Chaperone-mediated native folding of a β-scorpion toxin in the periplasm of Escherichia coli

Background

Animal neurotoxin peptides are valuable probes for investigating ion channel structure/function relationships and represent lead compounds for novel therapeutics and insecticides. However, misfolding and aggregation are common outcomes when toxins containing multiple disulfides are expressed in bacteria.

Methods

The β-scorpion peptide toxin Bj-xtrIT from Hottentotta judaica and four chaperone enzymes (DsbA, DsbC, SurA and FkpA) were co-secreted into the oxidizing environment of the Escherichia coli periplasm. Expressed Bj-xtrIT was purified and analyzed by HPLC and FPLC chromatography. Its thermostability was assessed using synchrotron radiation circular dichroism spectroscopy and its crystal structure was determined.

Results

Western blot analysis showed that robust expression was only achieved when cells co-expressed the chaperones. The purified samples were homogenous and monodisperse and the protein was thermostable. The crystal structure of the recombinant toxin confirmed that it adopts the native disulfide connectivity and fold.

Conclusions

The chaperones enabled correct folding of the four-disulfide-bridged Bj-xtrIT toxin. There was no apparent sub-population of misfolded Bj-xtrIT, which attests to the effectiveness of this expression method.

General significance

We report the first example of a disulfide-linked scorpion toxin natively folded during bacterial expression. This method eliminates downstream processing steps such as oxidative refolding or cleavage of a fusion-carrier and therefore enables efficient production of insecticidal Bj-xtrIT. Periplasmic chaperone activity may produce native folding of other extensively disulfide-reticulated proteins including animal neurotoxins. This work is therefore relevant to venomics and studies of a wide range of channels and receptors.     

Identification of N-terminal acetylation of recombinant human prothymosin α in Escherichia coli

Functional modification of protein through N-terminal acetylation is common in eukaryotes but rare in prokaryotes. Prothymosin α is an essential protein in immune stimulation and apoptosis regulation. The protein is N-terminal acetylated in eukaryotes, but similar modification has never been found in recombinant protein produced in prokaryotes. In this study, two mass components of recombinant human prothymosin α expressed in Escherichia coli were identified and separated by RP-HPLC. Mass spectrometry of the two components showed that one of them had a 42 Da mass increment as compared with the theoretical mass of human prothymosin α, which suggested a modification of acetylation. The mass of another one was equal to that of the theoretical one. Peptides mass spectrometry of the modified component showed that the 42-Da mass increment occurred in the N-terminal peptide domain, and MS/MS peptide sequencing of the N-terminal peptide found that the acetylated modification occurred at the N-terminal serine residue. So, part of the recombinant human prothymosin α produced by E. coli was N-terminal acetylated. This finding adds a new clue for the mechanism of acetylated modification in prokaryotes, and also suggested a new method for production of N-terminal modificated prothymosin α and thymosin α1.     

Is the secondary putative RNA–RNA interaction site relevant to GcvB mediated regulation of oppA mRNA in Escherichia coli?

GcvB is a non-coding RNA that regulates oppA mRNA in different bacterial species by binding a GcvB GU-rich region named R1 to oppA mRNA. A secondary putative interaction site (PS1) was identified in this study that is able to form a second nearly perfect 10 base-pair duplex between these two RNAs in Escherichia coli. In this work, we have studied whether the formation of a second interaction site could help stabilize the previously reported GcvB/oppA complex. Several mutations and the full deletion of PS1 were engineered. None of these modifications affected the ability of GcvB to control OppA expression. Therefore the second, putative, interaction site appears to be unnecessary for the regulatory function of GcvB with regard to its oppA target mRNA.     

Immediate stoichiometric appearance of β-galactosidase products in the medium of Escherichia coli cells incubated with lactose

Products of β-galactosidase action on lactose by intact E. coli cells appeared in the medium as soon as lactose was added and the amount of product was equal to the lactose used. No detectable levels of β-galactosidase were found in the medium and lactose was not significantly broken down unless lac permease was present. The appearance did not depend upon the presence of any of the commonly known galactose or glucose permease systems. The Km of product appearance from whole cells was equal to the K_t for lactose transport by lac permease. When the cells were broken the Km became the normal β-galactosidase Km.     

