Experimental alcoholism in rats. Effect of acute ethanol intoxication on the in vitro incorporation of ( 3 H)leucine into neuronal and glial proteins

Abstract— Ethanol administered in vivo or in vitro during incubation of brain slices was studied with respect to its effect on brain protein synthesis. In the in vivo series the rats were given a single intraperitoneal injection of ethanol 3 h before death. Slices of cerebral cortex and liver were incubated in isotonic saline media containing [³H]leucine. Amounts of free and protein-bound radioactivity were determined. Subcellular fractions and fractions enriched in neuronal perikarya and in glial cells were prepared from cortical slices subsequent to incubation, and the specific radioactivity determined for each cell type. The incorporation of [³H]leucine into brain proteins was inhibited while incorporation into liver proteins was stimulated in ethanol-treated rats. The levels of TCA-soluble radio-activity, however, did not differ between the ethanol group and the controls. In the fractionated material from cerebral cortex, the specific radioactivity in the neuronal fraction was unaffected by ethanol, while the radioactivity in the glial fraction was significantly depressed. In vitro administration of ethanol induced a non-linear response in both brain and liver, with depression of leucine incorporation into proteins of cerebral cortex at all concentrations used. When brain slices were exposed to ethanol in vitro, in concentrations corresponding to the in vivo experiments, a similar reduction of the leucine incorporation into the glial fraction was obtained. Incorporation of leucine into subcellular fractions from whole brain cortex was also investigated. The specific sensitivity of the glial fraction to ethanol is discussed in relation to the involvement of the different cell types with transport processes in the brain.     

Cerebral lipid metabolism in experimental hyperphenylalaninaemia: incorporation of 14C-labelled glucose into total lipids

—1. Effects of the administration of phenylalanine to rats on incorporation in vivo or in vitro of [U-¹⁴C]glucose into cerebral lipids were studied during the first 5–10 days of postnatal development. In addition, the effects of added phenylalanine and its deaminated metabolites on incorporation of [U-¹⁴C]glucose by homogenates into lipids of developing rat brain were investigated. Hyperphenylalaninaemia reduced incorporation both in vivo and in vitro of [U-¹⁴C]glucose into cerebral lipids. 2. Phenylalanine or tyrosine added in vitro at concentrations equivalent to those in the brain of the hyperphenylalaninaemic rat (0-1 μmole/ml incubation medium) did not inhibit incorporation of [U-¹⁴C)glucose into lipids, although at much higher concentrations of phenylalanine (36 μumoles/ml incubation medium) slight inhibition (10 per cent) of incorporation of [U-¹⁴C]glucose into lipids was observed. 3. In contrast, the deaminated metabolites in general exerted greater inhibitory effects at lower concentrations. Phenyllactic acid, in comparison to phenylpyruvic and phenyl-acetic acid, was the most potent inhibitor of the incorporation in vitro of [U-¹⁴C]glucose into cerebral lipids. These results indicated that these metabolites of phenylalanine were the more potent inhibitors of cerebral lipid metabolism in immature animals.     

EFFECTS OF EPILEPTIC SEIZURES ON BRAIN RIBOSOMES: MECHANISM AND RELATIONSHIP TO CEREBRAL ENERGY METABOLISM

Epileptic seizures were induced electrically in rats paralyzed and ventilated with oxygen. Dissociation of brain polysomes and increase in ribosomal dimers were observed after multiple (25 or more) seizures, but were not seen after shorter treatments (up to 10 seizures). Polysomal dissociation and dimer formation occurred in vivo and were accompanied by decreased amino acid incorporation into brain proteins in cell-free systems in vitro. These events paralleled changes in brain energy reserves rather than changes in behavior.     

