Recombinant allergens for analysing T-cell responses

T-cell responses constitute a central element of allergic disease and a model for studying Th1 and Th2 cytokine pathways. Most studies to date have used extracts of allergens which contain variable quantities of different allergens and non-allergenic antigens. Recombinant allergens provide the tools for studying the responses to allergens in a reproducible and dose-dependent manner and the different T-cell responses of allergic and non-allergic subjects provide a method for verifying the responses and their relationship to allergic sensitisation. Most allergies show dominant responses to one or a few major allergens. These allergens have been described for the common allergies and have been produced as recombinant allergens. A particular problem for allergens is that many are mixtures of proteins from multi-gene families or are highly polymorphic. Information now exists so the sequence variation can be represented. Purified recombinant allergens produced by standard expression systems stimulate the expected T-cell responses from the peripheral blood of allergic and non-allergics to allergen extracts. Although stimulation with recombinant allergens which are not produced with a natural IgE binding activity can provide a measure of allergenicity, the altered tertiary structure can reduce Th2 responses. The sequence information now available provides the means to use PCR to produce cDNA for the production of recombinant allergens from readily available sources. The production of the highly reactive recombinant Der p 2 allergen of house dust mite from natural sources is described.     

东亚飞蝗主要过敏原的分析、鉴定与纯化

通过十二烷基硫酸钠-聚丙烯酰胺凝胶电泳(SDS-PAGE)分离东亚飞蝗Locusta migratoria manilensis(Meyen)的蛋白质组分并测定其分子量,收集过敏病人血清,采用免疫印迹(Western—blotting)法鉴定其过敏原成分,通过凝胶过滤层析对东亚飞蝗过敏原进行分离纯化。结果表明:东亚飞蝗蛋白粗提液条带大概有30条左右,其中主带大约有10条,相对分子量约为13、15、25、28、40、45、55、70、100、110ku,其中蛋白含量最丰富的约在70ku左右。免疫印迹结果显示,蝗虫过敏条带主要有5条,相对分子量分别约为19、29、38、70、130ku。通过凝胶过滤层析对东亚飞蝗过敏原进行分离纯化,得到了一个高纯度相对分子质量约为70ku东亚飞蝗过敏原,并且发现了一个相对分子质量约为130ku的蝗虫新过敏原。本研究为临床上蝗虫食物变态反应性疾病的诊断和治疗奠定基础。     

Nucleotide sequence analysis of three cDNAs coding for Poa p IX isoallergens of Kentucky bluegrass pollen.

Grass pollen allergens are one of the major causes of type I allergic reactions (allergic rhinoconjunctivitis, allergic bronchial asthma, and hayfever) in temperate climates afflicting 15-20% of a genetically predisposed population. Workers have found considerable physico- and immunochemical heterogeneity within the grass pollen allergens which has made them difficult to purify for both therapeutic uses and further biochemical study. We recently reported the construction of a cDNA library in lambda gt11 using mRNA extracted from dehydrated Kentucky bluegrass (KBG, Poa pratensis). Here, we present the nucleotide and deduced amino acid sequences for three KBG pollen allergen cDNA clones, KBG 41, 60, and 31, which were isolated from the above library using a pool of six sera from grass pollen allergic patients. These clones exhibit an exceptionally high degree of sequence similarity to one another, only minor similarity to other known allergens, and no homologies to other known proteins or genes. The predicted molecular mass for the cloned proteins range from 28.3 to 37.8 kDa with pI values of 9.6-10.2. All three clones appear to possess leader peptides and lack asparagine sequons required for N-glycosylation. Therefore, the molecular mass of the post-translationally modified proteins were calculated to be 28.4-34.9 kDa, which is consistent with the size of the polypeptides revealed in Western blots of pollen proteins using an antiserum to a recombinant peptide encoded by the partial cDNA clone KBG 8.3. Northern blotting analysis indicates that expression of the genes corresponding to these clones is confined to pollen tissue. The results suggest that the clones code for a group of proteins that represent a new and previously uncharacterized group of grass pollen isoallergens, which have been hereby designated as Poa p IX.     

