Abstract
Grass pollen is among the most common outdoor aeroallergens eliciting pollen allergies throughout the world. Grass group-1 allergen or β-expansin is recognized as a major pollen allergen, particularly in the grass family Poaceae. Expression of β-expansin has been shown to be dynamic and can be influenced by environmental stresses. This study evaluated the relative expression of β-expansin and IgE-binding ability of crude pollen extract protein of rice and maize under three different stress conditions: flood, salt, and drought. After 1 week of treatments, anthers containing pollen were collected followed by RNA extraction and cDNA synthesis. To evaluate relative expression, qRT-PCR was performed using specific primers for β-expansin and reference genes. Physiological characteristics of treated and untreated maize and rice: plant height; fresh weight of anthers; number of inflorescences, anthers, and pollen grains were also recorded. To assess IgE-binding ability of proteins in rice pollen extracts, soluble crude proteins were extracted and IgE immunoblot and ELISA were performed using serum samples from grass-allergic subjects and healthy control donors. Results showed that plant height, fresh weight of anthers, number of inflorescences, anthers, and pollen grains of both maize and rice decreased significantly under drought stress conditions, but not in other conditions. Expression of β-expansin in pollen of rice showed an apparent increase in all stress treatments relative to control samples. In contrast, a significant decrease of β-expansin expression was detected in maize pollen under all stress-treated conditions. IgE-reactive protein bands from rice pollen extract proteins were ~30 kDa, as expected of the grass-group 1 protein. The intensity of IgE-reactive protein bands and the level of IgE to rice pollen proteins showed significant differences among stress conditions. In conclusion, environmental stresses—flood, salt, and drought, can elicit a change of β-expansin expression and IgE reactivity to grass group-1 pollen allergens. Changes in expression level of this gene likely reflected its importance during stress. However, the response is highly dependent on different schemes employed by each plant species.
Highlights
Atmospheric allergens are significant causes of allergic diseases of both the upper and lower respiratory tracts
Number of inflorescences, number of anthers, fresh weight of anthers, and number of pollen grains were recorded from stress-treated rice and maize plants (Figures 2B–F)
Rice and maize plants subjected to environmental stresses during pollen development, drought stress, exhibited significant differences in plant height, anther fresh weight, number of inflorescences, anthers, and pollen grains
Summary
Atmospheric allergens are significant causes of allergic diseases of both the upper and lower respiratory tracts. Environmental fluctuations including global climate change affect the quantity, quality, and distribution of aeroallergens such as pollen. This phenomenon impacts the severity of seasonal allergic rhinitis and other seasonal allergic diseases worldwide [1,2,3]. Major group pollen allergenic protein is abundantly found in all grass species including tropical/subtropical allergenic grasses [5,6,7,8,9,10]. Cyn d 1, Sor h 1, Pas n 1, Lol p 1, and Zea m 1 are recognized as major group-1 grass pollen allergens produced from Bermuda grass (Cynodon dactylon), Johnson grass (Sorghum halepense), Bahia grass (Paspalum notatum), ryegrass (Lolium perenne), and maize (Zea mays), respectively
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