Regulation of glutamine synthetase in L cells by cortisol and L-glutamine

Characterization of glutamine metabolism in two related murine hybridomas

Aspects of glutamine metabolism were examined in two related hybridomas, a high-producing line (PQX B1/2) and a low-producing line (PQX B2/2). The growth and metabolic characteristics of both cell lines were identical or very similar. During batch growth glutamine was completely exhausted from the medium and an examination of the fate of [14C]glutamine highlighted the importance of this amino acid as an energy source. The relative enzyme activities and the amount of ammonia produced during growth indicated that glutamine is oxidized preferentially via the transamination pathway. The overall rate of glutamine utilization from the growth medium was similar to the rate of [14C]glutamine uptake which suggests that transport may regulate glutamine metabolism.

Evidence for more than one mechanism of action of the glucocorticoid hormones

The data presented here provide evidence for at least two major cellular responses to the glucocorticoid hormones that do not seem to involve an interaction between the activated hormone-receptor complex and chromatin. We observed that 5mM pyridoxine in L-cell culture medium both increases the intracellular content of free pyridoxal phosphate by about 30% and decreases the glucocorticoid induction of glutamine synthetase to less than 30% of that at the normal (5 microM) concentration of the vitamin. Two other responses to the hormone-a major decrease in the polysome content of the cells and a decrease in the state of phosphorylation of ribosomal protein S6-are unaffected by the 5mM dose of the vitamin. In light of the findings of DiSorbo and Litwack ((1981) Biochem. Biophys. Res. Commun. 99, 1203-1208), pyridoxal phosphate appears to modulate the enzyme-inducing activity of dexamethasone in L-cells but not the polysome and ribosome related changes. These results are consistent with the hypothesis that certain important glucocorticoid induced responses are independent of nuclear function.

Effects of glutamine, methionine sulfone and dexamethasone on rates of synthesis of glutamine synthetase in cultured hepatoma cells

Glutamine synthetase (EC 6.3.1.2) activity of hepatoma tissue culture cells is elevated by corticosteroids and depressed by glutamine (Kulka, R.G., Tomkins, G.M. and Crook, R.B. (1972) J. Cell Biol., 54, 175--179). The transfer of cells from high (1--5 mM) to low (0.2--0.4 mM) concentrations of glutamine causes a marked increase in glutamine synthetase activity. The addition of a glutamine antagonist, methionine sulfone (1 mM) to cells suspended in high (1 mM) concentrations of glutamine also causes an increase of glutamine synthetase activity which is greater than that elicited by the transfer of cells to low concentrations of glutamine. Rates of synthesis of glutamine synthetase have been measured by radioimmunoprecipitation in hepatoma tissue culture cells incubated under various conditions. Incubation of cells with the synthetic corticosteroid hormone, dexamethasone, markedly stimulates the relative rate of glutamine synthetase biosynthesis. Glutamine, or its analogue, methionine sulfone, have no effect on the relative rate of synthesis of the enzyme. However, total protein and RNA synthesis increase markedly with increasing external glutamine concentration in the range 0--1 mM. Methionine sulfone (1 mM) inhibits the degradation of glutamine synthetase in the presence of 1 mM glutamine. The data are consistent with the conclusion that the corticosteroid, dexamethasone, elevates glutamine synthetase activity by stimulating its rate of synthesis, whereas methionine sulfone elevates glutamine synthetase activity by inhibiting the glutamine-stimulated degradation of preformed enzyme.

Age-associated changes in glutamine synthetase activity in WI-38 cells

The human fibroblast cell line WI-38 shows a gradual decline in glutamine synthetase specific activity with increasing age in culture. However, the level of functional enzyme per cell does not change with age. Heat inactivation profiles indicate that glutamine synthetase from younger cell cultures is more heat labile than that from older cultures. A possible explanation for these observations is that alterations in the glutamine synthetase molecule occur with increasing age of WI-38 cells in culture.

Optimum amino acid complement for protein synthesis by rat mammary cells in tissue culture

The amino acid requirement of rat mammary cells for milk protein synthesis was investigated in dispersed cell culture. A three-dimensional central composite design utilizing three variables (X1 = lysine; X2= methionine, valine, and arginine; X3 = isoleucine, tryptophan, threonine, phenylalanine, and histidine) at five concentrations each, was duplicated twice with mammary cells from lactating Sprague-Dawley rats. The optimum combination of amino acids for maximum milk protein synthesis from multiple regression models was X1 15.0-, X2 4.5-, and X3 1.5-fold their quantities in Eagle's minimal essential medium with leucine, tyrosine, cystine, and glutamine at the base 1-fold in the medium.

Chemically-defined medium for growth and differentiation of mixed epithelial and connective tissues in organ culture

The effect on tissue differentiation and growth in vitro of certain of the factors implicated in collagen synthesis (ascorbic acid, alpha-ketoglutarate and oxygen) and the influence of hydrocortisone was studied using organ cultures of fetal mouse mandible as a mixed epithelial and connective tissue system. Using serum-free Waymouth's MB 752/1 chemically-defined medium, addition of high levels of ascorbic acid (300mug per ml), hydrocortisone (1mug per ml) and oxygen (95%) enhanced differentiation in a number of tissues, in particular skin and appendages, tooth germs and bone, while osteoid and dentine production were noticeable promoted. It is suggested that an essential aspect of media design for organ culture involves the incorporaation of collagen-promoting factors to the in vitro enviornment particularly with regard to the controlling role implicated for collagen in a variety of biological processess.

Glutamine-stimulated modification and degradation of glutamine synthetase in hepatoma tissue culture cells

Effects of glutamine on glutamine synthetase (GS) activity of hepatoma tissue culture (HTC) cells were studied with the aid of a specific goat anti-rat GS serum. Immunodiffusion and immunoelectrophoretic tests show that rat liver GS and HTC cell GS are immunologically similar but not identical. Immunotitrations of HTC cell extracts demonstrate that in cells incubated in high concentrations (5 mM) of glutamine, a cross-reacting form of GS with a decreased enzyme-specific activity accumulates. On prolonged incubation of cells in high glutamine, there is net degradation of GS to form immunologically inactive products. Radio-immunoprecipitation experiments show that glutamine acts by accelerating the degradation of preformed GS.

Biochemical selection systems for mammalian cells: the essential amino acids

The essential amino acid requirement of cultured mammalian cells can be satisfied by 19 amino acid derivatives. This finding (a) confirms the results of animal nutritional studies and (b) identifies 19 essential amino acid derivatives and should permit the isolation of a new class of auxotrophic mutants. Five naturally occurring auxotrophic markers have been detected in this survey; namely, inability to utilize cystathionine and citrulline in Chinese hamster ovary (CHO) cells, inability to metabolize citrulline by HTC+hepatoma cells, and confirmation of Eagle's observation that KB cells can utilize homocystine in place of methionine or cystine and D-cystine in place of L-cystine.

Glutamine synthetase activity in WI-38 cells

In the presence of complete growth media (Eagle's MEM), human diploid WI-38 cells have a low level of glutamine synthetase activity. The activity could be increased by depriving the cells of exogenous glutamine; addition of hydrocortisone to either glutamine-deficient or complete medium had no effect on the acitivty of the enzyme. Cell growth ceased under conditions that enhanced glutamine synthetase activity, and hydrocortisone could not reverse this inhibition.