Abstract
Ferroptosis is a novel form of lipid peroxidation-driven, iron-dependent programmed cell death. Various metabolic pathways, including those involved in lipid and iron metabolism, contribute to ferroptosis regulation. The gut microbiota not only supplies nutrients and energy to the host, but also plays a crucial role in immune modulation and metabolic balance. In this review, we explore the metabolic pathways associated with ferroptosis and the impact of the gut microbiota on host metabolism. We subsequently summarize recent studies on the influence and regulation of ferroptosis by the gut microbiota and discuss potential mechanisms through which the gut microbiota affects ferroptosis. Additionally, we conduct a bibliometric analysis of the relationship between the gut microbiota and ferroptosis in the context of chronic kidney disease. This analysis can provide new insights into the current research status and future of ferroptosis and the gut microbiota.
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Facts
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Ferroptosis is a novel form of iron-dependent, lipid peroxidation-driven programmed cell death.
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Ferroptosis is regulated by various metabolic pathways, particularly those involved in iron and lipid metabolism.
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The gut microbiota plays a crucial role in maintaining the metabolic balance of the host.
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The gut microbiota is associated with ferroptosis in various organs, tissues, and diseases.
Open Questions
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What potential connections exist between ferroptosis and the gut microbiota?
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How does the gut microbiota regulate ferroptosis?
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Can targeting the gut microbiota become a therapeutic strategy to alleviate ferroptosis-related diseases?
Introduction
Ferroptosis is a distinct form of cell death characterized by iron-dependent, lipid peroxidation-driven, and accumulation of reactive oxygen species (ROS) [1]. This concept was initially proposed by Dr. Brent R Stockwell in 2012. Ferroptosis is directly influenced by the transport of cystine, the activity of glutathione peroxidase 4 (GPX4), the reduction of Fe, and the Fenton reaction. Cystine is transported across the membrane via system Xc-, where it is converted to cysteine and forms reduced glutathione (GSH) in conjunction with glutamic acid and glycine. The conversion of GSH to oxidized glutathione catalyzed by GPX4 coincides with a decrease in polyunsaturated fatty acid (PUFA)-O-OH. PUFA-O-OH then reacts with Fe2+ to generate ROS. GSH depletion, reduced GPX4 activity, and decreased cellular antioxidant capacity collectively lead to lipid peroxidation and ROS accumulation, ultimately resulting in ferroptosis. Therefore, ferroptosis is closely associated with the metabolism of lipids, iron, and mercaptans, and is triggered in cells with dysregulated redox metabolism [2].
The gut microbiota is a significant “organ” of the human body and plays a crucial role in human health. The microbiota that colonizes the mammalian gut gradually establishes a balanced symbiotic relationship during host development, resulting in a mutually beneficial correlation [3]. Disruption of the intestinal mucosal barrier, alterations in the microbiota, and microbial translocation lead to systemic inflammation, further impacting the host’s immune and metabolic homeostasis [4]. The gut microbiota influences the host’s inflammatory state and immune system, which in turn affects the prognosis of disease. Moreover, the intestinal microbiota contributes to the progression of host diseases through its metabolites, including short chain fatty acids (SCFAs), bile acids, tryptophan, branched-chain amino acids, and uremic toxins [5]. With the development of research, attention has gradually been given to whether the gut microbiota has the ability to regulate ferroptosis. The gut microbiota plays a regulatory role in ferroptosis through its microbial composition and metabolites, with different microbiota having varying effects on ferroptosis [6]. Pathogenic bacteria tend to promote ferroptosis and aggravate disease progression, while probiotics can prevent ferroptosis and alleviate disease progression [7]. However, it is important to note that the promotion or inhibition of ferroptosis may have different implications for tumor diseases and their progression. Hence, further exploration of the impact of the gut microbiota on ferroptosis will help us gain a deeper understanding of the mechanisms underlying disease occurrence and progression, as well as strategies to delay ferroptosis.
Chronic kidney disease (CKD) is a prevalent chronic progressive disease characterized by abnormal kidney structure and dysfunction resulting from various underlying conditions. The global prevalence of CKD is growing rapidly, leading to an increased risk of cardiovascular events, renal failure, and mortality [8]. As an organ responsible for metabolite excretion and reabsorption, the kidney is highly susceptible to disruptions in the redox balance. When intracellular iron accumulation and the redox system become imbalanced, excessive production of lipid peroxides will occur, ultimately inducing ferroptosis. Additionally, CKD is associated with lipid metabolism disorders and lipid accumulation. The buildup of lipids can activate the innate immune system, promote inflammatory fibrosis, trigger mitochondrial and kidney cell damage, and drive the progression of CKD [9]. Furthermore, the gut microbiota and its metabolites present intriguing therapeutic targets for delaying CKD progression and reducing uremic toxicity [10]. Evidently, the gut microbiota affects ferroptosis by regulating iron metabolism and related metabolites, and ferroptosis plays a crucial role in the progression of CKD. The progression of CKD leads to more severe dysbiosis, resulting in higher levels of ferroptosis, thus forming a vicious cycle and posing serious health risks. By comprehensively studying the relationship among ferroptosis, the gut microbiota, and CKD, new insights may be gained for effective personalized intervention strategies such as tailored diets and microbial interventions. This review explores the impact of the gut microbiota on ferroptosis and its underlying mechanisms from a metabolic perspective. In addition, we conduct a bibliometric analysis of studies investigating the relationship among ferroptosis, the gut microbiota, and CKD, aiming to provide a more comprehensive and in-depth understanding of the mechanisms of CKD progression and potential therapeutic approaches for associated complications.
