pAM401-based shuttle vectors that enable overexpression of promoterless genes and one-step purification of tag fusion proteins directly from Enterococcus faecalis

Two novel Enterococcus faecalis-Escherichia coli shuttle vectors that utilize the promoter and ribosome binding site of bacA on the E. faecalis plasmid pPD1 were constructed. The vectors were named pMGS100 and pMGS101. pMGS100 was designed to overexpress cloned genes in E. coli and E. faecalis and encodes the bacA promoter followed by a cloning site and stop codon. pMGS101 was designed for the overexpression and purification of a cloned protein fused to a Strep-tag consisting of 9 amino acids at the carboxyl terminus. The Strep-tag provides the cloned protein with an affinity to immobilized streptavidin that facilitates protein purification. We cloned a promoterless beta-galactosidase gene from E. coli and cloned the traA gene of the E. faecalis plasmid pAD1 into the vectors to test gene expression and protein purification, respectively. beta-Galactosidase was expressed in E. coli and E. faecalis at levels of 10(3) and 10 Miller units, respectively. By cloning the pAD1 traA into pMGS101, the protein could be purified directly from a crude lysate of E. faecalis or E. coli with an immobilized streptavidin matrix by one-step affinity chromatography. The ability of TraA to bind DNA was demonstrated by the DNA-associated protein tag affinity chromatography method using lysates prepared from both E. coli and E. faecalis that overexpress TraA. The results demonstrated the usefulness of the vectors for the overexpression and cis/trans analysis of regulatory genes, purification and copurification of proteins from E. faecalis, DNA binding analysis, determination of translation initiation site, and other applications that require proteins purified from E. faecalis.     

Modular Broad-Host-Range Expression Vectors for Single-Protein and Protein Complex Purification

A set of modular broad-host-range expression vectors with various affinity tags (six-His-tag, FLAG-tag, Strep-tag II, T7-tag) was created. The complete nucleotide sequences of the vectors are known, and these small vectors can be mobilized by conjugation. They are useful in the purification of proteins and protein complexes from gram-negative bacterial species. The plasmids were easily customized for Thiocapsa roseopersicina, Rhodobacter capsulatus, and Methylococcus capsulatus by inserting an appropriate promoter. These examples demonstrate the versatility and flexibility of the vectors. The constructs harbor the T7 promoter for easy overproduction of the desired protein in an appropriate Escherichia coli host. The vectors were useful in purifying different proteins from T. roseopersicina. The FLAG-tag-Strep-tag II combination was utilized for isolation of the HynL-HypC₂ protein complex involved in hydrogenase maturation. These tools should be useful for protein purification and for studying protein-protein interactions in a range of bacterial species.     

Construction and application of new Corynebacterium glutamicum vectors

The construction of new Corynebacterium glutamicum/Escherichia coli shuttle vectors with improved cloning properties and an increased chloramphenicol resistance (50 g ml^–1 MIC) is described. A modified glnB gene encoding a Strep-tag II domain modified P_II protein was expressed in C. glutamicum and streptavidin affinity chromatography was used to purify this protein.     

Genetic Analysis of Plasmid-specific Pheromone Signaling Encoded by pPD1 in Enterococcus faecalis

Certain plasmids in Enterococcus faecalis encode a mating response to recipient-produced peptide sex pheromones. Targeted disruption of tra genes on pPD1 suggested that TraA plays a central role in the plasmid-specific pheromone signaling pathway. TraA functioned as a negative regulator for the pheromone-inducible conjugal transfer. Complementation analysis of pPD1 tra gene mutants by pAD1 suggested that the pheromone binding function of TraC was non-specific between these plasmids, but the function of TraA and the pheromone shutdown function of TraB are plasmid-specific.     

