Isolation and characterisation of an equol-producing mixed microbial culture from a human faecal sample and its activity under gastrointestinal conditions

Only about one third of humans possess a microbiota capable of transforming the dietary isoflavone daidzein into equol. Little is known about the dietary and physiological factors determining this ecological feature. In this study, the in vitro metabolism of daidzein by faecal samples from four human individuals was investigated. One culture produced the metabolites dihydrodaidzein and O-desmethylangolensin, another produced dihydrodaidzein and equol. From the latter, a stable and transferable mixed culture transforming daidzein into equol was obtained. Molecular fingerprinting analysis (denaturing gradient gel electrophoresis) showed the presence of four bacterial species of which only the first three strains could be brought into pure culture. These strains were identified as Lactobacillus mucosae EPI2, Enterococcus faecium EPI1 and Finegoldia magna EPI3, and did not produce equol in pure culture. The fourth species was tentatively identified as Veillonella sp strain EP. It was found that hydrogen gas in particular, but also butyrate and propionate, which are all colonic fermentation products from poorly digestible carbohydrates, stimulated equol production by the mixed culture. However, when fructo-oligosaccharides were added, equol production was inhibited. Furthermore, the equol-producing capacity of the isolated culture was maintained upon its addition to a faecal culture originating from a non-equol-producing individual.     

The role of diet in the metabolism of daidzein by human faecal microbiota sampled from Italian volunteers

The intestinal microbial transformation of daidzein into equol is subject to a wide inter-individual variability. The aim of this study was to investigate in vitro this transformation and to evaluate possible correlations between individual diet and equol production. The transformation of daidzein was investigated in anaerobic batch cultures inoculated with mixed fecal bacteria from 90 volunteers. The daidzein metabolism was monitored by liquid chromatography-mass spectrometry, and a chiral column was used to distinguish equol and dihydrodaidzein enantiomers. The obtained results show that daidzein was unchanged (≈27%) or degraded to equol (≈28%), O-desmethylangolensin (≈12%) or dihydrodaidzein (≈31%). Furthermore, some subjects (≈2%) are able to produce both equol and O-desmethylangolensin. Bacteria represent sub-dominant populations (10⁵–10⁹ cell/g wet faeces) in “slow” equol producers, while higher counts of equol-producing microorganisms (10¹⁰–10¹¹ cell/g wet faeces) were found in “quick” equol producers. The in vitro test to evaluate equol-producing status is quick and not invasive, and the obtained results are comparable with those reported in vivo. Indeed, the only enantiomer present in the batch cultures containing equol was the S-form. No significant correlations between equol production, BMI, age and sex were found. It seems that the equol-producer group consumed less fibre, vegetables and cereals, and more lipids from animal sources.     

Enantioselective Synthesis of S-Equol from Dihydrodaidzein by a Newly Isolated Anaerobic Human Intestinal Bacterium

A newly isolated rod-shaped, gram-negative anaerobic bacterium from human feces, named Julong 732, was found to be capable of metabolizing the isoflavone dihydrodaidzein to S-equol under anaerobic conditions. The metabolite, equol, was identified by using electron impact ionization mass spectrometry, ¹H and ¹³C nuclear magnetic resonance spectroscopy, and UV spectral analyses. However, strain Julong 732 was not able to produce equol from daidzein, and tetrahydrodaidzein and dehydroequol, which are most likely intermediates in the anaerobic metabolism of dihydrodaidzein, were not detected in bacterial culture medium containing dihydrodaidzein. Chiral stationary-phase high-performance liquid chromatography eluted only one metabolite, S-equol, which was produced from a bacterial culture containing a racemic mixture of dihydrodaidzein. Strain Julong 732 did not show racemase activity to transform R-equol to S-equol and vice versa. Its full 16S rRNA gene sequence (1,429 bp) had 92.8% similarity to that of Eggerthella hongkongenis HKU10. This is the first report of a single bacterium capable of converting a racemic mixture of dihydrodaidzein to enantiomeric pure S-equol.     

