The effect of cortisol on the synthesis of rat plasma albumin, fibrinogen and transferrin

Tumor-Associated Neutrophils and Macrophages Promote Gender Disparity in Hepatocellular Carcinoma in Zebrafish

Hepatocellular carcinoma (HCC) occurs more frequently and aggressively in men than women, but the mechanistic basis of this gender disparity is obscure. Chronic inflammation is a major etiologic factor in HCC, so we investigated the role of cortisol in gender discrepancy in a zebrafish model of HCC. Inducible expression of oncogenic Kras^V12 in hepatocytes of transgenic zebrafish resulted in accelerated liver tumor progression in males. These tumors were more heavily infiltrated with tumor-associated neutrophils (TAN) and tumor-associated macrophages (TAM) versus females, and they both showed protumor gene expression and promoted tumor progression. Interestingly, the adrenal hormone cortisol was predominantly produced in males to induce Tgfb1 expression, which functioned as an attractant for TAN and TAM. Inhibition of cortisol signaling in males, or increase of cortisol level in females, decreased or increased the numbers of TAN and TAM, respectively, accompanied by corresponding changes in protumor molecular expression. Higher levels of cortisol, TGFB1, and TAN/TAM infiltration in males were also confirmed in human pre-HCC and HCC samples, features that positively correlated in human patients. These results identify increased cortisol production and TAN/TAM infiltration as primary factors in the gender disparity of HCC development in both fish and human. Cancer Res; 77(6); 1395-407. ©2017 AACR.

Isotopic and modeling investigation of long-term protein turnover in rat tissues

Fractional synthesis rates (FSR) of tissue proteins (P) are usually measured using labeled amino acid (AA) tracer methods over short periods of time under acute, particular conditions. By combining the long-term and non-steady-state (15)N labeling of AA and P tissue fractions with compartmental modeling, we have developed a new isotopic approach to investigate the degree of compartmentation of P turnover in tissues and to estimate long-term FSR values under sustained and averaged nutritional and physiological conditions. We measured the rise-to-plateau kinetics of nitrogen isotopic enrichments (δ(15)N) in the AA and P fractions of various tissues in rats for 2 mo following a slight increase in diet δ(15)N. Using these δ(15)N kinetics and a numerical method based on a two-compartment model, we determined reliable FSR estimates for tissues in which P turnover is adequately represented by such a simple precursor-product model. This was the case for kidney, liver, plasma, and muscle, where FSR estimates were 103, 101, 58, and 11%/day, respectively. Conversely, we identified tissues, namely, skin and small intestine, where P turnover proved to be too complex to be represented by a simple two-compartment model, evidencing the higher level of subcompartmentation of the P and/or AA metabolism in these tissues. The present results support the value of this new approach in gaining cognitive and practical insights into tissue P turnover and propose new and integrated FSR values over all individual precursor AA and all diurnal variations in P kinetics.

Transferrin synthesis is increased in nephrotic patients insufficiently to replace urinary losses

The urinary loss of transferrin is sufficient to reduce plasma transferrin concentrations in the nephrotic syndrome. Hypotransferrinemia may lead to iron loss and microcytic anemia. The mechanism responsible for the hypotransferrinemia in the nephrotic syndrome is, however, unknown. In the present study, synthesis rate of transferrin was measured in vivo in nephrotic patients (n = 7) compared with control subjects (n = 6) using L-[1-(13)C]-valine. Plasma transferrin and iron concentration in the patients were significantly lower than in control subjects (transferrin, 1.39 +/- 0.08 versus 2.57 +/- 0.11 g/L, P < 0.0001; iron, 10.2 +/- 0.8 versus 21.1 +/- 4.5 micromol/L, P = 0.02). Furthermore, albuminuria correlated with transferrinuria (r(2) = 0.901, P = 0.001). The absolute synthesis rate of transferrin was increased in the patients (10.0 +/- 1.1 versus 7.4 +/- 0.7 mg/kg per d, P = 0.07), although this value failed to achieve significance. C-reactive protein, plasma iron, and proteinuria did not correlate with transferrin synthesis. In contrast, transferrin synthesis correlated with albumin synthesis (r(2) = 0.648, P = 0.03; n = 7). The present study indicates that increased transferrin synthesis occurs in nephrotic patients but is insufficient to compensate for urinary losses. Because, overall, no significant relationship was found between transferrin synthesis and either C-reactive protein or iron, it is unlikely that inflammation suppresses or that iron deficiency stimulates increased transferrin synthesis in these patients. The correlation between transferrin synthesis and albumin synthesis suggests that transferrin synthesis is a component of a general response in hepatic protein synthesis in the nephrotic syndrome. This suggests that a therapeutic approach to maximize plasma transferrin concentrations in nephrotic patients should be aimed primarily at reducing urinary protein excretion.

