Stephen T. Mills

IL-4 acts as a myoblast recruitment factor during mammalian muscle growth.

Skeletal muscle formation and growth require the fusion of myoblasts to form multinucleated myofibers or myotubes, but few molecules are known to regulate myoblast fusion in mammals. The transcription factor NFATc2 controls myoblast fusion at a specific stage of myogenesis after the initial formation of a myotube and is necessary for further cell growth. By examining genes regulated by NFATc2 in muscle, this study identifies the cytokine IL-4 as a molecular signal that controls myoblast fusion with myotubes. Muscle cells lacking IL-4 or the IL-4alpha receptor subunit form normally but are reduced in size and myonuclear number. IL-4 is expressed by a subset of muscle cells in fusing muscle cultures and requires the IL-4alpha receptor subunit on myoblasts to promote fusion and growth. These data demonstrate that following myotube formation, myotubes recruit myoblast fusion by secretion of IL-4, leading to muscle growth.

A combinatorial role for NFAT5 in both myoblast migration and differentiation during skeletal muscle myogenesis

Skeletal muscle regeneration depends on myoblast migration, differentiation and myofiber formation. Isoforms of the nuclear factor of activated T cells (NFAT) family of transcription factors display nonredundant roles in skeletal muscle. NFAT5, a new isoform of NFAT, displays many differences from NFATc1-c4. Here, we examine the role of NFAT5 in myogenesis. NFAT5+/- mice displayed a defect in muscle regeneration with fewer myofibers formed at early times after injury. NFAT5 has a muscle-intrinsic function because inhibition of NFAT5 transcriptional activity caused both a migratory and differentiation defect in cultured myoblasts. We identified Cyr61 as a target of NFAT5 signaling in skeletal muscle cells. Addition of Cyr61 to cells expressing inhibitory forms of NFAT5 rescued the migratory phenotype. These results demonstrate a role for NFAT5 in skeletal muscle cell migration and differentiation. Furthermore, as cell-cell interactions are crucial for myoblast differentiation, these data suggest that myoblast migration and differentiation are coupled and that NFAT5 is a key regulator.

CD44 regulates myoblast migration and differentiation

CD44 is a transmembrane protein that plays a role in cell–cell interactions and motility in a number of cell types. Cell–cell interactions are critical for myoblast differentiation and fusion but whether CD44 regulates myogenesis is unknown. Here, we show that CD44 plays a functional role in early myogenesis. Analyses of myofiber cross‐sectional area, after local injury in mouse tibialis anterior (TA) muscles, revealed that growth was transiently delayed in the absence of CD44. A muscle‐intrinsic role for CD44 is suggested as primary myoblasts from CD44−/− mice displayed attenuated differentiation and subsequent myotube formation at early times in a differentiation‐inducing in vitro environment. Chemotaxis of CD44−/− myoblasts toward hepatocyte growth factor (HGF) and basic fibroblast growth factor (bFGF) was totally abrogated, although expression of their respective receptors did not appear to differ from wild‐type. Furthermore, motility of CD44−/− myoblasts was decreased at early stages of differentiation as determined by time‐lapse microscopy. Wild‐type myoblasts contained two subpopulations of slow‐ and fast‐migrating cells, whereas CD44−/− myoblasts were composed predominantly of the slower migrating subpopulation. Taken together, these data suggest that myoblast migration and differentiation are closely linked and CD44 is a key regulator. J. Cell. Physiol. 209: 314–321, 2006.

Aging promotes pro-fibrotic matrix production and increases fibrocyte recruitment during acute lung injury

Fibrotic lung diseases increase with age. Previously we determined that senescence increases tissue expression of fibronectin EDA (Fn-EDA) and decreases fibroblast expression of Thy-1, and that fibrocytes contribute to fibrosis following bleomycin-induced lung injury in mice. In this study we hypothesized that fibroblasts lacking Thy-1 expression produce an extracellular matrix that promotes fibrocyte retention and myofibroblast transdifferentiation, thereby promoting fibrogenesis. Young and old mice were treated with bleomycin intratracheally; fibrocytes in the bone marrow, blood, and lungs were quantified, and lung fibroblast Thy-1 expression assessed. Bone marrow-derived fibrocytes were cultured on matrices derived from Thy-1(+) or Thy-1(−) fibroblasts ± the pro-fibrotic cytokine TGFβ1. Older mice had more fibrocytes in their bone marrows at baseline and more fibrocytes in their lungs following bleomycin treatment. In parallel, lung fibroblasts in older mice had lower expression of Thy-1 at baseline that increased transiently 7 days after bleomycin treatment but then rapidly waned such that 14 days after bleomycin treatment Thy-1 expression was again markedly lower. Fibrocytes cultured on matrices derived from Thy-1(−) fibroblasts + TGFβ1 had increased gene expression for collagen type 1, fibronectin, Fn-EDA, and α-smooth muscle actin. In parallel, whereas the matrices derived from Thy-1(−) fibroblasts stimulated phosphorylation of Akt in cultured fibrocytes, the matrices derived from Thy-1(+) fibroblasts induced apoptosis. These findings suggest that senescence increases fibrocyte recruitment to the lung following injury and that loss of Thy-1 expression by lung fibroblasts promotes fibrocyte retention and myofibroblast trans-differentiation that renders the “aging lung” susceptible to fibrosis.

