Demonstration of the simultaneous presence of transferrin, hemopexin and albumin in the same adult rat hepatocyte.

The location of three plasma proteins (transferrin, hemopexin, and albumin) in hepatocytes was investigated in adult rats. The synthesis of transferrin anf hemopexin has been established by ultrastructural studies showing a labeling of the rough endoplasmic reticulum (RER). By using an indirect immunoenzymatic method with monospecific antibody solutions, the three proteins were detected in the same hepatocyte. The simultaneous presence of different plasma proteins in hepatocytes seems to point to the fact that the synthesis in these cells could be a non-specialized type.     

Synthesis and secretion of fibrinogen and albumin by isolated rat hepatocytes

In order to investigate the regulation of synthesis of some of the plasma proteins, especially fibrinogen, at the cellular level, we have chosen to work with suspensions of hepatocytes isolated by the perfusion of rat liver with crude bacterial collagenase. By adding soybean trypsin inhibitor to the collagenase and by avoiding mechanical damage, we have prepared cell suspensions that synthesize and secrete fibrinogen and albumin and that survive for longer than twenty hours. The fibrinogen secreted is clottable and shows the same pattern in acrylamide gel electrophoresis as fibrinogen purified from rat plasma. After a three hour lag, the rate of synthesis of fibrinogen, as measured by a solid-phase radioimmunoassay, continually accelerates, so that rates several fold greater than the $\text{in vivo}$ rate have been observed after twenty hours incubation. Cycloheximide (0.1 mM) completely abolished the appearance of fibrinogen in the medium; whereas colchicine (0.3 mM) reduced the rate by 85%. Insulin and cortisol succinate enhanced fibrinogen synthesis and secretion. The albumin secretion profile differs in several respects from that of fibrinogen, reflecting differences in intracellular pool levels and probably distinct regulatory mechanisms.     

Synthesis of albumin via a precursor protein in cell suspensions from rat liver.

The mechanism of the biosynthesis of albumin was studied in cell suspensions from rat liver. The cells were prepared by continuous perfusion of the liver in situ with 0.05% collagenase and 0.10% hyaluronidase and incubated under conditions optimized for the incorporation of amino acids into protein. Seven minutes after starting the incubation L-[1-14C]leucine was added, followed after 25 min by a 15 or 30-min chase with an 830-fold excess of non-radioactive L-leucine. Total protein, an albumin-like protein, and albumin were isolated from samples withdrawn immediately of total protein was found to remain constant after addition of the non-radioactive L-leucine, whereas that of the albumin-like protein decreased and that of albumin increased with incubation time. The increase in albumin radioactivity accounted for the decrease in radioactivity of the albumin-like protein, suggesting that the latter is a precursor of albumin. The precursor protein differed from albumin by an oligopeptide extension at the N-terminal end.     

Albumin, fibrinogen and transferrin synthesis in isolated rat hepatocyte suspensions. A model for the study of plasma protein synthesis.

A system using hepatocyte suspensions in vitro was developed for studying the synthesis of albumin, fibrinogen and transferrin. Conditions for optimum survival of the hepatocyte and for synthesis of these plasma proteins were defined for this system. These conditions included the use of horse serum (17.5 percent, v/v, heat-inactivated), an enriched medium (Waymouth's MB 752/1), an O2 tension of between 18.7 times 10(3) and 26.7 times 10(3) Pa and constant stirring. Albumin, fibrinogen and transferrin synthesis rates were obtained of 0.32 p 0.094(10), 0.12 p 0.030(11) and 0.097 p 0.017(10) [mean p S.D. (n)]mg/h per g of hepatocytes respectively. These rates were maintained for the first 12h of study and synthesis continued at a diminished rate up to 48h. The synthesis of albumin was decreased in a medium containing less amino acids and glucose, but that of fibrinogen was substantially unaffected. ATP concentrations up to 12h and RNA/DNA ratios up to 24h were comparable with values in vivo. The ability to study cells up to 48h permitted us to find that the addition of a mixture of hormones consisting of glucagon, cortisol, tri-iodothyronine and growth hormone enhanced fibrinogen synthesis. Addition of insulin to the above mixture resulted in increased synthesis for albumin and transferrin but not for fibrinogen.     