Determination of Reductones by High-Pressure Liquid Chromatographic Method

Asaccharobacter celatus AHU1763 is a Gram-positive, obligate anaerobic, non-spore forming, rod-shaped bacteria that was successfully isolated from rat cecal content. Daizein was converted to equol via dihydrodaidzein by this bacterium. A crude enzyme that converted daidzein to dihydrodaidzein was detected mainly in the culture supernatant. The ability of this enzyme dropped after the culture supernatant was exposed to a normal atmospheric environment for even 5 min. Furthermore, the enzyme responsible for changing dihydrodaidzein to equol was detected mainly in the cell debris, which required anaerobic conditions for its activity.     

<Emphasis Type="Italic">Lactobacillus rhamnosus</Emphasis> JCM 2771: Impact on Metabolism of Isoflavonoids in the Fecal Flora from a Male Equol Producer

Many beneficial effects of probiotics have been reported; however, few have focussed on the effects of Lactobacillus, a probiotic, on the bioconversion of isoflavonoids. We hypothesized that Lactobacillus rhamnosus will modify the metabolism of isoflavone. In an in vitro incubation, L. rhamnosus JCM 2771 produced daidzein from daidzin along with genistein. However, daidzin and genistein were not detected in the incubation solution of daidzein with L. rhamnosus. In the fecal suspension from a male equol producer with daidzein, equol was detected in the presence of a low or high concentration of L. rhamnosus. In the fecal incubation with daidzin, the equol concentration increased with an increasing concentration of L. rhamnosus JCM 2771. L. rhamnosus affected the equol production in the in vitro incubation of daidzein with fecal flora from a male equol producer. We demonstrated for the first time that L. rhamnosus JCM 2771 could produce genistein from daidzin and affect the equol production of fecal flora from a male equol producer in vitro.     

Conversion of Daidzein and Genistein by an Anaerobic Bacterium Newly Isolated from the Mouse Intestine

The metabolism of isoflavones by gut bacteria plays a key role in the availability and bioactivation of these compounds in the intestine. Daidzein and genistein are the most common dietary soy isoflavones. While daidzein conversion yielding equol has been known for some time, the corresponding formation of 5-hydroxy-equol from genistein has not been reported previously. We isolated a strictly anaerobic bacterium (Mt1B8) from the mouse intestine which converted daidzein via dihydrodaidzein to equol as well as genistein via dihydrogenistein to 5-hydroxy-equol. Strain Mt1B8 was a gram-positive, rod-shaped bacterium identified as a member of the Coriobacteriaceae. Strain Mt1B8 also transformed dihydrodaidzein and dihydrogenistein to equol and 5-hydroxy-equol, respectively. The conversion of daidzein, genistein, dihydrodaidzein, and dihydrogenistein in the stationary growth phase depended on preincubation with the corresponding isoflavonoid, indicating enzyme induction. Moreover, dihydrogenistein was transformed even more rapidly in the stationary phase when strain Mt1B8 was grown on either genistein or daidzein. Growing the cells on daidzein also enabled conversion of genistein. This suggests that the same enzymes are involved in the conversion of the two isoflavones.     

重组酿酒酵母催化二氢大豆苷元生产雌马酚

雌马酚是大豆异黄酮的代谢产物,是一种天然的选择性雌激素受体调节剂,稳定性和生物学活性高。为实现雌马酚的微生物合成,采用模块途径工程策略,构建编码雌马酚合成关键酶基因 orf-1、orf-2和orf-3 的表达载体,成功用于转化酿酒酵母BY4741,得到工程菌株。结果表明,工程菌株有效表达了外源基因,并可将大豆异黄酮代谢中间体二氢大豆苷元转化为雌马酚。为构建从头合成雌马酚的微生物细胞工厂提供了重要科学参考。     

Identification of a novel dihydrodaidzein racemase essential for biosynthesis of equol from daidzein in Lactococcus sp. strain 20-92

Equol is metabolized from daidzein, a soy isoflavone, by the gut microflora. In this study, we identified a novel dihydrodaidzein racemase (L-DDRC) that is involved in equol biosynthesis in a lactic acid bacterium, Lactococcus sp. strain 20-92, and confirmed that histidine-tagged recombinant L-DDRC (L-DDRC-His) was able to convert both the (R)- and (S)-enantiomers of dihydrodaidzein to the racemate. Moreover, we showed that recombinant L-DDRC-His was essential for in vitro equol production from daidzein by a recombinant enzyme mixture and that efficient in vitro equol production from daidzein was possible using at least four enzymes, including L-DDRC. We also proposed a model of the metabolic pathway from daidzein to equol in Lactococcus strain 20-92.     

