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.     

Roles of the hydrophobic cavity and lid of LolA in the lipoprotein transfer reaction in Escherichia coli

LolA, a periplasmic chaperone, binds to outer membrane-specific lipoproteins released from the inner membrane through the action of an ATP-binding cassette transporter, LolCDE and then transfers them to the outer membrane receptor LolB, thereby mediating the inner to outer membrane transport of lipoproteins. The crystal structure of free LolA revealed that it has an internal hydrophobic cavity, which is surrounded by hydrophobic residues and closed by a lid comprising alpha-helices. The hydrophobic cavity most likely represents the binding site for the lipid moiety of a lipoprotein. It is speculated that the lid undergoes opening and closing upon the binding and transfer of lipoproteins, respectively. To determine the functions of the hydrophobic cavity and lid in detail, 14 residues involved in the formation of these structures were subjected to random mutagenesis. Among the obtained 21 LolA derivatives that did not support growth, 14 were active as to the binding of lipoproteins but defective in the transfer of lipoproteins to LolB, causing the periplasmic accumulation of a lipoprotein as a complex with a LolA derivative. A LolA derivative, I93G, bound lipoproteins faster than wild-type LolA did, whereas it did not transfer associated lipoproteins to LolB. When I93G and wild type LolA co-existed, lipoproteins were bound only to I93G; which therefore exhibited a dominant negative property. Another derivative, L59R, was also defective in the transfer of lipoproteins to LolB but did not exhibit a dominant negative property. Taken together, these results indicate that both the hydrophobic cavity and the lid are critically important for not only the binding of lipoproteins but also their transfer.     

Disruption of lolCDE, encoding an ATP-binding cassette transporter, is lethal for Escherichia coli and prevents release of lipoproteins from the inner membrane

ATP-binding cassette transporter LolCDE was previously identified, by using reconstituted proteoliposomes, as an apparatus catalyzing the release of outer membrane-specific lipoproteins from the inner membrane of Escherichia coli. Mutations resulting in defective LolD were previously shown to be lethal for E. coli. The amino acid sequences of LolC and LolE are similar to each other, but the necessity of both proteins for lipoprotein release has not been proved. Moreover, previous reconstitution experiments did not clarify whether or not LolCDE is the sole apparatus for lipoprotein release. To address these issues, a chromosomal lolC-lolD-lolE null mutant harboring a helper plasmid that carries the lolCDE genes and a temperature-sensitive replicon was constructed. The mutant failed to grow at a nonpermissive temperature because of the depletion of LolCDE. In addition to functional LolD, both LolC and LolE were required for growth. At a nonpermissive temperature, the outer membrane lipoproteins were mislocalized in the inner membrane since LolCDE depletion inhibited the release of lipoproteins from the inner membrane. Furthermore, both LolC and LolE were essential for the release of lipoproteins. On the other hand, LolCDE depletion did not affect the translocation of a lipoprotein precursor across the inner membrane and subsequent processing to the mature lipoprotein. From these results, we conclude that the LolCDE complex is an essential ABC transporter for E. coli and the sole apparatus mediating the release of outer membrane lipoproteins from the inner membrane.     

Deletion of lolB, Encoding an Outer Membrane Lipoprotein, Is Lethal for Escherichia coli and Causes Accumulation of Lipoprotein Localization Intermediates in the Periplasm

Outer membrane lipoproteins of Escherichia coli are released from the inner membrane upon the formation of a complex with a periplasmic chaperone, LolA, followed by localization to the outer membrane. In vitro biochemical analyses revealed that the localization of lipoproteins to the outer membrane generally requires an outer membrane lipoprotein, LolB, and occurs via transient formation of a LolB-lipoprotein complex. On the other hand, a mutant carrying the chromosomal lolB gene under the control of the lac promoter-operator grew normally in the absence of LolB induction if the mutant did not possess the major outer membrane lipoprotein Lpp, suggesting that LolB is only important for the localization of Lpp in vivo. To examine the in vivo function of LolB, we constructed a chromosomal lolB null mutant harboring a temperature-sensitive helper plasmid carrying the lolB gene. At a nonpermissive temperature, depletion of the LolB protein due to loss of the lolB gene caused cessation of growth and a decrease in the number of viable cells irrespective of the presence or absence of Lpp. LolB-depleted cells accumulated the LolA-lipoprotein complex in the periplasm and the mature form of lipoproteins in the inner membrane. Taken together, these results indicate that LolB is the first example of an essential lipoprotein for E. coli and that its depletion inhibits the upstream reactions of lipoprotein trafficking.     

