Expression of Escherichia coli infC: identification of a promoter in an upstream thrS coding sequence

Global gene expression analysis of long-term stationary phase effects in E. coli K12 MG1655

Global gene expression was monitored in long-term stationary phase (LSP) cells of E. coli K12 MG1655 and compared with stationary phase (SP) cells that were sub-cultured without prolonged delay to get an insight into the survival strategies of LSP cells. The experiments were carried out using both LB medium and LB supplemented with 10% of glycerol. In both the media the LSP cells showed decreased growth rate compared to SP cells. DNA microarray analysis of LSP cells in both the media resulted in the up- and down-regulation of several genes in LSP cells compared to their respective SP cells in the corresponding media. In LSP cells grown in LB 204 genes whereas cells grown in LB plus glycerol 321 genes were differentially regulated compared to the SP cells. Comparison of these differentially regulated genes indicated that irrespective of the medium used for growth in LSP cells expression of 95 genes (22 genes up-regulated and 73 down-regulated) were differentially regulated. These 95 genes could be associated with LSP status of the cells and are likely to influence survival and growth characteristics of LSP cells. This is indeed so since the up- and down-regulated genes include genes that protect E. coli LSP cells from stationary phase stress and genes that would help to recover from stress when transferred into fresh medium. The growth phenotype in LSP cells could be attributed to up-regulation of genes coding for insertion sequences that confer beneficial effects during starvation, genes coding for putative transposases and simultaneous down-regulation of genes coding for ribosomal protein synthesis, transport-related genes, non-coding RNA genes and metabolic genes. As yet we still do not know the role of several unknown genes and genes coding for hypothetical proteins which are either up- or down-regulated in LSP cells compared to SP cells.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Mutants of Escherichia coli initiator tRNA defective in initiation. Effects of overproduction of methionyl-tRNA transformylase and the initiation factors IF2 and IF3

We describe the effects of overproduction of methionyl-tRNA transformylase and initiation factors IF2 and IF3 on the activity, in vivo, of initiator tRNA mutants defective at specific steps of the initiation process in protein synthesis. The activity of the U35A36/G72 and U35A36/G72G73 mutants, which are defective in formylation, was increased by overproduction of methionyl-tRNA transformylase. In contrast, the activity of the C30:G40/U35A36 mutant, which is formylated normally but is defective in binding to the ribosomal P site, was not increased. Overproduction of IF2 had a strong stimulatory effect on the activity of virtually all the mutants carrying the U35A36 anticodon sequence change, including the U35A36, U35A36/G72, U35A36/G72G73, and the C30:G40/U35A36 mutants. In cells overproducing IF2, the amount of protein made by translation of a mutant mRNA, which uses the U35A36 mutant initiator tRNA, is severalfold higher than that made by translation of a wild type mRNA. We discuss the possible implications of this result on overproduction of proteins and on the order of assembly of the 30 S ribosome.mRNA.fMet-tRNA initiation complex in Escherichia coli. Over-production of IF3 did not affect the initiator activity of any of the tRNA mutants studied.

Molecular cloning and sequencing of infC, the gene encoding translation initiation factor IF3, from four enterobacterial species

Translation initiation factor IF3 plays a crucial role in initiation of protein synthesis in bacteria. In order to elucidate the IF3 structural elements required for these functions, the evolutionary conservation of IF3 and its gene, infC, was investigated. Homologous infC sequences from Salmonella typhimurium, Klebsiella pneumoniae, Serratia marcescens and Proteus vulgaris were amplified by the polymerase chain reaction and sequenced. Analysis of these sequences, as well as that from Bacillus stearothermophilus, revealed several regions (e.g. residues 62-73 and 173-177) of absolute sequence conservation, suggesting an important role for these regions in IF3 function.

