Structures of Gram-Negative Cell Walls and Their Derived Membrane Vesicles

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Journal of Bacteriology, August 1999, p. 4725-4733, Vol. 181, No. 16
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

MINIREVIEW
Structures of Gram-Negative Cell Walls and Their Derived Membrane Vesicles

Terry J. Beveridge^*

Canadian Bacterial Disease Network, and Department of Microbiology, College of Biological Science, University of Guelph, Guelph, Ontario, Canada N1G 2W1

	INTRODUCTION

Top Introduction References

Gram-negative cell walls are strong enough to withstand ~3 atm of turgor pressure (40), tough enough to endure extreme temperaturesand pHs (e.g., Thiobacillus ferrooxidans grows at a pH of $approx$ 1.5)and elastic enough to be capable of expanding several times theirnormal surface area (41). Strong, tough, and elastic ... the gram-negativecell wall is a remarkable structure which protects the contentsof the cell and which has stood the test of time for many, manyyears. Presumably, these three descriptive traits, have much todo with the tremendous success gram-negative bacteria have hadas a life-form on our planet; members of the domain Bacteria inhabitalmost all imaginable habitats except those excruciatingly extremeenvironments in which (some) members of the domain Archaea thrive.Molecular biological methods have not yet given scientists a precisehistorical record of the origin of gram-negative bacteria, butancient stromatolites containing fossilized remains of cyanobacterium-likeprokaryotes date back to the Archean eon. Over such extraordinaryperiods of time (much of it when no other life existed), we canimagine that random mutation, selection, and the slowly but ever-changingglobal environment gave rise to two fundamentally different cellwall formats in Bacteria; gram-positive and gram-negative varieties.Gram-positive cell walls, once thought to be relatively simplestructural entities, can be quite different from one another,especially when cell wall turnover is taken into account (8,9, 25, 29). The cell walls of gram-negative bacteria followa more general structural format than that of gram-positive bacteria,which is strictly adhered to; gram-negative bacteria have an outermembrane situated above a thin peptidoglycan layer. Sandwichedbetween the outer membrane and the plasma membrane, a concentratedgel-like matrix (the periplasm) is found in the periplasmic space(7, 9). Because the periplasm exists above the plasma membrane,it is not part of the protoplast, and because the periplasm isdifferentiated from the external environment by the outer membrane,it is not part of the "outside." It is in fact an integral compartmentof the gram-negative cell wall (5). Together the plasma membraneand the cell wall (outer membrane, peptidoglycan layer, and periplasm)constitute the gram-negative envelope (5, 9).

Our entire perception of gram-positive and gram-negative walls ultimately relies on the response of bacteria to Gram staining.Unwittingly, in 1884, Christian Gram developed a staining regimenfor light microscopy which differentiated between these two typesof bacteria because of the chemical composition and structuralformat of their cell walls. Because gram-negative bacteria possessa lipid-rich outer membrane (as well as a plasma membrane) anda thin peptidoglycan layer, the alcohol decolorizing step of Gramstaining washes the primary stain (crystal violet) from the cellsand the secondary stain (carbol fuchsin or saffranin) colors thebacteria red (57). Gram-positive bacteria are enshrouded inthicker, more resilient cell walls which do not allow the crystalviolet to be removed and, accordingly, remain purple (57). Althoughthe vast majority of bacteria adhere to the color differentiationof the Gram stain, to the chagrin of microbiological taxonomists,some bacteria refuse to obey; these are called gram-variable bacteria(6). Members of the Archaea cannot be easily differentiatedby Gram staining (10). Interestingly, the staining responseof gram-variable bacteria and archaea is also due to their cellwall composition and structure (6, 10).

Advances in identifying gram-negative cell wall components, their cytoplasmic synthetic and plasma membrane translocationroutes, and their individual functional attributes have been electrifyingover the last decade. This is primarily due to their intricatedissection by modern molecular techniques. There are several up-to-datereviews describing specific gram-negative cell wall systems whichemphasize their molecular biological aspects (28, 56, 60),and I will not revisit them in thisminireview.

