The definitive identification of the lignans trans-2,3-bis(3-hydroxybenzyl)-gamma-butyrolactone and 2,3-bis(3-hydroxybenzyl)butane-1,4-diol in human and animal urine.

The definitive identification of the first lignans to be found in humans and animals is described. Gas chromatography--mass spectrometry, n.m.r. spectroscopy, i.r. spectroscopy and chemical techniques were employed to establish the structures of two lignans as trans-2,3-bis(3-hydroxybenzyl)-gamma-butyrolactone and 2,3-bis(3-hydroxybenzyl)butane-1,4-diol. Both compounds are essetially racemic. Evidence was also found for several methoxy analogues of these lignans in the vervet monkey.     

Uptake and metabolism of enterolactone and enterodiol by human colon epithelial cells

The enterolignans enterolactone and enterodiol are phytoestrogens that are formed from plant lignans by microorganisms in the human colon. Enterolignans circulate in plasma as conjugates. We hypothesized that conjugation of enterolignans takes place in colon epithelial cells, and studied the time course of uptake and metabolism of enterolactone and enterodiol in three human colon epithelial cell lines. In addition, the conjugates were identified by mass spectrometry with accurate mass measurement (LC/QTOFMS/MS). Intracellular levels of conjugated enterolactone and enterodiol in HT29 cells rose immediately after starting the exposure. This was accompanied by a rapid decrease in free enterolactone and enterodiol in the exposure medium of HT29 and (un)differentiated CaCo-2 but not of CCD841CoTr cells. Conjugation and excretion of enterolactone and enterodiol was complete within 8 h, except for enterodiol in CaCo-2 cells ( approximately 48 h). Enterolactone appears to be more rapidly metabolized and/or excreted than enterodiol, and also the appearance of conjugated enterolactone in medium is less affected by the presence of enterodiol than vice versa. Total (free plus conjugated) enterolignan concentrations remained constant throughout the experiments. Three conjugates were identified in exposure medium of HT29 cells: enterolactone-sulfate, enterolactone-glucuronide, and enterodiol-glucuronide.Taken together, our data suggest that phase II metabolism of enterolactone and enterodiol already may take place during uptake in the colon and that colon epithelial cells may be responsible for this metabolism.     

Diet and urinary excretion of lignans in female subjects

Lignans, a class of compounds having a 2,3-dibenzylbutane skeleton, have recently been identified for the first time in humans and animals and evidence indicating their formation by intestinal microflora has previously been established in rats and humans. In the present report the influence of diet on the biosynthesis of this new group of compounds was investigated by comparing the urinary excretion of the principal lignan, trans-2,3-bis-(3-hydroxybenzyl) -butyrolactone (enterolactone, HBBL), in 12 omnivoric and 14 vegetarian women. Young vegetarian women were found to excrete significantly greater amounts of enterolactone than omnivores, while old vegetarians excreted comparable amounts to the omnivore group. A statistically significant (P less than 0.01-0.001) correlation was found between the amount of fibre in the diet and the urinary enterolactone excretion.     

Production and metabolism of lignans by the human faecal flora

Lignans have, until recently, been found only in plants. Enterolactone and enterodiol are the major lignans present in the urine of humans and have a potential physiological protective role against cancer. It has been shown that these compounds can be formed in vitro by human faecal flora and that enterodiol is oxidized to enterolactone by bacteria that are present in stools at a concentration of up to 10(3)/g. It was also possible to produce both of these lignans in vitro from linseeds and from secoisolariciresinol, a precursor present in linseed, by bacteria present in stools, at a concentration of between 10(3) and 10(4)/g. Enterolactone was produced from matairesinol, a more abundant plant lignan than secoisolariciresinol, after incubation with a mixed faecal flora under both aerobic and anaerobic conditions. In each case conversion was dependent on the presence of viable bacteria. These findings indicate that a number of different pathways operate to produce enterolactone and enterodiol depending on the ingested dietary precursor.     

