scholarly article | Q13442814 |
P356 | DOI | 10.1126/SCIENCE.1087573 |
P698 | PubMed publication ID | 14645852 |
P50 | author | Gayle Smythe | Q73547778 |
Thomas A. Rando | Q79331501 | ||
P2093 | author name string | Irina M Conboy | |
Michael J Conboy | |||
P433 | issue | 5650 | |
P407 | language of work or name | English | Q1860 |
P1104 | number of pages | 3 | |
P304 | page(s) | 1575-1577 | |
P577 | publication date | 2003-11-01 | |
P1433 | published in | Science | Q192864 |
P1476 | title | Notch-mediated restoration of regenerative potential to aged muscle | |
P478 | volume | 302 |
Q37065378 | 'From death, lead me to immortality' - mantra of ageing skeletal muscle |
Q47675142 | * The Impact of Age on Skeletal Muscle Progenitor Cell Survival and Fate After Injury |
Q33687916 | 3D hydrogel environment rejuvenates aged pericytes for skeletal muscle tissue engineering |
Q91894666 | A Three-Dimensional Culture Model of Reversibly Quiescent Myogenic Cells |
Q30582498 | A canonical to non-canonical Wnt signalling switch in haematopoietic stem-cell ageing. |
Q42846094 | A cell-autonomous defect in skeletal muscle satellite cells expressing low levels of survival of motor neuron protein. |
Q44829950 | A cellular memory mechanism aids overload hypertrophy in muscle long after an episodic exposure to anabolic steroids |
Q33571203 | A home away from home: challenges and opportunities in engineering in vitro muscle satellite cell niches |
Q36294585 | A murine model of volumetric muscle loss and a regenerative medicine approach for tissue replacement |
Q42512299 | A tale of two niches: differential functions for VCAM-1 in satellite cells under basal and injured conditions |
Q42707203 | Absence of CCR2 results in an inflammaging environment in young mice with age-independent impairments in muscle regeneration |
Q34562223 | Activating Notch signaling post-SCI modulates angiogenesis in penumbral vascular beds but does not improve hindlimb locomotor recovery |
Q41858522 | Adipogenic fate commitment of muscle-derived progenitor cells: isolation, culture, and differentiation. |
Q40564636 | Adipose tissue biology in 2014: Advances in our understanding of adipose tissue homeostasis |
Q26822437 | Advancements in stem cells treatment of skeletal muscle wasting |
Q36288658 | Age dependent increase in the levels of osteopontin inhibits skeletal muscle regeneration |
Q40027450 | Age-associated NF-κB signaling in myofibers alters the satellite cell niche and re-strains muscle stem cell function |
Q38106786 | Age-associated changes in the ecological niche: implications for mesenchymal stem cell aging |
Q41775980 | Age-associated inflammation inhibits epidermal stem cell function |
Q36977666 | Age-dependent FOXO regulation of p27Kip1 expression via a conserved binding motif in rat muscle precursor cells |
Q37034374 | Age-dependent alteration in muscle regeneration: the critical role of tissue niche |
Q35088393 | Age-dependent effect of myostatin blockade on disease severity in a murine model of limb-girdle muscular dystrophy |
Q35375871 | Age-related Notch-4 quiescence is associated with altered wall remodeling during vein graft adaptation |
Q59125244 | Age-related declines in α-Klotho drive progenitor cell mitochondrial dysfunction and impaired muscle regeneration |
Q47131388 | Age-related gene expression in luminal epithelial cells is driven by a microenvironment made from myoepithelial cells |
Q35055585 | Age-related impairment of T cell-induced skeletal muscle precursor cell function |
Q36681378 | Age-related intrinsic changes in human bone-marrow-derived mesenchymal stem cells and their differentiation to osteoblasts |
Q35096716 | Age-specific functional epigenetic changes in p21 and p16 in injury-activated satellite cells |
Q37024979 | Aged skeletal muscle retains the ability to fully regenerate functional architecture |
Q47609609 | Ageing and the mystery at Arles |
Q45826802 | Ageing is associated with diminished muscle re-growth and myogenic precursor cell expansion early after immobility-induced atrophy in human skeletal muscle. |
Q28565133 | Ageing prolongs inflammatory marker expression in regenerating rat skeletal muscles after injury |
Q37183949 | Aging and disease as modifiers of efficacy of cell therapy |
Q41434529 | Aging and sarcopenia associate with specific interactions between gut microbes, serum biomarkers and host physiology in rats. |
Q90538157 | Aging induces aberrant state transition kinetics in murine muscle stem cells |
Q37161623 | Aging of signal transduction pathways, and pathology |
Q38237265 | Aging of the hematopoietic stem cells niche |
Q42252666 | Aging of the skeletal muscle extracellular matrix drives a stem cell fibrogenic conversion. |
Q37083890 | Altered Ca2+ sparks in aging skeletal and cardiac muscle |
Q30587469 | Amygdala-dependent fear memory consolidation via miR-34a and Notch signaling |
Q46032685 | An Intronic Enhancer Element Regulates Angiotensin II Type 2 Receptor Expression during Satellite Cell Differentiation, and Its Activity Is Suppressed in Congestive Heart Failure. |
Q50933925 | An alternate protocol for establishment of primary caprine fetal myoblast cell culture: an in vitro model for muscle growth study. |
