Role of murein lipoprotein in morphogenesis of the bacterial division septum: phenotypic similarity of lkyD and lpo mutants.

Phenotypes were compared in two different classes of mutants with defects in murein-lipoprotein (lkyD mutants of Salmonella typhimurium and an lpo mutant of Escherichia coli). Both mutations are associated with the same triad of phenotypic abnormalities, consisting of defective formation of the division septum, leakage of periplasmic proteins during growth, and increased sensitivity to several unrelated external toxic agents. The abnormality in septum formation consists of a defect in invagination of the outer membrane during formation of the nascent septum. The results suggest that formation of the murein-lipoprotein link plays an important role in differentiation of the division septum and perhaps also in maintaining the normal barrier function of the outer membrane.     

<Emphasis Type="Italic">Escherichia coli tat</Emphasis> mutant strains are able to transport maltose in the absence of an active <Emphasis Type="Italic">malE</Emphasis> gene

The twin-arginine transport (Tat) system is a prokaryotic protein transport system. Escherichia coli mutants in this pathway show a defect in cell separation during cell division, resulting in destabilization and permeability of the outer membrane. Maltose uptake is catalysed by a membrane-bound transporter of the ATP binding cassette (ABC) superfamily, where MalE is the essential periplasmic binding protein component. Here, we report that tat mutants are unexpectedly able to transport maltose in the absence of malE. This observation is specific to the MalE component since co-inactivation of malF, which encodes one of the channel components of the transporter, completely abolishes maltose transport even when the Tat system is inactivated. Genetic repair of the outer membrane leaky phenotype of the tat mutant strain re-established the absolute requirement for MalE in maltose uptake. In addition, we demonstrate that phenotypic repair of the outer membrane defect of the tat strain can also be achieved chemically by the inclusion of high concentrations of calcium or magnesium in the growth medium.     

Protein Excretion through Bleb Formation by PE4LA,a Mutant of Escherichia coli

A mutant of E. coli (PE4LA) excreted approximately 15% of total cellular protein without cell lysis. The materials in the culture supernatant of the mutant were precipitated with 5% cold TCA. Protein, lipopolysaccharide (LPS), and phospholipid were found in a ratio of approximately 5:6:1. In electrophoretical analyses, exoproteins appeared to contain both periplasmic and outer membrane proteins.

An electron microscopic study showed that PE4LA cells had many blebs around the cell surface and that these blebs were surrounded by double track layers. Some vesicles were also observed as free forms of blebs, while the parent cells had neither blebs nor vesicles. The vesicles appeared to be rich in LPS and lacked phosphatidylglycerol, compared to the outer membrane.

The physiological and morphological data suggested alterations in the PE4LA cell surface, but what was altered remains obscure. It was concluded that PE4LA cells do not have a substantial increase in permeability, but rather have some defect in the cell envelope organization, which causes the formation of blebs with periplasmic proteins.     

Biosynthesis and structure of lipopolysaccharide in an outer membrane-defective mutant of Escherichia coli J5

Membrane-defective mutants of Escherichia coli J5 were isolated on the basis of supersensitivity to the antibiotic novobiocin. These mutants display an increased sensitivity to a wide range of antibiotics and to several dyes and detergents. In addition, several mutants leak the periplasmic enzymes, alkaline phosphatase and ribonuclease. This evidence indicates an outer membrane defect in these mutants. The inner and outer membranes of one mutant were separated and subjected to compositional analysis. A deficiency in galactose-containing lipopolysaccharide in the outer membrane of the mutant was observed. Two possible causes of this deficiency were examined and discounted: defective galactose uptake into the cell, and defective translocation of lipopolysaccharide from the inner membrane. Extraction and chemical analysis of mutant and wild type lipopolysaccharides suggests that the mutant is defective in the enzyme which transfers glucose to the growing lipopolysaccharide core, UDPglucose transferase. Thus, the mutant's deficiency in galactose-containing lipopolysaccharide can be ascribed to the fact that addition of glucose to the lipopolysaccharide core is a prerequisite for galactose addition. The physiological implications of this alteration are discussed.     

