Effect of a nutritional shift on the degradation of abnormal proteins in the mouse liver. Decreased degradation during rapid liver growth.

1. The intravenous injection of puromycin to mice 0.5 min after administration of radioactive leucine resulted in the release of labelled ribosome-bound nascent protein chains with the next 0.5 min. 2. During the subsequent 13 min, 40% of the liver protein radioactivity disappeared. The rate of this process was already maximal 0.5 min after the injection of puromycin, with no apparent lag. 3. Evidence is presented that this phenomenon represents the selective degradation of puromycinyl-peptides: (a) the magnitude of this fraction corresponded to the calculated proportion of protein radioactivity in nascent chains at the time of the puromycin effect; (b) the size distribution of the proteins disappearing between 2 and 14 min was smaller than that of those retained at 14 min; and (c) when the injection of puromycin was delayed for 5 min, or when the leucine pulse was interrupted by the injection of cycloheximide (rather than puromycin), the fraction disappearing within 14 min was much smaller. 4. The degradation of puromycinyl-peptides was much slower in the rapidly growing livers of animals recovering from a protein depletion than in the protein-depleted controls. It is concluded that the large decrease in the overall rates of total liver protein degradation previously described during liver growth is a general phenomenon, also affecting the rate of scavenging of abnormal proteins.     

Effect of post-ischaemic recovery on albumin synthesis and relative amount of translatable albumin messenger RNA in rat liver.

In liver cells recovering from reversible ischaemia, total protein synthesis by postmitochondrial supernatant and membrane-bound and free polyribosomes is not different from that in sham-operated controls. However, the relative proportion of specific proteins is changed, since the incorporation of [3H]leucine in vivo into liver albumin, relative to incorporation into total protein, as determined by precipitation of labelled albumin with the specific antibody, decreases by 40-50% in post-ischaemic livers. Cell-free synthesis by membrane-bound polyribosomes and poly(A)-enriched RNA isolated from unfractionated liver homogenate shows that the decrease in albumin synthesis in liver of rats recovering from ischaemia is due to the relative decrease in translatable albumin mRNA.     

The effects of hyperphenylalaninaemia on the concentrations of aminoacyl-transfer ribonucleic acid in vivo. A mechanism for the inhibition of neural protein synthesis by phenylalanine.

An acute administration of phenylalanine to neonatal animals has been reported to result in large decreases in the intracellular concentrations of several essential amino acids in neural tissue, as well as an inhibition of neural protein synthesis. The present report evaluates the effects of the loss of amino acids on the concentrations of aminoacyl-tRNA in vivo, with the view that an alteration in the concentrations of specific aminoacyl-tRNA molecules could be the rate-limiting step in brain protein metabolism during hyperphenylalaninaemia. tRNA was isolated from saline- and phenylalanine-injected mice 30-45 min after injection, by using a procedure designed to maintain the concentrations of aminoacyl-tRNA present in vivo. Periodate oxidation of the non-acylated tRNA and aminoacylation with radioactively labelled amino acids was used to determine the proportion of tRNA that was present in vivo as aminoacyl-tRNA. Although decreases in the intracellular concentrations of alanine, lysine and leucine were observed after phenylalanine administration, the concentrations of alanyl-tRNA, lysyl-tRNA and leucyl-tRNA actually increased by 15%. Although tryptophan has been suggested to be rate-limiting during hyperphenylalaninaemia, the proportion of tryptophan tRNA that was acylated was maximal in both normal and hyperphenylalaninaemic animals. This unexpected increase in aminoacyl-tRNA concentration is discussed as perhaps a secondary effect resulting from the phenylalanine-induced inhibition of protein synthesis. In contrast, the proportion of methionine tRNA that was acylated in vivo after phenylalanine administration was demonstrated to be decreased by approx. 17%. When the isoaccepting species of methionine tRNA were separated by reverse-phase column chromatography, three species were separated, one of which was demonstrated to be the initiator species, tRNAfMet, by the selective aminoacylation and formylation with Escherichia coli enzymes. After the administration of phenylalanine, the acylation of each of the three methionine tRNA species was decreased, with the initiator species being lowered by 10%. This effect on aminoacylation of tRNAfMet may be the primary step by which phenylalanine affects neural protein synthesis, and this is consistent with previous reports that re-initiation may be inhibited during hyperphenylalaninaemia.     

