Inhibitory action of virginiamycin components on cell-free systems for polypeptide formation from Bacillus subtilis

Although virginiamycin components VM and VS are known to exert in vivo a synergistic inhibition of bacterial growth and viability, in cell-free systems only VM has proven active. In the present work, the in vivo and in vitro activities of VM and VS on Bacillus subtilis have been compared.Peptide formation in homogenates of bacteria previously incubated with either VM or VS was found strongly repressed; the 2 components acted synergistically. Ribosomes were fully responsible for this effect, as shown by mixed reconstitution experiments. On the other hand, cytoplasm from control bacteria disrupted in 10 mM Mg²⁺ buffer was refractory to in vitro inhibition by virginiamycin, whereas ribosomes prepared in 1 mM Mg²⁺ were sensitive to VM. VS was inactive on poly(U)-directed poly(phenylalanine) formation, and displayed some activity on the poly(A)-poly(lysine) system. In a cell-free system from Bacillus subtilis infected with phage 2C, both VM and VS were active and blocked synergistically protein synthesis in vitro. When the host cells were incubated with VS and the corresponding homogenate was then treated with VM, a complete inhibition of protein synthesis was observed. The present work, thus, describes the techniques for investigating the in vivo and in vitro action of synergimycins on the same organism, and for reproducing in vitro the synergistic interaction of type A and B components previously observed only in vivo.Abbreviations poly(U) poly(uridylic acid) - poly(A) poly(adenylic acid) - VM and VS the M and S components of virginiamycin - pfu plaque forming units     

Subcellular localization of a lesion in protein synthesis in rabbit reticulocytes incubated at elevated temperatures.

When rabbit reticulocytes are incubated at 43-45 degrees C their rate of protein synthesis rapidly decreases, compared to a contol 37 degrees C incubation. Lysates prepared from cells incubated at this supra-optimal temperature have an equally decreased capacity for endogenous, but not poly(uridylic acid)-directed, protein synthesis. Subcellular fractionation traced the lesion to the crude ribosomal pellet, 0.5 M KCl ribosomal wash and postribosomal supernatant of the temperature-shocked cells. Preparation of purified ribosomal subparticles showed, however, that they were as active as the control in protein synthesis. In this paper we present evidence that the decreased activity of the heated lysate, 0.5 mM KCl wash and postribosomal supernatant is due to an inhibitor and can be overcome by the addition of 0.5 M KCl or supernatant from control cells. The results are discussed in terms of the inactivation of a component, essential for initiation of endogenous protein synthesis, which is probably partitioned between ribosomes and supernatant. We also suggest that the decreased protein synthetic activity of the heated cells may be related to their decreased synthesis of haem.     

Protein synthesis and the viability of rye grains. Loss of activity of protein-synthesizing systems in vitro associated with a loss of viability

A study was made of the integrity of some components of the protein-synthesizing system from viable and non-viable embryos of rye grains. In comparison with viable-embryo components both post-ribosomal supernatant and ribosomal fractions from non-viable embryos are impaired, for neither will fully support polyphenylalanine synthesis in poly(U)-directed cell-free systems. The lesion in the supernatant lies in components other than the tRNA or the aminoacyl-tRNA synthetase, for these are as functional as those present in the fully active cell-free systems from viable embryos. The ribosomes of embryos of lowered viability show considerable fragmentation and degradation of both 18S and 25S rRNA. This breakdown does not, however, account for the complete lack of polypeptide synthesis in the poly(U)-directed non-viable-embryo system, for if provided with viable-embryo supernatant, non-viable-embryo ribosomes will sustain 60% of the viable-embryo ribosome activity. A lesion in non-viable-embryo supernatant has been located in the binding of the aminoacyl-tRNA to the ribosome. The impaired components in both supernatant and ribosomes in systems in vitro may reflect the site of faults in protein synthesis in vivo in the early hours of germination. The development of these lesions during grain storage could contribute to senescence and loss of viability in the embryos of rye.     

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.     

