| scholarly article | Q13442814 |
| P2093 | author name string | G Cossu | |
| S Alonso | |||
| R Kelly | |||
| M Buckingham | |||
| S Tajbakhsh | |||
| P2860 | cites work | Human myocyte-specific enhancer factor 2 comprises a group of tissue-restricted MADS box transcription factors | Q24294604 |
| The myosin alkali light chain proteins and their genes | Q24300135 | ||
| Positional specification of ventricular myosin light chain 2 expression in the primitive murine heart tube | Q28269837 | ||
| Myosin light chain-2 luciferase transgenic mice reveal distinct regulatory programs for cardiac and skeletal muscle-specific expression of a single contractile protein gene | Q28586592 | ||
| A short amino acid sequence able to specify nuclear location | Q29547781 | ||
| The MyoD family and myogenesis: redundancy, networks, and thresholds | Q29618503 | ||
| Simplified mammalian DNA isolation procedure | Q29618648 | ||
| Nerve-dependent accumulation of myosin light chain 3 in developing limb musculature. | Q30462998 | ||
| Use of a recombinant retrovirus to study post-implantation cell lineage in mouse embryos | Q33880924 | ||
| Myosin light chain enhancer activates muscle-specific, developmentally regulated gene expression in transgenic mice. | Q34310902 | ||
| Myosin isoforms in mammalian skeletal muscle | Q34328366 | ||
| Identification of the functional promoter regions in the human gene encoding the myosin alkali light chains MLC1 and MLC3 of fast skeletal muscle | Q34543364 | ||
| Making muscle in mammals | Q35230424 | ||
| Compartmentalized expression of the alpha- and gamma-subunits of the acetylcholine receptor in recently fused myofibers | Q70681036 | ||
| Relationships between alkali light-chain complement and myosin heavy-chain isoforms in single fast-twitch fibers of rat and rabbit | Q70754226 | ||
| Coexistence of cardiac-type and fast skeletal-type myosin light chains in embryonic chicken cardiac muscle | Q71104375 | ||
| The expression of the regulatory myosin light chain 2 gene during mouse embryogenesis | Q72163736 | ||
| Identification, distribution, and myosin subunit composition of type IIX fibers in mouse muscles | Q72740826 | ||
| Desmin sequence elements regulating skeletal muscle-specific expression in transgenic mice | Q72815415 | ||
| Functional activity of the two promoters of the myosin alkali light chain gene in primary muscle cell cultures: comparison with other muscle gene promoters and other culture systems | Q35997251 | ||
| Distribution and properties of myosin isozymes in developing avian and mammalian skeletal muscle fibers | Q36205845 | ||
| Aberrant regulation of MyoD1 contributes to the partially defective myogenic phenotype of BC3H1 cells | Q36223014 | ||
| The expression of myosin genes in developing skeletal muscle in the mouse embryo | Q36223588 | ||
| Developmental regulation of myosin gene expression in mouse cardiac muscle | Q36224282 | ||
| The same myosin alkali light chain gene is expressed in adult cardiac atria and in fetal skeletal muscle | Q36485720 | ||
| Fiber type- and position-dependent expression of a myosin light chain-CAT transgene detected with a novel histochemical stain for CAT | Q36530391 | ||
| Neural regulation of muscle acetylcholine receptor epsilon- and alpha-subunit gene promoters in transgenic mice | Q36534824 | ||
| Novel muscle-specific enhancer sequences upstream of the cardiac actin gene | Q36653449 | ||
| cis-acting sequences of the rat troponin I slow gene confer tissue- and development-specific transcription in cultured muscle cells as well as fiber type specificity in transgenic mice | Q36825922 | ||
| Developmentally regulated expression of a truncated myosin light-chain 1F/3F gene | Q36923168 | ||
| Myosin light-chain 1 and 3 gene has two structurally distinct and differentially regulated promoters evolving at different rates | Q36951591 | ||
| Extra-atrial expression of the gene for atrial natriuretic factor. | Q37398504 | ||
| Paired MyoD-binding sites regulate myosin light chain gene expression | Q37399134 | ||
| Rostrocaudal gradient of transgene expression in adult skeletal muscle | Q37542058 | ||
| Cellular and molecular diversities of mammalian skeletal muscle fibers | Q37865994 | ||
| Muscle cell differentiation | Q38782844 | ||
