Amikacin disrupts the cell envelope of Pseudomonas aeruginosa ATCC 9027

Amikacin, an aminoglycoside known to inhibit protein synthesis, was found to perturb the outer membrane of a sensitive Pseudomonas aeruginosa strain (ATCC 9027). This perturbation was monitored using electron microscopy and biochemical analyses. Following exposure to 20 micrograms amikacin/mL for 15 min, the outer membrane of exponentially growing cells lost 15% of its protein, 18% of its lipopolysaccharide, and 18% of its phosphate. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis showed that the whole spectrum of outer membrane protein and lipopolysaccharide was affected. Similarly, atomic absorption spectrophotometry revealed that magnesium and calcium were also lost. When cells were treated with amikacin, electron microscopy of negative stains showed a substantial increase in outer membrane blebbing. Freeze fractures revealed changes in membrane fracture pattern and particle distribution, and thin sections revealed a sequential disruption of the cell envelope beginning at the outer membrane and ending at the plasma membrane. This study supports the proposal that aminoglycoside antibiotics cross the outer membrane of Pseudomonas aeruginosa by displacing metal cations necessary to stabilize the organic constituents of the membrane. Their removal results in loss of the outer membrane and the formation of transient small holes which permit the antibiotic access to the cytoplasmic membrane where it is transported into the cytoplasm.     

Changes in the amount and distribution of prosomal subunits during the differentiation of U937 myeloid cells: high expression of p23K

Abstract. Prosomes (Proteasomes/Multicatalytic proteinase (MCP)-complexes) are protein particles built of 28 subunits in variable composition, having proteinase activity. We have studied the changes in prosomal subunits p29K, p31K and the highly expressed p23K during the differentiation of U937 cells. Control cells had little prosomal subunit p31K in the cytoplasm, while p29K antigen was detected in both the nucleus and cytoplasm; more p23K antigen was found in the cytoplasm than in the nucleus. Flow cytometry demonstrated a biphasic intracellular decrease in prosomes during differentiation induced by phorbol-myristic-acetate (PMA) and retinoic acid plus 1,25-dihydroxycholecalciferol (RA + VD). p23K and p29K decreased both in the cytoplasm and the nucleus of differentiated cells, though the p23K antigen was concentrated near vesicles and the plasma membrane in PMA-induced cells. The p31K antigens disappeared from RA + VD-induced cells, while in PMA-induced cells, cytoplasmic labelling was unchanged and nuclear labelling was increased. Small amounts of prosomal proteins p23K and p29K were found on the outer membrane of un-induced cells. While there was no labelling on the outer membrane of RA + VD-induced cells, p23K protein increased on the plasma membrane of PMA-induced cells. The prosome-like particle protein p21K was not present to any significant extent in the intracellular compartment of control or induced cells; however, p21K was detected on the outer surface of control cells and was increased only in PMA-induced cells. The culture medium of control and induced cells contained no p21K, p23K, p29K or p31K. RA + VD seemed to induce a general decrease of prosomal subunits within the cells and at the outer surface, whereas PMA caused a migration toward the plasma membrane and an increase at the outer surface. These changes in the distribution and type of prosomes in RA + VD- and PMA-induced cells indicate that prosomes may play a part in differentiation, especially p23K which is the most highly expressed protein among those studied and presents the more important changes.     

Physicochemical roles of soluble metal cations in the outer membrane of Escherichia coli K-12

Atomic absorption spectroscopy of isolated native and EDTA-modified (lipopolysaccharide-depleted) outer membrane revealed trace amounts of potassium, manganese, and iron (1.0-7.0 nmol/mg dry weight outer membrane). Sodium, magnesium, and calcium were approximately one order of magnitude more plentiful, but EDTA-modified outer membrane was deficient in calcium. When metal-binding assays were conducted to find the binding capacity of native and EDTA-modified outer membrane, potassium bound poorly compared with sodium. However, there was no difference in the binding of these ions between the OM preparations. In contrast, reduced amounts of magnesium, calcium, manganese, and iron III bound to the EDTA-modified OM. Partitioning of intact cells in a biphasic dextran-polyethyleneglycol system indicated that the reduced lipopolysaccharide content of the EDTA-modified outer membrane increased the hydrophobicity of the cell surface. Exposure of control and EDTA-treated cells to divalent metal salt solutions before phase partitioning also increased cell surface hydrophobicity. Freeze-etching showed that sodium ions had no effect on the membrane fractures observed in control cells, but with EDTA-treated cells, this cation increased the occurrence of small outer membrane fractures (plateaus) which are characteristic of EDTA treatment. Both magnesium and manganese increased the frequency of outer membrane cleavage in control cells, whereas calcium did not. In contrast, all three divalent metallic ions increased the frequency and extent of cleavage in the outer membrane of EDTA-treated cells.     

