Interaction between mutations of ribosomes and RNA polymerase: a pair of strA and rif mutants individually temperature-insensitive but temperature-sensitive in combination

Transcription-Translation Coupling in Bacteria

In bacteria, transcription and translation take place in the same cellular compartment. Therefore, a messenger RNA can be translated as it is being transcribed, a process known as transcription-translation coupling. This process was already recognized at the dawn of molecular biology, yet the interplay between the two key players, the RNA polymerase and ribosome, remains elusive. Genetic data indicate that an RNA sequence can be translated shortly after it has been transcribed. The closer both processes are in time, the less accessible the RNA sequence is between the RNA polymerase and ribosome. This temporal coupling has important consequences for gene regulation. Biochemical and structural studies have detailed several complexes between the RNA polymerase and ribosome. The in vivo relevance of this physical coupling has not been formally demonstrated. We discuss how both temporal and physical coupling may mesh to produce the phenomenon we know as transcription-translation coupling.

Two Old Dogs, One New Trick: A Review of RNA Polymerase and Ribosome Interactions during Transcription-Translation Coupling

The coupling of transcription and translation is more than mere translation of an mRNA that is still being transcribed. The discovery of physical interactions between RNA polymerase and ribosomes has spurred renewed interest into this long-standing paradigm of bacterial molecular biology. Here, we provide a concise presentation of recent insights gained from super-resolution microscopy, biochemical, and structural work, including cryo-EM studies. Based on the presented data, we put forward a dynamic model for the interaction between RNA polymerase and ribosomes, in which the interactions are repeatedly formed and broken. Furthermore, we propose that long intervening nascent RNA will loop out and away during the forming the interactions between the RNA polymerase and ribosomes. By comparing the effect of the direct interactions between RNA polymerase and ribosomes with those that transcription factors NusG and RfaH mediate, we submit that two distinct modes of coupling exist: Factor-free and factor-mediated coupling. Finally, we provide a possible framework for transcription-translation coupling and elude to some open questions in the field.

Structure of RNA polymerase bound to ribosomal 30S subunit

In bacteria, mRNA transcription and translation are coupled to coordinate optimal gene expression and maintain genome stability. Coupling is thought to involve direct interactions between RNA polymerase (RNAP) and the translational machinery. We present cryo-EM structures of E. coli RNAP core bound to the small ribosomal 30S subunit. The complex is stable under cell-like ionic conditions, consistent with functional interaction between RNAP and the 30S subunit. The RNA exit tunnel of RNAP aligns with the Shine-Dalgarno-binding site of the 30S subunit. Ribosomal protein S1 forms a wall of the tunnel between RNAP and the 30S subunit, consistent with its role in directing mRNAs onto the ribosome. The nucleic-acid-binding cleft of RNAP samples distinct conformations, suggesting different functional states during transcription-translation coupling. The architecture of the 30S•RNAP complex provides a structural basis for co-localization of the transcriptional and translational machineries, and inform future mechanistic studies of coupled transcription and translation.

Isolation and characterization of RNA polymerase rpoB mutations that alter transcription slippage during elongation in Escherichia coli

Transcription fidelity is critical for maintaining the accurate flow of genetic information. The study of transcription fidelity has been limited because the intrinsic error rate of transcription is obscured by the higher error rate of translation, making identification of phenotypes associated with transcription infidelity challenging. Slippage of elongating RNA polymerase (RNAP) on homopolymeric A/T tracts in DNA represents a special type of transcription error leading to disruption of open reading frames in Escherichia coli mRNA. However, the regions in RNAP involved in elongation slippage and its molecular mechanism are unknown. We constructed an A/T tract that is out of frame relative to a downstream lacZ gene on the chromosome to examine transcriptional slippage during elongation. Further, we developed a genetic system that enabled us for the first time to isolate and characterize E. coli RNAP mutants with altered transcriptional slippage in vivo. We identified several amino acid residues in the β subunit of RNAP that affect slippage in vivo and in vitro. Interestingly, these highly clustered residues are located near the RNA strand of the RNA-DNA hybrid in the elongation complex. Our E. coli study complements an accompanying study of slippage by yeast RNAP II and provides the basis for future studies on the mechanism of transcription fidelity.