BIOSYNTHESIS OF RAT BRAIN PHOSPHATIDYLCHOLINES FROM INTRACEREBRALLY INJECTED CHOLINE1

Abstract— [Me-³H] Choline was injected intracerebrally into male rats and the brains immediately removed by particular procedures at regular intervals over the first 1200 s. The incorporation of radioactivity into brain phosphorylcholine, CDP-choline and phosphatidylcholines was examined and quantitated, in order to investigate the relative roles of net synthesis and base-exchange reactions for choline incorporation into lipid. The molecular subspecies of phosphatidylcholines were also examined after isotope administration. Phosphorylcholine, CDP-choline and phosphatidylcholines all became labelled as early as 5 s after the administration of labelled choline. The time course of incorporation of choline into brain lipid is biphasic with two flex points at about 20 and 120 s from the injection. The specific radioactivity of different phosphatidylcholines appears to be different at early and later intervals from injection. The suggestion is made that the base-exchange pathway for choline incorporation into lipid might be operative in vivo in early periods after administration.     

THE METABOLISM OF LEUCINE BY DEVELOPING RAT BRAIN: EFFECT OF LEUCINE AND 2-OXO-4-METHYLVALERATE ON LIPID SYNTHESIS FROM GLUCOSE AND KETONE BODIES

Abstract— The oxidation of l -[U-¹⁴C]leucine and l -[l-¹⁴C]leucine at varying concentrations from 0.1 to 5mM to CO₂ and the incorporation into cerebral lipids and proteins by brain slices from 1-week old rats were markedly stimulated by glucose. Although the addition of S mM-dl -3-hydroxybutyrate had no effect on the metabolism of [U-¹⁴C]leucine by brain slices from suckling rats, the stimulatory effects of glucose on the metabolism of l -[U-¹⁴C]leucine were markedly reduced in the presence of dl -3-hydroxybutyrate. The stimulatory effect of glucose on leucine oxidation was, however, not observed in adult rat brain. Furthermore, the incorporation of leucine-carbon into cerebral lipids and proteins was also very low in the adult brain. The incorporation of l -[U-¹⁴C]leucine into cerebral lipids by cortex slices was higher during the first 2 postnatal weeks, which then declined to the adult level. During this time span, the oxidation of l -[U-¹⁴C]leucine to CO₂ remained relatively unchanged. The incorporation in vivo of D-3-hydroxy[3-¹⁴C]butyrate into cerebral lipids was markedly decreased by acute hyperleucinemia induced by injecting leucine into 9-day old rats. In in vitro experiments, 5 mM-leucine had no effect on the oxidation of [U-¹⁴C]glucose to CO₂ or its incorporation into lipids by brain slices from 1-week old rats. However, 5 mM-leucine inhibited the oxidation of d -3-hydroxy-[3-¹⁴C]butyrate, [3-¹⁴C]acetoacetate and [1-¹⁴C]acetate to CO₂ by brain slices, but their incorporation into cerebral lipids was not affected by leucine. In contrast 2-oxo-4-methylvalerate, a deaminated metabolite of leucine, markedly inhibited both the oxidation to CO₂ and the incorporation into lipids of labelled glucose, ketone bodies and acetate by cortex slices from 1-week old rats. These findings suggest that the reduction in the incorporation in vivo of d -3-hydroxy[3-¹⁴C]butyrate into cerebral lipids in rats injected with leucine is most likely caused by 2-oxo-4-methylvalerate formed from leucine. Since the concentrations of leucine and 2-oxo-4-methylvalerate in plasma of untreated patients with maple-syrup urine disease are markedly elevated, our findings are compatible with the possibility that an alteration in the metabolism of glucose and ketone bodies in the brain may contribute to the pathophysiology of this disease.     

THE EFFECT OF MORPHINE ADMINISTRATION ON THE INCORPORATION OF [14C]LEUCINE INTO PROTEIN IN CELL-FREE SYSTEMS FROM RAT BRAIN AND LIVER

—Ribosomes isolated from the brains of rats treated with morphine in vivo were less active in promoting the incorporation of [¹⁴C]leucine into protein than ribosomes isolated from untreated rats. This inhibitory phenomenon was studied in relation to dose of morphine, time after drug administration and the pharmacological responses of hypothermia and analgesia. The inhibition of [¹⁴C]leucine incorporation into brain proteins in vitro was transient after a single injection of morphine and dose-dependent, and related to the hypothermic response, but not prevented by keeping the rats at an ambient temperature which prevented hypothermia. The incorporation of [¹⁴C]leucine into protein by liver ribosomes was also inhibited in preparations from morphine treated rats.     