Co-expression of zinc binding motif and GFP as a cellular indicator of metal ions mobility

A significant role of zinc-binding motifs on metal mobility in Escherichia coli was explored using a chimeric metal-binding green fluorescent protein (GFP) as an intracellular zinc indicator. Investigation was initiated by co-transformation and co-expression of two chimeric genes encoding the chimeric GFP carrying hexahistidine (His6GFP) and the zinc-binding motif fused to outer membrane protein A (OmpA) in E. coli strain TG1. The presence of these two genes was confirmed by restriction endonucleases analysis. Co-expression of the two recombinant proteins exhibited cellular fluorescence activity and enhanced metal-binding capability of the engineered cells. Incorporation of the zinc-binding motif onto the membrane resulted in 60-fold more binding capability to zinc ions than those of the control cells. The high affinity to metal ions of the bacterial surface influenced influx of metal ions to the cells. This may affect the essential ions for triggering important cell metabolism. A declining of fluorescent intensity of GFP has been detected on the cell expressed of zinc binding motif. Meanwhile, balancing of metal homeostasis due to the presence of cytoplasmic chimeric His6GFP enhanced the fluorescent emission. These findings provide the first evidence of real-time monitoring of intracellular mobility of zinc by autofluorescent proteins.     

Respiration of metal (hydr)oxides by Shewanella and Geobacter: a key role for multihaem c-type cytochromes

Dissimilatory reduction of metal (e.g. Fe, Mn) (hydr)oxides represents a challenge for microorganisms, as their cell envelopes are impermeable to metal (hydr)oxides that are poorly soluble in water. To overcome this physical barrier, the Gram-negative bacteria Shewanella oneidensis MR-1 and Geobacter sulfurreducens have developed electron transfer (ET) strategies that require multihaem c-type cytochromes (c-Cyts). In S. oneidensis MR-1, multihaem c-Cyts CymA and MtrA are believed to transfer electrons from the inner membrane quinone/quinol pool through the periplasm to the outer membrane. The type II secretion system of S. oneidensis MR-1 has been implicated in the reduction of metal (hydr)oxides, most likely by translocating decahaem c-Cyts MtrC and OmcA across outer membrane to the surface of bacterial cells where they form a protein complex. The extracellular MtrC and OmcA can directly reduce solid metal (hydr)oxides. Likewise, outer membrane multihaem c-Cyts OmcE and OmcS of G. sulfurreducens are suggested to transfer electrons from outer membrane to type IV pili that are hypothesized to relay the electrons to solid metal (hydr)oxides. Thus, multihaem c-Cyts play critical roles in S. oneidensis MR-1- and G. sulfurreducens-mediated dissimilatory reduction of solid metal (hydr)oxides by facilitating ET across the bacterial cell envelope.     

A novel outer membrane lipoprotein, LolB (HemM), involved in the LolA (p20)-dependent localization of lipoproteins to the outer membrane of Escherichia coli.

The Escherichia coli major outer membrane lipoprotein (Lpp) is released from the inner membrane into the periplasm as a complex with a carrier protein, LolA (p20), and is then specifically incorporated into the outer membrane. An outer membrane protein playing a critical role in Lpp incorporation was identified, and partial amino acid sequences of the protein, named LolB, were identical to those of HemM, which has been suggested to play a role in 5-aminolevulinic acid synthesis in the cytosol. In contrast to this suggested role, the deduced amino acid sequence of HemM implied that the gene encodes a novel outer membrane lipoprotein. Indeed, an antibody raised against highly purified LolB revealed its outer membrane localization, and inhibited in vitro Lpp incorporation into the outer membrane. Furthermore, LolB was found to be synthesized as a precursor with a signal sequence and then processed to a lipid-modified mature form. An E.coli strain possessing chromosomal hemM under the control of the lac promoter-operator required IPTG for growth, indicating that hemM (lolB) is an essential gene. Outer membrane prepared from LolB-depleted cells did not incorporate Lpp. When the Lpp-LolA complex was incubated with a water-soluble LolB derivative, Lpp was transferred from LolA to LolB. Based on these results, the outer membrane localization pathway for E.coli lipoprotein is discussed with respect to the functions of LolA and LolB.     

