Simultaneous Evaluation of Membrane Permeability and UDP-Glucuronosyltransferase-Mediated Metabolism of Food-Derived Compounds Using Human Induced Pluripotent Stem Cell-Derived Small Intestinal Epithelial Cells.

Pharmacokinetic prediction after oral ingestion is important for quantitative risk assessment of food-derived compounds. To evaluate the utility of human intestinal absorption prediction, we compared the membrane permeability and metabolic activities of human induced pluripotent stem cell-derived small intestinal epithelial cells (hiPSC-SIECs) with Caco-2 cells or human primary enterocytes (hPECs). We found that membrane permeability in hiPSC-SIECs had better predictivity than that in Caco-2 cells against 21 drugs with known human intestinal availability (r = 0.830 and 0.401, respectively). Membrane permeability in hiPSC-SIECs was only 0.019-0.25-fold as compared with that in Caco-2 cells for 7 in 15 food-derived compounds, primarily those that were reported to undergo glucuronidation metabolism. The metabolic rates of the glucuronide conjugate were similar or higher in hiPSC-SIECs as compared with hPECs but lower in Caco-2 cells. Expression levels of UDP-glucuronosyltransferase (UGT) isoform mRNA in hiPSC-SIECs were similar or higher as compared with hPECs. Therefore, hiPSC-SIECs could be a useful tool for predicting human intestinal absorption to simultaneously evaluate membrane permeability and UGT-mediated metabolism. SIGNIFICANCE STATEMENT: Gastrointestinal absorption is an important step for predicting the internal exposure of food-derived compounds. This research revealed that human induced pluripotent stem cell-derived small intestinal cells (hiPSC-SIECs) had better predictivity of intestinal availability than Caco-2 cells; furthermore, the metabolic rates of UDP-glucuronosyltransferase (UGT) substrates of hiPSC-SIECs were closer to those of human primary enterocytes than those of Caco-2 cells. Therefore, hiPSC-SIECs could be a useful tool for predicting human intestinal absorption to simultaneously evaluate membrane permeability and UGT-mediated metabolism.

Simultaneous detection of eight species of tree nut in foods using two tetraplex polymerase chain reaction assays.

Tree nuts comprise a category of food allergens that must be included in the food labels in several countries. We developed a polymerase chain reaction (PCR) method using eight specific primer pairs to detect eight representative tree nuts (almond, Brazil nut, cashew, hazelnut, macadamia nut, pecan, pistachio, and walnut) under the same experimental conditions. The specificity of the eight primer pairs was confirmed by PCR testing against a variety of plant and animal samples. The detection limit of the method ranged from 1 fg to 1 pg DNA of individual tree nuts. The method detected tree nut DNA in processed and unprocessed food. In addition, the primer pairs could be combined into two sets of tetraplex PCR system. The developed method is specific, sensitive, and efficient, making it useful for detecting trace amounts of eight species of tree nut in foods.

Validation of a genotoxicity test based on p53R2 gene expression in human lymphoblastoid cells.

Genotoxicity assessment is important for predicting the carcinogenicity of chemical substances. p53R2 is a p53-regulated gene that is induced by various genotoxic stresses. We previously developed a p53R2-dependent luciferase reporter gene assay in the MCF-7 human breast adenocarcinoma cell line, and demonstrated its ability to detect genotoxic agents. In this paper, we investigate the applicability of the p53R2-based genotoxicity test in the human lymphoblastoid cell line TK6. TK6 cells that express wild-type p53 have been widely used for genetic toxicology studies. To evaluate the performance of the test system in TK6 cells, we referred to 61 of the chemicals on the list of 20 genotoxic and 42 non-genotoxic chemicals recommended for the evaluation of modified or new mammalian cell genotoxicity tests by the European Centre for the Validation of Alternative Methods. The overall accordance, sensitivity, and specificity of our results with the ECVAM list were 90% (55/61), 85% (17/20), and 93% (38/41), respectively. These results indicate that the p53R2-based genotoxicity test can detect various types of genotoxic chemicals without compromising its specificity. This test will be a valuable tool for rapid screen for identifying chemicals that may be genotoxic to humans.

Enolase in the RNA degradosome plays a crucial role in the rapid decay of glucose transporter mRNA in the response to phosphosugar stress in Escherichia coli.

The ptsG mRNA encoding the major glucose transporter is rapidly degraded in an RNase E-dependent manner in response to the accumulation of glucose 6-P or fructose 6-P when the glycolytic pathway is blocked at its early steps in Escherichia coli. RNase E, a major endonuclease, is associated with polynucleotide phosphorylase (PNPase), RhlB helicase and a glycolytic enzyme, enolase, which bind to its C-terminal scaffold region to form a multienzyme complex called the RNA degradosome. The role of enolase within the RNase E-based degradosome in RNA decay has been totally mysterious. In this article, we demonstrate that the removal of the scaffold region of RNase E suppresses the rapid degradation of ptsG mRNA in response to the metabolic stress without affecting the expression of ptsG mRNA under normal conditions. We also demonstrate that the depletion of enolase but not the disruption of pnp or rhlB eliminates the rapid degradation of ptsG mRNA. Taken together, we conclude that enolase within the degradosome plays a crucial role in the regulation of ptsG mRNA stability in response to a metabolic stress. This is the first instance in which a physiological role for enolase in the RNA degradosome has been demonstrated. In addition, we show that PNPase and RhlB within the degradosome cooperate to eliminate short degradation intermediates of ptsG mRNA.