A validated method for the quantification of enterodiol and enterolactone in plasma using isotope dilution liquid chromatography with tandem mass spectrometry

Enterolactone and enterodiol are phytoestrogens with structural similarity to endogenous estrogens. Because of their biological activities, they may affect the development of several diseases. To quantify enterodiol and enterolactone in plasma, we developed and validated a liquid chromatography-tandem mass spectrometry method with electrospray ionization using 13C3 labeled isotopes. The method consists of a simple enzymatic hydrolysis and ether extraction followed by a rapid LC separation (run-time of 11 min). Detection limits as low as 0.15 nM for enterodiol and 0.55 nM for enterolactone were achieved. The within-run R.S.D. ranges from 3 to 6% and the between-run R.S.D. ranges from 10 to 14% for both enterolignans. This method allows simple, rapid, and sensitive quantification, and is suitable for measuring large numbers of samples.     

The effect of estrogens and phytoestrogenic lignans on macrophage uptake of atherogenic lipoproteins

The present study examined the effect of estrogens and compounds with estrogenic activity on the uptake of atherogenic lipoproteins into macrophages, thought to be the initiating step in the development of atherosclerotic lesions. Isolated low density lipoprotein (LDL) and lipoprotein(a) (Lp(a)) were radiolabelled with (3)H-cholesterol linoleate, and incubated with J774 macrophages for 24 hours in the presence of pharmacological doses of estrogens and phytoestrogens. At a concentration of 0.1 microM, the estrogen 17beta-estradiol significantly reduced LDL uptake by macrophages by 14% (p < 0.05), but estrone did not have any effect. At 10 microM, both estrogens significantly reduced macrophage LDL uptake, but the phytoestrogenic-lignans enterodiol and enterolactone had no effect on LDL uptake. Lp(a) uptake into cells was significantly reduced by both estrone and estradiol, and by enterolactone and enterodiol at concentrations of 10 microM (p < 0.01), with enterodiol being most effective. The results of this study suggest that the uptake of these structurally similar lipoproteins is regulated differently. Macrophage Lp(a) uptake appears more phytoestrogen sensitive than does LDL uptake.     

Production and metabolism of lignans by the human faecal flora

Lignans have, until recently, been found only in plants. Enterolactone and enterodiol are the major lignans present in the urine of humans and have a potential physiological protective role against cancer. It has been shown that these compounds can be formed in vitro by human faecal flora and that enterodiol is oxidized to enterolactone by bacteria that are present in stools at a concentration of up to 10³/g. It was also possible to produce both of these lignans in vitro from linseeds and from secoisolariciresinol, a precursor present in linseed, by bacteria present in stools, at a concentration of between 10³ and 10⁴/g. Enterolactone was produced from matairesinol, a more abundant plant lignan than secoisolariciresinol, after incubation with a mixed faecal flora under both aerobic and anaerobic conditions. In each case conversion was dependent on the presence of viable bacteria. These findings indicate that a number of different pathways operate to produce enterolactone and enterodiol depending on the ingested dietary precursor.     

In vitro metabolism of flax lignans by ruminal and faecal microbiota of dairy cows

Aims: To determine the in vitro conversion of plant lignans from two flax products (hull and seed) into the mammalian lignans, enterolactone and enterodiol, by bovine ruminal and faecal microbiota. Methods and Results: Flax seeds and hulls were incubated in vitro over a 96-h time course with ruminal or faecal inoculum. Plant lignans in flax seeds and hulls averaged 9·2 and 32·0 nmol mg⁻¹, respectively. The highest net production of enterodiol at 72 and 96 h of incubation was obtained with flax hulls incubated with faecal microbiota. There was no difference in net production of enterodiol between flax products within the first 24 h of incubation. In general, net production of enterolactone over the 96-h time course was significantly higher for flax products incubated with ruminal than with faecal microbiota. Net production of enterolactone at 72 and 96 h of incubation was greater for flax hulls than flax seeds. Conclusions: Results of the present experiment suggest that, of the metabolites studied, the main mammalian lignan metabolite produced from flax hulls and seeds by ruminal microbiota is enterolactone while faecal microbiota leads mainly to the net production of enterodiol. Significance and Impact of the Study: This research will improve the understanding of the metabolic pathway of mammalian lignans in dairy cows, in order to enable targeted manipulation of their quantities in milk.     