Role of protein F in maintaining structural integrity of the Pseudomonas aeruginosa outer membrane.

To investigate the functional role of protein F of the outer membrane of Pseudomonas aeruginosa, we isolated mutants devoid of protein F, and the defective gene was transferred to a wild-type strain by plasmid FP5-mediated conjugation. Chemical analyses of the protein F-deficient outer membrane revealed that the amount of outer membrane protein was reduced to 72 to 74% of that of the protein F-sufficient strain and that lipopolysaccharides and phospholipids increased to 117 to 123% and 135 to 136%, respectively. The mutants and the transconjugant showed the following characteristics: (i) growth rates of protein F-deficient strains in low-osmolarity medium (e.g., L broth containing 0.1% NaCl) were less than 1/10 the rate of the protein F-sufficient strain; (ii) protein F-deficient cells were rounded, and the outer membrane formed large protruded blebs; and (iii) the outer membrane became physically fragile, since a significant amount of periplasmic proteins leaked out and the cells became highly sensitive to osmotic shock. The results suggested that protein F plays an important role in morphogenesis and in maintaining the integrity of the outer membrane. Determination of the diffusion rates of saccharides and beta-lactam antibiotics showed that the protein F-deficient outer membrane had no detectable transport defect compared with the protein F-sufficient outer membrane. The MICs of antibiotics for the protein F-deficient strains were nearly identical to those for the protein F-sufficient strain.     

Lanthanide accumulation in the periplasmic space of Escherichia coli B.

Treatment of growing Escherichia coli B with lanthanide ions [lanthanum(III), terbium(III), and europium(III)] and subsequent aldehyde-OsO4 fixation caused areas of high contrast to appear within the periplasm (the space between inner and outer membrane of the cell envelope). X-ray microanalysis of ultrathin sections of Epon-embedded or acrylic resin-embedded cells revealed the presence of the lanthanide and of phosphorus in the areas, whose contrast greatly exceeded that of other stained structures. Comparatively small amounts of the lanthanide were also present in the outer membrane and in the cytoplasm. The distribution of the periplasmic areas of high contrast was found to be random and not clustered at areas of current or future septum formation. Irregular cell shapes were observed after lanthanide treatment before onset of fixation. In contrast to glutaraldehyde-OsO4 fixation, glutaraldehyde used as the sole fixer caused a scattered distribution of the lanthanide. Cryofixation (slam-freezing) and freeze substitution revealed a lanthanum stain at both the periplasm and the outer part of the outer membrane. Deenergization of the cell membrane by either phage T4 or carbonyl cyanide m-chlorophenylhydrazone abolished the metal accumulation. Furthermore, addition of excess calcium, administered together with the lanthanide solution, diminished the quantity and size of areas of high contrast. Cells grown in media of high NaCl concentration revealed strongly stained areas of periplasmic precipitates, whereas cells grown under low-salt conditions showed very few high-contrast patches in the periplasm. Terbium treatment (during fixation) enhanced the visibility of the sites of inner-outer membrane contact (the membrane adhesion sites) in plasmolized cells, possibly as the result of an accumulation of the metal at the adhesion domains. The data suggest a rapid interaction of the lanthanides with components of the cell envelope, the periplasm, and the energized inner membrane.     

Localization and assembly into the Escherichia coli envelope of a protein required for entry of colicin A.

Mutations in tolQ, previously designated fii, render cells tolerant to high concentrations of colicin A. In addition, a short deletion in the amino-terminal region of colicin A (amino acid residues 16 to 29) prevents its lethal action, although this protein can still bind the receptor and forms channels in planar lipid bilayers in vitro. These defects in translocation across the outer membrane in the tolQ cells or the colicin A mutant cannot be bypassed by osmotic shock. The TolQ protein, which is constitutively expressed at a low level, was studied in recombinant plasmid constructs allowing the expression of various TolQ fusion proteins under the control of the inducible caa promoter. The TolQ protein was thus "tagged" with an epitope from the colicin A protein for which a monoclonal antibody is available. A fusion protein containing the entire TolQ protein plus the 30 N-terminal residues of colicin A was shown to complement the tolQ mutation. Pulse-chase labeling followed by gradient fractionation indicated that the bulk of the overproduced fusion protein was rapidly incorporated into the inner membrane, with small amounts localized to regions corresponding to the attachment sites between inner and outer membranes and to the outer membrane itself. However, most of the protein was rapidly degraded, leaving only that localized to the attachment sites and the outer membrane remaining at very late times of chase.     