Molecular modeling and functional analysis of the AtoS–AtoC two-component signal transduction system of Escherichia coli

The AtoS–AtoC two-component signal transduction system positively regulates the expression of the atoDAEB operon in Escherichia coli. Upon acetoacetate induction, AtoS sensor kinase autophosphorylates and subsequently phosphorylates, thereby activating, the response regulator AtoC. In a previous work we have shown that AtoC is phosphorylated at both aspartate 55 and histidine73. In this study, based on known three-dimensional structures of other two component regulatory systems, we modeled the 3D-structure of the receiver domain of AtoC in complex with the putative dimerization/autophosphorylation domain of the AtoS sensor kinase. The produced structural model indicated that aspartate 55, but not histidine 73, of AtoC is in close proximity to the conserved, putative phosphate-donor, histidine (H398) of AtoS suggesting that aspartate 55 may be directly involved in the AtoS–AtoC phosphate transfer. Subsequent biochemical studies with purified recombinant proteins showed that AtoC mutants with alterations of aspartate 55, but not histidine 73, were unable to participate in the AtoS–AtoC phosphate transfer in support of the modeling prediction. In addition, these AtoC mutants displayed reduced DNA-dependent ATPase activity, although their ability to bind their target DNA sequences in a sequence-specific manner was found to be unaltered.     

Spermidine triggering effect to the signal transduction through the AtoS–AtoC/Az two-component system in Escherichia coli

Recent analysis revealed that, in Escherichia coli the AtoS–AtoC/Az two-component system (TCS) and its target atoDAEB operon regulate the biosynthesis of short-chain poly-(R)-3-hydroxybutyrate (cPHB) biosynthesis, a biopolymer with many physiological roles, upon acetoacetate-mediated induction. We report here that spermidine further enhanced this effect, in E. coli that overproduces both components of the AtoS–AtoC/Az TCS, without altering their protein levels. However, bacteria that overproduce either AtoS or AtoC did not display this phenotype. The extrachromosomal introduction of AtoS–AtoC/Az in an E. coli ΔatoSC strain restored cPHB biosynthesis to the level of the atoSC⁺ cells, in the presence of the polyamine. Lack of enhanced cPHB production was observed in cells overproducing the TCS that did not have the atoDAEB operon. Spermidine attained the cPHB enhancement through the AtoC/Az response regulator phosphorylation, since atoC phosphorylation site mutants, which overproduce AtoS, accumulated less amounts of cPHB, compared to their wild-type counterparts. Exogenous addition of N⁸-acetyl-spermidine resulted in elevated amounts of cPHB but at lower levels than those attained upon spermidine addition. Furthermore, AtoS–AtoC/Az altered the intracellular distribution of cPHB according to the inducer recognized by the TCS. Overall, AtoS–AtoC/Az TCS was induced by spermidine to regulate both the biosynthesis and the intracellular distribution of cPHB in E. coli.     

Characterization of inosine–uridine nucleoside hydrolase (RihC) from Escherichia coli

A non-specific nucleoside hydrolase from Escherichia coli (RihC) has been cloned, overexpressed, and purified to greater than 95% homogeneity. Size exclusion chromatography and sodium dodecyl sulfate polyacrylamide gel electrophoresis show that the protein exists as a homodimer. The enzyme showed significant activity against the standard ribonucleosides with uridine, xanthosine, and inosine having the greatest activity. The Michaelis constants were relatively constant for uridine, cytidine, inosine, adenosine, xanthosine, and ribothymidine at approximately 480 μM. No activity was exhibited against 2′-OH and 3′-OH deoxynucleosides. Nucleosides in which additional groups have been added to the exocyclic N6 amino group also exhibited no activity. Nucleosides lacking the 5′-OH group or with the 2′-OH group in the arabino configuration exhibited greatly reduced activity. Purine nucleosides and pyrimidine nucleosides in which the N7 or N3 nitrogens respectively were replaced with carbon also had no activity.     

Role of quinones in electron transport to oxygen and nitrate in Escherichia coli. Studies with a ubiA− menA− double quinone mutant

A ubiA^? menA^? double quinone mutant of Escherichia coli K12 was constructed together with other isogenic strains lacking either ubiquinone or menaquinone. These strains were used to study the role of quinones in electron transport to oxygen and nitrate. Each of the four oxidases examined (NADH, d-lactate, α-glycerophosphate and succinate) required a quinone for activity. Ubiquinone was active in each oxidase system while menaquinone gave full activity in α-glycerophosphate oxidase, partial activity in d-lactate oxidase but was inactive in NADH and succinate oxidation. The aerobic growth rates, growth yields and products of glucose metabolism of the quinone-deficient strains were also examined. The growth rate and growth yield of the ubi⁺ menA^? strain was the same as the wild-type strain, whereas the ubiA^? men⁺ strain grew more slowly on glucose, had a lower growth yield (30% of wild type) and accumulated relatively large quantities of acetate and lactate. The growth of the ubiA^? menA^? strain was even more severely affected than that of the ubiA^? men⁺ strain.Electron transport from formate, d-lactate, α-glycerophosphate and NADH to nitrate was also highly dependent on the presence of a quinone. Either ubiquinone or menaquinone was active in electron transport from formate and the activity of the quinones in electron transport from the other substrates was the same as for the oxidase systems. In contrast, quinones were not obligatory carriers in the anaerobic formate hydrogenlyase system. It is concluded that the quinones serve to link the various dehydrogenases with the terminal electron transport systems to oxygen and nitrate and that the dehydrogenases possess a degree of selectivity with respect to the quinone acceptors.     