Synthesis and secretion of albumin and transferrin by foetal rat hepatocyte cultures

Hepatocytes derived from foetal rat liver synthesize and secrete albumin and transferrin when maintained in primary culture. These proteins are produced for at least seven days under the conditions of culture. Studies on hepatocyte cultures derived from 12, 13, 14, 15 and 19-day foetal rats show that the maximal cellular rate of secretion of both proteins increases about 50-fold over this period. The maximal rate of albumin secretion in all cultures is achieved after one day in culture and decreases in hepatocytes from early foetuses after the fourth to sixth day in culture. Transferrin secretion by hepatocytes from 12 to 15 day foetuses increases markedly during the second day of culture and is relatively constant thereafter. In contrast, secretion of transferrin by hepatocytes from 19-day foetuses is constant from the first day of culture. The results show that both albumin and transferrin are synthesized and secreted by the foetal liver as early as the twelfth day of gestation. The increase in the rate of transferrin secretion that occurs during culture of hepatocytes from 12 to 15 day foetuses may reflect the development of a secretory mechanism that is different from that for albumin.     

Conversion of pyruvate into ketone bodies in rat hepatocyte suspensions.

The contribution of pyruvate to ketogenesis was determined in rat hepatocyte suspensions by using [14C]pyruvate. The rates of conversion of pyruvate into ketone bodies in hepatocytes from fed and 24 h-starved rats were 10 and 17 mumol/h per g wet wt. respectively, and accounted for 50 and 29% of the total ketone bodies formed. In hepatocytes from fed rats, the addition of palmitate (0.25-1 mM) increased the rate of conversion of pyruvate into ketone bodies (80-140%), but decreased the relative contribution of pyruvate to total ketogenesis. In hepatocytes from starved rats, palmitate did not increase pyruvate conversion into ketone bodies.     

Competitive role between fibrinogen and albumin on thixotropy of red cell suspensions

Plasmatic proteins, namely fibrinogen and globulins, play a major role in red blood cell (RBC) aggregation which is accountable for the three-dimensional structure of blood. Consequently, blood rheological properties linked to this structure must be modified when the protein plasma content changes. This paper gives results and related comments on thixotropic properties of RBC suspensions (0.45 hematocrit) in isotonic solutions containing various amount of fibrinogen to which albumin is added. Thixotropic behavior of these RBC suspensions is studied with a low inertia coaxial cylinders viscometer at a shear rate step of Y = 1 s-1. Rheograms are interpreted in term of thixotropy coefficient. The main conclusion is that albumin improves RBC disaggregability of whole blood, resulting probably from a competitive effect between fibrinogen and albumin in the RBC aggregation process.     

Quantitative comparison of rat hepatocyte functions in two improved culture systems with or without rat liver epithelial cell line

We quantitatively evaluated two recently-developed novel techniques for hepatocyte cultivation in a dish level; that is, spheroid culture and membrane-supported collagen (CN) gel sandwich culture, in terms of cellular maintenance, albumin secretion and 7-ethoxycoumarin (7EC) metabolism to 7-hydroxycoumarin (7HC) as a marker for cytochrome P450 IA1 activity in the presence and absence of rat liver epithelial cell line (RLEC) during one month of culture, together with conventional coculture with RLEC in CN-coated dishes as a control. RLEC prevented spheroid loss caused by its detachment from the culture dishes often occurring in pure culture. CN-gel sandwich by itself improved remarkably hepatocyte maintenance when compared with CN-gel free systems, thereby resulting in enhancement of overall functional expressions as compared with CN-gel free systems. RLEC in CN-gel sandwhich, however, reduced cellular sustainment probably due to its suppression of hepatocyte growth. Although there were no significant differences in albumin secretion per cell among the five cultures examined, CN-gel sandwich expressed markedly higher 7EC metabolizing activity per cell, where RLEC presence had a preferable influence. Consequently, membrane-supported CN-gel sandwich was the most superior technique for hepatocyte cultivation from the standpont of both cellular maintenance and its functional expressions per cell.     

