Your search keyword '"Coletti, Dario"' showing total 10 results

1. Ormoni neuroipofisari: regolatori non canonici della struttura, funzione e omeostasi del muscolo

Author

Moresi, Viviana, Coletti, Dario, and Adamo, Sergio

Abstract

Nuovi, inaspettati ruoli degli ormoni neuroipofisari vasopressina e ossitocina sono emersi negli ultimi decenni. Gli effetti di tali ormoni sul muscolo striato sono stati oggetto di numerose ricerche in vitroe in vivoche hanno generato un’importante serie di dati circa la segnalazione intracellulare in cellule miogeniche, la loro risposta differenziativa, lo sviluppo e l’omeostasi del muscolo scheletrico. Riassumiamo qui gli studi su questi nuovi ruoli degli ormoni neuroipofisari, che aprono anche la possibilità di nuovi approcci terapeutici a patologie muscolari.

Published

2024

2. Cytoplasmic HDAC4 regulates the membrane repair mechanism in Duchenne muscular dystrophy

Author

Renzini, Alessandra, Marroncelli, Nicoletta, Cavioli, Giorgia, Di Francescantonio, Silvia, Forcina, Laura, Lambridis, Alessandro, Di Giorgio, Eros, Valente, Sergio, Mai, Antonello, Brancolini, Claudio, Giampietri, Claudia, Magenta, Alessandra, De Santa, Francesca, Adamo, Sergio, Coletti, Dario, and Moresi, Viviana

Abstract

Histone deacetylase 4 (HDAC4) is a stress‐responsive factor that mediates multiple cellular responses. As a member of class IIa HDACs, HDAC4 shuttles between the nucleus and the cytoplasm; however, HDAC4 cytoplasmic functions have never been fully investigated. Duchenne muscular dystrophy (DMD) is a genetic, progressive, incurable disorder, characterized by muscle wasting, which can be treated with the unspecific inhibition of HDACs, despite this approach being only partially effective. More efficient strategies may be proposed for DMD only after the different HDAC members will be characterized. To fully understand HDAC4 functions, we generated dystrophic mice carrying a skeletal muscle‐specific deletion of HDAC4 (mdx;KO mice). The progression of muscular dystrophy was characterized in mdx and age‐matched mdx;KO mice by means of histological, molecular, and functional analyses. Satellite cells (SCs) from these mice were differentiated in vitro, to identify HDAC4 intrinsic functions influencing the myogenic potential of dystrophic SCs. Gain‐of‐function experiments revealed the cytoplasmic functions of HDAC4 in mdx;KO muscles. Histone deacetylase 4 increased in the skeletal muscles of mdx mice (~3‐fold; P< 0.05) and of DMD patients (n= 3, males, mean age 13.3 ± 1.5 years), suggesting that HDAC4 has a role in DMD. Its deletion in skeletal muscles importantly worsens the pathological features of DMD, leading to greater muscle fragility and degeneration over time. Additionally, it impairs SC survival, myogenic potential, and muscle regeneration, ultimately compromising muscle function (P< 0.05–0.001). The impaired membrane repair mechanism in muscles and SCs accounts for the mdx;KO phenotype. Indeed, the ectopic expression of Trim72, a major player in the membrane repair mechanism, prevents SC death (~20%; P< 0.01) and increases myogenic fusion (~40%; P< 0.01) in vitro; in vivoit significantly reduces myofibre damage (~10%; P< 0.005) and improves mdx;KO muscle function (P< 0.05). The mdx;KO phenotype is also fully rescued by restoring cytoplasmic levels of HDAC4, both in vitroand in vivo. The protective role of HDAC4 in the cytoplasm of mdx;KO muscles is, in part, independent of its deacetylase activity. HDAC4 expression correlates with Trim72 mRNA levels; furthermore, Trim72 mRNA decays more rapidly (P< 0.01) in mdx;KO muscle cells, compared with mdx ones. Histone deacetylase 4 performs crucial functions in the cytoplasm of dystrophic muscles, by mediating the muscle repair response to damage, an important role in ensuring muscle homeostasis, probably by stabilizing Trim72 mRNA. Consequently, the cytoplasmic functions of HDAC4 should be stimulated rather than inhibited in muscular dystrophy treatments, a fact to be considered in future therapeutic approaches.