Positive epistasis drives the acquisition of multidrug resistance

The evolution of multiple antibiotic resistance is an increasing global problem. Resistance mutations are known to impair fitness, and the evolution of resistance to multiple drugs depends both on their costs individually and on how they interact—epistasis. Information on the level of epistasis between antibiotic resistance mutations is of key importance to understanding epistasis amongst deleterious alleles, a key theoretical question, and to improving public health measures. Here we show that in an antibiotic-free environment the cost of multiple resistance is smaller than expected, a signature of pervasive positive epistasis among alleles that confer resistance to antibiotics. Competition assays reveal that the cost of resistance to a given antibiotic is dependent on the presence of resistance alleles for other antibiotics. Surprisingly we find that a significant fraction of resistant mutations can be beneficial in certain resistant genetic backgrounds, that some double resistances entail no measurable cost, and that some allelic combinations are hotspots for rapid compensation. These results provide additional insight as to why multi-resistant bacteria are so prevalent and reveal an extra layer of complexity on epistatic patterns previously unrecognized, since it is hidden in genome-wide studies of genetic interactions using gene knockouts.

Understanding the nature of genetic interactions, known as epistasis, is crucial in biology. The strength and type of epistasis is relevant for the evolution of sex, buffering of genetic variation, speciation, and the topography of fitness landscapes. While epistasis between gene deletions has been the recent focus of research, interactions between randomly selected alleles, which are of the greatest evolutionary interest, have not. We have studied the strength and type of epistasis amongst alleles that confer antibiotic resistance and have found that: in an antibiotic-free environment, the cost of multiple resistance is smaller than expected—a signature of pervasive positive epistasis amongst alleles that confer resistance to antibiotics; epistatic interactions are allele specific; a significant fraction of resistant mutations can be beneficial in certain resistant genetic backgrounds; some double resistances entail no measurable cost; and some allelic combinations are hotspots for rapid compensation. Overall, our findings provide added reasoning as to why multi-resistance is so difficult to eradicate. Importantly, our results of allelic-specific epistasis reveal an extra layer of complexity on epistatic patterns previously unrecognized.

Genetic antagonism and hypermutability in Mycobacterium smegmatis

Multidrug-resistant strains of Mycobacterium tuberculosis are a serious and continuing human health problem. Such strains may contain as many as four or five different mutations, and M. tuberculosis strains that are resistant to both streptomycin and rifampin contain mutations in the rpsL and rpoB genes, respectively. Coexisting mutations of this kind in Escherichia coli have been shown to interact negatively (S. L. Chakrabarti and L. Gorini, Proc. Natl. Acad. Sci. USA 72:2084-2087, 1975; S. L. Chakrabarti and L. Gorini, Proc. Natl. Acad. Sci. USA 74:1157-1161, 1977). We investigated this possibility in Mycobacterium smegmatis by analyzing the frequency and nature of spontaneous mutants that are resistant to either streptomycin or rifampin or to both antibiotics. Mutants resistant to streptomycin were isolated from characterized rifampin-resistant mutants of M. smegmatis under selection either for one or for both antibiotics. Similarly, mutants resistant to rifampin were isolated from streptomycin-resistant strains. The second antibiotic resistance mutation occurred at a lower frequency in both cases. Surprisingly, in both cases a very high rate of reversion of the initial antibiotic resistance allele was detected when single antibiotic selection was used; the majority of strains resistant to only one antibiotic were isolated by this process. Determinations of rates of mutation to antibiotic resistance in M. smegmatis showed that the frequencies were enhanced up to 10(4)-fold during stationary phase. If such behavior is also typical of slow-growing pathogenic mycobacteria, these studies suggest that the generation of multiply drug-resistant strains by successive mutations may be a more complex genetic phenomenon than suspected.

