A4.1025

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$40.00
SKU: A4.1025
View product citations for antibody A4.1025 on CiteAb

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Available: 154

DSHB Data Sheet

Catalog Fields

Antigen: Myosin all isoforms
Hybridoma Cells Available: Yes
Antigen Species: Human
Depositor: Blau, H.M.
Isotype: MIgG2a
Antigen Sequence:
Host Species: mouse
Depositors Institution: Baxter Lab for Stem Cell Biology, Stanford University
Positive Tested Species Reactivity: Amphibian, Dogfish, Fish, Human, Rodent, Zebrafish
Depositors Notes:
Antigen Molecular Weight: 220 kDa
Human Protein Atlas:
Predicted Species Reactivity:  
Gene: MYH1
Immunogen: Myosin heavy chain (human MHC or MyHC) purified.
Alternate Gene Names: MYHa, HEL71, MYHSA1, MyHC-2x, MyHC-2X/D
Alternate Antibody Name:
Clonality: Monoclonal
Alternate Antigen Name:
Epitope Mapped:
Myeloma Strain: P3 x 63Ag8 653
Epitope Location or Sequence:
Uniprot ID: P12882 
Immunogen Sequence:
Entrez Gene ID: 4619 
Additional Characterization:
Antibody Registry ID: AB_528356 
Additional Information:
Recommended Applications: Immunofluorescence, Immunohistochemistry, Immunoprecipitation, Western Blot
These hybridomas were created by your colleagues. Please acknowledge the hybridoma contributor and the Developmental Studies Hybridoma Bank (DSHB) in the Materials and Methods of your publications. Please email the citation to us.
For your Materials & Methods section:
A4.1025 was deposited to the DSHB by Blau, H.M. (DSHB Hybridoma Product A4.1025)
Storage and Handling Recommendations
Although many cell products are maintained at 4°C for years without loss of activity, shelf-life at 4°C is highly variable. To ensure retention of antibody activity, we recommend aliquotting the product into two parts: 1) a volume of antibody stored at 4°C to be used within two weeks. 2) the remaining product diluted with an equal volume of molecular grade glycerol and stored at -20°C.
Usage Recommendations
While optimal Ig concentration for an application will vary, a good starting concentration for immunohistochemistry (IHC), immunofluorescence(IF) and staining is 2-5 µg/ml. For Western blots, the concentration is decreased by one order of magnitude (that is, 0.2-0.5 µg/ml).
All cell products contain the antimicrobial ProClin. Click here for additional information.

51 References

  • Initial Publication
  • IF References
  • WB References
  • IHC References
  • IP References
  • ELISA References
  • All References
  • Initial Publication
    IF References

    In vitro motility speed of slow myosin extracted from single soleus fibres from young and old rats.
    Larsson L
    The Journal of physiology 520 Pt 2. (1999 Oct 15): 463-71.

    Distinct functions of alternatively spliced isoforms encoded by zebrafish mef2ca and mef2cb.
    Molinari S
    Biochimica et biophysica acta 1839.7 (2014 Jul): 559-70.

    Cryptorchidism in the orl rat is associated with muscle patterning defects in the fetal gubernaculum and altered hormonal signaling.
    Akins RE Jr
    Biology of reproduction 91.2 (2014 Aug): 41.

    MicroRNA-30a regulates zebrafish myogenesis through targeting the transcription factor Six1.
    Ford HL
    Journal of cell science 127.Pt 10 (2014 May 15): 2291-301.

    Zebrafish models of BAG3 myofibrillar myopathy suggest a toxic gain of function leading to BAG3 insufficiency.
    Bryson-Richardson RJ
    Acta neuropathologica 128.6 (2014 Dec): 821-33.

    Mechanistic investigation of adult myotube response to exercise and drug treatment in vitro using a multiplexed functional assay system.
    Hickman JJ
    Journal of applied physiology (Bethesda, Md. : 1985) 117.11 (2014 Dec 1): 1398-405.

    The development of zebrafish tendon and ligament progenitors.
    Galloway JL
    Development (Cambridge, England) 141.10 (2014 May): 2035-45.

    MUNC, a long noncoding RNA that facilitates the function of MyoD in skeletal myogenesis.
    Dutta A
    Molecular and cellular biology 35.3 (2015 Feb): 498-513.

    Structure and interactions of myosin-binding protein C domain C0: cardiac-specific regulation of myosin at its neck?
    Pfuhl M
    The Journal of biological chemistry 286.14 (2011 Apr 8): 12650-8.

