Analysis of the haemolysin transport process through the secretion from Escherichia coli of PCM, CAT or β-galactosidase fused to the Hly C-terminal signal domain

Secretion of haemolysin (HlyA) is secA independent, but depends upon two accessory membrane proteins, HlyB and HlyD, encoded by the hly determinant. A fourth (cytoplasmic) protein, HlyC, is required to activate HlyA post-translationally, but has no role in export. Deletion studies have previously shown that the HlyA molecule contains a targeting signal close to the C-terminus which specifically directs its secretion to the medium. This targeting signal has been variously located within the terminal 27, 53, 60 or 113 amino acids. In this paper, we have sought to confirm the presence of a C-terminal targeting signal and to analyse the specificity of the Hly transport system through fusion of C-terminal fragments of HlyA to heterologous polypeptides. A C-terminal fragment (23 kDa) of HlyA, when fused at the C-terminus, efficiently promoted the secretion of the eukaryotic protein prochymosin (PCM) to the medium via HlyB and HlyD. This result is in contrast to previous findings that prochymosin, preceded by the alkaline phosphatase signal sequence, cannot be translocated across the Escherichia coli inner membrane. The HlyA targeting domain was also used to secrete to the medium varying portions of chloramphenicol acetyltransferase (CAT) and 98 per cent of the beta-galactosidase (LacZ) molecule (both E. coli cytoplasmic proteins). In the case of the PCM and CAT fusions the efficiency of secretion was reduced as the proportion of the PCM and CAT molecule increased. This result is consistent with inhibition of secretion through the irreversible folding of the larger passenger protein fragments, or the occlusion of the HlyA targeting signal by upstream sequences. Analysis of the nature of the C-terminal domain promoting secretion of prochymosin, demonstrated that shortening the signal domain from 218 to 113 amino acids significantly reduced the efficiency of secretion. This result may also reflect the importance of maintaining an independently folded signal motif well separated from a passenger domain.     

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.     

Selection for transport competence of C-terminal polypeptides derived from Escherichia coli hemolysin: the shortest peptide capable of autonomous HIyB/HIyD-dependent secretion comprises the C-terminal 62 amino acids of HlyA

Escherichia coli hemolysin (HlyA) is secreted by a specific export machinery which recognizes a topogenic secretion signal located at the C-terminal end of HlyA. This signal sequence has been variously defined as comprising from 27 to about 300 amino acids at the C-terminus of HlyA. We have used here a combined genetic and immunological approach to select for C-terminal HlyA peptides that are still secretion-component. A deletion library of HlyA mutant proteins was generated in vitro by successive degradation of hy1A from the 5′ end with exonuclease III. Secretion competence was tested by immunoblotting of the supernatant of each clone with an antiserum raised against a C-terminal portion of hemolysin. It was found that the hemolysin secretion system has no apparent size limitation for HlyA proteins over a range from 1024 to 62 amino acids. The smallest autonomously secretable peptide isolated in this selection procedure consists of the C-terminal 62 amino acids of HlyA. This sequence is shared by all secretion-competent, truncated HlyA proteins, which suggests that secretion of the E.coli hemolysin is strictly post-translational. The capacity of the hemolysin secretion machinery was found to be unsaturated by the steady-state level of its natural HlyA substrate and large amounts of truncated HlyA derivatives could still be secreted in addition to full-length HlyA.     

Improved secretory production of recombinant proteins by random mutagenesis of hlyB, an alpha-hemolysin transporter from Escherichia coli