Accumulation of periplasmic enterobactin impairs the growth and morphology of Escherichia coli tolC mutants

TolC is the outer membrane component of tripartite efflux pumps, which expel proteins, toxins and antimicrobial agents from Gram‐negative bacteria. Escherichia coli tolC mutants grow well and are slightly elongated in rich media but grow less well than wild‐type cells in minimal media. These phenotypes have no physiological explanation as yet. Here, we find that tolC mutants have highly aberrant shapes when grown in M9‐glucose medium but that adding iron restores wild‐type morphology. When starved for iron, E. coli tolC mutants synthesize but cannot secrete the siderophore enterobactin, which collects in the periplasm. tolC mutants unable to synthesize enterobactin display no growth or morphological defects, and adding exogenous enterobactin recreates these aberrations, implicating this compound as the causative agent. Cells unable to import enterobactin across the outer membrane grow normally, whereas cells that import enterobactin only to the periplasm become morphologically aberrant. Thus, tolC mutants grown in low iron conditions accumulate periplasmic enterobactin, which impairs bacterial morphology, possibly by sequestering iron and inhibiting an iron‐dependent reaction involved in cell division or peptidoglycan synthesis. The results also highlight the need to supply sufficient iron when studying TolC‐directed export or efflux, to eliminate extraneous physiological effects.     

Aperiplasmic protein (Skp) of Escherichia coli selectively binds a class of outer membrane proteins

A search was performed for a periplasmic molecular chaperone which may assist outer membrane proteins of Escherichia coli on their way from the cytoplasmic to the outer membrane. Proteins of the periplasmic space were fractionated on an affinity column with sepharose-bound outer membrane porin OmpF. A 17kDa polypeptide was the predominant protein retained by this column. The corresponding gene was found in a gene bank; it encodes the periplasmic protein Skp. The protein was isolated and it could be demonstrated that it bound outer membrane proteins, following SDS-PAGE, with high selectivity. Among these were OmpA, OmpC, OmpF and the maltoporin LamB. The chromosomal skp gene was inactivated by a deletion causing removal of most of the signal peptide plus 107 residues of the 141-residue mature protein. The mutant was viable but possessed much-reduced concentrations of outer membrane proteins. This defect was fully restored by a plasmid-borne skp gene which may serve as a periplasmic chaperone.     

Mutational change of membrane architecture. Mutants of Escherichia coli K12 missing major proteins of the outer cell envelope membrane

Mutant of Escherichia coli have been analyzed which miss two of the major proteins of the outer cell envelope membrane. The two proteins I and II1, normally are present at high concentrations (about 10⁵ copies per cell).In such mutants, as compared with wild type, the phospholipid-to-protein ratio in the outer membrane has increased by a factor of 2.3 causing a considerable difference in density between wild type and mutant membranes. The concentrations of two other major components of the outer membrane, lipopolysaccharide and Braun's lipoprotein, did not change.The protein-deficient mutants do not exhibit gross functional defects in vitro. An increased sensitivity to EDTA and a slight such increase to dodecyl sulfate (but not to deoxycholate or Triton X-100) was observed, loss of so-called periplasmic enzymes was not found, and other differences to wild type are marginal. The mutants can grow with normal morphology. It is not possible, however, to prepare “ghosts” (particles of size and shape of the cell without murein, surrounded by a derivative of the outer membrane, and posssessing the major proteins of this membrane) from them. This fact confirms our earlier suggestion that the proteins in question are required for the shape maintenance phenomenon in ghosts, and the mutants reject the speculation that these proteins are involved in the expression of the genetic information specifying cellular shape.Freeze-fracturing showed that in mutant cells, and in sharp contrast to wild type, the far predominant fracture plane is within the outer membrane. The concentration of the well known densely packed particles at the outer, concave leaflet of this fracture plane is greatly reduced. It was not possible, however, to clearly establish that one or the other protein is part of these particles because these ultrastructural differences were not apparent in mutants missing either one of the proteins only. The biochemical and ultrastructural data allow the conclusion that the loss of two major proteins and the concomitant increase of phospholipid concentration has changed the architecture of the outer membrane from a highly oriented structure. with a large fraction of protein-protein interaction, to one predominantly exhibiting planar lipid bilayer characteristics. E. coli thus can assemble rather different outer membranes, afact excluding that outer membrane formatin constitutes a highly ordered or strictly sequential assembly-line process.     