Key ferroptosis-related metabolic pathways
In reviewing the significant advancements in ferroptosis over the past decade, Stockwell comprehensively summarized the mechanisms and biological importance of ferroptosis in the domains of cell metabolism, ROS, and iron regulation [11]. Ferroptosis sensitivity is closely linked to various biological processes, including amino acid metabolism, iron metabolism, PUFA metabolism, GSH synthesis, and phospholipid (PL) synthesis. The key points of ferroptosis regulation are cystine transport, fatty acid synthesis, and iron transport. Moreover, several metabolic pathways are involved in the regulation of ferroptosis. Therefore, it is necessary to elucidate the principal metabolic pathways associated with ferroptosis, such as lipid metabolism, iron metabolism, and amino acid metabolism pathways (Fig. 1).
Lipid metabolism
Lipid metabolism plays a pivotal role in modulating ferroptosis by regulating PL peroxidation. While lipid peroxide substrates and oxidants that drive ferroptosis are generated during normal cell metabolism, only specific lipids that are activated and incorporated into membrane lipids ultimately induce ferroptosis [11]. Lipid peroxidation at the membrane can disrupt the ion balance and increase membrane permeabilization [12]. The composition of PLs is controlled by lipid metabolism through the regulation of fatty acid supply(especially PUFAs) and remodeling of PLs synthesis, which in turn affects cell susceptibility to ferroptosis [13]. Acyl-coenzyme A synthetase long-chain family (ACSL) 4 and lysophosphatidylcholine acyltransferase 3 are critical for ferroptosis because they promote the activation and incorporation of PUFAs into membrane lipids. The conversion of fatty acids to acyl-coenzyme A (CoA) esters is a crucial regulatory step in ferroptosis [14,15,16]. Remodeling lipid metabolism, particularly the redistribution of oxidizable PUFAs, leads to increased lipid peroxidation and induces ferroptosis in tumors [17]. Similarly, removal of the oxidized-PUFA tails on PLs can suppress ferroptosis [18]. In contrast to PUFAs, exogenous monounsaturated fatty acids effectively limit lipid peroxidation and block ferroptosis under ACSL3-dependent conditions [19].
In addition to oxidants that induce lipid peroxidation, inhibitors that prevent lipid peroxidation are also produced during normal metabolism. Among these inhibitors, GPX4 plays a central role in ferroptosis regulation, and GSH, which prevents oxidative stress caused by oxidants such as hydrogen peroxide, can restrain the accumulation of lipid ROS. The depletion of GSH increases the susceptibility of cells to ferroptosis, while GSH synthesis confers resistance to ferroptosis [20, 21]. Mechanisms that modulate the degradation of GPX4 also participate in regulating ferroptosis sensitivity. Both ferroptosis-inducer-56 and chaperone-mediated autophagy facilitate ferroptosis by inducing the degradation of GPX4 [22]. Additionally, there are other systems independent of GPX4 that regulate ferroptosis, such as ferroptosis suppressor protein 1 (FSP1)/ubiquinone (CoQ10) [23], dihydroorotate dehydrogenase (DHODH) [24], GTP cyclohydrolase-1 (GCH1)/tetrahydrobiopterin (BH4) [25], and amino acid oxidase interleukin-4-induced-1/indole-3-pyruvate [26]. Cholesterol, as a major component of the cell membrane, is involved in the synthesis of CoQ10 through an intermediate (isopentenyl pyrophosphate) in its synthesis pathway, thereby influencing ferroptosis. Furthermore, isopentenyl pyrophosphate can be utilized by a selenium protein to regulate GPX4 synthesis and increase ferroptosis sensitivity [27]. In summary, lipid peroxidation and disrupted lipid metabolism exacerbate ferroptosis, affecting disease progression and prognosis. A deeper understanding the mechanism of lipid metabolism in ferroptosis is of great significance for the development of new treatment strategies and preventive measures.