Fusion proteins with an alpha-hemolysin (HlyA) C-terminal signal sequence are known to be secreted by the HlyB-HlyD-TolC translocator in Escherichia coli. We aimed to establish an efficient Hly secretory expression system by random mutagenesis of hlyB and hlyD. The fusion protein of subtilisin E and the HlyA signal sequence (HlyA(218)) was used as a marker protein for evaluating secretion efficiency. Through screening of more than 1.5 x 10(4) E. coli JM109 transformants, whose hlyB and hlyD genes had been mutagenized by error-prone PCR, we succeeded in isolating two mutants that had 27- and 15-fold-higher levels of subtilisin E secretion activity than the wild type did at 23 degrees C. These mutants also exhibited increased activity levels for secretion of a single-chain antibody-HlyA(218) fusion protein at 23 and 30 degrees C but unexpectedly not at 37 degrees C, suggesting that this improvement seems to be dependent on low temperature. One mutant (AE104) was found to have seven point mutations in both HlyB and HlyD, and an L448F substitution in HlyB was responsible for the improved secretion activity. Another mutant (AE129) underwent a single amino acid substitution (G654S) in HlyB. Secretion of c-Myc-HlyA(218) was detected only in the L448F mutant (AE104F) at 23 degrees C, whereas no secretion was observed in the wild type at any temperature. Furthermore, for the PTEN-HlyA(218) fusion protein, AE104F showed a 10-fold-higher level of secretion activity than the wild type did at 37 degrees C. This result indicates that the improved secretion activity of AE104F is not always dependent on low temperature.     

Selection for transport competence of C-terminal polypeptides derived from Escherichia coli hemolysin: the shortest peptide capable of autonomous HIyB/HIyD-dependent secretion comprises the C-terminal 62 amino acids of HlyA

Escherichia coli hemolysin (HlyA) is secreted by a specific export machinery which recognizes a topogenic secretion signal located at the C-terminal end of HlyA. This signal sequence has been variously defined as comprising from 27 to about 300 amino acids at the C-terminus of HlyA. We have used here a combined genetic and immunological approach to select for C-terminal HlyA peptides that are still secretion-component. A deletion library of HlyA mutant proteins was generated in vitro by successive degradation of hy1A from the 5 end with exonuclease III. Secretion competence was tested by immunoblotting of the supernatant of each clone with an antiserum raised against a C-terminal portion of hemolysin. It was found that the hemolysin secretion system has no apparent size limitation for HlyA proteins over a range from 1024 to 62 amino acids. The smallest autonomously secretable peptide isolated in this selection procedure consists of the C-terminal 62 amino acids of HlyA. This sequence is shared by all secretion-competent, truncated HlyA proteins, which suggests that secretion of the E.coli hemolysin is strictly post-translational. The capacity of the hemolysin secretion machinery was found to be unsaturated by the steady-state level of its natural HlyA substrate and large amounts of truncated HlyA derivatives could still be secreted in addition to full-length HlyA.     

Protein secretion by heterologous bacterial ABC-transporters: the C-terminus secretion signal of the secreted protein confers high recognition specificity

Pseudomonas aeruginosa releases several extracellular proteins which are secreted via two independent secretion pathways. Alkaline protease (AprA) is released by its own specific secretion machinery which is an ABC-transporter. Despite sequence similarities between components of ABC-transporters in different bacteria, each transporter is dedicated to the secretion of a particular protein or a family of closely related proteins. Heterologous complementation between ABC-transporters for unrelated polypeptides can occur, but only at a very low level. We show that the 50 C-terminal amino acids of AprA constitute an autonomous secretion signal. By heterologous complementation experiments between the unrelated a-haemolysin (HlyA) and Apr secretion systems we demonstrated that it is only the recognition of the secretion signal by the trans-locator which confers specificity to the secretion process. Secretion was size-dependent. However inclusion of glycine-rich repeats from HlyA in AprA seems to overcome the size limitation exerted by the Apr secretion apparatus such that the machinery secreted a hybrid protein 20kDa larger than the normal maximal size.     

The Type 1 secretion pathway — The hemolysin system and beyond

Type 1 secretion systems (T1SS) are wide-spread among Gram-negative bacteria. An important example is the secretion of the hemolytic toxin HlyA from uropathogenic strains. Secretion is achieved in a single step directly from the cytosol to the extracellular space. The translocation machinery is composed of three indispensable membrane proteins, two in the inner membrane, and the third in the outer membrane. The inner membrane proteins belong to the ABC transporter and membrane fusion protein families (MFPs), respectively, while the outer membrane component is a porin-like protein. Assembly of the three proteins is triggered by accumulation of the transport substrate (HlyA) in the cytoplasm, to form a continuous channel from the inner membrane, bridging the periplasm and finally to the exterior. Interestingly, the majority of substrates of T1SS contain all the information necessary for targeting the polypeptide to the translocation channel — a specific sequence at the extreme C-terminus. Here, we summarize our current knowledge of regulation, channel assembly, translocation of substrates, and in the case of the HlyA toxin, its interaction with host membranes. We try to provide a complete picture of structure function of the components of the translocation channel and their interaction with the substrate. Although we will place the emphasis on the paradigm of Type 1 secretion systems, the hemolysin A secretion machinery from E. coli, we also cover as completely as possible current knowledge of other examples of these fascinating translocation systems. This article is part of a Special Issue entitled: Protein trafficking and secretion in bacteria. Guest Editors: Anastassios Economou and Ross Dalbey.     

