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Discussione: Le risposte ormonali all'allenamento con i pesi

  1. #1
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    Predefinito Le risposte ormonali all'allenamento con i pesi

    Nell'ultimo trentennio, sono stati intrapresi una serie di studi per identificare quali sono le risposte ormonali a fronte di un allenamento coi pesi.

    Potevo iniziare il post con un titolo magari più suggestivo, del tipo "Qual è la strada per gonfiarsi ?", poi ho pensato che la risposta sarebbe stata "buttarsi nudi in un alveare", perciò sono stato molto ma molto più classico.

    Sgombriamo subito il campo: gli ormoni che vengono prodotti dal nostro organismo come risposta ad un robusto allenamento coi pesi non sono molti, ma sicuramente è interessante vedere quali effettivamente comportano l'avvio del meccanismo anaboilico di costruzione di nuovo tessuto muscolare (cioè l'ipertrofia muscolare).

    Gli ormoni che vengono prodotti sono GH, Testosterone, Cortisolo, Catecolamine varie e Beta-endorfine (queste sono quelle che danno sollievo nello spogliatoio).

    Nel mentre, insulina e ormoni tiroidei (T3 e T4) diminuiscono o rimangono stabili. Non sto a spiegare quali siano gli scopi di ciascuno di essi poiché possono essere banalmente reperiti con Wikipedia.

    Oggi come oggi, non è più così chiaro che il testosterone sia talmente anabolico quanto gli studi e le terapie di quarant'anni fa facessero sperare, mentre è forse più chiara la sua azione di contrasto al catabolico effetto del cortisolo. Inoltre, l'insulina non gioca un ruolo fondamentale nell'anabolismo, quanto invece costituisce l'ormone anticatabolico per eccellenza.

    E', viceversa, appurato recentemente il ruolo chiave giocato dall'asse somatotropico (cioè il ruolo combinato del Growth Hormone e del Insuline-like Growth Factor-I). Gli eventi stimolatori del GH sono il sonno, l'esercizio fisico, lo stress e l'iperaminoacidemia postprandiale.

    Naturalmente, noi prendiamo come riferimento proprio il rilascio di GH e del suo mediatore IGF-I DOPO l'esercizio fisico, a livello epatico. Tuttavia, la domanda è "perché l'anabolismo muscolare avviene a livello del solo muscolo esercitato ? Risposta: è l'altro ormone isoforma del IGF-I, cioè il Mechano Growth Factor (MGF) che viene prodotto nel tessuto muscolare solo quando meccanicamente stimolato o danneggiato. Questo è l'ormone che avvia la ricostruzione muscolare, mediante potente stimolo della resintesi proteica.

    Quindi è l'asse GH-MGF che vi procura la soddisfazione dell'ipertrofia post allenamento, avviando l'attivazione delle cellule progenitrici muscolari.

    G Goldspink, "Research on mechano growth factor: its potential for optimising physical training as well as misuse in doping", British Journal of Sports Medicine 2005
    http://bjsm.bmj.com/cgi/content/full/39/11/787

  2. #2
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    Direi di postare lo studio in informazione scientifica.

  3. #3
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    Research on mechano growth factor: its potential for optimising physical training as well as misuse in doping

    </STRONG>G Goldspink
    Correspondence to:
    Correspondence to:
    Professor Goldspink
    Department of Surgery, Royal Free and University College Medical School, Hampstead Campus, Rowland Hill Street, London NW3 2PF, UK; g.goldspink@medsch.ucl.ac.uk

    Mechano growth factor can produce rapid increases in muscle and strength, giving it considerable therapeutic and doping potential


    Abbreviations: IGF, insulin-like growth factor; MGF, mechano growth factor

    Keywords: mechano growth factor (MGF); physical training; doping

    The sequencing of the human genome showed that there are only about 40 000 genes. However, there are many more proteins. This is because some genes are spliced to produce different protein/peptides which usually have different biological functions. Combining physiological and molecular biology methods made it possible for our team to identify and characterise a local muscle growth/repair factor (MGF). This we found is derived from the insulin-like growth factor I (IGF-I) gene by alternative splicing, but, owing to a reading frame shift, MGF has a unique C-terminal peptide. After resistance exercise, the IGF-I gene is spliced towards MGF which "kick starts" hypertrophy and repair of local muscle damage by activating the muscle stem cells as well as anabolic processes. Interestingly, loss of muscle mass in old age and in certain diseases is associated with an impaired ability to express MGF. In these conditions it seems that the muscle stem (satellite) cell pool is not adequately replenished.
    CLONING OF MGF AND OTHER HUMAN MUSCLE IGF-I SPLICE VARIANTS

