Abstract
Background
The formation of contractile myofibrils requires the stepwise onset of expression of muscle specific proteins. It is likely that elucidation of the expression patterns of muscle-specific sarcomeric proteins is important to understand muscle disorders originating from defects in contractile sarcomeric proteins.
Methods
We investigated the expression profile of a panel of sarcomeric components with a focus on proteins associated with a group of congenital disorders. The analyses were performed in cultured human skeletal muscle cells during myoblast proliferation and myotube development.
Results
Our culture technique resulted in the development of striated myotubes and the expression of adult isoforms of the sarcomeric proteins, such as fast TnI, fast TnT, adult fast and slow MyHC isoforms and predominantly skeletal muscle rather than cardiac actin. Many proteins involved in muscle diseases, such as beta tropomyosin, slow TnI, slow MyBPC and cardiac TnI were readily detected in the initial stages of muscle cell differentiation, suggesting the possibility of an early role for these proteins as constituent of the developing contractile apparatus during myofibrillogenesis. This suggests that in disease conditions the mechanisms of pathogenesis for each of the mutated sarcomeric proteins might be reflected by altered expression patterns, and disturbed assembly of cytoskeletal, myofibrillar structures and muscle development.
Conclusions
In conclusion, we here confirm that cell cultures of human skeletal muscle are an appropriate tool to study developmental stages of myofibrillogenesis. The expression of several disease-associated proteins indicates that they might be a useful model system for studying the pathogenesis of muscle diseases caused by defects in specific sarcomeric constituents.
Similar content being viewed by others
Background
The formation of skeletal muscle cells takes place during embryogenesis, postnatal growth and repair of postnatal skeletal muscle. Postnatal growth of muscle and regeneration of adult skeletal muscle tissue following injury is accomplished by activation of quiescent satellite cells that subsequently proliferate, differentiate and fuse with each other or pre-existing myofibers to regenerate myofibers thereby regenerating the muscle tissue [1]. For these characteristics of self-renewal, cultured satellite cells can provide an invaluable insight into the basic mechanisms of sarcomere expression profile, assembly and myofibrillogenesis. Although previous studies have revealed some distinct genetic requirements for embryonic, fetal, postnatal and adult regenerative myogenesis, the basic mechanisms are likely to be similar [2, 3].
Striated muscle formation is a fundamentally conserved process and requires the highly regulated and ordered expression of sarcomeric proteins and their assembly into the sarcomeric contractile unit [4]. The principle components of striated muscle sarcomeres include parallel arrays of actin-containing thin filaments, which overlap with myosin-containing thick filaments. Striated muscle function depends on the precise alignment of actin and myosin filaments, which is achieved by accessory proteins that link the different components and hold them in register with each other [5]. In the sarcomere many proteins cooperate to convert the molecular interactions of actin and myosin efficiently into mechanical force and movement [4].
A common property of many of the sarcomeric components of striated muscle is that they often exist as families of similar isoforms. These isoforms are developmentally regulated and differentially expressed in a tissue-specific manner in cardiac, slow and fast muscle [6, 7]. The generation of distinct protein isoforms within a family can result predominantly by two mechanisms: the differential expression of multigene families or the production of multiple protein variants from a single gene via alternative splicing. Muscle proteins, which exist as various isoforms in developing and mature skeletal and cardiac muscles are functionally unique and exhibit distinct contractile and physiological properties [8–10].
Although several studies have described that during myofibrillogenesis, the expression of proteins occurs in an ordered sequence [4], the sequential onset of the individual isoforms within a family of sarcomeric proteins is poorly characterized. Elucidation of the expression patterns of sarcomeric proteins and their distinct isoforms during myogenesis, is important to better understand their function, formation and assembly into sarcomeric structure in normal muscle cells. These data will allow a comparison with muscle cells obtained from patients suffering from one of the increasing number of diseases originating from genetic defects in these proteins. Congenital myopathies, a heterogeneous group of muscle disorders defined by distinctive morphologic abnormalities in skeletal muscle fibers, are often caused by structural defects in sarcomeric or cytoskeletal proteins [11]. In addition, distal arthrogryposis (DA) syndromes, a heterogeneous group of disorders with congenital contractures mainly of hands and feet, have recently been associated with mutations in sarcomeric components including ß-tropomyosin (TPM2) [12, 13], fast troponin T (TNNT3) [14], fast troponin I (TNNI2) [12, 15], embryonic myosin heavy chain (MYH3) [16, 17], prenatal myosin heavy chain (MYH8) [18] and slow myosin binding protein C (MYBPC1) [19].
In the present study, we characterize the expression profile of a panel of muscle-specific sarcomeric components that are associated with congenital diseases by combining molecular and morphological techniques on cultured human adult regenerative myoblasts and differentiated myotubes.