Enhancement of α-methylglucoside efflux by respiration in respiratory mutants of Escherichia coli K-12

The rate of α-methylglucoside efflux from wild-type cells of Escherichia coli K-12 is enhanced by different substrates, as long as they are readily respired. A similar enhancement takes place in strains with impaired oxidative phosphorylation (unc mutants), regardless of their being able (strains AN120, N₁₄₄, and AN382) or unable (strain NR70) to energize the membrane through respiratory electron flow. The uncouplers carbonylcyanide-m-chlorophenylhydrazone and tetrachlorosalicylanilide do not diminish the efflux acceleration in wild-type strains or unc mutants. However, the stimulation of α-methylglucoside efflux does not occur in the mutant AN59 which cannot perform a normal respiratory electron transport due to a defective synthesis of ubiquinone. The failure to stimulate the efflux is observed with succinate, which is a typical substrate of respiration, as well as with substrates which can yield ATP both at respiratory and substrate levels such as gluconate or glycerol. Moreover, potassium cyanide nullifies the acceleration of α-methylglucoside efflux caused in any type of strain and by any substrate. These results show that neither ATP nor an energized state of the membrane appears to be needed for respiration to accelerate α-methylglucoside release from E. coli cells, and question the existence of any energy-requiring reaction for αMG exit, previously proposed by other authors.     

Mutation and DNA replication in Escherichia coli treated with low concentrations of N-methyl-N′-nitro-N-nitrosoguanidine

N-Methyl-N′-nitro-N-nitrosoguanidine (nitrosoguanidine) causes an unexpectedly high frequency of closely linked double mutants because of its specificity for chromosome regions in replication. Low nitrosoguanidine concentrations (1 μg/ml) in liquid cultures allow replication at the normal rate and are mutagenic. It was expected that mutations would be spread over the chromosome as it replicated, but a high frequency of closely linked double mutants was found.If a thymine auxotroph is grown in the presence of 5-bromodeoxyuridine (BUdR) and nitrosoguanidine, then exposed to 313-nm radiation (which destroys BUdR-substituted DNA), the mutation frequency is much higher among survivors than among non-irradiated cells. It is concluded that nitrosoguanidine inhibits DNA replication in a small fraction of the population and that mutations are induced in that same fraction.Nitrosoguanidine treatment leads to a high frequency of closely linked double mutants under all known conditions.     

Single-step method for β-galactosidase assays in Escherichia coli using a 96-well microplate reader

Historically, the lacZ gene is one of the most universally used reporters of gene expression in molecular biology. Its activity can be quantified using an artificial substrate, o-nitrophenyl-ß-d-galactopyranoside (ONPG). However, the traditional method for measuring LacZ activity (first described by J. H. Miller in 1972) can be challenging for a large number of samples, is prone to variability, and involves hazardous compounds for lysis (e.g., chloroform, toluene).     

Preparation of nitrophorin 7(Δ1–3) from Rhodnius prolixus without start–methionine using recombinant expression in Escherichia coli

The heterologous recombinant expression of proteins in Escherichia coli without start–methionine is a common problem. The nitrophorin 7 heme properties and function strongly depend on the accurate N-terminal amino acid sequence. Leading protein expression into the periplasm by fusion with the leader peptide pelB yields functional protein; however, the folded protein sticks to the cell debris. Therefore, the periplasmic fraction was dissolved in guanidinium chloride and folded by a drop-in method. Separation from impurities including residual pelB–nitrophorin 7 required establishing an unconventional chromatographic technique using calcium-loaded Chelating Sepharose as cation exchanger and elution by a linear CaCl₂ gradient.     

