STUDIES ON THE RELATIONSHIP BETWEEN GABA SYNTHESIS AND PROTEIN SYNTHESIS IN BRAIN

Abstract— The synthesis of γ-aminobutyric acid (GABA) in mouse brain was decreased by treatment of the animals with pyridoxal phosphate- γ-glutamylhydrazone, an inhibitor of glutamate decarboxylase in vivo. Under these experimental conditions the following parameters were studied: (1) the incorporation of labeled leucine in vivo , into protein of brain subcellular fractions; (2) the brain polysome profile; (3) the incorporation of labeled leucine into protein in vitro , in ribosomal preparations isolated from brain tissue. In other experiments, GABA synthesis was also decreased in brain cortex slices by preincubation with aminooxyacetic acid. The incorporation of [³H]leucine or [¹⁴C]leucine into protein in these slices was studied, and samples from the proteins were subjected to acrylamide-sodium dodecylsulfate gel electrophoresis. Radioactivity was counted in slices of the gel. The results of the experiments in vivo and in vitro indicate that the previously reported decrease of protein synthesis induced by an inhibition of GABA synthesis affects proteins of all subcellular fractions and all populations of protein as separated by gel electrophoresis. The polysome profile from brains of mice with decreased GABA synthesis was similar to that of control mice. This result differs from that found when brain protein synthesis is inhibited by dopamine and serotonin.     

NUCLEAR CHROMATIN PROTEINS FROM RABBIT CEREBRUM, CEREBELLUM AND LIVER: SYNTHESIS AND PHOSPHORYLATION

Abstract— In order to investigate synthesis and phosphorylation of the various fractions of nuclear proteins. [³H]leucine and [³²P] phosphate incorporation were studied with tissue slices in vitro. Cerebral cortex and cerebellum were used to delineate the similarity and dissimilarity within CNS, and liver was taken to compare the extraneural organ. There were significant differences in [³H]leucine incorporation into nuclear proteins among those tissue sources examined, while [³²P]phosphate incorporation showed very similar results among them. Although the acidic chromatin protein demonstrated high activity in each tissue source for both synthesis and phosphorylation, 0.14M-NaCl soluble protein showed the activity as high as or even higher than the acidic chromatin protein. Both [³H]leucine incorporation and [³²P]phosphate incorporation were relatively low in histone. When the acidic chromatin protein was further fractionated with SDS-acrylamide gel electrophoresis, significant difference was found between CNS tissue and liver for synthesis and phosphorylation. However, considerable difference was also observed even between cerebral cortex and cerebellum. The present investigation demonstrated complicity and diversity of nuclear chromatin proteins in different organs, not only for their protein constituents but also for their synthesis and phosphorylation.     

Protein turnover in photoreceptor cells of isolated Limulus lateral eyes

Abstract— A system was devised for the study of protein turnover in isolated lateral eyes of Limulus . In eyes incubated in a medium containing L-[³H]leucine, radioactivity of the fraction soluble in trichloroacetic acid increased steadily during 8 h. Amino-acid incorporation into proteins was investigated by scintillation counting of trichloroacetic-acid precipitates and by radioautography. At least 89% of the incorporation was inhibited by puromycin and 86% by emetine, an inhibitor of cytoplasmic protein synthesis. Label accumulated preferentially in the rhabdomes, which contain the visual pigment. Radioautography indicated that labeled protein, probably synthesized in the cytoplasm, was distributed in the microvilli of the photoreceptor cells in a diffuse pattern. In contrast to in vivo results, the photoreceptor cells in isolated eyes were labeled to a greater extent in light than in the dark. These different kinetics of labeling were both explained by the hypothesis that light increased the rate of degradation of proteins (particularly opsin) in the visual cells.     