Methods
Muscle cell Cultures
Five standardized batches of human myoblasts were provided by MYOSIX through a collaborative program with Association Francaise contre les Myopathies (AFM). Skeletal muscle cells from donors with no clinical signs of muscle disease were enzymatically isolated and cultured as previously described [20, 21]. Isolated satellite cells, frozen in liquid nitrogen in their second passage, were quickly thawed and plated on chamber slides (Lab-Tek™ II - CC2™, Nalge Nunc International, Naperville, USA) using Dulbecco’s modified Eagle’s medium (DMEM) (Biochrom AG, Berlin, Germany), supplemented with 20% fetal bovine serum (Invitrogen, GIBCO, Auckland, New Zealand), 100x GlutaMAX (Invitrogen, GIBCO, Paisley, UK), 10 mg/ml penicillin/streptomycin (Biochrom AG, Berlin, Germany), 10 μm./ml insulin (Biochrom AG, Berlin, Germany) and 10 ng/ml fibroblast growth factor (BD Biosciences, Bedford, MA, USA). The cells were incubated at 37°C in a humidified 5% CO2 atmosphere.
To induce differentiation, cells were replenished at 85%-90% confluence with DMEM medium, supplemented with 5% horse serum (Invitrogen, GIBCO, Auckland, New Zealand) and further incubated in this medium for 6 days. The medium was changed three times a week.
RNA isolation, cDNA synthesis, polymerase chain reaction (PCR) and sequence analysis
Total RNA was isolated from proliferating myoblasts and differentiated cell cultures and treated with DNase I using the RNeasy Plus Mini Kit (Qiagen, Hilden, Germany) according to the manufacturer’s instructions. The total RNA concentration was determined by A260 and A280 (A260/A280=1.7-2.0) measurements using a NanoDrop ND 1000 Spectrophotometer (NanoDrop Technologies, Wilmington, USA). Synthesis of first-strand complementary DNA (cDNA) was performed from 400 ng total RNA using the iScript cDNA Synthesis kit (BioRad Laboratories, 2000 Alfred Nobel Drive Hercules, CA), according to the manufacturer’s instructions.
The expression of transcripts of a panel of genes encoding skeletal muscle sarcomeric components desmin (DES), titin (TTN), MyHC isoforms (MYH1, MYH2, MYH3, MYH4, MYH7 and MYH8), α-skeletal actin (ACTA1) and α-cardiac actin (ACTC1), tropomyosin isoforms (TPM1, TPM2 and TPM3), troponin T isoforms (TNNT1, TNNT2 and TNNT3), troponin I isoforms (TNNI1, TNNI2 and TNNI3), skeletal muscle myosin-binding protein C isoforms (MYBPC1, MYBPC2) and cardiac myosin-binding protein C (MYBPC3) was analyzed by reverse transcriptase polymerase chain reaction (PCR). In addition, the expression of transcripts of myogenic regulatory factors (MRFs) myogenic factor 5 (MYF5), myogenic differentiation 1 (MYOD1) and myogenin (MYOG) was analyzed.
The PCR analysis was performed on cDNA in a master mixture (ReddyMix PCR Master Mix, ABgene House, Blenheim Road, UK) containing 20 pmol of each primer. The PCR primers were directed to cDNA sequence flanking exons in order to exclude genomic DNA amplification, although the RNA samples were treated with DNase I. Primer sequences are available on request. PCR amplifications consisted of an initial preheating step for 5 min at 94°C, followed by a touchdown (TD)-PCR. TD-PCR analysis was performed by denaturation at 94°C for 30 sec, annealing at 65°C for 30 sec, extension at 72°C for 1 min with a 1°C temperature decrement per cycle during the first 10 cycles. The subsequent cycles (40 cycles) each consisted of 94°C for 30 sec, 55°C for 30 sec and 72°C for 1 min. The same PCR amplification reaction was performed for all genes, except for the amplification of myosin heavy chain isoforms that consisted of an initial preheating step for 3 min at 94°C, followed by denaturation at 94°C for 1 min, annealing at 57°C for 1 min and extension at 72°C for 1 min for 35 cycles. Samples were run in triplicate. The nucleotide sequence determination was carried out by cycle sequencing using an ABI 3730xl DNA sequencer (GATC Biotech AG, Konstanz, Germany).
Immunocytochemistry and immunofluorescence
Immunocytochemical analysis was performed on proliferating myoblasts and myotubes after 6 days of differentiation, grown on chamber slides using LSAB kit (DAKO, Glostrup, Denmark) according to manufacturer’s instructions. The cells were incubated with primary antibodies (Table 1) followed by incubation with EnVision™Flex/HRP. The immunoreactivity was visualized by the indirect peroxidase-antiperoxidase complex method (DAKO, Glostrup, Denmark) using diaminobenzidine as a chromogen. Nuclei were counterstained with hematoxylin (Novocastra, Leica Microsystems Newcastle Ltd). Immunoreactivity was analyzed by light microscopy using the Zeiss Axio Observer microscope (Carl Zeiss AG, Germany) equipped with 10×, 20× and 40× objectives.
