Véronique Garandel scite author profile

We have studied insulin-like-growth-factor (IGF) binding in two subclones of the C2 myogenic cell line. In the permissive parental subclone, myoblasts differentiate spontaneously into myotubes in medium supplemented with fetal calf serum. Unlike permissive myoblasts, inducible myoblasts require high concentrations of insulin (1.6 pM) or lower concentrations of IGF-J (25 nM) to differentiate, and expression of MyoDl is not constitutive. IGF receptors were studied in microsomal membranes of proliferating and quiescent myoblasts and myotubes. IGF-I1 binding was also studied in inducible myoblasts transfected with the MyoDl cDNA (clone EP5).Both It emerges from these experiments that C2 cells express a putative a282 IGF-I1 receptor structurally related to the insulin/IGF-I receptor family. It is present in myoblasts but not in myotubes. The possible relationship between expression of this receptor and expression of MyoDl as well as myoblast differentiation is discussed.

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A developmentally regulated form of insulin-like growth factor receptor beta-subunit in C2 myoblasts exhibiting altered requirements for differentiation.

Barenton

Domeyne

Garandel

et al. 1993

Endocrinology

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Ligand-dependent autophosphorylation and immunoprecipitation have been used to distinguish insulin and insulin-like growth factor-I (IGF-I) receptor beta-subunits in the permissive and inducible subclones of the C2 myoblast cell line. Permissive myoblasts differentiate spontaneously, whereas myoblasts of the inducible subclone require exogenous IGFs to undergo terminal differentiation. Permissive myoblasts contain beta-subunits of 95 and 101 kilodalton (kDa) mol wt. The 95-kDa subunits are immunoprecipitated with antipeptide antibodies directed against tyrosine kinase (AbP2), juxtamembrane (AbP4), and carboxy-terminal (AbP5) domains of the insulin receptor and insulin receptor monoclonal antibody 29B4. The tryptic phosphopeptide map of the 95-kDa band suggests that it contains both insulin and IGF-I receptor beta-subunits. The 101-kDa subunit is immunoprecipitated by AbP2, AbP4, and AbP5, because it forms a hybrid complex with the 95-kDa protein, but it does not react directly with AbP4, AbP5, or antibody 29B4. Phosphorylation of the 101-kDa subunit is more responsive to IGF-I than to IGF-II or insulin, indicating that it is a second IGF-I receptor beta-subunit. Inducible myoblasts exhibit a single major beta-subunit of 106 kDa mol wt. Its immunoreactivity and phosphopeptide map are virtually identical to those of the 101-kDa IGF-I receptor beta-subunit from permissive cells. However, unlike the 101-kDa beta-subunit, phosphorylation of the 106-kDa protein appears to be more responsive to IGF-II than to either IGF-I or insulin. It is lost upon differentiation of myoblasts into myotubes concomittant with the appearance of 95- and 101-kDa beta-subunits. These data demonstrate 1) an alpha 2 beta 2 IGF receptor that has high sensitivity for IGF-II in inducible, but not in permissive, myoblasts; 2) the beta-subunit of this receptor exhibits different migration in sodium dodecyl sulfate-polyacrylamide gels from either of those found in permissive cells; and 3) expression of this beta-subunit is developmentally regulated. This suggests that the inducible cell beta-subunit is a component of a stage-specific alpha 2 beta 2 IGF receptor subtype that functions as an IGF-II receptor.

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Effects of TRH and GRF administration on GH, TSH, T4 and T3 secretion in the lamb

Wrutniak¹,

Cabello²,

Charrier³

et al. 1987

Reprod. Nutr. Dévelop.