Performance and egg quality of laying hens fed flaxseed: highlights on n-3 fatty acids,cholesterol, lignans and isoflavones

Flaxseed is a rich source of α-linolenic acid and phytoestrogens, mainly lignans, whose metabolites (enterodiol and enterolactone) can affect estrogen functions. The present study evaluated the influence of dietary flaxseed supplementation on reproductive performance and egg characteristics (fatty acids, cholesterol, lignans and isoflavones) of 40 Hy-Line hens (20/group) fed for 23 weeks a control diet or the same diet supplemented with 10% of extruded flaxseed. The flaxseed diet had approximately three times the content of lignans (2608.54 ng/g) as the control diet, mainly secoisolariciresinol diglucoside (1534.24 v. 494.72 ng/g). When compared with the control group, hens fed flaxseed showed a similar deposition rate (72.0% v. 73.9%) and egg yield. Furthermore, there was no effect of flaxseed on the main chemical composition of the egg and on its cholesterol content. Estradiol was higher in the plasma of the control group (1419.00 v. 1077.01 pg/ml) probably due to the effect of flaxseed on phytoestrogen metabolites. The plasma lignans were higher in hens fed flaxseed, whereas isoflavones were lower, mainly due to the lower equol value (50.52 v. 71.01 ng/ml). A similar trend was shown in eggs: the flaxseed group had higher level of enterodiol and enterolactone, whereas the equol was lower (198.31 v. 142.02 ng/g yolk). Secoisolariciresinol was the main lignan in eggs of the flaxseed group and its concentration was three times higher then control eggs. Flaxseed also improved the n-3 long-chain polyunsaturated fatty acids of eggs (3.25 v. 0.92 mg/g egg), mainly DHA, however, its oxidative status (thiobarbituric reactive substances) was negatively affected. In conclusion, 10% dietary flaxseed did not affect the productive performance of hens or the yolk cholesterol concentration, whereas the lignans and n-3 polyunsaturated fatty acid content of eggs improved. Further details on the competition between the different dietary phytoestrogens and their metabolites (estrogen, equol, enterodiol and enterolactone) should be investigated.     

Synthesis of enterolactone and enterodiol precursors as potential inhibitors of human estrogen synthetase (aromatase)

A series of variably substituted derivatives of lignan lactones and diols were prepared using tandem conjugate addition reaction as a key step. These theoretical precursors of the mammalian lignans enterolactone 1 and enterodiol 3 are moderate or weak inhibitors of human aromatase activity.     

Phytoestrogens: new ligands for rat and human alpha-fetoprotein.

The binding of the lignans, enterolactone, enterodiol, nordihydroguaiaretic acid (NDGA), and the isoflavonic phytoestrogen equol, to human and rat alpha-fetoprotein (AFP) was studied. They had differential inhibitory effects (NDGA greater than equol greater than enterolactone greater than enterodiol) on the binding of estrone and estradiol to rat AFP and the binding of unsaturated fatty acid to both rat and human AFP. Inhibition was dose-dependent. The apparent dissociation constants (Kd) for phytoestrogens binding to AFP were: Kd NDGA = 5 +/- 1.2.10(-7) M, Kd equol = 6.7 +/- 0.8.10(-6) M, Kd enterolactone = 1.7 +/- 0.4.10(-5) M and Kd enterodiol = 2.2 +/- 0.6.10(-5) M. The Kd for estrone binding to rat AFP was increased by increasing concentrations of equol, but the number of esterone binding sites remained unchanged. This, plus the results of double-reciprocal plots, suggests that they compete for the same site(s). NDGA also competitively inhibited estrone binding at low NDGA concentrations (increased Kd), but high concentrations induced conformational changes in rat AFP, as both Kd and the number of binding sites (n) were altered. Both rat and human AFPs underwent changes in electrophoretic behaviour and loss of immunoreactivity with increasing NDGA, suggesting that NDGA binding induces conformational changes in the AFPs. However, equol did not alter the electrophoretic or immunological properties of either rat or human AFP, providing further evidence for qualitative differences in the effects of these diphenols. These findings indicate that phytoestrogens could play a role in AFP-dependent normal and pathological growth and development.     