Q35180702 | An overview of notch signaling in adult tissue renewal and maintenance |
Q41409749 | Analysis of αSMA-labeled progenitor cell commitment identifies notch signaling as an important pathway in fracture healing |
Q34234465 | Androgens and skeletal muscle: cellular and molecular action mechanisms underlying the anabolic actions. |
Q37099711 | Angiotensin II inhibits satellite cell proliferation and prevents skeletal muscle regeneration |
Q34248966 | Angiotensin type 2 receptor signaling in satellite cells potentiates skeletal muscle regeneration |
Q80434452 | Antagonism of myostatin enhances muscle regeneration during sarcopenia |
Q52695298 | Antagonistic function of Lmd and Zfh1 fine tunes cell fate decisions in the Twi and Tin positive mesoderm of Drosophila melanogaster. |
Q41693760 | Application of bio-orthogonal proteome labeling to cell transplantation and heterochronic parabiosis. |
Q34216980 | Are human and mouse satellite cells really the same? |
Q39783844 | Arsenic inhibits stem cell differentiation by altering the interplay between the Wnt3a and Notch signaling pathways |
Q24320093 | Association of common variants in the human eyes shut ortholog (EYS) with statin-induced myopathy: evidence for additional functions of EYS |
Q36145408 | Attenuation of p38α MAPK stress response signaling delays the in vivo aging of skeletal muscle myofibers and progenitor cells |
Q84779715 | Autografting Satellite Cells to Repair Damaged Muscle Induced by Repeated Compression: An Animal Model |
Q64246070 | Autophagy as a Therapeutic Target to Enhance Aged Muscle Regeneration |
Q37189212 | Basic biology of skeletal aging: role of stress response pathways |
Q59340677 | Bioinformatics analysis of differentially expressed genes in rotator cuff tear patients using microarray data |
Q26863489 | Biomaterial-based delivery for skeletal muscle repair |
Q39346557 | Biomaterials for skeletal muscle tissue engineering |
Q34137578 | Biophysics and dynamics of natural and engineered stem cell microenvironments |
Q92057341 | Blood autophagy defect causes accelerated non-hematopoietic organ aging |
Q36968228 | Bone and skeletal muscle: neighbors with close ties |
Q38359416 | Bone is Not Alone: the Effects of Skeletal Muscle Dysfunction in Chronic Kidney Disease |
Q42520819 | CD90-positive cells, an additional cell population, produce laminin alpha2 upon transplantation to dy(3k)/dy(3k) mice. |
Q38761095 | Calcium signaling in skeletal muscle development, maintenance and regeneration |
Q33753610 | Cdc42 and aging of hematopoietic stem cells |
Q29619469 | Cell type of origin influences the molecular and functional properties of mouse induced pluripotent stem cells |
Q88955687 | Cellular and epigenetic drivers of stem cell ageing |
Q35725714 | Cellular and molecular mechanisms of negligible senescence: insight from the sea urchin |
Q37701307 | Cellular mechanisms and local progenitor activation to regulate skeletal muscle mass. |
Q37696180 | Cellular mechanisms of somatic stem cell aging |
Q41887477 | Cellular players in skeletal muscle regeneration |
Q24629853 | Cellular senescence and tumor suppressor gene p16 |
Q58713722 | Centronuclear myopathies under attack: A plethora of therapeutic targets |
Q64230369 | Changes in Redox Signaling in the Skeletal Muscle with Aging |
Q26778013 | Changes in Regenerative Capacity through Lifespan |
Q37202531 | Characterization of mammary epithelial stem/progenitor cells and their changes with aging in common marmosets |
Q34964840 | Coaxing stem cells for skeletal muscle repair |
Q93354244 | Combination of Coenzyme Q10 Intake and Moderate Physical Activity Counteracts Mitochondrial Dysfunctions in a SAMP8 Mouse Model |
Q28547870 | Combinations of Kinase Inhibitors Protecting Myoblasts against Hypoxia |
Q34326261 | Comparative angiogenic activities of induced pluripotent stem cells derived from young and old mice |
Q42196621 | Constitutive Notch activation upregulates Pax7 and promotes the self-renewal of skeletal muscle satellite cells |
Q37019582 | Control of the adaptive response of the heart to stress via the Notch1 receptor pathway. |
Q41813617 | Correlations between microRNAs and their target genes in skeletal myoblasts cell therapy for myocardial infarction |
Q33761360 | Crystallin-αB regulates skeletal muscle homeostasis via modulation of argonaute2 activity |
Q92502907 | Deiodinases and their intricate role in thyroid hormone homeostasis |
Q42987220 | Deletion of Pofut1 in Mouse Skeletal Myofibers Induces Muscle Aging-Related Phenotypes in cis and in trans |
Q56911556 | Delta-like 1 protein, vitamin D binding protein and fetuin for detection of Mycobacterium tuberculosis meningitis |
Q42291306 | Deltex2 represses MyoD expression and inhibits myogenic differentiation by acting as a negative regulator of Jmjd1c |
Q36893184 | Diabetic mice exhibited a peculiar alteration in body composition with exaggerated ectopic fat deposition after muscle injury due to anomalous cell differentiation |
Q33675332 | Differential genomic responses in old vs. young humans despite similar levels of modest muscle damage after resistance loading |
