The chloroplast psbA promoter is more efficient in Escherichia coli than the T7 promoter for hyperexpression of a foreign protein

The T7 promoter is commonly used in E. coli expression studies but has several disadvantages due to induction with isopropylthio--D-galactoside (IPTG) including the prohibitive cost of IPTG, reduction in cell growth, and the poisonous nature of IPTG prohibiting its use in pharmaceutical products. The chloroplast psbA promoter produces an 18.5 fold increase in expression in E. coli compared to the T7 promoter. Also, the psbA promoter does not have the disadvantages of induction with IPTG.     

Over-production of 5-enolpyruvylshikimate-3-phosphate synthase in Escherichia coli: use of the T7 promoter.

5-Enolpyruvylshikimate-3-phosphate (EPSP) synthase, the product of the Escherichia coli aroA gene, has been overproduced in E. coli BL21(lambda DE3) under the control of the T7 gene 10 promoter and ribosome binding site, to a level of approximately 50% of total cell protein. EPSP synthase is the primary target of the post-emergence herbicide, glyphosate, commonly known as Roundup. A simple two step purification is described, which results in 99% pure homogeneous protein (as determined by PAGE). The integrity of the protein has been compared with previously characterized protein from E. coli AB2829(pKD501) by determination of its kinetic parameters, N-terminal protein and DNA sequences, amino acid analysis and 13C-NMR spectroscopy. This new overproducing strain readily provides the gram quantities of highly pure protein required for NMR studies of the active site and the development of novel time-resolved solid-state NMR techniques currently underway in this laboratory.     

Improving protein solubility: the use of the Escherichia coli dihydrofolate reductase gene as a fusion reporter

We have devised a strategy for screening mutant libraries for enzyme variants with enhanced solubility. The method is based on the observation that Escherichia coli can become insensitive to the antibiotic trimethoprim (TMP) if dihydrofolate reductase (DHFR) is expressed at an appropriate level. DHFR is a very soluble protein and can be expressed at levels that exceed normally lethal concentrations of TMP. In our approach, the gene encoding an insoluble target protein is placed in a vector so that the translated protein will be fused to DHFR. The resulting fusion protein will form inclusion bodies and inactivate DHFR-the cells will be susceptible to TMP. Mutations to the target protein that make it more soluble will also make the fusion protein more soluble so that DHFR will be at least partially active-the cells will be resistant to TMP. As the solubility of the target protein increases, the cells will become more resistant to TMP. The system was tested with a putative acetyltransferase (ACE) from a strain of the marine bacterium Vibrio fischerii. The gene encoding this protein was of interest since it is part of a mobile gene cassette within an integron array of the strain in question. After multiple rounds of shuffling and selection, ACE mutants were produced that had significantly improved solubility.     

The Mycobacterium marinum G13 promoter is a strong sigma 70-like promoter that is expressed in Escherichia coli and mycobacteria species

A Mycobacterium marinum promoter, designated G13, was isolated from a promoter-trap library as a constitutive producer of the mutant green fluorescent protein. Sequence analysis, primer extension analysis, and computer promoter prediction analysis indicate that the G13 promoter is very similar to Escherichia coli consensus sigma 70 promoters. Expression of the green fluorescent protein from the G13 promoter in M. marinum is, however, up to 40 times higher than that seen from the mycobacterial hsp60 promoter during exponential growth. Further, expression from this promoter does not appear to affect the growth of the organism in culture media or in macrophages. The strong expression of the G13 promoter allows it to be developed as a useful molecular tool for high level expression of markers in vitro.     

The Escherichia coli dam gene is expressed as a distal gene of a new operon

Summary DNA containing the Escherichia coli dam gene and sequences upstream from this gene were cloned from the Clarke-Carbon plasmids pLC29-47 and pLC13-42. Promoter activity was localized using pKO expression vectors and galactokinase assays to two regions, one 1650–2100 bp and the other beyon 2400 bp upstream of the dam gene. No promoter activity was detected immediately in front of this gene; plasmid pDam118, from which the nucleotide sequence of the dam gene was determined, is shown to contain the pBR322 promoter for the primer RNA from the pBR322 rep region present on a 76 bp Sau3A fragment inserted upstream of the dam gene in the correct orientation for dam expression. The nucleotide sequence upstream of dam has been determined. An open reading frame (ORF) is present between the nearest promoter region and the dam gene. Codon usage and base frequency analysis indicate that this is expressed as a protein of predicted size 46 kDa. A protein of size close to 46 kDa is expressed from this region, detected using minicell analysis. No function has been determined for this protein, and no significant homology exist between it and sequences in the PIR protein or GenBank DNA databases. This unidentified reading frame (URF) is termed urf-74.3, since it is an URF located at 74.3 min on the E. coli chromosome. Sequence comparisons between the regions upstream of urf-74.3 and the aroB gene show that the aroB gene is located immediately upstream of urf-74.3, and that the promoter activity nearest to dam is found within the aroB structural gene. This activity is relatively weak (about 15% of that of the E. coli gal operon promoter). The promoter activity detected beyond 2400 bp upstream of dam is likely to be that of the aroB gene, and is 3 to 4 times stronger than that found within the aroB gene. Three potential DnaA binding sites, each with homology of 8 of 9 bp, are present, two in the aroB promoter region and one just upstream of the dam gene. Expression through the site adjacent to the dam gene is enhanced 2-to 4-fold in dnaA mutants at 38°C. Restriction site comparisons map these regions precisely on the Clarke-Carbon plasmids pLC13-42 and pLC29-47, and show that the E. coli ponA (mrcA) gene resides about 6 kb upstream of aroB.     