Iron metabolism
Membrane lipid peroxidation with PUFA tails requires the involvement of the labile iron pool, which accelerates the Fenton reaction (Fe2+ + HOOH→Fe3+ + OH− + OH˙), as well as iron-dependent enzymes such as lipoxygenase and cytochrome P450 oxidoreductase [28]. Therefore, iron metabolism is significantly important for the regulation of ferroptosis. Ferritin, an essential iron-storage protein, chelates free iron into Fe3+ to prevent the Fenton reaction. Transferrin and ferroportin (FPN) are responsible for iron transport. The cellular abundance of iron, and hence the sensitivity to ferroptosis, is determined by the availability of ferritin, the level of transferrin, and the function of FPN [29, 30]. Fe3+ is taken up into cells in the form of ferritin through transferrin and transferrin receptor 1 and is then reduced to bivalent ferritin by the six-transmembrane epithelial antigen of prostate 3. Subsequently, bivalent ferritin is deproteinized via divalent metal-ion transporter-1 or metal transporter ZIP14 (Slc39a14) to form Fe2+ and enters the labile iron pool. Excess Fe2+ is transported out of cells through FPN. The accumulation of Fe2+ leads to the Fenton reaction between Fe2+ and PUFAs-O-OH, which generates ROS, accelerates lipid peroxidation, and induces ferroptosis. Thus, the critical aspect of iron metabolism regulation in ferroptosis lies in controlling the capacity of the labile iron pool.
A recent study suggested that O-GlcNAcylation modulates ferroptosis by regulating the content of labile iron [31]. The transcription factor NUPR1 prevents ferroptosis by reducing the accumulation of labile iron and oxidative damage [32]. Mice fed a high-iron diet and mice with mutations associated with hereditary hemochromatosis (an iron overload disease caused by inherited mutations in genes that regulate iron metabolism) both developed ferroptosis-related liver damage [33]. Conversely, the ubiquitin ligase E3 HUWE1/MULE, which acts as a negative regulator of ferroptosis, regulates iron metabolism by targeting transferrin receptor 1 and counteracts abnormal iron accumulation, thereby alleviating acute liver injury caused by hepatic ischemia-reperfusion (I/R) [34]. Under hypoxic conditions, human macrophages inhibit ferritin autophagy by reducing the expression of nuclear receptor coactivator 4 (NCOA4), resulting in increased mitochondrial ferritin expression and decreased intracellular free iron, thus regulating ferroptosis [35]. Similarly, tripartite motif-containing protein 7 mediates ferritin autophagy and ferroptosis in human glioblastoma cells by binding to NCOA4 [36]. Additionally, NCOA4-ferritin heavy polypeptide 1-mediated iron metabolism disorder is related to retinal ganglion cell ferroptosis following pathologically high intraocular pressure injury [37]. A study indicated that histone deacetylase inhibitors, which are used clinically to treat certain cancers, can increase ferroptosis-induced cell death, possibly due to increased iron accumulation and decreased FPN expression after epithelial-to-mesenchymal transition mediated by histone deacetylase inhibitors [38]. These findings highlight a significant link between iron metabolism and susceptibility to ferroptosis.
Amino acid metabolism
Ferroptosis is dependent on cystine transport and the synthesis of GSH. GSH, a significant antioxidant and enzyme cofactor in cells, consists of glutamic acid, cysteine, and glycine. In particular, cysteine is the rate-limiting substrate for GSH synthesis. Cysteine can be derived from cystine transported by System Xc- or produced through endogenous transsulfuration [39]. Dixon et al. demonstrated that erastin depletes cysteine and GSH by blocking cystine uptake via System Xc-, leading to ferroptosis [40]. In the absence of cystine, certain tumor cells can convert methionine to cysteine, enabling them to escape ferroptosis [41]. In contrast, when other amino acids are deficient (at levels still sufficient to stimulate cell proliferation), cystine deprivation can effectively induce ferroptosis for anticancer therapy [42]. Cysteine can be catabolized into acetyl-CoA and taurine through two main pathways. Interestingly, acetyl-CoA can synergize with GSH to exert an anti-ferroptosis effect [43], while the production of taurine reduces intracellular GSH levels and increases ROS production [44]. This may be related to the fact that CoQ10, a CoA derivative, is reduced to panthenol by the oxidoreductase FSP1, thus preventing lipid peroxidation, while taurine production competes with cysteine for GSH synthesis. Additionally, cystine/cysteine can regulate GPX4 protein synthesis by activating the Rag-mTORC1-4EBPs signaling axis in a GSH-independent manner, thereby preventing ferroptosis [45].
As the most abundant amino acid in the human body and an important fuel, glutamine metabolism is also closely linked to ferroptosis. Glutamine can be converted to glutamate by glutaminase, and glutamate can combine with cysteine and glycine to synthesize GSH [46]. Glutamine can act as an inducer of ferroptosis, promoting ferroptosis through its own hydrolysis, but this process requires cystine starvation [47]. As essential amino acids, elevated serum levels of branched-chain amino acids, including leucine, valine, and isoleucine, increase ROS production by activating the Akt-mTOR signaling pathway, thereby affecting ferroptosis [48]. Tryptophan metabolites, such as 5-hydroxytryptamine and 3- hydroxyanthranilic acid, act as potential radical-trapping antioxidants and can protect cells from ferroptosis by eliminating lipid peroxidation [49]. Moreover, interleukin-4-induced-1, an amino acid oxidase secreted by immune cells, can inhibit ferroptosis through indole-3-pyruvate produced from tryptophan metabolism [26]. L-arginine can alleviate the oxidative stress induced by lipopolysaccharide (LPS). L-arginine increases the cellular GPX4 content and decreases ROS production through the arginase-1 signaling pathway, suggesting its involvement in the regulation of ferroptosis [50]. Furthermore, a study has demonstrated that lysine oxidase can activate ferroptosis signals through the oxidative deamination of lysine and the rapid generation of ROS [51].
