Interplay Among Gut Microbiota-Derived TMAO, Autonomic Nervous System Dysfunction, and Heart Failure Progression

Heart failure (HF) is a complex clinical syndrome involving not only hemodynamic and structural abnormalities but also systemic inflammatory, metabolic, and neurohumoral dysregulation. Among emerging factors involved in HF development and progression, the gut microbiota and its metabolite TMAO have gained considerable attention. TMAO, produced through microbial metabolism of dietary precursors and hepatic oxidation, has been linked to endothelial dysfunction, mitochondrial stress, and chronic low-grade inflammation [1,2]. As previously described, TMAO is also produced in the aorta cellular layer and in adipose tissue [3,4,5]. Recent evidence also implicates TMAO in modulating the autonomic nervous system (ANS), contributing to sympathetic hyperactivity—a known driver of HF progression and arrhythmogenesis. Thus, a critical loop exists between gut microbiota ANS balance and function, inflammation, and cardiovascular diseases. Such a detrimental loop becomes strikingly manifest when considering the proactive interactions between these factors in favoring myocardial infarction occurrence and, more so, in post-MI negative remodeling into left ventricular dysfunction and HF. The growing appreciation of this integrated process is specifically highlighted by very recent publications by the American and European Cardiology and Psychiatric Societies [6,7]. Accordingly, this review integrates current evidence on TMAO as a molecular mediator bridging the gut–heart–brain axis, highlighting its influence on autonomic tone and cardiac outcomes. We also discuss the clinical implications of modulating TMAO levels as a therapeutic target for precision cardiology.

It is established knowledge that autonomic responses to a cardiac insult (mostly of ischemic origin) drive most of the pathophysiological processes of negative cardiac remodeling, eventually leading to heart failure [8]. In this context, sympathetic activation has long been appreciated as a fundamental compensatory mechanism of the failing heart, specifically in the presence of left ventricular dysfunction; thus, it is a welcome phenomenon and is to be supported.

In this context, the hypothesis of modulating the reflex sympathetic response to the loss of cardiac function was strongly denied by the cardiology community till the early 1990s. The efficacy of beta-blockers in HF with preserved LV function is still under debate [9], while the undisputed evidence of beta-blockers’ efficacy in heart failure with reduced ejection fraction [10] reversed the understanding of HF’s pathophysiology and opened a completely novel approach to its detection and treatment. Within this revolutionary process, the ATRAMI study [11,12] (Autonomic Tone and Reflexes After Myocardial Infarction) addressed the close relationship between autonomic balance after myocardial infarction (MI) and later mortality risk. The time course of cardiac autonomic control remodeling after a first MI and its influence on later left ventricular remodeling leading to progressive left ventricular dysfunction and sudden death was also documented [13]. This evidence is supported by a number of publications highlighting the role of autonomic imbalance in arrhythmogenesis, sudden death, and HF progression [14]. The key message emerging from both experimental and clinical studies can be expressed in a very condensed sentence: too much sympathetic cardiac drive leads to HF and/or death, while adequate vagal inhibitory control produces a longer and better life. This is, in essence, the key message that generated a novel line of research aimed at restoring balanced cardiac control as soon as possible after a cardiac perturbation, specifically if of ischemic origin [10,15].

Relevant to the present review is the role of the inflammatory process in cardiac mechanical and neural remodeling, driven by nerve growth factor (NGF). NGF is the most representative member of the neurotrophin family and plays a pivotal role in regulating neuronal growth and repair [16,17]. Indeed, preclinical models consistently showed that MI causes, within a very short time, a diffuse upregulation of NGF that is more pronounced in the border zone. The subsequent nerve sprouting signal, facilitated by a rise in the levels of NGF in the Left Stellate Ganglion and in serum, triggers an increase in cardiac nerve density in both peri-infarct and non-infarcted areas, likely leading to an increased risk of arrhythmias. Such findings were confirmed to be of clinical relevance by a study that analyzed cardiac tissue from patients suffering lethal arrhythmic events after MI. On the other hand, NGF is expressed by ischemic myocytes and may also increase cell survival during acute myocardial infarction. NGF promotes cardiac repair following myocardial infarction [18].

Thus, similarly to neural sympathetic activity, whose action is important to sustain the ischemic heart but becomes detrimental if it is excessive, NGF expression is protective if balanced but becomes detrimental if overexpressed. The combination of sympathetic sprouting and sympathetic neural activation indeed creates an anatomical and functional condition of catecholamine toxicity, with major detrimental effects on the entire pathophysiology of HF [16].

