Robert W. Poindexter

Immunologic tolerance in lymphatic filariasis. Diminished parasite-specific T and B lymphocyte precursor frequency in the microfilaremic state.

To explore the mechanisms of antigen-specific immune unresponsiveness seen in microfilaremic patients with bancroftian filariasis, T and B cell precursor frequency analysis was performed using PBMC from individuals with either asymptomatic microfilaremia (MF, n = 7) or chronic lymphatic obstruction (CP, n = 20). Highly purified CD3+ cells were partially reconstituted with adherent cells and their proliferative response to parasite antigens determined in cultures of T cells by limiting dilution analysis. A filter immunoplaque assay also assessed the frequency of both total and parasite-specific Ig-producing B cells. While the lymphocyte proliferation to mitogens and to a nonparasite antigen (Streptolysin-O, [SLO]) were similar in all groups of patients, the frequency of parasite-specific CD3+ T cells was significantly lower (geometric mean [GM], 1/3,757) in MF patients when compared to that in CP patients (GM 1/1,513; P less than 0.001). Similarly, the proportion of lymphocytes producing parasite-specific IgE or IgG was significantly lower in MF patients (IgE mean, 0.2%; IgG mean, 0.33%) compared with CP patients (IgE mean, 3.2%; IgG mean, 1.76%; P less than 0.05 for both comparisons). These observations imply that low numbers of parasite-specific T and B lymphocytes may be partially responsible for the severely diminished capacity of lymphocytes from patients with MF to produce parasite-specific antibody and to proliferate to parasite antigen in vitro. Such differences in parasite-specific lymphocyte responses suggest that tolerance by clonal anergy may be a critical mechanism for maintaining the microfilaremic state.

Antigens from the surface and excretions/secretions of the filariform larva of Strongyloides stercoralis

The surface and excretory/secretory (ES) antigens of the infective, filariform larva (L3) of Strongyloides stercoralis were identified. These studies provide a basis for the purification of these proteins as diagnostic allergens for human strongyloidiasis. The Mr values of the surface and ES molecules were determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography, fluorography, or silver staining following the recovery of these molecules after the radiolabelling of living parasites. At least 10 surface proteins were radioiodinated extrinsically using chloroglycoluril as the catalyst for iodination, and then extracted with detergents and/or beta-mercaptoethanol. Several surface molecules of the L3 were immunogenic in humans, as determined by immunoprecipitation with sera (IHS) from infected patients. About 30 proteins were present in the ES preparation. Many ES antigens were labelled biosynthetically during the culture of larvae in media supplemented with either [35S]methionine or [14C]glucose. Furthermore, several of the surface proteins of the L3 were found with the ES antigens recoverable by culturing larvae in vitro. About 10 of the ES proteins were immunogenic as determined by immunoaffinity chromatography using IHS; and two of these antigens with Mr 50,000 and 90,000 incorporated [35S]methionine during culture of larvae. Moreover, some ES proteins were allergenic when tested in an in vitro assay of histamine release from basophils from infected humans or monkeys. The isotype of the homocytophilic antibodies involved in this immediate hypersensitivity assay, which is the basis of a diagnostic skin test for human strongyloidiasis, appears to be IgE.

Use of monoclonal antibodies to quantify subclasses of human IgG: II. Enzyme immunoassay to define antigen specific (anti-filarial) IgG subclass antibodies

Because of their single epitope specificity, monoclonal antibodies (Mcabs) may perform with different levels of efficiency in immunoassays depending on the accessibility of the particular epitope recognized. In order to develop assays capable of detecting specific antibodies of each of the four human IgG subclasses, we have evaluated by ELISA the performance characteristics of a panel of Mcabs raised to the subclass proteins. At least one Mcab to each of the four subclasses was identified that was specific in its ability to capture its own relevant IgG subclass without any associated light chain, allotype or isoallotype activity and that was able to function effectively as a probe in an optimized, quantitative ELISA. When IgG subclass antibodies were measured in sera from patients with filariasis using specific filarial antigen, the sensitivities of each subclass antibody assay varied; for IgG1 and IgG4 antibodies the sensitivity of detection was 50 ng/ml and for IgG2 and IgG3, 10 ng/ml. The potency of the Mcab, determined by its titration for use as a probe, did not correlate with the sensitivity of the assay. These Mcabs were also capable of defining IgG subclass antibody responses qualitatively in immunoblot analyses with little or no non-specific binding. The availability of such highly characterized Mcabs for use in quantitative and qualitative definition of specific IgG subclass antibody responses should greatly improve our detection and subsequent understanding of the role of these IgG subclasses in various disease states.