TGFβ1 Mediates Alcohol-Induced Nrf2 Suppression in Lung Fibroblasts

Background Chronic alcohol ingestion induces the expression of transforming growth factor beta-1(TGFβ1), inhibits nuclear factor (erythroid-derived 2)-like 2 (Nrf2)-mediated activation of the antioxidant response element (ARE), depletes alveolar glutathione pools, and potentiates acute lung injury. In this study, we examined the mechanistic relationship between TGFβ1 and Nrf2-ARE signaling in the experimental alcoholic lung. Methods Wild-type mice were treated ± alcohol in drinking water for 8 weeks and their lungs were assessed for Nrf2 expression. In parallel, mouse lung fibroblasts were cultured ± alcohol and treated ± sulforaphane (SFP; an activator of Nrf2), ±TGFβ1, ±TGFβ1 neutralizing antibody, and/or ±activin receptor-like kinase 5 inhibitors (to block TGβ1 receptor signaling) and then analyzed for the expression of Nrf2, Kelch-like ECH-associated protein 1 (Keap1) and TGFβ1, Nrf2-ARE activity, and the expression of the Nrf2-ARE-dependent antioxidants glutathione s-transferase theta 2 (GSTT2) and glutamate-cysteine ligase catalytic subunit (GCLC). Finally, silencing RNA (siRNA) of Nrf2 was then performed prior to alcohol exposure and subsequent analysis of TGFβ1 expression. Results Alcohol treatment in vivo or in vitro decreased Nrf2 expression in murine whole lung and lung fibroblasts, respectively. In parallel, alcohol exposure in vitro decreased Keap1 gene and protein expression in lung fibroblasts. Furthermore, alcohol exposure increased TGFβ1 expression but decreased Nrf2-ARE activity and expression of the ARE-dependent genes for GSTT2 and GCLC. These effects of alcohol were prevented by treatment with SFP; in contrast, Nrf2 SiRNA expression exacerbated alcohol-induced TGFβ1 expression. Finally, TGFβ1 treatment directly suppressed Nrf2-ARE activity whereas blocking TGFβ1 signaling attenuated alcohol-induced suppression of Nrf2-ARE activity. Conclusions Alcohol-induced oxidative stress is mediated by TGFβ1, which suppresses Nrf2-ARE-dependent expression of antioxidant defenses and creates a vicious cycle that feeds back to further increase TGFβ1 expression. These effects of alcohol can be mitigated by activation of Nrf2, suggesting a potential therapy in individuals at risk for lung injury due to alcohol abuse.

Nuclear Thioredoxin-1 Overexpression Attenuates Alcohol-Mediated Nrf2 Signaling and Lung Fibrosis

Background Alcohol abuse, which impairs antioxidant defenses and promotes acute lung injury, increases Nrf2 nuclear translocation but nevertheless inhibits its activation of the antioxidant response element (ARE). Thioredoxin‐1 (Trx1) is required for optimal Nrf2 binding and activation of the ARE, and we hypothesized that its inhibition contributes to impaired Nrf2‐ARE signaling in the alcoholic lung. Methods Lung tissue and primary lung fibroblasts (PLFs) were isolated from C57/BL6 wild‐type (WT) and transgenic mice overexpressing the human Trx1 gene with a nuclear localizing sequence (NLS‐Tg); some mice consumed alcohol in water prior to lung tissue and PLF isolation; in some mice, acute lung injury was induced with intratracheal bleomycin. In other experiments, PLFs were isolated from WT and NLS‐Tg mice and then exposed to alcohol. Finally, PLF isolated from WT mice were transfected with Trx1 expression vector containing either a cytosolic localized sequence (NES) or a nuclear localized sequence (NLS) prior to alcohol exposure. Results Alcohol treatment in vivo or in vitro decreased Trx1 expression, and bleomycin‐treated alcohol‐fed mice had fibrotic disrepair in their lungs. In parallel, whereas alcohol exposure in vitro increased TGF β1 expression and decreased Nrf2‐ARE activity in PLF from WT mice, these effects were not observed in PLF from NLS‐Tg mice. Finally, selective overexpression of Trx1 in the nucleus but not in the cytosol preserved Nrf2‐ARE activity during alcohol exposure. Conclusions Although alcohol‐induced redox stress actually promotes Nrf2 nuclear translocation, the coincident suppression of Trx1 impairs Nrf2‐ARE activity within the nuclear compartment. Nuclear overexpression of Trx1 restored Nrf2‐ARE activity and attenuated alcohol‐induced TGF β1 expression and alcohol‐induced exaggerate response to bleomycin‐induced acute lung injury.