Published

2022

3. Ormoni neuroipofisari: regolatori non canonici della struttura, funzione e omeostasi del muscolo

Author

Moresi, Viviana, Coletti, Dario, and Adamo, Sergio

Abstract

Nuovi, inaspettati ruoli degli ormoni neuroipofisari vasopressina e ossitocina sono emersi negli ultimi decenni. Gli effetti di tali ormoni sul muscolo striato sono stati oggetto di numerose ricerche in vitroe in vivoche hanno generato un’importante serie di dati circa la segnalazione intracellulare in cellule miogeniche, la loro risposta differenziativa, lo sviluppo e l’omeostasi del muscolo scheletrico. Riassumiamo qui gli studi su questi nuovi ruoli degli ormoni neuroipofisari, che aprono anche la possibilità di nuovi approcci terapeutici a patologie muscolari.

Published

2018

4. Static magnetic fields enhance skeletal muscle differentiation in vitro by improving myoblast alignment

Author

Coletti, Dario, Teodori, Laura, Albertini, Maria C., Rocchi, Marco, Pristerà, Alessandro, Fini, Massimo, Molinaro, Mario, and Adamo, Sergio

Abstract

Static magnetic field (SMF) interacts with mammal skeletal muscle; however, SMF effects on skeletal muscle cells are poorly investigated. The myogenic cell line L6, an in vitro model of muscle development, was used to investigate the effect of a 80 ± mT SMF generated by a custom‐made magnet. SMF promoted myogenic cell differentiation and hypertrophy, i.e., increased accumulation of actin and myosin and formation of large multinucleated myotubes. The elevated number of nuclei per myotube was derived from increased cell fusion efficiency, with no changes in cell proliferation upon SMF exposure. No alterations in myogenin expression, a modulator of myogenesis, occurred upon SMF exposure. SMF induced cells to align in parallel bundles, an orientation conserved throughout differentiation. SMF stimulated formation of actin stress‐fiber like structures. SMF rescued muscle differentiation in the presence of TNF, a muscle differentiation inhibitor. We believe this is the first report showing that SMF promotes myogenic differentiation and cell alignment, in the absence of any invasive manipulation. SMF‐enhanced parallel orientation of myotubes is relevant to tissue engineering of a highly organized tissue such as skeletal muscle. SMF rescue of muscle differentiation in the presence of TNF may have important therapeutic implications. © 2007 International Society for Analytical Cytology

Published

2007

5. IGF-I–induced Differentiation of L6 Myogenic Cells Requires the Activity of cAMP-Phosphodiesterase

Author

De Arcangelis, Vania, Coletti, Dario, Conti, Marco, Lagarde, Michel, Molinaro, Mario, Adamo, Sergio, Nemoz, Georges, and Naro, Fabio

Abstract

Inhibition of type 4 cAMP-specific phosphodiesterase (PDE4) activity in L6-C5 and L6-E9 abolished myogenic differentiation induced by low-serum medium and IGF-I. L6-C5 cells cultured in low-serum medium displayed a PDE4 activity higher than cells cultured in serum-free medium, a condition not sufficient to induce differentiation. In the presence of serum, PDE4D3, the major isoform natively expressed in L6-C5 cells, translocated to a Triton-insoluble fraction, which increased the PDE specific activity of the fraction, and exhibited a Mr shift typical of phosphorylation of this isoform. Furthermore, serum promoted the localization of PDE4D3 to a vesicular subcellular compartment. In L6-C5 cells, IGF-I is a stronger inducer of myogenic differentiation in the presence than in absence of serum. Its ability to trigger differentiation in the absence of serum was restored by overexpressing wild-type PDE4D3, but not a phosphorylation-insensitive mutant. This finding was confirmed in single cells overexpressing a GFP-PDE4D3 fusion protein by assessing nuclear accumulation of myogenin in both L6-C5 and L6-E9. Overexpression of other PDE isoforms was less efficient, confirming that PDE4D3 is the physiologically relevant phosphodiesterase isoform in the control of myogenesis. These results show that downregulation of cAMP signaling through cAMP-phosphodiesterase stimulation is a prerequisite for induction of myogenesis.

