Glutamine synthetase induction in chick embryo retina monolayers

Induction of glutamine synthetase (GS) by cortisol has been shown to occur in monolayer cultures of cells obtained by enzymatic dissociation of retinas from 8- and 12-day-old chick embryos with papain (0.1%) or trypsin (0.25%). Although essentially sigle cells when plated, monolayers obtained by enzymatic dissociation show significant aggregation by 4–6 h. Monolayers prepared by mechanical dispersion (cells forced through successively smaller gage needles) are minimally inducible, perhaps owing to poor viability in such cultures. Storage at 4°C for 24 h prior to treatment with cortisol significantly elevated both basal GS activity and inducibility in whole (but not in monolayer) retina cultures.     

Glutamine synthetase localization in cortisol-induced chick embryo retinas

We report here for the first time, in chick retina, Muller cell localization of glutamine synthetase (GS) activity by an immunohistochemical technique, in agreement with previous reports of glial localization of this enzyme in rat brain and retina. Age-dependent changes in the endogenous enzyme activity as well as cortisol-induced changes in GS activity, both in ovo and in vitro, measured biochemically, reflect the changes observed by staining.     

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.     

Glutamine synthetase induction in embryonic neural retina. Interactions of receptor-hydrocortisone complexes with cell nuclei.

In the neural retina of the chick embryo, hydrocortisone (HC) elicits differential gene expression resulting in the induction of glutamine synthetase (GS), which is an enzyme marker of differentiation in the retina. The relationship between nuclear binding of receptor-hydrocortisone (R-HC) complexes and GS induction was investigated in cultures of retina tissue from 12-day chick embryos. The number of HC binding sites in the cytoplasm was estimated as 1650+/-200 per retina cell; there are approximately 1500+/-100 acceptor sites for R-HC per retina nucleus. GS induction in the retina became detectable only after R-HC bound to more than 40% of the nuclear acceptors sites; increased binding coincided with higher induction levels, until complete site saturation was attained; Proflavine, which blocks preferentially and completely GS induction in the retina by interfering in the nucleus with the enzyme-inducing action of the hormone, reduced nuclear binding of R-HC by only 20%; thus, only part of the R-HC that binds in the nucleus appears to be directly involved in eliciting the induction of GS. Within one hour after exposure of the retina to an inducing dose of HC, there was translocation of HC and HC-receptors (as R-HC complexes) from the cytoplasm into the nucleus and saturation of nuclear accepegan to decline; in 12 h, it was reduced to 50% of the initial saturation level. Since, during this time, the enzyme activity to increase, persistence of the induced state depends on association of the hormone with only a portion of the sites in the nucleus to which it can bind. The decrease in the amount of bound HC in the nuclei of induced cells was accompanied by an increase in the level of HC receptors in the cytoplasm. About 50% of this increase could be prevented by cycloheximide; this suggests that the reappearance of HC receptors in the cell cytoplasm may be due, at least in part, to de novo synthesis of HC receptors.     

Proteome profiling of embryo chick retina

Background  

Little is known regarding the molecular pathways that underlie the process of retinal development. The purpose of this study was to identify proteins which may be involved in development of retina. We used a proteomics-based approach to identify proteins that are up- or down-regulated during the development of the embryo chick retina.     

Glutamine synthetase in cultured whole retinas from the embryonic chick

Glutamine synthetase (GS) activity is enhanced in cultured whole retinas when a 72 h incubation at 37°C is preceded by storage at 4°C for 2–24 h. This enhancement occurs even in the absence of glucocorticoids and is maximal in retinas from 11 to 14 d embryos. In comparison, cortisol-induced increases in retinal GS activity at 37°C are optimal in retinas from 8 to 12 d embryos. This study, using cycloheximide (an inhibitor of protein synthesis) and cordycepin (an inhibitor of RNA synthesis), indicates that both protein and RNA synthesis are required for the 4°C storage enhancement of GS activity. The necessary RNA synthesis occurs within the first 48 h following transfer to 37°C and does not require concomitant protein synthesis. Uridine uptake, but not incorporation into trichloroacetic acid-precipitable material, is increased by initial 4°C storage when compared with whole retina controls incubated at 37°C for the total time. In contrast, both uptake and incorporation of amino acids are increased in 4°C-stored retinas for as long as 72 h subsequent to transfer from 4 to 37°C. This suggests that enhancement of GS activity may arise from a combination of elevated general protein synthesis and specific messenger-RNA synthesis following 4°C storage.     

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.     

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.     

Proteoglycan biosynthesis by chick embryo retina glial-like cells

In this report we present biochemical evidence that purified cultures of chick embryo retina glial-like cells actively synthesize heparan sulfate (HS) and chondroitin sulfate/dermatan sulfate (CS/DS) proteoglycans as well as hyaluronic acid. Glial-like cell cultures were metabolically labeled with [3H]glucosamine and 35SO4, and the medium, cell layer, and substratum-bound fractions were analyzed separately. Proteoglycans were characterized according to charge, apparent molecular size, and glycosaminoglycan (GAG) composition and were found to be differentially distributed among the cellular compartments. HS was the predominant GAG overall and was the major species found in the cell layer and substratum-bound fractions. CS/DS was also present in each fraction and comprised the largest proportion of GAGs in the medium. The major GAG-containing material resolved into three different size classes. The first, found in the cell layer and substratum-bound fractions, contained both CS/DS and HS and was of large size. A second, intermediately sized class with a higher CS/DS:HS ratio was found in the medium. The smallest class was found in the cell layer fraction and comprised HS, most likely present as free GAG chains. In addition, each fraction contained hyaluronic acid. Characteristics of these macromolecules differ from those produced by purified cultures of chick embryo retina neurons and photoreceptors in terms of size, compartmental distribution, and presence of hyaluronic acid.     

