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 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.     

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.     

E. coli ribosomal protein L4 is a feedback regulatory protein

We studied the synthesis of ribosomal proteins encoded by the S10 operon, an eleven gene operon from the str-spc region of the E. coli chromosome, using a λfus3 DNA-directed, in vitro protein synthesizing system. Addition of ribosomal protein L4 (1 μM) to in vitro protein synthesis reactions caused selective inhibition of synthesis of the promoter-proximal proteins of the S10 operon, S10, L3, L4, L23 and possibly L2. Proteins of the S10 operon other than L4 did not cause selective inhibition of protein synthesis. Autoregulatory ribosomal proteins previously identified from other operons, L1, S4 and S8, did not inhibit protein synthesis from the S10 operon; nor did L4 cause significant inhibition of protein synthesis from operons other than the S10 operon. As with L1, S4 and S8, L4 inhibits gene expression at the level of translation.     

1-Methylguanosine deficiency of tRNA influences cognate codon interaction and metabolism in Salmonella typhimurium.

1-Methylguanosine (m1G) is present next to the 3' end of the anticodon (position 37) in tRNA(1,2,3,Leu), tRNA(1,2,3,Pro), and tRNA(3Arg). A mutant of Salmonella typhimurium lacks m1G in these seven tRNAs when grown at or above 37 degrees C, as a result of a mutation (trmD3) in the structural gene (trmD) for the tRNA(m1G37)methyltransferase. The m1G deficiency induced 24 and 26% reductions in the growth rate and polypeptide chain elongation rate, respectively, in morpholinepropanesulfonic acid (MOPS)-glucose minimal medium at 37 degrees C. The expression of the leuABCD operon is controlled by the rate with which tRNA(2Leu) and tRNA(3Leu) read four leucine codons in the leu-leader mRNA. Lack of m1G in these tRNAs did not influence the expression of this operon, suggesting that m1G did not influence the efficiency of tRNA(2,3Leu). Since the average step time of the m1G-deficient tRNAs was increased 3.3-fold, the results suggest that the impact of m1G in decoding cognate codons may be tRNA dependent. The trmD3 mutation rendered the cell more resistant or sensitive to several amino acid analogs. 3-Nitro-L-tyrosine (NT), to which the trmD3 mutant is sensitive, was shown to be transported by the tryptophan-specific permease, and mutations in this gene (mtr) render the cell resistant to NT. Since the trmD3 mutation did not affect the activity of the permease, some internal metabolic step(s), but not the uptake of the analog per se, is affected. We suggest that the trmD3-mediated NT sensitivity is by an abnormal translation of some mRNA(s) whose product(s) is involved in the metabolic reactions affected by the analog. Our results also suggest that tRNA modification may be a regulatory device for gene expression.     

Structural alterations of the tRNA(m1G37)methyltransferase from Salmonella typhimurium affect tRNA substrate specificity

In Salmonella typhimurium, the tRNA(m1G37)methyltransferase (the product of the trmD gene) catalyzes the formation of m1G37, which is present adjacent and 3' of the anticodon (position 37) in seven tRNA species, two of which are tRNA(Pro)CGG and tRN(Pro)GGG. These two tRNA species also exist as +1 frameshift suppressor sufA6 and sufB2, respectively, both having an extra G in the anticodon loop next to and 3' of m1G37. The wild-type form of the tRNA(m1G37)methyltransferase efficiently methylates these mutant tRNAs. We have characterized one class of mutant forms of the tRNA(m1G37)methyltransferase that does not methylate the sufA6 tRNA and thereby induce extensive frameshifting resulting in a nonviable cell. Accordingly, pseudorevertants of strains containing such a mutated trmD allele in conjunction with the sufA6 allele had reduced frameshifting activity caused by either a 9-nt duplication in the sufA6tRNA or a deletion of its structural gene, or by an increased level of m1G37 in the sufA6tRNA. However, the sufB2 tRNA as well as the wild-type counterparts of these two tRNAs are efficiently methylated by this class of structural altered tRNA(m1G37)methyltransferase. Two other mutations (trmD3, trmD10) were found to reduce the methylation of all potential tRNA substrates and therefore primarily affect the catalytic activity of the enzyme. We conclude that all mutations except two (trmD3 and trmD10) do not primarily affect the catalytic activity, but rather the substrate specificity of the tRNA, because, unlike the wild-type form of the enzyme, they recognize and methylate the wild-type but not an altered form of a tRNA. Moreover, we show that the TrmD peptide is present in catalytic excess in the cell.     

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 ΔrimM mutant. Further, the RimM and RbfA proteins were found to be essential for efficient processing of 16S rRNA.     

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

Summary 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.     

Structure and organization of Marchantia polymorpha chloroplast genome. III. Gene organization of the large single copy region from rbcL to trnI(CAU)

The nucleotide sequence (25,320 base-pairs) of a part of the large single-copy region of chloroplast DNA from the liverwort Marchantia polymorpha was determined. This region encodes putative genes for four tRNAs, isoleucine tRNA(CAU), arginine tRNA(CCG), proline tRNA(UGG) and tryptophan tRNA(CCA); eight photosynthetic polypeptides, the large subunit of ribulose bisphosphate carboxylase/oxygenase (rbcL), 51,000 Mr photosystem II chlorophyll alpha apoprotein (psbB), apocytochrome b-559 polypeptides (psbE and psbF), 10,000 Mr phosphoprotein (psbH), cytochrome f preprotein (petA), cytochrome b6 polypeptide (petB), and cytochrome b6/f complex subunit 4 polypeptide (petD); 13 ribosomal proteins (L2, L14, L16, L20, L22, L23, L33, S3, S8, S11, S12, S18 and S19); initiation factor 1 (infA); ribosome-associating polypeptide (secX); and alpha subunit of RNA polymerase (rpoA). Functionally related genes were located in several clusters in this region of the genome. There were two ribosomal protein gene clusters: rpl23-rpl2-rps19-rpl22-rps3-rpl16-+ ++rpl14-rps8-infA-secX-rps11-rpoA, with a gene arrangement similar to that of the Escherichia coli S10-spc-alpha operons, and the rps12'-rpl20-rps18-rpl33 cluster. There were gene clusters encoding photosynthesis components such as the psbB-psbH-petB-petD and the psbE-psbF clusters. Thirteen open reading frames, ranging in length from 31 to 434 amino acid residues, remain to be identified.     

