Production in Escherichia coli and one-step purification of bifunctional hybrid proteins which bind maltose. Export of the Klenow polymerase into the periplasmic space

Two enzymes, the secreted Staphylococcus aureus nuclease A and the Klenow fragment of the cytoplasmic Escherichia coli DNA polymerase I, were fused, at the genetic level, to MalE, the periplasmic maltose-binding protein of E. coli, or to a signal-sequence mutant. The hybrid proteins were synthesized in large amounts by E. coli under control of promoter malEp. The synthesis was repressed with glucose and could be totally switched off in a malT mutant strain. The hybrid between MalE and the nuclease was exported into the periplasmic space. Several criteria demonstrated that a fraction of the hybrid chains with the Klenow polymerase was exported to the periplasm in a signal-sequence-specific manner and ruled out the possibility of a membrane leakage. The hybrid with the Klenow polymerase was not exported and remained in the cytoplasm when carrying a tight signal-sequence mutation in its MalE portion. The hybrid proteins were purified in one step by affinity chromatography on cross-linked amylose. Most of the hybrid chains in the periplasm but only a fraction of those in the other cell compartments had their MalE portion correctly folded. The nuclease and the Klenow polymerase had their full specific activities in the purified hybrids. The potential of MalE as a vector for the production, export and purification of desirable proteins in E. coli is discussed.     

The rate of folding dictates substrate secretion by the Escherichia coli hemolysin type 1 secretion system

Secretion of the Escherichia coli toxin hemolysin A (HlyA) is catalyzed by the membrane protein complex HlyB-HlyD-TolC and requires a secretion sequence located within the last 60 amino acids of HlyA. The Hly translocator complex exports a variety of passenger proteins when fused N-terminal to this secretion sequence. However, not all fusions are secreted efficiently. Here, we demonstrate that the maltose binding protein (MalE) lacking its natural export signal and fused to the HlyA secretion signal is poorly secreted by the Hly system. We anticipated that folding kinetics might be limiting secretion, and we therefore introduced the "folding" mutation Y283D. Indeed this mutant fusion protein was secreted at a much higher level. This level was further enhanced by the introduction of a second MalE folding mutation (V8G or A276G). Secretion did not require the molecular chaperone SecB. Folding analysis revealed that all mutations reduced the refolding rate of the substrate, whereas the unfolding rate was unaffected. Thus, the efficiency of secretion by the Hly system is dictated by the folding rate of the substrate. Moreover, we demonstrate that fusion proteins defective in export can be engineered for secretion while still retaining function.     

Insertion of a MalE β-Galactosidase Fusion Protein into the Envelope of Escherichia coli Disrupts Biogenesis of Outer Membrane Proteins and Processing of Inner Membrane Proteins

The synthesis of a membrane-bound MalE β-galactosidase hybrid protein, when induced by growth of Escherichia coli on maltose, leads to inhibition of cell division and eventually a reduced rate of mass increase. In addition, the relative rate of synthesis of outer membrane proteins, but not that of inner membrane proteins, was reduced by about 50%. Kinetic experiments demonstrated that this reduction coincided with the period of maximum synthesis of the hybrid protein (and another maltose-inducible protein, LamB). The accumulation of this abnormal protein in the envelope therefore appeared specifically to inhibit the synthesis, the assembly of outer membrane proteins, or both, indicating that the hybrid protein blocks some export site or causes the sequestration of some limiting factor(s) involved in the export process. Since the MalE protein is normally located in the periplasm, the results also suggest that the synthesis of periplasmic and outer membrane proteins may involve some steps in common. The reduced rate of synthesis of outer membrane proteins was also accompanied by the accumulation in the envelope of at least one outer membrane protein and at least two inner membrane proteins as higher-molecular-weight forms, indicating that processing (removal of the N-terminal signal sequence) was also disrupted by the presence of the hybrid protein. These results may indicate that the assembly of these membrane proteins is blocked at a relatively late step rather than at the level of primary recognition of some site by the signal sequence. In addition, the results suggest that some step common to the biogenesis of quite different kinds of envelope protein is blocked by the presence of the hybrid protein.     

Raising antibodies against OprD, an outer membrane protein of Pseudomonas aeruginosa using translational fusions to MalE.