Factors involved in increased protein synthesis in rat kidney after administration of DDT

Homogenates of kidney cortex obtained from control rats and rats treated with DDT have been separated into microsomes or ribosomes, and into postmicrosomal (S105) supernatant fraction or pH 5 supernatant fraction. The incorporation of [¹⁴C]phenylalanyl-tRNA into peptide was increased when microsomes derived from kidneys of DDT-treated rats were incubated with pH 5 supernatant fraction from control rats. Elongation factors (EF) 1 and 2, necessary for the binding of aminoacyltRNA to ribosomes and for translocation of peptidyl-tRNA from the A site to the P site of ribosomes, were present in the pH 5 supernatant fractions of kidney of control and DDT-treated rats and these fractions were incubated with KCl-washed ribosomes obtained from livers of control rats. The results provided evidence that the increased incorporation observed with the pH 5 supernatant fraction obtained from the DDT-treated animals could not be attributed to decreased ribonuclease activity or to increased elongation factor 2 activity but was due to an increase in elongation factor l activity.     

Membrane-bound ribosomes in kidney: methods of estimation and effect of compensatory renal growth

Membrane-bound ribosomes are thought to secrete protein for export and free ribosomes to secrete protein for intracellular use. The proportion of the total ribosomes that is bound to membranes in normal mouse kidneys has been estimated by three different methods, and the results have been compared with those obtained by a fourth method used by us previously. The most valid estimates appear to be those obtained (a) by comparison of radioactivity in peaks representing free and membrane-bound ribosomes on linear sucrose gradients after labeling for 24 hr with ¹⁴C-orotic acid, and (b) by measurements of optical density in free and bound ribosomes that had been separated by centrifugation on discontinuous gradients of 0.5 M/2.0 M sucrose. Analyses by these methods show that about 20–25% of the ribosomes in a postnuclear supernatant prepared from mouse kidneys, but only 10–15% of the ribosomes in a post-mitochondrial supernatant, are membrane-bound. About 75% of the bound ribosomes sediment as polysomes of many different sizes. The proportion of membrane-bound ribosomes and their aggregation into polysomes were unchanged in kidneys undergoing compensatory hypertrophy after removal of the opposite kidney. These experiments show that, unlike liver, kidney has a predominance of free ribosomes compared to bound ribosomes; those ribosomes that are membrane-bound do not become free during compensatory renal growth.     

Stimulation of gastric mucosal protein synthesis by different molecular forms of gastrin.

Protein synthesis in gastric mucosa was studied by measuring the incorporation of labeled amino acids into protein by isolated gastric mucosal ribosomes in a cell-free system. In 48-hour fasted rats, administration of the synthetic analogues pentagastrin, tetragastrin and gastrin-17 or naturally occurring molecular forms of human gastrin (G-14, G-34) markedly enhanced (23-123%) the capacity of the gastric mucosal ribosomes to synthesize endogenous mRNA-directed protein in a cell-free system. In the presence of exogenous mRNA (poly-U), the gastric mucosal ribosomes from the saline-treated controls showed a higher poly(U)-directed protein synthesis, compared to each fo the gastrin-treated groups. The protein/polyphenylalanine ratio which represents a ratio of polysomes to monosomes was found increased in ribosomes from the gastrin-treated groups.     

TRANSCRIPTIONAL CONTROL OF PROTEIN SYNTHISIS IN THE DEVELOPING OVARIES OF BOMBYX MORI*

Amino acid incorporation was studied with cell-free extracts and ribosomes prepared from pupal ovaries at different ages of Bombyx mori. Poly(U)-directed ³H-phenylalanine incorporation attained a maximum rate at a certain stage of development, but soon dropped to a low level and was replaced by ³H-leucine incorporation, which was due to endogenous mRNA. The latter incorporation occurred at the stage when actual protein synthesis takes place in the ovaries. “Run-off” of the ribosomes which had a high endogenous activity resulted in an enhancement of the poly(U)-dependent activity. The results indicate that the protein synthesis in the ovary is mainly controlled at the level of mRNA. This was further supported by the fact that the relative amount of an ovarian poly(A)-containing “mRNA” fraction increased in parallel with the endogenous activity.     

Hemoglobin transition in erythrocytes of developing chick. Studies with cell-free protein-synthesizing systems.