Corticosteroids: do they damage the cardiovascular system?

Since their introduction for the treatment of rheumatoid arthritis, corticosteroids have become widely used as effective agents in the control of inflammatory diseases. Although there have been undoubted benefits upon mortality in diseases such as systemic lupus erythematosus, many patients survive only to suffer a high incidence of premature atherosclerosis. There is also evidence of increased rates of vascular mortality in other corticosteroid-treated diseases, such as rheumatoid arthritis, reversible airways obstruction and transplant recipients. Possible mechanisms of damage include elevated blood pressure, impaired glucose tolerance, dyslipidaemia, and imbalances in thrombosis and fibrinolysis. This paper reviews the clinical evidence supporting the contention that there is an excess cardiovascular mortality in steroid-treated patients and the underlying mechanisms, and points to further areas of research.

Effects of adrenalectomy and of adrenal hormones on the tissue distribution of 14 elements in the rat

The effects of adrenalectomy (ADY) and of replacement therapy using a mineralocorticoid, deoxycorticosterone (DOC) and a glucocorticoid, dexamethasone (DEX) on the tissue distribution of elements in the rat, were studied under semichronic conditions. The elements Na, K, Ca, Mg, Fe, S, P, Rb, Sr, Mn, Cu, and Zn were determined in whole blood, plasma, brain, liver, kidney, heart, skeletal muscle, spleen, thymus, and bone. Additionally, Mo was determined in kidney and liver and Ba in bone. ADY modified concentrations of all elements tested. Small changes were observed for K, Mg, Ca, S, and P, whereas much larger changes were noted for Na, Rb, and Sr. Cu, Zn, and Fe were mainly modified in liver and kidney, organs involved in storage and/or elimination. The consequences of ADY were corrected fairly well by DEX for Mg, Mn, Ca, Cu, and Mo; by DOC for Na and K, and by the two corticoids for Zn, Fe, Sr, and Rb. This study revealed that corticoids, mainly glucocorticoids, play an important role in the plasma and tissue balance of elements. It is suggested that these results may have a pathological and clinical significance.

Short-term effects of corticosterone treatment on muscle protein synthesis in relation to the response to feeding

1. Rates of protein synthesis in liver and muscle of 100 g male rats were measured in vivo at 1 h or 4 h after injection of 2.5 mg of corticosterone and compared with those from animals given carrier medium alone. 2. In post-absorptive rats, corticosterone for 1 h had no effect on either muscle or liver protein synthesis. After 4 h there was a decrease in both tissues, but this was only statistically significant in muscle. 3. In fed rats, rates of protein synthesis were higher than those in post-absorptive animals, but the effects of corticosterone injection were similar. 4. Re-feeding of post-absorptive rats led to an increase in muscle protein synthesis after 1 h and 4 h. At 1 h this increase was not inhibited when plasma corticosterone concentrations were maintained high by injection of the hormone immediately before feeding commenced, but at 4 h there was a small inhibition. 5. It is concluded that the action of corticosterone in depressing muscle protein synthesis is time-dependent and requires longer than 1 h to develop. The failure of the hormone to alter the response to re-feeding for 1 h in post-absorptive rats suggest that corticosteroids are not important mediators of the acute stimulation of muscle protein synthesis by food intake.