Gut microbiota and host metabolic homeostasis
Host lipid metabolism
The gut microbiota plays an important role in host lipid metabolism process. Their crosstalk is essential for the development of various diseases, including obesity, alcoholic liver disease and other metabolic diseases [52, 53]. The gut microbiota can influence the composition of lipids in the host’s serum, adipose tissue, and liver, particularly triglycerides and phosphatidylcholine, thereby impacting the host’s energy and lipid metabolism [54]. For instance, Lactobacillus rhamnosus can regulate the abundance of beneficial bacteria in the gut microbiota of zebrafish larvae, thereby affecting the transcription of genes related to cholesterol-triglyceride metabolism and modulating host lipid processing and metabolism [55].
Researchers have focused on elucidating the specific mechanisms by which the gut microbiota affects host lipid metabolism. A previous study demonstrated that the circadian transcription factor NFIL3, which controls the expression of circadian-clock genes, may be a crucial molecule in the influence of the gut microbiota on host lipid metabolism and body composition [56]. The addition of exogenous melatonin improves the intestinal microbial composition and circadian rhythm in high-fat diet-fed mice, thereby regulating the host’s metabolic circadian clock and lipid metabolism [57]. Moreover, metabolites derived from the gut microbiota, such as SCFAs, secondary bile acids, triethylamine, and LPS, may mediate the regulation of host lipid metabolism and possess anti-obesity potential [58, 59]. In particular, free fatty acids and SCFAs play significant roles in the microbiota-host lipid metabolism axis, which has important implications for human health [60, 61]. In addition, specific strains of the gut microbiota can impact host lipid metabolism differently and have individual effects on disease progression [62]. For instance, Lactobacillus paracasei promotes lipid storage in intestinal cells, while Escherichia coli enhances lipid catabolism and ultimately inhibits lipid secretion [63]. Escherichia fergusonii interferes with host lipid metabolism by secreting microRNA-sized small RNAs that inhibit hepatic lipid β-oxidation and promote liver fat accumulation [64]. Further research in this field may provide valuable insights into potential therapeutic interventions for lipid-related diseases.
Host iron homeostasis
The gut microbiota is involved in the absorption of iron in the host intestine, and microbial metabolites are associated with the regulation of iron homeostasis. Specifically, the function of the gut microbiota impacts host iron absorption, while iron homeostasis in the host also influences the diversity, classification, function, and dominant bacterial community of the microbiota [65]. A study in diabetic mice showed that iron metabolism is closely related to the abundance of Lactobacillus in the gut microbiota [66]. A comparative study of germ-free and microbially colonized mice indicated that the gut microbiota can induce specific iron-related protein signaling pathways and alter the perception of iron by intestinal epithelial cells [67]. Commensal bacteria secrete the siderophore enterobactin, which binds to the α subunit of ATP synthase, facilitating host mitochondria iron uptake [68]. This potential host mechanism of beneficial enterobactin utilization contributes to the maintenance of iron homeostasis in the host. Interestingly, gut microbiota-derived metabolites can reduce iron absorption in the host intestine by suppressing intestinal hypoxia-inducible factor-2α activity and decreasing ferritin expression [69]. Moreover, in a whole-body iron overload mouse model, hypoxia-inducible factor-2α inhibitory microbial metabolites efficiently prevented tissue iron accumulation.
Iron depletion in the gut lumen can alter the function of intestinal epithelial cells and the composition of the intestinal microbiota [70], while different iron supplements also lead to differences in the regulation of the gut microbiota [71]. Compared with those in iron-sufficient rats, cecal butyrate and propionate levels are significantly lower in iron-deficient rats, and the abundance of dominant species is noticeably altered [72]. Furthermore, iron sulfate supplementation had a stronger effect on the gut microbiota than electrolytic iron, indicating that ferrous iron was more readily utilized by the microbiota. Interestingly, under iron-rich conditions and in the absence of host influences, iron has adverse effects, including a decrease in beneficial microorganisms and an increase in bacterial metabolite levels, which in turn impairs the barrier function of intestinal epithelial cells [73]. Different doses and regimens of iron supplements have been suggested to have opposite effects. For example, ferrous bisglycinate is beneficial in sodium sulfate-induced colitis, whereas ferric ethylenediaminetetraacetic acid is highly detrimental [74]. Additionally, oral supplementation with ferrous sulfate can enhance the beneficial effects of probiotics on colitis. In general, understanding the intricate interactions between the gut microbiota and host iron metabolism can provide valuable insights into interventions for iron-related disorders and the maintenance of intestinal health.
