A novel bicistronic vector for overexpressing Mycobacterium tuberculosis proteins in Escherichia coli

A putative DNA glycosylase encoded by the Rv3297 gene (MtuNei2) has been identified in Mycobacterium tuberculosis. Our efforts to express this gene in Escherichia coli either by supplementing tRNAs for rare codons or optimizing the gene with preferred codons for E. coli resulted in little or no expression. On the other hand, high-level expression was observed using a bicistronic expression vector in which the target gene was translationally coupled to an upstream leader sequence. Further comparison of the predicted mRNA secondary structures supported the hypothesis that mRNA secondary structure(s) surrounding the translation initiation region (TIR), rather than codon usage, played the dominant role in influencing translation efficiency, although manipulation of codon usage or tRNA supplementation did further enhance expression in the bicistronic vector. Addition of a cleavable N-terminal tag also facilitated gene expression in E. coli, possibly through a similar mechanism. However, since cleavage of N-terminal tags is determined by the amino acid at the P₁′ position downstream of the protease recognition sequence and results in the addition of an extra amino acid in front of the N-terminus of the protein, this strategy is not particularly amenable to Fpg/Nei family DNA glycosylases which carry the catalytic proline residue at the P₁′ position and require a free N-terminus. On the other hand, the bicistronic vector constructed here is potentially valuable particularly when expressing proteins from G/C rich organisms and when the proteins carry proline residues at the N-terminus in their native form. Thus the bicistronic expression system can be used to improve translation efficiency of mRNAs and achieve high-level expression of mycobacterial genes in E. coli.     

Study of the Escherichia coli tRNA nucleotidyltransferase. Specificity of the enzyme for nucleoside triphosphates

Besides the main reactions leading to the repair of tRNA molecules deprived of part or all of their 3′ terminal -pCpCpA sequence, purified E. coli tRNA nucleotidyltransferase catalyzes in vitro, under certain conditions the synthesis of sequences not found in natural tRNAs. In the absence of CTP, AMP is incorporated directly into tRNA-pX or tRNA-pXpC leading to tRNA-pXpA or tRNA-pXpCpA respectively. In the absence of ATP one extra CMP is added to tRNA-pXpCpC to form tRNA-pXpCpCpC. UMP can be incorporated instead of CMP and the sequence -pXpU and -pXpCpU formed. The incorporation of UMP cannot be followed by the incorporation of either a second UMP or an AMP. In all cases, the rate of misincorporation is lower than the rate of the synthesis of the normal sequence.The apparent K_M of the enzyme for UTP is 3.0 10⁻⁴ M. CTP inhibits competitively the incorporation of UMP into tRNA-pX with a K_i value (1.6 10⁻⁵ M) close to its apparent K_M.     

ATP increases chemoattractant induced cyclic GMP accumulation in Dictyostelium discoideum

Changes in guanosine cyclic 3′,5′-monophosphate associated with adenosine cyclic 3′,5′-monophosphate and folic acid addition in the presence of ATP have been examined in Dictyostelium discoideum. Preincubation with 1 mM ATP had no effect on the basal cyclic GMP level but increased the cycli GMP accumulation in response to cylci AMP (5·10⁻⁸ M) or folic acid (5·10⁻⁶ M) 40–50%. ATP could not be replaced by ADP of 5′-adenylyliminodiphosphate. Because ATP has no effect on cyclic AMP receptor binding these results indicate that structural membrane alterations (e.g. membrane phosphorylation) may control the transduction of a chemotactic signal.     

