Bordetella bronchiseptica Glycosyltransferase Core Mutants Trigger Changes in Lipid A Structure.

Bordetella bronchiseptica, known to infect animals and rarely humans, expresses a lipopolysaccharide that plays an essential role in host interactions, being critical for early clearance of the bacteria. On a B. bronchiseptica 9.73 isolate, mutants defective in the expression of genes involved in the biosynthesis of the core region were previously constructed. Herein, a comparative detailed structural analysis of the expressed lipids A by MALDI-TOF mass spectrometry was performed. The Bb3394 LPS defective in a 2-amino-2-deoxy-D-galacturonic acid lateral residue of the core presented a penta-acylated diglucosamine backbone modified with two glucosamine phosphates, similar to the wild-type lipid A. In contrast, BbLP39, resulting in the interruption of the LPS core oligosaccharide synthesis, presented lipid A species consisting in a diglucosamine backbone N-substituted with C14:0(3-O-C12:0) in C-2 and C14:0(3-O-C14:0) in C-2', O-acylated with C14:0(3-O-C10:0(3-OH) in C-3' and with a pyrophosphate in C-1. Regarding Bb3398 also presenting a rough LPS, the lipid A is formed by a hexa-acylated diglucosamine backbone carrying one pyrophosphate group in C-1 and one phosphate in C-4', both substituted with ethanolamine groups. As far as we know, this is the first description of a phosphoethanolamine modification in B. bronchiseptica lipid A. Our results demonstrate that although gene deletions were not directed to the lipid A moiety, each mutant presented different modifications. MALDI-TOF mass spectrometry was an excellent tool to highlight the structural diversity of the lipid A structures biosynthesized during its transit through the periplasm to the final localization in the outer surface of the outer membrane. Graphical Abstract.

Two efficient methods for the conjugation of smooth-form lipopolysaccharides with probes bearing hydrazine or amino groups. I. LPS activation with cyanogen bromide.

This chapter presents a conjugation method for coupling probes bearing hydrazine or primary amino groups to a smooth(S)-form lipopolysaccharide (LPS). LPS is modified by the activation of the hydroxyl groups present in its O-antigen moiety with cyanogen bromide in aqueous acetone. The method yields conjugates with good labeling ratios, preserving the endotoxic activity of the lipid A moiety. Conjugation of smooth-form LPS from Salmonella enterica sv. Minnesota with dansyl hydrazine and horseradish -peroxidase yields labeling ratios above 300 nmol dansyl per mg LPS, with nearly no loss of the original endotoxin activity. In the case of horseradish peroxidase, introducing a spacer, a ratio of 28 nmol HRP per mg LPS is obtained, preserving 65% of the original endotoxic activity.

Two efficient methods for the conjugation of smooth-form lipopolysaccharides with probes bearing hydrazine or amino groups. II. LPS activation with a cyanopyridinium agent.

This chapter presents a conjugation method for coupling probes bearing hydrazine or primary amino groups to a lipopolysaccharide (LPS). LPS is modified by the activation of the hydroxyl groups present in its O-antigen moiety with 1-cyano-4-dimethylaminopyridinium tetrafluoroborate (CDAP). The method yields conjugates with good labeling ratios, preserving the endotoxic activity of the lipid A moiety. Conjugation of smooth-form LPS from Salmonella enterica sv. Minnesota with dansyl hydrazine and horseradish peroxidase yields labeling ratios above 110 nmol dansyl/mg LPS, with nearly no loss of the original endotoxic activity. In the case of horseradish peroxidase, introducing a spacer, a ratio of 29 nmol HRP/mg LPS was obtained, preserving 65% of the original endotoxic activity and an enzymatic activity of 120 U/mg.

A matrix-assisted laser desorption/ionization mass spectrometry approach to the lipid A from Mesorhizobium loti.

The isolation, purification and analysis of the lipid A obtained from Mesorhizobium loti Ayac 1 BII strain is presented. Analysis of the carbohydrate moiety after acid hydrolysis by high-pH anion-exchange chromatography with pulse amperometric detection (HPAEC-PAD) showed the presence of glucosamine and galacturonic acid as the only sugar components. Gas chromatographic (GC) and GC/mass spectrometric (MS) analysis of the fatty acids revealed the presence of 3-OH-C12:0; 3-OH-C13:0; 3-OH-C20:0 and 27-OH-C28:0 among the major hydroxylated species. In addition, C16:0, C17:0, C18:0 and C 20:0 were shown as main saturated fatty acids. Different polyacylated species were evidenced by thin layer chromatography of lipid A, allowing the purification of two fractions. Ultraviolet matrix-assisted laser desorption/ionization time-of-flight (UV-MALDI-TOF) MS analysis with different matrices, in the positive- and negative-ion mode, was performed. The fast moving component revealed the presence of hexa-acylated species, varying in the fatty acid composition. Species containing three 3-OH fatty acids and a 27-OH-C28:0 fatty acid were observed. Individual ions within this family differ by +/-14 mass units. The slow moving component was enriched mainly in penta-acylated species. Among them, three subgroups were detected: the major one compatible with the sugar core bearing two 3-OH 20:0 fatty acids, a 3-OH 13:0 or a 3-OH 12:0 fatty acid, a 27-OH 28:0 fatty acid and one saturated fatty acid. Each signal differs in a C18:0 acyl unit from the corresponding hexa-acylated family. On the other hand, a subgroup bearing one 3-OH 20:0 fatty acid, one 27-OH 28:0 fatty acid and two non-polar fatty acids was shown. A minor subgroup compatible with structures containing two hydroxylated and three non-polar fatty acids was also detected. The results obtained showed that nor-harmane was an excellent matrix for charged lipid A structural studies in both, positive and negative ion modes.

Enhanced ELISA sensitivity using TCA for efficient coating of biologically active lipopolysaccharides or lipid A to the solid phase.

A new simple, reproducible and sensitive ELISA that uses trichloroacetic acid (TCA) for the coating of lipooligosaccharide (LOS), smooth lipopolysaccharide (LPS) or lipid A to the solid phase has been developed. The experimental parameters (temperature of coating, time of coating, antigen concentration and TCA concentration) were evaluated by a complete factorial design (2(4)). As a result of the evaluation, two main coating procedures were developed. In one, LOS was shown to coat efficiently in 0.2% TCA, at 37 degrees C, when incubated for only 30 min. In the other procedure, LOS in 0.2% TCA was coated at 37 degrees C for 16 h. The slower procedure proved, as expected, to be even more efficient than the former. The new ELISA was compared to three previously reported ELISAs, and showed the greatest sensitivity, probably, as a consequence of the higher coating efficiency of LOS to plates. The biologic activity of LOS was not modified by the low TCA concentration used, as proven by retention of its biological activity in the induction of procoagulant activity in blood mononuclear cells. We conclude that small amounts of biologically active LOS/LPS or lipid A can be coated on solid surfaces by this approach to achieve a rapid and economical assay procedure.