Synthesis and turnover of cerebrosides and phosphatidylserine of myelin and microsomal fractions of adult and developing rat brain.

The synthesis and turnover of cerebrosides and phospholipids was followed in microsomal and myelin fractions of developing and adult rat brains after an intracerebral injection of [U-14C]serine. The kinetics of incorporation of radioactivity into microsomal and myelin cerebrosides indicate the possibility of a precursor-product relationship between cerebrosides of these membranes. The specific radioactivity of myelin cerebrosides was corrected for the deposition of newly formed cerebrosides in myelin. Multiphasic curves were obtained for the decline in specific radioactivity of myelin and microsomal cerebrosides, suggesting different cerebroside pools in these membranes. The half-life of the fast turning-over pool of cerebrosides of myelin was 7 and 22 days for the developing and adult rat brain respectively. The half-life of the slowly turning-over pool of myelin cerebrosides was about 145 days for both groups of animals. The half-life of the rapidly turning-over microsomal cerebrosides was calculated to be 20 and 40 h for the developing and adult animals respectively. The half-life of the intermediate and slowly turning-over microsomal cerebrosides was 11 and 60 days respectively, for both groups of animals. The amount of incorporation of radioactivity into microsomal cerebrosides from L-serine was greatly decreased in the adult animals, and greater amounts of the precursor were directed towards the synthesis of phosphatidylserine. In the developing animals, considerable amounts of cerebrosides were synthesized from L-serine, besides phosphatidylserine. The time-course of incorporation indicated that a precursor-product relationship exists between microsomal and myelin phosphatidylserine. The half-life of microsomal phosphatidylserine was calculated to be about 8 h for the fast turning-over pool in both groups of animals.     

HE TURNOVER RATE OF TUBULIN IN RAT BRAIN

The turnover rate of tubulin in rat brain was determined from the decay in specific radioactivity of the protein after pulse-labeling. When precursors were administered by a parenteral route, the shortest half-life, 9.8 days, was obtained with [¹⁴C]NaHCO₃; the longer half-lives obtained with [U-¹⁴C]glucose or [4,5-³H]leucine suggest significant reutilization of label. Furthermore, with leucine as precursor maximal specific radioactivity of tubulin was not obtained until eight days after administration of label. Labeling and decay kinetics obtained with [4,5-³H]leucine were markedly different when the isotope was administered directly into the lateral ventricle. The difference between the turnover rates of the -α and β subunits of tubulin purified by means of high resolution polyacrylamide gel electrophoresis was not statistically significant. A half-life for tubulin of 6.2 days was measured by continuous intravenous infusion of [U-¹⁴C]tyrosine.     

Axonal transport in nigro-neostriatal neurons during morphine tolerance development and abstinence in rats.

Axonal transport of [³H]protein in the nigro-neostriatal pathway in rats was examined during acute and chronic morphine administration and during morphine abstinence. Two days after a microinjection of [³H]lysine into the left substantia nigra zona compacta, more than 95% of the radioactivity present in the rat forebrain was protein-bound. Examination of frozen frontal brain sections revealed that 80–90% of the labelled protein of the injected side was located in brain areas traversed by the nigro-neostriatal pathway. As a positive control, intranigrally administered colchicine reduced the amount of [³H]protein transported after 5 days to the nucleus caudatus-putamen (neostriatum) to approx 18-26% of control. In animals rendered morphine-dependent by subcutaneous implantation of tablets containing 75 mg of morphine base, 27–86% more radioactivity accumulated in the neostriatum at 3, 4 and 5 days after [³H]lysine injection. In contrast, 23–48% less radioactivity was recovered in the neostriatal areas of animals withdrawing from morphine 24 h after [³H]lysine. Gel electrophoresis of soluble and particulate [³H]protein fractions from neostriatal tissues indicated that the gel patterns of radioactivity were not altered by chronic morphine administration. Neither morphine administration nor morphine abstinence altered the rate or amount of [³H]lysine incorporation into protein of the substantia nigra. These data demonstrate that chronic morphine administration was accompanied by a generalized increase in the amount of labelled protein transported to the neostriatum but the procedure was not sufficiently sensitive to detect a minor qualitative alteration of any particular protein(s). Furthermore, these data suggest that either the capacity or the rate of nigro-neostriatal protein transport may be increased during chronic morphine administration in the rat.     