Cyclic 3′,5′-AMP phosphodiesterase in Physarum polycephalum: II. Kinetic properties

The effect of several inhibitors of the enzyme cyclic 3′,5′-AMP phosphodiesterase as chemoattractants in Physarum polycephalum was examined. Of the compounds tested, 4-(3-butoxy-4-methoxybenzyl)-2-imidazolidinone (Roche 20-1724/001) and 1-ethyl-4-(isopropylidinehydrazino)-1H-pyrazolo-(3,4-b)-pyridine-5-carboxylic acid ethyl ester, hydrochloride (Squibb 20009) were the most potent attractants. 3-Isobutyl-1-methyl xanthine, theophylline, and morin (a flavanoid) were moderate attractants and sometimes gave negative chemotaxis at high concentrations. Cyclic 3′,5′-AMP was an effective, but not potent attractant. A repellent effect following the positive chemotactic action was sometimes observed with cyclic 3′,5′-AMP at concentrations as high as 1 · 10⁻² M. Dibutyryl cyclic AMP appeared to be a somewhat more potent attractant than cyclic 3′,5′-AMP. The 8-thiomethyl and 8-bromoderivatives of cyclic AMP, which are poorly hydrolyzed by the phosphodiesterase, were not attractants in Physarum. Possible participation of cyclic 3′,5′-AMP in the directional movement in P. polycephalum is discussed.     

Single-chain ribosome inactivating proteins from plants depurinate Escherichia coli 23S ribosomal RNA

The rRNA N-glycosidase activities of the catalytically active A chains of the heterodimeric ribosome inactivating proteins (RIPs) ricin and abrin, the single-chain RIPs dianthin 30, dianthin 32, and the leaf and seed forms of pokeweed antiviral protein (PAP) were assayed on E. coli ribosomes. All of the single-chain RIPs were active on E. coli ribosomes as judged by the release of a 243 nucleotide fragment from the 3′ end of 23S rRNA following aniline treatment of the RNA. In contrast, E. coli ribosomes were refractory to the A chains of ricin and abrin. The position of the modification of 23S rRNA by dianthin 32 was determined by primer extension and found to be A₂₆₆₀, which lies in a sequence that is highly conserved in all species.     

Using native hydantoinase promoter to induce d-carbamoylase soluble expression in Escherichia coli

By use of PCR, the genes encoding d-carbamoylase from A. radiobacter TH572 were cloned in plasmid pET30a and transformed into Escherichia coli BL21 (DE3) to overexpress d-carbamoylase. However, almost all of the protein remained trapped in inclusion bodies. To improve the expression of the properly folded active enzyme, a constitutive plasmid of pGEMT-DCB was constructed using the native hydantoinase promoter (P_Hase) whose optimal length was confirmed to 209 bp. Furthermore, the RBS region in the downstream of P_Hase was optimized to increase the expression level, so the plasmid pGEMT-R-DCB was constructed and transformed into E. coli strain Top10F′. The enzyme activity of Top10F′/pGEMT-R-DCB grown at 37 °C was found to be 0.603 U/mg (dry cell weight, DCW) and increase 58-fold over cells of BL21 (DE3) harboring the plasmid pET-DCB grown at 28 °C.     

Construction of a Shuttle Vector for Use between Pasteurella multocida and Escherichia coli

The isolation of a small plasmid from Pasteurella multocida has enabled to construction of a shuttle vector for use between P. multocida and Escherichia coli. The vector pBAC64 contains the origin of replication from P. multocida, an antibiotic resistance gene which functions in P. multocida, and the E. coli vector pUC18. The presence of the pUC18 multiple cloning site together with the lacZ′ gene provides a screening method and allows cloning and manipulation in E. coli as well as cloning in P. multocida.     

Production of mevalonate by a metabolically-engineered Escherichia coli

Mevalonate is biosynthesized from acetyl-CoA and metabolized to isoprenoid compounds in a wide variety of organisms although certain types of prokaryotes employ another route for isoprenoid biosynthesis (the non-mevalonate pathway). To establish a fermentative process for mevalonate production, enzymes for mevalonate synthesis from Enterococcus faecalis were expressed in Escherichia coli, a non-mevalonate pathway bacterium. Mevalonate was accumulated, indicating a redirection of acetate metabolism by the expressed enzyme. The recombinant E. coli produced 47 g mevalonate l^–1 in 50 h of fed-batch cultivation in a 2 l jar fermenter; this is the highest titer ever reported demonstrating the superiority of E. coli in its ability of acetyl-CoA supply and its inability is degrade mevalonate.     

