Project description:Stac3 was identified as a nutritionally regulated gene from an Atlantic salmon subtractive hybridization library with highest expression in skeletal muscle. Salmon Stac3 mRNA was highly correlated with myogenin and myoD1a expression during differentiation of a salmon primary myogenic culture and was regulated by amino acid availability. In zebrafish embryos, stac3 was initially expressed in myotomal adaxial cells and in fast muscle fibers post-segmentation. Morpholino knockdown resulted in defects in myofibrillar protein assembly, particularly in slow muscle fibers, and decreased levels of the hedgehog receptor patched. The function of Stac3 was further characterized in vitro using the mammalian C2C12 myogenic cell line. Stac3 mRNA expression increased during the differentiation of the C2C12 myogenic cell line. Knockdown of Stac3 by RNAi inhibited myotube formation, and microarray analysis revealed that transcripts involved in cell cycle, focal adhesion, cytoskeleton, and the pro-myogenic factors Igfbp-5 and Igf2 were down-regulated. RNAi-treated cells had suppressed Akt signaling and exogenous insulin-like growth factor (Igf) 2 was unable to rescue the phenotype, however, Igf/Akt signaling was not blocked. Overexpression of Stac3, which results in increased levels of Igfbp-5 mRNA, did not lead to increased differentiation. In synchronized cells, Stac3 mRNA was most abundant during the G(1) phase of the cell cycle. RNAi-treated cells were smaller, had higher proliferation rates and a decreased proportion of cells in G(1) phase when compared with controls, suggesting a role in the G(1) phase checkpoint. These results identify Stac3 as a new gene required for myogenic differentiation and myofibrillar protein assembly in vertebrates.

Project description:STAC3 was identified as a nutritionally regulated gene from an Atlantic salmon subtractive hybridization library with highest expression in skeletal muscle. Salmon STAC3 mRNA was highly correlated with myogenin and myoD1a expression during differentiation of a salmon primary myogenic culture and was regulated by amino acid availability. In zebrafish embryos, STAC3 was initially expressed in myotomal adaxial cells and in fast muscle fibres post-segmentation. Morpholino knockdown resulted in defects in myofibrillar protein assembly, particularly in slow muscle fibres, and decreased levels of the hedgehog receptor patched. The function of STAC3 was further characterized in vitro using the mammalian C2C12 myogenic cell line. STAC3 mRNA expression increased during the differentiation of the C2C12 myogenic cell line. Knockdown of STAC3 by RNAi inhibited myotube formation, and microarray analysis revealed that transcripts involved in cell cycle, focal adhesion, cytoskeleton and the pro-myogenic factors IGFBP-5 and IGF2 were down regulated. RNAi-treated cells had suppressed AKT signalling and exogenous IGF2 was unable to rescue the phenotype, however, IGF/AKT signalling was not blocked. Overexpression of STAC3, which results in increased levels of IGFBP-5 mRNA, did not lead to increased differentiation. In synchronized cells, STAC3 mRNA was most abundant during the G1 phase of the cell cycle. RNAi-treated cells were smaller, had higher proliferation rates and decreased proportion of cells in G1 phase when compared to controls, suggesting a role in the G1 phase checkpoint. These results identify STAC3 as a new gene required for myogenic differentiation and myofibrillar protein assembly in vertebrates. We identified STAC3 as being essential for myogenic differentiation. The goal of the microarray analysis was to identify genes that were up- or down-regulated in C2C12 cells when STAC3 expression was inhibited by interfering RNA (RNAi). The microarray compares the C2C12 mouse myogenic cell line between control samples to samples treated with an interfering RNA directed at STAC3. The mouse C2C12 cell line was used at two time points: day 0, which was 24 hours after adding the RNAi, with cells growing in growth media (non-differentiating), and day 1, which was 48 hours after the interfering RNAi was added, and 24 hours after switching to differentiation media. RNAi-treated cells were transfected with an RNAi directed against STAC3, and control cells were transfected with a high-GC content control RNAi. Total RNA was extracted from control and RNAi-treated samples at two time points, at day 0 (24 h after treating with RNAi, while samples were still in growth media), and at day 1 (cells grown in differentiation media for 24h, 48 h after RNAi treatment). At each time point, STAC3 RNAi-treated cells were compared to controls. For the array comparison, at day 0, triplicate biological samples + one technical replicate were used for the controls, and four biological samples were used for the RNAi-treated cells. At day 1, four biological samples and one technical replicate were used for controls and RNAi-treated cells. Technical replicate identifiers are appended by _r.

