Synthesis and functioning of the colicin E1 lysis protein: comparison with the colicin A lysis protein.

The colicin E1 lysis protein, CelA, was identified as a 3-kDa protein in induced cells of Escherichia coli K-12 carrying pColE1 by pulse-chase labeling with either [35S]cysteine or [3H]lysine. This 3-kDa protein was acylated, as shown by [2-3H]glycerol labeling, and seemed to correspond to the mature CelA protein. The rate of modification and processing of CelA was different from that observed for Cal, the colicin A lysis protein. In contrast to Cal, no intermediate form was detected for CelA, no signal peptide accumulated, and no modified precursor form was observed after globomycin treatment. Thus, the rate of synthesis would not be specific to lysis proteins. Solubilization in sodium dodecyl sulfate of the mature forms of both CelA and Cal varied similarly at the time of colicin release, indicating a change in lysis protein structure. This particular property would play a role in the mechanism of colicin export. The accumulation of the signal peptide seems to be a factor determining the toxicity of the lysis proteins since CelA provoked less cell damage than Cal. Quasi-lysis and killing due to CelA were higher in degP mutants than in wild-type cells. They were minimal in pldA mutants.     

Lipoprotein nature of the colicin A lysis protein: effect of amino acid substitutions at the site of modification and processing.

The colicin A lysis protein (Cal) is required for the release of colicin A to the medium by producing bacteria. This protein is produced in a precursor form that contains a cysteine at the cleavage site (-Leu-Ala-Ala-Cys). The precursor must be modified by the addition of lipid before it can be processed. The maturation is prevented by globomycin, an inhibitor of signal peptidase II. Using oligonucleotide-directed mutagenesis, the alanine and cystein residues in the -1 and +1 positions of the cleavage site were replaced by proline and threonine residues, respectively, in two different constructs. Both substitutions prevented the normal modification and cleavage of the protein. The marked activation of the outer membrane detergent-resistant phospholipase A observed with wild-type Cal was not observed with the Cal mutants. Both Cal mutants were also defective for the secretion of colicin A. In one mutant, the signal peptide appeared to be cleaved off by an alternative pathway involving signal peptidase I. Electron microscope studies with immunogold labeling of colicin A on cryosections of pldA and cal mutant cells indicated that the colicin remains in the cytoplasm and is not transferred to the periplasmic space. These results demonstrate that Cal must be modified and processed to activate the detergent-resistant phospholipase A and to promote release of colicin A.     

Phospholipase-A-independent damage caused by the colicin A lysis protein during its assembly into the inner and outer membranes of Escherichia coli

The requirement for the activation of phospholipase A by the colicin A lysis protein (Cal) in the efficient release of colicin A by Escherichia coli cells containing colicin A plasmids was studied. In particular, we wished to determine if this activation is the primary effect of Cal or whether it reflects more generalized damage to the envelope caused by the presence of large quantities of this small acylated protein. E. coli tolQ cells, which were shown to be leaky for periplasmic proteins, were transduced to pldA and then transformed with the recombinant colicin A plasmid pKA. Both the pldA and pldA+ strains released large quantities of colicin A following induction, indicating that in these cells phospholipase A activation is not required for colicin release. This release was, however, still dependent on a functioning Cal protein. The assembly and processing of Cal in situ in the cell envelope was studied by combining pulse-chase labelling with isopycnic sucrose density gradient centrifugation of the cell membranes. Precursor Cal and lipid-modified precursor Cal were found in the inner membrane at early times of chase, and gave rise to mature Cal which accumulated in both the inner and outer membrane after further chase. The signal peptide was also visible on these gradients, and its distribution too was restricted to the inner membrane. Gradient centrifugation of envelopes of cells which were overproducing Cal resulted in very poor separation of the membranes. The results of these studies provide evidence that the colicin A lysis protein causes phospholipase A-independent alterations in the integrity of the E. coli envelope.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of DegP protease on levels of various forms of colicin A lysis protein

Abstract The total amount of the colicin A lysis protein produced by cells grown in rich medium was analysed by immunoblotting. The intermediate forms of synthesis of this small lipoprotein were present in the cells at any time of induction, confirming that processing and maturation of colicin A lysis protein are slow and incomplete processes. The level of these various forms varied according to the time of induction, the growth conditions, the producing strain and the plasmid carrying the cal gene. It depended mainly on the presence in the producing strain of a degP gene which encodes the DegP protease. According to growth conditions, the DegP protease hydrolysed either a part or the total amount of the acylated precursor form. In some cases, a protease(s) other than DegP seemed to act on either form(s) of the colicin A lysis protein.     