    Paralysis and delayed Z-disc formation in the Xenopus tropicalis unc45b mutant dicky ticker.
    Zimmerman LB
    BMC developmental biology 10. (2010 Jul 16): 75.

    Inhibition of mammalian muscle differentiation by excretory secretory products of muscle larvae of Trichinella spiralis in vitro.
    Liu M
    Parasitology research 110.6 (2012 Jun): 2481-90.

    Osteoblasts derived from induced pluripotent stem cells form calcified structures in scaffolds both in vitro and in vivo.
    Majka SM
    Stem cells (Dayton, Ohio) 29.2 (2011 Feb): 206-16.

    503unc, a small and muscle-specific zebrafish promoter.
    Currie PD
    Genesis (New York, N.Y. : 2000) 51.6 (2013 Jun): 443-7.

    Muscle development and differentiation in the urodele Ambystoma mexicanum.
    Grimaldi A
    Development, growth and differentiation 54.4 (2012 May): 489-502.

    Cooperation between Shh and IGF-I in promoting myogenic proliferation and differentiation via the MAPK/ERK and PI3K/Akt pathways requires Smo activity.
    Halevy O
    Journal of cellular physiology 227.4 (2012 Apr): 1455-64.

    Characterization and investigation of zebrafish models of filamin-related myofibrillar myopathy.
    Bryson-Richardson RJ
    Human molecular genetics 21.18 (2012 Sep 15): 4073-83.

    Isolation of a highly myogenic CD34-negative subset of human skeletal muscle cells free of adipogenic potential.
    Dani C
    Stem cells (Dayton, Ohio) 28.4 (2010 Apr): 753-64.

    Differentiation of mouse induced pluripotent stem cells into a multipotent keratinocyte lineage.
    Roop DR
    The Journal of investigative dermatology 131.4 (2011 Apr): 857-64.

    Engineering the cell-material interface for controlling stem cell adhesion, migration, and differentiation.
    Varghese S
    Biomaterials 32.15 (2011 May): 3700-11.

    Efficient myogenic reprogramming of adult white fat stem cells and bone marrow stem cells by freshly isolated skeletal muscle fibers.
    Patel K
    Translational research : the journal of laboratory and clinical medicine 158.6 (2011 Dec): 334-43.

    Development and evolution of the muscles of the pelvic fin.
    Currie PD
    PLoS biology 9.10 (2011 Oct): e1001168.

    Stereotypic generation of axial tenocytes from bipartite sclerotome domains in zebrafish.
    Huang P
    PLoS genetics 14.11 (2018 Nov): e1007775.

    WB References

    Evidence for myoblast-extrinsic regulation of slow myosin heavy chain expression during muscle fiber formation in embryonic development.
    Blau HM
    The Journal of cell biology 121.4 (1993 May): 795-810.

    Myosin heavy chain composition in rat laryngeal muscles after denervation.
    Flint PW
    The Laryngoscope 108.8 Pt 1 (1998 Aug): 1225-9.

    Fast myosin heavy chains expressed in secondary mammalian muscle fibers at the time of their inception.
    Blau HM
    Journal of cell science 107 ( Pt 9). (1994 Sep): 2361-71.

    Three slow myosin heavy chains sequentially expressed in developing mammalian skeletal muscle.
    Blau HM
    Developmental biology 158.1 (1993 Jul): 183-99.

    Myosin heavy chain composition in human laryngeal muscles.
    Flint PW
    The Laryngoscope 109.9 (1999 Sep): 1521-4.

    Evidence for differential post-translational modifications of slow myosin heavy chain during murine skeletal muscle development.
    Hughes SM
    Journal of muscle research and cell motility 21.2 (2000 Feb): 101-13.

    Urethral dysfunction in female mice with estrogen receptor β deficiency.
    Chen HY
    PloS one 9.9 (2014): e109058.

    Extracellular vesicles from a muscle cell line (C2C12) enhance cell survival and neurite outgrowth of a motor neuron cell line (NSC-34).
    Robinson GA
    Journal of extracellular vesicles 3. (2014): .

    The endocannabinoid 2-AG controls skeletal muscle cell differentiation via CB1 receptor-dependent inhibition of Kv7 channels.
    Di Marzo V
    Proceedings of the National Academy of Sciences of the United States of America 111.24 (2014 Jun 17): E2472-81.

