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Whole Allergen

w2 Western ragweed

w2 Western ragweed Scientific Information

Type:

Whole Allergen

Display Name:

Western ragweed

Route of Exposure:

Inhalation

Family:

Asteraceae (Compositae)

Species:

A. psilostachya

Latin Name:

Ambrosia psilostachya

Other Names:

Western ragweed, Perennial ragweed

Summary

Western ragweed (Ambrosia psilostachya) is an herbaceous perennial weed, native to North America and introduced to many countries in Europe, Asia and Africa. Ragweed flowers in late summer to autumn; its pollen is associated with allergic rhinoconjunctivitis and asthma. Western ragweed shows high levels of cross-reactivity with other ragweeds (Ambrosia species) and mugwort (Artemisia species). Ragweeds also cross-react with other members of the Asteraceae family (sunflower and feverfew), Timothy grass and potentially other grass and tree pollens. 

Allergen

Nature

Western ragweed (Ambrosia psilostachya) is an herbaceous perennial plant native to North America, particularly the Great Plains and Great Basin regions (1). It has been introduced to many countries in Europe, Asia, Africa and Australia (2). Western ragweed flowers from July to November and is mainly wind-pollinated; it also reproduces vegetatively via creeping root systems (1, 3). A large ragweed plant can produce up to 62,000 seeds, causing high concentrations of airborne pollen in August and September (4). The ragweed pollen season has become significantly longer over the last 20 years, possibly due to climate change influences on plant distribution, flowering season, pollen load and allergenicity (3). Weed pollen and grass pollen seasons overlap in most parts of Europe, as do ragweed and mugwort pollen seasons (3).

Taxonomy 

Taxonomic tree of Ambrosia psilostachya (2)

Domain

Eukaryota

Kingdom

Plantae

Phylum

Spermatophyta

Subphylum

Angiospermae

Class

Dicotyledonae

Family

Asteraceae

Genus

Ambrosia

Taxonomic tree of Ambrosia psilostachya (2)

Tissue 

Weed pollen

Epidemiology

Worldwide distribution 

Ragweed pollen is an important allergen source: Ambrosia species are major elicitors of type I pollen allergy in North America, with an estimated prevalence of approximately 26% (3, 5). A series of European studies recorded the prevalence of ragweed sensitization from 25% to over 80% in the late 1990s, with prevalence rates increasing constantly over time (4).

In a US national health survey, ragweed pollen was among the top three sensitizing allergens detected in participants aged 6 years and over; the prevalence of ragweed allergy increased rapidly from age 6 to young adulthood, then declined after age 30 (6).

Risk factors 

Elevated IgE activity has been demonstrated in response to ragweed pollen collected along busy roads, suggesting that environmental pollution may increase pollen allergenicity (3).

A study investigating the effect of environmental temperature on Ambrosia psilostachya pollen found that artificial warming increased the number of plant stems, leading to an 84% increase in total pollen production (7). Climate change modelling suggests a 27-89% increase in high allergy risk areas for Western ragweed by the year 2100, particularly in northern Europe (8).

Environmental Characteristics

Worldwide distribution 

Western ragweed (Ambrosia psilostachya) is an aggressive weed of pastures and cultivated land, where it inhibits crop germination and competes with other perennial grasses. It can also be found in orchards, on roadside verges, railway embankments, waste land and open prairies (1).

Route of Exposure

Main 

The main route of exposure is inhalation.

Clinical Relevance

Ragweed pollen causes allergic rhinoconjunctivitis and asthma. In a Romanian study of 83 ragweed-allergic patients, 75% had moderate to severe rhinoconjunctivitis and 25% showed symptoms of allergic asthma. Most of these patients were polysensitized to other allergens including mugwort, other cereal/ grass pollens and other tree pollens (9). Some sources state that Western ragweed (A. psilostachya) is not significantly allergenic compared to Short/Common ragweed (A. artemisiifolia) (5).

Asthma

Clinical experience suggests that ragweed pollen may induce asthma approximately twice as often as is found with other pollen allergies (i.e. in 40%–50% of ragweed-allergic patients) (4).

Prevention and Therapy

Allergen immunotherapy

In vitro data show substantial allergenic cross-reactivity between Amb a (Short/Common ragweed), Amb p (Western ragweed) and Amb t (Giant ragweed), suggesting that an Amb a-based, single-species allergen immunotherapy may be successful in patients allergic to diverse ragweed pollens (5).

Molecular Aspects

Allergenic molecules

Allergens of Western ragweed Ambrosia psilostachya (10, 11).