ARE MYELIN PROTEINS SYNTHESIZED IN RETINAL GANGLION CELLS?1

—We studied the incorporation of radioactivity into individual proteins of myelin by sodium dodecyl sulfate polyacrylamide gel electrophoresis after the injection of [³H]tryptophan into the right eye of developing rabbits. We found that the specific activity of basic protein (c.p.m./mg of basic protein) and the specific activity of DM-20 and proteolipid protein (c.p.m./mg total myelin protein applied to the gel) did not approach the ratio predicted by decussation of the fibres of the rabbit optic nerve. The specific activity of Wolfgram protein, however, approached an expected ratio of 15:1. We therefore concluded that myelin basic protein, DM-20 and proteolipid protein were probably not synthesized in retinal ganglion cells.     

Effects of Altered Thyroid States on Myelinogenesis

Abstract: Myelinogenesis was studied in controls and in rats treated since birth with Methimazole (hypothyroid) or thyroxine (hyperthyroid). The amount of myelin in forebrain and its protein composition were determined between 13 and 40 days of age, the period of most rapid myelin accumulation. Hypothyroid rats had reduced body and brain weights relative to controls and the yield of myelin was reduced on both a per brain and a per milligram brain protein basis. Developmental changes in the protein composition of isolated myelin followed the pattern of control animals (the percentage of total myelin protein present as proteolipid protein, large basic protein, and small basic protein increased, as did the ratio of proteolipid/large basic protein) but were delayed temporally by 1–2 days. Hyperthyroid rats also had reduced body and brain weights. At 13 days myelin accumulation was greater than that of controls, corresponding to an earlier initiation of myelination. At later ages myelin yield was reduced on a per brain basis but not on a per milligram brain protein basis. The developmental pattern of myelin protein composition was accelerated temporally by 1–2 days. Myelination in optic nerve, assayed by proteolipid protein content, also was slightly delayed in hypothyroid animals and somewhat accelerated in hyperthyroid animals. The relative synthesis of myelin proteins (determined as incorporation of intracranially injected [³H]glycine into myelin protein relative to incorporation into whole brain protein), as well as distribution of radioactivity among individual myelin proteins, was determined. The results supported the conclusion of the myelin protein accumulation study; hypothyroidism retards the developmental program for myelinogenesis, whereas in the hyperthyroid state myelin synthesis is initiated earlier but is also terminated earlier.     

Distribution, metabolism and excretion of [1-14C]dolichol injected intravenously into rats.

[1-14C]Dolichol mixed in vitro with rat serum and injected intravenously into rats was rapidly cleared from the circulation in a manner consistent with a two-compartment model. About 80% of the radioactivity recovered from animals killed after 1 day was in the liver, with smaller amounts being found in lung, carcass (internal organs removed), gastrointestinal tract and contents, and spleen. The kidneys, testes and heart contained little radioactivity, and the brain did not appear to take up any [1-14C]dolichol. The half-life for the turnover of radioactivity from [1-14C]dolichol in tissues varied considerably, being 2 days for the lung, 17 for liver and about 50 days for the carcass. After 1 day, and also after 4 and 21 days, most of the radioactivity in all tissues was as [1-14C]dolichol and as [1-14C]dolichyl fatty acyl ester, although a small amount of incorporation of [1-14C]dolichol radioactivity into phospholipids was also observed. Faeces collected over the first 4 days after injection contained 13% of the [1-14C]dolichol dose, but urine and expired air contained only small amounts of radioactivity. Radioactivity in faeces was nearly all as unchanged [1-14C]dolichol and as [1-14C]dolichyl fatty acyl ester. The [1-14C]dolichol remaining in liver after 21 days appeared to be in a pool (possibly lysosomes) where most of it was not subject to excretion.     