Q37351695 | Differentiation rather than aging of muscle stem cells abolishes their telomerase activity |
Q36812068 | Disruption of nuclear factor (erythroid-derived-2)-like 2 antioxidant signaling: a mechanism for impaired activation of stem cells and delayed regeneration of skeletal muscle |
Q89964419 | Divergent Roles of Inflammation in Skeletal Muscle Recovery From Injury |
Q33760580 | Dlk1 is necessary for proper skeletal muscle development and regeneration |
Q28389517 | Donor satellite cell engraftment is significantly augmented when the host niche is preserved and endogenous satellite cells are incapacitated |
Q39032912 | Early gene expression changes in skeletal muscle from SOD1(G93A) amyotrophic lateral sclerosis animal model. |
Q35237414 | Early life nutrition modulates muscle stem cell number: implications for muscle mass and repair. |
Q36919044 | Effects of the activin A-myostatin-follistatin system on aging bone and muscle progenitor cells |
Q28743774 | Efficient generation of iPS cells from skeletal muscle stem cells |
Q35403399 | Electroacupuncture in the repair of spinal cord injury: inhibiting the Notch signaling pathway and promoting neural stem cell proliferation |
Q36764108 | Elevated SOCS3 and altered IL-6 signaling is associated with age-related human muscle stem cell dysfunction |
Q39740143 | Embryonic anti-aging niche |
Q35671770 | Emerging models and paradigms for stem cell ageing |
Q38857342 | Engineered matrices for skeletal muscle satellite cell engraftment and function |
Q97643882 | Eosinophils regulate adipose tissue inflammation and sustain physical and immunological fitness in old age |
Q37088443 | Epigenetic drugs in the treatment of skeletal muscle atrophy. |
Q26745718 | Epigenetic perturbations in aging stem cells |
Q37858414 | Epigenetic regulation of aging stem cells |
Q33633254 | Epigenetic stress responses induce muscle stem-cell ageing by Hoxa9 developmental signals |
Q96817958 | Exercise rejuvenates quiescent skeletal muscle stem cells in old mice through restoration of Cyclin D1 |
Q92477566 | Expansion of Luminal Progenitor Cells in the Aging Mouse and Human Prostate |
Q42473280 | Expansion of stem cells counteracts age-related mammary regression in compound Timp1/Timp3 null mice. |
Q37233128 | Expression of growth-related genes in young and older human skeletal muscle following an acute stimulation of protein synthesis |
Q35222114 | Expression of the Notch signaling pathway and effect on exocrine cell proliferation in adult rat pancreas |
Q38200095 | Extrinsic Regulation of Satellite Cell Function and Muscle Regeneration Capacity during Aging |
Q93023182 | Fibro-adipogenic progenitors of dystrophic mice are insensitive to NOTCH regulation of adipogenesis |
Q36765815 | Fibroblast growth factor 2-stimulated proliferation is lower in muscle precursor cells from old rats |
Q37138197 | Functional role of Notch signaling in the developing and postnatal heart |
Q33682829 | Gene expression following induction of regeneration in Drosophila wing imaginal discs. Expression profile of regenerating wing discs. |
Q36528300 | Genes and the ageing muscle: a review on genetic association studies |
Q35864925 | Genes invoked in the ovarian transition to menopause |
Q35163122 | Genome instability, cancer and aging |
Q39127452 | Geometric control of myogenic cell fate |
Q36357842 | HEXIM1 controls satellite cell expansion after injury to regulate skeletal muscle regeneration |
Q37691004 | Hemato-vascular origins of endothelial progenitor cells? |
Q35693118 | Hesr1 and Hesr3 are essential to generate undifferentiated quiescent satellite cells and to maintain satellite cell numbers. |
Q36059679 | Heterochronic parabiosis for the study of the effects of aging on stem cells and their niches |
Q37789857 | Heterogeneity in the muscle satellite cell population |
Q36446142 | High glucose induces adipogenic differentiation of muscle-derived stem cells |
Q33282298 | High incidence of non-random template strand segregation and asymmetric fate determination in dividing stem cells and their progeny |
Q36879972 | Highly efficient, functional engraftment of skeletal muscle stem cells in dystrophic muscles |
Q41919865 | Host tissue response in stem cell therapy |
Q33567866 | Hyper-activation of Notch3 amplifies the proliferative potential of rhabdomyosarcoma cells. |
Q35475008 | Identification of microRNAs linked to regulators of muscle protein synthesis and regeneration in young and old skeletal muscle |
Q81510713 | Identification of novel pathway regulation during myogenic differentiation |
Q37574383 | Identifying and enumerating neural stem cells: application to aging and cancer |
Q34786450 | Imbalance between pSmad3 and Notch induces CDK inhibitors in old muscle stem cells. |
Q28308125 | Impact of genomic damage and ageing on stem cell function |
Q57025472 | Impaired Notch Signaling Leads to a Decrease in p53 Activity and Mitotic Catastrophe in Aged Muscle Stem Cells |
Q37042189 | Impaired regeneration: A role for the muscle microenvironment in cancer cachexia |
Q42793119 | Improvement of skeletal muscle performance in ageing by the metabolic modulator Trimetazidine |
