Intracellular processing of apo(a) in primary baboon hepatocytes.

We have developed a serum-free medium for the long-term culture of highly differentiated primary baboon hepatocytes. Hepatocytes isolated from animals with defined plasma Lp(a) levels and apo(a) glycoprotein phenotypes were used to study the assembly of Lp(a). A combination of steady-state and pulse-chase labeling studies and endoglycosidase digests demonstrated that apo(a) was synthesized as a lower molecular weight precursor. After a prolonged period of time in the endoplasmic reticulum, apo(a) was converted to a mature form and secreted. A proportion of mature apo(a) also had a prolonged residence time in the trans Golgi apparatus. In all experiments, apoB co-immunoprecipitated with apo(a) from the culture medium but not from the cell lysates, supporting an extracellular association of the proteins for the formation of Lp(a). Analysis of hepatic RNA from 29 'null' Lp(a) phenotype baboons revealed that one-third of the animals had detectable apo(a) transcripts, whereas the remainder had no detectable apo(a) mRNA. The baboon hepatocyte system therefore represents a valuable model to examine the effect of allelic variation at the apo(a) locus on Lp(a) assembly.

Immortalization of chimpanzee hepatocytes with an amphoteric retrovirus encoding simian virus 40 T antigen.

Primary chimpanzee (Pan troglodytes) hepatocyte cultures were maintained in a serum-free medium containing hormones and growth factors and exhibited the de novo synthesis and secretion of numerous liver-specific plasma proteins for over 3 weeks in vitro. The long-term maintenance of differentiated, primate hepatocytes in this serum-free medium allowed for subsequent immortalization events to occur after infection with the amphoteric retrovirus U19, which encodes the simian virus 40 large T antigen oncogene. Several hepatocyte cell lines were selected and examined for the expression of liver-specific plasma proteins and the capacity to synthesize apolipoproteins. Several cell lines expressed a majority of the plasma proteins investigated, including apolipoproteins A1 and E. These results demonstrate the ability of this serum-free medium to maintain long-term differentiated primate hepatocytes, allowing for the experimental immortalization of this cell type in vitro and the maintenance of differentiated functions in the established cell lines. This methodology should be amenable to the study of the liver and its related diseases.

Plasma protein and apolipoprotein synthesis by human yolk sac carcinoma cells in vitro.

Three human yolk sac carcinoma cell lines were characterized for the expression of several markers. Each of the cell lines expressed alpha-fetoprotein, without detectable levels of chorionic gonadotropin, and the level of alpha-fetoprotein expression increased dramatically when the cultures were held without passage for extended periods. The secretion of a number of plasma proteins was documented by metabolic labeling, immunoprecipitation, and gel analysis. The major plasma proteins detected were alpha-1-antitrypsin, alpha-fetoprotein, transthyretin, beta-2 microglobulin, and plasminogen, with lower levels of transferrin and complement C4 released. Apolipoproteins B, E, and A1 were secreted in high levels as well and were found in the form of lipoprotein particles. Time course experiments on the synthesis of apolipoproteins E and A1 indicated that, as with alpha-fetoprotein, the level of synthesis increased substantially when the cultures were held without passage. The results indicate that these yolk sac carcinoma cells display a protein expression profile similar to that observed for the human yolk sac, and the possibility that the cells may have the potential to differentiate is discussed.

Analysis of plasma protein and lipoprotein synthesis in long-term primary cultures of baboon hepatocytes maintained in serum-free medium.

The analysis of lipoprotein synthesis and secretion in primary hepatocytes has been restricted by the short-term viability and low proliferative response of hepatocytes in vitro. During this investigation a serum-free medium formulation was developed that supports long-term maintenance (greater than 70 d) and active proliferation of primary baboon hepatocytes. Examination of proliferating cells by electron microscopy revealed a distinctive hepatocyte ultrastructure including intercellular bile canaliculi and numerous surface microvilli. High levels of secreted apolipoproteins A-I and E were detected in the tissue culture medium by gel electrophoresis and immunoblot analysis. Immunoprecipitation of proteins from [35S]-methionine labeled tissue culture medium revealed the synthesis and secretion of numerous plasma proteins. Metabolic labeling of cells with [35S]-methionine followed by single-spin density gradient flotation of the media demonstrated that apolipoproteins were being secreted in the form of lipoprotein particles with buoyant densities corresponding to the very low density lipoprotein and low density lipoprotein range, and to the high density lipoprotein range. The labeled apolipoproteins included Bh, E, and A-I. This system for primary hepatocyte culture should prove very useful in future investigations on the regulation of lipoprotein production by hepatocytes.