	OUTER MEMBRANE

Although layers that are more external (such as capsules, S-layers, and sheaths) (5) can reside above the outer membrane,this lipid-protein bilayer is usually considered to be the outermostlayer of the gram-negative wall. It is a membrane which possessesproteins, phospholipids, and lipopolysaccharides (LPSs) and whichseparates the external environment from the periplasm. Becausebacteria rely on diffusion for nutrition and the disseminationof wastes, the outer membrane must be porous to certain substances(hence the addition of porins which assemble into pores) (e.g.,15) and must be capable of transporting others (e.g., iron).Even hydrophobic compounds can also make their way through (54).Yet, the outer membrane cannot be too porous, since larger periplasmicconstituents which are vital to the cell's livelihood must beretained. For example, the periplasm contains binding proteinsfor amino acids, sugars, vitamins, and ions, as well as degradativeand detoxifying enzymes. It can also act as a reservoir for suchsurface-associated components as certain pilins, S-layer proteins,and virulence factors (e.g., proelastin of Pseudomonas aeruginosa)(19, 39). Because of the concentration of these constituentsand so-called membrane-derived oligosaccharides (38), the osmolarityof the periplasm may approach the osmolarity of the cytoplasm.Koch recently argued that an osmotic gradient does not exist overthe outer membrane (40).

One of the few ways in which researchers can image the outer membrane has been with a transmission electron microscope (TEM).This membrane has been difficult to preserve for TEM observation.Although some of the outer membrane proteins (OMPs) can be associatedwith the underlying peptidoglycan layer (e.g., Braun's lipoproteinin Escherichia coli), many of the bilayer constituents (especiallythe lipids) are fluid and in continual rapid motion. This is oftena difficult concept for researchers to understand; at the nanoscalelevel, components such as LPS are constantly in motion. They moveat high speeds laterally around the cell, and they are, at thesame time, rotating on their long axis. Even the O-side chainsare flexing back and forth and seem to be driven entirely by entropy(53). Environmental conditions (e.g., temperature) and molecularassociations (e.g., LPS-OMP interactions) affect freemotion.

For electron microscopy, researchers have to (somehow) instantaneously stop the movement of molecules in the membrane anddenature any degradative enzymes which could affect bilayer structure.At the same time, underlying supportive structures for the membrane(such as the periplasm and peptidoglycan layer) must be accuratelymaintained and preserved. Traditionally, a procedure using conventionalembedding and thin sectioning has been considered to be one ofthe best ways to examine the outer membrane. For this, extremelytoxic chemical fixatives (such as glutaraldehyde and osmium tetroxide)are used to increase the covalent bonding in the specimen so thatit can withstand organic solvent dehydrating and plastic embeddingprotocols. Fixation, dehydration, and embedding rely on the diffusionof the chemical agents into the specimen (often at room temperature),and the process takes hours. Delicate structures, such as membranes,are notoriously poorly preserved, the periplasm is extracted,and the outer membrane usually shows an artificial wavy configuration(Fig. 1).

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FIG. 1. Thin section of the cell envelope of E. coli K-12 after conventional embedding. The periplasmic space is empty of substance, and the peptidoglycan layer (PG), outer membrane (OM), and plasma membrane (PM) can be seen. Bar = 100 nm.

With the recognition that extremely rapid freezing of biological samples could physically fix their structure, almost instantaneously,the technique of freeze-etching began to be used in microbiology.In this technique, bacteria are frozen so rapidly that vitreous(or amorphous) ice forms and molecular motion stops. The ice-cellmatrix is a hard solid and can be fractured in a freeze-etchingdevice. Since the fracture plane follows the regions of leastbond energy within a cell, membranes are most frequently cleavedthrough their hydrophobic domains and intrinsic membrane proteinsare exposed. Fortuitous fractions through gram-negative bacteriacan reveal the inner and outer faces of membranes by exposingconcave and convex surfaces (Fig. 2). Freeze-etching of a largevariety of gram-negative bacteria has consistently shown thatthe outer membrane is strongly bonded together, and for this reason,fractions through its hydrophobic domain are rare; the preferredfracture plane is through the plasma membrane (Fig. 2).

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FIG. 2. Freeze-etching of two E. coli K-12 cells in which the fracture planes have travelled through the cell envelope. The upper cell shows concave fractures through the outer membrane (OM) and plasma membrane (PM), whereas the lower cell shows convex fractures of the same membranes. The particles (or holes) in these membrane fractures correspond to intramembranous protein complexes. The arrowhead in the upper right-hand corner of the image points out the shadow direction. Bar = 500 nm. (Reprinted from reference 9.)