Cloning, E. coli overexpression, purification and binding properties of TraA and TraC, two proteins involved in the pheromone-dependent conjugation process in enterococci

The bacteriocin encoding plasmid pPD1 from Enterococcus faecalis is involved in a mating response to the sex pheromone cPD1 produced by recipient bacterial cells devoid of pPD1. Previous studies showed that cPD1 is internalized into donor cells in a process in which TraC plays the role of cell surface pheromone receptor. Inside the recipient cells, the pheromone binds to the plasmid-encoded cytoplasmic protein TraA, able to recognize specific DNA sequences and to modulate the conjugation process. To avoid self-induction of the conjugation process, donor cells produce the inhibitor iPD1, which competes with cPD1. This study was designed to produce recombinant TraA and TraC in a functionally active state and to evaluate their main functional properties. We have isolated the sequences encoding TraA and TraC from the plasmid pPD1 and cloned them in suitable expression vectors. The two recombinant proteins were successfully obtained in a soluble form using Escherichia coli as expression host and a T7 inducible expression system. TraC and TraA were purified to homogeneity by three or two chromatographic steps, respectively, leading to a final yield up to 4 mg/l of cell culture for TraC and up to 10 mg/l of cell culture for TraA. The ability of TraA and TraC to bind the specific pheromone and inhibitor peptides has been assessed by means of ESI-mass spectrometry. Moreover, the ability of recombinant TraA to bind DNA has been demonstrated by means of electrophoretic mobility shift assay. Overall these results are consistent with the heterologously expressed TraC and TraA being functionally active.     

Applications of a peptide ligand for streptavidin: the Strep-tag

The Strep-tag constitutes a nine amino acid-peptide that binds specifically to streptavidin and occupies the same pocket where biotin is normally complexed. Since the Strep-tag participates in a reversible interaction it can be applied for the efficient purification of corresponding fusion proteins on affinity columns with immobilized streptavidin. Elution of the bound recombinant protein can be effected under mild buffer conditions by competition with biotin or a suitable derivative. In addition, Strep-tag fusion proteins can be easily detected in immunochemical assays, like Western blots or ELISAs, by means of commercially available streptavidin-enzyme conjugates. The Strep-tag/streptavidin system has been systematically optimized over the past years, including the engineering of streptavidin itself. Structural insight into the molecular mimicry between the peptide and biotin was furthermore gained from X-ray crystallographic analysis. As a result the system provides a reliable and versatile tool in recombinant protein chemistry. Exemplary applications of the Strep-tag are discussed in this review.     

Molecular Recognition by a Polymorphic Cell Surface Receptor Governs Cooperative Behaviors in Bacteria

Cell-cell recognition is a fundamental process that allows cells to coordinate multicellular behaviors. Some microbes, such as myxobacteria, build multicellular fruiting bodies from free-living cells. However, how bacterial cells recognize each other by contact is poorly understood. Here we show that myxobacteria engage in recognition through interactions between TraA cell surface receptors, which leads to the fusion and exchange of outer membrane (OM) components. OM exchange is shown to be selective among 17 environmental isolates, as exchange partners parsed into five major recognition groups. TraA is the determinant of molecular specificity because: (i) exchange partners correlated with sequence conservation within its polymorphic PA14-like domain and (ii) traA allele replacements predictably changed partner specificity. Swapping traA alleles also reprogrammed social interactions among strains, including the regulation of motility and conferred immunity from inter-strain killing. We suggest that TraA helps guide the transition of single cells into a coherent bacterial community, by a proposed mechanism that is analogous to mitochondrial fusion and fission cycling that mixes contents to establish a homogenous population. In evolutionary terms, traA functions as a rare greenbeard gene that recognizes others that bear the same allele to confer beneficial treatment.     

