Structural studies of the membrane-derived oligosaccharides of Escherichia coli.

Membrane-derived oligosaccharides are a novel class of glucose-containing oligosaccharides found in the cell envelope of Escherichia coli and other Gram-negative organisms (Schulman, H., AND Kennedy, E.P. (1979) J. Bacteriol. 137, 686-688). Previous work has shown that these oligosaccharides contain sn-1-glycero-P and smaller amounts of phosphoethanolamine, derived from membrane phospholipids, attached to position 6 of certain of the glucose residues. The structure of the parent oligosaccharides (obtained by reduction with borohydride followed by alkaline hydrolysis) has now been studied. The oligosaccharide was permethylated, followed by hydrolysis and conversion of the products to methylated glucitol acetates, which were then analyzed and identified by gas-liquid chromatography and mass spectrometry. The membrane oligosaccharides contain 10 to 12 D-glucopyranoside residues/mol, linked solely by 1 yields 2 and 1 yields 6 bonds. They are highly branched structures, with four nonreducing termini per mol. Glucose units at the branch points are doubly substituted at positions 2 and 6. The low specific rotation of the oligosaccharide (+8.3 degrees) indicates that the glycosidic bonds are predominantly or entirely beta.     

Osmotic regulation of biosynthesis of membrane-derived oligosaccharides in Escherichia coli.

The osmotic regulation of the biosynthesis of membrane-derived oligosaccharides (MDO) in strains UB1005 and DC2 of Escherichia coli K-12 was examined; this regulation was previously reported by Clark (J. Bacteriol. 161:1049-1053, 1985) to be different from that observed by Kennedy for other strains of E. coli (Proc. Natl. Acad. Sci. USA 79:1092-1095, 1982). Osmotic regulation of the synthesis of MDO in UB1005 and DC2 is in fact indistinguishable from that previously reported for other strains of E. coli, with maximum production of MDO occurring in the medium of lowest osmolarity. The report of Clark to the contrary was apparently based on the inadequate methods for the measurement of MDO employed in that study. MDO are localized in the periplasm of wild-type E. coli cells. However, strain DC2, selected for hypersensitivity to a range of antibiotics, released most of its MDO into the medium, apparently as a result of greater outer membrane permeability.     

Properties of Escherichia coli mutants lacking membrane-derived oligosaccharides

Membrane-derived oligosaccharides (MDO) consist of branched substituted beta-glucan chains and are present in the periplasmic space of Escherichia coli and other gram-negative bacteria. A procedure for the isolation of mutants defective in MDO synthesis is described. Their phenotype was compared with a mdoA mutant previously identified, and they are mapped in the mdoA region. Mutants lacking MDO showed imparied chemotaxis on tryptone swarm plates, a reduced number of flagella, and an enhanced expression of the OmpC porin. Revertants able to form swarm rings again had regained the ability to synthesize MDO and showed the wild-type porin pattern. A second group of chemotactic revertants were mutated in the ompB gene region involved in osmoregulation, and they were still devoid of MDO. These findings provide evidence for a link between MDO biosynthesis and other functions of E. coli related to its adaptation to the environment.     

Isolation and characterization of Escherichia coli mutants blocked in production of membrane-derived oligosaccharides.

We report a new procedure for the facile selection of mutants of Escherichia coli that are blocked in the production of membrane-derived oligosaccharides. Four phenotypic classes were identified, including two with a novel array of characteristics. The mutations mapped to two genetic loci. Mutations in the mdoA region near 23 min are in two distinct genes, only one of which is needed for the membrane-localized glucosyltransferase that catalyzes the synthesis of the beta-1,2-glucan backbone of membrane-derived oligosaccharides. Another set of mutations mapped near 27 min closely linked to osmZ; these appear to be in the galU gene.     

Transfer of phosphoethanolamine residues from phosphatidylethanolamine to the membrane-derived oligosaccharides of Escherichia coli.