OprD is an outer membrane porin of Pseudomonas aeruginosa that mediates uptake of basic amino acids, peptides as well as carbapenem antibiotics. Polyclonal antibodies were raised against the OprD porin by creating protein fusions between the Escherichia coli maltose binding protein and four OprD fragments. These were expressed in E. coli and shown to be exported to the periplasm. The fusion proteins were purified by amylose affinity chromatography and used to immunize rabbits intramuscularly. We established that MalE fusions to OprD fragments retain maltose and amylose binding activities in vivo and in vitro, confirming proper folding of the MalE domain of hybrid proteins. Furthermore, we demonstrate that this strategy can be used to obtain specific antibodies against bacterial outer membrane proteins (OMPs).     

Genetic analysis of the membrane insertion and topology of MalF, a cytoplasmic membrane protein of Escherichia coli

MalF is an essential cytoplasmic membrane protein of the maltose transport system of Escherichia coli. We have developed a general approach for analysis of the mechanism of integration of membrane proteins and their membrane topology by characterizing a series of fusions of beta-galactosidase to MalF. The properties of the fusion proteins indicate the following. (1) The first two presumed transmembrane segments of MalF are sufficient to anchor beta-galactosidase firmly to the inner membrane. (2) Hybrid proteins with beta-galactosidase fused to a presumed cytoplasmic domain of MalF have high beta-galactosidase specific activity; fusions to periplasmic domains have low activity. We propose therefore, that periplasmic and cytoplasmic domains of integral membrane proteins can be distinguished by the enzymatic properties of such hybrid proteins. In general, it appears that cleaved or non-cleaved signal sequences when attached to beta-galactosidase cause it to become embedded in the membrane, and this results in the inability of the hybrid proteins to assemble into active enzyme. Additional properties of these fusion proteins contribute to our understanding of the regulation of MalF synthesis. The MalF protein, synthesized as part of the malEFG operon of E. coli, is approximately 30-fold less abundant in the cell than MalE protein (the maltose-binding protein). Differential amounts of the fusion proteins indicate that a regulatory signal occurs within the malF gene that is responsible for the step-down in expression from the malE gene to the malF gene.     

Expression of heterologous peptides at two permissive sites of the MalE protein: antigenicity and immunogenicity of foreign B-cell and T-cell epitopes.

We previously determined a number of 'permissive' sites in the periplasmic maltose-binding protein (MalE) from Escherichia coli. These sites accept the insertion of heterologous peptides without major deleterious consequences for the activities, structure and cellular location of the protein. This study explores the versatility of two such permissive sites for the synthesis of foreign peptides, and examines the antigenicity and the immunogenicity of the inserts. One site is located after amino acid 133 (aa133) of MalE, and the other after aa303. Both sites tolerate inserts of up to at least 70 aa and accept sequences of different natures. Hydrophobic aa sequences are accepted, although strongly hydrophobic sequences, such as the Sendai virus F protein membrane anchor, affected export. We compared the antigenic and the immunogenic properties of peptides derived from the coat proteins of HBV and poliovirus which contain well defined B-cell epitopes. Specific monoclonal antibodies show that the antigenic properties of the inserted B-cell epitopes were different at the two sites. Despite these differences, the inserted peptides elicited strong and comparable antibody responses in mice against the corresponding synthetic peptides. In this case, and with these criteria, the molecular context of the peptides did not affect the immunogenicity of B-cell epitopes. We show for the first time that when a foreign peptide carrying a T-cell epitope was inserted in MalE, the hybrid proteins can elicit a T-cell response against the foreign peptide both in vivo and in vitro. Furthermore, the MalE hybrid was as efficient as free peptide in stimulating T-cell hybridomas in vitro. The MalE vectors provide a powerful genetic system to study how the position and the conformation of a peptide within a protein affect the B-cell and T-cell responses.     

Using an E. coli Type 1 secretion system to secrete the mammalian, intracellular protein IFABP in its active form

A biotechnological production of proteins through protein secretion systems might be superior to the conventional cytoplasmic production, because of the absence of large amounts of proteases present in the extracellular space and the ease of purification or downstream processing. However, secretion of proteins is still a trial-and-error approach and many proteins fail to be secreted. Recently, a study of a Type 1 secretion system revealed that the folding rate of the passenger protein dictates secretion efficiency. Here, the well-known MalE failed to be secreted when fused to a C-terminal fragment of the natural substrate haemolysin A. In contrast, slow-folding mutants of MalE were secreted in high yields. However, MalE is a bacterial protein that is targeted to the periplasmic space of E. coli and possesses the intrinsic capability to cross a membrane. Therefore, we applied the same approach for another eukaryotic protein that resides in the cytoplasm. As an example, we chose the intestinal fatty acid binding protein (IFABP) and highlight the universal potential of this Type 1 secretion system to secrete proteins with slow-folding kinetics (here the G121V mutant). Finally, a one-step purification protocol was established yielding 1mg of pure IFABP G121V per liter culture supernatant. Moreover, secreted IFABP G121V was shown to reach a folded state, which is biologically active.     

