Abstract
Type 1 Diabetes Mellitus (T1DM) is a disease characterized by the destruction of insulin‐secreting pancreatic beta cells and results in hyperglycemia, muscle wasting, and vascular dysfunction. Patients afflicted with T1DM suffer from increased morbidity and early mortality, largely driven by an inability to appropriately maintain glucose homeostasis. Skeletal muscle is the body’s largest metabolic reservoir, absorbing significant amounts of glucose from the bloodstream. The myokine myostatin is a potent negative regulator of muscle growth and is upregulated in T1DM patients but downregulated following regular exercise. Physical exercise is also known to improve cardiovascular health and increase insulin sensitivity of muscle, but many T1DM patients are unable to exercise at a level that conveys benefit due to muscle atrophy. Thus, directly targeting skeletal muscle, independent of exercise, may prove beneficial for T1DM therapy. Our hypothesis is that genetic deletion of myostatin will preserve glucose homeostasis, maintain muscle function, and protect against vascular dysfunction and cardiometabolic effects in a mouse model of T1DM.T1DM was induced via streptozotocin (STZ) in adult male mice with (WT) and without myostatin (MyoKO). Multiple variables were assessed including glucose homeostasis (plasma glucose, HbA1c, IGTT), fluid dynamics, muscle function (in vivo plantarflexion), and vascular function (ex vivo pressure myography of gracilis arteriole).Myostatin deletion inhibited STZ‐induced increases in plasma glucose, preserved fluid dynamics, and prevented decreases in muscle function, independent of insulin. Further, endothelial function was protected with myostatin deletion. Taken together, this data suggests that myostatin inhibition may be a target for effective treatment and management of the cardiometabolic and skeletal muscle dysfunction that occurs with T1DM.
Published Version
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