Rat transferrin gene expression: tissue-specific regulation by iron deficiency

Rats raised on a low-iron diet were used as a model system for investigating the regulation of transferrin gene expression by iron deficiency. We quantitated transferrin mRNA in a variety of tissues from normal and iron-deficient rats and found that the level of transferrin mRNA in normal rat liver was about 6500 molecules per cell, while the level in iron-deficient animals was 2.4-fold higher. The increase of transferrin mRNA in iron deficiency was the result of a specific induction of transferrin gene transcriptional activity as measured in isolated nuclei. This increase in transferrin gene expression resulted in a corresponding increase in serum total-iron-binding capacity. Of the other tissues examined, moderate amounts of transferrin mRNA were found in brain (83 molecules per cell) and testis (114 molecules per cell), and low levels were measured in spleen and kidney. The transferrin mRNA content of brain, testis, spleen, and kidney remained unchanged in iron deficiency. The small intestine had no detectable transferrin mRNA in either normal or iron-deficient rats; however, transferrin protein was present, and its level was 2-fold higher in the iron-deficient group. We hypothesize that intestinal transferrin is synthesized in the liver and is delivered to the gut via the bile. Consistent with this idea, bile transferrin content was found to be elevated in iron deficiency and appeared to be sufficient to account for intestinal transferrin levels. In addition, treatment of plasma transferrin with bile caused an acidic shift in its isoelectric-focusing behavior so that it comigrated with intestinal transferrin.

The human transferrin gene: 5' region contains conserved sequences which match the control elements regulated by heavy metals, glucocorticoids and acute phase reaction

Transferrin is a major plasma protein that transports iron to proliferating cells throughout the body. A clone containing the 5' region of the human transferrin gene has been isolated and characterized. A 14 kb EcoRI fragment was identified that contained the first 8 exons of the transferrin gene and 3.6 kb of its 5' flanking region. Conserved sequences identical or homologous to regulatory elements responding to heavy metals, glucocorticoid receptor and a putative acute phase reaction signal were identified in the 5'flanking region and intron 1. Also, the regulatory region of the transferrin gene contains a 14-bp sequence which closely matches sequences found in the interleukin-2 and gamma-interferon genes. All three genes are expressed by T lymphocytes before proliferation. A secondary loop structure similar to that proposed for the ovotransferrin gene can be formed by sequences in the 5' untranslated region of the transferrin mRNA.

The influence of glucocorticoid on albumin synthesis and its messenger RNA in rat in vivo and in hepatocyte suspension culture

Corticosteroids are known to stimulate the synthesis of a number of liver-specific proteins. The reports regarding the effect of glucocorticoid on albumin synthesis in vivo and in vitro are controversial. In an attempt to determine the mechanism by which glucocorticoid exerts its influence on hepatic albumin synthesis and to find an explanation for the conflicting data, we have studied the effect of dexamethasone disodium phosphate on albumin synthesis and albumin messenger RNA as determined by the molecular hybridization technique in hepatocytes in rat in vivo and in suspension culture. In hepatocyte suspension culture, addition of 0.48 microM dexamethasone in medium at zero time led to a significant increase (20%) in incorporation of labeled precursor into albumin as compared to control experiments; this was accompanied by a maintainance of the initial level of full-length albumin mRNA for a 9 h period. In hepatocytes cultured without dexamethasone in the medium there was a progressive loss of albumin mRNA content. Despite this finding, dexamethasone was not able to increase the albumin mRNA content in hepatocyte to a level higher than the initial value. Moreover, administration of this hormone either intraperitoneally or intravenously into rats did not lead to enhanced cell-free albumin synthesis or to an increased level of albumin mRNA. These findings suggest that glucocorticoid does not play an essential role in the regulation of albumin synthesis in vivo. In vitro, however, glucocorticoid leads to a preservation of the initial level of albumin mRNA and thus plays a role in the control of spontaneous dedifferentiation of liver cells in culture.