Candida albicans HEX1 gene, a reporter of gene expression in Saccharomyces cerevisiae

A nonapeptide from IL-1β has been reported to be an immunostimulant and adjuvant. To investigate the possibility of enhancing the immunogenicity of recombinant antigens delivered by live-attenuated Salmonella strains, we inserted an oligonucleotide coding for the nonapeptide from murine IL-1β into the genes of three model proteins: LamB, MalE, and flagellin. The hybrid proteins were expressed and delivered in vivo by Salmonella aroA strains, and serum antibody responses were analyzed. The results showed that the nonapeptide induced an increase in the immune response against Salmonella-delivered flagellin, measured on day 28 post-immunization. However, the adjuvant effect was lost by day 42. In no case was an adjuvant effect detected for Salmonella-delivered LamB or MalE. Thus, by comparing the immune responses raised by purified MalE with and without the peptide, we investigated whether the insertion of the peptide affected the immunogenicity of the protein itself. Also in this case, a modest adjuvant effect was shown only after primary immunization and when very low doses of antigen were used. In conclusion, the immunomodulatory properties of the IL-1β peptide can also be detected when it is delivered in vivo by Salmonella; however, the effect is modest and antigen-dependent. Received: 30 May 1997 / Accepted: 15 September 1997     

Export and purification of a cytoplasmic dimeric protein by fusion to the maltose-binding protein of Escherichia coli

A hybrid between the maltose-binding protein (MalE) of Escherichia coli and the gene 5 protein (G5P) of phage M13 was constructed at the genetic level. MalE is a monomeric and periplasmic protein while G5P is dimeric and cytoplasmic. The hybrid (MalE-G5P) was synthesized in large amounts from a multicopy plasmid and efficiently exported into the periplasmic space of E. coli. The export was dependent on the integrity of the signal peptide. MalE-G5P was purified from a periplasmic extract by affinity chromatography on cross-linked amylose, with a yield larger than 50,000 molecules/E. coli cell. The hybrid specifically bound denatured but not double-stranded DNA cellulose, as native G5P. Sedimentation velocity and gel-filtration experiments showed that MalE-G5P exists as a dimer. Thus, it was possible to efficiently translocate through the membrane a normally cytoplasmic and dimeric protein, by fusion to MalE. Moreover, the passenger protein kept its activity, specificity and quaternary structure in the purified hybrid. MalE-G5P will enable the study of mutant G5P that no longer binds single-stranded DNA and therefore cannot be purified by DNA-cellulose chromatography.     

Neutralising properties for HIV virus of hybrid protein MalE-CD4 expressed in E. coli and purified in 1 step

Genetic fusions allowing the expression in E. coli of hybrid proteins between a bacterial periplasmic maltose binding protein (MalE) and the CD4 molecule (the receptor of the HIV virus) have been constructed. One of them has kept most of the properties of each constituent: it is exported, can be purified in one step on an affinity column, interacts with anti-MalE and anti-CD4 antibodies, binds HIV gp 120 protein and inactivates HIV virus in an in vitro test.     

Molecular strategies for protein stabilization: the case of a trehalose/maltose-binding protein from Thermus thermophilus

The trehalose/maltose-binding protein (MalE1) is one component of trehalose and maltose uptake system in the thermophilic organism Thermus thermophilus. MalE1 is a monomeric 48 kDa protein predominantly organized in alpha-helix conformation with a minor content of beta-structure. In this work, we used Fourier-infrared spectroscopy and in silico methodologies for investigating the structural stability properties of MalE1. The protein was studied in the absence and in the presence of maltose as well as in the absence and in the presence of SDS at different p(2)H values (neutral p(2)H and at p(2)H 9.8). In the absence of SDS, the results pointed out a high thermostability of the MalE1 alpha-helices, maintained also at basic p(2)H values. However, the obtained data also showed that at high temperatures the MalE1 beta-sheets underwent to structural rearrangements that were totally reversible when the temperature was lowered. At room temperature, the addition of SDS to the protein solution slightly modified the MalE1 secondary structure content by decreasing the protein thermostability. The infrared data, corroborated by molecular dynamics simulation experiments performed on the structure of MalE1, indicated that the protein hydrophobic interactions have an important role in the MalE1 high thermostability. Finally, the results obtained on MalE1 are also discussed in comparison with the data on similar thermostable proteins already studied in our laboratories.     

