Microbiota-Driven Immune Dysregulation Along the Gut–Lung–Vascular Axis in Asthma and Atherosclerosis

Dietary composition represents one of the principal determinants of gut microbiota architecture and metabolic function, acting as a major factor governing host–microbiome homeostasis. Sustained dietary patterns modulate microbial diversity, metabolic function and inflammatory balance, thereby exerting profound and long-term effects on host physiology and susceptibility to chronic conditions [47,54].

The Mediterranean diet, characterized by high consumption of fiber-rich plant foods, legumes, polyphenol-containing fruits, whole grains, fish and extra-virgin olive oil, consistently promotes microbial diversity and metabolic resilience. Individuals following a Mediterranean diet typically exhibit increased abundances of Bacteroides, Prevotella, Lactobacillus, Faecalibacterium, Clostridioides and Oscillospira. This microbial pattern is associated with a higher Bacteroidetes-to-Firmicutes ratio and greater alpha-diversity, reflecting a more balanced and resilient gut ecosystem. The beneficial effects are largely attributed to the diet’s high fiber and unsaturated fatty acid content, which favor saccharolytic and anti-inflammatory bacterial communities [55,56,57].

In contrast, Western-style diets, typically high in saturated fats, refined carbohydrates, animal protein and food additives, are associated with reduced microbial diversity, increased Firmicutes and a decline in Bacteroides and expansion of pathobionts such as Enterobacteriaceae, Bilophila wadsworthia and Alistipes spp. Such dysbiotic configurations favor the production of pro-inflammatory metabolites (e.g., TMAO, lipopolysaccharides (LPS)) that impair gut barrier function and activate toll-like receptor-mediated inflammatory signaling, promoting metabolic endotoxemia and insulin resistance [58,59]. Similarly, high-fat/high-fructose diets have been shown in animal and human studies to disrupt intestinal tight-junction integrity, suppress SCFA synthesis and elevate oxidative stress, collectively contributing to obesity-associated inflammation and vascular dysfunction [60,61].

Other dietary patterns also elicit distinct microbial responses. Plant-based diets, encompassing vegetarian and vegan regimens, increase the abundance of fiber-degrading and saccharolytic taxa such as Prevotella and Ruminococcus, thereby enhancing SCFA output and reducing intestinal pH. The resulting metabolic environment supports colonocyte health and anti-inflammatory immune regulation [62]. In contrast, ketogenic diets, while clinically beneficial for metabolic disorders, are linked to decreased microbial diversity and reduced levels of Bifidobacterium and Eubacterium rectale, accompanied by elevated bile-acid metabolism and inflammatory gene expression [63,64].

Low-fiber diets negatively affect gut microbial composition by depleting fermentable substrates for beneficial taxa such as Faecalibacterium prausnitzii and Roseburia. Sustained fiber deficiency fosters dysbiosis, increasing susceptibility to metabolic and inflammatory disorders, including obesity, diabetes and atherosclerosis [65,66,67].

Diets high in fermented foods enhance gut microbial diversity and promote beneficial taxa such as Lactobacillus and Bifidobacterium. Their bioactive metabolites support epithelial integrity, increase SCFA production and reduce systemic inflammation. Regular consumption of fermented foods like yogurt, kefir, sauerkraut, pickles, sourdough bread or fermented beverages has been linked to improved immune regulation and metabolic health [68,69].

Pharmaceutical agents profoundly influence gut microbial composition and function, often producing long-lasting effects on host metabolism and immunity [70].

Recent evidence indicates that pharmacological treatments, including corticosteroids and antibiotics (used in asthma exacerbation treatment), can notably alter GM composition and metabolic activity. Statins, such as atorvastatin and rosuvastatin, have been shown to reshape gut microbial profiles by increasing beneficial taxa such as Bifidobacterium longum, Akkermansia muciniphila and Ruminococcus obeum, while reducing potentially pathogenic species like Parabacteroides merdae [71,72]. These changes may enhance SCFA production and bile acid metabolism, contributing to the anti-inflammatory and lipid-lowering effects of statins, while interindividual differences in microbiota composition may explain variable therapeutic responses [72,73]. Such disruptions in microbial diversity and metabolite production (e.g., SCFAs, secondary bile acids, TMAO, LPS) have been linked to impaired gut-barrier integrity, immune dysregulation and altered drug metabolism, ultimately influencing both disease progression and therapeutic efficacy [25,31,74].

