clear search
Search
Recent searches Clear History
Kontaktieren Sie uns
Allergen Encyclopedia
Table of Contents

Komponente

f422 Ara h 1

f422 Ara h 1 Scientific Information

Typ:

Component

Name; WHO/IUIS:

Ara h 1

Route of Exposure:

Ingestion

Biological function:

7S globulin

Allergen code:

f422

Source Material:

Peanut Extract

Other Names :

Vicilin

Summary

Ara h 1 is a vicilin seed storage protein and a member of the 7S globulin family capable of withstanding the harsh conditions of the gastrointestinal tract. Ara h 1 is a highly abundant seed storage protein and accounts for approximately 20% of the total protein content of peanut. It is estimated that 97% of peanut allergy patients are sensitized to at least one of the allergens Ara h 1, 2 and 3. Individuals who are sensitized to Ara h 1 are at an increased risk for more severe symptoms and anaphylactic reactions. Roasting peanuts at high temperatures can increase the allergenicity of Ara h 1. Polysensitization to Ara 1, 2 and 3 can help to predict the severity of reaction at challenge. The use of specific IgE to Ara h 1 in combination with Ara h 2 and 3 could be helpful to diagnose individuals with peanut allergy. Cross-reactivity with other legume and tree nuts, and the seed storage proteins Ara h 2 and 3, have been reported with Ara h 1.

Epidemiology

Worldwide distribution

Studies have typically reported peanut allergy prevalence rates between 1–2% in Western nations. Peanut allergy appears to be less common in Asia and other global areas, although epidemiological studies in non-Western regions have been sparse (1). Peanut allergy usually begins in childhood and persists throughout the affected individual’s lifetime however, approximately 20% of young children develop tolerance (2).

Ara h 1 had the second highest frequency of specific IgE binding (65%) in 40 peanut-allergic patients compared to the other peanut allergen components Ara h 2, 3, 5, 6 and 7, with Ara h 2 being the highest at 85% (3). The prevalence of Ara h 1 sensitization was estimated to be 43% from a larger study using 12,155 serum samples in the USA (4). Ara h 1 is considered to be one of the major peanut allergens (5, 6).

It is estimated that 97% of peanut allergy patients are sensitized to at least one of the allergens Ara h 1, 2 and 3 (6). A study by Flinterman et al. (2007) examining the IgE reactivity to major peanut allergens in 20 peanut-allergic children found that all of them showed IgE reactivity to Ara h 2. Ara h 6 was recognized by 16 children, and Ara h 1 and 3 by 10 children (50%) (7). Similarly, in another study involving 30 peanut-allergic individuals, 16 patients (53%) were sensitized to Ara h 1 (8).

 

Environmental Characteristics

Source and tissue

Ara h 1 is a highly abundant seed storage protein and is structurally stable (4). The allergens Ara h 1, 2 and 3 provide >30% of the total protein content of peanuts with Ara h 1 accounting for an estimated 20% (9). Ara h 1 belongs to the vicilin protein family, also known as 7S globulin which is within the cupin protein superfamily (10). 

Clinical Relevance

Typical clinical symptoms of peanut allergy range from angioedema, urticaria, nausea, abdominal pain, vomiting, wheezing, and breathlessness which usually occur soon after peanut ingestion (11). Since Ara h 1 is a storage protein, individuals who are sensitized to this component are at an increased risk for more severe symptoms and anaphylactic reactions (12). Sensitization to peanut storage proteins, Ara h 1, 2 and 3 was associated with increased quantities of airway and systemic inflammation markers compared to patients who were not sensitized to these peanut allergen components in a population of asthma sufferers (13). Food hypersensitivity symptoms were also more regularly reported by those sensitized to Ara h 1, 2 and 3 than by any other participants in the study (13).

A study found specific IgE was positively correlated with clinical severity and Ara h 1 in adult patients (r = 0.74, P < 0.001) but this trend was not observed in children (14). In addition, another study found that sensitization to Ara h 2 and Ara h 1 and/or Ara h 3 appeared to be predictive of more severe reactions (15). Similarly, the results of a recent study in Australia found that polysensitization to Ara 1, 2 and 3 can help to predict the severity of reaction at challenge (16).