Biosynthesis and structure of lipopolysaccharide in an outer membrane-defective mutant of Escherichia coli J5.

Membrane-defective mutants of Escherichia coli J5 were isolated on the basis of supersensitivity to the antibiotic novobiocin. These mutants display an increased sensitivity to a wide range of antibiotics and to several dyes and detergents. In addition, several mutants leak the periplasmic enzymes, alkyline phosphatase and ribonuclease. This evidence indicates an outer membrane defect in these mutants. The inner and outer membranes of one mutant were separated and subjected to compositional analysis. A deficiency in galactose containing lipopolysaccharide in the outer membrane of the mutant was observed. Two possible causes of this deficiency were examined and discounted: defective galactose uptake into the cell, and defective translocation of lipopolysaccharide from the inner membrane. Extraction and chemical analysis of mutant and wild type lipopolysaccharides suggests that the mutant is defective in the enzyme which transfers glucose to the growing lipopolysaccharide core, UDPglucose transferase. Thus, the mutant's deficiency in galactose-containing lipopolysaccharide can be ascribed to the fact that addition of glucose to the lipopolysaccharide core is a prerequisite for galactose addition. The physiological implications of this alteration are discussed.     

Role of the periplasmic domain of the Escherichia coli NarX sensor-transmitter protein in nitrate-dependent signal transduction and gene regulation

The narX, narQ and narL genes of Escherichia coli encode a nitrate-responsive two-component regulatory system that controls the expression of many anaerobic electron-transport- and fermentation-related genes. When nitrate is present, the NarX and NarQ sensor-transmitter proteins function to activate the response-regulator protein, NarL, which in turn binds to its DNA-recognition sites to modulate gene expression. The sensor-transmitter proteins are anchored in the cytoplasmic membrane by two transmembrane domains that are separated by a periplasmic region of ≈115 amino acids. In this study we report the isolation and characterization of narX* (star) mutants that constitutively activate nitrate reductase (narGHJI) gene expression and repress fumarate reductase (frdABCD) gene expression when no nitrate is provided for the cell. An additional narX mutant was identified that has lost its ability to respond to environmental signals. Each narX defect was caused by a single amino acid substitution within a conserved 17 amino acid sequence, called the ‘P-box’, in the periplasmic exposed region of the NarX protein. As a result, DNA binding is then ‘locked-on’ or ‘locked-off’ to give the observed pattern of gene expression. Diploid analysis of these narX mutants showed that a NarX P-box mutant which confered a ‘locked-on’ phenotype was trans dominant over wild-type NarX. Both were also trans dominant over the NarX P-box mutant which conferred a ‘locked-off’ phenotype. Certain narX P-box mutations, when combined with a narX‘linker’ region mutation, were recessive to the NarX linker mutation. Finally, a truncated form of the NarX protein that lacked the periplasmic and membrane regions also showed a ‘locked-on’ phenotype in vivo. Thus, the periplasmic and membrane domains are essential for signal transduction to NarL. From these findings, we propose that nitrate is detected in the periplasmic space of the cell, and that a signal-transduction event through the cytoplasmic membrane into the interior of the cell modulates the NarX-dependent phosphorylation/dephosphorylation of NarL.     

