Host–gut microbiota interactions in health and disease: mechanisms and intervention strategies

The mammalian gut microbiota is a dynamically interacting ecosystem within the host’s digestive tract. It contains various microorganisms, including bacteria, fungi, and viruses. The gut microbiota (sometimes referred to as a “microbial organ”) influences host evolution and physiological regulation through its wide range of genetic and metabolic capabilities. Among these microorganisms, bacteria are the most abundant and the most extensively studied. In humans, the gut contains approximately 10¹³ bacteria, making the colon one of the largest known microbial ecosystems (Sender et al., 2016). Metagenomic studies have identified more than 10 phyla of bacteria, but in healthy adults, Bacteroidetes and Firmicutes dominate the gut microbiota. This is due to the stable ecological balance achieved by long-term symbiosis between the host and its microorganisms.

Other microorganisms, such as viruses and fungi, are often overlooked, resulting in less research compared to bacteria and a lack of comprehensive understanding. However, with the advancement of multi-omics technologies, the limitations in understanding them are gradually diminishing. Gut fungi, which constitute about 0.1% of all gut microbes, play unique ecological roles, such as shaping microbiota structure, controlling host mucosal immunity, and regulating GBA signaling. Secondary metabolites produced by some gut fungi can be useful in treating infections and may have potential functional roles (Chin et al., 2020). The gut virome may rival or surpass that of bacteria, and its composition is strongly influenced by age, diet, and location (Cao et al., 2022). As viromics progresses, increasing evidence suggests that gut viruses may contribute to the maturation of the host immune system and possibly also play a role in inflammatory diseases, metabolic disorders, and many other complex conditions.

Genomically, the gut microbiota contains a gene count that surpasses the host genome by more than a hundredfold (Gilbert et al., 2018). The swift advancement of metagenome-assembled genomes (MAGs) technology has significantly broadened our comprehension of the genomic resources of uncultured microorganisms. The gene library contains various functional modules, such as fiber degradation, short-chain fatty acid (SCFA) production, and antibiotic resistance (Zou et al., 2019). These modules provide a molecular foundation for understanding the ecological role of bacteria, developing microbial intervention strategies, and elucidating the host’s disease mechanisms. They play a pivotal role in controlling the host’s health status due to their structure, function, and dynamic changes. Future work should improve the annotation of functional genes and verify mechanisms to understand how this community contributes to maintaining host homeostasis and disease progression.

The gut microbiota, with its extensive metabolic gene pool surpassing that of the host, can convert dietary substrates that are challenging for the host to digest into a wide variety of structurally diverse metabolites. These substances influence host metabolism and immune function locally or systemically while also affecting nervous system function via the GBA.

SCFAs, key products of gut microbial metabolism, are saturated fatty acids containing fewer than six carbon atoms. The gut microbiota contains numerous enzyme genes associated with carbohydrate activation and degradation. These enzymes break down dietary fiber and other fermentable carbon sources via metabolic pathways, such as the Wood-Ljungdahl and succinate pathways, primarily producing SCFAs such as acetate, propionate, and butyrate (Shen et al., 2021). When fiber intake is insufficient, more than 80% of gut microbes encode genes for the cleavage of mucin glycans, with some encoding genes for the catabolism of derived monosaccharides, suggesting that these monosaccharides can serve as alternative energy sources (Ravcheev and Thiele, 2017). SCFAs act as signaling molecules linking the microbiota to host physiological functions. They provide an energy source for colon cells and regulate various physiological processes, such as anti-inflammatory reactions, insulin secretion, energy homeostasis, liver metabolism, and brain function once they pass into the blood (Portincasa et al., 2022).

The biotransformation of bile acids (BAs) demonstrates how gut microbiota regulate host signaling molecules. Primary bile acids are synthesized in the liver from cholesterol. Once they enter the gut, they undergo conversion into secondary bile acids through enzymatic reactions, including bacterial deconjugation and dehydroxylation. Notably, 7α-dehydroxylation is a crucial step in the production of deoxycholic acid (DCA) and lithocholic acid (LCA) (Wise and Cummings, 2022). Beyond their role in lipid absorption and cholesterol metabolism, secondary bile acids act as endogenous ligands that activate host receptors such as the farnesoid X receptor (FXR) and G protein-coupled bile acid receptor (TGR5/GPBAR1) (Cai et al., 2022). This regulation of bile acid synthesis and transport enhances intestinal barrier function, maintains immune homeostasis, and strengthens host resistance to pathogenic bacteria (Wise and Cummings, 2022; Larabi et al., 2023).

