Characterization of pectin methylesterase B, an outer membrane lipoprotein of Erwinia chrysanthemi 3937

The secretion of extracellular pectinases, among which there are least six isoenzymes of pectate lyase and one pectin methylesterase, allows the phytopathogenic bacterium Erwinia chrysanthemi to degrade pectin. A gene coding for a novel pectin methylesterase has been cloned from an E. chrysanthemi strain 3937 gene library. This gene, pemB , codes for a 433-amino-acid protein. The PemB N-terminal region has the characteristics of lipoprotein signal sequences. We have shown that the PemB precursor is processed and that palmitate is incorporated into the mature protein. The PemB lipoprotein is not released into the extracellular medium and is localized in the outer membrane. The PemB sequence presents homology with other pectin methylesterases from bacterial and plant origin. pemB -like proteins were detected in four other E. chrysanthemi strains but not in Erwinia carotovora strains. PemB was overproduced in Escherichia coli and purified to homogeneity. PemB activity is strongly increased by non-ionic detergents. The enzyme is more active on methylated oligogalacturonides than on pectin, and it is necessary for the growth of the bacteria on oligomeric substrates. PemB is more probably involved in the degradation of methylated oligogalacturonides present in the periplasm of the bacteria, rather than in a direct action on extracellular pectin. pemB expression is inducible in the presence of pectin and is controlled by the negative regulator KdgR.     

Secretion of the Serratia marcescens HasA protein by an ABC transporter.

We previously identified a Serratia marcescens extracellular protein, HasA, able to bind heme and required for iron acquisition from heme and hemoglobin by the bacterium. This novel type of extracellular protein does not have a signal peptide and does not show sequence similarities to other proteins. HasA secretion was reconstituted in Escherichia coli, and we show here that like many proteins lacking a signal peptide, HasA has a C-terminal targeting sequence and is secreted by a specific ATP binding cassette (ABC) transporter consisting of three proteins, one inner membrane protein with a conserved ATP binding domain, called the ABC; a second inner membrane protein; and a third, outer membrane component. Since the three S. marcescens components of the HasA transporter have not yet been identified, the reconstituted HasA secretion system is a hybrid. It consists of the two S. marcescens inner membrane-specific components, HasD and HasE, associated with an outer membrane component coming from another bacterial ABC transporter, such as the E. coli TolC protein, the outer membrane component of the hemolysin transporter, or the Erwinia chrysanthemi PrtF protein, the outer membrane component of the protease transporter. This hybrid transporter was first shown to allow the secretion of the S. marcescens metalloprotease and the E. chrysanthemi metalloproteases B and C. On account of that, the two S. marcescens components HasD and HasE were previously named PrtDSM and PrtESM, respectively. However, HasA is secreted neither by the PrtD-PrtE-PrtF transporter (the genuine E. chrysanthemi protease transporter) nor by the HlyB-HlhD-TolC transporter (the hemolysin transporter). Moreover, HasA, coexpressed in the same cell, strongly inhibits the secretion of proteases B and C by their own transporter, indicating that the E. chrysanthemi transporter recognizes HasA. Since PrtF could replace TolC in the constitution of the HasA transporter, this indicates that the secretion block does not take place at the level of the outer membrane component but rather at an earlier step of interaction between HasA and the inner membrane components.     

Defective Escherichia coli signal peptides function in yeast

To investigate structural characteristics important for eukaryotic signal peptide function in vivo, a hybrid gene with interchangeable signal peptides was cloned into yeast. The hybrid gene encoded nine residues from the amino terminus of the major Escherichia coli lipoprotein, attached to the amino terminus of the entire mature E. coli beta-lactamase sequence. To this sequence were attached sequences encoding the nonmutant E. coli lipoprotein signal peptide, or lipoprotein signal peptide mutants lacking an amino-terminal cationic charge, with shortened hydrophobic core, with altered potential helicity, or with an altered signal-peptide cleavage site. These signal-peptide mutants exhibited altered processing and secretion in E. coli. Using the GAL10 promoter, production of all hybrid proteins was induced to constitute 4-5% of the total yeast protein. Hybrid proteins with mutant signal peptides that show altered processing and secretion in E. coli, were processed and translocated to a similar degree as the non-mutant hybrid protein in yeast (approximately 36% of the total hybrid protein). Both non-mutant and mutant signal peptides appeared to be removed at the same unique site between cysteine 21 and serine 22, one residue from the E. coli signal peptidase II processing site. The mature lipo-beta-lactamase was translocated across the cytoplasmic membrane into the yeast periplasm. Thus the protein secretion apparatus in yeast recognizes the lipoprotein signal sequence in vivo but displays a specificity towards altered signal sequences which differs from that of E. coli.     

