Interferon suppresses glutamine synthetase induction in chick embryonic neural retina.

Two different proteins precipitable with antiserum to albumin exist in liver. One is albumin, the other is precursor albumin. Liver cells in suspension contain mainly precursor, but secrete only albumin. In subcellular fractions isolated from liver homogenate, 95.3% of anti-albumin precipitable protein in the rough endoplasmic reticulum, 51.4% in the smooth endoplasmic reticulum, 33.5% in the Golgi apparatus and 0% in the supernatant fraction was precursor albumin. The results suggest that albumin precursor is synthesized in the rough endoplasmic reticulum and converted into albumin in the smooth endoplasmic reticulum and the Golgi apparatus.     

Interferon suppresses steroid-inducible glutamine synthetase biosynthesis in embryonic chick neural retina.

Effect of chick interferon on the biosynthesis of glutamine synthetase (L-glutamate: ammonia ligase (ADP-forming), EC 6.3.1.2) was studied in the embryonic chick neural retina cultures induced for the enzyme activity by hydrocortisone. The retinal enzyme radioactively labelled with [3H]leucine was precipitated by specific antibody against the enzyme isolated from adult chick liver. The immunological determination offered evidence that the suppressive effect of interferon on the hormonal induction of the enzyme was primarily due to reduced rate of its synthesis and accumulation.     

Interferon suppresses steroid-inducible glutamine synthetase biosynthesis in embryonic chick neural retina

Effect of chick interferon on the biosynthesis of glutamine synthetase (L-glutamate: ammonia ligase (ADP-forming), EC 6.3.1.2) was studied in the embryonic chick neural retina cultures induced for the enzyme activity by hydrocortisone. The retinal enzyme radioactively labelled with [³H]leucine was precipitated by specific antibody against the enzyme isolated from adult chick liver. The immunological determination offered evidence that the suppressive effect of interferon on the hormonal induction of the enzyme was primarily due to reduced rate of its synthesis and accumulation.     

Early events in the induction of glutamine synthetase activity by hydrocortisone in embryonic chick neural retina.

Primary cultures of 10-day embryonic chick neural retinas were used to investigate early aspects of the mechanism of hydrocortisone action on glutamine synthetase activity. As little as 2 hr of hydrocortisone exposure served to initiate significant increases in the glutamine synthetase activity levels assayed after 24 hr culture. Time course studies indicated that the increase in glutamine synthetase activity observed after 24 hr in culture resulted from a two-phase rise in activity and that cycloheximide was effective in suppressing the second-phase rise. Additional inhibition studies demonstrated that the second-phase increase in enzyme activity required continuous protein synthesis during the initial 6 hr. The evidence suggests a mechanism of hydrocortisone action involving the production of a protein which is important for the induction of glutamine synthetase activity by hydrocortisone.     

Early events in the induction of glutamine synthetase activity by hydrocortisone in embryonic chick neural retina

Summary Primary cultures of 10-day embryonic chick neural retinas were used to investigate early aspects of the mechanism of hydrocortisone action on glutamine synthetase activity. As little as 2 hr of hydrocortisone exposure served to initiate significant increases in the glutamine synthetase activity levels assayed after 24 hr culture. Time course studies indicated that the increase in glutamine synthetase activity observed after 24 hr in culture resulted from a two-phase rise in activity and that cycloheximide was effective in suppressing the second-phase rise. Additional inhibition studies demonstrated that the second-phase increase in enzyme activity required continuous protein synthesis during the initial 6 hr. The evidence suggests a mechanism of hydrocortisone action involving the production of a protein which is important for the induction of glutamine synthetase activity by hydrocortisone. This work was supported by a National Science Foundation (U.S.A.) Training Grant.     

Cortisol receptors and inducibility of glutamine synthetase in embryonic retina

Glutamine synthetase (GS) is a marker enzyme for Müller glia cells in neural retina. In chick embryo retina GS begins to increase sharply on the 16th day of development, but can be precociously induced by premature supply of the inducer, cortisol, already on the 8th day. At this stage GS inducibility is low, but it increases progressively with embryonic age. We investigated whether there was a corresponding age-dependent increase of cortisol-binding molecules (cortisol receptors) and found that their level is highest in the early retina and decreases with development. In light of this inverse relationship, we examined whether functional characteristics of these receptors change with age, but detected no differences. In in vitro tests, receptors from older retina translocated cortisol into nuclei from young retina, and vice versa, with similar effectiveness. Also, cortisol receptors from liver cells (which differ from retina receptors) can translocate the hormone into retina nuclei, and vice versa. These findings indicate that translocation of cortisol receptors is neither tissue-specific or age-dependent, nor is it conditional on the total amount of receptors normally present in cells. Therefore, the age-dependent increase of GS inducibility in embryonic retina cannot be directly related to quantitative or functional differences of cortisol receptors and is evidently controlled primarily at the gene level. The very large amount of cortisol-binding molecules in early embryonic retina raises the possibility that they play some role in early differentiation of retina cells unrelated to hormone binding.     

Histogenesis and dependent glutamine synthetase inducibility in embryonic neural retina. Irreversible inhibition of differentiation by 5-bromodeoxyuridine

Young, mitotically active neural retinas from 7-day chick embryos were cultured with 5-bromodeoxyuridine (BrdU) for 8 hr or more. After this treatment, they failed to differentiate beyond the stage at which they were explanted; there was no histogenesis or increase in glutamine synthetase (GS) inducibility in intact tissues or in aggregates of dissociated cells. Normally GS can be induced in the retina with hydrocortisone as the cells cease to be mitotically active and begin showing histological organization after day 7. This inhibition by BrdU was irreversible even in the presence of excess thymidine. Overall incorporation of ¹⁴C-amino acids into protein was only slightly inhibited, and the ability of cells from treated tissue to aggregate and sort out from nonneural cell types was unaffected. Control cultures without BrdU showed considerable histogenesis and a parallel increase in enzyme inducibility. Postmitotic 10-day retinas appeared to be unaffected by BrdU. The incorporation rates of both tritiated BrdU and thymidine (dT) into DNA were 14× higher in 7- than in 10-day retinas. Simultaneous addition of excess unlabeled dT with either of the labeled nucleosides reduced their incorporation and reduced the inhibitory action of BrdU on differentiation.It is concluded that BrdU irreversibly inhibits the differentiation of retina cell surface properties involved in histogenesis and dependent cytodifferentiation without affecting already differentiated properties of the cell surface. The results support the hypothesis that histogenesis is directed by genes affecting specific cell surface properties.