal that nerve activity plays a vital role in muscle fibre formation and function within the embryo.
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Materials and Methods |
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Intracellular calcium measurements during muscle fibre contraction
Eggs were injected as described previously (Ashworth, 2004). The high affinity calcium indicator Oregon Green 488 BAPTA-1 dextran (10 kDa), with a Kd=265 nM and the low affinity calcium indicator Fluo-4 dextran (10 kDa), with a Kd of 3 µM were used to detect changes in cytosolic calcium in the nM and µM range, respectively (Molecular Probes) (Haugland, 2002
). The use of single wavelength calcium indicators to measure calcium fluxes presents the possibility of artefacts in fluorescence intensity changes, the most obvious in the present study being significant cell movement during muscle contraction (Fetcho et al., 1998
; Lipp and Niggli, 1993
). In the present study we have loaded cells with the calcium indicator (either Oregon Green BAPTA dextran or Fluo-4 dextran) in combination with the calcium insensitive fluorescent dye tetramethylrhodamine dextran (10 kDa; Molecular Probes). The assumptions are that: (1) the dyes have a good spectral separation (note that sequential imaging was performed to reduce signal overlap); (2) no significant bleaching was occurring; (3) that the dyes display a homogeneous distribution; and (4) that there is no compartmentalization (the use of dextran conjugate ensures the indicator is retained within the cytosol thus avoiding the problems of compartmentalisation associated with calcium indicators). During the recording the cells of interest were focused in the brightest plane, resulting in a decrease in fluorescence during movement but an increase in intensity due to changes in the calcium signal (Ashworth et al., 2001
; Fetcho et al., 1998
). Thus signal from the rhodamine will reflect changes in fluorescence due to movement and not changes in calcium, and provides a method of obtaining ratiometric measurements (supplementary material Fig. 1B,C). The Kd of Fluo-4 dextran means that the indicator does not emit a fluorescent signal in resting cells where the cytosolic calcium ion concentration will be in the nM range. Therefore, in the experiments using Fluo-4 dextran, fibres were identified from the signal emitted by excitation of rhodamine dextran. The dyes were loaded into cells to give an estimated intracellular concentration of 40-80 µM previously shown not to disrupt cellular development in neurons (Ashworth et al., 2001
). The use of the higher affinity indicator Fluo-4 at the same concentration is unlikely to buffer calcium signals.
Fluorescence imaging was performed on a confocal laser-scanning microscope (Zeiss LSM 510). All recordings were performed at room temperature (22°C). Embryos were mounted in 1% agar solution and orientated horizontally to obtain a side view. Specimens were viewed through a Zeiss Fluar x20 objective (N.A. 0.75). To capture the cytosolic calcium signals as the first neuromuscular contacts form, dye-labelled muscle fibres located at the nascent horizontal myoseptum (in a position consistent with their identity as a subset of slow muscle fibres, muscle pioneers) were selected (supplementary material Fig. 1A). Fibres were chosen on the basis that they could be identified as a single fibre that appeared to span the entire somite, and the four most caudal somites were never imaged. Oregon Green 488 BAPTA-1 dextran and Fluo-4 dextran were excited using a 488 nm laser line and collected through a 530-550 nm band pass filter. The rhodamine was excited using a 543 nm laser line and emission collected through a 570 nm long pass filter. To minimize cross talk between the two dyes the signals were collected sequentially. All images were processed and analyzed using Zeiss software. Changes in fluorescence were calculated as the average pixel intensity within user-defined regions drawn around the muscle fibres. Further analysis was performed using Microsoft Excel spreadsheets, and statistical analysis was performed using Graphpad InStat v3.05.
Administration of drugs to embryos
To gain access to internal tissues it was necessary to perform tail cuts on embryos, a procedure that has been described previously (Liu and Westerfield, 1990). For the experiments described in this study a cut was made at the caudal end using a sharp needle, and then embryos transferred to experimental solutions. The drugs used were Rhodamine
-bungarotoxin (Molecular Probes), Dantrolene (Calbiochem), nifedipine and ryanodine (Calbiochem). To determine whether drugs inhibit spontaneous contractions, tail cut embryos (20-20.5 hpf) was incubated in experimental treatments for 30 minutes at room temperature. Each embryo was then assessed over a 5 minute observational period and blockade of contractions was determined by lack of spontaneous movement and failure to respond to touch.