Trimethylamine (TMA) is a compound synthesized by the intestinal microbiota from precursors such as choline, carnitine, lecithin, gamma-butyrobetaine, and phosphatidylcholine. These precursors are abundantly present in common dietary sources, including red meat, saltwater fish, cheeses, eggs, dairy products, and, to a lesser extent, fruits, vegetables, and cereals [24]. TMA is synthesized from specific precursors through the action of bacterial enzymes and is subsequently converted to TMAO. The enzymatic pathways involved in this conversion include choline TMA lyase (genes cutC, cutD), carnitine monooxygenase (genes cntA, cntB), betaine reductase, and TMAO reductase. Additionally, TMA can be derived from the reduction of dietary TMAO by the intestinal microbiota. In the liver, TMA is oxidized to TMAO by flavin monooxygenase-3 (FMO3), which exhibits 15 times greater activity than flavin monooxygenase-1 (FMO1), primarily expressed in the kidney and intestine. In humans, there are five functional genes encoding FMO, and individual variations in FMO3 expression are associated with genetic and physiological factors [25]. The aorta expresses the TMAO-synthesizing enzyme (FMO3) in multiple vascular cell types (endothelial cells, fibroblasts, macrophages, pericytes, smooth muscle cells) in both mouse (including high-fat diet-fed) and human aortas, as shown by single-cell RNA sequencing and qPCR [26]. Further, recent evidence has demonstrated that with aging, TMAO is produced in adipose tissue [4]. The production of TMAO is lower in men than in women due to the inhibitory action exerted on FMO3 by testosterone [27].

The genetic architecture that regulates TMAO is complex and probably goes beyond the FMO3 [28]. TMAO is a biologically active metabolite that is eliminated by secretion in the proximal part of the renal tubule.

The physiological role of methylamines, including TMAO, is to stabilize protein structures, thereby protecting them from osmotic stress. However, this stabilizing property means that TMAO can also promote the aggregation of non-functional proteins, such as β-Amyloid, under certain conditions [29,30,31]. Moreover, it has been widely demonstrated that high levels of TMAO have toxic effects and lead to the arrest of cellular synthesis [32].

The gut microbiota is predominantly composed of two main phyla: Bacteroidetes and Firmicutes. Bacterial species capable of producing TMA are widely distributed across multiple phyla, including Actinobacteria and Proteobacteria, though they are most abundant among Firmicutes [33,34]. Beyond the commensal flora, several non-commensal bacteria, such as Burkholderia, Campylobacter, Aeromonas, Salmonella, Shigella, and Vibrio, can also produce TMAO [24]. Interestingly, the host microbiota is capable of performing a retroconversion process in which TMAO is reduced back to TMA by the intestinal flora. Once reabsorbed in the intestine, this TMA can then be reconverted to TMAO by hepatic enzymes [35,36]. Elevated circulating TMAO levels have been identified as an independent risk factor for the development of arteriosclerosis and diabetes [37,38]. Furthermore, TMAO plays a significant role in the pathogenesis of neurodegenerative diseases, including Parkinson’s disease and Alzheimer’s syndrome [29].

Emerging clinical questions related to the TMAO-mediated gut–brain–heart axis reveal limitations in classical models: static in vitro systems are too simple, and in vivo models are often too complex to provide the necessary cellular and molecular detail required to isolate specific mechanistic pathways. Advanced in vitro models bridge this methodological gap, moving basic research closer to modeling the complex gut–brain axis and microbiota–gut interactions, often developed within the framework of 3R concepts (Replacement, Reduction, and Refinement of animal models) [87].

Primary cells, immortalized cell lines, and induced pluripotent stem cells (iPSCs) can be cultivated as Next-Generation Testing Tools to better reproduce mammalian physiological conditions, essential for studying inter-organ communication relevant to HF progression [88]. Three main methodological approaches exist based on culture scale, crucial for mimicking the physiological environment of the gut–brain–heart axis:The Chip Level. Microfluidic devices containing hair-fine microchannels (tens to hundreds of micrometers) guide and manipulate picoliter-to-milliliter solution volumes [89]. These channels, etched or molded onto substrates like Polydimethylsiloxane or glass, enable high-precision experiments and biological assays at reduced scale.The Microfluidic Level. Scaffold-free cellular spheroids (e.g., iPSC-derived) of micrometer dimensions grow three-dimensionally at the base of 1.5 mL tubes with ≤1 mL medium. This system provides physiologically relevant conditions for genetic studies when transgenic models are unavailable, ensuring proper cell–cell contact across all surfaces [90].The Millifluidic Level. Coin-sized bioreactors support 2D/3D cell cultures (micro- to millimetric scale) with ~10 mL medium volumes and flow systems mimicking physiological circulation. These platforms investigate laminar flow, shear stress effects, and nonlinear dynamics, proving useful for modeling organ physiopathology, inter-organ communication, and disease conditions [91,92].

One of the first studies exploring gut cell cultures in an advanced bioreactor was published in 2014 [92]. The authors introduced a new dynamic bioreactor, validated using computational fluid dynamic models and pressure analysis, intended to overcome the limitations of traditional static models for studying epithelial permeability. They used fully differentiated Caco-2 cells as a model of the intestinal epithelium, comparing traditional static transwells with the effect of the flow of the medium applied in the bioreactor. They found that flow increased the barrier integrity and tight junction expression of Caco-2 cells compared to static controls. Also, transport across the barrier was increased after flow-induced stimulation, closely replicating the in vivo situation. The successful replication of the intestinal barrier under flow is crucial for accurately modeling the LPS and TMA/TMAO leakage central to the HF pathology.

