The rlmB gene is essential for formation of Gm2251 in 23S rRNA but not for ribosome maturation in Escherichia coli.

In Saccharomyces cerevisiae, the rRNA Gm2270 methyltransferase, Pet56p, has an essential role in the maturation of the mitochondrial large ribosomal subunit that is independent of its methyltransferase activity. Here we show that the proposed Escherichia coli ortholog, RlmB (formerly YjfH), indeed is essential for the formation of Gm in position 2251 of 23S rRNA. However, a DeltarlmB mutant did not show any ribosome assembly defects and was not outgrown by a wild-type strain even after 120 cell mass doublings. Thus, RlmB has no important role in ribosome assembly or function in E. coli.

Characterization of mutations in the metY-nusA-infB operon that suppress the slow growth of a DeltarimM mutant.

The RimM protein in Escherichia coli is associated with free 30S ribosomal subunits but not with 70S ribosomes. A DeltarimM mutant shows a sevenfold-reduced growth rate and a reduced translational efficiency, probably as a result of aberrant assembly of the ribosomal 30S subunits. The slow growth and translational deficiency can be partially suppressed by increased synthesis of the ribosome binding factor RbfA. Here, we have identified 14 chromosomal suppressor mutations that increase the growth rate of a DeltarimM mutant by increasing the expression of rbfA. Nine of these mutations were in the nusA gene, which is located upstream from rbfA in the metY-nusA-infB operon; three mutations deleted the transcriptional terminator between infB and rbfA; one was an insertion of IS2 in infB, creating a new promoter for rbfA; and one was a duplication, placing a second copy of rbfA downstream from a promoter for the yhbM gene. Two of the nusA mutations were identical, while another mutation (nusA98) was identical to a previously isolated mutation, nusA11, shown to decrease termination of transcription. The different nusA mutations were found to increase the expression of rbfA by increasing the read-through of two internal transcriptional terminators located just downstream from the metY gene and that of the internal terminator preceding rbfA. Induced expression of the nusA(+) gene from a plasmid in a nusA(+) strain decreased the read-through of the two terminators just downstream from metY, demonstrating that one target for a previously proposed NusA-mediated feedback regulation of the metY-nusA-infB operon expression is these terminators. All of the nusA mutations produced temperature-sensitive phenotypes of rimM(+) strains. The nusA gene has previously been shown to be essential at 42 degrees C and below 32 degrees C. Here, we show that nusA is also essential at 37 degrees C.

Hybrid protein between ribosomal protein S16 and RimM of Escherichia coli retains the ribosome maturation function of both proteins.

The RimM protein in Escherichia coli is associated with free 30S ribosomal subunits but not with 70S ribosomes and is important for efficient maturation of the 30S subunits. A mutant lacking RimM shows a sevenfold-reduced growth rate and a reduced translational efficiency. Here we show that a double alanine-for-tyrosine substitution in RimM prevents it from associating with the 30S subunits and reduces the growth rate of E. coli approximately threefold. Several faster-growing derivatives of the rimM amino acid substitution mutant were found that contain suppressor mutations which increased the amount of the RimM protein by two different mechanisms. Most of the suppressor mutations destabilized a secondary structure in the rimM mRNA, which previously was shown to decrease the synthesis of RimM by preventing the access of the ribosomes to the translation initiation region on the rimM mRNA. Three other independently isolated suppressor mutations created a fusion between rpsP, encoding the ribosomal protein S16, and rimM on the chromosome as a result of mutations in the rpsP stop codon preceding rimM. A severalfold-higher amount of the produced hybrid S16-RimM protein in the suppressor strains than of the native-sized RimM in the original substitution mutant seems to explain the suppression. The S16-RimM protein but not any native-size ribosomal protein S16 was found both in free 30S ribosomal subunits and in translationally active 70S ribosomes of the suppressor strains. This suggests that the hybrid protein can substitute for S16, which is an essential protein probably because of its role in ribosome assembly. Thus, the S16-RimM hybrid protein seems capable of carrying out the important functions that native S16 and RimM have in ribosome biogenesis.

RimM and RbfA are essential for efficient processing of 16S rRNA in Escherichia coli.

The trmD operon is located at 56.7 min on the genetic map of the Escherichia coli chromosome and contains the genes for ribosomal protein (r-protein) S16, a 21-kDa protein (RimM, formerly called 21K), the tRNA (m1G37)methyltransferase (TrmD), and r-protein L19, in that order. Previously, we have shown that strains from which the rimM gene has been deleted have a sevenfold-reduced growth rate and a reduced translational efficiency. The slow growth and translational deficiency were found to be partly suppressed by mutations in rpsM, which encodes r-protein S13. Further, the RimM protein was shown to have affinity for free ribosomal 30S subunits but not for 30S subunits in the 70S ribosomes. Here we have isolated several new suppressor mutations, most of which seem to be located close to or within the nusA operon at 68.9 min on the chromosome. For at least one of these mutations, increased expression of the ribosome binding factor RbfA is responsible for the suppression of the slow growth and translational deficiency of a deltarimM mutant. Further, the RimM and RbfA proteins were found to be essential for efficient processing of 16S rRNA.