For immunofluorescence assays, slides were washed three times in 0.01 M phosphate-buffered saline (PBS) and fixed in 4% formaldehyde (methanol-free 16% formaldehyde solution, Thermo scientific) for 10 min. Free aldehyde groups were blocked with 50 mM NH4Cl for 10 min and cells were permeabilized in 0,01 M PBS containing 0,1% Triton X-100 for 4 min. Cells were incubated with primary antibodies for 1 h in a humidified chamber at 37°C, followed by incubation with secondary antibodies for 1 h in the dark and three washes with 0.01 M PBS. Finally, the slides were mounted with a coverslip using Prolong® Gold antifade reagent with DAPI (Invitrogen, GIBCO, Auckland, New Zealand) to highlight cell nuclei. The slides were left overnight in the dark at room temperature before examinations.
Results
The experiments were conducted in triplicate with similar results.
RNA expression and sequence analysis
The appearance of the myogenic phenotype in the investigated cell cultures was verified by analyzing the expression of the genes encoding a family of transcription factors known as MRFs including MYOD1, MYF5 and MYOG that are responsible for controlling muscle-specific gene expression. Expression of all MRFs was readily detectable in both proliferating mononucleated myoblasts and cells after 6 days of differentiation (D6) (Figure 1A and B).
The expression of tropomyosin isoforms TPM1, TPM2, TPM3, α-skeletal and α-cardiac actin (ACTA1 and ACTC1), MyHC isoforms (MYH1, MYH2, MYH3, MYH4, MYH7, MYH8), DES, TTN, slow, fast and cardiac myosin-binding protein C isoforms (MYBPC1, MYBPC2, MYBPC3), troponin I isoforms (TNNI1, TNNI2, TNNI3), and troponin T isoforms (TNNT1, TNNT2, TNNT3) was detected in both myoblasts and D6 cells (Figure 1A-H).
In order to confirm and verify the expression of each specific transcript in both myoblasts and differentiated cells, a sequence analysis of the amplicons was performed. Using the NCBI BLAST website http://www.ncbi.nlm.nih.gov/BLAST/, the 100% identity to the reference sequences were confirmed for the MRF transcripts (MYOD1, MYF5 and MYOG), as well as the muscle specific alternative splicing variant of the investigated sarcomeric transcripts (Additional files 1, 2, 3, Figure S1–S3).
Immunocytochemistry and immunofluorescence
Mononucleated myoblasts were differentiated into multinucleated cells to induce the development of myotubes containing cross-striated myofibrils. The mature sarcomeric cross-striated pattern of the myofibrils within differentiated cells was confirmed by immunostaining with a panel of titin antibodies: all sarcomeric structures (Z-disk, A/I-junction, A-band and M-band) were clearly detected after only 5 days of differentiation (Figure 2).
To confirm the myogenic identity of the analyzed cells they were stained with an antibody against desmin. The expression of desmin was homogeneous and the antibody strongly stained virtually all cells of both proliferating myoblasts (Figure 3A) and differentiated (D6) cultures (Figure 4A). In order to determine the stage of differentiation of the mononucleated myoblasts and the differentiated cells, an antibody against myogenin was used. Only a small number of the myonuclei of proliferating mononucleated cells were found to express myogenin (Figure 3B), whereas the majority of the nuclei were myogenin positive in the multinucleated differentiated cells confirming their more advanced differentiation level (Figure 4B).
In order to examine the sequential onset of the expression of sarcomeric proteins and their isoforms, we performed immunocytochemical analyses on mononucleated myoblasts and differentiated cells using a large panel of antibodies (Table 1). While the expression of titin was observed in a subset of myoblasts (Figure 2A-D and 3C), this protein was expressed and organized into a cross-striated pattern in differentiated cells (Figure 2E-H and 4C). The expression analysis of various MyHC isoforms was performed using five different MyHC antibodies. Although MyHC isoforms were predominantly detected in differentiated cells, about 10% of mononucleated myoblasts also expressed embryonic, neonatal, slow and fast MyHC (Figure 3D-H, insets). The vast majority of multinucleated myotubes stained strongly with the antibody against embryonic MyHC (Figure 4D-H). The expression pattern of slow and fast MyBPC was studied using two specific antibodies. While virtually all proliferating mononucleated and differentiated cells appeared to be stained with the antibody against slow MyBPC, these cells were weakly stained with the antibody against fast MyBPC (Figure 3I-J and 4I-J). In addition, no specific staining of proliferating mononucleated myoblasts or multinucleated differentiated cells with cardiac-specific MyBPC antibody was detected (data not shown).