The newer cryotechnique of freeze-substitution has been more informative. Here, cells are rapidly frozen (as with freeze-etching)and immersed in a cryosubstitution mixture of osmium tetroxideand uranyl acetate in anhydrous acetone, and the mixture was heldat $-$ 80°C for 48 h (26). The bacteria are chemically fixed, stained,and dehydrated while being maintained in an ultrafrozen state.Eventually, they can be embedded in plastic at room temperatureand thin sectioned. Kazunobu Amako's group in Japan was the firstto apply freeze-substitution to a gram-negative bacterium (1)and produced remarkable images of E. coli that made all microscopistswho study microorganisms reevaluate their previous work. Thiswas soon followed by the remarkable images of E. coli's cell envelopefrom Eduard Kellenberger's group in Switzerland for which theterm periplasmic gel was coined (30). Here, for the first time,was tangible microscopic proof that a rich, dense periplasm existedin the periplasmic space of a gram-negativecell.

One of the unusual features of the outer membrane is its asymmetric distribution of lipids over its inner and outer faces.The outer face contains (virtually) all of the LPS, whereas theinner face has most of the phospholipid. LPS contains more chargeper unit of surface area than any phospholipid, and most of thischarge is anionic at neutral pH because of exposed phosphoryland carboxyl groups which can be readily ionized. The outer faceof the outer membrane is highly charged and is highly interactivewith cations in the outside milieu, so interactive, in fact, thatthese anionic groups can be sites for the development of fine-grainedminerals in natural environments (22). This reactivity of LPSis also convenient for the study of the outer membrane by TEMsince the outer face reacts strongly with heavy metal stains ifthe lipid asymmetry is retained. Freeze-substitution preservesthis asymmetry (Fig. 3) and reveals the length and distributionof the LPS O-side chains (Fig. 4). It is not uncommon to findmore than one LPS species on an outer membrane at a time. P. aeruginosaPAO1 has two LPS moieties; A-band LPS (the common antigen) whichis a short chain and neutral in charge, and B-band LPS (serotypeLPS) which is a longer chain and (overall) electronegative. Freeze-substitutionhas shown that the O-side chains of B-band LPS can extend up to40 nm from the outer membrane (Fig. 4) (43). Images such asthese have suggested that O-side chains are frequently in theirextended conformation (43).

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FIG. 3. Freeze-substitution image of the E. coli K-12 cell envelope for direct comparison with Fig. 1. The periplasmic space is filled with periplasm (P) (the so-called periplasmic gel), and the peptidoglycan layer is not visible. The outer face of the outer membrane (OM) is densely stained, because the LPS retains its asymmetric location in this region of the bilayer and is more highly charged than the phospholipid on the inner face of the OM. The periplasm is bounded by the OM and the plasma membrane (PM). Bar = 25 nm. (Reprinted from reference 9.)

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FIG. 4. Freeze-substitution image of the P. aeruginosa PAO1 cell envelope showing the long O-side chains of the B-band LPS extending ~40 nm from the face of the outer membrane (arrow). Bar = 35 nm. (Reprinted from reference 9.)

However, recent atomic force microscopy (AFM) measurements have not verified this observation (64), which presents an enigma.In these experiments, AFM was used as a pressure-measuring techniquewhere the AFM tip is lowered down to the level where it can firstmonitor pressure resistance from the surface molecules. For isolatedB-band LPS, resistance cannot be detected until the AFM tip is~10 nm from the surface of a LPS micelle (Fig. 5). This then begsthe question ... how can a cryoelectron microscopical techniqueshow B-band O-side chains extending up to 40 nm away from theouter membrane's bilayer structure and AFM pressure measurementsdetect the O-side chains only ~10 nm away? To solve this discrepancy,several B-band LPS molecules have been dynamically modeled togetherusing brush theory as they interact with one another on the outermembrane's surface. Remarkably, this analysis has shown the O-sidechains to be in constant motion; the side chains are flexing androtating continuously so that only a proportion of the chainsare in their ~40-nm-extended configuration at a single point intime (Fig. 6). These are the side chains that are captured ina single instant by the rapid-freezing, freeze-substitution technique(Fig. 4). Because longer times are required to perform an AFMpressure measurement and because the O-side chains are so rapidlymoving, the pressure measurements do not detect the flexible O-sidechains but detect only the core oligosaccharide molecules attachedto lipid A which have more restricted movement.