A novel ribosome-associated protein is important for efficient translation in Escherichia coli.

Previously, we showed that strains which have been deleted for the 21K gene (hereafter called yfjA), of the trmD operon, encoding a 21-kDa protein (21K protein) have an approximately fivefold-reduced growth rate in rich medium. Here we show that such mutants show an up to sevenfold reduced growth rate in minimal medium, a twofold-lower cell yield-to-carbon source concentration ratio, and a reduced polypeptide chain growth rate of beta-galactosidase. Suppressor mutations that increased the growth rate and translational efficiency of a delta yfjA mutant were localized to the 3' part of rpsM, encoding ribosomal protein S13. The 21K protein was shown to have affinity for free 30S ribosomal subunits but not for 70S ribosomes. Further, the 21K protein seems to contain a KH domain and a KOW motif, both suggested to be involved in binding of RNA. These findings suggest that the 21K protein is essential for a proper function of the ribosome and is involved in the maturation of the ribosomal 30S subunits or in translation initiation.

The Escherichia coli ribosomal protein S16 is an endonuclease.

The histone-like protein HU isolated from Escherichia coli exhibited, after several purification steps, a Mg(2+)-dependent nuclease activity. We show here that this activity can be dissociated from HU by a denaturation-renaturation step, and is due to a small fraction of ribosomal protein S16 co-purifying with HU. S16 is an essential component of the 30S ribosomal particles. We have cloned, overproduced, and purified a histidine-tagged S16 and shown that this protein is a DNA-binding protein carrying a Mg(2+)-Mn(2+)-dependent endonuclease activity. This is an unexpected property for a ribosomal protein.

Functional analysis of the ffh-trmD region of the Escherichia coli chromosome by using reverse genetics.

We have analyzed the essentiality or contribution to growth of each of four genes in the Escherichia coli trmD operon (rpsP, 21K, trmD, and rplS) and of the flanking genes ffh and 16K by a reverse genetic method. Mutant alleles were constructed in vitro on plasmids and transferred by recombination to the corresponding lambda phage clone (lambda 439) and from the phage clone to the E. coli chromosome. An ability to obtain recombinants only in cells carrying a complementing plasmid indicated that the mutated gene was essential, while an ability to obtain recombinants in plasmid-free cells indicated nonessentiality. In this way, Ffh, the E. coli homolog to the 54-kDa protein of the signal recognition particle of mammalian cells, and ribosomal proteins S16 and L19 were shown to be essential for viability. A deletion of the second gene, 21K, of the trmD operon reduced the growth rate of the cells fivefold, indicating that the wild-type 21-kDa protein is important for viability. A deletion-insertion in the same gene resulted in the accumulation of an assembly intermediate of the 50S ribosomal subunit, as a result of polar effects on the expression of a downstream gene, rplS, which encodes ribosomal protein L19. This finding suggests that L19, previously not considered to be an assembly protein, contributes to the assembly of the 50S ribosomal subunits. Strains deleted for the trmD gene, the third gene of the operon, encoding the tRNA (m1G37)methyltransferase (or TrmD) showed a severalfold reduced growth rate. Since such a strain grew much slower than a strain lacking the tRNA(m(1)G37) methyltransferase activity because of a point mutation, the TrmD protein might have a second function in the cell. Finally, a 16-kDa protein encoded by the gene located downstream of, and convergently transcribed to, the trmD operon was found to be nonessential and not to contribute to growth.

The GTPase activity of the Escherichia coli Ffh protein is important for normal growth.

The Escherichia coli (E. coli) Ffh protein is homologous to the 54kDa subunit of the eukaryotic signal recognition particle. We have examined an intrinsic GTPase activity of this protein and have created mutations in one sequence motif (GXXXXGK) of the putative GTP binding site. When glycine-112 was changed to valine (Ffh-G112V), Vmax was reduced to only 4% of the wildtype level. On the other hand, when glutamine-109 was altered to glycine (Ffh-Q109G), the major effect was a 50-fold increase in Km. These results show that the residues Q-109 and G-112 are essential for the binding and hydrolysis of GTP and that they are part of a catalytic site structurally related to that of many other GTPase proteins. Expression of the mutant protein Ffh-G112V in E. coli was highly toxic in the presence of the wildtype protein. In contrast, genetic complementation experiments showed that a viable strain could be constructed where the Ffh-Q109G mutant protein replaced wildtype Ffh. However, expression of the mutant protein had a negative effect on growth rate at 30 degrees C and resulted in elongated cells. These results demonstrate that the GTPase activity of the Ffh protein is required for proper function of the protein in vivo.