Structure-function analysis of Escherichia coli translation initiation factor IF3: tyrosine 107 and lysine 110 are required for ribosome binding

Translation initiation factor IF3 is required for peptide chain initiation in Escherichia coli. IF3 binds directly to 30S ribosomal subunits ensuring a constant supply of free 30S subunits for initiation complex formation, participates in the kinetic selection of the correct initiator region of mRNA, and destabilizes initiation complexes containing noninitiator tRNAs. The roles that tyrosine 107 and lysine 110 play in IF3 function were examined by site-directed mutagenesis. Tyrosine 107 was changed to either phenylalanine (Y107F) or leucine (Y107L), and lysine 110 was converted to either arginine (K110R) or leucine (K110L). These single amino acid changes resulted in a reduced affinity of IF3 for 30S subunits. Association equilibrium constants (M-1) for 30S subunit binding were as follows: wild-type, 7.8 x 10(7); Y107F, 4.1 x 10(7); Y107L, 1 x 10(7); K110R, 5.1 x 10(6); K110L, < 1 x 10(2). The mutant IF3s were similarly impaired in their abilities to specifically select initiation complexes containing tRNA(fMet). Toeprint analysis indicated that 5-fold more Y107L or K110R protein was required for proper initiator tRNA selection. K110L protein was unable to mediate this selection even at concentrations up to 10-fold higher than wild type. The results indicate that tyrosine 107 and lysine 110 are critical components of the ribosome binding domain of IF3 and, furthermore, that dissociation of complexes containing noninitiator tRNAs requires prior binding of IF3 to the ribosomes.

Growth rate regulation of translation initiation factor IF3 biosynthesis in Escherichia coli

infC, the gene encoding translation initiation factor IF3 in Escherichia coli, can be transcribed from three promoters. Two of these promoters, PI1 and PI2, are located in the upstream thrS sequence which codes for threonyl-tRNA synthetase. Previous studies had shown that PI2 was the major promoter for infC. In the present study, the extent of transcription from PI1 and/or PI2 at a variety of steady-state growth rates was analyzed by promoter fusion studies. PI2 was the more active promoter (two- to threefold stronger than PI1) at all growth rates tested. A fusion plasmid containing both PI1 and PI2 exhibited a transcription level approximately equal to the sum of those observed with the fusion plasmids containing the individual promoters. The transcriptional activities of PI1 and PI2 did not change as the growth rate was varied from 0.3 to 1.7 doublings per h. In contrast, a fusion plasmid carrying the rrnB P1 promoter displayed the expected growth rate response. The steady-state concentrations of infC mRNA in cells grown at different rates were measured and found not to vary. These results indicate that the previously reported growth rate regulation of IF3 biosynthesis neither is accomplished by transcriptional control nor is a result of differential mRNA stability. In view of these results, the steady-state levels of IF3 in cells grown at a number of different growth rates were determined by quantitative immunoblotting. IF3 levels were found to vary with growth rate in a manner essentially identical to that observed for ribosomes. A model accounting for these results and describing a mechanism for coordinate growth rate-regulated expression of ribosomes and IF3 is presented.

Inducible high expression of the Escherichia coli infC gene subcloned behind a bacteriophage T7 promoter

The gene for Escherichia coli translational initiation factor 3 (infC) has been inserted into an overexpression plasmid under the control of the bacteriophage T7 promoter. The infC plasmid was then used to transform a host with a chromosomal T7 RNA polymerase gene controlled by the lacUV5 promoter. Induction of T7 RNA polymerase expression in the host cells resulted in a 200-fold overexpression of infC mRNA and a 100-fold overproduction of initiation factor 3. Rapid batch purification of biologically active IF3 yielded predominantly the long form of IF3, implying that the short form is an artifact of purification by traditional methods.