Many routinely prescribed medications induce distinct shifts in gut microbial ecology, with some taxa, such as Streptococcus salivarius, increasing across multiple drug classes, while others displaying drug-specific signatures, including Bifidobacterium dentium with PPIs, Clostridium leptum with tricyclic antidepressants, Eubacterium ramulus with selective serotonin reuptake inhibitors (SSRIs) and a decrease in Bacteroides fragilis with metformin [75]. Other agents, such as steroid inhalers, statins, methotrexate, laxatives and L-thyroxine, also remodel microbial composition and functional pathways in predictable patterns [75].

Antibiotics remain the most potent disruptors, reducing microbial diversity, depleting beneficial taxa such as Bifidobacterium and Faecalibacterium prausnitzii and promoting the overgrowth of opportunistic pathogens and antibiotic-resistant strains. Broad-spectrum antibiotics have a very potent iatrogenic disruptor effect of the gut ecosystem, producing acute and occasionally long-lasting reductions in microbial diversity, loss of key commensals and changes in microbiome functional capacity. By eliminating susceptible taxa, they create microbial micro-environments that favor the overgrowth of opportunistic pathogens such as Clostridioides difficile, with varied clinical consequences that may result in life-threatening colitis [76,77]. Moreover, even short antibiotic courses can lead to persistent alterations in microbial metabolic capacity and resilience [78,79].

More broadly, metagenomic studies demonstrate that almost one-quarter of non-antibiotic medications exert antibiotic-like effects, suppressing gut bacterial strains and reshaping microbial composition [70].

Corticosteroids also modify the gut ecosystem by suppressing immune-regulated microbial niches and favoring the proliferation of pathobionts, contributing to increased intestinal permeability and systemic inflammation [80]. Oral glucocorticoid therapy markedly induces alterations in the gut microbiome, characterized by increased richness but reduced overall diversity. It leads to a higher Firmicutes/Bacteroidetes ratio, a signature frequently associated with metabolic dysregulation and induced consistent shifts at the genus level, including reductions in beneficial taxa such as Bifidobacterium, Faecalibacterium, Akkermansia and Prevotella, alongside a proliferation of Streptococcus, Collinsella and Parabacteroides [81]. Functionally, oral glucocorticoids impaired considerably the gut’s capacity to generate short-chain fatty acids, as confirmed by a reduced expression of key SCFA-producing enzymes and increased gut serotonin levels, reflecting broad metabolic rewiring [81]. It remains uncertain to what extent the inhaled corticosteroids reshape the diversity of specific bacterial taxa in the airways or in the gut, in the latter likely via the swallowed drug fraction and its systemic effects [73]. In severe asthma, high-dose inhaled corticosteroids modulate the pathological immune activation and airway inflammation. Their pharmacologic effects are associated with an enrichment of Proteobacteria and a reduced abundance of Bacteroidetes, Prevotella and Fusobacteria in the gut [82]. In parallel, a balanced intestinal microbiota has a reciprocal influence upon the immune cell activation, as outer membrane proteins from gut microbiota promote the formation and functionality of Tregs while inhibiting excessive Th2 and Th17 cell activation [83,84]. Consequently, the gut microbiota is essential for preserving immune homeostasis primarily by counterbalancing the detrimental impact of Th2/Th17 hyperactivation and beneficial effects of Tregs responses [83].