The construction of a synthetic Escherichia coli trp promoter and its use in the expression of a synthetic interferon gene.

An 82 base pair DNA fragment has been synthesised which contains the E. coli trp promoter and operator sequences and also encodes the first Shine Dalgarno sequence of the trp operon. This DNA fragment is flanked by EcoRI and ClaI/TaqI cohesive ends and is thus easy to clone, transfer between vector systems and couple to genes to drive their expression. It has been cloned into plasmid pAT153, producing a convenient trp promoter vector. We have also joined the fragment to a synthetic IFN-alpha 1 gene, using synthetic oligonucleotides to generate a completely natural, highly efficient bacterial translation initiation signal on the promoter proximal side of the IFN gene. Plasmids carrying this construction enable E. coli cells to express IFN-alpha 1 almost constitutively and with significantly higher efficiency than from a lacUV5 promoter based system.     

Purine N7 groups that are crucial to the interaction of Escherichia coli rnase P RNA with tRNA.

We have detected by nucleotide analog interference mapping (NAIM) purine N7 functional groups in Escherichia coli RNase P RNA that are important for tRNA binding under moderate salt conditions (0.1 M Mg2+, 0.1 M NH4+). The majority of identified positions represent highly or universally conserved nucleotides. Our assay system allowed us, for the first time, to identify c7-deaza interference effects at two G residues (G292, G306). Several c7-deazaadenine interference effects (A62, A65, A136, A249, A334, A351) have also been identified in other studies performed at very different salt concentrations, either selecting for substrate binding in the presence of 0.025 M Ca2+ and 1 M NH4+ or self-cleavage of a ptRNA-RNase P RNA conjugate in the presence of 3 M NH4+ or Na+. This indicates that these N7 functional groups play a key role in the structural organization of ribozyme-substrate and -product complexes. We further observed that a c7-deaza modification at A76 of tRNA interferes with tRNA binding to and ptRNA processing by E. coli RNase P RNA. This finding combined with the strong c7-deaza interference at G292 of RNase P RNA supports a model in which substrate and product binding to E. coli RNase P RNA involves the formation of intermolecular base triples (A258-G292-C75 and G291-G259-A76).     

The isolation of a 4-thiouridine-containing disulfide from oxidized Escherichia coli tRNA is not artifactual.

Iodine-oxidized Escherichia coli tRNA yields an oxidized 4-thiouridine dinucleoside after enzymatic digestion and dephosphorylation. The original isolation has been questioned on the basis of an observed instability of 4-thiouridine disulfide in Tris-Cl buffer and a persistent oxidizing capacity of some resins after exposure to iodine. It is here pointed out that the original isolation specifically negated both of these objections. The fragment recently isolated by Kaiser (Arch. Biochem. Biophys.183, 421–431, 1977) appears to be very similar to the one previously reported, although probably neither one is the symmetrical 4-thiouridine disulfide.     

Mutational analysis of the Escherichia coli serB promoter region reveals transcriptional linkage to a downstream gene.

Genes encoding proteins with unrelated functions can be cotranscribed, and this may be used by cells to coordinate different metabolic pathways during growth. We describe a gene, designated sms, which is downstream from the serine biosynthetic gene serB in Escherichia coli but does not appear to be involved in amino acid (aa) biosynthesis. The sms gene is 1380 bp long. The Sms product migrates at 55 kDa on sodium dodecyl sulfate(SDS)-polyacrylamide gels and has a M(r) of 49472 (460 aa residues) calculated from the nucleotide sequence. The deduced Sms aa sequence shares regions of similarity with two ATP-dependent proteases, Lon and RecA, and contains two motifs: a C-x(2)-C-x(n)-C-x(2)-C motif, which is found in some nucleic acid binding proteins, and an ATP/GTP binding site motif. Insertional inactivation of sms led to increased sensitivity to the alkylating agent methylmethane sulfonate, but not to a requirement for serine or other metabolites. Several promoter mutations were isolated and characterized, which suggest that serB has a typical promoter recognized by sigma 70. After the serB coding sequence there is a 48-bp region with no obvious promoter sequence preceding the sms translation start codon. Analyses using sms'-lacZ fusions cloned downstream from wild-type and mutant serB promoters showed that sms is cotranscribed with serB.     

Overexpression of cloned genes using recombinant Escherichia coli regulated by a T7 promoter: I. Batch cultures and kinetic modeling

A novel Eschericha coli expression system directed by bacteriophage T7 RNA Polymerase utilized for overexpression of the cloned gene. The recombinant cell contains the plasmid with a bacteriophage promoter, the T7 promoter, to regulate the expression of the target gene. This promoter is recongnized only by T7 RNA polymerase, whose gene has been fused into the host chromosome and is under control of the lacUV5 promoter. Therefore, the target gene on the plasmid can be expressed only in the presence of T7 RNA polymerase, which is induced by isopropyl-beta-D-thiogalactopyranoside (IPTG). The batch cultures were performed to investigate the effect of induction on kinetics of cell growth and foreign protein formation and to determine the optimal induction strategy. It was observed that the specific growth rates of the recombinant cells dramatically decrease after induction, and that there is an optimal induction time for maximizing the accumulated intracellular foreign protein. This optimal induction time varies singificantly with inducer concentration. To better understand the optimal behavior, a lumped mechanistic model was constructed to analyze the induced cell growth and foreign protein formation rates. (c) 1992 John Wiley & Sons, Inc.