Attachment of rat hepatocytes to plastic substrata in the absence of serum requires protein synthesis.

Female rats were pair-fed nutritionally adequate liquid diets containing either ethanol (36 % of total cal.) or isocaloric carbohydrates (controls) for 4 weeks. Compared to controls, chronic alcohol consumption led to slightly increased activities of various hepatic enzymes in the serum. Paracetamol administered 18 hours after ethanol withdrawal resulted within 18 hours in a significant increase of serum GOT and GPT activities, which was much more pronounced in rats fed ethanol chronically than in their pair-fed controls. Thus, chronic alcohol consumption predisposes to increased hepatotoxicity due to paracetamol.     

Adhesion of rat hepatocytes to collagen

Rat hepatocytes, freshly isolated with a collagenase perfusion technique, were found to attach within 1 h on collagen substrates and on culture dishes coated with cold insoluble globulin (CIG) or asialoceruloplasmin (AC). Spreading was observed on collagen and CIG but not on AC. Both attachment and spreading occurred in a simple balanced salt solution in the absence of serum. In the absence of serum no attachment was observed on plain plastic dishes or on dishes coated with serum albumin or other plasma proteins, unless divalent manganese ions were present. In the presence of manganese the hepatocytes attached to all surfaces tested, but no spreading occurred. Attachment to collagen occurred equally well to collagens type I or type III both in the native, fibrillar state and in the denatured state. Collagen attachment required magnesium ions but did not appear to involve the collagen-linked carbohydrates. Different mechanisms were found to operate in hepatocyte attachment to collagen and to AC; the latter is most likely mediated by the hepatocyte surface receptor involved in recognition and uptake of asialoglycoproteins. The role of CIG in hepatocyte attachment to collagen was investigated. Data are presented suggesting that this glycoprotein, which mediates the adhesion of fibroblasts to collagen, is not required for hepatocyte attachment to collagen.     

Influence of collagen gel substrata on certain biochemical activities of hepatocytes in primary culture

In order to study the influence of cell shape as modulated by the extracellular matrix on the cellular activity, hepatocytes isolated from liver were maintained on collagen I coated plastic substrata and collage I gel substrata and certain hepatocyte specific functions were investigated. The incorporation of³[H]-leucine into total proteins and albumin secreted by cells maintained on collagen gel was found to be significantly higher compared to those maintained on a collagen coated plastic substrata, indicating that hepatocytes on collagen gel have an enhanced albumin synthesizing capacity. Increased incorporation of³⁵[S]-sulphate into total proteoglycans (PG) and a relatively higher fraction of the³⁵[S]-PG in the extracellular space showed an increased rate of synthesis and secretion of sulphated PGs by cells maintained on collagen gels. But in contrast to the above results, the incorporation of³[H]-leucine into cytokeratins C₈, C₁₈ and actin were significantly low in cells maintained on collagen gel. The tyrosine amino transferase activity exhibited by hepatocytes preincubated with dexamethasone on collagen gel was also significantly low. The different forms of collagen substrata appeared to have no effect on the amino acid transport by hepatocytes, further suggesting that the various hepatocyte specific functions are not uniformly altered when hepatocytes are maintained on three-dimensional collagen gel substrata. These results indicate that the shape of the cell as determined by the nature of the matrix substratum influences the synthetic activity of secretory proteins and those remaining intracellularly, differently.     

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.     

Differential rates of glycoprotein secretion by isolated rat hepatocytes studied in terms of concanavalin A binding.

Using a concanavalin-A-based method which respects cell function, we have shown that the kinetics of glycoprotein secretion appear to depend on the nature of the oligosaccharide moiety. In 37 degrees C pulse/chase experiments using freshly isolated normal rat hepatocytes, we found that except for transferrin, whose rate of secretion was independent of its concanavalin A reactivity, the secretion of the concanavalin-A-retained forms of alpha 1 acid glycoprotein, T-kininogen, alpha 1 protease inhibitor and alpha 1 inhibitor III was slower than that of the concanavalin-A-non-retained forms. When hepatocytes were incubated at 20 degrees C, secretion was blocked with the accumulation of mainly endoglycosidase-H-sensitive forms. The secretion kinetics of the concanavalin-A-differentiated forms were still different when the temperature was shifted back to 37 degrees C. The divergence between the secretion rates of the concanavalin-A-differentiated forms would appear to be due to a late event in intracellular protein trafficking, which may depend on the sugar content and/or the number of carbohydrate chains of the glycoproteins.     

Synthesis and secretion of serum phosphorylcholine-binding protein by rat hepatocytes

The incorporation of [1-14C]glucosamine into rat serum phosphorylcholine-binding protein in an isolated rat hepatocyte system was used to demonstrate the synthesis and secretion of this protein by the liver. The hepatocytes after incubating with colchicine resulted in an increased intracellular accumulation of phosphorylcholine-binding protein and less of the synthesized phosphorylcholine-binding protein was secreted into the medium. The synthesis of phosphorylcholine-binding protein was found to be significantly impaired when the hepatocytes were incubated with tunicamycin. The radiolabelled phosphorylcholine-binding protein co-eluted with exogenous phosphorylcholine-binding protein as a homogeneous peak by affinity chromatography. The identity of the radiolabelled phosphorylcholine-binding protein was further established by quantitative immunoprecipitation, polyacrylamide gel electrophoresis and isoelectric focusing.     