An essential role for UshA in processing of extracellular flavin electron shuttles by Shewanella oneidensis

The facultative anaerobe Shewanella oneidensis can reduce a number of insoluble extracellular metals. Direct adsorption of cells to the metal surface is not necessary, and it has been shown that S. oneidensis releases low concentrations flavins, including riboflavin and flavin mononucleotide (FMN), into the surrounding medium to act as extracellular electron shuttles. However, the mechanism of flavin release by Shewanella remains unknown. We have conducted a transposon mutagenesis screen to identify mutants deficient in extracellular flavin accumulation. Mutations in ushA, encoding a predicted 5′‐nucleotidase, resulted in accumulation of flavin adenine dinucleotide (FAD) in culture supernatants, with a corresponding decrease in FMN and riboflavin. Cellular extracts of S. oneidensis convert FAD to FMN, whereas extracts of ushA mutants do not, and fractionation experiments show that UshA activity is periplasmic. We hypothesize that S. oneidensis secretes FAD into the periplasmic space, where it is hydrolysed by UshA to FMN and adenosine monophosphate (AMP). FMN diffuses through outer membrane porins where it accelerates extracellular electron transfer, and AMP is dephosphorylated by UshA and reassimilated by the cell. We predict that transport of FAD into the periplasm also satisfies the cofactor requirement of the unusual periplasmic fumarate reductase found in Shewanella.     

Involvement and necessity of the Cpx regulon in the event of aberrant β‐barrel outer membrane protein assembly

The Cpx and σ^E regulons help maintain outer membrane integrity; the Cpx pathway monitors the biogenesis of cell surface structures, such as pili, while the σ^E pathway monitors the biogenesis of β‐barrel outer membrane proteins (OMPs). In this study we revealed the importance of the Cpx regulon in the event of β‐barrel OMP mis‐assembly, by utilizing mutants expressing either a defective β‐barrel OMP assembly machinery (Bam) or assembly defective β‐barrel OMPs. Analysis of specific mRNAs showed that ΔcpxR bam double mutants failed to induce degP expression beyond the wild type level, despite activation of the σ^E pathway. The synthetic conditional lethal phenotype of ΔcpxR in mutant Bam or β‐barrel OMP backgrounds was reversed by wild type DegP expressed from a heterologous plasmid promoter. Consistent with the involvement of the Cpx regulon in the event of aberrant β‐barrel OMP assembly, the expression of cpxP, the archetypal member of the cpx regulon, was upregulated in defective Bam backgrounds or in cells expressing a single assembly‐defective β‐barrel OMP species. Together, these results showed that both the Cpx and σ^E regulons are required to reduce envelope stress caused by aberrant β‐barrel OMP assembly, with the Cpx regulon principally contributing by controlling degP expression.     

Efficient production of heat-labile enterotoxin mutant proteins by overexpression of dsbA in a degP-deficient Escherichia coli strain

Escherichia coli heat-labile enterotoxin (LT) mutants containing Val⁶⁰→Gly or Ser¹¹⁴→Lys substitutions in the A subunit do not produce the A subunit efficiently in E. coli. These mutants accumulate mostly the B pentamer devoid of the A subunit in the periplasmic space. Here we show that overproduction of the periplasmic chaperone DsbA, which is involved in disulfide bond formation, in a strain deficient in the periplasmic protease DegP allows efficient production of the mutant LT molecules. Our results suggest that the formation of the oligomeric toxin is influenced by DsbA, which helps protein folding, and by DegP, which removes the folded intermediates that can be untoxic for the cell. Received: 30 October 1996 / Accepted: 8 January 1997     

Cell envelope proteins involved in the transport of maltose and sn-glycerol-3-phosphate in Escherichia coli

Two types of proteins are discussed in their role of facilitating the transport of maltose and sn-glycerol-3-phosphate in E. coli. The first protein is the receptor for phage δ, known to be an outer membrane protein. By facilitating the diffusion of maltose and the higher maltodextrins through the outer membrane the effect of the δ receptor is to decrease the K_m of the transport system without influencing the V_max of substrate flux. The second protein is a periplasmic protein that is induced by growth on glycerol and is essential for transport of sn-glycerol-3-phosphate in whole cells but not in membrane vesicles. This protein has solely been identified by the use of a two-dimensional polyacrylamide gel electrophoresis of periplasmic proteins in wild-type and mutants defective in sn-glycerol-3-phosphate transport.     