Analysis of the haemolysin secretion system by PhoA-HlyA fusion proteins

Summary We studied the efficiency of the pHly152-derived haemolysin transport system using PhoA-HlyA fusion proteins and different constructs which provide HlyB/HlyD in trans. The optimal C-terminal HlyA signal consists of the last 60 amino acids. Longer stretches of HlyA do not improve the transport efficiency of PhoA-HlyA fusion proteins. The introduction of deletions and/or replacements in the 60 amino acid HlyA signal domain revealed at least three functional regions with different degrees of specificity. Amino acids 1–21 (numbered from the N-terminal part of the 60 amino acid HlyA signal), termed region I, could be replaced by a Pro-containing peptide. The other two regions II and III (amino acids 22–40 and 41–60, respectively) seem to interact directly with the HlyB/HlyD translocator since a PhoA fusion protein which contains either of the two regions was still secreted in a HlyB/HlyD-dependent mode, albeit at low efficiency. An efficient trans-complementing HlyB/HlyD system was only obtained from the pHLy152-encoded hly determinant when the regulatory hlyR element was provided in cis. Secretion of the PhoA-HlyA fusion protein did not interfere with the secretion of HlyA even when the fusion protein was induced to a high level. This suggests that the capacity of the HlyB/HlyD translocation system is high and not normally saturated by its natural HlyA substrate.Dedicated to Prof., Dr. F. Lingens on the occasion of his 65th birthday     

Identification of individual amino acids required for secretion within the haemolysin (HlyA) C-terminal targeting region

The release of haemolysin from Escherichia coli involves direct secretion across both the inner and outer membranes. Secretion of HlyA is dependent upon a specific membrane export complex composed of HlyB, -D and possibly TolC. HlyA is targeted to the medium via the membrane translocation complex, by a novel C-terminal secretion signal. Previous studies involving deletion and fusion analyses have given contradictory results for the minimal length (20-60 residues) of this HlyA signal region and little is known of the nature of the specific residues and structural features required for function. In this study we have analysed, quantitatively, the effect upon secretion of many point mutations introduced into the HlyA C-terminus. The results indicate the presence of a minimal secretion signal domain whose proximal boundary extends to at least residue -46 and which contains at least four individual residues essential for maximal secretion levels. We propose that such residues act co-operatively, forming multiple contact points with the translocator proteins, with the 'best fit' promoting maximal levels of secretion.     

Mutations in HlyD, part of the type 1 translocator for hemolysin secretion, affect the folding of the secreted toxin

HlyD, a member of the membrane fusion protein family, is essential for the secretion of the RTX hemolytic toxin HlyA from Escherichia coli. Random point mutations affecting HlyA secretion were obtained, distributed in most periplasmic regions of the HlyD molecule. Analysis of the secretion phenotypes of different mutants allowed the identification of regions in HlyD involved in different steps of HlyA translocation. Four mutants, V349-I, T85-I, V334-I and L165-Q, were conditionally defective, a phenotype shown to be linked to the presence of inhibitory concentrations of Ca2+ in extracellular medium. Hly mutant T85-I was defective at an early stage in secretion, while mutants V334-I and L165-Q appeared to accumulate HlyA in the cell envelope, indicating a block at an intermediate step. Mutants V349-I, V334-I, and L165-Q were only partially defective in secretion, allowing significant levels of HlyA to be transported, but in the case of V349-I and L165-Q the HlyA molecules secreted showed greatly reduced hemolytic activity. Hemolysin molecules secreted from V349-I and V334-I are defective in normal folding and can be reactivated in vitro to the same levels as HlyA secreted from the wild-type translocator. Both V349-I and V334-I mutations mapped to the C-terminal lipoyl repeat motif, involved in the switching from the helical hairpin to the extended form of HlyD during assembly of the functional transport channel. These results suggest that HlyD is an integral component of the transport pathway, whose integrity is essential for the final folding of secreted HlyA into its active form.     