Disruption of allergenic activity of the major grass pollen allergen Phl p 2 by reassembly as a mosaic protein

The recognition of conformational epitopes on respiratory allergens by IgE Abs is a key event in allergic inflammation. We report a molecular strategy for the conversion of allergens into vaccines with reduced allergenic activity, which is based on the reassembly of non-IgE-reactive fragments in the form of mosaic proteins. This evolution process is exemplified for timothy grass pollen-derived Phl p 2, a major allergen for more than 200 million allergic patients. In a first step, the allergen was disrupted into peptide fragments lacking IgE reactivity. cDNAs coding for these peptides were reassembled in altered order and expressed as a recombinant mosaic molecule. The mosaic molecule had lost the three-dimensional structure, the IgE reactivity, and allergenic activity of the wild-type allergen, but it induced high levels of allergen-specific IgG Abs upon immunization. These IgG Abs crossreacted with group 2 allergens from other grass species and inhibited allergic patients' IgE binding to the wild-type allergen. The mosaic strategy is a general strategy for the reduction of allergenic activity of protein allergens and can be used to convert harmful allergens into safe vaccines.     

Baculoviral infection reduces the expression of four allergen proteins of silkworm pupa

Silkworm (Bombyx mori) larvae are widely used to express exogenous proteins. Moreover, some silkworm pupal proteins can be used as drug‐loading materials for selfexpressed oral tolerance drugs. However, several proteins expressed in silkworm pupae cause severe allergic reactions in humans and animals. Interestingly, some baculovirus vectors have been shown to alter the host gene and its expression in insect cells, but this has not been confirmed in silkworm. Here, we analyzed the effects of infection with an empty B. mori baculovirus (BmNPV) vector on silkworm pupal protein expression. Using a proteomics approach, the allergens thiol peroxiredoxin (Jafrac1), 27‐kDa glycoprotein (p27k), arginine kinase, and paramyosin as well as 32 additional differentially expressed proteins were identified. Downregulation of the messenger RNA expression of the four known allergens was observed after BmNPV infection; subsequent changes in protein expression were confirmed by the western blot analysis using polyclonal antibodies prepared with recombinant proteins of the four allergens. Collectively, these data indicate that the four known allergens of silkworm pupae can be reduced by infection ith an empty BmNPV vector to increase the safety of silkworm pupa‐based exogenous protein expression and drug delivery of oral pharmaceuticals. In addition, the four recombinant allergen proteins may contribute to the diagnosis of allergic diseases of silkworm pupa.     

Identification of a villin-related tobacco protein as a novel cross-reactive plant allergen

In a paradigmatic approach we identified cross-reactive plant allergens for allergy diagnosis and treatment by screening of a tobacco leaf complementary DNA (cDNA) library with serum IgE from a polysensitized allergic patient. Two IgE-reactive cDNA clones were isolated which code for proteins with significant sequence similarity to the actin-binding protein, villin. Northern- and Western-blotting demonstrate expression of the villin-related allergens in pollen and somatic plant tissues. In addition, villin-related proteins were detected in several plant allergen sources (tree-, grass-, weed pollen, fruits, vegetables, nuts). A recombinant C-terminal fragment of the villin-related protein was expressed in Escherichia coli, purified and shown to react specifically with allergic patients IgE. After profilin, villin-related proteins represent another family of cytoskeletal proteins, which has been identified as cross-reactive plant allergens. They may be used for the diagnosis and treatment of patients suffering from multivalent plant allergies.     

Major house dust mite allergens Dermatophagoides pteronyssinus 1 and Dermatophagoides farinae 1 degrade and inactivate lung surfactant proteins A and D

Lung surfactant proteins (SP) A and D are calcium-dependent carbohydrate-binding proteins. In addition to playing multiple roles in innate immune defense such as bacterial aggregation and modulation of leukocyte function, SP-A and SP-D have also been implicated in the allergic response. They interact with a wide range of inhaled allergens, competing with their binding to cell-sequestered IgE resulting in inhibition of mast cell degranulation, and exogenous administration of SP-A and SP-D diminishes allergic hypersensitivity in vivo. House dust mite allergens are a major cause of allergic asthma in the western world, and here we confirm the interaction of SP-A and SP-D with two major mite allergens, Dermatophagoides pteronyssinus 1 and Dermatophagoides farinae 1, and show that the cysteine protease activity of these allergens results in the degradation of SP-A and SP-D under physiological conditions, with multiple sites of cleavage. A recombinant fragment of SP-D that is effective in diminishing allergic hypersensitivity in mouse models of dust mite allergy was more susceptible to degradation than the native full-length protein. Degradation was enhanced in the absence of calcium, with different sites of cleavage, indicating that the calcium associated with SP-A and SP-D influences accessibility to the allergens. Degradation of SP-A and SP-D was associated with diminished binding to carbohydrates and to D. pteronyssinus 1 itself and diminished capacity to agglutinate bacteria. Thus, the degradation and consequent inactivation of SP-A and SP-D may be a novel mechanism to account for the potent allergenicity of these common dust mite allergens.     