Recently, Kim and colleagues developed a system to simulate the interaction between gut microbes and human neurons [93]. Employing a gut–brain axis chip containing iPSC-derived human neurons, the authors investigated how metabolites and exosomes produced by gut microbiota affect both neurodevelopmental and neurodegenerative processes. The chip contained channels for intestinal epithelial cells and neural stem cells. Caco-2 cells formed a polarized intestinal layer with in vivo-like morphology, while bacterial co-culture remained stable without overgrowth. The authors were able to demonstrate that microbial metabolites and exosomes promoted neural differentiation and synaptic protein expression in iPSC-derived neurons.

Horvath et al. [94] proposed a protocol including bacterial cultures, organoids, and in vivo samples which would enable studies on the connections between microbial colonization and intestinal and brain neurotransmitters. This strategy would allow for a comprehensive evaluation of metabolites in an in vitro system represented by organoids and in vivo mouse model systems.

In 2019, the group of Giordano et al. [95] introduced MINERVA (MIcrobiota-Gut-BraiN EngineeRed platform to eVAluate intestinal microflora impact on brain functionality). This is a multi-organ-on-a-chip platform specifically designed to investigate the influence of the microbiota on neurodegeneration. The device facilitates the co-cultivation and communication between cells representing the microbiota, the gut epithelium, the immune system, and the blood–brain barrier all integrated onto a single chip. The future application would be to assess drug therapeutic strategies in a context of personalized medicine approach.

Hall and colleagues [96] discussed the use of iPSCs in gut–brain axis chips and the challenges to be faced, and Raimondi et al. summarized several organ-on-a-chip models to study the microbiota-gut–brain axis and its involvement in neurological diseases [97].

The primary goal, therefore, is to develop a comprehensive gut–brain–heart multi-organ system. This involves placing cardiac cells, which have already been successfully cultivated and studied in flow-based bioreactors [91,98], in communication with the described gut–brain axis chip devices. This integration would allow the reproduction, with unprecedented detail, of the complex cross-talk that exists between these systems. This approach represents the application possible in the immediate future: assessing drug therapeutic strategies and personalized medicine approaches specifically targeting the TMAO pathway and its downstream effects on the heart.

Diet influences TMAO through both food type and total energy intake [99,100,101]. Beyond lifestyle changes, various pharmacological and bioactive strategies are emerging to mitigate the deleterious effects of the microbiota-derived metabolite TMAO. Current evidence suggests that conventional cardiovascular drugs, such as statins and loop diuretics, significantly interact with TMAO pathways, either by reducing its production or by influencing its renal excretion. Furthermore, the use of targeted nutraceuticals offers a promising non-pharmacological approach to reshape the gut microbiota and attenuate TMAO-induced vascular and metabolic damage. The following sections detail how these diverse interventions—ranging from lipid-lowering therapies to polyphenol-rich extracts—can be integrated into heart failure management to improve patient outcomes and risk stratification.

In conclusion, this complex pathophysiological cascade demonstrates how gut dysbiosis can initiate a devastating chain reaction through vagal signaling, leading to neuroinflammation, cerebral damage, and subsequent cardiac dysfunction. The bidirectional nature of this gut–brain–heart axis creates a vicious cycle where cardiac dysfunction can further compromise cerebral perfusion, potentially exacerbating neuroinflammation and perpetuating the pathological process. Metabolites like TMAO serve as molecular messengers in this intricate network, simultaneously affecting both neural and cardiovascular systems through multiple pathways. Understanding the impact of TMAO and associated conditions like stroke and hypertension is crucial, as they exacerbate chronic heart conditions. Atrial fibrillation and ventricular arrhythmias are well-known causes and complications of heart failure, further underscoring the severity of these interconnected cardiovascular events. A deeper comprehension of these networked mechanisms opens new therapeutic avenues targeting the vagus nerve, gut microbiota modulation, or anti-inflammatory strategies to break this pathological cycle.

Future translational research must intensify its focus on dissecting the complex, multidirectional gut–brain–heart axis dysfunction. This crucial endeavor necessitates the robust application of cutting-edge research methodologies, particularly advanced in vitro tools such as organ-on-a-chip models and complex co-culture systems that faithfully replicate in vivo physiological conditions. The primary scientific objective must be the precise identification of early, predictive biomarkers. These markers, which could include specific microbial metabolites, inflammatory mediators, or neurohormonal signals, are essential for recognizing the incipient stages of dysfunction long before overt symptoms manifest.

Simultaneously, this research effort must transition into the development of highly targeted interventions. These strategies should move beyond broad-spectrum approaches to focus specifically on restoring eubiosis and correcting the pathological signaling pathways initiated by gut dysbiosis. The ultimate and critical goal is to create effective prophylactic and therapeutic measures capable of preventing the progression from a disturbed gut microbiome and associated systemic inflammation with severe, life-threatening cardiovascular complications, thereby significantly improving patient prognosis and public health outcomes.