    Distinct functions of alternatively spliced isoforms encoded by zebrafish mef2ca and mef2cb.
    Molinari S
    Biochimica et biophysica acta 1839.7 (2014 Jul): 559-70.

    Inhibition of mammalian muscle differentiation by excretory secretory products of muscle larvae of Trichinella spiralis in vitro.
    Liu M
    Parasitology research 110.6 (2012 Jun): 2481-90.

    Myosin heavy chain isoform expression in human extraocular muscles: longitudinal variation and patterns of expression in global and orbital layers.
    Oh SY
    Muscle and nerve 45.5 (2012 May): 713-20.

    Cardiomyopathy mutations in the tail of β-cardiac myosin modify the coiled-coil structure and affect integration into thick filaments in muscle sarcomeres in adult cardiomyocytes.
    Peckham M
    The Journal of biological chemistry 288.44 (2013 Nov 1): 31952-62.

    TGF-β isoforms inhibit IGF-1-induced migration and regulate terminal differentiation in a cell-specific manner.
    Niesler CU
    Journal of muscle research and cell motility 31.5-6 (2011 Mar): 359-67.

    Muscle development and differentiation in the urodele Ambystoma mexicanum.
    Grimaldi A
    Development, growth and differentiation 54.4 (2012 May): 489-502.

    Cooperation between Shh and IGF-I in promoting myogenic proliferation and differentiation via the MAPK/ERK and PI3K/Akt pathways requires Smo activity.
    Halevy O
    Journal of cellular physiology 227.4 (2012 Apr): 1455-64.

    Deficiency in APOBEC2 leads to a shift in muscle fiber type, diminished body mass, and myopathy.
    Rada C
    The Journal of biological chemistry 285.10 (2010 Mar 5): 7111-8.

    Differential expression of myosin heavy chain isoforms in cardiac segments of gnathostome vertebrates and its evolutionary implications.
    Fernández B
    Frontiers in zoology 16. (2019): 18.

    IHC References

    Evidence for differential post-translational modifications of slow myosin heavy chain during murine skeletal muscle development.
    Hughes SM
    Journal of muscle research and cell motility 21.2 (2000 Feb): 101-13.

    Distinct functions of alternatively spliced isoforms encoded by zebrafish mef2ca and mef2cb.
    Molinari S
    Biochimica et biophysica acta 1839.7 (2014 Jul): 559-70.

    MicroRNA-30a regulates zebrafish myogenesis through targeting the transcription factor Six1.
    Ford HL
    Journal of cell science 127.Pt 10 (2014 May 15): 2291-301.

    Zebrafish models of BAG3 myofibrillar myopathy suggest a toxic gain of function leading to BAG3 insufficiency.
    Bryson-Richardson RJ
    Acta neuropathologica 128.6 (2014 Dec): 821-33.

    Human and mouse skeletal muscle stem cells: convergent and divergent mechanisms of myogenesis.
    Billin AN
    PloS one 9.2 (2014): e90398.

    The development of zebrafish tendon and ligament progenitors.
    Galloway JL
    Development (Cambridge, England) 141.10 (2014 May): 2035-45.

    Pulmonary endoderm, second heart field and the morphogenesis of distal outflow tract in mouse embryonic heart.
    Ya J
    Development, growth and differentiation 56.4 (2014 May): 276-92.

    Retinoic acid regulates size, pattern and alignment of tissues at the head-trunk transition.
    Skromne I
    Development (Cambridge, England) 141.22 (2014 Nov): 4375-84.

    Paralysis and delayed Z-disc formation in the Xenopus tropicalis unc45b mutant dicky ticker.
    Zimmerman LB
    BMC developmental biology 10. (2010 Jul 16): 75.

    Myosin heavy chain isoform expression in human extraocular muscles: longitudinal variation and patterns of expression in global and orbital layers.
    Oh SY
    Muscle and nerve 45.5 (2012 May): 713-20.

    Cardiomyopathy mutations in the tail of β-cardiac myosin modify the coiled-coil structure and affect integration into thick filaments in muscle sarcomeres in adult cardiomyocytes.
    Peckham M
    The Journal of biological chemistry 288.44 (2013 Nov 1): 31952-62.

    503unc, a small and muscle-specific zebrafish promoter.
    Currie PD
    Genesis (New York, N.Y. : 2000) 51.6 (2013 Jun): 443-7.

    Muscle development and differentiation in the urodele Ambystoma mexicanum.
    Grimaldi A
    Development, growth and differentiation 54.4 (2012 May): 489-502.