    For some time it has been apparent that muscle mass and strength must be under the control of local growth factors because if one exercises a particular muscle, it is that muscle and not all the muscles of the body that undergo hypertrophy. A little over 10 years ago, our group set out to clone the factor(s) that are involved in autocrine regulation of muscle mass. For this purpose we needed to have an animal model in which we could make muscle grow rapidly. Previous work had shown that the tibialis anterior muscle in the mature rabbit, when held in the stretched position by plaster cast immobilisation combined with low voltage electrical stimulation, increased in mass by 35% in just over a week.1 It was known that muscles adapt to a new functional length by adding sarcomeres in series at the ends of the existing myofibrils. However, if muscles are also subjected to electrical stimulation, they increase in girth as well as length. Total RNA in these muscles was found to increase by about four times within a couple of days. We also studied specific messenger RNAs using a technique known as differential display and detected an mRNA that was expressed in exercised but not in resting muscles.2 This was converted into cDNA and sequenced, and the genome database showed that it was derived from the IGF-I gene. This local type of IGF-I we called mechano growth factor (MGF) as it was expressed in response to mechanical stimuli and because it has a different downstream (C-terminal) sequence from the liver or systemic types of IGF-I. From physiological experiments it became apparent that the muscle forms of IGF-I have different functions and that in the case MGF its unique C-terminal peptide has a special function of activating and replenishing the muscle stem (satellite) cell pool. As with the central nervous system, skeletal muscle is a post-mitotic tissue. Therefore there has to be an effective local cellular repair mechanism otherwise cell death will ensue. The extra nuclei required for growth and repair come from the muscle stem (satellite) cells fusing with the muscle fibres. This is also one of the early events in the hypertrophy process. MGF is responsible for replenishing the pool of muscle stem cells,3,4 and this provides the means by which strength adaptation occurs after exercise and/or local muscle damage.
    SPLICING OF THE IGF-I GENE IN RESPONSE TO EXERCISE AND HORMONES

    Previous research had shown that resistance exercise which results in muscle hypertrophy is associated with an increase in IGF-I expression.2,5,6 However, these studies failed to distinguish between the different types of IGF-I. As mentioned above, the way MGF was discovered was by studying the RNA transcript of exercised and non-exercised muscle.2 Shortly after this, the group of Ken Baldwin and Greg Adams in the United States7 showed that MGF is expressed earlier than IGF-IEa in response to exercise. Using specific primers (gene probes), we measured the mRNA concentrations of MGF and IGF-IEa using quantitative polymerase chain reaction mechanically in overloaded rodent muscle8 as well as in human volunteers in which muscle biopsy specimens were taken 2.5 hours after a single bout of high intensity exercise of knee extensor muscles.9 In young muscle, MGF mRNA concentrations were significantly increased as a result of resistance exercise, but no significant change was observed in older muscle when subjected to the same degree of mechanical overload. However, elderly male volunteers when given growth hormone combined with exercise training produced increased concentrations of MGF,10 which could be correlated with increased muscle cross sectional area as determined from computed tomography scans. Figure 1 shows the way the IGF-I gene is spliced after exercise and in response to hormones.


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    Figure 1 Splicing of the insulin-like growth factor (IGF) gene to produce different forms of IGF-I in human muscle. Mechano growth factor (MGF) is produced locally in response to exercise and it differs from the two systemic types of IGF-I as the 49 base insert in the exon creates a reading frame shift so that the downstream or C-terminal peptide sequence is different. This unique peptide has been found to be involved in activating the muscle stem cells and to "kick start" the tissue repair and/or hypertrophy processes. In the elderly, who are growth hormone (GH) deficient, there is an improvement in MGF expression when administration of recombinant human GH is combined with exercise. Reg Seqn, Regulatory sequence.

