Thyroid hormone stimulation of plasma protein synthesis in cultured hepatocytes

Thyroid hormone receptor-dependent transcriptional regulation of fibrinogen and coagulation proteins

Thyroid hormone (T(3)) regulates growth, development, and differentiation. These activities are mediated by the nuclear thyroid hormone receptors (TRs), which belong to the steroid/TR superfamily of ligand-dependent transcription factors. The effect of T(3) treatment on target gene regulation was investigated in a TRalpha-overexpressing hepatoma cell line (HepG2-TRalpha), by performing cDNA microarrays. We demonstrate that 148 of the 7597 genes represented were up-regulated by T(3), including fibrinogen and several other components of the coagulation factor system. To confirm the microarray results, fibrinogen and a small number of the blood clotting components were further investigated using quantitative RT-PCR. The T(3)-induction ratios observed with quantitative RT-PCR for factors such as thrombin (8-fold), coagulation factor X (4.9-fold), and hepatoglobin (30-fold) were similar to those observed by the cDNA microarray analysis. Further investigation, using HepG2-TRalpha (cell lines, revealed a 2- to 3-fold induction of fibrinogen transcription after 24 h of T(3) treatment. In addition, T(3) treatment increased the level of fibrinogen protein expression 2.5- to 6-fold at 48 h. The protein synthesis inhibitor, cycloheximide, did not inhibit the induction of fibrinogen by T(3), indicating that this regulation was direct. Furthermore, transcription run-on experiments indicate that the induction of fibrinogen by T(3) is regulated largely at the level of transcription. Similar observations were made on the regulation of fibrinogen by T(3) using rats that received surgical thyroidectomy (TX) as an in vivo model. These results suggest that T(3) plays an important role in the process of blood coagulation and inflammation and may contribute to the understanding of the association between thyroid diseases and the misregulation of the inflammatory and clotting profile evident in the circulatory system of these patients.

Induction by cyproterone acetate of DNA synthesis and mitosis in primary cultures of adult rat hepatocytes in serum free medium

The aim of this study was to elucidate whether serum-free conditions could be found in primary hepatocyte cultures under which the growth inducing properties of xenobiotics and hormones could be tested. Cyproterone acetate (CPA), a steroid with anti-androgenic and progestogenic activity, was chosen as a model compound because of its known strong mitogenic properties in rat liver in vivo. EGF served as a positive control. Induction of DNA synthesis was studied by [3H]-thymidine labeling and autoradiography. Mitoses were counted in hematoxylin stained specimens. The main steps which led to an efficient stimulation of DNA synthesis by CPA were (i) reduction of hormone concentrations to levels approaching (approx. 10x) physiological concentrations better than the previously used pharmacological ones (up to 2500x); (ii) supplementation with glucocorticoid (most effective at 10-100 nM dexamethasone); (iii) selection of the interval for cumulative labeling with thymidine at 44-68 h; (iv) lowering of cell density at seeding to 50,000 cells/cm2 (subconfluency); (v) treatment with concentrations of 10-100 microM CPA. With these conditions CPA labelling was 13-20% (increase 4- to 9-fold). Mitotic incidence was 0.56% (CPA) versus 0.08% in controls. From a dose response study (0.1-100 microM) a no-effect-level for induction of DNA synthesis was found in the range of 0.1-1 microM. None of the high concentrations of CPA did cause cytotoxicity as estimated by morphological observations or release of lactate dehydrogenase into the medium. This work demonstrates that CPA under appropriate, defined culture conditions induces DNA synthesis and mitosis.(ABSTRACT TRUNCATED AT 250 WORDS)

Growth and hepatospecific gene expression of human hepatoma cells in a defined medium

The production of albumin, alpha-fetoprotein (AFP), and alpha-1 antitrypsin has been compared among human hepatoma cells cultured in medium containing serum, medium containing hormones and growth factors, and a basal medium containing selenium as the only supplement. Growth is sustained in all three media, and the expression of all three proteins was maintained for over 4 mo. in the various media. However, the quantitative production of albumin and AFP were dramatically different in the three media. Two hormones, insulin and triiodothyronine, influenced the level of secreted proteins. Triiodothyronine increases the amount of secreted albumin whereas insulin at 10 micrograms/ml reduced the level of total secreted protein.