Mutants that overproduce TraTp, a plasmid-specified major outer membrane protein of Escherichia coli

Summary The isolation of a series of plasmid mutant derivatives that overproduce the traT outer membrane protein, TraTp, is described. Some of the mutants directed the synthesis of 10-fold more TraTp (200,000 copies/cell) than did the parental plasmid (20,000 copies/cell). The proteins specified by all mutant plasmids except one were correctly inserted into the outer membrane and exposed on the cell surface. The TraTp that was not correctly inserted did not mediate the expected levels of surface exclusion and serum resistance, suggesting that surface localization is a requirement of TraTp function. The overproduction of TraTp was deleterious to bacterial growth, particularly that of minicell mutants of E. coli K-12.     

A synergistic role for two predicted inner membrane proteins of Escherichia coli in cell envelope integrity

The bacterial cytoplasmic membrane is a principal site of protein translocation, lipid and peptidoglycan biogenesis, signal transduction, transporters and energy generating components of the respiratory chain. Although 25–30% of bacterial proteomes consist of membrane proteins, a comprehensive understanding of their influence on fundamental cellular processes is incomplete. Here, we show that YciB and DcrB, two small cytoplasmic membrane proteins of previously unknown functions, play an essential synergistic role in maintaining cell envelope integrity of Escherichia coli. Lack of both YciB and DcrB results in pleiotropic cell defects including increased levels of lipopolysaccharide, membrane vesiculation, dynamic shrinking and extension of the cytoplasmic membrane accompanied by lysis and cell death. The stalling of an abundant outer membrane lipoprotein, Lpp, at the periplasmic face of the inner membrane leads to lethal inner membrane–peptidoglycan linkages. Additionally, the periplasmic chaperone Skp contributes to yciB dcrB mutant cell death by possibly mistargeting stalled porins into the inner membrane. Consistent with the idea of a compromised envelope in the yciB dcrB mutant, multiple envelope stress response systems are induced, with Cpx signal transduction being required for growth. Taken together, our results suggest a fundamental role for YciB and DcrB in cell envelope biogenesis.     

Examination of AsmA and its effect on the assembly of Escherichia coli outer membrane proteins

asmA mutations were isolated as extragenic suppressors of an OmpF assembly mutant, OmpF315. This suppressor locus produced a protein that was present in extremely low levels and could only be visualized by Western blotting in cells where AsmA expression was induced from a plasmid. Detailed fractionation analyses showed that AsmA localized with the inner membrane. Curiously, however, the mutant OmpF assembly step influenced by AsmA occurred in the outer membrane, perhaps indicating an indirect involvement of AsmA in the assembly of outer membrane proteins. Biochemical examination of the outer membrane showed that asmA null mutations reduce lipo-polysaccharide (LPS) levels, thereby lowering the ratios of glycerolphospholipids to LPS and envelope proteins to LPS in the outer membrane. Despite these quantitative alterations, no apparent structural changes in LPS or major phospholipids were noted. Reduced LPS levels in asmA mutants indicate a possible role of AsmA in LPS biogenesis. Data presented in this study suggest that asmA-mediated OmpF assembly suppression may have been achieved by altering the outer membrane fluidity, thus making it more amenable for the assembly of mutant proteins.     

Skp, a molecular chaperone of gram-negative bacteria, is required for the formation of soluble periplasmic intermediates of outer membrane proteins.

Using a cross-linking approach, we have analyzed the function of Skp, a presumed molecular chaperone of the periplasmic space of Escherichia coli, during the biogenesis of an outer membrane protein (OmpA). Following its transmembrane translocation, OmpA interacts with Skp in close vicinity to the plasma membrane. In vitro, Skp was also found to bind strongly and specifically to pOmpA nascent chains after their release from the ribosome suggesting the ability of Skp to recognize early folding intermediates of outer membrane proteins. Pulse labeling of OmpA in spheroplasts prepared from an skp null mutant revealed a specific requirement of Skp for the release of newly translocated outer membrane proteins from the plasma membrane. Deltaskp mutant cells are viable and show only slight changes in the physiology of their outer membranes. In contrast, double mutants deficient both in Skp and the periplasmic protease DegP (HtrA) do not grow at 37 degrees C in rich medium. We show that in the absence of an active DegP, a lack of Skp leads to the accumulation of protein aggregates in the periplasm. Collectively, our data demonstrate that Skp is a molecular chaperone involved in generating and maintaining the solubility of early folding intermediates of outer membrane proteins in the periplasmic space of Gram-negative bacteria.     