Immunocytochemistry
For immunocytochemistry embryos were fixed and stained as described previously (Ashworth et al., 2001). Primary antibodies were mouse anti-myosin (F59, originally kind gift from F. Stockdale) used at a 1:10 dilution, mouse anti-ryanodine receptors (34C, from DSHB) used at a 1:250, rabbit anti-human prox-1 (from RELIATech GnbH, Germany) used at a 1:500 dilution. The secondary antibodies were Goat anti mouse IgG, Cy-5 linked (Amersham) used at a dilution of 1:1000 and Goat anti rabbit IgG Cy-3 linked (Jackson ImmunoResearch) used at a dilution of 1:500. After incubation with secondary antibodies actin was stained in wholemount embryos using Alexa Fluor 488 phalloidin (Molecular Probes) diluted 1:20 in phosphate buffer for 2.5 hours. Images from whole mount stained embryos were collected using laser scanning confocal microscope (Zeiss LSM 510), using Fluar 20x/0.7 UV and C-Apochromat 63x/1.2 W. Stacks of images were reconstructed in three dimensions to generate lateral and transverse projections.
In situ hybridization and immunohistochemistry
Zebrafish ryanodine receptor fragment clones from the EST database were used to synthesise digoxigenin (DIG)-labelled antisense riboprobeS for in-situ hybridization as described (Thisse et al., 1993). A 1:250-400 dilution of the riboprobe was used to establish embryonic expression. Primary antibody was used at a 1:10 dilution (pan muscle myosin A41025; gift from Simon Hughes) and secondary antibodies at a 1:600 dilution (monoclonal anti mouse IgG; Calbiochem). For cryostat sectioning wholemount stained embyos were embedded in low-melting-point agarose, equilibrated in 30% sucrose/PBS solution and sectioned at 15 microns (Leica cryostat).
Sequence alignment
Plasmid clone (019-D04-2, Acc No AL916615) obtained from Peng Jinrong, Functional Genomics Laboratory, Institute of Molecular and Cell Biology, National University of Singapore, 30 Medical Drive, Singapore 117609. The nucleotide sequence for clone 019-D04-2 was used to search the zebrafish genomic database and produced a 100% match with the coding sequence from genomic clone BX682544.5 from base 14023 to base 14595. Translation of the full-length coding sequence from BX682544.5 produced a protein sequence that was used to generate a multiple alignment using ClustalW (http://www2.ebi.ac.uk/clustalw/). Multiple alignment protein parameters used default parameter settings: gap opening 75.00, extension 0.30. A phylogenetic tree (dendogram) was created based on this ClustalW generated alignment (http://taxonomy.zoology.gla.ac.uk/rod/treeview.html).
TEM
Embryos for TEM were dechorionated, wild type anaesthetized in Tricaine (MS-222) and fixed in 0.1 M sodium cacodylate, 0.5% calcium chloride, 2% paraformaldehyde and 2.5% glutaraldehyde. After fixation, embryos were rinsed in 0.1 M sodium cacodylate, post-fixed in 1% osmium tetroxide in 0.1 M sodium cacodylate, rinsed in H2O and then incubated in 2% uranyl acetate in H2O for 15 minutes. Specimens were further washed in H2O before being dehydrated through a graded ethanol series. Embryos were embedded in Agar Resin mix and ultrathin sections were cut. Sections were examined using a Jeol 1010 transmission electron microscope.
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Results |
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Activity-generated calcium signals in embryonic muscle are generated via L-type calcium channels and ryanodine receptors
Postsynaptic calcium signals in vertebrate skeletal muscles are generated via mechanical coupling of specialized calcium channels, namely dihydropyridine (DHPR) in the sarcolemma and ryanodine receptors (RyR) in the sarcoplasmic reticulum. To establish the involvement of these proteins in early nerve-mediated calcium signals in zebrafish slow muscle, initially we characterised the developmental expression of zebrafish RyR using in situ hybridisation and immunohistochemistry. We used pharmacological blockade with nifedipine and dantrolene to demonstrate a functional role of DHPR and RyR respectively.