The gut microbiota can synthesize various vitamins, providing the host with micronutrients in addition to those obtained from the diet. Although the absolute amount of microbiota-derived vitamins is often smaller than that of dietary vitamins, they are essential for energy metabolism, immune cell activation, and the regulation of inflammation (Yoshii et al., 2019). Vitamins are also important for the gut microbiota network, supporting the growth and metabolism of different microbes and maintaining community structure and ecological stability through competition and sharing (Tarracchini et al., 2024). These findings indicate complex cross-feeding relationships based on vitamin dependence within the gut microbiota, which are fundamental to its ecological functions as a “microbial organ.”

Mammals and their gut microbiota form a metabolic community that helps the body absorb nutrients and use energy efficiently. The gut microbiota has complementary enzyme systems and metabolic pathways, which help the host digest complex nutrients efficiently.

SCFAs, primarily produced by the gut microbiota through the fermentation of dietary fiber, play key roles in regulating energy metabolism. Butyrate is the main energy source for colonocytes and maintains intestinal barrier structure and function. Propionic acid enters the liver via the portal vein and can serve as a precursor to gluconeogenesis (Figure 1A; Mukhopadhya and Louis, 2025). While the gut microbiota composition influences the proportion of SCFAs, their production depends more on diet, providing a biological basis for metabolic regulation via diet (Arnoldini et al., 2025). SCFAs are also important metabolic signaling molecules that promote the release of glucagon-like peptide-1 (GLP-1) and peptide YY (PYY) from intestinal L cells (Mishra et al., 2020; Nazarinejad et al., 2025), suppress appetite, improve glucose metabolism, and enhance insulin sensitivity. SCFAs also mediate epigenetic regulation of host metabolic genes through DNA methylation, histone modification, and non-coding RNA regulation, improving obesity, chronic inflammation, and other metabolic diseases (Figure 1A; Kopczyńska and Kowalczyk, 2024).

Beyond carbon sources, the breakdown of proteins by the gut microbiota significantly affects host metabolism. The gut microbiota breaks down proteins into oligopeptides and amino acids. It produces metabolites like SCFAs, indole derivatives, and hydrogen sulfide (H₂S) (Zhao et al., 2019). H₂S acts in a dose-dependent manner. At physiological doses, it promotes immune homeostasis, reduces excessive inflammation, and aids tissue repair (Dilek et al., 2020). However, in cases of gut microbiota dysbiosis, especially with the overabundance of sulfate-reducing bacteria such as Desulfovibrio, H₂S can inhibit GLP-1 secretion from L cells and disrupt glucose homeostasis and energy balance (Qi et al., 2024).

The gut microbiota regulates energy metabolism through bile acid metabolism. Secondary bile acids, such as DCA and LCA, are potent endogenous agonists of TGR5. TGR5 participates in energy, glucose, and lipid metabolism (Figure 1A; Wise and Cummings, 2022). During dysbiosis, however, the bile acid pool undergoes changes. For example, decreases in ω-muricholic acid (ω-MCA) and hyocholic acid (HCA) can reduce TGR5-mediated GLP-1 secretion, resulting in impaired blood glucose regulation and appetite control (Wang et al., 2023). Changes in the bile acid profile may play an important role in microbiota-related metabolic diseases.

Vitamins produced by the gut microbiota are important for the host’s energy metabolism. B group vitamins, key components of coenzymes for various metabolic enzymes, are involved in energy processes such as the tricarboxylic acid cycle, fat oxidation, and the electron transport chain (Yoshii et al., 2019). Vitamin K₂ (e.g., menaquinone-4) is a ligand for pregnane X receptor (PXR) and regulates the expression of genes related to hepatic bile acid synthesis and energy metabolism (Sultana et al., 2018). Vitamin B9 supplementation can change the microbiota structure, regulate lipid metabolism and energy intake, and boost the expression of metabolic genes (Chen S. et al., 2022). This suggests that vitamins, the microbiota, and the host have a network of synergistic regulation.

