Daniel Béchet

Class III phosphoinositide 3-kinase--Beclin1 complex mediates the amino acid-dependent regulation of autophagy in C2C12 myotubes.

Increased proteolysis contributes to muscle atrophy that prevails in many diseases. Elucidating the signalling pathways responsible for this activation is of obvious clinical importance. Autophagy is a ubiquitous degradation process, induced by amino acid starvation, that delivers cytoplasmic components to lysosomes. Starvation markedly stimulates autophagy in myotubes, and the present studies investigate the mechanisms of this regulation. In C(2)C(12) myotubes incubated with serum growth factors, amino acid starvation stimulated autophagic proteolysis independently of p38 and p42/p44 mitogen-activated protein kinases, but in a PI3K (phosphoinositide 3-kinase)-dependent manner. Starvation, however, did not alter activities of class I and class II PI3Ks, and was not sufficient to affect major signalling proteins downstream from class I PI3K (glycogen synthase kinase, Akt/protein kinase B and protein S6). In contrast, starvation increased class III PI3K activity in whole-myotube extracts. In fact, this increase was most pronounced for a population of class III PI3K that coimmunoprecipitated with Beclin1/Apg6 protein, a major determinant in the initiation of autophagy. Stimulation of proteolysis was reproduced by feeding myotubes with synthetic dipalmitoyl-PtdIns3 P, the class III PI3K product. Conversely, protein transfection of anti-class III PI3K inhibitory antibody into starved myotubes inverted the induction of proteolysis. Therefore, independently of class I PI3K/Akt, protein S6 and mitogen-activated protein kinase pathways, amino acid starvation stimulates proteolysis in myotubes by regulating class III PI3K-Beclin1 autophagic complexes.

The ubiquitin-proteasome system and skeletal muscle wasting.

The ubiquitin-proteasome system (UPS) is believed to degrade the major contractile skeletal muscle proteins and plays a major role in muscle wasting. Different and multiple events in the ubiquitination, deubiquitination and proteolytic machineries are responsible for the activation of the system and subsequent muscle wasting. However, other proteolytic enzymes act upstream (possibly m-calpain, cathepsin L, and/or caspase 3) and downstream (tripeptidyl-peptidase II and aminopeptidases) of the UPS, for the complete breakdown of the myofibrillar proteins into free amino acids. Recent studies have identified a few critical proteins that seem necessary for muscle wasting {i.e. the MAFbx (muscle atrophy F-box protein, also called atrogin-1) and MuRF-1 [muscle-specific RING (really interesting new gene) finger 1] ubiquitin-protein ligases}. The characterization of their signalling pathways is leading to new pharmacological approaches that can be useful to block or partially prevent muscle wasting in human patients.

Leucine Limitation Induces Autophagy and Activation of Lysosome-dependent Proteolysis in C2C12 Myotubes through a Mammalian Target of Rapamycin-independent Signaling Pathway

Loss of muscle mass usually characterizes different pathologies (sepsis, cancer, trauma) and also occurs during normal aging. One reason for muscle wasting relates to a decrease in food intake. This study addressed the role of leucine as a regulator of protein breakdown in mouse C2C12 myotubes and aimed to determine which cellular responses regulate the process. Determination of the rate of protein breakdown indicated that leucine is one key regulator of this process in myotubes because starvation for this amino acid is responsible for 30–40% of the total increase generated by total amino acid starvation. Leucine restriction rapidly accelerates the rate of protein breakdown (+11 to 15% (p < 0.001) after 1 h of starvation) in a dose-dependent manner. By using various inhibitors, evidence is provided that acceleration of protein catabolism results mainly from an induction of autophagy, activation of lysosome-dependent proteolysis, without modification of mRNA levels encoding the lysosomal cathepsins B, L, or D. Those results suggest that autophagy is an essential cellular response for increasing protein breakdown in muscle following food deprivation. Induction of autophagy precedes a decrease in global protein synthesis (−20% to −30% (p < 0.001)) that occurs after 3 h of leucine starvation. Inhibition of the mammalian target of rapamycin (mTOR) activity does not abolish the effect of leucine starvation and the level of phosphorylated ribosomal S6 protein is not affected by leucine withdrawal. These latter data provide clear evidence that the mTOR signaling pathway is not involved in the mediation of leucine effects on both protein synthesis and degradation in C2C12 myotubes.

