DISAGGREGATION OF BRAIN POLYSOMES AFTER d-LYSERGIC ACID DIETHYLAMIDE ADMINISTRATION IN VIVO: MECHANISM AND EFFECT OF AGE AND ENVIRONMENT1

Abstract— The cell-free protein synthesis activity and tRNA content of the increased pool of brain monosomes produced after d -lysergic acid diethylamide (LSD) administration were analyzed. Decreased reinitiation of protein synthesis rather than RNase activation or premature termination was shown to be the mechanism which results in brain polysome disaggregation after administration of the drug in vivo. At a constant dosage of 50 μg/kg the degree of polysome shift increases with age from 3-week-old rabbits to adults. There is also an extensive disaggregation of fetal brain polysomes when LSD is administered maternally. The LSD-induced polysome shift was shown to be altered by holding cage environment, pre-LSD sedation and post-LSD handling with brief restraint. It was apparent that elements of environment and physiological arousal were involved in the macromolecular effect of the drug on the protein synthesis apparatus of the brain.     

Comparison of the Effect of Intravenous Administration of d-Lysergic Acid Diethylamide on Free and Membrane-Bound Polysomes in the Rabbit Brain

Abstract: The intravenous administration of LSD to young adult rabbits resulted in the disaggregation of both free and membrane-bound classes of brain polysomes. Based on the analysis of LSD dosage and the time course of the LSD-induced brain polysome shift, it was found that free polysomes were more sensitive to the drug than the membrane-bound polysome fraction. LSD-induced hyperthermia may be involved in the disaggregation of free and membrane-bound polysomes, since a correlation was found between the extent of LSD-induced hyperthermia and the degree of brain polysome shift. Prevention of LSD-induced hyperthermia by maintaining the animal at 4°C blocked the disaggregation of both polysome classes. Induction of hyperthermia by elevation of ambient temperature also resulted in a shift in free and membrane-bound polysomes. In all cases the disaggregation of polysomes to monosomes was not caused by RNase activation. During polysome disaggregation, polyadenylated mRNA associated with both free and membrane-bound polysomes was not degraded but was relocalized from polysomes to monosomes.     

Disaggregation of brain polysomes after LSD in vivo

LSD-induced hyperthermia is implicated in the brain-specific disaggregation of polysomes which is induced following intravenous administration of the drug to rabbits. Both LSD-induced hyperthermia and brain polysome disaggregation were found to increase in parallel under conditions which accentuated the effect of the drug on brain protein synthesis. Pretreatment with neurotransmitter receptor blockers or placing the animal at an ambient temperature of 4°C after LSD administration prevented both hyperthermia and brain polysome disaggregation. The administration of apomorphine, which causes hyperthermia in rabbits also caused disaggregation of brain polysomes. Direct elevation of the body temperature to levels similar to that found after LSD was achieved by placing animals at an ambient temperature of 37°C. Under these conditions a brain-specific disaggregation of polysomes resulted which was not due to RNAase activation. After either LSD or direct heating, the brain polysome shift was associated with a relocalization of polyadenylated mRNA from polysomes to monosomes as determined by [³H]polyuridylate hybridization. Since polysome disaggregation was found only in brain, it appears that the brain may be more sensitive to elevations in body temperature compared to other organs.     

DISAGGREGATION OF POLYSOMES IN FETAL ORGANS AND MATERNAL BRAIN AFTER ADMINISTRATION OF d-LYSERGIC ACID DIETHYLAMIDE IN VIVO

The intravenous administration of d-lysergic acid diethylamide (LSD) to pregnant female rabbits induced hyperthermia as well as disaggregation of polysomes in fetal organs and maternal brain. The LSD-induced polysome shift in maternal brain and fetal organs was not due to an activation of ribonuclease or associated with alterations in the levels of free amino acids. Pretreatment with the receptor blocking agents haloperidol and pizotyline blocked both LSD-induced polysome shift in maternal brain and fetal organs and LSD-induced hyperthermia. Fine dissection of adult rabbit brain showed that the extent of LSD-induced disaggregation of polysomes does not exhibit any marked regional variation.     