Proton-pump inhibitors (PPIs) are recognized as major and usually under-appreciated promoters of gut dysbiosis. Their use is associated with reduced bacterial abundance and changes involving up to 20% of detectable taxa, resulted from altering gastric pH and facilitating the survival and translocation of oral bacteria to the gut and increasing the abundance of Enterococcus, Streptococcus and Escherichia coli, which have been linked to dysbiosis-related disorders [85,86,87]. Sometimes, the microbiome impact of PPIs could exceed that of antibiotics or other common drugs [85].

Additionally, cardiovascular drugs such as statins, beta-blockers, ACE inhibitors and platelet aggregation inhibitors can modulate gut microbial metabolism, influencing bile acid transformation, SCFA production, TMAO and microbial diversity [73]. Altered gut microbiota and their associated metabolites are closely connected to the pathogenesis of atherosclerosis, dyslipidaemia, hypertension and heart failure, indicating that gut bacteria could biotransform cardiovascular drugs, consequently modifying their pharmacodynamics, pharmacokinetics and toxicity. For statins, pretreatment levels of microbiota-derived bile acids reliably predict the extent of LDL-cholesterol lowering, reflecting a bidirectional relationship in which microbial communities both influence and are modulated by lipid-lowering therapy [73,88]. In atherosclerosis, gut dysbiosis is marked by depletion of SCFA-producing Faecalibacterium and Roseburia and increase in Streptococcus, Escherichia and other opportunistic pathogens, enhancing TMAO production, NLRP3–IL-1 activation and endothelial dysfunction [40]. Statins can remodel gut microbial communities, typically shifting towards more SCFA-producing and BA-transforming taxa, while also lowering pro-atherogenic TMAO generating bacteria and inflammatory markers. Conversely, baseline dysbiosis characterized by reduction of SCFA-producing genera and a proliferation of pathobionts has been linked to attenuated LDL-cholesterol reduction and sustained vascular inflammation under statin treatment. Further supporting this, higher levels of SCFA-producing gut microbiota were reported during effective statin therapy [40,72,89]. Therefore, lipid control alone might not be a fully effective preventive strategy in some cases of atherosclerosis [40]. Furthermore, statin treatment in mice led to increased blood glucose levels and body weight, accompanied by specific alterations in the metabolic profile of the gut microbiota [72,75,90]. This pattern would indicate that lipid-lowering medications are partly microbiota-dependent and that the gut microbiota is both a target and a determinant of statin efficacy.

Across the human lifespan, the gut microbiota experiences continuous and finely regulated transitions that mirror developmental, metabolic and immunological changes. The gut microbiome undergoes predictable transitions, from rapid colonization and ecological instability in infancy, through relative equilibrium in adulthood and finally to compositional decline in elderly [38,91,92,93]. Advancing age, is associated with a progressive decline in community diversity, reduced abundance of short-chain fatty acid-producing taxa and an increase in pro-inflammatory bacteria, fostering low-grade systemic inflammation and metabolic dysfunction, characteristic of “inflammaging” [94,95]. Large-scale cohort analyses have further linked these compositional shifts with frailty, immune dysregulation and cardiometabolic disease [96]. Evidence from studies of healthy aging populations indicates that gut microbiome decline is not inevitable. A large Chinese cohort found that healthy older adults, even beyond 94 years, shared microbiome profiles similar to young adults [97]. Centenarians often display higher microbial diversity, enriched in beneficial taxa such as Akkermansia, Christensenellaceae, Lachnospiraceae and Ruminococcaceae, suggesting links between microbial richness, resilience and longevity [98,99]. In contrast, frailty and cognitive decline are associated with reduced diversity, loss of Faecalibacterium prausnitzii and increased abundance of proinflammatory taxa including Eggerthella and Ruminococcus gnavus [100,101]. Despite these trends, inconsistencies across studies emphasize the observational nature of most microbiome-aging research and the need for mechanistic insight into how specific microbial shifts influence health outcomes in older adults [94].