Secretion processing and activation of Erwinia chrysanthemi proteases

E chrysanthemi, a phytopathogenic enterobacterium, secretes several enzymes into the medium such as pectinases cellulases and proteases. It also produces 3 distinct and antigenically related extracellular proteases. The proteases secretion pathway seems to be distinct from that of the other extracellular enzymes since pleiotropic mutants impaired in cellulase and pectinase secretion are unimpaired in protease secretion. E chrysanthemi proteases B and C secretion occurs without an N-terminal signal peptide and is dependent upon specific secretion functions which are encoded by genes adjacent to the protease structural genes. This secretion pathway might be analogous to the alpha-hemolysin secretion pathway in E coli. Protection against intracellular proteolytic activity is achieved by 2 distinct mechanisms: the proteases are synthesized as inactive precursors with an N-terminal extension of 15 aminoacids (protease B) and 17 aminoacids (protease C) absent in the mature active extracellular enzymes; an intracellular specific protease inhibitor is produced by some E chrysanthemi strains.     

Molecular cloning, nucleotide sequence, and marker exchange mutagenesis of the exo-poly-alpha-D-galacturonosidase-encoding pehX gene of Erwinia chrysanthemi EC16.

The pehX gene encoding extracellular exo-poly-alpha-D-galacturonosidase (exoPG; EC 3.2.1.82) was isolated from a genomic library of the pectate lyase-deficient Erwinia chrysanthemi mutant UM1005 (a Nalr Kanr delta pelABCE derivative of EC16) by immunoscreening 2,800 Escherichia coli HB101 transformants with an antibody against exoPG protein. The cloned pehX gene was expressed highly from its own promoter in E. coli, and most of the enzyme was localized in the periplasm. The nucleotide sequence of pehX revealed the presence of an amino-terminal signal peptide and an open reading frame encoding a preprotein of 64,608 daltons. The cloned pehX gene was insertionally inactivated with TnphoA and used to mutate the chromosomal pehX gene of E. chrysanthemi AC4150 (Nalr) and CUCPB5006 (Nalr Kans delta pelABCE) by marker exchange mutagenesis. Analysis of the resulting mutants, CUCPB5008 (Pel+ Peh-) and CUCPB5009 (Pel- Peh-), indicated that exoPG can contribute significantly to bacterial utilization of polygalacturonate and the induction of pectate lyase in the presence of extracellular pectic polymers. CUCPB5009 retained a slight ability to pit polygalacturonate semisolid agar and macerated chrysanthemum pith tissues when large numbers of bacteria were inoculated.     

Subset of hybrid eukaryotic proteins is exported by the type I secretion system of Erwinia chrysanthemi

Erwinia chrysanthemi exports degradative enzymes by using a type I protein secretion system. The proteases secreted by this system lack an N-terminal signal peptide but contain a C-terminal secretion signal. To explore the substrate specificity of this system, we have expressed the E. chrysanthemi transporter system (prtDEF genes) in Escherichia coli and tested the ability of this ABC transporter to export hybrid proteins carrying C-terminal fragments of E. chrysanthemi protease B. The C terminus contains six glycine-rich repeated motifs, followed by two repeats of the sequences DFLV and DIIV. Two types of hybrid proteins were assayed for transport, proteins with the 93-residue-protease-B C terminus containing one glycine-rich repeat and both hydrophobic terminal repeats and proteins with the 181-residue C terminus containing all repeat motifs. Although the shorter C terminus is unable to export the hybrids, the longer C terminus can promote the secretion of hybrid proteins with N termini as large as 424 amino acids, showing that the glycine-rich motifs are required for the efficient secretion of these hybrids. However, the secretion of hybrids occurs only if these proteins do not carry disulfide bonds in their mature structures. These latter results suggest that disulfide bond formation can occur prior to or during the secretion. Disulfide bonds may prevent type I secretion of hybrids. One simple hypothesis to explain these results is that the type I channel is too narrow to permit the export of proteins with secondary structures stabilized by disulfide bonds.     