Absence of the outer membrane phospholipase A suppresses the temperature-sensitive phenotype of Escherichia coli degP mutants and induces the Cpx and sigma(E) extracytoplasmic stress responses

DegP is a periplasmic protease that is a member of both the sigma(E) and Cpx extracytoplasmic stress regulons of Escherichia coli and is essential for viability at temperatures above 42 degrees C. [U-(14)C]acetate labeling experiments demonstrated that phospholipids were degraded in degP mutants at elevated temperatures. In addition, chloramphenicol acetyltransferase, beta-lactamase, and beta-galactosidase assays as well as sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis indicated that large amounts of cellular proteins are released from degP cells at the nonpermissive temperature. A mutation in pldA, which encodes outer membrane phospholipase A (OMPLA), was found to rescue degP cells from the temperature-sensitive phenotype. pldA degP mutants had a normal plating efficiency at 42 degrees C, displayed increased viability at 44 degrees C, showed no degradation of phospholipids, and released far lower amounts of cellular protein to culture supernatants. degP and pldA degP mutants containing chromosomal lacZ fusions to Cpx and sigma(E) regulon promoters indicated that both regulons were activated in the pldA mutants. The overexpression of the envelope lipoprotein, NlpE, which induces the Cpx regulon, was also found to suppress the temperature-sensitive phenotype of degP mutants but did not prevent the degradation of phospholipids. These results suggest that the absence of OMPLA corrects the degP temperature-sensitive phenotype by inducing the Cpx and sigma(E) regulons rather than by inactivating the phospholipase per se.     

High-level expression of the colicin A lysis protein

Summary Two plasmids that overproduce the colicin A lysis protein, Cal, are described. Plasmid AT1 was constructed by a deletion in the colicin A operon, which placed thecal gene near a truncatedcaa gene in such a way that both gene products were synthesized at high levels following induction. Plasmid Ck4 was constructed by insertion of thecal gene downstream from thetac promoter of an expression vector. Overproduction of Cal was obtained after mitomycin C induction of pAT1 cells and after IPTG induction of pCK4 cells. The kinetics of Cal synthesis were examined with [³⁵S] methionine and [2-³H] glycerol inlpp orlpp ⁺ host strains. Each of the steps of the lipid modification and maturation pathway of Cal was demonstrated. The modified precursor form of overproduced Cal was not chased as efficiently as when it is produced in pColA cells. After treatment with globomycin, a significant amount of this modified precursor form accumulated and was degraded with time into smaller acylated proteins, but without release of the signal peptide. Release of cellular proteins and quasi-lysis were observed after about 1 hour of induction for cells containing either plasmid. In addition, in Cal-overproducing cells, the rate of quasi-lysis was increased but not its extent. InpldA cells, quasi-lysis was reduced but not abolished. Lethality of the Cal induction in the overproducing cells was in the same range as that in wild-type cells.     

Amino acid sequence and length requirements for assembly and function of the colicin A lysis protein.

The roles of the various parts of the mature colicin A lysis protein (Cal) in its assembly into the envelope and its function in causing "quasi-lysis," the release of colicin A, and the activation of phospholipase A were investigated. By using cassette mutagenesis, many missense mutations were introduced into the highly conserved portion of the lysis protein. In vitro mutagenesis was also used to introduce stop codons after amino acids 16 and 18 and a frameshift mutation at amino acid 17 of the mature Cal sequence. The processing and modification of the mutants were identical to those of the wild type, except for the truncated Cal proteins, which were neither acylated nor processed. Thus, the carboxy-terminal half of Cal must be present (or replaced by another peptide) for the proper processing and assembly of the protein. However, the specific sequence of this region is not required for the membrane-damaging function of the protein. Furthermore, the sequence specificity for even the conserved amino acids of the amino-terminal half of the protein is apparently exceedingly relaxed, since only those mutant Cal proteins in which a highly conserved amino acid has been replaced by a glutamate were impaired in their function.     

Characterization of degQ and degS, Escherichia coli genes encoding homologs of the DegP protease.