Isolation of Escherichia coli mRNA and Comparison of Expression Using mRNA and Total RNA on DNA Microarrays

Bacterial messenger RNA (mRNA) is not coherently polyadenylated, whereas mRNA of Eukarya can be separated from stable RNAs by virtue of polyadenylated 3′-termini. We have developed a method to isolate Escherichia coli mRNA by polyadenylating it in crude cell extracts with E. coli poly(A) polymerase I and purifying it by oligo(dT) chromatography. Differences in lacZRNA levels were similar with purified mRNA and total RNA in dot blot hydridizations for cultures grown with or without gratuitous induction of the lactose operon. More broadly, changes in gene expression upon induction were similar when cDNAs primed from mRNA or total RNA with random hexanucleotides were hydridized to DNA microarrays for the E. coli genome. Comparable signal intensities were obtained with only 1% as much oligo(dT)-purified mRNA as total RNA, and hence in vitro poly(A) tailing appears to be selective for mRNA. These and additional studies of genome-wide expression with DNA microarrays provide evidence that in vitro poly(A) tailing works universally for E. coli mRNAs.     

Immunochemical determination of the cellular content of polypeptide chain release factor RF3 in Escherichia coli

Polypeptide chain termination in Escherchia coli is known to require two codon specific release factors. RF1 and RF2. A third factor, RF3, has been described to stimulate the termination. Earlier investigations have estimated the cellular content of factors RF1 and RF2. Two different immunological techniques for measuring the amount of RF3 per cell in crude E coli cell extracts are reported here, using a sensitive immunoblotting method and a sandwich assay by ELISA. Monoclonal murine antibodies and polyclonal rabbit antibodies were raised against extensively purified recombinant E coli RF3. The immunoblotting involves a specific monoclonal antibody (mAb), biotinylated second antibody and finally radioactive iodinated streptavidin. In the sandwich assay polyclonal antibodies are immobilised on a polystyrene surface before addition of crude cell extract: a specific mAb serves as primary antibody and an HRP-labelled anti-mouse Ig as secondary antibody. Both methods are accurate and rapid to perform. The number of RF3 molecules per cell in exponentially growing E coli cells was found to vary considerably according to the K12 strain examined and depended on the culture medium (from 20 to 500 molecules per cell), faster growth being positively correlated with the number of RF3 molecules per cell.     

The chemotactic effect of 5′-amido analogues of adenosine cyclic 3′,5′-monophosphate in the cellular slime moulds

Previously it was shown that amoebae of some Dictyostelium species are attracted by adenosine cyclic 3′,5′-monophosphate (cyclic AMP), and to a lesser extent, by the analogues of this nucleotide.We measured the chemotactic activity of several 5′-amido analogues of cyclic AMP by using a small population assay.Our investigations have shown unequivocally that the molecular receptor systems of cyclic AMP of the amoebae are highly sensitive to stereochemical alternation at the 5′position of the cyclophosphate ring, while the replacement of oxygen by nitrogen seems to exert no major influence. Alteration of the stereochemical envelope of the ring by a protruding group decisively alters the biological activity of the molecule, an effect which clearly does not depend on the type ot the group which protrudes.     

