Polysomal Localization of R17 Bacteriophage-Specific Protein Synthesis

Synthesis of viral ribonucleic acid (RNA) polymerase, maturation protein, and coat protein in Escherichia coli infected with bacteriophage R17 occurs mainly on polysomes containing four or more ribosomes. The 30S ribosomal subunits through trimer-size polysomes, which are associated with all of the R17-specific proteins and are predominant in the infected cell, synthesize only coat protein. These structures may accumulate as products derived from larger polysomes as a result of failure in the release of nascent polypeptides after termination of chain growth. Appreciable amounts of viral coat protein remain attached to ribosomes and polysomes during R17 bacteriophage replication, supporting the hypothesis of the repressor role of this protein. The time course of synthesis of virus-specific proteins obtained from the polysomes of infected cells demonstrated regulated R17 messenger RNA translation consistent with the idea that coat protein is preferentially synthesized whereas the synthesis of noncoat proteins is suppressed.     

Ribonucleic Acid and Protein Synthesis in a Mutant of Bacillus subtilis Defective in Potassium Retention

A mutant of Bacillus subtilis 168 (strain 168 KL), which had lost its normal capacity to accumulate K(+), was used to explore the interrelationship between protein and ribonucleic acid (RNA) synthesis. In contrast to the wild type, the growth rate of strain 168 KL was markedly dependent on the K(+) concentration in the medium. K(+) uptake in the mutant strain was identical to that in the parent, but the mutant was unable to retain and accumulate K(+). Protein synthesis was markedly dependent on the K(+) concentration in the medium, whereas RNA synthesis was relatively unaffected by changes in the level of K(+). Most of the RNA synthesized during K(+) depletion was ribosomal RNA; it appeared in crude extracts in the form of ribonucleoproteins particles with sedimentation values between 4S and 30S. These particles were converted into mature ribosomes when growth was allowed to resume by the addition of K(+). Simultaneous synthesis of RNA and protein was necessary for the quantitative conversion of the ribonucleoprotein particles into ribosomes. During recovery from K(+) depletion, ribosomal protein was synthesized in preference to the other proteins of the cell.     

Protein synthesis defects in temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins

The ribosomes from four temperature-sensitive mutants of Escherichia coli have been examined for defects in cell-free protein synthesis. The mutants examined had alterations in ribosomal proteins S10, S15, or L22 (two strains). Ribosomes from each mutant showed a reduced activity in the translation of phage MS2 RNA at 44 degrees C and were more rapidly inactivated by heating at this temperature compared to control ribosomes. Ribosomal subunits from three of the mutants demonstrated a partial or complete inability to reassociate at 44 degrees C. 70-S ribosomes from two strains showed a reducton in messenger RNA binding. tRNA binding to the 30 S subunit was reduced in the strains with altered 30-S proteins and binding to the 50 S subunit was affected in the mutants with a change in 50 S protein L22. The relation between ribosomal protein structure and function in protein synthesis in these mutants is discussed.     

Translation elongation by a hybrid ribosome in which proteins at the GTPase center of the Escherichia coli ribosome are replaced with rat counterparts.

Ribosomal L10-L7/L12 protein complex and L11 bind to a highly conserved RNA region around position 1070 in domain II of 23 S rRNA and constitute a part of the GTPase-associated center in Escherichia coli ribosomes. We replaced these ribosomal proteins in vitro with the rat counterparts P0-P1/P2 complex and RL12, and tested them for ribosomal activities. The core 50 S subunit lacking the proteins on the 1070 RNA domain was prepared under gentle conditions from a mutant deficient in ribosomal protein L11. The rat proteins bound to the core 50 S subunit through their interactions with the 1070 RNA domain. The resultant hybrid ribosome was insensitive to thiostrepton and showed poly(U)-programmed polyphenylalanine synthesis dependent on the actions of both eukaryotic elongation factors 1alpha (eEF-1alpha) and 2 (eEF-2) but not of the prokaryotic equivalent factors EF-Tu and EF-G. The results from replacement of either the L10-L7/L12 complex or L11 with rat protein showed that the P0-P1/P2 complex, and not RL12, was responsible for the specificity of the eukaryotic ribosomes to eukaryotic elongation factors and for the accompanying GTPase activity. The presence of either E. coli L11 or rat RL12 considerably stimulated the polyphenylalanine synthesis by the hybrid ribosome, suggesting that L11/RL12 proteins play an important role in post-GTPase events of translation elongation.     