The degQ and degS genes of Escherichia coli encode proteins of 455 and 355 residues, respectively, which are homologs of the DegP protease. The purified DegQ protein has the properties of a serine endoprotease and is processed by the removal of a 27-residue amino-terminal signal sequence. A plasmid expressing degQ rescues the temperature-sensitive phenotype of a strain bearing the degP41 deletion, implying that DegQ, like DegP, functions as a periplasmic protease in vivo. Deletions in the degQ gene cause no obvious growth defect, while those in the degS gene result in a small-colony phenotype. The latter phenotype is rescued by a plasmid expressing the degS gene but not by plasmids expressing the degQ or degP genes. This result and the inability of a plasmid expressing degS to rescue the temperature-sensitive degP41 phenotype indicate that the DegS protein is functionally different from the DegQ and DegP proteins.     

In Vivo Analysis of Sequence Requirements for Processing and Degradation of the Colicin A Lysis Protein Signal Peptide

The lipid modification and processing of a number of colicin lysis proteins take place exceedingly slowly and result in the release of a stable signal peptide. It is possible that this peptide or the presence of lipid-modified precursors which result from the slow processing plays a role in the release of colicins and in the quasilysis that occurs in induced colicinogenic cultures. We used in vitro mutagenesis and pulse-chase radiolabeling and immunoprecipitation to examine the reasons for the slow processing and signal peptide degradation reactions for the colicin A lysis protein (Cal). In one mutant, isoleucine 13 was replaced with serine, and in another, alanine 18, the last residue of the signal peptide, was replaced with glycine. In each case, the mutation caused a striking increase in the rate of maturation of the precursor, and in the case of the serine 13 derivative, the mutation also destabilized the signal peptide. A precursor containing both of these mutations was completely matured and its signal sequence degraded within seconds of its synthesis. The release of colicin A and the quasilysis of producing cultures were unchanged for each of these mutants, indicating that neither the stable signal peptide nor lipid-modified processing intermediates of Cal are required for either of these events in wild-type cells.     

Escherichia coli DegP protease cleaves between paired hydrophobic residues in a natural substrate: the PapA pilin

The DegP protein, a multifunctional chaperone and protease, is essential for clearance of denatured or aggregated proteins from the inner-membrane and periplasmic space in Escherichia coli. To date, four natural targets for DegP have been described: colicin A lysis protein, pilin subunits and MalS from E. coli, and high-molecular-weight adherence proteins from Haemophilus influenzae. In vitro, DegP has shown weak protease activity with casein and several other nonnative substrates. We report here the identification of the major pilin subunit of the Pap pilus, PapA, as a natural DegP substrate and demonstrate binding and proteolysis of this substrate in vitro. Using overlapping peptide arrays, we identified three regions in PapA that are preferentially cleaved by DegP. A 7-mer peptide was found to be a suitable substrate for cleavage by DegP in vitro. In vitro proteolysis of model peptide substrates revealed that cleavage is dependent upon the presence of paired hydrophobic amino acids; moreover, cleavage was found to occur between the hydrophobic residues. Finally, we demonstrate that the conserved carboxyl-terminal sequence in pilin subunits, although not a cleavage substrate for DegP, activates the protease and we propose that the activating peptide is recognized by DegP's PDZ domains.     

An unmodified form of the ColE2 lysis protein, an envelope lipoprotein, retains reduced ability to promote colicin E2 release and lysis of producing cells

Site-directed mutagenesis was used to replace the codon for the N-terminal cysteine residue of pColE2-P9-encoded mature lysis protein (CelB) by an arginine codon. In contrast to the wild-type CelB protein, the product of the mutated gene, which has an altered signal peptidase cleavage site, was neither processed nor acylated. However, the mutant protein retained sufficient residual activity to cause partial, Mg2+-suppressible lysis and could activate envelope phospholipase A1-A2 and promote colicin release, albeit with reduced efficiency compared to the wild-type protein. We propose that the uncleaved signal peptide of the mutant protein acts as the functional equivalent of the fatty acyl groups normally linked to the N-terminal cysteine residue of the wild-type protein, thereby anchoring the protein in the cell envelope where it exerts its various effects.     

Colicin E2 release: lysis,leakage or secretion? Possible role of a phospholipase.