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Summary. The effects of various amounts of thyrotropin-releasing hormone (TRH) injected subcutaneously or intravenously (alone or in combination with growth hormonereleasing factor : GRF 1-44) on growth hormone (GH), thyroid-stimulating hormone (TSH), thyroxine (T 4 ) and triiodothyronine (T 3 ) were studied in the plasma of 2-week, 2-month and 3-month old lambs.1. After subcutaneous TRH administration, increases in plasma TSH, T 4 and T 3 levels were equivalent, whatever the amount of TRH used (1, 2, 5 or 10 0 pg/kg) . These responses lasted longer after 5 and 10 !g/kg.2. After intravenous TRH administration in 2-week old lambs, the maximal increase in plasma TSH levels occurred after the injection of 0.25 gg/kg. However, plasma T 4 and T 3 responses were not different, whatever the amount used. As previously, the amount of TRH affected the duration of these responses more than the magnitude of the pituitarythyroid axis response. 3. Whatever the injection route, amount used or animal age, TRH alone did not increase GH secretion in lambs. However, it slightly delayed the GH response to GRF.4. GRF did not affect the response of TSH and T 4 to TRH ; however it could inhibit T 3 increase.In conclusion, in contrast to results obtained in calves by Hodate et al. (1985), TRH did not enhance GH secretion in lambs but, as expected, induced sharp increases in plasma thyroid hormone levels. Its classification as a « growth factor » is therefore questionable, at least in lambs.Introduction.

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Rabbit slow and fast skeletal muscle-derived satellite myoblast phenotypes do not involve constitutive differences in the components of the insulin-like growth factor system

Barjot¹,

Navarro²,

Cotten³

et al. 1996

J. Cell. Physiol.

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The insulin-like growth factor (IGF) system is actively involved in the control of proliferation and differentiation of several myogenic cell lines, and phenotypic differences between myoblasts are associated with modifications of the equilibrium of the components of the IGF system. To determine whether this observation is a physiologic feature that also concerns the phenotypes of ex vivo adult satellite myoblasts in primary cell culture, we investigated the IGF system in rabbit slow-twitch muscle-derived satellite myoblasts (SSM), which differ phenotypically from fast-twitch muscle-derived satellite myoblasts (FSM) by their proliferation and differentiation kinetics in vitro. The expression of IGF-I and IGF-II were similar in SSM and FSM as well as their concentrations measured in cell-conditioned media. Ligand blotting of conditioned media samples indicated the presence of five IGF binding protein (IGFBP) species of Mr 37-40, 32, 30-31, 28, and 24 kDa. The 30-31 kDa doublet was visible in SSM-conditioned medium only and associated with the presence of a 22-kDa protein, which may represent a proteolytic fragment. In contrast, the 32-kDa band was observed in FSM conditioned medium only. The other IGFBP moieties were present in both SSM- and FSM-conditioned media. Cross-linking experiments revealed the presence of the M6P/IGF-II receptor on both SSM and FSM membranes. We also observed an IGF-I receptor form bearing unusual high affinity for IGF-II: the binding of [125I]IGF-I on this receptor was preferentially displaced by IGF-I but that of [125I]IGF-II was mostly inhibited by IGF-II, suggesting that the two tracers did not bind on the same epitopes. [125I]IGF-II binding to this receptor was greater on SSM than on FSM membranes. Autophosphorylation of WGA-purified receptors revealed an approximately 400-kDa band after SDS-PAGE under nonreducing conditions, which corresponded to the alpha 2 beta 2 form of the IGF-I receptor, and two beta subunit moieties of Mr 101 and 105 kDa under reducing conditions in both SSM and FSM extracts. Phosphorylation of the 105-kDa moiety was more intensively increased than that of the 101-kDa protein after growth factor stimulation. Basal phosphorylation state of the two beta subunits was similarly stimulated by IGF-I and IGF-II and less by insulin. Since both insulin and IGF-I receptors were expressed in FSM and SSM, one of the two beta subunits may actually correspond to that of the insulin receptor. We conclude that the IGF system is not considerably affected by the phenotypes of SSM and FSM. The differences observed, which mostly concern IGFBP species, more likely appear as regulatory adaptations than as phenotypic changes targeting the components of the IGF system.

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