| Developmental changes in chicken skeletal myosin isoenzymes | Q39877119 | ||
| A highly conserved enhancer downstream of the human MLC1/3 locus is a target for multiple myogenic determination factors | Q40525469 | ||
| Synaptic structure and development: the neuromuscular junction | Q40873412 | ||
| Transcriptional regulation of multigene loci: multilevel control | Q40919870 | ||
| Detection of messenger RNA by in situ hybridization. | Q41587073 | ||
| An axial gradient of transgene methylation in murine skeletal muscle: genomic imprint of rostrocaudal position | Q41592980 | ||
| Reprogramming of myosin light chain expression in muscle heterokaryons | Q41686495 | ||
| A muscle-specific enhancer is located at the 3' end of the myosin light-chain 1/3 gene locus | Q44531497 | ||
| Mammalian muscle cells bear a cell-autonomous, heritable memory of their rostrocaudal position | Q44856376 | ||
| Fast skeletal muscle myosin light chains 1 and 3 are produced from a single gene by a combined process of differential RNA transcription and splicing | Q48386074 | ||
| A single locus in the mouse encodes both myosin light chains 1 and 3, a second locus corresponds to a related pseudogene | Q48386606 | ||
| Alternative transcription and two modes of splicing results in two myosin light chains from one gene | Q48391887 | ||
| A population of myogenic cells derived from the mouse neural tube. | Q52213809 | ||
| Complex fiber-type-specific expression of fast skeletal muscle troponin I gene constructs in transgenic mice. | Q52222137 | ||
| Emergence of the mature myosin phenotype in the rat diaphragm muscle. | Q52237638 | ||
| Myosin subunit types in skeletal and cardiac tissues and their developmental distribution. | Q52288011 | ||
| Murine PGK-1 promoter drives widespread but not uniform expression in transgenic mice. | Q54629479 | ||
| Skeletal muscle myosin light chains are essential for physiological speeds of shortening. | Q54650986 | ||
| Unloaded shortening velocity and myosin heavy chain and alkali light chain isoform composition in rat skeletal muscle fibres | Q57973358 | ||
| Regional Differences in Troponin I Isoform Switching during Rat Heart Development | Q57973371 | ||
| A transgene target for positional regulators marks early rostrocaudal specification of myogenic lineages | Q62397554 | ||
| Actin and myosin genes are transcriptionally regulated during mouse skeletal muscle development | Q67721269 | ||
| Fiber-type proportions in mammalian soleus muscle during postnatal development | Q68096409 | ||
| Myosin light chain gene expression in developing and denervated fetal muscle in the mouse | Q69317984 | ||
| The myosin alkali light chains of mouse ventricular and slow skeletal muscle are indistinguishable and are encoded by the same gene | Q69802990 | ||
| Isometric contractions of motor units and immunohistochemistry of mouse soleus muscle | Q70255276 | ||
| Transcripts of alpha-cardiac and alpha-skeletal actins are early markers for myogenesis in the mouse embryo | Q70266090 | ||
| P433 | issue | 2 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 383-396 | |
| P577 | publication date | 1995-04-01 | |
| P1433 | published in | Journal of Cell Biology | Q1524550 |
| P1476 | title | Myosin light chain 3F regulatory sequences confer regionalized cardiac and skeletal muscle expression in transgenic mice | |
| P478 | volume | 129 |
| Q48048927 | A 900 bp genomic region from the mouse dystrophin promoter directs lacZ reporter expression only to the right heart of transgenic mice |
| Q36565168 | A combination of MEF3 and NFI proteins activates transcription in a subset of fast-twitch muscles. |
| Q36473287 | A contemporary atlas of the mouse diaphragm: myogenicity, vascularity, and the Pax3 connection. |
| Q35018054 | A novel genetic hierarchy functions during hypaxial myogenesis: Pax3 directly activates Myf5 in muscle progenitor cells in the limb |
| Q42665458 | A triad of serum response factor and the GATA and NK families governs the transcription of smooth and cardiac muscle genes |
| Q33598506 | Absence of CD34 on murine skeletal muscle satellite cells marks a reversible state of activation during acute injury |
| Q42451733 | Alteration in myosatellite cell commitment with muscle maturation |
