Sexual Dimorphism of Skeletal Muscle in a Mouse Model of Breast Cancer: A Functional and Molecular Analysis.
Lauren E RentzMarcella A WhetsellStuart A ClaytonAlan D MizenerIda HoláskováMatthew G ChapaEmily H HoblitzellTimothy D EubankEmidio E PistilliPublished in: International journal of molecular sciences (2023)
Breast cancer incidence in men is statistically rare; however, given the lack of screening in males, more advanced stages at initial diagnosis result in lower 5-year survival rates for men with breast cancer compared to women. A sexual dimorphism, with respect to the effect of tumor growth on cachexia incidence and severity, has also been reported across cancer types. The purpose of this study was to examine the sexual dimorphism of breast cancer as it pertains to skeletal muscle function and molecular composition. Using female and male transgenic PyMT mice, we tested the hypothesis that the isometric contractile properties and molecular composition of skeletal muscle would be differentially affected by breast tumors. PyMT tumor-bearing mice of each sex, corresponding to maximal tumor burden, were compared to their respective controls. RNA sequencing of skeletal muscle revealed different pathway alterations that were exclusive to each sex. Further, differentially expressed genes and pathways were substantially more abundant in female tumor mice, with only minimal dysregulation in male tumor mice, each compared to their respective controls. These differences in the transcriptome were mirrored in isometric contractile properties, with greater tumor-induced dysfunction in females than male mice, as well as muscle wasting. Collectively, these data support the concept of sexually dimorphic responses to cancer in skeletal muscle and suggest that these responses may be associated with the clinical differences in breast cancer between the sexes. The identified sex-dependent pathways within the muscle of male and female mice provide a framework to evaluate therapeutic strategies targeting tumor-associated skeletal muscle alterations.
Keyphrases
- skeletal muscle
- insulin resistance
- high fat diet induced
- mouse model
- risk factors
- gene expression
- single cell
- polycystic ovary syndrome
- type diabetes
- oxidative stress
- wild type
- genome wide
- resistance training
- mental health
- squamous cell carcinoma
- pregnant women
- drug induced
- machine learning
- rna seq
- heart rate
- drug delivery
- diabetic rats
- squamous cell
- middle aged
- endothelial cells
- high intensity
- artificial intelligence
- high glucose
- smooth muscle
- big data
- transcription factor