Rapidly labelled ribonucleic acid from rat liver. Studies in the attachment to ribosomes and stimulation of the incorporation of amino acids into polypeptides in cell-free systems

1. Rapidly labelled RNA from rat liver, either as a complex with DNA (m-RNA-DNA) or with ribosomal RNA (m-RNA-RNA) binds to ribosomes in the polysome region. No binding could be demonstrated with ribosomal RNA or native DNA from Bacillus subtilis. 2. With ribosomes from rat liver, Escherichia coli or hepatoma the m-RNA-DNA stimulated incorporation of amino acids with rat-liver ribosomes only, whereas the m-RNA-RNA complex was effective with ribosomes from E. coli or the hepatoma. 3. Polyuridylic acid was effective as messenger RNA with all three ribosomes but much greater stimulation was obtained with ribosomes from E. coli and the hepatoma. 4. The degree of incorporation of phenylalanine with polyuridylic acid and ribosomes from a hepatoma was decreased by about 50% when ribosomal RNA was present.     

Lack of effect of amino acid concentration on protein synthesis in the perfused rat liver.

The effect of increasing the perfusate concentration of amino acids on the incorporation of labelled valine into protein was followed in perfusions of rat livers lasting for 2h. A fixed amount of labelled and unlabelled valine was added to the perfusate as the other amino acids were increased in multiples of the concentrations normally found in rat plasma. Under these conditions no increase in valine incorporation was observed, which appeared to be in conflict with results published by other workers, However, a different method of labelling from that used here was used in the earlier studies. An increasing amount of a labelled amino acid was added as the concentrations of the unlabelled amino acids were increased in the perfusate. An experiment directly comparing to the two labelling methods produced results that indicated that the apparent increase in liver protein synthesis observed by the other workers could have been due to the method of radioisotope addition. It is therefore concluded that increasing the perfusate concentration of amino acids does not increase amino acid incorporation into liver protein.     

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.     

Influence of amino acid supply on ribosomes and protein synthesis of perfused rat liver

1. The livers of rats were perfused in situ with medium containing mixtures of amino acids in multiples of their concentration in normal rat plasma. The incorporation of labelled amino acid into protein of the liver and of the perfusing medium increased with increasing amino acid concentration. During 60min. perfusions, labelling of liver protein reached a plateau, and labelling of medium protein was inhibited when the initial concentration of the amino acid mixture was more than ten times the normal plasma value. 2. Examination of polysome profiles derived from livers perfused without amino acids in the medium showed that the number of large aggregates was decreased and the number of small aggregates, particularly monomers and dimers, was increased with time of perfusion. The addition of amino acids to the perfusion medium reversed this polysome shift to an extent that was dependent on the initial concentration of amino acids. Polysome profiles derived from livers perfused for 60min. with ten times the normal plasma concentration of amino acids were essentially the same as the polysome profiles of normal non-perfused livers. 3. The ability of ribosome preparations from perfused livers to incorporate amino acids into protein in vitro decreased with increasing time of perfusion when no amino acids were added to the medium, but increased as the concentration of amino acids in the perfusion medium was increased. 4. The ability of cell sap from perfused livers to support protein synthesis in vitro was not influenced by the amino acid concentration of the perfusion medium. 5. Livers were perfused for 60min. with medium containing amino acid mixtures at ten times the normal plasma concentration but deficient in one amino acid. Maximal incorporation of labelled amino acid into liver protein, the stability of the polysome profile and the ability of ribosome preparations to incorporate amino acids into protein were found to depend on the presence of 11 amino acids: arginine, asparagine, isoleucine, leucine, lysine, methionine, phenylalanine, proline, threonine, tryptophan and valine. A mixture of these 11 amino acids, at ten times their normal plasma concentration, stimulated the incorporation of labelled amino acid into liver protein, stabilized the polysome profile and increased the ability of ribosome preparations to incorporate amino acids into protein to the same extent as the complete mixture. 6. It is concluded that the availability of certain amino acids plays an important role in the control of protein synthesis, possibly by stimulating the ability of ribosomes to become, and to remain, attached to messenger RNA.     