External Loops at the C Terminus of Erwinia chrysanthemi Pectate Lyase C Are Required for Species-Specific Secretion through the Out Type II Pathway

The type II secretion system (main terminal branch of the general secretion pathway) is used by diverse gram-negative bacteria to secrete extracellular proteins. Proteins secreted by this pathway are synthesized with an N-terminal signal peptide which is removed upon translocation across the inner membrane, but the signals which target the mature proteins for secretion across the outer membrane are unknown. The plant pathogens Erwinia chrysanthemi and Erwinia carotovora secrete several isozymes of pectate lyase (Pel) by the out-encoded type II pathway. However, these two bacteria cannot secrete Pels encoded by heterologously expressed pel genes from the other species, suggesting the existence of species-specific secretion signals within these proteins. The functional cluster of E. chrysanthemi out genes carried on cosmid pCPP2006 enables Escherichia coli to secrete E. chrysanthemi, but not E. carotovora, Pels. We exploited the high sequence similarity between E. chrysanthemi PelC and E. carotovora Pel1 to construct 15 hybrid proteins in which different regions of PelC were replaced with homologous sequences from Pel1. The differential secretion of these hybrid proteins by E. coli(pCPP2006) revealed M118 to D175 and V215 to C329 as regions required for species-specific secretion of PelC. We propose that the primary targeting signal is contained within the external loops formed by G274 to C329 but is dependent on residues in M118 to D170 and V215 to G274 for proper positioning.     

Illicit secretion of a cytoplasmic protein into the periplasm of Escherichia coli requires a signal peptide plus a portion of the cognate secreted protein. Demarcation of the critical region of the mature protein

The beta-lactamase signal peptide alone is not sufficient to direct secretion of chicken muscle triosephosphate isomerase, a normally cytoplasmic protein, into the periplasm of Escherichia coli. The signal peptide and at least the first 3 residues of the mature beta-lactamase are required before any secretion of the isomerase can be observed. At this point the level of secretion is very low, but the addition of further residues of the mature beta-lactamase enhances the secretion of the hybrid protein. The maximum level of secretion is achieved when 12 or more residues of the mature beta-lactamase intervene between the signal peptide and the isomerase. It is the proximity of an arginine residue at position 3 of the isomerase that is responsible for the blockade to secretion of these hybrid proteins (see Summers, R.G., Harris, C.R., and Knowles, J.R. (1989) J. Biol. Chem. 264, 20082-20088). With 12 residues of the mature beta-lactamase between the signal peptide and the isomerase, the offending arginine now lies at position 15 of the hybrid. The 14 residues that immediately follow the signal peptide therefore define a region of constrained properties that is critical to the secretability of proteins from E. coli.     

Artificial insertion of peptides between signal peptide and mature protein: effect on secretion and processing of hybrid thermostable alpha-amylases in Bacillus subtilis and Escherichia coli cells

To study the effect of inserted peptides on the secretion and processing of exported proteins in Bacillus subtilis and Escherichia coli, pBR322-derived DNA fragments coding for small peptides were inserted between the DNA coding for the 31 amino acid B. subtilis alpha-amylase signal peptide and that coding for the mature part of the extracellular thermostable alpha-amylase of B. stearothermophilus. Most of the inserted peptides (21 to 65 amino acids) decreased the production of the enzyme in B. subtilis and E. coli, the effect of each peptide being similar in the two strains. In contrast, with one peptide (a 21 amino acid sequence encoded by the extra DNA in pTUBE638), the production of alpha-amylase was enhanced more than 1.7-fold in B. subtilis in comparison with that of the parent strain. The molecular masses of the thermostable alpha-amylases in the periplasm of the E. coli transformants varied for each peptide insert, whereas those in the culture supernatants of the B. subtilis transformants had molecular masses similar to that of the mature enzyme. Based on the NH2-terminal amino acid sequence of the hybrid protein from pTUBE638, it was shown that in E. coli, the NH2-terminally extended thermostable alpha-amylase was translocated and remained in the periplasm after the 31 amino acid signal sequence was removed. In the case of B. subtilis, after the removal of a 34-amino acid signal sequence, the hybrid protein was secreted and processed to the mature form.     

Export and processing analysis of a fusion between the extracellular heat-stable enterotoxin and the periplasmic B subunit of the heat-labile enterotoxin in Escherichia coli

