β2-Adrenoceptors activation regulates muscle trophic-related genes following acute resistance exercise in mice

Resistance exercise (RE) training and pharmacological stimulation of β2-Adrenoceptors (β2-ARs) alone can promote muscle hypertrophy and prevent muscle atrophy. Although the activation of the sympathetic nervous system (SNS) is a well-established response during RE, the physiological contribution of the endogenous catecholamines and β2-ARs to the RE-induced changes on skeletal muscle protein metabolism remains unclear. This study investigated the effects of the β2-ARs blockade on the acute molecular responses induced by a single bout of RE in rodent skeletal muscles. Male C57BL6/J mice were subjected to a single bout of progressive RE (until exhaustion) on a vertical ladder under β2-AR blockade with ICI 118,551 (ICI; 10 mg kg-1, i. p.), or vehicle (sterile saline; 0.9%, i. p.), and the gene expression was analyzed in gastrocnemius (GAS) muscles by qPCR. We demonstrated that a single bout of RE acutely increased the circulating levels of stress-associated hormones norepinephrine (NE) and corticosterone (CORT), as well as the muscle phosphorylation levels of AMPK, p38 MAPK and CREB, immediately after the session. The acute increase in the phosphorylation levels of CREB was followed by the upregulation of CREB-target genes Sik1, Ppargc1a and Nr4a3 (a central regulator of the acute RE response), 3 h after the RE session. Conversely, β2-AR blockade reduced significantly the Sik1 and Nr4a3 mRNA levels in muscles of exercised mice. Furthermore, a single bout of RE stimulated the mRNA levels of the atrophic genes Map1lc3b and Gabarapl1 (autophagy-related genes) and Mstn (a well-known negative regulator of muscle growth). Unexpectedly, the gene expression of Igf-1 or Il-6 were not affected by RE, while the atrophic genes Murf1/Trim63 and Atrogin-1/Mafbx32 (ubiquitin-ligases) were increased only in muscles of exercised mice under β2-AR blockade. Interestingly, performing a single bout of RE under β2-AR blockade increased the mRNA levels of Mstn in muscles of exercised mice. These data suggest that β2-ARs stimulation during acute RE stimulates the hypertrophic gene Nr4a3 and prevents the overexpression of atrophic genes such as Mstn, Murf1/Trim63, and Atrogin-1/Mafbx32 in the first hours of postexercise recovery, indicating that he SNS may be physiologically important to muscle adaptations in response to resistance training

