Stimulative effect of non-parenchymal liver cells on ability of tyrosine aminotransferase induction in hepatocytes

Hepatocytes and non-parenchymal liver cells were isolated from adult rat liver and co-cultured for 48 hours as a monolayer on polystyrene culture dishes. The ability of tyrosine aminotransferase (TAT) induction in hepatocytes was examined in the presence of dexamethasone and dibutyryl cAMP. Non-parenchymal cells greatly enhance the ability of TAT induction of hepatocytes. A soluble factor with molecular weight of more than 10,000 is responsible for this enhancement, because conditioned medium prepared from non-parenchymal cells is also stimulatory. Non-parenchymal cells restored the ability in hepatocytes damaged with the addition of D-galactosamine. Conditioned medium prepared from non-parenchymal cells treated with D-galactosamine had higher activity of enhancement than the medium from normal cells. The soluble factor might be released in response to some signal of injury. Hepatocytes and non-parenchymal cells were immobilized within Ca-alginate, and although immobilized hepatocytes rapidly lost the ability to induce TAT, hepatocytes co-immobilized with non-parenchymal cells maintained the ability during 4 days of culture. These results indicated that non-parenchymal liver cells, as well as hepatocytes, could be used to construct a bioartificial liver support system.     

Involvement of conserved asparagine and arginine residues from the N-terminal region in the catalytic mechanism of rat liver and Trypanosoma cruzi tyrosine aminotransferases

Rat liver and Trypanosoma cruzi tyrosine aminotransferases (TATs) share over 40% sequence identity, but differ in their substrate specificities. To explore the molecular features related to these differences, comparative mutagenesis studies were conducted on full length T. cruzi TAT and N-terminally truncated rat TAT recombinant enzymes. The functionality of Arg315 and Arg417 in rat TAT was investigated for comparison with the conserved Arg292 and Arg386 in aspartate and bacterial aromatic aminotransferases (ASATs and ARATs). The rat TAT Arg315Lys variant remained fully active indicating that, as in T. cruzi TAT and contrary to subfamily Ialpha aminotransferases, this residue is not critical for activity. In contrast, the Arg417Gln variant was inactive. The catalytic relevance of the putative rat TAT active site residues Asn54 and Arg57, which are strictly conserved in TATs (Asn17 and Arg20 in T. cruzi TAT) but differ in ASATs and ARATs, was also explored. The substitutions Arg57Ala and Arg57Gln abolished enzymatic activity of these mutants. In both variants, spectral studies demonstrated that aromatic but not dicarboxylic substrates could efficiently bind in the active site. Thus, Arg57 appears to be functionally equivalent to Arg292 of ASATs and ARATs. Asn54 also appears to be involved in the catalytic mechanism of rat TAT since its exchange for Ser lowered the k(cat)/K(m) ratios towards its substrates. Mutation of the analogous residues in T. cruzi TAT also lowered the catalytic efficiencies (k(cat)/K(m)) of the variants substantially. The results imply that the mamalian TAT is more closely related to the T. cruzi TAT than to ASATs and ARATs.     

Differential effects of Mg2+ on various hydrolytic and synthetic activities of multifunctional glucose-6-phosphatase

The adaptive synthesis of fatty acid synthetase in the livers of rats fed a fat-free diet following 48 hr of fasting has been studied using immunochemical methods. The development of fatty acid synthetase activity during adaptive synthesis occurs about 3 hr following feeding, whereas the synthesis of material precipitable by anti-fatty acid synthetase serum, as judged by the incorporation of ³H-labeled amino acids into the immunoprecipitate, commenced within 1 hr. Extracts of liver of rats fed a fat-free diet for 1–3 hr following fasting contain increasing amounts of material which competes with purified fatty acid synthetase for antibody binding sites, even though they have no fatty acid synthetase activity. This suggests the presence of enzymatically inactive precursors of fatty acid synthetase in the liver extracts. The incorporation of [¹⁴C]pantothenate into fatty acid synthetase during adaptive synthesis follows the same pattern as the development of enzyme activity, indicating that these enzymatically inactive precursors of fatty acid synthetase may represent an apoenzyme which is converted to the enzymatically active holoenzyme by the incorporation of the 4′-phosphopantetheine prosthetic group. The subcellular site of synthesis of fatty acid synthetase was shown to be in the pool of polysomes that are not membrane bound, rather than in the rough endoplasmic reticulum.     