    It was noted that in exon 5 of MGF in the human there is a 49 base insert (52 in the rat) which results in a reading frame shift. Amino acids are coded for by triplets of bases. As the exon 5 insert is not a multiple of 3, the downstream peptide sequence of MGF is different from that of the other kinds of IGF-I. This region has important functional consequences as the carboxy peptide of some IGF-I isoforms is involved in the recognition of the specific binding proteins that stabilise these growth factors. At least two forms of systemic IGF-I are expressed by muscle even at rest. However, it is apparent that in response to exercise and/or damage, MGF is expressed locally and that it has a dual action. This includes activating the muscle stem cell pool through its C-terminal domain (encoded in exons 5 and 6) and increasing anabolic effects as the result of its IGF-I receptor binding domain (encoded in exons 3 and 4), which all the IGF-I genes possess.
    GENE TRANSFER AND ENHANCEMENT OF MUSCLE MASS AND STRENGTH

    One of the methods we used to establish the biological action of MGF was to engineer a gene into which its cDNA was inserted into a vector. To our surprise a single intramuscular injection into a mouse muscle resulted in a 25% increase in mean muscle fibre cross section area within three weeks.11 Similar experiments have been carried out using the systemic or liver type of IGF-I in an adenoviral vector under the control of a muscle regulatory sequence. However, this took four months to produce a 15% increase and is probably due to the anabolic effect of IGF-I, which is common to all the splice variants.12 The use of the DNA of IGF-I and particularly MGF is therefore a prime candidate for gene doping for enhancement of athletic performance. This presents the anti-doping agencies with a challenge, as the range of vectors available for use in engineering these genes enable them to be designed so that the gene product can be delivered locally or systemically and also so that they can be switched on and switched off after they have been introduced into the body. Our research unit is using the extremely sensitive and specific reverse transcriptase polymerase chain reaction to amplify a vector and/or the enhancer cDNA as a means of detecting gene doping. We also know that MGF as well as IGF-I exist as class I and class 2 isoforms and that the ratios of these in serum change if they are introduced as the peptide or by gene transfer. Therefore there is the possibility of detecting the misuse of these strength generating substances even if delivered in the form of "gene doping".


    1. <LI value=1>Goldspink G, Scutt A, Loughna P, et al. Gene expression in skeletal muscle in response to mechanical signs. Am J Physiol 1992;262:R326–63. <LI value=2>Yang SY, Alnaqeeb M, Simpson H, et al. Cloning and characterisation of an IGF-I isoform expressed in skeletal muscle subjected to stretch. J Muscle Res Cell Motil 1996;17:487–95.[CrossRef][Medline] <LI value=3>Yang SY, Goldspink G. Different roles of the IGF-IEc peptide (MGF) and mature IGF-I in myoblast proliferation and differentiation. FEBS Lett 2002;522:156–60.[CrossRef][Medline] <LI value=4>Hill M, Goldspink G. Expression and splicing of the insulin-like growth factor gene in rodent muscle is associated with muscle satellite (stem) cell activation following local tissue damage. J Physiol 2003;549:409–18.[Abstract/Free Full Text] <LI value=5>Yan Z, Biggs RB, Booth FW. Insulin-like growth factor immunoreactivity increases in muscle after acute eccentric contractions. J Appl Physiol 1993;74:410–14.[Abstract/Free Full Text] <LI value=6>Czerwinski SM, Martin JM, Bechtel PJ. Modulation of IGF mRNA abundance during stretch-induced skeletal muscle hypertrophy and regression. J Appl Physiol 1994;76:2026–30.[Abstract/Free Full Text] <LI value=7>Haddad F, Adams GR. Selected contribution: acute cellular and molecular responses to resistance exercise. J Appl Physiol 2002;93:394–403.[Abstract/Free Full Text] <LI value=8>Owino V, Yang SY, Goldspink G. Age-related loss of skeletal muscle function and the inability to express the autocrine form of insulin-like growth factor-1 (MGF) in response to mechanical overload. FEBS Lett 2001;505:259–63.[CrossRef][Medline] <LI value=9>Hameed M, Orrell RW, Cobbold M, et al. Expression of IGF-I splice variants in young and old human skeletal muscle after high resistance exercise. J Physiol 2003;547:247–54.[Abstract/Free Full Text] <LI value=10>Hameed M, Lange KH, Andersen JL, et al. The effect of recombinant human growth hormone and resistance training on IGF-I mRNA expression in the muscles of elderly men. J Physiol 2004;555:231–40.[Abstract/Free Full Text] <LI value=11>Goldspink G, Yang SY. Method of treating muscular disorders. United States Patent. Patent No US 6,221,842 B1, Apr 24 2001.
    2. Barton-Davis E, Shoturma DI, Musaro A, et al. Viral mediated expression of insulin-like growth factor-I blocks the aging-related loss of skeletal muscle function. Proc Natl Acad Sci USA 1998;95:15603–7.[Abstract/Free Full Text]