Host genetic variation influences gut microbiota via bile acid metabolism. A murine study identified the Slc10a2 transporter as a key link between bile acid regulation and microbial composition [102]. Gut microbes transform primary bile acids into diverse metabolites that influence host signaling and microbial ecology [103]. The gut microbiome is partly regulated by host genetics, with heritability estimates ranging from 5–45%, though more recent studies suggest that only 3–13% of microbial taxa are heritable, indicating that genetics accounts for only a small fraction of inter-individual microbiome variation [104,105]. Twin and genome-wide studies have identified numerous host loci and at least 30 genes have been experimentally validated to influence microbial composition. Genetic variants can affect disease either directly, by altering host physiology, or indirectly, through microbiome-mediated mechanisms, emphasizing the need for integrative research linking host genetics, microbiota and disease phenotypes [104]. Although genetic effects are modest compared to environmental influences, they define a physiological framework within which diet, immunity and microbial ecology interact to maintain host-microbe homeostasis [106]. Probiotics can regulate miRNA expression, influencing immune balance and inflammation. The proposed microbiota–miRNA–lung axis suggests that gut microbes may epigenetically affect lung health. Combining probiotics with miRNA-modulating therapies (agomiRs and antagomiRs) could enhance anti-inflammatory effects, but more studies are needed to confirm these mechanisms and therapeutic benefits [4,107].

The maternal microbiota profoundly modulates neonatal immune ontogeny, with microbial transfer during gestation contributing to the programming of immune tolerance and predisposing or protecting against allergic asthma in later life [39]. Early-life microbial exposures, including delivery mode, breastfeeding and antibiotic use, further modulate immune tolerance, with dysbiosis in infancy predisposing individuals to chronic inflammation and heightened cardiovascular risk [38,91]. During vaginal birth, infants acquire microbes primarily from the mother’s vaginal and intestinal flora, whereas those delivered by C-section are mainly colonized by skin-associated bacteria [108]. Moreover, C-section and subsequent colonization with Clostridioides difficile have been linked to increased asthma risk, whilst vaginally born children were only pre-disposed if a parent suffered from an atopic disease. Probiotic supplementation has shown potential as an adjunctive approach for asthma prevention and symptom control [109,110]. Although defining a universal core respiratory microbiota remains challenging due to substantial individual variability, several genera, including Staphylococcus, Streptococcus, Haemophilus, Moraxella and Veillonella, are consistently detected within the respiratory tract [111].

Early-life gut and airway microbiota shape immune development and influence susceptibility to allergic asthma or ACVDs later in life [38,40,112]. Infants with reduced Bifidobacterium, Akkermansia, Faecalibacterium or fungal genera such as Candida and Rhodotorula are at higher risk of developing allergic diseases, whereas the presence of Faecalibacterium, Lachnospira, Veillonella or Rothia supports immune tolerance and modulates asthma risk [34,112,113]. These findings emphasize the importance of early microbial exposures and suggest that targeted interventions, dietary, probiotic and/or prebiotic, beneficially reshape the GM, enhance SCFAs synthesis and ameliorate systemic inflammation, providing potential benefits for both asthma management and vascular health.

Environmental exposures such as hygiene practices, urban versus rural living and interactions with animals strongly shape early microbial colonization. For example, infants raised in rural households or on farms show greater colonization by beneficial bacteria like Bifidobacterium, Lactobacillus and Bacteroides, as well as higher diversity of anaerobic commensals, which is associated with lower allergy risk [114]. In contrast, children growing up in urban environments exhibit less microbial richness, altered gut and airway microbiota and increased susceptibility to asthma and sensitization [115]. Moreover, household exposures to animals and animal fecal contamination further modify the gut microbiome and resistome in early childhood, especially in less-sanitized environments [116]. A prospective analysis of over 200,000 participants from the UK Biobank found that urban environment features (air pollution, complex street networks) were associated with greater ASCVD risk, partly mediated by adverse cardiometabolic status and mental health pathways [117]. Additionally, recent studies indicate that higher levels of ambient particulate matter (PM_2.5), nitrogen dioxide (NO₂) and road traffic noise are linked to increased incident CVD risk, emphasizing these as key environmental risk factors [118,119].