Project description:Cytoskeletal remodeling in circulating tumor cells (CTCs) facilitates metastatic spread. Previous oncology studies examine sustained aberrant calcium (Ca2+) signaling and cytoskeletal remodeling scrutinizing long-term phenotypes such as tumorigenesis and metastasis. The significance of acute Ca2+ signaling in tumor cells that occur within seconds to minutes is overlooked. This study investigates rapid cytoplasmic Ca2+ elevation in suspended cells on actin and tubulin cytoskeletal rearrangements and the metastatic microtentacle (McTN) phenotype. The compounds Ionomycin and Thapsigargin acutely increase cytoplasmic Ca2+, suppressing McTNs in the metastatic breast cancer cell lines MDA-MB-231 and MDA-MB-436. Functional decreases in McTN-mediated reattachment and cell clustering during the first 24 h of treatment are not attributed to cytotoxicity. Rapid cytoplasmic Ca2+ elevation was correlated to Ca2+-induced actin cortex contraction and rearrangement via myosin light chain 2 and cofilin activity, while the inhibition of actin polymerization with Latrunculin A reversed Ca2+-mediated McTN suppression. Preclinical and phase 1 and 2 clinical trial data have established Thapsigargin derivatives as cytotoxic anticancer agents. The results from this study suggest an alternative molecular mechanism by which these compounds act, and proof-of-principle Ca2+-modulating compounds can rapidly induce morphological changes in free-floating tumor cells to reduce metastatic phenotypes.

Project description:Fusion of myoblasts into multinucleated myofibers is crucial for skeletal muscle development and regeneration. However, the mechanisms controlling this process remain to be determined. Here we identified the involvement of a new extracellular matrix protein in myoblast fusion. Collagen XXV is a transmembrane-type collagen highly transcribed during early myogenesis when primary myofibers form. Limb muscles of E12.5 and E14.5 Col25a1-/- embryos show a clear defect in the formation of multinucleated myofibers. In cell culture, the cleaved soluble extracellular domain of the collagen XXV is sufficient to promote the formation of highly multinucleated myofibers. Col25a1 is transiently expressed during myogenic differentiation and Col25a1 transcripts are down-regulated in multinucleated myofibers by a muscle-specific microRNA, miR-499. Altogether, these findings indicate that collagen XXV is required in vivo and in vitro for the fusion of myoblasts into myofibers and give further evidence that microRNAs participate to the regulation of this process.