Overexpression of LolCDE allows deletion of the Escherichia coli gene encoding apolipoprotein N-acyltransferase

Bacterial lipoproteins represent a subset of membrane-associated proteins that are covalently modified with lipids at the N-terminal cysteine. The final step of lipoprotein modification, N-acylation of apolipoproteins, is mediated by apolipoprotein N-acyltransferase (Lnt). Examinations with reconstituted proteoliposomes and a conditional mutant previously indicated that N-acylation of lipoproteins is required for their efficient release from the inner membrane catalyzed by LolA and LolCDE, the lipoprotein-specific chaperone and ABC transporter, respectively. Because Lnt is essential for Escherichia coli, a mutant lacking Lnt activity has not been isolated. However, we report here that lnt-null strains can be constructed when LolCDE is overproduced in strains lacking either the major outer membrane lipoprotein Lpp or transpeptidases that cross-link Lpp with peptidoglycan. Lipoproteins purified from the lnt-null strain exhibited increased mobility on SDS-PAGE compared to those from wild-type cells and could be sequenced by Edman degradation, indicating that lipoproteins in this mutant exist as apolipoproteins that lack N-acylation. Overexpression of Lpp in the lnt-null strain resulted in the accumulation of apoLpp in the inner membrane and caused growth arrest. In contrast to the release of mature Lpp in the presence of LolA and LolCDE, that of apoLpp from the inner membrane was significantly retarded. Furthermore, the amount of lipoproteins copurified with LolCDE was significantly reduced in the lnt-null strain. These results indicate that the affinity of LolCDE for apolipoprotein is very low, and therefore, overexpression of LolCDE is required for its release and sorting to the outer membrane.     

Construction and evaluation of a plasmid vector for the expression of recombinant lipoproteins in Escherichia coli

Outer membrane lipoproteins are emerging as key targets for protective immunity to many bacterial pathogens. Heterologous expression of lipoproteins in Escherichia coli does not always result in high level expression of acylated recombinant protein. Thus, these proteins do not take up their correct membrane topology and are lacking the immunostimulatory properties endowed by the lipid. To this end, we have designed a lipoprotein expression vector (pDUMP) that results in the production of fusion proteins containing the E. coli major outer membrane lipoprotein (Lpp) signal sequence, lipoprotein signal peptidase recognition site, and the +2 outer membrane sorting signal at their N termini. To test the ability of pDUMP to express lipoproteins from heterologous hosts, the surface lipoprotein PsaA from the Gram-positive organism Streptococcus pneumoniae and the outer membrane lipoproteins MlpA from the Gram-negative Pasteurella multocida and BlpA from the spirochete Brachyspira hyodysenteriae were cloned into both hexahistidine fusion vectors and pDUMP. High level expression of antigenically active protein from both the hexahistidine fusion vectors and pDUMP resulted in abundant bands of the predicted molecular masses when analyzed by SDS-PAGE. When grown in the presence of 3[H]palmitic acid, proteins encoded by pDUMP were observed to incorporate palmitic acid whilst the hexahistidine fusion proteins did not. Using mass spectrometry and image analysis we determined the efficiency of lipidation between the three clones to vary from 31.7 to 100%. In addition, lipidated, but not hexahistidine, forms of the proteins were presented on the E. coli surface.     

Pal Lipoprotein of Escherichia coli Plays a Major Role in Outer Membrane Integrity

The Tol-Pal system of gram-negative bacteria is composed of five proteins. TolA, TolQ, and TolR are inner membrane proteins, TolB is a periplasmic protein, and Pal, the peptidoglycan-associated lipoprotein, is anchored to the outer membrane. In this study, the roles of Pal and major lipoprotein Lpp were compared in Escherichia coli. lpp and tol-pal mutations have previously been found to perturb the outer membrane permeability barrier and to cause the release of periplasmic proteins and the formation of outer membrane vesicles. In this study, we showed that the overproduction of Pal is able to restore the outer membrane integrity of an lpp strain but that overproduced Lpp has no effect in a pal strain. Together with the previously reported observation that overproduced TolA complements an lpp but not a pal strain, these results indicate that the cell envelope integrity is efficiently stabilized by an epistatic Tol-Pal system linking inner and outer membranes. The density of Pal was measured and found to be lower than that of Lpp. However, Pal was present in larger amounts compared to TolA and TolR proteins. The oligomeric state of Pal was determined and a new interaction between Pal and Lpp was demonstrated.     