Proteolytic digestion and labelling studies of the organization of the proteins in the outer membrane of Escherichia coli.

The arrangement of the proteins in the outer membrane of Escherichia coli was examined by treating intact cells and isolated membrane preparations with fluorescamine and with pronase. Intact wild-type cells, or those of a mutant in which the core region of the lipopolysaccharide was absent, were equally resistant to pronase treatment. The protein components of isolated outer membrane preparations varied in their rate of digestion and labelling with fluorescamine. The N-terminal portion of protein B was removed by pronase to yield a fragment (protein Bp) still embedded in the membrane. Protein Bp was not significantly enriched in nonpolar amino acids, suggesting that protein B may not be held in the membrane primarily by hydrophobic interactions. This was confirmed by reconstitution experiments in which protein B could be reassociated with itself, without lipopolysaccharide or phospholipid, in the presence of divalent cation such that pronase digestion of the reassociated material gave protein Bp.     

Composition and properties of the outer cell wall layer in Bacillus brevis--the producer of gramicidin S

Two membrane antigens were found by cross immunoelectrophoresis in the cell walls of Bacillus brevis var. G.-B., R form, which started to synthesize gramicidin S (20 mg per 1 ml of cultural broth). The cell wall contained no membrane components in cells at the beginning of the logarithmic growth phase. The protein with a molecular mass of 100 kDa is a component of the cell wall outer layer. The protein is not digested by trypsin or pronase when it comprises the cell walls of cells synthesizing gramicidin S. In the preparation of isolated cell walls, this protein becomes susceptible to the action of the above proteases only when the peptidoglycan layer is broken down by lysozyme. Electron microscopy of cells treated with proteases and shadowed with a metal revealed that many cells lacked the cytoplasm. Therefore, the outer layer of B. brevis R cell wall contains small regions susceptible to the action of protease along with regions composed of the 100 kDa protein and resistant to these enzymes. It is possible that the small regions contain membrane components.     

Lipid fluidity-dependent biosynthesis and assembly of the outer membrane proteins of E. coli.

The reduction of the membrane lipids of E. coli to a nonfluid state resulted in the accumulation in the cell envelope of a high molecular weight precursor of the protoIG protein, a major outer membrane protein. The protoIG protein was as sensitive to trypsin as the mature toIG protein assembled in the outer membrane. In contrast to the toIG protein, however, the accumulated protoIG protein was easily released from the envelope fraction by both sodium lauryl sarcosinate extraction and sonication. This indicated that the precursor protein was loosely associated with the cell membrane. When a fluid lipid state was restored, the protoIG protein was processed to the mature form which was then correctly assembled in the outer membrane. These results suggest that the protoIG protein produced under nonfluid lipid conditions was properly translocated across the cytoplasmic membrane, but could not be assembled in the outer membrane due either to the reversible inhibition of the processing of the ProtoIG to the toIG protein or to the lack of interaction with a specific outer membrane component(s). Reduced lipid fluidity also caused various alterations in the biosynthesis and assembly of other membrane proteins. In addition to the toIG protein, a large number of new proteins were accumulated in the membrane. Alternatively, the matrix protein as well as the promatrix protein were not detected in the cell envelope. On the other hand, the lipoprotein was normally produced, processed, modified and assembled in the outer membrane. These results indicate that the outer membrane proteins are synthesized and assembled according to several different mechanisms, on which the physical state of the membrane has various effects.     

Architecture of the outer membrane of Escherichia coli K12. I. Action of phospholipases A2 and C on wild type strains and outer membrane mutants.

Phospholipids in whole cells of wild type Escherichia coli K12 are not degraded by exogenous phospholipases, whereas those of isolated outer membranes are completely degraded. It is concluded that the resistance of phospholipids in whole cells is due to shielding by one or more other outer membrane components. The nature of the shielding component(s) was investigated by testing the sensitivity of whole cells of a number of outer membrane mutants. Mutants lacking both major outer membrane proteins b and d or the heptose-bound glucose of their lipopolysaccharide, are sensitive to exogenous exogenous phospholipases. Moreover, cells of a mutant which lacks protein d can be sensitized by pretreatment of the cells with EDTA. From these results and from data on the chemical composition of the outer membranes, it is concluded that proteins b and d, the heptose-bound glucose of lipopolysaccharide and divalent cations are responsible for the inaccessibility of phospholipids to to exogenous phospholipases.     

