Mechanisms of Gut Microbial Enzyme-Mediated Metabolism of Glucuronide Conjugates and Drug Biotransformation
Mechanisms of Gut Microbial Enzyme-Mediated Metabolism of Glucuronide Conjugates and Drug Biotransformation
Glucuronidation is an important phase II metabolic pathway in the clearance of drugs and endogenous metabolites, but its biological consequences do not necessarily terminate once the host conjugation reaction is completed. After large amounts of glucuronide conjugates enter the intestinal lumen through biliary excretion or intestinal epithelial transport, they may undergo deconjugation under the action of gut microbiota-derived enzyme systems, thereby re-releasing parent drugs, active metabolites, or intermediates with toxic potential, and further altering the extent of enterohepatic circulation, local exposure levels, systemic pharmacokinetic processes, and the spectrum of adverse reactions. Therefore, gut microbial enzyme-mediated deconjugation is an important reprocessing step after host conjugative metabolism and also a key entry point for understanding interindividual variability in drug response, microbiota-dependent toxicity, and co-metabolic regulation.
Keywords: gut microbiota; glucuronide conjugates; beta-glucuronidase; drug biotransformation; enterohepatic circulation; pharmacokinetics; toxicity reactivation; microbial metabolism
1. Formation, Transport, and Intestinal Re-Exposure of Glucuronide Conjugates
1.1 Glucuronidation is an important component of the host clearance system
(1) The core function of glucuronidation is to increase hydrophilicity and promote excretion
After drugs and their phase I metabolites are catalyzed by UDP-glucuronosyltransferases, they form glucuronide conjugates, which generally exhibit increased polarity, enhanced water solubility, and reduced membrane permeability. These changes facilitate excretion through bile, urine, or intestinal epithelial transport systems and are therefore often regarded as a typical detoxification and inactivation process.
(2) Conjugation does not necessarily mean terminal inactivation
For some compounds, glucuronidation does significantly reduce the binding capacity of the parent drug to its target; however, for other drugs or endogenous metabolites, this step more often represents transient inactivation and cross-organ redistribution rather than the true end of the metabolic chain. Once these conjugates enter the intestinal lumen and are hydrolyzed again by microbial enzymes, their pharmacological activity, toxic potential, and local exposure patterns may all be redefined.
1.2 The intestinal phase is a critical node at which the fate of glucuronide conjugates diverges
(1) Biliary excretion delivers large amounts of conjugates into the intestinal lumen
Many glucuronide conjugates with relatively large molecular weights, high polarity, or specific transport characteristics are more likely to be excreted into the intestine through bile rather than cleared directly by the kidney. After entering the intestinal lumen, the subsequent fate of these compounds is jointly influenced by host transport processes and the gut microbial enzymatic network.
(2) The intestinal lumen is an important compartment for conjugate reprocessing
In the intestine, glucuronide conjugates may further undergo multiple processes, including deconjugation, hydrolysis, reabsorption, reconjugation, rereduction, dehydroxylation, demethylation, or fermentative utilization. Therefore, the intestine is not a passive terminal site of drug metabolism, but rather a reprocessing compartment formed by the coupling of host and microbial metabolism.
2. Key Enzyme Systems Involved in Glucuronide Conjugate Metabolism
2.1 Host-side enzymes determine how conjugates are formed
(1) The UGT family are the core executors of glucuronidation
The UGT family determines whether a drug enters the glucuronidation pathway, where conjugation occurs, and how efficient the process is. Among them, UGT1A1, UGT1A9, and UGT2B7 are of representative importance in the metabolism of many drugs. Differences in the expression of distinct UGT subtypes determine whether individuals differ in their ability to form conjugates from the same drug.
(2) Phase I metabolic enzymes influence whether subsequent glucuronidation can occur
Before undergoing glucuronidation, many drugs must first be converted by CYP enzymes, esterases, or reductases into hydroxylated, carboxylated, or de-esterified products that are more suitable for conjugation. Therefore, the formation of glucuronide conjugates is not solely the result of UGT activity, but rather the product of the sequential action of phase I and phase II metabolism.
2.2 Microbial enzymes determine whether conjugates can be deconjugated and further transformed
(1) Beta-glucuronidase is the most critical deconjugating enzyme
This enzyme can directly hydrolyze the glucuronide bond and release the original aglycone, making it the core functional enzyme in the intestinal reactivation process. For irinotecan, mycophenolic acid, and certain nonsteroidal anti-inflammatory drugs, this step often directly determines whether re-exposure and toxicity reactivation occur.