| Q34627330 | An evolutionarily acquired genotoxic response discriminates MyoD from Myf5, and differentially regulates hypaxial and epaxial myogenesis |
| Q43949536 | An improved method for beta-galactosidase activity detection on muscle tissue. A light and electron microscopic study |
| Q28591703 | Analysis of Mlc-lacZ Met mutants highlights the essential function of Met for migratory precursors of hypaxial muscles and reveals a role for Met in the development of hyoid arch-derived facial muscles |
| Q43624803 | Atrial chamber-specific expression of the slow myosin heavy chain 3 gene in the embryonic heart |
| Q33943795 | Cardiomyocytes induce endothelial cells to trans-differentiate into cardiac muscle: implications for myocardium regeneration |
| Q28592640 | Characterization of a cardiac-specific enhancer, which directs {alpha}-cardiac actin gene transcription in the mouse adult heart |
| Q35062652 | Clonal analysis reveals a common origin between nonsomite-derived neck muscles and heart myocardium |
| Q36559531 | Common core sequences are found in skeletal muscle slow- and fast-fiber-type-specific regulatory elements |
| Q27322323 | Deregulation of the protocadherin gene FAT1 alters muscle shapes: implications for the pathogenesis of facioscapulohumeral dystrophy |
| Q37351695 | Differentiation rather than aging of muscle stem cells abolishes their telomerase activity |
| Q28504737 | Distinct gene expression patterns in skeletal and cardiac muscle are dependent on common regulatory sequences in the MLC1/3 locus |
| Q36561039 | Distinct regulatory elements control muscle-specific, fiber-type-selective, and axially graded expression of a myosin light-chain gene in transgenic mice |
| Q42527040 | Divergence in species and regulatory role of beta -myosin heavy chain proximal promoter muscle-CAT elements |
| Q33533474 | Dynamics of muscle fibre growth during postnatal mouse development |
| Q27312712 | Ectopic Expression of Retrotransposon-Derived PEG11/RTL1 Contributes to the Callipyge Muscular Hypertrophy |
| Q36580613 | Emerging vectors and targeting methods for nonviral gene therapy. |
| Q33928516 | Expression of CD34 and Myf5 defines the majority of quiescent adult skeletal muscle satellite cells |
| Q36236547 | Expression of the SM22alpha promoter in transgenic mice provides evidence for distinct transcriptional regulatory programs in vascular and visceral smooth muscle cells |
| Q35023888 | Extraocular muscle satellite cells are high performance myo-engines retaining efficient regenerative capacity in dystrophin deficiency |
| Q28592591 | Eya1 and Eya2 proteins are required for hypaxial somitic myogenesis in the mouse embryo |
| Q36556667 | Fast-muscle-specific DNA-protein interactions occurring in vivo at the human aldolase A M promoter are necessary for correct promoter activity in transgenic mice. |
| Q28593038 | Fgf10 dosage is critical for the amplification of epithelial cell progenitors and for the formation of multiple mesenchymal lineages during lung development |
| Q51542190 | Fibre type-specific and nerve-dependent regulation of myosin light chain 1 slow promoter in regenerating muscle. |
| Q28594696 | Fibroblast growth factor 10 is required for survival and proliferation but not differentiation of intestinal epithelial progenitor cells during murine colon development |
| Q36116815 | Follistatin induction by nitric oxide through cyclic GMP: a tightly regulated signaling pathway that controls myoblast fusion |
| Q33534486 | Functional conservation between rodents and chicken of regulatory sequences driving skeletal muscle gene expression in transgenic chickens |
| Q37625989 | Fusion of bone marrow-derived stem cells with striated muscle may not be sufficient to activate muscle genes |
| Q40698740 | GDNF acts through PEA3 to regulate cell body positioning and muscle innervation of specific motor neuron pools |
| Q36459361 | Gene and genon concept: coding versus regulation. A conceptual and information-theoretic analysis of genetic storage and expression in the light of modern molecular biology |
| Q34563335 | Grafting of a single donor myofibre promotes hypertrophy in dystrophic mouse muscle |
| Q37381930 | High efficiency myogenic conversion of human fibroblasts by adenoviral vector-mediated MyoD gene transfer. An alternative strategy for ex vivo gene therapy of primary myopathies |