Cross-reactive Molecules

A study involving three patients with a history of anaphylaxis to peas also demonstrated peanut-related symptoms, highlighting that clinically relevant cross-reactivity between pea and peanut does occur and is due to the vicilin homologues, Pis s 1 and Ara h 1 (17). The peanut-related symptoms included oral symptoms, urticaria and angioedema (17).

Cosensitization to Ara h 1, 2 and 3 is caused by the IgE cross-reactivity between them (18).

Molecular Aspects

Biochemistry

Ara h 1 is a 64 kDa vicilin (7S globulin) protein belonging to the cupin superfamily which provides nourishment for seedling growth (10, 19). With trypsin inhibitory activity, it has been suggested that Ara h 1 may have a role in plant defense against insects (20). The vicilins are usually disc-shaped trimeric proteins, however, the subunits vary depending on the extent of posttranslational proteolytic processing and glycosylation (10). Ara h 1 contains a glycosylation motif in the C-terminal region on which a heterogeneous assortment of N-glycans with the structure, Man5–6Glc NAc2 or Man3–4XylGlcNAc2 is conjugated through asparagine (21). Ara h 1 is the only peanut allergen with a xylosylated N-Glycan (21)

Roasting peanuts at high temperatures allows for the formation of globular protein aggregates which are able to increase the allergenicity of Ara h 1 (12) however, boiling peanuts decreases the IgE binding capacity of the allergen component (20). Ara h 1 bound increased levels of IgE and was more resistant to heat and gastrointestinal digestive enzymes after undergoing the Maillard reaction (22). The Maillard reaction occurs during the processing or browning of food and is important for developing the flavor and color of peanuts (22). It has been proposed that the six cysteine residues could help Ara h 1 withstand digestive denaturation (20).

Isoforms, epitopes, antibodies

There is one isoform of Ara h 1, Ara h 1.0101 (19). 

Cross-reactivity

Cross-reactivity with other legume and tree nuts, and the seed storage proteins Ara h 2 and 3, has been reported with Ara h 1 (10). The high extent of cross-reactivity between Ara h 1, 2 and 3 is due to these components having similar sequences (18).

Although Ara h 1 and the cashew vicilin, Ana o 1 share 27% identity and 45% similarity in amino acid sequence, there is a lack of sequence conservation with respect to their linear epitopes (23). However, sera from peanut-allergic patients that react with Ara h 1 often also react with the vicilins from walnut, hazelnut and cashew nut known as Jug r 2, Cor a 11 and Ana o 1, respectively (24). In addition, the walnut vicilin, Jug r 2 has IgE-binding epitopes which are structurally similar to Ara h 1 and they share a sequence identity of 54% (25).

7S globulins are found in other legumes. For example, soybean beta-conglycinin, Gly m 5, is the closest known homolog of Ara h 1, demonstrating a similar 3D structure and 51% amino acid sequence identity (26). In addition, an IgE-binding cross-reactivity was discovered with the lentil and pea vicilins, Len c 1 and Pis s 1, respectively (27). Also, the β-conglutin precursor of lupine has been found to be significantly homologous to Ara h 1, with an identity ranging from 50 to 76%, and a homology between 63 and 93% but this is not of clinical significance (28, 29).

Ses i 3, the 7S vicilin-type globulin found in sesame seeds has 36% homology to Ara h 1 however, one of the IgE-binding epitopes has 80% homology with the equivalent region of the sesame seed vicilin (30). 

Diagnostic Relevance

Disease Severity

Results from a cross-sectional study involving 222 Australian children reported that using a combination of Ara h 1, 2 and 3 for peanut component testing could be helpful to identify patients with peanut allergy (16). An earlier study found that using the combination of Ara h 1, 2, and 3 resulted in a higher specificity (94%) when diagnosing peanut allergy in Japanese children in comparison to using IgE to Ara h 2 alone resulting in a sensitivity and specificity of 88% and 84%, respectively. However, the sensitivity of using the combination of Ara h 1, 2, and 3 was 31% (31). A study found that cosensitization to rAra h 2 and rAra h 1 and/or rAra h 3 was predictive of more severe reactions in peanut allergy (15). The results of a recent meta-analysis identified that specific IgE to Ara h 1, 2 and 3 are highly specific for peanut allergy in children (32). 

