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Allergen Encyclopedia
Table of Contents

Whole Allergen

t213 Pine

t213 Pine Scientific Information

Type:

Whole Allergen

Display Name:

Pine

Route of Exposure:

Inhalation

Family:

Pinaceae

Species:

Pinus sylvestris, Pinus radiata, Pinus nigra

Latin Name:

Pinus sylvestris, Pinus radiata, Pinus nigra

Other Names:

Scotch pine, Scots pine, European red pine, Baltic pine (P. sylvestris) Monterey pine (P. radiata) Black pine (P. nigra) Stone pine, Italian stone pine, Umbrella pine, Parasol pine (P. pinea)

Summary

Pine trees (Pinus spp.) are distributed widely in the Northern hemisphere, both naturally and as part of commercial forestry. Although pine pollen was thought to have low allergenic potential, it is now an inhaled allergen of growing concern. Pine pollen causes allergic rhinitis, conjunctivitis and asthma in adults and children. Lung function deficits and reduced performance of the bronchial epithelial barrier are reported in clinical literature. There is a high level of cross-reactivity between Pinus species. Cross-reactivity to Cypress, Olive and Perennial Ryegrass allergens has been found in some studies. 

Allergen

Nature

The pine family (Pinaceae) comprises approximately 120 species of coniferous trees, found throughout the Northern hemisphere and increasingly worldwide. Pine trees are wind-pollinated and flower in spring. In Zhanjiang, China, pollen concentrations increase rapidly from the end of February, reaching a peak in March; Pinus was one of two dominant species of pollen found during the peak pollen concentration in early spring (1). In South Korea, the highest pine pollen concentrations occurred in May and September (2). In Spain, Pinus showed a single pollination period during late March in the Eurosiberian region and two pollination periods (late March and late May/ early June) in the Mediterranean region (3). Peak Pinus pollen counts in Zhanjiang, China were associated with increased number of sunshine hours, average air temperature and relative humidity (1). In the Southern hemisphere, peak pollen counts are seen from July to October (4). Pinus species produce up to 1 million pollen grains per ovule; these are large (60-80 µm) compared to grass and other pollens (5, 6).

Taxonomy 

Taxonomic tree of Pinus species (7)

Domain

Eukaryota

Kingdom

Plantae

Phylum

Spermatophyta

Subphylum

Gymnospermae

Class

Pinopsida

Family

Pinaceae

Genus

Pinus

Epidemiology

Worldwide distribution 

Pine pollen was long considered to be non-allergenic (8). However, sensitization to conifer tree pollen (Cupressaceae and Pinaceae) is thought to have increased dramatically in recent years; in a Spanish study of conifer pollen allergy, 11 of 499 allergic patients (2.2%) showed a positive skin prick test to Pinus pinea (9). Among 48 patients with suspected pollen allergy, 12% were sensitized to Pinus radiata; this may be primary sensitization to or allergic sensitization to other pines or cross-reactive species. (6).

Pediatric issues 

Aeroallergen sensitization to P. radiata was found in 7.5% of 371 skin-prick tests in pediatric patients studied over 5 years in Cova da Beira, Portugal (10).

The prevalence of ambient Pinus pollen on the day before and 3 days before assessment was associated with reduced lung function (when measured by forced expiratory volume in the first second [FEV1] and forced vital capacity [FVC]) in a cohort of 8-year-old Australian children (4).

Environmental Characteristics

Worldwide distribution 

The Scotch pine (P. sylvestris) is the most widely distributed conifer, used extensively in commercial forestry to produce softwood timber (6). The Monterey pine (P. radiata) originated in California and is classified as an invasive species, naturalizing in several countries including Australia, New Zealand, Argentina, Chile, Zimbabwe and South Africa (7). P. radiata is increasingly planted in the Mediterranean for rapid afforestation and as a timber source (6). The Black pine (P.nigra) has a wide but scattered distribution in mountainous areas across Europe and Asia (7).

Route of Exposure

Main

The main route of exposure is inhalation. The relatively large size of Pinus pollen may limit its exposure to the larger airways (trachea and bronchi); however, pollen grains can rupture into fragments small enough to penetrate the lower airways (4).

Detection

Pine pollen is sampled using a vacuum air sampler such as the Burkard spore trap (2) or a large flow pollen collector (1) and extracted using hydrofluoric acid (1) or ammonium bicarbonate (9).

Clinical Relevance

Pine pollen is associated with allergic rhinitis, conjunctivitis and increasingly with asthma (9). It was previously considered of low allergological relevance (5) (6). Regional sensitization has been recorded in excess of 8%, so its clinical relevance is likely to be underestimated (6). Pine pollen is considered a plant allergen of emerging importance (9). Bacteria, endotoxins and molds found on Pinus pollen may contribute to respiratory symptoms in sensitized individuals (5).

Pinus pollen exposure is associated with decreased lung function test measurements (forced expiratory volume and forced vital capacity) (4). Components of P. sylvestris pollen reduce bronchial epithelial barrier functionality, via increased trans-epithelial electrical resistance and polarized release of inflammatory mediators by epithelial cells (11). 