Host amino acid metabolism
The gut microbiota performs several functions in the host’s life, including the conversion of nutrients that the host cannot digest into usable compounds. It can provide the host with essential amino acids necessary for tissue structure synthesis and may also play a significant role in amino acid metabolism in protein-deficient animals [75]. The alteration of amino acid metabolism in the host brain was presented based on the differentiated amino acid concentrations of plasma and brain between conventionally raised mice and germ-free mice, which attributed to the participation of gut microbiota [76]. Moreover, studies based on gene expression data and tissue-specific genome-scale metabolic models have demonstrated that the gut microbiota can influence host amino acid metabolism and contribute to changes in glutathione metabolism [77]. Similarly, experiments with different concentrations of antibiotics for bumblebees have shown that the gut microbiota may regulate host growth through essential amino acids and BCAAs [78]. For instance, supplementation with BCAAs can alleviate gut microbial dysbiosis, improving amino acid metabolism and host growth performance [79]. The impact of the gut microbiota on host amino acid metabolism can further influence disease progression and therapeutic response [80]. Understanding the complicated relationship between the gut microbiota and amino acid metabolism is critical for elucidating disease progression and optimizing therapeutic interventions.
Advanced studies on the correlation between the gut microbiota and ferroptosis
In recent years, there has been a growing focus on the role of the gut microbiota in the occurrence of ferroptosis, with the aim of elucidating the potential relationship between the microbiota and ferroptosis (Fig. 2). For instance, a recent study revealed that microbial metabolic disorders leading to Th17/Treg imbalance can trigger hepatocyte ferroptosis, potentially explaining the involvement of Porphyromonas gingivalis in the progression of non-alcoholic fatty liver disease [81]. Obeticholic acid, a clinical drug for non-alcoholic fatty liver disease treatment, can induce liver lipid peroxidation by affecting the gut microbiota, which subsequently mediates hepatocyte ferroptosis and compromises its antioxidative and antifibrotic effects [82]. In the presence of environmental toxins, gut microbiota-derived metabolites (such as glycochenodeoxycholate) can induce ferroptosis, lipid metabolic disorders, and inflammation by activating the TFR and ACSL4 [83]. Exogenous toxins also increase the synthesis of LPS, intensifying hepatocyte ferroptosis and resulting in hepatic lipid metabolic disorders. However, melatonin can decrease microbiota-derived LPS and hepatocyte ferroptosis by modulating the gut microbiota [84]. The total flavonoids of Rhizoma Drynaria can prevent oxidative stress and hepatic lipid deposition, reverse hepatic ferroptosis by improving the host intestinal microenvironment, and play a protective role in aflatoxin B1-induced liver damage [85]. Daidzein, released by gut microbial β-galactosidases, can suppress hepatocyte ferroptosis by reducing farnesyl diphosphate synthase expression [86]. Urolithin C can alleviate the adverse effects of a choline-deficient amino acid-defined high-fat diet by regulating the AMPK-ferroptosis axis, which involves the gut-liver axis. Furthermore, the application of urolithin C can ameliorate intestinal mucosal barrier and gut microbiota dysbiosis [87]. These studies highlight therapeutic interventions targeting the gut microbiota, which are expected to alleviate hepatic lipid metabolism disorders and ferroptosis-associated liver damage.
Ferroptosis and the gut microbiota are closely related in the context of gastrointestinal disease. A previous study indicated that capsiate enhances GPX4 expression and suppresses ferroptosis through the activation of transient receptor potential cation channel subfamily V member 1, along with the attenuation of intestinal I/R injury [88]. Ferroptosis caused by microbiota dysbiosis can be inhibited by early-life gut microbiota-derived ether lipids (plasmalogens), which also influence susceptibility to colitis [89]. The effect of maternal embryonic leucine zipper kinase pharmacological inhibitors, which suppress ferroptosis in intestinal tissue and alleviate intestinal inflammation in mice with colitis, is closely related to the regulation of the gut microbiota [90]. The therapeutic effect of protocatechuic acid on ulcerative colitis is accomplished by regulating the gut microbiota and suppressing ferroptosis [91]. In addition to inhibiting ferroptosis, the iron chelator deferasirox also improves gut microbiota dysbiosis and enhances the production of SCFAs during dextran sulfate sodium salt-induced ulcerative colitis [92]. Similarly, ferrostatin-1 can restore gut microbiota homeostasis and alleviate ionizing radiation-induced intestinal injury by inhibiting ferroptosis and the p53-mediated apoptosis signaling pathway [93]. A recent study illustrated that trans-3-indoleacrylic acid, a tryptophan metabolite derived from the intestinal microbe P. anaerobius, accelerates colorectal carcinogenesis by inhibiting ferroptosis [94]. These findings highlight the complex role of understanding the regulation of the gut microbiota in the development and treatment of gastrointestinal diseases related to ferroptosis, contributing to the elucidation of potential mechanisms underlying gastrointestinal diseases and the exploration of new therapeutic approaches.