A Pair of Ligation-Independent Escherichia coli Expression Vectors for Rapid Addition of a Polyhistidine Affinity Tag to the N- or C-Termini of Recombinant Proteins

6×His tag is one of the most widely used affinity fusion tags that facilitates detection and purification of recombinant proteins. However, the location of this tag within a particular type of protein may influence the expression, solubility, and bioactivity of the protein, and the optimal location needs to be determined experimentally. To provide a tool for rapid generation of 6× His tags at the N- or C-terminus of any recombinant protein, we have constructed a pair of Escherichia coli expression vectors—pLIC-NHis and pLIC-CHis—based on the pET30a vector, for ligation-independent cloning (LIC). Construction of this new pair of LIC vectors was accomplished by replacement of the multiple cloning site of pET30a with two specifically designed LIC cloning sites. A target gene derived by PCR with a pair of predesigned primers can be inserted into the LIC site of pLIC-NHis for expression of recombinant proteins fused with the N-terminal sequence MHHHHHHG or into that of pLIC-CHis for expression of recombinant proteins with the C-terminal sequence THHHHHH. Successful expression of two normal mammalian prion proteins and five bacterial proteins in E. coli using this pair of LIC vectors reveals that these vectors are valuable tools for the production of recombinant His-tagged proteins in E. coli.     

The Strep-tag system for one-step purification and high-affinity detection or capturing of proteins

The Strep-tag II is an eight-residue minimal peptide sequence (Trp-Ser-His-Pro-Gln-Phe-Glu-Lys) that exhibits intrinsic affinity toward streptavidin and can be fused to recombinant proteins in various fashions. We describe a protocol that enables quick and mild purification of corresponding Strep-tag II fusion proteins--including their complexes with interacting partners--both from bacterial and eukaryotic cell lysates using affinity chromatography on a matrix carrying an engineered streptavidin (Strep-Tactin), which can be accomplished within 1 h. A high-affinity monoclonal antibody (StrepMAB-Immo) permits stable immobilization of Strep-tag II fusion proteins to solid surfaces, for example, for surface plasmon resonance analysis. Selective and sensitive detection on western blots is achieved with Strep-Tactin/enzyme conjugates or another monoclonal antibody (StrepMAB-Classic). Thus, the Strep-tag II, which is short, biologically inert, proteolytically stable and does not interfere with membrane translocation or protein folding, offers a versatile tool both for the rapid isolation of a functional gene product and for its detection or molecular interaction analysis.     

Cloning and genetic analyses of the bacteriocin 41 determinant encoded on the Enterococcus faecalis pheromone-responsive conjugative plasmid pYI14: a novel bacteriocin complemented by two extracellular components (lysin and activator)

The conjugative plasmid pYI14 (61 kbp) was isolated from Enterococcus faecalis YI714, a clinical isolate. pYI14 conferred a pheromone response on its host and encoded bacteriocin 41 (bac41). Bacteriocin 41 (Bac41) only showed activity against E. faecalis. Physical mapping of pYI14 showed that it consisted of EcoRI fragments A to P. The clone pHT1100, containing EcoRI fragments A (12.6 kbp) and H (3.5 kbp), conferred the bacteriocin activity on E. faecalis strains. Genetic analysis showed that the determinant was located in a 6.6-kbp region within the EcoRI AH fragments. Six open reading frames (ORFs) were identified in this region and designated ORF7 (bacL₁) ORF8 (bacL₂), ORF9, ORF10, ORF11 (bacA), and ORF12 (bacI). They were aligned in this order and oriented in the same direction. ORFs bacL₁, bacL₂, bacA, and bacI were essential for expression of the bacteriocin in E. faecalis. Extracellular complementation of bacteriocin expression was possible for bacL₁ and -L₂ and bacA mutants. bacL₁ and -L₂ and bacA encoded bacteriocin component L and activator component A, respectively. The products of these genes are secreted into the culture medium and extracellularly complement bacteriocin expression. bacI encoded immunity, providing the host with resistance to its own bacteriocin activity. The bacL₁-encoded protein had significant homology with lytic enzymes that attack the gram-positive bacterial cell wall. Sequence data for the deduced bacL₁-encoded protein suggested that it has a domain structure consisting of an N-terminal signal peptide, a second domain with the enzymatic activity, and a third domain with a three-repeat structure directing the proenzyme to its cell surface receptor.     