Biosynthesis in vitro of tryptophanase by polyribosomes from induced cultures of Escherichia coli

1. Polyribosomes were isolated from Escherichia coli grown in media in which tryptophanase is induced and in which it is repressed. The polyribosomes from the induced bacteria had a small amount of tryptophanase activity associated with them. 2. A portion of the enzyme activity remained bound to polyribosomes during centrifuging in sucrose gradients. 3. Incubation of tryptophanase-containing polyribosomes with puromycin released enzyme activity. 4. The binding of the enzyme to the polyribosomes did not depend on the presence of DNA. 5. When the polyribosomes were incubated under conditions of protein synthesis with supernatant fraction obtained from repressed bacteria, a small but statistically significant increase in enzyme activity was produced. 6. When a radioactive amino acid was included in the incubation mixture for the tryptophanase system a radioactive protein was obtained whose chromatographic, electrophoretic and sedimentation properties were identical with those of tryptophanase. 7. The amount of incorporation was consistent with the amount of new enzyme synthesis predicted by the increase in enzyme activity. Both radioactive incorporation and increase in enzyme activity were shown to be energy-dependent and also negative controls were obtained by using zero-time incubations or polyribosomes isolated from either repressed cells or a mutant lacking the ability to produce tryptophanase. 8. The distribution of radioactive leucine in the carboxyl region of the newly labelled tryptophanase was examined by digesting the labelled protein with carboxypeptidases. It was shown that the radioactivity was more highly concentrated towards the carboxyl terminus when the incubation times for protein synthesis were shorter (implying that, with longer incubation times, longer lengths of polypeptide chain contained radioactive amino acid residues).     

The kinetics of ribosomal peptidyl transfer revisited

The speed of protein synthesis determines the growth rate of bacteria. Current biochemical estimates of the rate of protein elongation are small and incompatible with the rate of protein elongation in the living cell. With a cell-free system for protein synthesis, optimized for speed and accuracy, we have estimated the rate of peptidyl transfer from a peptidyl-tRNA in P site to a cognate aminoacyl-tRNA in A site at various temperatures. We have found these rates to be much larger than previously measured and fully compatible with the speed of protein elongation for E. coli cells growing in rich medium. We have found large activation enthalpy and small activation entropy for peptidyl transfer, similar to experimental estimates of these parameters for A site analogs of aminoacyl-tRNA. Our work has opened a useful kinetic window for biochemical studies of protein synthesis, bridging the gap between in vitro and in vivo data on ribosome function.     

Response of Cultured Mammalian Cells to Diphtheria Toxin III. Inhibition of Protein Synthesis Studied at the Subcellular Level

Diphtheria toxin inhibited protein synthesis in intact KB cells. The action of the toxin upon the cell did not result in disaggregation of polyribosomes, or in impairment of their ability to function in protein synthesis. A reduction in single ribosomes and a concomitant increase in polyribosomes did result from the action of toxin. Nascent peptides were not cleaved from polyribosomes by the action of toxin, but treatment of fully intoxicated cells with puromycin resulted in cleavage of these peptides, and caused accelerated polyribosome breakdown. Our data indicated that the toxin must enter the cell to exert its effect. The component or components sensitive to toxin were localized in the 100,000 x g supernatant fraction of cytoplasmic extracts. When extracts from intoxicated cells were treated with nicotinamide, a significant proportion of their capacity to synthesize protein was restored. The specificity of this reaction suggested that nicotinamide adenine dinucleotide is involved in the action of toxin in the intact cell, and that one component inactivated by toxin is soluble transferase II.     

Inhibition by Thiopeptin of Bacterial Protein Synthesis

Thiopeptin, a sulfur-containing antibiotic, was found to inhibit protein synthesis in a bacterial ribosomal system. The pretreatment of ribosomal subunits with the antibiotic revealed that thiopeptin may act on the 50 S ribosomal subunit. The elongation of peptide chain on the ribosome is more profoundly blocked by the antibiotic than the initiation of protein synthesis. It was demonstrated that thiopeptin inhibits elongation factor (EF)-Tu-dependent GTP hydrolysis and binding of aminoacyl-tRNA to the ribosome. The peptidyl transferase-catalyzed puromycin reaction is not significantly affected by the antibiotic. Thiopeptin inhibits EF-G-associated GTPase reaction, and translocation of peptidyl-tRNA and mRNA from the acceptor site to the donor site. Protein synthesis in ribosomal systems, obtained from rat liver and rabbit reticulocytes are insensitive to the antibiotic.     