Membrane morphogenesis in retinal rod outer segments: inhibition by tunicamycin

Isolated Xenopus laevis retinas were incubated with 3H-labeled mannose or leucine in the presence or absence of tunicamycin (TM), a selective inhibitor of dolichyl phosphate-dependent protein glycosylation. At a TM concentration of 20 micrograms/ml, the incorporation of [3H]mannose and [3H]leucine into retinal macromolecules was inhibited by approximately 66 and 12-16%, respectively, relative to controls. Cellular uptake of the radiolabeled substrates was not inhibited at this TM concentration. Polyacrylamide gel electrophoresis revealed that TM had little effect on the incorporation of [3H]leucine into the proteins of whole retinas and that labeling of proteins (especially opsin) in isolated rod outer segment (ROS) membranes was negligible. The incorporation of [3H]mannose into proteins of whole retinas and ROS membranes was nearly abolished in the presence of TM. Autoradiograms of control retinas incubated with either [3H]mannose or [3H]leucine exhibited a discrete concentration of silver grains over ROS basal disc membranes. In TM-treated retinas, the extracellular space between rod inner and outer segments was dilated and filled with numerous heterogeneously size vesicles, which were labeled with [3H]leucine but not with [3H]mannose. ROS disc membranes per se were not labeled in the TM-treated retinas. Quantitative light microscopic autoradiography of retinas pulse-labeled with [3H]leucine showed no differences in labeling of rod cellular compartments in the presence or absence of TM as a function of increasing chase time. These results demonstrate that TM can block retinal protein glycosylation and normal disc membrane assembly under conditions where synthesis and intracellular transport of rod cell proteins (e.g., opsin) are not inhibited.     

Effects of Monensin on Assembly of Po Protein into Peripheral Nerve Myelin

Abstract: The ionophore monensin has been used in a variety of systems to block secretion of glycoproteins or assembly of glycoproteins into membranes. We examined the effects of monensin on assembly of the Po glycoprotein into PNS myelin, and compared this agent with the glycosylation inhibitor tunicamycin in our system. Sciatic nerves from 9-day-old rat pups were sliced and incubated in vitro . Electron microscopy of the Schwann cells in slices incubated with monensin revealed extensive swelling of the Golgi complex. Incubation with 10⁻⁷ M monensin inhibited total protein synthesis by about 20% and fucose incorporation into protein about 35%. Following isolation of myelin, proteins were separated by sodium dodecyl sulfate gel electrophoresis. Monensin inhibited the appearance of Po in myelin, while causing its accumulation in a denser membrane fraction. In addition, a slightly faster-migrating species of P_o labeled with both [³H]fucose and [¹⁴C]glycine was observed in all fractions. Assembly of basic proteins into myelin was not affected. Preincubation with 10 μg/ml tunicamycin for 30 min prior to incubation with [³H]fucose and [¹⁴C]glycine for 2 h resulted in a 65% decrease in [³H]fucose incorporation into P_o, and the appearance of a new [¹⁴C]glycine-labeled peak that migrated in the region of the 23K protein reported by Smith and Sternberger. [³H]Fucose incorporation was inhibited earlier, and to a greater extent, than protein synthesis. Our results show that processing of the P_o glycoprotein is sensitive to both monensin and tunicamycin, and that monensin partially blocks assembly of P_o into myelin.     

Phorbol Ester Binding Sites in the Fish Retina: Correlation with Stimulation of Endogenous Phosphorylation and Protein Kinase C Activation

Abstract: The injection of phorbol esters into the eyes of dark-adapted teleost fish can mimic light effects in the retina and induces corresponding synaptic plasticity of horizontal cells (HCs). It is therefore very likely that protein kinase C (PKC) mediates light-induced synaptic plasticity. In the present study, we investigated the distribution of PKC, the phorbol ester receptor, in isolated HCs and in the whole retina by using tritiated phorbol 12,13-dibutyrate ([³H]PDBu). The binding characteristics analyzed for HC homogenates and retinal homogenates revealed that [³H]PDBu binding is time dependent, specific, saturable, and reversible. Binding sites in HCs displayed a dissociation constant of 11.5 n M and a total number of 2.8 pmol/mg of protein. Autoradiography revealed that [³H]PDBu labeling is present in all retinal layers, including HCs, where it is associated with the somata. Furthermore, the treatment with PDBu strongly affected the endogenous phosphorylation of several membrane, cytosolic, and HC proteins and led to PKC activation as measured by H1 histone phosphorylation. In HCs, the treatment with PDBu in particular affected the amount of ³²P incorporated into a group of phosphoproteins (68, 56/58, 47, 28, and 15 kDa) that were recently shown to be affected by light adaptation. These proteins might therefore be considered as important components of the observed morphological and physiological synaptic plasticity of HCs in the course of light adaptation.     