  4. #4
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    Bell'articolo

    Citazione Originariamente Scritto da tattoos Visualizza Messaggio
    E', viceversa, appurato recentemente il ruolo chiave giocato dall'asse somatotropico (cioè il ruolo combinato del Growth Hormone e del Insuline-like Growth Factor-I). Gli eventi stimolatori del GH sono il sonno, l'esercizio fisico, lo stress e l'iperaminoacidemia postprandiale.
    Aggiungo la febbre.
    E aggiungo che e' stimolatd da bassi livelli di glicemia dall'ormone GH-RH( viceversa inibito da alti livelli di glicemia e bassi livelli di a.a. dalla Somatostatina).
    Specifico che lo stress attiva il s.n.a. e quindi adrenalina e cortisolo ( cosi' come avevi detto tu per l'eserizio fisico ). Lo dico giusto per evitare che qualcuno "si stressi" pensando di crescere

  5. #5
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    Molto dubbioso l'iperaminoacidemia postprandiale

    Citazione Originariamente Scritto da tattoos Visualizza Messaggio
    Gli eventi stimolatori del GH sono il sonno, l'esercizio fisico, lo stress e l'iperaminoacidemia postprandiale.
    cosa s'intende perl'iperaminoacidemia postprandiale?
    nella pratica quali fattori aiutano ad ottenerla e quali tendono a limitarla?

  6. #6
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    L'aminoacidemia postprandiale si eleva nel momento in cui si è svolta la catabolizzazione delle proteine in aminoacidi, mediante gli enzimi proteolitici, che vengono immensi nel torrente ematico.

    Perciò, l'iperaminoacidemia la raggiungi pappandoti una bistecca o ingurgitando dei BCAA.

  7. #7
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    Ciao Tattoos,

    non conoscevo questo Mechano Growth Factor e che forse sia lui stesso il responsabile della rapida crescita muscolare e della forza muscolare attivando tutti i processi di ricostruzione muscolare.

    Praticamente sarebbe l'operaio che fisicamente mette i mattoni e fa' su' casa quando questa viene danneggiata.

    Appurato che sia sempre necessario avere buone scorte di energia per lavorare e di mattoni per costruire (Kcal e proteine) questo MGF viene stimolato quando il muscolo è danneggiato.

    Le mie domande sono queste:

    - Un allenamento con eccentriche enfatizzate (ovviamente utilizzando carichi medio-alti) creano molto danno alle fibre muscolari. Un allenamento del genere rispetto ad uno con eccentriche poco enfatizzate stimola piu' MGF come conseguenza del maggior danno procurato ai muscoli?

    - Il GH viene prodotto moltissimo come risposta ad un incremento di acido lattico nei muscoli o comunque viene prodotto soprattutto in allenamenti dove enfatizziamo l'eccentrica (cioe' procuriamo maggior danno ai muscoli). Il MGF cresce a cavallo col GH oppure ha un suo ruolo a parte "dopo" l'allenamento per ricostruire il tutto?

    La prima domanda mi è sorta leggendo questo.
    "Previous research had shown that resistance exercise which results in muscle hypertrophy is associated with an increase in IGF-I expression.2,5,6"

    La seconda leggendo questo.
    "However, elderly male volunteers when given growth hormone combined with exercise training produced increased concentrations of MGF,10 which could be correlated with increased muscle cross sectional area as determined from computed tomography scans"

    Scusate se le domande sono banali, ma l'argomento è molto interessante.

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