Cell-free hemoglobin-synthesizing systems from erythrocytes of 4- and 17-day chick embryos have been developed. These systems have been used to investigate possible structural and functional differences in factors involved in protein synthesis obtained from these different developmental stages. Each cell-free system consists of three major cellular fractions i.e., the S-100 supernatant, the salt-washed ribosomes, and the 0.5 m KCl ribosomal wash. When the ribosomal wash fraction from one developmental stage is included in a cell-free system containing ribosomes and S-100 supernatant from the other developmental stage, a drastic reduction in the kinetics of [³H]leucine incorporation into globin products is observed, when compared to the homologous control cell-free systems. A similar depression of the kinetics of incorporation is observed when the mixed component is either the S-100 supernatant or the ribosomes. Control rates of incorporation can be reestablished when the corresponding homologous component is added back to the incubation mixture. The predominant types of hemoglobins produced in the salt-wash heterologous systems are those hemoglobins characteristic of the developmental stage of the salt wash. This seems to imply that the ribosomal salt-wash fraction may possess developmental stage specificity for the globins.     

Preparation of Escherichia coli 70S ribosomes labeled with 35S

[35S]--70S ribosomes (150 Ci/mmol) were isolated from E. coli MRE-600 cells grown on glucose-mineral media in the presence of [35S] ammonium sulfate. The labeled 30S and 50S subunits were obtained from [35S] ribosomes by centrifugation in a sucrose density gradient of 10--30% under dissociating conditions (0.5 mM Mg2+). The activity of [35S]--70S ribosomes obtained by reassociation of the labeled subunits during poly(U)-dependent diphenylalanine synthesis was not less than 70%. The activity of [35S]--70S ribosomes during poly(U)-directed polyphenylalanine synthesis was nearly the same as that of the standard preparation of unlabeled ribosomes. The 23S, 16S and 5S RNAs isolated from labeled ribosomes as total rRNA contained no detectable amounts of their fragments as revealed by polyacrylamide gel electrophoresis. The [35S] ribosomal proteins isolated from labeled ribosomes were analyzed by two-dimensional gel electrophoresis. The [35S] label was found in all proteins, with the exception of L20, L24 and L33 which did not contain methionine or cysteine residues.     

Radioactive labelling of ribosomal proteins with reductive alkylation and its use in studying ribosome-cytosol interactions.

Mouse brain ribosomes were radioactively labelled by a cell-free reductive alkylation reaction with NaBH4 and [14C]formaldehyde. The radioactivity was largely associated with ribosomal proteins, but little, if any, of the rRNA was radioactive after the alkylation procedure. Both ribosomal structural proteins and loosely associated components were successfully labelled by this procedure. The sedimentation properties of the ribosomes were unaltered and their ability to carry out poly(U)-directed protein synthesis, although decreased, was largely retained. Incubation of 14C-labelled ribosomes with brain cytosol resulted in a 17% loss of radioactivity, although treatment of the ribosomes with 1.0 m-KCl to remove the loosely associated factors rendered the ribonucleoprotein particles resistant to cytosol effects. The ribosome-cytosol interactions did not appear to be related to an exchange process, since the released radioactivity was largely degraded to acid-soluble material. In addition, the incubation of native ribosomes with brain cytosol resulted in an almost complete loss in the ability of the ribosomes to participate in cell-free protein synthesis.     

Binding of ricin A chain to rat liver ribosomes: Relationship to ribosome inactivation

Ricin A chain was radioactively labeled using reductive alkylation, lactoperoxidase catalyzed iodination, and reaction with iodoacetamide or N-ethylmaleimide (NEM). The inhibition of cell-free rat liver protein synthesis by the modified A chains and the ribosome binding characteristics of each of the labeled derivatives was examined. [³H] NEM was found to quantitatively react with the A chain sulfhydryl group normally involved in a disulfide bond with the B chain in intact ricin. Labeling the protein with [³H] NEM had no effect on the in vitro inhibition of protein synthesis by the A chain. [³H] NEM-labeled A chain binds to rat liver ribosomes in a manner which is dependent on the concentrations of NaCl and Mg²⁺. At optimal Mg²⁺ concentration (5.5 mM), A chain binding to ribosomes is saturable and fully reversible either by dilution of the reaction mixture or by addition of unlabeled A chain. At 5.5 mM Mg²⁺, A chain was found to bind to a single site on rat liver ribosomes with a dissociation constant of 6.2 X 10^?8 M. [³H] NEM-labeled A chain did not bind to isolated 40S ribosomal subunits and bound to 60S ribosomal subunits with a 1 : 1 molar stoichiometry and a dissociation constant of 2.2 X 10^?7 M. The relationship between ribosome binding and A chain inhibition of eucaryotic protein synthesis is discussed.     