Project description:STAC3 was identified as a nutritionally regulated gene from an Atlantic salmon subtractive hybridization library with highest expression in skeletal muscle. Salmon STAC3 mRNA was highly correlated with myogenin and myoD1a expression during differentiation of a salmon primary myogenic culture and was regulated by amino acid availability. In zebrafish embryos, STAC3 was initially expressed in myotomal adaxial cells and in fast muscle fibres post-segmentation. Morpholino knockdown resulted in defects in myofibrillar protein assembly, particularly in slow muscle fibres, and decreased levels of the hedgehog receptor patched. The function of STAC3 was further characterized in vitro using the mammalian C2C12 myogenic cell line. STAC3 mRNA expression increased during the differentiation of the C2C12 myogenic cell line. Knockdown of STAC3 by RNAi inhibited myotube formation, and microarray analysis revealed that transcripts involved in cell cycle, focal adhesion, cytoskeleton and the pro-myogenic factors IGFBP-5 and IGF2 were down regulated. RNAi-treated cells had suppressed AKT signalling and exogenous IGF2 was unable to rescue the phenotype, however, IGF/AKT signalling was not blocked. Overexpression of STAC3, which results in increased levels of IGFBP-5 mRNA, did not lead to increased differentiation. In synchronized cells, STAC3 mRNA was most abundant during the G1 phase of the cell cycle. RNAi-treated cells were smaller, had higher proliferation rates and decreased proportion of cells in G1 phase when compared to controls, suggesting a role in the G1 phase checkpoint. These results identify STAC3 as a new gene required for myogenic differentiation and myofibrillar protein assembly in vertebrates. We identified STAC3 as being essential for myogenic differentiation. The goal of the microarray analysis was to identify genes that were up- or down-regulated in C2C12 cells when STAC3 expression was inhibited by interfering RNA (RNAi). The microarray compares the C2C12 mouse myogenic cell line between control samples to samples treated with an interfering RNA directed at STAC3. The mouse C2C12 cell line was used at two time points: day 0, which was 24 hours after adding the RNAi, with cells growing in growth media (non-differentiating), and day 1, which was 48 hours after the interfering RNAi was added, and 24 hours after switching to differentiation media.

Project description:Endothelial cells are known to release prostacyclin (PGI2) in response to agonists, and this has generally been assumed to be caused, at least in part, by activation of a phospholipase A2 by elevated concentrations of cytoplasmic free calcium ([Ca2+]i). However, it has been shown in the blood platelet that agonists can cause arachidonate release without elevating [Ca2+]i. In the present study, rigorous analysis is made of the [Ca2+]i-dependence of PGI2 production in the human umbilical-vein endothelial cell. Thrombin caused a rapid increase in [Ca2+]i from the resting basal value of 0.1 microM to a peak, within 10-15 s, of approx. 2 microM. In the absence of extracellular Ca2+, [Ca2+]i then declined back to the resting value within 2-3 min. In the presence of extracellular Ca2+, [Ca2+]i partly decreased to a new steady-state value of approx. 1 microM. The elevated [Ca2+]i was maintained while the stimulus and the source of extracellular Ca2+ were present, suggesting that it was dependent on influx of Ca2+ across the plasma membrane. Thrombin stimulated the production of PGI2 in the presence or in the absence of extracellular Ca2+. However, the production of PGI2 was more prolonged in the presence of extracellular Ca2+. Total accumulated amounts of 6-oxo-prostaglandin F1 alpha on stimulation with thrombin without extracellular Ca2+ were only 65% of those accumulated with extracellular Ca2+ present. Cells depleted of extracellular and intracellular sources of Ca2+ by incubation with 1 mM extracellular EGTA and exposing them to ionomycin to discharge intracellular stores produced no elevation of [Ca2+]i on stimulation with thrombin or production of PGI2. The threshold [Ca2+]i required to support the production of PGI2 was measured to be 0.8-1.0 microM by using different doses of ionomycin selectively to increase [Ca2+]i. This relationship between [Ca2+]i and PGI2 production was similar to that produced by using different doses of thrombin. Our results show that the major and probably exclusive intracellular stimulus for the production of PGI2 by the vascular endothelial cell in response to thrombin is the elevation of [Ca2+]i.

Project description:Epidermal keratinocytes achieve sequential differentiation from basal to granular layers, and undergo a specific programmed cell death, cornification, to form an indispensable barrier of the body. Although elevation of the cytoplasmic calcium ion concentration ([Ca2+]i) is one of the factors predicted to regulate cornification, the dynamics of [Ca2+]i in epidermal keratinocytes is largely unknown. Here using intravital imaging, we captured the dynamics of [Ca2+]i in mouse skin. [Ca2+]i was elevated in basal cells on the second time scale in three spatiotemporally distinct patterns. The transient elevation of [Ca2+]i also occurred at the most apical granular layer at a single cell level, and lasted for approximately 40 min. The transient elevation of [Ca2+]i at the granular layer was followed by cornification, which was completed within 10 min. This study demonstrates the tightly regulated elevation of [Ca2+]i preceding the cornification of epidermal keratinocytes, providing possible clues to the mechanisms of cornification.

