Secretion of CyaA-PrtB and HlyA-PrtB fusion proteins in Escherichia coli: involvement of the glycine-rich repeat domain of Erwinia chrysanthemi protease B.

Protease B from Erwinia chrysanthemi was shown previously to have a C-terminal secretion signal located downstream of a domain that contains six glycine-rich repeats. This domain is conserved in all known bacterial proteins secreted by the signal peptide-independent pathway. The role of these repeats in the secretion process is controversial. We compared the secretion processes of various heterologous polypeptides fused either directly to the signal or separated from it by the glycine-rich domain. Although the repeats are not involved in the secretion of small truncated protease B carboxy-terminal peptides, they are required for the secretion of higher-molecular-weight fusion proteins. Secretion efficiency was also dependent on the size of the passenger polypeptide.     

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.     

Extracellular secretion of pullulanase is unaffected by minor sequence changes but is usually prevented by adding reporter proteins to its N- or C-terminal end.

Linker insertions in the pullulanase structural gene (pulA) were examined for their effects on pullulanase activity and cell surface localization in Escherichia coli carrying the cognate secretion genes from Klebsiella oxytoca. Of the 23 insertions, 11 abolished pullulanase activity but none were found to prevent secretion. To see whether more drastic changes affected secretion, we fused up to five reporter proteins (E. coli periplasmic alkaline phosphatase, E. coli periplasmic maltose-binding protein, periplasmic TEM beta-lactamase, Erwinia chrysanthemi extracellular endoglucanase Z, and Bacillus subtilis extracellular levansucrase) to three different positions in the pullulanase polypeptide: close to the N terminus of the mature protein, at the C terminus of the protein, or at the C terminus of a truncated pullulanase variant lacking the last 256 amino acids. Only 3 of the 13 different hybrids were efficiently secreted: 2 in which beta-lactamase was fused to the C terminus of full-length or truncated pullulanase and 1 in which maltose-binding protein was fused close to the N terminus of pullulanase. Affinity-purified endoglucanase-pullulanase and pullulanase-endoglucanase hybrids exhibited apparently normal levels of pullulanase activity, indicating that the conformation of the pullulanase segment of the hybrid had not been dramatically altered by the presence of the reporter. However, pullulanase-endoglucanase hybrids were secreted efficiently if the endoglucanase component comprised only the 60-amino-acid, C-terminal cellulose-binding domain, suggesting that at least one factor limiting hybrid protein secretion might be the size of the reporter.     

The SecB chaperone is involved in the secretion of the Serratia marcescens HasA protein through an ABC transporter.

The secretion pathways of the heme-binding protein HasA from Serratia marcescens and of the metalloproteases A, B, C and G from Erwinia chrysanthemi have been reconstituted in Escherichia coli. They are secreted in a single step from the cytoplasm across both membranes of the Gram-negative envelope, after recognition of their specific C-terminal secretion signal by their cognate ABC transporter. We report strong evidence that both HasA and the metalloproteases bind the SecB chaperone involved in the export of several envelope proteins via the Sec pathway. We also show that the secretion of the HasA protein is strongly dependent upon SecB in the reconstituted system, whereas that of the proteases is not. HasA secretion in the original host is strongly inhibited by a protein known to interfere with E.coli SecB function. We propose that the proteins secreted by the ABC pathway may have to be unfolded for efficient secretion.     

The N terminus of the HasA protein and the SecB chaperone cooperate in the efficient targeting and secretion of HasA via the ATP-binding cassette transporter.

Secretion of the HasA hemophore is mediated by a C-terminal secretion signal as part of an ATP-binding cassette (ABC) pathway in the Gram-negative bacterium Serratia marcescens. We reconstituted the HasA secretion pathway in Escherichia coli. In E. coli, this pathway required three specific secretion functions and SecB, the general chaperone of the Sec pathway that recognizes HasA. The secretion of the isolated C-terminal secretion signal was not SecB-dependent. We have previously shown that intracellular folded HasA can no longer be secreted, and we proposed a step in the secretion process before the recognition of the secretion signal. Here we show that the secretion of a fully functional HasA variant, lacking the first 10 N-terminal amino acids, was less efficient than that of HasA and was SecB-independent. The N terminus of HasA was required, along with SecB, for the efficient secretion of the whole protein. We have also previously shown that HasA inhibits the secretion of metalloproteases from Erwinia chrysanthemi by their specific ABC transporter. Here we show that this abortive interaction between HasA and the E. chrysanthemi metalloprotease ABC transporter required both SecB and the N terminus of HasA. N-terminal fragments of HasA displayed this abortive interaction in vivo and also interacted specifically in vitro with the ABC protein of the Prt system. SecB also interacted specifically in vitro with the ABC protein of the Prt system. Finally, the HasA variant, lacking the first 10 N-terminal amino acids did not display this abortive interaction with the Prt system. We suggest that the N-terminal domain of HasA specifically recognizes the ABC protein in a SecB-dependent fashion, facilitating functional interaction with the C-terminal secretion signal leading to efficient secretion.     