Bacteriophage Mu late promoters: four late transcripts initiate near a conserved sequence

Late transcription of bacteriophage Mu, which results in the expression of phage morphogenetic functions, is dependent on Mu C protein. Earlier experiments indicated that Mu late RNAs originate from four promoters, including the previously characterized mom promoter. S1 nuclease protection experiments were used to map RNA 5' ends in the three new regions. Transcripts were initiated at these points only in the presence of C and were synthesized in a rightward direction on the Mu genome. Amber mutant marker rescue analysis of plasmid clones and limited DNA sequencing demonstrated that these new promoters are located between C and lys, upstream of I, and upstream of P within the N gene. A comparison of the promoter sequences upstream from the four RNA 5' ends yielded two conserved sequences: the first (tA . . cT, where capital and lowercase letters indicate 100 and 75% base conservation, respectively), at approximately -10, shares some similarity with the consensus Escherichia coli sigma 70 -10 region, while the second (ccATAAc CcCPuG/Cac, where Pu indicates a purine), in the -35 region, bears no resemblance to the E. coli -35 consensus. We propose that these conserved Mu late promoter consensus sequences are important for C-dependent promoter activity. Plasmids containing transcription fusions of these late promoters to lacZ exhibited C-dependent beta-galactosidase synthesis in vivo, and C was the only Mu product needed for this transactivation. As expected, the late promoter-lacZ fusions were activated only at late times after induction of a Mu prophage. The C-dependent activation of lacZ fusions containing only a few bases of the 5' end of Mu late RNA and the presence of altered promoter sequences imply that C acts at the level of transcription initiation.

Transcriptional patterns for the thrS-infC-rplT operon of Escherichia coli

The genes coding for threonyl-tRNA synthetase (thrS), translation initiation factor 3 (infC) and ribosomal protein L20 (rplT) are clustered in the Escherichia coli genome. Previous studies had suggested the possibility that the expression of these genes is coupled. The transcriptional events in this operon have now been examined by S1 nuclease mapping and promoter fusion studies. The results indicate that infC-containing mRNAs are initiated from three separate promoters. Two of these are located in the protein-coding region of thrS and one, P12, is the major promoter at all growth rates tested. In addition, there is co-transcription of thrS and infC from the thrS promoter (PT). A single promoter for thrS has been mapped approx. 170 nucleotides upstream from its translation initiation site. Another promoter has been located within the infC-coding region. It is separated from the next downstream gene, rplT, by a transcription end point. However, termination at this region is only 50-70% efficient and transcripts starting at this promoter can read through into rplT. These findings demonstrate that the pattern of transcription in this operon is highly complex and the mRNA levels for each of the genes is determined by a variety of factors, including multiple promoters, co-transcription and readthrough of transcription termination signals.

First committed step of lipid A biosynthesis in Escherichia coli: sequence of the lpxA gene

The min 4 region of the Escherichia coli genome contains genes (lpxA and lpxB) that encode proteins involved in lipid A biosynthesis. We have determined the sequence of 1,350 base pairs of DNA upstream of the lpxB gene. This fragment of DNA contains the complete coding sequence for the 28.0-kilodalton lpxA gene product and an upstream open reading frame capable of encoding a 17-kilodalton protein (ORF17). In addition there appears to be an additional open reading frame (ORF?) immediately upstream of ORF17. The initiation codon for lpxA is a GUG codon, and the start codon for ORF17 is apparently a UUG codon. The start and stop codons overlap between ORF? and ORF17, ORF17 and lpxA, and lpxA and lpxB. This overlap is suggestive of translational coupling and argues that the genes are cotranscribed. Crowell et al. (D.N. Crowell, W.S. Reznikoff, and C.R.H. Raetz, J. Bacteriol. 169:5727-5734, 1987) and Tomasiewicz and McHenry (H.G. Tomasiewicz and C.S. McHenry, J. Bacteriol. 169:5735-5744, 1987) have demonstrated that there are three similarly overlapping coding regions downstream of lpxB including dnaE, suggesting the existence of a complex operon of at least seven genes: 5'-ORF?-ORF17-lpxA-lpxB-ORF23-dnaE-ORF37-3 '.