Tyrosine aminotransferase and gamma-glutamyl transferase activity in human fetal hepatocyte primary cultures under proliferative conditions

The ontogeny of gamma-glutamyl transferase (GGTase; E.C.2.3.2.2) and tyrosine aminotransferase (TAT; E.C.2.6.1.5) activities in 14 to 36 weeks gestational and neonatal hepatocytes during development of human fetal liver was studied. Subsequently, 20-24 weeks gestational hepatocytes were cultured in media supplemented with epidermal growth factor (EGF) and insulin with or without glucagon and dexamethasone to investigate the proliferation and differentiation of fetal hepatocyte in vitro using GGTase and TAT as biochemical markers. During the development of the liver, the activity of GGTase increased continuously from the first trimester through the third trimester and decreased (p < 0.001) in neonates. A low basal level of TAT activity was seen only during the third trimester, which then increased significantly (p < 0.001) in neonates. Fetal hepatocytes, in the presence of EGF and insulin, undergo proliferation from the fourth to 10th day with an increase in cell number (p < 0.001) and concomitant increase (p < 0.001) in GGTase activity. As the cells attain confluence, enzyme activity decreased significantly (p < 0.001) from the 10th to 16th day. Maximal TAT activity (p < 0.001) was observed at 48 h of culture, which decreased, but not significantly, during cell proliferation and the enzyme activity was regained as the cultures attained confluence. Furthermore, TAT activity was induced synergistically (p<0.001) in the presence of glucagon and dexamethasone, while GGTase was inhibited (p<0.001). These results indicate that GGTase increases with proliferation, whereas TAT, once it has been expressed, is not suppressed during cell proliferation. In conclusion, human fetal hepatocytes undergo enzymic differentiation by 48 h of culture, and proliferate with an increase in GGTase in the presence of growth factors with maintenance of differentiated status up to the studied 16 days of culture.     

Chimeric molecule IL-6/soluble IL-6 receptor is a potent mitogen for fetal hepatocytes

A novel recombinant molecule, termed IL-6c and consisting of a chimera of interleukin 6 (IL-6) and its soluble receptor is extremely potent in stimulating proliferation of hematopoietic progenitors. We investigated the effect of the IL-6c on the proliferation and differentiation of E14 fetal hepatocytes. IL-6c, in a dose-dependent manner, stimulated proliferation of E14 fetal rat hepatocytes. Adult hepatocyte mitogens together with IL-6c showed no further effect on proliferation. Hematopoietic stem cells mitogens SCF and flt3 ligand (FL) were also mitogenic for fetal hepatocytes, but did not further enhance the effect of IL-6c on cell proliferation. IL-6c decreased expression of fetal markers alpha-fetoprotein (AFP) and gamma-glutamyltranspeptidase, and induced expression of adult enzyme glucose-6-phosphatase (Gluc-6-P) in E14 hepatocytes. On the other hand, IL-6c strongly reduced, in a dose-dependant manner, expression of albumin and tyrosine aminotransferase (TAT). However, when the cells were grown for 3 days with IL-6c, and IL-6c was removed for the next 5 days, expression of albumin and TAT returned to levels found in control cultures. In conclusion, IL-6c stimulated proliferation and affected gene expression in fetal hepatocytes in culture.     

2-D gel membrane protein patterns during fetal rat hepatocyte development

Fetal hepatocytes from rats of 13-20 days of gestation were 125I/surface-labelled. Autoradiographs of the plasma membrane proteins, analyzed by 2-D gel electrophoresis, were compared with those from adult hepatocytes and two hepatoma lines. The autoradiographic patterns of membrane proteins from 13 and 15 day fetal hepatocytes were similar. Between days 13 and 20 of gestation, at least 24 new iodinatable proteins appeared in the plasma membrane of fetal hepatocytes. Whilst between day 20 of gestation and adult life, at least 21 new membrane proteins appeared. Two membrane proteins, one acidic (MW 25,000) and a more basic protein (MW 45,000) were present in fetal hepatocytes but absent from adult hepatocytes. The membrane protein patterns from two hepatoma lines were less complex than those of adult hepatocytes.     

Patterns of soluble cellular proteins during fetal rat hepatocyte development

Soluble cellular proteins from fetal rat hepatocytes, at 13-20 days of gestation were analyzed by 2-D gel electrophoresis and compared with protein patterns from adult hepatocytes and two hepatoma lines. The patterns of 13, 15 and 17 day fetal hepatocyte proteins were very similar. A number of proteins which were prominent in early fetal hepatocytes, were absent from the adult hepatocyte. Several proteins, which were also present in the adult pattern, appeared by day 17 of gestation. By day 20 of gestation, numerous proteins appeared and increased levels of a number of other proteins were observed. The adult hepatocyte protein pattern differed markedly from those of fetal hepatocytes. Many proteins present at low levels in fetal hepatocytes were increased in the adult, and at least thirty six new proteins appeared. The protein patterns of two hepatoma lines more closely resembled the early fetal rather than the adult hepatocyte pattern.     

