REGULATION OF PROTEIN SYNTHESIS IN DEVELOPING MOUSE BRAIN TISSUE: IN VITRO BINDING OF TEMPLATE RNA TO BRAIN RIBOSOMES

Abstract— Ribosomes, isolated from brain tissue of mice of various ages, were tested for their ability to participate in cell-free protein synthesis and to bind polyuridylic acid. Although protein synthesis was markedly reduced by ribosomal preparations obtained from increasingly older animals, no significant differences could be measured with respect to template RNA binding. Similar binding properties were also measured with ribosomal subunits purified from young and mature brain cell ribonucleoprotein particles. In addition, no differences could be detected in the relative firmness of template RNA binding that could explain the maturation-dependent loss in ribosomal activity.     

Comparison of cell-free protein synthesis by different regions of chicken brain

The cell-free protein synthesis by the postmitochondrial supernatant from chicken cerebrum was twofold greater than protein synthesis by the cerebellum or optic lobes. Ribosomal aggregation of mRNA and ribonuclease activity of the postmitochondrial supernatant from the three brain regions was not statistically different. The higher protein synthetic activity of the cerebral postmitochondrial supernatant was associated with both the postribosomal supernatant (cell sap) and microsomal fractions. Cerebral monomeric ribosomes were more active in polyuridylic acid directed polyphenylalanine synthesis than monomeric ribosomes from either the cerebellum or optic lobes. The ability of cerebral cell sap to support polyuridylic acid directed polyphenylalanine synthesis was 1.6 to 2 times greater than cell sap from the other two regions. Cell sap factors other than tRNA^phe or phenylalanyl-tRNA synthetases appear to be responsible for the higher protein synthetic activity of the cbr cell sap.     

Regulation of Prenatal and Postnatal Protein Synthesis in Mouse Brain

Abstract: Regulation of protein synthesis during prenatal and postnatal brain development was examined using postmitochondrial supernatant (PMS) fractions and isolated ribosome-pH 5 enzyme systems from fetal, neonatal, and adult neural tissue. The rate of polyuridylic acid (poly-U)-dependent protein synthetic activity was inversely proportional to the endogenous rate of protein synthesis in either the PMS fractions or ribosomal preparations. A careful analysis of the kinetics of the poly-U-dependent polypeptide synthesis revealed that there was a lag in the time at which certain of the PMS preparations could begin to utilize the poly-U template as sole source of mRNA. The lag period was dependent upon the developmental age of the neural tissue used and the Mg²⁺ concentration of the protein synthesis reaction. Since previous work reported that the observed developmental decrease in the rate of polypeptide synthesis utilizing a poly-U template could not be measured in a purified ribosomal-pH 5 enzyme system, ribosomes were obtained by several isolation techniques to determine if the purification procedure might have affected the ribosomes in some manner by removing a specific protein(s) involved in ribosome-cytosol interactions. At 6 mM-Mg²⁺ the rate of poly-U-dependent protein synthesis was inversely proportional to the rate of endogenous synthesis and depended upon the method used to isolate the ribosomes: microsomes ∼Triton X-100-treated < DOC-treated < KCl-treated. However, there was no age-dependent effect with any of the ribosomal preparations. The data suggest that there is a developmental modulating effect of ribosomal activity in PMS preparations which is not found in association with the isolated ribosome-pH 5 enzyme protein synthesizing system.     

Differences in the ribosomes prepared from lactating and non-lactating bovine mammary gland

1. Ribosomes prepared from bovine lactating mammary gland are able to synthesize protein, whereas similar preparations from non-lactating glands are not. Washing the ribosome suspensions through a medium containing 0.5m-ammonium chloride enhanced their ability to incorporate phenylalanine into polyphenylalanine. 2. Ribosomes isolated from non-lactating bovine mammary gland, in contrast with those from rat liver and lactating mammary gland, contained significant amounts of extraneous nucleases. These enzymes could be removed by washing with a medium A buffer containing 0.5m-ammonium chloride. 3. Only those ribosomes from functionally active tissues were able to bind polyuridylic acid and phenylalanyl-tRNA.     