Q62661527 | In vivo GDF3 administration abrogates aging related muscle regeneration delay following acute sterile injury |
Q28389659 | In vivo Monitoring of Transcriptional Dynamics After Lower-Limb Muscle Injury Enables Quantitative Classification of Healing |
Q41853105 | In vivo imaging of tumor-propagating cells, regional tumor heterogeneity, and dynamic cell movements in embryonal rhabdomyosarcoma |
Q42419013 | Increased Adipocyte Area in Injured Muscle With Aging and Impaired Remodeling in Female Mice. |
Q35752238 | Increased Stiffness in Aged Skeletal Muscle Impairs Muscle Progenitor Cell Proliferative Activity |
Q34317812 | Increased expression of BubR1 protects against aneuploidy and cancer and extends healthy lifespan. |
Q29615155 | Increasing p16INK4a expression decreases forebrain progenitors and neurogenesis during ageing |
Q52579566 | Induction of muscle stem cell quiescence by the secreted niche factor Oncostatin M. |
Q57061866 | Inflammation-associated miR-155 activates differentiation of muscular satellite cells |
Q52571235 | Influence of physical exercise on microRNAs in skeletal muscle regeneration, aging and diseases. |
Q34315282 | Inhibition of JAK-STAT signaling stimulates adult satellite cell function. |
Q30427044 | Inhibition of Notch3 signalling induces rhabdomyosarcoma cell differentiation promoting p38 phosphorylation and p21(Cip1) expression and hampers tumour cell growth in vitro and in vivo. |
Q39947147 | Inhibition of myogenesis by Notch: evidence for multiple pathways |
Q36976407 | Inhibition of myostatin signaling through Notch activation following acute resistance exercise |
Q34285424 | Insulin-like 6 Is Induced by Muscle Injury and Functions as a Regenerative Factor |
Q48235527 | Integrated Analyses Reveal Overexpressed Notch1 Promoting Porcine Satellite Cells' Proliferation through Regulating the Cell Cycle. |
Q35907071 | Integrating physiological regulation with stem cell and tissue homeostasis |
Q36100758 | Interaction between bone and muscle in older persons with mobility limitations |
Q47148629 | Interleukin-1beta (IL-1β)-induced Notch ligand Jagged1 suppresses mitogenic action of IL-1β on human dystrophic myogenic cells |
Q90612446 | Interplay between Metabolites and the Epigenome in Regulating Embryonic and Adult Stem Cell Potency and Maintenance |
Q36034995 | Intervention Effect of Electroacupuncture Combined with EPCs Transplantation on the Mice in Aging Model |
Q52687524 | Intraoperative delivery of the Notch ligand Jagged-1 regenerates appendicular and craniofacial bone defects. |
Q36933565 | Intrinsic ability of adult stem cell in skeletal muscle: an effective and replenishable resource to the establishment of pluripotent stem cells |
Q28084614 | Intrinsic and extrinsic mechanisms regulating satellite cell function |
Q36961239 | Intrinsic changes and extrinsic influences of myogenic stem cell function during aging |
Q33605791 | Involvement of Notch1 signaling in neurogenesis in the subventricular zone of normal and ischemic rat brain in vivo |
Q42583863 | Irina Conboy: making the old feel young again. Interview by Kendall Powell |
Q50581803 | Ischaemia-reperfusion modulates inflammation and fibrosis of skeletal muscle after contusion injury. |
Q37663796 | Isolation of progenitors that exhibit myogenic/osteogenic bipotency in vitro by fluorescence-activated cell sorting from human fetal muscle |
Q36344905 | Jagged 1 Rescues the Duchenne Muscular Dystrophy Phenotype |
Q94050448 | Knocked down a Notch with age |
Q89550626 | Lack of PKCθ Promotes Regenerative Ability of Muscle Stem Cells in Chronic Muscle Injury |
Q82656708 | Lack of muscle recovery after immobilization in old rats does not result from a defect in normalization of the ubiquitin-proteasome and the caspase-dependent apoptotic pathways |
Q35127396 | Levels of soluble delta-like ligand 1 in the serum and cerebrospinal fluid of tuberculous meningitis patients |
Q42733180 | Lkb1 deletion upregulates Pax7 expression through activating Notch signaling pathway in myoblasts. |
Q93233959 | LncRNAs regulating stemness in aging |
Q37625904 | Long term human reconstitution and immune aging in NOD-Rag (-)-γ chain (-) mice |
Q28384001 | Long-term supplementation with a cystine-based antioxidant delays loss of muscle mass in aging |
Q28390560 | Long-term supplementation with resveratrol alleviates oxidative stress but does not attenuate sarcopenia in aged mice |
Q39587049 | Losing stem cells in the aged skeletal muscle niche |
Q34853001 | Loss of Notch1 disrupts the barrier repair in the corneal epithelium |
Q28273548 | Loss of a single allele for Ku80 leads to progenitor dysfunction and accelerated aging in skeletal muscle |
Q36117006 | Loss of stem cell regenerative capacity within aged niches |
Q91766490 | Loss of the adipokine lipocalin-2 impairs satellite cell activation and skeletal muscle regeneration |
Q33962042 | Managing sarcopenia and its related-fractures to improve quality of life in geriatric populations |
Q34973330 | Matrix metalloproteinase-9 inhibition improves proliferation and engraftment of myogenic cells in dystrophic muscle of mdx mice |
Q36103986 | Mechanisms of Cachexia in Chronic Disease States |
