Unbalanced rRNA gene dosage and its effects on rRNA and ribosomal-protein synthesis

Costs of ribosomal RNA stabilization affect ribosome composition at maximum growth rate

Ribosomes are key to cellular self-fabrication and limit growth rate. While most enzymes are proteins, ribosomes consist of 1/3 protein and 2/3 ribonucleic acid (RNA) (in E. coli).Here, we develop a mechanistic model of a self-fabricating cell, validated across diverse growth conditions. Through resource balance analysis (RBA), we explore the variation in maximum growth rate with ribosome composition, assuming constant kinetic parameters.Our model highlights the importance of RNA instability. If we neglect it, RNA synthesis is always cheaper than protein synthesis, leading to an RNA-only ribosome at maximum growth rate. Upon accounting for RNA turnover, we find that a mixed ribosome composed of RNA and proteins maximizes growth rate. To account for RNA turnover, we explore two scenarios regarding the activity of RNases. In (a) degradation is proportional to RNA content. In (b) ribosomal proteins cooperatively mitigate RNA instability by protecting it from misfolding and subsequent degradation. In both cases, higher protein content elevates protein synthesis costs and simultaneously lowers RNA turnover expenses, resulting in mixed RNA-protein ribosomes. Only scenario (b) aligns qualitatively with experimental data across varied growth conditions.Our research provides fresh insights into ribosome biogenesis and evolution, paving the way for understanding protein-rich ribosomes in archaea and mitochondria.

Unlinked rRNA genes are widespread among bacteria and archaea

Ribosomes are essential to cellular life and the genes for their RNA components are the most conserved and transcribed genes in bacteria and archaea. Ribosomal RNA genes are typically organized into a single operon, an arrangement thought to facilitate gene regulation. In reality, some bacteria and archaea do not share this canonical rRNA arrangement-their 16S and 23S rRNA genes are separated across the genome and referred to as "unlinked". This rearrangement has previously been treated as an anomaly or a byproduct of genome degradation in intracellular bacteria. Here, we leverage complete genome and long-read metagenomic data to show that unlinked 16S and 23S rRNA genes are more common than previously thought. Unlinked rRNA genes occur in many phyla, most significantly within Deinococcus-Thermus, Chloroflexi, and Planctomycetes, and occur in differential frequencies across natural environments. We found that up to 41% of rRNA genes in soil were unlinked, in contrast to the human gut, where all sequenced rRNA genes were linked. The frequency of unlinked rRNA genes may reflect meaningful life history traits, as they tend to be associated with a mix of slow-growing free-living species and intracellular species. We speculate that unlinked rRNA genes may confer selective advantages in some environments, though the specific nature of these advantages remains undetermined and worthy of further investigation. More generally, the prevalence of unlinked rRNA genes in poorly-studied taxa serves as a reminder that paradigms derived from model organisms do not necessarily extend to the broader diversity of bacteria and archaea.

Recombineering with tolC as a selectable/counter-selectable marker: remodeling the rRNA operons of Escherichia coli

This work describes the novel use of tolC as a selectable/counter-selectable marker for the facile modification of DNA in Escherichia coli. Expression of TolC (an outer membrane protein) confers relative resistance to toxic small molecules, while its absence renders the cell tolerant to colicin E1. These features, coupled with the lambdaredgam recombination system, allow for selection of tolC insertions/deletions anywhere on the E. coli chromosome or on plasmid DNA. This methodology obviates the need for minimal growth media, specialized wash protocols and the lengthy incubation times required by other published recombineering methods. As a rigorous test of the TolC selection system, six out of seven 23S rRNA genes were consecutively and seamlessly removed from the E. coli chromosome without affecting expression of neighboring genes within the complex rrn operons. The resulting plasmid-free strain retains one 23S rRNA gene (rrlC) in its natural location on the chromosome and is the first mutant of its kind. These new rRNA mutants will be useful in the study of rRNA gene regulation and ribosome function. Given its high efficiency, low background and facility in rich media, tolC selection is a broadly applicable method for the modification of DNA by recombineering.

Transcriptional polarity in rRNA operons of Escherichia coli nusA and nusB mutant strains

Synthesis of ribosomes in Escherichia coli requires an antitermination system that modifies RNA polymerase to achieve efficient transcription of the genes specifying 16S, 23S, and 5S rRNA. This modification requires nucleotide signals in the RNA and specific transcription factors, such as NusA and NusB. Transcription of rrn operons in strains lacking the ability to produce either NusA or NusB was examined by electron microscopy. The distribution and numbers of RNA polymerase molecules on rrn operons were determined for each mutant. Compared to the wild type, the 16S gene in the nusB mutant strain had an equivalent number of RNA polymerase molecules, but the number of RNA polymerase molecules was reduced 1.4-fold for the nusA mutant. For both mutant strains, there were twofold-fewer RNA polymerase molecules on the 23S RNA gene than for the wild type. Overall, the mutant strains each had 1.6-fold-fewer RNA polymerase molecules on their rrn operons than did the wild type. To determine if decreased transcription of the 23S gene observed by electron microscopy also affected the 30S/50S ribosomal subunit ratio, ribosome profiles were examined by sucrose gradient analysis. The 30S/50S ratio increased 2.5- to 3-fold for the nus mutant strains over that for wild-type cells. Thus, strains carrying either a nusA mutation or a nusB mutation have defects in transcription of 23S rRNA.