Detection of active oxygen in rat hepatocyte suspensions with the chemiluminigenic probe lucigenin

The chemiluminigenic probe lucigenin has been employed to detect the production of active oxygen species in suspensions of intact rat hepatocytes. Light emission from lucigenin arises from oxygenation by superoxide anion; hydrogen peroxide or a species derived from it may contribute to the reaction. The inhibitory action of antioxidants on the availability of active oxygen species produced by hepatocytes was tested. Propyl gallate was the most potent inhibitor, butylated hydroxyanisole and butylated hydroxytoluene were less active. The latter compounds cause an alteration of the cell membrane at high concentrations.     

Acute hormonal control of pyruvate kinase and lactate formation in the isolated rat hepatocyte.

The activity of pyruvate kinase from the isolated rat hepatocyte was studied under conditions which allow investigation into the hormonal regulation of the enzyme. Incubating hepatocytes from fed or fasted rats with 1 μm glucagon gives approximately 60% inhibition of the enzyme activity determined at 1.6 mm P-enolpyruvate. A good correlation between the regulation of pyruvate kinase and lactate formation from 10 mm dihydroxyacetone is observed in hepatocytes from fasted rats. When hepatocytes are incubated in a Krebs-Ringer phosphate buffer, the inhibition of the pyruvate kinase activity by 1 μm glucagon is not accompanied by a marked inhibition of lactate production from fructose. Half-maximal regulation is observed at 0.26 ± 0.02 nm glucagon and 0.37 ± 0.05 nm glucagon for the enzyme and lactate formation from dihydroxyacetone respectively. Incubating hepatocytes with 10 mm l-alanine enhances inhibition of pyruvate kinase by physiological concentrations of glucagon, lowering the half-maximally effective concentration of glucagon from 0.3 nm to approximately 0.1 nm. A small but consistent inhibition of pyruvate kinase by 10 μm epinephrine is also observed and this inhibition is enhanced by 0.5 mm theophylline and by 10 mm l-alanine. The inhibition of pyruvate kinase by epinephrine both in the absence and presence of theophylline is blocked by the α-adrenergic antagonist phenoxybenzamine. The β-adrenergic blocker propranolol has no influence on the inhibition of the enzyme by epinephrine. Adenosine 3′:5′-monophosphate, N⁶O²-dibutyryl adenosine 3′:5′-monophosphate, and guanosine 3′:5′-monophosphate also inhibit glycolysis from dihydroxyacetone and modulate pyruvate kinase activity in hepatocytes from fasted rats. Oleate, ethanol, and 3-hydroxybutyrate inhibit dihydroxyacetone glycolysis, but they do not influence the activity of pyruvate kinase. The divalent metal ionophore A23187 slightly stimulates lactate synthesis from dihydroxyacetone, but it has no influence on pyruvate kinase activity.     

Comparison of albumin and fibrinogen biosynthesis in stimulated rats and cultured fetal rat hepatocytes.

Evidence is presented that cultured fetal rat hepatocytes, when incubated with a crude leucocytic extract derived from rabbits undergoing an inflammatory response, show a marked increase in fibrinogen production and a concomitant decrease in albumin production. Antibody binding to polyribosomes synthesizing fibrinogen and albumin shows the same inverse relationship in rats undergoing an artificially induced inflammatory response. These data demonstrate directly and unequivocally that during the acute phase (inflammatory) response, the biosynthesis of these two plasma proteins is inversely affected by a factor or factors acting directly on the liver.     

Techniques for pharmacological and toxicological studies with isolated hepatocyte suspensions.

Since its introduction in 1969, the high-yield preparation of isolated hepatocytes has become a frequently used tool for the study of hepatic uptake, excretion, metabolism and toxicity of drugs and other xenobiotics. Basic preparative methods are now firmly established involving perfusion of the liver with a balanced-saline solution containing collagenase. Satisfactory procedures are available for determining cell yields, for expressing cellular activities and for establishing optimal incubation conditions. Gross cellular damage can be detected by means of trypan blue or by measuring enzyme leakage, and damaged cells can be removed from the preparation. Specialized techniques are available for preparing hepatocyte couplets and suspensions enriched with periportal or perivenous hepatocytes. The isolated hepatocyte preparation is particularly convenient for the study of the kinetics of hepatic drug uptake and excretion because the cells can be rapidly separated from the incubation medium. Isolated liver cells have also proved valuable for investigating drug metabolism since they show many of the features of the intact liver. However, they also show important differences such as losses of membrane specialization, some degree of cell polarity and the capacity to form bile. The many consequences of the hepatic toxicity of xenobiotics including lipid peroxidation, free radical formation, glutathione depletion, and covalent binding to macromolecules are also readily studied with the isolated liver cell preparation. A particular advantage is the ease with which morphological changes as a result of drug exposure can be observed in isolated hepatocytes. However, it must be remembered that the isolation procedure inevitably introduces changes that may make the cells more susceptible than the normal liver to damage by xenobiotic agents. Despite its limitations, the isolated hepatocyte preparation is now firmly established in the armamentarium of the investigator examining the interaction of the liver with xenobiotics.     