In summary, the gut microbiota enhances the metabolic capacity of the host genome through complex metabolic interactions and is crucial for maintaining energy balance. Dysbiosis can disrupt hormonal and metabolic signals, reprogram tissue energy metabolism, and trigger chronic, low-grade inflammation (Zarrinpar et al., 2018).

The gut microbiota establishes a complex, bidirectional communication network with the host nervous system via the GBA. Its metabolites can traverse tissue barriers and, by integrating neural, immune, and endocrine signals, significantly affect the host’s neural behavior, brain function, and the progression of neurodegenerative diseases.

Gut microbiota metabolites are essential for maintaining neural structure and function. SCFAs can cross the blood-brain barrier through monocarboxylate transporters (MCTs), promote brain-derived neurotrophic factor (BDNF) expression, activate the downstream Phosphatidylinositol3-kinase (PI3K)/Protein kinase B (Akt) pathway, increase neuronal survival, improve synaptic plasticity, and provide cognitive enhancement and neuroprotection (Figure 1C; Facchin et al., 2024; Liu et al., 2025). Microbiota metabolites are also critical environmental factors for microglia, maintaining homeostasis and proper immune function. SCFAs support the maturation and normal morphology of microglia under physiological conditions, and N6-carboxymethyllysine (CML) can trigger oxidative stress responses and mitochondrial damage in microglia (Schaible et al., 2025). This suggests that gut-derived metabolites have a bidirectional regulatory effect on brain health.

Second, gut microbiota can indirectly affect neural behavior through endocrine-neural linkages. Microbial compounds like SCFAs, BAs, and 3-indoxyl sulfate bind to enteroendocrine cells, activating the gut-vagal nerve axis, which regulates the excitability of central nervous system neurons, thereby affecting appetite, stress response, and mood (Jameson et al., 2025). The gut microbiota also synthesizes neurotransmitters such as serotonin, dopamine, norepinephrine, and γ-aminobutyric acid, activating the myenteric and submucosal plexuses of the enteric nervous system (Figure 1C; Hamamah et al., 2022).

Dysbiosis plays a role in abnormal neurobehavior and neurodevelopmental disorders. GF mice are aggressive, but early life colonization can reverse this behavior (Watanabe et al., 2021). This demonstrates the role of the microbiota in early neurobehavioral development. Further studies show that supplementation with Lactobacillus reuteri improves social deficits in mouse models of neurodevelopmental disorders, with the effective window extending into adulthood (Buffington et al., 2021). This suggests that microbiota intervention is specific to certain age stages and emphasizes the importance of the “critical developmental time window” in microbiota-behavior interactions.

Gut microbiota dysbiosis is considered a potential peripheral factor in Alzheimer’s disease (AD). Studies show that microbiota imbalance can lead to abnormal gene expression and altered microglial subtypes similar to those found in AD brains (Huang et al., 2023). Furthermore, transplanting microbiota from AD patients into healthy mice can induce AD-like neuropathological changes (Upadhyay et al., 2025). Intervention strategies targeting the microbiota can also be neuroprotective. For example, supplementation with Bacteroides ovatus or its metabolite lysophosphatidylcholine (LPC) significantly improves AD-related pathological indicators by inhibiting ferroptosis and reducing the overactivation of microglia and astrocytes (Zha et al., 2025). This provides theoretical support for microbiota- or metabolite-based interventions in neurodegenerative diseases.

The gut microbiota is important for neural development, neurophysiology regulation, and the progression of neurodegenerative diseases. Future regulatory approaches targeting the gut microbiota and its metabolites will create a new paradigm for treating neurodegenerative diseases, promising new approaches for abnormal neural behavior and degenerative diseases.

The host is not only passively subject to colonization but also actively shapes and regulates the composition and metabolic activity of the gut microbiota through many layers of interrelated regulatory mechanisms. These host-induced changes are mediated by food, mucosal immune responses, endogenous metabolic products, the physicochemical features of the intestinal environment, and lifestyle factors. Together, they create a bidirectional regulatory system that maintains microbial homeostasis and supports overall host health.

Cardiovascular disease (CVD) is one of the leading causes of death worldwide. Atherosclerotic cardiovascular disease (ASCVD) is a primary type of CVD and is influenced not only by dyslipidemia. One manifestation of ASCVD is gut microbiota dysbiosis, with more pathogenic bacteria such as Megamonas, Veillonella, and Streptococcus, and fewer anti-inflammatory bacteria such as Bifidobacterium and Roseburia (Alexandrescu et al., 2024). Pro-inflammatory bacteria similar to those present in gut microbiota are also found in plaques, suggesting that microbiota translocation may be involved in local inflammation (Pisano et al., 2023).