Simplified analytical methods for the measurement of the synthesis rate of plasma proteins in vivo by the [14C]carbonate method

We describe a method for obtaining the specific activity of 14C in urea, essential in the measurement of the synthesis rate of a plasma protein in vivo, which is simpler than the original procedure. The principle is the measurement of 14CO2 and NH4+ separately, after incubation with urease. A simple alteration gives samples of 13CO2 for mass spectrometry. The 'recoveries' of 14C and 13C in urea were invariably between 90 and 96% and the CV was 3%.

The influence of glucocorticoid on the fibrinogen messenger RNA content of rat liver in vivo and in hepatocyte suspension culture

The plasma concentration of fibrinogen, one of the major acute-phase proteins produced by the liver, increases during the acute-phase response as a result of enhanced synthesis in liver. Since adrenal-cortical hormones have been thought to have a key role in the regulation of the fibrinogen synthesis, fibrinogen-polypeptide mRNA sequences were determined in the present study, by using a specific complementary-DNA probe, in RNA fractions obtained from rat hepatocytes exposed to glucocorticoids in vitro (hepatocyte suspension cultures) and in vivo. Maximal induction of the fibrinogen-polypeptide mRNA (to 400% of the control value) was found in vitro at 0.1 microM-dexamethasone after 9 h of incubation. The same magnitude of induction was obtained with 20 microM-cortisol or 60 microM-corticosterone. In contrast with the findings in vitro, no induction of the fibrinogen-polypeptide mRNA was observed in the liver at various times after injection of different doses of glucocorticoids into rats. These results suggest that more complex regulatory mechanisms are involved and that glucocorticoids are not the sole regulatory factors in vivo in the enhanced synthesis of fibrinogen during the acute-phase response.

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.

Acute effects of ethanol intake on albumin and total protein synthesis in free and membrane-bound polyribosomes of rat liver

Controversial results have been reported in the last few years concerning the effects of ethanol on hepatic protein synthesis. In most of the studies no distinction has been made between the synthetic capabilities of the polyribosomes and the secretory product of labelled protein by the hepatocytes. In order to assess the influence of a single feeding of ethanol on the synthesis of albumin and total protein by the polyribosomes of rat liver, free and membrane-bound polyribosomes were isolated quantitatively from rats given 4--8 g ethanol per kg body weight 3--5 h before killing. The following results were obtained: (1) No difference was found in yield and size of free and membrane-bound polyribosomes isolated from control and ethanol-treated rats. The abilities to synthesize albumin and total protein were also equal for polyribosomes from both groups. (2) Addition of 1% ethanol to the incubation mixture of protein synthesis lowered albumin and total protein synthesis by 20%. No effect was observed with 0.5% ethanol. (3) Cell sap prepared from ethanol-treated rats contains a factor or factors which stimulate protein synthesis (10--15%). (4) The albumin mRNA sequence content was not changed in free and membrane-bound polyribosomal RNA fractions of ethanol-treated rats as compared to the control animals.

The effects of dexamethasone on metabolic activity of hepatocytes in primary monolayer culture

The effects of dexamethasone on multiple metabolic functions of adult rat hepatocytes in monolayer culture were studied. Adult rat liver parenchymal cells were isolated by collagenase perfusion and cultured as a primary monolayer in HI/WO/BA, a serum free, completely defined, synthetic culture medium. Cells inoculated into the culture medium formed a monolayer within 24 hr. Electron microscopy showed that the cells in primary culture had a fine structure identical to liver parenchymal cells in vivo, including the observation of desmosomes and bile canaliculi in intercellular space. There was significant gluconeogenesis by the cells 24 hr postinoculation but it had decreased markedly by 48 hr. There was a marked induction of tyrosine aminotransferase (TAT) by dexamethasone, which was maintained for up to 72 hr postinoculation of cells. The transport of alpha-aminoisobutyric acid into the cells in monolayer culture was stimulated by dexamethasone and was dependent on the concentration of dexamethasone. Albumin synthesis and secretion by the cells was measured by a quantitative electroimmunoassay. Albumin production was shown to increase linearly over an incubation period of 24 to 48 hr postinoculation. Dexamethasone depressed the albumin synthesis. The effects of dexamethasone are slow, and at times require more than 6 hr to show variation from the control, indicating that dexamethasone is not a single controlling hormone. Possibly it functions in a cooperative and coordinating role in the regulation of cell metabolism.