Recent evidence highlights the microbiota contribution to the pathogenesis of numerous chronic diseases, including autoimmune disorders, inflammatory diseases, metabolic syndromes and cancer, through its intricate crosstalk with the host immune system [120]. Dysbiosis has been associated with increased inflammatory responses and impaired metabolic regulation, as observed in some diseases such as type 2 diabetes and obesity [121]. Moreover, microbiota composition can influence tumor initiation, progression and therapeutic outcomes [122]. Modulation of gut microbial communities, through probiotics, prebiotics or bioactive compounds like phenolics, represents an emerging therapeutic strategy aimed at restoring eubiosis and improving clinical outcomes in complex chronic diseases [123,124].

Lifestyle factors significantly influence the gut microbiota: for example, higher levels of physical activity have been associated consistently with increased microbial diversity and favorable changes in microbial composition in numerous human cohorts [125,126]. Disruption of circadian rhythms and sleep–wake cycles alters the diurnal dynamics of microbial communities and has been shown to impair gut barrier function and microbial-derived metabolite production [127]. Habitual behaviors such as excessive alcohol consumption and smoking are linked to decreased microbial diversity, increased conditionally pathogenic abundance and heightened intestinal permeability, thus promoting dysbiosis and inflammation [128,129]. Physiological stress exerts pronounced effects on the gut microbiota through activation of the hypothalamic–pituitary–adrenal (HPA) axis, sympathetic nervous system and associated hormonal mediators, which in turn alter gut motility, secretions and barrier integrity [130]. In humans, higher levels of psychological stress are associated with reductions in microbial abundance and diversity, characterized by a reduction in beneficial genera such as Lachnospira, Sutterella, Lachnospiraceae, Phascolarctobacterium and Veillonella, alongside an increased prevalence of taxa including Methanobrevibacter, Rhodococcus and Roseburia [130,131]. Animal models further reveal that stress-induced increases in glucocorticoids and catecholamines promote shifts toward potentially pathogenic taxa and increased intestinal permeability [132,133,134]. Emerging evidence shows that microbiota changes can influence stress responses by altering HPA axis activity, creating a bidirectional gut–brain feedback loop under prolonged stress conditions [135].

In recent years, the hypothesis of the existence of a "gut–lung axis" has become increasingly relevant in explaining the pathogenic mechanisms of asthma, pointing to the complex and bidirectional interaction between intestinal and pulmonary immunity [19,35,42,83]. Recent data suggest that alterations in the composition of the intestinal microbiota can influence inflammatory processes in the airways through microbial metabolites, bacterial components (such as endotoxins) and systemic immune regulation [136,137]. Prospective studies in infants have shown that delayed or abnormal development of the intestinal microbiota in the first years of life correlates with an increased likelihood of childhood asthma [112,138].

Studies have shown that fermentation of dietary fiber by Lactobacillaceae and Bifidobacteriaceae increases SCFAs, which suppress Th2-type inflammation partly via Treg induction [139,140]. Lactobacillus and Bifidobacterium enhance IL-10 and inhibit IgE-dependent responses, while probiotics also modulate Th17 pathways. DCs conditioned with Lactobacillus reuteri or Lactobacillus casei promote Th1 polarization and Treg expansion [141,142]. Probiotic use has likewise been associated with increased IFN-γ [143].

At the same time, analysis of the respiratory microbiome has shown notable differences between asthmatic patients and healthy individuals, indicating that dysbiosis in the respiratory tract may contribute to the perpetuation of chronic lung inflammation [43,144]. Taken together, this evidence supports the existence of a functional connection in the gut–lung axis, in which microbial communities at these levels interact and influence each other in the development of allergic respiratory diseases.