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FIG. 5. AFM tracing over a single hot-phenol-extracted A- and B-band LPS micelle from P. aeruginosa PAO1 obtained under water (pH 7.0) after the micelle had attached to a silicon nitride surface. The 12-nm height (Z on the y axis) of the vesicle represents both the lower and upper faces of the LPS bilayer and is consistent with only the lipid A plus the core oligosaccharide being detected on the 300-nm-diameter micelle. Yet, sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the preparation showed that the O-side chains of both LPSs are present, and freeze-substitution images of intact outer membrane surfaces (Fig. 4) revealed that the B-band O-side chain extends ~40 nm. We believe the O-side chains are so rapidly moving under the aqueous conditions of our AFM experiment that the AFM tip cannot detect them.

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FIG. 6. Schematic diagram showing the different alignments (i.e., movement) of the B-band O-side chains of P. aeruginosa as we perceive them from the AFM experiments shown in Fig. 5 (53). The model assumes that all ionizable groups are charged. The core oligosaccharide and lipid A moieties are not shown but would be at the bottom of the diagram.

This rapid motion of O-side chains has important consequences. The B-band side chains are charged with an overall electronegative(anionic) charge at neutral pH. Intuitively, the chains should(then) interact with environmental electrolytes such as multivalentmetal ions. They should be salt bridged by ions, such as Ca²⁺, Cu²⁺, Mg²⁺, or Fe³⁺, and be relatively immobile. This does not seem to be the case(44). It is possible that the side chains are moving so rapidlythat metal ion salt bridges are not energetically possible. Ifthis were true, then the same binding constraints should applyto other ionizable external components such as immunoglobulinsor even components on bacteriophage tails or phagocytotic cells(i.e., receptors). Certainly, these components do bind to bacterialsurfaces but maybe the length of LPS O-side chains and their rapidmotion could, in a general way, affect how strongly such externalcomponents caninteract.

	PERIPLASM AND MEMBRANE VESICLES (MVS)

Cryo-TEM has not helped in the elucidation of the peptidoglycan layer (or murein sacculus) of gram-negative bacteria. Thisis not so much because the layer is not preserved as well as usualbut because it is difficult to see it in thin sections of freeze-substitutedcells. Cryopreservation has retained so much substance in theperiplasmic space (where the peptidoglycan layer resides) thatthe layer is obscured (Fig. 3) (1, 9, 27, 30). For thefirst time, researchers can actually see how much material residesin the periplasmic space, which indirectly points out the importanceof this region to the vitality of gram-negative cells. Periplasmicenzymes, trafficking proteins, secreted materials, and newly synthesizedouter membrane- or peptidoglycan layer-directed components allreside in this space at some point during the bacterium's metaboliclife (7). It is possible that membrane junctions occur betweenouter and plasma membranes (the so-called Bayer's junctions) toaid in the transfer of outgoing materials (3), but the peptidoglycanlayer still separates the two membranes at these junctions. Freeze-substitution,though, has certainly revealed so much substance within the periplasmthat it should behave as a gel (30).

Periplasm. It is important to recognize the full scope of the variety of macromolecules that can inhabit the periplasm of a gram-negativebacterium. It is clear that a bacterium relies on environmentalsignals to influence its synthesis and secretion pathways. Quorumsensing can help coordinate such a response in relatively largebacterial populations or even in biofilms (13, 16, 52).For example, many of the virulence factors of P. aeruginosa, whichis an opportunistic pathogen often implicated in cystic fibrosis,require induction before they are secreted (51). In fact, evenosmotic differences between the cytoplasm and periplasm can triggerthe production of membrane-derived oligosaccharides (38). Theperiplasm, then, is a region between the two bilayered membranesof the gram-negative cell envelope which is in dynamic flux possessingan ever-changing variety of macromolecules which reflect the cell'smetabolic and environmentalstatus.

