Functioning of the cloned phage MS2 lysis protein in Escherichia coli impaired in murein synthesis

Abstract The mode of action of the phage MS2 lysis protein seems not to involve a direct interaction with the murein synthesis machinery as is the case for lysis induced by β-lactam antibiotics. Mutants with defects in various penicillin-binding proteins, which are involved in murein synthesis, were found to show normal lysis sensitivity towards the cloned MS2 lysis protein. In addition, both processes, longitudinal growth of the murein sacculus in the presence of furazlocillin, cephalexin and nalidixic acid as well as spherical growth in the presence of mecillinam were sensitive to the phage lysis protein. No change in the capacity of the binding proteins to bind ¹⁴C-labelled penicillin G was observed in the presence of the MS2 lysis gene product.     

Programmed Escherichia coli cell lysis by expression of cloned T4 phage lysis genes

Self-disruptive Escherichia coli that produces foreign target protein was developed. E. coli was co-transformed with two vector plasmids, a target gene expression vector and a lysis gene expression vector. The lytic protein was produced after the expression of the target gene, resulting in simplification of the cell disruption process. In this study, the expression of cloned T4 phage gene e or t was used for the disruption of E. coli that produced beta-glucuronidase (GUS) as a model target protein. The expression of gene e did not lead to prompt cell disruption but weakened the cell wall. Resuspension with deionized water facilitated cell lysis, and GUS activity was observed in the resuspended liquid. Expression of gene e at mid logarithmic growth phase was the optimal induction period for GUS production and release. On the other hand, the expression of gene t induced immediate cell lysis, and intracellular GUS was released to the culture medium. Maximum GUS production was obtained when gene t was induced at late logarithmic growth phase.     

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.     

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.     

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.     

Lysis of Escherichia coli by the bacteriophage phi X174 E protein: inhibition of lysis by heat shock proteins.

Lysis of Escherichia coli by the cloned E protein of bacteriophage phi X174 was more rapid than expected when bacteria were shifted from 30 to 42 degrees C at the time of E induction. Since such treatment also induces the heat shock response, we investigated the effect of heat shock proteins on lysis. An rpoH mutant was more sensitive to lysis by E, but a secondary suppressor mutation restored lysis resistance to parental levels, which suggests that the sigma 32 subunit itself did not directly increase lysis resistance. At 30 degrees C, mutants in five heat shock genes (dnaK, dnaJ, groEL, groES, and grpE) were more sensitive to lysis than were their wild-type parents. The magnitude of lysis sensitivity varied with mutation and strain background, with dnaK, dnaJ, and groES mutants consistently exhibiting the greatest sensitivities. Extended protection against lysis occurred when overproduction of heat shock proteins was induced artificially in cells that contained a plasmid with the rpoH+ gene under control of the tac promoter. This protective effect was completely abolished by mutations in dnaK, dnaJ, or groES but not by grpE or groEL mutations. Altered membrane behavior probably explains the contradiction whereby an actual temperature shift sensitized cells to lysis, but production of heat shock proteins exhibited protective effects. The results demonstrate that E-induced lysis can be divided into two distinct operations which may now be studied separately. They also emphasize a role for heat shock proteins under non-heat-shock conditions and suggest cautious interpretation of lysis phenomena in systems where E protein production is under control of a temperature-sensitive repressor.     

Thymol-triggered lysis of Escherichia coli expressing Lactobacillus phage LL-H muramidase

Effective disruption of Escherichia coli cells is achieved by the intracellularly accumulated recombinant murein hydrolase (Lactobacillus bacteriophage LL-H muramidase) after the addition of 5 mM thymol. Thymol destroys the integrity and electric potential of the cytoplasmic membrane, and as a consequence the muramidase can access and hydrolyze the cell wall murein leading to cell lysis. Lysis occurred within 5 min after the addition of thymol and seemed to be efficient at high culture densities. This lysis method does not require cell harvesting or addition of other cell wall weakening substances or exogenous enzymes. As a cell disruption method, thymol-triggered lysis is as efficient as sonication in the presence of 1% Triton. Furthermore, thymol did not interfere with the purification steps of Mur by expanded bed adsorption chromatography (EBA), suggesting that the lysis method presented here is well suited for large-scale production and purification of intracellular proteins of E. coli. Received 21 April 1998/ Accepted in revised form 5 December 1998     

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.     

