Abstract
Lipopolysaccharide (LPS) isolated from Escherichia coli D31m4, a heptoseless mutant, was studied by 13C and 31P NMR spectroscopy. Modified isolation and purification procedures are described which permitted high resolution NMR spectra to be obtained from samples of intact LPS. 31P NMR was used to monitor the purity and native heterogeneity of LPS samples. The anomeric carbon region of the 13C NMR spectrum taken at pH 7 contained five resonances that were assigned on the basis of chemical shift correlation, 13C-1H couplings, and T1 relaxation times. Two resonances, at 99.9 and 100.8 ppm, were attributed to two residues of 3-deoxy-D-manno-octulosonate (KDO) of which both were tentatively assigned to the alpha configuration. The Lipid A moiety gave rise to resonances at 94.0 and 94.9 ppm, both assigned to GlcNI, and a resonance at 103.1 ppm, assigned to GlcNII. The two anomeric carbon resonances observed for GlcNI reflected the variable substitution of C-1 with monophosphate or diphosphate groups. GlcNI and GlcNII were ascertained to be of the alpha and beta anomeric configuration, respectively, through chemical shift comparisons with model saccharides. The accepted KDO linkage site at C-3' of GlcNII appears not to be supported by the 13C chemical shift data.
Highlights
Lipopolysaccharide (LPS) isolated from Escherichia coli D31m4, a heptoseless mutant, was studied by I3C and 31PNMR spectroscopy
The anomeric carbonregion of the I3CNMR spectrumtaken at pH 7 contained five resonances that were assigned on the basis of chemical shift correlation, 13C-'H couplings, and TIrelaxation times
The Lipid A moiety gave riseto resonances at 94.0 and 94.9 ppm, both assigned to GlcNI, and a resonance at 103.1 ppm, assigned to GlcNn
Summary
Characterization of Lipopolysaccharide from a HeptoselessMutant of Escherichia coliby Carbon 13 Nuclear Magnetic Resonance". Analysis of LPS structure habseen impaired by its propensity for micellar aggregation with occlusion of metal ions, phospholipids, or other membrane components, difficult solubility, and the natural heterogeneity of LPS from a given bacterial source coupled with a lack of suitable techniques for isolation of single molecular species [1, 3,6, 11,12,13]. These difficultieshave only added more uncertainty tothat inherent in the chemical degradative techniques upon which previous LPS structural studies have relied. We report on the first use of 13CNMR to characterize LPS obtained from a heptoseless mutant of Escherichia coli, whose structure has been the subject of earlier chemical degradative studies [6, 12, 20], and more recently has been analyzed by "P N M R [21]
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