Choline Diet and Its Gut Microbe–Derived Metabolite, Trimethylamine N-Oxide, Exacerbate Pressure Overload–Induced Heart Failure

Organ, Chelsea L.; Otsuka, Hiroyuki; Bhushan, Shashi; Wang, Zeneng; Bradley, Jessica M.; Trivedi, Rishi; Polhemus, David J.; Tang, W.H. Wilson; Wu, Yuping; Hazen, Stanley L.; Lefer, David J.

doi:10.1161/circheartfailure.115.002314

Cited by 273 publications

(208 citation statements)

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“…Similar to our observations in angiotensin-II treated germ-free mice, showing increased cardiac fibrosis, macrophage and neutrophil accumulation, and increased cardiomyocyte area together with increased end-organ damage and angiotensin-II induced hypertension in the conventionally-raised controls [65], myocardial fibrosis was significantly enhanced in mice on a choline-rich or TMAO supplemented diet in the transverse aortic constriction model [113].…”

Section: Association Of the Gut Microbiota-derived Metabolite Trimethsupporting

confidence: 89%

“…In addition to its role in promoting atherosclerotic lesion development, choline-rich diet or TMAO were demonstrated to exacerbate pressure overload-induced heart failure in mice that were subjected to a transverse aortic constriction [113]. Similar to our observations in angiotensin-II treated germ-free mice, showing increased cardiac fibrosis, macrophage and neutrophil accumulation, and increased cardiomyocyte area together with increased end-organ damage and angiotensin-II induced hypertension in the conventionally-raised controls [65], myocardial fibrosis was significantly enhanced in mice on a choline-rich or TMAO supplemented diet in the transverse aortic constriction model [113].…”

Section: Association Of the Gut Microbiota-derived Metabolite Trimethmentioning

confidence: 99%

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The gut microbiota: An emerging risk factor for cardiovascular and cerebrovascular disease

2018

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Commensal gut microbiota have recently been implicated in cardiovascular disease (CVD) and cerebrovascular disease. Atherosclerotic plaque formation depends on the colonization status of the host. In addition to host nutrition and the related microbiota-dependent metabolic changes, activation of innate immune pathways triggers the development of atherosclerosis and supports arterial thrombosis. Gnotobiotic mouse models have uncovered that activation of Toll-like receptor-2 by gut microbial ligands supports von Willebrand factor-integrin mediated platelet deposition to the site of vascular injury. Depending on nutritional factors, the microbiota-derived choline-metabolite trimethylamine Noxide (TMAO) increases atherosclerotic plaque size, triggers prothrombotic platelet function and promotes arterial thrombus growth. Hence, the composition of the commensal microbiota is an emerging risk factor for CVD. Here, we provide an overview on microbiota-dependent pathomechanisms that drive the development of CVD and arterial thrombosis.Keywords: Arterial thrombosis r Atherosclerosis r Cardiovascular disease r Microbiota r Toll-like receptors IntroductionAt birth, our body surfaces are colonized by microbial communities (microbiota), representing one of the most densely colonized microbial ecosystems [1]. This process is strongly influenced by genetic, nutritional, and environmental factors [2]. The commensal microbiota constitutes a permanent inflammatory stimulus [3], which is kept in check by the host's immune responses [4]. The microbiota can be viewed as an organ that impacts host physiology [5,6]. Changes in gut microbiota composition were associated with intestinal diseases (e.g. inflammatory bowel disease, colon cancer) and cardiometabolic disease states, such as diet-induced obesity, type 2 diabetes, atherosclerosis, and arterial thrombosis [7]. The results from recent experimental and clinical studies have led to the assumption that Correspondence: Christoph Reinhardt e-mail: Christoph.Reinhardt@unimedizin-mainz.de molecules synthesized by the intestinal microbiota are involved in the development of cardiovascular disease (CVD) [8] and may increase the risk of arterial thrombosis [9, 10] as well as the outcome of ischemic stroke [11]. Experimental evidence from germ-free mouse studies and metagenomics analyses have associated the gut microbiota with obesity [12][13][14][15], type 2 diabetes [3, 16, 17], stroke [11, 18], and CVD [8, 9, 19]. Therefore, targeting the composition and metabolic function of the intestinal microbiota may represent a therapeutic option that in the future may allow prevention and treatment of cardiometabolic diseases [20].Here, we provide a comprehensive overview on the emerging link between gut microbiota and CVD. We delineate the contribution of this complex microbial ecosystem to metabolic inflammation and its impact on host metabolism. The main focus of this review is to highlight how gut microbiota may contribute to the development of CVD, cerebrovascular disease and arterial thromb...

