THE EFFECT OF ISCHAEMIA AND RECIRCULATION ON PROTEIN SYNTHESIS IN THE RAT BRAIN

Abstract— Rats were subjected to cerebral compression ischaemia for 15min and were subsequently recirculated with blood for periods up to 3 h. In vivo incorporation of intravenously administered L-[1–¹⁴C]valine into total brain proteins was found to be severely inhibited (about 20% of controls) after 45 min of recirculation. After 3 h, protein synthesis had increased, the specific radioactivity of proteins then being about 40% of controls. The post-ischaemic inhibition of protein synthesis was accompanied by a breakdown in polyribosomes and a concomitant increase in ribosomal subunits. In vitro incorporation of L-[1–¹⁴C]phenylalanine by a postmitochondrial supernatant system derived from animals subjected to 15 min ischaemia and 15 min recirculation was also severely reduced and showed, in contrast to control animals, no response to the addition of a specific inhibitor of polypeptide chain initiation (Poly(I)). Together with the in vivo accumulation of ribosomal subunits this indicates a block in peptide chain initiation during the early stages of recirculation.
Polyribosomes from animals subjected to 15 min ischaemia without recirculation showed a normal rate of in vitro protein synthesis which was inhibited by Poly(I) to a similar extent as polyribosomes from control animals. These results suggest that the post-ischaemic inhibition in chain initiation develops during the early stages of recirculation rather than during the ischaemic period itself.     

IN VITRO PROTEIN SYNTHESIS ON FREE POLYRIBOSOMES ISOLATED FROM THE DEVELOPING MOUSE BRAIN

Abstract— Free polyribosomes were isolated at three ages (newborn, 2 weeks and 8 weeks) from the developing mouse brain. All three preparations were found to be highly polyribosomal in nature and were essentially identical with respect to their chemical composition and sedimentation properties. An estimate of the sedimentation coefficients of the first seven members of these polysome preparations yielded S °_20,w values of 76, 114, 146, 174, 196, 217 and 236. All three preparations were found to be very active when employed in in vitro protein synthesizing systems. An age-dependent response to the concentration of K⁺ was observed in the activities of the in vitro protein synthesizing systems. Optical K⁺ concentrations for the 0, 2 and 8 week old systems were 30, 50 and 65 mm, respectively. No such age dependence was observed when NH⁺₄ was used as the sole monovalent cation, with all systems exhibiting maximal activity at 50mm-NH⁺₄. The highest in uitro activities were consistently observed (at all three ages) when NNH⁺₄ was employed as the sole monovalent cation. Under optimal conditions, the newborn in vitro protein synthesizing system was observed to be approx 40% as active as either the 2 week or the 8 week systems which were equivalent in activity. The reduced activity of the newborn system appeared to be a function of both the polyribosomal and pH 5 enzyme preparations.     

FETAL DEVELOPMENT: THE EFFECTS OF MATURATION ON IN VITRO PROTEIN SYNTHESIS BY MOUSE BRAIN TISSUE

—The elucidation of the translational regulatory events which function during the critical fetal and neonatal period is an important prerequisite to our understanding of normal, as well as abnormal, brain growth and differentiation. Brain cell suspensions and cell-free homogenates were employed to study the protein synthetic activity during the maturation of fetal- neural tissue. The results clearly demonstrated that while neural tissue from 1-day postnatal mice was 10 times more active in protein synthesis than brain tissue from adult mice, the former was many fold less active in translational events than fetal neural tissue from 13-day post-zygotic mice. Fetal polypeptide synthetic activity was found to decrease from the 13th day to the 19th day post-zygotic. This decrement in the translational activity was not due to amino acid availability or pools, or to differences, quantitatively or qualitatively, in polysome concentrations. The enhanced rate of protein synthetic activity measured with neural tissue from 13-day post-zygotic mice was shown to be due to an increase in rate of protein synthesis and not to an enhanced rate of protein degradation.     

PROTEIN SYNTHESIS IN NORMAL AND SCRAPIE MOUSE BRAIN

Damage to the brain as a result of an intracerebral injection of physiological saline does not appreciably affect the rate of protein synthesis in mouse brain. The in vivo and in vitro incorporation of labelled amino acids into mitochondria and their in vivo incorporation into nuclei, microsomes, nerve ending particles, myelin and cell sap were compared in normal and scrapie-affected mice. No significant differences were found.     

INCREASE OF BRAIN TRYPTOPHAN BY ELECTROCONVULSIVE SHOCK IN RATS

—ECS markedly increased tryptophan and 5-hydroxyindoleacetic acid levels in brain. Brain serotonin and plasma tryptophan levels were unaffected.     