The gut microbiota has a significant impact on ferroptosis and stability in other parts of the host, beyond just the liver and intestine. Gut microbiota dysbiosis and microbiota-derived metabolites interfere with the regulation of ferroptosis. For example, dysbiosis of the esophageal/intestinal microbiome and elevation of peripheral blood LPS can regulate ferroptosis in the esophageal epithelium by increasing ACSL4 expression, serum ferritin secretion, and iron accumulation [95]. Gut microbiota dysbiosis caused by perfluorooctanoic acid can lead to fetal growth retardation through ferroptosis and inflammation [96]. Obesity-related atrial fibrillation susceptibility is increased by gut microbiota dysbiosis, which activates the toll-like receptor 4/nuclear factor kappa-B/NOD-like receptor thermal protein domain associated protein 3 signaling pathway and induces ferroptosis [97]. Mercury exposure-induced brain injury in common carp is associated with neuronal ferroptosis via the augmentation of intestinal A.hydrophila [98]. Additionally, the gut microbiota-derived metabolite capsiate relieves ferroptosis-related osteoarthritis through the regulation of solute carrier family 2 member 1 and HIF-1α [99]. On the other hand, interventions targeting the gut microbiota, such as berberine supplementation can suppress neuronal ferroptosis by modulating the gut microbiota and mitigating cerebral I/R injury [100]. Similarly, the neuroprotective effect of sinomenine on cognitive dysfunction following type 2 diabetes mellitus is achieved through the inhibition of ferroptosis in hippocampal neurons via the classical ferroptosis signaling pathway (epidermal growth factor/nuclear factor erythroid derived 2-related factor 2 (Nrf2)/heme oxygenase 1) and the microbiota-gut-brain axis [101]. Furthermore, electroacupuncture inhibits ovarian oxidative stress and Fe2+ accumulation in premature ovarian failure mice by altering the gut microbiota [102]. Probiotic supplementation can reverse bacteroidaceae-induced intestinal ferroptosis, thereby relieving systemic inflammation and hematopoietic toxicity [7]. Moreover, the use of probiotics inhibits perfluorobutanesulfonate-mediated ferroptosis and improves metabolic disorders in the host [103]. The next-generation probiotic strain L. lactis MG1363-pMG36e-GLP-1 plays a neurotrophic role in Parkinson’s disease through the regulation of oxidative stress, prevention of ferroptosis, and correction of dysbiosis [104]. In conclusion, the complex relationship between the gut microbiota and ferroptosis emphasizes the importance of maintaining a healthy microbiota for host health. Further research in this field holds the potential to develop new therapeutic strategies for iron-related diseases.
Potential mechanisms of gut microbiota interaction with ferroptosis
System Xc-/GPX4 axis
System Xc-, also known as the cystine-glutamate reverse transporter, is primarily responsible for the intracellular and extracellular transport of amino acids [105]. Specifically, it transports intracellular glutamate out of the cell and takes up extracellular cystine, which is then reduced to cysteine. It consists of the transporter proteins solute carrier family 7 member 11 and solute carrier family 3 member 2. System Xc- plays a critical role in maintaining the body’s levels of GSH by participating in glutamate release, cystine uptake, and GSH synthesis. GSH is an important antioxidant in mammalian cells and is synthesized from glutamate, cysteine, and glycine [106]. GSH functions as a prosthetic group of glyceraldehyde phosphate dehydrogenase and as a coenzyme of glyoxalase and triose dehydrogenase. It is involved in the tricarboxylic acid cycle, glucose metabolism, and can activate various enzymes to promote glycometabolism, lipid metabolism, and protein metabolism. Additionally, the active sulfhydryl group carried by GSH can combine with free radicals in the body, eliminate oxidants, and participate in redox reactions. GPX4, a crucial oxidoreductase, is essential for removing lipid peroxidation products by using GSH as a reducing agent [107]. GPX4 converts GSH to oxidized glutathione, resulting in a decrease in the peroxidation of PUFAs. Undoubtedly, GPX4 is a key suppressor of ferroptosis. Inactivation of system Xc- or dysfunction in GSH synthesis leads to reduced GPX4 activity, impairing cellular antioxidant capacity and ultimately resulting in ferroptosis.
A study on the intestinal microbiome of young and old mice has revealed that the gut microbial-derived metabolite 3-hydroxyphenylacetic acid upregulates GPX4 expression, inhibits ferroptosis, and alleviates spermatogenic dysfunction in aging mice [108]. Another gut microbial-derived metabolite, capsiate, alleviates ferroptosis induced by intestinal I/R injury by promoting GPX4 expression through the activation of transient receptor potential cation channel subfamily V member 1 [88]. However, dysbiosis of the gut microbiota, leading to the colonization of harmful bacteria such as adherent-invasive E. coli, exacerbates lipid peroxidation and ferroptosis in intestinal epithelial cells by reducing GPX4 and ferritin heavy chain levels [109]. In a study on the alleviation of kidney injury using the traditional Chinese medicine Mori Fructus aqueous extracts, it was found that extracts altered the gut microbiota in experimental mice, accelerated the nuclear transport of Nrf2, and increased the expression of heme oxygenase 1 and GPX4. Nonetheless, there is a lack of direct evidence linking the increase in Nrf2 to alterations in the gut microbiota. Another recent study confirmed that gut microbiota-derived butyrate improves ferroptosis in mice with ulcerative colitis through the Nrf2/GPX4 signaling pathway and protects the integrity of the intestinal mucosal barrier [110]. Fecal microbiota transplantation experiments further verified that the regulation of the gut microbiota can upregulate the Nrf2/GPX4 pathway to attenuate ferroptosis in septic liver injury [111].