Role of glucocorticoids and resident liver macrophages in induction of tyrosine aminotransferase

Administration of cortisol to an animal induces tyrosine aminotransferase (TAT) in the liver. A similar effect was observed after stimulation of resident liver macrophages (Kupffer cells) by dextran sulfate. Actinomycin D completely blocks enzyme induction both by cortisol and dextran sulfate, whereas their combined effect gives an additive result. In primary culture of hepatocytes, dextran sulfate inhibits TAT activity, but conditioned macrophage medium reliably increases enzyme activity in hepatocytes. However, incubation of isolated macrophages in the presence of dextran sulfate and such medium transfer into hepatocyte culture results in even more pronounced increase in TAT activity. In a combined culture of hepatocytes and non-parenchymal liver cells, reproducing intercellular interactions in vitro, cortisol and non-parenchymal cells exhibit an additive effect on TAT activity. These results show that liver macrophages release a factor of unknown nature launching the mechanism of TAT induction independently of cortisol, a classic TAT inducer.     

Direct production of an activated matrix metalloproteinase-9 (gelatinase B) from mammalian cells

Matrix metalloproteinase-9 (MMP-9) is produced by the inactive proform and activated by a proteolytic process. However, it has not been reported to produce the active form directly from cells, which has hindered the research to elicit the physiological roles of this enzyme. In this study, we prepared mutant MMP-9 containing the furin-recognizing sequence in the prodomain and showed that the mutant MMP-9 was secreted as the active form directly from CHO-K1 cells and primary hepatocytes after the gene was transfected. The secreted MMP-9 showed proteolytic activity without further activation and degraded collagen IV in vitro. In addition, the transfection of the gene into the liver resulted in the efficient expression of active MMP-9 in the liver and the serum in vivo.     

Characterization of the L-tryptophan transport system in the liver of growing rats

In order to characterize the system of L-tryptophan (TRP) transport into liver during the growing period of 10 to 42 days, the changes of tryptophan 2,3-dioxygenase (TDO) activity, levels of serum, liver, brain, and muscle TRP, and the rate and mode of TRP uptake into isolated hepatocytes were examined in male Wistar rats. Liver TDO activity increased rapidly at 16 days of age. A marked and rapid decrease in free serum TRP level occurred before weanling, while a small decrease in total serum TRP level was found after weanling. The change of liver TRP level was similar to that of free serum TRP level and correlated well. There was a significant inverse correlation between liver TDO activity and either free serum TRP level or liver TRP level. A rapid change in TRP level did not occur in brain and muscle during the growing period. The concentrations of brain and muscle TRP correlated better with those of total serum TRP than with those of free serum TRP. The rate of TRP uptake into hepatocytes isolated from rats aged 10 days was lower than that from rats aged 21 and 42 days. The former hepatocytes were lacking in a high-affinity saturable transport component for TRP uptake which was present in the latter ones. The present results indicate that a great change in the system of TRP transport into liver occurs in growing rats, and that in suckling rats a high level of free serum TRP contributes to the efficient transport of the amino acid into the liver.     

Diurnal variations in inducibility of rat liver tyrosine aminotransferase activity.

The activity of tyrosine aminotransferase (TAT) was measured in the livers of rats which were entrained to eat for the first 2 hours of a daily 12 hour dark period (‘2+22’ schedule) and were treated with the synthetic glucocorticoid dexamethasone and with glucagon at several times of day. TAT activity in untreated animals varies diurnally with a maximum 4 to 6 hours after the beginning of feeding. In both fed and fasted rats there was a small diurnal variation in inducibility by dexamethasone: in fed rats induction was greatest near the beginning of the dark period, shortly after feeding; in fasted rats induction increased towards the end of the dark period. Glucagon induction showed a marked diurnal variation in fed rats with a decrease coincident with the decline in control TAT activity after its food-induced peak. This variation did not appear to be depemdent on food intake, however, since the decline in inducibility occurred in fasted rats at the same time as in fed rats. Co-treatment with dexamethasone did not affect the decrease in glucagon inducibility. The diurnal variation in TAT induction may reflect a diurnal rhythm in the components of the enzyme synthesizing system (e.g. in the availability of mRNA or in enzyme degradation).     