Expression,Isolation, and Purification of Soluble and Insoluble Biotinylated Proteins for Nerve Tissue Regeneration

Recombinant protein engineering has utilized Escherichia coli (E. coli) expression systems for nearly 4 decades, and today E. coli is still the most widely used host organism. The flexibility of the system allows for the addition of moieties such as a biotin tag (for streptavidin interactions) and larger functional proteins like green fluorescent protein or cherry red protein. Also, the integration of unnatural amino acids like metal ion chelators, uniquely reactive functional groups, spectroscopic probes, and molecules imparting post-translational modifications has enabled better manipulation of protein properties and functionalities. As a result this technique creates customizable fusion proteins that offer significant utility for various fields of research. More specifically, the biotinylatable protein sequence has been incorporated into many target proteins because of the high affinity interaction between biotin with avidin and streptavidin. This addition has aided in enhancing detection and purification of tagged proteins as well as opening the way for secondary applications such as cell sorting. Thus, biotin-labeled molecules show an increasing and widespread influence in bioindustrial and biomedical fields. For the purpose of our research we have engineered recombinant biotinylated fusion proteins containing nerve growth factor (NGF) and semaphorin3A (Sema3A) functional regions. We have reported previously how these biotinylated fusion proteins, along with other active protein sequences, can be tethered to biomaterials for tissue engineering and regenerative purposes. This protocol outlines the basics of engineering biotinylatable proteins at the milligram scale, utilizing  a T7 lac inducible vector and E. coli expression hosts, starting from transformation to scale-up and purification.     

Fusion expression of mutated cecropin CMIV inE. coli

A cDNA coding mutated cecropin CMIV fromBombyx mori was synthesized according to its amino acid sequence usingE. coli biased codons. The gene was cloned into the fusion expression vector pEZZ318 and was expressed inE. coli HB101. The fusion protein produced was purified by affinity chromatography to yield 26 mg/L fusion product. The anti-bacterial activities of recombinant cecropin CMIV were recovered after cleavage by chemical method.     

One-step Purification of Twin-Strep-tagged Proteins and Their Complexes on Strep-Tactin Resin Cross-linked With Bis(sulfosuccinimidyl) Suberate (BS3)

Affinity purification of Strep-tagged fusion proteins on resins carrying an engineered streptavidin (Strep-Tactin) has become a widely used method for isolation of protein complexes under physiological conditions. Fusion proteins containing two copies of Strep-tag II, designated twin-Strep-tag or SIII-tag, have the advantage of higher affinity for Strep-Tactin compared to those containing only a single Strep-tag, thus allowing more efficient protein purification. However, this advantage is offset by the fact that elution of twin-Strep-tagged proteins with biotin may be incomplete, leading to low protein recovery. The recovery can be dramatically improved by using denaturing elution with sodium dodecyl sulfate (SDS), but this leads to sample contamination with Strep-Tactin released from the resin, making the assay incompatible with downstream proteomic analysis. To overcome this limitation, we have developed a method whereby resin-coupled tetramer of Strep-Tactin is first stabilized by covalent cross-linking with Bis(sulfosuccinimidyl) suberate (BS3) and the resulting cross-linked resin is then used to purify target protein complexes in a single batch purification step. Efficient elution with SDS ensures good protein recovery, while the absence of contaminating Strep-Tactin allows downstream protein analysis by mass spectrometry. As a proof of concept, we describe here a protocol for purification of SIII-tagged viral protein VPg-Pro from nuclei of virus-infected N. benthamiana plants using the Strep-Tactin polymethacrylate resin cross-linked with BS3. The same protocol can be used to purify any twin-Strep-tagged protein of interest and characterize its physiological binding partners.     

