| Q50906236 | A Cell Fusion-Based Screening Method Identifies Glycosylphosphatidylinositol-Anchored Protein Ly6e as the Receptor for Mouse Endogenous Retroviral Envelope Syncytin-A. |
| Q36603866 | A MED13-dependent skeletal muscle gene program controls systemic glucose homeostasis and hepatic metabolism |
| Q33891096 | A defect in myoblast fusion underlies Carey-Fineman-Ziter syndrome. |
| Q28513835 | A micropeptide encoded by a putative long noncoding RNA regulates muscle performance |
| Q49199284 | A novel in vitro model for the assessment of postnatal myonuclear accretion |
| Q52332064 | A novel long non-coding RNA Myolinc regulates myogenesis through TDP-43 and Filip1. |
| Q50000068 | A real-time monitoring platform of myogenesis regulators using double fluorescent labeling |
| Q54982478 | Abnormalities in Skeletal Muscle Myogenesis, Growth, and Regeneration in Myotonic Dystrophy. |
| Q50176856 | Acting on identity: Myoblast fusion and the formation of the syncytial muscle fiber |
| Q46406984 | Altered expression of ganglioside GM3 molecular species and a potential regulatory role during myoblast differentiation |
| Q90295543 | Altered protein turnover signaling and myogenesis during impaired recovery of inflammation-induced muscle atrophy in emphysematous mice |
| Q36369804 | Annexin A1 Deficiency does not Affect Myofiber Repair but Delays Regeneration of Injured Muscles |
| Q47985383 | Autonomous xenogenic cell fusion of murine and chick skeletal muscle myoblasts. |
| Q36265728 | Basal Lamina Mimetic Nanofibrous Peptide Networks for Skeletal Myogenesis. |
| Q90677333 | Carey-Fineman-Ziter syndrome with mutations in the myomaker gene and muscle fiber hypertrophy |
| Q90277963 | Cell fusion is differentially regulated in zebrafish post-embryonic slow and fast muscle |
| Q55311954 | Cell surface flip-flop of phosphatidylserine is critical for PIEZO1-mediated myotube formation. |
| Q37589632 | Changes in Communication between Muscle Stem Cells and their Environment with Aging. |
| Q48051837 | Changes in muscle fiber contractility and extracellular matrix production during skeletal muscle hypertrophy |
| Q92619888 | Circular RNA Regulation of Myogenesis |
| Q96304805 | Circular RNAs in Embryogenesis and Cell Differentiation With a Focus on Cancer Development |
| Q64061815 | Collagen XXV promotes myoblast fusion during myogenic differentiation and muscle formation |
| Q64093213 | Continuous exposure of isoprenaline inhibits myoblast differentiation and fusion through PKA/ERK1/2-FOXO1 signaling pathway |
| Q53763050 | Contractile function recovery in severely injured gastrocnemius muscle of rats treated with either oleic or linoleic acid. |
| Q33112265 | Control of muscle formation by the fusogenic micropeptide myomixer. |
| Q52731213 | Cry2 Is Critical for Circadian Regulation of Myogenic Differentiation by Bclaf1-Mediated mRNA Stabilization of Cyclin D1 and Tmem176b. |
| Q45931257 | Cullin E3 Ligase Activity Is Required for Myoblast Differentiation. |
| Q64970946 | Cullin-3 dependent deregulation of ACTN1 represents a new pathogenic mechanism in nemaline myopathy. |
| Q91454835 | DA-Raf, a dominant-negative regulator of the Ras-ERK pathway, is essential for skeletal myocyte differentiation including myoblast fusion and apoptosis |
| Q38738050 | Degree of Suppression of Mouse Myoblast Cell Line C₂C12 Differentiation Varies According to Chondroitin Sulfate Subtype |
| Q91946410 | Depletion of branched-chain aminotransferase 2 (BCAT2) enzyme impairs myoblast survival and myotube formation |
| Q48184096 | Different outcome of sarcoglycan missense mutation between human and mouse |
| Q49189890 | Dissection of Myogenic Differentiation Signatures in Chickens by RNA-Seq Analysis |
| Q64282178 | Dynamic membrane proteome of adipogenic and myogenic precursors in skeletal muscle highlights EPHA2 may promote myogenic differentiation through ERK signaling |
| Q33784603 | Dysregulation of nuclear receptor COUP-TFII impairs skeletal muscle development |