Isolation and characterization of active ribosomal subunits from human placenta.

We have developed a method for the large-scale isolation of active ribosomal subunits from human placenta. The technique involves incubating crude ribosomes for 15 min at 37 degrees C with 0.2 mM puromycin in 50 mM Tris-HCl buffer, pH 7.6, 500 mM KCl and 3 mM MgCl2 followed by centrifugation at 5 degrees C in a BXV zonal rotor using an equivolumetric sucrose gradient in the same buffer, upon which 80--90% of all ribosomes are dissociated into subunits. The purified subunits differ in their chemical composition, the 60-S particle containing no more than 36% protein whereas the 40-S subunit consists of 43% protein. In poly(U)-directed protein synthesis, tested in a completely homologous cell-free system, one recombined couple polymerizes at 37 degrees C 12 to 17 phenylalanine residues at an initial rate of 0.7 residues per minute. However, free 80-S ribosomes obtained by puromycin treatment of the crude ribosomes and reassociation of the subunits without prior isolation, have an even higher incorporating activity (20--25 mol phenylalanine/mol of ribosome). At least 55% of the subunits were estimated to actively participate in the polyphenylalanine synthesis.     

Changes in ribosomal activity during incubation of Daucus carota root disks

Cytoplasmic monoribosomes from freshly cut and ‘aged’ carrot root disks were characterized relative to the Mg²⁺ optima for poly U (polyuridylic acid)-directed phenylalanine incorporation, the ease of dissociation by KCl in the presence of Mg²⁺, the ability to bind ³H-poly U, and acrylamide gel fractionation of the ribosomal proteins. The differences in in vitro amino acid incorporation by ribosomes and supernatant from fresh and ‘aged’ disks were confined to the ribosome fraction. The Mg²⁺ optima for poly U-directed ¹⁴C-phenylalanine incorporation was 16 mM for ribosomes from ‘aged’ disks compared to 20 mM for ribosomes from fresh disks. Monoribosomes from the fresh disks were easily dissociated into subunits (0·2 M KCl in 5 mM Mg²⁺) while the ribosomes from ‘aged’ disks were not completely dissociated even in 0·5 M KCl. Ribosomes from ‘aged’ disks were more effective in binding ³H-poly U than ribosomes from fresh disks. When the disks were subjected to an anaerobic environment prior to ribosome extraction (to strip monoribosomes of peptidyl-t RNA) the above effects of ‘aging’ were reversed. These results suggest that increased monoribosome activity associated with ‘aging’ may be related in part to an increase in the level of peptidyl-tRNA associated with the ribosomes. Acrylamide gel electrophoresis profiles of ribosomal proteins extracted from ribosomes of fresh and ‘aged’ tissue suggest that a change in the protein complement may also be important to the observed changes in ribosomal activity. The ribosomes from ‘aged’ disks contained at least two components not associated with ribosomes from fresh disks.     

Inhibition of peptide chain initiation by a nonhemin-regulated translational repressor from Friend leukemia cells.