Evidence for the absence of the terminal adenine nucleotide at the amino acid-acceptor end of transfer ribonucleic acid in non-lactating bovine mammary gland and its inhibitory effect on the aminoacylation of rat liver transfer ribonucleic acid

1. tRNA isolated from non-lactating bovine mammary gland competitively inhibits the formation of aminoacyl-tRNA in the rat liver system. 2. Non-lactating bovine mammary gland tRNA and twice-pyrophosphorolysed rat liver tRNA are unable to accept amino acids in a reaction catalysed by aminoacyl-tRNA synthetases from either rat liver or bovine mammary gland. Deacylated rat liver tRNA can however be aminoacylated in the presence of either enzyme. 3. Bovine mammary gland tRNA lacks the terminal adenine nucleotide at the 3′-terminus amino acid acceptor end, which can be replaced by incubation in the presence of rat liver nucleotide-incorporating enzyme, ATP and CTP. 4. The enzymically modified bovine tRNA (tRNApCpCpA) can bind labelled amino acids to form aminoacyl-tRNA, which can then transfer its labelled amino acids to growing polypeptide chains on ribosomes. 5. Molecules of rat liver tRNA or bovine mammary gland tRNA that lack the terminal adenine nucleotide or the terminal cytosine and adenine nucleotides inhibit the aminoacylation of normal rat liver tRNA to varying degrees. tRNA molecules lacking the terminal −pCpCpA nucleotide sequence exhibit the major inhibitory effect. 6. The enzyme fraction from bovine mammary gland corresponding to that containing the nucleotide-incorporating enzyme in rat liver is unable to catalyse the incorporation of cytosine and adenine nucleotides in pyrophosphorolysed rat liver tRNA and deacylated bovine tRNA. This fraction also markedly inhibits the action of the rat liver nucleotide-incorporating enzyme.     

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.     

Amino acid incorporation in a cell-free system derived from rat liver studied with the aid of selenodiglutathione

Selenodiglutathione (GSSeSG), a potent inhibitor of elongation factor 2 (EF2) has been used to study amino acid incorporation in a rat liver cell-free system. While translocation of the ribosomes was inhibited by GSSeSG, ribosomes with a free acceptor site were still capable of incorporating one amino acid residue. From this the average number of amino acids incorporated per ribosomes was calculated to be 2--5. In this respect virtually no difference has been observed between ribosomes present on small or large aggregates. The time required for one translocation by all active ribosomes, and the time required for the incorporation of one amino acid (starting with aminoacyl-tRNA or amino acids) has also been determined. By incubation under conditions for amino acid incorporation, part of the ribosomes were completely inactivated whereas the rest remained as active as at the start of the incubation.     

A direct effect of growth hormone on the incorporation of precursors into proteins and nucleic acids of perfused rat liver

1. The livers of rats were perfused in situ. When the amino acid concentration in the perfusing medium was that present in rat plasma, the addition of growth hormone to the medium stimulated the incorporation of labelled amino acids into liver protein only marginally and not to a statistically significant extent. When, however, the amino acid concentration was raised to three times that present in rat plasma, growth hormone significantly and substantially stimulated amino acid incorporation into protein within 30min. of perfusion of normal rat liver. 2. A significant effect of growth hormone on labelling of normal rat-liver protein was seen with concentrations not much greater than those reported to be present in rat plasma. 3. The labelling of nucleic acids of normal and hypophysectomized rat liver by [(3)H]orotic acid was enhanced by addition of growth hormone to the perfusing medium when normal concentrations of amino acids were used. 4. At elevated concentrations of amino acids, growth hormone stimulated labelling of nucleic acids of hypophysectomized rat liver at 30 and 60min. of perfusion. Under these conditions, nucleic acids of normal rats were labelled to about the same extent in control and hormone-treated livers at 30min. and, because of a fall in the radioactivity of the control livers, there was more labelled nucleic acids in growth-hormone-treated livers at 60min. than in the control livers. 5. Growth hormone, unlike insulin, had no inhibitory effect on the release of glucose by the perfused liver. 6. It is concluded that growth hormone can stimulate the incorporation of precursor into proteins and nucleic acids of liver directly and without the mediation of other organs or of insulin.     