Importance of mRNA folding and start codon accessibility in the expression of genes in a ribosomal protein operon of Escherichia coli.

The trmD operon of Escherichia coli consists of the genes for the ribosomal protein (r-protein) S16, a 21 kilodalton protein (21K) of unknown function, the tRNA(m1G37)methyltransferase (TrmD), and r-protein L19, in that order. The synthesis of the 21K and TrmD proteins is 12 and 40-fold lower, respectively, than that of the two r-proteins, although the corresponding parts of the mRNA are equally abundant. This translational control of expression of at least the 21K protein gene (21K), is mediated by a negative control element located between codons 18 and 50 of 21K. Here, we present evidence for a model in which mRNA sequences up to around 100 nucleotides downstream from the start codon of 21K fold back and base-pair to the 21K translation initiation region, thereby decreasing the translation initiation frequency. Mutations in the internal negative control element of 21K that would prevent the formation of the proposed mRNA secondary structure over both the Shine-Dalgarno (SD) sequence and the start codon increased expression up to about 20-fold, whereas mutations that would disrupt the base-pairing with the SD-sequence had only relatively small effects on expression. In addition, the expression increased 12-fold when the stop codon of the preceding gene, rpsP, was moved next to the SD-sequence of 21K allowing the ribosomes to unfold the postulated mRNA secondary structure. The expression increased up to 150-fold when that stop codon change was combined with the internal negative control element base-substitutions that derepressed translation about 20-fold. The negative control element of 21K does not seem to be responsible for the low expression of the trmD gene located downstream. However, a similar negative control element native to trmD can explain at least partly the low expression of trmD. Possibly, the two mRNA secondary structures function to decouple translation of 21K and trmD from that of the respective upstream cistron in order to achieve their independent regulation.

Efficient introduction of cloned mutant alleles into the Escherichia coli chromosome.

An efficient method for moving mutations in cloned Escherichia coli DNA from plasmid vectors to the bacterial chromosome was developed. Cells carrying plasmids that had been mutated by the insertion of a resistance gene were infected with lambda phage containing homologous cloned DNA, and resulting lysates were used for transduction. Chromosomal transductants (recombinants) were distinguished from plasmid transductants by their ampicillin-sensitive phenotype, or plasmid transductants were avoided by using a recBC sbcB E. coli strain as recipient. Chromosomal transductants were usually haploid when obtained in a nonlysogen because of selection against the lambda vector and partially diploid when obtained in a lysogen. Pure stocks of phage that carry the resistance marker and transduce it at high frequency were obtained from transductant bacteria. The lambda-based method for moving mutant alleles into the bacterial chromosome described here should be useful for diverse analyses of gene function and genome structure.

A regulatory element within a gene of a ribosomal protein operon of Escherichia coli negatively controls expression by decreasing the translational efficiency.

The trmD operon of Escherichia coli consists of the genes for the ribosomal protein (r-protein) S16, a 21 kDa protein (21K) of unknown function, the tRNA(m1G37)methyltransferase (TrmD), and r-protein L19, in this order. Previously we have shown that the steady-state amount of the two r-proteins exceeds that of the 21K and TrmD proteins 12- and 40-fold, respectively, and that this differential expression is solely explained by translational regulation. Here we have constructed translational gene fusions of the trmD operon and lacZ. The expression of a lacZ fusion containing the first 18 codons of the 21K protein gene is 15-fold higher than the expression of fusions containing 49 or 72 codons of the gene. This suggests that sequences between the 18th and the 49th codon may act as a negative element controlling the expression of the 21K protein gene. Evidence is presented which demonstrates that this regulation is achieved by reducing the efficiency of translation.

Prevention of translational frameshifting by the modified nucleoside 1-methylguanosine.

The methylated nucleoside 1-methylguanosine (m1G) is present next to the 3' end of the anticodon (position 37) in all transfer RNAs (tRNAs) that read codons starting with C except in those tRNAs that read CAN codons. All of the three proline tRNA species, which read CCN codons in Salmonella typhimurium, have been sequenced and shown to contain m1G in position 37. A mutant of S. typhimurium that lacks m1G in its tRNA when grown at temperatures above 37 degrees C, has now been isolated. The mutation (trmD3) responsible for this methylation deficiency is in the structural gene (trmD) for the tRNA(m1G37)methyltransferase. Therefore, the three proline tRNAs in the trmD3 mutant have an unmodified guanosine at position 37. Furthermore, the trmD3 mutation also causes at least one of the tRNAPro species to frequently shift frame when C's are present successively in the message. Thus, m1G appears to prevent frameshifting. The data from eubacteria apply to both eukaryotes and archaebacteria.