Incorporation in vivo of intracisternally injected 33 P i into phospholipids of rat brain

The incorporation in vivo of intracisternally injected ³³Pⁱ into individual phospholipids of rat brain was studied at intervals ranging froml min to 8 days after injection. At 1 min after injection there was significant incorporation of “Pi into PA and the phosphoino-sitides, with the pattern of incorporation TPI > DPI > PA > PI. There was a 10-min lag period before significant labelling of the remaining phospholipids. In general, the extent of incorporation measured during the first 8 days after injection paralleled the quantity of each phospholipid in the brain, except for the values of PA and the phosphoinositides which were all higher than would be predicted by this criterion and reached maximal incorporation sooner than the other phospholipids. The possible correlation of the high metabolic activities of PA and the phosphoinositides with neuronal function, as well as the importance of short-term experiments in clarifying such relationships are discussed.     

Incorporation of [14C] ethanolamine and [3H] Methionine into phospholipids of rat brain and liver in vivo and in vitro

Comparative studies were undertaken on the in vivo and in vitro incorporation of [¹⁴C] ethanolamine, [³H] methionine and [¹⁴C] S-adenosyl-methionine into phosphatidylethanolamine (PhE) and phosphatidylcholine (PhC) of rat liver and brain. It was observed that brain can synthesize de novo PhC from PhE via the transmethylation pathway, however synthesis rates were (1) markedly lower than those of liver and (2) decreased significantly with age. In the choline-containing lipids more than 95% of the radioactivity was found in PhC. Studies on the localization of the radioactivity in PhC following the intracranial injection of [³H] methionine or [¹⁴C] ethanolamine revealed that both precursors are incorporated almost exclusively into the choline moiety of this phospholipid. There was significant labeling of PhC only when the precursors were administered intracranially and much less incorporation was observed with the systemic routes. Thus following the intravenous administration of [¹⁴C] ethanolamine, the specific radioactivities of liver PhE and PhC were up to 75 times as high as those of brain and 4 to 5 times as high in the organs of the 20-day old as those of the adult. In contrast, when this precursor was administered intracranially the specific radioactivities of both phospholipids in liver were only twice as high as those of brain. Although the short-and long-term time-course studies on the in vivo incorporation of [¹⁴C] ethanolamine and [³H] methionine into PhC of both organs could suggest a precursor-product relationship between the biosynthesis of this phospholipid in liver and brain, this apparent relationship could also be due to the high turnover of PhE in liver, with half-life of 2.87 hr, and its low turnover in brain, with half-life of 10.7 days. The present findings on the low rate of formation of PhC from PhE in brain coupled with the fact that this conversion declines sharply with age, especially when the isotopes are administered systemically, could explain the observation of previous investigators that the brain cannot synthesize its own choline and thus it must derive its choline from exogenous sources such as lipid-choline. It was concluded that the brain can synthesize its own choline; however it remains also dependent on liver and dietary choline which are probably transported into the brain as free choline.     

Ketone-body utilization and lipid synthesis by developing rat brain—a comparison between in vivo and in vitro experiments

The distribution of ketone bodies between oxidation and lipid synthesis was analysed in homogenates of developing rat brain. The capacity for lipid synthesis of homogenized or minced brain preparations was compared with rates of lipid synthesis in vivo, assessed by incorporation of ³H from ³H₂O into fatty acids and cholesterol. Brain homogenates of suckling rats (but not those of adults) incorporated label from [3-¹⁴C]ketone bodies into lipids, but this process was slow as compared to ¹⁴CO₂ production (< 5%) and much slower than the total rate of ketone-body utilization (< 0.5%). Study of ³H₂O incorporation demonstrated that the rates of lipogenesis and cholesterogenesis are at least one order of magnitude higher in vivo than in vitro. Maximal rates of ³H incorporation into fatty acids (3 μmol/g brain . h) and into cholesterol (0.6 μmol/g brain . h) were found during the third postnatal week. Adult rats still incorporated ³H into brain fatty acids at an appreciable rate (1 μmol/g brain . h), whereas cholesterogenesis was very low. It is concluded that in vitro measurements of lipid synthesis severely underestimate the rates that occur in developing rat brain in vivo. The high rate of ³H incorporation into lipids by developing and adult rat brain as compared to the amounts of these lipids present in the brain suggests an important contribution of endogenous lipid synthesis during brain development and an appreciable rate of fatty acid turnover during brain growth, but also in the adult brain.     