As an initial approach in the study of the mechanism of secretion of the extracellular heat-stable enterotoxin of Escherichia coli (STA), and in order to use this polypeptide as an extracellular carrier we previously constructed a fusion between the complete STA toxin (pre-pro-STA) and the mature B subunit of the periplasmic heat-labile enterotoxin (LTB); the resulting STA-LTB hybrid was not secreted to the extracellular environment, and cells expressing the hybrid lysed at temperatures above 35 degrees C. In this work we have established that the hybrid is initially detected as pre-pro-STA-LTB and converted to pro-STA-LTB, which lacks the 19 amino acids that share the properties of a signal peptide; the sequenced 17 amino-terminal residues of pro-STA-LTB defined the processing site of pre-pro-STA-LTB at pro-3phe-2ala-1 decreases gln+1. This process was sensitive to an energy uncoupler (CCCP) and was correlated with translocation of pro-STA-LTB across the inner membrane. Additionally, we are able to show that although pre-pro-STA-LTB is processed at 37 degrees C and 29 degrees C, it is more efficiently processed at the latter temperature. At 37 degrees C, pro-STA-LTB was poorly released into the periplasm, resulting in accumulation of this protein, pre-pro-STA-LTB, and pre-beta-lactamase in the inner membrane, and in cell lysis. In contrast, at 29 degrees C pro-STA-LTB was localized in the periplasm and in the inner membrane, and pre-pro-STA-LTB and pre-beta-lactamase did not accumulate; however, translocation of periplasmic pro-STA-LTB across the outer membrane still did not occur, and a second processing step that would eliminate the pro segment from pro-STA-LTB was never observed. Thus, the fusion of pre-pro-STA and LTB resulted in a polypeptide that, while incompatible with secretion to the extracellular medium, is exported to the periplasm in a temperature-conditional fashion. This latter observation is consistent with an STA secretion pathway whereby pre-pro-STA is first processed to periplasmic pro-STA by the removal of a 19-amino-acid signal peptide.     

Characterization of a protein inhibitor of extracellular proteases produced by Erwinia chrysanthemi

Erwinia chrysanthemi, a phytopathogenic bacterium, produces a protease inhibitor which is a low-molecular-weight, heat-stable protein. In addition to its action on the three E. chrysanthemi extracellular proteases A, B and C, it also strongly inhibits the 50 kD extracellular protease of Serratia marcescens. Its structural gene (inh) was subcloned and expressed in Escherichia coli, in which it encodes an active inhibitor which was purified. The nucleotide sequence of the inh gene shows an open reading frame of 114 condons. The N-terminal amino acid sequence of the purified inhibitor was also determined. It indicated the existence of an amino-terminal signal peptide absent from the mature protein. The inhibitor is entirely periplasmic in E. chrysanthemi and partially periplasmic in E. coli.     

A short N-proximal region of prochymosin inhibits the secretion of hybrid proteins from Escherichia coli

A gene encoding bovine prochymosin (PC) was fused to the coding sequence (phoA) for the Escherichia coli alkaline phosphatase (AP) signal peptide and expressed in E. coli under the control of the phoA promoter. Upon induction, an AP-PC fusion protein was produced which was neither processed nor exported into the periplasm. We investigated this lack of secretion by constructing a series of gene fusions in which different regions of the PC gene were inserted between the coding regions of the AP leader and mature protein. Analysis of the cellular location of the proteins encoded by these fusions revealed that a region of PC (between amino acids 6 and 29) prevented processing and secretion of an AP-PC fusion when inserted near to the AP signal peptide. In contrast, when this 'blocking sequence' was inserted elsewhere in AP the hybrid proteins were efficiently processed and translocation was initiated.     

Translocation of green fluorescent protein by comparative analysis with multiple signal peptides

Type I and II secretory pathways are used for the translocation of recombinant proteins from the cytoplasm of Escherichia coli. The purpose of this study was to evaluate four signal peptides (HlyA, TorA, GeneIII, and PelB), representing the most common secretion pathways in E. coli, for their ability to target green fluorescent protein (GFP) for membrane translocation. Signal peptide-GFP genetic fusions were designed in accordance with BioFusion standards (BBF RFC 10, BBF RFC 23). The HlyA signal peptide targeted GFP for secretion to the extracellular media via the type I secretory pathway, whereas TAT-dependent signal peptide TorA and Sec-dependent signal peptide GeneIII exported GFP to the periplasm. The PelB signal peptide was inefficient in translocating GFP. The use of biological technical standards simplified the design and construction of functional signal peptide-recombinant protein genetic devices for type I and II secretion in E. coli. The utility of the standardized parts model is further illustrated as constructed biological parts are available for direct application to other studies on recombinant protein translocation.     

