Biosynthesis and assembly of the polysialic acid capsule in Escherichia coli K1. Activation of sialyl polymer synthesis in inactivate sialyltransferase complexes requires protein synthesis (original) (raw)
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Biosynthesis of the Polysialic Acid Capsule in Escherichia coli Kl
2001
The nature of endogenous acceptor molecules implicated in the membrane-directed synthesis of the polysialic acid (polysia) capsule in Escherichia coli Kl serotypes is not known. The capsule contains at least 200 sialic acid (Sia) residues that are elongated by the addition of new Sia residues to the nonreducing termini of growing nascent chains (Rohr, T. E., and Troy, F. A. (1980) J. Biol. Chem. 255, 2332-2342). Presumably, chain growth starts when activated Sia residues are transferred to acceptors that are not already sialylated. In the present study, we used an acapsular mutant defective in synthesis of CMP-NeuAc to label acceptors with [14C]NeuAc and an anti-polysia-specific antibody (H.46) to identify the molecules to which the polySia was attached. I’4C]Sia-labeled acceptors were solubilized with 2% Triton X-100, immunoprecipitated with H.46, and partially depolymerized with poly-a-2,8-endo-N-acetylneuraminidase. Approximately 5% of the [14C]Sia incorporated remained attached ...
Biomaterials, 2008
Bioencapsulation is an intriguing way to immobilize biological materials, including cells, in silica, metal-oxides or hybrid sol-gel polymers. Until now only the sol-gel precursor technology was utilized to immobilize bacteria or yeast cells in silica. With the discovery of silicatein, an enzyme from demosponges that catalyzes the formation of poly(silicate), it became possible to synthesize poly(silicate) under physiological (ambient) conditions. Here we show that Escherichia coli can be transformed with the silicatein gene, its expression level in the presence of isopropyl b-D-thiogalactopyranoside (IPTG) can be efficiently intensified by co-incubation with silicic acid. This effect could be demonstrated on the level of recombinant protein synthesis as well as by immunostaining analysis. The heterologously produced silicatein is enzymatically active, as confirmed by staining with Rhodamine 123 (formation for poly[silicate] from silicic acid) and by reacting free silicic acid with the b-silicomolybdato color system. Electron microscopic analysis revealed that the bacteria that express silicatein form a viscous cover around them when growing in the presence of silicic acid. Finally, we demonstrate that the growth kinetics of E. coli remains unaffected whether or not the bacteria had been transformed with silicatein or grown in medium, supplemented with silicic acid. It is concluded that silicatein-mediated encapsulation of bacteria with silica might improve, extend and optimize the range of application of bacteria for the production of recombinant protein. r
Improved methods for producing outer membrane vesicles in Gram-negative bacteria
Research in Microbiology, 2004
Outer membrane vesicle formation occurs during Gram-negative bacterial growth. However, natural production of large amounts of outer membrane vesicles has only been described in a few bacterial genera. The purified vesicles of some bacterial pathogens have shown potential applications in vaccinology and in antibiotic therapy. This study focused on the development of a gene expression system able to induce production of large amounts of outer membrane vesicles. The Tol-Pal system of Escherichia coli, required to maintain outer membrane integrity, is composed of five cell envelope proteins, TolA, TolB, TolQ, TolR and Pal. Tol proteins are parasitized by filamentous bacteriophages and by colicins. The phage infection process and colicin import require, respectively, the N-terminal domain of the minor coat g3p protein and the translocation domain of colicins, with both domains interacting with Tol proteins. In this study, we show that the periplasmic production of either Tol, g3p or colicin domains was able to specifically destabilize the E. coli or Shigella flexneri cell envelope and to induce production of high amounts of vesicles. This technique was further found to work efficiently in Salmonella enterica serovar Typhimurium. 2004 Elsevier SAS. All rights reserved.
Large-scale production and homogenous purification of long chain polysialic acids from E. coli K1
Journal of Biotechnology, 2008
The study of new biomaterials is the objective of many current research projects in biotechnological medicine. A promising scaffold material for the application in tissue engineering or other biomedical applications is polysialic acid (polySia), a homopolymer of ␣2,8-linked sialic acid residues, which represents a posttranslational modification of the neural cell adhesion molecule and occurs in all vertebrate species. Some neuroinvasive bacteria like, e.g. Escherichia coli K1 (E. coli K1) use polySia as capsular polysaccharide. In this latter case long polySia chains with a degree of polymerization of >200 are linked to lipid anchors. Since in vertebrates no polySia degrading enzymes exist, the molecule has a long half-life in the organism, but degradation can be induced by the use of endosialidases, bacteriophage-derived enzymes with pronounced specificity for polySia.
Substrate-induced membrane association of phosphatidylserine synthase from Escherichia coli
Journal of Bacteriology, 1986
To better establish the intracellular location of the phosphatidylserine synthase of Escherichia coli and hence better understand how it is regulated in the cell, we compared the size, function, and binding properties of the enzyme made in vitro with the enzyme found in cell lysates and with the purified enzyme. The enzyme made either in vivo or in an active form in vitro was found primarily associated with the ribosomal fraction of the cell and had the same apparent molecular mass as the purified enzyme. These results were unaffected by the presence of protease inhibitors. Addition of unsupplemented E. coli membranes or membranes supplemented with phosphatidylethanolamine did not affect the subcellular distribution of the enzyme in these experiments. However, addition of membranes supplemented with either the lipid substrate, CDP-diacylglycerol, or the lipid product, phosphatidylserine, resulted in membrane association by the enzyme rather than ribosomal association. Addition of me...