Mutations in 16S rRNA in Escherichia coli at methyl-modified sites: G966, C967, and G1207

Mutations were constructed at three sites in 16S rRNA in E. coli by oligonucleotide-directed mutagenesis, and cloned into the rrnB operon on either pKK3535 or pNO2680. The mutated bases, G966, C967, and G1207, are located in the 3' major domain of 16S rRNA and are sites post-transcriptionally modified by methylation. We constructed a deletion mutation at C967 (delta 967) and three substitution mutations at each of the following sites: G966, C967, and G1207. By maxicell analysis, we found that all of the mutations were processed normally and incorporated into 30S subunits and 70S ribosomes. We found that delta 967 was a dominant lethal mutation while the substitution mutations at G966 and C967 had no effects on cell growth rate. The mutants C1207 and U1207 were shown to have dominant lethal phenotypes while A1207 had no effect on cell growth rate. These results help to establish the importance of methyl-modified regions to ribosome function.

Ribosomal protein L4 of Escherichia coli: in vitro analysis of L4-mediated attenuation control

Ribosomal protein L4 of Escherichia coli functions not only as a component of the ribosome but also as a regulatory factor inhibiting both transcription and translation of its own operon, the 11 gene S10 operon. L4-mediated transcription control results in premature termination of transcription within the 172 base S10 operon leader. This attenuation control can be reproduced in a purified transcription system containing RNA polymerase, but depends on the addition of transcription factor NusA. The NusA stimulation saturates at about 2-4 copies per RNA polymerase. The L4 effect plateaus at about 4 copies per RNA polymerase. The specific recognition sites on 23S rRNA and in the S10 leader for L4 binding are not yet known. However, we can demonstrate that a fragment of 23S rRNA containing the proximal 840 bases can eliminate in vitro L4-stimulated attenuation, and hence, contains the information sufficient for L4 binding to 23S rRNA.

The tL structure within the leader region of Escherichia coli ribosomal RNA operons has post-transcriptional functions

We have investigated a series of mutations within a plasmid encoded E. coli ribosomal RNA leader region. The mutations are localized within a structure known as tL, which has been shown to mediate RNA polymerase pausing in vitro, and which is assumed to have a control function in rRNA transcription antitermination. The effects of the mutated plasmids were analyzed by in vivo and in vitro experiments. Some of the base change mutations led to severely reduced cell growth. As opposed to previous results obtained with mutants where the tL structure has been deleted in part or totally, the tL base change mutations did not result in polar transcription in vivo, rather they revealed a general reduction in the amount of the promoter proximal 16S versus the distal 23S RNA. The deficiency of the 16S RNA, which was most pronounced for some of the slowly growing transformants, can only be explained by a post-transcriptional degradation. In addition, many mutants showed a defective processing after the initial RNase III cut. In line with these results a quantitative analysis of the ratio of ribosomal subunits and 70S tight couple ribosomes showed a reduced capacity to form stable 70S particles for the slowly growing mutants. Together, these findings indicate an important function of the tL structure in post-transcriptional events like processing of rRNA precursors and correct assembly of 30S subunits.

Relationship between protein synthesis and concentrations of charged and uncharged tRNATrp in Escherichia coli

We have continuously monitored Trp-tRNA(Trp) concentrations in vivo and, in the same cultures, measured rates of protein synthesis in isogenic stringent and relaxed strains. We have also manipulated cellular charged and uncharged [tRNA(Trp)] by two means: (i) the strain used contains a Trp-tRNA synthetase mutation that increases the Km for Trp; thus, varying exogenous Trp varies cellular Trp-tRNA(Trp); and (ii) we have introduced into the mutant strain a plasmid containing the tRNA(Trp) gene behind an inducible promoter; thus, total [tRNA(Trp)] also can be varied depending on length of induction. The use of these conditions, combined with a previously characterized assay system, has allowed us to demonstrate that (i) the rate of incorporation of Trp into protein is proportional to the fraction of tRNA(Trp) that is charged; for any given total [tRNA(Trp)], this rate is also proportional to the [Trp-tRNA(Trp)]; (ii) uncharged tRNA(Trp) inhibits incorporation of Trp into protein; and (iii) rates of incorporation into protein of at least two other amino acids, Lys and Cys, are also sensitive to [Trp-tRNA(Trp)] and are inhibited by uncharged tRNA(Trp). Our results are consistent with models of translational control that postulate modulating polypeptide chain elongation efficiency by varying concentrations of specific tRNAs.