Translocation of green fluorescent protein to cyanobacterial periplasm using ice nucleation protein

The translocation of proteins to cyanobacterial cell envelope is made complex by the presence of a highly differentiated membrane system. To investigate the protein translocation in cyanobacterium Synechococcus PCC 7942 using the truncated ice nucleation protein (InpNC) from Pseudomonas syringae KCTC 1832, the green fluorescent protein (GFP) was fused in frame to the carboxyl-terminus of InpNC. The fluorescence of GFP was found almost entirely as a halo in the outer regions of cells which appeared to correspond to the periplasm as demonstrated by confocal laser scanning microscopy, however, GFP was not displayed on the outermost cell surface. Western blotting analysis revealed that InpNC-GFP fusion protein was partially degraded. The N-terminal domain of InpNC may be susceptible to protease attack; the remaining C-terminal domain conjugated with GFP lost the ability to direct translocation across outer membrane and to act as a surface display motif. The fluorescence intensity of cells with periplasmic GFP was approximately 6-fold lower than that of cells with cytoplasmic GFP. The successful translocation of the active GFP to the periplasm may provide a potential means to study the property of cyanobacterial periplasmic substances in response to environmental changes in a non-invasive manner.     

The Bradyrhizobium japonicum fsrB gene is essential for utilization of structurally diverse ferric siderophores to fulfill its nutritional iron requirement

In Bradyrhizobium japonicum, iron uptake from ferric siderophores involves selective outer membrane proteins and non-selective periplasmic and cytoplasmic membrane components that accommodate numerous structurally diverse siderophores. Free iron traverses the cytoplasmic membrane through the ferrous (Fe²⁺) transporter system FeoAB, but the other non-selective components have not been described. Here, we identify fsrB as an iron-regulated gene required for growth on iron chelates of catecholate- and hydroxymate-type siderophores, but not on inorganic iron. Utilization of the non-physiological iron chelator EDDHA as an iron source was also dependent on fsrB. Uptake activities of ⁵⁵Fe³⁺ bound to ferrioxamine B, ferrichrome or enterobactin were severely diminished in the fsrB mutant compared with the wild type. Growth of the fsrB or feoB strains on ferrichrome were rescued with plasmid-borne E. coli fhuCDB ferrichrome transport genes, suggesting that FsrB activity occurs in the periplasm rather than the cytoplasm. Whole cells of an fsrB mutant are defective in ferric reductase activity. Both whole cells and spheroplasts catalyzed the demetallation of ferric siderophores that were defective in an fsrB mutant. Collectively, the data support a model whereby FsrB is required for reduction of iron and its dissociation from the siderophore in the periplasm, followed by transport of the ferrous ion into the cytoplasm by FeoAB.     

Isolation and characterization of mutants of a marine Vibrio strain that are defective in production of extracellular proteins

A marine Vibrio strain, Vibrio sp. strain 60, produces several extracellular proteins, including protease, amylase, DNase, and hemagglutinin. Mutants of Vibrio sp. strain 60 (epr mutants) pleiotropically defective in production of these extracellular proteins were isolated. They fell into two classes, A and B. In class A, no protease activity was detected in the cells either, whereas in class B, considerable protease activity was detected in the cells. Gel electrophoretic analysis revealed that the protease detected in class B mutant cells was similar to the protease excreted by the parent strain. In addition, the protease in class B mutant cells was found to be localized in the periplasmic space. These results suggest that the passage of the protease through the outer membrane is blocked in class B mutants. Comparison of membrane protein profiles by polyacrylamide gel electrophoresis revealed that all the epr mutants contained an increased amount of a 94,000-Mr protein that may be an outer membrane protein. Four epr mutations were mapped in two different regions of the Vibrio chromosome by transduction; two class A mutations and one class B mutation were located close to each other, whereas another class B mutation was located in a different region of the chromosome.