Mutational analysis supports a role for multiple structural features in the C-terminal secretion signal of Escherichia coli haemolysin

We have carried out an extensive mutational analysis of the C-terminal signal which targets the export of the 1024-residue haemolysin protein (HlyA) of Escherichia coli across both bacterial membranes into the surrounding medium. Over 60 variants of the HlyA C-terminal 53-amino-acid sequence were created by oligonucleotide-directed mutagenesis and fused to the HlyA N-terminal 830 residues. Transport of the HlyA derivatives by the HlyB/HlyD system was compared with the wild-type level and the data indicate that the HlyA C-terminal export signal lies within the last 48 amino acids and comprises three functional domains: an amphipathic, charged helix between residues 1,977 and R,996; a 13-amino-acid uncharged region from residue T,997 to S,1009; and an 8-amino-acid hydroxylated tail at the extreme C-terminus. Analogous features were found in the C-terminal sequences of an extended family of haemolysins, leukotoxins and proteases which are secreted by HlyB/HlyD-type translocators. In particular, all nine proteins which are secreted into the extracellular medium possess potential extended amphipathic helices. These results suggest a possible role for multiple regions of the HlyA C-terminal export signal in which the first two domains span the membranes and the third domain remains in the cytoplasm.     

Formation of disulphide bonds during secretion of proteins through the periplasmic-independent type I pathway

In this work, we have investigated whether the bacterial type I secretion pathway, which does not have a periplasmic intermediate of the secreted protein, allows the formation of disulphide bridges. To this end, the formation of disulphide bonds has been studied in an antibody single-chain Fv (scFv) fragment secreted by the Escherichia coli haemolysin (Hly) transporter (a paradigm of type I secretion). The scFv antibody fragment was used as a disulphide bond and protein-folding reporter, as it contains two disulphide bridges that are required for its correct folding (i.e. to preserve its antigen-binding activity). We show that an scFv-HlyA hybrid secreted by Hly type I transporter (TolC, HlyB, HlyD) is accumulated in the extracellular medium with the disulphide bonds correctly formed. Neither periplasmic and inner membrane-bound Dsb enzymes (e.g. DsbC, DsbG, DsbB and DsbD) nor cytoplasmic thioredoxins (TrxA and TrxC) were required for scFv-HlyA oxidation. However, a mutation of the thioredoxin reductase gene (trxB), which leads to the cytoplasmic accumulation of the oxidized forms of thioredoxins, had a specific inhibitory effect on the Hly-dependent secretion of disulphide-containing proteins. These data suggest that premature cytoplasmic oxidation of the substrate may interfere with the secretion process. Taken together, these results indicate not only that the type I system tolerates secretion of disulphide-containing proteins, but also that disulphide bonds are specifically formed during the passage of the polypeptide through the export conduit.     

The mechanism of secretion of hemolysin and other polypeptides from Gram-negative bacteria

In the secretion of polypeptides from Gram-negative bacteria, the outer membrane constitutes a specific barrier which has to be circumvented. In the majority of systems, secretion is two-step process, with initial export to the periplasm involving an N-terminal signal sequence. Transport across the outer membrane then involves a variable number of ancillary polypeptides including both periplasmic and outer membrane. While such ancillary proteins are probably specific for each secreted protein, the mechanism of movement across the outer membrane is unknown. In contrast to these systems, secretion of theE. coli hemolysin (HlyA) has several distinctive features. These include a novel targeting signal located within the last 50 or so C-terminal amino acids, the absence of any periplasmic intermediates in transfer, and a specific membrane-bound translocator, HlyB, with important mammalian homologues such as P-glycoprotein (Mdr) and the cystic fibrosis protein. In this review we discuss the nature of the HlyA targeting signal, the structure and function of HlyB, and the probability that HlyA is secreted directly to the medium through a trans-envelope complex composed of HlyB and HlyD.     