CHARACTERISTICS AND PRODUCTS OF A CELL-FREE POLYPEPTIDE SYNTHESIZING SYSTEM FROM NEONATAL AND ADULT MOUSE BRAIN

—The regulation of protein synthesis by ribosomes isolated from mouse brain tissue was studied using a cell-free polyphenylalanine synthesizing system. Polypeptide synthesis was followed by assaying translocation and analysing the reaction products by BD-cellulose chromatography. The brain ribosomal activity could be divided by these methods into two distinct steps : binding of aminoacyl-tRNA to the ribosome and active translocation leading to subsequent polyphenylalanine synthesis. In comparison to initial binding of aminoacyl-tRNA, translocation in the cell-free system increased the incorporation of labelled phenylalanine by 10-fold. An analysis of the reaction products clearly showed active ribosomal synthesis of oligophenylalanine from [³H]phe-tRNA. Ribosomes isolated from neonatal brain tissue were 2–4 times as active as those obtained from adult brain tissue in polypeptide synthesis. In addition, polypeptides synthesized on the more active ribosomes from neonates tended to be of greater chain length than those from adult. Therefore, the maturation-dependent decrease in ribosomal protein synthetic activity during neural development was shown to be directly associated with the ribosome particles.     

The attachment of polyuridylic acid to reticulocyte ribosomes

The attachment of polyuridylic acid to reticulocyte ribosomes was studied by using polyadenylic acid, which inhibits the attachment reaction only, while permitting translation of polyuridylic acid bound to ribosomes. After addition of polyadenylic acid the amount of polyphenylalanine synthesized under standard conditions was taken as a measure of the bound polyuridylic acid. In this way certain parameters of the attachment reaction and the subsequent translation of attached polyuridylic acid were defined: (1) polyuridylic acid-ribosome interaction at 37 degrees requires only Mg(2+) at an optimum concentration of 8mm; (2) K(+) (required for translation) is a non-competitive inhibitor of the attachment reaction; (3) optimum polyphenylalanine synthesis directed by attached polyuridylic acid occurs at 5mm-Mg(2+) concentration; (4) from kinetic studies single ribosomes appear to participate in the attachment reaction.     

Regulation of Protein Synthesis in Zoospores of Blastocladiella

The factors responsible for the regulation of protein synthesis in the zoospores of Blastocladiella emersonii were studied by means of cell fractionation and in vitro assays. Charged transfer ribonucleic acid (tRNA) and aminoacyl-tRNA synthetases were found both inside the membrane-bound, ribosomal nuclear cap, and in the extracap cytoplasm. Ribosomes isolated from zoospore nuclear caps in low salt buffer failed to support polyuridylic acid-dependent phenylalanine incorporation. After washing with high salt buffer, the cap ribosomes were equivalent in activity to similarly prepared plant ribosomes. Both the high-salt wash from cap ribosomes and the extracap supernatant fraction contained an unidentified material which inhibited aminoacyl-tRNA binding and peptide bond formation by ribosomes. Ribosomal binding of polyuridylic acid was not inhibited. Washed cap ribosomes supported very low incorporation rates without added messenger RNA, and were highly dependent upon added poly U for phenylalanine incorporation, indicating a low level of messenger in nuclear caps. It is concluded that enclosure of the ribosomes in the nuclear cap does not in itself prevent protein synthesis, and that the lack of activity may be due to the presence of a ribosome inhibitor.     