Results presented here and by others indicate that the release of colicins from producing cells can be uncoupled from the decline in culture turbidity which usually occurs within 2-3 h after the induction of colicin synthesis. This excludes lysis as a necessary event in colicin release. Conversely, the failure to dissociate colicin release from the normally simultaneous release of a specific subset of soluble proteins argues against the idea of a specific colicin secretion system sensu-stricto. Rather, colicin release appears to be a consequence of semi-specific leakage resulting from an alteration of the permeability properties of the cell envelope. This alteration is caused by the 'lysis protein' known to be encoded by most multiple copy number Col plasmids. The finding that the expression of the lysis gene of plasmid ColE2 renders the cells exquisitely sensitive to lysozyme demonstrates that the permeability of the outer membrane must indeed be altered. Evidence is presented that this alteration could be due at least in part to the activation of the detergent-resistant phospholipase A (pldA product). Lysophosphatidylethanolamine, a product of the action of phospholipase on phosphatidylethanolamine, is a membrane perturbant which could alter the permeability properties of the envelope and allow some proteins such as colicin to leak out of the cell.     

Functioning of the colicin A lysis protein is affected by Triton X-100, divalent cations and EDTA

The colicin A lysis protein, Cal, is synthesized at the same time as colicin A by Escherichia coli harbouring plasmid pColA after induction by mitomycin C. Its function in the induced bacteria involves the release of colicin A, quasi-lysis, the death of the producing cells and the activation of the outer membrane phospholipase A. We have found that these various functions are affected differently by treatment of the induced cells with Triton X-100, divalent cations or EDTA. Triton X-100 and EDTA caused increased quasi-lysis and a higher level of mortality of the producing cells, but while Triton X-100 enhanced the release of colicin A, EDTA reduced it. Divalent cations protected the cells against both killing and quasi-lysis without greatly affecting colicin release. The effects of these agents were similar for both wild-type and phospholipase A mutants and depended only on the presence of a functional cal gene.     

pCloDF13-encoded bacteriocin release proteins with shortened carboxyl-terminal segments are lipid modified and processed and function in release of cloacin DF13 and apparent host cell lysis.

By oligonucleotide-directed mutagenesis, stop codon mutations were introduced at various sites in the pCloDF13-derived bacteriocin release protein (BRP) structural gene. The expression, lipid modification (incorporation of [3H]palmitate), and processing (in the presence and absence of globomycin) of the various carboxyl-terminal shortened BRPs were analyzed by a special electrophoresis system and immunoblotting with an antiserum raised against a synthetic BRP peptide, and their functioning with respect to release of cloacin DF13, lethality, and apparent host cell lysis were studied in Sup-, supF, and supP strains of Escherichia coli. All mutant BRPs were stably expressed, lipid modified, and processed by signal peptidase II, albeit with different efficiencies. The BRP signal peptide appeared to be extremely stable and accumulated in induced cells. Full induction of the mutant BRPs, including the shortest containing only 4 amino acid residues of the mature polypeptide, resulted in phospholipase A-dependent and Mg2+-suppressible apparent cell lysis. The extent of this lysis varied with the mutant BRP used. Induction of all mutant BRPs also prevented colony formation, which appeared to be phospholipase A independent. One shortened BRP, containing 20 amino acid residues of the mature polypeptide, was still able to bring about the release of cloacin DF13. The results indicated that the 8-amino-acid carboxyl-terminal segment of the BRP contains a strong antigenic determinant and that a small segment between amino acid residues 17 and 21, located in the carboxyl-terminal half of the BRP, is important for release of cloacin DF13. Either the stable signal peptide or the acylated amino-terminal BRP fragments (or both) are involved in host cell lysis and lethality.     

Characterization of degP, a gene required for proteolysis in the cell envelope and essential for growth of Escherichia coli at high temperature.

The degP gene, required for proteolysis in the cell envelope of Escherichia coli, maps at approximately 3.5 min on the chromosome. Null mutations in degP result in temperature-sensitive growth. In certain genetic backgrounds, expression of abnormal periplasmic or inner membrane proteins (protein fusions or proteins with internal deletions) enhances the temperature-sensitive phenotype. Such growth defects were used as a selection for cloning the degP gene into Mud4042 and pACYC184 plasmid vectors, and a restriction map was determined. Analysis of deletion and insertion mutations on one of these plasmids showed that the degP gene is approximately 1.5 kilobases in size. The plasmid-encoded DegP protein had an apparent molecular weight of 50,000, as determined by maxicell analysis. Protein fusions between DegP and alkaline phosphatase had high alkaline phosphatase enzymatic activity, indicating that DegP is a periplasmic or membrane protein.     

