Quality of timothy pollen (Phleum pratense) from different pollen seasons and different suppliers

We investigated seven batches of timothy (Phleum pratense) pollen from four different pollen seasons and three different manufacturers in the USA and Europe by several biochemical and immunochemical methods. By measuring the contents of hexoses, proteins and the total allergenic activity using RAST inhibition we could not find any significant differences in quality between pollen of different seasons, different geographical origin and different manufacturers. There were only slight differences in the staining of some protein bands and in peak height of some antigens in isoelectric focusing (IEF), SDS-PAGE and crossed immunoelectrophoresis. These differences in IEF and SDS-PAGE patterns seem to be specific for the pollen samples from the USA and Europe, respectively. We also observed minor differences in IEF immunoprint patterns, mainly for some basic proteins. The allergen patterns in crossed radioimmunoelectrophoresis were very similar, with only minor differences in concentration of the basic allergens. It appears that timothy pollen from different years can be produced in different geographical areas by different manufacturers with fairly constant allergenic activity.     

Complementary DNA cloning and expression of a newly recognized high molecular mass allergen Phl p 13 from timothy grass pollen (Phleum pratense)

BACKGROUND: Grass pollen extracts contain a range of different allergenic components that can be classified as having low, middle or high molecular mass. Almost 75% of patients allergic to grass pollen display immunoglobulin (Ig) E-reactivity to allergens in the high molecular mass range of 55-60 kDa. These proteins have not yet been fully characterized on the protein and DNA level. OBJECTIVE: The aim of this study was to identify and characterize an allergen of the high molecular mass fraction of Phleum pratense pollen by N-terminal protein sequencing and molecular cloning. METHODS: A previously uncharacterized allergen which migrates as a double band with a molecular mass of 55-60 kDa was biochemically purified and investigated by N-terminal sequencing. Subsequently, a DNA primer was designed to amplify the corresponding cDNA using PCR. The cloned cDNA and deduced amino acid sequence were compared with sequence data bases. Immunoblots carrying the recombinant expression product were developed with monoclonal antibodies and sera derived from allergic subjects. The IgE-binding capacity of natural and recombinant allergen was determined using EAST. RESULTS: The nucleic acid sequence as well as the deduced amino acid sequence consisting of 394 amino acids indicated homology with pollen specific polygalacturonases. Four potential sites for glycosylation and 16 cysteine residues were found. The recombinant expression product exhibited the same molecular size as the natural allergen and was clearly IgE-reactive. CONCLUSION: The newly characterized allergen Phl p 13, which shows homology with polygalacturonases, is clearly different from the allergen designated as Phl p 4 and therefore the high molecular mass fraction is composed of at least two different allergens. A possible reason why this important allergen has not been detected until now is that Phl p 13 and Phl p 4 are hardly separable by one dimensional SDS-PAGE.     

Comparison of antigenic and allergenic components of Holoptelea integrifolia pollen collected from different source materials

Antigenic extracts prepared from pollen samples collected at weekly intervals during the same season did not exhibit significant variation in protein concentration. Stored pollen samples from different years, however, showed highly significant variations in protein concentration. The protein content of samples from different ecozones of India also varied (CV = +/- 32%). The IEF and SDS-PAGE patterns were almost identical in samples from the same season, but were variable in the samples stored from different years and different parts of India. IgE binding proteins from different samples also varied depending on the overall protein profiles. Almost all the patients, however, showed IgE binding to four proteins at 50, 60, 66 and 70 kD, indicating the important allergenic components of Holoptelea integrifolia.     

Phleum pratense pollen starch granules induce humoral and cell-mediated immune responses in a rat model of allergy

BACKGROUND: Timothy grass (Phleum pratense) pollen allergens are an important cause of allergic symptoms. However, pollen grains are too large to penetrate the deeper airways. Grass pollen is known to release allergen-bearing starch granules (SG) upon contact with water. These granules can create an inhalable allergenic aerosol capable of triggering an early asthmatic response and are implicated in thunderstorm-associated asthma. OBJECTIVE: We studied the humoral (IgE) and bronchial lymph node cells reactivities to SG from timothy grass pollen in pollen-sensitized rats. METHODS: Brown-Norway rats were sensitized (day 0) and challenged (day 21) intratracheally with intact pollen and kept immunized by pollen intranasal instillation by 4 weeks intervals during 3 months. Blood and bronchial lymph nodes were collected 7 days after the last intranasal challenge. SG were purified from fresh timothy grass pollen using 5 microm mesh filters. To determine the humoral response (IgE) to SG, we developed an original ELISA inhibition test, based on competition between pollen allergens and purified SG. The cell-mediated response to SG in the bronchial lymph node cells was determined by measuring the uptake of [3H]thymidine in a proliferation assay. RESULTS: An antibody response to SG was induced, and purified SG were able to inhibit the IgE ELISA absorbance by 45%. Pollen extract and intact pollen gave inhibitions of 55% and 52%, respectively. A cell-mediated response was also found, as pollen extract, intact pollen and SG triggered proliferation of bronchial lymph node cells. CONCLUSIONS: It was confirmed that timothy grass pollen contains allergen-loaded SG, which are released upon contact with water. These granules were shown to be recognized by pollen-sensitized rats sera and to trigger lymph node cell proliferation in these rats. These data provide new arguments supporting the implication of grass pollen SG in allergic asthma.     