The use of biochemical solid-phase techniques in the study of alcohol dehydrogenase. 1. Some studies on subunit interactions in alcohol dehydrogenase with subunits covalently bound to agarose

The EE and SS isozymes of horse liver alcohol dehydrogenase have been immobilized separately to weakly CNBr-activated Sepharose 4B. The resulting immobilized dimeric preparations lost practically all of their activity after treatment with 6 M urea. However, enzyme activity was regenerated by allowing the urea-treated Sepharose-bound alcohol dehydrogenase to interact specifically with either soluble subunits of dissociated horse liver alcohol dehydrogenase or soluble dimeric enzyme. The regeneration of steroid activity in the immobilized preparations after treatment of the bound S subunits with soluble E subunits seems to show that true reassociation of the enzyme had taken place on the solid phase, since only isozymes with an S-polypeptide chain are active when using 5 beta-dihydrotestosterone as substrate. The results presented in this paper indicate that immobilized single subunits of horse liver alcohol dehydrogenase are inactive and that dimer formation is a prerequisite for the enzymic activity.     

Structural organization of a hexamer of glutamate dehydrogenase. 3. Effect of the coenzyme and substrate on the urea-induced dissociation and inactivation of the hexamer

Effects of coenzyme (NADH) and substrate (2-oxoglutarate) on the urea-induced dissociation and inactivation of immobilized phosphopyridoxyl derivative of bovine liver glutamate dehydrogenase (L-glutamate-NAD(P)-oxidoreductase, EC 1.4.1.3) have been studied. Urea at concentration 3.0 to 4.0 M in the presence of NADH induced dissociation of the enzyme's hexamer to catalytically inactive immobilized dimer. In the presence of both NADH and 2-oxoglutarate at the urea concentration 1.0 to 2.0 M the hexamer dissociated to the conformationally stable immobilized trimer possessing 60% catalytic activity of the hexamer. Studies of regulatory properties of the immobilized trimer showed that the allosteric inhibition of glutamate dehydrogenase by GTP was realized on the level of trimers, where the subunits interact through identical heterological contacts.     

Demonstration of collagenase activity in rat liver homogenate

Collagenase activity became detectable in rat liver homogenate by washing liver tissue repeatedly with buffered saline before homogenization. This enzyme activity was inhibited by adding minute quantities of serum. These data suggest that collagenase is active $\text{in situ}$ in the liver, but is made inactive during the homogenization by forming a complex with contaminating serum factors.     

Insulin-induced increases in the activity of the spontaneously active and ATP.Mg-dependent forms of phosphatase-1 in alloxan-diabetic rat liver

Liver supernatant from normal and alloxan-diabetic rats was fractionated by DEAE-cellulose chromatography and the separated phosphoprotein phosphatase fractions were assayed with [32P]histone f2b, [32P]phosphorylase a and [32P]phosphorylase kinase as substrates. In diabetic rat liver, one of the phosphatase fractions found in the normal liver was significantly reduced. This fraction was identified as a mixture of the spontaneously active form and the ATP . Mg-dependent form of phosphoprotein phosphatase-1 (Fc) based on sensitivity to inhibitor-2, substrate specificity, and the fact that it could be activated 42-70% by glycogen synthase kinase-3 in the presence of ATP . Mg. Further analysis of this fraction showed that liver cytosol from diabetic rats contained 62-79% lower spontaneously active phosphatase-1 activity and 40-51% lower combined spontaneously active and ATP . Mg-dependent protein phosphatase-1 (Fc) activity. Insulin administration increased the spontaneously active and the ATP . Mg-dependent protein phosphatase-1 activities approximately 45% and 36%, respectively, in alloxan-diabetic rats. These data imply that the lower levels of spontaneously active phosphatase-1 activity in diabetic rat liver cannot be explained by presuming phosphatase-1 to have been present as Fc, the inactive form. Moreover, insulin restored the total activity of the spontaneously active and activatable forms of phosphatase-1 to those present in normal liver implying that both forms of phosphatase-1 activity are under hormonal control.     