The membrane-derived oligosaccharides (MDO) of Escherichia coli are periplasmic constituents composed of glucose residues linked by beta-1,2 and beta-1,6 glycosidic bonds. MDO are substituted with phosphoglycerol, phosphoethanolamine, and succinic acid moieties. The phosphoglycerol residues present on MDO are derived from phosphatidylglycerol (B. J. Jackson and E. P. Kennedy, J. Biol. Chem. 258:2394-2398, 1983), but evidence as to the source of the phosphoethanolamine residues has been lacking. We now report that phosphatidylethanolamine, exogenously added to intact cells of E. coli, provides a source of phosphoethanolamine residues that are transferred to MDO. The biosynthesis of phosphoethanolamine-labeled MDO is osmotically regulated, with maximum synthesis occurring during growth in medium of low osmolarity.     

Biosynthesis of membrane-derived oligosaccharides. Membrane-bound glucosyltransferase system from Escherichia coli requires polyprenyl phosphate.

The periplasmic glucans of Gram-negative bacteria, including the membrane-derived oligosaccharides (MDO) of Escherichia coli and the cyclic glucans of the Rhizobiaceae, are now recognized to be a family of closely related substances with important functions in osmotic adaptation and cell signaling. The synthesis of the beta-1,2-glucan backbone of MDO is catalyzed by a membrane-bound glucosyltransferase system previously shown to require UDP-glucose and (surprisingly) acyl carrier protein (Therisod, H., Weissborn, A. C., and Kennedy, E. P. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 7236-7240). In the present study, no glucan intermediates bound to acyl carrier protein or to UDP could detected. The enzyme system, however, was found to be strongly inhibited by bacitracin and by amphomycin. Because the two antibiotics function by forming specific complexes with polyprenyl phosphates, their inhibitory effect suggests a prenol requirement for MDO biosynthesis. Furthermore, the activity of the glucosyltransferase was greatly stimulated by the addition of polyprenyl phosphates such as decaprenyl-P and dihydroheptaprenyl-P, but not by farnesyl-P. The same membrane preparations carry out the synthesis of polyprenyl-P-glucose, which is also stimulated by added polyprenyl-P, including farnesyl-P, the most active of those tested. Pulse chase experiments, however, indicate that the endogenous pool of polyprenyl-P-glucose cannot be an obligate intermediate in the MDO glucosyltransferase system.     

Construction of GFP vectors for use in Gram-negative bacteria other than Escherichia coli

Abstract A set of vectors containing a mutated gfp gene was constructed for use with Gram-negative bacteria other than Escherichia coli . These constructs were: pTn 3gfp for making random promoter probe gfp insertions into cloned DNA in E. coli for subsequent introduction into host strains; pUTmini-Tn 5gfp for making random promoter probe gfp insertions directly into host strains; p519 gfp and p519 ngfp , broad host range mob ⁺ plasmids containing gfp from a lac and an npt 2 promoter, respectively.     

Identification of UDP-glucose as an intermediate in the biosynthesis of the membrane-derived oligosaccharides of Escherichia coli.

The membrane-derived oligosaccharides of Escherichia coli constitute a closely related family of oligosaccharides containing approximately 9 glucose units variously substituted with sn-glycero-1-phosphate and phosphoethanolamine residues derived from the head groups of membrane phospholipids, and also with succinate in O-ester linkage (Kennedy, E.P., Rumley, M.K., Schulman, H., and van Golder, L.M.G. (1976) J. Biol. Chem. 251, 4208-4213). Studies with mutant strains defective in the synthesis of various nucleoside diphosphate sugars have now revealed that UDP-glucose is an essential intermediate in the biosynthesis of these oligosaccharides. Mutants unable to synthesize UDP-glucose do not contain significant amounts of the membrane-derived oligosaccharides. In contrast, a strain unable to synthesize ADP-glucose, the glucosyl donor for glycogen synthesis in E. coli, contained normal amounts of the membrane-derived oligosaccharides, although with a somewhat different pattern of distribution of the various subspecies. In confirmation of these genetic studies, pulse-label isotope tracer studies have been carried out with glucose of high specific activity, under conditions in which UDP-glucose comprises a large fraction of the total radioactivity in the low molecular weight pool. Subsequent "chase" experiments clearly revealed the conversion of UDP-glucose to the higher molecular weight membrane-derived oligosaccharides.     