The distribution of ribosomes between different functional states in livers of fed and starved mice

1. To investigate the role of ribosome function in regulating protein synthesis, the activity, distribution and functional states of ribosomal particles were investigated in livers of mice fed ad libitum or starved overnight. 2. The distribution of protein-synthesizing activity between polyribosomes of different sizes was analysed after incorporation of radioactive leucine, and the quantitative distribution of ribosomes as native subunits, monomers and polyribosomes was analysed after incorporation of orotic acid. Precursors labelled with ³H or ¹⁴C were given separately to fed and starved mice, so that livers from the two groups of animals were processed together. 3. The former experiments showed that starvation has little effect on the distribution of protein-synthesizing activity across polyribosome sedimentation patterns, though the latter experiments showed that the proportion of ribosomes existing as monomers increased from 9.5% to 15.2%, whereas the proportion existing as polyribosomes decreased from 81.4% to 75.6%. Starvation had a negligible effect on the proportion of native subunits, which accounted for 9.1% and 9.2% of the ribosomes in fed and starved mice respectively. 4. The monomeric ribosome fraction was isolated and subjected to ionic conditions which selectively dissociate single ribosomes. Starvation increased the proportion of monomers that dissociated from 59% to 72%, so the monomers that accumulate in livers of starved animals are single ribosomes and not monoribosomes resulting from degradation of polyribosomes. 5. The fate of newly formed ribosomal particles was studied by measuring the specific radioactivity of native subunits, monomers and polyribosomes at different times after injection of radioactively labelled orotic acid. Starvation did not appear to affect equilibration between newly formed particles and polyribosomes, and the radioactivity of polyribosomes in both groups of mice reached about 90% of that in native subunits after 4h. The radioactive labelling of monomers proceeded at a slower rate, especially after starvation. At 4h, the radioactivity of monomers was 64% and 55% that of native subunits in fed and starved mice respectively.     

Measurement of the protein-synthetic activity in vivo of various tissues in rats by using [3H]Puromycin.

The validity of a new technique was examined for estimating the protein-synthetic activity of various tissues in vivo. The basic assumption underlying the method is that the number of peptide chains growing on each active ribosome would increase as the protein-synthetic activity of each tissue increases. The principle of the procedure, which was devised originally by Wool & Kurihara [(1967) Proc. Natl. Acad. Sci. U.S.A. 58, 2401-2407] to determine in vitro the number of functional ribosomes in skeletal muscle, is as follows. Puromycin is known to bind easily to the C-terminal end of the growing peptide on ribosomes and thus stop further chain elongation. Hence, if the number of puromycin molecules attached to the nascent peptide is determined by using radioactive puromycin as a tracer, one can estimate the number of growing peptides, i.e. the activity of tissue protein synthesis. By using this technique, it is shown that both starvation and the feeding of a protein-free diet caused marked decreases in the relative rate of formation of peptidyl-puromycin, i.e. activity of protein synthesis in liver, skeletal muscle, heart, spleen, testis, lung, kidney and intestine.     

The diurnal response of muscle and liver protein synthesis in vivo in meal-fed rats

1. The rate of protein synthesis in rat tissues was measured by constant intravenous infusion of [(14)C]tyrosine. A modification has been developed for the method of calculating the rate of protein synthesis in individual tissues from the specific radioactivity of the free and protein-bound amino acid in tissue at the end of the infusion. This technique gives greater accuracy and allows a greater choice of labelled amino acids. The specific radioactivity of free tyrosine in plasma was used to calculate the plasma tyrosine flux, an index of the rate of protein synthesis in the whole body. 2. Young male Wistar rats were allowed access to food for only 4h in every 24h. The tyrosine flux and the rate of protein synthesis in liver and muscle at different periods of time after a single feed were estimated. 3. The tyrosine flux did not alter after feeding nor even after starvation for 48h. 4. The average fractional rate of protein synthesis in muscle was 7.2%/day, i.e. the proportion of the protein mass which is replaced each day. The rate rose after eating and declined during starvation for 48h. In addition the rate of muscle protein synthesis correlated with the growth rate of the rat. 5. In liver the average fractional rate of protein synthesis was 50%/day. There was no change in the rate after eating nor after starvation for 48h. In contrast with muscle this suggests that the changes in protein mass were accompanied by changes in the rate of protein breakdown rather than synthesis.     

