Increased ATP-ubiquitin-dependent proteolysis in skeletal muscles of tumor-bearing rats.

Little information is available on proteolytic pathways responsible for muscle wasting in cancer cachexia. Experiments were carried out in young rats to demonstrate whether a small (< 0.3% body weight) tumor may activate the lysosomal, Ca(2+)-dependent, and/or ATP-ubiquitin-dependent proteolytic pathway(s) in skeletal muscle. Five days after tumor implantation, protein mass of extensor digitorum longus and tibialis anterior muscles close to a Yoshida sarcoma was significantly reduced compared to the contralateral muscles. According to in vitro measurements, protein loss totally resulted from increased proteolysis and not from depressed protein synthesis. Inhibitors of lysosomal and Ca(2+)-dependent proteases did not attenuate increased rates of proteolysis in the atrophying extensor digitorum longus. Accordingly, cathepsin B and B+L activities, and mRNA levels for cathepsin B were unchanged. By contrast, ATP depletion almost totally suppressed the increased protein breakdown. Furthermore, mRNA levels for ubiquitin, 14 kDa ubiquitin carrier protein E2, and the C8 or C9 proteasome subunits increased in the atrophying muscles. Similar adaptations occurred in the muscles from cachectic animals 12 days after tumor implantation. These data strongly suggest that the activation of the ATP-ubiquitin-dependent proteolytic pathway is mainly responsible for muscle atrophy in Yoshida sarcoma-bearing rats.

Regulation of ATP-ubiquitin-dependent proteolysis in muscle wasting.

Protein breakdown plays a major role in muscle growth and atrophy. However, the regulation of muscle proteolysis by nutritional, hormonal and mechanical factors remains poorly understood. In this review, the methods available to study skeletal muscle protein breakdown, and our current understanding of the role of 3 major proteolytic systems that are well characterized in this tissue (ie the lysosomal, Ca(2+)-dependent and ATP-ubiquitin-dependent proteolytic pathways) are critically analyzed. ATP-ubiquitin-dependent proteolysis is discussed in particular since recent data strongly suggest that this pathway may be responsible for the loss of myofibrillar proteins in many muscle-wasting conditions in rodents. In striking contrast to either the lysosomal or the Ca(2+)-dependent processes, ATP-ubiquitin-dependent protein breakdown is systematically influenced by nutritional manipulation (fasting and dietary protein deficiency), muscle activity and disuse (denervation atrophy and simulated weightlessness), as well as pathological conditions (sepsis, cancer, trauma and acidosis). The hormonal control of this pathway, its possible substrates, rate-limiting step, and functional associations with other proteolytic systems are discussed.

Euglycemic hyperinsulinemia and hyperaminoacidemia decrease skeletal muscle ubiquitin mRNA in goats.

Insulin inhibits protein breakdown at the whole body level, but neither the tissues nor the proteolytic pathways on which insulin exerts its antiproteolytic effect are well characterized. We measured the effects of insulin on mRNA levels for cathepsin D and m-calpain (a lysosomal and Ca2(+)-dependent proteinase, respectively) and ubiquitin (a component of ubiquitin-dependent proteolysis) in skeletal muscle, skin, liver, and intestine. We used a 6-h hyperinsulinemic, euglycemic, and hyperaminoacidemic clamp in goats, a species in which insulin markedly inhibited whole body protein breakdown under similar conditions [S. Tesseraud, J. Grizard, E. Debras, I. Papet, Y. Bonnet, G. Bayle, and C. Champredon. Am. J. Physiol. 265 (Endocrinol. Metab. 28): E402-E413, 1993]. Hyperinsulinemia and hyperaminoacidemia had no effect on cathepsin D, m-calpain, and ubiquitin mRNA levels in liver, skin, and jejunum. In contrast, depressed ubiquitin mRNA levels were seen in skeletal muscle without any concomitant reduction in mRNA levels for cathepsin D, m-calpain, and other components of the ubiquitin-dependent proteolytic pathway. The reduced ubiquitin mRNA levels in skeletal muscle may represent a possible mechanism explaining the antiproteolytic effect of insulin in vivo.