Quantification of isoflavones and lignans in urine using gas chromatography/mass spectrometry

Phytoestrogens (isoflavones and lignans) are of increasing interest due to their potential to prevent certain types of complex diseases. However, epidemiological evidence is needed on the levels of phytoestrogens and their metabolites in foods and biological fluids in relation to risk of these diseases. We report an assay for phytoestrogens which is sensitive, accurate, and uses low volumes of sample. Suitable for epidemiological studies, the assay consists of a simple sample preparation procedure and has been developed for the analysis of five isoflavones (daidzein, O-desmethylangolensin, equol, genistein, and glycitein) and two lignans (enterodiol and enterolactone), which requires only 200 microl of urine and utilizes one solid-phase extraction stage for sample preparation prior to derivatization for GC/MS analysis. Limits of detection were in the region 1.2 ng/ml (enterodiol) to 5.3ng/ml (enterolactone) and the method performed well in the UK Government's Food Standards Agency-sponsored quality assurance scheme for phytoestrogens. For the first time, average levels of all the above phytoestrogens were measured in samples of urine collected from a free living population sample of women. Results show a large range in both the amount and the type of phytoestrogens excreted.     

Synthesis of phosphonate and ether analogs of rac-phosphatidyl-L-serine

The chemical synthesis of four phosphonate-containing phosphatidylserine analogs namely, L-serine (±)-[2,3-bis(hexadecyloxy) and 2,3-bis(Palmitoyloxy)-propyl] phosphonates, and L-serine (±)-[3,4-bis(hexadecyloxy and 3,4-bis(palmitoyloxy)-butyl]phosphonates is described. (±)-2,3-Bis(hexadecyloxy) and 2,3-bis(palmitoyloxy)-propylphosphonic acids and (±)-3,4-bis (hexadecyloxy)butylphosphonic acid were prepared by reaction of tris(trimethylsilyl) phosphite on the corresponding haloalkane. Condensation of the above phosphonic acids or (±)-3,4-bis (palmitoyloxy)butylphosphonic acid with N-carboxy-L-serine dibenzyl ester in the presence of trichloroacetonitrile or triisopropylbenzenesulfonyl chloride yielded the protected serine intermediates, which on hydrogenolysis gave the desired L-serine analogs. By a similar route, 1,2-dihexadecyl-rac-glycero-3-phosphoric acid was converted to 1,2-dihexadecyl-rac-glycerophospho-L-serine [L-serine (±)-2,3-bis(hexadecyloxy)propyl hydrogen phosphate(ester)].     

Synthesis of some A- and D-ring fused steroidal pyrazoles, isoxazoles and pyrimidines

The preparation of steroidal heterocycles containing pyrazole, isoxazole and pyrimidine rings fused to the 2,3- and 16,17-positions of the steroid nucleus is described. These were prepared by the reaction of hydrazine, hydroxylamine and guanidine, respectively, with 2-ethoxymethylene-3-oxo- or 16-ethoxymethylene-17-oxo- or 2-bis(methylthio)methylene-3-oxo- or 16-bis(methylthio)methylene-17-oxo-steroids.     