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.     

Extracellular secretion of pectate lyase by the Erwinia chrysanthemi out pathway is dependent upon Sec-mediated export across the inner membrane.

The plant pathogenic enterobacterium Erwinia chrysanthemi EC16 secretes several extracellular, plant cell wall-degrading enzymes, including pectate lyase isozyme PelE. Secretion kinetics of 35S-labeled PelE indicated that the precursor of PelE was rapidly processed by the removal of the amino-terminal signal peptide and that the resulting mature PelE remained cell bound for less than 60 s before being secreted to the bacterial medium. PelE-PhoA (alkaline phosphatase) hybrid proteins generated in vivo by TnphoA insertions were mostly localized in the periplasm of E. chrysanthemi, and one hybrid protein was observed to be associated with the outer membrane of E. chrysanthemi in an out gene-dependent manner. A gene fusion resulting in the substitution of the beta-lactamase signal peptide for the first six amino acids of the PelE signal peptide did not prevent processing or secretion of PelE in E. chrysanthemi. When pelE was overexpressed, mature PelE protein accumulated in the periplasm rather than the cytoplasm in cells of E. chrysanthemi and Escherichia coli MC4100 (pCPP2006), which harbors a functional cluster of E. chrysanthemi out genes. Removal of the signal peptide from pre-PelE was SecA dependent in E. coli MM52 even in the presence of the out gene cluster. These data indicate that the extracellular secretion of pectic enzymes by E. chrysanthemi is an extension of the Sec-dependent pathway for general export of proteins across the bacterial inner membrane.     

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.     

Protein secretion by hybrid bacterial ABC-transporters: specific functions of the membrane ATPase and the membrane fusion protein.

The Erwinia chrysanthemi metalloprotease C and the Serratia marcescens haem acquisition protein HasA are both secreted from Gram-negative bacteria by a signal peptide-independent pathway which requires a C-terminal secretion signal and a specific ABC-transporter made up of three proteins: a membrane ATPase (the ABC-protein), a second inner membrane component belonging to the membrane fusion protein family and an outer membrane polypeptide. HasA and protease C transporters are homologous although the secreted polypeptides share no sequence homology. Whereas protease C can use both translocators, HasA is secreted only by its specific transporter. Functional analysis of protease C and HasA secretion through hybrid transporters obtained by combining components from each system demonstrates that the ABC-protein is responsible for the substrate specificity and that inhibition of protease C secretion in the presence of HasA results from a defective interaction between HasA and the ABC-protein. We also show that the outer membrane protein, TolC, can combine with the membrane fusion protein HasE in the presence of either ABC-protein to form a functional transporter but not with the membrane fusion protein, PrtE. This indicates a specific interaction between the outer membrane component and the membrane fusion protein.     

Release of a chimeric protein into the medium from Escherichia coli using the C-terminal secretion signal of haemolysin.

Recently, we have identified a novel topogenic sequence at the C terminus of Escherichia coli haemolysin (HlyA) which is essential for its efficient secretion into the medium. This discovery has introduced the possibility of using this secretion system for the release of chimeric proteins from E. coli directly into the medium. We have now successfully fused this C-terminal signal to a hybrid protein containing a few residues of beta-galactosidase and the majority of the E. coli outer membrane porin OmpF lacking its own N-terminal signal sequence. We find that this chimeric protein is specifically translocated across the inner and outer membranes and is released into the medium. In addition, we have further localized the HlyA secretion signal to the final 113 amino acids of the C terminus. In fact, a specific secretion signal appears to reside at least in part within the last 27 amino acids of HlyA.     

