| Q33363816 | A P-Loop NTPase Regulates Quiescent Center Cell Division and Distal Stem Cell Identity through the Regulation of ROS Homeostasis in Arabidopsis Root |
| Q33313934 | A mechanism regulating the onset of Sox2 expression in the embryonic neural plate |
| Q28594783 | A novel mouse HSF3 has the potential to activate nonclassical heat-shock genes during heat shock |
| Q35603112 | A systems view of the protein expression process |
| Q38348926 | AATF mediates an antiapoptotic effect of the unfolded protein response through transcriptional regulation of AKT1 |
| Q33832542 | Acute modulation of sugar transport in brain capillary endothelial cell cultures during activation of the metabolic stress pathway |
| Q38329876 | An improved restriction enzyme accessibility assay for analyzing changes in chromatin structure in samples of limited cell number |
| Q36004275 | Brahma is required for cell cycle arrest and late muscle gene expression during skeletal myogenesis |
| Q40876337 | Brg1 Controls the Expression of Pax7 to Promote Viability and Proliferation of Mouse Primary Myoblasts. |
| Q89529817 | CK2-Dependent Phosphorylation of the Brg1 Chromatin Remodeling Enzyme Occurs during Mitosis |
| Q39990000 | CMF1-Rb interaction promotes myogenesis in avian skeletal myoblasts |
| Q91900409 | Calcineurin Broadly Regulates the Initiation of Skeletal Muscle-Specific Gene Expression by Binding Target Promoters and Facilitating the Interaction of the SWI/SNF Chromatin Remodeling Enzyme |
| Q28513492 | Chd2 interacts with H3.3 to determine myogenic cell fate |
| Q34774545 | Chromatin remodelling and actin organisation |
| Q36481551 | Chromatin remodelling in mammalian differentiation: lessons from ATP-dependent remodellers |
| Q33593168 | Chromatin: the interface between extrinsic cues and the epigenetic regulation of muscle regeneration |
| Q33335957 | Comparative in silico analysis identifies bona fide MyoD binding sites within the Myocyte stress 1 gene promoter |
| Q28072184 | Concise Review: Epigenetic Regulation of Myogenesis in Health and Disease |
| Q41850497 | Contrasting roles for MyoD in organizing myogenic promoter structures during embryonic skeletal muscle development |
| Q37308540 | Contributions of extracellular matrix signaling and tissue architecture to nuclear mechanisms and spatial organization of gene expression control |
| Q42412056 | Determinants of myogenic specificity within MyoD are required for noncanonical E box binding |
| Q40451015 | Differential cooperation between heterochromatin protein HP1 isoforms and MyoD in myoblasts. |
| Q27022808 | Differential modulation of cell cycle progression distinguishes members of the myogenic regulatory factor family of transcription factors |
| Q35167424 | Differentiation and fiber type-specific activity of a muscle creatine kinase intronic enhancer |
| Q42073882 | Distinct protein arginine methyltransferases promote ATP-dependent chromatin remodeling function at different stages of skeletal muscle differentiation |
| Q37461990 | Effects of myogenin on expression of late muscle genes through MyoD-dependent chromatin remodeling ability of myogenin |
| Q38112733 | Epigenetic control of skeletal muscle regeneration: Integrating genetic determinants and environmental changes |
| Q33582052 | Epigenetic mechanisms modulate thyroid transcription factor 1-mediated transcription of the surfactant protein B gene |
| Q30538794 | Epigenetic reprogramming of human embryonic stem cells into skeletal muscle cells and generation of contractile myospheres. |
| Q35207442 | Excitation‐transcription coupling in skeletal muscle: the molecular pathways of exercise |
| Q50425197 | Finding MyoD and lessons learned along the way. |
| Q36904587 | Functional studies of the Ciona intestinalis myogenic regulatory factor reveal conserved features of chordate myogenesis |
| Q33523288 | GSMA: Gene Set Matrix Analysis, An Automated Method for Rapid Hypothesis Testing of Gene Expression Data. |
| Q36262540 | Genetic and epigenetic mechanisms of gene regulation during lens development |
| Q55284543 | HDAC4 regulates satellite cell proliferation and differentiation by targeting P21 and Sharp1 genes. |
| Q37534478 | Histone H3 Methyltransferase Suv39h1 Prevents Myogenic Terminal Differentiation by Repressing MEF2 Activity in Muscle Cells |
| Q36916651 | How many remodelers does it take to make a brain? Diverse and cooperative roles of ATP-dependent chromatin-remodeling complexes in development |
| Q47421649 | Identification of MyoD Interactome Using Tandem Affinity Purification Coupled to Mass Spectrometry |
| Q39821089 | Identification of a Chemical Probe for Family VIII Bromodomains through Optimization of a Fragment Hit |
| Q38925516 | Incorporation of histone H3.1 suppresses the lineage potential of skeletal muscle. |
| Q51970369 | Integration of embryonic and fetal skeletal myogenic programs at the myosin light chain 1f/3f locus. |