Purification and characterization of c-Ki-ras p21 from bovine brain crude membranes

In the present studies, we attempted to purify the native molecular forms of the c-ras proteins (c-ras p21s) from bovine brain crude membranes and separated at least three GTP-binding proteins (G proteins) cross-reactive with the antibody recognizing all of Ha-, Ki-, and N-ras p21s. Among them, one G protein with a Mr of about 21,000 was highly purified and characterized. The Mr 21,000 G protein bound maximally about 0.6 mol of [35S]guanosine 5'-(3-O-thio)triphosphate (GTP gamma S)/mol of protein with a Kd value of about 30 nM. [35S]GTP gamma S-binding to Mr 21,000 G protein was inhibited by GTP and GDP, but not by other nucleotides such as ATP, UTP, and CTP. [35S]GTP gamma S-binding to Mr 21,000 G protein was inhibited by pretreatment with N-ethylmaleimide. Mr 21,000 G protein hydrolyzed GTP to liberate Pi with a turnover number of about 0.01 min-1. Mr 21,000 G protein was not copurified with the beta gamma subunits of the G proteins regulatory for adenylate cyclase. Mr 21,000 G protein was not recognized by the antibody against the ADP-ribosylation factor for Gs. The peptide map of Mr 21,000 G protein was different from those of the G proteins with Mr values of 25,000 and 20,000, designated as smg p25A and rho p20, respectively, which we have recently purified from bovine brain crude membranes. The partial amino acid sequence of Mr 21,000 G protein was identical with that of human c-Ki-ras 2B p21. These results indicate that Mr 21,000 G protein is bovine brain c-Ki-ras 2B p21 and that c-Ki-ras 2B p21 is present in bovine brain membranes.     

First complete nucleotide sequence and heterologous gene organization of the two rRNA operons in the phytoplasma genome

Phytoplasmas are cell-wallless Gram-positive low G + C bacteria belonging to the Mollicutes that inhabit the cytoplasm of plants and insects. Although phytoplasmas possess two ribosomal RNA (rrn) operons, only one has been fully sequenced. Here, we determined the complete nucleotide sequence of both rrn operons (designated rrnA and rrnB) of onion yellows (OY) phytoplasma. Both operons have rRNA genes organized as 5'-16S-23S-5S-3' with very highly conserved sequences; the 16S, 23S, and 5S rRNA genes are 99.9, 99.8, and 99.1% identical between the two operons. However, the organization of tRNA genes in the upstream region from 16S rRNA gene and in the downstream region from 5S rRNA gene differs markedly. Several promoter candidates were detected upstream from both operons, which suggests that both operons are functional. Interestingly, both have a tRNA(Ile) gene in the 16S-23S spacer region, while the reported rrnB operon of loofah witches' broom phytoplasma does not, indicating heterogenous gene organization of rrnB within phytoplasmas. The phytoplasma tRNA gene organization is similar to that of acholeplasmas, a closely related mollicute, and different from that of mycoplasmas, another mollicute. Moreover, the organization suggests that the rrn operons were derived from that of a related nonmollicute bacterium, Bacillus subtilis. This data should shed light on the evolutionary relationships and phylogeny of the mollicutes.     

Computer analysis of regulatory signals in complete bacterial genomes. Translation initiation of ribosomal protein operons]

Signals of translation initiation of operons of Haemophilus influenzae ribosomal proteins were predicted. This process is regulated by the formation of secondary RNA structures to which one of the proteins encoded in a particular operon binds. In some cases, these structures imitate the region of protein binding to rRNA. Predictions are made by comparing with homologous operons of Escherichia coli and analogous regions of rRNA and by estimating the energy of secondary structure formation. It is shown that this regulatory mechanism occurs: in operons L11, S10, S15, spc, and alpha of H.influenzae and, probably, in operon S15 of Helicobacter pylori, Bacillus subtilis, and Mycoplasma genitalium.     

The roles of proteins L28 and L33 in the assembly and function of Escherichia coli ribosomes in vivo

Strain BM108 of Escherichia coli has a chromosomal mutation in the rpmB , G operon that prevents synthesis of ribosomal proteins L28 and L33. The mutation was lethal unless synthesis of protein L28 was induced from a plasmid. Without protein L28, RNA and protein synthesis were linear rather than exponential. No 70S ribosomes were made. Instead, RNA accumulated in '30S material' and '47S particles'; the latter were distinct from 50S ribosomal subunits, lacked proteins L28 and L33 and had substoicheometric amounts of three other proteins. When L28 synthesis was induced (but protein L33 was still absent), the strain grew as well as, and assembled 70S ribosomes with similar kinetics to, a wild-type control. Thus, protein L28 is required for ribosome assembly in strain BM108 while protein L33 has no significant effect on ribosome synthesis or function.