Beyond “you are what you eat”: Unlocking gut microbiota‐mediated biotransformation of dietary phytochemicals

The “efficacy paradox” of phytochemicals, low bioavailability yet significant health benefits, is associated with gut microbiota, which biotransforms dietary precursors into bioactive metabolites, enabling systemic effects. Thus, health outcomes of diet depend not just on intake “the rainbow”, but on gut microbial metabolism, redefining “you are what you eat” to “you are what your microbes make of what you eat”. The health-promoting properties of dietary phytochemicals have been extensively documented in preclinical data from in vitro and animal studies, where they exhibit potent bioactivities 1. However, when translated into human interventions, the benefits of these compounds are often inconsistent, highly variable across individuals, and sometimes disappointingly ineffective 2-4. This disconnect is often termed the “efficacy paradox”, representing a significant bottleneck in the field of nutrition, since it challenges the conventional dietary recommendations and highlights our incomplete understanding of how phytochemicals are metabolized within the human body (Figure 1). Multiple factors contribute to this paradox, including the food matrix, processing methods, dosage, host genetics, hepatic metabolism, and lifestyle. However, a rapidly growing number of evidence indicates that the gut microbiota is the most influential and personalized determinant of phytochemical's efficacy 5. In fact, the vast majority of dietary phytochemicals (up to 90%–95%) cannot be absorbed in the upper gastrointestinal tract and enter the colon, where the microbial “black box”—trillions of anaerobic microbes, act as an essential, highly personalized, and biological processing unit for phytochemical biotransformation (Figure 2A). These microbes possess a vast and diverse arsenal of metabolic enzymes (e.g., β-glycosidase, carbohydrate-active enzymes (CAZymes), esterase, reductase, decarboxylase, dehydroxylase, demethylases, and dehydrogenases) that are most absent in the human host, enabling them to deconstruct the complex dietary precursors into smaller, more lipophilic, and often more bioactive metabolites that can be readily absorbed through the colonic epithelium into circulation and exert systemic health effect 6. Consequently, the composition of individual's gut microbiota determines whether a specific phytochemical is activated into its potent form, giving rise to the concept of “metabotypes” (metabolic phenotypes), the distinct population subgroups defined by their ability to produce certain key metabolites 7. Although previous studies have comprehensively identified the biotransformation pathways of specific phytochemicals (e.g., ellagitannins to urolithins, daidzein to S-equol, and flavan-3-ols to phenyl-γ-valerolactones), the field now faces a more profound challenge—how can we translate preclinical mechanisms into personalized nutritional interventions? Despite decades of research, several critical questions remain unanswered, like (1) which steps within these pathways are supported by the microbe–enzyme–gene evidence in the human body, rather than inferences from preclinical studies; (2) what limitations exist in the current human research; (3) what is the optimal way to combine multi-omics and traditional biochemical methods to understand how correlation and causation are connected; (4) and most importantly, how can this mechanistic understanding be translated into personalized nutrition practice? This work, therefore, aims to discuss the aforementioned questions through a comprehensive framework that closely links mechanistic discoveries with practical applications. Specifically, we rigorously evaluate evidence regarding the biotransformation pathways of key phytochemicals, clearly distinguishing among definitive validation, in vitro inferences, and human trial evidence, while highlighting their respective limitations. Furthermore, we integrate current methodologies into a systematic discovery-to-validation strategy encompassing multi-omics, bioinformatics, and classical biochemistry. Finally, a concrete roadmap for developing next-generation probiotics (NGPs), precision synbiotics, and postbiotic nutraceuticals is proposed. By doing so, we can unlock the true potential of dietary phytochemicals and pioneer a new generation of truly effective functional ingredients from their gut metabolites. The journey to uncover these microbial secrets has yielded fascinating insights, transforming our understanding of how diet influences nutrition and health. In recent years, increasing work has been carried out to answer two fundamental questions involved in gut microbiota-mediated metabolism of phytochemicals. First, what are the key gut bioactive metabolites of phytochemicals, and how do the key metabolites contribute to the health benefits of phytochemical precursors? Second, how is gut microbiota-mediated metabolism and biotransformation process implemented, especially specific gut bacteria species/strains, their metabolic enzymes and encoding genes? Several well-characterized examples are elaborated and discussed below. Ellagitannins, abundant in many plant-based foods like pomegranates, berries, and walnuts, are large polyphenols with poor bioavailability. Upon reaching the colon, they are hydrolyzed to ellagic acid (EA) by gastric acid, which is then sequentially converted by gut bacteria into a series of smaller, more absorbable compounds dibenzopyran-6-one derivatives known as urolithins (Figure 2B) 8. The biological significance of this transformation is well-established. Urolithin A and Urolithin B are the major end-products of EA, and Urolithin A in particular exhibits significant health functions including antioxidant, anti-inflammatory, anti-cancer, anti-aging, cardioprotective properties, and muscle function-enhancing effects that exceed those of EA itself 8, 9. However, this microbial biotransformation is not universal. Based on the gut microbial capacity, individuals can be classified into distinct “urolithin metabotypes”, including metabotype A (produces only Urolithin A), metabotype B (produces Urolithin A, Isourolithin A, and/or Urolithin B), and metabotype 0 (produces no above urolithins at all) 10. These urolithin metabotypes are directly linked to the presence of a functional microbial “assembly line” with key dehydroxylation capabilities. Foundational work identified Gordonibacter urolithinfaciens DSM 27213T, and G. pamelaeae DSM 19378T capable of converting EA into intermediate urolithins such as Urolithin C 11. Subsequently, Ellagibacter isourolithinifaciens DSM 104140T was isolated and shown to produce isourolithin A from EA 12. However, these species alone cannot complete the pathway to Urolithin A/B, as they lack the capacity for the final dehydroxylation steps. A subsequent study revealed that certain Enterocloster species (e.g., E. asparagiformis, E. bolteae, and E. citroniae) are responsible for this final dehydroxylation step that produce the end-stage Urolithins A/B, defining each metabotype 13. The dehydroxylation mechanism, especially the challenging sequential dihydroxylation of urolithins, has been clarified recently at the enzymatic and genetic levels. Pidgeon et al. uncovered an inducible Urolithin C dehydroxylase (ucd) operon in Enterocloster species, which includes ucdC (FAD-binding subunit), ucdF (2Fe2S-binding subunit), and ucdO (molybdopterin cytosine dinucleotide (MCD)-binding subunit), and this operon encodes a novel molybdopterin-dependent enzyme complex that specifically dehydroxylates urolithins at its 9-hydroxy position 14. To move forward, Bae et al. systematically identified four urolithin dehydroxylases from Gordonibacter strains and E. isourolithinifaciens, including three catechol dehydroxylases (Eadh1, Eadh2, and Eadh3) belonging to the dimethyl sulfoxide reductase family, and a xanthine oxidase family enzyme (Ucdh) from E. bolteae 15. These enzymes target individual hydroxyl groups on the urolithins and exhibit substrate specificity. 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