Characterization of the LolA-LolB system as the general lipoprotein localization mechanism of Escherichia coli.

The major outer membrane lipoprotein (Lpp) of Escherichia coli requires LolA for its release from the cytoplasmic membrane, and LolB for its localization to the outer membrane. We examined the significance of the LolA-LolB system as to the outer membrane localization of other lipoproteins. All lipoproteins possessing an outer membrane-directed signal at the N-terminal second position were efficiently released from the inner membrane in the presence of LolA. Some lipoproteins were released in the absence of externally added LolA, albeit at a slower rate and to a lesser extent. This LolA-independent release was also strictly dependent on the outer membrane sorting signal. A lipoprotein-LolA complex was formed when the release took place in the presence of LolA, whereas lipoproteins released in the absence of LolA existed as heterogeneous complexes, suggesting that the release and the formation of a complex with LolA are distinct events. The release of LolB, an outer membrane lipoprotein functioning as the receptor for a lipoprotein-LolA complex, occurred with a trace amount of LolA, and therefore was extremely efficient. The LolA-dependent release of lipoproteins was found to be crucial for the specific incorporation of lipoproteins into the outer membrane, whereas lipoproteins released in the absence of LolA were nonspecifically and inefficiently incorporated into the membrane. The outer membrane incorporation of lipoproteins including LolB per se was dependent on LolB in the outer membrane. From these results, we conclude that lipoproteins in E. coli generally utilize the LolA-LolB system for efficient release from the inner membrane and specific localization to the outer membrane.     

Overexpression of protease-deficient DegP(S210A) rescues the lethal phenotype of Escherichia coli OmpF assembly mutants in a degP background

Replacement of OmpF's conserved carboxy-terminal phenylalanine with dissimilar amino acids severely impaired its assembly into stable trimers. In some instances, interactions of mutant proteins with the outer membrane were also affected, as judged by their hypersensitivity phenotype. Synthesis of all mutant OmpF proteins elevated the expression of periplasmic protease DegP, and synthesis of most of them made its presence obligatory for cell viability. These results showed a critical role for DegP in the event of aberrant outer membrane protein assembly. The lethal phenotype of mutant OmpF proteins in a degP null background was eliminated when a protease-deficient DegP(S210A) protein was overproduced. Our data showed that this rescue from lethality and a subsequent increase in mutant protein levels in the envelope did not lead to the proper assembly of the mutant proteins in the outer membrane. Rather, a detergent-soluble and thermolabile OmpF species resembling monomers accumulated in the mutants, and to a lesser extent in the parental strain, when DegP(S210A) was overproduced. Interestingly, this also led to the localization of a significant amount of mutant polypeptides to the inner membrane, where DegP(S210A) also fractionated. These results suggested that the DegP(S210A)-mediated rescue from toxicity involved preferential sequestration of misfolded OmpF monomers from the normal assembly pathway.     

Proton motive force drives the interaction of the inner membrane TolA and outer membrane pal proteins in Escherichia coli

The Tol-Pal system of the Escherichia coli envelope is formed from the inner membrane TolQ, TolR and TolA proteins, the periplasmic TolB protein and the outer membrane Pal lipoprotein. Any defect in the Tol-Pal proteins or in the major lipoprotein (Lpp) results in the loss of outer membrane integrity giving hypersensitivity to drugs and detergents, periplasmic leakage and outer membrane vesicle formation. We found that multicopy plasmid overproduction of TolA was able to complement the membrane defects of an lpp strain but not those of a pal strain. This result indicated that overproduced TolA has an envelope-stabilizing effect when Pal is present. We demonstrate that Pal and TolA formed a complex using in vivo cross-linking and immunoprecipitation experiments. These results, together with in vitro experiments with purified Pal and TolA derivatives, allowed us to show that Pal interacts with the TolA C-terminal domain. We also demonstrate using protonophore, K+ carrier valinomycin, nigericin, arsenate and fermentative conditions that the proton motive force was coupled to this interaction.     