MVs. Gram-negative cell walls have a dynamic feature that is not seen in their gram-positive counterparts ... outer membrane vesiclesare constantly being discharged from the surface of the cell duringbacterial growth. As the vesicles are being extruded from thesurface, they entrap some of the underlying periplasm so thatthey are actually small particles of gram-negative cell wall.They possess OMPs, LPS, phospholipids, and periplasmic constituents,all situated as they normally would be in a bacterium, but ona much smaller scale. These 50- to 250-nm-diameter spherical,bilayered, membranous structures (Fig. 7) are released from thesurfaces of virtually all gram-negative bacteria (11, 34,47). Reports of these vesicles date back ~30 years (47), andadditional reports have been published since then (17, 18,21, 32, 42, 45, 59, 61, 62, 65). The general importanceof their release has recently been recognized, and they are calledmembrane vesicles or MVs (11, 32, 34). MVs are found emanatingfrom gram-negative bacteria growing in the planktonic or biofilmmode (12), on solid or liquid media (34), as swarming cultures(23), and in natural environments (Fig. 8) (12). The MVs fromP. aeruginosa have been the most intensively studied (30-32, 45).

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FIG. 7. Negative-stained n-MVs which have been isolated and purified from P. aeruginosa as previously described (32). Bar = 250 nm.

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FIG. 8. Thin section of an unidentified gram-negative bacterium found in a freshwater biofilm in a river near laboratory. This bacterium possesses a microcapsule and is liberating a prodigious amount of MVs. Bar = 1 µm.

As MVs form blebs from the outer membrane, they encapsulate periplasm so that once they are free of the bacterium, the MVbecomes a small membrane-bound vessel of periplasmic constituents(Fig. 9). This phenomenon was aptly demonstrated for P. aeruginosaMVs, since they were found to contain protease, phospholipaseC, alkaline phosphatase, and an autolysin (32, 33, 45).These MVs also contained proelastase which was proof of periplasmencapsulation, since the pro amino acid sequence is cleaved fromthe enzyme only after translocation across the outer membraneduring its normal secretion (19, 39). It is important to recognizethat the method by which MVs are released from gram-negative cellsurfaces ensures that the natural outer membrane arrangement isgenerally maintained. The normal low curvature of the outer membrane(while it resides on the bacterium) is abruptly changed to thehigh-curvature form of the vesicle (Fig. 9), but LPS, phospholipids,and OMPs are still integral constituents of the MV's bilayer,and the outer membrane LPS-phospholipid asymmetry is retained(32). Interestingly, there is one important alteration fromnormal outer membranes in the P. aeruginosa system. Instead ofpossessing both A- and B-band LPS (as the outer membrane does),only B-band (or serotype-specific) LPS is present in MVs (32).Somehow, P. aeruginosa, by pooling B-band LPS into small, localizedregions on its outer membrane, forces the membrane of these regionsinto high-curvature structures, thereby encouraging the formationof blebs and release of MVs (32).

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FIG. 9. Thin section of P. aeruginosa PAO1 showing the development of n-MVs before they are liberated from the cell. The arrow points to one vesicle in which the membrane bilayer and the periplasm within its lumen (i.e., electron-dense area inside the vesicle) can be seen. Bar = 250 nm.

Peptidoglycan hydrolases of MVs. Gram-negative bacterial periplasm normally contains autolysins which along with penicillin-binding proteins are used to helpfabricate the peptidoglycan layer as a bacterium grows. Becauseof this, it is possible that MVs entrap a proportion of thesepeptidoglycan-hydrolyzing enzymes during MVformation.

P. aeruginosa produces 11 autolysins which can be renatured after hot sodium dodecyl sulfate extraction (4). One of theseautolysins, the major 26-kDa peptidoglycan hydrolase (PGase) ispackaged into MVs (45). There seemed to be little point forthis PGase encapsulation until experiments were devised to seewhether the MVs could affect the integrity of other bacteria.Remarkably, MVs can lyse other bacteria as long as these bacteriaare suffering from low nutrition and growing poorly (46). MVscan attack both gram-positive and -negative bacteria, and thepotency of MV attack depends on the peptidoglycan chemotype ofthe attacked cells; those with chemotypes identical or similarto the chemotype of P. aeruginosa (A1 $gamma$ ) were readily lysed. Acloser inspection by electron microscopy revealed that MVs attackgram-positive and -negative surfaces in a different manner (33).For gram-positive bacteria, MVs adhere to the surface of the cellwall, break open, and hydrolyze the peptidoglycan immediatelyunder the adherence junction. The same mechanism occurs even ifthe cell wall has a S-layer on top of it (36); presumably, afterthe MV has broken open, the 26-kDa PGase can penetrate the latticenetwork of the S-layer and attack the underlying cell wall. Inthis way, whether or not gram-positive cells possess a S-layer,MVs attack their surfaces through a single-hit route which producesa single large lesion in the cell wall (33).