The international collaborative study establishing the first international standard for timothy (Phleum pratense) grass pollen allergenic extract

A selected candidate international reference preparation of timothy grass (Phleum pratense)-pollen extract was studied together with two other freeze-dried timothy pollen allergenic extracts in a multinational study. The collaborators used RAST inhibition, histamine release, quantitative immunoelectrophoresis (crossed immunoelectrophoresis/crossed radioimmunoelectrophoresis and rockets), isoelectric focusing, and other methods. The total allergenic potencies measured in RAST inhibition were evaluated for validity of linearity and parallel-line response. The relative concentrations of some important individual allergenic components were measured. The relative potencies for the total allergenic activity and the timothy components studied in each preparation were expressed relative to the selected candidate. This preparation was established in 1983 by the World Health Organization expert committee on biologic standardization as the international standard for timothy grass-pollen extracts with assigned units of 100,000 IU per ampule.     

Design of an optimally-diagnostic skin test solution for diagnosis of sensitivity to timothy grass (Phleum pratense) pollen

Background Although most of the common allergen extracts that are used for diagnosis of type 1 hypersensitivity are now well standardized, this gives no assurance that they are within the concentration range that gives the best chance of a true diagnosis. Objective The objective of this study was to identify the most appropriate concentration range of timothy grass pollen Phleum pratense extract to diagnose sensitivity to this pollen correctly through skin-testing. Methods Dilutions of a well-standardized extract were made and used to skin test ‘true’ positive and ‘true’ negative populations of subjects as identified by case history, challenge tests and radioallergosorbent test (RAST). Weal diameters were measured and the data were submitted to receiver operating characteristics (ROC) analysis. For any particular weal size cut–off, the optimal diagnostic concentration (ODC) range was thus calculated. Results A 3 mm weal diameter cut-off was chosen as an appropriate size for routine diagnosis. Therefore the ODC range at this diameter was used to establish a product target concentration and specification for formulation of the diagnostic reagent. This method of allergen extract standardization can lead to a true-biological unitage that can be used for labelling purposes. Conclusion The optimun concentration range at which to formulate an allergen extract, in terms of an in vitro immunologically based assay, can be determined by carrying out ROC analysis of the results of clinical studies as described in this communication. Diagnostic units (DU), are now used by us for labelling of such final formulations which conveys the information that the product is at the most appropriate concentration for diagnosis.     

Molecular and immunological characterization of a novel timothy grass (Phleum pratense) pollen allergen, Phl p 11

BACKGROUND: Allergy to grass pollen is typically associated with serum IgE antibodies to group 1 and/or group 5 allergens, and additionally often to one or several less prominent allergens. Most of the grass pollen allergens identified to date have been characterized in detail by molecular, biochemical and immunological methods, timothy grass being one of the most thoroughly studied species. However, a 20-kDa allergen frequently recognized by IgE antibodies from grass pollen allergics has so far escaped cloning and molecular characterization. OBJECTIVE: To clone and characterize the 20 kDa timothy grass pollen allergen Phl p 11. METHODS: Phl p 11 cDNA was cloned by PCR techniques, utilizing N-terminal amino acid sequence obtained from the natural allergen. Phl p 11 was expressed as a soluble fusion protein in Escherichia coli, purified to homogeneity and used for serological analysis and to study Phl p 11 specific induction of histamine release from basophils and skin reactivity in sensitized and control subjects. RESULTS: Phl p 11 cDNA defined an acidic polypeptide of 15.8 kDa with homology to pollen proteins from a variety of plant species and to soybean trypsin inhibitor. The sequence contained one potential site for N-linked glycosylation. Serological analysis revealed that recombinant Phl p 11 shared epitopes for human IgE antibodies with the natural protein and bound serum IgE from 32% of grass pollen-sensitized subjects (n = 184). Purified recombinant Phl p 11 elicited skin reactions and dose-dependent histamine release from basophils of sensitized subjects, but not in non-allergic controls. CONCLUSION: As the first representative of group 11 grass pollen allergens, Phl p 11 has been cloned and produced as a recombinant protein showing allergenic activity. One-third of grass pollen-sensitized subjects showed specific IgE reactivity to recombinant Phl p 11, corresponding in magnitude to a significant proportion of specific IgE to grass pollen extract.     