Cell-free synthesis of tryptophanase from Escherichia coli. Use of ribonucleic acid isolated from induced cells and a comparison of the product from a system employing ribosomes with that from one employing ribosomes and exogenous ribonucleic acid

1. Polyribosomes and RNA were isolated from cultures in which tryptophanase (EC 4.2.1.-) was induced. The polyribosomes were incubated under conditions of protein synthesis, in the presence of a radioactive amino acid and a post-ribosomal supernatant fraction obtained from repressed cells. The RNA preparations were incubated under conditions of protein synthesis in the presence of a radioactive amino acid and a supernatant fraction containing ribosomes from repressed cells. 2. The system was characterized and the synthesis of a radioactive protein with the same chromatographic properties as tryptophanase was demonstrated. This synthesis was shown to be time-dependent and required the presence of RNA from induced cultures, ribosomes and an energy supply; it was inhibited by chloramphenicol. 3. The maximum activity for the synthesis of this protein was found to be associated with 23S rRNA isolated from sucrose gradients. 4. The N-terminal amino acid of tryptophanase was labelled in the protein synthesized in this system but not in the protein synthesized by polyribosomes (without added RNA). Conversely, the C-terminal amino acid of tryptophanase was labelled in the polyribosome system but not in the RNA-containing system. 5. Tryptic digests of protein labelled in vitro were compared with those of tryptophanase. No labelled tryptic peptides were identified other than tryptophanase tryptic peptides. An analysis of the results implied that in the polyribosome system almost the complete tryptophanase subunit chain was labelled but that in the RNA-containing system these chains were incompletely synthesized. 6. Sucrose-gradient analysis of protein synthesized in the RNA-containing system suggested that it cannot be converted into structures with the same sedimentation properties as native tryptophanase. 7. The significance of these results for the assay of tryptophanase mRNA and for an understanding of the control of the translation of this mRNA in vivo is discussed.     

Mode of action of bottromycin A2: effect of bottromycin A2 on polysomes

When bottromycin A2 was added to an in vitro protein synthesis system carried out by naturally occurring polysomes, it inhibited protein synthesis effectively. Examination of the 3 steps of peptide chain elongation revealed that the binding of aminoacyl-tRNA to the polyribosomes was inhibited by bottromycin A2. In contrast, we concluded that the peptide bond formation and the translocation steps in this system were not inhibited by bottromycin A2 on the basis of the following observations: (1) The break-down of polysomes, which is dependent on EFG, puromycin and RR (ribosome releasing) factor, was insensitive to bottromycin A2; (2) The puromycin dependent release of polypeptide from polysomes, with or without EFG, was not inhibited by bottromycin A2. Thus bottromycin specifically interferes with proper functioning of the A sites of polysomes. This is consistent with the results obtained using the model system with synthetic polynucleotides.     

The protein-synthesizing activity of ribosomes isolated from the mammary gland of lactating and pregnant guinea pigs

1. Polyribosome preparations were made from the deoxycholate-treated post-nuclear fractions obtained by the disruption of mammary glands from lactating and pregnant guinea pigs. 2. A high proportion of large polyribosomes was obtained from the glands of lactating animals whereas mainly small polyribosomes were obtained from the glands of pregnant animals. The isolated preparations incorporated [(14)C]phenylalanine into protein. The polyribosomes from the glands of pregnant animals were less active than those from the glands of lactating animals but the activity of the former was stimulated more by poly(U) than was the latter. 3. The ribosomes from mammary gland could be dissociated into subunits after incubation, under conditions necessary for protein synthesis, in the presence of puromycin. The subunits could be recombined to give a preparation that actively polymerized [(14)C]phenylalanine in the presence of poly(U). The subunits from guinea-pig mammary gland could be combined with subunits from liver of either guinea pig or rat. Hybrid ribosomes were also formed from subunits derived from glands of pregnant and lactating animals. The hybrids were as active as were the ribosomes formed by reassociation of subunits from the same tissue, suggesting that in this respect the ribosomes from pregnant animals were not defective. 4. Polyribosomes from mammary glands of lactating animals when incubated with cell sap from the same source were tested for their ability to synthesize alpha-lactalbumin. The polyribosomes were incubated in the presence of [(3)H]leucine and alpha-lactalbumin was isolated from the supernatant. The protein was finally treated with cyanogen bromide and the C-terminal and N-terminal fragments were separated and their radioactivity was determined. Both fragments were radioactive consistent with the synthesis of alpha-lactalbumin. 5. The results are discussed in relation to protein synthesis in the mammary gland after parturition.     

