New findings from Cleveland Clinic researchers suggest how the gut microbiome impacts severity and functional impairment following stroke. The results, published in Cell Host & Microbe, could lay the groundwork for potential new interventions to help treat or prevent stroke, Cleveland Clinic notes in a media release.

Weifei Zhu, PhD, and Stanley Hazen, MD, PhD, of Cleveland Clinic’s Lerner Research Institute led the research. The study builds on more than a decade of research spearheaded by Dr Hazen and his team related to the gut microbiome’s role in cardiovascular health and disease, including the adverse effects of TMAO (trimethylamine N-oxide) – a byproduct produced when gut bacteria digest certain nutrients abundant in red meat and other animal products.

“In this study we found that dietary choline and TMAO produced greater stroke size and severity, and poorer outcomes in animal models. Remarkably, simply transplanting gut microbes capable of making TMAO was enough to cause a profound change in stroke severity.”

— Stanley Hazen, chair of the Department of Cardiovascular & Metabolic Sciences and director of Cleveland Clinic’s Center for Microbiome & Human Health

Previously, Hazen and his team discovered that elevated TMAO levels can lead to the development of cardiovascular disease. In clinical studies involving thousands of patients, they have shown that blood levels of TMAO predict future risk of heart attack, stroke and death. Earlier studies, also led by Drs. Zhu and Hazen, suggested a link between TMAO and enhanced risk for blood clotting.

“This new study expands on these findings, and for the first time provides proof that gut microbes in general – and through TMAO specifically – can directly impact stroke severity or post-stroke functional impairment,” Hazen adds.

Compared Brain Damage

The researchers compared brain damage in preclinical stroke models between those with elevated or reduced TMAO levels. Over time, those with higher levels of TMAO had more extensive brain damage and a greater degree of motor and cognitive functional deficits following stroke. The researchers also found that dietary changes that alter TMAO levels, such as eating less red meat and eggs, impacted stroke severity.

“Functionality after a stroke – which occurs when blood flow to the brain is blocked – is a major concern for patients. To understand if choline and TMAO affect post-stroke functionality, in addition to stroke severity, we compared performance on various tasks pre-stroke, and then both in the short- and long-term following stroke.”

— Dr. Hazen, who is also co-section head of Preventive Cardiology & Cardiac Rehabilitation in Cleveland Clinic’s Miller Heart, Vascular & Thoracic Institute

Target This Gut Microbe Enzyme

The team found that a gut microbe enzyme critical to TMAO production called CutC drove heightened stroke severity and worsened outcomes.

According to Dr. Zhu, targeting this gut microbe enzyme may be a promising approach to prevent stroke.

“When we genetically silenced the gut microbe gene that encodes CutC, stroke severity significantly diminished. Ongoing research is exploring this treatment approach, as well as the potential for dietary interventions to help reduce TMAO levels and stroke risk, since both a Western diet and a diet rich in red meat are known to elevate TMAO levels. Switching to plant-based protein sources helps to lower TMAO.”

— Weifei Zhu, PhD

[Source(s): Cleveland Clinic, EurekAlert]

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