Immunohistochemical analysis with alpha-cardiac and alpha-skeletal actin antibodies revealed uniform staining of proliferating myoblasts (Figure 3K and L). While strong expression of alpha-cardiac actin was detected in the myoblasts (Figure 3K), these cells appeared weakly stained by the alpha-skeletal actin antibody (Figure 3L). In contrast, in multinucleated differentiated cells the intensity of staining for alpha-skeletal actin appeared to be much stronger than for alpha-cardiac actin (Figure 4K and L).
The expression of tropomyosin isoforms was studied in both myoblasts and differentiated cells using two different antibodies. The monoclonal anti-sarcomeric tropomyosin antibody detects all three TM isoforms (α-, β- and γ-TM isofoms), whereas the TPM2 antibody is specific for the β-TM isoform. Although both antibodies produced uniform staining of proliferating mononucleated cells (Figure 5A and B), the intensity of staining of multinucleated cells appeared to be much stronger (Figure 5C and D). While expression of the fast TnT isoform was undetectable in proliferating myoblasts, strong expression was detected in multinucleated cells (Figure 5E and F). To assess the expression of TnI isoforms, specific anti-slow and anti-fast troponin I antibodies were used. Expression of slow TnI isoforms was detected in both mononucleated and multinucleated differentiated cells (Figure 5G and H), whereas the fast TnI isoform was solely expressed in myotubes (Figure 5I and J). Notably, a subset of the multinucleated myotubes formed myofibre-like cells with peripheral nuclei (Figure 5H and J; arrows). Immunocytochemical analyses of cardiac TnI confirmed a uniform staining of proliferating mononucleated myoblasts (Figure 5K) and a vast majority of myotubes (Figure 5L). Immunofluorescence analysis confirmed these results (Additional file 4: Figure S4).
Supplemental information
Supplemental Appendix includes four figures.
Discussion
Skeletal muscle myoblasts are capable of proliferation and differentiation in vitro, which imitates early embryonic development and muscle regeneration. In several studies mammalian or avian cultured myocytes have been used as an experimental model to analyze the temporal and spatial expression of myofibrillar proteins during myogenesis in cardiac and skeletal muscles [1, 4, 22–25]. These studies have lead to the understanding that during myofibrillogenesis, the initiation of the expression of the many proteins involved occurs in an ordered sequence, suggesting a specific impact of the individual proteins in the complex mechanisms associated with sarcomere formation [4]. Due to their limited availability and reduced level of differentiation, human cells were only used in few studies. A better knowledge of their expression patterns and contribution to the assembly of cytoskeletal and myofibrillar structures in human cells might provide insights into the pathomechanisms of diseases associated with mutations in genes encoding sarcomeric proteins. In the current study we have used cultured primary human skeletal muscle cells to investigate the expression patterns of a panel of sarcomeric components and their isoforms with a focus on proteins associated with a group of muscle diseases. It is of interest to understand the onset of the expression of such proteins related to the congenital feature of the disease. Our differentiated cultures were predominantly occupied by myotubes, showing a mature sarcomeric cross-striated pattern. We observed a subsequent expression and development stages of myofibril components from an initial unorganized pattern in myoblasts, into a mature cross-striated pattern with clearly distinguishable Z-disks, A/I-junctions, A-bands and M-bands. The appearance of these four well-defined sarcomeric structures, and in particular, the integration of M-band titin, which is a late stage in myofibrillogenesis [26], indicated the formation of mature sarcomeric structures in vitro. This indicates the high quality of our human tissue culture and confirms its usability as a model system for studying the pathogenesis of muscle diseases caused by defects in sarcomeric or cytoskeletal constituents during skeletal muscle development.
Our results identify α-cardiac actin and α-skeletal actin as the predominant actin isoform in mononucleated myoblasts and in multinucleated differentiated cells, respectively demonstrating that the expression of actin isoforms is developmentally regulated in a temporal, tissue-specific manner. This is in accordance with previous results in chicken and mouse (27–29), that revealed that α-cardiac actin is the main isoform in early skeletal muscle development [27, 28]. Its expression is down-regulated in later development and α-skeletal actin becomes the predominant isoform in adult skeletal muscle fibres [29].
We also show the predominant expression of the β-TM isoform in proliferating human myoblasts and myotubes during myogenesis in vitro. This indicates an important role for β-TM in early stages of myofibrillogenesis. In addition, our data indicate that myoblasts and early-differentiated myotubes contain predominantly slow TnI, suggesting the importance of this isoform during development. This is further supported by the previous notion that the slow troponin I gene is the major isoform in early fetal heart in vertebrates and it is predominantly expressed during development in fast muscles with a subsequent switch to fast troponin I [30–32]. Similarly, we detected the expression of fast TnI and T solely in differentiated myotubes, indicating their impact in later stages of muscle development. Moreover, in accordance with previous results [33] the homogeneous expression of cardiac TnI in proliferating myoblasts and early myotubes suggest a role for this protein in the initial stages of myofibrillogenesis.
