Rapid Publication Muscle Protein Waste in Tumor-bearing Rats Is Effectively Antagonized by a 12-Adrenergic Agonist (Clenbuterol) Role of the ATP-Ubiquitin-dependent Proteolytic Pathway (original) (raw)
Related papers
Journal of Clinical Investigation, 1995
Tissue protein hypercatabolism (TPH) is a most important feature in cancer cachexia, particularly with regard to the skeletal muscle. The rat ascites hepatoma Yoshida AH-130 is a very suitable model system for studying the mechanisms involved in the processes that lead to tissue depletion, since it induces in the host a rapid and progressive muscle waste mainly due to TPH (Tessitore, L., G. Bonelli, and F. M. Baccino. 1987. Biochem. J. 241:153-159). Detectable plasma levels of tumor necrosis factor-a associated with marked perturbations in the hormonal homeostasis have been shown to concur in forcing metabolism into a catabolic setting (Tessitore, L., P. Costelli, and F. M. Baccino. 1993. Br. J. Cancer. 67:15-23). The present study was directed to investigate if .2-adrenergic agonists, which are known to favor skeletal muscle hypertrophy, could effectively antagonize the enhanced muscle protein breakdown in this cancer cachexia model. One such agent, i.e., clenbuterol, indeed largely prevented skeletal muscle waste in AH-130-bearing rats by restoring protein degradative rates close to control values. This normalization of protein breakdown rates was achieved through a decrease of the hyperactivation of the ATP-ubiquitin-dependent proteolytic pathway, as previously demonstrated in our laboratory (Llovera, M., C. . 1994. FEBS (Fed. Eur. Biochem. Soc.) Left. 338:311-318). By contrast, the drug did not exert any measurable effect on various parenchymal organs, nor did it modify the plasma level of corticosterone and insulin, which were increased and decreased, respectively, in the tumor hosts.
Journal of Clinical …, 1995
Tissue protein hypercatabolism (TPH) is a most important feature in cancer cachexia, particularly with regard to the skeletal muscle. The rat ascites hepatoma Yoshida AH-130 is a very suitable model system for studying the mechanisms involved in the processes that lead to tissue depletion, since it induces in the host a rapid and progressive muscle waste mainly due to TPH (Tessitore, L., G. Bonelli, and F. M. Baccino. 1987. Biochem. J. 241:153-159). Detectable plasma levels of tumor necrosis factor-a associated with marked perturbations in the hormonal homeostasis have been shown to concur in forcing metabolism into a catabolic setting (Tessitore, L., P. Costelli, and F. M. Baccino. 1993. Br. J. Cancer. 67:15-23). The present study was directed to investigate if .2-adrenergic agonists, which are known to favor skeletal muscle hypertrophy, could effectively antagonize the enhanced muscle protein breakdown in this cancer cachexia model. One such agent, i.e., clenbuterol, indeed largely prevented skeletal muscle waste in AH-130-bearing rats by restoring protein degradative rates close to control values. This normalization of protein breakdown rates was achieved through a decrease of the hyperactivation of the ATP-ubiquitin-dependent proteolytic pathway, as previously demonstrated in our laboratory (Llovera, M., C.
Comparative effects of β2-adrenergic agonists on muscle waste associated with tumour growth
Cancer Letters, 1997
The implantation of the Yoshida AH-130 ascites hepatoma (a fast growing tumour) to rats resulted in a drarnatic loss of both white adipose tissue and muscle (skeletal and cardiac) mass. Administration of &adrenergic agonists to rumour-hearing rats resulted in a partial recovery of skeletal muscle and heart mass. Treatment of the tumour-bearing animals with the different drugs (salbutamol, salmeterol and clenbuterol) did not influence tumour growth or food intake so it can be suggested that the effects were solely due to metabolic changes. In addition, while the three drugs had clear effects on gastrocnemius muscles, clenbuterol and salbutamol had also an effect on soleus, and salbutamol had a clear effect on cardiac muscle. It is suggested that any of the studied &adrenergic agonists (but perhaps, particularly salmeterol) could be used clinicany in the treatment of cancer cachexia. 0 1997 Elsevier Science Ireland Ltd.
Mechanism of muscle protein degradation induced by a cancer cachectic factor
British Journal of Cancer, 1998
Birmingham B4 7ET. UK: and 2Rowett Research Institute Greenbum Road. Bucksbum. Aberdeen AB21 9SB. UK Summary A proteolysis-inducing factor (PIF) isolated from a cachexia-inducing murne tumour (MAC16) produced a decrease in body weight (1.6 g, P. 0.01 compared with control subjects) within 24 h after i.v. administration to non-tumour-bearing mice. Weight loss was associated with significant decreases in the weight of the spleen and soleus and gastrocnemius muscles. with no effect on the weight of the heart or kidney and with an increase in weight of the liver. Protein degradation in isolated soleus muscle was signfficantly increased in mice bearing the MAC16 tumour. To define which proteolytic pathways contribute to this increase, soleus muscles from mice bearing the MAC16 tumour and non-tumour-bearing animals administered PIF were incubated under conditions that modify different proteolytic systems. In mice bearing the MAC16 tumour, there were increases in both cathepsin B and L, and the Ca2-dependent lysosomal and ATP-dependent pathways were found to contribute to the increased proteolysis; whereas, in PIF-injected animals, there was activation only of the ATP-dependent pathway. Further studies in mice bearing the MAC16 tumour have provided evidence for increased levels of ubiquitin-conjugated proteins and increased mRNA levels for the 14 kDa ubiquitin carrier protein E2 and the C9 proteasome subunit in gastrocnemius muscle, suggesting activation of the ATP-ubiquitin-dependent proteolytic pathway. A monoclonal antibody to PIF attenuated the enhanced protein degradation in soleus muscle from mice bearing the MAC16 tumour, confirming that PIF is responsible for the loss of skeletal muscle in cachectic mice.