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.

Effects of bacterial endotoxin and corticosteroids on plasma concentrations of alpha 2 macroglobulin, haptoglobin and fibrinogen in rats

Bacterial endotoxin injected into rats resulted in increased plasma concentration of alpha 2 macroglobulin, haptoglobin and fibrinogen. Cortisone acetate injected i.m. by itself was sufficient to increase the plasma concentration of haptoglobin by 54% and to a lesser extent the concentrations of the other two proteins. When cortisone acetate and/or cortisol succinate were injected simultaneously with varying doses of endotoxin, the effects of the corticosteroid differed for each plasma protein. Doubtless because of the effect of cortisone by itself the slope of the dose-response relationship for haptoglobin was greatly reduced. In contrast to this the slope for alpha 2 macroglobulin was reduced and that for fibrinogen was unaffected. These findings suggest that, if effects due to endogenous corticosteroids are to be avoided, increases in plasma fibrinogen will serve best as indicators of stimulation of the acute-phase response. Since, however, the relative increase of alpha 2 macroglobulin due to the lowest dose of endotoxin was much greater than that of fibrinogen, increases in concentration of the former protein represent the most sensitive indication of the acute-phase response. Consideration of the responses in individual rats has made possible division into those with more or less than average increases for all 3 plasma proteins and those showing irregular responses. Especially in the group which had received the lowest dose of endotoxin, a much larger number than would be expected on a random basis was found to respond regularly with either more or less than average increases for all 3 proteins.

Fibrinogen synthesis in serum-free hepatocyte cultures: stimulation by glucocorticoids

Fibrinogen synthesis was investigated in cultures of chicken embryo hepatocytes initiated and maintained in chemically defined, serum-free medium. 11-Hydroxy glucocorticoids caused a 3-fold stimulation of fibrinogen synthesis. Half-maximal stimulation was achieved with 1 nM corticosterone or hydrocortisone, as compared with only 0.1 nM dexamethasone. Increased fibrinogen production in the presence of these glucocorticoids was characterized by a 4-hr delay in onset, a sensitivity to actinomycin D, and a requirement for the continuous presence of the steroid. Crossed immunoelectrophoresis permitted analysis of the simultaneous effects of glucocorticoids on the synthesis of more than 20 plasma proteins secreted in culture. The absence of an effect on the synthesis of most of these proteins was in sharp contrast to the 3-fold increase in fibrinogen production. Sera from a variety of animals also stimulated an increase in fibrinogen synthesis that was similar in degree but less specific than that due to glucocorticoids and that partially masked the response of the cells to the steroid hormones. The presence of an anticoagulant in the medium was found to be necessary for detection of the fibrinogen secreted in culture. Although insulin was routinely included in the chemically defined medium, the cells synthesized fibrinogen and responded to glucocorticoids in the absence of hormonal supplementation of the medium. These findings are consistent with the thesis that variations in glucocorticoid levels contribute to the regulation of fibrinogen production in the intact animal.

[The regulation of serum albumin in physiological and pathological conditions (author's transl)]

12 g of albumin are synthesized daily by the bound polyribosomes of all human liver cells together, corresponding to 10% of the intravascular albumin mass. The cell is producing a precursor albumin. During secretion albumin is liberated by splitting of a small peptide. Only 40% of the total body albumin is located intravascularly. 12g of albumin are degraded or excreted daily, 30% of it by the liver, the kidneys and the gastrointestinal tract. The main site of albumin catabolism is unknown. Albumin with a half-life of about 20 days is degraded at a constant fractional catabolic rate. The absolute rate of degradation varies depending on the plasma content. This mechanism allows an effective regulation of the serum albumin level. The fractional catabolic rate, however, is not completely fixed. It is slowly reduced if the serum albumin content is markedly reduced as in protein deficiency, the blind loop syndrome, cirrhosis, nephrosis, and diseases of the gastrointestinal tract. Infusion of albumin increases the fractional catabolic rate slowly. This must be taken in consideration substitution albumin in chronic diseases. The shift from the extravascular to the intravascular compartment is a short-term regulatory mechanism. The regulation of synthesis and degradation are independent from each other. The molecular mechanism of regulation of synthesis and degradation are unknown, partially due to inadequate methods.