Association of mutations in slow skeletal muscle MyBPC isoform (MYBPC1) with autosomal dominant DA type 1 has recently been reported [19]. We identified this specific isoform as the major MyBPC variant at the initial phases of myofibrillogenesis in human skeletal muscle myoblasts and early myotubes, indicating that it is the main MyBPC isoform involved in early myofibril development. Accordingly, previous results indicate that slow MyBPC is first expressed in developing skeletal muscle both in mice and humans and fast MyBPC is detected at later developmental stages [3]. Also in accordance with a previous study, which indicated that cardiac MyBPC is not expressed in human skeletal muscles, not even during development [3], the expression of this isoform was not detected in our cultures. This indicates that the cardiac MyBPC appears not to be essential for human skeletal muscle development. However the cardiac MyBPC transcript was clearly detected in both, proliferating mononucleated myoblasts and myotubes, indicating the ectopic expression of this gene, as previously suggested [34]. In addition, we observed the expression of muscle-specific sarcomeric transcripts in proliferating mononucleated myoblasts, which either suggests the existence of myoblasts that had begun to express these components prior to fusion, or an expression of muscle-specific proteins in mononucleated myoblasts that differentiate prematurely. We found early expression of various MyHC protein isoforms, in a population of proliferating mononucleated myoblasts with an elongated spindle-shaped morphology without fusion. This may indicate the co-existence of early differentiated but non-fused myoblasts within the population of proliferating myoblasts in adult regenerative muscle. In addition, a small number of the proliferating mononucleated myoblasts expressed myogenin, confirming their differentiated state.
The essential roles of sarcomeric proteins have been highlighted by identification of mutations in their genes associated with various diseases. This includes mutations in genes encoding β-TM and γ-TM isoforms (TPM2 and TPM3) in association with congenital myopathies with a range of clinical and morphological phenotypes [12, 13, 35–42]. In addition, mutations in TPM2, TNNI2, MYH3, MYH8 and MYBPC1 have recently been identified to cause the DA syndromes, characterized by congenital contractures [12, 15]. The sequential onset of distinct sarcomeric protein isoforms within a family has not been well-characterized in human, except for the MYH3 and MYH8, which are known to be expressed during fetal development and also during muscle regeneration [43, 44]. The impact of embryonic and fetal MyHC isoforms for normal fetal development was supported by the identification of MYH3 and MYH8 mutations [16, 17, 45][18, 46]. It was suggested that they cause a developmental myopathy resulting in reduced fetal movement and joint contractures [16, 17]. Our results here demonstrated the predominant expression of β-TM, cardiac alpha actin, slow TnI and slow MyBPC isoforms in proliferating human mononucleated myoblasts and myotubes during myogenesis in vitro. This points to a possible role for these protein isoforms in the early stages of myofibrillogenesis. Mutations in such proteins may affect muscle function during early development either through haploinsufficiency with insufficient dosage of a functional protein or a dominant negative effect of the mutated allele by functional or structural alterations.
Conclusion
In conclusion, we here confirm that cell cultures of human skeletal muscle are an appropriate tool to study developmental stages of myofibrillogenesis. We show that many proteins involved in muscle diseases are readily detected in the stages of skeletal muscle cell differentiation that can be reached in vitro. The early and uniform expression of these proteins suggests their impact on the developmental mechanisms involved in the initial stages of myofibril assembly, differentiation and formation of muscle. This indicates that myoblasts isolated from patients with a mutation in one of the investigated genes may be an invaluable tool to analyze the effects of these mutations on sarcomere assembly and disassembly or myofibril turnover. It would provide us new insights into development of muscle to indicate whether these diseases are disorders of myofibrillogenesis and muscle development.
References
Sanger JW, Kang S, Siebrands CC: How to build a myofibril. J Muscle Res Cell Motil. 2005, 26: 343-354.
Fürst DO, Osborn M, Weber K: Myogenesis in the mouse embryo: differential onset of expression of myogenic proteins and the involvement of titin in myofibril assembly. J Cell Biol. 1989, 109: 517-527. 10.1083/jcb.109.2.517.
Gautel M, Fürst DO, Cocco A, Schiaffino S: Isoform transitions of the myosin binding protein C family in developing human and mouse muscles: lack of isoform transcomplementation in cardiac muscle. Circ Res. 1998, 82: 124-129. 10.1161/01.RES.82.1.124.