    Cellular and molecular investigations into the development of the pectoral girdle.
    Patel K
    Developmental biology 357.1 (2011 Sep 1): 108-16.

    Characterization and investigation of zebrafish models of filamin-related myofibrillar myopathy.
    Bryson-Richardson RJ
    Human molecular genetics 21.18 (2012 Sep 15): 4073-83.

    Correlation of embryonic skeletal muscle myotube physical characteristics with contractile force generation on an atomic force microscope-based bio-microelectromechanical systems device.
    Hickman JJ
    Applied physics letters 103.8 (2013 Aug 19): 83108.

    Efficient myogenic reprogramming of adult white fat stem cells and bone marrow stem cells by freshly isolated skeletal muscle fibers.
    Patel K
    Translational research : the journal of laboratory and clinical medicine 158.6 (2011 Dec): 334-43.

    The sensory innervation of the human pharynx: searching for mechanoreceptors.
    Vega JA
    Anatomical record (Hoboken, N.J. : 2007) 296.11 (2013 Nov): 1735-46.

    Development and evolution of the muscles of the pelvic fin.
    Currie PD
    PLoS biology 9.10 (2011 Oct): e1001168.

    α2-Chimaerin regulates a key axon guidance transition during development of the oculomotor projection.
    Guthrie S
    The Journal of neuroscience : the official journal of the Society for Neuroscience 33.42 (2013 Oct 16): 16540-51.

    Lack of Apobec2-related proteins causes a dystrophic muscle phenotype in zebrafish embryos.
    Strähle U
    The Journal of cell biology 189.3 (2010 May 3): 527-39.

    Zebrafish miR-1 and miR-133 shape muscle gene expression and regulate sarcomeric actin organization.
    Giraldez AJ
    Genes and development 23.5 (2009 Mar 1): 619-32.

    Induced early expression of mrf4 but not myog rescues myogenesis in the myod/myf5 double-morphant zebrafish embryo.
    Cossu G
    Journal of cell science 122.Pt 4 (2009 Feb 15): 481-8.

    Regulation of slow and fast muscle myofibrillogenesis by Wnt/beta-catenin and myostatin signaling.
    Zivkovic D
    PloS one 4.6 (2009 Jun 11): e5880.

    Six1a is required for the onset of fast muscle differentiation in zebrafish.
    Korzh V
    Developmental biology 323.2 (2008 Nov 15): 216-28.

    Heat-shock protein 90alpha1 is required for organized myofibril assembly in skeletal muscles of zebrafish embryos.
    Zhong Y
    Proceedings of the National Academy of Sciences of the United States of America 105.2 (2008 Jan 15): 554-9.

    Control of her1 expression during zebrafish somitogenesis by a delta-dependent oscillator and an independent wave-front activity.
    Nüsslein-Volhard C
    Genes and development 14.13 (2000 Jul 1): 1678-90.

    Differential expression of myosin heavy chain isoforms in cardiac segments of gnathostome vertebrates and its evolutionary implications.
    Fernández B
    Frontiers in zoology 16. (2019): 18.

    IP References
    ELISA References
    All References

    Evidence for differential post-translational modifications of slow myosin heavy chain during murine skeletal muscle development.
    Hughes SM
    Journal of muscle research and cell motility 21.2 (2000 Feb): 101-13.

    Distinct functions of alternatively spliced isoforms encoded by zebrafish mef2ca and mef2cb.
    Molinari S
    Biochimica et biophysica acta 1839.7 (2014 Jul): 559-70.

    MicroRNA-30a regulates zebrafish myogenesis through targeting the transcription factor Six1.
    Ford HL
    Journal of cell science 127.Pt 10 (2014 May 15): 2291-301.

    Zebrafish models of BAG3 myofibrillar myopathy suggest a toxic gain of function leading to BAG3 insufficiency.
    Bryson-Richardson RJ
    Acta neuropathologica 128.6 (2014 Dec): 821-33.

    Human and mouse skeletal muscle stem cells: convergent and divergent mechanisms of myogenesis.
    Billin AN
    PloS one 9.2 (2014): e90398.

    The development of zebrafish tendon and ligament progenitors.
    Galloway JL
    Development (Cambridge, England) 141.10 (2014 May): 2035-45.

    Pulmonary endoderm, second heart field and the morphogenesis of distal outflow tract in mouse embryonic heart.
    Ya J
    Development, growth and differentiation 56.4 (2014 May): 276-92.