Changes in the composition and diversity of the airway microbiota are now widely recognized as important features of allergic asthma, reflecting both disease-related dysbiosis and immune–microbial interactions. The phylum Proteobacteria, with prominent genera such as Haemophilus and Moraxella, is often overrepresented in the respiratory tract of individuals with asthma. These taxa have been linked to epithelial barrier disruption and reduced responsiveness to corticosteroid therapy [144]. Certain members of the Firmicutes phylum, including Streptococcus species, may influence airway immune tone and inflammatory signaling, though their impact appears to vary depending on strain-specific characteristics and local microenvironmental conditions. In contrast, commensal Actinobacteria, notably Corynebacterium and Dolosigranulum, are associated with a stable, health-related airway microbiome. Their early colonization in infancy has been correlated with a lower risk of respiratory infections and allergic airway disease later in life, suggesting a protective role in maintaining epithelial and immune homeostasis [43].

The gut microbiota exerts a profound influence on immune homeostasis and allergic sensitization. Reduced abundance of Bacteroidetes in infancy has been consistently linked to an increased risk of asthma development [31]. In contrast, Clostridia (class Firmicutes), including genera such as Faecalibacterium and Roseburia, are known producers of SCFAs that enhance regulatory T-cell function and promote immune tolerance [138]. These compositional patterns suggest that both local (airway) and distal (gut) microbial shifts are intertwined in shaping asthma susceptibility and phenotype expression.

Co-sensitization to ragweed pollen and house dust mites induces a more severe allergic asthma phenotype, especially in animals receiving a high-fructose diet, which exacerbates systemic inflammation, obesity, dyslipidemia and airway hyperresponsiveness. These changes are commonly associated with diet-induced dysbiosis and metabolic imbalance [145].

Dysbiosis may disrupt immune homeostasis by promoting Th2 polarization (via increased IL-4, IL-5, IL-13 production) and diminishing regulatory responses. Conversely, specific commensals or their metabolites enhance Treg differentiation and suppress effector T-cell activation [146]. Dendritic cells and innate lymphoid cells (ILC2s) are also modulated by microbial signals, influencing antigen presentation, cytokine release and epithelial crosstalk [71].

Microbial metabolites are key mediators of the gut–lung axis.

Emerging therapeutic strategies aim to restore microbial balance and enhance host-microbe interactions.

Microbiota-based strategies hold promise for complementing standard asthma therapies by re-establishing immune balance along the gut–lung axis. However, further randomized controlled trials are needed to determine optimal microbial strains, dosage, patient phenotype, regiotype or endotype and treatment duration for clinical benefit.

In recent years, mounting evidence has implicated the intestinal microbiome as a significant modulator of CVD, including the development and progression of atherosclerosis. The “gut–heart axis” concept emphasizes that alterations in gut microbial ecology may influence vascular health through metabolic, inflammatory and immune-mediated pathways [159].

Several human cohort studies and animal investigations demonstrate that dysbiosis, for example shifts in the relative abundance of major phyla such as Firmicutes versus Bacteroidetes, or expansion of potentially pathogenic taxa is associated with increased markers of subclinical atherosclerosis and coronary artery disease [160,161,162].

The gut microbiota may not only modulate classical risk factors (hypertension, dyslipidemia, diabetes mellitus and/or obesity) but may act directly on the vascular wall and atherogenic process [163].

One of the central mechanistic links between the gut microbiome and atherosclerosis is the generation of biologically active microbial metabolites that enter the systemic circulation and act on vascular or immune targets.

Several fundamental questions remain at the forefront of cardiovascular microbiome research. A primary objective is to determine whether distinct microbial and metabolomic signatures possess sufficient specificity and reproducibility to serve as prognostic or diagnostic biomarkers for atherosclerotic disease [161].

Equally important is the rigorous evaluation of microbiota-modulating interventions, including dietary modification, administration of prebiotics or probiotics and selective inhibition of microbial enzymatic pathways, with regard to their translational applicability, safety and efficacy in human populations [208].

Moreover, the intricate interdependence between host determinants such as genetic architecture, metabolic phenotype, environmental exposures and pharmacologic treatments and their collective influence on the gut–vascular axis, remains insufficiently elucidated. Addressing these unresolved issues will require comprehensive, longitudinal and multicentric investigations integrating advanced multi-omic profiling and high-resolution vascular imaging to delineate causal mechanisms and identify clinically actionable microbial targets for precision cardiovascular medicine [209].

