Glutamine synthetase induction in embryonic neural retina: immunochemical identification of polysomes involved in enzyme synthesis

Light and electron microscopic immunocytochemical localization of glutamine synthetase in the superficial pineal gland of the rat

Glutamine synthetase (L-glutamate:ammonia ligase; EC 6.3.1.2), an enzyme catalysing the ATP-dependent formation of glutamine from glutamate and ammonia, was detected immunocytochemically only in glial (interstitial) cells of the superficial pineal gland of the rat. The results show the important role of pineal glial cells in the metabolism of the presumptive neurotransmitters, glutamate and gamma-aminobutyric acid (GABA) as well as in detoxification of ammonia.

Messenger RNA for glutamine synthetase. Review article

Of the various eucaryotic tissues, where glutamine synthetase (GS) mRNA and its regulation have been investigated, the induction of GS by glucocorticoids in the embryonic chick retina represents one of the systems most extensively studied. GS mRNA was first identified at the polysomal level by immunochemical precipitation of fractionated polysomes containing nascent GS chains with anti-GS gamma-globulin. The mRNA has been shown to be polyadenylated at the 3' end; on this basis, it has been partially purified from embryonic chick retina as well as from N. Crassa by chromatography on oligo(dT)-cellulose or poly(U)-sepharose and translated in cell-free protein synthesizing systems derived from wheat germ. Hormonal regulation of GS activity studied in the embryonic retina, hepatoma tissue culture cells, or in other tissues is always shown to be mediated by GS mRNA. In the retina, hydrocortisone (HC) elicits an age-related and transcription-dependent induction of GS by enhancing the level of GS mRNA in the polysomes through an increased supply of this mRNA from the nucleus. Comparative studies of three inhibitors of transcription, viz. actinomycin D, leucanthone and proflavine on the induction of GS by HC indicate that the latter inhibits GS mRNA selectively and reversibly with minimal effects on other RNA synthesis. Since proflavine acts by competing with HC-receptor binding sites in the nuclei, further studies on its interaction with the retina genome are likely to help identify the DNA sequences involved in the GS induction. In bacteria, studies on the genetics and physiology of various mutants with lesions in the structural gene for GS show that the transcription of the GS gene (gln A) is regulated both positively and negatively by GS and the product of another gene gln F. Purification of GS mRNA to homogeneity cloning of its cDNA and development of assay systems for cell-free transcription of GS are other studies likely to advance our knowledge on GS mRNA and its regulation.

Induction of glutamine synthetase in embryonic neural retina: localization in Müller fibers and dependence on cell interactions

The cellular localization of glutamine synthetase [GSase; L-glutamate:ammonia ligase(ADP)-forming), EC 6.3.1.2] induced by cortisol in the neural retina of chicken embryos was investigated by immunostaining with GSase-specific antiserum and indirect immunofluorescence. In organ cultures of retina tissue, and in the retina in vivo, hormone-induced GSase was found to be confined only to the Müller fibers (retinoglia). Also, in mature chicken retina, which contains a very high level of GSase, the enzyme was detected solely in Müller fibers. In short-term monolayer cultures of dispersed embryonic retina cells, there was no GSase induction and no immunodetectable increase in enzyme level. However, when the dispersed cells were reaggregated and they restituted retinotypic cell associations, GSase could be induced and it was localized in Müller fibers. The results suggest that, in addition to the hormonal stimulus, contact-dependent interactions between Müller glia cells and retina neurons are involved in the mechanism of GSase induction in the retina.

Binding of specific ATP citrate lyase and fatty acid synthetase antibodies to heavy populations of rat liver polysomes

The polysome fractions involved in the synthesis of the rat-liver inducible lipogenic enzymes, ATP citrate lyase and fatty acid synthetase, were identified by their binding of radioiodinated specific antibodies to enzyme. Both of these populations of specific polysomes were shown to be markedly heavier than specific polysomes involved in albumin synthesis. The quanity of antibody bound to the lipogenic enzyme-related polysomes was markedly affected by the dietary status of the animal. A dietary regimen which induced ipogenesis resulted in a tenfold increase in the hepatic activities of these enzymes found in normally fed animals. The radioactivity bound to hepatic polysomes of induced rats was likewise greater than tenfole higher, presumably reflecting an increase in the number of polysomes active in enzyme synthesis. The fasting state resulted in lower hepatic enzyme activity than normal and correspondingly less binding of ATP citrate lyase and fatty acid synthetase antibodies to the heavy polysomes of the sucrose gradient.

The development of inducibility for glutamine synthetase in embryonic neural retina: inhibition by BrdU

The hydrocortisone-mediated induction of glutamine synthetase (GS) in the neural retina of the chick embryo is a characteristic and unique feature of differentiation of this tissue. The induction involves genomic activity elicited by the inducer resulting in synthesis and accumulation of the enzyme. We describe correlations between the growth of embryonic retina tissue in vivo and in vitro and the development of its inducibility for GS, and demonstrate that this development proceeds through two phases: competence-acquisition phase (before the 7th day of development), and maturation phase. BrdU applied for 24 h to retinas of 5-day embryos irreversibly suppresses the development of induction-competence. However, BrdU does not affect the progressive maturation of inducibility when applied to retinas that already are fully induction-competent (8 days and older). The short treatment with BrdU of 5-day retinas also causes defective histogenesis resulting in drastic malformation of the tissue. The nature of the processes involved in competence-acquisition and in the maturation of inducibility for GS are examined. Possible mechanisms by which BrdU prevents the development of induction-competence for GS in the early embryonic retina and elicits defective histogenesis are discussed.

Effects of cytosine arabinoside on differential gene expression in embryonic neural retina. II. Immunochemical studies on the accumulation of glutamine synthetase

Cytosine arabinoside (Ara-C) elicits a significant increase in the level of the enzyme glutamine synthetase (GS) while it markedly reduces overall RNA and protein synthesis in cultures of embryonic chick neural retina. This increase was analyzed by radioimmunochemical procedures and compared with the induction of GS by hydrocortisone (HC). Accumulation of GS in Ara-C-treated retinas was found to be due to de novo synthesis of the enzyme; however, unlike the induction of GS by HC, Ara-C caused no measurable increase in the rate of GS synthesis. The results indicate that Ara-C facilitates GS accumulation largely by preventing degradation of the enzyme. Even though Ara-C inhibits the bulk of RNA synthesis in the retina, it does not stop the formation of GS-specific RNA templates. However, the progressive accumulation of these templates does not result in an increased rate of GS synthesis unless Ara-C is withdrawn from such cultures under suitable experimental conditions. Thus, it is suggested that the continuous presence of Ara-C imposes a reversible hindrance at the translational level which limits the rate of GS synthesis. The results demonstrate that the increase in retinal GS elicited by Ara-C is achieved through mechanisms which are quite different from those involved in the hydrocortisone-mediated induction of this enzyme.

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.

Absence of mRNA for casein in free polysomes of lactating ewe mammary gland

Total polysomal RNA or poly A- containing RNA extracted from free polysomes of lactating ewe mammary gland was unable to direct a significant synthesis of alpha-s- and beta-casein. Polyacrylamide gel electrophoresis of poly A- containing RNA revealed that the two major peaks of mRNA isolated from membrane-bound polysomes were not observed in mRNA isolated from free polysomes. Purified 125-I anti-alpha-s-casein could bind significantly to membrane-bound polysomes only. These data suggest that casein synthesis occurs almost exclusively on membrane-bound polysomes and that this specificity may be attributed to the presence of casein mRNAs on these polysomes and their absence from free polysomes.