(2) Subsequent microbial enzymes can further reshape the fate of the released aglycone
Deconjugation is only the first step. After release, the aglycone may continue to undergo the action of microbially derived reductases, dehydroxylases, demethylases, azoreductases, or lyases, thereby generating new microbiota-derived metabolites. The actual outcome of drug biotransformation usually depends on the coordinated action of deconjugating enzymes and downstream transforming enzymes, rather than on a single enzymatic step.
Table 1. Key enzymes involved in gut microbial enzyme-mediated metabolism of glucuronide conjugates
Enzyme class | Representative enzyme/family | Main reaction step | Significance for drug biotransformation |
Host phase I metabolic enzymes | CYP family | Activation of drug precursors or structural modification | Provide conjugatable sites for subsequent glucuronidation |
Host hydrolases | Carboxylesterases | Prodrug activation, ester bond hydrolysis | Generate active metabolites that can be further conjugated or reactivated |
Host phase II metabolic enzymes | UGT1A1 | Glucuronidation | Forms representative conjugates such as SN-38G |
Host phase II metabolic enzymes | UGT1A9 | Glucuronidation | Participates in the metabolism of many phenolic hydroxyl- and carboxyl-containing drugs |
Host phase II metabolic enzymes | UGT2B7 | Glucuronidation | Participates in the conjugative metabolism of many drugs and endogenous molecules |
Microbial deconjugating enzymes | Beta-glucuronidase | Deconjugation hydrolysis | Releases parent drugs or active/toxic aglycones |
Microbial reductases | Nitroreductases, carbonyl reductases, etc. | Downstream aglycone modification | Alter the activity and stability of the released molecules |
Microbial dehydroxylases | Aromatic dehydroxylation-related enzyme systems | Deep transformation of aromatic aglycones | Reshape the terminal metabolic profile of the released products |
Microbial demethylases | O-demethylation-related enzyme systems | Removal of aromatic methoxy groups | Generate new active or inactive derivatives |
Microbial lyases | Aromatic ring-cleavage-related enzyme systems | Further degradation of small molecules | Promote conversion of drugs into terminal microbial metabolites |
3. Pharmacokinetic and Toxicological Consequences of Deconjugative Metabolism
3.1 Enterohepatic circulation is one of the most important systemic consequences of deconjugative metabolism
(1) Reabsorption after deconjugation can markedly prolong in vivo drug exposure
When glucuronide conjugates are hydrolyzed in the intestine and release parent molecules that are more readily absorbable, the drug can re-enter the portal vein and systemic circulation through the intestinal epithelium, thereby forming a typical enterohepatic circulation process. This process can prolong the apparent half-life, maintain plasma drug concentrations, and increase overall exposure.
(2) Secondary absorption reshapes the kinetic structure of exposure
Enterohepatic circulation often causes drug concentration-time curves to exhibit kinetic features such as double peaks, multiple peaks, or prolongation of the terminal elimination phase. Therefore, microbiota-mediated deconjugation does not merely increase total exposure; more importantly, it can remodel the kinetic structure of exposure, thereby influencing dosing frequency, duration of action, and assessment of accumulation risk.
3.2 Deconjugation can cause high local exposure
(1) The intestinal mucosa is the first site exposed to rereleased active molecules
In many cases, molecules released after deconjugation are not immediately and completely absorbed, but instead first establish a state of high local exposure in the intestinal lumen and on the intestinal mucosal surface. If the molecule itself has cytotoxic, irritative, or pro-inflammatory properties, local toxicity often emerges before systemic effects.
(2) Local re-exposure often constitutes the key layer in toxicity interpretation
Some drugs may not show prominent systemic toxicity, yet after deconjugation of their glucuronide conjugates in the intestine, they may cause severe diarrhea, mucosal injury, or enteritis-like reactions. Therefore, research should not be confined to plasma drug concentrations alone, but should also analyze the process of local rerelease within the intestinal lumen.