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.     

Expression of differentiated functions in dexamethasone-resistant hepatoma cells

Abstract. The expression of liver-specific functions of different dexamethasone-resistant variants derived from a well-differentiated dexamethasone-sensitive Reuber H35 rat hepatoma cell line (Faza 967) was examined during long-term cultivation. The dexamethasone-sensitive Faza 967 cells are characterized by the activity of tyrosine aminotransferase (TAT) and gluconeogenic enzymes, secretion of serum albumin, and the presence of liver isozymes of alcohol dehydrogenase (L-ADH), aldolase (aldolase-B), and five isoenzymes of lactate dehydrogenase (LDH). The hormone-resistant cells undergo a very dramatic change in expression of most liver-specific functions (dedifferentiation) during long-term culture, in contrast to the sensitive cells in which only certain functions (TAT activity, inducibility, and synthesis of serum albumin) exhibit considerable changes. The hormone-dependent growth sensitivity and the expression of other differentiated functions is not controlled in coordinated way in Faza 967 cells. The time course of the expression of liver-specific functions shows that the cells are resistant before they became 'dedifferentiated', i.e., loss of these liver-specific functions is not a prerequisite of the establishment of the hormone-resistant state.     

Expression of differentiated functions in dexamethasone-resistant hepatoma cells

The expression of liver-specific functions of different dexamethasone-resistant variants derived from a well-differentiated dexamethasone-sensitive Reuber H35 rat hepatoma cell line (Faza 967) was examined during long-term cultivation. The dexamethasone-sensitive Faza 967 cells are characterized by the activity of tyrosine aminotransferase (TAT) and gluconeogenic enzymes, secretion of serum albumin, and the presence of liver isozymes of alcohol dehydrogenase (L-ADH), aldolase (aldolase-B), and five isoenzymes of lactate dehydrogenase (LDH). The hormone-resistant cells undergo a very dramatic change in expression of most liver-specific functions (dedifferentiation) during long-term culture, in contrast to the sensitive cells in which only certain functions (TAT activity, inducibility, and synthesis of serum albumin) exhibit considerable changes. The hormone-dependent growth sensitivity and the expression of other differentiated functions is not controlled in coordinated way in Faza 967 cells. The time course of the expression of liver-specific functions shows that the cells are resistant before they became 'dedifferentiated', i.e., loss of these liver-specific functions is not a prerequisite of the establishment of the hormone-resistant state.     

Behaviour of tyrosine amino transferase and convertase during the first hours after hepatectomy in rats

The activity of rat liver tyrosine amino transferase (TAT) increases after hepatectomy with a first prominent peak at 8 h and a second peak at 18 h. This change in activity is probably due to de novo enzyme synthesis since it is prevented by actinomycin-D (AMD). In the same period an increase of the lysosomal converting enzyme (convertase) which catalyses the in vitro transition of TAT from form I to form III, has been observed; this is not accompanied by changes of other lysosomal enzymes, such as acid phosphatase and cathepsin L. The activity of convertase is equal to that of the controls (sham operated animals) 2 h after hepatectomy, increases three times at 5 h, maintains the same value at 8 h and then decreases slowly to control level after 24 h. The correlation between the activity changes of the two enzymes strongly suggests a physiological role of convertase in TAT turnover.     