Galectin-1 as a fusion partner for the production of soluble and folded human β-1,4-galactosyltransferase-T7 in E. coli

The expression of recombinant proteins in Escherichia coli often leads to inactive aggregated proteins known as the inclusion bodies. To date, the best available tool has been the use of fusion tags, including the carbohydrate-binding protein; e.g., the maltose-binding protein (MBP) that enhances the solubility of recombinant proteins. However, none of these fusion tags work universally with every partner protein. We hypothesized that galectins, which are also carbohydrate-binding proteins, may help as fusion partners in folding the mammalian proteins in E. coli. Here we show for the first time that a small soluble lectin, human galectin-1, one member of a large galectin family, can function as a fusion partner to produce soluble folded recombinant human glycosyltransferase, β-1,4-galactosyltransferase-7 (β4Gal-T7), in E. coli. The enzyme β4Gal-T7 transfers galactose to xylose during the synthesis of the tetrasaccharide linker sequence attached to a Ser residue of proteoglycans. Without a fusion partner, β4Gal-T7 is expressed in E. coli as inclusion bodies. We have designed a new vector construct, pLgals1, from pET-23a that includes the sequence for human galectin-1, followed by the Tev protease cleavage site, a 6× His-coding sequence, and a multi-cloning site where a cloned gene is inserted. After lactose affinity column purification of galectin-1-β4Gal-T7 fusion protein, the unique protease cleavage site allows the protein β4Gal-T7 to be cleaved from galectin-1 that binds and elutes from UDP-agarose column. The eluted protein is enzymatically active, and shows CD spectra comparable to the folded β4Gal-T1. The engineered galectin-1 vector could prove to be a valuable tool for expressing other proteins in E. coli.     

Signal Peptide does not Inhibit Binding of Biotin to Streptavidin

Three recombinant polypeptides of streptavidin: the full-length streptavidin with a signal peptide (rsavS), full-length streptavidin (rsavF) and core streptavidin (rsavC), were expressed in E. coli strain BL21 (DE3) and purified by Ni-NTA chromatography. Although all three recombinant streptavidins had biotin-binding activity, the stability and solubility of rsavC tetraunits were much better than those of rsavS and rsavF, indicating that signal peptide and/or extra amino acid residues in rsavS and rsavF have negative effects on streptavidin. Meanwhile, the signal peptide and extra amino acid residues in rsavS and rsavF made it difficult for polypeptides to fold into functional proteins. After refolding of denaturing-purified proteins in vitro, both the specific activities and biotin binding sites of renatured streptavidins were 1.4-times as that of proteins obtained by native Ni-NTA purification. Because the denaturing-purified rsavC is easy of refolding into functional protein, the better strategy for production of active rsavC is to isolate the protein from IPTG-induced E. coli extracts by denaturing Ni-NTA affinity chromatography followed by refolding of purified polypeptide in vitro.     

Isolation of a Derivative ofEscherichia coli–Enterococcus faecalisShuttle Vector pAM401 Temperature Sensitive for Maintenance inE. faecalisand Its Use in Evaluating the Mechanism of pAD1par-Dependent Plasmid Stabilization

A derivative of theEscherichia coli–Enterococcus faecalisshuttle vector pAM401 was isolated by mutagenesis in anE. colimutator strain. This plasmid, designated pAM401ts, was more than an order of magnitude less stable at 38°C than at 30°C in theE. faecalishost strain JH2-2. TheE. faecalisplasmid pAD1-encodedparstability locus was cloned onto pAM401ts, and its effects on plasmid stability and host cell viability were assessed. It was found thatparstabilized pAM401ts at 38°C but also caused a substantial drop in cell viability three to four generations after a temperature shift from 30 to 38°C. After a maximum viability drop of 94%, culture growth recovered as plasmid-free cells began to accumulate. Provision of excess RNAII, the putativeparantidote,in transattenuated cell killing. These characteristics support a postsegregational killing mechanism forpar-mediated plasmid stabilization.     