Synthesis of angiotensinogen by isolated rat liver cells and its regulation in comparison to serum albumin

Angiotensinogen (renin substrate) and albumin are synthesized by isolated hepatocytes almost linearly for 5 hr. The incorporation of radioactive leucine into total protein proceeded linearly for 3 hr. Without addition of amino acids to the incubation medium the synthesis of both proteins was still linear but fell off to 40% compared to the synthesis rate obtained by incubation with amino acids in serum concentrations. Higher amino acid concentrations could not further stimulate the synthesis. Addition or withdrawal of tryptophan had no effect on the synthesis rate of both proteins. After 5 hr incubation hydrocortisone had stimulated the incorporation of radioactive leucine into total protein by 13%, the albumin synthesis by 43%, and the angiotensinogen synthesis by 142%.     

Plasmodium berghei: preparation of rat hepatic cell suspensions that include infective exoerythrocytic schizonts.

Employing an enzymatic method to dissociate rat liver, we prepared suspensions of liver cells from rats infected with sporozoites of Plasmodium berghei 3 to 10, 18 to 28, or 29 to 36 hr prior to liver dissociation. These suspensions of liver cells included hepatocytes, Kupffer cells, fibroblasts, and unidentified cells, as well as hepatocytes infected with exoerythrocytic schizonts (HEX) of P. berghei. These HEX were infective for recipient rodents when inoculated intraperitoneally into the recipients. The number of infective HEX present in the liver cell suspensions was quantitated by varying the number of HEX inoculated into recipients. This infectivity assay made it possible to compare the numbers of HEX in suspensions of liver cells from different donor rats. Infective HEX were obtained from donor rats in 35 of 41 experiments. The greatest number of infective HEX was obtained from donors injected with sporozoites 18 to 28 hr prior to liver dissociation. For morphological observation of mature HEX in cell suspensions, hepatic cells were prepared from donors infected with sporozoites 48 hr prior to liver dissociation. For experimental purposes, the preparation of infective HEX in suspensions of liver cells is superior to the preparation of infective HEX in liver fragments, because it is possible to quantitate the number of HEX which are present either visually or by means of the infectivity assay.     

Ultrastructural location of albumin and fibrinogen in primary cultures of new-born rat liver tissue

In primary cultures of new-born rat liver tissue, albumin and frbrinogen, two proteins normally synthesized by the liver and secreted into plasma were demonstrated by specific antibodies labelled with peroxidase in about 50 and 70% of the hepatocytes; these proteins were not demonstrated in the other types of cells, in particular fibroblasts, present in primary cultures. These two proteins were detected on the ribosomes of the rough endoplasmic reticulum and were also present in the lumina of the rough and smooth endoplasmic reticulum and in the Golgi apparatus. It is concluded that

1. 1. In primary cultures of liver tissue, only the hepatocytes synthesize albumin and fibrinogen.

2. 2. Proliferating cultured hepatocytes are able to synthesize albumin and fibrinogen.

3. 3. The presence of detectable albumin and fibrinogen in the lumina of the rough and smooth endoplasmic reticulum and in the Golgi apparatus in hepatocytes of primary cultures and their absence in the lumina of the rough and smooth endoplasmic reticulum and in the Golgi apparatus in the hepatocytes of adult rat liver might indicate an alteration in the translocation of albumin and fibrinogen through these organelles in cultured hepatocytes.

     

Cell density-dependent regulation of albumin synthesis and DNA synthesis in rat hepatocytes by hepatocyte growth factor.