Table 2. Major consequences of gut microbial enzyme-mediated drug biotransformation of glucuronide conjugates
Transformation type | Direct result | Pharmacokinetic impact | Pharmacodynamic/toxicological impact |
Reabsorption after deconjugation | Parent drug re-enters circulation | Prolonged half-life, increased AUC | May prolong drug efficacy, but may also increase systemic toxicity |
Local accumulation after deconjugation | Active or toxic molecules rise locally in the intestinal lumen | High local exposure | May cause intestinal mucosal injury, inflammation, and diarrhea |
Reoxidation/reconjugation after deconjugation | Re-entry into host metabolic circulation | Increased metabolic cycling complexity | Alters exposure duration and interindividual variability |
Further microbial transformation after deconjugation | Generation of novel microbiota-derived metabolites | Reshapes the terminal metabolic profile | May alter activity, toxicity, or target spectrum |
Reduced deconjugation capacity | More complete clearance of conjugates | Weakened enterohepatic circulation | May reduce toxicity, but may also shorten the duration of drug action |
4. Representative Drug and Endogenous Molecule Scenarios
4.1 Irinotecan-related toxicity is a classic model of “host conjugation-microbial deconjugation-local reactivation”
(1) SN-38G is not a truly safe endpoint
The active irinotecan metabolite SN-38 is glucuronidated by the host to form SN-38G, which originally facilitates inactivation and excretion; however, after entering the intestine, it can be hydrolyzed again by microbial beta-glucuronidase to release SN-38, resulting in renewed exposure of the intestinal mucosa.
(2) Local reactivation directly drives delayed diarrhea
This process constitutes an important mechanistic basis for irinotecan-related delayed diarrhea and intestinal mucosal injury, and it has therefore become a representative model for studies of strategies targeting microbial deconjugating enzymes.
4.2 Mycophenolic acid-related gastrointestinal toxicity indicates that immunosuppressants are likewise affected by microbial deconjugation
(1) Glucuronide metabolites of mycophenolic acid can rerelease active mycophenolic acid
After glucuronide conjugates formed during mycophenolic acid metabolism enter the intestine, they can be converted back to mycophenolic acid under the action of microbial beta-glucuronidase, thereby participating in enterohepatic circulation and altering the exposure profile.
(2) Increased microbial enzyme activity can simultaneously amplify therapeutic exposure and gastrointestinal intolerance risk
The activity of microbial beta-glucuronidase is mechanistically linked to mycophenolic acid-related gastrointestinal intolerance, indicating that adverse effects of immunosuppressants are not determined solely by host metabolism.
4.3 Intestinal injury related to nonsteroidal anti-inflammatory drugs may likewise be associated with deconjugation
(1) Acyl glucuronide metabolites of certain NSAIDs can enter enterohepatic circulation
Represented by diclofenac, some drugs form glucuronide-related metabolites that can enter the intestine through bile and participate in recirculation under the influence of the microbiota.
(2) There is a clear mechanistic link between deconjugation and intestinal injury
Inhibition of intestinal beta-glucuronidase activity can attenuate diclofenac-related enterohepatic circulation and reduce enteropathy-like injury, suggesting that this process influences not only pharmacokinetics but also toxic expression.
4.4 Hormones and bile-related endogenous molecules are also important subjects within this mechanistic framework
(1) Estrogen-related glucuronide conjugates can be regulated by microbial deconjugation
Estradiol, estrone, and their related conjugates may be influenced by microbial deconjugation in the intestine, thereby altering the extent of reabsorption and systemic hormonal homeostasis. This process is relevant not only to endocrine balance, but also to the formation of exposure differences in hormone-based drugs.
(2) Bilirubin and other bile-related substrates help broaden the scope of this field
The conjugation-deconjugation processes of bilirubin and certain bile-related metabolites indicate that this mechanism is not limited to exogenous drugs, but also involves reprocessing of endogenous host molecules in the intestine. Therefore, intestinal deconjugation has broader significance in metabolic regulation.