Failure of E. coli K-12 to transport PhoE-LacZ hybrid proteins out of the cytoplasm.

A phoE-lacZ hybrid gene encoding the N-terminal 300 amino acid residues of pre-PhoE protein, fused to an almost complete beta-galactosidase molecule was constructed in vitro. Cell fractionation experiments suggested that the hybrid gene product is transported to the outer membrane. However, by using immuno-cytochemical labelling on ultra-thin cryosections it was shown that the hybrid protein accumulated in the cytoplasm. Thus, it appears that: (i) data on the localization of hybrid proteins merely based on cell fractionation experiments are not reliable, and (ii) either the C-terminal 15% of PhoE protein contain information which is essential for transport, or PhoE-LacZ hybrid proteins can never be transported out of the cytoplasm. The implications of these results for current models on the translocation of outer membrane proteins are discussed.     

Iron-sulfur cluster reconstitution of spinach chloroplast Rieske protein requires a partially prefolded apoprotein

The Rieske 2Fe-2S protein is a central component of the photosynthetic electron transport cytochrome b6f complex in chloroplast and cyanobacterial thylakoid membranes. We have constructed plasmids for expression in Escherichia coli of full-length and truncated Spinacia oleracea Rieske (PetC) proteins fused to the MalE, maltose binding protein. The expressed Rieske fusion proteins were found predominantly in soluble form in the E. coli cytoplasm. These proteins could be readily purified for further experimentation. In vitro reconstitution of the characteristic, "Rieske-type" 2Fe-2S cluster into these fused proteins was accomplished by a chemical method employing reduced iron and sulfide. Cluster incorporation was monitored by electron paramagnetic resonance and optical circular dichroism (CD) spectroscopy. CD spectral analysis in the ultraviolet region suggests that the spinach Rieske apoprotein must be in a partially folded conformation to incorporate an appropriate iron-sulfur cluster. These data further suggest that upon cluster integration, further folding occurs, allowing the Rieske protein to attain a final, native structure. The data presented here are the first to demonstrate successful chemical reconstitution of the 2Fe-2S cluster into a Rieske apoprotein from higher plant chloroplasts.     

Discovery of an auto-regulation mechanism for the maltose ABC transporter MalFGK2

The maltose transporter MalFGK(2), together with the substrate-binding protein MalE, is one of the best-characterized ABC transporters. In the conventional model, MalE captures maltose in the periplasm and delivers the sugar to the transporter. Here, using nanodiscs and proteoliposomes, we instead find that MalE is bound with high-affinity to MalFGK2 to facilitate the acquisition of the sugar. When the maltose concentration exceeds the transport capacity, MalE captures maltose and dissociates from the transporter. This mechanism explains why the transport rate is high when MalE has low affinity for maltose, and low when MalE has high affinity for maltose. Transporter-bound MalE facilitates the acquisition of the sugar at low concentrations, but also captures and dissociates from the transporter past a threshold maltose concentration. In vivo, this maltose-forced dissociation limits the rate of transport. Given the conservation of the substrate-binding proteins, this mode of allosteric regulation may be universal to ABC importers.     

Crystallization of genetically engineered active maltose-binding proteins, including an immunogenic viral epitope insertion.

Three mutants of the maltose- or maltodextrin-binding protein encoded by the malE gene of Escherichia coli, with extensive genetic changes, have been purified and crystallized in different crystal forms. Two of these mutant proteins, MalE178 and MalE341, carry net deletions of seven and 13 residues, respectively, near the surface of the molecule. These mutations have very little effect on either the transport activity of the mutant strains or the sugar-binding activity of the purified mutant proteins. The third mutant protein involves the insertion of an 11-residue peptide of the C3 epitope from type 1 poliovirus VP1 protein into the MalE178 deletion mutant, with retention of essentially all the biological properties of the wild-type and the immunological properties of the C3 epitope. We are undertaking three-dimensional structure analysis in order to understand how the protein accommodates these large changes in its surface structure and how the C3 epitope retains its immunological properties in this new environment. The same system could be used to determine easily the structures of other peptide epitopes, especially those in proteins with unknown structures.     