Characterization, Localization, and Biosynthesis of an Interstitial Retinol-Binding Glycoprotein in the Human Eye

Abstract: Human eyes contain an M_r 135K retinol-binding protein that is analogous to interstitial retinol-binding protein (IRBP) in the subretinal space of bovine eyes. It is a glycoprotein, because it binds ¹²⁵I-concanavalin A, ¹²⁵I-wheat germ agglutinin and ¹²⁵I- Lens culinaris hemagglutinin. It does not bind Ricinus communis agglutinin I. After desialation, it binds Ricinus communis agglutinin I, but loses its capacity to bind wheat germ agglutinin. These observations, coupled with the known specificities of these lectins, suggest that at least one of the oligosaccharide chains is a sialated, biantennary complex type containing fucose. Both by direct analysis of dissected ocular tissues and by immunocytochemistry it was shown that human interstitial retinol binding protein is an extracellular protein that is confined predominantly to the subretinal space. Monkey retinas incubated in vitro in medium containing [³H]leucine were shown to synthesize and secrete this protein into the medium, a conclusion that was confirmed by immunoprecipitation with an immunoglobulin fraction prepared from rabbit antibovine IRBP serum. Virtually no other labeled proteins were detectable in the medium. It is concluded that interstitial retinol-binding protein meets many of the requirements for a putative transport protein implicated in the transfer of retinol between the pigment epithelium and retina during the visual cycle, and that the neural retina may play an important role in regulating its amount in the subretinal space.     

THE SYNTHESIS OF MYELIN IN DEVELOPING RAT BRAIN

Abstract— —The synthesis of myelin proteins has been studied in the grey and white matter slices of developing rat brain by measuring the incorporation of [³H]lysine and [¹⁴C]arginine into polypeptide. The incorporation was sensitive to cycloheximide and puromycin at 1 mM concentration. Developing rat optic nerve slices, free of retinal ganglion cells, were able to synthesize myelin basic and proteolipid proteins, but rat retinal preparation failed to synthesize myelin basic protein. Rabbit retinae were able to synthesize myelin basic and proteolipid proteins. Significant activity of the myelin marker enzyme 2',3'-cyclic nucleotide-2'-phosphodiesterase has been found in the rabbit retina but not in rat retina. The results presented in this communication suggest that myelin proteins in the rat CNS are synthesized by the oligodendroglial cells and that neurons probably do not participate.     

Light-induced Changes in the Pattern of Protein Synthesis during the Early Stages of Greening of Etiolated Maize Leaves

The effect of light on protein synthesis during the early stages of greening of etiolated maize (Zea mays) leaves was studied using double labeling with leucine and fractionation of proteins by gel filtration and acrylamide gel electrophoresis. The incorporation of labeled leucine into a relatively small number of plastid proteins is effected within the first 30 to 60 minutes of illumination. These proteins do not accumulate with time. When illumination is prolonged, additional proteins are effected.     