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Section: Association Of the Gut Microbiota-derived Metabolite Trimethsupporting

confidence: 89%

Section: Association Of the Gut Microbiota-derived Metabolite Trimethmentioning

confidence: 99%

The gut microbiota: An emerging risk factor for cardiovascular and cerebrovascular disease

2018

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“…63 In addition, elevation of TMAO level is a risk factor for development of HF in both diabetic and non-diabetic individuals. 64 In a murine LV pressure overload model, a diet enriched in TMAO or choline was shown to promote cardiac systolic dysfunction, together with severe cardiac fibrosis, 65 indicating a causative role of TMAO in promoting HF pathology. In addition, it is reported that TMAO contributes to progression of atherosclerotic plaque by reducing reverse cholesterol transport.…”

Section: Trimethylamine-n-oxidementioning

confidence: 99%

Metabolomic Analysis in Heart Failure

Ikegami

Shimizu

Yoshida

et al. 2018

Circ J

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10 s, resulting in the cycling of approximately 6 kg of ATP daily, and the heart displays metabolic flexibility to meet this extremely high demand for energy. 8 Under normal conditions, more than 95% of the ATP consumed in the heart is generated by oxidative phosphorylation, while glycolysis is responsible for approximately 5% and the tricarboxylic acid (TCA) cycle for the remainder. Metabolism of fatty acids generates 70-90% of the ATP required by the heart, with the rest being produced by oxidation of glucose, lactate, ketone bodies, and amino acids. 9 It is well known that utilization of fatty acids is reduced in the failing heart and there is a metabolic shift to generation of ATP from glucose. Such metabolic remodeling is considered to be reasonable because HF is associated with hypoxia and ATP generation per oxygen atom is more efficient when glucose is consumed, compared with fatty acids. 9 In patients with advanced HF, the heart is unable to utilize either metabolite and thus "runs out of fuel". 10 It is reported that the ATP level is approximately 30% lower in failing human hearts compared with non-failing hearts. 11 In addition to this classical premise about the metabolic profile of the failing heart, recent advances in the field of metabolomics have indicated that several metabolites and/or metabolic pathways have a role in HF, as described next. LipidsUnder physiological conditions, the heart mainly generates ATP from fatty acids, but this process declines with progression of HF. Under left ventricular (LV) pressure overload, excessive lipolysis occurs in visceral fat because of increased adrenergic signaling, and this leads to high circulating levels of free fatty acids (FFAs). 12 The serum I t is thought that at least 6,500 low-molecular-weight metabolites exist in humans, and these metabolites have various important roles in biological systems in addition to proteins and genes. 1 Comprehensive assessment of endogenous metabolites is called metabolomics, and recent advances in this field have enabled us to understand the critical role of previously unknown metabolites or metabolic pathways in the maintenance of homeostasis under both physiological and stress conditions. Techniques of metabolomic analysis have been elegantly reported and reviewed elsewhere, 2-4 so the details will not be repeated here. Instead, we will describe the metabolites/metabolic pathways that have been characterized using these techniques and analyzed to improve understanding of various physiological and pathological processes in the field of cardiology. In particular, we will focus on heart failure (HF) and how metabolomic analysis has contributed for improving our understanding of the pathogenesis of this critical condition. Cardiac MetabolismThe number of patients with HF continues to increase and this condition has become a major healthcare issue in many countries. Because the prognosis of severe HF is poor, there are many unmet medical needs for these patients, 5, 6 The pathogenesis of HF is complex and a simple approa...

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“…Several studies have found that elevated serum TMAO is associated with increased incidence of myocardial infarction, HF, and cardiovascular mortality [35–40]. The mechanisms underlying these adverse associations between TMAO and cardiovascular have been partially described.…”

Section: Normal and Abnormal Gut Physiology: Implications For Patientmentioning

confidence: 99%

Visceral Congestion in Heart Failure: Right Ventricular Dysfunction, Splanchnic Hemodynamics, and the Intestinal Microenvironment

Polsinelli

Sinha

Shah

2017

Curr Heart Fail Rep

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Purpose of review Visceral venous congestion of the gut may play a key role in the pathogenesis of right-sided heart failure (HF) and cardiorenal syndromes. Here we review the role of right ventricular (RV) dysfunction, visceral congestion, splanchnic hemodynamics, and the intestinal microenvironment in the setting of right-sided HF. We review recent literature on this topic, outline possible mechanisms of disease pathogenesis, and discuss potential therapeutics. Recent Findings There are several mechanisms linking RV-gut interactions via visceral venous congestion which could result in (1) hypoxia and acidosis in enterocytes, which may lead to enhanced sodium-hydrogen exchanger 3 (NHE3) expression with increased sodium and fluid retention; (2) decreased luminal pH in the intestines which could lead to alteration of the gut microbiome which could increase gut permeability and inflammation; (3) alteration of renal hemodynamics with triggering of the cardiorenal syndrome; and (4) altered phosphate metabolism resulting in increased pulmonary artery stiffening, thereby increasing RV afterload. A wide variety of therapeutic interventions that act on the RV, pulmonary vasculature, intestinal microenvironment, and the kidney could alter these pathways and should be tested in patients with right-sided HF. Summary The RV-gut axis is an important aspect of HF pathogenesis that deserves more attention. Modulation of the pathways interconnecting the right heart, visceral congestion, and the intestinal microenvironment could be a novel avenue of intervention for right-sided HF.

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Choline Diet and Its Gut Microbe–Derived Metabolite, Trimethylamine N-Oxide, Exacerbate Pressure Overload–Induced Heart Failure

Cited by 273 publications

References 22 publications

The gut microbiota: An emerging risk factor for cardiovascular and cerebrovascular disease

The gut microbiota: An emerging risk factor for cardiovascular and cerebrovascular disease

Metabolomic Analysis in Heart Failure

Visceral Congestion in Heart Failure: Right Ventricular Dysfunction, Splanchnic Hemodynamics, and the Intestinal Microenvironment

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