Protein synthesis by membrane-bound and free ribosomes of the developing rat cerebral cortex

1. Rates of RNA and protein synthesis were measured in rat cerebral-cortex slices, and compared with amino acid incorporation into protein by membrane-bound and free ribosomes from the same tissue, in the first 3 weeks of life. 2. A rapid age-dependent decline in the incorporation of labelled precursors into both RNA and protein was observed, which was more marked for amino acid incorporation into protein. 3. Although membrane-bound ribosomes comprise only a small fraction of total ribosomes, they were more active in incorporating amino acids into protein than were free ribosomes, especially immediately after birth. The decline in activity with age was more marked in the membrane-bound fraction than in free ribosomes. This loss of activity was largely independent of alterations in soluble factors or endogenous mRNA content and appeared to involve some alteration of the function of the ribosome itself, with relatively small alterations in the ratio of membrane-bound to free ribosomes. 4. Thyroidectomy, performed soon after birth, had no effect on the incorporation of radioactive precursors into RNA or protein by either slices or the cell-free preparations during the first 3-4 weeks of life.     

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.     

Biochemical changes in mouse liver after palmitoyl-ethanolamide (PEA) administration

PEA (palmitoylethanolamide; N-(2-hydroxyethyl)palmitamide) daily and orally administered to male mice caused: (1) increased incorporation of labelled orotic acid into DNA and RNA, (2) an increase in the activity of uridine kinase and decrease of tryptophan pyrrolase, (3) decreased ribonuclease activity of isolated liver ribosomes, (4) raising of specific radioactivity after injection of labelled amino acids in both mitochondrial and microsomal fractions of liver homogenate, (5) increased incorporation of [¹⁴C]-palmitic acid and ³²P into liver phospholipids.     

Different binding of poly(A)-containing and poly(A)-free fractions of nuclear ribonucleic acid to ribosomes from rat liver.

Total nuclear RNA extracted from nuclei of rat liver cells by phenol/chloroform in the presence of sodium dodecyl sulphate was separated by combined gel filtration on Sepharose 4 B and affinity chromatography on poly(U) Sepharose into fractions differing in their molecular weights and contents of poly(A) sequences. The poly(A)-containing 45-S RNA became labelled most rapidly if rats were administered [3H] orotic acid. This fraction showed a high template activity when added to postmitochondrial supernatants of the Krebs ascites tumour. Fractions of nRNA, free of poly(A) sequences, had no stimulating effect on protein synthesis in this system. The 45-S RNA-containing poly(A) was readily bound to crude polyribosomes from rat liver at 0 degrees C and both ATP and GTP were necessary for this reaction. Sucrose gradient analyses provided evidence that this RNA species is bound predominantly to 80-S ribosomes. No binding was obtained with polyribosomes washed with 0.5 M KCl. The binding ability of washed polyribosomes was restored by the addition of the ribosomal wash fraction or rat liver cytosol. Crude polyribosomes bound significantly lower quantities of nRNA species free of poly(A) when compared with poly(A)-45-S RNA. The label was scattered through the whole ribosomal sedimentation pattern with no predominant peaks and the binding reaction required neither soluble factors nor nucleotide cofactors. The labelling kinetics and high template activity of poly(A)-45-S nRNA indicate that this fraction contains precursors of cytoplasmic mRNA. Requirements for soluble factors and nucleotide cofactors in the binding of this RNA species to 80-S ribosomes suggest that this binding, unlike that of other nRNA species, has a specific mechanism resembling that of mRNA binding during peptide initiation.     

Rat liver bile acid CoA:amino acid N-acyltransferase: expression,characterization, and peroxisomal localization

Bile acid CoA:amino acid N-acyltransferase (BAT) is responsible for the amidation of bile acids with the amino acids taurine and glycine. Rat liver BAT (rBAT) cDNA was isolated from a rat liver lambdaZAP cDNA library and expressed in Sf9 insect cells using a baculoviral vector. rBAT displayed 65% amino acid sequence homology with human BAT (hBAT) and 85% homology with mouse BAT (mBAT). Similar to hBAT, expressed rBAT was capable of forming both taurine and glycine conjugates with cholyl-CoA. mBAT, which is highly homologous to rBAT, forms only taurine conjugated bile acids (Falany, C. N., H. Fortinberry, E. H. Leiter, and S. Barnes. 1997. Cloning and expression of mouse liver bile acid CoA: Amino acid N-acyltransferase. J. Lipid Res. 38: 86-95). Immunoblot analysis of rat tissues detected rBAT only in rat liver cytosol following homogenization and ultracentrifugation. Subcellular localization of rBAT detected activity and immunoreactive protein in both cytosol and isolated peroxisomes. Rat bile acid CoA ligase (rBAL), the enzyme responsible for the formation of bile acid CoA esters, was detected only in rat liver microsomes. Treatment of rats with clofibrate, a known peroxisomal proliferator, significantly induced rBAT activity, message, and immunoreactive protein in rat liver. Peroxisomal membrane protein-70, a marker for peroxisomes, was also induced by clofibrate, whereas rBAL activity and protein amount were not affected. In summary, rBAT is capable of forming both taurine and glycine bile acid conjugates and the enzyme is localized primarily in peroxisomes in rat liver.     