Cytoplasmic effects of cortisol in liver

1. The time-course of the induction by cortisol of tryptophan pyrrolase in mouse liver was established. 2. The kinetics of labelling of mouse liver polyribosomes and the distribution of radioactivity in the various sizes of polyribosomes were investigated. It is concluded that the major part of the messenger RNA is monocistronic. 3. Cortisol administered to adrenalectomized mice stimulates in parallel the ability of ribosomes and polyribosomes, both free and bound, to incorporate amino acids into protein. 4. This stimulation does not appear to affect in a selective manner particular regions of the gradients of polyribosomes. 5. Administration of cortisol enhances the ability of the denser fraction of the rough microsomes to incorporate labelled amino acids. Adrenalectomy has minor effects on the pool sizes and specific radioactivities of liver amino acids which are counteracted by the hormone. However, these appear insufficient to influence the changes observed. 6. Adrenalectomy causes an increase in the percentage of ribosomes existing as polyribosomes and a fall in the proportion bound to the membrane of the endoplasmic reticulum. After treatment of these animals with cortisol there is a marked increase in the proportion of bound ribosomes. 7. The influence of cortisol on the membranous components of liver cytoplasm is discussed.     

The mode of action of alpha sarcin and a novel assay of the puromycin reaction.

A new technique was developed for measuring the amount of peptidyl-tRNA in a protein-synthesizing system in vitro. By this technique the course of the puromycin reaction may be followed and the modes of action of various inhibitors of protein synthesis readily determined. We conclude that the polypeptide alpha sarcin inhibits the binding of aminoacyl-tRNA into the ribosomal 'A' site, that sparsomycin inhibits the peptidyl transferase reaction and that cycloheximide may block translocation.     

Further studies on the effects of blocking agents on protein synthesis in goldfish brain

Abstract— In further experiments on the effects of antibiotic agents on protein synthesis in the goldfish brain, doses of intracranially-injected puromycin or acetoxycycloheximide higher than those previously employed did not hasten the onset of inhibition of incorporation of intraperitoneally-injected [³H]leucine into brain protein. The antibiotic-resistant incorporation was not due to the presence of labelled blood protein in the brain. After the intracranial injection of labelled puromycin, the appearance of radioactivity in the acid-soluble fraction of brain was blocked by acetoxycycloheximide. Repeated daily intracranial or intraperitoneal injections of puromycin were lethal, and acetoxycycloheximide was not protective, indicating that peptidyl-puromycin was present in the brain but did not account for the lethality of puromycin. Behavioural experiments argued against but did not totally exclude the possibility that peptidyl-puromycin was responsible for the amnestic effect of puromycin. Puromycin aminonucleoside, O-methyl tyrosine and 5-guanylyl methylenediphosphonate had little or no effect on protein synthesis in brain, but gougerotin was slightly inhibitory.     

Inhibitory effect of pH5 enzyme from non-lactating bovine mammary gland on various stages of protein synthesis in the rat liver amino acid-incorporating system

1. pH5 enzyme from non-lactating bovine mammary gland was found to contain potent inhibitors of protein synthesis in the rat liver cell-free system. These inhibitors affect (a) formation of aminoacyl-tRNA where tRNA represents transfer RNA, (b) transfer of labelled amino acids from rat liver amino[(14)C]acyl-tRNA to protein in rat liver polyribosomes, and (c) incorporation of (14)C-labelled amino acids into peptide by rat liver polyribosomes supplemented with rat liver pH5 enzyme. 2. Increasing amounts of pH5 enzyme from bovine mammary gland progressively inhibited the incorporation of labelled amino acids into protein by a complete incorporating system from rat liver. Approx. 80% inhibition was observed at a concentration of 2mg. of protein of pH5 enzyme from bovine mammary gland. The inhibitory effect of the bovine pH5 enzyme fraction could not be overcome by the addition of increasing amounts of rat liver pH5 enzyme. 3. Fractionation of bovine pH5 enzyme with ammonium sulphate into four fractions showed that all the fractions inhibited the incorporation of (14)C-labelled amino acids in the rat liver system, but to varying extents. The highest inhibition observed (90%) was exhibited by the 60%-saturated-ammonium sulphate fraction. 4. Heat treatment of bovine pH5 enzyme at various temperatures caused only a partial loss of its inhibitory effect on labelled amino acid incorporation by the rat liver system. Treatment at 105 degrees for 5min. resulted in the bovine pH5 enzyme fraction losing 30% of its inhibitory activity. 5. pH5 enzyme from bovine mammary gland strongly inhibited the charging of rat liver tRNA in the presence of its own pH5 enzymes. 6. The transfer of labelled amino acids from rat liver amino[(14)C]acyl-tRNA to protein in a system containing rat liver polyribosomes and pH5 enzyme was almost completely inhibited by bovine pH5 enzyme at a concentration of 2mg. of protein of the enzyme fraction. 7. One of the inhibitors of various stages of protein synthesis in rat liver present in bovine pH5 enzyme was identified as an active ribonuclease, and the second inhibitor present was shown to be tRNA.     

