ra5-protein--ambrosia-trifida and Rhinitis--Allergic--Seasonal

The reported significant HLA association is consistent with the codominant expression of MHC-linked Ir genes. Similar studies are needed in the case of the other HLA-immune response associations. It seems unlikely that any unique HLA-D genetic sequence will be found only among subjects responding to a particular Ag. It is likely, however, that we will find that a particular sequence is a necessary, but not sufficient, requirement for responsiveness to a particular antigenic epitope. Previous family studies, in which failed to observed parent-to-child transmission of specific immune responsiveness to a particular allergen, suggest that further genetic and/or environmental factors are required for the expression of specific immune responsiveness. These factors include variations in the degree of antigenic exposure. Of particular importance is the need for Ag-specific TcR genes to be expressed in the mature T-cell repertoire. In study of the specific immune response, there have been several studies of the protein and DNA sequences of allergenic proteins; therefore, in regard to understanding the genetics of specific immune responsiveness to allergens and its relationship to atopic diseases, rapid advances can be anticipated over the next several years.

Topics: Allergens; Antigen-Presenting Cells; Antigens, Plant; Epitopes; Genes, Dominant; Genes, Immunoglobulin; Genes, MHC Class II; HLA-DR Antigens; Humans; Hypersensitivity, Immediate; Immunoglobulin E; Lymphocyte Activation; Plant Proteins; Pollen; Receptors, Antigen, T-Cell; Rhinitis, Allergic, Seasonal

A number of mechanisms participate in virus-induced asthma. Previously, we described enhanced basophil histamine release (HR) during an experimentally induced rhinovirus infection and after in vitro incubation of peripheral blood mononuclear cells (PBMC) with influenza virus. This study extends our previous observations and examines the effect of influenza A virus on basophil leukotriene C4 (LTC4) release as well as the effect of T-cell depletion on virus-enhanced basophil HR. PBMC were isolated from ragweed-allergic subjects and incubated with live influenza A virus or control medium (allantoic fluid). After incubation with influenza A, ragweed antigen (AgE) stimulated LTC4 and HR were enhanced (P less than 0.05). To further define the role of T cells in virus-enhanced basophil secretion, PBMC were isolated and divided into two aliquots. In one aliquot, T cells were removed by magnetic bead separation of mouse monoclonal anti-CD3-coated lymphocytes. T-cell-depleted and nontreated PBMC suspensions were incubated with influenza A or control medium, collected, and challenged with AgE to release histamine. Basophil HR was enhanced in the virus-treated group of PBMC that had not undergone T-cell depletion. In contrast, virus incubation did not enhance HR in the T-cell-depleted fraction. Finally, preliminary analysis of the supernate from virus-treated leukocytes indicates the presence of interferon-gamma. These findings suggest that T cells, and their cytokine products, play an integral role in the process by which viruses enhance basophil HR.

Topics: Adult; Allergens; Antibodies, Monoclonal; Antigens, Plant; Basophils; Cell Survival; Eosinophils; Female; Granulocyte-Macrophage Colony-Stimulating Factor; Histamine Release; Humans; In Vitro Techniques; Influenza A virus; Interferon-gamma; Interleukin-3; Interleukin-5; Lymphocyte Depletion; Male; Plant Proteins; Pollen; Rhinitis, Allergic, Seasonal; SRS-A; T-Lymphocytes

Human IgE and IgG antibody responsiveness to the short ragweed-pollen allergen Amb a V (formerly known as Ra5) has been found to be strongly associated with HLA-D specificities Dw2 and DR2 in ragweed-allergic white individuals. To study the molecular basis of these associations, restriction fragment length polymorphism (RFLP) mapping was performed on a group of 45 white ragweed-allergic patients with full-length HLA-DR beta, DQ beta, and DQ alpha cDNA probes. The data on 41 of these subjects were used for the purposes of statistical analysis. With the DR beta probe, we found that the presence of three polymorphic restriction fragments correlated with responsiveness to Amb a V and with the DR2 specificity, namely, a 6.5 kb Eco RI fragment, a 9.4 kb Hind III fragment, and a 2.2 kb Hind III fragment. The presence of four fragments detected with the DQ beta probe correlated with responsiveness to Amb a V and with Dw2 specificity: a 2.3 kb Eco RI fragment, a 13.0 kb Pst I fragment, a 2.9 kb Taq I fragment, and a 5.2 kb Eco RV fragment. The DR beta Eco RI 6.5 kb and the DQ beta Eco RI 2.3 kb fragments were studied in detail; the concordant presence of these fragments was even more strongly associated with responsiveness to Amb a V. Fifteen of 17 responders had both fragments, whereas only one of 24 nonresponders had both fragments (p = 5 x 10(-7). This is the first time that such an association has been found between a person's immune response to a well-defined antigen and a set of HLA class II DNA restriction fragments.

Topics: Adult; Aged; Allergens; Antigens, Plant; Blotting, Southern; DNA Probes, HLA; HLA-D Antigens; HLA-DQ Antigens; HLA-DR Antigens; Humans; Male; Middle Aged; Plant Extracts; Plant Proteins; Pollen; Polymorphism, Genetic; Polymorphism, Restriction Fragment Length; Rhinitis, Allergic, Seasonal

Giant ragweed pollen allergen Amb.t. V (Ra5G), a homologue of short ragweed pollen Amb.a. V (Ra5S), was isolated in ultrapure form from a 16-min extract of ragweed pollen by a combination of molecular sieving through an Amicon hollow fiber cartridge (H1P5), cation-exchange chromatography, and gel filtration. The size was found to be 4400 daltons (D) by amino acid analysis and 6000 D by SDS-PAGE, and the pI was 8.3 as determined by isoelectric focusing. There was no cross-reactivity detected between the two Amb. V antigens by immunodiffusion and IEP with the use of hyperimmune antisera raised against crude or highly purified antigens. Cross-reactivity between the two Amb. V antigens was further investigated by inhibition double antibody radioimmunoassay by using the sera of nine selected ragweed-allergic patients who had recently been immunized with either mixed short-giant ragweed pollen extract or with short ragweed extract alone and who had IgG antibodies (Ab) to Amb.t. V and generally to Amb.a. V. Unlabeled Amb.t. V did not inhibit the binding of 125I-Amb.a. V to the IgG Ab in any of the sera tested. Conversely, unlabeled Amb.a. V produced some inhibition of the binding of 125I-Amb.t. V to the patients' IgG Ab, primarily in those patients who had received immunotherapy with short ragweed alone. This weak cross-reactivity was probably a result of the primary structural homology between the two protein allergens. The sera from two groups of ragweed-allergic individuals were investigated for the presence of IgG and IgE Ab to Amb.t. V. The presence of IgG Ab was found to be associated both with previous (or current) immunotherapy with giant ragweed extract and with HLA-Dw2. The HLA association is of interest in view of the previously established association between Dw2 and response toward the homologue Amb.a. V. The result suggests the existence of a similar genetic control at the primary level of antigenic recognition of the two Amb. V antigens.

Topics: Allergens; Animals; Antigens; Antigens, Plant; Chemical Fractionation; Chemical Phenomena; Chemistry, Physical; Cross Reactions; Electrophoresis, Agar Gel; Goats; Histocompatibility Antigens Class II; Histocompatibility Testing; Humans; Immunoglobulin G; Plant Proteins; Pollen; Precipitin Tests; Rabbits; Rhinitis, Allergic, Seasonal