Journal of Biological Chemistry
The soluble form of a bacteriophage-induced endo-N-acetylneuraminidase (Endo-N) specific for hydrolyzing oligo-or poly-a-2,s-linked sialosyl units in sources as disparate as bacterial and neural membrane glycoconjugates was purified approximately 10,000fold and characterized. The enzyme appears homogenous by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and has a subunit M , 105,000. This corresponds to one of the higher M , phage proteins which comprises 7.6% (by weight) of the total phage protein. The holoenzyme is active at neutral pH and has a M , by gel filtration of 328,000, suggesting that the active enzyme is a trimer. Endo-N requires a minimum of 6 sialyl residues (DP6, where DP represents degree of polymerization) for activity. The limit digest products from the a-2,s-linked polysialic acid capsule of Escherichia coli K1 are DP4 with some DP3 and DP1,2. DP2-4 do not appear to inhibit depolymerization of polysialic acid. Endo-N digestion of the polysialosyl moiety on neural cell adhesion molecules yields sialyl oligomers with DP3 and DP4. The presence of a terminal sialitol changes both the distribution of limit digestion products and the apparent minimum substrate size. Higher M . a-2,s-linked sialyl polymers (-DP200) are better substrates (K,,, 60-70 PM) than sialyl oligomers of -DP10-20 ( K , 1.2 mM). Endo-N activity is inhibited by DNA and several other polyanions tested. An examination of the distribution of intermediate products shows that Endo-N binds and cleaves at random sites on the polysialosyl chains, in contrast to initiating cleavage at one end and depolymerizing processively. Endo-Ncan serve as a specific molecular probe to detect and selectively modify polya-2,s-sialosyl carbohydrate units which have been implicated in bacterial meningitis and neural cell adhesion.
Journal of Biological Chemistry, 1998
For the first time the transmembrane movement of an endogenously synthesized phospholipid across the inner membrane of E. coli is reported. [ 14 C]phosphatidylethanolamine (PE) was biosynthetically introduced into inner membrane vesicles from the PE-deficient strain AD93, by reconstitution with the enzyme phosphatidylserine (PS) synthetase. Upon addition of wild type cell lysate containing PS synthetase, and the metabolic substrates CTP and [ 14 C]serine to inside-out vesicles from AD93, [ 14 C]PS was synthesized, which was for the most part converted into [ 14 C]PE. [ 14 C]PE was introduced in right-side out vesicles by enclosing PS synthetase and CTP in the vesicle lumen and adding [ 14 C]serine. The newly synthesized [ 14 C]PE immediately equilibrated over both membrane leaflets (t 1/2 less than one min), as determined by its accessibility toward the amino-reactive chemical fluorescamine. In both insideout and right-side out vesicles, a 35-65% distribution was found of the newly synthesized PE over the cytoplasmic and periplasmic leaflet, respectively. The transport process of PE was not influenced by the presence of ATP or the proton motive force in inside out vesicles. Pretreatment of both types of vesicles with sulfhydryl reagents, or of right-side out vesicles with proteinase K, did not affect the rate and extent of the transmembrane distribution of the newly synthesized PE.
Journal of Biological Chemistry, 2009
The morphology and curvature of biological bilayers are determined by the packing shapes and interactions of their participant molecules. Bacteria, except photosynthetic groups, usually lack intracellular membrane organelles. Strong overexpression in Escherichia coli of a foreign monotopic glycosyltransferase (named monoglycosyldiacylglycerol synthase), synthesizing a nonbilayer-prone glucolipid, induced massive formation of membrane vesicles in the cytoplasm. Vesicle assemblies were visualized in cytoplasmic zones by fluorescence microscopy. These have a very low buoyant density, substantially different from inner membranes, with a lipid content of >60% (w/w). Cryo-transmission electron microscopy revealed cells to be filled with membrane vesicles of various sizes and shapes, which when released were mostly spherical (diameter ≈100 nm). The protein repertoire was similar in vesicle and inner membranes and dominated by the glycosyltransferase. Membrane polar lipid composition was similar too, including the foreign glucolipid. A related glycosyltransferase and an inactive monoglycosyldiacylglycerol synthase mutant also yielded membrane vesicles, but without glucolipid synthesis, strongly indicating that vesiculation is induced by the protein itself. The high capacity for membrane vesicle formation seems inherent in the glycosyltransferase structure, and it depends on the following: (i) lateral expansion of the inner monolayer by interface binding of many molecules; (ii) membrane expansion through stimulation of phospholipid synthesis, by electrostatic binding and sequestration of anionic lipids; (iii) bilayer bending by the packing shape of excess nonbilayer-prone phospholipid or glucolipid; and (iv) potentially also the shape or penetration profile of the glycosyltransferase binding surface. These features seem to apply to several other proteins able to achieve an analogous membrane expansion.
Analytical Biochemistry, 2009
The WecA transferase is an integral membrane protein and a member of the polyprenyl phosphate N-acetylhexosamine-1-phosphate transferase superfamily. It initiates the biosynthesis of various bacterial cell envelope components such as the lipopolysaccharide O-antigen. We report on the first large-scale enzymatic synthesis, purification, and characterization of the undecaprenyl-pyrophosphoryl-N-acetylglucosamine product of the WecA transferase. This is an essential lipid intermediate for the biosynthesis of various bacterial cell envelope components. Its availability in a pure form will allow the biochemical and structural characterization of the various enzymes requiring it as a substrate for the synthesis of cell wall polymers.