Aminoacylation of the N-terminal cysteine is essential for Lol-dependent release of lipoproteins from membranes but does not depend on lipoprotein sorting signals

Lipoproteins are present in a wide variety of bacteria and are anchored to membranes through lipids attached to the N-terminal cysteine. The Lol system of Escherichia coli mediates the membrane-specific localization of lipoproteins. Aspartate at position 2 functions as a Lol avoidance signal and causes the retention of lipoproteins in the inner membrane, whereas lipoproteins having residues other than aspartate at position 2 are released from the inner membrane and localized to the outer membrane by the Lol system. Phospholipid:apolipoprotein transacylase, Lnt, catalyzes the last step of lipoprotein modification, converting apolipoprotein into mature lipoprotein. To reveal the importance of this aminoacylation for the Lol-dependent membrane localization, apolipoproteins were prepared by inhibiting lipoprotein maturation. Lnt was also purified and used to convert apolipoprotein into mature lipoprotein in vitro. The release of these lipoproteins was examined in proteoliposomes. We show here that the aminoacylation is essential for the Lol-dependent release of lipoproteins from membranes. Furthermore, lipoproteins with aspartate at position 2 were found to be aminoacylated both in vivo and in vitro, indicating that the lipoprotein-sorting signal does not affect lipid modification.     

Targeted mutagenesis of five conserved tryptophan residues of LolB involved in membrane localization of Escherichia coli lipoproteins

LolB, catalyzing the last step of lipoprotein transfer from the inner to the outer membrane of Escherichia coli, is itself a lipoprotein anchored to the outer membrane. Five Trp residues of LolB are conserved among LolB homologs in Gram-negative bacteria. These Trp residues were mutagenized to obtain defective LolB mutants. Mutation of Trp at position 52 to Pro impaired the receptor activity and caused accumulation of the LolA-lipoprotein complex in the periplasm. Similar mutants were obtained for Trp at position 117. A mutant with Gly instead of Trp at position 148 retained the receptor activity but inhibited growth upon its overproduction. The outer membrane sorting of this mutant seemed to be defective, lipoprotein transfer thereby being perturbed when it was overproduced. Despite the strong conservation, no defective mutant for Trp at position 183 was obtained, and only weak mutants were isolated for Trp at position 18. Based on the crystal structure of LolB, the phenotypes of these mutants are discussed.     

A short helix in the C-terminal region of LolA is important for the specific membrane localization of lipoproteins

The structures of a lipoprotein carrier, LolA, and a lipoprotein receptor, LolB, are similar except for an extra C-terminal loop containing a 3(10) helix and beta-strand 12 in LolA. Lipoprotein release was significantly reduced when beta-12 was deleted. Deletion of the 3(10) helix also inhibited the lipoprotein release. Furthermore, lipoproteins were non-specifically localized to membranes when LolA lacked the 3(10) helix. Thus, the membrane localization of lipoproteins with the LolA derivative lacking the 3(10) helix was independent of LolB whereas LolB was essential for the outer membrane localization of lipoproteins with the wild-type LolA.     

A novel periplasmic carrier protein involved in the sorting and transport of Escherichia coli lipoproteins destined for the outer membrane.

Lipoproteins are localized in the outer or inner membrane of Escherichia coli, depending on the species of amino acid located next to the N-terminal fatty acylated Cys. The major outer membrane lipoprotein (Lpp) expressed in spheroplasts was, however, retained in the inner membrane as a mature form. A novel protein that is essential for the release of Lpp from the inner membrane was discovered in the periplasm and purified. The partial amino acid sequence of this 20 kDa protein (p20) was determined and used to clone a gene for p20. Sequencing of the gene revealed that p20 is synthesized as a precursor with a signal sequence. p20 formed a soluble complex only with outer membrane-directed lipoproteins such as Lpp, indicating that p20 plays a critical role in the sorting of lipoproteins. Lpp released from the inner membrane in the presence of p20 was specifically assembled into the outer membrane in vitro. These results indicate that p20 is a periplasmic carrier protein involved in the translocation of lipoproteins from the inner to the outer membrane.     