The ryanodine receptor in particular has been implicated in myotome development (Ferrari and Spitzer, 1999). We examined the expression patterns of available zebrafish RyR EST clones showing a high homology with other vertebrate RyR by mRNA in situ hybridisation (Fig. 3 and data not shown). The RyR3 clone (019-D04-2) was expressed in the developing somites, specifically in the adaxial slow muscle precursor cells from the four somite stage (data not shown). At the 10 somite stage RyR3 expression was detected in the muscle pioneer and adaxial cells of all formed somites and within the lateral somitic mesoderm of the more mature somites (Fig. 3C). At 24 hpf, expression was detected throughout the somitic mesoderm in both fast and slow muscle populations (Fig. 3D,E). Elevated levels of expression in the most dorsal domain of the somite corresponded to the dorsal growth zone of the somite (Barresi et al., 2001
). Somite specific expression of RyR3 got stronger as the embryo matured from 16-24 hpf up to 48 hpf. In mammals three isoforms of the ryanodine receptor (1, 2 and 3) have been cloned and sequenced. RyR3 is expressed in mouse foetal and neonatal tissues and has a role in amplification of the calcium signal during the perinatal period (Bertocchini et al., 1997
). We show that ryanodine receptor mRNA, analgous to vertebrate RyR3, is expressed exclusively in skeletal muscle of the zebrafish embryo from early somite formation onwards.
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Having established that RyR receptors are expressed within the zebrafish slow muscle precursors from the earliest stages of differentiation we adopted a pharmacological approach to demonstrate their functional role. Drugs do not readily diffuse across the skin of later stage embryos but can be introduced via tail cuts (Liu and Westerfield, 1992). The frequency of intracellular calcium signals in muscle fibres of tail cut embryos (0.088±0.004 Hz, n=2) was not significantly different from intact embryos (0.082±0.023 Hz, n=12, unpaired t-test) at 19 hpf. Therefore tail cuts alone do not disrupt the generation of cytosolic calcium transients in the muscle. Tailcut embryos were bathed in relatively high concentrations of drugs to encourage penetration into internal tissues; however the uptake and concentration at the target site could not be measured. Between 20 and 21 hpf the majority (94±3.4%) of embryos display activity dependent spontaneous contractions (n=50 embryos). We tested the effect of calcium channel blockers on the generation of activity dependent muscle contraction in embryos. The organic blocker nifedipine targets the dihydropyridine binding site on the
1 subunit of the skeletal muscle L-type calcium channel (Zamponi, 1997
). Nifedipine treatment, at a concentration of 10 µM and 100 µM, produced a significant dose dependent decrease in the number of contracting embryos (54.54±7.5% n=56 and 58.92±6.57% n=44, respectively, ANOVA P<0.001 compared with controls). Dantrolene and ryanodine can suppress intracellular calcium release from the sarcoplasmic reticulum (SR) by inactivating the ryanodine receptor (Meissner, 1986
; Paul-Pletzer et al., 2002
). A significant dose dependent decrease in the number of contracting embryos were observed in the presence of 10 µM, 100 µM and 1000 µM Dantrolene (51.85±9.62% n=18, 41.66±10.06% n=24, 38.89±11.49% n=27 respectively, ANOVA, P<0.001 compared with controls). Ryanodine treatment also produced a dose dependent decrease in the number of contracting embryos, at a 10 µM and 50 µM (25±15.3% n=37 and 0% n=25, respectively, ANOVA P<0.001 compared with controls). With the exception of 50 µM ryanodine, muscle contraction was not completely inhibited in treated embryos even at higher drug concentrations. These observations suggest that the calcium signalling pathways that mediate contraction are more complex than originally supposed, consisting of several components perhaps nerve dependent and independent. Our observations in the zebrafish embryo, that application of ryanodine completely abolishes movement, is in contrast to C. elegans where intracellular calcium release from ryanodine receptors is not essential for excitation-contraction coupling (Maryon et al., 1996
). The pharmacological data we present here suggests that L-type calcium channels and ryanodine receptors contribute to the earliest activity-dependent contractions in zebrafish embryos. Application of drugs to the whole embryo has not allowed us to determine whether the effects are specific to sites at the neuromuscular junction or elsewhere. The expression analysis suggests the involvement of a zebrafish RyR3 homologue in the developing muscle fibres. Immunocytochemistry has revealed that ryanodine receptor protein is expressed and forms clusters in developing muscle fibres. Further identification of the signalling proteins that contribute to the muscle contraction will help in the design of experiments to target the pathway more directly.
