Erika Pfeiffer

Curcumin uptake and metabolism

Curcumin (CUR) is the major orange pigment of turmeric and believed to exert beneficial health effects in the gastrointestinal tract and numerous other organs after oral intake. However, an increasing number of animal and clinical studies show that the concentrations of CUR in blood plasma, urine, and peripheral tissues, if at all detectable, are extremely low even after large doses. The evidence and possible reasons for the very poor systemic bioavailablity of CUR after oral administration are discussed in this brief review. Major factors are the chemical instability of CUR at neutral and slightly alkaline pH, its susceptibility to autoxidation, its avid reductive and conjugative metabolism, and its poor permeation from the intestinal lumen to the portal blood. In view of the very low intestinal bioavailablity, it is difficult to attribute the putative effects observed in peripheral organs to CUR. Therefore, metabolites and/or degradation products of CUR should be taken into consideration as mediators of the pharmacological activity.

Zearalenone and its metabolites as endocrine disrupting chemicals

Zearalenone (ZEA) is a macrocyclic β-resorcylic acid lactone produced by numerous species of Fusarium. It frequently contaminates corn and cereal products in many regions of the world. The biological activity of ZEA is dominated by its pronounced oestrogenicity, which is even enhanced in certain reductive metabolites. This review updates the metabolism in fungi, plants and mammalian systems, as well as the pharmacokinetics of ZEA. The present evidence for the hormonal effects of the parent mycoestrogen and some of its metabolites in vitro and in farm and experimental animals in vivo is reviewed, together with its association with endocrine-disruptive effects in humans. Possible mechanisms of the oestrogenic and carcinogenic activity of ZEA are discussed and future areas of research proposed.

Alternaria toxins: DNA strand-breaking activity in mammalian cellsin vitro.

Treatment, for 1 h, of cultured Chinese hamster V79 cells, human liver HepG2 cells, and human colon HT-29 cells with theAlternaria toxins alternariol (AOH) and alternariol methyl ether (AME) caused a concentration-dependent induction of DNA strand breaks at concentrations ranging from 5 to 50 micromolar. After treatment for 24 h, DNA strand breaks were observed in HepG2 but not HT-29 cells. Analysis of the 24 h-incubation media of HT-29 cells showed that both toxins were completely conjugated, whereas 75% were still present as unconjugated compounds in the 24 h-media of HepG2 cells. Lysates of both cell types fortified with UDPGA were found to convert both toxins into two glucuronides each, but HT-29 cells exhibited a much high activity than HepG2 cells and gave rise to a different ratio of glucuronides. It is concluded that glucuronidation eliminates the DNA strandbreaking potential of AOH and AME, and that the two glucuronides of eachAlternaria toxin are generated by different UGT isoforms.

Alternaria toxins: Altertoxin II is a much stronger mutagen and DNA strand breaking mycotoxin than alternariol and its methyl ether in cultured mammalian cells

Altertoxin II (ATX II) is one of the several mycotoxins produced by Alternaria fungi. It has a perylene quinone structure and is highly mutagenic in Ames Salmonella typhimurium, but its mutagenicity in mammalian cells has not been studied before. Here we report that ATX II is a potent mutagen in cultured Chinese hamster V79 cells, inducing a concentration-dependent increase of mutations at the hypoxanthine guanine phosphoribosyltransferase gene locus at concentrations similar to that of the established mutagen 4-quinoline-N-oxide. Thus, ATX II is at least 50-times more potent as a mutagen than the common Alternaria toxins alternariol (AOH) and alternariol methyl ether (AME). In contrast to AOH and AME, ATX II does not affect the cell cycle of V79 cells. ATX II also causes DNA strand breaks in V79 cells, with a potency again exceeding that of AOH and AME. The high mutagenic and DNA strand breaking activity of ATX II raises the question of whether this Alternaria toxin poses a risk for public health, and warrants studies on the occurrence of ATX II and other perylene quinone-type mycotoxins in food and feed.

Studies on the stability of turmeric constituents

In order to investigate the stability of curcuminoids in physiological media, two samples with different composition of curcumin (CUR I), mono-demethoxycurcumin (CUR II) and bis-demethoxycurcumin (CUR III) were incubated in phosphate buffer and cell culture medium without or with fetal calf serum. The curcuminoids decomposed very rapidly (more than 90% within 12 h) when serum was omitted, but were more stable in the presence of serum. The stability differed between the curcuminoids: CUR I was the least, and CUR III was the most stable curcuminoid. Several degradation products of CUR I were detected, most of which were not yet identified; ferulic acid and vanillin were disclosed as minor products.

Glucuronidation of zearalenone, zeranol and four metabolites in vitro: formation of glucuronides by various microsomes and human UDP-glucuronosyltransferase isoforms.

Glucuronidation constitutes an important pathway in the phase II metabolism of the mycotoxin zearalenone (ZEN) and the growth promotor α-zearalanol (α-ZAL, zeranol), but the enzymology of their formation is yet unknown. In the present study, ZEN, α-ZAL and four of their major phase I metabolites were glucuronidated in vitro using hepatic microsomes from steer, pig, rat and human, intestinal microsomes from humans, and eleven recombinant human UDP-glucuronosyltransferases (UGTs). After assigning chemical structures to the various glucuronides by using previously published information, the enzymatic activities of the various microsomes and UGT isoforms were determined together with the patterns of glucuronides generated. All six compounds were good substrates for all microsomes studied. With very few exceptions, glucuronidation occurred preferentially at the sterically unhindered phenolic 14-hydroxyl group. UGT1A1, 1A3 and 1A8 had the highest activities and gave rise to the phenolic glucuronide, whereas glucuronidation of the aliphatic hydroxyl group was mostly mediated by UGT2B7 with low activity. Based on these in vitro data, ZEN, α-ZAL and their metabolites must be expected to be readily glucuronidated both in the liver and intestine as well as in other extrahepatic organs of humans and various animal species.