    Retinoic acid regulates size, pattern and alignment of tissues at the head-trunk transition.
    Skromne I
    Development (Cambridge, England) 141.22 (2014 Nov): 4375-84.

    Paralysis and delayed Z-disc formation in the Xenopus tropicalis unc45b mutant dicky ticker.
    Zimmerman LB
    BMC developmental biology 10. (2010 Jul 16): 75.

    Myosin heavy chain isoform expression in human extraocular muscles: longitudinal variation and patterns of expression in global and orbital layers.
    Oh SY
    Muscle and nerve 45.5 (2012 May): 713-20.

    Cardiomyopathy mutations in the tail of β-cardiac myosin modify the coiled-coil structure and affect integration into thick filaments in muscle sarcomeres in adult cardiomyocytes.
    Peckham M
    The Journal of biological chemistry 288.44 (2013 Nov 1): 31952-62.

    503unc, a small and muscle-specific zebrafish promoter.
    Currie PD
    Genesis (New York, N.Y. : 2000) 51.6 (2013 Jun): 443-7.

    Muscle development and differentiation in the urodele Ambystoma mexicanum.
    Grimaldi A
    Development, growth and differentiation 54.4 (2012 May): 489-502.

    Cellular and molecular investigations into the development of the pectoral girdle.
    Patel K
    Developmental biology 357.1 (2011 Sep 1): 108-16.

    Characterization and investigation of zebrafish models of filamin-related myofibrillar myopathy.
    Bryson-Richardson RJ
    Human molecular genetics 21.18 (2012 Sep 15): 4073-83.

    Correlation of embryonic skeletal muscle myotube physical characteristics with contractile force generation on an atomic force microscope-based bio-microelectromechanical systems device.
    Hickman JJ
    Applied physics letters 103.8 (2013 Aug 19): 83108.

    Efficient myogenic reprogramming of adult white fat stem cells and bone marrow stem cells by freshly isolated skeletal muscle fibers.
    Patel K
    Translational research : the journal of laboratory and clinical medicine 158.6 (2011 Dec): 334-43.

    The sensory innervation of the human pharynx: searching for mechanoreceptors.
    Vega JA
    Anatomical record (Hoboken, N.J. : 2007) 296.11 (2013 Nov): 1735-46.

    Development and evolution of the muscles of the pelvic fin.
    Currie PD
    PLoS biology 9.10 (2011 Oct): e1001168.

    α2-Chimaerin regulates a key axon guidance transition during development of the oculomotor projection.
    Guthrie S
    The Journal of neuroscience : the official journal of the Society for Neuroscience 33.42 (2013 Oct 16): 16540-51.

    Lack of Apobec2-related proteins causes a dystrophic muscle phenotype in zebrafish embryos.
    Strähle U
    The Journal of cell biology 189.3 (2010 May 3): 527-39.

    Zebrafish miR-1 and miR-133 shape muscle gene expression and regulate sarcomeric actin organization.
    Giraldez AJ
    Genes and development 23.5 (2009 Mar 1): 619-32.

    Induced early expression of mrf4 but not myog rescues myogenesis in the myod/myf5 double-morphant zebrafish embryo.
    Cossu G
    Journal of cell science 122.Pt 4 (2009 Feb 15): 481-8.

    Regulation of slow and fast muscle myofibrillogenesis by Wnt/beta-catenin and myostatin signaling.
    Zivkovic D
    PloS one 4.6 (2009 Jun 11): e5880.

    Six1a is required for the onset of fast muscle differentiation in zebrafish.
    Korzh V
    Developmental biology 323.2 (2008 Nov 15): 216-28.

    Heat-shock protein 90alpha1 is required for organized myofibril assembly in skeletal muscles of zebrafish embryos.
    Zhong Y
    Proceedings of the National Academy of Sciences of the United States of America 105.2 (2008 Jan 15): 554-9.

    Control of her1 expression during zebrafish somitogenesis by a delta-dependent oscillator and an independent wave-front activity.
    Nüsslein-Volhard C
    Genes and development 14.13 (2000 Jul 1): 1678-90.

    Differential expression of myosin heavy chain isoforms in cardiac segments of gnathostome vertebrates and its evolutionary implications.
    Fernández B
    Frontiers in zoology 16. (2019): 18.

    In vitro motility speed of slow myosin extracted from single soleus fibres from young and old rats.
    Larsson L
    The Journal of physiology 520 Pt 2. (1999 Oct 15): 463-71.

