Some effects of antibiotics on bacterial polyribosomes as studied by gel electrophoresis

Three distinct ribosome assemblies modulated by translation are the building blocks of polysomes

Translation is increasingly recognized as a central control layer of gene expression in eukaryotic cells. The overall organization of mRNA and ribosomes within polysomes, as well as the possible role of this organization in translation are poorly understood. Here we show that polysomes are primarily formed by three distinct classes of ribosome assemblies. We observe that these assemblies can be connected by naked RNA regions of the transcript. We show that the relative proportions of the three classes of ribosome assemblies reflect, and probably dictate, the level of translational activity. These results reveal the existence of recurrent supra-ribosomal building blocks forming polysomes and suggest the presence of unexplored translational controls embedded in the polysome structure.

Model-based inference of gene expression dynamics from sequence information

A dynamic model of prokaryotic gene expression is developed that makes considerable use of gene sequence information. The main contribution arises from the fact that the combined gene expression model allows us to access the impact of altering a nucleotide sequence on the dynamics of gene expression rates mechanistically. The high level of detail of the mathematical model is considered as an important step towards bringing together the tremendous amount of biological in-depth knowledge that has been accumulated at the molecular level, using a systems level analysis (in the sense of a bottom-up, inductive approach). This enables to the model to provide highly detailed insights into the various steps of the protein expression process and it allows us to access possible targets for model-based design. Taken as a whole, the mathematical gene expression model presented in this study provides a comprehensive framework for a thorough analysis of sequence-related effects on the stages of mRNA synthesis, mRNA degradation and ribosomal translation, as well as their nonlinear interconnectedness. Therefore, it may be useful in the rational design of recombinant bacterial protein synthesis systems, the modulation of enzyme activities in pathway design, in vitro protein biosynthesis, and RNA-based vaccination.

Hypothesis: the RNase-sensitive restraint to unfolding of spermidine nucleoids from Escherichia coli is composed of cotranslational insertion linkages

The genomic DNA of bacteria is highly localized in one or a few bodies known as nucleoids. A number of restraints to the unfolding of the DNA of spermidine nucleoids from Escherichia coli were previously associated with characteristic urea concentrations (U(m) values). The dominant restraint to unfolding was sensitive to pancreatic RNase and underwent a cooperative transition at U(m) = 3.2 M urea. The losses of the RNase-sensitive restraint caused by urea or pancreatic RNase appear to result from breakage of cotranslational insertion linkages which joined the nucleoid to the cell envelope in growing cells. This conclusion is based upon effects from exposures of cells to antibiotics (chloramphenicol, rifampicin, streptomycin), treatment of nucleoid preparations with formaldehyde or concentrated NaCl solutions, and effects of urea on purified ribosomes. The specific RNase-sensitive and urea-sensitive components of the spermidine nucleoids are suggested to be the mRNA and ribosomes, respectively, of cotranslational insertion linkages.

Macrolide antibiotics inhibit 50S ribosomal subunit assembly in Bacillus subtilis and Staphylococcus aureus

Macrolide antibiotics are clinically important antibiotics which are effective inhibitors of protein biosynthesis in bacterial cells. We have recently shown that some of these compounds also inhibit 50S ribosomal subunit formation in Escherichia coli. Now we show that certain macrolides have the same effect in two gram-positive organisms, Bacillus subtilis and Staphylococcus aureus. Assembly in B. subtilis was prevented by erythromycin, clarithromycin, and azithromycin but not by oleandomycin. 50S subunit formation in S. aureus was prevented by each of seven structurally related 14-membered macrolides but not by lincomycin or two streptogramin antibiotics. Erythromycin treatment did not stimulate the breakdown of performed 50S subunits in either organism. The formation of the 30S ribosomal subunit was also unaffected by these compounds. Assembly was also inhibited in a B. subtilis strain carrying a plasmid with the ermC gene that confers macrolide resistance by rRNA methylation. These results suggest that ribosomes contain an additional site for the inhibitory functions of macrolide antibiotics.