Microbial equol production attenuates colonic methanogenesis and sulphidogenesis in vitro

Hydrogen gas produced during colonic fermentation is excreted in breath and flatus, or removed by hydrogen-consuming bacteria such as methanogens and sulphate-reducing bacteria. However, recent research has shown that H₂ is also consumed by equol-producing bacteria during the reduction of daidzein into equol. In this study, the interactions between methanogens, sulphate-reducing, and equol-producing bacteria were investigated under in vitro simulated intestinal conditions. In the presence of daidzein, the equol-producing bacterial consortium EPC4 gave rise to equol production in cultures of Methanobrevibacter smithii or Desulfovibrio sp. as well as in faecal samples with methanogenic or sulphate-reducing abilities. Moreover, this supplementation significantly (P < 0.001) decreased the methanogenesis and sulphidogenesis. The attenuation did not occur in the absence of a daidzein source. Additionally, there was no influence of soy germ powder, daidzein or equol as such, excluding a possible inhibition by these compounds. Finally, a stronger decrease was observed with increasing amounts of EPC4 and a constant equol production, suggesting that the observed effect was only partly caused by the action of daidzein as a hydrogen sink. These findings are of relevance since abdominal discomfort such as bloating and flatulence, are related to colonic gas production, whereas equol has potential health benefits.     

Dietary daidzein decreases food intake accompanied with delayed gastric emptying in ovariectomized rats

ABSTRACT

We previously found that equol, a metabolite of intestinal bacterial conversion from soy isoflavone daidzein, has female-specific anorectic effects. In the present study, we used seven-week-old female ovariectomized (OVX) Sprague Dawley rats to test the hypothesis that the anorectic effect of dietary daidzein may be attributed to delayed gastric emptying. Results suggest that dietary daidzein delays gastric emptying and that it has an anorectic effect with residual gastric contents, but not without gastric contents. Dietary equol significantly decreased daily food intake in the OVX rats without sleeve gastrectomy, but not in those with sleeve gastrectomy, suggesting that the accumulation of food in the stomach is required for the anorectic effect of equol to occur. These results support the hypothesis that the anorectic effect of dietary daidzein is attributed to delayed gastric emptying.     

Studies on the antioxidant properties of some phytoestrogens

Isoflavones genistein and daidzein are nonsteroidal phytoestrogens occurring mainly in soybean foods. These phytoestrogens possess estrogenic properties and show a variety of health benefits as anti‐inflammatory agents. However, the mechanism of their action has not been identified in detail. The aim of this study is to characterize the antioxidant powers of genistein, daidzein and daidzein metabolite–equol through their activities to scavenge superoxide anion radical (O^?₂^?), hydroxyl radical (HO^?), 2,2–diphenyl–1‐picrylhydrazyl radical (DPPH^?) and hydrogen peroxide (H₂O₂) using chemiluminescence and spectrophotometry techniques. Potassium superoxide in dimethyl sulphoxide (DMSO) and 18‐crown‐6 ether were used as a source of O^?₂^?. Hydroxyl radicals were produced using the Fenton reaction. In free radical assays, genistein had the IC₅₀ values (an amount of antioxidant concentration required to decrease the initial radical concentration by 50%) 0.391 ± 0.012 mM for O^?₂^?, 0.621 ± 0.028 mM for HO^? and 1.89 ± 0.16 mM for DPPH^?. The IC₅₀ values for daidzein for these free radicals were 1.924 ± 0.011 mM, 0.702 ± 0.012 mM and 2.81 ± 0.03 mM, respectively. Equol was the most active the free radical scavenger with IC₅₀ = 0.451 ± 0.018 mM for HO^? and IC₅₀ = 1.36 ± 0.11 mM for DPPH^?. All tested compounds exerted a significant effect on the H₂O₂: IC₅₀ = 18.1 ± 1.1 μM for genistein, IC₅₀ = 2.1 ± 0.5 μM for daidzein, and IC₅₀ = 1.06 ± 0.2 μM for equol. These findings show that genistein, daidzein and equol are effective free radical scavengers and possess high antioxidant power in vitro. Copyright © 2016 John Wiley & Sons, Ltd.     