Q34217593 | Mechanisms of action of hESC-secreted proteins that enhance human and mouse myogenesis |
Q36810649 | Mechanisms that regulate stem cell aging and life span |
Q28511899 | Megf10 regulates the progression of the satellite cell myogenic program |
Q92238221 | Metabolic Reprogramming Promotes Myogenesis During Aging |
Q37315249 | Methods to promote Notch signaling at the biomaterial interface and evaluation in a rafted organ culture model |
Q47440082 | Methylmercury exposure causes a persistent inhibition of myogenin expression and C2C12 myoblast differentiation |
Q38609398 | MiR-34c represses muscle development by forming a regulatory loop with Notch1 |
Q28475539 | Mice deficient in ribosomal protein S6 phosphorylation suffer from muscle weakness that reflects a growth defect and energy deficit |
Q33735493 | Minireview: Mechano-growth factor: a putative product of IGF-I gene expression involved in tissue repair and regeneration |
Q36810964 | Mitophagy is required for mitochondrial biogenesis and myogenic differentiation of C2C12 myoblasts. |
Q33349016 | Models of accelerated sarcopenia: critical pieces for solving the puzzle of age-related muscle atrophy |
Q90334919 | Moderate Intensity Resistive Training Reduces Oxidative Stress and Improves Muscle Mass and Function in Older Individuals |
Q49540642 | Modulating the metabolism by trimetazidine enhances myoblast differentiation and promotes myogenesis in cachectic tumor-bearing c26 mice |
Q30494635 | Molecular aging and rejuvenation of human muscle stem cells |
Q37033031 | Molecular circuitry of stem cell fate in skeletal muscle regeneration, ageing and disease |
Q37138465 | Molecular mechanisms and signaling pathways of angiotensin II-induced muscle wasting: potential therapeutic targets for cardiac cachexia |
Q38111713 | Molecular mechanisms of muscle plasticity with exercise |
Q37256787 | Molecular regulation of stem cell quiescence. |
Q50803903 | Morphological, molecular and functional differences of adult bone marrow- and adipose-derived stem cells isolated from rats of different ages. |
Q36519891 | Mouse model of testosterone-induced muscle fiber hypertrophy: involvement of p38 mitogen-activated protein kinase-mediated Notch signaling |
Q36941459 | Murine models of atrophy, cachexia, and sarcopenia in skeletal muscle |
Q26752770 | Muscle Satellite Cells: Exploring the Basic Biology to Rule Them |
Q37270346 | Muscle contraction is required to maintain the pool of muscle progenitors via YAP and NOTCH during fetal myogenesis |
Q37002317 | Muscle development, regeneration and laminopathies: how lamins or lamina-associated proteins can contribute to muscle development, regeneration and disease. |
Q54548018 | Muscle diseases and aging. |
Q26770557 | Muscle memory and a new cellular model for muscle atrophy and hypertrophy |
Q33648473 | Muscle precursor cells isolated from aged rats exhibit an increased tumor necrosis factor- alpha response |
Q24815340 | Muscle regeneration in dystrophin-deficient mdx mice studied by gene expression profiling |
Q21131319 | Muscle satellite cell heterogeneity and self-renewal |
Q36802239 | Muscle satellite cells from GRMD dystrophic dogs are not phenotypically distinguishable from wild type satellite cells in ex vivo culture. |
Q30504731 | Muscle-derived stem/progenitor cell dysfunction limits healthspan and lifespan in a murine progeria model |
Q37364150 | Muscle-specific deletion of SOCS3 increases the early inflammatory response but does not affect regeneration after myotoxic injury |
Q88441149 | Myeloid Cell Responses to Contraction-induced Injury Differ in Muscles of Young and Old Mice |
Q91760092 | Myeloid cell-derived tumor necrosis factor-alpha promotes sarcopenia and regulates muscle cell fusion with aging muscle fibers |
Q28290654 | Myonuclei acquired by overload exercise precede hypertrophy and are not lost on detraining |
Q35836830 | Nestin-GFP reporter expression defines the quiescent state of skeletal muscle satellite cells |
Q28564350 | Neuropeptide y and neuropeptide y y5 receptor interaction restores impaired growth potential of aging bone marrow stromal cells |
Q84454172 | No change in skeletal muscle satellite cells in young and aging rat soleus muscle |
Q36663765 | Notch Signaling in Meibomian Gland Epithelial Cell Differentiation |
Q37785203 | Notch Signaling in the Regulation of Stem Cell Self-Renewal and Differentiation |
Q41464948 | Notch and TGFβ form a reciprocal positive regulatory loop that suppresses murine prostate basal stem/progenitor cell activity |
Q37766757 | Notch and Wnt signaling, physiological stimuli and postnatal myogenesis |
Q36603527 | Notch pathway activation targets AML-initiating cell homeostasis and differentiation |
Q30482922 | Notch signaling and Hes labeling in the normal and drug-damaged organ of Corti |
Q35946564 | Notch signaling and cardiac repair |
Q33813202 | Notch signaling and neurogenesis in normal and stroke brain. |
Q36903753 | Notch signaling at a glance |
Q38985595 | Notch signaling components are upregulated during both endochondral and intramembranous bone regeneration |
Q33784595 | Notch signaling genes: myogenic DNA hypomethylation and 5-hydroxymethylcytosine |