Expression in Escherichia coli and Simple Purification of Human Fhit Protein

The fragile histidine triad (Fhit) protein is a homodimeric protein with diadenosine 5′,5-P¹,P³-triphosphate (Ap₃A) asymmetrical hydrolase activity. We have cloned the human cDNA Fhit in the pPROEX-1 vector and expressed with high yield in Escherichia coli with the sequence Met-Gly-His₆-Asp-Tyr-Asp-Ile-Pro-Thr-Thr followed by a rTEV protease cleavage site, denoted as “H6TV,” fused to the N-terminus of Fhit. Expression of H6TV–Fhit in BL21(DE3) cells for 3 h at 37°C produced 30 mg of H6TV–Fhit from 1 L of cell culture (4 g of cells). The H6TV–Fhit protein was purified to homogeneity in a single step, with a yield of 80%, using nickel-nitrilotriacetate resin and imidazole buffer as eluting agent. Incubation of H6TV–Fhit with rTEV protease at 4°C for 24 h resulted in complete cleavage of the H6TV peptide. There were no unspecific cleavage products. The purified Fhit protein could be stored for 3 weeks at 4°C without loss of activity. The pure protein was stable at −20°C for at least 18 months when stored in buffer containing 25% glycerol. Purified Fhit was highly active, with a K_m value for Ap₃A of 0.9 μM and a k_cat(monomer) value of 7.2 ± 1.6 s⁻¹ (n = 5). The catalytic properties of unconjugated Fhit protein and the H6TV–Fhit fusion protein were essentially identical. This indicates that the 24-amino-acid peptide containing the six histidines fused to the N-terminus of Fhit does not interfere in forming the active homodimers or in the binding of Ap₃A.     

The commonly-used DNA probe for diffusely-adherent Escherichia coli cross-reacts with a subset of enteroaggregative E. coli

Background  

The roles of diffusely-adherent Escherichia coli (DAEC) and enteroaggregative E. coli (EAEC) in disease are not well understood, in part because of the limitations of diagnostic tests for each of these categories of diarrhoea-causing E. coli. A HEp-2 adherence assay is the Gold Standard for detecting both EAEC and DAEC but DNA probes with limited sensitivity are also employed.     

Expression, in Escherichia coli, of a soluble human Tumor Necrosis Factor receptor

We have expressed in Escherichia coli a soluble, truncated form of the human 55 kDa Tumor Necrosis Factor (TNF) receptor. For this purpose a plasmid was constructed which contains the extracellular domain of the 55 kDa TNF receptor fused to the coding sequence of the IgG binding domains of protein A from Staphylococcus aureus. The fusion product (TNFR-PA) obtained in E. coli is a soluble protein which bound human TNFα (huTNFα) with high affinity. In ligand-blotting experiments huTNFα bound to a single 52 kDa protein, a molecular mass corresponding to that expected for the monomeric fusion product. In gel filtration experiments binding activity was recovered from fractions that eluted at a volume corresponding to 140–150 kDa. TNFR-PA neutralized huTNFα in an in vitro cytotoxicity assay.     

Acetylphosphinate is the most potent mechanism-based substrate-like inhibitor of both the human and Escherichia coli pyruvate dehydrogenase components of the pyruvate dehydrogenase complex

Two analogues of pyruvate, acetylphosphinate and acetylmethylphosphinate were tested as inhibitors of the E1 (pyruvate dehydrogenase) component of the human and Escherichia coli pyruvate dehydrogenase complexes. This is the first instance of such studies on the human enzyme. The acetylphosphinate is a stronger inhibitor of both enzymes (K_i < 1 μM) than acetylmethylphosphinate. Both inhibitors are found to be reversible tight-binding inhibitors. With both inhibitors and with both enzymes, the inhibition apparently takes place by formation of a C2α-phosphinolactylthiamin diphosphate derivative, a covalent adduct of the inhibitor and the coenzyme, mimicking the behavior of substrate and forming a stable analogue of the C2α-lactylthiamin diphosphate. Formation of the intermediate analogue in each case is confirmed by the appearance of a positive circular dichroism band in the 305–306 nm range, attributed to the 1′,4′-iminopyrimidine tautomeric form of the coenzyme. It is further shown that the αHis63 residue of the human E1 has a role in the formation of C2α-lactylthiamin diphosphate since the αHis63Ala variant is only modestly inhibited by either inhibitor, nor did either compound generate the circular dichroism bands assigned to different tautomeric forms of the 4′-aminopyrimidine ring of the coenzyme seen with the wild-type enzyme. Interestingly, opposite enantiomers of the carboligase side product acetoin are produced by the human and bacterial enzymes.     

