Infulence of hormones and medium composition on the degradation of phosphoenolpyruvate carboxykinase (GTP) and total protein in Reuber H35 cells

Receptor/gene-mediated pharmacodynamic effects of methylprednisolone on phosphoenolpyruvate carboxykinase regulation in rat liver

Phosphoenolpyruvate carboxykinase (PEPCK) is the rate-limiting enzyme for gluconeogenesis. To investigate underlying mechanisms of corticosteroid (CS) action in regulating glucose, temporal patterns of hepatic PEPCK gene expression, enzyme activity, and cAMP content were examined in adrenalectomized rats receiving acute and chronic methylprednisolone (MPL) treatments. After single MPL intravenous doses, PEPCK mRNA showed a fast increase, reaching a maximum at around 0.75 h, which was followed by an immediate decline to below baseline after 4 h, an apparent acute tolerance/rebound phenomenon. However, PEPCK enzyme showed continuous hyperactivity for over 72 h. This may be the result of generation of cAMP, an important inducer of PEPCK activity, which peaked at around 6 h. During 7-day subcutaneous infusion of MPL, PEPCK mRNA showed profiles consistent with single-dose results, whereas PEPCK activity increased to a comparable maximum followed by a slow decline. However, the extent of cAMP induction was markedly higher during infusion, which could be attributed to amplification of cAMP synthesis and/or a stabilizing effect of MPL on cAMP degradation. A pharmacokinetic/pharmacodynamic model was developed based on receptor/gene mechanisms of CS action. It successfully described the dual effects of MPL on regulating PEPCK message and the post-transcriptional control by cAMP. Our results exemplify the importance of the extent and duration of steroid exposure in mediating pharmacological effects. The model provides quantitation of multiple controlling factors regulating PEPCK and presents insights into its function in glucose metabolism.

Regulation of intracellular protein degradation in IMR-90 human diploid fibroblasts

Human diploid fibroblasts (IMR-90) regulate their overall rates of proteolysis in response to the composition of the culture medium and the ambient temperature. The magnitude and, in some cases, the direction of the response depend on the half-lives of the cellular proteins that are radioactively labeled and the time chosen for measurements of protein degradation. Fetal calf serum, insulin, fibroblast growth factor, epidermal growth factor, and amino acids selectively regulate catabolism of long-lived proteins without affecting degradation of short-lived proteins. Fetal calf serum reduces degradative rates of long-lived proteins and is maximally effective at a concentration of 20%, but the effect of serum on proteolysis is evident only for the first 24 hr. Insulin inhibits degradation of long-lived proteins in the presence or absence of glucose and amino acids in the medium, but is maximally effective only at high concentrations (10(-5) M). Amino acid deprivation increases degradative rates of long-lived proteins for the first 6 hr, but then decreases their catabolism for the subsequent 20 hr. Lowered temperature is the only condition tested that significantly alters degradative rates of short-lived proteins. Although cells incubated at 27 degrees C have reduced rates of degradation for both short-lived and long-lived proteins compared to cells at 37 degrees C, lowered temperature reduces catabolism of long-lived proteins to a greater extent.

The relationship between the insulin content and inhibitory effects of bovine colostrum on protein breakdown in cultured cells

Protein Degradation in ten mammalian cell lines is markedly inhibited by small amounts of bovine colostrum. This response is consistent with the growth-promoting activity of colostrum that has been reported previously. Fractionation of colostrum on DEAE cellulose showed that most of the inhibitory activity against protein breakdown on H35 cells coeluted with insulin. Insulin concentrations in different batches of bovine colostrum ranged from 0.67 nM to 5.7 nM, approximately 100-fold higher than in blood. The sensitivity of protein breakdown in H35 or MH1C1 hepatoma lines to these colostrum samples was proportional to their insulin concentrations and could largely be accounted for by the amount of insulin present. Removal of insulin from colostrum by means of a protein A-anti-insulin antibody affinity column was accompanied by a loss of the ability of colostrum to inhibit protein breakdown in H35 or MH1C1 cells. However, in IMR90 fibroblasts, a cell line with a similar sensitivity to colostrum as the two hepatomas but very insensitive to insulin, protein breakdown was still inhibited by the insulin-free colostrum. These results suggest that, whereas the effect of bovine colostrum in H35 or MH1C1 cells is actually a response to insulin, different growth factors in colostrum account for the inhibition of protein breakdown in other cell lines.

Lectins mimic insulin in the induction of tyrosine aminotransferase

Various lectins were found to induce tyrosine aminotransferase in H-35 rat hepatoma cells grown in monolayer culture. Wheat germ agglutinin gave a maximal induction of tyrosine aminotransferase 6 hours after its addition. The induction time course was similar to that elicited by insulin. Fourteen micrograms of wheat germ agglutinin per milliliter gave half-maximal enzyme induction and 50 micrograms per milliliter gave the maximal response. The induction of tyrosine aminotransferase by wheat germ agglutinin was additive with the induction by either dexamethasone or dibutyryl adenosine 3',5'-monophosphate, but was not additive with the tyrosine amino transferase induction by insulin. Wheat germ agglutinin also mimicked insulin in the inhibition of cellular protein degradation in the absence of serum. The insulin-like effects of lectins should be considered in lectin-mediated manipulations such as agglutination.