| Q36990698 | E2F1-miR-20a-5p/20b-5p auto-regulatory feedback loop involved in myoblast proliferation and differentiation |
| Q38857342 | Engineered matrices for skeletal muscle satellite cell engraftment and function |
| Q92112216 | EphA7 promotes myogenic differentiation via cell-cell contact |
| Q48099947 | Expression of nuclear factor of activated T cells (NFAT) and downstream muscle-specific proteins in ground squirrel skeletal and heart muscle during hibernation |
| Q35103393 | FHL1 reduces dystrophy in transgenic mice overexpressing FSHD muscular dystrophy region gene 1 (FRG1). |
| Q47155111 | Functional validation and expression analysis of myotubes converted from skin fibroblasts using a simple direct reprogramming strategy |
| Q24338272 | G-protein coupled receptor BAI3 promotes myoblast fusion in vertebrates |
| Q36121710 | Genetic Evidence That Captured Retroviral Envelope syncytins Contribute to Myoblast Fusion and Muscle Sexual Dimorphism in Mice |
| Q93363137 | Genetic Mutations in jamb, jamc, and myomaker Revealed Different Roles on Myoblast Fusion and Muscle Growth |
| Q26746405 | Genetic variation and exercise-induced muscle damage: implications for athletic performance, injury and ageing |
| Q36110170 | HACD1, a regulator of membrane composition and fluidity, promotes myoblast fusion and skeletal muscle growth. |
| Q57490987 | HDAC4 Regulates Skeletal Muscle Regeneration via Soluble Factors |
| Q35618657 | Heterogeneous activation of a slow myosin gene in proliferating myoblasts and differentiated single myofibers |
| Q59794924 | Histological, transcriptomic and in vitro analysis reveal an intrinsic activated state of myogenic precursors in hyperplasic muscle of trout |
| Q92765296 | How cells fuse |
| Q64069475 | Human induced pluripotent stem cell models for the study and treatment of Duchenne and Becker muscular dystrophies |
| Q42374870 | IL-15 promotes human myogenesis and mitigates the detrimental effects of TNFα on myotube development |
| Q28389659 | In vivo Monitoring of Transcriptional Dynamics After Lower-Limb Muscle Injury Enables Quantitative Classification of Healing |
| Q50233651 | In vivo myomaker-mediated heterologous fusion and nuclear reprogramming |
| Q98611552 | Inhibition of inflammatory CCR2 signaling promotes aged muscle regeneration and strength recovery after injury |
| Q51165642 | Inhibition of platelet-derived growth factor signaling prevents muscle fiber growth during skeletal muscle hypertrophy. |
| Q38599179 | Insights into the localization and function of myomaker during myoblast fusion |
| Q27315997 | Integrin Adhesions Suppress Syncytium Formation in the Drosophila Larval Epidermis. |
| Q33895182 | Intercellular adhesion molecule-1 augments myoblast adhesion and fusion through homophilic trans-interactions |
| Q35071042 | Intercellular adhesion molecule-1 expression by skeletal muscle cells augments myogenesis. |
| Q89905217 | Interleukin-4 administration improves muscle function, adult myogenesis, and lifespan of colon carcinoma-bearing mice |
| Q59808421 | Intramuscular preadipocytes impede differentiation and promote lipid deposition of muscle satellite cells in chickens |
| Q42645901 | Irisin is a pro-myogenic factor that induces skeletal muscle hypertrophy and rescues denervation-induced atrophy. |
| Q24294821 | Juno is the egg Izumo receptor and is essential for mammalian fertilization |
| Q28585181 | KLHL40 deficiency destabilizes thin filament proteins and promotes nemaline myopathy |
| Q41560314 | KLHL41 stabilizes skeletal muscle sarcomeres by nonproteolytic ubiquitination. |
| Q39071476 | Keep Your Friends Close: Cell-Cell Contact and Skeletal Myogenesis |
| Q35686043 | Long-Term Endurance Exercise in Humans Stimulates Cell Fusion of Myoblasts along with Fusogenic Endogenous Retroviral Genes In Vivo |
| Q54114360 | Loss of myogenic potential and fusion capacity of muscle stem cells isolated from contractured muscle in children with cerebral palsy. |
| Q36400477 | Low Intensity Exercise Training Improves Skeletal Muscle Regeneration Potential |
| Q28081230 | Mechanisms of myoblast fusion during muscle development |