Dissecting a cyanobacterial proteolytic system: efficiency in inducing degradation of the D1 protein of photosystem II in cyanobacteria and plants

A chromatography fraction, prepared from isolated thylakoids of a fatty acid desaturation mutant (Fad6/desA Colon, two colons Km(r)) of the cyanobacterium Synechocystis 6803, could induce an initial cleavage of the D1 protein in Photosystem II (PSII) particles of Synechocystis 6803 mutant and Synechococcus 7002 wild type as well as in supercomplexes of PSII-light harvesting complex II of spinach. Proteolysis was demonstrated both in darkness and in light as a reduction in the amount of full-length D1 protein or as a production of C-terminal initial degradation fragments. In the Synechocystis mutant, the main degradation fragment was a 10-kDa C-terminal one, indicating an initial cleavage occurring in the cytoplasmic DE-loop of the D1 protein. A protein component of 70-90 kDa isolated from the chromatographic fraction was found to be involved in the production of this 10-kDa fragment. In spinach, only traces of the corresponding fragment were detected, whereas a 24-kDa C-terminal fragment accumulated, indicating an initial cleavage in the lumenal AB-loop of the D1 protein. Also in Synechocystis the 24-kDa fragment was detected as a faint band. An antibody raised against the Arabidopsis DegP2 protease recognized a 35-kDa band in the proteolytically active chromatographic fraction, suggesting the existence of a lumenal protease that may be the homologue DegP of Synechocystis. The identity of the other protease cleaving the D1 protein in the DE-loop exposed on the stromal (cytoplasmic) side of the membrane is discussed.     

Plasmid ColE3 specifies a lysis protein.

Tn5 insertion mutations in plasmid ColE3 were isolated and characterized. Several of the mutants synthesized normal amounts of active colicin E3 but, unlike wild-type colicinogenic cells, did not release measurable amounts of colicin into the culture medium. Cells bearing the mutant plasmids were immune to exogenous colicin E3 at about the same level as wild-type colicinogenic cells. All of these lysis mutants mapped near, but outside of, the structural genes for colicin E3 and immunity protein. Cells carrying the insertion mutations which did not release colicin E3 into the medium were not killed by UV exposure at levels that killed cells bearing wild-type plasmids. The protein specified by the lysis gene was identified in minicells and in mitomycin C-induced cells. A small protein, with a molecular weight between 6,000 and 7,000, was found in cells which released colicin into the medium, but not in mutant cells that did not release colicin. Two mutants with insertions within the structural gene for colicin E3 were also characterized. They produced no colicin activity, but both synthesized a peptide consistent with their map position near the middle of the colicin gene. These two insertion mutants were also phenotypically lysis mutants--they were not killed by UV doses lethal to wild-type colicinogenic cells and they did not synthesize the small putative lysis protein. Therefore, the lysis gene is probably in the same operon as the structural gene for colicin E3.     

Protease-deficient DegP suppresses lethal effects of a mutant OmpC protein by its capture

The expression of assembly-defective outer membrane proteins can confer lethality if they are not degraded by envelope proteases. We report here that the expression of a mutant OmpC protein, OmpC(2Cys), which forms disulfide bonds in the periplasm due to the presence of two non-native cysteine residues, is lethal in cells lacking the major periplasmic protease, DegP. This lethality is not observed in dsbA strains that have diminished ability to form periplasmic disulfide bonds. Our data show that this OmpC(2Cys)-mediated lethality in a degP::Km(r) dsbA(+) background can be reversed by a DegP variant, DegP(S210A), that is devoid of its proteolytic activity but retains its reported chaperone activity. However, DegP(S210A) does not reverse the lethal effect of OmpC(2Cys) by correcting its assembly but rather by capturing misfolded mutant OmpC polypeptides and thus removing them from the assembly pathway. Displacement of OmpC(2Cys) by DegP(S210A) also alleviates the negative effect that the mutant OmpC protein has on wild-type OmpF.