Aminoacyltransferase I-catalysed binding of phenylalanyl-transfer ribonucleic acid to muscle ribosomes from normal and diabetic rats

The aminoacyltransferase I-catalysed binding of phenylalanyl-tRNA (unfractionated Escherichia coli B tRNA acylated with radioactive phenylalanine and 19 non-radioactive amino acids) to skeletal-muscle ribosomes from diabetic rats was less than that to ribosomes from normal rats when the Mg(2+) concentration was low (7.5mm); whereas just the reverse was true when the concentration of the cation was higher (15mm). Thus the Mg(2+) dependency of aminoacyltransferase I-catalysed binding of phenylalanyl-tRNA to ribosomes from normal and diabetic rats paralleled the effect of Mg(2+) concentration on synthesis of polyphenylalanine reported before. During incubation at 7.5mm-Mg(2+) phenylalanyl-tRNA was bound only to ribosomes bearing nascent peptidyl-tRNA. There are fewer such ribosomes in a preparation from the muscle of diabetic animals because diabetic animals synthesize less protein in vivo. Thus the difference in polyphenylalanine synthesis in vitro is adequately explained by the difference in enzyme-catalysed binding of phenylalanyl-tRNA to ribosomes, however, the basis of the difference in protein synthesis in vivo is still unknown.     

GTP and Protein Synthesis in Cell-Free Systems

Abstract

Two supernatant fractions, T1 and T2, have been isolated and partially purified from rat liver and rabbit reticulocytes. In a cell-free system programmed with polyuridylic acid, both fractions are needed for phenylalanine polymerization. T1 factor and GTP are required for the enzymatic binding of phenylalanil-tRNA to template charged ribosomes. In the course of the binding reaction, GTP is hydrolyzed while no dipeptide formation can be detected. T2 factor coincides with a ribosome-linked GTPase, which is not stimulated by the addition of polyuridylic acid and phenylalanil-tRNA.     

RIBOSOMAL ACTIVITY IN PRENATAL MOUSE BRAIN

Abstract— Regulation of protein synthesis is important for the proper growth and development of the brain. Our previous work on the regulation of protein synthetic activity in fetal mouse brain cell suspensions showed that the rate of protein synthesis decreased during the prenatal period. In the present study, ribosomal activity of cell-free homogenates and purified ribosomes obtained from fetal neural tissue was measured. The post-mitochondrial supernatant (PMS) fraction actively incorporated amino acids into polypeptides using either endogenous mRNA or polyuridylic acid as template. The protein synthetic activity was dependent upon the age of the fetus. Ribosomes purified from this fraction were also active in protein synthesis. Incorporation of phenylalanine was linear for 20 min, and dependent upon the concentration of ribosomes and the pH 5 enzyme fraction. The age dependent decrease in protein synthetic activity observed with the post-mitochondrial supernatant fractions was not found when these purified ribosomes were employed. Ribosomes obtained from fetal, newborn or adult neural tissue were compared and found equally active in their protein synthetic capacity.     

Effect of polaymines on yeast cell-free protein synthesizing system. I. Influence of spermine and spermidine on aminoacyl-tRNA transfer reaction.

Spermine and spermidine added to a Saccharomyces cerevisiae cell-free protein synthesizing system increased phenylalanine polymerization reaction several-fold at suboptimal concentration of Mg2+ and approximately two-fold at optimal amounts of Mg2+. The addition of polyamines greatly stimulated the enzymatic and nonenzymatic binding of phenylalanyl-tRNA and N-acetylphenylalanyl-tRNA to ribosomes. The binding of the acetylated derivative was higher than phenylalanyl-tRNA, however, as it was shown the former was bound exclusively to the A site of the ribosome. Contrary to the binding process, the puromycin reaction was not stimulated by spermine added at a concentration which enhanced the polyphenylalanine synthesis. These results indicate that polyamines have not only a sparing effect on the Mg2+ requirement for yeast protein synthesis in vitro and suggest that one of the possible sites of polyamines action might be the binding of aminoacyl-tRNA to ribosomes.     

