Lectinlike properties of pertussis toxin

Immunomodulatory Lectin-like Peptides for Fish Erythrocytes-Targeting as Potential Antiviral Drug Delivery Platforms

One of the challenges of science in disease prevention is optimizing drug and vaccine delivery. Until now, many strategies have been employed in this sector, but most are quite complex and labile. To overcome these limitations, great efforts are directed to coupling drugs to carriers, either of natural or synthetic origin. Among the most studied cell carriers are antigen-presenting cells (APCs), however, red blood cells (RBCs) are positioned as attractive carriers in drug delivery due to their abundance and availability in the body. Furthermore, fish RBCs have a nucleus and have been shown to have a strong involvement in modulating the immune response. In this study, we evaluated the binding of three peptides to rainbow trout RBCs, two lectin-like peptides and another derived from Plasmodium falciparum membrane protein, in order to take advantage of this peptide-RBCs binding to generate tools to improve the specificity, efficacy, immunostimulatory effect, and safety of the antiviral therapeutic or prophylactic administration systems currently used.

Identification of binding proteins for pertussis toxin on pancreatic beta cell-derived insulin-secreting cells

The ability of pertussis toxin (PT) to recognize and bind to surface proteins on cells derived from pancreatic insulin-secreting beta cells and alpha cell-like glucagon-producing cells was investigated employing HIT-T15 (beta cell-derived) and In-R1-G9 (alpha cell-like) cell lines. PT recognition of membrane binding proteins on HIT-T15 and In-R1-G9 cells was first assessed with immunofluorescence microscopy in tissue culture. Both cell lines were equally well recognized by PT. N-octylglucoside extracts of whole cells and isolated membranes were separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) and blotted onto nitrocellulose membranes. PT, the B-oligomer, or the isolated PT dimers S2-S4 and S3-S4 recognized distinct proteins in HIT-T15 and In-R1-G9 cells of about 220 kDa. Recognition by the sialic acid specific Sambucus nigrica lectin identified these proteins as sialoglycoproteins. Incubation of the blotted membrane proteins with sialidase or pretreatment of PT with anti-PT polyclonal antibodies abolished the recognition and binding of these proteins by PT. To demonstrate that these glycoproteins are also able to transduce PT mediated effects and thus might serve as PT binding proteins, the stimulation of insulin secretion in HIT-T15 cells was assessed. As the secretion of insulin in HIT-T15 cells increased about 30% upon interaction with PT it was concluded that these glycoproteins are indeed functional as PT receptors.

The 70-kilodalton pertussis toxin-binding protein in Jurkat cells

125I-ASD photoaffinity-labeling derivatives of pertussis toxin (125I-ASD-PT) or lipopolysaccharide (125I-ASD-LPS) labeled similar 70-kDa proteins in Jurkat cells, a cell line derived from human CD4+ T lymphocytes. Labeling of this 70-kDa protein by 125I-ASD-PT was inhibited by underivatized PT but not by underivatized LPS. However, an immunoglobulin M monoclonal antibody with specificity for the p73 LPS receptor in murine splenocytes (S. W. Bright, T.-Y. Chen, L. M. Flebbe, M.-G. Lei, and D. C. Morrison, J. Immunol. 145:1-7, 1990) inhibited 125I-ASD-PT labeling of the 70-kDa species in Jurkat cells. Our results suggested that PT may bind to the same 70-kDa protein as LPS does in Jurkat cells but that PT and LPS bind to different sites on this receptor candidate. 125I-ASD-PT photoaffinity labeling of the 70-kDa protein was also inhibited by underivatized glycoproteins to which PT has been shown to bind, and this inhibition correlated with the relative binding affinities of the glycoproteins for PT. 125I-ASD derivatives of two sialic acid-specific plant lectins, Maackia amurensis leukoagglutinin and Sambucus nigra agglutinin, with oligosaccharide binding specificities similar to those of PT also labeled a 70-kDa protein in Jurkat cells. This suggests that the 70-kDa PT receptor candidate in Jurkat cells likely contains sialooligosaccharide sequences to which PT, M. amurensis leukoagglutinin, and S. nigra agglutinin bind. The cross-reacting epitope recognized by monoclonal antibody 5D3 in this 70-kDa species might overlap the PT- and LPS-binding sites.

AB5 ADP-ribosylating toxins: comparative anatomy and physiology

The crystal structures recently determined for pertussis toxin, cholera toxin, and E. coli heat-labile toxins promise advances in rational vaccine design and improved understanding of G protein-mediated signal transduction.

Adjuvant action of cholera toxin and pertussis toxin in the induction of IgA antibody response to orally administered antigen

The ability of cholera toxin B-subunit to bind to intestinal epithelium and in particular the dome epithelium of the Peyer's patch can account for its potency as an immunogen. However, pure B-subunit is a less effective immunogen than whole cholera toxin. The immunogenicity of B-subunit may be restored by the addition of either traces of whole toxin or by pertussis toxin. Cholera toxin and pertussis toxin were both able to stimulate a response when fed in conjunction with keyhole limpet haemocyanin, whereas recombinant B- subunit of heat-labile toxin from Escherichia coli had no effect, demonstrating that the adjuvant action is a property of the enzymically active A-subunits. The adjuvant activity of both pertussis toxin and cholera toxin may be due to their ability to cause an increase in the activity of adenylate cyclase via their action on GTP-binding regulatory proteins. However, feeding of forskolin, a direct activator of adenylate cyclase, had no effect on the mucosal immune response, indicating a role for cholera and pertussis toxin which is independent of enhancement of adenylate cyclase activity in the regulation of the immune response. Antibody to pertussis toxin was not detected, which was attributed to inadequate absorption of pertussis toxin.