| Q37734542 | HuR and miR-1192 regulate myogenesis by modulating the translation of HMGB1 mRNA |
| Q34158865 | Human satellite cells: identification on human muscle fibres |
| Q22003970 | Identification of a novel slow-muscle-fiber enhancer binding protein, MusTRD1 |
| Q33610186 | Identification of novel transcripts from the porcine MYL1 gene and initial characterization of its promoters |
| Q49142991 | Inducible regulation of human brain natriuretic peptide promoter in transgenic mice |
| Q22003948 | Inhibition of myogenesis by transforming growth factor beta is density-dependent and related to the translocation of transcription factor MEF2 to the cytoplasm |
| Q51970369 | Integration of embryonic and fetal skeletal myogenic programs at the myosin light chain 1f/3f locus. |
| Q59120502 | Intrinsic phenotypic diversity of embryonic and fetal myoblasts is revealed by genome-wide gene expression analysis on purified cells. |
| Q33948987 | Irx4 forms an inhibitory complex with the vitamin D and retinoic X receptors to regulate cardiac chamber-specific slow MyHC3 expression. |
| Q42506319 | Isolation, Culture, and Immunostaining of Skeletal Muscle Myofibers from Wildtype and Nestin-GFP Mice as a Means to Analyze Satellite Cell |
| Q80818428 | Knowing in your heart what's right |
| Q35239339 | Loss of Wnt5a disrupts second heart field cell deployment and may contribute to OFT malformations in DiGeorge syndrome |
| Q40705738 | MLC3F transgene expression in iv mutant mice reveals the importance of left-right signalling pathways for the acquisition of left and right atrial but not ventricular compartment identity |
| Q34548463 | Magnetic Resonance Microscopy (MRM) of Single Mammalian Myofibers and Myonuclei |
| Q37331561 | Mature adult dystrophic mouse muscle environment does not impede efficient engrafted satellite cell regeneration and self-renewal. |
| Q41983710 | Mesenchymal stem cells are recruited to striated muscle by NFAT/IL-4-mediated cell fusion |
| Q33918696 | Modular regulation of the MLC1F/3F gene and striated muscle diversity |
| Q40735023 | Mouse dystrophin enhancer preferentially targets lacZ expression in skeletal and cardiac muscle. |
| Q42465353 | Muscle satellite cells adopt divergent fates: a mechanism for self-renewal? |
| Q38508660 | Muscle satellite cells are a functionally heterogeneous population in both somite-derived and branchiomeric muscles. |
| Q34009256 | Muscle-derived hematopoietic stem cells are hematopoietic in origin |
| Q41649834 | Myogenesis in the mouse embryo. |
| Q36444539 | Myogenic reprogramming of retina-derived cells following their spontaneous fusion with myotubes |
| Q33947773 | Myogenic stem cells for the therapy of primary myopathies: wishful thinking or therapeutic perspective? |
| Q34807060 | Myogenic stem cells from the bone marrow: a therapeutic alternative for muscular dystrophy? |
| Q42020060 | Noggin recruits mesoderm progenitors from the dorsal aorta to a skeletal myogenic fate |
| Q35061706 | Non-viral gene delivery in skeletal muscle: a protein factory |
| Q45878193 | Nonmuscle stem cells fail to significantly contribute to regeneration of normal muscle |
| Q36018705 | Persistence in muscle of an adenoviral vector that lacks all viral genes |
| Q39852941 | Reduced mobility of fibroblast growth factor (FGF)-deficient myoblasts might contribute to dystrophic changes in the musculature of FGF2/FGF6/mdx triple-mutant mice |
| Q40688494 | Regulation of C2C12 myogenic terminal differentiation by MKK3/p38alpha pathway |
| Q28592248 | Regulation of cardiac mesodermal and neural crest development by the bHLH transcription factor, dHAND |
| Q28505919 | Regulation of vertebrate myotome development by the p38 MAP kinase-MEF2 signaling pathway |
| Q28589630 | Rescue of cardiac defects in id knockout embryos by injection of embryonic stem cells |
| Q32104815 | Role of the nerve in determining fetal skeletal muscle phenotype |
| Q58734749 | Satellite cells delivered in their niche efficiently generate functional myotubes in three-dimensional cell culture |
| Q35009253 | Satellite cells from dystrophic muscle retain regenerative capacity |
| Q27339607 | Sepsis induces long-term metabolic and mitochondrial muscle stem cell dysfunction amenable by mesenchymal stem cell therapy. |