Differential proteome analysis of aging in rat skeletal muscle

To identify the mechanisms underlying muscle aging, we have undertaken a high‐resolution differential proteomic analysis of gastrocnemius muscle in young adults, mature adults, and old LOU/c/jall rats. Two‐dimensional gel electrophoresis and subsequent MALDI‐ToF mass spectrometry analyses led to the identification of 40 differentially expressed proteins. Strikingly, most differences characterized old (30‐month) animals, whereas young (7‐month) and mature (18‐month) adults exhibited similar patterns of expression. Important modifications in contractile (actin, myosin light‐chains, troponins‐T) and cytoskeletal (desmin, tubulin) proteins, and in essential regulatory proteins (gelsolin, myosin binding proteins, CapZ‐β, P23), likely account for dysfunctions in old muscle force generation and speed of contraction. Other features support decreases in cytosolic (triose‐phosphate isomerase, enolase, glycerol‐3‐P dehydrogenase, creatine kinase) and mitochondrial (isocitrate dehydrogenase, cytochrome‐c oxidase) energy metabolisms. Muscle aging is often associated with increased oxidative stress. Accordingly, we observed differential regulation of molecular chaperones (hsp20, hsp27, reticuloplasmin ER60) and of proteins implicated in reactive aldehyde detoxification (aldehyde dehydrogenase, glutathione transferase, glyoxalase). We further noticed up‐regulation of proteins involved in transcriptional elongation (RNA capping protein) and RNA‐editing (Apobec2). Most of these proteins were previously unrecognized as differentially expressed in old muscles, and they represent novel starting points for elucidating the mechanisms of muscle aging.

A leucine-supplemented diet restores the defective postprandial inhibition of proteasome-dependent proteolysis in aged rat skeletal muscle

We tested the hypothesis that skeletal muscle ubiquitin–proteasome‐dependent proteolysis is dysregulated in ageing in response to feeding. In Experiment 1 we measured rates of proteasome‐dependent proteolysis in incubated muscles from 8‐ and 22‐month‐old rats, proteasome activities, and rates of ubiquitination, in the postprandial and postabsorptive states. Peptidase activities of the proteasome decreased in the postabsorptive state in 22‐month‐old rats compared with 8‐month‐old animals, while the rate of ubiquitination was not altered. Furthermore, the down‐regulation of in vitro proteasome‐dependent proteolysis that prevailed in the postprandial state in 8‐month‐old rats was defective in 22‐month‐old rats. Next, we tested the hypothesis that the ingestion of a 5% leucine‐supplemented diet may correct this defect. Leucine supplementation restored the postprandial inhibition of in vitro proteasome‐dependent proteolysis in 22‐month‐old animals, by down‐regulating both rates of ubiquitination and proteasome activities. In Experiment 2, we verified that dietary leucine supplementation had long‐lasting effects by comparing 8‐ and 22‐month‐old rats that were fed either a leucine‐supplemented diet or an alanine‐supplemented diet for 10 days. The inhibited in vitro proteolysis was maintained in the postprandial state in the 22‐month‐old rats fed the leucine‐supplemented diet. Moreover, elevated mRNA levels for ubiquitin, 14‐kDa ubiquitin‐conjugating enzyme E2, and C2 and X subunits of the 20S proteasome that were characteristic of aged muscle were totally suppressed in 22‐month‐old animals chronically fed the leucine‐supplemented diet, demonstrating an in vivo effect. Thus the defective postprandial down‐regulation of in vitro proteasome‐dependent proteolysis in 22‐month‐old rats was restored in animals chronically fed a leucine‐supplemented diet.

Skeletal muscle proteolysis in aging

Purpose of reviewTo understand age-related changes in proteolysis and apoptosis in skeletal muscle in relation to oxidative stress and mitochondrial alterations. Recent findingsDuring aging, a progressive loss of muscle mass (sarcopenia) has been described in both human and rodents. Sarcopenia is attributable to an imbalance between protein synthesis and degradation or between apoptosis and regeneration processes or both. Major age-dependent alterations in muscle proteolysis are a lack of responsiveness of the ubiquitin–proteasome-dependent proteolytic pathway to anabolic and catabolic stimuli and alterations in the regulation of autophagy. In addition, increased oxidative stress leads to the accumulation of damaged proteins, which are not properly eliminated, aggregate, and in turn impair proteolytic activities. Finally, the mitochondria-associated apoptotic pathway may be activated. These age-induced changes may contribute to sarcopenia and decreased ability of old individuals to recover from stress. SummaryAlterations in proteasome-dependent or lysosomal proteolysis, increased oxidative stress, mitochondrial dysfunction, and apoptosis presumably contribute to the development of sarcopenia.

Muscle actin is polyubiquitinylated in vitro and in vivo and targeted for breakdown by the E3 ligase MuRF1

Muscle atrophy prevails in numerous diseases (cancer cachexia, renal failure, infections, etc.), mainly results from elevated proteolysis, and is accelerated by bed rest. This largely contributes to increased health costs. Devising new strategies to prevent muscle wasting is a major clinical challenge. The ubiquitin proteasome system (UPS) degrades myofibrillar proteins, but the precise mechanisms responsible for actin breakdown are surprisingly poorly characterized. We report that chimeric flag‐actin was destabilized and polyubiquitinylated in stably transfected C2C12 myotubes treated with the catabolic agent dexa‐methasone (1 μM) and that only proteasome inhibitors blocked its breakdown. Actin polyubiquitinylation was also detected in wild‐type C2C12 myotubes and human muscle biopsies from control participants and patients with cancer. The muscle‐specific E3 ubiquitin ligase MuRF1 is up‐regulated in catabolic conditions and polyubiquitinylates components of the thick filament. We also demonstrate that recombinant GST‐MuRF1 physically interacted and polyubiquitinylated actin in vitro and that MuRF1 is a critical component for actin breakdown, since MuRF1 siRNA stabilized flag‐actin. These data identify unambiguously the abundant contractile protein actin as a target of the UPS in skeletal muscle both in vitro and in vivo, further supporting the need for new strategies blocking specifically the activation of this pathway in muscle wasting conditions.—Polge, C., Heng, A.‐E., Jarzaguet, M., Ventadour, S., Claustre, A., Combaret, L., Béchet, D., Matondo, M., Uttenweiler‐Joseph, S., Monsarrat, B., Attaix, D., Taillandier, D. Muscle actin is polyubiquitinylated in vitro and in vivo and targeted for breakdown by the E3 ligase MuRF1. FASEB J. 25, 3790–3802 (2011). www.fasebj.org

