Human milk lipids bind Shiga toxin.

Hemolytic uremic syndrome, a serious complication of Shiga toxin-associated diarrhea, is rare before 6 months of age. Immunologic and nonimmunologic factors present in human milk may partially explain this observation. In prior studies, we have demonstrated that human milk contains Gb3, the receptor for the B subunit of Shiga toxin, and also contains secretory IgA (sIgA) against the toxin. We therefore sought to determine the relative importance of milk glycolipid and toxin-specific sIgA in toxin binding. We studied two populations that differed in their frequency of exposure to Shiga toxin. Human milk samples obtained from healthy donors from Boston and Buenos Aires were separated by centrifugation into aqueous (antibody enriched) and cream (glycosphingolipid enriched) fractions. An emulsion of equal volumes of aqueous phase or cream layer of each sample and purified Shiga toxin was incubated, and the amount of free toxin present in each was determined by enzyme immunoassay. The cream layers bound 85%+/-2 (mean +/- SE) (Argentina milk samples) and 86%+/-1 (Boston milk samples) of Shiga toxin. In contrast, the soluble fraction in samples from Buenos Aires, a population expected to frequently have antibodies to Shiga toxin, bound more toxin (48%+/-2) than did this fraction in samples from Boston, an area where toxin exposure is infrequent (30%+/-3) (P < 0.0001). Toxin-binding lipids present in human milk are biologically active and may contribute to the putative protective effect of human milk. In a population frequently exposed to Shiga toxins (Argentina), protection may be due to both immune (sIgA), and nonimmune (lipid) factors present in human milk. In a population infrequently exposed to Shiga toxins, cream fraction-associated glycolipids represent the major toxin binding activity in human milk.

Protective role of human lactoferrin against invasion of Shigella flexneri M90T.

Lactoferrin is an iron-binding protein found in human mucosal secretions such as milk. A variety of functions have been ascribed to this protein, it appears to contribute to antimicrobial host defense. Still its overall physiological role remains to be defined. We sought to study the role of recombinant human lactoferrin (rhLf) in Shigella infection. Invasion of epithelial cells is essential to the development of bacillary dysentery. Shigella flexneri 5 M90T, a virulent strain, was evaluated in the classic HeLa cell invasion model, in immunoblots, and by transmission electron microscopy, immunofluorescence, and deconvolved microscopy Bacteria not exposed to rhLf were used as controls. We found that rhLf decreased significantly the invasiveness of S. flexneri 5 M90T in a HeLa cell model. The immunoblot data showed that invasion plasmid antigen B (IpaB) was released from the bacteria during incubation with rhLf. Lactoferrin treatment did not directly dissociate the complex of IpaB and IpaC (IpaBC) once the complex had been formed. Furthermore, ferric iron had no effect on release of IpaB. Electron microscopy of rhLf-treated bacteria suggested a reduction in vacuolization of the HeLa cell cytoplasm and decreased number of bacteria within HeLa cells. At 40,000 x magnification the few rhLf-treated Shigella that invaded exhibited a dense ring completely surrounding them. Immunofluorescence and deconvolved microscopy suggested that rhLf-treated bacteria were completely surrounded by a thick layer of actin. The fact that two cell surface functions (invasion and actin-mediated movement) were deranged suggests that rhLf disrupts the integrity of the bacterial outer membrane in which virulence proteins are anchored. The mechanism by which rhLf impairs Shigella invasiveness may be relevant to other enteropathogens that share similar virulence strategies.