Polyamine turnover in different regions of rat brain

The dynamics of the formation and disappearance of polyamines in rat brain have been examined after intraventricular administration of a tracer dose of [³H]putrescine. After 2 days [³H]putrescine was no longer detectable in any brain region examined. [³H] Spermidine and [³H] spermine were formed in all brain areas. In the midbrain, hypothalamus and cerebellum (regions which manifested the greatest initial accumulation of tritium) the specific radioactivity of spermidine declined with a half-life of 16-19 days. However, in areas with a low initial accumulation of tritium (the medulla-pons, internal capsule, cerebral cortex and corpus striatum) the specific radioactivity of spermidine changed very little between 2 and 19 days after the putrescine administration. Levels of [³H]spermine increased continuously in all brain areas for a 14-day period after the putrescine injection.     

Appearance of newly synthesized protein in myelin of young rats.

Abstract— Seventeen-day-old rats were injected intracranially with [³H]leucine, then sacrificed between 1 and 24 h. Myelin was prepared from the brains on discontinuous sucrose gradients and the proteins were separated by discontinuous gel electrophoresis in buffers containing sodium dodecyl sulphate. Proteins were stained with acid Fast Green and the distribution was quantitated by densitometry. The gels were then sliced and the radioactivity in each slice was determined. Between 1 and 24 h, the radioactivity in proteolipid protein increased from 18% to 37% of the total radioactivity in the proteins of isolated myelin. During this same period, the per cent distribution of radioactivity in basic and Wolfgram proteins remained constant while that in the remaining high molecular weight proteins decreased. Similar results were also obtained with [³H]glycine as a precursor. The relative specific activity of all of the myelin proteins increased between 1 and 6 h, then remained constant between 6 and 24 h. At 1 h, proteolipid protein reached only 25% of its maximal (6 h) relative specific radioactivity, while the other two proteins reached 50% of maximum. These results indicate a lag in the appearance of labelled amino acids in proteolipid protein relative to the other myelin proteins.     

Cell-free acylation of rat brain myelin proteolipid protein and DM-20.

Incubation of rat brain myelin with [3H]palmitic acid in the presence of ATP, CoA and MgCl2 or [14C]-palmitoyl-CoA in a cell-free system resulted in the selective labelling of 'PLP' [proteolipid protein; Folch & Lees (1951) J. Biol. Chem. 191, 807-817] and 'DM-20' [Agrawal, Burton, Fishman, Mitchell & Prensky (1972) J. Neurochem. 19, 2083-2089] which, after polyacrylamide-gel electrophoresis in SDS, were revealed by fluorography. These results provide evidence of the association of fatty acid-CoA ligase and acyltransferase in isolated myelin. Palmitic acid is covalently bound to PLP and DM-20, because 70 and 92% of the radioactivity was removed from proteolipid proteins after treatment with hydroxylamine and methanolic NaOH respectively. Incubation of myelin with [3H]palmitic acid in the absence of ATP, CoA, MgCl2, or all three, decreased incorporation of fatty acid into PLP to 3, 55, 18 and 2% respectively. The cell-free system exhibits specificity with respect to the chain length of the fatty acids, since myristic acid is incorporated into PLP at a lower rate when compared with palmitic and oleic acids. The acylation of PLP is an enzymic reaction, since (1) maximum incorporation of [3H]palmitic acid into PLP occurred at physiological temperatures and decreased with an increase in the temperature; (2) acylation of PLP with [3H]palmitic acid and [14C]palmitoyl-CoA was severely inhibited by SDS (0.05%); and (3) the incorporation of fatty acid and palmitoyl-CoA into PLP was substantially decreased by the process of freezing-thawing and freeze-drying of myelin. We have provided evidence that all of the enzymes required for acylation of PLP and DM-20 are present in isolated rat brain myelin. Acylation of PLP in a cell-free system with fatty acids and palmitoyl-CoA suggests that a presynthesized pool of non-acylated PLP and DM-20 is available for acylation.     

