ovalbumin and metaperiodate

Intact, inactivated Streptococcus pneumoniae [including the unencapsulated S. pneumoniae, serotype 2 strain (R36A)] markedly inhibits the humoral immune response to coimmunized heterologous proteins, a property not observed with several other intact Gram-positive or Gram-negative bacteria. In this study, we determined the nature of this immunosuppressive property. Because phosphorylcholine (PC), a major haptenic component of teichoic acid in the S. pneumoniae cell wall, and lipoteichoic acid in the S. pneumoniae membrane were previously reported to be immunosuppressive when derived from filarial parasites, we determined whether R36A lacking PC (R36A(pc-)) was inhibitory. Indeed, although R36A(pc-) exhibited a markedly reduced level of inhibition of the IgG response to coimmunized chicken OVA (cOVA), no inhibition was observed when using several other distinct PC-expressing bacteria or a soluble, protein-PC conjugate. Further, treatment of R36A with periodate, which selectively destroys PC residues, had no effect on R36A-mediated inhibition. Because R36A(pc-) also lacks choline-binding proteins (CBPs) that require PC for cell wall attachment, and because treatment of R36A with trypsin eliminated its inhibitory activity, we incubated R36A in choline chloride, which selectively strips CBPs from its surface. R36A lacking CBPs lost most of its inhibitory property, whereas the supernatant of choline chloride-treated R36A, containing CBPs, was markedly inhibitory. Coimmunization studies using cOVA and various S. pneumoniae mutants, each genetically deficient in one of the CBPs, demonstrated that only S. pneumoniae lacking the CBP pneumococcal surface protein A lost its ability to inhibit the IgG anti-cOVA response. These results strongly suggest that PspA plays a major role in mediating the immunosuppressive property of S. pneumoniae.

Topics: Animals; Bacterial Proteins; Immune Tolerance; Immunization; Immunoglobulin G; Immunosuppressive Agents; Mice; Mutation; Ovalbumin; Periodic Acid; Phosphorylcholine; Streptococcus pneumoniae; Trypsin

Innate immunity directs the adaptive immune response by identifying antigens that are associated with infectious agents. Although some microbial antigens can be recognized by innate immune receptors, most cannot, and these require identification by some other means. The introduction of aldehydes into antigens by glycolaldehyde, which can be produced by activated neutrophils reacting with serine, or by the oxidation of an N-linked oligosaccharide with NaIO4, enhances by several orders of magnitude their immunogenicity in mice. The augmented immunogenicity requires the presence of an aldehyde on the antigen, and is not dependent on protein aggregation. An in vitro correlate of augmented immunogenicity is the enhanced presentation of glycolaldehyde-modified antigen to T cells by macrophages and bone marrow-derived dendritic cells. The potential clinical importance of this form of antigen modification is twofold: glycolaldehyde renders a model self antigen immunogenic, and it converts a relatively non-immunogenic malaria antigen, merozoite surface protein-1, into an effective immunogen. Thus, the tagging of antigens by the addition of aldehydes, which may be an innate immune mechanism to facilitate their recognition by the adaptive immune system, may have a role in the genesis of autoimmunity and the development of vaccines.

Topics: Acetaldehyde; Aldehydes; Animals; Antibody Formation; Antigens; Antigens, Protozoan; Autoantigens; Autoimmunity; Chickens; Columbidae; Cytochrome c Group; Immunity, Innate; Merozoite Surface Protein 1; Mice; Muramidase; Neutrophils; Ovalbumin; Oxidation-Reduction; Periodic Acid; Serine; Structure-Activity Relationship; Vaccines

Topics: Alkylation; Biochemical Phenomena; Biochemistry; Chemical Phenomena; Chemistry; Chromatography; Formates; Glycopeptides; Glycoproteins; Ovalbumin; Peptides; Periodic Acid; Research

Topics: Animals; Carbohydrates; Chickens; Female; Glycopeptides; Glycoproteins; Ovalbumin; Periodic Acid; Proteins