Anoxybacillus kamchatkensis sp. nov., a novel thermophilic facultative aerobic bacterium with a broad pH optimum from the Geyser valley, Kamchatka

A facultative aerobic, moderately thermophilic, spore forming bacterium, strain JW/VK-KG4 was isolated from an enrichment culture obtained from the Geyser valley, a geothermally heated environment located in the Kamchatka peninsula (Far East region of Russia). The cells were rod shaped, motile, peritrichous flagellated stained Gram positive and had a Gram positive type cell wall. Aerobically, the strain utilized a range of carbohydrates including glucose, fructose, trehalose, proteinuous substrates, and pectin as well. Anaerobically, only carbohydrates are utilized. When growing on carbohydrates, the strain required yeast extract and vitamin B₁₂. Anaerobically, glucose was fermented to lactate as main product and acetate, formate, ethanol as minor products. Aerobically, even in well-aerated cultures (agitated at 500 rpm), glucose oxidation was incomplete and lactate and acetate were found in culture supernatants as by-products. Optimal growth of the isolate was observed at pH^{25 C} 6.8–8.5 and 60°C. The doubling times on glucose at optimal growth conditions were 34 min (aerobically) and 40 min (anaerobically). The G+C content was 42.3 mol% as determined by T_m assay. Sequence analysis of the 16S rRNA gene indicated an affiliation of strain JW/VK-KG4 with Anoxybacillus species. Based on its morphology, physiology, phylogenetic relationship and its low DNA-DNA homology with validly published species of Anoxybacillus, it is proposed that strain JW/VK-KG4 represents a new species in the genus Anoxybacillus as A. kamchatkensis sp. nov. The type strain for the novel species is JW/VK-KG4^T (=DSM 14988, =ATCC BAA-549). The GenBank accession number for the 16S rDNA sequence is AF510985.     

Production of dihydrodaidzein and dihydrogenistein by a novel oxygen-tolerant bovine rumen bacterium in the presence of atmospheric oxygen

The original bovine rumen bacterial strain Niu-O16, capable of anaerobically bioconverting isoflavones daidzein and genistein to dihydrodaidzein (DHD) and dihydrogenistein (DHG), respectively, is a rod-shaped obligate anaerobic bacterium. After a long-term domestication, an oxygen-tolerant bacterium, which we named Aeroto-Niu-O16 was obtained. Strain Aeroto-Niu-O16, which can grow in the presence of atmospheric oxygen, differed from the original obligate anaerobic bacterium Niu-O16 by various characteristics, including a change in bacterial shape (from rod to filament), in biochemical traits (from indole negative to indole positive and from amylohydrolysis positive to negative), and point mutations in 16S rRNA gene (G398A and G438A). We found that strain Aeroto-Niu-O16 not only grew aerobically but also converted isoflavones daidzein and genistein to DHD and DHG in the presence of atmospheric oxygen. The bioconversion rate of daidzein and genistein by strain Aeroto-Niu-O16 was 60.3% and 74.1%, respectively. And the maximum bioconversion capacity for daidzein was 1.2 and 1.6 mM for genistein. Furthermore, when we added ascorbic acid (0.15%, m/v) in the cultural medium, the bioconversion rate of daidzein was increased from 60.3% to 71.7%, and that of genistein from 74.1% to 89.2%. This is the first reported oxygen-tolerant isoflavone biotransforming pure culture capable of both growing and executing the reductive activity under aerobic conditions.     