METABOLISM OF HIGHLY BASIC PROTEINS OF RAT BRAIN DURING POSTNATAL DEVELOPMENT

Abstract— (1) The encephalitogenic basic protein obtained from adult rat brain by treatment with 0·03 N-HCl was demonstrable in the brain on the 10th day after birth. It showed a marked increase in quantity during the phase of active myelination.
(2) The proteins extracted under similar conditions from 5-day old rat brain contained several highly basic proteins other than the encephalitogenic basic protein. These basic proteins, which were electrophoretically similar to highly basic proteins extracted similarly from adult rat liver, are histones.
(3) For metabolic studies the entire group of highly basic proteins in the acid extract was obtained after one-step adsorption of other proteins on DEAE-cellulose equilibrated at pH 9·8
(4) After injection of [¹⁴C]lysine the fractions containing highly basic proteins, water soluble non-basic proteins and other tissue proteins of the brain showed higher relative specific radioactivities during the period 1–10 days after birth than during later stages of postnatal development. The fraction containing proteolipid protein, another myelin protein, showed a low relative specific radioactivity throughout the whole period of postnatal development. The relative specific radioactivity of proteolipid protein was somewhat higher in young than in adult rat brain.     

In vivo identification and characterization of binding sites for selective serotonin reuptake inhibitors in mouse brain

The present study was undertaken to identify and characterize in vivo binding sites of selective serotonin reuptake inhibitors (SSRIs) in the mouse brain by using [3H]paroxetine as radioligand. Relatively higher concentration of [3H]paroxetine was detected in the whole brain (minus cerebellum) than in the plasma of mice after the i.v. injection of the radioligand, and the half-life (t1/2) of elimination was much slower. The in vivo specific [3H]paroxetine binding in the mouse brain after the i.v. injection was defined as the difference of particulate-bound radioactivity between the whole brain and cerebellum, and it was dose-dependently attenuated by oral or intraperitoneal administration of fluoxetine (8.68-116 micromol/kg). Furthermore, oral administration of fluvoxamine, fluoxetine, paroxetine and sertraline at the pharmacologically relevant doses reduced significantly (25-94%) in vivo specific [3H]paroxetine binding in the cerebral cortex, striatum, hippocampus, thalamus and midbrain of mice, and their significant decreases were observed up to at least 8 h (fluvoxamine), 24 h (fluoxetine), and 12 h (paroxetine and sertraline) later. The value of area under the curve (AUC) for decrease in [3H]paroxetine binding vs. time in each brain region was largest for fluoxetine among these SSRIs, due to the relatively longer-lasting occupation of brain serotonin transporter. The AUC value in mouse brain after oral administration of each SSRI was 1.2-3.2 times greater in the thalamus and midbrain than in the cerebral cortex, striatum and hippocampus. Thus, the present study has revealed that [3H]paroxetine may be a suitable radioligand for in vivo characterization of brain binding sites and pharmacological effects of SSRIs.     