5. Commonly Used Products in Studies of Gut Microbial Enzyme-Mediated Glucuronide Conjugates
5.1 Enzymatic Products for Research on Glucuronide Biotransformation
Catalog No. | Product Name | Grade and Purity | Mechanistic Step | Research Direction / Intended Use |
Human CYP1A2,High-Reductase | — | Host phase I metabolism | Suitable for studying oxidation of aromatic drug precursors and for evaluating structural modification steps before glucuronidation. | |
Human CYP2C9,High-Reductase+b5 | — | Host phase I metabolism | Suitable for studying oxidative metabolism of common drugs such as NSAIDs, and can be linked with model compounds such as diclofenac, naproxen, and ibuprofen to analyze the “oxidation–conjugation–intestinal re-exposure” pathway. | |
Human CYP2E1,High-Reductase+b5 | — | Host phase I metabolism | Suitable for studies of small-molecule drug activation and oxidative metabolism, and can serve as a supplementary upstream model before glucuronidation. | |
Human CYP3A4,High-Reductase+b5 | — | Host phase I metabolism | Suitable for broad-spectrum drug metabolism studies and is one of the most representative CYP tools for constructing in vitro systems of “host metabolism–conjugate formation–intestinal reprocessing.” | |
Human CYP3A5,High-Reductase +b5 | — | Host phase I metabolism | Suitable for comparison with CYP3A4 to analyze how differences in precursor generation under different CYP backgrounds affect subsequent glucuronidation potential. | |
Micro Carboxylesterase (CarE) Activity Assay Kit (1-Naphthyl acetate, Micro Method) | BioReagent | Host hydrolysis / prodrug activation | Suitable for studies related to activation of prodrugs such as irinotecan, and can be used to connect the classic mechanistic model of “CarE generation of active metabolites–UGT conjugation–microbial deconjugation and reactivation.” | |
Carboxylesterase (CarE) Activity Assay Kit (1-Naphthyl Acetate, Colorimetric Method) | BioReagent | Host hydrolysis / prodrug activation | Suitable for routine-throughput CarE activity determination and can serve as a basic tool for evaluating prodrug activation capacity and for subsequent SN-38/SN-38G studies. | |
β-Glucuronidase from abalone | Purified, aqueous solution, β-glucuronidase 150,000-250,000 units/mL, β-glucuronidase≥20,000,000 units/g protein | Microbial deconjugation | Suitable for high-activity liquid enzyme systems and can be directly used for hydrolysis of glucuronide conjugates and evaluation of deconjugation efficiency. | |
β-Glucuronidase | Bioactive,Recombinant,ActiBioPure™,High Performance,EnzymoPure™,≥5000 U/mg enzyme powder; ≥30000 U/mg protein | Microbial deconjugation | Suitable for constructing standardized recombinant enzyme deconjugation models, facilitating substrate comparison, kinetic analysis, and inhibition studies. | |
β-Glucuronidase from Escherichia coli | ActiBioPure™, Bioactive, High Performance, EnzymoPure™, ≥10,000 U/mg protein | Microbial deconjugation | Suitable for routine enzymology experiments, substrate screening, and comparison of hydrolytic capacity toward different glucuronide conjugates. | |
β-Glucuronidase from Escherichia coli | Type VII-A, lyophilized powder, 5,000,000-20,000,000 units/g protein, pH 6.8 (30 min assay) | Microbial deconjugation | Suitable for deconjugation experiments requiring high activity and a stable liquid system, and can be used for mechanistic validation and kinetic studies. | |
β-Glucuronidase from Escherichia coli | Recombinant, ≥20,000,000 units/g protein, expressed in E. coli, aqueous glycerol solution | Microbial deconjugation | Suitable for rapid modeling in liquid enzyme systems and for in vitro hydrolysis of glucuronide conjugates and condition optimization. | |
β-Glucuronidase from limpets (Patella vulgata) | aqueous glycerol solution,≥5,000,000 units/g protein, pH 6.8 (biuret) | Microbial deconjugation | Suitable for comparing activities of β-glucuronidases from different sources and for studying substrate-source preferences. | |
β-Glucuronidase from limpets (Patella vulgata) | ActiBioPure™, Bioactive, BioPerformance Certified, EnzymoPure™, 1000-5000 U/mg protein | Microbial deconjugation | Suitable for source-difference comparison and routine hydrolysis experiments, and can serve as a supplementary non-bacterial enzyme model. | |
β-Glucuronidase from limpets (Patella vulgata) | aqueous solution,≥85,000 units/mL | Microbial deconjugation | Suitable for lyophilized enzyme formulation scenarios and for deconjugation experiments requiring long-term storage followed by reconstitution. | |
β-Glucuronidase from Helix aspersa (garden snail) | aqueous solution | Microbial deconjugation | Suitable for functional comparison of β-glucuronidases from different animal sources, expanding the range of deconjugation model sources. | |
β-Glucuronidase from bovine liver | Type L-II, lyophilized powder, 1,000,000-3,000,000 units/g solid | Microbial deconjugation | Suitable for comparative studies of deconjugation capacity between host-derived and microbially derived enzymes. | |