Characterization of an Initiating Cell-Free Protein Synthesis System Derived from Rabbit Brain

Abstract: Protein synthesis in the brain is known to be affected by a wide range of treatments. The detailed analysis of the mechanisms that are involved would be facilitated by the development of cell-free translation systems derived from brain tissue. To date, brain cell-free systems have not been fully characterized to demonstrate a capacity for initiation of translation. The following criteria were utilized to demonstrate that a cell-free protein synthesis system derived from rabbit brain was capable of initiation in vitro : (a) sensitivity of cell-free translation to the initiation inhibitor aurintricarboxylic acid (ATA); (b) binding of [³⁵S]Met-tRNA_f to 40S and 80S initiation complexes; (c) incorporation of labeled initiation methionine into high-molecular-weight proteins; and (d) the association of labeled exogenous mRNA with polysomes. The optimum conditions for amino acid incorporation in this system were 4 mM-Mg²⁺, 140 mM-K⁺, and pH 7.55. Incorporation was dependent on the addition of ATP, GTP, and an energy-generating system. Cell-free protein synthesis reflected the normal process, since a similar spectrum of proteins was synthesized in vitro and in vivo. This initiating cell-free translation system should have wide application in the analysis of the mechanisms whereby various treatments affect protein synthesis in the brain.     

Lactate Dependent Protein Synthesis in Round Spermatids from Rat Testes

Lactate (20 mM) markedly increased protein labeling of round spermatids (steps 1–8) from rat testes. The stimulatory effect of lactate on protein labeling was also observed to some degree in spermatocytes and late spermatids (steps 13–16), but not in Leydig cells and 7 day-old testis cell suspznsions. In the lactate-treated spermatids, 51 % of the labeled proteins was found in the water-soluble fraction (the 105,000 × g 1 hr supernatant), whereas only 21%, in the control cells. The labeled proteins did not break down for at least 90 minutes in the presence of lactate. Actinomycin D (20 μg/ml) had no effect on [³H]leucine incorporation into the water-soluble proteins of spermatids, while labeling of the water-insoluble proteins (the 105,000 × g 1 hr pellet) was decreased by 23%.
These findings suggest that the round spermatids might be the most susceptible for the lactate-induced stimulation of protein synthesis among various types of testicular cells, and that lactate increases the synthesis of water-soluble proteins which may be regulated in the translational level of protein synthesis.     

Phosphorylation and nucleotidylation of proteins in Rhodocyclus gelatinosus

Abstract Cells of Rhodocyclus gelatinosus were radioactively labeled by addition of [³²P]orthophosphate, [¹⁴C]inosine or [¹⁴C]orotic acid during anaerobic growth on citrate in the light. Protein analysis by two-dimensional gel electrophoresis and autoradiography of the gels revealed the presence of several radioactively labeled protein species in this organism. The molecular mass and the isoelectric point of all these proteins were determined. Treatment of the ³²P-labeled protein fractions with acid and alkaline phosphatase clearly showed that at least 8 protein species were modified by phosphorylation. The experiments conducted with the ¹⁴C-labeled precursors of purines and pyrimidines indicated the presence of 4 protein species which were modified by a compound containing a purine and phosphate, and a single protein simultaneously being labeled with pyrimidine and phosphate.     

Brain Slice Protein Degradation and Development

Protein degradation rates were measured in brain slices prepared from rats of various ages. This was done by adding the protein synthesis rate, determined by incorporation of a labeled precursor, and the net protein degradation rate, determined by measuring the changes with time of total free amino acids. These rates are about 30% higher than those previously calculated from data on protein synthesis rates and protein accumulation rates in vico. The protein degradation rates in brain slices diminish with age; i.e., 2-day cerebellum > 2-day cerebral hemisphere > 12-day cerebral hemisphere > young adult cerebral hemisphere. Protein degradation rates in slices from young brain are initially slightly higher than protein synthesis rates, resulting in a small net degradation with time. Unlike slices from adult brain, the protein degradation rates in slices from young brain decline only modestly with time for as much as 100 min of incubation. The characteristics of protein degradation in brain slices from young animals are roughly similar to some of the data calculated for protein degradation in vivi. suggesting that this system may prove useful for studying factors which control or affect brain protein degradation.     