Acidic and basic fibroblast growth factor mRNAS are expressed by skeletal muscle satellite cells

We postulated that Fibroblast Growth Factor (FGF) involved in fetal or regenerative morphogenesis of skeletal muscle originated from this tissue. Using a bovine retina cDNA probe encoding acidic FGF, we showed that growing muscles from bovine fetuses express this mRNA, but that this expression is reduced in neonate muscles. Cultures of proliferating satellite cells isolated from adult rat muscles expressed aFGF mRNA strongly but bFGF mRNA weakly; these mRNAs disappeared in cells differentiated into myotubes. 10(-7)M 12-O-tetradecanoyl phorbol -13-acetate (TPA) increased aFGF mRNA expression in both proliferating and differentiated satellite cells. Contrastingly, proliferating L6 myogenic cells only expressed aFGF mRNA significantly under TPA treatment. Therefore, the satellite cells did seem to be a possible source for FGF, especially aFGF, which might regulate the myogenic process.

Glucocorticoids regulate mRNA levels for subunits of the 19 S regulatory complex of the 26 S proteasome in fast-twitch skeletal muscles.

Circulating levels of glucocorticoids are increased in many traumatic and muscle-wasting conditions that include insulin-dependent diabetes, acidosis, infection, and starvation. On the basis of indirect findings, it appeared that these catabolic hormones are required to stimulate Ub (ubiquitin)-proteasome-dependent proteolysis in skeletal muscles in such conditions. The present studies were performed to provide conclusive evidence for an activation of Ub-proteasome-dependent proteolysis after glucocorticoid treatment. In atrophying fast-twitch muscles from rats treated with dexamethasone for 6 days, compared with pair-fed controls, we found (i) increased MG132-inhibitable proteasome-dependent proteolysis, (ii) an enhanced rate of substrate ubiquitination, (iii) increased chymotrypsin-like proteasomal activity of the proteasome, and (iv) a co-ordinate increase in the mRNA expression of several ATPase (S4, S6, S7 and S8) and non-ATPase (S1, S5a and S14) subunits of the 19 S regulatory complex, which regulates the peptidase and the proteolytic activities of the 26 S proteasome. These studies provide conclusive evidence that glucocorticoids activate Ub-proteasome-dependent proteolysis and the first in vivo evidence for a hormonal regulation of the expression of subunits of the 19 S complex. The results suggest that adaptations in gene expression of regulatory subunits of the 19 S complex by glucocorticoids are crucial in the regulation of the 26 S muscle proteasome.

The ubiquitin-proteasome and the mitochondria-associated apoptotic pathways are sequentially downregulated during recovery after immobilization-induced muscle atrophy

Immobilization produces morphological, physiological, and biochemical alterations in skeletal muscle leading to muscle atrophy and long periods of recovery. Muscle atrophy during disuse results from an imbalance between protein synthesis and proteolysis but also between apoptosis and regeneration processes. This work aimed to characterize the mechanisms underlying muscle atrophy and recovery following immobilization by studying the regulation of the mitochondria-associated apoptotic and the ubiquitin-proteasome-dependent proteolytic pathways. Animals were subjected to hindlimb immobilization for 4-8 days (I4 to I8) and allowed to recover after cast removal for 10-40 days (R10 to R40). Soleus and gastrocnemius muscles atrophied from I4 to I8 to a greater extent than extensor digitorum longus and tibialis anterior muscles. Gastrocnemius muscle atrophy was first stabilized at R10 before being progressively reduced until R40. Polyubiquitinated proteins accumulated from I4, whereas the increased ubiquitination rates and chymotrypsin-like activity of the proteasome were detectable from I6 to I8. Apoptosome and caspase-3 or -9 activities increased at I6 and I8, respectively. The ubiquitin-proteasome-dependent pathway was normalized early when muscle stops to atrophy (R10). By contrast, the mitochondria-associated apoptotic pathway was first downregulated below basal levels when muscle started to recover at R15 and completely normalized at R20. Myf 5 protein levels decreased from I4 to I8 and were normalized at R10. Altogether, our results suggest a two-stage process in which the ubiquitin-proteasome pathway is rapidly up- and downregulated when muscle atrophies and recovers, respectively, whereas apoptotic processes may be involved in the late stages of atrophy and recovery.