Associations Between the Microbiome, Skeletal Muscle Perfusion, and Fitness Status

Cardiovascular disease (CVD) is the leading cause of morbidity and mortality in the United States. Nitric oxide (NO) is a gaseous diatomic free-radical and is essential for a plethora of physiological functions involved in cardiometabolic health and CVD risk. NO bioavailability is associated with greater tissue perfusion, mitochondrial function, glucose regulation, and overall reduced CVD risk. The primary source of circulating NO is vascular endothelial nitric oxide synthase.

Unfortunately, the endothelium can be disrupted/damaged via a variety of CVD risk factors such as hypertension, smoking, hyperlipidemia, diabetes, inflammation, and hypercholesteremia. Disruption of the vascular endothelium and loss of bioavailable NO is a preliminary step in the progression of atherosclerosis and CVD. Decreased NO bioavailability and vascular dysfunction have been shown in a variety of clinical conditions including patients heart failure and peripheral artery disease (PAD).

Recently, an exogenous approach to increasing NO bioavailability via oral supplementation of inorganic nitrate (NO3-) has been utilized to increase NO bioavailability in various healthy and clinical populations. Briefly, inorganic NO3- is swallowed, absorbed into the circulation, and sequestered back into the salivary glands. NO3- is then secreted into the oral cavity, where bacteria containing nitrate reductase enzymes convert NO3- to nitrite (NO2-), which is again swallowed and absorbed into the circulation. NO2- in the plasma is then easily reduced to NO via non-enzymatic reactions.

This study aims to better elucidate the relationship between the oral microbiome abundance and diversity and NO3- to NO2- to NO conversion across a variety of subject populations ranging from healthy subjects to those with risk factors for CVD and people with diagnosed CVD. We also aim to examine the relationship between oral microbiome NO3- reduction and impaired skeletal muscle perfusion and exercise capacity as NO bioavailability plays a large role in these physiological processes.

The results of this study may allow us to better understand how novel interventions to modify the oral microbiome may improve cardiometabolic health and physical function in individuals with CVD and outline potential new therapeutic approaches.

The primary objective of this preliminary study is to compare the abundance and diversity of oral NO3- reducing bacteria in a variety of subjects with varying cardiometabolic health status and their ability to convert oral inorganic nitrate to nitrite measured in the saliva and plasma.