Cloning allergens via phage display

Although an impressive list of allergenic structures has been elucidated during the last decade by classical cloning methods, the size of the repertoire of molecular structures able to elicit allergic reactions is still unknown. Selective enrichment of cDNA libraries displayed on phage surface with serum IgE from allergic individuals combined with robotic-based high-throughput screening technology has proved to be extremely successful for the rapid isolation of allergens. The basic concept of linking the phenotype, expressed as gene product displayed on the phage coat, to its genetic information integrated into the phage genome, creates fusion proteins covalently associated with the infectious particle itself. Therefore, cDNA libraries displayed on phage surface can be screened for the presence of specific clones using the discriminative power of affinity purification. The selection of IgE-binding clones involves the enrichment of phage binding to serum IgE immobilised to a solid phase during consecutive rounds of affinity selection. As a consequence of the physical linkage between genotype and phenotype, sequencing of the DNA of the integrated section of the phage genome can readily elucidate the amino acid sequence of the surface-displayed allergen. In spite of some biological limitations imposed by Escherichia coli as expression host, phage surface display technology has strongly contributed to the rapid isolation of a vast variety of IgE-binding structures.     

植物过敏性蛋白质及其生物学功能

在引起I型超敏反应的变应原中 ,植物的花粉、果实和汁液可以分别作为吸入性变应原 (inhalentallergen)、食入性变应原 (ingestentallergen)、接触性变应原 (contactentallergen)使过敏者患上鼻炎、哮喘、枯草热等疾病。而其中引起这些超敏反应的植物类蛋白质本身在植物体内亦行使着特定的生物学功能。对这些植物类过敏性蛋白质的研究不仅在植物学本身研究中具有一定意义 ,同时在变态反应性疾病的免疫治疗中亦具有重要的应用价值。目前 ,这类涉及植物学、免疫学和变态反应学的研究逐渐形成了一个新的交叉研究领域。     

An attempt to define allergen-specific molecular surface features: a bioinformatic approach

Allergens are proteins that elicit T helper lymphocyte type 2 (Th2) responses culminating in IgE antibody production and allergic disease. However, we have no answer to the fundamental question of why certain proteins are allergens, while others are not. We hypothesized that analysis of the surface of diverse allergens may reveal common structural features which might enable them to be recognized as Th2-inducing antigens by cells of the innate immune system. We have therefore used the ConSurf server to search for allergen-specific motifs. This has enabled us to identify residue conservation patterns in the homologues of Ara t 8 (plant profilin), Act c 1 (actinidin), Bet v 1 (plant pathogenesis-related protein) and Ves v 5 (venom allergen). The results demonstrate the presence of allergen-specific patches consisting of an unusually high proportion of surface-exposed hydrophobic residues. The patches that have been identified may represent molecular patterns recognizable by cells of the innate immune system.     

Sub-proteome analysis of novel IgE-binding proteins from Bermuda grass pollen

Bermuda grass (Cynodon dactylon) pollen (BGP) is one of the most common causes of airway allergic disease, and has been shown to contain over 12 allergenic proteins on 1-D immunoglobulin E (IgE) immunoblots. However, only a few allergens have been identified and characterized. Cyn d 1 is a major allergen and the most abundant protein in BGP, representing 15% of the whole-pollen extract. To investigate variability in the IgE-reactive patterns of BGP-sensitized patients and to identify other prevalent allergens, a BGP extract was passed through an affinity column to remove Cyn d 1, and the non-bound material was collected and analyzed by 2-DE. IgE-reactive proteins were subsequently characterized by immunoblotting using serum samples from ten BGP-allergic patients. The prevalent IgE-reactive proteins were identified by MALDI-TOF MS, N-terminal sequence similarity, and LC-MS/MS. Here, we present a sub-proteome approach for allergen investigation and its use for determining BGP 2-DE profiles and identifying six novel allergens.     

Purification and partial characterization of two basic proteins from human peripheral nerve.