TMAO, a crucial metabolite derived from gut microbiota, plays a significant role in promoting atherosclerosis (Figure 2C). It promotes the expression of inflammatory including cytokines TNF-α and IL-6, expression and regulates macrophage foaming through the CD36/MAPK/JNK pathway. TMAO also disrupts plaque stability by causing endothelial pyroptosis, inhibiting antioxidant pathways, and stimulating thrombus formation (Geng et al., 2018; Zhai et al., 2025). A lack of SCFAs also increases systemic inflammation and promotes plaque formation (Brandsma et al., 2019). A high-fat diet or irregular daily routine can disrupt the circadian rhythm of gut microbiota, which leads to increased TMAO levels and lower SCFAs levels. This increases the risk of early morning vascular endothelial dysfunction and thrombosis (Zhai et al., 2025).

In heart failure (HF), gut microbiota dysbiosis exhibits a “double-hit” pattern (Figure 2C). First, the population of beneficial bacteria declines, while pro-inflammatory bacteria proliferate. This shift is accompanied by increased production of LPS and TMAO, along with reduced synthesis of SCFAs (Cui et al., 2018). TMAO can promote the transformation of cardiac fibroblasts into myofibroblasts and aggravate cardiac fibrosis and cardiac functional injury (Yang et al., 2019). Second, decreased cardiac output results in insufficient intestinal perfusion and venous congestion, which heighten intestinal permeability (Mahenthiran et al., 2024). This facilitates the translocation of LPS into the bloodstream, activating the TLR4/NF-κB inflammatory pathway and worsening myocardial injury (Zhang et al., 2025). Additionally, the reduction in SCFAs diminishes their anti-inflammatory, energy-providing, and microenvironment-repairing functions (Palm et al., 2022). Gut microbiota and its metabolites play a role throughout the progression from ASCVD to HF through translocation, metabolism, and microenvironment reconstruction, providing a new avenue for precise intervention.

Diet plays an important role in mammalian health and disease development. A balanced diet helps maintain homeostasis and can also be used to treat chronic diseases. One way diet affects mammals is through the regulation of gut microbiota.

A high fiber diet can contribute to the abundance and diversity of gut microbiota, improve microbiota structure, and increase the abundance of beneficial bacteria such as Parabacteroides and Ruminococcaceae, while reducing the presence of pro-inflammatory bacteria such as Clostridium (Wang Z. et al., 2022). It also provides substrates for SCFA-producing bacteria to increase SCFA levels in the body. SCFAs are important for maintaining the energy supply to the intestinal epithelium, strengthening barrier function, and controlling immune inflammation and metabolism. This mechanistic basis provides the potential for high-fiber diets to be used in the treatment of chronic diseases such as IBD, T2DM, CVD, and neurological disorders.

In contrast, a long-term high-fat diet can shift gut microbiota toward the “pro-inflammatory and pro-obesity” state (Imdad et al., 2024), with a lower Bacteroidetes-to-Firmicutes ratio, lower microbiota diversity, and higher levels of harmful bacteria. This imbalance in microbiota is considered one of the main mechanisms through which a high-fat diet promotes obesity and metabolic diseases.

Beyond the type of diet, the timing of eating, or dietary rhythm, significantly affects gut microbiota. Intermittent fasting can improve gut microbiota diversity, increase beneficial bacteria such as Bifidobacterium and Lactobacillus, and improve the host’s lipid profile (Khan et al., 2022). Intermittent fasting restores the metabolic rhythm of SCFAs by controlling gut microbiota function, and SCFAs, as important signaling molecules, act on multiple organs in the body through circulation, improving metabolic health (Ceperuelo-Mallafré et al., 2025). Feeding rhythms regulate segmented filamentous bacteria (SFB) attachment rhythms, which in turn regulate the rhythmic expression of antimicrobial proteins, thereby affecting resistance to infection (Brooks et al., 2021). However, the effects of dietary interventions depend on individual differences. Some studies show that identical dietary interventions can actually increase differences in gut microbiota among individuals (Vermeulen et al., 2025). Future precision nutrition interventions should take into account baseline microbiota, genetic background, immune status, and metabolic characteristics of the host to create customized plans for regulating gut microbiota.