| Q36372961 | Membrane fusion in muscle development and repair |
| Q41995854 | Memory or amnesia: the dilemma of stem cell therapy in muscular dystrophies |
| Q90015607 | Methylation status and expression patterns of myomaker gene play important roles in postnatal development in the Japanese flounder (Paralichthys olivaceus) |
| Q91872133 | Mitochondria in Embryogenesis: An Organellogenesis Perspective |
| Q39248771 | Muscle cell communication in development and repair |
| Q45330039 | MyD88 promotes myoblast fusion in a cell-autonomous manner |
| Q48131580 | Myoblast fusion confusion: the resolution begins. |
| Q40975816 | Myocardin-related transcription factors are required for skeletal muscle development |
| Q57471964 | Myogenin promotes myocyte fusion to balance fibre number and size |
| Q28585754 | Myomaker is essential for muscle regeneration |
| Q47073980 | Myomaker is required for the fusion of fast-twitch myocytes in the zebrafish embryo |
| Q40352908 | Myomaker, Regulated by MYOD, MYOG and miR-140-3p, Promotes Chicken Myoblast Fusion |
| Q91090178 | Myomaker, and Myomixer-Myomerger-Minion modulate the efficiency of skeletal muscle development with melatonin supplementation through Wnt/β-catenin pathway |
| Q33112259 | Myomerger induces fusion of non-fusogenic cells and is required for skeletal muscle development |
| Q104134975 | Myonuclear content regulates cell size with similar scaling properties in mice and humans |
| Q91896403 | NADPH Oxidase 4 Contributes to Myoblast Fusion and Skeletal Muscle Regeneration |
| Q57095632 | Naked mole-rat transcriptome signatures of socially suppressed sexual maturation and links of reproduction to aging |
| Q26799278 | New insights into the epigenetic control of satellite cells |
| Q64967827 | Ninjurin1 regulates striated muscle growth and differentiation. |
| Q104134913 | Nuclear numbers in syncytial muscle fibers promote size but limit the development of larger myonuclear domains |
| Q52716623 | Oxidative stress-mediated senescence in mesenchymal progenitor cells causes the loss of their fibro/adipogenic potential and abrogates myoblast fusion. |
| Q30837213 | Palmdelphin promotes myoblast differentiation and muscle regeneration |
| Q90425460 | Phosphatidylserine on viable sperm and phagocytic machinery in oocytes regulate mammalian fertilization |
| Q42721929 | Pias1 is essential for erythroid and vascular development in the mouse embryo. |
| Q36142754 | Probing for a deeper understanding of rhabdomyosarcoma: insights from complementary model systems. |
| Q98244050 | Proteomic resolution of IGFN1 complexes reveals a functional interaction with the actin nucleating protein COBL |
| Q55003034 | RNA-Seq identifies genes whose proteins are transformative in the differentiation of cytotrophoblast to syncytiotrophoblast, in human primary villous and BeWo trophoblasts. |
| Q35728231 | RNAseq analysis of fast skeletal muscle in restriction-fed transgenic coho salmon (Oncorhynchus kisutch): an experimental model uncoupling the growth hormone and nutritional signals regulating growth |
| Q57233423 | Regulation of nuclear factor of activated T cells (NFAT) and downstream myogenic proteins during dehydration in the African clawed frog |
| Q50669913 | Reproductive biology: Sperm protein finds its mate. |
| Q37682790 | Requirement of myomaker-mediated stem cell fusion for skeletal muscle hypertrophy |
| Q46273123 | Requirement of the fusogenic micropeptide myomixer for muscle formation in zebrafish. |
| Q30009101 | SORBS2 transcription is activated by telomere position effect-over long distance upon telomere shortening in muscle cells from patients with facioscapulohumeral dystrophy |
| Q38542445 | Satellite Cells and Skeletal Muscle Regeneration. |
| Q35625089 | Seeking balance: Potentiation and inhibition of multiple sclerosis autoimmune responses by IL-6 and IL-10. |
| Q30666846 | Separating myoblast differentiation from muscle cell fusion using IGF-I and the p38 MAP kinase inhibitor SB202190. |