Conjugal Transfer of Plasmid DNA fromEscherichia colito Enterococci: A Method to Make Insertion Mutations

Shuttle vector pAT18 was transferred by conjugation fromEscherichia coliS17-1 toEnterococcus faecalisOG1RF andEnterococcus faeciumSE34. Transfer was mediated by the transfer functions of plasmid RK2 inE. coliS17-1 and the origin of conjugal transfer (oriT) located on pAT18. TheoriTsequence was then inserted into two plasmids to generate vectors pTEX5235 and pTEX5236. These two vectors cannot replicate in gram-positive bacteria and can be used to make insertion mutants in gram-positive bacteria. An internal sequence from an autolysin gene ofE. faecalisOG1RF was cloned into pTEX5235 and transferred by conjugation fromE. coliS17-1 toE. faecalisOG1RF. The plasmid was found to integrate into the chromosome of OG1RF by a single crossover event, resulting in a disrupted autolysin gene. A cosmid carrying the pyrimidine gene cluster fromE. faecalis,with a transposon insertion inpyrC,was also transferred fromE. coliS17-1 toE. faecalisOG1RF. After selection for the transposon, it was found to have recombined into the recipient chromosome by a double crossover between the cosmid and the chromosome of OG1RF. This resulted in apyrCknockout mutant showing an auxotrophic phenotype.     

Construction and application of the vectors to identify genes encoding exported proteins of Escherichia coli

In order to clone genes having signal sequences of Escherichia coli, four vectors with or without Lac or Ara promoter were constructed using a leaderless β-lactamase as reporter. Fragments of tetracycline resistance gene (Tet) with or without promoter were used to confirm the vectors’ ability to clone and report signal sequences. The minimum inhibitory concentration of ampicillin of the transformants was measured to detect the expression and secretion efficiency of the vectors. The results showed that the β-lactamase could be co-expressed and secreted with Tet protein. The Lac or Ara promoter in the vectors could be regulated by different inducers, and the Ara promoter showed higher regulative efficiency than the Lac. The best induction dose of l-arabinose for the Ara promoter is 1.25 %. All the four vectors were stably maintained in host after being inoculated for 20 passages in antibiotics-free media. Genomic library of an avian pathogenic strain, E. coli O₂, was constructed using the pMB-Ara-T vector we developed. 318 clones were obtained from the genomic library of E. coli strain O₂, and the inserts in these clones represented 276 genes based on sequence analysis. Among the 276 cloned fragments, only 128 had complete promoter sequence. For the 128 fragments with promoter, only 27 could be expressed under LB culture condition without inducer, the other 101 were only expressed under induction. The results showed our constructed vectors could efficiently capture all kinds of exported protein genes in vitro, including the ones without promoter or with inactive promoter.     

Bacteriocin Protein BacL1 of Enterococcus faecalis Is a Peptidoglycan d-Isoglutamyl-l-lysine Endopeptidase

Enterococcus faecalis strains are commensal bacteria in humans and other animals, and they are also the causative agent of opportunistic infectious diseases. Bacteriocin 41 (Bac41) is produced by certain E. faecalis clinical isolates, and it is active against other E. faecalis strains. Our genetic analyses demonstrated that the extracellular products of the bacL₁ and bacA genes, which are encoded in the Bac41 operon, coordinately express the bacteriocin activity against E. faecalis. In this study, we investigated the molecular functions of the BacL₁ and BacA proteins. Immunoblotting and N-terminal amino acid sequence analysis revealed that BacL₁ and BacA are secreted without any processing. The coincidental treatment with the recombinant BacL₁ and BacA showed complete bacteriocin activity against E. faecalis, but neither BacL₁ nor BacA protein alone showed the bacteriocin activity. Interestingly, BacL₁ alone demonstrated substantial degrading activity against the cell wall fraction of E. faecalis in the absence of BacA. Furthermore, MALDI-TOF MS analysis revealed that BacL₁ has a peptidoglycan d-isoglutamyl-l-lysine endopeptidase activity via a NlpC/P60 homology domain. These results collectively suggest that BacL₁ serves as a peptidoglycan hydrolase and, when BacA is present, results in the lysis of viable E. faecalis cells.