Probiotics are living organisms that provide health benefits to the host when consumed in sufficient quantities. They improve intestinal health by strengthening the barrier, enhancing beneficial flora, increasing beneficial metabolites, improving mucosal immunity, and decreasing inflammation. They also prevent pathogenic bacterial colonization through competitive exclusion and metabolic interference, thereby maintaining intestinal homeostasis (Du et al., 2025; Qu et al., 2025). Some probiotics also activate tryptophan metabolism, upregulating indole-3-lactic acid production (Du et al., 2025), which has anti-inflammatory and promotes intestinal repair.

Traditional probiotic products typically rely on strains chosen based on empirical knowledge. These strains offer a broad array of functions but lack targeted effects, and their mechanisms of action are not fully understood, resulting in generalized efficacy issues. Recently, next-generation probiotics have emerged due to their advantages, including well-defined strain functions that allow personalized treatment of particular diseases and can be precisely engineered using multi-omics approaches (Jan et al., 2024). However, technical difficulties persist for next-generation probiotics, and their long-term safety and efficacy must be tested through randomized controlled trials.

Prebiotics are substances that the host does not digest or absorb but are selectively used by probiotics. For example, fructooligosaccharides can be consumed by probiotics to help them grow and inhibit pathogenic bacterial colonization. The SCFAs produced during the fermentation of prebiotics in the intestinal tract are essential for their health benefits (Singh P. et al., 2025). Unlike probiotics, prebiotics do not require the introduction of live bacteria, have stable physical and chemical properties, and can be easily integrated into functional foods or pharmaceuticals. However, effects vary among individuals and depend on the dose; excessive intake may cause discomfort, such as abdominal distension.

Probiotic and prebiotic interventions have shown promise for disease prevention and treatment, but their effectiveness differs according to strain types, host conditions, and disease types, leading to inconsistent reproducibility of results (Sharpton et al., 2019). In the future, a predictive model for microecological interventions could be developed using artificial intelligence to identify the best strain combinations and suitable populations from vast data sets. Large-scale clinical trials are needed to support their long-term effectiveness and safety.

FMT involves transferring fecal microbiota from healthy donors into a patient’s gut to restore the balance of the recipient’s gut microbiome. By reconstructing microbiota diversity, optimizing microbiota structure, inhibiting pathogens, and regulating immune function, this method can correct gut microbiota dysbiosis and potentially treat various diseases (Brunse et al., 2019; Reddi et al., 2025).

In treating recurrent Clostridioides difficile infection (rCDI), FMT has shown high efficacy, with cure rates ranging from 70 to 91% in clinical studies, far exceeding those of antibiotics (Weerakoon et al., 2025). FMT could also be useful in other diseases, such as irritable bowel syndrome, metabolic disorders, and immune diseases.

However, as FMT has become more widely used in clinical practice, risks and challenges have become apparent. In 2019, two patients developed bacteremia from highly drug-resistant Escherichia coli within days of FMT; one died. Tracing showed that the resistant strains were from the same donor (DeFilipp et al., 2019), suggesting that FMT could serve as a conduit for the horizontal transmission of antimicrobial-resistant pathogens. Furthermore, the colonization efficiency of donor strains is low. Metagenomic tracking showed that only 10.8% of donor strains can stably colonize long-term, while most are cleared or fail to establish (Podlesny et al., 2022). Factors influencing colonization efficiency include the baseline structure of the recipient’s gut, antibiotic pre-treatment, donor-recipient strain compatibility, and individual strain ecological adaptability.

FMT provides a direct and effective approach to gut microbial reconstruction and can be used to treat refractory dysbiosis diseases. However, balancing therapeutic efficacy and safety remains a priority for future research and clinical applications. Advances in understanding colonization mechanisms, artificial intelligence-based donor–recipient matching algorithms, and personalized synthetic microbial consortia can improve the success rate and safety of FMT, resulting in better microbiome restoration.