Introduction of a lethal redox switch that controls the opening and closing of the hydrophobic cavity in LolA

LolA plays a critical role in the outer membrane sorting of Escherichia coli lipoproteins because it carries a hydrophobic lipoprotein from the inner membrane through the hydrophilic periplasm to the outer membrane receptor LolB. LolA has an incomplete beta-barrel structure composed of 11 beta-strands with an alpha-helical lid forming a hydrophobic cavity inside. The accompanying study revealed that the hydrophobic cavity opens and closes upon the binding and release of lipoproteins, respectively. Ile(93) in the alpha-helix and Phe(140) in the beta-strand are located close to each other in the hydrophobic cavity. These two residues were replaced by Cys to construct the I93C/F140C derivative. Expression of I93C/F140C immediately arrested growth whether wild-type LolA was present or not. However, this dominant negative phenotype was abolished by reducing agents, indicating that the intramolecular disulfide bonding between the two Cys residues is lethal. I93C/F140C was unstable, and its periplasmic level was lower than that of wild-type LolA or its single Cys derivative. Reduction of I93C/F140C was essential for the release of lipoproteins from the inner membrane. Moreover, treatment of I93C/F140C with divalent cross-linkers having different side chain lengths revealed that opening of the lid for a sufficient distance is required for the release activity. The binding of a fluorescent probe to the hydrophobic cavity of I93C/F140C also depended on reducing agents. Taken together, these results indicate that the two Cys residues introduced into LolA function as a redox switch, which regulates the opening and closing of the hydrophobic cavity.     

Roles of the Protruding Loop of Factor B Essential for the Localization of Lipoproteins (LolB) in the Anchoring of Bacterial Triacylated Proteins to the Outer Membrane

The Lol system comprising five Lol proteins, LolA through LolE, sorts Escherichia coli lipoproteins to outer membranes. The LolCDE complex, an ATP binding cassette transporter in inner membranes, releases outer membrane-specific lipoproteins in an ATP-dependent manner, causing formation of the LolA-lipoprotein complex in the periplasm. LolA transports lipoproteins through the periplasm to LolB on outer membranes. LolB is itself a lipoprotein anchored to outer membranes, although the membrane anchor is functionally dispensable. LolB then localizes lipoproteins to outer membranes through largely unknown mechanisms. The crystal structure of LolB is similar to that of LolA, and it possesses a hydrophobic cavity that accommodates acyl chains of lipoproteins. To elucidate the molecular function of LolB, a periplasmic version of LolB, mLolB, was mutagenized at various conserved residues. Despite the lack of acyl chains, most defective mutants were insoluble. However, a derivative with glutamate in place of leucine 68 was soluble and unable to localize lipoproteins to outer membranes. This leucine is present in a loop protruding from mLolB into an aqueous environment, and no analogous loop is present in LolA. Thus, leucine 68 was replaced with other residues. Replacement by acidic, but not hydrophobic, residues generated for the first time mLolB derivatives that can accept but cannot localize lipoproteins to outer membranes. Moreover, deletion of the leucine with neighboring residues impaired the lipoprotein receptor activity. Based on these observations, the roles of the protruding loop of LolB in the last step of lipoprotein sorting are discussed.     

Direct visualization of red fluorescent lipoproteins indicates conservation of the membrane sorting rules in the family Enterobacteriaceae

Chimeras created by fusing the monomeric red fluorescent protein (RFP) to a bacterial lipoprotein signal peptide (lipoRFPs) were visualized in the cell envelope by epifluorescence microscopy. Plasmolysis of the bacteria separated the inner and outer membranes, allowing the specific subcellular localization of lipoRFPs to be determined in situ. When equipped with the canonical inner membrane lipoprotein retention signal CDSR, lipoRFP was located in the inner membrane in Escherichia coli, whereas the outer membrane sorting signal CSSR caused lipoRFP to localize to the outer membrane. CFSR-RFP was also routed to the outer membrane, but CFNSR-RFP was located in the inner membrane, consistent with previous data showing that this sequence functions as an inner membrane retention signal. These four lipoproteins exhibited identical localization patterns in a panel of members of the family Enterobacteriaceae, showing that the lipoprotein sorting rules are conserved in these bacteria and validating the use of E. coli as a model system. Although most predicted inner membrane lipoproteins in these bacteria have an aspartate residue after the fatty acylated N-terminal cysteine residue, alternative signals such as CFN can and probably do function in parallel, as indicated by the existence of putative inner membrane lipoproteins with this sequence at their N termini.