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Nerve activity and downstream signals can influence the proportion of fibre types in mammalian skeletal muscle (Spangenburg and Booth, 2003). We used expression of prox-1 to follow the effect of nerve activity on slow muscle fibre number in embryonic zebrafish. Slow muscle fibres in the zebrafish myotome are mononucleate and express the regulatory protein prox-1 within the nucleus at 24 hpf (Roy et al., 2001
). The expression of prox-1 was not disrupted in the presence of ryanodine (data not shown). The number of prox-1 expressing nuclei in dorsal half of the somite was not significantly different in ryanodine treated embryos (50 µM ryanodine, 8±0.2, n=4) compared with controls (9±0.25, n=5). We show that ryanodine receptor activation does not appear to regulate the number of nuclei, gross morphological movements or striation (sarcomere) formation in slow muscle fibres. However, ryanodine receptor activation, and resulting intracellular calcium release, is required, for myofibril bundling in slow muscle.
Activity-generated signals are required for the organisation of slow muscle myofibrils
Application of ryanodine to the embryo does not allow us to resolve whether our observations on muscle development are a result of direct inhibition within the muscle fibre or secondary inhibition of nervous activity. To determine if activity evoked signals within the muscle fibre regulate development we targeted the acetylcholine receptor. In the zebrafish embryo the first muscle movements occur at 17 hpf and are generated via acetylcholine (ACh) release from motor nerve terminals (Grunwald, et al., 1988; Melancon, et al., 1997
). In zebrafish, nicotinic AChR expression and clustering is observed exclusively in somites, beginning around the time of innervation (Liu and Westerfield, 1992
). To investigate the role of acetylcholine driven pathways in slow muscle development we have used both pharmacological and genetic approaches. Administration of
-bungarotoxin at the onset of movement (16-17 hpf) inhibited spontaneous contractions in embryos at 24 hpf (n=55 embryos). Cytosolic calcium transients in the muscle fibres of embryos aged between 18 hpf and 20 hpf were completely abolished in the presence of 0.5 µM
-bungarotoxin (n=18) (Fig. 5A,B). Embryos were fixed at 24 hpf and slow muscle development examined using immunocytochemistry. In
-bungarotoxin treated embryos adaxial cells were observed to have elongated and migrated to form a layer of superficial muscle cells; however, in treated embryos the fibres appear more disorganised (Fig. 5C,D). Thus inhibition of the acetylcholine receptor during neuromuscular development does not affect slow muscle cell migration but disrupts myofibril organisation. To address the role of acetylcholine receptors in more detail we followed up our observations from the pharmacological approach in an established mutant line.
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Previously, the role of acetylcholine receptors in development has been studied using the nic1 zebrafish line that carries a mutation in the -subunit of the receptor (Sepich et al., 1998
; Westerfield et al., 1990
). Embryos carrying the nic1 mutation do not express AChRs and are immotile; however, observations that somite and skeletal muscle fibre formation appears grossly normal suggests that functional acetylcholine receptors are not required for their development. In the present study, we performed a detailed analysis of slow muscle fibre development in nic1 mutants. By 24 hpf adaxial cells had elongated and migrated to the lateral surface of the somite in both mutant (Fig. 6D-F, n=8) and wild-type embryos (Fig, 6A-C, n=12); a result indicative that the cholinergic system is not involved in these processes. In the wild-type embryos the myofibrils are packed together into longitudinal bundles to form fibres, while in the mutant embryos myofibrils are not aligned laterally but appear disorganised. Average somite width, taken from measurements in the dorsal half of trunk, was not significantly different in wild type (49.42±1.51, n=24) compared with mutants (52.75±1.91, n=22, unpaired t-test). However, myofibril length relative to somite width was shown to be significantly larger in nic1 mutant compared with wild-type embryos at 24 and 48 hpf (Fig. 6G). Expression of the homeobox gene prox-1 required for terminal differentiation of slow muscle fibres was not disrupted in the mutant or in BTX treated embryos (data not shown). There was no significant difference between the number of prox-1 expressing nuclei in the anterior somites of wild type (8±2 nuclei in the dorsal somite, n=8 somites from three embryos) compared with homozygote embryos (9±1 nuclei in the dorsal somite, n=9 somites from three embryos). Dystroglycan, a key component linking the sarcolemma and the extracellular matrix (Chambers et al., 2003
), was strongly expressed at the myosepta in homozygous mutants (data not shown) suggesting the muscle attachments are intact. The myosin and actin bands were visible in the myofibrils of wild type and homozygotes (Fig. 3H,I). Furthermore, using electron microscopy, we have confirmed that sarcomere formation was not disrupted in the mutant (Fig. 3J,K); however, the sarcomere length (distance between Z-bands) was significantly smaller in mutants (1.65±0.02 µm, n=2 embryos) compared with wild types (1.83±0.06 µm, n=3 embryos, P<0.0001 unpaired t-test). In summary, these results reveal that fibre length, lateral alignment of the myofibrils and sarcomere length are disrupted in the nic1 mutant embryos. This phenotype shows similarity to that observed on inhibition of ryanodine receptors suggesting that during development AChR induced calcium signaling is a key regulator of slow muscle myofibril organisation.
