Construction and physical mapping of plasmids containing the MetA gene of Escherichia coli K-12

Summary Plasmids containing the metA gene of E. coli K-12 were constructed in vitro using pBR322 as the cloning vehicle and metA transducing phage as the source of metA DNA. EcoRI digests of pBR322 and metA20 were joined by ligase and plasmids carrying the metA gene were selected after transformation in a metA deletion strain. Recombinant DNA molecules contained one pBR322 fragment and one metA20 fragment of 12.2 kb which was present in either of two possible orientations. Plasmids constructed by BamH1 digestion of metA2 contained a single bacterial DNA fragment of 5.8 kb inserted in the tet gene. Insertion of the metA fragment led to loss of resistance to tetracycline in one orientation and partial resistance in the opposite orientation.     

Improved Thermostability and Acetic Acid Tolerance of Escherichia coli via Directed Evolution of Homoserine o-Succinyltransferase

In Escherichia coli, growth is limited at elevated temperatures mainly because of the instability of a single enzyme, homoserine o-succinyltransferase (MetA), the first enzyme in the methionine biosynthesis pathway. The metA gene from the thermophile Geobacillus kaustophilus cloned into the E. coli chromosome was found to enhance the growth of the host strain at elevated temperature (44°C), thus confirming the limited growth of E. coli due to MetA instability. In order to improve E. coli growth at higher temperatures, we used random mutagenesis to obtain a thermostable MetA_{E. coli} protein. Sequencing of the thermotolerant mutant showed five amino acid substitutions: S61T, E213V, I229T, N267D, and N271K. An E. coli strain with the mutated metA gene chromosomally inserted showed accelerated growth over a temperature range of 34 to 44°C. We used the site-directed metA mutants to identify two amino acid residues responsible for the sensitivity of MetA_{E. coli} to both heat and acids. Replacement of isoleucine 229 with threonine and asparagine 267 with aspartic acid stabilized the protein. The thermostable MetA_{E. coli} enzymes showed less aggregation in vivo at higher temperature, as well as upon acetic acid treatment. The data presented here are the first to show improved E. coli growth at higher temperatures solely due to MetA stabilization and provide new knowledge for designing E. coli strains that grow at higher temperatures, thus reducing the cooling cost of bioprocesses.     

Functional dissection of a napin gene promoter: identification of promoter elements required for embryo and endosperm-specific transcription

The promoter region (?309 to +44) of the Brassica napus storage protein gene napA was studied in transgenic tobacco by successive 5′ as well as internal deletions fused to the reporter gene GUS (β-glucuronidase). The expression in the two main tissues of the seed, the endosperm and the embryo, was shown to be differentially regulated. This tissue-specific regulation within the seed was found to affect the developmental expression during seed development. The region between ?309 to ?152, which has a large effect on quantitative expression, was shown to harbour four elements regulating embryo and one regulating endosperm expression. This region also displayed enhancer activity. Deletion of eight bp from position ?152 to position ?144 totally abolished the activity of the napA promoter. This deletion disrupted a cis element with similarity to an ABA-responsive element (ABRE) overlapping with an E-box, demonstrating its crucial importance for quantitative expression. An internal deletion of the region ?133 to ?120, resulted in increased activity in both leaves and endosperm and a decreased activity in the embryo. Within this region, a cis element similar to the (CA)_n element, found in other storage protein promoters, was identified. This suggest that the (CA)_n element is important for conferring seed specificity by serving both as an activator and a repressor element.     

Synthetic promoter libraries for Corynebacterium glutamicum

The ability to modulate gene expression is an important genetic tool in systems biology and biotechnology. Here, we demonstrate that a previously published easy and fast PCR-based method for modulating gene expression in lactic acid bacteria is also applicable to Corynebacterium glutamicum. We constructed constitutive promoter libraries based on various combinations of a previously reported C. glutamicum -10 consensus sequence (gngnTA(c/t)aaTgg) and the Escherichia coli -35 consensus, either with or without an AT-rich region upstream. A promoter library based on consensus sequences frequently found in low-GC Gram-positive microorganisms was also included. The strongest promoters were found in the library with a -35 region and a C. glutamicum -10 consensus, and this library also represents the largest activity span. Using the alternative -10 consensus TATAAT, which can be found in many other prokaryotes, resulted in a weaker but still useful promoter library. The upstream AT-rich region did not appear to affect promoter strength in C. glutamicum. In addition to the constitutive promoters, a synthetic inducible promoter library, based on the E. coli lac-promoter, was constructed by randomizing the 17-bp spacer between -35 and -10 consensus sequences and the sequences surrounding these. The inducible promoter library was shown to result in β-galactosidase activities ranging from 284 to 1,665 Miller units when induced by IPTG, and the induction fold ranged from 7–59. We find that the synthetic promoter library (SPL) technology is convenient for modulating gene expression in C. glutamicum and should have many future applications, within basic research as well as for optimizing industrial production organisms.     