Two basic proteins, denoted P1 and P2 protein, were purified from human sciatic nerve. The isolation was achieved by the following steps: delipidation with chloroform/methanol mixtures, dry acetone and dry ether; acid extraction at pH 2; ion exchange chromatography on QAE-Sephadex A-25 and gel filtration on Sephadex G-100. P1, P2 proteins and the basic protein of the central nervous system have been shown to have different electrophoretic mobility, and each of the two peripheral basic proteins was shown to be homogeneous by disc electrophoresis. The molecular weight of P1 protein is around 14 100 and that of P2 protein is around 12 200, as determined by ultracentrifugal analysis. There was some difference in the amino acid composition of human P1 and P2 protein, and a marked difference between their composition and the composition of central basic protein and bovine peripheral P1 and P2 proteins which were described previously. When injected to animals, P1 protein induced only experimental allergic neuritis while P2 protein induced both mild experimental allergic neuritis and experimental allergic encephalomyelitis. Thus, the human P1 protein is similar to the bovine P1 protein and human P2 protein is similar to bovine P2 protein, concerning their electrophoretic mobilities, molecular weights and biological properties.     

Proteome of conidial surface associated proteins of Aspergillus fumigatus reflecting potential vaccine candidates and allergens

Aspergillus fumigatus is a mold causing most of the invasive fungal lung infections in the immunocompromised host. In addition, the species is the causative agent of certain allergic diseases. Both in invasive and in allergic diseases, the conidial surface mediates the first contact with the human immune system. Thus, conidial surface proteins may be reasonable vaccine candidates as well as important allergens. To broaden the list of those antigens, intact viable Aspergillus conidia were extracted with mild alkaline buffer at pH 8.5 in the presence of a 1,3-beta-glucanase. The proteome of this fraction was separated by two- dimensional gel electrophoresis (2-DE) and analyzed by liquid chromatography coupled with tandem mass spectrometry. Altogether 26 different A. fumigatus proteins were identified, twelve of which contain a signal for secretion. Among these were the known major conidial surface protein rodlet A, one acid protease PEP2, one lipase, a putative disulfide isomerase and a putative fructose-1,6-biphosphatase. The known allergen Aspf 3 was identified among the proteins without a signal for secretion. On the basis of the recently annotated A. fumigatus genome (Nature 2005, 438, 1151-1156), proteome analysis is now a powerful tool to confirm expression of hypothetical proteins and, thereby to identify additional vaccine candidates and possible new allergens of this important fungal pathogen.     

Isolation of three allergenic fractions of the major allergen from Olea europea pollen and N-terminal amino acid sequence

A method to isolate the major allergen from olive pollen (Ole e I) in high yield is described. The allergenic fraction has been separated into 3 subfractions by reverse-phase HPLC. All these fractions were reactive to allergic sera from olive-sensitized patients, giving similar responses. No significant differences were observed between the amino acid compositions of these three proteins. The amino acid sequence of the first 27 amino acid residues from the N-terminal end is given. No homologies have been detected between Ole e I and other known allergens obtained from pollen.     

Identification of grass pollen allergens by two-dimensional gel electrophoresis and serological screening

Approximately 50% of allergic patients are sensitized against grass pollen allergens. The characterization of specific immunoglobulin E (IgE) reactivity to allergen components in pollen-allergic patients is fundamental for clinical diagnosis and for immunotherapy. Complex allergen extracts are commonly used in diagnostic tests as well as in immunotherapy preparations, but their composition in single allergenic molecules is only partially known. Diagnostic tests which utilize recombinant or immuno-purified allergens have been made available in clinical practice. They allow to obtain specific profiles of IgE reactivity, but the panel of available molecules is far from complete. Here, we used a proteomic approach in order to detect grass allergens from a natural protein extract. A five-grass pollen extract used for diagnosis and immunotherapy was resolved by two dimensional gel electrophoresis (2-DE), and assayed with 9 sera from pollen-allergic patients whose sensitization profile was dissected by using IgE reactivity to recombinant allergens. 2-DE immunoreactivity patterns were matched with IgE reactivity to identify protein spots as candidate allergens. Identity was confirmed by mass spectrometry analysis. We identified 6 out of 8 expected clinically relevant allergens in the natural grass extract. Moreover, we identified different molecular isoforms of single allergens, thus obtaining a more detailed profile of IgE reactivity. Some discrepancies in protein isoform profile and sera immunoreactivity between recombinant and native allergen 5 from Phleum pratense were observed and a new putative allergen was described. The proteomic approach applied to the analysis of a natural allergen allows the comprehensive evaluation of the sensitization profile of allergic patients and the identification of new allergens.     