Optimization of conditions for the enzymatic hydrolysis of phytoestrogen conjugates in urine and plasma

Optimal pH, temperature, and concentration of enzyme conditions for the rate of hydrolysis of five isoflavone conjugates (daidzein, O-desmethylangolensin, equol, genistein, and glycitein) and two lignans (enterodiol and enterolactone) from two biological matrices (urine and plasma) were studied using beta-glucuronidase from Helix pomatia. In addition, the use of mixtures of beta-glucuronidase and sulfatase enzymes from different sources was investigated to find enzyme preparations that contained lower amounts of naturally present phytoestrogens. Quantification of aglycones spiked with (13)C(3)-labeled internal standards was carried out by LC-MS/MS. In urine, all of the phytoestrogen conjugates hydrolyzed within 2h under standard hydrolysis conditions (24mul H. pomatia, pH 5, 37 degrees C). Hydrolysis rates were improved at 45 degrees C and by doubling the enzyme concentration and may be used to further reduce hydrolysis times down to 100min. In plasma, a 16-h hydrolysis was required to ensure complete hydrolysis of all conjugates. As with urine, the use of increased temperature or increased enzyme concentration reduced hydrolysis times for most analytes. However, the rate of hydrolysis in plasma was significantly slower than that in urine for all analytes except enterodiol, for which the reverse was true. Neither increased temperature nor increased enzyme concentration increased the rate of hydrolysis of enterolactone. Hydrolysis at pH 6 proved to be detrimental to hydrolysis of phytoestrogen conjugates, especially those in plasma. Other enzyme preparations from different sources, such as beta-glucuronidase from Escherichia coli, were found to contain lower amounts of contaminating phytoestrogens and showed increased enzyme activity for isoflavones, but lower activity for lignans, when used with other sulfatase enzymes. In addition, this involved complicating the analytical procedure through using mixtures of enzymes. Therefore, the use of beta-glucuronidase from H. pomatia combined with an enzyme "blank" to correct for phytoestrogen contamination was shown to be a suitable method for hydrolysis of phytoestrogens.     

Sensitive high-performance liquid chromatographic method for profiling phytoestrogens using coulometric electrode array detection: application to plasma analysis.

An HPLC method for profiling 13 phytoestrogens and their metabolites using coulometric electrode array detection was developed. Sensitivity of the method was slightly less than that of our GC-MS method, but significantly higher compared to the HPLC methods using diode-array or UV detection. Detection limits varied from 3.4 (secoisolariciresinol) to 40.3 (genistin) pg on column. Signal linearities ranged from the detection limits to 61 ng on column. Resolution values for the peak pairs varied from 1.1 (O-desmethylangolensin-anhydrosecoisolariciresinol) to 16 (daidzin-genistin). Intra- and interassay retention time variations were negligible and detector response variation was eliminated by frequent calibration. Chromatographic method was applied to plasma analyses and 6 of the 13 compounds were detected. Method accuracy for those six analytes varied from 69% (enterodiol) to 118% (genistein). Intraassay precision CVs ranged from 1.5% (enterolactone, 12.4 nmol/liter) to 14% (genistein, 245 nmol/liter) and interassay precision CVs ranged from 9.9% (daidzein, 67.4 nmol/liter) to 44% (enterodiol, 1.20 nmol/liter).     

Enterolactone and estradiol inhibit each other''s proliferative effect on MCF-7 breast cancer cells in culture

In earlier studies it has been shown that women with breast cancer and at risk for breast cancer have low excretion of urinary mammalian lignans (enterolactone and enterodiol) mainly due to low intake of whole-grain products and other fiber-rich foods. It is well known that estradiol (E2) has proliferative effects on estrogen dependent cancer cells and that antiestrogens inhibit this effect. To elucidate whether enterolactone (Enl) has antiestrogenic properties we studied, using MCF-7 breast cancer cells in culture, the in vitro effect of relatively low concentrations of Enl added both alone and in combination with E2. E2 (1 nmol/l) and Enl (0.5–2 μmol/l) separately stimulated the proliferation of MCF-7 cells, but their combination always resulted in lower stimulation than any of them alone, or the combined compounds had no stimulatory effect at all compared to the control. Higher concentrations above 10 μmol/l of Enl inhibited significantly the growth of the cells suggesting a toxic effect. The lignan was very rapidly conjugated to its monosulfate. It is suggested that one possible mechanism by which Enl may affect the growth of these estrogen sensitive cells is by competition of Enl and its sulfate with the estrogens for sulfokinases and sulfatases involved in estrogen metabolism in the cells. It is concluded that Enl inhibits E2-stimulated MCF-7 breast cancer cell growth in vitro, and vice versa. The concentrations of Enl needed for the elimination of the proliferative effect of E2 are physiologic and similar to those used in corresponding experiments utilizing tamoxifen.     