The cellular location of a foreign B cell epitope expressed by recombinant bacteria determines its T cell-independent or T cell-dependent characteristics.

We have targeted two foreign B cell antigenic determinants to different locations in the Escherichia coli cell to examine what effect this had on antibody responses elicited by the recombinant bacteria. The two epitopes were the 132-145 peptide from the PreS2 region of hepatitis B virus and the C3 neutralization epitope of poliovirus type 1. They were each expressed in two forms either on the surface, as part of the outer-membrane protein LamB, or soluble in the periplasm, as part of the periplasmic protein MalE. When live bacteria expressing the foreign epitope at the cell surface were used for immunization of mice, they induced T cell-independent antibody responses characterized by a rapid induction of IgM and IgG antibodies. In contrast, when the same foreign epitope was inserted into the MalE protein, the antibody response was only detectable after 3 wk, belonged only to the IgG class and was strictly T cell dependent. This study has therefore identified two major pathways by which epitopes expressed by bacterial cells can stimulate specific antibody responses. The first pathway is mediated by direct activation of B cells by bacterial cell-surface Ag and does not require T cell help. The second pathway is T cell dependent and concerns Ag that can be released from the bacteria in a soluble form. We have also studied the effect of the exact position of the B cell antigenic determinant within the LamB protein and with respect to the outer membrane by comparing the immunogenicity of the PreS epitope inserted at three different permissive sites of LamB. The data indicated that to obtain an antibody response with intact bacteria, the epitope must be protruding sufficiently from the outside of the outer membrane. In contrast, when semipurified hybrid proteins were used as immunogen, the exact position of the B cell antigenic determinant within solubilized LamB protein does not influence its immunogenicity.     

Hybrid human lymphokine genes. I.Design of recombinant plasmids coding hybrids of immune interferon and human tumor necrosis factor

Recombinant plasmids coding for hybrid proteins between human interferon gamma and human tumour necrosis factor alpha or beta have been constructed using site-directed mutagenesis. The genes were fused via a synthetic oligonucleotide linker coding for tetrapeptide Pro-Val-Gly-Pro. The fused genes were expressed in Escherichia coli under control of early promoters of bacteriophage T7. E. coli cells harbouring the plasmids with the hybrid genes gave rather high level of the fused proteins biosynthesis. The hybrid recombinant proteins proved to be unstable in E. coli cells.     

Overexpression and reconstitution of a Rieske iron-sulfur protein from the higher plant

The iron-sulfur protein subunit, known as the Rieske protein, is one of the central components of the cytochrome b(6)f complex residing in chloroplast and cyanobacterial thylakoid membranes. We have constructed plasmids for overexpression in Escherichia coli of full-length and truncated Rieske (PetC) proteins from the Spinacia oleracea fused to MalE. Overexpressed fusion proteins were predominantly found (from 55 to 70%) in cytoplasm in a soluble form. The single affinity chromatography step (amylose resine) was used to purify about 15mg of protein from 1 liter of E. coli culture. The isolated proteins were electrophoretically pure and could be used for further experiments. The NifS-like protein IscS from the cyanobacterium Synechocystis PCC 6803 mediates the incorporation of 2Fe-2S clusters into apoferredoxin and cyanobacterial Rieske apoprotein in vitro. Here, we used the recombinant IscS protein for the enzymatic reconstitution of the iron-sulfur cluster into full-length Rieske fusion and truncated Rieske fused proteins. Characterization by EPR spectroscopy of the reconstituted proteins demonstrated the presence of a 2Fe-2S cluster in both full-length and truncated Rieske fusion proteins.     

Expression and purification of cytokine receptor homology domain of human granulocyte-colony-stimulating factor receptor fusion protein in Escherichia coli

Direct expression of the cytokine receptor homology (CRH) domain of granulocyte-colony-stimulating factor (G-CSF) receptor is lethal to Escherichia coli. For the efficient and stable production of an active CRH domain in E. coli, we fused the CRH domain with different proteins, such as maltose-binding protein (MalE), glutathione S-transferase, and thioredoxin (Trx). Among these, Trx appeared to be the best in terms of the protein expression level, purification efficiency by affinity chromatography, and binding activity to its ligand, G-CSF. The yield of active Trx-CRH fusion protein increased about 200-fold compared to that of previously reported MalE-CRH fusion.