Insertion of a MalE β-Galactosidase Fusion Protein into the Envelope of Escherichia coli Disrupts Biogenesis of Outer Membrane Proteins and Processing of Inner Membrane Proteins

The synthesis of a membrane-bound MalE β-galactosidase hybrid protein, when induced by growth of Escherichia coli on maltose, leads to inhibition of cell division and eventually a reduced rate of mass increase. In addition, the relative rate of synthesis of outer membrane proteins, but not that of inner membrane proteins, was reduced by about 50%. Kinetic experiments demonstrated that this reduction coincided with the period of maximum synthesis of the hybrid protein (and another maltose-inducible protein, LamB). The accumulation of this abnormal protein in the envelope therefore appeared specifically to inhibit the synthesis, the assembly of outer membrane proteins, or both, indicating that the hybrid protein blocks some export site or causes the sequestration of some limiting factor(s) involved in the export process. Since the MalE protein is normally located in the periplasm, the results also suggest that the synthesis of periplasmic and outer membrane proteins may involve some steps in common. The reduced rate of synthesis of outer membrane proteins was also accompanied by the accumulation in the envelope of at least one outer membrane protein and at least two inner membrane proteins as higher-molecular-weight forms, indicating that processing (removal of the N-terminal signal sequence) was also disrupted by the presence of the hybrid protein. These results may indicate that the assembly of these membrane proteins is blocked at a relatively late step rather than at the level of primary recognition of some site by the signal sequence. In addition, the results suggest that some step common to the biogenesis of quite different kinds of envelope protein is blocked by the presence of the hybrid protein.     

Architecture of the outer membrane of Escherichia coli K12. I. Action of phospholipases A2 and C on wild type strains and outer membrane mutants

Phospholipids in whole cells of wild type Escherichia coli K12 are not degraded by exogenous phospholipases, whereas those of isolated outer membranes are completely degraded. It is concluded that the resistance of phospholipids in whole cells is due to shielding by one or more other outer membrane components. The nature of the shielding component(s) was investigated by testing the sensitivity of whole cells of a number of outer membrane mutants. Mutants lacking both major outer membrane proteins b and d or the heptose-bound glucose of their lipopolysaccharide, are sensitive to exogenous phospholipases. Moreover, cells of a mutant which lacks protein d can be sensitized by pretreatment of the cells with EDTA. From these results and from data on the chemical composition of the outer membranes, it is concluded that proteins b and d, the heptose-bound glucose of lipopolysaccharide and divalent cations are responsible for the inaccessibility of phospholipids to exogenous phospholipases.     

Integration of the overproduced bacteriophage T5 receptor protein in the outer membrane of Escherichia coli

The tonA gene codes for an outer membrane protein, a receptor of phage T5, the TonA protein. Strains harboring pLG513, a multicopy plasmid in which the tonA gene has been cloned, overproduced TonA protein, which appeared in sodium dodecyl sulfate-polyacrylamide gel electrophoresis of cell envelope proteins as a 78,000-molecular-weight protein. Identical results have been observed by Plastow et al. (FEBS Lett. 131:262-264, 1981) with plasmid pLC19-19, in which the tonA gene has also been cloned. The activity of the TonA protein, measured by its capacity to inactivate phage T5, increased by five- to sixfold in purified envelopes of cells harboring pLG513 compared with cells lacking the plasmid. Solubilization of the cytoplasmic membrane by Triton-Mg2+ treatment did not increase this activity. However, partial solubilization of outer membrane proteins by Triton-EDTA unmasked further T5 receptor activity, resulting in a final increase of around 50-fold, a value more consistent with the expected gene dosage effect. Treatment of whole cells by trypsin in conditions in which trypsin is allowed to enter the outer membrane revealed that part of the overproduced T5 receptors were embedded in the outer membrane and masked by a trypsin-sensitive protein. In addition, no T5 receptor activity was detected in either the periplasmic space or the cytoplasm. These results suggest that all of the overproduced TonA molecules were synthesized in an active form and integrated in the outer membrane, but only a small fraction could be reached or recognized by phage T5 in vivo.     