THE INCORPORATION OF RADIOACTIVE AMINO ACIDS INTO BRAIN SUBCELLULAR PROTEINS DURING TRAINING

—Total proteins, free amino acids, tritiated water and subcellular proteins of mouse brain were examined for changes in radioactivity during operant conditioning after subcutaneous administration of labelled amino acids. The conditioning was based on appetitive learning, using sweetened milk as a reward. During training and incorporation for 20-30 min, both [³H]leucine and [1-¹⁴C]leucine underwent a significant increase in catabolism, resulting in a decreased radioactivity in the free amino acids. [2-²H]Methionine underwent a rapid loss of isotope, so that 90% of the radioactivity was in the form of tritiated water at the end of training, and this phenomenon masked any possible effect of training. The brain uptake of [³⁵S]methionine increased during the training, resulting in an increased radioactivity in the proteins. Uptake of [³H]lysine increased slightly during training only after 1 h incorporation and not after 20 or 30 min, as judged from a time course of radioactivity in the free amino acids. Incorporation into nuclear proteins increased selectively during 20 min, and into nuclear and cytosol proteins after 60 min incorporations. It is concluded that changes in the observed rate of incorporation of a precursor into brain subcellular proteins under the influence of behaviour might be the result of changes in precursor catabolism or uptake, or both, and that each amino acid behaves in a different way. Even the same amino acid gives different results depending on the isotope and its position in the amino acid.     

Generation of Arachidonic Acid and Diacylglycerol Second Messengers from Polyphosphoinositides in Ischemic Fetal Brain

Intracerebral administration of [3H]arachidonic acid ([3H]ArA) into 19-20-day-old rat embryos, resulted in a rapid incorporation of label into brain lipids. One hour after injection, 55.6 +/- 8.2, 18.0 +/- 3.4, and 13.7 +/- 1.3% of the total radioactivity was associated with phosphatidylcholine, phosphatidylinositol, and phosphatidylethanolamine, respectively. Approximately 10% of radioactivity was found acylated in neutral lipids of which free ArA comprised only 1.5 +/- 0.2% of the total radioactivity. Complete restriction of the maternal-fetal circulation for < or = 40 min did not affect the rate of [3H]ArA incorporation (t1/2 = 2 min) into fetal brain lipids, suggesting an effective acylation mechanism that proceeds irrespective of the impaired blood flow. After a short restriction period (5 min), the radioactivity in diacylglycerol was elevated by 50%. After a longer restriction period (20 min), the radioactivity in the free fatty acid and diacylglycerol fractions increased to values of 130 and 87%, respectively. Polyphosphoinositides prelabeled with either [3H]ArA or 32P were rapidly degraded after 5 min of ischemia. After 20 min, the decrease in phosphatidylinositol-4-phosphate and phosphatidylinositol-4,5-bisphosphate radioactivity was 47 and 70%, respectively. Double labeling of phospholipids with [14C]palmitic acid and [3H]ArA indicated a preferential loss of [3H]ArA within the polyphosphoinositide species after 20 min, but not after 5 min of ischemia. The specific activity of [14C]palmitate remained unchanged. The current data suggest phospholipase C-mediated diacylglycerol formation at the beginning of the insult followed by a phospholipase A2-mediated ArA liberation at a later time, both enzymes presumably acting preferentially on polyphosphoinositide species.     

3H]tryptophan-[14C]proline dual label method for the simultaneous determination of collagen and noncollagen protein production

A new method for the simultaneous determination of newly synthesized collagen and noncollagen proteins has been developed. Because tryptophan is not found in collagen noncollagen proteins were specifically labeled with [3H]tryptophan. [14C]Proline was used to label both groups of proteins. To calculate the 14C-labeled noncollagen protein the 3H radioactivity of the protein mixture was divided by the ratio of 3H:14C in noncollagen protein of a representative sample. This value was obtained by collagenase digestion. The remaining 14C radioactivity in the protein mixture was attributed to [14C]collagen. There was a very good correlation between the dual label method and the widely used collagenase digestion method for the measurement of collagen and noncollagen protein production and for the calculation of the relative rate of collagen synthesis. This new method provides a simple and accurate analysis of collagen production, and it is suitable for rapid processing of a large number of biological samples.     