Allergen name

Protein group

Amb p 5a variant

Secreted basic protein

Amb p 5b variant

Secreted basic protein

Allergen name

Protein group

Although Amb p 5 variants are the only formally recognized allergens of A. psilostachya, one study has identified the pectate lyases Amb a 1.2, 1.3, and Amb a 2 in Western ragweed, as well as Amb a 6 and profilin-3; these proteins are normally associated with Short/Common ragweed (A. artemisiifolia) (10).

The Amb p 5a variant shares 90% sequence identity with its A. artemisiifolia homolog, Amb a 5, whereas the Amb p 5b variant shares approximately 65% sequence identity with Amb a 5 (4).

Cross-reactivity

The presence of homologous allergens leads to extensive IgE cross-reactivity between the pollen extracts Amb p from Western ragweed (A. psilostachya), Amb a from Short/Common ragweed (A. artemisiifolia) and Amb t from Giant ragweed (A. trifida) (4, 12).

A high degree of IgE cross-reactivity is seen among different species of Ambrosia (ragweed) and Artemisia (mugwort) and to other allergenic plants of the Asteraceae family. There is moderate IgE cross-reactivity between the pectate lyases of ragweed and mugwort (Amb a 1 and Art v 6) and between the defensin-like proteins of ragweed, mugwort, feverfew and sunflower (Art v 1, Amb a 4, Par h 1, and Hel a 1) (3).

A major Timothy grass pollen allergen (Phl p 4) has also demonstrated IgE cross-reactivity to the main ragweed allergen (Amb a 1), while another Timothy grass allergen (Phl p 7) is a broad cross-reacting allergen present in many different tree-, grass- and weed pollens, including ragweeds (3).

A recent Romanian study found cross-reactivity between Amb a 1 and Cry j 1, the main allergenic molecule from Japanese cedar (Cryptomeria japonica), a species not found in the local area. Although both are pectate lyase proteins, their sequence identity is only 46-49% (9).

Compiled By

Author: RubyDuke Communications

Reviewer: Dr. Christian  Fischer

 

Last reviewed:February 2022

References
  1. LOINC. Western Ragweed IgE Ab [Units/volume] in Serum 2021 [cited 2021 6.12.21]. Available from: https://loinc.org/6275-2/.
  2. CABI. Ambrosia psilostachya
  3. (perennial ragweed) Wallingford, UK2021 [cited 2021 6.12.21]. Available from: https://www.cabi.org/isc/datasheet/4692.
  4. 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.
  5. Gadermaier G, Dedic A, Obermeyer G, Frank S, Himly M, Ferreira F. Biology of weed pollen allergens. Current Allergy and Asthma Reports. 2004;4(5):391-400.
  6. Christensen LH, Ipsen H, Nolte H, Maloney J, Nelson HS, Weber R, et al. Short ragweeds is highly cross-reactive with other ragweeds. Ann Allergy Asthma Immunol. 2015;115(6):490-5.e1.
  7. Salo PM, Arbes SJ, Jr., Jaramillo R, Calatroni A, Weir CH, Sever ML, et al. Prevalence of allergic sensitization in the United States: results from the National Health and Nutrition Examination Survey (NHANES) 2005-2006. The Journal of allergy and clinical immunology. 2014;134(2):350-9.
  8. Wan S, Yuan T, Bowdish S, Wallace L, Russell SD, Luo Y. Response of an allergenic species, Ambrosia psilostachya (Asteraceae), to experimental warming and clipping: implications for public health. Am J Bot. 2002;89(11):1843-6.
  9. Rasmussen K, Thyrring J, Muscarella R, Borchsenius F. Climate-change-induced range shifts of three allergenic ragweeds (Ambrosia L.) in Europe and their potential impact on human health. PeerJ. 2017;5:e3104.
  10. Haidar L, Tamas T-P, Stolz F, Patrascu RFP, Chen K-W, Panaitescu C. Symptom patterns and comparison of diagnostic methods in ragweed pollen allergy. Experimental and therapeutic medicine. 2021;21(5):525-.
  11. Barton JS, Schomacker R. Comparative protein profiles of the Ambrosia plants. Biochim Biophys Acta Proteins Proteom. 2017;1865(6):633-9.
  12. Ghosh B, Rafnar T, Perry MP, Bassolino-Klimas D, Metzler WJ, Klapper DG, et al. Immunologic and molecular characterization of Amb p V allergens from Ambrosia psilostachya (western Ragweed) pollen. J Immunol. 1994;152(6):2882-9.
  13. Würtzen PA, Hoof I, Christensen LH, Váczy Z, Henmar H, Salamanca G, et al. Diverse and highly cross-reactive T-cell responses in ragweed allergic patients independent of geographical region. Allergy. 2020;75(1):137-47.
  14.