Recent studies indicate that allergic asthma and atherosclerosis, traditionally viewed as separate airway and vascular disorders, share microbiome-driven, immunometabolic and microRNA-mediated pathways along a gut–lung–vascular axis (Figure 2 and Figure 3, Table 1, Table 2 and Table 3) [4,138,161].

The Burkitt hypothesis, first proposed in the 1970s and later revisited in recent decades, postulated that the low incidence of “Western diseases” such as colon cancer, cardiovascular and inflammatory/metabolic disorders among rural African populations was attributable to their high dietary fiber intake [210,211,212]. Contemporary epidemiological and mechanistic studies have confirmed that fiber deficiency is strongly associated with increased risks of asthma and also atherosclerosis, largely through gut microbiota dysbiosis and reduced production of SCFAs, key metabolites with anti-inflammatory, immunomodulatory and barrier-protective properties [31,65,136,213]. Conversely, sustained consumption of fiber-rich diets enhances microbial fermentation, restores SCFA levels and supports systemic metabolic and immune homeostasis. Data suggest that increasing dietary fiber intakes by 15 g per day or to 35 g per day could extend lifespan, improve cardiometabolic health and substantially reduce long-term healthcare costs [214,215].

In both conditions, intestinal dysbiosis (reduced diversity and loss of beneficial commensals) associates with disease onset/severity in longitudinal and cross-sectional human studies, including pediatric cohorts for asthma and cardiometabolic cohorts for vascular disease [216,217,218].

A recurring signature of dysbiosis is reduced SCFA tone due to depletion of SCFA-producing taxa (e.g., Faecalibacterium, Roseburia) and low fiber intake. SCFAs promote epithelial barrier integrity, induce Treg differentiation through GPCR signaling and HDAC inhibition and dampen type-2/ILC2 and Th17-skewed airway inflammation; human cohorts link higher early-life or maternal SCFAs with lower risk of atopy/asthma [219,220]. Loss of barrier function increases translocation of microbe-derived products (metabolic endotoxemia), including LPS, which activates TLR-NF-κB signaling in distal tissues. In the airway, this fuels Th2/Th17 inflammation and bronchial hyperresponsiveness; in the vasculature, LPS/TLR signaling drives endothelial dysfunction, macrophage activation and foam-cell formation, which are central processes in atherogenesis [221,222].

Microbial metabolites also bridge gut and vessel biology. TMAO, generated from dietary choline/carnitine by gut microbes, is associated with adverse cardiovascular events in meta-analyses and cohort studies. It is also mechanistically linked to impaired cholesterol metabolism and increased vascular inflammation [223].

Beyond SCFAs and TMAO, BA signaling has emerged as a shared regulator. Microbiota-modified secondary BAs signal via FXR and the GPCR TGR5 on immune and barrier cells to restrain NF-κB-driven inflammation and remodel macrophage polarization; experimental and translational work suggests BA-receptor pathways influence pulmonary immunity and vascular tone, providing another conduit between gut metabolism and airway/vascular inflammation [220,224].

A convergent pro-inflammatory cytokine environment is increasingly recognized as a mechanistic bridge between airway and vascular pathology. Elevated levels of IL-6, IL-1β, IL-17, TNF-α and TGF-β orchestrate chronic immune activation and tissue remodeling within both pulmonary and vascular compartments. Through the activation of transcriptional regulators such as NF-κB and JAK/STAT, these cytokines amplify downstream inflammatory signaling, induce adhesion molecule expression and promote fibroblast and smooth muscle proliferation. The persistence of this signaling milieu favors structural changes in the bronchial wall and vascular endothelium, sustaining airway hyperresponsiveness and vascular dysfunction [225,226].

