Rat hepatocyte spheroids formed by rocked technique maintain differentiated hepatocyte gene expression and function.

UNLABELLED: The culture of primary hepatocytes as spheroids creates an efficient three-dimensional tissue construct for hepatic studies in vitro. Spheroids possess structural polarity and functional bile canaliculi with normal differentiated function. Thus, hepatocyte spheroids have been proposed as the cell source in a variety of diagnostic, discovery, and therapeutic applications, such as a bioartificial liver. Using a novel rocking technique to induce spheroid formation, kinetics of spheroid formation, cell-cell adhesion, gene expression, and biochemical activities of rat hepatocyte spheroids were tested over 14 days of culture. Evidence was provided that the formation of spheroids occurred faster and with fewer nonadherent hepatocytes in rocked suspension culture compared to a traditional rotational system. Hepatocyte spheroids in rocked culture showed stable expression of more than 80% of 242 liver-related genes including those of albumin synthesis, urea cycle, phase I and II metabolic enzymes, and clotting factors. Biochemical activity of rocked spheroid hepatocytes was superior to monolayer culture of hepatocytes on tissue culture plastic and collagen. CONCLUSION: Spheroid formation by rocker technique was more rapid and more efficient than by rotational technique. Rocker-formed spheroids appear suitable for application in a bioartificial liver or as an in vitro liver tissue construct.

Gene expression and functional analyses of primary rat hepatocytes on nanofiber matrices.

Long term culture of primary hepatocytes is valuable for diagnostic and therapeutic applications. However, standard monolayer culture of primary hepatocytes on tissue culture plastic (TCP) - either uncoated or coated with a biological material such as collagen or laminin - is problematic. Thus, novel support matrices are under development to better maintain gene expression and differentiated function of primary hepatocytes in vitro. In this study, a fabricated nanofiber matrix was compared to control conditions of uncoated and laminin-coated TCP. Gene expression and biochemical analyses were performed to compare functional abilities of the hepatocytes in the different conditions. Hepatocytes cultured on nanofibers maintained higher cytochrome P450 1A activity (0.49 +/- 0.08 ng resorufin/ml/min) compared to hepatocytes on laminin (0.11 +/- 0.05 ng resorufin/ml/min). In addition, albumin production of hepatocytes on nanofibers was greater than twice the production of hepatocytes on laminin (day 14, 34.4 +/- 1.8 vs. 15.9 +/- 4.5 microg albumin/ml/day). Hepatocytes demonstrated the ability to generate urea from ammonia in all conditions; however, hepatocytes performed ureagenesis more effectively on nanofibers than on laminin (0.55 +/- 0.25 microM vs. 0.36 +/- 0.24 microM urea, day 14). Gene expression of hepatocytes cultured on nanofiber and laminin conditions were similar on a per cell basis determined by analysis using a custom microarray of 250 genes expressed in hepatocytes. Similar cell attachment data between conditions and similar numbers of cells expressing the hepatocyte marker hepatocyte nuclear factor 4alphaindicates that hepatocytes grown on nanofibers only marginally display improved hepatic functions compared to laminin control conditions.

E-cadherin protects primary hepatocyte spheroids from cell death by a caspase-independent mechanism.

Cultivation of primary hepatocytes as spheroids creates an efficient three-dimensional model system for hepatic studies in vitro and as a cell source for a spheroid reservoir bioartificial liver. The mechanism of spheroid formation is poorly understood, as is an explanation for why normal, anchorage-dependent hepatocytes remain viable and do not undergo detachment-induced apoptosis, known as anoikis, when placed in suspension spheroid culture. The purpose of this study was to investigate the role of E-cadherin, a calcium-dependent cell adhesion molecule, in the formation and maintenance of hepatocyte spheroids. Hepatocyte spheroids were formed by a novel rocker technique and cultured in suspension for up to 24 h. The dependence of spheroid formation on E-cadherin and calcium was established using an E-cadherin blocking antibody and a calcium chelator. We found that inhibiting E-cadherin prevented cell-cell attachment and spheroid formation, and, surprisingly, E-cadherin inhibition led to hepatocyte death through a caspase-independent mechanism. In conclusion, E-cadherin is required for hepatocyte spheroid formation and may be responsible for protecting hepatocytes from a novel form of caspase-independent cell death.