Interaction of human mannose-binding lectin (MBL) with Yersinia enterocolitica lipopolysaccharide

tThe lipopolysaccharide (LPS) is involved in the interaction between Gram-negative pathogenic bacteriaand host. Mannose-binding lectin (MBL), complement-activating soluble pattern-recognition receptortargets microbial glycoconjugates, including LPS. We studied its interactions with a set of Yersinia ente-rocolitica O:3 LPS mutants. The wild-type strain LPS consists of lipid A (LA) substituted with an inner coreoligosaccharide (IC) which in turn is substituted either with the O-specific polysaccharide (OPS) or theouter core hexasaccharide (OC), and sometimes also with the enterobacterial common antigen (ECA). TheLPS mutants produced truncated LPS, missing OPS, OC or both, or, in addition, different IC constituentsor ECA. MBL bound to LA-IC, LA-IC-OPS and LA-IC-ECA but not LA-IC-OC structures. Moreover, LA-IC sub-stitution with both OPS and ECA prevented the lectin binding. Sequential truncation of the IC heptosesdemonstrated that the MBL targets the IC heptose region. Furthermore, microbial growth temperatureinfluenced MBL binding; binding was stronger to bacteria grown at room temperature (22◦C) than to bac-teria grown at 37◦C. In conclusion, our results demonstrate that MBL can interact with Y. enterocoliticaLPS, however, the in vivo significance of that interaction remains to be elucidated

Serological characterization of the enterobacterial common antigen substitution of the lipopolysaccharide of "Yersinia enterocolitica" O:3

Enterobacterial common antigen (ECA) is a polysaccharide present in all members of Enterobacteriaceae anchored either via phosphatidylglycerol (PG) or LPS to the outer leaflet of the outer membrane (ECAPG and ECALPS, respectively). Only the latter form is ECAimmunogenic. We previously demonstrated that Yersinia enterocolitica O: 3 and its rough (Ospecific polysaccharide-negative) mutants were ECA-immunogenic, suggesting that they contained ECALPS; however, it was not known which part of the LPS core region was involved in ECA binding. To address this, we used a set of three deep-rough LPS mutants for rabbit immunization. The polyvalent antisera obtained were: (i) analysed for the presence of anti-LPS and anti-ECA antibodies; (ii) treated with caprylic acid (CA) to precipitate IgM antibodies and protein aggregates; and (iii) adsorbed with live ECA-negative bacteria to obtain specific anti-ECA antisera. We demonstrated the presence of antibodies specific for both ECAPG and ECALPS in all antisera obtained. Both CA treatment and adsorption with ECA-negative bacteria efficiently removed anti-LPS antibodies, resulting in specific anti-ECA sera. The LPS of the ECALPS-positive deepest-rough mutant contained only lipid A and 3-deoxy-D-manno-oct-2-ulosonic acid (Kdo) residues of the inner core, suggesting that ECALPS was linked to the Kdo region of LPS in Y. enterocolitica O:3

Scabies Mite Peritrophins Are Potential Targets of Human Host Innate Immunity

The gut of most invertebrates is lined by a protective layer of chitin and glycoproteins, often designated as a peritrophic matrix. Previous research suggests that it forms a barrier that may protect the midgut epithelium from abrasive food particles and pathogens. Parasitic invertebrates ingesting vertebrate plasma have evolved additional strategies to protect themselves from hazardous host molecules consumed during feeding. An important part of the immediate defense in vertebrate plasma is complement-mediated killing. The Complement system is a complex network of more than 35 proteins present in human plasma that results in killing of foreign cells including the gut epithelial cells of a feeding parasite. Recently we found that scabies mites, who feed on skin containing plasma, produce several proteins that inhibit human complement within the mite gut. The mites excrete these molecules into the upper epidermis where they presumably also inhibit complement activity. Mite gut antigens that initially trigger the complement cascade have not been identified previously. Obvious possible targets of complement attack within the mite gut could be peritrophins. Our study describes the first peritrophin identified in scabies mites and indicates a possible role in complement activation