Exploration of structure–function relationships in Escherichia coli cystathionine γ-synthase and cystathionine β-lyase via chimeric constructs and site-specific substitutions

Cystathionine γ-synthase (CGS) and cystathionine β-lyase (CBL) share a common structure and several active-site residues, but catalyze distinct side-chain rearrangements in the two-step transsulfuration pathway that converts cysteine to homocysteine, the precursor of methionine. A series of 12 chimeric variants of Escherichia coli CGS (eCGS) and CBL (eCBL) was constructed to probe the roles of two structurally distinct, ~ 25-residue segments situated in proximity to the amino and carboxy termini and located at the entrance of the active-site. In vivo complementation of methionine-auxotrophic E. coli strains, lacking the genes encoding eCGS and eCBL, demonstrated that exchange of the targeted regions impairs the activity of the resulting enzymes, but does not produce a corresponding interchange of reaction specificity. In keeping with the in vivo results, the catalytic efficiency of the native reactions is reduced by at least 95-fold, and α,β versus α,γ-elimination specificity is not modified. The midpoint of thermal denaturation monitored by circular dichroism, ranges between 59 and 80 °C, compared to 66 °C for the two wild-type enzymes, indicating that the chimeric enzymes adopt a stable folded structure and that the observed reductions in catalytic efficiency are due to reorganization of the active site. Alanine-substitution variants of residues S32 and S33, as well as K42 of eCBL, situated in proximity to and within, respectively, the targeted amino-terminal region were also investigated to explore their role as determinants of reaction specificity via positioning of key active-site residues. The catalytic efficiency of the S32A, S33A and the K42A site-directed variants of eCBL is reduced by less than 10-fold, demonstrating that, while these residues may participate in positioning S339, which tethers the catalytic base, their role is minor.     

Functional symmetry of the β-galactoside carrier in escherichia coli

Cytoplasmic membrane vesicles with either normal or inverted orientation were prepared from Escherichia coli. The lactose transport activity of these vesicle preparations was compared. The parameters measured were net efflux, counterflux, and K⁺/valinomycin-induced active uptake of lactose. With membrane vesicles derived from both wild-type and cytochrome-deficient strains the right-side-out and inverted membrane preparations showed similar rates of lactose flux in all assays. According to these criteria, the activity of the β-galactoside transport protein is inherently symmetrical.One major difference was observed between the native and inverted vesicle preparations: the inverted vesicles had approximately twice the specific activity of native vesicles in the counterflux and K⁺/valinomycin-induced uptake assays. This difference can be largely ascribed to the presence in the normal vesicle preparation of vesicles with a high passive permeability to lactose. Such vesicles are apparently absent from the inverted vesicle preparations.     

Exploration of the six tryptophan residues of Escherichia coli cystathionine β-lyase as probes of enzyme conformational change

Cystathionine β-lyase (CBL) catalyzes the hydrolysis of l-cystathionine (l-Cth), producing l-homocysteine (l-Hcys), pyruvate and ammonia, in the second step of the transsulfuration pathway of bacteria and plants. A series of 17 site-directed variants of Escherichia coli CBL (eCBL) was constructed to probe the contributions of the six tryptophan residues (W131, W188, W230, W276, W300 and W340) to the fluorescence spectrum of eCBL and to assess their mutability and utility as conformational probes. The effects of these Trp → Phe substitutions on k_cat and K_m^l-Cth are less than 2-fold, with the exception of the 8-fold increase in K_m^l-Cth observed for eCBL-W340F. The midpoint of thermal denaturation, as monitored by circular dichroism spectroscopy, is reduced 4.7 °C by the W188F substitution while the targeted replacement of the other five tryptophans alter T_m by less than 1.7 °C. The fluorescence spectrum of eCBL is dominated by W230 and the contribution of W340, situated in the active site, is minor. The observed 5-fold increase in the 336 nm fluorescence emission of W188 between 0 and 2 M urea, suggests a conformational change at the domain interface. Residues W188 and W340, conserved in proteobacterial CBL enzymes, are situated at the core of the domain interface that forms the active-site cleft. The results of this study suggest that W188 is a useful probe of subtle conformational changes at the domain interface and active site.     

Molecular Analysis of the Functional Role of β-Adrenergic Receptor Kinase 1 Amino-Terminal

Abstract

Receptor phosphorylation is a key step in the process of rapid desensitization. β-adrenergic receptor kinase (βARK) is a specific receptor kinase that is known to phosphorylate and induce desensitization of several G-coupled receptors only when they are occupied by their agonists. In the present study we have done several modifications to the amino-terminal of βARK1, in order to clarify its functional role. The recombinant mutants were tested for their ability to phosphorylate rhodopsin present in purified bovine ROS membranes which serves as a substrate for βARK1. Their expression levels were detected by Western blot analysis. We found that when the amino-terminal of βARK1 is modified its expression level is very low, hence it is not able to phosphorylate over the basal. These findings suggest that this region is crucial for the normal processing of the protein.