Prediction of Bacterial and Archaeal Allergenicity with AllPred Program

Nowadays, allergic disorders have become one of the most important social problems in the world. This can be related to the advent of new allergenic agents in the environment, as well as an increasing density of human contact with known allergens, including various proteins. Thus, the development of computer programs designed for the prediction of allergenic properties of proteins becomes one of the urgent tasks of modern bioinformatics. Previously we developed a web accessible Allpred Program (http://www-bionet.sscc.ru/ psd/cgi-bin/programs/Allpred/allpred.cgi) that allows users to assess the allergenicity of proteins by taking into account the characteristics of their spatial structure. In this paper, using AllPred, we predicted the allergenicity of proteins from 462 archaea and bacteria species for which a complete genome was available. The segregation of considered proteins on archaea and bacteria has shown that allergens are predicted more often among archaea than among bacteria. The division of these proteins into groups according to their intracellular localization has revealed that the majority of allergenic proteins were among the secreted proteins. The application of methods for predicting the level of gene expression of microorganisms based on DNA sequence analysis showed a statistically significant relationship between the expression level of the proteins and their allergenicity. This analysis has revealed that potentially allergenic proteins were more common among highly expressed proteins. Sorting microorganisms into the pathogenic and nonpathogenic groups has shown that pathogens can potentially be more allergenic because of a statistically significant greater number of allergens predicted among their proteins.     

Characterization of Aspergillus fumigatus protein disulfide isomerase family gene.

Aspergillus fumigatus is an opportunistic fungus which causes pulmonary complications in humans and animals. The clinical spectrum observed with A. fumigatus is attributed to the multifunctional nature of its antigens. Lack of understanding on the molecular processes and complexity of the fungus have spurred interest in the identification and characterization of its antigens/allergens with biological activities and virulence functions. For identification of some of these antigens/allergens, a cDNA library of A. fumigatus was screened with antibodies of allergic bronchopulmonary aspergillosis (ABPA) patients. One of the reactive clones was sequenced and observed to have an open reading frame of 1095 nucleotides corresponding to a polypeptide of 364 amino acids. The nucleotide and deduced amino acid sequence showed significant homology with the protein disulfide isomerase (PDI) superfamily. The expressed recombinant fusion protein exhibited specific IgG and IgE binding with antibodies present in ABPA patients' sera. The recombinant protein in vitro catalyzed folding of scrambled RNase. The probable epitopic regions of the deduced amino acid sequence were mapped by algorithmic analysis. This is the first report of isolation of a gene encoding a member of the PDI family from A. fumigatus. The PDI superfamily of proteins may play an important role in the protein folding mechanisms of A. fumigatus antigens/allergens for their interaction with the host.     

Detection of low-molecular weight allergens resolved on two-dimensional electrophoresis with acid-urea polyacrylamide gel

Two-dimensional electrophoresis with immobilized pH gradient (IPG) followed by acetic acid/urea-polyacrylamide gel electrophoresis (AU-PAGE) was developed for the detection of low-molecular weight food allergens. Wheat proteins were used to test the applicability of AU-PAGE for the analysis of food allergens. Isoelectric focusing (IEF) for first dimension was performed with IPG pH 3-10. AU-PAGE was performed as a second-dimensional electrophoresis and high resolution was obtained, especially for proteins below 15 kDa. For immunodetection, the proteins resolved on AU gel were transferred to a polyvinylidene difluoride membrane. The assembly of semidry electroblotting for AU gel was set reversed as for sodium dodecyl sulfate (SDS)-PAGE gel. The electroblotted membrane was immunolabeled with serum from a radio-allergosorbent test-positive individual for wheat to identify allergenic proteins. Protein spots strongly recognized by the patient's serum were chosen for further analysis. Mass spectrometry analysis revealed that these proteins were alpha-amylase/trypsin inhibitors and lipid transfer protein. The system developed in this study was shown to be useful as a standard protocol for the separation of low-molecular weight proteins. Moreover, the IPG strips on which IEF was performed could be used either for SDS-PAGE or AU-PAGE by only changing equilibrating conditions, allowing for a wide range of allergen analysis.