β-Glucuronidase from Helix pomatia | Type HA-4 | Microbial deconjugation | Suitable for deconjugation validation in liquid enzyme systems and for analyzing activity differences among enzymes from different sources. | |
β-Glucuronidase from Helix pomatia | Type B-3,≥2,000,000 units/g solid | Microbial deconjugation | Suitable for substrate hydrolysis and rapid mechanistic validation in relatively high-activity liquid systems. | |
β-Glucuronidase from Helix pomatia | Type H-3AF, aqueous solution,≥60,000 units/mL | Microbial deconjugation | Suitable for reconstruction of glucuronide deconjugation reactions and comparison of source-dependent differences. | |
β-Glucuronidase from Helix pomatia | Type HP-2, aqueous solution,≥100,000 units/mL | Microbial deconjugation | Suitable for mechanistic studies under powdered enzyme system conditions and with partially purified enzyme preparations. | |
β-Glucuronidase from Helix pomatia | Type H-2, aqueous solution,≥85,000 units/mL | Microbial deconjugation | Suitable for substrate screening and stability studies using lyophilized enzyme preparations. | |
β-Glucuronidase from Helix pomatia | Type H-1, partially purified powder,≥300,000 units/g solid | Microbial deconjugation | Suitable for routine liquid enzyme hydrolysis systems and deconjugation experiments with good reproducibility. | |
MS β-Glucuronidase | Type H-5, lyophilized powder,≥400,000 units/g solid | Microbial deconjugation / sample preparation | Suitable for automated pretreatment and mass-spectrometry sample hydrolysis workflows, and can be used to establish analytical workflows after deconjugation of glucuronide conjugates. |
5.2 Substrates and Tool Reagents for Research on Glucuronide Biotransformation
Name | CAS No. | Experimental step | Key use | Use notes |
D-Glucaric acid-1,4-lactone monohydrate | Enzyme inhibition studies | Used as a classical beta-glucuronidase inhibitor to validate the contribution of deconjugation to drug reactivation and intestinal toxicity | Suitable as a positive inhibitory control and mechanistic blocking tool | |
4-Nitrophenyl beta-D-glucuronide | Enzyme activity assay | Used as a chromogenic substrate to measure beta-glucuronidase activity | Suitable for initial screening in crude microbial enzyme preparations, fecal bacterial suspensions, and purified enzyme systems | |
4-Methylumbelliferyl-beta-D-glucuronide | Fluorometric enzyme activity assay | Used as a fluorescent substrate for highly sensitive detection of beta-glucuronidase activity | Suitable for microsamples and kinetic analysis | |
D-Glucuronic acid | Product/metabolite analysis | Used as a deconjugation product or control substrate for method development and metabolic pathway validation | Suitable for LC-MS/MS or enzymatic control systems | |
4-Nitrophenol | Chromogenic detection | Used as the readout product standard after hydrolysis of 4-nitrophenyl beta-D-glucuronide | Suitable for standard curves and enzyme activity quantification | |
4-Methylumbelliferone | Fluorescent detection | Used as the fluorescent product standard after hydrolysis of 4-methylumbelliferyl-beta-D-glucuronide | Suitable for fluorometric activity quantification | |
Acetaminophen | Typical glucuronidated drug model | Used to study the intestinal remetabolic potential of drugs with a high proportion of glucuronidation | Suitable for comparison with sulfation pathways | |
Diclofenac sodium | NSAID enterohepatic circulation studies | Used to analyze the relationship between glucuronide-related metabolite reflux and intestinal injury | Suitable for integrated pharmacokinetic-intestinal toxicity analysis | |
Indomethacin | NSAID-related control studies | Used for extended studies of acyl glucuronide-related intestinal injury and microbial involvement | More suitable for comparative studies among nonsteroidal anti-inflammatory drugs | |
Naproxen | NSAID model | Used to analyze glucuronidation and recirculation of aromatic acid drugs | Suitable for pharmacokinetic time-course and biliary excretion studies | |
Ibuprofen | NSAID model | Used to compare differences in conjugation and intestinal re-exposure among different arylpropionic acid drugs | Suitable for comparison with diclofenac and naproxen | |
Irinotecan hydrochloride trihydrate | Representative drug model | Used to study the classic mechanism of “host glucuronidation-intestinal deconjugation-local reactivation” | Suitable for establishing irinotecan-related intestinal toxicity models | |
SN-38 | Toxicity reactivation studies | Used as the active irinotecan metabolite to construct models of local toxicity and re-exposure after deconjugation | Suitable for studies of intestinal toxicity and reactivation mechanisms | |
Mycophenolic acid | Microbiota-dependent exposure studies | Used to study deconjugation of glucuronide metabolites of mycophenolic acid and their intestinal toxic consequences | Suitable for studies of gastrointestinal adverse reactions related to immunosuppressants | |