Published

2003

6. Static magnetic fields affect calcium fluxes and inhibit stress-induced apoptosis in human glioblastoma cells

Author

Teodori, Laura, Göhde, Wolfgang, Valente, Maria Giovanna, Tagliaferri, Fausto, Coletti, Dario, Perniconi, Barbara, Bergamaschi, Antonio, Cerella, Claudia, and Ghibelli, Lina

Abstract

Epidemiologic data revealed increased brain tumor incidence in workers exposed to magnetic fields (MFs), raising concerns about the possible link between MF exposure and cancer. However, MFs seem to be neither mutagenic nor tumorigenic. The mechanism of their tumorigenic effect has not been elucidated. To evaluate the interference of MFs with physical (heat shock, HS) and chemical (etoposide, VP16) induced apoptoses, respectively, we exposed a human glioblastoma primary culture to 6 mT static MF. We investigated cytosolic Ca²⁺ ([Ca²⁺]i) fluxes and extent of apoptosis as key endpoints. The effect of MFs on HS- and VP16-induced apoptoses in primary glioblastoma cultures from four patients was also tested. Static MFs increased the [Ca²⁺]i from a basal value of 124 ± 4 nM to 233 ± 43 nM (P &lt; 0.05). MF exposure dramatically reduced the extent of HS- and VP16-induced apoptoses in all four glioblastoma primary cultures analyzed by 56% (range, 28–87%) and 44% (range, 38–48%), respectively. However, MF alone did not exert any apoptogenic activity. Differences were observed across the four cultures with regard to apoptotic induction by HS and VP16 and to MF apoptotic reduction, with an individual variability with regard to apoptotic sensitivity. The ability of static MFs to reduce the extent of damage-induced apoptosis in glioblastoma cells might allow the survival of damaged and possibly mutated cells. Cytometry 49:143–149, 2002. © 2002 Wiley-Liss, Inc.

Published

2002

7. Polychlorobiphenyls Inhibit Skeletal Muscle Differentiation in Culture

Author

Coletti, Dario, Palleschi, Simonetta, Silvestroni, Leopoldo, Cannavò, Andrea, Vivarelli, Elisabetta, Tomei, Francesco, Molinaro, Mario, and Adamo, Sergio

Abstract

Polychlorinated biphenyls (PCBs) are ubiquitous and persistent pollutants whose role in developmental toxicity is of great concern. The observation that the offspring of PCB-exposed mothers (both in humans and rodents) display reduced body mass prompted us to investigate the effects of commercial mixtures of PCB congeners (Aroclor 1232, 1254, and 1262) on differentiation of both a myogenic cell line and primary myogenic cell cultures. The fusion of L6 myoblasts into multinucleated myotubes and the increase of creatine kinase (CK) activity were dose-dependently inhibited by Aroclor 1254 at concentrations (0.1–4 μg/ml) that caused no effect on cell density. Ultrastructural analysis demonstrated that Aroclor 1254 also prevented the accumulation of contractile filaments while inducing hypertrophy of the smooth endoplasmic reticulum and appearance of membrane-filled autophagosomes. Half-maximal inhibition (IC50) of CK activity accumulation occurred at 0.01 μg/ml for Aroclor 1262, 2 μg/ml for Aroclor 1254, and 8 μg/ml for Aroclor 1232. Aroclor-dependent inhibition of myogenic differentiation was also shown by the reduced expression and nuclear accumulation of β-galactosidase in primary cultures of fetal myoblasts from transgenic mice expressing this reporter gene under the control of the myosin light chain promoter. These data show that skeletal muscle differentiation is specifically impaired by PCBs and may explain the reported depression of body mass growth in PCB-exposed offspring at birth. Furthermore, myogenic cell cultures are highly sensitive to PCBs and allow the detection of biological effects of environmental levels of these pollutants.