| Q45870253 | Single hematopoietic stem cells generate skeletal muscle through myeloid intermediates |
| Q24563940 | Six1 and Eya1 expression can reprogram adult muscle from the slow-twitch phenotype into the fast-twitch phenotype |
| Q79379076 | Skeletal muscle stem cells express anti-apoptotic ErbB receptors during activation from quiescence |
| Q59120569 | Skeletal myogenic potential of human and mouse neural stem cells |
| Q40624839 | Skeletal myogenic progenitors in the endothelium of lung and yolk sac. |
| Q41985321 | Skeletal myogenic progenitors originating from embryonic dorsal aorta coexpress endothelial and myogenic markers and contribute to postnatal muscle growth and regeneration |
| Q34466460 | Somatic stem cell plasticity: current evidence and emerging concepts. |
| Q36240934 | Sonic hedgehog acts cell-autonomously on muscle precursor cells to generate limb muscle diversity |
| Q52115307 | Species-specific differences of myosin content in the developing cardiac chambers of fish, birds, and mammals. |
| Q50522388 | Stable, conditional, and muscle-fiber-specific expression of electroporated transgenes in chick limb muscle cells. |
| Q34065460 | Stage-specific modulation of skeletal myogenesis by inhibitors of nuclear deacetylases. |
| Q36017254 | Stem cell-mediated muscle regeneration is enhanced by local isoform of insulin-like growth factor 1. |
| Q52170886 | Suppression of atrial myosin gene expression occurs independently in the left and right ventricles of the developing mouse heart. |
| Q43819573 | Sympathetic modulation of renal blood flow by rilmenidine and captopril: central vs. peripheral effects |
| Q51708460 | Terminal end bud maintenance in mammary gland is dependent upon FGFR2b signaling. |
| Q77153201 | The arterial pole of the mouse heart forms from Fgf10-expressing cells in pharyngeal mesoderm |
| Q36561845 | The atrial natriuretic factor promoter is a downstream target for Nkx-2.5 in the myocardium |
| Q33817722 | The birth of muscle progenitor cells in the mouse: spatiotemporal considerations |
| Q52192232 | The chicken GATA-6 locus contains multiple control regions that confer distinct patterns of heart region-specific expression in transgenic mouse embryos. |
| Q33788099 | The depletion of skeletal muscle satellite cells with age is concomitant with reduced capacity of single progenitors to produce reserve progeny |
| Q52185125 | The formation and maturation of skeletal muscle in the mouse: the myosin MLC1F/3F gene as a molecular model. |
| Q41415584 | The genetics of left-right development and heterotaxia |
| Q40068711 | The homeobox gene Arx is a novel positive regulator of embryonic myogenesis. |
| Q35141295 | The isolated muscle fibre as a model of disuse atrophy: characterization using PhAct, a method to quantify f-actin. |
| Q43571933 | The lacZ gene under the control of the 7 kb of human dystrophin muscle specific promoter is expressed in cardiac muscle but not in adult skeletal muscle in transgenic mice |
| Q37978773 | The origin and fate of muscle satellite cells. |
| Q35767940 | The skeletal muscle satellite cell: still young and fascinating at 50 |
| Q33938529 | The transcriptional activator PAX3-FKHR rescues the defects of Pax3 mutant mice but induces a myogenic gain-of-function phenotype with ligand-independent activation of Met signaling in vivo. |
| Q35783030 | Tissue-Specific Gain of RTK Signalling Uncovers Selective Cell Vulnerability during Embryogenesis |
| Q55094954 | Tissue-specific activities of the Fat1 cadherin cooperate to control neuromuscular morphogenesis. |
| Q95851047 | Transgenesis and web resources in quail |
| Q33654959 | Transgenic mouse models of muscle aging |
| Q44328134 | Upstream and intronic regulatory sequences interact in the activation of the glutamine synthetase promoter |
| Q36236418 | VAMP/synaptobrevin isoforms 1 and 2 are widely and differentially expressed in nonneuronal tissues |
| Q36263590 | Vascular bed-specific expression of an endothelial cell gene is programmed by the tissue microenvironment |
| Q41100052 | Vertebrate heart development |
| Q33656159 | What does chronic electrical stimulation teach us about muscle plasticity? |
| Q52123673 | [Regulation of myocardial gene expression during heart development]. |
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