Long-term in vitro function of adult hepatocytes in a collagen sandwich configuration.

In an effort to reconstruct the cellular polarity normally found in the liver, adult rat hepatocytes were sandwiched between two layers of hydrated rat tail tendon collagen matrix. Functionally, sandwiched hepatocytes maintained the secretion of albumin, transferrin, fibrinogen, bile acids, and urea for at least 6 weeks, whereas cells cultured on a single layer of collagen gel ceased such secretion in 1-2 weeks. After 1 week of culture on a single layer of collagen gel, hepatocytes could still recover these lost functions when a second layer of collagen gel was applied. The exact nature of the substrate for constructing the sandwich system appeared to be unimportant as long as it allowed cellular attachment. Hepatocytes cultured in the sandwich system appeared to maintain a distribution of actin filaments similar to the in vivo state, whereas cells cultured on a single layer of collagen gel showed abnormal formation of stress fibers. These studies suggest that simple manipulations of the configuration of extracellular elements can dramatically alter the behavior of cultured hepatocytes.     

Substrate adhesion of rat hepatocytes: Mechanism of attachment to collagen substrates

Attachment of rat hepatocytes to collagen, which occurs without the aid of fibronectin, was found to be a time-dependent reaction characterized by an initial lag phase of 10–20 min before stable attachment bonds began to form. Increasing the density of molecules in the collagen substrates enhanced the rate of cell attachment. The hepatocytes attached essentially equally well to all the collagen types tested (types I, II, III, IV and V). The initial rate of cell attachment was more rapid to native collagen than to denatured collagen or α1(I) chains, apparently indicating different affinities of the cells for these substrates. However, if cells were incubated for 60 min or more, efficient attachment occurred to the α1(I) chain and to all cyanogen-bromide-treated peptides tested (α1-CB2, α1-CB3, α1-CB4, α1-CB5, α1-CB6A, α1-CB7, α1-CB8, α2-CB2, α2-CB3 and α2-CB4) but not to the aminopropeptide of type I procollagen. A low but significant degree of attachment also took place to substrates made of synthetic peptides with the collagen-like structures (Gly-Ala-Pro)_n, (Gly-Pro-Pro)_n and (Gly-Pro-Hyp)_n, whereas no attachment was observed to polyproline. We suggest that the cell-binding sites in collagen have a simple structure and occur in multiple copies along the collagen molecule. Addition of collagen in solution inhibited intial cell attachment, an effect that persisted longer on substrates made of α1(I) chain than on denatured collagen. The collected data are interpreted in terms of a model for cell-to-collagen adhesion where the formation of stable attachment bonds requires the binding of several low-affinity receptors, clustered at the site of adhesion, to collagen molecules in the substrate.     

Effects of vanadate on protein kinases in rat hepatocytes.

In rat hepatocytes, vanadate modifies neither the intracellular concentration of cyclic AMP nor the --cyclic AMP/+cyclic AMP activity ratio for cyclic AMP-dependent protein kinase. Vanadate can, however, counteract the increase in cyclic AMP and the increase in the --cyclic AMP/+cyclic AMP activity ratio of cyclic AMP-dependent protein kinase induced by glucagon. On the other hand, vanadate treatment of hepatocytes can produce a time- and concentration-dependent increase in cyclic AMP- and Ca2+-independent casein kinase activity. Maximal activation at the optimal time with 5 mM-vanadate was about 70% over control. A clear relationship was observed between the activation of casein kinase and the inactivation of glycogen synthase after vanadate treatment. These results suggest that casein kinase activity may be involved in vanadate actions in rat hepatocytes.     

Type I collagen structure regulates cell morphology and EGF signaling in primary rat hepatocytes through cAMP-dependent protein kinase A

Adhesion to type 1 collagen elicits different responses dependent on whether the collagen is in fibrillar (gel) or monomeric form (film). Hepatocytes adherent to collagen film spread and proliferate, whereas those adherent to collagen gel remain rounded and growth arrested. To explore the role of potential intracellular inhibitory signals responsible for collagen gel-mediated growth arrest, cAMP-dependent protein kinase A (PKA) was examined in hepatocytes adherent to collagen film or gel. PKA activity was higher in hepatocytes on collagen gel than on film during G1 of the hepatocyte cell cycle. Inhibition of PKA using H89 increased cell spreading on collagen gel in an EGF-dependent manner, whereas activation of PKA using 8-Br-cAMP decreased cell spreading on collagen film. PKA inhibition also restored ERK activation, cyclin D1 expression and G1-S progression on collagen gel, but had no effect on cells adherent to collagen film. Analysis of EGF receptor phosphorylation revealed that adhesion to collagen gel alters tyrosine phosphorylation of the EGF receptor, leading to reduced phosphorylation of tyrosine residue 845, which was increased by inhibition of PKA. These results demonstrate that fibrillar type 1 collagen can actively disrupt cell cycle progression by inhibiting specific signals from the EGF receptor through a PKA-dependent pathway.     