RIBOSOMAL SUBUNITS FROM NEONATAL MOUSE BRAIN HIGHLY ACTIVE IN POLYPHENYLALANINE SYNTHESIS

Abstract— A highly active subcellular protein synthesising system is described, in which uncomplexed ribosomes isolated from 5 to 7 day old mouse brain can be reprogrammed with polyuridylic acid. Either purified free polyribosomes or microsomes were used as the starting material for the preparation of uncomplexed ribosomes by treatment with 0.5 m -KCl and puromycin. After reduction of the salt concentration 80S ribosomes were isolated by washing through sucrose. When, subsequently, zonal centrifugation in equivolumetric sucrose gradients containing 0.5 m -KCI was performed, purified ribosomal subunits were obtained. Cross-contamination of subunits was less than 5%. Re-associated ribosomes and recombined isolated ribosomal subunits both showed high activities in vitro. Incorporation levels of 50–60 phenylalanine residues per ribosome could be reached, at a rate of 0.5–2.0 residues/min/ribosome, depending on the activity of the high speed supernatant enzymes added. It was shown by paper chromatography of the cell-free product that only oligophenylalanine formation takes place. It was estimated that 6&70% of the ribosomes present in vitro were actively participating in the protein synthesis process.     

Effect of modeccin on the steps of peptide-chain elongation.

Modeccin inhibits polypeptide-chain elongation catalysed by Artemia salina (brine shrimp) ribosomes by inactivating the 60 S ribosomal subunit. Among the individual steps of elongation, peptide-bond formation, catalysed by 60 S peptidyltransferase, is unaffected by the toxin, whereas the binding of EF 2 (elongation factor 2) to ribosomes is strongly inhibited. Modeccin does not affect the poly(U)-dependent non-enzymic binding of either deacylated tRNAPhe or phenylalanyl-tRNA to ribosomes. The inhibitory effect of modeccin on the EF 1 (elongation factor 1)-dependent binding of phenylalanyl-tRNA is discussed, since it is decreased by tRNAPhe, which stimulates the binding reaction. The analysis of the distribution of ribosome-bound radioactivity during protein synthesis shows that modeccin consistently inhibits the radioactivity bound as long-chain peptides, but depending on the experimental conditions, can leave unchanged or even greatly stimulates the radioactivity bound as phenylalanyl-tRNA and/or short-chain peptides. It is concluded that, during the complete elongation cycle, modeccin does not affect the binding of the first aminoacyl-tRNA to ribosomes, but inhibits some step in the subsequent repetitive activity of either EF 1 or EF 2. The results obtained indicate that the mechanism of action of modeccin is very similar to that of ricin and related plant toxins such as abrin and crotin.     

Function of ribosomes and glutamyl-tRNA isoacceptors in protein synthesis in regenerating skeletal muscle

Ribosomes from 8-day-regenerating rat skeletal muscle have been shown to be more active in poly(U)-directed polyphenylalanine synthesis than ribosomes from control muscle. This difference persists after salt washing of the ribosomes and does not appear to be due to the presence of ribonuclease associated with the control ribosome population. Ribosomes from control muscle were also less active than those from regenerates in the nonenzymatic binding of phenylalanyl-tRNA to ribosomes and in the peptidyltransferase reaction. Three glutamyl-tRNA isoacceptors have been isolated from 8-day-regenerating rat skeletal muscle by preparative RPC-5 chromatography of total tRNA charged with [3H]glutamic acid. The two major isoacceptors observed, tRNAgluI and tRNAgluIII, respond to the glutamic acid codons GAG and GAA, respectively. A third, minor glutamyl isoacceptor, tRNAgluII, also responds to the codon GAA. When the three isoacceptors were tested for function in a polysomal cell-free protein synthesizing system, it was found that their relative levels of utilization were essentially identical to their relative abundances. Thus, the tRNA which increases in relative amount after the induction of regeneration, tRNAgluII, is not preferentially utilized for overall muscle protein synthesis.     

Growth of liver accompanied by an increased binding of aminoacyl-transfer ribonucleic acids.