Regulation of hepatic phosphoenolpyruvate carboxykinase (GTP). Role of dietary proteins and amino acids in vivo and in the isolated perfused rat liver

The effect of protein feeding and the addition of amino acids on the activity of hepatic phosphoenolpyruvate carboxykinase (GTP : oxalacetate carboxylyase (transphosphorylating), EC 4.1.1.32) was investigated in vivo and in the isolated perfused rat liver. Protein feeding resulted in a considerable increase in phosphoenolpyruvate carboxykinase activity within 6 h. This rise was independent of the presence of glucocorticoids. In the isolated perfused liver system amino acids per se had a small effect on phosphoenolpyruvate carboxykinase activity and led to an increase by 20% when glucocorticoids were present, but resulted in a rise by 100% when glucocorticoids plus dibutyryl cyclic AMP were added to the perfusion medium. The effect of amino acids in the presence of dibutyryl cyclic AMP could also be observed in the liver of glucocorticoid-deprived rats. Cycloheximide, a translational inhibitor, totally blocked all effects of amino acids on enzyme activity. These results indicate that the concentration of amino acids in the portal vein modify the regulation of phosphoenolpyruvate carboxykinase by cyclic AMP.

Suppression of myocardial protein degradation in the rat during fasting. Effects of insulin, glucose, and leucine

To study the effects of leucine, glucose, and insulin on myocardial protein degradation in fed and fasted nutritional states, we developed and validated a sensitive method for measuring rates of total protein degradation in rat isolated left atrial preparations. Fasting resulted in a progressive decrease in myocardial protein breakdown to 71% of control over a 24-hour period, with no further reduction in degradation rate between 24 and 72 hours of fasting. Insulin (100 mU/ml) suppressed atrial protein degradation by 38% in fed animals (P less than 0.001) and by 51% in fasted animals (P less than 0.001). Glucose alone had no effect on protein degradation in either nutritional state. At 5 times normal plasma levels, leucine suppressed protein breakdown by 21% in fed and by 15% in fasted animals. The decrease in degradation induced by fasting and the absence of an effect of glucose are in contrast to the behavior reported for skeletal muscle.

Role of lysosomes in protein turnover: catch-up proteolysis after release from NH4Cl inhibition

Cultured rat embryo fibroblasts, when placed in media with 10% serum containing 20 mM NH4Cl, show an inhibition of protein degradation and, concurrently, an accumulation of numerous, large vacuoles, partially filled with cellular debris. Cells placed in a serum-free media exhibit an enhanced degradation of cell protein, which is also inhibited by NH4Cl. When these cells are removed from media containing NH4Cl and placed in fresh media, the material accumulated in these vacuoles is rapidly and quantitatively released to the media in both an acid-soluble and acid-insoluble from. NH4Cl inhibits rapidly and specifically the lysosomal proteolytic mechanism, and is without effect on the basal turnover mechanism. The lysosomal proteolytic mechanism accounts for approximately 25% of protein turnover, and, at least in low density cultures, can be stimulated to levels which account for more than half of the protein turnover in the cell. The major pathway for the degradation of fast turnover proteins appears to be separate from lysosomal mechanism.

Regulation of gluconeogenesis by glucocorticoids

1. Regulation of gluconeogenic substrate supply and modulation of the gluconeogenic pathway in the liver are both important in the control of gluconeogenesis by glucocorticoids. 2. Adrenal deficiency decreases the release of gluconeogenic and other amino acids from skeletal muscle during starvation. The effect is reversed by glucocorticoid replacement. The changes in amino acid release are accompanied by similar alterations in tissue amino acid levels and are not explained by alterations in net protein breakdown. Glucocorticoids do not alter protein catabolism and cause a small inhibition of protein synthesis. The biochemical alterations underlying the changes in amino acid metabolism induced by these steroids remain to be elucidated. Glucocorticoids may also regulate the supply of gluconeogenic substrates through permissive effects on the lipolytic action of catecholamines and other hormones in adipose tissue and on the glycogenolytic action of catecholamines on skeletal muscle. 3. Glucocorticoids are required for the increases in gluconeogenesis in starvation and diabetes. Part of their action is exerted directly on the liver and appears to involve modulation of P-enlopyruvate carboxykinase levels. Glucocorticoids increase the synthesis of this enzyme apparently through effects at the level of transcription. 4. Glucocorticoids exert permissive effects on the stimulation of gluconeogenesis in the liver by glucagon and epinephrine. The steroids are not required for cAMP generation or protein kinase activation by these hormones, but appear to act by maintaining the responsiveness of certain enzymes to the effects of the cAMP and alpha-adrenergic systems. It is proposed that this involves the maintenance of a normal intracellular ionic environment.

Inhibition of basal protein degradation in rat embryo fibroblasts by cycloheximide: correlation with activities of lysosomal proteases

Rat embryo fibroblasts were grown in medium containing 14C-leucine and 3H-thymidine. After a 24-hour chase in nonlabeled medium, cultures were placed in either fresh growth medium or medium containing 10-20 microgram/ml cycloheximide. Cell monolayers were processed at daily intervals for three days. Four hours prior to processing, cultures were placed in fresh medium and the accumulation rate of trichloroacetic acid soluble 14C in the media assayed. Cycloheximide effects a progressive decrease in the fractional degradation rate of the labeled cell protein, primarily during the first 24 hours. The specific activities of cathepsin D, cathepsin B, and neutral protease correlate closely with the fractional degradation rate. Other lysosomal hydrolases show little change during this period. The activities of the lysosomal proteases approach a new steady state which is correlated with the new steady state level of protein synthesis. A model is proposed which relates the rate of protein breakdown in the cell to the level of protein synthesis. The data also suggests the possibility that subpopulations of high turnover and low turnover cells exist in these cultures.