Drug interactions with the gut microbiota are bidirectional. Antibiotics, as core anti-infective agents, profoundly impact gut microbial communities. Broad-spectrum antibiotics target pathogenic bacteria but also disrupt commensal populations, leading to lower diversity, structural imbalance, and enrichment of resistance genes, resulting in dysbiosis (Suvvari et al., 2025). Epidemiological studies have linked excessive antibiotic use to an increased risk of asthma, obesity, diabetes, and other immune-metabolic disorders, with dysbiosis considered a potential mediating mechanism (McDonnell et al., 2021). Moreover, alterations in microbial composition and metabolic function may persist for months after antibiotic cessation—a phenomenon termed the “antibiotic scar” by Anthony et al. (2022)Anthony et al. (2022). This long-term and potentially irreversible effect underscores the importance of rational antibiotic use, awareness of long-term risks, and precise microbiota-targeted interventions.

On the other hand, certain pharmaceuticals require biotransformation by the gut microbiota to generate their active forms, thereby exerting therapeutic effects. A prime example of this is sulfasalazine, which is cleaved by azoreductase enzymes in gut microbes, releasing sulfapyridine and 5-aminosalicylic acid (Doestzada et al., 2018). These metabolites exert the anti-inflammatory effects in the colon, playing a crucial role in the treatment of ulcerative colitis. However, the gut microbiota can also influence drug efficacy and toxicity. For example, microbial β-lactamases can hydrolyze antibiotics and protect both the host and the bacteria from antimicrobial effects, while simultaneously reducing efficacy against infections (Jeong et al., 2024). These findings prompt us to consider whether enhancing drug efficacy could be achieved by modulating the activity of relevant enzymes within the gut microbiota.

Targeting key microbial enzymes with small molecule inhibitors has been proposed as a novel tool for precise microbiota intervention. Unlike antibiotics, such approaches modulate microbial metabolism without killing bacteria, theoretically conserving beneficial functions. Moreover, 3,3-dimethyl-1-butanol (DMB) inhibits gut microbial trimethylamine (TMA) lyase, thus reducing the level of the pathogenic metabolite TMAO and decreasing the risk of CVDs such as atherosclerosis (Motte et al., 2025). Microbial TDC can convert levodopa into dopamine directly in the gut, thereby diminishing its therapeutic activity in PD (Romano et al., 2025). Based on this, Rekdal et al. developed selective TDC inhibitors, (S)-α-fluoromethyltyrosine (AFMT), which block microbial metabolism of levodopa in vivo, increasing plasma drug exposure and bioavailability (Maini Rekdal et al., 2019).

However, targeting microbial enzymes is a double-edged sword. Long-term use of inhibitors can induce compensatory changes in microbial metabolic networks, leading to off-target effects or resistance in strains. Most current studies are limited to animal models. Safety and efficacy evaluations require long-term studies in animals and clinical trials.

Metagenomics is one of the key areas of microbiome research and allows for the analysis of the gene composition and functional potential of bacteria in samples through high-throughput sequencing. This technology not only detects species composition but also predicts metabolic pathways, antibiotic resistance genes, and other functions. With the rapid development of metagenomics next-generation sequencing (mNGS), metagenomic analysis has become much faster and more accurate. For example, mNGS can measure differences in fiber-degrading genes in pigs with different physiological features. Research suggests that the gut microbiota of sows with high reproductive performance is richer in carbohydrate-active enzyme (CAZyme) genes and fiber-degrading bacteria. Fiber-degrading capability could be used as a biomarker for host health and production performance (Miura et al., 2024). However, mNGS has difficulty resolving repetitive sequences, large-scale structural variations, and strain-level resolution. Hence, hybrid sequencing approaches combine the strengths of sequencing technologies to help tackle genomes at the strain level and provide a higher resolution analytical framework for gut microbiota research (Chen L. et al., 2022).

Metagenomics can predict the potential of the microbiota but cannot directly quantify its metabolites. Metabolomics, based on the analysis of metabolites in biological samples, can indicate the metabolic activity of microbiota and the effect on the host. In gut microbiota research, targeted metabolomics can be used for the quantitative analysis of specific metabolites, such as TMAO and SCFAs. Kuo et al. (2022) found a significant correlation between serum TMAO and metabolic syndrome in patients with coronary artery disease (Kuo et al., 2022), further confirming the role of microbiota metabolites in the pathogenesis of CVDs. Multi-omics integrated analysis, combining metagenomics and metabolomics, can establish association networks from microbiota genes to metabolic functions. For example, in vascular calcification research, metagenomics identifies microbiota gene markers and metabolic pathways associated with the disease, while metabolomics validates the effects of relevant metabolites, such as methionine, on host function and correlates with disease severity (Huang et al., 2026). A dual-omics collaborative approach forms a complete evidence chain from prediction to intervention and provides a new model for understanding gut microbiota action.