| Q35874839 | Investigation of the Expression of Myogenic Transcription Factors, microRNAs and Muscle-Specific E3 Ubiquitin Ligases in the Medial Gastrocnemius and Soleus Muscles following Peripheral Nerve Injury |
| Q39435006 | Isolation of nuclei from skeletal muscle satellite cells and myofibers for use in chromatin immunoprecipitation assays |
| Q37427738 | Loss of MEF2D expression inhibits differentiation and contributes to oncogenesis in rhabdomyosarcoma cells |
| Q36738573 | Mechanisms of ATP dependent chromatin remodeling |
| Q38344532 | Myogenic microRNA expression requires ATP-dependent chromatin remodeling enzyme function |
| Q40189148 | Myogenin and the SWI/SNF ATPase Brg1 maintain myogenic gene expression at different stages of skeletal myogenesis |
| Q36685174 | Myogenin recruits the histone chaperone facilitates chromatin transcription (FACT) to promote nucleosome disassembly at muscle-specific genes |
| Q37013516 | NF-κB forms a complex with the chromatin remodeler BRG1 to regulate Schwann cell differentiation |
| Q36628270 | Networks and hubs for the transcriptional control of osteoblastogenesis. |
| Q35933500 | Opposing calcium-dependent signalling pathways control skeletal muscle differentiation by regulating a chromatin remodelling enzyme |
| Q37875927 | Polycomb proteins in mammalian cell differentiation and plasticity |
| Q34976679 | Polycomb-mediated repression during terminal differentiation: what don't you want to be when you grow up? |
| Q33813287 | Protein kinase D2 is an essential regulator of murine myoblast differentiation |
| Q28592770 | Quantitative proteomic identification of MAZ as a transcriptional regulator of muscle-specific genes in skeletal and cardiac myocytes |
| Q34079529 | Rbfox2-coordinated alternative splicing of Mef2d and Rock2 controls myoblast fusion during myogenesis |
| Q37769115 | Regulation of cellular chromatin state: insights from quiescence and differentiation. |
| Q58578790 | Requirement of Pitx2 for Skeletal Muscle Homeostasis |
| Q50888054 | SWI/SNF chromatin remodeling ATPase Brm regulates the differentiation of early retinal stem cells/progenitors by influencing Brn3b expression and Notch signaling. |
| Q35873705 | SWI/SNF chromatin remodeling enzyme ATPases promote cell proliferation in normal mammary epithelial cells |
| Q37765666 | SWI/SNF complexes, chromatin remodeling and skeletal myogenesis: it's time to exchange! |
| Q34852520 | SWI/SNF enzymes promote SOX10- mediated activation of myelin gene expression |
| Q35212612 | Sculpting chromatin beyond the double helix: epigenetic control of skeletal myogenesis. |
| Q41883703 | Sequential association of myogenic regulatory factors and E proteins at muscle-specific genes |
| Q46868643 | Smarcd3 regulates the timing of zebrafish myogenesis onset. |
| Q39378020 | Sodium arsenite represses the expression of myogenin in C2C12 mouse myoblast cells through histone modifications and altered expression of Ezh2, Glp, and Igf-1. |
| Q35131082 | Spatial re-organization of myogenic regulatory sequences temporally controls gene expression |
| Q28590317 | Target gene selectivity of the myogenic basic helix-loop-helix transcription factor myogenin in embryonic muscle |
| Q47288294 | Temporal regulation of chromatin during myoblast differentiation. |
| Q33360735 | The Arabidopsis SWI2/SNF2 Chromatin Remodeling ATPase BRAHMA Targets Directly to PINs and Is Required for Root Stem Cell Niche Maintenance |
| Q64065056 | The BAF complex in development and disease |
| Q36478015 | The BRG1 transcriptional coregulator |
| Q24305243 | The RNA helicases p68/p72 and the noncoding RNA SRA are coregulators of MyoD and skeletal muscle differentiation |
| Q34278363 | The SWI/SNF subunit/tumor suppressor BAF47/INI1 is essential in cell cycle arrest upon skeletal muscle terminal differentiation |
| Q36909803 | The Scaffold attachment factor b1 (Safb1) regulates myogenic differentiation by facilitating the transition of myogenic gene chromatin from a repressed to an activated state |
| Q39271742 | The core binding factor CBF negatively regulates skeletal muscle terminal differentiation |
| Q34609239 | The expression of myogenic microRNAs indirectly requires protein arginine methyltransferase (Prmt)5 but directly requires Prmt4. |
| Q41855667 | The p38 MAPK family, a pushmi-pullyu of skeletal muscle differentiation |
| Q42834494 | The protein arginine methyltransferase Prmt5 is required for myogenesis because it facilitates ATP-dependent chromatin remodeling |
| Q51795485 | The putative SWI/SNF complex subunit BRAHMA activates flower homeotic genes in Arabidopsis thaliana. |
| Q35512942 | The role of BAF (mSWI/SNF) complexes in mammalian neural development |
| Q36948978 | Tissue-specific splicing of a ubiquitously expressed transcription factor is essential for muscle differentiation |
| Q35229139 | Unbiased chromatin accessibility profiling by RED-seq uncovers unique features of nucleosome variants in vivo |
| Q34124906 | p38 MAPK signaling regulates recruitment of Ash2L-containing methyltransferase complexes to specific genes during differentiation |