Attachment and long term survival of adult rat hepatocytes in primary monolayer cultures: Comparison of different substrata and tissue culture media formulations

Summary Long-term monolayer cultures of adult rat hepatocytes were tested for their ability to glucuronize phenol red and to maintain initial levels of cell proteins, glucose consumption, and lactic acid production. Lactate dehydrogenase leakage served as an index of culture status because a high value indicates cell death. Three tissue culture (TC) media formulations were the main variables introduced to determine ideal conditions for cell survival in vitro. Investigations of long-term cultures were preceded by studies of hepatocyte attachment to polystyrene surfaces. This attachment was influenced by the amount of substrate deposited and the number of cells seeded, but not by the uniformity of the substrate coating. A statistical analysis of our data revealed that in the absence of fetal bovine serum (FBS), air dried collagen (ADC) and Biomatrix (BMX) were superior to saline precipitated collagen and fibronectin as attachment substrates. In the presence of 10% FBS, all of the substrates performed equally. Chee's Medium (CEM) proved to be the best for preserving cell proteins over a time course of 28 d and Williams' E medium also performed adequately up to 14 d. The glucuronization of phenol red was at 50% of initial values at Day 7 in CEM-ADC hepatocytes in contrast to 30% for cells in Williams' E medium and 5% for cells grown in Waymouth's. At 14 d glucuronization was still present at 40% of original values in CEM-ADC cells but had ceased in the other two media. When BMX was used, none of the TC media supported glucuronization levels comparable to ADC cells. This research was supported in part by grant 1R01-AM-26520 from the National Institute of Arthritis, Diabetes and Digestive Kidney Diseases, NIH, Bethesda, Maryland.     

Metabolism Comparative Cytotoxicity Assay (MCCA) and Cytotoxic Metabolic Pathway Identification Assay (CMPIA) with cryopreserved human hepatocytes for the evaluation of metabolism-based cytotoxicity in vitro: proof-of-concept study with aflatoxin B1

Recently, we have improved the cryopreservation procedures for human hepatocytes, leading to cells that can be cultured after thawing (“plateable” cryopreserved human hepatocytes). The ability to culture cryopreserved human hepatocytes allows application of the cells for prolonged incubations such as long-term (days) metabolism studies, enzyme induction studies, and cytotoxicity studies. We report here the application of the plateable cryopreserved human hepatocytes to evaluate the relationship between xenobiotic metabolism and toxicity. Two assays were developed: The Metabolism Comparative Cytotoxicity Assay (MCCA) and the Cytotoxic Metabolic Pathway Identification Assay (CMPIA). The MCCA was designed for the initial identification of the role of metabolism in cytotoxicity by comparing the cytotoxic potential of a toxicant in a metabolically competent (primary human hepatocytes) and a metabolically incompetent (Chinese hamster ovary (CHO)) cell type, as well as the evaluation of the role of P450 metabolism by comparing the cytotoxicity of the toxicant in question in human hepatocytes in the presence and absence of a nonspecific, irreversible P450 inhibitor, 1-aminobenzotriazole (ABT). The CMPIA was designed for the identification of the P450 isoforms involved in metabolic activation via the evaluation of the cytotoxicity of the toxicant in the presence and absence of isoform-selective P450 inhibitors. Results of a proof-of-concept study with the MCCA and CMPIA with a known hepatotoxicant, aflatoxin B1 (AFB1), are reported. AFB1 is known to require P450 metabolism for its toxicity. In the MCCA, AFB1 was found to have significantly higher cytotoxicity in human hepatocytes than CHO cells, therefore confirming its requirement for biotransformation to be toxic. ABT was found to effectively attenuate AFB1 cytotoxicity, confirming that P450 metabolism was involved in its metabolic activation. In the CMPIA, AFB1 cytotoxicity was found to be attenuated by ketoconazole and diethyldithiocarbamate, but not by furafylline, quinidine, and sulfaphenazole. Results with the isoform-selective inhibitors suggest that the isoforms inhibited by ketoconazole (mainly CYP3A4) and diethyldithiocarbamate (mainly CYP2A6, and CYP2E1), but not the isoforms inhibited by furafylline (mainly CYP1A2), sulfaphenazole (mainly CYP2C9) and quinidine (mainly CYP2D6) are involved in the metabolic activation of AFB1. This proof-of-concept study suggests that MCCA and CMPIA with cryopreserved human hepatocytes are potentially useful for the evaluation of the relationship between human xenobiotic metabolism and toxicity.     