Streptomycin- and rifampin-resistant mutants of Escherichia coli perturb F exclusion of bacteriophage T7 by affecting synthesis of the F plasmid protein PifA

Certain alleles of rpsL that confer resistance to the antibiotic streptomycin almost completely relieve F exclusion of bacteriophage T7. Introduction of a specific rpoB allele conferring resistance to rifampin into the rpsL strain restores the ability of the F-containing strain to exclude T7. This variation in the severity of F exclusion is reflected in the levels of the F-encoded inhibitor protein PifA: F'-containing cells that harbor specific rpsL alleles are phenotypically Pif-, but become Pif+ by the further acquisition of a specific rpoB allele. F-containing cells harboring the gyrA43(Ts) mutation also appear phenotypically Pif-, possibly because repression of the pif operon is enhanced by an altered DNA conformation in the gyrase mutant strain.

Characterization of the pleiotropic phenotypes of rifampin-resistant rpoB mutants of Escherichia coli

We used our collection of 17 sequenced rifampin resistance alleles in rpoB to perform a systematic analysis of the phenotypes historically reported with this class of mutants, including growth phenotype, ability to support the growth of different bacteriophages, ability to maintain the F' episome, interaction with mutant alleles at other loci, sensitivity to uracil, inhibition by 5-fluorouridine, and dominance. We found that mutational changes leading to the same phenotype were often located together and that certain phenotypes were associated with one another.

Intragenic suppression of the temperature-sensitivity caused by a mutation in a gene controlling transcription (fit) in Escherichia coli

Starting from a transcription-defective strain harbouring a temperature-sensitive mutation in the fit gene, a rifampicin-resistant, temperature-insensitive derivative has been isolated. Genetic analysis of this derivative demonstrated the presence of a second temperature-sensitive mutation in the same gene. The two mutations mutually suppress each other's phenotype. From cotransduction experiments, the fit gene has been mapped 0.32 min and 0.16 min clockwise from the aroD and pps loci, respectively, at 37.5 min on the linkage map. The mutants harbouring either or both of the fit mutations are defective in RNA synthesis at the non-permissive temperature. The fit gene product is suggested to function as an accessory transcription factor.

Promoter selectivity of Escherichia coli RNA polymerase. II: Altered promoter selection by mutant holoenzymes

Using the in vitro mixed transcription system (Kajitani and Ishihama (1983a, 1983b), we examined selective transcription of truncated DNA templates carrying lac(UV5), rrnE or rpsA promoters by RNA polymerase holoenzymes from pairs of wild-type parents and mutants with a mutation in one or more RNA polymerase subunit genes. The promoter selectivity of RNA polymerases from two sigma-subunit mutants carrying either rpoD2 or rpoD285 differed markedly from that of the respective wild-type enzymes. Both the parental RNA polymerases, however, exhibited abnormal promoter selectivity compared with holoenzymes from various wild-type E. coli strains. On the other hand, all the RNA polymerases from rpoB and/or rpoC mutants and the respective wild-type parents were similar, if not identical, in promoter selection at low temperature. At high temperature, however, RNA polymerases from mutants carrying rpoB2B7 and rpoC4, affecting the beta and beta' subunits, respectively, showed decreased transcription from the high-affinity slow-transcribable promoter rrnEp2 whereas the rpoC92 and rpoB906 X rpoC907 mutant enzymes both lost transcription activity from the strong promoter lacP(UV5). Taking all these observations together we conclude that not only the sigma subunit but also the beta and beta' subunits are involved in the recognition of promoters.

Genetic studies on the beta subunit of Escherichia coli RNA polymerase. I. The effect of known, single amino acid substitutions in an essential protein

The use of five different nonsense suppressors, in conjunction with a collection of 95 independent, spontaneously-occurring amber mutants affecting expression of rpoB, allows the generation of a maximum of 475 potential variants of the beta subunit of E. coli RNA polymerase, each carrying a known amino acid substitution at a particular site. The effect of these amino acid exchanges has been investigated in vivo. A significant majority (363/475) of substitutions lead to cellular death and altered properties--temperature sensitivity, apparently altered transcription termination and a changed stringent response--indicating that RNA polymerase function (unlike that of dispensable proteins) is extremely sensitive to such single site changes.