Diagnosis of grass pollen allergy with recombinant timothy grass (Phleum pratense) pollen allergens.

In order to establish a test system for grass pollen allergy based on the use of recombinant allergens we chose timothy grass (Phleum pratense), a widely spread grass, as a model. From a lambda gt11 cDNA expression library that we had constructed from pollen RNA of timothy grass (P. pratense), we had obtained with serum IgE from a grass pollen-allergic individual 60 IgE-binding clones. By differential testing with sera from different grass pollen-allergic patients, we selected three distinct clones encoding Phl p I (group I), Phl p V (group V) and profilin from timothy grass, which when used together allowed the diagnosis of grass pollen allergy in 97 out of 98 tested grass pollen-allergic patients employing a simple plaque lift technique. This recombinant test based on plaque lifts containing allergen-beta-galactosidase fusion proteins was compared with IgE immunoblots using crude pollen protein extracts from timothy grass. Both methods were in good agreement with RAST scores and clinical data, and proofed to be useful for the diagnosis of grass pollen allergy. Our results further indicate that a limited panel of only two recombinant grass pollen allergens, Phl p I and Phl p V, together with the plant panallergen profilin could be sufficient for the diagnosis and possibly immunotherapy of grass pollen allergy.     

Nature of the allergenic activity of pollen from certain species of plants

Fractions with allergenic activity, with molecular weight of 37,000, 19,000, 35,000, and 14,000, respectively, were isolated by chromatography from ragweed, wormwood, goosefoot, and sunflower pollen on Sephadex. All the allergens had similar properties. Affinity for Sephadex resins was stronger for Sephadex G-75 than for G-100, the adsorbed components were inactive, and allergenic and antigenic activity was found only in fractions eluted in the bed volume of the column. The affinity of the allergens for Sephadex was independent of the type of eluate but was reduced if the ionic strength of the buffer was increased.Department of Pharmacology, Red Army Kuban Medical Institute, Krasnodar. (Presented by Academician of the Academy of Medical Sciences of the USSR A. D. Ado.) Translated from Byulleten' Éksperimental'noi Biologii i Meditsiny, Vol. 88, No. 9, pp. 332–333, September, 1979.     

The high molecular mass allergen fraction of timothy grass pollen (Phleum pratense) between 50–60 kDa is comprised of two major allergens: Phl p 4 and Phl p 13

BACKGROUND: More than 70% of the patients allergic to grass pollen exhibit IgE-reactivity against the high molecular mass fraction between 50 and 60 kDa of timothy grass pollen extracts. One allergen from this fraction is Phl p 4 that has been described as a basic glycoprotein. A new 55/60 kDa allergen, Phl p 13, has recently been purified and characterized at the cDNA level. OBJECTIVE: The relative importance of the two high molecular mass allergens has been characterized with respect to their IgE-binding frequency and capacity. METHODS: Both high molecular mass allergens were biochemically purified and subjected to nitrocellulose strips. About 306 sera obtained from subjects allergic to grass pollens were used to determine specific IgE-binding frequency to Phl p 4 and Phl p 13. IgE-binding of allergens was quantified by ELISA measurements. Pre-adsorption of sera with purified allergens and subsequent incubation of nitrocellulose-blotted timothy grass pollen extract was performed to determine whether or not Phl p 4 and Phl p 13 represent the whole high molecular mass allergen fraction. Proteolytic stability of both allergens was investigated by addition of protease Glu-C. RESULTS: More than 50% of 300 patients displayed IgE-binding with both allergens. Clear differences concerning the immunological properties of Phl p 4 and Phl p 13 were confirmed by individual IgE reactivities. Quantification of specific IgE for both allergens revealed comparable values. For complete inhibiton of IgE-binding in the high molecular mass range preincubation of sera with both allergens was necessary. Interestingly, inhibition of strong reacting sera with Phl p 13 eliminated not only reactivity of the 55/60 kDa double band, but in addition a 'background smear'. Whilst undenatured Phl p 4 was resistent to proteolytic digestion with Glu-C, native Phl p 13 was degraded rapidly. CONCLUSION: Phl p 4 and Phl p 13 are immunologically different and must both be considered as major allergens. They are judged to be important candidates for potential recombinant therapeutics that may provide a basis for improved immunotherapy.     