| Q28975628 | Severe myopathy in mice lacking the MEF2/SRF-dependent gene leiomodin-3 |
| Q64914220 | Shisa2 regulates the fusion of muscle progenitors. |
| Q63407324 | Single-cell RNA-seq reveals the diversity of trophoblast subtypes and patterns of differentiation in the human placenta |
| Q51129101 | Skeletal muscle patch engineering on synthetic and acellular human skeletal muscle originated scaffolds. |
| Q52870713 | Skeletal muscle satellite cells as myogenic progenitors for muscle homoeostasis, growth, regeneration and repair. |
| Q92589002 | Skeletal muscle: A review of molecular structure and function, in health and disease |
| Q38771964 | Spatial Geometries of Self-Assembled Chitohexaose Monolayers Regulate Myoblast Fusion |
| Q58115610 | Spatiotemporal regulation of the GPCR activity of BAI3 by C1qL4 and Stabilin-2 controls myoblast fusion |
| Q92753667 | Stabilin Receptors: Role as Phosphatidylserine Receptors |
| Q47174651 | Starring or Supporting Role? Satellite Cells and Skeletal Muscle Fiber Size Regulation. |
| Q36646542 | Structure-function analysis of myomaker domains required for myoblast fusion |
| Q27310000 | Surface apposition and multiple cell contacts promote myoblast fusion in Drosophila flight muscles. |
| Q48325250 | Sustained Depolarization of the Resting Membrane Potential Regulates Muscle Progenitor Cell Growth and Maintains Stem Cell Properties In Vitro |
| Q83228829 | Sustained expression of HeyL is critical for the proliferation of muscle stem cells in overloaded muscle |
| Q89686912 | TLR9 and beclin 1 crosstalk regulates muscle AMPK activation in exercise |
| Q96137198 | TMEM16F phospholipid scramblase mediates trophoblast fusion and placental development |
| Q38694152 | Targeted Lipidomic Analysis of Myoblasts by GC-MS and LC-MS/MS. |
| Q42496118 | Temporal correlation between differentiation factor expression and microRNAs in Holstein bovine skeletal muscle |
| Q37685883 | Ten-Eleven Translocation-2 (Tet2) Is Involved in Myogenic Differentiation of Skeletal Myoblast Cells in Vitro |
| Q27023254 | Tethering membrane fusion: common and different players in myoblasts and at the synapse |
| Q37675742 | The Ancient Gamete Fusogen HAP2 Is a Eukaryotic Class II Fusion Protein |
| Q35234123 | The RNA-binding protein Rbfox1 regulates splicing required for skeletal muscle structure and function |
| Q91386356 | The SMYD3 methyltransferase promotes myogenesis by activating the myogenin regulatory network |
| Q59806119 | The Trithorax protein Ash1L promotes myoblast fusion by activating Cdon expression |
| Q43119631 | The brain expressed x-linked gene 1 (Bex1) regulates myoblast fusion. |
| Q36375580 | The chicken embryo as an efficient model to test the function of muscle fusion genes in amniotes |
| Q90131696 | The fusogenic synapse at a glance |
| Q47279331 | The hallmarks of cell-cell fusion. |
| Q94562425 | The micropeptide LEMP plays an evolutionarily conserved role in myogenesis |
| Q33112257 | The microprotein Minion controls cell fusion and muscle formation |
| Q36742922 | Topologically associated domains enriched for lineage-specific genes reveal expression-dependent nuclear topologies during myogenesis. |
| Q89500866 | Transcriptional landscape of myogenesis from human pluripotent stem cells reveals a key role of TWIST1 in maintenance of skeletal muscle progenitors |
| Q38709532 | Transiently expressed pattern during myogenesis and candidate miRNAs of Tmem8C in goose |
| Q92021900 | Trout myomaker contains 14 minisatellites and two sequence extensions but retains fusogenic function |
| Q39159750 | Up-regulated exosomal miRNA-140-3p in CML patients with musculoskeletal pain associated with discontinuation of tyrosine kinase inhibitors |
| Q38901764 | WNT/β-Catenin Signaling Regulates Multiple Steps of Myogenesis by Regulating Step-Specific Targets |
| Q55016177 | Whole-exome sequencing identifies mutations in MYMK in a mild form of Carey-Fineman-Ziter syndrome. |
| Q91106459 | Zfp422 promotes skeletal muscle differentiation by regulating EphA7 to induce appropriate myoblast apoptosis |