Ameliorating Synaptic and Mitochondrial Dysfunctions of the Respiratory Neuromotor System in Alzheimer's Disease
Mayo Clinic Rochester, Rochester MN
Investigators
Linked publications & trials
Abstract
ABSTRACT The studies in the proposal are focused on the neuromotor system in Alzheimerâs disease (AD) and natural aging. Increased age is associated with muscle atrophy and weakness (sarcopenia) and is a significant predictor of chronic disease and mortality in the elderly. Aging is a major risk factor for conditions such as AD and obstructive sleep apnea (OSA). In the elderly population, pneumonia incidence is 3-times higher than in younger age groups, with AD further increasing the incidence and severity of airway infections. The incidence of airway infection in aging and age-associated disorders is undoubtedly related to sarcopenia of the diaphragm muscles (DIAm) and discoordination of airway protective manoeuvres, which involve both DIAm and an assortment of other respiratory-associated muscles including individual tongue muscles. This proposal leverages the extensive experience of the PI in both respiratory neuromotor systems and in neurodegeneration. Previously, we found that DIAm sarcopenia was related to a loss of larger phrenic motor neurons (MNs) and subsequent denervation, consistent with motor unit specific effects on maximum transdiaphragmatic pressure generation. Our preliminary observations in both intrinsic (longitudinal and transversalis muscles) and extrinsic (genioglossus) tongue muscles suggest that sarcopenia in tongue may also be due to denervation. Despite the cause of age-related MN loss being unknown, clues from neurodegenerative conditions that affect MNs suggest that synaptic loss and mitochondrial disfunctions contribute to MN death, with disproportionate effects on larger MNs. The major conceptual advancement in this proposal is to comprehensively evaluate the entire motor unit: hypoglossal and phrenic MNs â recruited to perform motor tasks; neuromuscular junctions â connecting neural impulse to the muscle; and tongue and DIAm â the effector cell. We hypothesize that in old age and AD, motor impairments and loss of larger MNs (denervation) of respiratory muscles is underpinned by MN and NMJ synapse loss and mitochondrial dysfunction (reduced volume density, fragmentation and activity). In addition, we will trial two approaches to ameliorate the contribution of synaptic loss (via riluzole) or mitochondrial dysfunction (via edaravone) to MN death in AD and aging. The proposed studies employ an array of innovative techniques, with assessments ranging from sub-cellular through to system level behavior in Fischer 344 rats and in an AD model (TgF344-AD) on the same genetic background. In Aim 1, we will assess excitatory and inhibitory synapse loss, dendritic and dendritic spine loss, and survival of hypoglossal and phrenic MNs. Additionally, we will evaluate denervation, sarcopenia and functional impairments in tongue and DIAm across aging and AD. In Aim 2, we will assess mitochondrial volume density (MVD) and fragmentation and function SDHmax in hypoglossal and phrenic MNs and in tongue and DIAm in aging and AD. In Aim 3, we will assess whether mitigating synaptic dysfunction (by riluzole) and/or mitochondrial dysfunction (by edaravone) improves outcomes in respiratory MNs and muscles in aging and AD.
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