Functional modification of rat liver ribosomes by the in vitro action of N-methyl-N'-nitro-N-nitrosoguanidine

The mechanism by which N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) inhibits protein synthesis has been studied in a rat liver cell free system. Using preformed aminoacyl-tRNA it was observed that incorporation of amino acid into polyribosomal protein was inhibited in the presence of low concentration of MNNG. This inhibition was not reversed by increasing the concentration of soluble factors. Transfer RNAs modified previously by treatment with MNNG and subsequently esterified with amino acids were transferred to polyribosomes with the same efficiency as those species which were not modified. Polyribosomes, on the other hand, lost activity to incorporate amino acids after pretreatment with MNNG. This inactivation was dependent on the concentration of MNNG with which polyribosomes were treated. When poly(U) was used with MNNG-treated polyribosomes, its translation, after correction for endogenous translation, was also found to be significantly low as compared to the case with untreated polyribosomes. Purified ribosomes stripped of endogenous mRNA when treated with increasing concentrations of MNNG progressively lost ability to support polyphenylalanine synthesis programmed by poly(U). The treated ribosomes, however, neither inhibited the activity of control ribosomes nor induced any loss of fidelity of translation by poly(U). It is concluded that MNNG inhibits protein synthesis through functional inactivation of ribosomes resulting from direct modification of ribosomal proteins possibly involving nitroguanidination of lysine residues.     

Reactivity of the P-site-bound donor in ribosomal peptide-bond formation

The puromycin reaction, catalyzed by the ribosomal peptidyltransferase, has been carried out so as to make the definition of two distinct parameters of this reaction possible. These are (a) the final degree of the reaction which gives the proportion of peptidyl (P)-site binding of the donor and (b) the reactivity of the donor substrate expressed as an apparent rate constant (kobs). This kobs varies with the concentration of puromycin; the maximal value (k3) of the kobs, at saturating concentrations of puromycin, gives the reactivity of the donor independently of the concentrations of both the donor and puromycin. k3 is also a measure of the activity of peptidyltransferase expressed as its catalytic rate constant (kcat). If we assume that the puromycin-reactive donor is bound at the ribosomal P site, we observe the following, depending on the conditions of the experiment: the proportion of P-site binding of the donor substrates AcPhe-tRNA or fMet-tRNA can be the same and close to 100%, while there is a tenfold increase in the reactivity of the donor (k3 = 0.8 min-1 versus 8.3 min-1). On the other hand there are conditions, under which the proportion of P-site binding increases from 30% to 100% while k3 remains low and equal to 0.8 min-1. Using the puromycin reaction it was also found that an increase of Mg2+ from 10 mM to 20 mM reduces the reactivity of the donor and, hence, the activity of peptidyltransferase, provided that this change in Mg2+ occurs during the binding of the donor but not when it occurs during peptide bond formation per se. The fact that the donor substrate may exist in various states of reactivity in this cell-free system raises the possibility that the rate of peptide bond formation may not be uniform during protein synthesis.     

INTERACTIVE EFFECTS OF CYCLOHEXIMIDE AND PUROMYCIN IN ALTERING BRAIN POLYRIBOSOMES AND NEURAL AND BEHAVIOURAL RESPONSES TO ELECTROSHOCK IN MICE

Abstract— Interactive effects of puromycin and cycloheximide on brain polyribosomes and cortical electrical activity were investigated. The time courses of action of the drugs on these parameters, in comparison to their inhibitory actions on protein synthesis, were also observed. The results indicate that the disruption of brain polyribosomes by cycloheximide was independent of its inhibition of protein synthesis, whereas the two processes were closely linked in the case of puromycin. For both the disruption of polyribosomes and the alteration of electrical activity, the order in which the drugs were administered was critical, with preadministration of cycloheximide having a protective effect. In contrast to the massive effect of cycloheximide on brain polyribosomes, the drug had no such effect on polyribosomes from liver.