Q36317949 | Notch signaling in hematopoietic stem cells |
Q34480012 | Notch signaling in pediatric soft tissue sarcomas |
Q33784355 | Notch signaling regulates the lifespan of vascular endothelial cells via a p16-dependent pathway |
Q33649282 | Notch signalling in ischaemia-induced angiogenesis. |
Q37472316 | Notch-1 signalling is activated in brain arteriovenous malformations in humans |
Q37337308 | Notch1 signaling modulates neuronal progenitor activity in the subventricular zone in response to aging and focal ischemia |
Q85226461 | Notch3 Null Mutation in Mice Causes Muscle Hyperplasia by Repetitive Muscle Regeneration |
Q35829811 | Novel intriguing strategies attenuating to sarcopenia |
Q37319521 | Numb-deficient satellite cells have regeneration and proliferation defects. |
Q98465004 | Optimizing Skeletal Muscle Anabolic Response to Resistance Training in Aging |
Q58547334 | Orienting Muscle Stem Cells for Regeneration in Homeostasis, Aging, and Disease |
Q39052032 | Outside in: The matrix as a modifier of muscular dystrophy |
Q89771836 | Overview of Basic Mechanisms of Notch Signaling in Development and Disease |
Q35883021 | Oxytocin is an age-specific circulating hormone that is necessary for muscle maintenance and regeneration |
Q36030982 | PAX7+ satellite cells in young and older adults following resistance exercise |
Q34357219 | Pericytes at the intersection between tissue regeneration and pathology |
Q37729327 | Pharmacological inhibition of myostatin/TGF-β receptor/pSmad3 signaling rescues muscle regenerative responses in mouse model of type 1 diabetes |
Q38738830 | Phosphatidylserine directly and positively regulates fusion of myoblasts into myotubes |
Q50076158 | Plasticity of the Muscle Stem Cell Microenvironment |
Q92856883 | Podocan Promotes Differentiation of Bovine Skeletal Muscle Satellite Cells by Regulating the Wnt4-β-Catenin Signaling Pathway |
Q28509714 | Premature myogenic differentiation and depletion of progenitor cells cause severe muscle hypotrophy in Delta1 mutants |
Q37454742 | Presenilin-1 acts via Id1 to regulate the function of muscle satellite cells in a gamma-secretase-independent manner |
Q37845288 | Primer and interviews: The dynamic stem cell niche |
Q23916423 | Proapoptotic factor Bax is increased in satellite cells in the tibialis anterior muscles of old rats |
Q37078868 | Progressive impairment of muscle regeneration in muscleblind-like 3 isoform knockout mice. |
Q47626666 | Protein sequestration at the nuclear periphery as a potential regulatory mechanism in premature aging. |
Q90119945 | R3hdml regulates satellite cell proliferation and differentiation |
Q35670105 | RBP-J (Rbpsuh) is essential to maintain muscle progenitor cells and to generate satellite cells |
Q33949667 | RNA surveillance-an emerging role for RNA regulatory networks in aging |
Q47753820 | Randomized, four-arm, dose-response clinical trial to optimize resistance exercise training for older adults with age-related muscle atrophy. |
Q41170120 | Reciprocal interaction between TRAF6 and notch signaling regulates adult myofiber regeneration upon injury |
Q39059046 | Redox Control of Skeletal Muscle Regeneration. |
Q27318138 | Reduced Satellite Cell Numbers and Myogenic Capacity in Aging Can Be Alleviated by Endurance Exercise |
Q35746503 | Reflections on lineage potential of skeletal muscle satellite cells: do they sometimes go MAD? |
Q34737490 | Regenerative capacity of old muscle stem cells declines without significant accumulation of DNA damage |
Q24323315 | Regulation of Pax3 by proteasomal degradation of monoubiquitinated protein in skeletal muscle progenitors |
Q38878232 | Regulation of Skeletal Muscle by microRNAs. |
Q37746040 | Regulation of skeletal myogenesis by Notch |
Q95301635 | Regulation of vitamin D system in skeletal muscle and resident myogenic stem cell during development, maturation, and ageing |
Q39121185 | Rejuvenating stem cells to restore muscle regeneration in aging |
Q29615250 | Rejuvenation of aged progenitor cells by exposure to a young systemic environment |
Q92678605 | Rejuvenation of brain, liver and muscle by simultaneous pharmacological modulation of two signaling determinants, that change in opposite directions with age |
Q34404503 | Rejuvenation of the muscle stem cell population restores strength to injured aged muscles |
Q35222931 | Rejuvenation: an integrated approach to regenerative medicine |
Q42264762 | Relative roles of TGF-beta1 and Wnt in the systemic regulation and aging of satellite cell responses |
Q45987864 | Reversible Age-Related Phenotypes Induced during Larval Quiescence in C. elegans. |
Q89022021 | Role of genetics in the prediction of statin-associated muscle symptoms and optimization of statin use and adherence |
Q35335210 | Role of protein and amino acids in the pathophysiology and treatment of sarcopenia |
Q90230822 | Roles of mTOR Signaling in Tissue Regeneration |
Q36028202 | Sarcopenia and cachexia: the adaptations of negative regulators of skeletal muscle mass |
Q33706637 | Sarcopenia: etiology, clinical consequences, intervention, and assessment. |
Q36804785 | Sarcopenic obesity and endocrinal adaptation with age |