Prevention and Therapy

Allergen immunotherapy

Due to the high number of allergic patients mono-sensitized to pine pollen, specific immunotherapy may be useful (8).

Avoidance

Avoidance may be impossible during the pollen season, due to the high prevalence of Pinus species throughout the Northern hemisphere and their global spread. Studies of pollen prevalence in Slovakia and South Korea found Pinus spp. to be the predominant tree pollen (2, 12).

Molecular Aspects

Allergenic molecules

Allergens of the Pinales order (13)

Allergen name

Protein group (if known)

Jun v 3

Thaumatin-like protein

Jun a 3

Thaumatin-like protein

Cup s 3

Thaumatin-like protein

Jun v 1

Pectate lyase

Jun a 1

Pectate lyase

Cup s 1

Pectate lyase

Cup a 1

Pectate lyase

Cha o 1

Pectate lyase

Cry j 1

Pectate lyase

Jun a 2

Polygalacturonase

Cha o 3

Polygalacturonase

Cry j 2

Polygalacturonase

Jun o 4

Calmodulin

A Spanish study found two main Pinus allergens: a 42 kDa band in 85% of 65 patients and a 6-8 kDa band in 40% of the same group (8)

Cross-reactivity

Most patients are mono-sensitized to pine pollen, with a high level of cross-reactivity between Pinus species (6, 8).

Cross-reactivity between pine and cypress (Cupressaceae) pollen is reported as present (6, 14) and absent (9). Cross-reaction between Monterey pine (P. radiata) and olive tree pollens (Olea europaea) has been identified in Germany (6). Correlation between sensitivity scores for pine pollen and grass pollen has been reported (14), although a previous study found this only in patients also sensitized to perennial ryegrass (8).

Compiled By

Author: RubyDuke Communications

Reviewer: Dr. Christian  Fischer

 

Last reviewed:January 2022

References
  1. Bishan C, Bing L, Chixin C, Junxia S, Shulin Z, Cailang L, et al. Relationship between airborne pollen assemblages and major meteorological parameters in Zhanjiang, South China. PLOS ONE. 2020;15(10):e0240160.
  2. So HJ, Moon SJ, Hwang SY, Kim JH, Jang HJ, Jo JH, et al. Characteristics of airborne pollen in Incheon and Seoul (2015-2016). Asia Pac Allergy. 2017;7(3):138-47.
  3. Fernández-González M, Lara B, González-Fernández E, Rojo J, Pérez-Badia R, Rodríguez-Rajo FJ. Pinus Pollen Emission Patterns in Different Bioclimatic Areas of the Iberian Peninsula. Forests. 2021;12(6).
  4. Lambert KA, Katelaris C, Burton P, Cowie C, Lodge C, Garden FL, et al. Tree pollen exposure is associated with reduced lung function in children. Clin Exp Allergy. 2020;50(10):1176-83.
  5. Shevtsova T, Kacaniova M, Petrová J, Brindza J, Garkava K. Microbiota of pinus pollen as adjuvant factor of allergy. Journal of Microbiology, Biotechnology and Food Sciences. 2016;05:627-32.
  6. Röseler STM, Baron JM, Höflich C, Merk HF, Bas M, Bier H, et al. "New" inhalant plant allergens. Allergol Select. 2020;4:1-10.
  7. CABI. Pinus (pines) Wallingford, UK: CABI Internatioonal; 2021 [cited 2021 02.11.21]. Available from: https://www.cabi.org/isc/datasheet/41522.
  8. Gastaminza G, Lombardero M, Bernaola G, Antepara I, Muñoz D, Gamboa PM, et al. Allergenicity and cross-reactivity of pine pollen. Clin Exp Allergy. 2009;39(9):1438-46.
  9. Domínguez-Ortega J, López-Matas M, Alonso MD, Feliú A, Ruiz-Hornillos J, González E, et al. Prevalence of allergic sensitization to conifer pollen in a high cypress exposure area. Allergy Rhinol (Providence). 2016;7(4):200-6.
  10. Loureiro G, Rabaça MA, Blanco B, Andrade S, Chieira C, Pereira C. Aeroallergens sensitization in an allergic paediatric population of Cova da Beira, Portugal. Allergol Immunopathol (Madr). 2005;33(4):192-8.
  11. Blume C, Swindle EJ, Gilles S, Traidl-Hoffmann C, Davies DE. Low molecular weight components of pollen alter bronchial epithelial barrier functions. Tissue Barriers. 2015;3(3):e1062316.
  12. Ščevková J, Dušička J, Hrubiško M, Mičieta K. Influence of airborne pollen counts and length of pollen season of selected allergenic plants on the concentration of sIgE antibodies on the population of Bratislava, Slovakia. Ann Agric Environ Med. 2015;22(3):451-5.
  13. Asam C, Hofer H, Wolf M, Aglas L, Wallner M. Tree pollen allergens-an update from a molecular perspective. Allergy. 2015;70(10):1201-11.
  14. Katotomichelakis M, Danielides G, Iliou T, Anastassopoulos G, Nikolaidis C, Kirodymos E, et al. Allergic sensitization prevalence in a children and adolescent population of northeastern Greece region. Int J Pediatr Otorhinolaryngol. 2016;89:33-7.