RNA and ribosomal protein patterns during aerial spore germination in Streptomyces granaticolor

Disruption of the external sheath of Streptomyces granaticolor aerial spores and subsequent cultivation in a rich medium result in a synchronous germination. This method was used to analyze RNA and protein patterns during the germination. The germination process took place through a sequence of time-ordered events. RNA and protein synthesis started during the first 5 min and net DNA synthesis at 60-70 min of germination. Within the first 10 min of germination, synthesis of RNA was not sensitive to the inhibitory effect of rifamycin. During this period rRNA and other species including 4-5-S RNA were synthesized. Dormant spores contained populations of ribosomes or ribosomal precursors that were structurally and functionally defective. The ribosomal particles bound a sporulation pigment(s) of the melanine type. The ribosomal proteins complexed to the pigments formed insoluble aggregates which were easily removed from the ribosomes by one wash with 1 M NH4Cl. During the first 10 min of germination, pigment(s) were liberated from the complexes with the ribosomes and protein extracts of the washed ribosomes had essentially the same pattern as the extracts of ribosomes of vegetative cells. These structural alterations were accompanied by enhancement of the ribosome activities in polypeptide synthesis in vivo and in vitro. When the spores were incubated with a 14C-labelled amino acid mixture in the presence of rifamycin, only three proteins (GS1, GL1 and GS9) were identified to be radiolabelled in the extracts from the washed ribosomes. These experiments indicate that liberation of the sporulation pigment(s) from the complexes with ribosomal proteins and assembly of de novo synthesized proteins and proteins from a preexisting pool in the spore are involved in the reactivation of the ribosomes of dormant spores of S. granaticolor.     

Localization of polyamine enhancement of protein synthesis to subcellular components of Escherichia coli and Pseudomonas sp. strain Kim.

At 5 mM Mg2+, spermidine stimulation of polyphenylalanine synthesis by cell-free extracts of Escherichia coli was found to be about 30 times greater than that by extracts of Pseudomonas sp. strain Kim, a unique organism which lacks detectable levels of spermidine. By means of reconstitution experiments, the target of spermidine stimulation was localized to the protein fraction of the highspeed supernatant component (S-100) of E. coli and was absent from, or deficient in, the S-100 fraction of Pseudomonas sp. strain Kim. The spermidine stimulation did not appear to be due to the presence in the E. coli S-100 fraction of ribosomal protein S1, elongation factors, or E. coli aminoacyl-tRNA synthetases. The failure to observe spermidine stimulation by the Pseudomonas sp. strain Kim S-100 fraction was also not due to a spermidine-enhanced polyuridylic acid degradation. The synthesis of polyphenylalanine by Pseudomonas sp. strain Kim extracts was stimulated by putrescine and by S-(+)-2-hydroxyputrescine to a greater degree than was synthesis by E. coli extracts. The enhancement by putrescine and by S-(+)-2-hydroxyputrescine with Pseudomonas sp. strain Kim extracts was found to be due to effects on its ribosomes.     

Ribosome Synthesis in Thermally Shocked Cells of Staphylococcus aureus

Thermally shocked cells of Staphylococcus aureus rapidly synthesized ribonucleic acid (RNA) during the early stages of recovery. During this period, protein synthesis was not observed and occurred only after RNA had reached a maximum level. Even in the absence of coordinated protein synthesis, a large portion of the RNA appeared in newly synthesized ribosomes. Although the 30S subunit was specifically destroyed by the heating process, both ribosomal particles were reassembled during recovery. The addition of chloramphenicol did not inhibit the formation of the ribosomal subunits, nor was the presence of immature chloramphenicol particles detected. Extended recovery with highly prelabeled cells showed that the original ribosomal proteins present before heating are conserved and recycled. Furthermore, the data indicate that the 50S subunit is turned over and used as a source of protein for new ribosome assembly. Kinetic studies of the assembly process by pulse labeling have not revealed the presence of the normally reported precursor particles. Rather, the data suggest that assembly may occur, in this system, in a manner similar to that reported for in vitro assembly of Escherichia coli subunits.     

Reversion from erythromycin dependence in Escherichia coli: strains altered in ribosomal sub-unit association and ribosome assembly

A mutant of Escherichia coli dependent on erythromycin for growth spontaneously gives erythromycin-independent strains with altered or missing ribosomal proteins. strains with defects in ribosome assembly were sought and obtained from among these revertants. Two organisms in which ribosomal protein L19 is altered and absent respectively have 70S ribosomes whose dissociation into sub-units is particularly sensitive to pressures generated during centrifuging. The mutant that lacks protein L19 also accumulates ribosome precursor particles during exponential growth as do others including mutants that lack proteins S20 or L1. These strains also show unbalanced synthesis of RNA and so will be useful in investigating both the pathways and the regulation of ribosome assembly.     