In vivo neurogenesis is inhibited by neutralizing antibodies to basic fibroblast growth factor

While extracellular growth factors govern neuronal precursor mitosis in culture, little is known about their roles in regulating neurogenesis in vivo. Previously, we reported that subcutaneously administered basic fibroblast growth factor (bFGF) promoted neuroblast proliferation in P1 rat brain, in regions in which bFGF and FGF receptors are expressed during development. To define the role of endogenous bFGF in neurogenesis, we employed a neutralizing monoclonal antibody to the factor. In culture, bFGF-induced granule precursor proliferation was progressively inhibited by increasing concentrations of antibody. In contrast, heat-inactivated or nonneutralizing anti-bFGF antibodies were ineffective. The inhibition was specific for bFGF, since EGF-induced [³H]dT incorporation was not altered. To study effects in vivo, neutralizing antibody was administered to newborn rats via the cisterna magnum. Four hours after injection, DNA synthesis in cerebellum and hippocampus was decreased by 53% and 63%, respectively, suggesting that endogenous bFGF was involved in brain development. To define effects on neurogenesis specifically, granule cell precursors were isolated after antibody treatment. [³H]dT incorporation in granule precursors was decreased by 50%, indicating that the neutralizing antibody inhibited neuroblast proliferation in vivo. In contrast, no reduction was observed using nonneutralizing or the heat-inactivated antibodies. The inhibition of precursor proliferation following immunoneutralization of bFGF in vivo suggests that the endogenous factor normally regulates brain neurogenesis. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 289–296, 1997     

THE EFFECT OF METHIONINE SULPHOXIMINE ON THE INCORPORATION OF LABELLED GLUCOSE, ACETATE, PHENYLALANINE AND PROLINE INTO GLUTAMATE AND RELATED AMINO ACIDS IN THE BRAINS OF MICE

—The incorporation of radioactivity from labelled glucose, acetate, phenylalanine and proline into glutamate, aspartate and glutamine was measured in mice treated with methionine sulphoximine and in the control animals. The labelled precursors were injected and their incorporation determined before the onset of convulsions. The incorporation of radioactivity from labelled glucose into the dicarboxylic amino acids was reduced, in particular the incorporation into glutamine. The incorporation of radioactivity from labelled acetate and phenylalanine into glutamate and aspartate was increased by methionine sulphoximine, while the incorporation into glutamine was not changed very much. The labelling of glutamine, relative to glutamate, was reduced with all precursors, indicating that glutamine synthetase was inhibited in vivo by methionine sulphoximine. It is very likely that methionine sulphoximine affects many aspects of energy metabolism in brain; in particular the metabolism of glucose seems to be inhibited, while the rate of conversion of substrates other than glucose seems to be increased.     

Effects of γ-aminobutyric acid on 33Pi incorporation into rat brain phospholipids in vivo

The effects of γ-aminobutyric acid (GABA), bicuculline and strychnine on the incorporation $\text{in vivo}$ of ³³Pi into phospholipids of rat brain were studied at 10 and 30 minutes after intracisternal injection of the radionuclide. GABA inhibited labeling of phospholipids in the three brain regions studied at both times. Bicuculline by itself had no significant effect on ³³Pi incorporation, but totally blocked the inhibitory effect of GABA in all three brain regions. Strychnine by itself inhibited phospholipid labeling in the brain stem and forebrain, had no significant effect on GABA inhibition of ³³Pi incorporation in the cerebellum and forebrain, and partially blocked the GABA effect in the brain stem. GABA inhibited ³³Pi incorporation into phosphatidic acid, phosphatidylinositol, phosphatidyl choline and phosphatidyl ethanolamine but had no effect on phosphatidyl serine. The data suggest that the inhibitory effects of GABA on CNS phospholipid labeling are mediated specifically through GABA receptor sites.     