Published

2001

8. Myomegalin Is a Novel Protein of the Golgi/Centrosome That Interacts with a Cyclic Nucleotide Phosphodiesterase*

Author

Verde, Ignacio, Pahlke, Gudrun, Salanova, Michele, Zhang, Gu, Wang, Sonya, Coletti, Dario, Onuffer, James, Jin, S.-L. Catherine, and Conti, Marco

Abstract

Subcellular targeting of the components of the cAMP-dependent pathway is thought to be essential for intracellular signaling. Here we have identified a novel protein, named myomegalin, that interacts with the cyclic nucleotide phosphodiesterase PDE4D, thereby targeting it to particulate structures. Myomegalin is a large 2,324-amino acid protein mostly composed of α-helical and coiled-coil structures, with domains shared with microtubule-associated proteins, and a leucine zipper identical to that found in theDrosophilacentrosomin. Transcripts of 7.5–8 kilobases were present in most tissues, whereas a short mRNA of 2.4 kilobases was detected only in rat testis. A third splicing variant was expressed predominantly in rat heart. Antibodies against the deduced sequence recognized particulate myomegalin proteins of 62 kDa in testis and 230–250 kDa in heart and skeletal muscle. Immunocytochemistry and transfection studies demonstrate colocalization of PDE4D and myomegalin in the Golgi/centrosomal area of cultured cells, and in sarcomeric structures of skeletal muscle. Myomegalin expressed in COS-7 cells coimmunoprecipitated with PDE4D3 and sequestered it to particulate structures. These findings indicate that myomegalin is a novel protein that functions as an anchor to localize components of the cAMP-dependent pathway to the Golgi/centrosomal region of the cell.

Published

2001

9. Vesicle-Mediated Phosphatidylcholine Reapposition to the Plasma Membrane Following Hormone-Induced Phospholipase D Activation

Author

Coletti, Dario, Silvestroni, Leopoldo, Naro, Fabio, Molinaro, Mario, Adamo, Sergio, and Palleschi, Simonetta

Abstract

Phospholipase D (PLD) activation involved in signal transduction may lead to the hydrolysis of conspicuous amounts of phosphatidylcholine (PC). This study shows that PLD activation significantly alters the plasma membrane (PM) environment and the membrane exchange dynamics. PC-PLD activation in vasopressin (AVP)-stimulated L6 myogenic cells was accompanied by increased exocytosis and decreased membrane fluidity, as shown by transmission EM and fluorescence spectroscopy of trimethylammonium-diphenyl-hexatriene. AVP-induced exocytosis appeared to be brefeldin A-insensitive. PLD inhibition by Zn2+and PC de novosynthesis inhibition by hexadecylphosphocholine abolished AVP-induced vesicle traffic. Upon AVP stimulation, metabolically labeled PC decreased in PM, then transiently increased in microsomes, and returned to the prestimulus level in the PM within 5 min, a phenomenon requiring PC neosynthesis and microtubule functionality. Vesicle traffic with similar features was also observed after endothelin-1-induced PC-PLD activation in rat peritubular myoid cells. These results indicate that, in nonsecretory cells, exocytosis coupled to PC de novosynthesis restores PM-PC, conspicuously consumed during PLD-mediated signal transduction.

Published

2000

10. Static magnetic fields modulate X-ray-induced DNA damage in human glioblastoma primary cells

Author

Teodori, Laura, Giovanetti, Anna, Albertini, Maria Cristina, Rocchi, Marco, Perniconi, Barbara, Valente, Maria Giovanna, and Coletti, Dario

Abstract

Although static magnetic fields (SMFs) are used extensively in the occupational and medical fields, few comprehensive studies have investigated their possible genotoxic effect and the findings are controversial. With the advent of magnetic resonance imaging-guided radiation therapy, the potential effects of SMFs on ionizing radiation (IR) have become increasingly important. In this study we focused on the genotoxic effect of 80 mT SMFs, both alone and in combination with (i.e. preceding or following) X-ray (XR) irradiation, on primary glioblastoma cells in culture. The cells were exposed to: (i) SMFs alone; (ii) XRs alone; (iii) XR, with SMFs applied during recovery; (iv) SMFs both before and after XR irradiation. XR-induced DNA damage was analyzed by Single Cell Gel Electrophoresis assay (comet assay) using statistical tools designed to assess the tail DNA (TD) and tail length (TL) as indicators of DNA fragmentation. Mitochondrial membrane potential, known to be affected by IR, was assessed using the JC-1 mitochondrial probe. Our results showed that exposure of cells to 5 Gy of XR irradiation alone led to extensive DNA damage, which was significantly reduced by post-irradiation exposure to SMFs. The XR-induced loss of mitochondrial membrane potential was to a large extent averted by exposure to SMFs. These data suggest that SMFs modulate DNA damage and/or damage repair, possibly through a mechanism that affects mitochondria.

Published

2014