Hepatocytes--the choice to investigate drug metabolism and toxicity in man: in vitro variability as a reflection of in vivo

The pharmaceutical industry is committed to marketing safer drugs with fewer side effects, predictable pharmacokinetic properties and quantifiable drug-drug interactions. Drug metabolism is a major determinant of drug clearance and interindividual pharmacokinetic differences, and an indirect determinant of the clinical efficacy and toxicity of drugs. Progressive advances in the knowledge of metabolic routes and enzymes responsible for drug biotransformation have contributed to understanding the great metabolic variations existing in human beings. Phenotypic as well genotypic differences in the expression of the enzymes involved in drug metabolism are the main causes of this variability. However, only a minor part of phenotypic variability in man is attributable to gene polymorphisms, thus making the definition of a normal liver complex. At present, the use of human in vitro hepatic models at early preclinical stages means that the process of selecting drug candidates is becoming much more rational. Cultured human hepatocytes are considered to be the closest model to human liver. However, the fact that hepatocytes are located in a microenvironment that differs from that of the cell in the liver raises the question: to what extent does drug metabolism variability observed in vitro actually reflect that of the liver in vivo? By comparing the metabolism of a model compound both in vitro and in vivo in the same individual, a good correlation between the in vitro and in vivo relative abundance of oxidized metabolites and the hydrolysis of the compound was observed. Thus, it is reasonable to consider that the variability observed in human hepatocytes reflects the existing phenotypic heterogeneity of the P450 expression in human liver.     

Immunohistochemical analysis of the adaptation of adult guinea-pig cardiomyocytes in long-term cultures and in cocultures with cardiac neurons: A novel model for studies of myocardial function

In this study, we used laser confocal scanning microscopy and immunofluorescent markers to describe the establishment of long-term cultures of adult guinea-pig cardiomyocytes and their cocultures with adult intrinsic cardiac neurons. We have also investigated the effect of plating density on the adaptation of the myocytes in culture. Providing that the preparation of freshly isolated cardiomyocytes consists mostly (> 80%) of rod-shaped, Ca-tolerant, and quiescent cells and these are plated under optimal conditions and density (105/cm2), these myocytes have the following characteristics: (1) they remain elongated with regular ultrastructural characteristics and quiescent for several days; (2) within 10-14 days, they reestablish their intercellular contacts and resume contractile activity, which becomes synchronous all through the confluent layers; (3) they retain their regular myofibrilar striation all through the adaptation to culture conditions without any sign of dedifferentiation or redifferentiation; (4) these characteristics are lost when the cells are plated at too low (< 104/cm2) or too high (2 × 105/cm2) a density and they exhibit signs of dedifferentiation; (5) the adult ventricular myocytes appear to retain their ability to express atrial natriuretic peptide (ANP), as indicated by immunoreactivity to anti-ANP antibody; (6) this activity seems to be directly related to the surface area of the myocytes in contact with the substrate (i.e. to the stretch of the myocytes); (7) the intrinsic cardiac neurons grow intricate networks of neurites, which form a free-ending type of contact with the cocultured myocytes.abstract typed in here; if it is more than one paragraph use Long-term cultures of adult guinea-pig ventricular myocytes, alone or in their cocultures with cardiac neurons in which both are fully active functionally, provide a valuable experimental model which opens new possibilities for studying the cellular and molecular regulation of myocardial function under acute or chronic effects of various intrinsic and/or extrinsic factors, including neuroregulation.