Cross-Reactivity

Often, specific IgE measurements for Ara h 1 and Ara h 3 are not necessarily due to the high level of cross-reactivity between them and monosensitization to these seed storage allergen components is uncommon (12).

Compiled By

Author: RubyDuke Communications

Reviewer: Dr. Magnus Borres

 

Last reviewed: December 2020

References
  1. Lieberman JA, Gupta R, Knibb RC, Haselkorn T, Tilles S, Mack DP, et al. The Global Burden of Illness of Peanut Allergy: A Comprehensive Literature Review. Allergy. 2021;76(5):1367–84 .
  2. Sicherer SH. Clinical update on peanut allergy. Ann Allergy Asthma Immunol. 2002;88(4):350-61; quiz 61-2, 94.
  3. Kleber-Janke T, Crameri R, Appenzeller U, Schlaak M, Becker WM. Selective Cloning of Peanut Allergens, Including Profilin and 2S Albumins, by Phage Display Technology. International Archives of Allergy and Immunology. 1999;119(4):265-74.
  4. Valcour A, Jones JE, Lidholm J, Borres MP, Hamilton RG. Sensitization profiles to peanut allergens across the United States. Annals of Allergy, Asthma & Immunology. 2017;119(3):262-6.e1.
  5. Mueller GA, Maleki SJ, Pedersen LC. The molecular basis of peanut allergy. Curr Allergy Asthma Rep. 2014;14(5):429.
  6. Hemmings O, Du Toit G, Radulovic S, Lack G, Santos AF. Ara h 2 is the dominant peanut allergen despite similarities with Ara h 6. J Allergy Clin Immunol. 2020;146(3):621-30.e5.
  7. Flinterman AE, van Hoffen E, den Hartog Jager CF, Koppelman S, Pasmans SG, Hoekstra MO, et al. Children with peanut allergy recognize predominantly Ara h2 and Ara h6, which remains stable over time. Clin Exp Allergy. 2007;37(8):1221-8.
  8. Peeters KA, Koppelman SJ, van Hoffen E, van der Tas CW, den Hartog Jager CF, Penninks AH, et al. Does skin prick test reactivity to purified allergens correlate with clinical severity of peanut allergy? Clin Exp Allergy. 2007;37(1):108-15.
  9. Chassaigne H, Nørgaard JV, Hengel AJ. Proteomics-based approach to detect and identify major allergens in processed peanuts by capillary LC-Q-TOF (MS/MS). J Agric Food Chem. 2007;55(11):4461-73.
  10. Bublin M, Breiteneder H. Cross-Reactivity of Peanut Allergens. Current Allergy and Asthma Reports. 2014;14(4):426.
  11. Anagnostou K, Clark A. The management of peanut allergy. Arch Dis Child. 2015;100(1):68-72.
  12. Matricardi PM, Kleine-Tebbe J, Hoffmann HJ, Valenta R, Hilger C, Hofmaier S, et al. EAACI Molecular Allergology User's Guide. Pediatr Allergy Immunol. 2016;27 Suppl 23:1-250.
  13. Johnson J, Malinovschi A, Lidholm J, Petersson CJ, Nordvall L, Janson C, et al. Sensitization to storage proteins in peanut and hazelnut is associated with higher levels of inflammatory markers in asthma. Clin Mol Allergy. 2020;18:11.
  14. Klemans RJ, Liu X, Knulst AC, Knol MJ, Gmelig-Meyling F, Borst E, et al. IgE binding to peanut components by four different techniques: Ara h 2 is the most relevant in peanut allergic children and adults. Clin Exp Allergy. 2013;43(8):967-74.
  15. Astier C, Morisset M, Roitel O, Codreanu F, Jacquenet S, Franck P, et al. Predictive value of skin prick tests using recombinant allergens for diagnosis of peanut allergy. J Allergy Clin Immunol. 2006;118(1):250-6.