    Cryptorchidism in the orl rat is associated with muscle patterning defects in the fetal gubernaculum and altered hormonal signaling.
    Akins RE Jr
    Biology of reproduction 91.2 (2014 Aug): 41.

    Mechanistic investigation of adult myotube response to exercise and drug treatment in vitro using a multiplexed functional assay system.
    Hickman JJ
    Journal of applied physiology (Bethesda, Md. : 1985) 117.11 (2014 Dec 1): 1398-405.

    MUNC, a long noncoding RNA that facilitates the function of MyoD in skeletal myogenesis.
    Dutta A
    Molecular and cellular biology 35.3 (2015 Feb): 498-513.

    Structure and interactions of myosin-binding protein C domain C0: cardiac-specific regulation of myosin at its neck?
    Pfuhl M
    The Journal of biological chemistry 286.14 (2011 Apr 8): 12650-8.

    Inhibition of mammalian muscle differentiation by excretory secretory products of muscle larvae of Trichinella spiralis in vitro.
    Liu M
    Parasitology research 110.6 (2012 Jun): 2481-90.

    Osteoblasts derived from induced pluripotent stem cells form calcified structures in scaffolds both in vitro and in vivo.
    Majka SM
    Stem cells (Dayton, Ohio) 29.2 (2011 Feb): 206-16.

    Cooperation between Shh and IGF-I in promoting myogenic proliferation and differentiation via the MAPK/ERK and PI3K/Akt pathways requires Smo activity.
    Halevy O
    Journal of cellular physiology 227.4 (2012 Apr): 1455-64.

    Isolation of a highly myogenic CD34-negative subset of human skeletal muscle cells free of adipogenic potential.
    Dani C
    Stem cells (Dayton, Ohio) 28.4 (2010 Apr): 753-64.

    Differentiation of mouse induced pluripotent stem cells into a multipotent keratinocyte lineage.
    Roop DR
    The Journal of investigative dermatology 131.4 (2011 Apr): 857-64.

    Engineering the cell-material interface for controlling stem cell adhesion, migration, and differentiation.
    Varghese S
    Biomaterials 32.15 (2011 May): 3700-11.

    Stereotypic generation of axial tenocytes from bipartite sclerotome domains in zebrafish.
    Huang P
    PLoS genetics 14.11 (2018 Nov): e1007775.

    Evidence for myoblast-extrinsic regulation of slow myosin heavy chain expression during muscle fiber formation in embryonic development.
    Blau HM
    The Journal of cell biology 121.4 (1993 May): 795-810.

    Myosin heavy chain composition in rat laryngeal muscles after denervation.
    Flint PW
    The Laryngoscope 108.8 Pt 1 (1998 Aug): 1225-9.

    Fast myosin heavy chains expressed in secondary mammalian muscle fibers at the time of their inception.
    Blau HM
    Journal of cell science 107 ( Pt 9). (1994 Sep): 2361-71.

    Three slow myosin heavy chains sequentially expressed in developing mammalian skeletal muscle.
    Blau HM
    Developmental biology 158.1 (1993 Jul): 183-99.

    Myosin heavy chain composition in human laryngeal muscles.
    Flint PW
    The Laryngoscope 109.9 (1999 Sep): 1521-4.

    Urethral dysfunction in female mice with estrogen receptor β deficiency.
    Chen HY
    PloS one 9.9 (2014): e109058.

    Extracellular vesicles from a muscle cell line (C2C12) enhance cell survival and neurite outgrowth of a motor neuron cell line (NSC-34).
    Robinson GA
    Journal of extracellular vesicles 3. (2014): .

    The endocannabinoid 2-AG controls skeletal muscle cell differentiation via CB1 receptor-dependent inhibition of Kv7 channels.
    Di Marzo V
    Proceedings of the National Academy of Sciences of the United States of America 111.24 (2014 Jun 17): E2472-81.

    TGF-β isoforms inhibit IGF-1-induced migration and regulate terminal differentiation in a cell-specific manner.
    Niesler CU
    Journal of muscle research and cell motility 31.5-6 (2011 Mar): 359-67.

    Deficiency in APOBEC2 leads to a shift in muscle fiber type, diminished body mass, and myopathy.
    Rada C
    The Journal of biological chemistry 285.10 (2010 Mar 5): 7111-8.

    Fast muscle fibers are preferentially affected in Duchenne muscular dystrophy.
    Blau HM
    Cell 52.4 (1988 Feb 26): 503-13.

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