The normally periplasmic enzyme β-lactamase is specifically and efficiently translocated through the Escherichia coli outer membrane when it is fused to the cell-surface enzyme pullulanase

Hybrid proteins were constructed in which C-terminal regions of the bacterial cell surface and extracellular protein pullulanase were replaced by the mature forms of the normally periplasmic Escherichia coli proteins beta-lactamase or alkaline phosphatase. In E. coli strains expressing all pullulanase secretion genes, pullulanase-beta-lactamase hybrid protein molecules containing an N-terminal 834-amino-acid pullulanase segment were efficiently and completely transported to the cell surface. This hybrid protein remained temporarily anchored to the cell surface, presumably via fatty acids attached to the N-terminal cysteine of the pullulanase segment, and was subsequently specifically released into the medium in a manner indistinguishable from that of pullulanase itself. These results suggest that the C-terminal extremity of pullulanase lacks signal(s) required for export to the cell surface. When beta-lactamase was replaced by alkaline phosphatase, the resulting hybrid also became exposed at the cell surface, but exposition was less efficient and specific release into the medium was not observed. We conclude that proteins that do not normally cross the outer membrane can be induced to do so when fused to a permissive site near the C-terminus of pullulanase.     

Secretion of recombinant Bacillus hydrolytic enzymes using Escherichia coli expression systems

Bacillus spp. are Gram-positive bacteria that secrete a large number of extracellular proteins of industrial relevance. In this report, three Bacillus extracellular hydrolytic enzymes, i.e., alpha-amylase, mannanase and chitinase, were cloned and over-expressed in Gram-negative Escherichia coli. We found that both the native signal peptides and that of E. coli outer membrane protein, OmpA, could be used to direct the secretion of the recombinant enzymes. The expressed enzymes were observed as clearing zones on agar plates or in zymograms. Determination of enzyme activities in different cell compartments suggested that the ability of the enzymes to be secreted out into the culture medium depends on the time of induction, the type of the signal peptides and the molecular mass of the enzymes. After overnight induction, most of the enzyme activities (85-96%) could be harvested from the culture supernatant. Our results suggest that various signal peptides of Bacillus spp. can be recognized by the E. coli secretion machinery. It seems possible that other enzymes with similar signal peptide could be secreted equally well in E. coli expression systems. Thus, our finding should be able to apply for cloning and extracellular production of other Bacillus hydrolytic enzymes as well as other proteins.     

Production of secretory and extracellular N-linked glycoproteins in Escherichia coli

The Campylobacter jejuni pgl gene cluster encodes a complete N-linked protein glycosylation pathway that can be functionally transferred into Escherichia coli. In this system, we analyzed the interplay between N-linked glycosylation, membrane translocation and folding of acceptor proteins in bacteria. We developed a recombinant N-glycan acceptor peptide tag that permits N-linked glycosylation of diverse recombinant proteins expressed in the periplasm of glycosylation-competent E. coli cells. With this "glycosylation tag," a clear difference was observed in the glycosylation patterns found on periplasmic proteins depending on their mode of inner membrane translocation (i.e., Sec, signal recognition particle [SRP], or twin-arginine translocation [Tat] export), indicating that the mode of protein export can influence N-glycosylation efficiency. We also established that engineered substrate proteins targeted to environments beyond the periplasm, such as the outer membrane, the membrane vesicles, and the extracellular medium, could serve as substrates for N-linked glycosylation. Taken together, our results demonstrate that the C. jejuni N-glycosylation machinery is compatible with distinct secretory mechanisms in E. coli, effectively expanding the N-linked glycome of recombinant E. coli. Moreover, this simple glycosylation tag strategy expands the glycoengineering toolbox and opens the door to bacterial synthesis of a wide array of recombinant glycoprotein conjugates.     

Nucleotide sequence of the Erwinia chrysanthemi gene encoding 2-keto-3-deoxygluconate permease

The phytopathogenic bacterium Erwinia chrysanthemi produces a group of pectolytic enzymes able to depolymerise the pectic compounds in plant cell walls. The resulting tissue maceration is known as soft rot disease. The degraded pectin products are transported by 2-keto-3-deoxygluconate permease into the bacterial cell, where they serve as carbon and energy sources. This H+ coupled transport system is encoded by the kdgT gene; we report the nucleotide sequence of kdgT. It is encoded by an open reading frame (ORF) of 1194 bp, which is preceded by an Escherichia coli-type promoter region. The ORF encodes a protein with 398 amino acid (aa) residues and a predicted Mr of 48,550. As would be expected for a membrane protein, it is very hydrophobic, containing 63% nonpolar aa. However, the kdgT gene has no apparent evolutionary relationship to other genes encoding sugar transport proteins, such as lacY, melB or the E. coli citrate transport gene. Southern hybridization experiments indicate a strong homology between the Er. chrysanthemi and E. coli kdgT genes; there is also a second region on the E. coli chromosome with homology to kdgT. The kdgT gene is located near the ade-377 marker on the Er. chrysanthemi chromosome (equivalent to the region between 20 and 30 min in E. coli), whereas the E. coli kdgT gene is located at 88 min. Thus, these two enterobacteria show some significant differences in their genomic organization.