In both conditions, innate lymphoid cells (ILC2 and ILC3) and macrophage polarization toward pro-inflammatory M1 phenotypes amplify these cytokine cascades, perpetuating tissue infiltration and impaired resolution. The resulting oxidative stress, driven by NADPH oxidase, myeloperoxidase and mitochondrial ROS, induces endothelial activation and epithelial barrier dysfunction, key pathogenic events that contribute to both airway hyperresponsiveness and endothelial atherogenesis [227,228].

Respiratory ecosystems mirror these systemic links: enrichment of pathobiont-leaning genera such as Moraxella, Haemophilus and Streptococcus is repeatedly observed in airway microbiomes of children with asthma and relates to exacerbation-prone phenotypes, indicating that microbial community structure can amplify airway inflammation once systemic pro-inflammatory cues are present [229].

Oral–gut translocation may also contribute to vascular disease. DNA from oral taxa such as Streptococcus, Veillonella and Porphyromonas gingivalis has been detected in human atherosclerotic plaques, experimental studies show that Porphyromonas gingivalis can aggravate plaque biology via TLR-dependent effects on vascular cells and defective efferocytosis [201,205,206,230].

Together, these observations support a unifying model: dysbiosis reduces SCFA-mediated immune tolerance and barrier protection, increases systemic exposure to microbial products (e.g., LPS) and pro-atherogenic metabolites (e.g., TMAO) and perturbs BA signaling, changes that converge on shared inflammatory nodes (TLR/NF-κB, Th2/Th17 programs) in the lungs and vessel walls [166,221,222]. Clinically, the confluence of these biological pathways is evident in the coexistence of asthma and atherosclerosis [7]. Individuals with asthma exhibit an increased burden of cardiovascular outcomes, including myocardial infarction, cerebrovascular events and markers of subclinical atherosclerosis, when compared with non-asthmatic populations [3,5,7,231]. Moreover, patients with inadequately controlled asthma frequently display a clustering of cardiometabolic disturbances, such as abdominal obesity, insulin resistance, atherogenic lipid profiles and persistent low-grade inflammation, which collectively exacerbate disease severity and compromise therapeutic responsiveness [2,35,228,232,233].

This pattern of multimorbidity reinforces the idea that the gut–lung–vascular axis provides an integrated explanatory model. In this context, disturbances in the gut microbiota are not limited to gastrointestinal or metabolic consequences, but can simultaneously influence airway inflammation and vascular pathology [177,203,218]. In this way, immune and metabolic signals derived from the microbiota can shape the evolution of respiratory and cardiovascular function in the same individual, providing a unifying mechanism behind the co-expression of asthma and ASCVD.

According to a recent article, a high-fructose diet aggravates metabolic, inflammatory and vascular dysfunction in allergic asthma, while rosuvastatin ameliorates dyslipidemia, systemic inflammation, endothelial reactivity and airway remodeling [234].

The microbiome provides interface modulating these immune and redox processes. Gut dysbiosis, characterized by the loss of Faecalibacterium prausnitzii, Roseburia and Bacteroides species, reduces SCFAs production, weakening Treg induction and enabling unchecked Th17/ILC3 activation [31,166,172,220,235]. Meanwhile, microbial metabolites such as TMAO and LPS trigger endothelial and macrophage TLR signaling, bridging intestinal dysbiosis to systemic vascular inflammation [24,161]. In parallel, airway microbiota alterations, including enrichment of Haemophilus, Moraxella and Streptococcus mirror inflammatory signatures of vascular dysbiosis, suggesting microbial–immune crosstalk between airway and cardiovascular compartments [43,144,164,165].

Complementary to the gut–lung–vascular interactions discussed in our manuscript, recent work on dermatological conditions also highlights the systemic impact of intestinal dysbiosis. A review on chronic spontaneous urticaria reports that reduced microbial diversity, depletion of SCFA-producing bacteria and expansion of Proteobacteria may contribute to increased intestinal permeability, systemic immune activation and mast cell dysregulation, emphasizing the broader relevance of microbiota-driven immune disturbances across organ systems [236].