Role of carbohydrate recognition domains of pertussis toxin in adherence of Bordetella pertussis to human macrophages

Pertussis toxin (PT) and filamentous hemagglutinin can each mediate the association of Bordetella pertussis with human macrophages. Adherence via filamentous hemagglutinin leads to integrin-mediated entry and survival of the bacteria within the human cell. We determined the contribution of PT to bacterial adherence to human macrophages. Plating macrophages on wells coated with recombinant PT subunit 2 (S2) or S3 decreased PT-dependent bacterial binding by greater than 60%; S1, S4, and S5 were ineffective. S3-dependent adherence was reduced 63% +/- 8% by sialic acid, while S2-dependent adherence was reduced 53% +/- 11% by galactose. Loss of the carbohydrate recognition properties of S2 by deletion of residues 40 to 54 or site-specific mutations at Asn-93, His-47, or Arg-50 eliminated the ability of the subunit protein to competitively inhibit bacterial binding. Peptides corresponding to residues 28 to 45 of S2 and S3 competitively inhibited adherence. Treatment of macrophages with antibodies to Le(a) or Le(x) but not CD14, CD15, CD18, or HLA interfered with PT-mediated binding. Exposure of the macrophages to the B oligomer, S2, or S3 increased binding to the CD11b/CD18 integrin. These results indicate that the carbohydrate recognition domains of both S2 and S3 participate in adherence of B. pertussis to human macrophages. The PT receptor(s), as yet unidentified, appears to carry the Le(a) or Le(x) determinants and is functionally capable of modulating integrin-mediated binding to the macrophage.

Pertussis toxin has eukaryotic-like carbohydrate recognition domains

Bordetella pertussis is bound to glycoconjugates on human cilia and macrophages by multiple adhesins, including pertussis toxin. The cellular recognition properties of the B oligomer of pertussis toxin were characterized and the location and structural requirements of the recognition domains were identified by site-directed mutagenesis of recombinant pertussis toxin subunits. Differential recognition of cilia and macrophages, respectively, was localized to subunits S2 and S3 of the B oligomer. Despite greater than 80% sequence homology between these subunits, ciliary lactosylceramide exclusively recognized S2 and leukocytic gangliosides bound only S3. Substitution at residue 44, 45, 50, or 51 in S2 resulted in a shift of carbohydrate recognition from lactosylceramide to gangliosides. Mutational exchange of amino acid residues 37-52 between S2 and S3 interchanged their carbohydrate and target cell specificity. Comparison of these carbohydrate recognition sequences to those of plant and animal lectins revealed that regions essential for function of the prokaryotic lectins were strongly related to a subset of eukaryotic carbohydrate recognition domains of the C type.

Synthesis and characterization of a Pertussis toxin-biotin conjugate

We prepared a Pertussis toxin-biotin conjugate and found its biological properties to be similar to those of native Pertussis toxin with respect to the hemagglutination, Chinese hamster ovary cell, and lymphocyte proliferation assays. Direct binding to Chinese hamster ovary and Jurkat cells was observed using fluorescence microscopy. Pertussis toxin-biotin was also found to possess similar glycoconjugate binding specificities as those of 125I-labeled Pertussis toxin.

Lymphocyte receptors for pertussis toxin

We have investigated human T-lymphocyte receptors for pertussis toxin by affinity isolation and photoaffinity labeling procedures. T lymphocytes were obtained from peripheral human blood, surface iodinated, and solubilized in Triton X-100. The iodinated mixture was then passed through pertussis toxin-agarose, and the fractions were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Autoradiography of the fixed, dried gels revealed several bands in the pertussis toxin-bound fraction that were not observed in fractions obtained from histone or fetuin-agarose. Further investigations employed a photoaffinity labeling reagent, sulfosuccinimidyl 2-(p-azido-salicylamido)-1,3'-dithiopropionate, to identify pertussis toxin receptors in freshly isolated peripheral blood monocytic cells, T lymphocytes, and Jurkat cells. In all three cell systems, the pertussis toxin affinity probe specifically labeled a single protein species with an apparent molecular weight of 70,000 that was not observed when the procedure was performed in the presence of excess unmodified pertussis toxin. A protein comparable in molecular weight to the one detected by the photoaffinity labeling technique was also observed among the species that bound to pertussis toxin-agarose. The results suggest that pertussis toxin may bind to a 70,000-Da receptor in human T lymphocytes.

Comparison of the lectin-like activity of pertussis toxin with two plant lectins that have differential specificities for alpha (2-6) and alpha (2-3)-linked sialic acid

In this report we have compared the lectin-like properties of Pertussis toxin with two plant lectins which are known to possess different specificities towards terminal Neu5Ac Gal linkages on glycoconjugates. The hemagglutinin from elderberry bark (Sambucus nigra) has a binding specificity for terminal Neu5Ac alpha (2-6) Gal sequences and was found to bind a series of glycoconjugates with a similar specificity as Pertussis toxin. The binding specificity of Pertussis toxin was different from that of the leukoagglutinin from the seeds of Maackia amurensis which preferentially binds terminal Neu5Ac alpha (2-3) Gal sequences. These observations confirm the specificity of Pertussis toxin for Neu5Ac alpha (2-6) Gal glycoconjugate sequences.