Cell envelope and shape of Escherichia coli: multiple mutants missing the outer membrane lipoprotein and other major outer membrane proteins.

Starting with an Escherichia coli strain missing the outer membrane lipoprotein, multiple mutants were constructed than in addition to this defect miss the outer membrane proteins II, Ia and Ib, or Ia, Ib, and II. In contrast to all single mutants or strains missing the lipoprotein and polypeptides Ia and Ib, drastic influences on the integrity of the outer membrane and cell morphology were observed in mutants without lipoprotein and protein II. Such strains exhibited spherical morphology. They required increased concentrations of electrolytes for optimal growth, and Mg2+ or Ca2+ were the most efficient. These mutants were sensitive to hydrophobic antibiotics and detergents. Electron microscopy revealed abundant blebbing of the outer membrane, and it could clearly be seen that the murein layer was no longer associated with the outer membrane.     

Regulation of the synthesis of membrane-derived oligosaccharides in Escherichia coli. Assay of phosphoglycerol transferase I in vivo

Membrane-derived oligosaccharides are periplasmic constituents of Escherchia coli and other Gram-negative bacteria. Oligosaccharides in this family may be variously substituted with O-succinyl ester residues, and with sn-1-phosphoglycerol and phosphoethanolamine residues derived from membrane phospholipids. Membrane-derived oligosaccharides appear to be important in osmoregulation, because their synthesis is under strict control (Kennedy, E.P. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 1092-1095). Maximum rate of synthesis is at very low osmolarity of the medium. Phosphoglycerol residues are transferred from phosphatidylglycerol to membrane-derived oligosaccharides, or to certain beta-glucoside acceptors, in a reaction catalyzed by phosphoglycerol transferase I, an enzyme of the inner membrane (Jackson, B. J., and Kennedy, E.P. (1983) J. Biol. Chem. 258, 2394-2398). We now report that this enzyme catalyzes the transfer of phosphoglycerol residues to arbutin (p-hydroxyphenyl-beta-D-glucoside) added to the medium with Km similar to that observed with the cell-free enzyme. The active site of the enzyme must therefore be on the periplasmic face of the inner membrane. We assayed phosphoglycerol transferase I in vivo and found that it is present and completely active even in cells growing in medium of very high osmolarity, in which the synthesis of membrane-derived oligosaccharides is severely reduced. We conclude that osmotic regulation must occur at the stage of the synthesis of oligosaccharide chains. A study of the kinetics of transfer of phosphoglycerol residues to membrane-derived oligosaccharides in vivo revealed that synthesis of the polyglucose chains must stop abruptly upon transfer of cells from medium of low to high osmolarity, inconsistent with a model postulating simple dilution of some rate-limiting enzyme during growth at the higher osmolarity.     

Localization of proteolytic activity in the outer membrane of Escherichia coli.

An enzyme in the cytoplasmic membrane, nitrate reductase, can be solubilized by heating membranes to 60 degrees C for 10 min at alkaline pH. A protease in the cell envelope has been shown to be responsible for this solubilization. The localization of this protease in the outer membrane was demonstrated by separating the outer membrane from the cytoplasmic membrane, adding back various forms of outer membrane protein to the cytoplasmic membrane, and following the increase in nitrate reductase solubilization with increasing amounts of outer membrane proteins. This solubilization is accompanied by the cleavage of one of the subunits of nitrate reductase and is inhibited by the protease inhibitor p-aminobenzamidine. Analysis of membrane proteins synthesized by cells grown in the presence of various amounts of p-aminobenzamidine revealed that p-aminobenzamidine affects the synthesis of the major outer membrane proteins but has little effect on the synthesis of cytoplasmic membrane proteins. When outer membrane is reacted with the protease inhibitor [3H]diisopropylfluorophosphate, a single protein in the outer membrane is labeled. Since the interaction with diisopropylfluorophosphate is inhibited by p-aminobenzamidine, it is suggested that this single outer membrane protein is responsible for the in vitro solubilization of nitrate reductase and the in vivo processing of the major outer membrane proteins.     