lac Transcription in Escherichia coli cells treated with chloramphenicol

When protein synthesis was blocked by chloramphenicol in vivo, transcription initiation of lac mRNA was severely inhibited. In a promoter mutant (L8-UV5) or in wild-type cells supplemented with adenosine 3',5'-phosphate (greater than or equal to 5 mM), nearly normal initiation could be achieved, and when the mRNA chains formed were extracted, they coded for the 5'-terminal alpha-peptide of the lacZ gene in vitro. However, even under such conditions, only a fraction of RNA polymerases proceeded to the end of the Z gene in the presence of chloramphenicol; as a consequence, a wide range of sizes of mRNA was produced, and very few transcripts were formed all the way to the natural termination site of the operon. In other words, premature transcription termination occurred in chloramphenicol-treated cells, as current models predict, but terminations occurred to variable extents at several intragenic sites and apparently at least one intergenic site. Termination at intragenic sites occurred far less in cells bearing a mutation in the transcription termination factor rho.

An antibiotic dependent conditional lethal mutant with a lesion affecting transcription and translation

A conditioned lethal mutant of E. coli was isolated which required the presence of either the RNA polymerase targeted antibiotic, rifampicin, or the ribosomally targeted antibiotic, kasugamycin, for survival. This mutant was characterised. The locus of the mutation responsible for the antibiotic dependent phenotype, ridA, was mapped at about 70.5 min on the chromosomal linkage map, between argR and fabE. The mutant was investigated as a candidate for a strain with a lesion in some cellular component acting on both RNA polymerase and the ribosome. A close interaction with RNA polymerase was evident from the interplay arising from the combination of ridA and various rpoB mutations as manifested in the phenotype. The ability of kasugamycin, but not other ribosomally targeted aminoglycoside antibiotics, to relieve the lethality due to the ridA mutation was an indication of the specificity in the interaction of the ridA gene product with the ribosome.

Defective lysis of streptomycin-resistant escherichia coli cells infected with bacteriophage f2

A lysis defect was found to account for the failure of a streptomycin-resistant strain of Escherichia coli to form plaques when infected with the male-specific bacteriophage f2. The lysis defect was associated with the mutation to streptomycin resistance. Large amounts of apparently normal bacteriophage accumulated in these cells. Cell-free extracts from both the parental and mutant strains synthesized a potential lysis protein in considerable amounts in response to formaldehyde-treated f2 RNA but not in response to untreated RNA. As predicted from the nucleotide sequence of the analogous MS2 phage, the protein synthesized in vitro had the expected molecular weight and lacked glycine. The cistron for the lysis protein overlapped portions of the coat and replicase cistrons and was translated in the +1 reading frame. Initiation at the lysis protein cistron may be favored by translation errors that expose the normally masked initiation site, and streptomycin-resistant ribosomes, known to have more faithful translation properties, may be unable to efficiently synthesize the lysis protein.

Lactose operon transcription from wild-type and L8-UV5 lac promoters in Escherichia coli treated with chloramphenicol

In cells treated with chloramphenicol and the inducer isopropyl-beta-D-thiogalacto-pyranoside, messenger ribonucleic acid transcription from the wild-type lac promoter was not detected. Transcription occurred from the mutant UV5-L8 promoter. The transcripts were of variable length; some included the whole Z gene. No major site of transcription arrest within the Z gene was apparent.

regA protein of bacteriophage T4D: identification, schedule of synthesis, and autogenous regulation