THE EFFECT OF A LOW PROTEIN DIET AND EXOGENOUS INSULIN ON BRAIN TRYPTOPHAN AND ITS METABOLITES IN THE WEANLING RAT

—Male Wistar rats aged 24 days were divided into three groups. Two groups were given a high protein (250 g/kg casein) and a low protein (30 g/kg casein) diet respectively. The third group was given an amount of the high protein diet containing the same amount of energy as that consumed by the low protein diet rats. The plasma of the animals on low protein contained 20% of the concentration of tryptophan of animals on the other two diets. In these animals the concentration of tryptophan was reduced in the forebrain, cerebellum and brain stem, and the concentrations of 5-HT and 5-hydroxyindoleacetic acid were reduced in the forebrain and brain stem. The low protein diet decreased the total uptake of l -[G-³H]tryptophan into the brain and its incorporation into brain protein. Plasma insulin concentrations were reduced in the low protein and ‘restricted high protein’ animals and the plasma corticosterone concentration was raised in the low protein animals. Exogenous insulin did not raise the plasma tryptophan concentration in the low protein animals but it increased the uptake of l -[G-³H]tryptophan into the brain and its incorporation into protein. Rehabilitation for 7 days restored the plasma and brain tryptophan concentrations and those of brain 5-HT and 5-hydroxyindoleacetic acid to control values.     

THE INFLUENCE OF PORTOCAVAL ANASTOMOSIS ON THE METABOLISM OF LABELLED OCTANOATE, BUTYRATE AND LEUCINE IN RAT BRAIN

Rats were given a portocaval anastomosis and 3 weeks later, when the only ultrastructural change in the CNS is watery swelling of astrocytes, several aspects of brain metabolism were studied. The uptake of leucine by the brain, its incorporation into protein and its oxidation were followed after the simultaneous injection of a mixture of L-[1¹⁴C]leucine and L-[4,5-³H]leucine. The concentration of leucine in blood was lowered in the operated animals whereas in brain it was increased. The specific radioactivity of leucine in the brain was comparable to values in control animals and there was no evidence of a decrease in incorporation of [1-¹⁴C]leucine into brain proteins over the short experimental time period studied. The only difference from the controls in the oxidation of [4,5-³H]leucine was a greater accumulation in glutamine. The amount of glutamine in the brains of the operated animals had increased 4-fold at the time of the metabolic studies. From dual-labelled experiments in which a mixture containing [1-¹⁴C]butyrate and L-[4,5-³H]leucine was injected intravenously, it was shown that, in both control and operated animals, the pools of brain glutamate and glutamine labelled from butyrate were metabolically distinct from those labelled from leucine. The total radioactivity appearing in brain from [1-¹⁴C]butyrate was markedly reduced in operated animals, but the radioactivity from L-[4,5-³H]leucine was not. The metabolism of [1-¹⁴C]octanoate was compared with that of [1-¹⁴C]butyrate. In control animals the labelling of metabolites was almost identical with either precursor. In operated animals there was no reduction in the uptake of [1-¹⁴C]octanoate into the brain. There was evidence that the size of the glutamine pool labelled, relative to glutamate, was increased but that it had a slower fractional turnover coefficient. A link between astroglial changes and an impairment to the carrier mechanism for transport of short chain monocarboxylic acids across the blood-brain barrier is suggested.     

METABOLIC RELATIONSHIPS BETWEEN MYELIN SUBFRACTIONS: ENTRY OF PROTEINS 1

Abstract— Partially purified myelin from brains of 17-day-old rats was separated into 4 subfractions on a discontinuous sucrose gradient by virtue of heterogeneity in density and particle size. The protein composition of each subfraction was determined by densitometry following separation of proteins on polyacrylamide gels in buffers containing sodium dodecyl sulphate. The major proteins studied included two basic proteins, proteolipid protein, the major high molecular weight protein (W) and a group of high molecular weight proteins. The percentage of high molecular weight proteins decreased sequentially from fraction D to A, that of the W protein remained constant, while relative amounts of the two basic proteins increased. Proteolipid protein concentration also increased as a percentage of the total protein from fraction D to B, but the uppermost fraction. A, had a markedly lower amount than fraction B. At 1 h after intracranial injection of [³H]leucine, the specific radioactivity of the basic and proteolipid proteins decreased from fraction D to B, with proteolipid protein in fraction A again anomalous (specific radioactivity higher than expected). These results are consistent with (but do not prove) a precursor-product relationship for individual proteins from denser to lighter subfractions, with the exception of myelin subfraction A. Experiments involving time staggered injections of a [¹⁴C] and later a [³H] labelled amino acid gave data which demonstrated that the W and basic proteins were added simultaneously (or with delays of much less than 20 min) to all of the subfractions, while proteolipid protein was added sequentially, from lower to upper fractions on the gradient. This double isotope technique also confirmed our previous observations that proteolipid protein shows a lag in entry into myelin compared to basic protein.     