Non-autogenous control of ribosomal protein synthesis from the trmD operon in Escherichia coli.

The trmD operon of Escherichia coli encodes the ribosomal proteins S16 and L19, the tRNA(m1G37)methyltransferase and a 21,000 Mr protein of unknown function. Here we demonstrate that, in contrast to the expression of other ribosomal protein operons, the amount of trmD operon mRNA and the rate of synthesis of the proteins encoded by the operon respond to increased gene dosage. The steady-state level of the mRNA was about 18 times higher, and the relative rate of synthesis of the ribosomal proteins S16 and L19, the tRNA(m1G37)methyltransferase and the 21,000 Mr protein was 15, 9, 25 and 23 times higher, respectively, in plasmid-containing cells than in plasmid-free cells. Overproduced tRNA(m1G37)methyltransferase and 21,000 Mr protein were as stable as E. coli total protein, whereas the two ribosomal proteins were degraded to a large extent. The steady-state amount of S16 and L19 in the plasmid-containing cells exceeded that in plasmid-free cells by threefold and twofold, respectively. No significant effect on the synthesis of the trmD operon proteins from the chromosomally located genes was observed when parts of the operon were expressed on different plasmids. Taken together, these results suggest that the expression of the trmD operon is not subject to transcriptional or translational feedback regulation, and demonstrate that not all ribosomal protein operons are regulated in the same manner. We propose that ribosomal protein operons that do not encode proteins that bind directly to rRNA are not under autogenous control. Metabolic regulation at the transcriptional level and protein degradation are plausible mechanisms for the control of expression of such operons.

Noncoordinate translation-level regulation of ribosomal and nonribosomal protein genes in the Escherichia coli trmD operon.

The trmD operon of Escherichia coli contains the genes for the ribosomal protein S16, a 21-kilodalton polypeptide of unknown function, the tRNA(1-methylguanosine)methyltransferase, and the ribosomal protein L19, in that order. As reported elsewhere, the operon is transcribed as a single polycistronic mRNA species, and there is no significant difference in the steady-state amounts of different parts of the mRNA (A.S. Byström, A. von Gabain, and G.R. Björk, submitted for publication). Furthermore, accumulation of all parts of the transcript is altered in a stringently controlled manner upon starvation for valyl-tRNA. Here we show that the rate of synthesis of the trmD operon proteins increased with increasing growth rate and that the amount in steady state, at a specific growth rate (k = 1.0), of the tRNA(1-methylguanosine)methyltransferase was 260 molecules per gene copy, which is about 40 times lower than the amount of the two ribosomal proteins, whereas the 21-kilodalton protein was synthesized to the amount of about 850 molecules per gene copy. The lower steady-state amount of the two nonribosomal proteins was not due to a higher turnover rate. Synthesis of the 21-kilodalton and TrmD proteins responded differently from that of the two ribosomal proteins during conditions which provoked amino acid starvation, although accumulation of the entire mRNA molecule responds similarly to the rate of synthesis of the two ribosomal proteins. We conclude that the observed differential and noncoordinate expression is achieved by regulation at the level of mRNA translation.

The nucleotide sequence of an Escherichia coli operon containing genes for the tRNA(m1G)methyltransferase, the ribosomal proteins S16 and L19 and a 21-K polypeptide.

The nucleotide sequence of a 4.6-kb SalI-EcoRI DNA fragment including the trmD operon, located at min 56 on the Escherichia coli K-12 chromosome, has been determined. The trmD operon encodes four polypeptides: ribosomal protein S16 (rpsP), 21-K polypeptide (unknown function), tRNA-(m1G)methyltransferase (trmD) and ribosomal protein L19 (rplS), in that order. In addition, the 4.6-kb DNA fragment encodes a 48-K and a 16-K polypeptide of unknown functions which are not part of the trmD operon. The mol. wt. of tRNA(m1G)methyltransferase determined from the DNA sequence is 28 424. The probable locations of promoter and terminator of the trmD operon are suggested. The translational start of the trmD gene was deduced from the known NH2-terminal amino acid sequence of the purified enzyme. The intercistronic regions in the operon vary from 9 to 40 nucleotides, supporting the earlier conclusion that the four genes are co-transcribed, starting at the major promoter in front of the rpsP gene. Since it is known that ribosomal proteins are present at 8000 molecules/genome and the tRNA-(m1G)methyltransferase at only approximately 80 molecules/genome in a glucose minimal culture, some powerful regulatory device must exist in this operon to maintain this non-coordinate expression. The codon usage of the two ribosomal protein genes is similar to that of other ribosomal protein genes, i.e., high preference for the most abundant tRNA isoaccepting species. The trmD gene has a codon usage typical for a protein made in low amount in accordance with the low number of tRNA-(m1G)methyltransferase molecules found in the cell.