Erythromycin inhibits the assembly of the large ribosomal subunit in growing Escherichia coli cells

Erythromycin and other macrolide antibiotics have been examined for their effects on ribosome assembly in growing Escherichia coli cells. Formation of the 50S ribosomal subunit was specifically inhibited by erythromycin and azithromycin. Other related compounds tested, including oleandomycin, clarithromycin, spiramycin, and virginiamycin M1, did not influence assembly. Erythromycin did not promote the breakdown of ribosomes formed in the absence of the drug. Two erythromycin-resistant mutants with alterations in ribosomal proteins L4 and L22 were also examined for an effect on assembly. Subunit assembly was affected in the mutant containing the L22 alteration only at erythromycin concentrations fourfold greater than those needed to stop assembly in wild-type cells. Ribosomal subunit assembly was only marginally affected at the highest drug concentration tested in the cells that contained the altered L4 protein. These novel results indicate that erythromycin has two effects on translation, preventing elongation of the polypeptide chain and also inhibiting the formation of the large ribosomal subunit.

Absolute in vivo translation rates of individual codons in Escherichia coli. The two glutamic acid codons GAA and GAG are translated with a threefold difference in rate

We have determined the absolute translation rates for four individual codons in Escherichia coli. We used our previously described system for direct measurements of in vivo translation rates using small, in-frame inserts in the lacZ gene. The inserts consisted of multiple synthetic 30 base-pair DNA oligomers with high densities of the four individual codons, GAA (Glu), GAG (Glu), CCG (Pro) and CGA (Arg). Our method is independent of expression level, of mRNA half-life and of transcription rate. Codon GAA was found to be translated with a rate of 21.6 codons/second whereas codon GAG was translated 3.4-fold slower (6.4 codons/s). These two codons are read by the same tRNA species. Codon CCG and CGA are both read by abundant tRNA species but nevertheless we found them to be translated slowly with rates of 5.8 and 4.2 codons/second, respectively. The context of these codons were varied, but we found no significant influence of context on their translation rates and we suggest a mechanism for why context may not affect translation rates. One insert with a low translation rate gave results that most readily can be explained by assuming queue formation of ribosomes on the insert. Such a queue was found to reduce the expression level by approximately 35%. Our experiments allowed us to estimate the average distance between ribosomes and thereby the translation initiation frequency on the wild-type lacZ mRNA. This was found to be one per three seconds.

Characterization of a 40S ribosomal subunit complex in polyribosomes of Saccharomyces cerevisiae treated with cycloheximide

Under specific conditions cycloheximide treatment of Saccharomyces cerevisiae caused the accumulation of a type of polyribosome called "halfmer." Limited ribonuclease digestion of halfmers released particles from the polyribosomes identified as 40S ribosomal subunits. The data demonstrated that halfmers are polyribosomes containing an additional 40S ribosomal subunit attached to the messenger ribonucleic acid. Protein gel electrophoretic analysis of halfmers revealed numerous nonribosomal proteins. Two of these proteins comigrate with subunits of yeast initiation factor eIF2.

Structural and functional analysis of Escherichia coli ribosomes containing small deletions around position 1760 in the 23S ribosomal RNA

Three different small deletions were produced at a single Pvu 2 restriction site in E. coli 23S rDNA of plasmid pKK 3535 using exonuclease Bal 31. The deletions were located around position 1760 in 23S rRNA and were characterized by DNA sequencing as well as by direct fingerprinting and S1-mapping of the rRNA. Two of the mutant plasmids, Pvu 2-32 and Pvu 2-33, greatly reduced the growth rate of transformed cells while the third mutant, Pvu 2-14 grew as fast as cells containing the wild-type plasmid pKK 3535. All three mutant 23S rRNAs were incorporated into 50S-like particles and were even found in 70S ribosomes and polysomes in vivo. The conformation of mutant 23S rRNA in 50S subunits was probed with a double-strand specific RNase from cobra venom. These analyses revealed changes in the accessibility of cleavage sites near the deletions around position 1760 and in the area around position 800 in all three mutant rRNAs. We suggest, that an altered conformation of the rRNAs at the site of the deletion is responsible for the slow growth of cells containing mutant plasmids Pvu 2-32 and Pvu 2-33.

Characterization of a 40S ribosomal subunit complex in polyribosomes of Saccharomyces cerevisiae treated with cycloheximide

Under specific conditions cycloheximide treatment of Saccharomyces cerevisiae caused the accumulation of a type of polyribosome called "halfmer." Limited ribonuclease digestion of halfmers released particles from the polyribosomes identified as 40S ribosomal subunits. The data demonstrated that halfmers are polyribosomes containing an additional 40S ribosomal subunit attached to the messenger ribonucleic acid. Protein gel electrophoretic analysis of halfmers revealed numerous nonribosomal proteins. Two of these proteins comigrate with subunits of yeast initiation factor eIF2.