Evaluation of inter‐individual differences in gut bacterial isoflavone bioactivation in humans by PCR‐based targeting of genes involved in equol formation

Aim

To identify human subjects harbouring intestinal bacteria that bioactivate daidzein to equol using a targeted PCR‐based approach.

Methods and Results

In a pilot study including 17 human subjects, equol formation was determined in faecal slurries. In parallel, faecal DNA was amplified by PCR using degenerate primers that target highly conserved regions of dihydrodaidzein reductase and tetrahydrodaidzein reductase genes. PCR products of the expected size were observed for six of the eight subjects identified as equol producers. Analysis of clone libraries revealed the amplification of sequences exclusively related to Adlercreutzia equolifaciens in four of the subjects tested positive for equol formation, whereas in three of the equol producers, only sequences related to Slackia isoflavoniconvertens were observed. No amplicons were obtained for one equol‐forming subject, thus suggesting the presence of nontargeted alternative genes. Amplicons were only sporadically observed in the nonequol producers.

Conclusion

The majority of human subjects who produced equol were also detected with the developed PCR‐based approach.

Significance and Impact of the Study

The obtained results shed light on the distribution and the diversity of known equol‐forming bacterial species in the study group and indicate the presence of as yet unknown equol‐forming bacteria.     

Production of phytoestrogen <Emphasis Type="Italic">S</Emphasis>-equol from daidzein in mixed culture of two anaerobic bacteria

An anaerobic incubation mixture of two bacterial strains Eggerthella sp. Julong 732 and Lactobacillus sp. Niu-O16, which have been known to transform dihydrodaidzein to S-equol and daidzein to dihydrodaidzein respectively, produced S-equol from daidzein through dihydrodaidzein. The biotransformation kinetics of daidzein by the mixed cultures showed that the production of S-equol from daidzein was significantly enhanced, as compared to the production of S-equol from dihydrodaidzein by Eggerthella sp. Julong 732 alone. The substrate daidzein in the mixed culture was almost completely converted to S-equol in 24 h of anaerobic incubation. The increased production of S-equol from daidzein by the mixed culture is likely related to the increased bacterial numbers of Eggerthella sp. Julong 732. In the mixture cultures, the growth of Eggerthella sp. Julong 732 was significantly increased while the growth of Lactobacillus sp. Niu-O16 was suppressed as compared to either the single culture of Eggerthella sp. Julong 732 or Lactobacillus sp. Niu-O16. This is the first report in which two metabolic pathways to produce S-equol from daidzein by a mixed culture of bacteria isolated from human and bovine intestinal environments were successfully linked under anaerobic conditions.     

Effects of Nitrogen Source and Bacterial Elicitor on Isoflavone Accumulation in Root Cultures of Albizzia kalkora （Roxb.） Prain

Changes in cellular isoflavone （daidzein and genistein） contents were monitored in root cultures of Albizzia kalkora （Roxb.） Prain after feeding different ratios of NH4^＋/NO3^- and treatment with a biotic elicitor （three strains of Rhizobium sp.）. The NH4^＋/NO3^- ratio appears to be positively correlated with daidzein content in the roots and shows a negative correlation with genistein. Among the three different strains of Rhizobium used, the strain ATCC 15834 caused a 35% increase in daidzein production by infection. In the case of genistein, maximum production （94%） was obtained when cultures were treated on Day 6 by the strains ATCC 15834 and KCTC 1541. The biosynthetic pathway of the two isoflavones apparently reacts differently to the same culture conditions and the same strains of Rhizobium. Therefore, the present data suggest that the production of daidzein and genistein could be modulated by changing the NH4^＋/NO3^- ratio and the application of Rhizobium.     