Primary culture of rat hepatocytes entrapped in cylindrical collagen gels: An in vitro system with application to the bioartificial liver

A static culture model employing cylindrical collagen-hepatocyte gels is reported for large scale testing of conditions relevant to the three compartment hollow fiber bioartificial liver. High density hepatocyte cultivation was achieved by cell entrapment within the collagen-hepatocyte gel. Hepatocyte viability was assessed by vital staining, gel contraction, and insulin utilization. Measures of hepatocyte-specific function included albumin synthesis, ureagenesis, lidocaine biotransformation, and cholate conjugation. Although hepatocyte viability remained stable through the seven day incubation period, hepatocyte functions were not uniformly preserved. Albumin synthesis remained stable, while representative P-450 and conjugation activities decreased with time. This static culture system will facilitate the development of a hollow fiber bioartificial liver which utilizes cylindrical collagen-hepatocyte gels.Abbreviations FDA fluorescein diacetate - EB ethidium bromide - MEGX monoethylglycinexylidide     

Processing of concanavalin A-receptor complexes by rat osteoclasts in vitro

The osteoclast is a large multinucleate cell that is widely accepted as the primary effector cell responsible for normal bone resorption. In a previous study, we demonstrated that concanavalin A (con A) has a dose-dependent biphasic effect on the bone-resorbing capacity of osteoclasts, using a 45Ca bone-organ culture system; bone resorption was stimulated at low concentrations and inhibited at high concentrations. The mitogenic property of con A in lymphocyte cultures is well documented; therefore con A has been used extensively to study the manner in which lymphocytes and other mononuclear cells process the cell-bound lectin. In this study, we have investigated the processing of con A-receptor complexes by osteoclasts in culture, using con A-FITC to evaluate the redistribution of cell-bound con A via epifluorescence microscopy and using con A-ferritin to determine whether the lectin receptor complexes are internalized. The osteoclasts were obtained from the long bones of newborn rats and allowed to attach to glass coverslips at 37 degrees C. Following attachment, the nonadherent cells were removed by rinsing. The adherent osteoclasts were preincubated in 50 micrograms/ml con A-FITC or con A-ferritin at 4 degrees C for 10 min, washed to remove unbound con A, and incubated at 37 degrees C for 15 or 30 min in the absence of con A. Positive controls were fixed immediately after preincubation at 4 degrees C; negative controls were preincubated in con A-FITC and alpha-methyl mannoside, the haptenic inhibitor of con A binding. The results demonstrate that redistribution and endocytosis of con A-receptor complexes occurs within 30 min. These findings confirm the hypothesis that cell-bound con A can alter the structure and activity of osteoclast membrane components in a manner similar to that observed in mononuclear cell cultures. The internalization of con A may be important in altering osteoclastic activity by mediating intracellular mechanisms involved in the bone-resorbing process.     

A 50 kDa, actin-binding protein in plasma membranes of rat hepatocytes and of rat liver tumors

Plasma membranes from normal rat livers and rat liver tumors were compared by SDS-gel electrophoresis, and analyzed for actin-binding proteins by an 125I-labelled actin gel-overlay assay and by actin-affinity blotting. After treatment of rats with alpha-hexachlorocyclohexane and after induction of liver tumors by combined treatment with N-nitrosomorpholine and phenobarbital, liver plasma membranes prepared from these animals were found to be highly enriched in an actin-binding, 50 kDa polypeptide. This polypeptide seemed to be an integral protein of the plasma membrane as judged by Triton X-114-phase separation. Microsomes did not contain an actin-binding polypeptide in the 50 kDa region. Therefore, the 50 kDa protein is a candidate for interaction of actin with the liver cell plasma membrane. A possible relationship of this protein with the multi-specific, cholate transporting system of the rat liver plasma membrane is discussed.     

Morphological changes of rat small intestine after short-time exposure to concanavalin A or wheat germ agglutinin

Dietary lectins of gluten origin have been suggested to play an important role in the mechanisms leading to the characteristic morphology of the intestine found in patients with celiac disease. To further explore this issue we have used Wheat Germ Agglutinin (WGA) or Concanavalin A (Con A) to challenge rat small intestine and study the ultrastructural changes of such a treatment. Both lectins affected the enterocytes at the base of the villi more than those at the top. The morphological findings included disarrangement of the cytoskeleton, increased endocytosis and shortening of the microvilli. The interrelationship between the observed changes, and their relevance for similar morphological alterations found in patients with celiac disease are discussed. In conclusion, the morphological findings in our rat model resemble early changes in patients with celiac disease, thus supporting the idea that lectins or lectin-like substances are involved in the pathogenesis of this disease.