Stringent control and protein synthesis in bacteria

Most bacteria have evolved a number of regulatory mechanisms which allow them to maintain a balanced and rather constant cellular composition in response to nutritional variations. In particular, when the availability of any aminoacyl-tRNA species becomes limiting (namely through amino acid starvation or inactivation of an aminoacyl-tRNA synthetase), several biochemically distinct physiological processes are significantly modified. This coordinate adjustment of cellular activity is termed the "stringent response". Under such conditions of aminoacyl-tRNA limitation, protein synthesis still proceeds, but various quantitative as well as qualitative changes in polypeptide metabolism can be observed. In this review, after a brief recall of the main characteristics of the stringent response, several aspects concerning protein synthesis in deprived bacteria have been presented. First, the rates of residual protein formation, peptide chain growth and protein degradation, and the molecular weight distribution of proteins newly synthesized have been analyzed. Then, the data relative to the biosynthetic regulation of non-ribosomal and ribosomal proteins have been summarized and compared to the results obtained from in vitro experiments using transcription-translation coupled systems. Finally, the problem of translational fidelity during deprivation has been discussed in connection with the metabolic behavior of polysomal structures which are still maintained in cells. The stringent dependence of cellular activity on aminoacyl-tRNA supply is known to be abolished by single-site mutations which confer to bacteria a phenotype referred to as "relaxed". These mutant strains provide an useful analytical tool in the scope of understanding the stringency phenomenon. Therefore, their proteosynthetic activity under aminoacyl-tRNA deprivation has also been studied here, in comparison to that of normal wild-type strains.

Analysis of rpsD mutations in Escherichia coli. III. Effects of rpsD mutations on expression of some ribosomal protein genes

Relative rates of production and steady state levels of ribosomal proteins were determined in a temperature sensitive rpsD (S4) mutant of Escherichia coli. Some proteins (S4, S12, S13) were overproduced in the mutant at permissive temperature but steady state levels of all examined ribosomal proteins were normal. In a rpsD+/rpsD+ homodiploid strain the relative rates of production of ribosomal proteins were not affected by the increased gene dose. In a rpsD+/rpsD heterodiploid strain only wild type, but not mutant S4, was found. In such a strain S4, S7, S12 and probably S13 is overproduced. It is implied that S4 is involved in the regulation of expression of proximal genes of the two transcriptional units including the genes coding for S4 itself and S12, respectively. A degradation system for ribosomal proteins, which is rapid enough to be of regulatory significance, is demonstrated.

Analysis of rpsD mutations in Escherichia coli. II. Physiology of some representative mutants

The effects of ribosomal ambiguity mutations (ram A-) on the assembly of ribosomal 30S subunits in Escherichia coli were studied in some representative mutant strains. It was found that the inability of these strains to produce active 30S subunits at nonpermissive temperatures is correlated with a halt in the accumulation of protein S4. It is demonstrated that 30S-precursor particles lacking this protein accumulate and break down at nonpermissive temperatures and that most of the 30S proteins as well as the 17S RNA constituting these particles are similarly unstable. These findings are discussed and related to the finding that merodiploid strains containing genes for both mutant and wild type protein S4 do not accumulate the mutant form of the protein. Experiments indicating that ribosomal precursor particles are associated with polysomes are presented. The implications of these findings are discussed and it is suggested that the assembly of ribosomes is tightly coupled to the synthesis of ribosomal proteins.

Fractionation on the microscale of brain polyribosomes by electrophoresis on acrylamide gels

A method is described for brain polyribosome fractionation by acrylamide gel electrophoresis. Brain polyribosomes were run in 2.0% gels in quartz capillaries of 800 mum inner diameter where the gels were supported by capillary force. The gels could then be ultraviolet-scanned in situ. Amounts of brain polyribosomes as small as 10-10(-3) A260nm unit could be analysed by this method. The method was checked by running a macroscale-prepared brain polyribosome sample. The various electrophoretic bands obtained showed a favourable A260nm: A280 ratio. A short RNase treatment caused the disappearance of the slowly migrating bands and the emergence of a predominant band migrating faster than the dimer. The various polyribosomal bands were then identified by comparison with the mobility of polyribosome fractions taken from a sucrose gradient fractionation. Finally, the electrophoretic pattern of brain polyribosomes compared favourably with the pattern obtained by the classic method of sucrose gradient sedimentation. The electrophoretic fractionation of polyribosomes prepared from one rat hippocampus (80 mg) is presented.