Neonatal undernutrition and RNA synthesis in developing rat brain

—Underfeeding of newborn rats results in a decreased body and brain weight at 10, 20 and 30 days of age. The DNA and RNA content of the brain in these animals are similar to those of normal controls. The in vivo and in vitro synthesis of RNA in brain is significantly decreased in undernourished rats at 10 days of age when compared with controls. The metabolic transformation of ³H-orotic acid to nucleotides is also diminished. A short period of food rehabilitation produces -an improvement in the above mentioned alterations. However, a reduced incorporation of label into microsomal RNA persists even in the last condition. The results suggest that malnutrition, during the first days of life, alters the metabolism of cerebral RNA.     

MEASUREMENT OF ACETYLCHOLINE TURNOVER WITH GLUCOSE USED AS PRECURSOR: EVIDENCE FOR COMPARTMENTATION OF GLUCOSE METABOLISM IN BRAIN

The turnover of acetylcholine in whole mouse brain in vivo has been determined using [U-¹⁴C]glucose as a precursor of the acetyl moiety. The standard requirements for the measurement of turnover were met: the injection did not change the concentrations of precursor or product, the amount of radioactivity in the brain was proportional to the amount injected, and the relationship between the specific activity of glucose and that of acetylcholine was typical of a precursor and a product. The value for acetylcholine turnover was 64 pmol/min per mg protein, approx 6.4 nmol/min per g brain. Treatment with amobarbital (0.16 mmol/kg) decreased the incorporation of glucose into acetylcholine by 73 × 7%, and treatment with atropine increased it by 18 × 6%. These values agree with those using choline as a precursor, supporting the validity of the values for turnover obtained with either labelled precursor. The specific activity of acetylcholine was higher than that of pyruvate at all times in mouse brain in vivo and in rat brain slices in vitro. These observations demonstrate compartmentation of glucose metabolism with respect to acetylcholine synthesis in the brain. They agree with observations by others of compartmentation of acetyl metabolism. They provide an explanation for the close linkage which has been observed between carbohydrate catabolism and acetylcholine synthesis in the CNS.     

Brain ribosomes in intracranial hypertension

Abstract— Increased intracranial pressure was produced by perfusion of cerebrospinal fluid (CSF) at various pressures into the lateral ventricles of adult Sprague-Dawley rats with bilateral chronic intraventricular cannulas. When CSF perfusion was carried out at pressures of 150, 300 or 600 mm of water, brain polysomal profiles were similar to controls. Rats perfused under a pressure of 1500 mm water for 30 min were comatose, had slow electroencephalograms and showed a fall in brain polysomes from 66 to 24 per cent of the total ribosomes (P < 0.01) while ribosomal monomers and dimers increased. These monomers and dimers were completely and reversibly dissociated into subunits in 500 niM KC1 buffers, unless prefixed in formaldehyde. [³H]leucine incorporation into brain ribosomes in vivo was decreased by severe intracranial hypertension. In cell-free systems in vitro, pathological ribosomes were less active in protein synthesis than controls (P < 0.01) but were at least as readily stimulated by poly U. After intracranial pressure was returned to normal, there was a progressive reassociation of ribosomes into polysomes, even in the presence of Actinomycin D. These findings suggest that during severe intracranial hypertension cerebral protein synthesis is inhibited, perhaps through reversible inactivation of the translation of messenger RNA.     

Protein metabolism in goldfish brain

Abstract— Protein metabolism of goldfish brain was studied in vivo by means of intraperitoneal or intracranial injections of [³H]leucine and compared with concomitant studies in the mouse. Heterogeneity of turnover values was observed. Long turnover times were seen relative to other organs examined. The free amino acid pools of goldfish brain were determined, and the fate of tritium from labelled leucine was followed at various times after injection. Following ‘chasing’ with large amounts of unlabelled leucine or protein inhibitors shortly after isotope injection, further incorporation was arrested, but examination of the labelled protein over a period of 2 weeks indicated a slow decay, similar to that seen without ‘chasing’. Possible use of ‘pulse-chase’ experiments in vivo in animals is discussed in relation to behavioural studies.     