Plasma protein synthesis by isolated rat hepatocytes

A system of preparation of rat hepatocytes with extended viability has been developed to study the role of hormones and other plasma components upon secretory protein synthesis. Hepatocytes maintained in minimal essential medium reduced the levels of all amino acids in the medium except the slowly catabolized amino acids leucine, isoleucine, and valine, which steadily increase as the result of catabolism of liver protein. Although the liver cells catabolize 10-15% of their own protein during a 20-h incubation, the cells continue to secrete protein in a linear fashion throughout the period. The effects of insulin, cortisol, and epinephrine on general protein synthesis, and specifically on fibrinogen and albumin synthesis, have been tested on cells from both normal rats and adrenalectomized rats. Cells from normal animals show preinduction of tyrosine amino transferase (TAT), having at the time of isolation a high level of enzyme which shows only an increase of approximately 60% upon incubation with cortisol. In contrast, cells from adrenalectomized animals initially have a low level of enzyme which increases fourfold over a period of 9 h. The effects of both epinephrine and cortisol on protein synthesis are also much larger in cells from adrenalectomized animals. After a delay of several hours, cortisol increases fibrinogen synthesis sharply, so that at the end of the 20-h incubation, cells treated with hormone have secreted nearly 2.5 times as much fibrinogen as control cells. The effect is specific; cortisol stimulates neither albumin secretion nor intracellular protein synthesis. The combination of cortisol and epinephrine strongly depresses albumin synthesis in both types of cells. Insulin enhances albumin and general protein synthesis but has little effect on fibrinogen synthesis.

Factors affecting incorporation of (14C) leucine into albumin and transferrin by the liver in the postnatal rat

The mechanisms responsible for the increase in incorporation of radioactive amino acid into albumin, transferrin and total soluble liver protein which occurs in the immediate postnatal period in the rat was investigated in rats delivered surgically in the last 2 days of gestation. The in vivo incorporation of [14C]leucine into the proteins in the liver was low at birth, but increased rapidly during the first half hour after delivery and then more gradually during the subsequent 4.5 h. Neonatal adrenalectomy had no effect on this pattern of results. Intraperitoneal administration of an amino acid supplement had little effect on [14C]leucine incorporation immediately after birth but increased incorporation at 0.5 h and eliminated the second phase of rising incorporation values between 0.5 and 5 h. The in vitro incorporation of 14C into albumin, transferrin and total protein by slices of the liver from animals immediately after delivery was as great as with slices from animals 5 h after delivery. It is concluded that the initial increase in synthesis of proteins in the liver in the first 0.5 h after delivery is probably due to an increase in the supply of metabolic energy due to improved oxygenation of the rats and that the slower increase in protein synthesis between 0.5-5.0 h results from an improved supply of amino acids to liver cells. It is unlikely that changes in the secretion of adrenal hormones in involved.

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.

A plasma protein fractionation procedure for use in studies of protein metabolism

A two-step method for the separation of five different plasma proteins on a preparative scale, which is capable of being extended to allow the separation of other plasma proteins, is described. The proteins separated were fibrinogen, two alpha(1)-glycoproteins, albumin and transferrin. The alpha(1)-glycoproteins were characterized in terms of electrophoretic mobility, ultracentrifugal and immunological characteristics. By using this method, it was shown that a single sample of plasma could be fractionated to yield purified proteins in sufficient quantity to simultaneously measure the synthesis of the two alpha(1)-glycoproteins, albumin and transferrin in the rat with McFarlane's technique (McFarlane, 1963; Reeve et al., 1963; McFarlane et al., 1965).