Formation of the Arabidopsis pentatricopeptide repeat family

In Arabidopsis (Arabidopsis thaliana) the 466 pentatricopeptide repeat (PPR) proteins are putative RNA-binding proteins with essential roles in organelles. Roughly half of the PPR proteins form the plant combinatorial and modular protein (PCMP) subfamily, which is land-plant specific. PCMPs exhibit a large and variable tandem repeat of a standard pattern of three PPR variant motifs. The association or not of this repeat with three non-PPR motifs at their C terminus defines four distinct classes of PCMPs. The highly structured arrangement of these motifs and the similar repartition of these arrangements in the four classes suggest precise relationships between motif organization and substrate specificity. This study is an attempt to reconstruct an evolutionary scenario of the PCMP family. We developed an innovative approach based on comparisons of the proteins at two levels: namely the succession of motifs along the protein and the amino acid sequence of the motifs. It enabled us to infer evolutionary relationships between proteins as well as between the inter- and intraprotein repeats. First, we observed a polarized elongation of the repeat from the C terminus toward the N-terminal region, suggesting local recombinations of motifs. Second, the most N-terminal PPR triple motif proved to evolve under different constraints than the remaining repeat. Altogether, the evidence indicates different evolution for the PPR region and the C-terminal one in PCMPs, which points to distinct functions for these regions. Moreover, local sequence homogeneity observed across PCMP classes may be due to interclass shuffling of motifs, or to deletions/insertions of non-PPR motifs at the C terminus.     

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.     

Structural and functional relationships among the RTX toxin determinants of gram-negative bacteria.

The RTX (repeats in toxin) cytolytic toxins represent a family of important virulence factors that have disseminated widely among Gram-negative bacteria. They are characterised by a series of glycine-rich repeat units at the C-terminal end of each protein. They also have other features in common. Secretion from the cell occurs without a periplasmic intermediate by a novel mechanism which involves recognition of a signal sequence at the C-terminus of the toxin by membrane-associated proteins that export the toxin directly to the outside of the cell. The structural gene for each protein encodes an inactive toxin which is modified post-translationally to an active cytotoxic form by another gene product before secretion. The genes for toxin synthesis, activation and secretion are for the most part grouped together on the chromosome and form an operon. The toxins all create pores in the cell membrane of target cells leading to eventual cell lysis and they appear to require Ca2+ for cytotoxic activity. Although the toxins have a similar mode of action, they vary in target cell specificity. Some are cytotoxic for a wide variety of eukaryotic cell types while others exhibit precise target cell specificity and are only active against leukocytes from certain host species. The characteristic glycine-rich repeat units have been identified in other exoproteins besides those with cytotoxic activity and it is likely that the novel secretory mechanism has been harnessed by a variety of pathogens to release important virulence-associated factors from the cell or to locate them on the cell surface.     

Structural and functional relationships among the RTX toxin determinants of Gram-negative bacteria

Abstract The RTX (repeats in toxin) cytolytic toxins r represent a family of important virulence factors that have disseminated widely among Gram-negative bacteria. They are characterised by a series of glycine-rich repeat units at the C-terminal end of each protein. They also have other features in common. Secretion from the cell occurs without a periplasmic intermediate by a novel mechanism which involves recognition of a signal sequence at the C-terminus of the toxin by membrane-associated proteins that export the toxin directly to the outside of the cell. The structural gene for each protein encodes an inactive toxin which is modified post-translationally to an active cytotoxic form by another gene product before secretion. The genes for toxin synthesis, activation and secretion are for the most part grouped together on the chromosome and form an operon. The toxins all create pores in the cell membrane of target cells leading to eventual cell lysis and they appear to require Ca²⁺ for cytotoxic activity. Although the toxins have a similar mode of action, they vary in target cell specificity. Some are cytotoxic for a wide variety of eukaryotic cell types while others exhibit precise target cell specificity and are only active against leukocytes from certain host species. The characteristic glycine-rich repeat units have been identified in other exoproteins besides those with cytotoxic activity and it is likely that the novel secretory mechanism has been harnessed by a variety of pathogens to release important virulence-associated factors from the cell or to locate them on the cell surface.     

Statistical characterization of the GxxxG glycine repeats in the flagellar biosynthesis protein FliH and its Type III secretion homologue YscL

Background  

FliH is a protein involved in the export of components of the bacterial flagellum and we herein describe the presence of glycine-rich repeats in FliH of the form AxxxG(xxxG) _m xxxA, where the value of m varies considerably in FliH proteins from different bacteria. While GxxxG and AxxxA patterns have previously been described, the long glycine repeat segments in FliH proteins have yet to be characterized. The Type III secretion system homologue to FliH (YscL, AscL, PscL, etc.) also contains a similar GxxxG repeat, and hence the presence of the repeat is evolutionarily conserved in these proteins, suggesting an important structural role or biological function.     