The urocortin 2 effects on protein metabolism in skeletal muscles of rodents

A urocortina 2 (Ucn2) é um peptídeo que pertence à família dos fatores liberadores de corticotrofina (CRF) e, assim como seu receptor específico CRF2R? (corticotropin releasing factor receptor type 2?), encontram-se expressos no músculo esquelético. Embora tenha sido demonstrado que o tratamento sistêmico com Ucn2 seja capaz de induzir hipertrofia e prevenir a perda de massa muscular, nada se conhece acerca dos mecanismos moleculares através dos quais a Ucn2 desempenha suas ações biológicas. O principal objetivo deste trabalho foi investigar o mecanismo de ação da Ucn2 no músculo esquelético de roedores para o aparecimento da resposta hipertrófica e a possível participação das vias de sinalização Akt/mTOR, Akt/Foxo e ERK1/2 neste efeito anabólico. Para isto foi utilizado o modelo de transfecção in vivo da Ucn2 pelo método da eletroporação em músculos tibialis anterior de camundongos. Nestes músculos foram quantificados: 1) o estado de fosforilação de componentes efetores destas vias; 2) moléculas sinalizadoras da via autofágica; 3) a taxa de síntese proteica in vivo e 4) a expressão de genes relacionados à atrofia muscular (atrogenes). Outra metodologia utilizada para verificar o efeito direto da Ucn2 na musculatura esquelética foi a incubação in vitro de músculos soleus e EDL isolados de roedores com este peptídeo a fim de investigar a taxa de degradação proteica total, bem como a atividade dos sistemas proteolíticos lisossomal¸ ubiquitina-proteassoma e dependente de Ca+2. A superexpressão in vivo da Ucn2 por 14 dias promoveu hipertrofia e preveniu a atrofia em músculos tibialis anterior de camundongos normais e submetidos ao modelo de desnervação motora isquiática.Resumo Este crescimento muscular induzido pela Ucn2 in vivo foi associado a ativação das vias de sinalização AMPc/PKA/CREB, AMPc/Epac, Akt/mTOR/S6, Akt/mTOR/4E-BP1 e ERK1/2/eIF4E com consequente estimulação da síntese proteica. Em concordância, utilizando uma técnica de manipulação genética in vivo, demonstramos que a hipertrofia promovida pela Ucn2 é dependente da estimulação das cascatas de sinalização ativadas por Akt e ERK1/2. Ademais, essa alteração fenotípica promovida pela Ucn2 induziu melhora da resistência à fadiga muscular, sendo este impacto funcional dependentente de ERK1/2, mas não de Akt. Além disso, a superexpressão da Ucn2 induziu \"shifting\" para o tipo de fibra oxidativa (tipo I), sendo esta plasticidade possivelmente mediada por PGC-1?, o que pode ter contribuído pelo menos em parte, para o efeito benéfico promovido pela Ucn2 na função muscular. O efeito antiatrófico da Ucn2 in vivo foi associado à estimulação da via Akt/Foxo1,3 concomitante com a redução da atividade transcricional de Foxo, resultando na diminuição da expressão da E3-ligase atrogin-1 e do gene autofágico LC3. Em paralelo, a Ucn2 in vivo promoveu inibição do fluxo autofágico, inferido pelo acúmulo das proteínas LC3-I, LC3-II e p62 nestes músculos. Corroborando os achados in vivo, os efeitos antiproteolíticos da Ucn2 in vitro parecem ser mediados pelo AMPc e envolvem a supressão da atividade do sistema lisossomal/autofágico em músculos EDL de ratos normais. Portanto, além da participação de efetores dowsntream do AMPc, como PKA e EPAC, diferentes quinases participam dos efeitos biológicos da Ucn2 na musculatura esquelética. Esses resultados são importantes para caracterizar novas estratégias terapêuticas capazes de atuar no combate à atrofia muscular em diversas situações catabólicas.Urocortin 2 (Ucn2) is a peptide that belongs to corticotrophin releasing factors (CRF) family and, as well as its specific receptor CRF2R? (corticotropin releasing factor receptor type 2?), are expressed in skeletal muscle. Although it has been demonstrated that Ucn2 systemic treatment is able to induce hypertrophy and prevent loss of muscle mass, nothing is known about the molecular mechanisms through which Ucn2 plays its biological actions. The main objective of this work was to investigate the Ucn2 mechanism of action in rodent skeletal muscle for the appearance of the hypertrophic response and the possible participation of Akt/mTOR, Akt/Foxo and ERK1/2 signaling pathways in this anabolic effect. For this, an in vivo transfection model of Ucn2 was used by the electroporation method in tibialis anterior muscles of mice. Were quantified in these muscles: 1) the phosphorylation state of effector components of these pathways; 2) signaling molecules of the autophagic pathway; 3) the rate of protein synthesis in vivo and 4) the expression of genes related to muscle atrophy (atrogenes). Another methodology used to verify the direct effect of Ucn2 in skeletal muscle was the incubation of soleus and EDL muscles isolated from rodents with this peptide in vitro in order to investigate the total rate of protein degradation, as well as the activity of the lysosomal, ubiquitin-proteasome and Ca+2 dependent proteolytic systems. Ucn2 overexpression in vivo for 14 days promoted hypertrophy and prevented atrophy in tibialis anterior muscles of normal mice and submitted to the sciatic motor denervation model. This muscle growth induced by Ucn2 in vivo was associated with the activation ofAbstract cAMP/PKA/CREB, cAMP/Epac, Akt/mTOR/S6, Akt/mTOR/4E-BP1 and ERK1/2/eIF4E signaling pathways with consequent stimulation of protein synthesis. In agreement, using a genetic manipulation technique in vivo, we demonstrated that the hypertrophy promoted by Ucn2 is dependent on the stimulation of the signaling cascades activated by Akt and ERK1/2. In addition, this phenotypic alteration promoted by Ucn2 induced an improvement in muscle fatigue resistance, being this functional impact dependent on ERK1/2, but not on Akt. Moreover, Ucn2 overexpression in vivo induced the shift to type I oxidative fiber, and this plasticity is possibly mediated by PGC-1?, which may have contributed at least in part to the beneficial effect promoted by Ucn2 in muscle function. The anti-atrophic effect of Ucn2 in vivo was associated with the stimulation of Akt/Foxo1,3 pathway concomitant with the reduction of Foxo transcriptional activity, resulting in a decrease in the expression of the atrogin-1 E3-ligase and of the autophagic gene LC3. In parallel, Ucn2 in vivo promoted inhibition of autophagic flow, inferred by the accumulation of LC3-I, LC3-II and p62 proteins in these muscles. Corroborating the in vivo findings, the antiproteolytic effects of Ucn2 in vitro appear to be mediated by cAMP and involve the suppression of lysosomal/autophagic system activity in EDL muscles of normal rats. Thus, in addition to the participation of cAMP dowsntream effectors, such as PKA and EPAC, different kinases participate in the biological effects of Ucn2 on skeletal muscle. These results are important to characterize new therapeutic strategies able to prevent muscular atrophy in several catabolic situations