Hyperthermia and disaggregation of brain polysomes induced by bacterial pyrogen.

Hyperthermia induced following injection of bacterial pyrogen to rabbits was associated with a disaggregation of brain polysomes to monosomes. Direct elevation of the body temperature to levels similar to that found after pyrogen administration also resulted in a brain polysome shift. The disaggregation of brain polysomes after either pyrogen injection or elevation of ambient temperature was not due to ribonuclease activation and the phenomenon was associated with a relocalization of polyadenylated mRNA from polysomes to monosomes. Since polysome disaggregation was not found in kidney, it appears that the brain may be more sensitive to elevations in body temperature.     

Antipsychotic drugs block LSD-induced disaggregation of brain polysomes.

Intravenous injection of LSD at 10, 25 and 100 μg/kg to young rabbits induces brain specific disaggregation of polysomes to monosomes. Polysomes in the cerebral hemispheres, cerebellum and remaining brain stem are affected. Neurotransmitter receptors are involved since prior injection of the receptor blockers haloperidol, chlorpromazine, propranolol, phentolamine, or pizotyline prevent drug-induced polysome shift. Depression of neuronal activity with sedative levels of ethanol or pentobarbital also eliminates polysome disaggregation.     

Disaggregation of brain polysomes by L-5-hydroxytryptophan: Mediation by serotonin

In rats, intraperitoneal administration of L-5-hydroxytryptophan (200 mg/kg) causes extensive disaggregation of whole brain polysomes after one hour. Polysome disaggregation is prevented if the conversion of L-5-hydroxytryptophan to serotonin is blocked by pretreatment with an aromatic L-amino acid decarboxylase inhibitor; disaggregation is potentiated by pretreatment with a monoamine oxidase inhibitor. The brain polysome disaggregation induced by L-phenylalanine administration (1 g/kg) is not blocked by decarboxylase inhibition.     

Stress-accentuation of the LSD-induced disaggregation of brain polysomes

The application of three types of stress; restraint, food deprivation or epinephrine injection markedly accentuated the disaggregation of rabbit brain polysomes to monosomes induced by LSD (25 μg/kg) whereas no shift of polysomes to monosomes was found with any of the stress treatments alone. LSD when administered intravenously at a very low dose of 1 μg/kg and combined with the restraint procedure produced a massive brain polysome shift. LSD alone at this dosage did not induce a disaggregation of polysomes. Elevations in plasma corticosteroid levels relative to control were found following LSD administration with or without the stressing procedures. LSD and certain elements of environment and physiological arousal appear to have a synergistic effect on disrupting the protein synthesis apparatus of brain.     

PARTICIPATION OF DOPAMINE- AND SEROTONIN-RECEPTORS IN THE DISAGGREGATION OF BRAIN POLYSOMES BY l-DOPA AND l-5-HTP

Abstract— It has previously been shown that the disaggregation of brain polysomes and suppression of brain protein synthesis observed in rats given the amino acids l -dopa or l -5-HTP is mediated by the decarboxylation products dopamine and serotonin. Present studies demonstrate that the poly-some disaggregation is caused by the interactions of the monoamines with specific receptor sites. Thus, dopa-induced disaggregation is blocked if rats are pretreated with haloperidol or pimozide (but not methysergide or cyproheptadine), while 5-HTP-induced disaggregation is blocked by methysergide or cyproheptadine (but not by haloperidol or pimozide).
Pretreatment of rats with MK-486, a drug that inhibits dopa decarboxylase in blood vessels and peripheral tissues but not brain, does not block dopa-induced brain polysome disaggregation; hence this disaggregation depends on the interaction of dopamine with receptors in the brain parenchyma. Brain polysomes are not disaggregated in rats given intraperitoneal apomorphine (or intracisternal dopamine). The disaggregation caused by dopa is not reduced in animals pretreated with sufficient intracisternal 6-hydroxydopamine to cause major damage to catecholaminergic nerve terminals.     