Hepatocyte growth factor (HGF), a potent mitogen for mature hepatocytes, has been considered to act as a hepatotropic factor for liver regeneration. We examined the effect of HGF on albumin synthesis and DNA synthesis of adult rat hepatocytes cultured at various cell densities. HGF stimulated albumin synthesis of hepatocytes by 40-60% when they were cultured at higher cell densities such that there was tight cell-cell contact. But at lower cell densities HGF failed to stimulate albumin synthesis. In contrast, the stimulatory effect of HGF on DNA synthesis of hepatocytes was more potent at lower than at higher cell densities: HGF did not stimulate DNA synthesis of hepatocytes cultured at confluent cell density. Thus, HGF seems to stimulate both albumin synthesis and DNA synthesis of hepatocytes, in a reciprocal relationship depending on cell density. When the effects of various cytokines were examined, epidermal growth factor, transforming growth factor-alpha, and acidic fibroblast growth factor also stimulated albumin synthesis by 20-30%. However, transforming growth factor-beta 1, basic fibroblast growth factor, and interleukin-1 beta had no effect on albumin synthesis, while interleukin-6 inhibited it by 42%. Thus HGF was the most potent in stimulating albumin synthesis in these cytokines. Since HGF is markedly increased in the liver or plasma following various liver insults, HGF may be involved in liver regeneration through the potential to stimulate both cell growth and liver-specific functions such as albumin synthesis in a cell density-dependent manner.     

Synthesis and degradation of eicosanoids in primary rat hepatocyte cultures

Arachidonic acid metabolites may play an important role in liver physiology, yet hepatocyte prostaglandin synthesis has not been characterized extensively. We used RIA to study production and clearance of several eicosanoids in confluent primary cultures of rat hepatocytes in serum-free, hormonally-defined medium. Under basal, unstimulated conditions 6-keto-PGF1 alpha (spontaneous breakdown product of prostacyclin) and 13,14-dihydro-15-keto-PGE (DHK-PGE, a metabolite of PGE) accumulated in the culture medium. Hepatocytes cleared 6-keto-PGF1 alpha, thromboxane B2, and DHK-PGE from the medium. Production of eicosanoids by primary cultures appeared resistant to indomethacin and several other cyclooxygenase inhibitors. This apparent resistance to indomethacin was not caused by rapid metabolism of indomethacin, by failure of the drug to enter hepatocytes, or by insensitivity of hepatocyte cyclooxygenase to the drug. Metabolism of PGE to DHK-PGE may be saturated under in vitro conditions. Hepatocytes can synthesize significant amounts of eicosanoids, although they are probably less active in this regard than are non-parenchymal cells.     

Enhanced synthesis of albumin and fibrinogen at high altitude.

The acute effects of active and passive ascent to high altitude on plasma volume (PV) and rates of synthesis of albumin and fibrinogen have been examined. Measurements were made in two groups of healthy volunteers, initially at low altitude (550 m) and again on the day after ascent to high altitude (4,559 m). One group ascended by helicopter (air group, n = 8), whereas the other group climbed (foot group, n = 9), so that the separate contribution of physical exertion to the response could be delineated. PV was measured by dilution of (125)I-labeled albumin, whereas synthesis rates of albumin and fibrinogen were determined from the incorporation of isotope into protein after injection of [ring-(2)H(5)]phenylalanine. In the air group, there was no change in PV at high altitude, whereas, in the foot group, there was a 10% increase in PV (P < 0.01). Albumin synthesis (mg. kg(-1). day(-1)) increased by 13% in the air group (P = 0.058) and by 32% in the foot group (P < 0.001). Fibrinogen synthesis (mg. kg(-1). day(-1)) increased by 40% in the air group (P = 0.068) and by 100% in the foot group (P < 0.001). Hypoxia and alkalosis at high altitude did not differ between the groups. Plasma interleukin-6 was increased modestly in both groups but C-reactive protein was not changed in either group. It is concluded that increases in PV and plasma protein synthesis at high altitude result mainly from the physical exercise associated with climbing. However, a small stimulation of albumin and fibrinogen synthesis may be attributable to hypobaric hypoxia alone.