Q38542445 | Satellite Cells and Skeletal Muscle Regeneration. |
Q33816665 | Satellite cells and the muscle stem cell niche |
Q26777962 | Satellite cells in human skeletal muscle plasticity |
Q37261298 | Satellite-cell pool size does matter: defining the myogenic potency of aging skeletal muscle |
Q37371320 | Sca-1-expressing nonmyogenic cells contribute to fibrosis in aged skeletal muscle |
Q35212612 | Sculpting chromatin beyond the double helix: epigenetic control of skeletal myogenesis. |
Q37596364 | Self-renewal and differentiation of muscle satellite cells are regulated by the Fas-associated death domain |
Q81623652 | Serum of youth? |
Q64914220 | Shisa2 regulates the fusion of muscle progenitors. |
Q29346965 | Sirt1 increases skeletal muscle precursor cell proliferation |
Q33766697 | Skeletal muscle as a regulator of the longevity protein, Klotho |
Q89599729 | Skeletal muscle as an experimental model of choice to study tissue aging and rejuvenation |
Q28262423 | Skeletal muscle homeostasis and plasticity in youth and ageing: impact of nutrition and exercise |
Q34389066 | Skeletal muscle satellite cells: mediators of muscle growth during development and implications for developmental disorders |
Q36121427 | Skeletal muscle stem and progenitor cells: reconciling genetics and lineage |
Q60300380 | Skeletal muscle stem cells in comfort and stress |
Q37810057 | Skeletal myoblasts for cardiac repair |
Q35167984 | Slow-adhering stem cells derived from injured skeletal muscle have improved regenerative capacity. |
Q36715665 | Sorting single satellite cells from individual myofibers reveals heterogeneity in cell-surface markers and myogenic capacity |
Q41360491 | Sprouting a new take on stem cell aging. |
Q37351564 | Stage-specific effects of Notch activation during skeletal myogenesis. |
Q90190005 | Stem Cell Aging in Skeletal Muscle Regeneration and Disease |
Q40966771 | Stem Cells and Tissue Niche: Two Faces of the Same Coin of Muscle Regeneration. |
Q34402704 | Stem cell ageing and non-random chromosome segregation. |
Q37005066 | Stem cell ageing: does it happen and can we intervene? |
Q34159765 | Stem cell aging: mechanisms, regulators and therapeutic opportunities |
Q34314546 | Stem cells and aging: a chicken-or-the-egg issue? |
Q34450999 | Stem cells and the niche: a dynamic duo. |
Q33616166 | Stem cells as vehicles for youthful regeneration of aged tissues. |
Q35088530 | Stem cells for skeletal muscle repair |
Q36523915 | Stem cells, ageing and the quest for immortality. |
Q33393564 | Stem cells, their niches and the systemic environment: an aging network |
Q47717967 | Stem cells: Aging and transcriptional fingerprints |
Q36118320 | Stra13 regulates satellite cell activation by antagonizing Notch signaling |
Q48325250 | Sustained Depolarization of the Resting Membrane Potential Regulates Muscle Progenitor Cell Growth and Maintains Stem Cell Properties In Vitro |
Q34070002 | Syndecan-3 and Notch cooperate in regulating adult myogenesis |
Q38112137 | Syndecans in skeletal muscle development, regeneration and homeostasis |
Q38625964 | Systemic Problems: A perspective on stem cell aging and rejuvenation |
Q35828481 | Systemic attenuation of the TGF-β pathway by a single drug simultaneously rejuvenates hippocampal neurogenesis and myogenesis in the same old mammal |
Q92453264 | Systemic milieu and age-related deterioration |
Q39032975 | THE RENIN-ANGIOTENSIN SYSTEM AND THE BIOLOGY OF SKELETAL MUSCLE: MECHANISMS OF MUSCLE WASTING IN CHRONIC DISEASE STATES. |
Q37153111 | Targeting β1-integrin signaling enhances regeneration in aged and dystrophic muscle in mice |
Q83987360 | Taurine postponed the replicative senescence of rat bone marrow-derived multipotent stromal cells in vitro |
Q36686910 | Testosterone improves the regeneration of old and young mouse skeletal muscle |
Q34111489 | Testosterone is essential for skeletal muscle growth in aged mice in a heterochronic parabiosis model |
Q33634392 | Testosterone supplementation reverses sarcopenia in aging through regulation of myostatin, c-Jun NH2-terminal kinase, Notch, and Akt signaling pathways |
Q51761058 | The Bioelectric Code: Reprogramming Cancer and Aging From the Interface of Mechanical and Chemical Microenvironments. |
Q45833603 | The Combination of Physical Exercise with Muscle-Directed Antioxidants to Counteract Sarcopenia: A Biomedical Rationale for Pleiotropic Treatment with Creatine and Coenzyme Q10. |
Q51786747 | The Fountain of Youth: A Tale of Parabiosis, Stem Cells, and Rejuvenation. |
Q24307354 | The IGF-I splice variant MGF increases progenitor cells in ALS, dystrophic, and normal muscle |
Q38671086 | The NOTCH1/SNAIL1/MEF2C Pathway Regulates Growth and Self-Renewal in Embryonal Rhabdomyosarcoma |
Q24306223 | The Notch coactivator, MAML1, functions as a novel coactivator for MEF2C-mediated transcription and is required for normal myogenesis |
Q33569692 | The Notch effector Hey1 associates with myogenic target genes to repress myogenesis. |
Q55024852 | The RNA-binding protein YBX1 regulates epidermal progenitors at a posttranscriptional level. |
Q90740037 | The Spectrum of Fundamental Basic Science Discoveries Contributing to Organismal Aging |