Specific localization of the lysis protein of bacteriophage MS2 in membrane adhesion sites of Escherichia coli.

Specific localization of the lysis (L) protein of bacteriophage MS2 in the cell wall of Escherichia coli was determined by immunoelectron microscopy. After induction of the cloned lysis gene, the cells were plasmolyzed, fixed, and embedded in either Epon or Lowicryl K4M. Polyclonal L-protein-specific antiserum was purified by preabsorption to membranes from cells harboring a control plasmid. Protein A-gold was used to label the protein-antibody complexes. Between 42.8% (Lowicryl) and 33.8% (Epon) of the label was found in inner and outer membranes, but 30.3% (Lowicryl) and 32.8% (Epon) was present mostly in clusters in the adhesion sites visible after plasmolysis. The remaining label (26.9 and 33.4%, respectively) appeared to be present in the periplasmic space but may also have been part of membrane junctions not visible because of poor contrast of the specimen. In contrast, a quite different distribution of the L protein was found in cells grown under conditions of penicillin tolerance, i.e., at pH 5, a condition that had previously been shown to protect cells from L-protein-induced lysis. At tolerant conditions, only 21.0% of the L protein was in the adhesion sites; most of the protein (68.2%) was found in inner and outer membranes. It is concluded that lysis of the host, E. coli, was a result of the formation of specific L-protein-mediated membrane adhesion sites.     

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.     

A synthetic peptide corresponding to the C-terminal 25 residues of phage MS2 coded lysis protein dissipates the protonmotive force in Escherichia coli membrane vesicles by generating hydrophilic pores.

The RNA phage MS2 encodes a protein, 75 amino acids long, that is necessary and sufficient for lysis of the host cell. DNA deletion analysis has shown that the lytic activity is confined to the C-terminal half of the protein. We have examined the effects of a synthetic peptide, covering the C-terminal 25 amino acids of the lysis protein, on the electrochemical potential, generated in Escherichia coli membrane vesicles and in liposomes reconstituted with cytochrome c oxidase. In all cases the peptide dissipates the electrochemical potential. The peptide also induces the release of carboxyfluorescein (376 daltons), but not of inuline (5500 daltons), from protein-free liposomes. The phenomena are observed at a lipid to peptide molar ratio of approximately 100:1. The possible connection between the dissipation of the proton-motive force and bacteriolysis is discussed.     

Role of superinfecting phage in lysis inhibition with phage T4 in Escherichia coli

Rutberg, Blanka (Karolinska Institutet, Stockholm, Sweden), and Lars Rutberg. Role of superinfecting phage in lysis inhibition with phage T4 in Escherichia coli. J. Bacteriol. 90:891-894. 1965.-The ability of bacteriophage T4 to induce lysis inhibition upon superinfection was investigated after various treatments of the phage. This ability was found not to be a property of the external protein part of the phage, nor was it dependent on the functional and possibly structural integrity of the phage genetic material.     

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.     

Induction of the autolytic system of Escherichia coli by specific insertion of bacteriophage MS2 lysis protein into the bacterial cell envelope.

Bacterial lysis induced by the expression of the cloned lysis gene of the RNA bacteriophage MS2 in Escherichia coli was shown to be under the same regulatory control mechanisms as penicillin-induced lysis. It was controlled by the stringent response and showed the phenomenon of tolerance when E. coli was grown at pH 5. Changes in the fine structure of the murein were found to be the earliest physiological changes in the cell, taking place 10 min before the onset of cellular lysis and inhibition of murein synthesis. Both the average length of the glycan strands and, with a time lag, the degree of cross-linkage were altered, indicating that a lytic transglycosylase and a DD-endopeptidase had been triggered. After extensive separation of the membranes by isopycnic sucrose gradient centrifugation, the lysis protein was present predominantly in the cytoplasmic membrane and in a fraction of intermediate density and, to a lesser degree, in the outer membrane, irrespective of the conditions of growth. However, only under lysis-permissive conditions could a 17% increase in the number of adhesion sites between the inner and outer membranes be observed. Thus, a casual relationship between lysis and the formation of lysis protein-induced adhesion sites seems to exist.