MVs attack gram-negative bacteria in a much different manner. Here, MVs adhere to the outer membrane and rapidly fuse intoit (33). In so doing, the luminal contents (including the PGase)are released directly into the periplasmic space of the recipientcell. Once inside the periplasmic space, the PGase can fully diffusearound the protoplast and hydrolyze the peptidoglycan layer ata number of different sites so that multisite lysis canoccur.

MV-mediated lysis of bacteria does not readily occur if the recipient cells are actively growing and dividing; it occurs onlywhen they are under the constraints of poor nutrition. Presumably,with active growth, the MV-induced cell wall lesions can be repairedby the recipient's normal cell wall turnover cycle, and as thecell grows and divides, the MV PGase is gradually diluted. Becausepoor growth conditions are required for efficient killing of otherbacteria by MVs, we have speculated that MVs are a predatory responseby the donor cell (in this case, P. aeruginosa) to increase itsnutrient load under poor environmental conditions (33). TheMVs lyse surrounding foreign bacteria, thereby liberating highlycomplex nutritious constituents for the use of donor cells. Theidea of foreignness is important in this concept; MVs would notkill neighboring cells of an identical strain (i.e., those surroundingthe donor) because the MV PGase would be one of their own normalautolysins and could be regulated as such. In this way, MVs wouldbenefit the entire population of a single or identical clone ina natural environment. Since MVs are frequently encountered inbiofilms (12), this could be one way in which microcoloniesretain their integrity and sustenance at the expense of the surroundingmicroflora.

MVs and virulence. The pathogenicity of a variety of gram-negative bacterial pathogens relies, at least in part, on their ability to secretea number of virulence factors into the menstruum surrounding theirtargeted tissue (e.g., hemolysin, aerolysin, verotoxin, etc.).These factors diffuse into the tissue and begin to break it down.Yet, free diffusion of such metabolically expensive macromoleculescan be wasteful. Once free of the pathogen, the factors are dilutedby diffusion, and external host constituents (e.g., hydrolyticenzymes, antibodies, and other serum constituents) can inactivatethem.

MVs could provide an alternative route for the delivery of virulence factors. For example, the MVs of P. aeruginosa, Proteusmirabilis, and Serratia marcescens package phospholipase C, proteases,proelastase, and hemolysins (23, 24, 32). It is probablethat MVs from Borrelia, enterotoxigenic E. coli, Haemophilus,Neisseria, and Vibrio species also contribute to the virulenceof these other pathogens (17, 42, 59, 61, 62). The constituentswhich are packaged into the lumens of MVs are protected from theaction of inactivating environmental enzymes by the MV's bilayerwhich contains LPS, phospholipids, and OMPs. Because LPS is endotoxicand OMPs can be highly antigenic, MVs can be even more antagonisticto thehost.

Recently, it has been discovered that a chromosome-encoded $beta$ -lactamase in P. aeruginosa (an enzyme which normally hydrolyzes $beta$ -lactam antibiotics in the periplasm of these cells) can alsobe packaged into MVs (14). This raises the intriguing possibilitythat $beta$ -lactamase-containing MVs could be discharged from pathogensat their infection sites in tissue to increase the breakdown of $beta$ -lactam antibiotics in the local tissue environment. BecauseMVs contain porins as part of their OMP complement, the antibioticreadily diffuses into these MVs and is inactivated. This couldbe a general strategy for reducing antibiotic concentrations atinfection sites, and it could also be one of the ways in whichchronic, hard-to-treat infections (such as cystic fibrosis) aremaintained by the infecting bacterium (14). Since MVs can readilyfuse to the outer membranes of a wide range of other gram-negativebacterial pathogens (37), thereby emptying their luminal contentsinto the periplasm of recipient cells, $beta$ -lactamase (and otherantibiotic-inactivating enzymes) could be physically transferredfrom a donor cell to a non- $beta$ -lactamase-producing recipient (e.g.,following the cystic fibrosis analogy, from P. aeruginosa [donor]to Burkholderia cepacia [recipient]). In this way, a varied groupof gram-negative nonproducers in close proximity to a donor cellcould withstand antibiotic treatment and contribute to the infectionwithout these same bacteria having the genetic capacity to producethe inactivating enzyme themselves. This type of synergy betweenpathogens has not been suggested before and certainly requiresfurther investigation. Interestingly, a study by Dorward et al.(18) has shown that MV-mediated transfer of an antibiotic resistanceplasmid can occur between two strains of Neisseria gonorrhoeae.It is therefore possible that MVs influence antibiotic resistancein other bacteria in two ways: the physical dissemination of preformedantibiotic-inactivating enzymes into their periplasm and the deliveryof antibiotic resistance plasmids to nonproducingstrains.