Effects of the hepatotoxic agents retrorsine and aflatoxin B1 on hepatic protein synthesis in the rat

1. Aflatoxin and the pyrrolizidine alkaloid retrorsine inhibited the incorporation of labelled amino acids into rat liver and plasma proteins in vivo. Inhibition was greater and detected earlier with retrorsine (1hr.) than with aflatoxin (3hr.). 2. Both toxins affected the liver ribosomal aggregates, causing increases in the proportion of monomers plus dimers. The effect of retrorsine was greater than that of aflatoxin. 3. Incorporation of labelled amino acids into proteins of cell-free preparations of liver from rats treated with aflatoxin was lower than in control preparations. The main site of inhibition appeared to be the ribosomes. 4. Both toxins inhibited the incorporation of orotate into liver nuclear RNA 1hr. after administration.     

Quantification and regulation of the subcellular distribution of bile acid coenzyme A:amino acid N-acyltransferase activity in rat liver

Bile acid coenzyme A:amino acid N-acyltransferase (BAT) is responsible for the amidation of bile acids with the amino acids glycine and taurine. To quantify total BAT activity in liver subcellular organelles, livers from young adult male and female Sprague-Dawley rats were fractionated into multiple subcellular compartments. In male and female rats, 65-75% of total liver BAT activity was found in the cytosol, 15-17% was found in the peroxisomes, and 5-10% was found in the heavy mitochondrial fraction. After clofibrate treatment, male rats displayed an increase in peroxisomal BAT specific activity and a decrease in cytosolic BAT specific activity, whereas females showed an opposite response. However, there was no overall change in BAT specific activity in whole liver homogenate. Treatment with rosiglitazone or cholestyramine had no effect on BAT activity in any subcellular compartment. These experiments indicate that the majority of BAT activity in the rat liver resides in the cytosol. Approximately 15% of BAT activity is present in the peroxisomal matrix. These data support the novel finding that clofibrate treatment does not directly regulate BAT activity but does alter the subcellular localization of BAT.     

Effect of some polycyclic aromatic hydrocarbons on protein synthesis in vitro

1. The effect of the strongly carcinogenic polycyclic aromatic hydrocarbons benzo[a]pyrene, 3-methylcholanthrene and dibenz[a,h]anthracene and of the non-carcinogenic anthracene, pyrene and phenanthrene on protein synthesis was studied in vitro with subcellular systems from rat liver. 2. Both types of hydrocarbons affect amino acid activation and inhibit transfer of labelled amino acids from transfer RNA to ribosomes. 3. Only the carcinogenic compounds stimulate the incorporation of labelled algal-protein hydrolysate and of some individual amino acids into transfer RNA. The most active dose was 10mmug. under the conditions used. This effect is abolished by preincubation of pH5 enzymes with the carcinogens before the addition of radioactive amino acids. 4. The carcinogens stimulate the incorporation of some amino acids into ribosomal protein whereas the non-carcinogenic compounds have no such effects. 5. Polynucleotide-dependent stimulation of protein synthesis is greatly enhanced in the presence of the carcinogenic hydrocarbons when either free amino acids or transfer RNA charged with labelled amino acids are used. The non-carcinogenic compounds induce a partial inhibition of this process. 6. It is concluded, in agreement with other authors, that carcinogens may increase the number of active incorporation sites on both transfer and ribosomal RNA. Possible mechanisms of such an effect are discussed.     

Partial purification, characterization and translation in vitro of rat liver metallothionein messenger ribonucleic acid.

Poly(A)+ (polyadenylated) mRNA coding for metallothioneins was purified 13-fold from rat liver polyribosomes and was identified by its ability to direct the biosynthesis of these proteins in a wheat-germ cell-free system. The carboxymethylated products of the protein-synthesizing system in vitro were analysed with sodium dodecyl sulphate/20% polyacrylamide-gel electrophoresis. The labelled compounds [3H]serine and [35S]cysteine were incorporated at high specific radioactivity into proteins that co-migrated with authentic metallothioneins. No [3H]leucine incorporation was found, in agreement with the amino acid composition of the metallothioneins. Metallothionein mRNA had a sedimentation coefficient of 9 S and carried a maximum of four ribosomes. At 5 h after a subcutaneous injection of ZnCl2 or CdCl2 (10 mumol/kg body wt.), the amount of this mRNA increased approx. 2- and 4-fold respectively, on the basis of translation in vitro. The increase in metallothionein mRNA (defined by translation in the wheat-germ system) was transient and, after CdCl2 treatment, fell back to control values by 17 h. Metallothioneins constituted a maximum of 0.8% of the total protein products synthesized in the wheat-germ system by total mRNA isolated from rat liver after CdCl2 treatment.     