The Skeletal Muscle as an Active Player Against Cancer Cachexia
Frontiers in Physiology, 2019
The management of cancer patients is frequently complicated by the occurrence of cachexia. This is a complex syndrome that markedly impacts on quality of life as well as on tolerance and response to anticancer treatments. Loss of body weight, wasting of both adipose tissue and skeletal muscle and reduced survival rates are among the main features of cachexia. Skeletal muscle wasting has been shown to depend, mainly at least, on the induction of protein degradation rates above physiological levels. Such hypercatabolic pattern is driven by overactivation of different intracellular proteolytic systems, among which those dependent on ubiquitin-proteasome and autophagy. Selective rather than bulk degradation of altered proteins and organelles was also proposed to occur. Within the picture described above, the muscle is frequently considered a sort of bystander tissue where external stimuli, directly or indirectly, can poise protein metabolism toward a catabolic setting. By contrast, several observations suggest that the muscle reacts to the wasting drive imposed by cancer growth by activating different compensatory strategies that include anabolic capacity, the activation of autophagy and myogenesis. Even if muscle response is eventually ill-fated, its occurrence supports the idea that in the presence of appropriate treatments the development of cancer-induced wasting might not be an ineluctable event in tumor hosts.
Cancer Research
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. Fur...
International Journal of Cancer, 1995
Rats bearing the Yoshida AH-I30 ascites hepatoma for 7 days showed an important decrease in muscle mass-over 30% in gastrocnemius and extensor digitorum longus (EDL)-in relation to non-tumour-bearing controls, which is associated with an increased proteolytic rate in in vitro incubation. In order to identify the precise biochemical process which was involved, we measured different proteolytic systems in incubated EDL muscles. The capacity for intralysosomal proteolysis, as measured by sensitivity to methylamine, was not increased in tumour-bearing rats, suggesting that the mechanism involved in the increased proteolytic rate was extralysosomal. Incubations using the Ca2+ ionophore A23187 revealed no change in the activity of calcium-dependent proteases as a consequence of tumour growth. Finally, muscle incubation in an ATP-depleted medium allowed us to conclude that energy-dependent proteases were involved in the activation of muscle proteolysis in tumour-bearing rats. In particular, the ubiquitin-dependent proteolytic system is involved, since there is an important increase in ubiquitin conjugates in the skeletal muscle of turnour-bearing rats. It may thus be suggested that extralyso-soma1 ATP-and ubiquitin-dependent proteases underlie the biochemical mechanism of muscle wastage associated with cancer cachexia. o 1995 Wilq-Liss. Inc.
Increased ATP-ubiquitin-dependent proteolysis in skeletal muscles of tumor-bearing rats
Cancer research, 1994
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. Fur...
Frontiers in Physiology
Protein hypercatabolism significantly contributes to the onset and progression of muscle wasting in cancer cachexia. In this regard, a major role is played by the ATP-ubiquitin-proteasome-dependent pathway and by autophagy. However, little is known about the relevance of the Ca 2+-dependent proteolytic system. Since previous results suggested that this pathway is activated in the skeletal muscle of tumor hosts, the present study was aimed to investigate whether inhibition of Ca 2+-dependent proteases (calpains) may improve cancer-induced muscle wasting. Two experimental models of cancer cachexia were used, namely the AH-130 Yoshida hepatoma and the C26 colon carcinoma. The Ca 2+-dependent proteolytic system was inhibited by treating the animals with dantrolene or by overexpressing in the muscle calpastatin, the physiologic inhibitor of Ca 2+-dependent proteases. The results confirm that calpain-1 is overexpressed and calpastatin is reduced in the muscle of rats implanted with the AH-130 hepatoma, and show for the first time that the Ca 2+-dependent proteolytic system is overactivated also in the C26-bearing mice. Yet, administration of dantrolene, an inhibitor of the Ca 2+-dependent proteases, did not modify tumor-induced body weight loss and muscle wasting in the AH-130 hosts. Dantrolene was also unable to reduce the enhancement of protein degradation rates occurring in rats bearing the AH-130 hepatoma. Similarly, overexpression of calpastatin in the tibialis muscle of the C26 hosts did not improve muscle wasting at all. These observations suggest that inhibiting a single proteolytic system is not a good strategy to contrast cancer-induced muscle wasting. In this regard, a more general and integrated approach aimed at targeting the catabolic stimuli rather than the proteolytic activity of a single pathway would likely be the most appropriate therapeutic intervention.