Bee venom phospholipase A2 as a membrane-binding vector for cell surface display or internalization of soluble proteins.

We showed that bee venom phospholipase A2 can be used as a membrane-binding vector to anchor to the surface of cells a soluble protein fused to its C-terminus. ZZ, a two-domain derivative of staphylococcal protein A capable of binding constant regions of antibodies was fused to the C-terminus of the phospholipase or to a mutant devoid of enzymatic activity. The fusion proteins bound to the surface of cells and could themselves bind IgGs. Their fate depended on the cell type to which they bound. On the A431 carcinoma cell line the proteins remained exposed on the cell surface. In contrast, on human dendritic cells the proteins were internalized into early endosomes.

Development and preliminary clinical evaluation of a peptide immunotherapy vaccine for cat allergy.

BACKGROUND: Allergic sensitization to cat allergens is common and represents a major risk factor for asthma. Specific immunotherapy (SIT) is effective but cumbersome and associated with IgE-dependent adverse events. Immunotherapy targeting allergen-specific T cells, with synthetic peptides representing T-cell epitopes, might improve safety and reduce the duration of treatment. OBJECTIVE: We sought to define major T-cell epitopes of Fel d 1 for peptide immunotherapy, generate a peptide vaccine, and evaluate its safety and tolerability in subjects with cat allergy. METHODS: We determined the binding affinities of Fel d 1 peptides for 10 commonly expressed HLA-DR molecules. Functionally immunodominant peptides were identified by means of proliferation and cytokine secretion. Histamine-releasing activity was assessed, and a peptide vaccine was formulated. Safety and tolerability were evaluated in a dose-ranging phase IIa clinical trial. RESULTS: MHC-binding sequences were identified throughout Fel d 1. Some regions contained multiple overlapping T-cell epitopes that bound multiple MHC molecules. Immunodominant sequences were identified on the basis of proliferative and cytokine (IFN-γ, IL-10, and IL-13) responses. Cat allergen extract, but not peptides, induced histamine release in blood basophils. A single administration of peptide vaccine was safe and well tolerated. The dose of vaccine resulting in the greatest inhibition of the late-phase skin response to intradermal whole allergen challenge was 3 nmol. CONCLUSIONS: Fel d 1 contains multiple overlapping MHC-binding motifs. A peptide vaccine comprising the immunodominant regions of the allergen was safe and well tolerated when given to subjects with cat allergy as a single dose. The dose of vaccine resulting in the greatest reduction in late-phase skin response was defined for future clinical development.

Immunotherapeutic potential of the immunodominant T-cell epitope of lipocalin allergen Bos d 2 and its analogues.

Lipocalin allergens, which contain most of the important animal-derived respiratory sensitizers, induce T helper type 2 (Th2) deviation, but the reasons for this are not clear. To explore the prospects for peptide-based allergen immunotherapy and to elucidate the characteristics of the immunodominant epitope of Bos d 2, BALB/c mice were immunized with a peptide containing the epitope, peptides containing its analogues, peptides from the corresponding regions of other lipocalin proteins, and peptides with a homologous sequence. We observed that murine spleen cells recognized the immunodominant epitope of Bos d 2, p127-142, in almost the same way as human Bos d 2-specific T cells did. Enzyme-linked immunosorbent spot-forming cell assay (ELISPOT) analyses showed that p127-142 and a corresponding peptide from horse Equ c 1 induced a Th2-deviated cellular response, whereas a homologous bacterial peptide from Spiroplasma citri induced a Th0-type response. Interestingly, the spleen cell response to the bacterial peptide and p127-142 was cross-reactive, that is, able to induce reciprocally the proliferation and cytokine production of primed spleen cells in vitro. More importantly, the peptides were able to skew the phenotype of T cells primed with the other peptide. Our results suggest that modified peptides can be useful in allergen immunotherapy.

Alteration of the tertiary structure of the major bee venom allergen Api m 1 by multiple mutations is concomitant with low IgE reactivity.

We have engineered a recombinant form of the major bee venom allergen (Api m 1) with the final goal of reducing its IgE reactivity. This molecule (Api mut) contains 24 mutations and one deletion of 10 amino acids. The successive introduction of these sequence modifications led to a progressive loss of specific IgE and IgG reactivity and did not reveal any immunodominant epitopes. However, Api mut exhibited a clear loss of reactivity for Api m 1-specific IgE and IgG. Injection of Api mut into mice induced specific antibody production. This humoral response was as high as that induced by the Api m 1 but the cross-reactivity of the antibodies was weak. As inferred by far UV circular dichroism, this mutant was correctly folded. However, near UV circular dichroism and denaturation curves of Api mut showed that it exhibits a dynamic tertiary structure and that it is a highly flexible molecule. Finally, as all the sequence modifications have been introduced outside the human and murine T cell epitope regions, we investigated its T cell properties in mice. We showed that Api mut-specific T lymphocytes induced in vivo were stimulated in vitro by both proteins. These data provide new insights in the design of hypoallergenic molecules.

The immunodominant epitope of lipocalin allergen Bos d 2 is suboptimal for human T cells.