Long-term distribution and metabolism of [1-14C]dolichol injected intravenously into rats

We have previously shown that [1-14C]dolichol mixed in vitro with rat serum and injected intravenously is rapidly cleared from the circulation and appears primarily in the liver. One day after injection the liver accounted for 80% of the isotope in whole animals, whereas after 130 days it represented only 50%. During the 130 days the specific radioactivity (dpm/g liver) decreased by more than 20-fold. In contrast, the spleen retained at 130 days 85% of the radioactivity initially present and its specific radioactivity decreased by only a factor of two. At this time small amounts of isotope were also found in carcass (internal organs removed), gastrointestinal tract and contents, and lungs. Trace amounts of radioactivity were extractable from testes and kidneys, while the heart and brain were essentially free of radioactivity. At all times after injection nearly all the radioactivity present in all tissues was still associated with dolichol. Only trace amounts of [1-14C]dolichyl fatty acyl ester and no [1-14C]phosphorylated derivatives of dolichol were present in the liver and spleen removed 156 days postinjection. Fractionation of liver between 1h and 93 days after injection suggested that [1-14C]dolichol becomes associated primarily with a lysosome-enriched fraction. The accumulation of [1-14C]dolichol in this and other subcellular compartments involved both an inward and outward flow of radioactivity, suggesting that deposition of dolichol in lysosomes is not a one-way terminal process.     

Extremely rapid degradation of [3H] methionine-enkephalin by various rat tissues in vivo and in vitro

Thirty sec after the intrajugular injection of [³H] methionine-enkephalin (met-enkephalin) in the rat, the radioactivity was already distributed in an apparent volume of 53 ml and the metabolic clearance rate calculated from the characteristics of the plasma disappearance curve was 10 ml/min. As shown by partition chromatography plasma extracts obtained 15 sec after injection of [³H] met-enkephalin, only 5% of the total radioactivity migrated as the intact pentapeptide, while no detectable intact pentapeptide remained 2 min after injection, thus indicating a half-life of [³H] met-enkephalin of the order of 2 to 4 sec. Incubation of rat cerebral tissue with [³H] met-enkephalin indicates that the first step in the breakdown of met-enkephalin in both plasma and brain tissue is cleavage of the Tyr-Gly amide bond. These data offer an explanation for the low activity of met-enkephalin after intraventricular or intravenous administration.     

SUBCELLULAR DISTRIBUTION OF RADIOACTIVITY IN NEURONAL AND GLIAL-ENRICHED FRACTIONS AFTER INCORPORATION OF [3H]LEUCINE IN VIVO AND IN VITRO

Abstract— The distribution of protein-bound radioactivity among subcellular organelles of cerebral cortex was followed after intravenous administration of [3H]leucine and after incubation of brain slices in the presence of [3H]leucine. Neuronal and glial cell-enriched fractions were prepared by discontinuous sucroseFicol1 gradient centrifugation of cerebral cortex cell suspensions. Subcellular fractions were obtained from each of the cell prepara- tions and the protein-bound radioactivity determined after in uiuo and in vitro incorporation of [3H]leucine. The unfractionated neuronal material had a considerably higher level of protein-bound radioactivity than the glial material. The most marked neuronal-glial dif- ferences were observed in microsomes and soluble proteins, while the radioactive labelling of the nuclear and mitochondria1 fractions was similar for the two cell types.