Change in the cellular localization of alkaline phosphatase by alteration of its carboxy-terminal sequence

Summary Alkaline phosphatase (AP) is secreted into the medium when the carboxy-terminal 25 amino acids are replaced by the 60 amino acid carboxy-terminal signal peptide (HlyA_s) ofEscherichia coli haemolysin (HlyA). Secretion of the AP-HlyA_s fusion protein is dependent on HlyB and HlyD but independent of SecA and SecY. The efficiency of secretion by HlyB/HlyD is decreased when AP carries its own N-terminal signal peptide. Translocation of this fusion protein into the periplasm is not observed even in the absence of HlyB/HlyD. The failure of the Sec export machinery to transport the latter protein into the periplasm seems to be due in part to the loss of the carboxy-terminal sequence of AP since even AP derivatives which do not carry the HlyA signal peptide but lack the 25 C-terminal amino acids of AP are localized in the membrane but not translocated into the periplasm.     

Comparative analysis of the secretion capability of early and late flagellar type III secretion substrates

A remarkable feature of the flagellar‐specific type III secretion system (T3SS) is the selective recognition of a few substrate proteins among the many thousand cytoplasmic proteins. Secretion substrates are divided into two specificity classes: early substrates secreted for hook‐basal body (HBB) construction and late substrates secreted after HBB completion. Secretion was reported to require a disordered N‐terminal secretion signal, mRNA secretion signals within the 5′‐untranslated region (5′‐UTR) and for late substrates, piloting proteins known as the T3S chaperones. Here, we utilized translational β‐lactamase fusions to probe the secretion efficacy of the N‐terminal secretion signal of fourteen secreted flagellar substrates in Salmonella enterica. We observed a surprising variety in secretion capability between flagellar proteins of the same secretory class. The peptide secretion signals of the early‐type substrates FlgD, FlgF, FlgE and the late‐type substrate FlgL were analysed in detail. Analysing the role of the 5′‐UTR in secretion of flgB and flgE revealed that the native 5′‐UTR substantially enhanced protein translation and secretion. Based on our data, we propose a multicomponent signal that drives secretion via the flagellar T3SS. Both mRNA and peptide signals are recognized by the export apparatus and together with substrate‐specific chaperones allowing for targeted secretion of flagellar substrates.     

Protein secretion in gram-negative bacteria. The extracellular metalloprotease B from Erwinia chrysanthemi contains a C-terminal secretion signal analogous to that of Escherichia coli alpha-hemolysin

The secretion signal of extracellular metalloprotease B that is secreted without a signal peptide by the Gram-negative phytopathogenic bacterium Erwinia chrysanthemi is shown by deletion and gene fusion analyses to be located within the last 40 C-terminal amino acids. Secretion of a peptide containing only this region of the protease requires the same three secretion factors (PrtD, PrtE, and PrtF) that were previously shown to be required for the secretion of the full-length protease. This secretion signal can also be recognized, albeit inefficiently, by the analogous secretion machinery of alpha-hemolysin, another protein with a C-terminal secretion signal that is secreted by some strains of the Gram-negative bacterium Escherichia coli. The secretion signal was fused to an internal 200-amino acid fragment from the sequence of the cytoplasmic protein amylomaltase to promote its specific secretion by the protease secretion pathway. Almost exactly the same sequence as that identified as the protease B secretion signal was also found at the C terminus of metalloprotease C that is also secreted by E. chrysanthemi.     

Improved Secretory Production of Recombinant Proteins by Random Mutagenesis of hlyB, an Alpha-Hemolysin Transporter from Escherichia coli

Fusion proteins with an alpha-hemolysin (HlyA) C-terminal signal sequence are known to be secreted by the HlyB-HlyD-TolC translocator in Escherichia coli. We aimed to establish an efficient Hly secretory expression system by random mutagenesis of hlyB and hlyD. The fusion protein of subtilisin E and the HlyA signal sequence (HlyA₂₁₈) was used as a marker protein for evaluating secretion efficiency. Through screening of more than 1.5 × 10⁴ E. coli JM109 transformants, whose hlyB and hlyD genes had been mutagenized by error-prone PCR, we succeeded in isolating two mutants that had 27- and 15-fold-higher levels of subtilisin E secretion activity than the wild type did at 23°C. These mutants also exhibited increased activity levels for secretion of a single-chain antibody-HlyA₂₁₈ fusion protein at 23 and 30°C but unexpectedly not at 37°C, suggesting that this improvement seems to be dependent on low temperature. One mutant (AE104) was found to have seven point mutations in both HlyB and HlyD, and an L448F substitution in HlyB was responsible for the improved secretion activity. Another mutant (AE129) underwent a single amino acid substitution (G654S) in HlyB. Secretion of c-Myc-HlyA₂₁₈ was detected only in the L448F mutant (AE104F) at 23°C, whereas no secretion was observed in the wild type at any temperature. Furthermore, for the PTEN-HlyA₂₁₈ fusion protein, AE104F showed a 10-fold-higher level of secretion activity than the wild type did at 37°C. This result indicates that the improved secretion activity of AE104F is not always dependent on low temperature.     