Proteins labeled with 14C-amino acids after infection of Escherichia coli B by T4 phage were examined by electrophoresis in the presence of sodium dodecyl sulfate. Four regA mutants (regA1, regA8, regA11, and regA15) failed to make a protein having a molecular weight of about 12,000, whereas mutant regA9 did make such a protein; regA15 produced a new, apparently smaller protein that was presumably a nonsense fragment, whereas regA11 produced a new, apparently larger protein. We conclude that the 12,000-dalton protein was the product of the regA gene. The molecular weight assignment rested primarily on our finding that the regA protein had the same mobility as the T4 gene 33 protein, which we identified by electrophoresis of whole-cell extracts of E. coli B infected with a gene 33 mutant, amE1120. Synthesis of wild-type regA protein occurred from about 3 to 11 min after infection at 37 degrees C in the DNA+ state and extended to about 20 min in the DNA- state. However, synthesis of the altered regA proteins of regA9, regA11, and regA15 occurred at a higher rate and for a much longer period in both the DNA+ and DNA- states; thus, the regA gene is autogenously regulated. At 30 degrees C, both regA9 and regA11 exhibited partial regA function by eventually shutting off the synthesis of many T4 early proteins; the specificity of this shutoff differed between these two mutants. We also obtained evidence that the regA protein is not Stevens's "polypeptide 3." As a technical point, we found that, when quantitating acid-precipitable radioactivity in protein samples containing sodium dodecyl sulfate, it was necessary to use 15 to 20% trichloroacetic acid; use of 5% acid, e.g., resulted in loss of over half of the labeled protein.

Transcription and translation in a pleiotropic streptomycin-resistant mutant of Escherichia coli

The role of the ribosomal protein S12 (streptomycin protein) in ribosome function and in other metabolic processes in the cell has been investigated. A spontaneous streptomycin-resistant strain of Escherichia coli (SM3) carrying a mutation in the rpsL gene is deficient in its ability to induce the synthesis of the enzyme bets-galactosidase. It was demonstrated that the reduced rate of enzyme synthesis results from deficiencies in both the transcription of the lactose operon and translation of the lactose operon mRNA. The transcription deficiency was in part due to increased catabolite repression and could therefore be partially suppressed by the addition of cyclic AMP. Streptomycin also appeared to partially suppress catabolite repression. In the SM3 mutant strain, the translation of the lactose operon mRNA was only about 60% as efficient as in the parental control, and addition of streptomycin did not alter the translation efficiency. In contrast, both transcription and translation of ribosomal protein mRNA were equally efficient in the two strains. These observations imply that mutational alterations in the ribosomal protein S12 either directly or indirectly alter (i) the extent of catabolite repression, (ii) the efficiency of transcription of the lactose operon even in the absence of catabolite repression, and (iii) the efficiency of translation of some but not all mRNA species in the cell.

Suppression of temperature-sensitive sporulation of a Bacillus subtilis elongation factor G mutant by RNA polymerase mutations

A class of rifampin-resistant (rfm) mutations of Bacillus subtilis suppresses the temperature-sensitive sporulation of a fusidic acid-resistant mutant. FUS426, which has an altered elongation factor G. The rfm mutation suppressed only the sporulation defect caused by the elongation factor G mutation, but could not suppress other types of induced sporulation defects. Genetic and biochemical analyses showed that the sporulation suppression by the rfm mutation was caused by a single mutation in RNA polymerase. After the early sporulation phase, the apparent rate of RNA synthesis of FUS426, measured by [3H]uracil or [3H]uridine incorporation into RNA, became lower than that of the wild-type strain, and this decrease was reversed by the rfm mutation. However, when the total rate of RNA synthesis of FUS426 was calculated by measuring the specific activity of [3H]UTP and [3H]CTP, it was higher than that of the rfm mutant, RIF122FUS426. The possible mechanism of the functional interaction between elongation factor G and RNA polymerase during sporulation is discussed.

Suppression of Temperature-Sensitive Sporulation of a Bacillus subtilis Elongation Factor G Mutant by RNA Polymerase Mutations

A class of rifampin-resistant ( rfm ) mutations of Bacillus subtilis suppresses the temperature-sensitive sporulation of a fusidic acid-resistant mutant, FUS426, which has an altered elongation factor G. The rfm mutation suppressed only the sporulation defect caused by the elongation factor G mutation, but could not suppress other types of induced sporulation defects. Genetic and biochemical analyses showed that the sporulation suppression by the rfm mutation was caused by a single mutation in RNA polymerase. After the early sporulation phase, the apparent rate of RNA synthesis of FUS426, measured by [ 3 H]uracil or [ 3 H]uridine incorporation into RNA, became lower than that of the wild-type strain, and this decrease was reversed by the rfm mutation. However, when the total rate of RNA synthesis of FUS426 was calculated by measuring the specific activity of [ 3 H]UTP and [ 3 H]CTP, it was higher than that of the rfm mutant, RIF122FUS426. The possible mechanism of the functional interaction between elongation factor G and RNA polymerase during sporulation is discussed.