Retinoic Acid-Induced Cartilage Resorption

The addition of retinoic acid to fetal rat bones in culture induces the release of proteoglycans followed by cartilage resorption. In this system retinoic acid markedly suppressed ³H-leucine and ³H-mannose incorporation into acid-precipitable macromolecules, and specifically changed the ³H-leucine incorporation pattern as revealed by gel electrophoresis. Tunicamycin, which selectively inhibits glycosylation of the asparagine residues in proteins, prevented the cartilage cell degradation in response to retinoic acid. Inhibitors of DNA synthesis did not affect the retinoic acid-induced changes indicating that cell division was not required for the cartilage degradation processes induced by retinoic acid. In consideration of our previous and present demonstrations that retinoic acid-induced cartilage resorption required RNA, protein, and glycoprotein synthesis and specifically changed the protein synthesis pattern, we suggest that retinoic acid may exert its action by altering gene expression.     

Accumulation of phosphatidic acid in microsomes from propranolol-treated retinas during short-term incubations

Abstract: The pool size and synthesis of phosphatidic acid derived from [2-³H]glycerol were studied in bovine whole retinas and subcellular fractions. Microsomal preparations from retinas incubated with [2-³H]glycerol displayed the highest percentage labeling of phosphatidic acid at 5 min of incubation; labeling decreased rapidly thereafter. In drug-treated retinas,0.5 m M propranolol increased the endogenous content of phosphatidic acid and stimulated [2-³H]glycerol labeling in whole retina and microsomal and postmicrosomal supernatant fractions. This effect was observed during short-term incubations and was reversible. In pulse-chase experiments, 60 min of reincubation greatly reduced the labeling effect, although propranolol still enhanced phosphatidic acid labeling. At the same time, endogenous phosphatidic acid accumulated and reincubation without propranolol reversed the effect. During accumulation, the amount of palmitate increased and that of oleate decreased, whereas the relatively high level of docosahexaenoate in phosphatidic acid remained unchanged. It was concluded that this propranolol-induced effect is due to cationic amphiphilic drug activity in the endoplasmic reticulum that results in a partial inhibition of phosphatidic acid degradation and a stimulation of its de novo synthesis. Hence, net synthesis of phosphatidic acid can be assessed in the retina during short-term incubation with propranolol.     

The Synthesis and Release of [3H-Tyrosine1]Methionine5-Enkephalin from Guinea Pig Brain Slices

Abstract: Stores of methionine-enkephalin were labelled on the N -terminal by incubation of whole brain slices with [³H]tyrosine (10 °Ci/ml). The ³H radioactivity corresponding to the position of authentic Met-enkephalin after extraction on Amberlite XAD₂ and separation by thin-layer chromatography was taken as an index of synthesis. Maximal incorporation of the labelled tyrosine into Met-enkephalin was attained after 4 h of incubation at 37°C and was inhibited in the presence of 10 μ M cycloheximide. Isolated nerve terminals failed to incorporate any [³H]tyrosine. The labelled compound had opiatelike activity and consisted of the same five amino acids as an authentic standard. Incubations with leucine aminopeptidase indicated that the labelled tyrosine was on the N -terminus and removal of this tyrosine resulted in loss of opiate-like activity. The incorporation of [¹⁴C]glycine, selected as an alternative precursor, was consistent with de novo synthesis and not N -terminal exchange. A radioimmunoassay was also used to quantify the amount of labelled Met-enkephalin. KCl (50 m M ) elicited a Ca²⁺-dependent release of the synthesised [³H]Met-enkephalin from whole brain slices and also from isolated nerve terminals. The release of Met-enkephalin radioimmunoactivity paralleled that of [³H]met-enkephalin. Preliminary investigations have suggested that carbamyl choline inhibited this release and its effect was partially reversed by atropine.     