We have proposed earlier that the poor capacity of the lipocalin allergen Bos d 2 to stimulate highly allergic subjects' peripheral blood mononuclear cells could be ascribed to endogenous lipocalins and could be related to the allergenic potential of the molecule. Here, we have characterized the proliferative and cytokine responses of human T cell clones against the immunodominant epitope of Bos d 2. We observed, for clone F1-9, that a substitution of aspartic acid for asparagine in the core region of the epitope increased the stimulatory capacity of the peptide about 100-fold in comparison with the natural peptide. For clone K3-2, from a different patient, the substitution of lysine for glutamine or isoleucine for leucine in the core region resulted in about 30-fold and 10-fold increases in the stimulatory capacity of the peptides, respectively. The clones also recognized self-protein-derived peptides but not the peptides derived from other lipocalins. We suggest that the poor recognition of the immunodominant epitope of Bos d 2 can be a factor accounting for Bos d 2-allergic subjects' weak cellular responses. Suboptimal recognition of self and allergen epitopes by T cells may be of significance for the allergenicity of proteins.

CD4+ T-cell clones specific for wild-type factor VIII: a molecular mechanism responsible for a higher incidence of inhibitor formation in mild/moderate hemophilia A.

Mild/moderate hemophilia A patients carrying certain mutations in the C1 domain of factor VIII (FVIII) have a higher risk of inhibitor occurrence. To analyze the mechanisms responsible for inhibitor development in such patients, we characterized FVIII-specific CD4(+) T-cell clones derived from a mild hemophilia A patient carrying an Arg2150His substitution in the C1 domain and who presented with a high titer inhibitor toward normal but not self-FVIII. All T-cell clones recognized synthetic peptides encompassing Arg2150. The peptides were presented to the T-cell clones by DRB1*0401/DRB4*01 or DRB1*1501/DRB5*01. Interestingly, the latter haplotype was previously reported as being associated with an increased incidence of inhibitor formation. Peptide I2144-T2161 also bound to other DR molecules such as DRB1*0101 and DRB1*0701, indicating that the peptide binds to major histocompatibility complex (MHC) class II molecules expressed in more than 60% of the population. None of the T-cell clones recognized recombinant FVIII carrying the substitution Arg2150His, even when FVIII was presented by an FVIII-specific B-cell line. The mutation likely alters T-cell recognition of the mutated peptide associated to MHC molecules, because the mutated peptide bound to immunopurified DR molecules nearly as effectively as the native peptide. These observations demonstrate that T cells of this patient with mutation Arg2150His distinguish between self- and wild-type FVIII and provide a plausible mechanism for the frequent occurrence of an inhibitor in patients carrying this substitution. A similar phenomenon may occur with other mutations associated to an increased incidence of inhibitor formation.

HLA-DP4, the most frequent HLA II molecule, defines a new supertype of peptide-binding specificity.

Among HLA-DP specificities, HLA-DP4 specificity involves at least two molecules, HLA-DPA1*0103/DPB1*0401 (DP401) and HLA-DPA1*0103/DPB1*0402 (DP402), which differ from each other by only three residues. Together, they are present worldwide at an allelic frequency of 20-60% and are the most abundant human HLA II alleles. Strikingly, the peptide-binding specificities of these molecules have never been investigated. Hence, in this study, we report the peptide-binding motifs of both molecules. We first set up a binding assay specific for the immunopurified HLA-DP4 molecules. Using multiple sets of synthetic peptides, we successfully defined the amino acid preferences of the anchor residues. With these assays, we were also able to identify new peptide ligands from allergens and viral and tumor Ags. DP401 and DP402 exhibit very similar patterns of recognition in agreement with molecular modeling of the complexes. Pockets P1 and P6 accommodate the main anchor residues and interestingly contain only two polymorphic residues, beta86 and beta11, respectively. Both positions are almost dimorphic and thus produce a limited number of pocket combinations. Taken together, our results support the existence of three main binding supertypes among HLA-DP molecules and should significantly contribute to the identification of universal epitopes to be used in peptide-based vaccines for cancer, as well as for allergic or infectious diseases.

Emerging principles for the design of promiscuous HLA-DR-restricted peptides: an example from the major bee venom allergen.

Mechanisms underlying successful immunotherapy of allergic patients operate at the level of CD4+ helper T cells. T cell epitopes from allergens may thus constitute interesting molecules for immunotherapy, provided they are efficient for all patients and are not recognized by IgE. In an attempt to define such peptides for allergy to bee venom, we have investigated the capacity of peptides encompassing the sequence of the major bee venom allergen to stimulate PBMC from allergic patients and to react specifically with their IgE. The region 77-110 emerged as the most frequently T cell stimulating. We then analyzed the binding modes of the sequence 81-97 for ten different HLA-DR molecules and introduced punctual mutations to enhance the peptide affinity for these molecules. Six different modes have been identified on the sequence 81-97, one mode being common to eight HLA-DR molecules. Four HLA-DR molecules can bind the P85-97 peptide by two different modes with an equivalent affinity. The peptide N89L has a higher affinity for DRB1*0301 and DRB3*0101 and remains as active as the native peptide towards the other HLA-DR molecules.