Molecular receptors on Group III-IV sensory neurons detecting muscle metabolites Fatigue due to chronic heart failure, chronic obstructive pulmonary disorder (COPD), and other chronic fatiguing disorders is serious, debilitating, and creates poor prognoses for long-term outcomes in these patients. Many more patients are affected by idiopathic, injury, or disease-caused short-term fatigue and myalgia that sometimes remits with treatment or for unknown reasons becomes chronic. Considerable evidence indicates that peripheral sensory dysregulation of group III/IV muscle afferents, and autonomic dysregulation may cause or contribute to the excessive fatigue of chronic heart failure. Our long-term goal is to determine the fundamental mechanisms that signal fatigue to sensory and motor systems, and determine the mechanisms that cause enhanced fatigue in diseases such as heart failure and COPD. In the next three years, we propose a comprehensive evaluation of the molecular receptors on group III/IV muscle afferent neurons that endow these specialized endings with the ability to detect and signal the increases in muscle metabolites that occur with muscle contraction and exercise. Experiments proposed here will use: 1) innovative neuron harvesting and quantitative real-time, PCR (qPCR) to determine which molecular receptors are expressed selectively in group III/IV afferent neurons. 2) calcium imaging, cell harvesting and qPCR to determine how fatigue-selective neurons selectively encode non-painful levels of metabolites. 3) immunohistochemistry to determine if mRNA expressed is translated protein inserted into membrane. 4) whole-cell recording of metabolite activated currents to determine the function of the molecular receptor proteins;and 5) single unit electrophysiological recording in a nerve muscle preparation to determine which metabolites activate these sensory neurons in situ. The results of these experiments will provide the basic science background for the concept of fatigue as an integrated system with powerful influence on the cardiovascular/autonomic system, the sensory-perceptual experience of fatigue, and motor system inhibition. This concept, and the molecular receptors discovered will lead to rational, targeted effective treatments for the excessive fatigue experienced by heart failure patients, patients with COPD, and other patients suffering from prolonged, unexplained fatigue.
Chronic heart failure and chronic obstructive pulmonary disease are commonly associated with debilitating fatigue that is not consistent with the cardiac and respiratory insufficiencies these patients have. This proposal will comprehensively determine the molecular receptors that allow group III/IV afferent neurons to detect muscle contraction produced metabolites, and 1) signal fatigue the sympathetic nervous system causing the exercise pressor response that normally reduces fatigue, 2) signal the motor system to reduce the ability to contract exercising muscle, and 3) signal the sensory areas of the brain leading to the overwhelming sensation of fatigue. Knowing these receptors will lead to new targets to control and treat excessive, debilitating fatigue in cardiovascular disorders.
|Amann, Markus; Light, Alan R (2015) From Petri dish to human: new insights into the mechanisms mediating muscle pain and fatigue, with implications for health and disease. Exp Physiol 100:989-90|
|Pollak, Kelly A; Swenson, Jeffrey D; Vanhaitsma, Timothy A et al. (2014) Exogenously applied muscle metabolites synergistically evoke sensations of muscle fatigue and pain in human subjects. Exp Physiol 99:368-80|
|Gautam, Mamta; Benson, Christopher J (2013) Acid-sensing ion channels (ASICs) in mouse skeletal muscle afferents are heteromers composed of ASIC1a, ASIC2, and ASIC3 subunits. FASEB J 27:793-802|
|Kusama, Nobuyoshi; Gautam, Mamta; Harding, Anne Marie S et al. (2013) Acid-sensing ion channels (ASICs) are differentially modulated by anions dependent on their subunit composition. Am J Physiol Cell Physiol 304:C89-101|