Characterization of grass group I allergens in timothy grass pollen

Using Phl p V-depleted timothy grass pollen extract (Phleum pratense) as immunogen, we obyained a monoclonal antibody, QG 4, which recognized proteins of 33, 35, and 37 kd as determined by Western blotting. The antibody cross-reacted with pollen proteins of other grass species in the molecular weight range of 30 to 37 kd. By means of two-dimensional polyacrylamide gel electrophoresis blot of timothy grass pollen extract, we demonstrated at least seven protein spots: two of 37 kd with isoelectric points of 6.4 and 6.6; four of 35 kd with isoelectric points of 6.5, 6.8, 7.1, and 7.3; and one of 33 kd with an isoelectric point of 8.5. These protein spots were also detected by patients' pooled serum. Microsequencing of the 20 N-terminal amino acid residues revealed structures with sequence identities up to 90% to the well-established allergen, Lol p 1 of ryegrass (Lolium perenne). Therefore we assume that the monoclonal antibody QG 4 recognized the corresponding allergen Phl p I in timothy grass pollen.     

Immunochemical estimations of allergenic activities from outdoor aero-allergens, collected by a high-volume air sampler

To quantify airborne allergens in amorphus and morphological particles, a survey with collection of aero-allergens on glass fibre filters by means of a high-volume air-sampler (HIVOL) was conducted. In preliminary laboratory experiments we compared various filter elution techniques, and the pulverizing elution technique was found to be optimal with regard to yield and convenience. When a surfactant, Tween 20 (0.5% v/v), was added to the elution buffer, a recovery of 80% could be obtained. Allergens in eluates were analysed by means of an IgG-subclass RAST inhibition assay. This immunochemical method for quantification of airborne allergens was validated, as a high recovery of timothy grass pollen allergens was eluted from air filters, and eluates were shown specific by RAST inhibition. The amount of immunochemically measured airborne timothy and birch allergens collected by means of the HIVOL sampler was highly correlated with pollen counts obtained with a Burkard sampler (pollen trap) situated in the same place.     

Skin test with a timothy grass (Phleum pratense) pollen extract vs. IgE to a timothy extract vs. IgE to rPhl p 1, rPhl p 2, nPhl p 4, rPhl p 5, rPhl p 6, rPhl p 7, rPhl p 11, and rPhl p 12: epidemiological and diagnostic data

BACKGROUND: The diagnostic approach to grass pollen allergy is now possible by detecting specific IgE to its allergenic components. OBJECTIVE: To compare the IgE reactivity to a timothy grass pollen extract with the IgE reactivity to eight allergenic components from the same source (Phl p 1, 2, 4, 5, 6, 7, 11, 12). Both were compared with the skin test reactivity to a timothy grass extract. METHODS: A population survey was carried out by means of the skin test to identify grass-allergic subjects, and to characterize them in terms of demographic and allergological parameters. Seven hundred and forty-nine sera were available for IgE detection to a timothy extract, to the recombinant Phl p 1, 2, 5, 6, 7, 11, 12, and to native Phl p 4 and bromelain. Results were stratified by means of demographic and allergy parameters. RESULTS: Ninety-five per cent of the sera had detectable IgE to the timothy extract. Prevalence of IgE reactivity increased from 86.8% to 93.3% as the number of combined reactive molecules rose from 2 to 8. Adjusted prevalences for each allergen were: rPhl p 1 = 83%, rPhl p 2 = 55%, nPhl p 4 = 70%, rPhl p 5 = 50%, rPhl p 6 = 44%, rPhl p 7 = 7%, rPhl p11 = 43%, rPhl p 12 = 15%. Isolated reactivity to rPhl p 1 was 6%, whereas it was negligible for the remaining molecules. IgE reactivity prevalence and mean values differed when patients were stratified on the basis of their associated pollen reactivity and their skin test reactivity grade. No differences were found when age, symptom type and duration were considered. Up to eight-fold higher IgE concentrations were found when the sum of IgE to molecules was compared with IgE to the extract. Testing for the IgE reactivity to the glycan of the native Phl p 4 allergen showed a possible interference with prevalence and value estimation. Higher prevalence values were found in previously immunotherapy-treated patients. CONCLUSIONS: The use of a complete panel of grass allergenic molecules can mimic the current use of allergenic extracts, but new relevant information, such as individual pattern of reactivity, adjusted prevalence, correct specific IgE concentration, can be achieved only by means of discrete allergenic molecules.     

