Julian F. Bond

Definition of the human T-cell epitopes of Fel d 1, the major allergen of the domestic cat

BACKGROUND A heterodimeric acidic glycoprotein (Fel d 1) has been defined as the major allergen of the domestic cat. Because T-cell help is required for the initiation and maintenance of allergic responses, it is of importance to determine the T-cell-reactive regions of the Fel d 1 molecule. METHODS Overlapping peptides corresponding to the two chains of Fel d 1 were tested in proliferation assays on polyclonal T-cell lines and for the ability to bind Fel d 1-specific IgE in ELISA and histamine release assays. RESULTS Assay of T-cell lines derived from 53 subjects allergic to cats demonstrated that the majority of T-cell reactivity is found in chain 1 of Fel d 1. Two peptides (Fel-1 and Fel-2) containing major epitopes, alone or as a mixture, efficiently activated T cells and exhibited minimal detectable reactivity with IgE by ELISA or histamine release assay. CONCLUSIONS Two Fel d 1 peptides containing major T-cell epitopes have been identified, have been shown to bind minimal Fel d 1-specific IgE, and are now being tested for the ability to decrease T-cell responses in patients with cat allergy as a new form of immunotherapy.

Native and recombinant Fel dI as probes into the relationship of allergen structure to human IgE immunoreactivity

To delineate the relationship between the structural conformation and the stability of an allergen and its antigenicity, we have chosen the major allergen from cat dander, Fel dI. From protein sequence analysis data we have examined the structure of the naturally occurring Fel dI and we have found it to exist as an anti-parallel heterodimer. We have used ELISA, RAST, Western blot and histamine release techniques to compare the IgE reactivity of a set of cat allergic patient samples to purified, native Fel dI and the E. coli expressed chains 1 and 2. Results from these studies demonstrate a significant level of IgE reactivity to all forms when examined for direct binding. However, both blot and ELISA competition assays show a much higher reactivity to Fel dI in solution compared to the separate recombinant chains and this is supported by the histamine release data. Although native Fel dI chain 2 contains an N-linked carbohydrate moiety, this does not seem to play a role in the reactivity of IgE to chain 2. Denaturation of Fel dI with alkali conditions leads to a dramatic decrease in IgE reactivity, even though measurable changes to the backbone structure of the protein are minimal. One proposed explanation is that both chains possess a core region determined by their primary structures and that the major IgE epitopes are dependent upon them. The relative reactivity amongst these allergen forms varied with the method of analysis, implying that the conformational requirements for IgE antibody binding are best studied by the application of more than one experimental protocol. Results from these qualitative analyses afford insight into the allergenicity of this exceptionally stable cat pelt protein.

Potential therapeutic recombinant proteins comprised of peptides containing recombined T cell epitopes

The complete primary structure of Fel d I2 has been determined and shown to be comprised of two separate polypeptide chains (designated chain 1 and 2). Overlapping peptides covering the entire sequence of both chains of Fel d I have been used to map the major areas of human T cell reactivity. The present study describes three non-contiguous T cell reactive regions of < 30 aa in length that were assembled in all six possible configurations using PCR and recombinant DNA methods. These six recombinant proteins comprised of defined non-contiguous T cell epitope regions artificially combined into single polypeptide chains have been expressed in E. coli, highly purified, and examined for their ability to bind to human cat-allergic IgE and for human T cell reactivity. Several of these recombined T cell epitope-containing polypeptides exhibit markedly reduced IgE binding as compared to the native Fel d I. Importantly, the human T cell reactivity to individual T cell epitope-containing regions is maintained even though each was placed in an unnatural position as compared to the native molecule. In addition, T cell responses to potential junctional epitopes were not detected. It was also demonstrated in mice that s.c. injection of T cell epitope-containing polypeptides inhibits the T cell response to the individual peptides upon subsequent challenge in vitro. Thus, these recombined T cell epitope-containing polypeptides, which harbor multiple T cell reactive regions but have significantly reduced reactivity with allergic human IgE, constitute a novel potential approach for desensitization to important allergens.