FSP1/CoQ10/NADPH system
FSP1, identified as another ferroptosis suppressor through genome-wide screening, primarily prevents lipid peroxidation and ferroptosis by reducing lipid free radicals in lipid droplets or plasma membranes [112]. The FSP1/CoQ10/NADPH system protects cells from ferroptosis in a manner independent of the GPX4 axis by inhibiting lipid peroxidation and ferroptosis through the NAD(P)H-dependent reduction of CoQ10 to ubiquinol (CoQH2) [23]. Recent research has demonstrated that trans-3-indoleacrylic acid, a tryptophan metabolite derived from the gut microbiota, suppresses ferroptosis and facilitates colorectal cancer progression [94]. Metabolite-dependent resistance to ferroptosis relies on the FSP1/CoQ10/NADPH system. Specifically, as an endogenous ligand of the aromatic hydrocarbon receptor, trans-3-indoleacrylic acid upregulates the expression of aldehyde dehydrogenase 1 family member A3, leading to increased production of NADH by utilizing retinol as a substrate. Furthermore, it promotes FSP1-mediated synthesis of reductive CoQ10 and inhibits ferroptosis in tumor cells. During disease progression, alterations in the gut microbiota are accompanied by functional changes in GSH metabolism and CoQ10 biosynthesis pathways [113]. Moreover, some quinones, particularly menaquinones, are essential growth factors for the gut microbiota and regulate microbiota homeostasis by improving the growth medium and promoting symbiotic bacterial growth [114]. CoQ10-rich pumpkin juice obtained through the fermentation of Rhodobacter sphaeroides not only exhibits antioxidant capacity, especially ferric ion reduction antioxidant capacity but also modulates the gut microbiota of mammals to protect the intestinal barrier [115]. These studies highlight the crucial role of CoQ10 in lipid peroxidation, ferroptosis, and microbiota growth.
GCH1/BH4/dihydrofolate reductase (DHFR) system
The GCH1/BH4/DHFR system is a novel mechanism for suppressing ferroptosis that operates independently of GPX4 [25]. BH4 promotes the synthesis of CoQ10 by converting phenylalanine to tyrosine, thereby serving as a free radical-trapping antioxidant [116]. Additionally, GCH1, a rate-limiting enzyme synthesized by BH4, has the potential to suppress ferroptosis [117]. The expression of GCH1 induces lipid remodeling in cells, inhibiting ferroptosis by selectively preventing the consumption of PLs with two PUFA tails [25]. DHFR, a component of the BH4 recycling process, can cooperate with GPX4 inhibitors to promote the occurrence of ferroptosis. A study suggested that in GCH1-deficient mice, BH4 could still accumulate with age, which was associated with the production of BH4 by specific gut microbiota, such as intestinal Actinobacteria [118]. BH4 derived from the microbiota also stimulates the gut microbiota to enhance the production of L-DOPA, thereby improving brain function and behavior [119, 120]. Therefore, interventions targeting the gut microbiota may increase the levels of BH4 in the body, which can be beneficial for human health, especially for patients with congenital biopterin deficiency. Furthermore, the diversity of gut microbiota taxa and the abundance of bacterial gene families are associated with the inhibitory effect of drugs on DHFR [121].
DHODH/CoQH2 system
DHODH is located on the inner mitochondrial membrane and its primary function is to catalyze the synthesis of pyrimidine nucleotides. During this process, DHODH oxidizes dihydroorotate to orotate, while CoQ10 receives electrons and is reduced to CoQH2 [24]. CoQH2 is a free radical-trapping antioxidant that prevents lipid peroxidation and inhibits ferroptosis. Similar to FSP1, DHODH is a CoQ10-reduced flavin protein that acts as a GPX4-independent defense system against ferroptosis in mitochondria. Moreover, GPX4 downregulation limits mitochondrial lipid peroxidation and ferroptosis [122]. The use of metformin in patients with gestational diabetes mellitus affects the composition and metabolic characteristics of the gut microbiota, particularly the metabolic pathways related to CoQH2 biosynthesis [123]. However, further studies are needed to establish a direct relationship between CoQH2 synthesis and the therapeutic effects of metformin. In a study on aging-related diseases, an increase in the abundance of gut microbiome genes involved in the CoQH2 synthesis pathway was observed with age [124]. Nevertheless, a more in-depth discussion of the underlying mechanisms is still lacking.