IN VIVO INHIBITION OF RAT BRAIN PROTEIN SYNTHESIS BY d-AMPHETAMINE

Abstract— Between 1 and 4 h after rats received a single injection of d-amphetamine (15 mg/kg)(when brain polysomes are known to be disaggregated), the in vivo incorporation of [¹⁴C]lysine into trichloroacetic acid-precipitable brain protein was reduced by 28–48%. Incorporation of the ¹⁴C label into the protein present in a 100,000 g supernatant extract of whole brain was similarly reduced (by 44%). Amphetamine administration suppressed protein synthesis in rat cerebral cortex, cerebellum, hypothalamus, striatum, and brainstem to an equivalent extent. The drug did not significantly affect lysine pool sizes measured in these brain regions; thus the reduced incorporation of labeled lysine was not the result of an isotope dilution effect. We therefore conclude that the brain polysome disaggregation resulting from amphetamine administration is associated with decreased in vivo synthesis of some brain proteins.     

Inhibition of protein synthesis and induction of helical polysomes in rat liver by N-hydroxy-2-fluorenylacetamide

After a single intraperitoneal injection of the hepatocarcinogen N-hydroxy-2-fluorenylacetamide (OH-FAA), numerous helical polysomes were found in the hepatocytic cytoplasm at 2 and 6 but not 24 h after treatment. Electron microscopy also demonstrated nucleolar segregation, disarray of endoplasmic reticuium (ER), and disaggregation of polyribosomes at the times when helical polysomes were present. Polyribosome disaggregation was confirmed and quantified by determining size distribution of polyribosomes at 2 h after OH-FAA treatment. Protein synthesis was inhibited at the time of helical polysome induction but the degree of inhibition did not noticeably alter the number of helical polysomes found electron microscopically.     

Translation of mRNA associated with monosomes and residual polysomes following disaggregation of brain polysomes by LSD and hyperthermia

Intravenous administration of LSD to young adult rabbits induces a transient disaggregation of brain polysomes and a relocalization of mRNA from polysomes to monosomes. To analyze the spectrum of mRNA molecules which were associated with either the residual polysomes or the translationally inactive monosome complex, these two fractions were isolated on sucrose gradients and translated in a reticulocyte cell-free system. Analysis of [³⁵S]methionine labeled translation products by one and two dimensional gel electrophoresis revealed that a full spectrum of mRNA molecules was relocalized from polysomes to monosomes following drug induced polysome disaggregation. The only exception was the mRNA coding for the LSD-induced 74K protein which was associated with the residual polysome fraction and not with the monosome complex. This brain protein is similar in molecular weight to one of the major heat shock proteins which are induced in tissue culture cells following elevation of ambient temperature and disaggregation of existing polysomes. The mRNA coding for the 74K brain protein was not observed in polysomes isolated following blockage of LSD-induced hyperthermia but it was noted when hyperthermia was induced by elevation of ambient temperature. The mRNA species coding for the 74K protein was polyadenylated.     

Influence of the Dietary Protein Deficiency on the Activities of Ribosomes and Polysome Patterns in Muscle and Liver of Rats

A group of rats weighing about 120 g were killed at the beginning of the experiment and after 10 days on the 20% casein diet (C-0 and C-10 groups), and another group of rats were killed after 1, 2 and 10 days on the protein-free diet (PF-1, PF-2 and PF-10 groups). From muscle and the liver of each group ribosomes were prepared, and the protein synthesis activity and the polysome patterns were investigated. The activity of polysome fractionated into each size was also measured.