Mapping of a locus (mdoA) that affects the biosynthesis of membrane-derived oligosaccharides in Escherichia coli.

Mutants of Escherichia coli defective in the newly discovered mdoA locus are blocked at an early stage in the biosynthesis of membrane-derived oligosaccharides. The mutation has now been mapped and found to be located near 23 min on the E. coli chromosome between putA and pyrC. The mdoA mutants are defective in the membrane-localized component of the glucosyl transferase system described by Weissborn and Kennedy (A. C. Weissborn and E. P. Kennedy, Fed. Proc. 42:2122, 1983).     

Fishing new proteins in the twilight zone of genomes: the test case of outer membrane proteins in Escherichia coli K12, Escherichia coli O157:H7, and other Gram-negative bacteria

We address the problem of clustering the whole protein content of genomes into three different categories-globular, all-alpha, and all-beta membrane proteins-with the aim of fishing new membrane proteins in the pool of nonannotated proteins (twilight zone). The focus is then mainly on outer membrane proteins. This is performed by using an integrated suite of programs (Hunter) specifically developed for predicting the occurrence of signal peptides in proteins of Gram-negative bacteria and the topography of all-alpha and all-beta membrane proteins. Hunter is tested on the well and partially annotated proteins (2160 and 760, respectively) of Escherichia coli K 12 scoring as high as 95.6% in the correct assignment of each chain to the category. Of the remaining 1253 nonannotated sequences, 1099 are predicted globular, 136 are all-alpha, and 18 are all-beta membrane proteins. In Escherichia coli 0157:H7 we filtered 1901 nonannotated proteins. Our analysis classifies 1564 globular chains, 327 inner membrane proteins, and 10 outer membrane proteins. With Hunter, new membrane proteins are added to the list of putative membrane proteins of Gram-negative bacteria. The content of outer membrane proteins per genome (nine are analyzed) ranges from 1.5% to 2.4%, and it is one order of magnitude lower than that of inner membrane proteins. The finding is particularly relevant when it is considered that this is the first large-scale analysis based on validated tools that can predict the content of outer membrane proteins in a genome and can allow cross-comparison of the same protein type between different species.     

Release of outer membrane vesicles by Gram-negative bacteria is a novel envelope stress response

Conditions that impair protein folding in the Gram-negative bacterial envelope cause stress. The destabilizing effects of stress in this compartment are recognized and countered by a number of signal transduction mechanisms. Data presented here reveal another facet of the complex bacterial stress response, release of outer membrane vesicles. Native vesicles are composed of outer membrane and periplasmic material, and they are released from the bacterial surface without loss of membrane integrity. Here we demonstrate that the quantity of vesicle release correlates directly with the level of protein accumulation in the cell envelope. Accumulation of material occurs under stress, and is exacerbated upon impairment of the normal housekeeping and stress-responsive mechanisms of the cell. Mutations that cause increased vesiculation enhance bacterial survival upon challenge with stressing agents or accumulation of toxic misfolded proteins. Preferential packaging of a misfolded protein mimic into vesicles for removal indicates that the vesiculation process can act to selectively eliminate unwanted material. Our results demonstrate that production of bacterial outer membrane vesicles is a fully independent, general envelope stress response. In addition to identifying a novel mechanism for alleviating stress, this work provides physiological relevance for vesicle production as a protective mechanism.     

Major proteins of the Escherichia coli outer cell envelope membrane as bacteriophage receptors.