The relationship of protein and lipid synthesis during the biogenesis of mitochondrial membranes

Summary Rat liver mitochondria were fractionated into inner and outer membrane components at various times after the intravenous injection of¹⁴C-leucine or¹⁴C-glycerol. The time curves of protein and lecithin labeling were similar in the intact mitochondria, the outer membrane fraction, and the inner membrane fraction. In rat liver slices also, the kinetics of³H-phenylalanine incorporation into mitochondrial KCl-insoluble proteins was identical to that of¹⁴C-glycerol incorporation into mitochondrial lecithin. These results suggest a simultaneous assembly of protein and lecithin during membrane biogenesisThe proteins and lecithin of the outer membrane were maximally labeledin vivo within 5 min after injection of the radioactive precursors, whereas the insoluble proteins and lecithin of the inner membrane reached a maximum specific acitivity 10 min after injection.Phospholipid incorporation into mitochondria of rat liver slices was not affected when protein synthesis was blocked by cycloheximide, puromycin, or actinomycin D. The injection of cycloheximide 3 to 30 min prior to¹⁴C-choline did not affect thein vivo incorporation of lecithin into the mitochondrial inner or outer membranes; however treatment with the drug for 60 min prior to¹⁴C-choline resulted in a decrease in lecithin labeling. These results suggest that phospholipid incorporation into membranes may be regulated by the amount of newly synthesized protein available.When mitochondria and microsomes containing labeled phospholipids were incubated with the opposite unlabeled fractionin vitro, a rapid exchange of phospholipid between the microsomes and the outer membrane occurred. A slight exchange with the inner membrane was observed.     

In vivo incorporation of [14C]tyrosine into the C-terminal position of the α subunit of tubulin

In vitro incorporation of [¹⁴C]tyrosine into the C-terminal position of the α subunit of tubulin was not affected by 4 mm cycloheximide. This inhibitor of protein synthesis was used for in vivo experiments. The in vivo incorporation of [¹⁴C]tyrosine into soluble brain protein of cycloheximide-treated rats was 10% of that of untreated rats. Treatment with vinblastine sulfate of the soluble brain protein showed that the incorporation of [¹⁴C]tyrosine into tubulin was higher in cycloheximide-treated than in untreated rats with respect to the incorporation into the total soluble protein. In the case of cycloheximide-treated rats, about 60% of the radioactivity incorporated into protein was released by the action of carboxypeptidase A, whereas 10% was liberated from the protein of untreated rats. The radioactive compound released by the action of carboxypeptidase A was identified as [¹⁴C]tyrosine. The α and β subunits of tubulin from animals that received [¹⁴C]tyrosine were separated by polyacrylamide gel electrophoresis. The radiosactivity ratio of $\text{α}\text{β}$ subunits of tubulin from cycloheximide-treated rats was threefold higher than that of untreated rats. When a mixture of [¹⁴C]amino acids was injected, the radioactivity ratio of $\text{α}\text{β}$ subunits of tubulin was similar for cycloheximide-treated and untreated rats. The results reported are consistent with the assumption that the α subunit of tubulin can be tyrosinated in vivo.     

The effect of 2,4-dichlorophenoxyacetic acid upon the metabolism and composition of soybean hypocotyl mitochondria

Summary Dark-grown, 3-day-old soybean seedlings were sprayed with 1 mM 2,4-dichlorophenoxyacetic acid 24 hours before harvest. Mitochondria from 2,4-D-treated lower hypocotyls were found to be larger and showed greater incorporation in vivo, of amino acids into protein and phosphate into phospholipids and RNA, than mitochondria from untreated tissue. Mitochondria isolated from 2,4-D-treated hypocotyls showed an enhanced energy-dependent incorporation of amino acids into protein, although the incorporation of nucleoside triphosphates into the RNA of isolated mitochondria was not affected. No effect of 2,4-D, applied in vitro, was noted, and no enhancement of mitochondrial respiratory efficiency followed auxin treatment. A method of isolating mitochondria with a very low level of bacterial contamination is reported.