Cloning and Expression of a Novel NADP(H)-Dependent Daidzein Reductase,an Enzyme Involved in the Metabolism of Daidzein,from Equol-Producing Lactococcus Strain 20-92

Equol is a metabolite produced from daidzein by enteric microflora, and it has attracted a great deal of attention because of its protective or ameliorative ability against several sex hormone-dependent diseases (e.g., menopausal disorder and lower bone density), which is more potent than that of other isoflavonoids. We purified a novel NADP(H)-dependent daidzein reductase (L-DZNR) from Lactococcus strain 20-92 (Lactococcus 20-92; S. Uchiyama, T. Ueno, and T. Suzuki, international patent WO2005/000042) that is involved in the metabolism of soy isoflavones and equol production and converts daidzein to dihydrodaidzein. Partial amino acid sequences were determined from purified L-DZNR, and the gene encoding L-DZNR was cloned. The nucleotide sequence of this gene consists of an open reading frame of 1,935 nucleotides, and the deduced amino acid sequence consists of 644 amino acids. L-DZNR contains two cofactor binding motifs and an 4Fe-4S cluster. It was further suggested that L-DZNR was an NAD(H)/NADP(H):flavin oxidoreductase belonging to the old yellow enzyme (OYE) family. Recombinant histidine-tagged L-DZNR was expressed in Escherichia coli. The recombinant protein converted daidzein to (S)-dihydrodaidzein with enantioselectivity. This is the first report of the isolation of an enzyme related to daidzein metabolism and equol production in enteric bacteria.Isoflavones are flavonoids present in various plants and are known to be abundant in soybeans and legumes. These compounds have been called phytoestrogens because their chemical structure is similar to that of the female sex hormone, estrogen. Isoflavones have an ability to bind to estrogen receptors and show protection against or improvement in several sex hormone-dependent diseases, such as breast cancer, prostate cancer, menopausal disorder, lower bone density, and hypertension, due to their weak agonistic or antagonistic effects (1, 19, 27).Daidzein is one of the main soy isoflavonoids produced from daidzin by the glucosidase of intestinal bacteria (17). Equol is a metabolite produced from daidzein by the enterobacterial microflora (5). Recently, equol has attracted a great deal of attention because its estrogenic activity is more potent than that of other isoflavonoids, including daidzein (27). It is well known that individual variation exists in the ability of these enteric microflora to produce equol and that less than half the human population is capable of producing equol after ingesting soy isoflavones (3). Therefore, to increase the production of equol in the enteric environment of each individual, the development of probiotics using safe bacteria which have the ability to produce equol from daidzein is ongoing.Lactococcus strain 20-92 (Lactococcus 20-92; 30a) is an equol-producing lactic acid bacterium isolated from the feces of healthy humans by Uchiyama et al. (30). This bacterium is spherical and Gram positive and is a strain of L. garvieae. The application of Lactococcus 20-92 in probiotics is advantageous because L. garvieae is not pathogenic or toxic to humans.To date, other bacterial strains that are capable of transforming daidzein to dihydrodaidzein or equol have been isolated (9, 21, 22, 23, 29, 32, 36, 37). Daidzein is thought to be metabolized by human intestinal bacteria to equol or to O-desmethylangolensin via dihydrodaidzein and tetrahydrodaidzein (14, 15, 22, 32); however, neither the enzymes involved in the metabolism of daidzein to equol nor even the metabolic pathway has been clarified fully for equol-producing bacteria.In this study, we purified an enzyme from Lactococcus 20-92 that assisted in the conversion of daidzein to dihydrodaidzein. Furthermore, we cloned the L-DZNR gene and expressed the active recombinant enzyme in E. coli.     

雌马酚产生细菌及其雌马酚合成代谢机制

大豆食品中通常富含染料木素和大豆苷元等异黄酮素,人和动物肠道中的某些细菌具有将异黄酮素代谢转化为S-雌马酚的能力。到目前为止,S-雌马酚被认为是一种具有潜在健康调节作用的化合物。啮齿类动物均具备产雌马酚的能力,但不同人群之间存在差异,产雌马酚细菌是否存在可能是造成这种差异的重要原因;不同产雌马酚细菌的代谢机制可能不同,并影响机体最终产雌马酚的能力。本文对已知的各种产雌马酚细菌及其细菌的雌马酚合成机制进行综述,以期为进一步了解雌马酚产生个体差异、雌马酚代谢转化效率、体外雌马酚的发酵生产,以及临床产雌马酚细菌的应用等提供理论参考。