Evaluation of human hepatocytes cultured by three-dimensional spheroid systems for drug metabolism.

We investigated the utility of three-dimensional (3D) spheroid cultures of human hepatocytes in discovering drug metabolites. Metabolites of acetaminophen, diclofenac, lamotrigine, midazolam, propranolol and salbutamol were analyzed by liquid chromatography-tandem mass spectrometry (LC/MS/MS) to measure enzyme activities in this system cultured for 2 and 7 days. Sequential metabolic reactions by Phase I and then Phase II enzymes were found in diclofenac [CYP2C9 and UDP-glucuronyltransferases (UGTs)], midazolam (CYP3A4 and UGTs) and propranolol (CYP1A2/2D6 and UGTs). Moreover, lamotrigine and salbutamol were metabolized to lamotrigine-N-glucuronide and salbutamol 4-O-sulfate, respectively. These metabolites, which are human specific, could be observed in clinical studies, but not in conventional hepatic culture systems as in previous reports. Acetaminophen was metabolized to glucuronide and sulfate conjugates, and N-acetyl-p-benzo-quinoneimine (NAPQI) and its metabolites were not observed. In addition, mRNA of drug-metabolism enzymes [CYP1A2, CYP2C9, CYP2C19, CYP2D6, CYP2E1, CYP3A4, UGT1A1, UGT2B7, sulfotransferase 1A1 (SULT1A1) and glutathione S-transferase pi 1 (GSTP1)], which were measured by qRT-PCR, were expressed in the human hepatocyte spheroids. In conclusion, these results suggest that human hepatocyte spheroids are useful in discovering drug metabolites.

Antitumor and anti-invasive effects of diverse new macrocyclic lactones, alkylolides and alkenylolides, and their enhancement by hyperthermia.

Alkylolides and alkenylolides of 198-254 Da such as hexadecan-16-olide and 9-hexadecen-16-olide were chemically synthesized in the present study as new macrocyclic lactones that are structurally different from widespread natural macrocyclic lactones including bryostatin (887 Da) and rhizoxin (613 Da), and were investigated for antitumor activity to Ehrlich ascites tumor cells by mitochondrial dehydroganase-based WST-1 assay and dye-exclusion assay. Of the alkylolides having 12, 15 or 16 carbon-atoms (D12:0, P15:0 or H16:0) and alkenylolides having 15 or 16 carbon-atoms with a double bond (P15:1 or H16:1), H16:0 was the most carcinostatic when administered at 37 degrees C for 20 h, with cell deformation and microvillus disappearance as detected by scanning electron microscopy. The carcinostatic activity was increased markedly for H16:0 and P15:0 when the administration period was prolonged to 72 h, but was not enhanced by intramolecular introduction of a double bond for P15:1 or H16:1. Hyperthermia at 42 degrees C for 30 min additively intensified the carcinostatic activity for H16:0 and P15:0, but scarcely for D12:0, and intensified the alkenyloides P15:1 and H16:1 only upon the subsequent 72-h treatment. Invasion of human fibrosarcoma HT-1080 cells through the reconstituted basement membrane was inhibited by alkyl- and alkenylolides even after the short-term exposure at 25 microM for 3 h without diminishing the cell viability. H16:0 also exhibited the most inhibitory activity to tumor invasion in addition to the highest carcinostatic activity. Both inhibitions were promoted by combination with hyperthermia. Thus diverse alkyl-/alkenylolides, may be potent multi-applicable anticancer agents in terms of either dual inhibitory activities against both tumor progression and invasion or hyperthermia-combined therapy.

Anti-tumor and anti-invasive effects of diverse delta-alkyllactones: dependence on molecular side-chain length, action period and intracellular uptake.

New delta-alkyllactones (DALs) with diverse side-chain lengths (184-254 Da), which are structurally different from the widespread, naturally occurring delta-lactones of higher molecular weight (348-439 Da), such as camptothecin and sultriecin, were chemically synthesized and analyzed for their carcinostatic activity. Of the DALs with 11, 12, 13, 14, or 16 carbon atoms, delta-hexadecalactone (DH16:0) was the most carcinostatic when administered to Ehrlich ascites tumor (EAT) cells at 37 degrees C for 20 h, and measured by the mitochondrial dehydrogenase-based WST-1 assay. Prolongation of the administration period to 72 h enhanced the carcinostatic activity more markedly for DH16:0 than for other DALs. The carcinostatic activity of DALs was unexpectedly augmented by increasing the number of carbon atoms, in contrast to the conventional view that carcinostatic activity is attenuated by the addition of carbon atoms to fatty acids. Intracellular accumulation of DH16:0, as analyzed by gas chromatography, was detected (1.5 Pg/cell), whereas other DALs studied were rarely found. The results indicate a close relationship between carcinostatic activity and intracellular accumulation. Invasion of human fibrosarcoma HT-1080 cells through the reconstituted basement membrane was inhibited by several DALs, even at doses as low as 5-10% of those necessary for carcinostatic activity, suggesting an invasive mechanism different from carcinostasis. The invasion-inhibitory activity was intensified by increasing the number of carbon atoms, in a manner similar to that for the carcinostatic activity. The lifespan of EAT-cell-transplanted mice was markedly prolonged with DH16:0, presumably due to excellent distribution throughout the body and tumor cells. Thus DH16:0 may be a potent anticancer agent, in term of its carcinostatic, anti-invasive, and lifespan-prolonging activities.

Enhancement of carcinostatic activity of omega-hydroxy fatty acids by their esterification through increased uptake into tumor cells.

Diverse omega-hydroxy fatty acids (omegaHFAs) and their derivatives were examined for their ability to diminish the cell viability of Ehrlich ascites tumor cells by the mitochondrial dehydrogenase-based WST-1 assay and trypan blue dye exclusion assay. Of the diverse omegaHFAs, hydroxyhexadecanoic acid (omegaH16:0) was appreciably carcinostatic, and hydroxypentadecanoic acid (omegaH15:0) or hydroxypentadecenoic acid (omegaH15:1) was weakly carcinostatic at a dose of 100 micro M, whereas hydroxydodecanoic acid (omegaH12:0) and hydroxyhexadecenoic acid (omegaH16:1) acid were scarcely carcinostatic at the same dose. In contrast their sodium salt derivatives except omegaH16:0 were not carcinostatic. Enhancement of the carcinostatic activity was markedly exerted by ethylesterization of omegaHFAs with the saturated fatty moiety such as omegaH16:0 and omegaH15:0, whereas ethylesters of the unsaturated omegaHFAs such as omegaH15:1 and omegaH16:1 were weakly carcinostatic. Thus intramolecular introduction of a double bond was shown to weaken the carcinostatic activity in case of either omegaHFAs or their ethylester, being in contrast to the conventional knowledge concerning the enhancement of carcinostatic activities of non-hydroxy fatty acids appendant with more double bonds. The intracellular uptake amount of each omegaHFA as quantified by gas chromatography was the following order: omegaH16:0 ethylester (10.1 pg/cell) > omegaH15:0 ethylester (6.4 pg/cell) > omegaH16:0 (3.4 pg/cell) > omegaH15:0 (2.8 pg/cell), which accords with the order of carcinostatic activities of four saturated omegaHFAs in contrast to discord between both the orders for unsaturated omegaHFAs which could be scarcely detected as the intact form within cells. The results indicate that enhancement of carcinostatic activity of omegaH16:0 by ethylesterization was attributed to an appreciable correlation between intracellular uptake amounts and carcinostatic activities for diverse omegaHFAs with saturated fatty moiety, being not true for unsaturated omegaHFAs.