Ezetimibe | Enterohepatic circulation studies | Used to analyze re-exposure and maintenance of absorption after extensive glucuronidation | Suitable for studies of intestinal transport and sustained exposure | |
Raloxifene hydrochloride | Conjugation-deconjugation cycling studies | Used to study microbial reactivation phenomena of highly conjugated compounds with prominent enterohepatic circulation | Suitable as a supplementary model for highly conjugated drugs | |
Estradiol | Endogenous substrate model | Used to study microbial re-editing of glucuronide conjugates of hormone-like compounds | Suitable for host-microbiota co-metabolism research | |
Estrone | Endogenous substrate model | Used to compare deconjugation differences among different estrogen substrates | Suitable for studies of hormonal homeostasis and microbiota relationships | |
Ethinyl estradiol | Pharmaceutical hormone model | Used to study the problem of intestinal re-exposure of exogenous hormone drugs | Suitable for studies of oral hormonal formulations | |
Bilirubin | Endogenous glucuronidation-related model | Used to analyze bilirubin-related conjugation metabolism and the deconjugation process | More suitable for bile metabolism and microbiota interaction studies | |
Baicalin | Natural product glucuronide conjugate model | Used to study deconjugation and reabsorption of conjugates derived from natural medicines | Suitable for in vivo transformation studies of traditional Chinese medicine | |
Baicalein | Deconjugated product model | Used as the aglycone after deconjugation of baicalin to study reabsorption and restoration of activity | Suitable for paired aglycone-conjugate studies | |
Glycyrrhizic acid | Natural product model containing glucuronic acid structures | Used to study hydrolysis of glucuronic acid-related structures in natural ingredients by gut microbiota | Suitable for intestinal transformation studies of natural medicines | |
Glycyrrhetinic acid | Post-deglycosylation active product model | Used as the transformed product related to glycyrrhizic acid to analyze functional changes after deconjugation | Suitable for natural product reactivation studies | |
Scutellarin | Natural flavonoid glycoside model | Used to study deglycosylation, reabsorption, and retransformation of flavonoid glycosides in the intestine | Suitable for studies of plant-derived metabolism | |
Scutellarein | Aglycone model | Used as the product after deconjugation of flavonoids to study exposure differences after structural remodeling | Suitable for paired comparison with flavonoid glycosides | |
Puerarin | Extended model for natural product glycosides and gut microbial transformation | Used to study the transformation pathways of plant-derived glycosylated compounds by the gut microbiota | Suitable for microbiota-natural product interaction studies | |
Genistein | Flavonoid aglycone model | Used to analyze absorption and restoration of function after deconjugation of flavonoid structures | Suitable for studies of estrogen-like natural products | |
Daidzein | Microbial retransformation studies | Used to study further reduction and structural remodeling of flavonoid compounds by the microbiota | Suitable for analysis of downstream microbial transformation of aglycones |
6. Common Misconceptions in Research on Gut Microbial Enzyme-Mediated Transformation of Glucuronide Conjugates
6.1 Common misconceptions
(1) Treating glucuronidation simply as terminal inactivation
This understanding overlooks the reactivation process during the intestinal phase and also underestimates the importance of enterohepatic circulation, local toxicity, and interindividual variability.
(2) Reducing microbial effects to simply “whether beta-glucuronidase is present”
The true outcome of drug biotransformation depends not only on whether the enzyme is present, but also on its activity level, substrate compatibility, microbial network structure, local transport, and reabsorption capacity. Therefore, the mere presence or absence of a single enzyme is not sufficient to replace a complete mechanistic analysis.
In essence, gut microbial enzyme-mediated metabolism of glucuronide conjugates is a re-editing process that occurs after host clearance metabolism. It may prolong effective drug exposure, cause local toxicity reactivation, and further reshape the terminal metabolic profile through additional microbial biotransformation. Research on this process should not remain at the level of the general statement that “the microbiota affects drug metabolism,” but should instead be further grounded in the continuous mechanistic chain composed of specific conjugates, specific deconjugating enzymes, specific reabsorption processes, and specific pharmacodynamic and toxicological consequences. Only by establishing a closed-loop explanatory framework linking host metabolism, microbial enzymology, and pharmacokinetics can the rules governing gut microbiota-mediated drug biotransformation be understood more accurately.