Ehler E, Gautel M: The sarcomere and sarcomerogenesis. Adv Exp Med Biol. 2008, 642: 1-14. 10.1007/978-0-387-84847-1_1.
Clark KA, McElhinny AS, Beckerle MC, Gregorio CC: Striated muscle cytoarchitecture: an intricate web of form and function. Annu Rev Cell Dev Biol. 2002, 18: 637-706. 10.1146/annurev.cellbio.18.012502.105840.
Perry SV: Properties of the muscle proteins–a comparative approach. J Exp Biol. 1985, 115: 31-42.
Bandman E: Contractile protein isoforms in muscle development. Dev Biol. 1992, 154: 273-283. 10.1016/0012-1606(92)90067-Q.
Lynch GS, Stephenson DG, Williams DA: Analysis of Ca2+ and Sr2+ activation characteristics in skinned muscle fibre preparations with different proportions of myofibrillar isoforms. J Muscle Res Cell Motil. 1995, 16: 65-78. 10.1007/BF00125311.
Bottinelli R, Reggiani C: Human skeletal muscle fibres: molecular and functional diversity. Prog Biophys Mol Biol. 2000, 73: 195-262. 10.1016/S0079-6107(00)00006-7.
Pette D, Staron RS: Myosin isoforms, muscle fiber types, and transitions. Microsc Res Tech. 2000, 50: 500-509. 10.1002/1097-0029(20000915)50:6<500::AID-JEMT7>3.0.CO;2-7.
Goebel HH: Congenital myopathies in the new millennium. J Child Neurol. 2005, 20: 94-101. 10.1177/08830738050200020201.
Sung SS, Brassington AM, Grannatt K: Mutations in genes encoding fast-twitch contractile proteins cause distal arthrogryposis syndromes. Am J Hum Genet. 2003, 72: 681-690. 10.1086/368294.
Tajsharghi H, Kimber E, Holmgren D, Tulinius M, Oldfors A: Distal arthrogryposis and muscle weakness associated with a beta-tropomyosin mutation. Neurology. 2007, 68: 772-775. 10.1212/01.wnl.0000256339.40667.fb.
Sung SS, Brassington AM, Krakowiak PA: Mutations in TNNT3 cause multiple congenital contractures: a second locus for distal arthrogryposis type 2B. Am J Hum Genet. 2003, 73: 212-214. 10.1086/376418.
Kimber E, Tajsharghi H, Kroksmark AK, Oldfors A, Tulinius M: A mutation in the fast skeletal muscle troponin I gene causes myopathy and distal arthrogryposis. Neurology. 2006, 67: 597-601. 10.1212/01.wnl.0000230168.05328.f4.
Toydemir RM, Rutherford A, Whitby FG: Mutations in embryonic myosin heavy chain (MYH3) cause Freeman-Sheldon syndrome and Sheldon-Hall syndrome. Nat Genet. 2006, 38: 561-565. 10.1038/ng1775.
Tajsharghi H, Kimber E, Kroksmark AK: Embryonic myosin heavy-chain mutations cause distal arthrogryposis and developmental myosin myopathy that persists postnatally. Arch Neurol. 2008, 65: 1083-1090. 10.1001/archneur.65.8.1083.
Toydemir RM, Chen H, Proud VK: Trismus-pseudocamptodactyly syndrome is caused by recurrent mutation of MYH8. Am J Med Genet A. 2006, 140: 2387-2393.
Gurnett CA, Desruisseau DM, McCall K: Myosin binding protein C1: a novel gene for autosomal dominant distal arthrogryposis type 1. Hum Mol Genet. 2010, 19: 1165-1173. 10.1093/hmg/ddp587.
Vilquin JT, Marolleau JP, Sacconi S: Normal growth and regenerating ability of myoblasts from unaffected muscles of facioscapulohumeral muscular dystrophy patients. Gene Ther. 2005, 12: 1651-1662. 10.1038/sj.gt.3302565.
Lecourt S, Marolleau JP, Fromigue O: Characterization of distinct mesenchymal-like cell populations from human skeletal muscle in situ and in vitro. Exp Cell Res. 2010, 316: 2513-2526. 10.1016/j.yexcr.2010.04.020.
van der Ven PF, Schaart G, Jap PH: Differentiation of human skeletal muscle cells in culture: maturation as indicated by titin and desmin striation. Cell Tissue Res. 1992, 270: 189-198. 10.1007/BF00381893.
van der Ven PF, Fürst DO: Assembly of titin, myomesin and M-protein into the sarcomeric M band in differentiating human skeletal muscle cells in vitro. Cell Struct Funct. 1997, 22: 163-171. 10.1247/csf.22.163.