Pleiotropic effect of a rifampin-resistant mutation in Bacillus subtilis

Rifampin-resistant (Rifr) mutants were isolated spontaneously from Bacillus subtilis strain 168. A fraction of the mutants did not grow on a minimal medium. A high concentration of one of the L-amino acids (glutamic acid, glutamine, arginine, proline, aspartic acid, or asparagine) was required to restore their growth on the medium. Further analysis of one of the mutants (strain RF 161) suggested that the mutant is unable to use ammonia as a nitrogen source and requires amino acids instead. Activity of glutamate synthase was not detected in the crude extract of the mutant. The Rifr mutation was closely located to cysA and the drug resistance was cotransformed with the property of amino acid requirement at 100% frequency. All revertants to prototrophy tested showed the rifampin-sensitive (Rifs) property. The activity of the DNA-dependent RNA polymerase of the mutant was resistant to rifampin. It is concluded that some alteration of RNA polymerase may cause absence of the activity of an enzyme involved in the nitrogen metabolism.

The temperature sensitive mutant 72c. I. Pleiotropic growth behaviour and changed response to some antibiotics and mutations in the transcription or translation apparatus

The spontaneous temperature sensitive mutant 72c is shown to be more tolerant to fusidic acid, but less tolerant to trimethoprim on plates at permissive temperature, than is the parental strain. The poor growth of the mutant on amino acids supplemented plates, as well as its inability to grow on broth plates at 40 degrees, can be compensates by sublethal amounts of chloroamphenicol. Also some mutations to Rif-R or Str-R improve growth of the mutant under certain conditions. Reversion and other genetic analysis strongly suggest, that the pleiotropic behaviour of the mutant is due to a single mutation in a gene, which is designated fusB and is closely cotransducible with lip at min 14 of the E. coli chromosome. The gene order is lip-fusB-supE.

Coupling of lac mRNA transcription to translation in Escherichia coli cell extracts

In an extract containing all the components for lac gene expression except washed ribosomes, lac mRNA formation was increased 4- to 6-fold by the addition of washed ribosomes. The formation of beta-galactosidase mRNA and enzyme showed very different dependency on added ribosomes. Enzyme was formed in proportion to the number of ribosomes added, whereas 10% of the standard level of ribosomes promoted full levels of transcription. Consistent with their action in vivo, chloramphenicol and erythromycin blocked the ribosome-dependent lac transcription. The same inhibition was seen with RNA pulse-labeled for 1 or 5 min, so that the effect was truly a blockage of formation rather than an increased hyperlability of nascent mRNA. The effect was specified for some RNA species, as it is in vivo: phage lambda N gene transcription was increased rather than inhibited in the presence of chloramphenicol. Chloramphenicol did not stop lac transcription as a result of its blockage of formation of the regulatory nucleotide tetraphosphate (ppGpp), because addition of the nucleotide did not restore mRNA formation in chloramphenicol-treated extracts. Rather, the data are consistent with the ideas that one or a few ribosomes moving closely behind RNA polymerase can prevent its arrest and that, when ribosome movement is blocked by chloramphenicol, the RNA polymerase is exposed to factors that provoke premature RNA chain termination.

[Correlation between a novel phenotype towards streptomycin and the binding of an additional protein to the ribosome in mutants of Escherichia coli B]

Mutants of Escherichia coli have been isolated containing streptomycin suppressors that exhibit novel phenotypes with respect to strA alleles. In one class of these mutants, the suppressor effect parallels a strong binding to the ribosome of an additional protein in at least stoichiometric amounts. Transduction experiments confirmed that the level of suppression and the degree of binding of this protein were correlated.