Enhanced immunoreactivity and preferential heterodimer formation of reassociated Fel d I recombinant chains

In this study we have addressed the question of whether reassociating the two recombinant protein chains that comprise the major cat dander allergen, Fel d I, would change the overall IgE and allergic patient T cell immunoreactivity compared to the native molecule. To accomplish this, the chains were combined under reducing and denaturing conditions, then allowed to reassociate by dilution and extensive dialysis against a physiological buffer. An initial examination of the reaction products using quantitative capture ELISA demonstrated comparable reactivity to Fel d I. Further analysis, using a pool of cat allergic patient plasma, showed that the products of the reassociation reaction (rFel d I) also possessed an enhanced IgE binding capacity. Depletion ELISA results gave only a 5% difference in reactivity between rFel d I and the native protein versus a 20% difference with the mixture of the two chains. Comparative secondary T cell stimulation assays were subsequently performed using cat allergic patient peripheral blood lymphocytes. Here the results demonstrated no loss of reactivity with the reassociated chains as compared to Fel d I or the two mixed recombinant chains. To biochemically characterize the products of the reassociation reaction we have performed reverse phase HPLC and then analysed the isolated fractions by mass spectrometry. It was clear from these results that like the native Fel d I, the products of the reassociation reaction favored heterodimer formation, with no homodimer being detected. This implies that the reassociated protein chains had preferentially adopted a native-like conformation.

Purification and immunochemical characterization of recombinant and native ragweed allergen Amb a II

The complete sequence of a cDNA encoding Amb a II and its relationship to the Amb a I family of allergens has recently been described [Rogers et al. (1991) J. Immun. 147, 2547-2552; Griffith et al. (1991a), Int. Archs Allergy appl. Immun. 96, 296-304]. In this study, we present results generated with rabbit antipeptide antisera that recognize Amb a II or Amb a I, but not both. The specificity of two anti-Amb a II antipeptide sera, anti-RAE-50.K and anti-RAE-51.K, was verified on Western blots of recombinant Amb a II and Amb aI.1. These two sera, directed against separate regions of the Amb a II molecule, detected three individual 38-kDa Amb a II isoforms on 2D Western blots of aqueous ragweed pollen extract. These Amb a II isoforms have pI in the 5.5-5.85 range and can be easily distinguished from Amb a I isoforms with pI in the 4.5-5.2 range detected by an anti-Amb a I specific peptide antiserum. The Amb a II isoforms have also been individually purified from pollen, positively identified as Amb a II by amino acid sequencing, and visualized as separate bands on IEF gels. An analysis of Amb a II cDNA sequences generated by PCR led to the prediction of three Amb a II isoforms with pI of 5.74, 5.86 and 5.97 that are very similar to the pI deduced from 2D Western blot analysis. Recombinant Amb aI.1 and Amb a II have been expressed in E. coli, purified in their denatured form, and examined by ELISA for their capacity to bind pooled allergic human IgE. Purified native Amb a and Amb a II from pollen were shown to have very similar IgE-binding properties. In contrast, Amb a II had a markedly reduced IgE-binding capacity as compared to Amb a I.1. These data suggest that recombinant Amb a I.1 and Amb a II, isolated in a denatured form, differ significantly in their IgE-binding properties whereas the native molecules isolated from pollen do not.

Perspective of purified natural and recombinant allergens in diagnosis and treatment of inhalant allergies.

nant allergens was tested in sera of patients with allergy to grass pollen (n=141) [1], birch pollen (n=220) [2] or cat epithelium (n=509) [manuscript in preparation]. Sera were selected on a positive RAST to whole allergen extracts. For each of the allergen sources two purified allergens were tested: Lol p 1 and Lol p 5 in case of grass pollen, Bet v 1 and Bet v 2 (profilin) for birch pollen and Fel d 1 and cat albumin in case of cat epithelium. These three combinations of purified natural allergens gave less than 10% false-negative RAST results, compared to the whole allergen extracts. However, all false-negative sera were low-responder sera on whole allergen extracts: RAST results were almost without exception in the class 1+. These observations indicate that reliable in vitro diagnosis is possible with a limited number of individual allergens. This is not only true for relatively simple allergen sources like cat and birch, but also for grass pollen. Are recombinant molecules suitable to replace natural allergens for the purpose of in vitro diagnosis [3–6]? Five Allergen Testing and Immunotherapy: Current and Future Approaches

Immunological Characterization of the Major Ragweed Allergens Amb a I and Amb a II

Pollen from short ragweed (Ambrosia artemisiifolia) is the source of one of North America’s most important allergens (King, 1976). Ambrosia artemisiifolia is a widespread weed of the Compositae family, which is comprised of several related species (King and Norman, 1986). Although the pollinating season for ragweed varies depending on the geographical location, it is generally from midsummer to late autumn in the eastern and central United States. Approximately 10% of the U.S. population is allergic to ragweed pollen, making this allergen source highly significant in terms of clinical disease.