Characterization of immunoglobulin E responses in Balb/c mice against the major allergens of timothy grass (Phleum pratense) pollen

BACKGROUND: Grass pollen, such as that from timothy grass (Phleum pratense), represents a major cause of type I allergy. OBJECTIVE: To characterize the IgE immune response and to identify the major allergens eliciting an IgE response in a mouse model using pollen extract of P. pratense for sensitization, in order to assess analogies to human hyperreactivity and to gain information on the allergenic potential as determined by the IgE-reactivity kinetics of defined allergens. METHODS: Balb/c mice were sensitized with pollen extract or with purified natural allergens. Serum IgE levels, the induction of specific IgE antibodies and immediate hypersensitivity were monitored by ELISA, Western blot and a skin test, respectively. RESULTS: The sensitized mice mounted a strong IgE response and showed IgE-reactivity first against Phl p 5a and 5b, then Phl p 4 and 13 and lastly against Phl p 6. No IgE response was mounted against Phl p 1. However, all purified fractions examined (Phl p 5a, 5b, 6 and 1) induced specific IgE and showed similar kinetics of IgE induction as pollen extract (first Phl p 5a and 5b, then Phl p 6). Skin test experiments demonstrated positive reactivity only in sensitized mice. CONCLUSION: The IgE reactivity induced by the major allergens in Balb/c mice was very similar to that found in allergic patients, with the exception of Phl p 1. The kinetics of the specific IgE response was comparable using either pollen extract or the purified major allergens, indicating that the intrinsic properties of the allergens are of importance rather than their proportionate amounts in pollen extract. This model should prove to be suitable for investigations regarding the mechanisms of induction and manifestation of timothy grass pollen allergy and for the evaluation of therapeutic strategies.     

Clustering of allergenic pollen on the basis of skin responses of atopic patients by matrix analysis

The responses of 148 atopic patients to some 43 different extracts of allergenic pollen were tested by prick tests. The measure of dissimilarity was introduced and calculated for all pairs of allergens. The investigated allergens were clustered into groups, according to their unbiased greatest similarity, by a matrix-structuring method. Results indicate that subgroups of allergens can be distinguished even within groups of closely related pollen allergens that were believed to be fully cross-reactive. A few cases are demonstrated for various varieties of olives, pecans, date palms, and turf grasses and for some wild chenopods and amaranths. The usefulness of the suggested solution for allergy research and for clinical practice is discussed.     

Allergens from rye pollen (Secale cereale)

We have studied the proteins and allergens released by rye pollen in the course of a 19-h pollen incubation process. Nearly 40% of the total extracted proteins were collected during the first 5 min, and most of them had a molecular weight less than 28 kDa. Between 5 and 30 min, 15% of the proteins from total extract were released, showing in the SDS-PAGE analysis an increase in which components moved close to 30 kDa standard. From 30 min to 19 h several extracts were collected. Electrophoretical profile of components from these extracts reveals that bands moving below 28 kDa were practically absent and those of 28 and 23 kDa became very intense. At the end of the process there was a rise of 67 kDa proteins. Dot-immunobinding and immunoblotting techniques reveal that allergens leave the rye pollen, for the most part, after 5 min incubation and are proteins with 28 kDa, 33 kDa, 48 kDa and 67 kDa molecular weights.     

Allergens from rye pollen (Secale cereale)

Rye pollen was incubated for 30 min and proteins extracted at this time were collected as extract A (EA). The same pollen grains were resuspended in buffer and incubated for 18.5 h. Proteins extracted in this period were designated extract B (EB). Both extracts were subfractionated by DEAE ion-exchange chromatography and allergen presence in peaks detected by the dot-immunobinding technique. The results reveal that unretained proteins (peaks 1 and 2) and proteins eluted at 0.2 M NaCl from extract B contain the highest proportion of allergens. SDS-PAGE of chromatographic peaks showed that peak 2 from extract B contains a highly purified 28 kDa band. On the skin of allergic patients this band gave a stronger positive prick test than for the crude extract.     

Head-high, airborne pollen grains from different areas of metropolitan Delhi

A survey of airborne pollen grains from four zones of metropolitan Delhi was conducted for 1 year (February 1988-January 1989) at human height level (5'-6'). Sampling was carried out in different inhabited areas in the four zones using Burkard Volumetric Personal Samplers. Sampling was carried out at weekly intervals, three times a day (7, 14, & 20 h) for 15 min. Poaceae, Ricinus, Cheno-Amaranth, Morus, Artemisia, Myrtaceae, Parthenium, Prosopis and Cannabis are important pollen contributors to the atmosphere, especially at lower heights. In general, pollen concentration was low at human height. Quantitative zonal variations have been recorded within an urban city.