  16. Kaur N, Mehr S, Katelaris C, Wainstein B, Altavilla B, Saad R, et al. Added Diagnostic Value of Peanut Component Testing: A Cross-Sectional Study in Australian Children. J Allergy Clin Immunol Pract. 2021;9(1):245–253.
  17. Wensing M, Knulst AC, Piersma S, O'Kane F, Knol EF, Koppelman SJ. Patients with anaphylaxis to pea can have peanut allergy caused by cross-reactive IgE to vicilin (Ara h 1). Journal of Allergy and Clinical Immunology. 2003;111(2):420-4.
  18. Bublin M, Kostadinova M, Radauer C, Hafner C, Szépfalusi Z, Varga EM, et al. IgE cross-reactivity between the major peanut allergen Ara h 2 and the nonhomologous allergens Ara h 1 and Ara h 3. J Allergy Clin Immunol. 2013;132(1):118-24.
  19. IUIS. WHO/IUIS Allergen Database 2020 [cited 2020 November]. Available from: http://www.allergen.org/.
  20. Palladino C, Breiteneder H. Peanut allergens. Molecular Immunology. 2018;100:58-70.
  21. Becker WM, Petersen A, Jappe U. Peanut allergens: new consolidated findings on structure, characteristics, and allergome. Allergol Select. 2018;2(1):67-79.
  22. Maleki SJ, Chung SY, Champagne ET, Raufman JP. The effects of roasting on the allergenic properties of peanut proteins. J Allergy Clin Immunol. 2000;106(4):763-8.
  23. Wang F, Robotham JM, Teuber SS, Tawde P, Sathe SK, Roux KH. Ana o 1, a cashew (Anacardium occidental) allergen of the vicilin seed storage protein family. J Allergy Clin Immunol. 2002;110(1):160-6.
  24. Barre A, Sordet C, Culerrier R, Rancé F, Didier A, Rougé P. Vicilin allergens of peanut and tree nuts (walnut, hazelnut and cashew nut) share structurally related IgE-binding epitopes. Mol Immunol. 2008;45(5):1231-40.
  25. Costa J, Carrapatoso I, Oliveira MB, Mafra I. Walnut allergens: molecular characterization, detection and clinical relevance. Clin Exp Allergy. 2014;44(3):319-41.
  26. Masilamani M, Commins S, Shreffler W. Determinants of food allergy. Immunol Allergy Clin North Am. 2012;32(1):11-33.
  27. Barre A, Borges JP, Rougé P. Molecular modelling of the major peanut allergen Ara h 1 and other homotrimeric allergens of the cupin superfamily: a structural basis for their IgE-binding cross-reactivity. Biochimie. 2005;87(6):499-506.
  28. Guarneri F, Guarneri C, Benvenga S. Identification of potentially cross-reactive peanut-lupine proteins by computer-assisted search for amino acid sequence homology. Int Arch Allergy Immunol. 2005;138(4):273-7.
  29. Villa C, Costa J, Mafra I. Lupine allergens: Clinical relevance, molecular characterization, cross-reactivity, and detection strategies. Comprehensive Reviews in Food Science and Food Safety. 2020;19(6):3886-915.
  30. Beyer K, Bardina L, Grishina G, Sampson HA. Identification of sesame seed allergens by 2-dimensional proteomics and Edman sequencing: seed storage proteins as common food allergens. J Allergy Clin Immunol. 2002;110(1):154-9.
  31. Ebisawa M, Movérare R, Sato S, Maruyama N, Borres MP, Komata T. Measurement of Ara h 1-, 2-, and 3-specific IgE antibodies is useful in diagnosis of peanut allergy in Japanese children. Pediatr Allergy Immunol. 2012;23(6):573-81.
  32. Nilsson C, Berthold M, Mascialino B, Orme ME, Sjölander S, Hamilton RG. Accuracy of component-resolved diagnostics in peanut allergy: Systematic literature review and meta-analysis. Pediatr Allergy Immunol. 2020;31(3):303-14.