Insulin/IGF1 signalling mediates the effects of β2‐adrenergic agonist on muscle proteostasis and growth

Abstract Background Stimulation of β2‐adrenoceptors can promote muscle hypertrophy and fibre type shift, and it can counteract atrophy and weakness. The underlying mechanisms remain elusive. Methods Fed wild type (WT), 2‐day fasted WT, muscle‐specific insulin (INS) receptor (IR) knockout (M‐IR−/−), and MKR mice were studied with regard to acute effects of the β2‐agonist formoterol (FOR) on protein metabolism and signalling events. MKR mice express a dominant negative IGF1 receptor, which blocks both INS/IGF1 signalling. All received one injection of FOR (300 μg kg−1 subcutaneously) or saline. Skeletal muscles and serum samples were analysed from 30 to 240 min. For the study of chronic effects of FOR on muscle plasticity and function as well as intracellular signalling pathways, fed WT and MKR mice were treated with formoterol (300 μg kg−1 day−1) for 30 days. Results In fed and fasted mice, one injection of FOR inhibited autophagosome formation (LC3‐II content, 65%, P ≤ 0.05) that was paralleled by an increase in serum INS levels (4‐fold to 25‐fold, P ≤ 0.05) and the phosphorylation of Akt (4.4‐fold to 6.5‐fold, P ≤ 0.05) and ERK1/2 (50% to two‐fold, P ≤ 0.05). This led to the suppression (40–70%, P ≤ 0.05) of the master regulators of atrophy, FoxOs, and the mRNA levels of their target genes. FOR enhanced (41%, P ≤ 0.05) protein synthesis only in fed condition and stimulated (4.4‐fold to 35‐fold, P ≤ 0.05) the prosynthetic Akt/mTOR/p70S6K pathway in both fed and fasted states. FOR effects on Akt signalling during fasting were blunted in both M‐IR−/− and MKR mice. Inhibition of proteolysis markers by FOR was prevented only in MKR mice. Blockade of PI3K/Akt axis and mTORC1, but not ERK1/2, in fasted mice also suppressed the acute FOR effects on proteolysis and autophagy. Chronic stimulation of β2‐adrenoceptors in fed WT mice increased body (11%, P ≤ 0.05) and muscle (15%, P ≤ 0.05) growth and downregulated atrophy‐related genes (30–40%, P ≤ 0.05), but these effects were abolished in MKR mice. Increases in muscle force caused by FOR (WT, 24%, P ≤ 0.05) were only partially impaired in MKR mice (12%, P ≤ 0.05), and FOR‐induced slow‐to‐fast fibre type shift was not blocked at all in these animals. In MKR mice, FOR also restored the lower levels of muscle SDH activity to basal WT values and caused a marked reduction (57%, P ≤ 0.05) in the number of centrally nucleated fibers. Conclusions NS/IGF1 signalling is necessary for the anti‐proteolytic and hypertrophic effects of in vivo β2‐adrenergic stimulation and appears to mediate FOR‐induced enhancement of protein synthesis. INS/IGF1 signalling only partially contributes to gain in strength and does not mediate fibre type transition induced by FOR