The receptor of bacteriophage lambda: evidence for a biosynthesis dependent on lipid synthesis

Inhibition of lipid synthesis in cerulenin-treated cells or in a mutant strain defective in sn-glycerol-3-phosphate acyltransferase after glycerol deprivation, results in a marked decrease of insertion of lamB protein into the outer membrane. No lambda receptor was found in any other cell compartment or in the medium under these conditions. The LamB protein synthesis was inhibited by about 70% in the absence of lipid synthesis. The residual 30% protein produced during inhibition of fatty-acid or phospholipid synthesis, was probably incorporated into the outer membrane since no further incorporation was observed after resumption of these syntheses. Besides OmpF and OmpC protein [Bocquet-Pagès, C., Lazdunski, C., and Lazdunski, A. (1981) Eur. J. Biochem. 118, 105-111], at least four other proteins of the outer membrane are also subject to alteration of levels in the absence of lipid synthesis. Under these conditions the uptake of maltose, like the uptake of 5'AMP [Bocquet-Pagès, C., Lazdunski, C., and Lazdunski, A. (1981) Eur. J. Biochem. 118, 105-111], was inhibited as much as 60%. These results are discussed with regard to the biosynthesis and assembly of the outer membrane proteins.     

The proton motive force drives the outer membrane transport of cobalamin in Escherichia coli.

Cells of Escherichia coli pump cobalamin (vitamin B12) across their outer membranes into the periplasmic space, and it was concluded previously that this process is potentiated by the proton motive force of the inner membrane. The novelty of such an energy coupling mechanism and its relevance to other outer membrane transport processes have required confirmation of this conclusion by studies with cells in which cobalamin transport is limited to the outer membrane. Accordingly, I have examined the effects of cyanide and of 2,4-dinitrophenol on cobalamin uptake in btuC and atp mutants, which lack inner membrane cobalamin transport and the membrane-bound ATP synthase, respectively. Dinitrophenol eliminated cobalamin transport in all strains, but cyanide inhibited this process only in atp and btuC atp mutant cells, providing conclusive evidence that cobalamin transport across the outer membrane requires specifically the proton motive force of the inner membrane. The coupling of metabolic energy to outer membrane cobalamin transport requires the TonB protein and is stimulated by the ExbB protein. I show here that the tolQ gene product can partly replace the function of the ExbB protein. Cells with mutations in both exbB and tolQ had no measurable cobalamin transport and thus had a phenotype that was essentially the same as TonB-. I conclude that the ExbB protein is a normal component of the energy coupling system for the transport of cobalamin across the outer membrane.     

Immunochemical characterization of the outer membrane complex of Serratia marcescens and identification of the antigens accessible to antibodies on the cell surface

Serratia marcescens New CDC O14:H12 contains major outer membrane proteins of 43.5 kDal, 42 kDal (the porins) and 38 kDal (the OmpA protein) which can be separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Immunoblotting of whole cell or outer membrane preparations using antiserum raised against the whole cells revealed similar complex patterns of antigens. The OmpA protein was the major immunogen, although six other outer membrane proteins were also detected; the porins reacted only weakly with antibodies in this system. Immunoabsorption of antisera with whole cells showed that only the O antigenic chains of lipopolysaccharide and the H (flagella) antigens were accessible to antibody on the cell surface. Failure to detect the OmpA protein and other envelope antigens in this way suggests that their antigenic sites are not able to react with antibodies and are possibly masked by the O antigen.     

Nature of the regions involved in the insertion of newly synthesized protein into the outer membrane of Escherichia coli.

Outer membrane proteins are synthesized by cytoplasmic membrane-bound polysomes, and inserted at insertion sites which cover about 10% of the total outer membrane when cells grow with a generation time of 1 h. A membrane fraction enriched in outer membrane insertion regions was isolated and partly characterized. The rat at which newly inserted proteins are transferred from such insertion regions into the rest of the outer membrane was found to be very fast; the new protein content of insertion regions and that of the remaining outer membrane equilibrate completely within about 20 s at 25 degrees C. Given the rather rigid structure of the outer membrane and the multiple interactions between outer membrane components and the murein layer, lateral diffusion of newly inserted proteins from insertion sites to the remaining outer membrane is not likely to explain this rapid equilibration. Instead, the data support a model in which insertion regions move along the cell surface, leaving behind stationary, newly inserted outer membrane proteins.