Possible medical application of MVs. Early in our research with P. aeruginosa MVs, we learned that membrane surface-active agents such as gentamicin could increasethe production of MVs about threefold (32). In so doing, smallamounts of the aminoglycoside became entrapped in the MVs. Gentamicin-containingMVs (g-MVs) also differ from natural MVs (n-MVs) by containingsmall amounts of A-band LPS in addition to B-band LPS. g-MVs havea greater size variability than n-MVs, and they sometimes containplasma membrane and small amounts of DNA (32). Yet, the increasedproduction of MVs and their retention of gentamicin (~5 to 10ng of gentamicin per µg of MV protein) make g-MVs a tempting vehiclefor antibiotic delivery to hard-to-kill pathogens. For example,g-MVs can kill Pseudomonas spp. which are normally impermeableto aminoglycoside antibiotics (33). This is because g-MVs fuseto the normally impermeable outer membrane of the resistant strainand deliver gentamicin into the periplasm where it can be activelyimported to the cytoplasm and inhibit protein synthesis. Althoughg-MVs possess small amounts of gentamicin, the antibiotic is targetedto the correct region of the cell for strong inhibitoryeffect.

Aminoglycoside antibiotics also have trouble entering eukaryotic tissue to inhibit the growth of intracellular bacterial pathogens.Recent experimentation with Shigella flexneri g-MVs (these contain85 ng of gentamicin per µg of MV protein [35]) has revealedthat these particular MVs contain the invasion proteins (49,50) of this intracellular pathogen. For this reason, when epithelialcell lines are treated with S. flexneri g-MVs, the vesicles areengulfed by the tissue cells and the gentamicin is eventuallyfound in the eukaryotic cytoplasm (35). Indeed, when this sametissue was first infected with S. flexneri and then treated withS. flexneri g-MVs, a substantial quantity (~1.5 log₁₀ CFU) ofthe intracellular pathogen was cleared from the tissue within60 min because the g-MVs conveyed gentamicin to the cells (35).

These experiments suggest that MVs could be used to deliver drugs to a number of different prokaryotic and eukaryoticsystems.

Another possible medical application for MVs (in this case, n-MVs) is as new vaccine agents, because when MVs are releasedfrom the bacterium, they contain the surface identity of the donorbacterium. The LPS is serotype LPS and is strain specific, andthe same is true for the OMPs. Important, highly antigenic virulencefactors are also present. Strains of P. mirabilis and S. marcescenswhich possess adhesins (pili or fimbriae) also have these structuresassociated with the MVs (23, 24). Clearly, MVs are stronglyantigenic particulate structures which could also possess naturaladjuvant qualities for enhancing an immuneresponse.

A major obstacle in the use of MVs as particulate vaccines is the presence of endotoxic LPS; if this substance cannot be detoxified,the use of MVs as vaccine agents would be limited to oral routeadministration. Since detoxification requires chemical manipulationof the lipid A of LPS and, possibly, reformulation of MV compositionand structure, it may be more promising to look more closely atadministering MVs via the oral route. MVs from a number of gram-negativepathogens can be integrated into the outer membranes of membersof the family Enterobacteriaceae (37), and it may be possibleto use oral, attenuated vaccine strains containing incorporatedforeign MVs as multiepitope vaccinecandidates.

Are MVs a new form of secretion? Over the last 2 decades, a number of different secretion systems have been elucidated (55). Most systems involve steps necessaryto translocate a preformed polypeptide across the plasma membrane.During this translocation, the polypeptide can be matured (e.g.,a signal sequence can be cleaved off or disulfur bonds can beformed from thiols) (2, 20, 31, 55) so that the periplasmicform is different from the originally synthesized form. In addition,some periplasmic polypeptides must undergo further transformationbefore they are expelled into the external milieu (e.g., proelastaseis cleaved as it passes through the outer membrane to become activeelastase) (19, 39), or two (or more) periplasmic componentscan anneal together only after they have been expelled (e.g.,subunits A and B of cholera toxin [48]). Only in rare instancesare the polypeptides actively translocated through the outer membrane(58, 63). Usually, simple diffusion through outer membranepores is invoked for the vast number of these relatively largecompounds, sometimes with the assistance of outer membrane-plasmamembrane adhesion zones (3). Certainly they do make it throughthis last limiting membrane, and soluble secretion products canbe readily found in the externalfluid.