Homogenates of rat liver obtained 3 or 14 days after partial hepatectomy were used to prepare the postmicrosomal pH5-supernatant fraction and to prepare salt-wash fractions of the 40S ribosomal subunits and the 80S ribosomes. The factor-dependent binding of methionyl-tRNAfMet to ribosomes and the elongation-factor-1-dependent binding of phenylalanyl-tRNA to ribosomes were both increased after 3 days of growth, but not after 14 days of growth. An activity inhibitory to phenylalanyl-tRNA binding that was located in ribosomal wash fractions was decreased after 14 days of growth. Since the decreased inhibitory activity was obtained from the ribosomes and was tested against ribosomes and excess of pH5-supernatant fraction from control rat liver, its action was separate from the phenylalanyl-tRNA binding activities of the pH5-supernatant fractions from sham-operated and regenerating liver.     

Effect of food deprivation and hypophysectomy on in vitro protein synthesis by membrain-bound and free hepatic ribosomes.

The protein synthetic activities of membrane-bound and free hepatic ribosomes isolated from intact rats fed ad libitum, and normal rats subjected to food restriction to match that of hypophysectomised (Hx) rats were compared to the in vitro protein synthetic capacity of hepatic ribosomes isolated from Hx rats. Hypophysectomy resulted in decreased protein synthetic ability of bound ribosomes, whether protein synthesis was directed by endogenous messenger RNA (mRNA) (p less than 0.05) or by polyuridylic acid (polyU) (p less than 0.01). In contrast, the protein synthetic activity of free hepatic ribosomes from Hx rats was reduced when protein synthesis was directed by endogenous mRNA (p less than 0.05) but, when polyU was substituted as the messenger, the protein synthetic activity of these free ribosomes was equal to that of control rats. On the other hand the effects of food restriction on hepatic ribosomal function could be clearly differentiated from the effects observed following hypophysectomy. Thus, the reduced protein synthetic activity of hepatic bound ribosomes isolated from food restricted normal rats was not demonstrable, when polyU was used to direct protein synthesis. Further, food restriction had no effect on the protein synthetic activity of free hepatic ribosomes, and this was true when protein synthesis was directed by either endogenous or artificial messenger. It is concluded that hypophysectomy reduces the protein synthetic ability of both bound and free hepatic ribosomes, and this change of ribosomal function of Hx rats cannot be attributed to their decreased food intake.     

The effects of polyuridylic acid on phenylalanine incorporation by subcellular fractions from carbon tetrachloride-poisoned rat liver

1. Ribosomes and microsomes isolated from the livers of rats that had received carbon tetrachloride 1hr. previously had decreased endogenous capacity to incorporate amino acid. 2. The capacity of the isolated structures to respond to a synthetic messenger, polyuridylic acid, and to incorporate phenylalanine was investigated. 3. It was found that ribosomes from carbon tetrachloride-treated animals, prepared with detergent and at high ionic strength, could be restored to the same specific activity as control particles with polyuridylic acid but that these particles required more Mg(2+) in the incubation mixture. 4. Microsomes could also be stimulated to control activities with polyuridylic acid, but had a narrow optimum range of Mg(2+) concentration. 5. Microsomes prepared from poisoned animals could be preprogrammed with polyuridylic acid to a significantly greater degree than could control particles, and this response was greater with increasing Mg(2+) concentrations. These data suggested that in carbon tetrachloride poisoning the messenger-ribosome interaction had been altered. 6. Attempts to deprogramme particles from control and treated animals resulted in decreased endogenous activity of both particles and a decreased capacity for the treated particles to be restored with the synthetic messenger. 7. It is suggested that two effects are present in carbon tetrachloride poisoning, namely an alteration of the messenger-ribosome interaction and an increased lability of the ribosome, as either separate or related events.     