Glutamine synthetase enhances the clearance of extracellular glutamate by the neural retina

Clearance of synaptic glutamate by glial cells is required for the normal function of excitatory synapses and for prevention of neurotoxicity. Although the regulatory role of glial glutamate transporters in glutamate clearance is well established, little is known about the influence of glial glutamate metabolism on this process. This study examines whether glutamine synthetase (GS), a glial-specific enzyme that amidates glutamate to glutamine, affects the uptake of glutamate. Retinal explants were incubated in the presence of [(14)C]glutamate and glutamate uptake was assessed by measurement of the amount of radioactively labeled molecules within the cells and the amount of [(14)C]glutamine released to the medium. An increase in GS expression in Müller glial cells, caused by induction of the endogenous gene, did not affect the amount of glutamate accumulated within the cells, but led to a dramatic increase in the amount of glutamine released. This increase, which was directly correlated with the level of GS expression, was dependent on the presence of external sodium ions, and could be completely abolished by methionine sulfoximine, a specific inhibitor of GS activity. Our results demonstrate that GS activity significantly influences the uptake of glutamate by the neural retina and suggest that this enzyme may represent an important target for neuroprotective strategies.     

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.     

Glutamine synthetase activity in the developing secondary palate and induction by dexamethasone

Glutamine synthetase (EC 6.3.1.2) (GS) and glutamyltransferase (EC 2.3.2.1) (GT) specific activity were examined in developing A/Jax and C57BL/6J (C57) mouse fetal secondary palates. In addition, the induction of palatal GS was also examined after maternal injection of dexamethasone. Palatal GT activity was uniformly higher in A/J than C57 palates with both strains showing highest activity late on day 13 of gestation and a drop in activity by early day 14. In contrast, A/J palatal GS activity peaked transiently late on day 13, dropped by early day 14 and remained lower throughout the remaining period of palatal development. Palatal GS activity in C57 mouse fetuses, although failing to show a discrete transient peak of activity, remained at a constant elevated level from early day 13 to late day 14 and did not decrease until day 15 of gestation. These elevated levels of palatal GS and GT activity correspond to the gestation period of maximal palatal glycoconjugate biosynthesis. Thus, palatal GS activity may play an important regulatory role in the synthesis of these macromolecules. A/J and C57BL/6J mice exhibit different susceptibilities to glucocorticoid-induced cleft palate. However, maternal administration of a non-teratogenic dose of dexamethasone on either late day 12 or late day 13 resulted in a dramatic stimulation of both A/J and C57 fetal palatal GS but not GT activity when assay 18 h later. A/J palatal tissue responded to dexamethasone with greater induction of palatal GS activity than enzyme activity in C57 palates. Palatal GS, sensitive to glucocorticoid stimulation, may thus be an important link in expressing hormonal control of normal palatal differentiation.     

Neural induction and regionalisation in the chick embryo.

Induction and regionalisation of the chick nervous system were investigated by transplanting Hensen's node into the extra-embryonic region (area opaca margin) of a host embryo. Chick/quail chimaeras were used to determine the contributions of host and donor tissue to the supernumerary axis, and three molecular markers, Engrailed, neurofilaments (antibody 3A10) and XlHbox1/Hox3.3 were used to aid the identification of particular regions of the ectopic axis. We find that the age of the node determines the regions of the nervous system that form: young nodes (stages 2-4) induced both anterior and posterior nervous system, while older nodes (stages 5-6) have reduced inducing ability and generate only posterior nervous system. By varying the age of the host embryo, we show that the competence of the epiblast to respond to neural induction declines after stage 4. We conclude that during normal development, the initial steps of neural induction take place before stage 4 and that anteroposterior regionalisation of the nervous system may be a later process, perhaps associated with the differentiating notochord. We also speculate that the mechanisms responsible for induction of head CNS differ from those that generate the spinal cord: the trunk CNS could arise by homeogenetic induction by anterior CNS or by elongation of neural primordia that are induced very early.     

Hormonal regulation of fatty acid synthetase in chick embryo liver.

Fatty acid synthetase activity in chick embryonic liver is negligible compared to that in newly hatched, fed chicks. The enzyme activity is prematurely induced 5–50-fold in 20-day-old embryos and in newly hatched chicks by the administration of insulin, hydrocortisone, growth hormone, glucagon or dibutyryl cyclic AMP. The induction of the enzyme activity is blocked by the administration of cycloheximide, indicating that new protein synthesis is required. Immunochemical titrations of different enzyme preparations from 5-day-old chicks, adult chicken and various inducer-treated embryos gave an identical equivalence point, indicating that the changes in synthetase activity after hormonal induction in embryos are related entirely to changes in content of enzyme. The increase in liver synthetase content after administration of insulin, glucagon or dibutyryl cyclic AMP is directly related to an increase in the rate of synthetase synthesis. The induction of the synthetase activity by suboptimal doses of glucagon or cyclic AMP is potentiated by the phosphodiesterase inhibitory theophylline. There is a very rapid decay of synthetase activity, with a half-life of about 4 h after elevation to higher levels following administration of insulin, glucagon or dibutyryl cyclic AMP. Glucagon and dibutyryl cyclic AMP induction of the synthetase activity is observed early in the embryonic development, whereas insulin induction is noted 2 days before hatching. Insulin, glucagon and cyclic AMP are potentially capable of altering the levels of glycolytic intermediates which may be involved in the induction of synthetase.