Time-Dependent Pharmacokinetics and Toxicity of cyclosporine

Although the circadian pattern of cyclosporine (CSA) pharmacokinetics and toxicity has been described previously in both animal and clinical studies, the mechanism of this action is unknown. The present study compared the pharmacokinetics and experimental nephrotoxicity of chronic CSA in both the genetically-hyperlipidemic rat model and the lean litter-mate. Once daily dosing (25 mg/kg via gavage) was either at the start of the active (1900) or inactive (0700) cycle (Nov 1987 to Jan 1988). Serial serum samples following the final dose were assayed by both polyclonal (nonspecific) and monoclonal (specific for parent CSA) RIA. Renal toxicity was assessed by 24-hr creatinine clearances, fractional clearances of sodium and potassium, and inulin clearances (CIN). Despite a greater than 2-fold increase in serum CSA concentrations, there were no changes in renal function in obese rats dosed at the start of the active period compared to the inactive period. Furthermore, mean CIN of the lean group administered drug at the start of the active period was not significantly different from time-matched placebo-treated lean rats. However, there was an 80% drop in CIN in rats treated with CSA at the start of the inactive period compared to control group. There were no differences in electrolyte handling. Insulin concentrations, independent of time of dosing, were markedly elevated in obese rats dosed CSA compared to placebo-treated obese or both lean groups. Serum triglyceride levels were significantly correlated with pharmacokinetic parameters of total but not parent CSA. In summary, significant differences in toxicity were observed due to time of dosing and lipid profiles. Although the mechanism of this action remains unclear, it appears that increased non-fasting serum triglyceride levels following the active period most likely reduced CSA distribution into kidney tissue preventing the dose-limiting nephrotoxicity.     

Dosing-time-dependent differences in lipopolysaccharide-induced liver injury in rats

Dosing-time-dependent differences in lipopolysaccharide (LPS)-induced liver injury were examined in rats housed under a 12 h light:dark (LD) cycle. LPS (5 mg/kg) was intravenously injected into different groups of rats at 2, 14, or 20 h after light on (HALO). Elevations in serum liver enzymes after 14 HALO were significantly greater than those after 2 HALO. These parameters were lower in rats given LPS at 20 HALO, compared to 14 HALO. The number of polymorphonuclear cells (PMN) in the liver and the amount of hepatic myeloperoxidase activity, which reflects the number of PMN in liver tissues, was significantly greater in the 14 than in the 2 HALO group. In addition, hepatic interleukin-6 (IL-6) production in the 14 HALO group was enhanced compared to that in the 2 HALO trial. These results suggest that LPS-induced liver injury is greater during the early active than during the early resting period. Dosing-time-dependent variation in the accumulation of PMN in the liver and, potentially, subsequent IL-6 production in liver tissues might be involved in this phenomenon.     

Time-Dependent Pharmacokinetics and Toxicity of cyclosporine

Although the circadian pattern of cyclosporine (CSA) pharmacokinetics and toxicity has been described previously in both animal and clinical studies, the mechanism of this action is unknown. The present study compared the pharmacokinetics and experimental nephrotoxicity of chronic CSA in both the genetically-hyperlipidemic rat model and the lean litter-mate. Once daily dosing (25 mg/kg via gavage) was either at the start of the active (1900) or inactive (0700) cycle (Nov 1987 to Jan 1988). Serial serum samples following the final dose were assayed by both polyclonal (nonspecific) and monoclonal (specific for parent CSA) RIA. Renal toxicity was assessed by 24-hr creatinine clearances, fractional clearances of sodium and potassium, and inulin clearances (CIN). Despite a greater than 2-fold increase in serum CSA concentrations, there were no changes in renal function in obese rats dosed at the start of the active period compared to the inactive period. Furthermore, mean CIN of the lean group administered drug at the start of the active period was not significantly different from time-matched placebo-treated lean rats. However, there was an 80% drop in CIN in rats treated with CSA at the start of the inactive period compared to control group. There were no differences in electrolyte handling. Insulin concentrations, independent of time of dosing, were markedly elevated in obese rats dosed CSA compared to placebo-treated obese or both lean groups. Serum triglyceride levels were significantly correlated with pharmacokinetic parameters of total but not parent CSA. In summary, significant differences in toxicity were observed due to time of dosing and lipid profiles. Although the mechanism of this action remains unclear, it appears that increased non-fasting serum triglyceride levels following the active period most likely reduced CSA distribution into kidney tissue preventing the dose-limiting nephrotoxicity.