Muscle ribosome activity in PF-1, PF-2 and PF-10 groups decreased to about 60%, 40% and 40% of that in C groups, respectively, and this decrease was due to a fall in activity of polysome itself rather than disaggregation of polysome. Liver ribosome activity in PF-1, PF-2 and PF-10 groups were reduced to about 95%, 90% and 65% of that in C groups, respectively. These alterations in PF-1 and PF-2 groups seemed to be in part related to changes in polysome pattern, whereas ribosome activity in PF-10 group was reduced without changes in polysome pattern.     

RIBOSOME CRYSTALLIZATION IN CHICKEN EMBRYOS : II. Conditions for the Formation of Ribosome Tetramers In Vivo

Slow cooling of fertilized chicken eggs permits the elongation and termination of nascen^t polypeptides in the polysomes but prevents the initiation of new protein chains. This leads to polysome disaggregation during the first 30 min of cooling, and to the formation, of a pool of inactive ribosomes prone to crystallization. After 2 hr these ribosomes began to form tetramers, which do not contain any labeled proteins synthesized during cooling. If protein synthesis is inhibited by cycloheximide, added to eggs before cooling, tetramer formation in the embryos is prevented. Puromycin, on the other hand, leads to polysome disassembly and does not prevent tetramer formation. Rapid cooling of explanted embryos after short incubation at 37°C, with or without cycloheximide, largely prevents polysome disaggregation and the formation of tetramers. On the other hand, the addition of puromycin to explanted embryos promotes tetramer formation after rapid cooling. When cooled eggs are rewarmed, tetramers are disassembled into monomers, even if protein synthesis is inhibited. When those embryos were rapidly recooled tetramers reformed spontaneously from tetramer-derived monomers, even in the presence of cycloheximide. We conclude that the formation of tetramers at low temperature is an inherent property of the normal ribosomes.     

Inhibition of the initiation of hepatic protein synthesis during ethionine mediated ATP depletion in vivo: modification to ribosomal subunits, evidence of impaired ternary complex formation and a subcellular redistribution of eIF-2 alpha

Acute ethionine intoxication is known to induce a reversible hepatic injury in female rats by reducing the level of hepatic ATP. The injury indirectly impairs the initiation of hepatic protein synthesis, with resultant polysome disaggregation. Administration of adenine rapidly restores the ATP levels and protein synthesis. Analysis of liver polysome and ribosomal subunits reveals that polysome disaggregation occurs following 3 h of the intoxication, and reaggregation occurs following the administration of adenine. Inactive hepatic ribosomes accumulate as monomers and disomes when analysed by sucrose gradient sedimentation in low-salt buffers. High-salt buffers dissociate the inactive ribosomes into the component 40 S and 60 S subunits. The level of higher density, 1.48 g/cc, 40 S subunit increases during the inhibition of protein synthesis, while the lower density, 1.41 g/cc, 40 S subunit species does not change significantly. Hepatic microsomal and cytosolic extracts examined for their ability to support the formation of the ternary complex of eIF-2-GTP and [35S]Met-tRNAi demonstrate that during acute ethionine intoxication, ternary complex formation in the two extracts decrease 65% and 85%, respectively. These changes are coincident with polysome disaggregation. Administration of adenine to reverse the intoxication restores the ternary complex forming ability of the cytosolic extract, but does not affect the activity of the microsomal salt wash extracts. Mixing experiments indicate the accumulation of an inhibitor of ternary complex formation in the microsomal salt wash fraction. The application of quantitative western blotting demonstrates that the level of antigenic eIF-2 alpha in the microsomal salt wash extract increases 31% during the inhibition. These observations are consistent with the idea that the inhibition of the initiation of hepatic protein synthesis induced by ethionine is mediated by eIF-2 alpha phosphorylation. The latter results in an inhibition of ternary complex formation, redistribution of eIF-2 to the microsome fraction, polysomal disaggregation, and accumulation of inactive ribosomal subunits.     