Studies of fibronectin synthesized by cultured chick hepatocytes

We have adapted a chick embryo liver cell system for studying the synthesis of proteins secreted by hepatocytes. In primary liver cell cultures maintained for several days in arginine-deficient medium containing ornithine (0.7 mM) and carbamyl phosphate (1 mM), only hepatocytes demonstrated normal morphological and biosynthetic characteristics, indicating that they possessed a functional ornithine cycle as a source of arginine production. Non-parenchymal liver cells, such as fibroblasts, which lack the ornithine cycle were excluded. Hepatocytes in arginine-deficient or arginine-containing medium synthesized fibronectin (Fn) over several days at a constant rate of 3 micrograms +/- 1 microgram/mg cell protein per day, with fibronectin representing approximately 3% of the total secreted hepatocyte proteins during any culture period after the first 24 h. Pulse-chase experiments indicated that Fn synthesis and secretion was relatively rapid (t1/2 = 45 min) and represented approximately 95% of the intracellularly labelled Fn. This Fn is secreted predominantly as a 450 kD dimer with a subunit size that is indistinguishable from the plasma form as assessed by one-dimensional electrophoretic analysis. Continuous exposure of hepatocytes to insulin caused a moderate decrease (26%) in Fn synthesis, whereas there was no effect of short-term exposure. In contrast, dexamethasone stimulated Fn production 2-3-fold, consistent with its known ability to stimulate hepatocyte production of acute phase proteins. Under these conditions, electrophoretic analyses showed that an increased quantity of intact hepatocyte Fn was produced having the same molecular size of plasma Fn.

Thyroid hormone action on intermediary metabolism. Part III. Protein metabolism in hyper- and hypothyroidism

In their physiological concentrations, thyroid hormones stimulate the synthesis as well as the degradation of proteins, whereas in supraphysiological doses protein catabolism predominates. In hyperthyroidism skeletal muscle protein stores suffer depletion which is reflected by an increased urinary N- and methylhistidine -excretion. Due to the enhanced skeletal muscle amino acid release, the plasma concentration of glucoplastic amino acids are often enhanced, contributing by means of an elevated substrate supply to the increased hepatic gluconeogenesis. Thyroid hormone excess induces cardiac hypertrophy which is in direct contrast to the hypotroph skeletal muscle in hyperthyroid patients. Thyroid hormones stimulate a series of intracellular and secretory proteins in the liver, although in hyperthyroid liver alcohol dehydrogenase and the enzymes of histidine and tryptophan metabolism show reduced activities. The stimulatory effect is due to thyroid hormone-induced increase in the protein synthesis at a pretranslational level and is supported experimentally for malic enzyme, alpha 2u-globulin and albumin by the measurement of their specific messenger RNA activities. Thyroid hormone action at the cellular level is reflected by a generalized increase in total cellular RNA with a selective increase or decrease in a small population of specific mRNA. The activities of protein catabolizing lysosomal enzymes are stimulated by thyroid hormones; up to now effects of T3 on the degradation of specific enzymes have not been reported. Serum total protein concentration is slightly reduced or even unchanged in hyperthyroidism. The thyroid hormone-induced increase in the turnover of total body protein is part of the hypermetabolism observed in hyperthyroidism.

Effect of ethanol on hepatic secretory proteins

Both acute and chronic ethanol administration inhibit the secretion of albumin and glycoproteins from the liver. Impairment of posttranslational steps of the secretory process are mainly involved in this secretory defect, although in some instances altered synthesis of the protein moiety may be a factor. Decreased secretion following ethanol administration results in the intrahepatic retention of export proteins. The secretory defect is a consequence of the metabolism of ethanol and is likely mediated via acetaldehyde, although more conclusive proof is still required. The manner by which acetaldehyde impairs the secretory process is unknown, but may be related to its high reactivity with hepatocellular proteins. The specific posttranslational steps or processes involved in the secretory defect are still unclear; however, it appears that the final steps of secretion (post-Golgi events) may be the primary site of impairment. Impaired secretion of proteins from the liver could contribute to altered levels of plasma proteins and hepatomegaly as well as to the liver injury observed in the alcoholic.