Project description:BackgroundCytosolic Ca2+ plays vital roles in myogenesis and muscle development. As a major Ca2+ release channel of endoplasmic reticulum (ER), ryanodine receptor 1 (RyR1) key mutations are main causes of severe congenital myopathies. The role of RyR1 in myogenic differentiation has attracted intense research interest but remains unclear.ResultsIn the present study, both RyR1-knockdown myoblasts and CRISPR/Cas9-based RyR1-knockout myoblasts were employed to explore the role of RyR1 in myogenic differentiation, myotube formation as well as the potential mechanism of RyR1-related myopathies. We observed that RyR1 expression was dramatically increased during the late stage of myogenic differentiation, accompanied by significantly elevated cytoplasmic Ca2+ concentration. Inhibition of RyR1 by siRNA-mediated knockdown or chemical inhibitor, dantrolene, significantly reduced cytosolic Ca2+ and blocked multinucleated myotube formation. The elevation of cytoplasmic Ca2+ concentration can effectively relieve myogenic differentiation stagnation by RyR1 inhibition, demonstrating that RyR1 modulates myogenic differentiation via regulation of Ca2+ release channel. However, RyR1-knockout-induced Ca2+ leakage led to the severe ER stress and excessive unfolded protein response, and drove myoblasts into apoptosis.ConclusionsTherefore, we concluded that Ca2+ release mediated by dramatic increase in RyR1 expression is required for the late stage of myogenic differentiation and fusion. This study contributes to a novel understanding of the role of RyR1 in myogenic differentiation and related congenital myopathies, and provides a potential target for regulation of muscle characteristics and meat quality.

Project description:While spinal muscular atrophy (SMA) is characterized by motor neuron degeneration, it is unclear whether and how much survival motor neuron (SMN) protein deficiency in muscle contributes to the pathophysiology of the disease. There is increasing evidence from patients and SMA model organisms that SMN deficiency causes intrinsic muscle defects. Here we investigated the role of SMN in muscle development using muscle cell lines and primary myoblasts. Formation of multinucleate myotubes by SMN-deficient muscle cells is inhibited at a stage preceding plasma membrane fusion. We found increased expression and reduced induction of key muscle development factors, such as MyoD and myogenin, with differentiation of SMN-deficient cells. In addition, SMN-deficient muscle cells had impaired cell migration and altered organization of focal adhesions and the actin cytoskeleton. Partially restoring SMN inhibited the premature expression of muscle differentiation markers, corrected the cytoskeletal abnormalities and improved myoblast fusion. These findings are consistent with a role for SMN in myotube formation through effects on muscle differentiation and cell motility.

Project description:The conversion of proliferating skeletal muscle precursors (myoblasts) to terminally-differentiated myocytes is a critical step in skeletal muscle development and repair. We show that EphA7, a juxtacrine signaling receptor, is expressed on myocytes during embryonic and fetal myogenesis and on nascent myofibers during muscle regeneration in vivo. In EphA7-/- mice, hindlimb muscles possess fewer myofibers at birth, and those myofibers are reduced in size and have fewer myonuclei and reduced overall numbers of precursor cells throughout postnatal life. Adult EphA7-/- mice have reduced numbers of satellite cells and exhibit delayed and protracted muscle regeneration, and satellite cell-derived myogenic cells from EphA7-/- mice are delayed in their expression of differentiation markers in vitro. Exogenous EphA7 extracellular domain will rescue the null phenotype in vitro, and will also enhance commitment to differentiation in WT cells. We propose a model in which EphA7 expression on differentiated myocytes promotes commitment of adjacent myoblasts to terminal differentiation.