Metronomic 5-Fluorouracil Delivery Primes Skeletal Muscle for Myopathy but Does Not Cause Cachexia.
Dean G CampeljCara A TimpaniTabitha CreeAaron C PetersenAlan HayesCraig A GoodmanEmma RybalkaPublished in: Pharmaceuticals (Basel, Switzerland) (2021)
Skeletal myopathy encompasses both atrophy and dysfunction and is a prominent event in cancer and chemotherapy-induced cachexia. Here, we investigate the effects of a chemotherapeutic agent, 5-fluorouracil (5FU), on skeletal muscle mass and function, and whether small-molecule therapeutic candidate, BGP-15, could be protective against the chemotoxic challenge exerted by 5FU. Additionally, we explore the molecular signature of 5FU treatment. Male Balb/c mice received metronomic tri-weekly intraperitoneal delivery of 5FU (23 mg/kg), with and without BGP-15 (15 mg/kg), 6 times in total over a 15 day treatment period. We demonstrated that neither 5FU, nor 5FU combined with BGP-15, affected body composition indices, skeletal muscle mass or function. Adjuvant BGP-15 treatment did, however, prevent the 5FU-induced phosphorylation of p38 MAPK and p65 NF-B subunit, signalling pathways involved in cell stress and inflammatory signalling, respectively. This as associated with mitoprotection. 5FU reduced the expression of the key cytoskeletal proteins, desmin and dystrophin, which was not prevented by BGP-15. Combined, these data show that metronomic delivery of 5FU does not elicit physiological consequences to skeletal muscle mass and function but is implicit in priming skeletal muscle with a molecular signature for myopathy. BGP-15 has modest protective efficacy against the molecular changes induced by 5FU.
Keyphrases
- skeletal muscle
- body composition
- small molecule
- oxidative stress
- late onset
- early stage
- squamous cell carcinoma
- type diabetes
- signaling pathway
- mesenchymal stem cells
- single molecule
- electronic health record
- stem cells
- bone mineral density
- muscular dystrophy
- young adults
- high glucose
- resistance training
- early onset
- protein kinase
- replacement therapy
- squamous cell
- high fat diet induced