Three Escherichia coli phages, TuIa, TuIb, and TuII, were isolated from local sewage. We present evidence that they use the major outer membrane proteins Ia, Ib, and II, respectively, as receptors. In all cases the proteins, under the experimental conditions used, required lipopolysaccharide to exhibit their receptor activity. For proteins Ia and II, an approximately two- to eightfold molar excess of lipopolysaccharide (based on one diglucosamine unit) was necessary to reach maximal receptor activity. Lipopolysaccharide did not appear to possess phage-binding sites. It seemed that the lipopolysaccharide requirement reflected a protein-lipopolysaccharide interaction in vivo, and lipopolysaccharide may thus cause the specific localization of these proteins. Inactivation of phage TuII by a protein II-lipopolysaccharide complex was reversible as long as the complex was in solution. Precipitation of the complex with Mg2+ led to irreversible phage inactivation with an inactivation constant (37 degrees C)K = 7 X 10-2 ml/min per microgram. With phages TuIa and TuIb and their respective protein-lipopolysaccharide complexes, only irreversible inactivation was found at 37 degrees C. The activity of the three proteins as phage receptors shows that part of them must be located at the cells surface. In addition, the association of proteins Ia and Ib with the murein layer of the cell envelope makes this pair trans-membrane proteins.     

Molecular cloning and expression of a locus (mdoA) implicated in the biosynthesis of membrane-derived oligosaccharides in Escherichia coli

Mutants of Escherichia coli defective in the mdoA locus are blocked at an early stage in the biosynthesis of membrane-derived oligosaccharides. The mdoA locus has now been cloned into multicopy plasmids. A 5 kb DNA fragment is necessary to complement mdoA mutations. Cells harbouring the mdoA+ plasmid produced three to four times more MDO than wild-type cells. MDO overproduction did not affect the degree of MDO substitution with sn-1-phosphoglycerol residues. The biosynthesis of MDO remained under osmotic control in overproducing strains.     

Characterization of the β-lactamase specified by the resistance factor R-1818 in Escherichia coli K12 and other Gram-negative bacteria

1. The amino acid composition of the beta-lactamase from E. coli (R-1818) was determined. 2. The R-1818 beta-lactamase is inhibited by formaldehyde, hydroxylamine, sodium azide, iodoacetamide, iodine and sodium chloride. 3. The K(m) values for benzylpenicillin, ampicillin and oxacillin have been determined by using the R-factor enzyme from different host species. The same values were obtained, irrespective of the host bacterium. 4. The molecular weight of the enzyme was found to be 44600, and was the same for all host species. 5. The relationship of R-1818 and R-GN238 beta-lactamases is discussed.     

Characterization of an Escherichia coli mdoB mutant strain unable to transfer sn-1-phosphoglycerol to membrane-derived oligosaccharides

A procedure for the isolation of mutants affected in components containing glycerol derived from phospholipids yielded two mutant strains that contain membrane-derived oligosaccharides (MDO) devoid of glycerol (Rotering, H., Fiedler, W., Rollinger, W., and Braun, V. (1984) FEMS Microbiol. Lett. 22, 61-68). MDO are found in the periplasmic space of Escherichia coli and other Gram-negative bacteria, and they may comprise up to 7% of the cells dry weight. The biosynthesis of MDO is osmoregulated (Kennedy, E. P. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 1092-1095) and linked to the metabolism of phospholipids (van Golde, L. M. G., Schulman, H., and Kennedy, E. P. (1973) Proc. Natl. Acad. Sci. U. S. A. 70, 1368-1372). This leads to substitution of MDO with sn-1-phosphoglycerol and phosphoethanolamine (Kennedy, E. P., Rumley, M. K., Schulman, P., and van Golde, L. M. G. (1976) J. Biol. Chem. 251, 4208-4213). MDO also contain succinate in O-ester linkage. We now report that one mutant strain lacks phosphoglycerol transferase I activity and thus is unable to transfer sn-1-phosphoglycerol residues from phosphatidylglycerol to MDO. The mdoB gene affected in this mutant has been located at 99.2 min on the E. coli chromosome. The ethanolamine content of MDO isolated from the mutant strain is elevated, whereas the number of succinate residues is not affected. The only phenotype of mdoB mutants we found is a dramatic reduction of the diglyceride content observed in dgk mdoB double mutants when the beta-glucoside arbutin is present in the growth medium.