Effect of variation of charged and uncharged tRNA(Trp) levels on ppGpp synthesis in Escherichia coli

We introduced into a stringent Escherichia coli tryptophan auxotroph a plasmid bearing the tRNA(Trp) gene under the control of an inducible promoter. This allows us to manipulate the total concentration of tRNA(Trp) in the cell according to whether and when inducer is added to the culture. We also manipulated the concentration of Trp-tRNA(Trp) in vivo since the strain used bears a mutation in the Trp-tRNA synthetase affecting the Km for tryptophan, such that varying the exogenous concentration of tryptophan led to variation in the level of Trp-tRNA(Trp) in the cell. With this system, we found that the signal eliciting ppGpp synthesis during a stringent response triggered by tryptophan limitation did not depend on the absolute concentration of either charged or uncharged tRNA(Trp) but rather depended on a decline in the ratio of charged/uncharged tRNA(Trp). In addition, we found that the amplitude of the response, once triggered by tryptophan limitation, was determined by the total concentration of tRNA(Trp) present in the cell (which is mostly uncharged at that point in time). However, excess uncharged tRNA(Trp) did not amplify ppGpp synthesis triggered by limitation of a different amino acid. These data provide in vivo support for the in vitro-derived model of ppGpp synthesis on ribosomes.

Effects of induction of rRNA overproduction on ribosomal protein synthesis and ribosome subunit assembly in Escherichia coli

Overproduction of rRNA was artificially induced in Escherichia coli cells to test whether the synthesis of ribosomal protein (r-protein) is normally repressed by feedback regulation. When rRNA was overproduced more than twofold from a hybrid plasmid carrying the rrnB operon fused to the lambda pL promoter (pL-rrnB), synthesis of individual r-proteins increased by an average of about 60%. This demonstrates that the synthesis of r-proteins is repressed under normal conditions. The increase of r-protein production, however, for unknown reasons, was not as great as the increase in rRNA synthesis and resulted in an imbalance between the amounts of rRNA and r-protein synthesis. Therefore, only a small (less than 20%) increase in the synthesis of complete 30S and 50S ribosome subunits was detected, and a considerable fraction of the excess rRNA was degraded. Lack of complete cooperativity in the assembly of ribosome subunits in vivo is discussed as a possible explanation for the absence of a large stimulation of ribosome synthesis observed under these conditions. In addition to the induction of intact rRNA overproduction from the pL-rrnB operon, the effects of unbalanced overproduction of each of the two large rRNAs, 16S rRNA and 23S rRNA, on r-protein synthesis were examined using pL-rrnB derivatives carrying a large deletion in either the 23S rRNA gene or the 16S rRNA gene. Operon-specific derepression after 23S or 16S rRNA overproduction correlated with the overproduction of rRNA containing the target site for the operon-specific repressor r-protein. These results are discussed to explain the apparent coupling of the assembly of one ribosomal subunit with that of the other which was observed in earlier studies on conditionally lethal mutants with defects in ribosome assembly.

Deletions in the tL structure upstream to the rRNA genes in the E. coli rrnB operon cause transcription polarity

A number of deletions have been constructed within the leader region of the rrnB operon from E. coli. The deletions remove a potential transcription terminator structure downstream from an antitermination recognition sequence (Box A), which precedes the structural gene for the 16S RNA. Cells harbouring plasmids, where the terminator structure was deleted, partially or totally, showed a reduction in growth rate under minimal growth conditions. Measurement of the ribosomal RNA synthesis rates of such cells determined by pulselabeling and hybridisation to appropriate DNA probes, showed that the amount of the more distally located 23S RNA was reduced compared to the promoter-proximal 16S RNA. This polarity in transcription, resulting in a non-stoichiometric synthesis of the ribosomal RNAs, is most likely the result of a defective antitermination. The reduction in the amount of 23S RNA in such cells is compensated for by an increase in the overall ribosomal RNA synthesis, in concordance with the ribosomal RNA feedback regulation model. The accumulation of transcripts of the tRNAGlu2 gene, coded in the spacer region between the 16S and 23S RNA genes, in cells with an altered rRNA stoichiometry supports this interpretation.

Translational regulation is responsible for growth-rate-dependent and stringent control of the synthesis of ribosomal proteins L11 and L1 in Escherichia coli

The physiological importance of translational regulation in controlling the synthesis of ribosomal proteins from the L11 ribosomal protein operon was determined for the classical regulatory phenomena of growth rate dependence and stringent control. Translational regulation of the L11 operon by ribosomal protein L1, the L11 operon-specific translational repressor protein, was abolished by introducing a chromosomal mutation that causes an alteration of the site where L1 interacts with L11 operon mRNA. It was found that abolishing translational regulation of the L11 operon also abolished growth-rate-dependent regulation and stringent control of the L11 operon ribosomal proteins without affecting the normal regulation of ribosomal proteins from other operons that are not regulated by L1. These results show that both growth-rate-dependent control and stringent control of ribosomal protein synthesis in the L11 operon are a direct result of translational regulation.