Amino acid incorporation by ribosomes and polyribosomes from wheat chloroplasts

Sucrose-gradient and analytical ultracentrifugation showed that chloroplast polyribosomes from 4-day-old seedlings had mono-, di-, tri-, tetra- and traces of penta-ribosomes, in contrast with those from 7-day-old seedlings in which only the mono-, di- and traces of tri-ribosomes were present. Without Mg(2+) the polyribosomes dissociated into ribosomal subunits. The rate of l-[U-(14)C]phenylalanine incorporation was threefold greater for preparations from 4- than from 7-day-old seedlings. Incorporation by the latter was stimulated by polyuridylic acid. The rates of incorporation were similar whether the reaction mixture contained chloroplast or wheat-germ transfer RNA and amino acid synthetases purified on methylated albumin-on-kieselguhr and Sephadex G-75 columns respectively. The cofactor requirement was the same as for isolated intact chloroplasts. Osmotic rupture of chloroplasts with and without Triton X-100 revealed the presence of free and bound ribosomes. Free single ribosomes isolated by osmotic shrinkage or prepared by pancreatic ribonuclease digestion of chloroplast polyribosomes had negligible incorporation activity. This activity was increased by washing or by polyuridylic acid, but was still only a fraction of that given by polyribosomes. A comparison of incorporation activity of chloroplast polyribosomes with those from the surrounding cytoplasm showed the former to be 20 times more active.     

Inhibition of protein synthesis by polypeptide antibiotics.. II. In vitro protein synthesis

Ennis, Herbert L. (St. Jude Children's Research Hospital, Memphis, Tenn.). Inhibition of protein synthesis by polypeptide antibiotics. II. In vitro protein synthesis. J. Bacteriol. 90:1109-1119. 1965.-This investigation has shown that the polypeptide antibiotics of the PA 114, vernamycin, and streptogramin complexes are potent inhibitors of the synthetic polynucleotide-stimulated incorporation of amino acids into hot trichloroacetic acid-insoluble peptide. The antibiotics inhibited the transfer of amino acid from aminoacyl-soluble ribonucleic acid (s-RNA) to peptide. The A component of the antibiotic complex was active alone in inhibiting in vitro protein synthesis, whereas the B fraction was totally inactive. However, the A component, when in combination with the B component, gave a greater degree of inhibition than that observed with the A fraction alone. On the other hand, the endogenous incorporation of amino acid was much less susceptible to inhibition than the incorporation of the corresponding amino acid in a system stimulated by synthetic polynucleotide. In addition, synthesis of polyphenylalanine stimulated by polyuridylic acid was inhibited to a greater extent when the antibiotics were added before the addition of polyuridylic acid to the reaction mixture than when the antibiotics were added after the polynucleotide had a chance to attach to the ribosomes. However, the antibiotics apparently did not inhibit the binding of C(14)-polyuridylic acid or C(14)-phenylalanyl-s-RNA to ribosomes. The antibiotics did not affect the normal release of nascent protein from ribosomes and did not disturb protein synthesis by causing misreading of the genetic code. The antibiotics bind irreversibly to the ribosome, or destroy the functional identity of the ribosome. The antibiotic action is apparently a result of the competition between antibiotic and messenger RNA for a functional site(s) on the ribosome.     

In vitro Protein Synthesis by Polyribosomes of Peach Flower Buds at Different Physiological Stages

The in vitro phenylalanine incorporation by polyribosomes of peach flower buds (Prunus persica Stokes) during dormancy, dormancy break and flowering was investigated. Protein synthesis was measured using as catalyst either calf liver soluble factors or the ribosomal supernatant from the peach flower buds in the presence or the absence of the synthetic mRNA, polyuridylic acid. In the presence of polyuridylic acid, the activity of protein synthesis of dormant ribosomes is the same as that of ribosomes during dormancy break and flowering. The absence of synthetic messenger did not cause a change in activity. The ribosomal supernatant of dormant buds, but not of flowering buds, reduces the phenylalanine incorporation by polyribosomes from buds harvested at dormancy break.