THE EFFECT OF dl-ALLYLGLYCINE ON POLYAMINE AND GABA METABOLISM IN MOUSE BRAIN

Abstract— dl -Allylglycine, a potent inhibitor of glutamate decarboxylase in vivo when given intraperitoneally, causes a marked decrease in brain GABA concentration and at the same time a dramatic increase in l -ornithine decarboxylase activity and a simultaneous decrease in S -adenosyl- l -methionine decarboxylase activity followed by putrescine accumulation. It does not, however, alter the degree of GABA formation from putrescine. The timing of the recovery of glutamate decarboxylase activity after the injection of dl -allylglycine is concomitant with that of the GABA concentration, indicating that it is probably glutamate decarboxylase that is solely responsible for making up the GABA deficit caused by dl -allylglycine, and that the changes in polyamine metabolism are associated in some indirect way with the recovery process.     

EFFECT OF OXOTREMORINE ON THE APPARENT REGIONAL TURNOVER OF ACETYLCHOLINE IN MOUSE BRAIN

The effect of oxotremorine (1 mg kg^-1 i.p.) on the steady state concentration of acetylcholine (ACh) and choline (Ch) and the transformation of radioactive choline ([³H]Ch) was studied in different brain regions of the mouse following death by microwave irradiation of the head. Oxotremorine significantly increased the concentration of endogenous ACh in the cortex and hippocampus and of endogenous Ch in the cortex. Pretreatment with atropine (5 mg kg^-1 i.p.) prevented the increase in ACh. The biosynthesis of radioactive ACh ([³H]ACh) was decreased in all brain regions. Atropine (5 mg kg^-1) pretreatment counteracted this effect of oxotremorine (1 mg kg^-1), while methylatropine (5 mg kg^-1) had no effect except in the striatum. A calculation of the apparent turnover rate of ACh showed that oxotremorine (1 mg kg^-1) decreased the turnover in the cortex, hippocampus, midbrain. and striatum.     

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.     

DNA SYNTHESIS IN THE GLIAL CELLS OF SCRAPIE-AFFECTED MOUSE BRAIN

Radioautographic techniques have been used to study the incorporation of [³H]-thymidine into the DNA of glial cells in normal and scrapie-affected mouse brain. Some differences were seen in the morphological distribution and also in the size distribution of labelled nuclei in sagittal sections of normal and affected brain. Counts of the total number of labelled nuclei per sagittal section showed a progressive decline from 50 to 15 per section in normal brain over the 4-month experimental period. However, in scrapie-affected brain the number increased markedly to 120 per section 5-6 weeks after inoculation and stayed at this level for the remaining 9-10 weeks of the incubation period. The significance of these results in relation to the pathogenesis of scrapie is discussed.     

REGULATION OF PROTEIN SYNTHESIS IN DEVELOPING MOUSE BRAIN TISSUE: IN VITRO BINDING OF TEMPLATE RNA TO BRAIN RIBOSOMES

Abstract— Ribosomes, isolated from brain tissue of mice of various ages, were tested for their ability to participate in cell-free protein synthesis and to bind polyuridylic acid. Although protein synthesis was markedly reduced by ribosomal preparations obtained from increasingly older animals, no significant differences could be measured with respect to template RNA binding. Similar binding properties were also measured with ribosomal subunits purified from young and mature brain cell ribonucleoprotein particles. In addition, no differences could be detected in the relative firmness of template RNA binding that could explain the maturation-dependent loss in ribosomal activity.     

CHANGES IN THE PROTEIN COMPOSITION OF MOUSE BRAIN MYELIN DURING DEVELOPMENT

Abstract— Myelin was isolated from the brains of mice at various ages by a procedure involving a final purification on a continuous CsCl gradient. Myelin protein accumulated throughout development, increasing from 0.25 mg of protein/brain at 8 days of postnatal age to 3.5 mg of protein/brain at 300 days, although the rate of accumulation was greatest at about 21 days of age. Quantitative studies of the protein composition of these samples were carried out, utilizing discontinuous polyacrylamide gel electrophoresis in buffers containing sodium lauryl sulphate. Mouse brain myelin, contained (in order of increasing molecular weight) two basic proteins, an uncharacterized doublet, proteolipid protein, and a group of high molecular weight proteins. There were marked changes in the quantitative distribution of these proteins with increasing postnatal age. The basic protein fraction of total myelin protein increased from about 18 per cent at 8 days to 30 per cent at 300 days of age. Proteolipid protein increased even more dramatically, from 7 to 27 per cent in the same time interval. These chemical studies were correlated with ultrastructural investigations, both of the developing myelin sheath in situ and the isolated myelin obtained from mice of various ages. A hypothesis, relating the observed changes in protein composition of myelin during development to its mode of formation, is developed. Another subcellular fraction, separated from myelin, by virtue of its greater density in a CsCl gradient, was also studied. It was a vesicular, membranous fraction present at a level of 0.35 mg of protein/brain at all ages and was related to myelin in terms of protein composition.     