Enzymes related to catecholamine biosynthesis in Tetrahymena pyriformis. Presence of GTP cyclohydrolase I.

We first identified GTP cyclohydrolase I activity (EC 3.5.4.16) in the ciliated protozoa, Tetrahymena pyriformis. The V_max value of the enzyme in the cellular extract of T. pyriformis was 255 pmol mg⁻¹ protein h⁻¹. Michaelis–Menten kinetics indicated a positive cooperative binding of GTP to the enzyme. The GTP concentration producing half-maximal velocity was 0.8 mM. By high-performance liquid chromatography (HPLC) with fluorescence detection, a major peak corresponding to -monapterin (2-amino-4-hydroxy-6-[(1′R,2′R)-1′,2′,3′-trihydroxypropyl]pteridine, -threo-neopterin) and minor peaks of -erythro-neopterin and -erythro-biopterin were found to be present in the cellular extract of Tetrahymena. Thus, it is strongly suggested that Tetrahymena converts GTP into unconjugated pteridine derivatives. In this study, dopamine was detected as the major catecholamine, while neither epinephrine nor norepinephrine was identified. Indeed, this protozoa was shown to possess the activity of a dopamine synthesizing enzyme, aromatic -amino acid decarboxylase. On the other hand, activities of tyrosine hydroxylase or tyrosinase which converts tyrosine into dopa, the substrate of aromatic -amino acid decarboxylase, could not be detected in this protozoa. Furthermore, neither dopamine β-hydroxylase activity nor phenylethanolamine N-methyltransferase activity could be identified by the HPLC methods.     

An adenosine 3′,5′-monophosphate-requiring mutant of the luminous bacteria Beneckea harveyi

We have isolated a mutant of the luminous bacterium Beneckea harveyi, which requires exogenous adenosine 3′,5′-monphosphate (cyclic AMP) to snnthesize luciferase and emit light. The mutant was pleiotropic, lacking not only the ability to luminesce, but also the capacities to form flagella and the ability to utilize a variety of carbohydrates for growth. All these deficiencies could be corrected by added cyclic AMP. The cyclic AMP-induced de novo synthesis of luciferase was possible only ffter autoinduction had occurred. The induction time by cyclic AMP ranged between 6 and 10 min at 27°C.     

Importance of non-conserved distal carboxyl terminal amino acids in two peptidases belonging to the M1 family: Thermoplasma acidophilum Tricorn interacting factor F2 and Escherichia coli Peptidase N

Enzymes belonging to the M1 family play important cellular roles and the key amino acids (aa) in the catalytic domain are conserved. However, C-terminal domain aa are highly variable and demonstrate distinct differences in organization. To address a functional role for the C-terminal domain, progressive deletions were generated in Tricorn interacting factor F2 from Thermoplasma acidophilum (F2) and Peptidase N from Escherichia coli (PepN). Catalytic activity was partially reduced in PepN lacking 4 C-terminal residues (PepNΔC4) whereas it was greatly reduced in F2 lacking 10 C-terminal residues (F2ΔC10) or PepN lacking eleven C-terminal residues (PepNΔC11). Notably, expression of PepNΔC4, but not PepNΔC11, in E. coliΔpepN increased its ability to resist nutritional and high temperature stress, demonstrating physiological significance. Purified C-terminal deleted proteins demonstrated greater sensitivity to trypsin and bound stronger to 8-amino 1-napthalene sulphonic acid (ANS), revealing greater numbers of surface exposed hydrophobic aa. Also, F2 or PepN containing large aa deletions in the C-termini, but not smaller deletions, were present in high amounts in the insoluble fraction of cell extracts probably due to reduced protein solubility. Modeling studies, using the crystal structure of E. coli PepN, demonstrated increase in hydrophobic surface area and change in accessibility of several aa from buried to exposed upon deletion of C-terminal aa. Together, these studies revealed that non-conserved distal C-terminal aa repress the surface exposure of apolar aa, enhance protein solubility, and catalytic activity in two soluble and distinct members of the M1 family.