Endocrine Regulation of Fetal Adipose Tissue Metabolism in the Pig: Role of Hydrocortisone

Glucocorticoids have been shown to be essential for the excessive fat deposition and development of obesity in several animal models. This study was performed to characterize the role of glucocorticoids in the developmental regulation of adipose tissue metabolism. On day 70 of gestation, pig fetuses were hypophysectomized by micro-cauterization. Hypophysectomized fetuses were implanted subcutaneously with hydrocortisone pellets or received no hormone replacement. Fetuses were removed by laparotomy on day 90 of gestation. Additional fetuses were hypophysectomized on day 70, implanted with hydrocortisone pellets on day 90 and removed on day 105 of gestation. Several intact fetuses were also implanted subcutaneously with hydrocortisone pellets during this later gestational period. Serum cortisol concentrations were reduced in hypophysectomized pigs at both fetal ages and were restored to intact levels by hydrocortisone treatment. Hydrocortisone supplementation enhanced lipolytic response to isoproterenol in intact fetuses but failed to restore lipolytic response to isoproterenol in hypophysectomized animals at either fetal age. Hydrocortisone induced a slight increase in lipogenesis in hypophysectomized fetuses when administered from 70 to 90 days of gestation and a more dramatic increase when administered from days 90 to 105 of gestation. However, hydrocortisone had no effect on basal or insulin stimulated lipogenesis in intact fetuses when administered from days 90 to 105 of gestation. These results indicate that hydrocortisone may have a primary influence on adipose tissue metabolism during late fetal development only in the absence of inhibition from counterregulatory hormones of pituitary origin.     

Cadmium exposure on day 12 of gestation in the Wistar rat: distribution, uteroplacental blood flow, and fetal viability

The effects of cadmium exposure (40 mumole CdCl2/kg, s.c.) on day 12 of gestation were evaluated in the Wistar rat. At 16-18 hours following such cadmium exposure, blood flow (as determined by radiolabeled microspheres) to the chorioallantoic placenta (CAP) was significantly reduced by 35%; at 24-26 hours, blood flow to the CAP had returned to control levels and was still unaffected at 38-43 hours. Uterine blood flow was not significantly altered at any of these timepoints. Between 16-18 and 24-26 hours after cadmium exposure, the concentration of cadmium in the placenta decreased significantly, while total cadmium content did not change. By 38-43 hours after cadmium exposure, total cadmium content of the placenta had increased significantly, although cadmium concentration was unchanged. There were no adverse effects on fetal viability or growth, as determined on day 20 of gestation. In sharp contrast, near-term (day 18) exposure to 40 or 50 mumole CdCl2/kg (s.c.) resulted in 53% and 82% mean incidences of fetolethality, respectively, within 24 hours. Administration of 50 mumole CdCl2/kg (sc) on day 12 also had no effect on fetal growth but resulted in increased fetolethality (12%). Thus midgestational cadmium exposure and its accompanying alterations in placental blood flow do not compromise fetal viability or growth. The differential response to cadmium at mid- and late gestation, in terms of fetolethality, is not due to maternal cadmium dose.     

The ACTH content of plasma in fetal and newborn swine]

ACTH concentration has been estimated radioimmunologically in fetal plasma (100th day of gestation) and in plasma of newborn piglets during the first 24 hours of life and in sows. In comparison to the values of ACTH in sows at the 100th day of gestation during anaesthesia (175 pg/ml) and sows at parturition (235 +/- 77 pg/ml) the concentration in fetal (558 +/- 163 pg/ml) and newborn piglets (448 +/- 158 pg/ml) was much higher. On an average ACTH concentration increased during the first 24 hours of life up to 998 +/- 628 pg/ml. The results are compared to those in other species.     

Modulation of mitogen-independent hepatocyte proliferation during the perinatal period in the rat

Summary Late gestation fetal rat hepatocytes can proliferate under defined in vitro conditions in the absence of added mitogens. However, this capacity declines with advancing gestational age of the fetus from which the hepatocytes are derived. The present studies were undertaken to investigate this change in fetal hepatocyte growth regulation. Examination of E19 fetal hepatocyte primary cultures using immunocytochemistry for 5-bromo-2′-deoxyuridine (BrdU) incorporation showed that approximately 80% of these cells traverse S-phase of the cell cycle over the first 48 h in culture. Similarly, 65% of E19 hepatocytes maintained in culture under defined mitogen-free conditions for 24 h showed nuclear expression of proliferating cell nuclear antigen (PCNA). These in vitro findings correlated with a high level of immunoreactive PCNA in immunofluorescent analyses of E19 liver. In contrast, E21 (term) liver showed little immunoreactive PCNA. The in vivo finding was recapitulated by in vitro studies showing that E21 hepatocytes had low levels of BrdU incorporation during the first day in culture and were PCNA negative shortly after isolation. However, within 12 h of plating, E21 hepatocytes showed cytoplasmic staining for PCNA. Although maintained under mitogen-free conditions, PCNA expression progressed synchronously to a nucleolar staining pattern at 24 to 48 h in culture followed by intense, diffuse nuclear staining at 60 h which disappeared by 72 h. This apparently synchronous cell cycle progression was confirmed by studies showing peak BrdU incorporation on the third day in culture. Whereas DNA synthesis by both E19 and E21 hepatocytes was potentiated by transforming growth factor α (TGFα), considerable mitogen-independent DNA synthesis was seen in hepatocytes from both gestational ages. These results may indicate that fetal hepatocytes come under the influence of an exogenous, in vivo growth inhibitory factor as term approaches and that this effect is relieved when term fetal hepatocytes are cultured.