Sanger JW, Wang J, Fan Y, White J, Sanger JM: Assembly and dynamics of myofibrils. J Biomed Biotechnol. 2010, 2010: 858606-
Sanger JW, Chowrashi P, Shaner NC: Myofibrillogenesis in skeletal muscle cells. Clin Orthop Relat Res. 2002, 403: 153-162.
van der Loop FT, van der Ven PF, Fürst DO: Integration of titin into the sarcomeres of cultured differentiating human skeletal muscle cells. Eur J Cell Biol. 1996, 69: 301-307.
Hayward LJ, Schwartz RJ: Sequential expression of chicken actin genes during myogenesis. J Cell Biol. 1986, 102: 1485-1493. 10.1083/jcb.102.4.1485.
Bains W, Ponte P, Blau H, Kedes L: Cardiac actin is the major actin gene product in skeletal muscle cell differentiation in vitro. Mol Cell Biol. 1984, 4: 1449-1453.
Vandekerckhove J, Bugaisky G, Buckingham M: Simultaneous expression of skeletal muscle and heart actin proteins in various striated muscle tissues and cells. A quantitative determination of the two actin isoforms. J Biol Chem. 1986, 261: 1838-1843.
Saggin L, Gorza L, Ausoni S, Schiaffino S: Troponin I switching in the developing heart. J Biol Chem. 1989, 264: 16299-16302.
Bhavsar PK, Dhoot GK, Cumming DV: Developmental expression of troponin I isoforms in fetal human heart. FEBS Lett. 1991, 292: 5-8. 10.1016/0014-5793(91)80820-S.
Sutherland CJ, Esser KA, Elsom VL, Gordon ML, Hardeman EC: Identification of a program of contractile protein gene expression initiated upon skeletal muscle differentiation. Dev Dyn. 1993, 196: 25-36. 10.1002/aja.1001960104.
Ferrer-Martinez A, Montell E, Montori-Grau M: Long-term cultured human myotubes decrease contractile gene expression and regulate apoptosis-related genes. Gene. 2006, 384: 145-153.
Miller TE, You L, Myerburg RJ, Benke PJ, Bishopric NH: Whole blood RNA offers a rapid, comprehensive approach to genetic diagnosis of cardiovascular diseases. Genet Med. 2007, 9: 23-33. 10.1097/GIM.0b013e31802d74de.
Laing NG, Wilton SD, Akkari PA: A mutation in the alpha tropomyosin gene TPM3 associated with autosomal dominant nemaline myopathy. Nat Genet. 1995, 9: 75-79. 10.1038/ng0195-75.
Penisson-Besnier I, Monnier N, Toutain A, Dubas F, Laing N: A second pedigree with autosomal dominant nemaline myopathy caused by TPM3 mutation: a clinical and pathological study. Neuromuscul Disord. 2007, 17: 330-337. 10.1016/j.nmd.2007.01.017.
Clarke NF, Kolski H, Dye DE: Mutations in TPM3 are a common cause of congenital fiber type disproportion. Ann Neurol. 2008, 63: 329-337. 10.1002/ana.21308.
Ohlsson M, Quijano-Roy S, Darin N: New morphologic and genetic findings in cap disease associated with beta-tropomyosin (TPM2) mutations. Neurology. 2008, 71: 1896-1901. 10.1212/01.wnl.0000336654.44814.b8.
Donner K, Ollikainen M, Ridanpaa M: Mutations in the beta-tropomyosin (TPM2) gene–a rare cause of nemaline myopathy. Neuromuscul Disord. 2002, 12: 151-158. 10.1016/S0960-8966(01)00252-8.
Lehtokari VL: Ceuterick-de Groote C, de Jonghe P, et al.: Cap disease caused by heterozygous deletion of the beta-tropomyosin gene TPM2. Neuromuscul Disord. 2007, 17: 433-442. 10.1016/j.nmd.2007.02.015.
Tajsharghi H, Ohlsson M, Lindberg C, Oldfors A: Congenital myopathy with nemaline rods and cap structures caused by a mutation in the beta-tropomyosin gene (TPM2). Arch Neurol. 2007, 64: 1334-1338. 10.1001/archneur.64.9.1334.
Monnier N, Lunardi J, Marty I: Absence of beta-tropomyosin is a new cause of Escobar syndrome associated with nemaline myopathy. Neuromuscul Disord. 2009, 19: 118-123. 10.1016/j.nmd.2008.11.009.
Feghali R, Leinwand LA: Molecular genetic characterization of a developmentally regulated human perinatal myosin heavy chain. J Cell Biol. 1989, 108: 1791-1797. 10.1083/jcb.108.5.1791.
Karsch-Mizrachi I, Travis M, Blau H, Leinwand LA: Expression and DNA sequence analysis of a human embryonic skeletal muscle myosin heavy chain gene. Nucleic Acids Res. 1989, 17: 6167-6179. 10.1093/nar/17.15.6167.