Q35754387 | The Spindle Assembly Checkpoint Safeguards Genomic Integrity of Skeletal Muscle Satellite Cells |
Q39641300 | The Wnt pathway limits BMP signaling outside of the germline stem cell niche in Drosophila ovaries |
Q34302715 | The aged niche disrupts muscle stem cell quiescence. |
Q35105101 | The altered fate of aging satellite cells is determined by signaling and epigenetic changes |
Q26801427 | The central role of muscle stem cells in regenerative failure with aging |
Q33788099 | The depletion of skeletal muscle satellite cells with age is concomitant with reduced capacity of single progenitors to produce reserve progeny |
Q47753639 | The effect of downhill running on Notch signaling in regenerating skeletal muscle. |
Q27008819 | The effect of physiological stimuli on sarcopenia; impact of Notch and Wnt signaling on impaired aged skeletal muscle repair |
Q92803290 | The effects of minodronate and activated vitamin D on bone mineral density and muscle mass in postmenopausal women with osteoporosis |
Q37219522 | The genetics of vertebrate myogenesis |
Q36730830 | The harmonies played by TGF-β in stem cell biology |
Q46505558 | The influence of eccentric exercise on mRNA expression of skeletal muscle regulators |
Q26771242 | The ins and outs of muscle stem cell aging |
Q36357449 | The lymphocyte secretome from young adults enhances skeletal muscle proliferation and migration, but effects are attenuated in the secretome of older adults |
Q36971718 | The microenvironment of the embryonic neural stem cell: lessons from adult niches? |
Q39275635 | The obestatin/GPR39 system is up-regulated by muscle injury and functions as an autocrine regenerative system |
Q34248711 | The p53 network: cellular and systemic DNA damage responses in aging and cancer |
Q26800207 | The quasi-parallel lives of satellite cells and atrophying muscle |
Q35935201 | The rejuvenating effect of pregnancy on muscle regeneration |
Q39924099 | The role of Delta-like 1 shedding in muscle cell self-renewal and differentiation. |
Q34291439 | The satellite cell in male and female, developing and adult mouse muscle: distinct stem cells for growth and regeneration |
Q26827224 | The stem cell niche in regenerative medicine |
Q37068201 | The therapeutic potential of IGF-I in skeletal muscle repair |
Q64894373 | The transcription factor Slug represses p16Ink4a and regulates murine muscle stem cell aging. |
Q37383091 | The value of mammalian models for duchenne muscular dystrophy in developing therapeutic strategies |
Q38208211 | Therapeutic modulation of Notch signalling--are we there yet? |
Q26852708 | Therapies for sarcopenia and regeneration of old skeletal muscles: more a case of old tissue architecture than old stem cells |
Q37429379 | Tissue resident stem cells: till death do us part |
Q92659664 | Tissue-Resident PDGFRα+ Progenitor Cells Contribute to Fibrosis versus Healing in a Context- and Spatiotemporally Dependent Manner |
Q34445002 | Toward molecular understanding of polar overdominance at the ovine callipyge locus |
Q50104779 | Transforming growth factor-β in stem cells and tissue homeostasis |
Q53479362 | Translational strategies and challenges in regenerative medicine. |
Q54062963 | Traumatic muscle fibrosis: From pathway to prevention. |
Q39987998 | Tumor necrosis factor-alpha and endothelial cells modulate Notch signaling in the bone marrow microenvironment during inflammation |
Q48453522 | Turning neurogenesis up a Notch |
Q41021385 | Type 2 innate signals stimulate fibro/adipogenic progenitors to facilitate muscle regeneration. |
Q64236814 | Unraveling the Paradoxical Action of Androgens on Muscle Stem Cells |
Q43299475 | Up-regulation of calcium-dependent proteolysis in human myoblasts under acute oxidative stress. |
Q36867965 | Vascular endothelial growth factor-A inhibits EphB4 and stimulates delta-like ligand 4 expression in adult endothelial cells. |
Q34333066 | Vitamin D deficiency down-regulates Notch pathway contributing to skeletal muscle atrophy in old wistar rats |
Q21245383 | What does the concept of the stem cell niche really mean today? |
Q26770845 | When stem cells grow old: phenotypes and mechanisms of stem cell aging |
Q33945336 | Wnt/β-catenin signaling induces the aging of mesenchymal stem cells through the DNA damage response and the p53/p21 pathway |
Q28588627 | Wnt10b deficiency promotes coexpression of myogenic and adipogenic programs in myoblasts |
Q41440209 | Young blood heals old muscles |
Q36981493 | hESC-secreted proteins can be enriched for multiple regenerative therapies by heparin-binding |
Q37745404 | miR-127 enhances myogenic cell differentiation by targeting S1PR3. |
Q36005429 | microRNA-206 promotes skeletal muscle regeneration and delays progression of Duchenne muscular dystrophy in mice |
Q64241257 | p16Ink4a Prevents the Activation of Aged Quiescent Dentate Gyrus Stem Cells by Physical Exercise |
Q37202809 | p21 both attenuates and drives senescence and aging in BubR1 progeroid mice |
Q33806427 | p38 MAPK signaling underlies a cell-autonomous loss of stem cell self-renewal in skeletal muscle of aged mice |
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