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Discussion |
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Muscle fibres are composed of bundles of myofibrils that run from one end of the cell to the other. In longitudinal section myofibrils align laterally resulting in longitudinal arrangement of sarcomeres. Our observations from the nic1 mutant reveals that the early steps of myofibrillogenesis (Sanger et al., 2002), resulting in sarcomere formation do not appear to be controlled via nerve input. Our findings reveal that it is the organisation, most notably the shortening of the sarcomeres and the lengthening of the myofibrils, which is disrupted in the absence of nerve generated activity. Sarcomere length is one of the main factors contributing to force generation in skeletal muscle (Burkholder and Lieber, 2001
). In myofibrils serial sarcomere number is adjusted to achieve the optimum sarcomere length and hence force generation (Burkholder and Lieber, 2001
). Our observations that blockade of the acetylcholine receptor generated shorter sarcomeres and increased myofibril length suggest an increase in sarcomere number. Our hypothesis is that nerve activity and calcium signalling act to limit sarcomere number and therefore produce the optimal sarcomere length required for force generation during embryogenesis.
Serial sarcomere number and consequently sarcomere length are important physiological parameters incorporated into the design of different muscle types. For example, in fish there is a functional specialisation of the muscle: red fibres that are slow contracting for steady swimming and white fibres for bursts of activity (Raamsdonk et al., 1982). Sarcomere length and contraction velocities in various muscle types operate at different optimal ranges in order to perform specific functions (steady swimming versus startle response) (Rome, 2002
). The results presented here suggest that in the later stages of development nerve input works to refine the parameters that determine functional specialisation of the muscle. Indeed in other systems electrical activity has been implicated as the main contributing factor determining sarcomere number and optimal sarcomere lengthening (Herring et al., 1984
). Our zebrafish study suggests that electrical activity regulates the sarcomere arrangement in myofibrils within embryos. The purpose of early embryonic movements in zebrafish, although proposed to be involved in hatching (Kimmel et al., 1974
; Saint-Amant and Drapeau, 1998
), has never been established. We propose that coordinated movements could be important for refining the properties (myofibril organisation) of the different embryonic muscle types. The zebrafish nic1 mutant represents a unique vertebrate model in which to study the later steps of activity-dependent myofibrillogenesis during development in vivo.
Our study has revealed that acetylcholine and calcium signalling can control myofibril organisation; however, downstream steps of the pathway remain to be determined. Intermediate filaments, such as desmin (Li et al., 1997), making up the exosarcomeric cytoskeleton are responsible for the alignment of myofibrils. Evidence, from studies in desmin knockout mice after hindlimb immobilisation, has revealed a role for desmin in the regulation of sarcomere number in different skeletal muscle types (Shah et al., 2001
). Interestingly binding of the calcium-modulated proteins, S100A1 and S100B, results in the inhibition of desmin assemblies and disassembly of preformed desmin (Garbuglia et al., 1999
). Garbuglia and colleagues (Garbuglia et al., 1999
) suggest that an elevated intracellular calcium concentration promotes interaction of S100B with desmin causing intermediate filament disassembly in vivo. Our observations using the nic1 mutant reveal that the lack of activity dependent calcium signalling resulted in increased myofibril and decreased sarcomere length. This is consistent with a model whereby acetylcholine generated calcium signals promote S100A1 and S100B and desmin interaction thereby causing intermediate filament disassembly and regulation of sarcomere number and myofibril organisation.
In summary, our study demonstrates a role for nerve activity and downstream intracellular calcium signals in the regulation of myofibril organisation during embryogenesis. Myofibrillogenesis and the organisation of the contractile units (sarcomeres) are critical for proper muscle function in both the embryo and adult. An important future step will be the identification of other signalling proteins involved in activity regulated fibre formation in the embryo.
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Acknowledgments |
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Footnotes |
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References |
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