THE NATURE OF THE INCREASED RATE OF DNA SYNTHESIS IN SCRAPIE-AFFECTED MOUSE BRAIN

—In vivo studies have been made of the incorporation of radioactive thymidine into acid insoluble components of control and scrapie-affected mouse brain. Experiments with hot trichloroacetic acid extracts of brain and with purified preparations of DNA have confirmed that there is an increased rate of DNA synthesis in scrapie brain which is entirely associated with nuclei. No increase was found in the rate of DNA synthesis in cytoplasmic fractions of scrapie brain. Hydroxyapatite chromatography of heat denatured and renatured DNA suggests that in scrapie brain there is a similar increase in the rates of synthesis of the poorly, moderately and highly reiterated (i.e. satellite) species of nuclear DNA. Experiments involving brain dissection indicate that the increased rate of DNA synthesis in scrapie does not take place exclusively in the subependymal layer of the lateral ventricles. From these and previously reported studies using radioautographic techniques it is concluded that the increased DNA synthesis in scrapie brain is not associated specifically with cells undergoing mitosis.     

PROTEIN SYNTHESIS IN THE BRAIN OF OCTOPUS VULGARIS, LAM

Abstract— The process of protein synthesis in the brain of Octopus vulgaris Lam has been examined after systemic administration of [³H]leucine and upon incubation of the tissue in sea water containing the radioactive precursor. After injection of [³H]leucine in the branchial heart, the radioactivity of the TCA-soluble fractions of the three main brain divisions reached a maximum in about 30 min and decreased thereafter, while incorporation into the protein fractions was complete in approx. 2 h. Per unit wet weight the radioactivity of brain proteins was higher than that of most other organs. In vitro the rate of incorporation of [³H]leucine in the protein fraction of the optic lobe remained low for more than 1 h, but increased several fold thereafter. Preincubation of the tissue in sea water abolished the lag period. Similar effects were observed in the vertical lobe as well as in the optic lobe of young and adult octopuses but not in the white body, a non-nervous organ. The process of protein synthesis in the optic lobe is markedly inhibited by puromycin, cycloheximide and chloramphenicol. Electrophoretic analysis on polyacrylamide gels indicated that the soluble proteins labelled in vitro and in vivo are similar.     

THE EFFECT OF ELEVATED AMINO ACIDS ON AMINOTRANSFERASE LEVELS IN BRAIN AND LIVER OF THE MOUSE

Abstract— Adult mice were fed standard diets that were enriched with selected amino acids, i.e. 3% methionine, 6% valine, or 8% lysine. These diets caused the following changes in the amino acid pool of the brain measured at 7 and 21 days. The high methionine diet resulted in 50-fold higher levels of methionine and cysteine and somewhat lower levels of serine and glutamine. The valine and lysine-enriched diets also caused 2- to 4-fold increases in valine and lysine contents of brain, respectively. In spite of the large changes in amino acid levels, however, there were essentially no changes in aspartate: α-ketoglutarate, alanine: α-ketoglutarate, ornithine: α-ketoglutarate, methionine: α-ketoglutarate, and the branched chain aminotransferase activities of brain 3, 10, and 21 days after the onset of the dietary regimen. In contrast, these diets produced significant changes in some of these enzyme activities in liver. Changes in liver included a 2-fold increase in ornithine and alanine aminotransferase activities with the methionine-enriched diet. Liver ornithine aminotransferase activity also increased slightly in animals fed the valine-enriched or lysine-enriched diet.     

THE EFFECT OF FASTING ON THE METABOLISM OF 5-HYDROXYTRYPTAMINE AND DOPAMINE IN THE BRAIN OF THE MOUSE

Abstract— The turnover of 5-hydroxytryptamine in the forebrain and of dopamine in the striatum was studied in mice fasted for 20 h. Such mice showed an increased tissue concentration of 5-hydroxyindoleacetic acid in the forebrain and an increased accumulation of this acid after probenecid. Fasted mice also showed a higher concentration of homovanillic acid in the striatum than fed mice. However, the administration of probenecid produced a smaller increase in homovanillic acid concentration in fasted than in fed mice. The decay of dopamine following α-methyl- p -tyrosine was reduced in fasted mice at 2 h, but not at 1 h or 6 h after administration of the inhibitor. The possibility that fasting increases the activity of some dopaminergic neurones while decreasing the activity of others is considered. The existence of a pool of homovanillic acid at a site within the striatum where the probenecid-sensitive transport is not effective is postulated.     

EFFECT OF BRAIN CORTEX PHOSPHOLIPIDS ON ADENYLATE-CYCLASE ACTIVITY OF MOUSE BRAIN

Intravenous injection of a sonicated dispersion of bovine brain phospholipids results in a significant change in both NaF-dependent and dopamine dependent adenylate cyclase activity. High dosage of phospholipids inhibits the dopamine dependent, but not the NaF dependent, adenylate cyclase activity. The stimulation of cyclase activity is accompanied by an increased level of cAMP in mice brains. Treatment with haloperidol abolishes the increase in cAMP. Among individual phospholipids, phosphatidylserine is the most active component for inducing the activation of DA-dependent adenylate cyclase activity.