Inductively coupled plasma emission spectroscopy was used to quantitate the metal cations bound to outer and cytoplasmic membranes and to extracted lipopolysaccharide from several Escherichia coli K12 strains. The outer membrane was found to be enriched in both calcium and magnesium relative to the cytoplasmic membrane. Both membranes contained significant levels of iron, aluminum, and zinc. The multivalent cation content of the lipopolysaccharide resembled that of the intact outer membrane. Lipopolysaccharide extracted from wild-type k12 strains contained higher levels of Mg than Ca regardless of the growth medium, but the medium used for growth did affect the relative amounts of bound Mg as well as the levels of the minor cations iron, aluminum, and zinc. In contrast, lipopolysaccharide isolated from a deep rough mutant strain, D21f2, contained more Ca than Mg. Electrodialysis of lipopolysaccharide from wild-type k12 strains removed 1 mol of Mg per mol of lipopolysaccharide but did not significantly affect the level of other bound metal ions. Dialysis of lipopolysaccharide against sodium (ethylenedinitrilo)tetraacetate removed most of the Mg and Ca, resulting in a sodium salt. The equimolar replacement of divalent cations with sodium in the sodium salt resulted in a net loss of counterion change. The sodium salt was dialyzed against either tris(hydroxymethyl)aminomethane hydrochloride, CaCl2, MgCl2, or TbCl3, and the resulting lipopolysaccharide salts were analyzed for their ionic composition. It was shown that tris(hydroxymethyl)aminomethane and Ca can replace some but not all of the Na bound to the sodium salt, but all of the other multivalent cations tested replaced Na, resulting in uniform lipopolysaccharide salts. Lipopolysaccharide isolated from the deep rough mutant strain D21f2 was also converted into a sodium salt. Relative to the wild-type lipopolysaccharide, Na was able to neutralize the anionic charge to a greater extent in the mutant lipopolysaccharide. Our results suggest that the loss of specific groups in the core region of the lipopolysaccharide from the mutant strain results in a more open structure that allows the binding of larger cations and of more monovalent cations.
An indirect immunofluorescence assay for the detection of human antibodies to the agent of human granulocytic ehrlichiosis (HGE) was developed and standardized. Antigen was prepared from a human promyelocytic leukemia cell line (HL-60) infected with a tick-derived isolate of the HGE agent (USG3). Suitable antigen presentation and preservation of cellular morphology were obtained when infected cells were applied and cultured on the slide, excess medium was removed, and cells were fixed with acetone. Use of a buffer containing bovine serum albumin and goat serum reduced background fluorescence, and use of an immunoglobulin G (␥-specific) conjugate reduced nonspecific binding. The assay readily detected specific antibody from HGE patients and did not detect antibody from healthy individuals. No significant reactivity was noted in sera from patients with high titers of antibodies to other rickettsial species. We were able to identify antibodies reactive to USG3 antigen in samples from areas where HGE is endemic that had tested negative to other rickettsial agents. Animal sera reactive against Ehrlichia equi or Ehrlichia phagocytophila bound to the HGE antigen, indicating that the assay may be useful for veterinary use. Comparability between two different laboratories was assessed by using coded human sera exchanged between laboratories. Results from the two laboratories were similar, indicating that the assay can be easily integrated into use for routine testing for HGE. The assay was then compared to an assay using horse neutrophils infected with ehrlichiae. The two assays gave comparable results, indicating that the cell culture-derived antigen can be used for testing samples that have been previously tested with E. equi as an antigen. The new assay offers several advantages over other immunofluorescence methods that use animal-derived antigen and is suitable for use in testing for human antibodies to the HGE agent.
Lipopolysaccharide (LPS) bound to isolated porin was detected on polyacrylamide gels by using a carbohydrate-specific silver stain and on Western blots by using anti-lipid A monoclonal antibodies. Porin was isolated from Escherichia coli JF733 (Ra chemotype) and D21f2 (Re chemotype). Isolated porin was separated from loosely associated LPS by polyacrylamide gel electrophoresis (PAGE) in sodium dodecyl sulfate (SDS). Unheated porin traveled on gels as aggregates, presumably trimers, with an apparent molecular weight of 78,000 to 83,000. After heating to 100°C for 2 min in SDS, the porin traveled as a monomer with a molecular weight of 36,000. The unheated, high-molecular-weight trimer band reacted in the gel with the carbohydratespecific silver stain, while the heated monomer band showed no staining. In contrast, lipid A-specific monoclonal antibodies showed reactivity on Western blots to the 36,000-molecular-weight band but not to the trimer. Finally, both monomer and trimer bands were isolated from gels and rerun by SDS-PAGE. LPS was released from the trimer preparation when the sample was heated, but the monomer band that was formed by heating the trimer isolate still reacted with anti-lipid A antibodies. Quantitative Limulus amebocyte lysate analysis revealed an approximately equal molar ratio of LPS to protein in the electroeluted porin monomer. Thus, some but not aHl of the LPS could be released from trimer complexes by boiling in SDS. The isolated monomer did not release more LPS on boiling in SDS a second time but still had LPS tightly bound, as detected by lipid A-specific monoclonal antibodies.The structure and interactions of the outer membrane porin proteins OmpF and OmpC from Escherichia coli are very similar. They have similar molecular weights and amino acid sequences (22), the native proteins are very high in beta structure (25, 32), both are tightly associated with the peptidoglycan (9, 19, 32), and they are very tightly associated with lipopolysaccharide (LPS) (10,12,36,40). Porins are known to form water-filled channels (2, 33) and are unusually stable to a wide variety of perturbants such as sodium dodecyl sulfate (SDS) detergent (24, 25, 41), pH extremes from 2 to 12 (8), and temperatures up to 70°C (32). Porins are also resistant to many proteases, perhaps because of their tight association with LPS (12); the proteins are thought to be functional only in the presence of LPS (12,20,33). Nakae et al. (24) have suggested that only the lipid component of LPS is essential for porin function. In contrast, Parr and co-workers (30) have reported that porin is functional in the absence of LPS. Thus, the importance of bound LPS for porin structure and function has yet to be resolved.The OmpF porin exists as a trimeric complex (24, 29) with three identical subunits with approximate molecular weights of 36,000 (13, 32). Low SDS binding coupled with the tight, compact shape of the trimer results in more rapid migration on polyacrylamide gels than the aggregate molecular weight would suggest. Investigator...
The electron spin resonance probes 5-doxylstearate and 4-(dodecyldimethylammonio)-1-oxy-2,2,6,6-tetramethylpiperidine bromide were used to characterize the fluidity of the acyl chain and head-group regions, respectively, of defined salts of lipopolysaccharide (LPS) from Escherichia coli K12. The removal of the weakly bound divalent cations from native LPS by electrodialysis and their replacement by sodium had little effect on the midpoint of the lipid-phase transition or on head-group mobility. In contrast, lipopolysaccharide acyl chain mobility increased following electrodialysis. The replacement of most of the remaining cations with sodium resulted in a further dramatic increase in mobility in both the polar and nonpolar regions of lipopolysaccharide. Head-group mobility of the sodium salt of LPS was shown to be reduced with the addition of divalent cations. Furthermore, evidence is presented which suggests that low magnesium concentrations may induce phase separations in the sodium salt. The magnesium salt of lipopolysaccharide closely resembled the native form in both head-group and acyl chain mobility although the cation charge to phosphorus ratio in the magnesium salt was greater than that detected in the native isolate. Analyses of other lipopolysaccharide salts support our hypothesis that many of the observed differences in the physical and pathological properties of lipopolysaccharide salts may simply be explained by the degree of charge neutralization.
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