Cachexia has a devastating impact on survival and quality of life of many cancer patients and remains an unmet medical need. Pancreatic cancer patients present with the highest incidence of cachexia (~90%), and approximately one-third of these patients lose more than 10% of their pre-illness weight, leading to general muscle weakness, impairment of normal activities, and eventually death through respiratory failure. A deeper understanding of the underlying mechanisms that lead to the complex metabolic defects of cachexia, coupled with effective treatment options, would improve management of muscle wasting in cancer patients. We have recently reported that ectopic expression of the transcription factor Twist1 in muscle progenitor cells is sufficient to cause severe muscle atrophy akin to muscle cachexia. Using several genetic mouse models of pancreatic ductal adenocarcinoma (PDAC), we detected high Twist1 expression in muscle undergoing cancer cachexia. Of particular importance, inactivating muscle Twist1, either genetically or pharmacological, was sufficient to reverse muscle cachexia and improve survival in several genetic mouse models of cancer cachexia, implicating Twist1 as a possible target for attenuating muscle cachexia in cancer patients. Quite serendipitously, we found that muscle Twist1 was highly crosslinked during cancer cachexia. We obtained strong evidence that this process was mediated by the crosslinking enzyme Transglutaminase 2 (TGM2). Treatment of cells with a specific TGM2 inhibitor completely suppressed Twist1-induced expression of MuRF1 and Atrogin1, two ubiquitin ligases that drive muscle protein degradation during muscle cachexia. Other preliminary data showed that expression of Twist1 in vivo promotes muscle TGM2 expression. More crucially, we detected a marked increase in both muscle Twist1 and TGM2 expression in cachectic cancer patients as compared to healthy individuals, attesting to the clinical relevance of our findings. Based on these intriguing findings, we hypothesize that TGM2 might function in partnership with Twist1 to orchestrate a feed-forward network that initiates and sustains muscle cachexia during cancer progression. We also hypothesize that developing combinatorial therapeutic strategies targeting both TGM2 and Twist1 could mitigate potential drug toxicity by lowering the dose needed for each medicine and combat the development of resistance. These overarching hypotheses will be tested in our research proposal.
Specific Aim 1 : Investigate the relationship between TGM2 and Twist1 during muscle cachexia Specific Aim 2: Explore the role of the TGM2-Twist1 axis in muscle cachexia using genetic approaches Specific Aim 3: Test the therapeutic value of targeting both TGM2 and Twist1 in muscle cachexia We believe that our innovative proposal to exploit this novel TGM2/Twist1 axis in muscle cachexia will culminate in a paradigm shift in our understanding and therapeutic treatment of this lethal wasting syndrome.
Muscle cachexia is a debilitating syndrome that has a dramatic impact on survival and quality of life of many cancer patients and remains a poorly explored area. We believe that achievement of this research program to validate the role of Transglutaminase 2 in cancer-driven muscle cachexia will lead to a paradigm shift, both in terms of understanding the etiology of muscle cachexia, and in terms of drug discovery to curb this life-threatening comorbidity.