Nature of ribonucleic acid stimulated by streptomycin in the absence of protein synthesis

Freda, Celia E. (University of Pennsylvania School of Medicine, Philadelphia), and Seymour S. Cohen. Nature of ribonucleic acid stimulated by streptomycin in the absence of protein synthesis. J. Bacteriol. 92:1680-1688. 1966.-The ribonucleic acid (RNA) synthesized in a thymineless, arginineless, uracil-less Escherichia coli strain 15 in the absence of arginine was characterized by sucrose density gradient centrifugation. About 60% of this RNA had sedimentation rates in the range between 4S and 16S, and the remainder was comprised of the 23S and 16S ribosomal components. On addition of streptomycin for 1 hr in the absence of the amino acid, there was an inhibition of synthesis of material of 4S to 16S, whereas 16S RNA was slightly stimulated. Between 1 and 3 hr after addition of the antibiotic, during the precipitous killing of the bacteria in the arginine-deficient culture, the synthesis of 16S ribosomal RNA was specifically and sharply stimulated.     

Functional analysis of the invariant residue G791 of Escherichia coli 16S rRNA

The nucleotide at position 791(G791) of E. coli 16S rRNA was previously identified as an invariant residue for ribosomal function. In order to characterize the functional role of G791, base substitutions were introduced at this position, and mutant ribosomes were analyzed with regard to their protein synthesis ability, via the use of a specialized ribosome system. These ribosomal RNA mutations attenuated the ability of ribosomes to conduct protein synthesis by more than 65%. A transition mutation (G to A) exerted a moderate effect on ribosomal function, whereas a transversion mutation (G to C or U) resulted in a loss of protein synthesis ability of more than 90%. The sucrose gradient profiles of ribosomes and primer extension analysis showed that the loss of protein-synthesis ability of mutant ribosomes harboring a base substitution from G to U at position 791 stems partially from its inability to form 70S ribosomes. These findings show the involvement of the nucleotide at position 791 in the association of ribosomal subunits and protein synthesis steps after 70S formation, as well as the possibility of using 16S rRNA mutated at position 791 for the selection of second-site revertants in order to identify ligands that interact with G791 in protein synthesis.     

Ribosomal protein synthesis by a mutant of Escherichia coli

The mutant strain of Escherichia coli, TP28, synthesises ribosomes by an abnormal pathway and accumulates large quantities of 47S ribonucleoprotein particles. The protein complement of mutant 70S ribosomes is normal but 47S particles contain only traces of proteins L28 and L33 and have a significantly reduced content of four other proteins. The mutation reduces the rates of synthesis of L28 and L33 by about half but other widespread alterations ensue. In particular, ribosomal protein synthesis in the mutant strain becomes less well balanced than in its parent: some proteins, particularly those from promoter-proximal genes, are oversynthesized and their excess then degraded.     

The difference in the stimulation by putrescine of DNA synthesis using DNA polymerase extracts of normal rat liver or of tumour tissue or host liver from tumour-bearing rats

Putrescine biosynthesis is elevated before DNA replication, and a stimulation of DNA synthesis by 20 mM putrescine has been found using an in vitro DNA synthesizing system. Furthermore, this stimulation of DNA synthesis by putrescine involves a particular factor (factor PA). This factor PA stimulates DNA polymerases alpha, beta, and gamma, and is present in nuclei and mitochondria but not in cytoplasm. Factor PA loses about 80% of its activity by heating at 45 degrees C for 15 min or by hydrolysis with 100 mg ml(-1) Enzygel trypsin. These properties indicate that factor PA is a protein. Its size is estimated to be about 2.1 S. DNA synthesis in nuclear and mitochondrial DNA polymerase extracts from tumour tissues and host livers of tumour-bearing rats are not stimulated by 20 mM putrescine. However, the addition of excess factor PA to DNA synthesizing systems using DNA polymerase extracts from proliferative tissues again results in a stimulation of DNA synthesis by exogenous putrescine. These findings indicate that the stimulatory effect of DNA synthesis in vitro by exogenous putrescine is controlled by the ratio between factor PA and endogenously synthesized putrescine in proliferative tissues or that sent by the bloodstream from proliferative tissues. These results suggest that a non-stimulatory effect of putrescine on DNA synthesis may be diagnostic in tumour-bearing patients.