A nonhemin-regulated translational repressor protein has been purified partially from the postribosomal supernatant fraction of Friend leukemia cells grown in the absence of dimethylsulfoxide. This repressor inhibits protein synthesis in lysates from rabbit reticulocytes or Friend leukemia cells and in a fractionated system using Artemia salina ribosomes, reticulocyte mRNA, and soluble components from reticulocytes. In contrast, the hemin-controlled repressor from reticulocytes does not inhibit protein synthesis in lysates from Friend leukemia cells. The repressor from Friend leukemia cells has no effect on poly(U)-directed synthesis of polyphenylalanine using reticulocyte ribosomes nor on the extension and release of nascent globin chains that were initiated in intact reticulocytes. It does not block completion of peptides on ribosomes isolated from reticulocytes incubated with NaF nor does it inhibit initiation factor-dependent formation of methionylpuromycin, but it inhibits globin mRNA-dependent methionylvaline synthesis. The Friend leukemia cell repressor promotes peptide synthesis-dependent breakdown of polysomes in reticulocyte lysates that appears to involve inhibition of ribosome reattachment to mRNA during peptide chain initiation. It is concluded that the Friend leukemia cell repressor blocks peptide initiation at a point between the addition of methionyl-tRNA^fMet to the ribosomal initiation complex and the NaF-sensitive reaction.     

Localization of host poly(A)+ mRNA in the ribosome profile of mengovirus-infected Ehrlich ascites tumor cells

The distribution of poly(A)⁺ mRNA among polysomes, monosomes, and ribosome-free supernatant fractions after mengovirus infection of Ehrlich ascites tumor (EAT) cells was investigated employing sucrose gradient centrifugation of their corresponding postnuclear supernatants. Poly(A)⁺ mRNA was isolated from sucrose gradient fractions and quantitated in a cell-free protein synthesizing system from uninfected EAT cells. It was also localized by annealing [³H]-poly(U) to the poly(A)-tracts of mRNA present in the sucrose gradient fractions. Both experiments revealed a gradual shift of host poly(A)⁺ mRNA from large to small polysomes and monosomes, respectively, with the time postinfection. The greatest part of host template RNA appears to remain ribosome-bound and only a fraction seems to be detached from the ribosomes in the course of mengovirus infection. At the end of the infectious cycle, 8 h postinfection, approximately 70% of the poly(A)⁺ mRNA detected in uninfected cells is still biologically active, but not translated in vivo, in agreement with data from the [³H] poly(U) hybridization experiment.     

Fidelity of protein synthesis does not decline during aging of cultured human fibroblasts

To ascertain whether the fidelity of protein synthesis declines during cellular aging in vitro, we have developed a cell-free protein synthesizing system from cultured human fibroblasts which actively incorporates phenylalanine into acid-insoluble material upon addition of poly (U). The accuracy of poly(U)-directed protein synthesis was determined by comparing the ratio of leucine to phenylalanine incorporation in extracts of early- and late-passage fibroblasts derived from normal persons and from subjects with two genetic disorders of premature aging, progeria, and Werner syndrome. The results show no decline in translational fidelity at late passage or in prematurely aging cells, and thus fail to support the error catastrophe theory of cellular aging.     

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.     

In vitro protein synthesis by the moderate halophile Vibrio costicola: site of action of Cl- ions.

In vitro protein synthesis in Vibrio costicola [poly(U)-directed incorporation of phenylalanine] was studied. The extent of protein synthesis was limited by the number of ribosomes present. Density gradient centrifugation experiments suggested that, after runoff of ribosomes from the artificial messenger, the 50S subunit was unable to attach to the 30S-messenger complex. As shown previously (M. Kamekura and D. J. Kushner, J. Bacteriol. 160:385-390, 1984), Cl- ions inhibited protein synthesis; indeed, the highest rate of synthesis took place in the lowest attainable Cl- concentration (37 mM). The inhibitory effects were partly reversed by glutamate and betaine, both of which are concentrated within cells of V. costicola. The strongest reversal was seen when both glutamate and betaine were present. Cl- ions can prevent binding of ribosomes to poly(U) and displace ribosomes already bound to this artificial messenger. The effects of Cl- ions on binding were also reversed by glutamate and betaine. Cl- ions did not affect accuracy of translation; they were shown previously (Kamekura and Kushner, J. Bacteriol. 160:385-390, 1984) not to affect phenylalanyl-tRNA synthetase. It was also found that washing ribosomes with inhibitory NaCl concentrations did not interfere with their ability to carry out protein synthesis later in optimal (low) salt concentrations. On the contrary, these ribosomes were more active than before they were washed. We conclude that the main site of action of Cl- in the system studied is on the binding of ribosomes to the mRNA.