Single-cell sequencing (scSeq) has moved microbiota research from a community-wide perspective to single-cell analysis. It addresses the heterogeneity of host cells, captures gene expression data from both host cells and microbiota, and shows the host-microbiota interaction network (Chen et al., 2017). Single-cell correlation analysis shows that gut microbiota can work together with immune checkpoint inhibitors to enhance antigen presentation and T-cell activation in tumors (Cao et al., 2025). Although current studies focus on host cells and rarely investigate single-cell analysis of the metabolic state of the microbiota, single-cell and microbial single-cell sequencing technologies will allow researchers to characterize the microbiota’s functional state and its interaction network with the host at single-cell and single-bacterium levels, offering new opportunities for precise research.

To establish a causal link between gut microbiota and host phenotypes, and to thoroughly examine their interaction mechanisms, a reliable experimental model system is essential. GF animal models and intestinal organoids serve as the two primary tools in this field, effectively complementing one another.

GF mice have several advantages in studying the causal effects of the microbiota on host physiology, immunity, and diseases. Mice raised in germ-free conditions exhibit developmental defects in different systems, such as structural defects in gut lymphoid tissues and underdeveloped immune cells (Shen J. et al., 2025). Colonizing GF mice with specific strains or microbiota allows for the observation of effects on host physiological or disease phenotypes, thereby establishing causality. For example, transplantation of fecal bacteria from patients into GF mice can replicate disease phenotypes, thereby demonstrating the microbiota’s pathogenic role in those diseases (Sheikh et al., 2024).

The GF animal model faces challenges such as species differences, high maintenance costs, and ethical issues, which motivate researchers to seek alternative solutions. Organoid technology, closely modeling physiological conditions, provides a controllable platform with minimal ethical concerns for studying host-microbiota interactions. In intestinal research, organoids are useful for modeling IBD, personalized drug screening and toxicity evaluation, and have wide potential for application (Fatehullah et al., 2016). Using a bacteria-organoid co-culture system, researchers found that Bacillus subtilis promotes the differentiation of intestinal stem cells into secretory cells, improves intestinal barrier function, and reduces infection risk (Hou et al., 2022). Organoids lack a vascular system; activation with CHIR99021, FGF4, and VEGFA may induce vascular networks in intestinal organoids (Miao et al., 2025), offering new approaches for developing mature organoid models with complete microenvironmental interactions.

High-throughput omics technologies have produced vast amounts of gut microbiota data, and artificial intelligence, particularly machine learning (ML), can be used to extract patterns from these huge datasets. ML finds patterns in training data to predict new samples. ML is promising for disease prediction, diagnosis, and personalized intervention.

ML models using gut microbiota characteristics can significantly improve disease prediction accuracy. For example, the Comprehensive Data Optimization and Risk Prediction Framework (CDORPF) can predict IBD with 90.4% accuracy and has robust and generalization capabilities (Peng et al., 2024). The framework integrates and optimizes multi-source microbiota data, showing that microbiota-based ML diagnosis provides non-invasive and highly efficient advantages.

ML, combined with deep reinforcement learning and multi-objective optimization, can quickly identify the best strain combinations for specific diseases by analyzing large data on probiotic-host interactions. This allows researchers to adjust dosages and ratios with dynamic feedback for target interventions. For example, by using high-throughput gut-on-chip and unsupervised ML, researchers can quantify the differences among different probiotics against enteritis and have identified Bifidobacterium longum 3–14 as the most effective strain for IBD among several strains (Wu et al., 2024). Such techniques allow rapid optimization of probiotic combinations, reduce animal experiments, and speed up the development of customized microbiota interventions.

However, the application of ML still faces several critical challenges, including data bias that may lead to unreliable models or results, limited model interpretability, and obstacles to reproducibility (Zhou and Zhao, 2025). Future efforts should focus on developing novel data imputation methods and ML models to enhance data quality and model interpretability. Furthermore, as ML captures correlations rather than causation, integrating diverse omics data types could deepen our understanding of the microbiome-host health interaction. This approach holds promise for building more precise models and improving predictive capabilities, thereby opening new avenues for precision medicine and drug development.