ON THE MECHANISM OF OUABAIN INHIBITION OF SYNAPTOSOME PROTEIN SYNTHESIS

Abstract— Ouabain (200μ m ) inhibited incorporation of radiolabelled leucine or glycine into the protein of neonatal synaptosome fractions but had minimal effect on preparations from adult rats. Leucine uptake into synaptosomes was rapid but not influenced by 200μ m -ouabain in contrast to ouabain inhibition of [¹⁴C]glycine and [¹⁴C]γ-aminobutyric acid uptake. Ouabain blocked the Na⁺ -dependent (stimulated) component of synaptosome fraction protein synthesis in the presence of 25m m -K⁺. Ouabain inhibition was not alleviated by addition of ADP or ATP. 100μ m -atractylate failed to influence [³H]leucine uptake or incorporation. Synergistic inhibition by ouabain was observed with the cycloheximide-sensitive component of protein synthesis and the chloramphenicol sensitive phase. Increasing the medium Ca²⁺ concentration stimulated protein synthesis and this stimulated component was inhibited by ouabain. Ouabain inhibition was associated with decreasing intraterminal K⁺ concentration and [K]_i was linearly related to the protein synthesis rate in control and ouabain treated preparations.     

THE EFFECT OF DIABETES, INSULIN AND WALLERIAN DEGENERATION ON LEUCINE METABOLISM OF ISOLATED RAT SCIATIC NERVES

Abstract– ¹⁴CO₂ production and ¹⁴C incorporation into proteins was studied in isolated rat sciatic nerves during incubation with 0.1 mM-[1-¹⁴C]leucine. Rats were made diabetic with streptozotocin. Nerves from diabetic rats incubated with glucose oxidized more [¹⁴C]leucine than controls. This difference was abolished in the presence of insulin (1 mU/ml). The effects of diabetes and insulin on leucine oxidation could not be demonstrated in the absence of glucose. Insulin stimulated the incorporation of [¹⁴C] from leucine into proteins by nerves from controls and diabetic rats.
Nerves undergoing Wallerian degeneration showed a marked increase in DNA content and stimulated incorporation of [¹⁴C]leucine into proteins. ¹⁴CO₂ production from leucine proceeded at 75% of the rate observed in intact nerves. Neither insulin nor diabetes affected leucine metabolism in degenerating nerves.
Neither the extracellular space nor the concentration of free amino acids were significantly different in nerves obtained from control and diabetic rats, except for lower glutamine content in the latter.
In vitro leucine metabolism of nerves is affected by diabetes, insulin and the integrity of the axon. The Schwann cell is suggested as a possible site of the observed changes in leucine metabolism.     

Protein Turnover in Retina

Abstract: Rabbit retinas were exposed in vitro to 0.5-h pulses of [³H]leucine or [¹⁴C]Ieucine. Some retinas were harvested promptly after labeling to measure synthesis. These were combined, in double-labeling experiments, with retinas that had been returned to unlabeled medium for a subsequent 1 h or 3.75 h to measure degradation. All of the proteins were solubilized, and separated according to size by gel electrophoresis. The gels were cut into 95 slices, and each slice was differentially counted. The amount of protein in the slice was estimated from the Coomassie blue staining, and its molecular weight from the distribution of molecular weight (MW) standards. Turnover rates of the various sizes of proteins were calculated from these data using certain well-defined assumptions. Retinal protein contained about 32 ± 10³ nmol of polypeptide per g, with a median MW of 27,000. Total synthesis was at the rate of 103 nmol/g of protein/h, with the most rapid synthesis in the 33,000–43,000 MW range, at 2 nmol/g/h for every 1000 increment in MW. Protein renewal averaged 0.52%/h, but varied directly (p < 0.0001) with MW, so that proteins of 10,000 MW were being renewed at about 0.1%/h and proteins of 140,000 MW at about 1.4%/h. Taken together, the measurements of fractional renewal and the measurements of degradation of the newly synthesized proteins demonstrated that each slice contained proteins with markedly different breakdown coefficients, and provided enough information to characterize the proteins in the slice in terms of a fast and a slow subgroup. This analysis indicated that: breakdown coefficients varied much more than rates of synthesis and were therefore the prime determinant of the amount of each protein that was present; as MW increased, breakdown coefficients of the long-lived proteins increased (p < 0.0001), accounting in major part for the correlation between size and turnover; most staining bands were due to proteins with peculiarly long lifespans; the proteins with the slowest turnover of all appeared to be histones: there was an unusually rapid synthesis of a 138,000 MW polypeptide with a moderately short half-life (about 3 h).