Alvarado DM, Buchan JG, Gurnett CA, Dobbs MB: Exome sequencing identifies an MYH3 mutation in a family with distal arthrogryposis type 1. J Bone Joint Surg Am. 2011, 93: 1045-1050.
Veugelers M, Bressan M, McDermott DA: Mutation of perinatal myosin heavy chain associated with a Carney complex variant. N Engl J Med. 2004, 351: 460-469. 10.1056/NEJMoa040584.
Pre-publication history
The pre-publication history for this paper can be accessed here:http://www.biomedcentral.com/1471-2474/13/262/prepub
Acknowledgements
The study was supported by a grant from the Swedish Research Council (Project No 073018 to HT), Åke Wiberg’s Foundation to HT. We thank the company Myosix and Association Francaise contre les Myopathies (AFM) for giving free access to the myoblast batches.
Author information
Authors and Affiliations
Corresponding author
Additional information
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
S A-H performed the experiments, assisted in analyzing data and assisted in writing the mauscript; PFMV assisted in analysing data, writing and editing the manuscript; HT performed the study design, analyzed data and wrote and editing the manuscript. Principal investigator and corresponding author. All authors read and approved the final manuscript.
Electronic supplementary material
12891_2012_1572_MOESM1_ESM.tiff
Additional file 1:Figure S1. Sequence analysis of MRF transcripts, TM isoforms, α-skeletal and α-cardiac actin, desmin and titin in both proliferating mononucleated myoblasts and cells after 6 days of differentiation. (A) Sequence chromatograms of part of cDNA of MRFs (MYOD1, MYF5 and MYOG) genes. (B) Sequence chromatograms of part of cDNA of different TM isoforms including TPM1, TPM2 and TPM3. (C) Sequence chromatograms of part of cDNA of α-skeletal and (ACTA1) α-cardiac (ACTC1) actin. (D) Sequence chromatograms of part of desmin (DES) and titin (TTN) genes. The accession number and position of each gene is indicated. (TIFF 9 MB)
12891_2012_1572_MOESM2_ESM.tiff
Additional file 2:Figure S2. Sequence analysis of TnT, TnI and MyBPC isoforms in proliferating mononucleated myoblasts and cells after 6 days of differentiation. (A) Sequence chromatograms of part of cDNA of slow skeletal (TNNT1), cardiac (TNNT2) and fast skeletal (TNNT3) muscle troponin T. (B) Sequence chromatograms of part of cDNA of slow, fast and cardiac troponin I (TNNI1, TNNI2 and TNNI3). (C) Sequence chromatograms of part of cDNA of slow and fast skeletal muscle MyBPC (MYBPC1 and MYBPC2) and cardiac-specific (MYBPC3) isoforms. The accession number and position of each gene is indicated. (TIFF 5 MB)
12891_2012_1572_MOESM3_ESM.tiff
Additional file 3:Figure S3. Sequence analysis of different MyHC isoforms in proliferating mononucleated myoblasts and cells after 6 days of differentiation. Sequence chromatograms of a specific region of cDNA of different MyHC isoforms including MYH1, MYH2, MYH3, MYH4, MYH7 and MYH8. The accession number and position of each isoform is indicated. (TIFF 7 MB)
12891_2012_1572_MOESM4_ESM.tiff
Additional file 4:Figure S4. Immunofluorescence micrographs of myoblasts and cells after 6 days of differentiation. (Emphasis>/Emphasis>) Proliferating myoblasts stained with antibodies against desmin, (B) embryonic MyHC, (C) neonatal MyHC and (D) fast and slow MyHC, (E) alpha-skeletal actin, (F) all tropomyosin isoforms, (G) beta-tropomyosin isoform, (H) slow troponin I and (I) cardiac troponin I. Cells after 6 days of differentiation stained with antibody against (J) desmin, (K) embryonic MyHC, (L) neonatal MyHC and (M) fast and slow MyHC, (N) alpha-skeletal actin and (O) cardiac troponin I. These staining patterns confirm the data obtained by immunocytochemistry. Nuclei were stained with DAPI (blue). The bar represents 10 μm. (TIFF 13 MB)
Authors’ original submitted files for images
Below are the links to the authors’ original submitted files for images.
Rights and permissions
Open Access This article is published under license to BioMed Central Ltd. This is an Open Access article is distributed under the terms of the Creative Commons Attribution License ( https://creativecommons.org/licenses/by/2.0 ), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
About this article
Cite this article
Abdul-Hussein, S., van der Ven, P.F.M. & Tajsharghi, H. Expression profiles of muscle disease-associated genes and their isoforms during differentiation of cultured human skeletal muscle cells. BMC Musculoskelet Disord 13, 262 (2012). https://doi.org/10.1186/1471-2474-13-262
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/1471-2474-13-262