Are these the only routes for the final secretion steps of such compounds? Maybe not. MVs appear to be an alternative routewhich, so far, has been poorly recognized by those in the secretionfield. Yet, the evidence is undeniable ... MVs are produced by virtuallyall gram-negative bacteria, they are commonly filled with componentsconsidered to be secretion products, and they have the capacityto protect these products by their limiting membrane as they areconveyed to other cells, whether these cells be prokaryotic oreukaryotic.

Are MVs a new form of secretion? Intuitively, MVs are not a brand-new structural device for gram-negative bacteria. Becauseof their complexity, they must have slowly evolved into the systemswe see today ... we have just not recognized their importance untilrecently!

	ACKNOWLEDGMENTS

Some of the research reviewed here comes from the work of students, postdoctoral fellows, and scientists who have passed throughmy laboratory over the last few years. They will know who theyare, and I thank them all. The biophysical aspects of LPS weredone in collaboration with M. Jericho, Dalhousie University, andD. Pink, St. Francis XavierUniversity.

My research has been supported by grants from the Natural Sciences and Engineering Council (both Research and Major FacilitiesAccess grants) and from the Canadian Bacterial Disease Networkwhich is a National Centre ofExcellence.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology, College of Biological Science, University of Guelph, Guelph,Ontario, Canada N1G 2W1. Phone: (519) 824-4120, ext. 3366. Fax:(519) 837-1802. E-mail: tjb{at}micro.uoguelph.ca.

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Bjerre, A., Brusletto, B., Rosenqvist, E., Namork, E., Kierulf, P., Ovstebo, R., Joo, G.-B., Brandtzaeg, P. (2000). Cellular activating properties and morphology of membrane-bound and purified meningococcal lipopolysaccharide. Innate Immunity 6: 437-445 [Abstract]
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Pink, D., Moeller, J., Quinn, B., Jericho, M., Beveridge, T. (2000). On the Architecture of the Gram-Negative Bacterial Murein Sacculus. J. Bacteriol. 182: 5925-5930 [Abstract] [Full Text]
Yaron, S., Kolling, G. L., Simon, L., Matthews, K. R. (2000). Vesicle-Mediated Transfer of Virulence Genes from Escherichia coli O157:H7 to Other Enteric Bacteria. Appl. Environ. Microbiol. 66: 4414-4420 [Abstract] [Full Text]
Howell, M. L., Alsabbagh, E., Ma, J.-F., Ochsner, U. A., Klotz, M. G., Beveridge, T. J., Blumenthal, K. M., Niederhoffer, E. C., Morris, R. E., Needham, D., Dean, G. E., Wani, M. A., Hassett, D. J. (2000). AnkB, a Periplasmic Ankyrin-Like Protein in Pseudomonas aeruginosa, Is Required for Optimal Catalase B (KatB) Activity and Resistance to Hydrogen Peroxide. J. Bacteriol. 182: 4545-4556 [Abstract] [Full Text]
Prangishvili, D., Holz, I., Stieger, E., Nickell, S., Kristjansson, J. K., Zillig, W. (2000). Sulfolobicins, Specific Proteinaceous Toxins Produced by Strains of the Extremely Thermophilic Archaeal Genus Sulfolobus. J. Bacteriol. 182: 2985-2988 [Abstract] [Full Text]
Horstman, A. L., Kuehn, M. J. (2000). Enterotoxigenic Escherichia coli Secretes Active Heat-labile Enterotoxin via Outer Membrane Vesicles. J. Biol. Chem. 275: 12489-12496 [Abstract] [Full Text]
Wilhelm, S., Tommassen, J., Jaeger, K.-E. (1999). A Novel Lipolytic Enzyme Located in the Outer Membrane of Pseudomonas aeruginosa. J. Bacteriol. 181: 6977-6986 [Abstract] [Full Text]

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MINIREVIEW Structures of Gram-Negative Cell Walls and Their Derived Membrane Vesicles

MINIREVIEW
Structures of Gram-Negative Cell Walls and Their Derived Membrane Vesicles