Cloning and promoter analysis of the cotton lipid transfer protein gene Ltp3

A cotton Ltp3 gene and its 5′ and 3′ flanking regions have been cloned with a PCR-based genomic DNA walking method. The amplified 2.6 kb DNA fragment contains sequences corresponding to GH3 cDNA which has been shown to encode a lipid transfer protein (LTP3). The gene has an intron of 80 bp which is located in the region corresponding to the C-terminus of LTP3. The Ltp3 promoter was systematically analyzed in transgenic tobacco plants by employing the Escherichia coli β-glucuronidase gene (GUS) as a reporter. The results of histochemical and fluorogenic GUS assays indicate that the 5′ flanking region of the Ltp3 gene contains cis-elements conferring the trichome specific activity of Ltp3 promoter.     

Expression plasmid vectors containing Escherichia coli tryptophan promoter transcriptional units lacking the attenuator

Two DNA fragments which contain the Escherichia coli tryptophan promoter-operator region but lack the attenuator have been used in the construction of a series of pAT153 based plasmids suitable for the regulated expression of foreign genes in E. coli. The first, a 139-bp HhaI fragment includes 59 bp of the trp leader sequence, ending within the “attenuator peptide” coding sequence, eleven codons from the N-terminus. A fusion-type expression plasmid incorporating this fragment has been constructed. The second, a 99-bp HaeIII-TaqI fragment contains no coding sequence but includes the “attenuator peptide” SD site situated 4 bp upstream of the TaqI site. This fragment has been incorporated in expression vectors which result in the direct expression of cloned gene sequences. To further maximise expression, plasmids with directly repeating trp promoter HaeIII-TaqI units have been constructed.     

Effects of alterations in the translation control region on bacterial gene expression: use of cat gene constructs transcribed from the lac promoter as a model system

The region controlling translation of the cat gene, which codes for chloramphenicol acetyltransferase, has been varied structurally in a series of plasmids that place the gene under control of the lac promoter. These plasmid constructs have enabled study of the structural features that affect the efficiency of mRNA translation. Altering the potential for secondary structure formation within the translation control region caused a tenfold variation in the synthesis of CAT enzyme, whereas varying the distance between the Shine-Dalgarno sequence (SD) and the translation start codon from 7 to 13 bases did not significantly affect the yield of CAT. If the SD was situated in a region of mRNA that is capable of base pairing, the efficiency of translation was decreased; however, the translation start codon, AUG, can initiate translation efficiently even when located in a segment capable of duplex formation. Overlapping of the cat translation control region by translation initiated upstream markedly affected initiation of translation within the cat gene: out-of-frame overlapping translation reduced CAT production by 90%; in-frame overlapping translation prevented detectable initiation of protein synthesis at the cat gene translation start codon, and yielded only fusion proteins. The enzymatic activity of such proteins was influenced by the length of the adventitious peptide segment added to the amino-terminus of the CAT polypeptide.     

Functional characterization of the promoter region of human TNFAIP1 gene

Tumor necrosis factor, alpha-induced protein 1 (TNFAIP1) is an immediate-early response gene of endothelium induced by TNF alpha. However, little is really known concerning the TNFAIP1 expression regulation. To better understand how TNFAIP1 expression is regulated, we functionally characterized the promoter region of human TNFAIP1 gene. Deletion mutation analysis, gel electrophoretic mobility shift, and site-directed mutagenesis assays allowed the identification of one functional Sp1-binding site within the human TNFAIP1 core promoter region. Moreover, chromatin immunoprecipitation analysis indicated that Sp1 was associated in vivo with the TNFAIP1 promoter. Further, Sp1 overexpression enhanced TNFAIP1 promoter activity. These findings suggest that Sp1 is implicated in the control of basal TNFAIP1 gene expression. Accordingly, Sp1 is supposed to be involved in the elevation of TNFAIP1 in response to TNF alpha induction, and thus participate in inflammation-associated angiogenesis.     

Functional analysis of the Lactococcus lactis usp45 secretion signal in the secretion of a homologous proteinase and a heterologous α-amylase

The ups45 gene encodes the major extracellular protein from Lactococcus lactis. The deduced sequence of the 27 residue leader peptide revealed the tripartite characteristics of a signal peptide. This leader peptide directed the efficient secretion of the homologous proteinase (PrtP) in L. lactis, indicating that the putative signal peptide of PrtP can be replaced by the 27 residue Usp45 leader peptide. In addition, the 27 residue leader peptide could be used to secrete the Bacillus stearothermophilus α-amylase, encoded by the amyS gene. Fusion of the usp45 promoter region and various parts of the leader sequence to an amyS gene devoid of its signal sequence, showed that in Escherichia coli the first 19, 20, and 27 residues of the Usp45 leader are able to direct α-amylase secretion. In L. lactis the shorter signal peptides did not result in secretion of α-amylase, providing experimental evidence for the hypothesis that gram-positive bacteria require a longer signal peptide for secretion than gram-negative organisms.     

DNA sequence of the promoter region of the ompC gene and the amino acid sequence of the signal peptide of pro-OmpC protein in Escherichia coli

The osmoregulated ompC gene of Escherichia coli was cloned and the DNA sequence of a fragment encompassing the promoter region and a portion of the coding region was determined. There were no obvious homologies in the DNA sequence of the promoter regions of the ompC and ompF genes, in contrast to those of the coding regions of the two genes, both of which code for the matrix porins (major outer membrane proteins) and form passive diffusion pores. The amino acid sequence of the signal peptide of pro-OmpC protein was also deduced from the DNA sequence