Metabolism and permeability of curcumin in cultured Caco‐2 cells

SCOPE Curcumin (CUR) and its major metabolite hexahydro-CUR were studied in Caco-2 cells and in the Caco-2 Millicell® system in vitro to simulate their in vivo intestinal metabolism and absorption in humans. METHODS AND RESULTS Analysis of the incubation medium and cell lysate showed that Caco-2 cells reduce CUR to hexahydro-CUR and octahydro-CUR, and conjugate CUR and its reductive metabolites with glucuronic acid and sulfate. Using the Caco-2 Millicell® system, an efficient transfer of the conjugates into the basolateral, but not the apical, compartment was observed after apical administration. Likewise, hexahydro-CUR was reduced to octahydro-CUR, and glucuronide and sulfate conjugates almost exclusively permeated to the basolateral side. The apparent permeability coefficients (Papp values) of CUR, hexahydro-CUR and their metabolites were determined and found to be extremely low for unchanged CUR, but somewhat higher for hexahydro-CUR and the conjugated metabolites. CONCLUSION The results of this study clearly show that the systemic bioavailability of CUR from the intestine after oral intake must be expected to be virtually zero. Reductive and conjugated metabolites, formed from CUR in the intestine, exhibit moderate absorption. Thus, any biological effects elicited by CUR in tissues other than the gastrointestinal tract are likely due to CUR metabolites.

Aromatic hydroxylation is a major metabolic pathway of the mycotoxin zearalenone in vitro

Zearalenone (ZEN) is a common mycotoxin, for which only reductive metabolites have been identified so far. We now report that ZEN is extensively monohydroxylated by microsomes from human liver in vitro. Two of the major oxidative metabolites arise through aromatic hydroxylation and are catechols. Their chemical structures have been unambiguously determined by using deuterium-labeled ZEN and by comparison with authentic reference compounds. Moreover, both catechol metabolites of ZEN were substrates of the enzyme catechol-O-methyl transferase. One of the monomethyl ethers represented the major metabolite when ZEN was incubated with rat liver slices, thus demonstrating that catechol formation also takes place under in vivo-like conditions. Out of ten major human cytochrome P450 (hCYP) isoforms only hCYP1A2 was able to hydroxylate ZEN to its catechols with high activity. Catechol formation represents a novel pathway in the metabolism of ZEN and may be of toxicological relevance.

Absorption and metabolism of the mycotoxins alternariol and alternariol-9-methyl ether in Caco-2 cells in vitro

Alternariol (AOH) and alternariol-9-methyl ether (AME) are major toxins produced by fungi of the genus Alternaria. In order to simulate their in vivo intestinal absorption and metabolism, AOH and AME have been studied in differentiated Caco-2 cells and in the Caco-2 Millicell® system in vitro. AOH was found to be readily conjugated to two glucuronides and one sulfate, whereas AME gave rise to one major glucuronide and one sulfate. Whereas the glucuronides of AOH and AME were sequestered about equally well into the basolateral and the apical compartment, the sulfates of both toxins were preferentially released to the apical side. Unconjugated AOH but not AME aglycone reached the basolateral chamber. The apparent permeability coefficients (Papp values) were calculated for the aglycones as well as total mycotoxin-associated compounds using an initial apical concentration of 20 µmol/l AOH or AME. Based on these Papp values, AOH must be expected to be extensively and rapidly absorbed from the intestinal lumen in vivo and reach the portal blood both as aglycone and as glucuronide and sulfate. In contrast, intestinal absorption of AME appears to be poor and sluggish, with no AME agylcone and only AME conjugates reaching the portal blood.

Metabolism of curcumin and induction of mitotic catastrophe in human cancer cells

In cultured cells, curcumin (CUR) causes cell death by interfering with mitosis and leading to fragmented nuclei and disrupted microtubules, a process named mitotic catastrophe. In order to clarify the role of the known CUR metabolites hexahydro-CUR (HHC) and CUR-glucuronide (CUR-gluc) in mitotic catastrophe, the effects of CUR were studied in three human cancer cell lines with different metabolism of CUR. In Ishikawa and HepG2 cells, CUR was metabolized to HHC and small amounts of octahydro-CUR (OHC), whereas the only metabolism in HT29 cells was the formation of CUR-gluc. Despite their different metabolism, all three cell systems responded to CUR with arrest in G2/M phase and mitotic catastrophe. Fractionation of the cells showed that concentrations of CUR were higher in the ER and cytosol than in the incubation medium by a factor of up to about 150 and 8, respectively. In contrast to CUR, the metabolite HHC and the products of spontaneous degradation did not elicit any effects in Ishikawa cells. These results imply that the causative agent of mitotic catastrophe is the parent CUR molecule, whereas reductive metabolism and chemical degradation render CUR inactive.