Calcitonin increases fatty acid synthetase activity dependently of calcium-calmodulin in the hepatic cytosol of fed rats

The effect of calcitonin (CT) on fatty acid synthetase activity in the hepatic cytosol was investigated after a single subcutaneous administration of the hormone to fed rats. Administration of CT (synthetic [Asu1,7] eel CT; 80 MRC mU/100 g body weight) produced significant increases in fatty acid synthetase activity and calcium concentration in the hepatic cytosol of intact and thyroparathyroidectomized rats. The hormonal effect on the enzyme activity was not observed in rats fasted for 24 h. The increase in fatty acid synthetase activity by CT administration was completely inhibited by treatment with 10 microM EGTA. This enzyme activity was restored by addition of calcium ion (2.5-10 microM). The increased enzyme activity of CT-treated rats was markedly reduced by addition of W-7 (15 microM), a calmodulin inhibitor, in the enzyme assay system. Moreover, the cytosolic enzyme activity of normal rat liver was markedly raised by in vitro addition of both calcium ion (5 microM) and calmodulin (2.5 micrograms). These results suggest that CT increases fatty acid synthetase activity in the hepatic cytosol of fed rats, and that this hormonal regulation may depend on calmodulin, and be mediated through raised calcium in the cytosol.     

Stimulatory effect of gamma-aminobutyric acid upon animo acid incorporation into protein by a ribosomal system from immature rat brain

Abstract—

• 1 GABAstimulated the incorporation of L-[U-¹⁴C]leucine, primarily into the particulate protein of a ribosomal system from immature rat brain, but not from immature rat liver.
• 2 The GABA effect required the presence of Na⁺ and occurred at GABA concentrations which are thought to be physiological (1–5 mM).
• 3 Of all other amino acids tested at tissue extract concentrations in the system, only glycine had a similar effect. No analogues of GABA tested had a significant stimulatory effect upon leucine incorporation into protein, with the exception of homocarnosine which was mildly stimulatory.
• 4 The effect of GABA upon the incorporation of L-[U-¹⁴C]leucine was examined in the presence of added amino acid substrates, both individually and as mixtures. Also, the incorporation of L-[U-¹⁴C]leucine was compared with incorporation of L-[U-¹⁴C]Iysine and L-[U-¹⁴C]phenylalanine. The results are discussed in terms of GABA interaction with activating, transfer and transport mechanisms of other amino acids, inhibition of proteinase activity, and the possibility that GABA is stimulating the synthesis or turnover of specific proteins in the brain ribosomal system.
• 5 The results illustrate the fact that studies of ‘protein synthesis’ in immature rat brain ribosomes, as measured by amino acid incorporation, will yield answers which depend heavily upon substrate conditions and upon the labelled amino acid used as the marker for protein synthesis or turnover.

     

Identification by RNA-protein cross-linking of ribosomal proteins located at the interface between the small and the large subunits of mammalian ribosomes

Protein constituents at the subunit interface of rat liver ribosomes were analysed by cross-linking with the bifunctional reagent, diepoxybutane (distance between reactive groups 4 A). Isolated 40S and 60S subunits were labelled with 125I and recombined with unlabelled complementary subunits. The two kinds of selectively labelled 80S ribosomes were treated with diepoxybutane at low concentration. Radioactive ribosomal proteins covalently attached to the rRNA of the unlabelled complementary subparticles were isolated by repeated gradient centrifugation. The RNA-bound, labelled proteins were identified by two-dimensional gel electrophoresis. The experiments showed that proteins S2, S3, S4, S6, S7, S13, and S14 in the small subunit of rat liver ribosomes are located at the ribosomal interface in close proximity to 28S rRNA. Similarly, proteins L3, L6, L7, and L8 were found at the the interface of the large ribosomal subunit in the close vicinity of 18S rRNA.