Using CKD as an example: bibliometric analysis of ferroptosis and the gut microbiota
We conducted a literature search on the Web of Science Core Collection (https://www.webofscience.com/wos/woscc/basic-search) from January 1, 2012 (the year when the concept of ferroptosis was introduced), to January 28, 2024. The search criteria were as follows: 1st: (TS = (ferroptosis)) AND TS = (chronic kidney disease); 2nd: (TS = (gut microbiota)) AND TS = (chronic kidney disease); 3rd: (TS = (ferroptosis)) AND TS = (gut microbiota). We selected articles of the “Article” and “Review Article” types and limited the search to articles published in English. This resulted in a total of 1113 articles on ferroptosis and the gut microbiota in the context of CKD. Subsequently, we utilized Microsoft Office Excel 2019, CiteSpace, VOSviewer, and the R package “bibliometrix” for analysis and visualization.
Figure 3a displays the increasing number of publications on ferroptosis and the gut microbiota in CKD over the past decade, with a particularly notable increase in the last 5 years. Numerous scholars have dedicated their efforts to this research area, and close collaboration among them is evident (Fig. 3b). Similarly, a positive and strong cooperative relationship exists between co-cited authors (Fig. 3c). The majority of these publications originate from Asia, North America, and Europe, including countries such as China, the United States, and Italy. Notably, there is substantial collaboration among different countries (Fig. 3d, e). Co-occurrence analysis of authors’ keywords indicates that metabolism, dysbiosis, inflammation, and uremic toxins are the primary research directions in the field of ferroptosis and gut microbiota in CKD (Fig. 4a). Keyword trend topic analysis demonstrates that ferroptosis and the gut microbiota have emerged as focal points in CKD research in recent years (Fig. 4b). Finally, the co-cited references network and references with citation bursts provide insight into the frequently cited literature in this field and the co-citation relationships among them (Fig. 4c, d). The majority of the top 15 cited references focus on the gut microbiota and CKD. This could be attributed to the emergence of the concept of ferroptosis only within the last decade, with ongoing research exploring its role in CKD each year. The top 15 references with strongest citation bursts show alterations in the gut microbiota in CKD patients and animal models [125, 126], characterized by a decrease in bacteria-producing SCFAs and an increase in bacteria-producing uremic toxins [127]. Dysbiosis of the gut microbiota disrupts the structure and function of the intestinal epithelial barrier [128], forming harmful metabolic profiles [129], which induce inflammation and immune dysfunction via the gut-kidney axis [130, 131], exacerbating renal injury [132]. CKD patients should consume more foods rich in dietary fiber [133, 134] and avoid high-choline foods such as L-carnitine [135] and phosphatidylcholine [136] because trimethylamine-N-oxide, generated from choline metabolism by the gut microbiota, contributes to the progression of CKD and the risk of death [137]. In conclusion, targeting the gut microbiota is a novel therapeutic direction to improve CKD outcomes, and interventions such as probiotics to modulate the gut microbiota may provide new insights into individualized CKD treatment.
Summary and perspective
Ferroptosis is a regulated, iron-dependent, lipid peroxidation-driven cell death process that has gained increasing attention in recent years. Alterations in the gut microbiota can impact host metabolic homeostasis and the antioxidant system, suggesting that the gut microbiota and its metabolites may regulate ferroptosis. However, despite of numerous studies indirectly demonstrating a link between ferroptosis and the gut microbiota, there is a lack of robust evidence directly supporting the causal relationship. Furthermore, the specific role of the gut microbiota in regulating ferroptosis and the key regulatory factors involved require further discussion. Additionally, we provide a summary of studies on ferroptosis and the gut microbiota in CKD, aiming to identify meaningful clues for investigating disease mechanisms and developing treatment strategies. Currently, there are several unresolved questions that warrant further study:
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1.
Role of specific microbiota and metabolites: Identifying which specific microbiota species and metabolites play a regulatory role in ferroptosis and determining whether their impact on ferroptosis is positive or negative.
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2.
Mechanisms of gut microbiota modulation: Investigating the influence of the gut microbiota on the defense system against ferroptosis and the signaling pathways through which the gut microbiota regulates ferroptosis.
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3.
Influence of interventions: Exploring the effects of interventions that regulate the gut microbiota, such as probiotics, prebiotics, and fecal microbiota transplantation, on ferroptosis, as well as the therapeutic implications of these interventions for ferroptosis-related diseases.
By addressing these problems, a deeper understanding of the influence of the gut microbiota on ferroptosis and its implications for various diseases can be gained, paving the way for potential therapeutic interventions and personalized treatment approaches.
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Funding
This work was supported by the Natural Science Foundation of Henan Province (222300420089), the National Natural Science Foundation of China (32371170, 31971065), the Scientific Research and Innovation Team of the First Affiliated Hospital of Zhengzhou University (QNCXTD2023006), and the Medical Science and Technology Research Project of Henan Province (LHGJ20230165).
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PW and ZSL conceived the study. ZHM drafted the manuscript. ZHM and SKP prepared the figures. PW, ZXZG, and DWL revised the manuscript. All the authors have read and approved the final version.
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Mao, ZH., Gao, ZX., Pan, SK. et al. Ferroptosis: a potential bridge linking gut microbiota and chronic kidney disease. Cell Death Discov. 10, 234 (2024). https://doi.org/10.1038/s41420-024-02000-8
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DOI: https://doi.org/10.1038/s41420-024-02000-8