Proteome-based identification of signal peptides for improved secretion of recombinant cyclomaltodextrin glucanotransferase in Escherichia coli

Secretion of recombinant proteins in heterologous host has drawn attention for its simpler purification and downstream processes. Searching for secretion aid molecules to improve protein secretion can be done through synthetic biology, screening of genome data and proteome-based approach. In the present study, the extracellular proteome on starch-containing medium of Bacillus lehensis G1 was analyzed to identify naturally secreted proteins with signal peptide. A total of 87 protein spots were identified by mass spectrometry, which were categorized mostly in the metabolism of carbohydrates and related molecules (20%). Over-expression and secretion studies were performed for all the 14 selected signal peptides fused to a reporter protein, cyclomaltodextrin glucanotransferase (CGTase). All clones were found to allow CGTase to be excreted into the medium, as observed and measured from the iodine plate assay and enzyme activity assay. Compared to native signal peptide (G1) of CGTase, signal peptide of GlcNAc-binding protein A (GAP) significantly improved CGTase activities by 735% and 205% in extracellular and periplasmic compartment, respectively, with an increase of only ∼1.7 fold the amount of β-galactosidase (cell lysis) in the medium. GAP has the highest secretion rate of 45.6 U/ml/h among all clones, where physicochemical characteristics of signal peptide play significant role.     

A specific interaction between the NBD of the ABC-transporter HlyB and a C-terminal fragment of its transport substrate haemolysin A

A member of the family of RTX toxins, Escherichia coli haemolysin A, is secreted from Gram-negative bacteria. It carries a C-terminal secretion signal of approximately 50 residues, targeting the protein to the secretion or translocation complex, in which the ABC-transporter HlyB is a central element. We have purified the nucleotide-binding domain of HlyB (HlyB-NBD) and a C-terminal 23kDa fragment of HlyA plus the His-tag (HlyA1), which contains the secretion sequence. Employing surface plasmon resonance, we were able to demonstrate that the HlyB-NBD and HlyA1 interact with a K(D) of approximately 4 microM. No interaction was detected between the HlyA fragment and unrelated NBDs, OpuAA, involved in import of osmoprotectants, and human TAP1-NBD, involved in the export of antigenic peptides. Moreover, a truncated version of HlyA1, lacking the secretion signal, failed to interact with the HlyB-NBD. In addition, we showed that ATP accelerated the dissociation of the HlyB-NBD/HlyA1 complex. Taking these results together, we propose a model for an early stage of initiation of secretion in vivo, in which the NBD of HlyB, specifically recognizes the C terminus of the transport substrate, HlyA, and where secretion is initiated by subsequent displacement of HlyA from HlyB by ATP.     

Secretion of genetically-engineered dihydrofolate reductase from Escherichia coli using an E. coli α-hemolysin membrane translocation system

Summary Secretion of fusion proteins composed of cytoplasmic protein dihydrofolate reductase (DHFR) and the Escherichia coli -haemolysin (HlyA) C-terminal sequence was examined through the haemolysin secretion machinery of E. coli. DHFR of various lengths was combined with the HlyA C-terminal region, and both secretion and DHFR activity of the fusions were measured. The secretion was found to be inversely correlated with the intracellular DHFR activity. Moreover, when one amino acid (Ile155) in a -sheet of the DHFR C-terminal region was replaced with Lys, the enzymatically active DHFR fusion protein was secreted into the medium. We discuss the possibility of a relationship between folding and secretion of HlyA-fused protein in the HlyA secretion system. Correspondence to: H. Nakano