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.     

The Extreme C Terminus of the ABC Protein DrrA Contains Unique Motifs Involved in Function and Assembly of the DrrAB Complex

Two novel regulatory motifs, LDEVFL and C-terminal regulatory Glu (E)-rich motif (CREEM), are identified in the extreme C terminus of the ABC protein DrrA, which is involved in direct interaction with the N-terminal cytoplasmic tail of the membrane protein DrrB and in homodimerization of DrrA. Disulfide cross-linking analysis showed that the CREEM and the region immediately upstream of CREEM participate directly in forming an interaction interface with the N terminus of DrrB. A series of mutations created in the LDEVFL and CREEM motifs drastically affected overall function of the DrrAB transporter. Mutations in the LDEVFL motif also significantly impaired interaction between the C terminus of DrrA and the N terminus of DrrB as well as the ability of DrrA and DrrB to co-purify, therefore suggesting that the LDEVFL motif regulates CREEM-mediated interaction between DrrA and DrrB and plays a key role in biogenesis of the DrrAB complex. Modeling analysis indicated that the LDEVFL motif is critical for conformational integrity of the C-terminal domain of DrrA and confirmed that the C terminus of DrrA forms an independent domain. This is the first report which describes the presence of an assembly domain in an ABC protein and uncovers a novel mechanism whereby the ABC component facilitates the assembly of the membrane component. Homology sequence comparisons showed the presence of the LDEVFL and CREEM motifs in close prokaryotic and eukaryotic homologs of DrrA, suggesting that these motifs may play a similar role in other homologous drug and lipid export systems.     

Construction of silk fiber core in lepidoptera

The formation and properties of lepidopteran silk fibers depend on amino acid repeats in the principal protein, heavy chain fibroin (H-fibroin). In H-fibroins of the "bombycoid" type, concatenations of alanine or of the GAGAGS crystalline motifs (1st tier repeats) and adjacent sequences breaking periodicity make 2nd tier repeats. Two to six such repeats comprise a 3rd tier assembly, and 12 assemblies, linked by an amorphous sequence, constitute the repetitive H-fibroin region. Heterogeneity in the repeat length and intercalation of amorphous regions prevent excessive crystallization. In the "pyraloid" H-fibroins, iterations of simple motifs are absent and assemblies of several complex motifs constitute highly regular repeats that are organized in about 12 highest order reiterations without specific spacers. Repeat homogeneity appears crucial for the alignment and interaction of the disjunct motifs that must be registered precisely to form crystallites; repeat heterogeneity is associated with decreased fiber strength. Both H-fibroin types are typically hydrophobic, and their secretion requires disulfide linkage to light chain fibroin and participation of another protein, P25. These auxiliary proteins are absent in saturniid moths with amphiphilic H-fibroin repeats. The selection at nucleic acid and protein levels and the availability of nutrients play roles in H-fibroin evolution.     

JPDI,a novel endoplasmic reticulum-resident protein containing both a BiP-interacting J-domain and thioredoxin-like motifs

Several endoplasmic reticulum (ER)-resident luminal proteins have a characteristic ER retrieval signal, KDEL, or its variants at their C terminus. Our previous work searching EST databases for proteins containing the C-terminal KDEL motif predicted some novel murine proteins, one of which designated JPDI (J-domain-containing protein disulfide isomerase-like protein) is characterized in this study. The primary structure of JPDI is unique, because in addition to a J-domain motif adjacent to the N-terminal translocation signal sequence, four thioredoxin-like motifs were found in a single polypeptide. As examined by Northern blotting, the expression of JPDI was essentially ubiquitous in tissues and almost independent of ER stress. A computational prediction that JPDI is an ER-resident luminal protein was experimentally supported by immunofluorescent staining of epitope-tagged JPDI-expressing cells together with glycosylation and protease protection studies of this protein. JPDI probably acts as a DnaJ-like partner of BiP, because a recombinant protein carrying the J-domain of JPDI associated with BiP in an ATP-dependent manner and enhanced its ATPase activity. We speculate that for the folding of some proteins in the ER, chaperoning by BiP and formation of proper disulfide bonds may synchronously occur in a JPDI-dependent manner.