Contact inhibition, polyribosomes, and cell surface membranes in cultured mammalian cells

An “overlay” method for rapidly and synchronously inducing contact inhibition in normal cultured cells has been developed. Using this method, disaggregation of cytoplasmic polyribosomes has been observed to occur within a matter of hours after overlay, followed by a decrease in cellular ribosomal RNA. Polysome disaggregation was influenced by the extent of cell-cell interaction and was inhibited by pretreatment of overlay cells with cycloheximide. Treatment of underlay cells with cytosine arabinoside also induced polysome disaggregation, but only after an appreciable lag as compared to that observed in overlaid cultures. Disaggregation could be induced by this method in cultured cells derived from normal tissue but not in cells derived from cancerous tissue. Polysome synthesis in growing “normal” cells (as measured by incorporation of tracer uridine into RNA) was markedly decreased when a cell surface membrane preparation was added to cultures.     

Effects of juvenile hormone on polysome integrity

Juvenile hormone inhibits protein and RNA synthesis in cell cultures from Trichoplusia ni and in the testicular germinal cysts of Hyalophora cecropia pupae in vitro. Sucrose gradient analyses revealed that the polysomes of both the T. ni cells and the germinal cysts were disaggregated almost immediately after the addition of juvenile hormone in vitro with a corresponding dose-dependent increase in monosomes. It is suggested that previous reports revealing juvenile hormone inhibition of ecdysone stimulated RNA and protein synthesis may be due to polysome disaggregation. Further studies demonstrated that the effect is not restricted to insect cells and can be elicited by several other lipids devoid of juvenile hormone morphogenetic activity. Experiments with broken cell preparations and isolated polysomes suggest the necessity of cell membrane integrity for the effect on the polysomes. Several probing studies utilizing cycloheximide, ribonuclease, and high K⁺ concentrations were conducted on the means by which juvenile hormone and other lipids may elicit polysome disaggregation.     

Effect of nucleoside triphosphate and magnesium ion concentration on the stability and function of rat liver polysomes in vitro

The effects of different concentrations of ATP, GTP, UTP and CTP on polysome stability and function in a cell-free protein-synthesizing system prepared from rat liver were studied. Increasing the concentration of ATP in the incubation medium to 15mm resulted in progressive disaggregation of the polysomes; at ATP concentrations above 2mm their capacity to incorporate amino acids into peptide chains diminished. The same disaggregation phenomenon could be produced by incubating polysomes in a buffered medium containing 5mm-Mg(2+) and increasing concentrations of ATP. Although the disaggregating action of ATP could be prevented by increasing Mg(2+) concentration, the amino acid incorporation in the cell-free protein-synthesizing system remained impaired. The effects of different concentrations of GTP, UTP and CTP on polysome stability were similar to those of ATP. Increasing the concentrations of each nucleoside triphosphate also inhibited the hydrolysis of GTP in the cell-free protein-synthesizing system.     

The breakdown of Tetrahymena ribosomes in vivo. The effects of inhibitors.

1. When Tetrahymena were deprived of nutrients 50% of the polysomes disaggregated within 20 min and 20% of the total RNA broke down in 2 h. Ribosomal RNA accounted for 75% of the RNA breakdown. 2. RNA labelled by a long incubation with [14C]uridine was stable in growing cells and in the presence of actinomycin D, but broke down at the same rate as bulk RNA in starved cells. 3. The following substances inhibited the loss of RNA during starvation: cycloheximide (which inhibited both polysome disaggregation and protein synthesis), inhibitors of energy metabolism and puromycin (all of which caused polysome disaggregation and inhibited protein synthesis), and chloroquine and 7-amino-1-chloro-3-L-tosylamidoheptan-2-one ('TLCK') (neither of which affected polysomes or protein synthesis). 4. Starvation appears to activate a ribosome degradation mechanism that may involve lysosomal and non-lysosomal enzymes.