High throughput quantification of phytoestrogens in human urine and serum using liquid chromatography/tandem mass spectrometry (LC-MS/MS)

Phytoestrogens are currently the subject of intense study owing to their potential protective effects against a number of complex diseases. However, in order to investigate the interactions between phytoestrogens and disease state effectively, it is necessary to have analytical methods which are sensitive, reproducible, and require low sample volumes. We report an assay for three isoflavones (daidzein, genistein, and glycitein), two metabolites of daidzein (equol and O-desmethylangolensin), three lignans (secoisolariciresinol, enterodiol, and enterolactone), and one flavanone (naringenin) in human urine and serum. A high throughput of samples has been achieved via the use of 96-well plate sample extraction and liquid chromatography/tandem mass spectrometry (LC-MS/MS) analysis incorporating column switching, thus making the assay suitable for use on large sample numbers, such as those found in epidemiological studies. The robustness of the assay was proven via the comparison of data generated on two different LC-MS/MS systems, with and without column switching.     

Metabolism of isoflavones, lignans and prenylflavonoids by intestinal bacteria: producer phenotyping and relation with intestinal community

Many studies have investigated the importance of the intestinal bacterial activation of individual phytoestrogens. However, human nutrition contains different phytoestrogens and the final exposure depends on the microbial potential to activate all different groups within each individual. In this work, interindividual variations in the bacterial activation of the different phytoestrogens were assessed. Incubation of feces from 100 individuals using SoyLife EXTRA, LinumLife EXTRA and isoxanthohumol suggested that individuals could be separated into high, moderate and low O-desmethylangolensin (O-DMA), equol, enterodiol (END), enterolactone (ENL) or 8-prenylnaringenin producers, but that the metabolism of isoflavones, lignans and prenylflavonoids follows separate, independent pathways. However, O-DMA and equol production correlated negatively, whereas a positive correlation was found between END and ENL production. In addition, END production correlated negatively with Clostridium coccoides-Eubacterium rectale counts. Furthermore, O-DMA production was correlated with the abundance of methanogens, whereas equol production correlated with sulfate-reducing bacteria, indicating that the metabolic fate of daidzein may be related to intestinal H(2) metabolism.     

Phylogeny of human intestinal bacteria that activate the dietary lignan secoisolariciresinol diglucoside

The human intestinal microbiota is essential for the conversion of the dietary lignan secoisolariciresinol diglucoside (SDG) via secoisolariciresinol (SECO) to the enterolignans enterodiol (ED) and enterolactone (EL). However, knowledge of the species that catalyse the underlying reactions is scant. Therefore, we focused our attention on the identification of intestinal bacteria involved in the conversion of SDG. Strains of Bacteroides distasonis, Bacteroides fragilis, Bacteroides ovatus and Clostridium cocleatum, as well as the newly isolated strain Clostridium sp. SDG-Mt85-3Db, deglycosylated SDG. Demethylation of SECO was catalysed by strains of Butyribacterium methylotrophicum, Eubacterium callanderi, Eubacterium limosum and Peptostreptococcus productus. Dehydroxylation of SECO was catalysed by strains of Clostridium scindens and Eggerthella lenta. Finally, the newly isolated strain ED-Mt61/PYG-s6 catalysed the dehydrogenation of ED to EL. The results indicate that the activation of SDG involves phylogenetically diverse bacteria, most of which are members of the dominant human intestinal microbiota.