Hormonal regulation of fibrinogen synthesis in cultured hepatocytes

Most of what was originally known of the effects of hormones on fibrinogen synthesis was based, as noted above, on experiments involving surgical removal of endocrine glands. Some caution should be exercised when using such in vivo experiments to derive the hormonal requirements of fibrinogen synthesis, however, since multiple hormonal alterations often occur in these animals. The development of a variety of ex vivo systems has allowed investigators to more carefully control the hepatocellular environment. The work of several laboratories, including our own, has now made it clear that hormones and other agents directly stimulate hepatocellular synthesis of fibrinogen. From the studies summarized here, using chick embryo hepatocytes as a model, several generalizations emerge: Fibrinogen synthesis may be considered to be a "constitutive" liver function, since hepatocytes cultured without serum, hormones or other macromolecular supplements synthesize this protein at a basal rate for several days. Addition of certain hormones (e.g. T3, dexamethasone, insulin), individually and in physiological concentrations, elicits an increase in fibrinogen production, varying with each agent in onset, dose, minimum exposure required and accompanying effects on the synthesis of other plasma proteins. Glucocorticoids and thyroid hormones are similar in the selectivity of their stimulation (neither affects albumin or transferrin synthesis) but differ in that thyroid hormones need to be present for just a short "triggering" period. The stimulation of fibrinogen synthesis by insulin occurs only following prolonged exposure to concentrations 10-times higher than the very low doses to which albumin synthesis responds rapidly.

Structural analysis of fibrinogen synthesized by cultured chicken hepatocytes in the presence or absence of dexamethasone

Hepatocyte monolayers, derived from chick embryos and cultured in chemically defined medium without hormones, synthesize and secrete fibrinogen that resembles chicken plasma fibrinogen immunochemically and structurally. Addition of a synthetic glucocorticoid, dexamethasone, to the cultured cells resulted in an appreciable and relatively selective increase in fibrinogen synthesis. Autoradiography of fibrinogen that had been metabolically labelled with [35S]methionine and then subjected to SDS-polyacrylamide gel electrophoresis, unreduced or under disulfide-reducing conditions, revealed that only dimeric forms of fibrinogen, containing undegraded A alpha, B beta, and gamma chains, were secreted under stimulated and unstimulated culture conditions.

Serum stimulation of plasma protein synthesis in culture is selective and rapidly reversible

Primary hepatocyte monolayers, derived from chick embryos, can be cultured from the onset in a completely chemically defined medium, free of added hormones. The liver cells synthesize and secrete a wide spectrum of plasma proteins for several days in this serum-free environment. Addition of fetal bovine serum elicits a 3-5-fold increase in the production of certain plasma proteins: fibrinogen, albumin, and the alpha1-globulin M. This effect of serum is selective; transferrin and plasminogen syntheses are enhanced less than 1.5-fold. Significant stimulation is observed with 0.1% fetal bovine serum, and half-maximal values for individual plasma proteins are obtained with concentrations ranging between 0.4 and 1%. The stimulatory activity of serum shows no developmental or species specificity. Plasma is active as serum derived from the same blood sample. The hepatocytes respond rapidly to serum, significant changes in albumin synthesis occurring less than 1 h after serum addition or removal. The effect of short exposure is fully reversible. These results establish the capacity of low concentrations of serum to stimulate plasma protein synthesis and underscore the importance of studying the effects of hormones and other factors under serum-free conditions. The findings suggest that, in addition to the classical hormones, ubiquitous but as yet uncharacterized serum components play a role in controlling this major hepatic function.