Seed Storage Protein, Functional Diversity and Association with Allergy

Jain, A. C.

doi:10.3390/allergies3010003

Cited by 12 publications

(4 citation statements)

References 144 publications

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“…Particularly, the proteins able to bind to nutrients and important for nutrient accumulation during seed germination, for example, are usually also involved in host defense and provide resistance to disease. These include seed storage proteins 141 which include the large prolamin superfamily 142–144 comprised of lipid transfer proteins, 2S albumins, cereal prolamins, and the cupins consisting of globulins (legumin‐like proteins) and conglutins (vicilin‐like proteins) as well as pathogenesis‐related proteins 141 . From animal sources animal proteins such as albumins, lipocalins, transferrins, and globulins are similarly serving as carrier for nutrients binding to carbohydrates, 145 minerals, 146–159 lipids, 160–163 phenolics, 146,154–156 and vitamins 149–153 and often play a regulatory role in host defense.…”

Section: Dietary Absorption Of Nutrients: the Bioavailability Differs...mentioning

confidence: 99%

Nutrition in chronic inflammatory conditions: Bypassing the mucosal block for micronutrients

Roth‐Walter,

Berni Canani,

O'Mahony

et al. 2023

Allergy

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Nutritional Immunity is one of the most ancient innate immune responses, during which the body can restrict nutrients availability to pathogens and restricts their uptake by the gut mucosa (mucosal block). Though this can be a beneficial strategy during infection, it also is associated with non‐communicable diseases—where the pathogen is missing; leading to increased morbidity and mortality as micronutritional uptake and distribution in the body is hindered. Here, we discuss the acute immune response in respect to nutrients, the opposing nutritional demands of regulatory and inflammatory cells and particularly focus on some nutrients linked with inflammation such as iron, vitamins A, Bs, C, and other antioxidants. We propose that while the absorption of certain micronutrients is hindered during inflammation, the dietary lymph path remains available. As such, several clinical trials investigated the role of the lymphatic system during protein absorption, following a ketogenic diet and an increased intake of antioxidants, vitamins, and minerals, in reducing inflammation and ameliorating disease.

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Section: Dietary Absorption Of Nutrients: the Bioavailability Differs...mentioning

confidence: 99%

Nutrition in chronic inflammatory conditions: Bypassing the mucosal block for micronutrients

Roth‐Walter,

Berni Canani,

O'Mahony

et al. 2023

Allergy

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“…The cross-reactivities between fruit allergens and homologous proteins from other vegetable, seed, and pollen sources account for different food-pollen syndromes. The allergens responsible for these food-pollen syndromes essentially consist of the pan-allergens nsLTPs, profilins, GRPs, β-1,3-glucanases, but also the seed storage proteins [4]. Most often these pollen-food syndromes result in a benign oral allergy syndrome (OAS) but can, less frequently, lead to a more severe systemic reaction, especially with the peach nsLTP Pru p 3 [27,75].…”

Section: Cross-reactivity Of Fruit Allergensmentioning

confidence: 99%

“…In addition, a few allergens, including Cuc m 3 of the PR-1 family, bromelain (Ana c 2) and kiwelin (Act c 5), belong to a single fruit or a restricted number of fruits. Finally, proteins that belong to the three classes of seed storage proteins from higher plants, 2S albumins, 7S globulins (vicilin), and 11S globulins (legumin) [4], should also be retained as possible potential fruit allergens resulting from the unintended consumption of the seeds of kernels [5]. Many of these fruit allergens represent widely distributed pan-allergens, which are responsible for IgE-binding cross-reactivity often associated with some cross-allergenicity.…”

Section: Introductionmentioning

confidence: 99%

An Overview of Fruit Allergens: Structural, Functional, Phylogenetical, and Clinical Aspects

2023

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Most of the allergenic proteins from fruits identified so far belong to different families of pathogenesis-related (PR) proteins. These PR proteins have been classified in different families of structurally and functionally unrelated proteins, but the majority of all fruit allergens belong to three groups, in particular PR-5 thaumatin-like proteins (TLP), PR-10 Bet v 1-like proteins, and PR-14 non-specific lipid transfer proteins (nsTLP). Some allergenic proteins from fruits can also be found among PR-protein families of PR-2 β1,3-glucanase proteins, PR-3 chitinases I, II, IV–VII, and PR-8 chitinases III. In addition, other important fruit allergens occur in protein families unrelated to the PR-protein families, such as the profilins and the newly emerging group of gibberellin-regulated proteins (GBRP). Finally, proteins that belong to seed storage proteins from higher plants, including 2S albumins, 7S globulins (vicilin), and 11S globulins (legumin), must be retained as possible potential fruit allergens resulting from the unintended consumption of the seeds. Here, we present an overview of the structural organization, functional properties, and phylogenetical relationships among these different groups of fruit allergens, supporting the occurrence of cross-reactivity and cross-allergenicity often described between fruit allergens, and the corresponding allergens from vegetables and pollens.

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“…Several studies demonstrated that rice SSPs modulate glutathione metabolism, mitigate oxidative damage to lipids and proteins, and provoke antioxidative responses against hypercholesterolemia, although glutelins appeared to be superior to prolamins as antioxidants [ 19 , 20 , 21 ]. Moreover, prolamins found in grains such as wheat, barley, and rye are known to cause allergic reactions such as celiac disease and IgE-mediated food allergies [ 22 , 23 , 24 ]. It is interesting that amino acid sequence analysis has revealed a close proximity between prolamins and protein allergens ( RA16/17 ) in rice seeds [ 25 , 26 ].…”

Section: Introductionmentioning

confidence: 99%

Compensatory Modulation of Seed Storage Protein Synthesis and Alteration of Starch Accumulation by Selective Editing of 13 kDa Prolamin Genes by CRISPR-Cas9 in Rice

Pham,

Cho,

Tran

et al. 2024

IJMS

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Rice prolamins are categorized into three groups by molecular size (10, 13, or 16 kDa), while the 13 kDa prolamins are assigned to four subgroups (Pro13a-I, Pro13a-II, Pro13b-I, and Pro13b-II) based on cysteine residue content. Since lowering prolamin content in rice is essential to minimize indigestion and allergy risks, we generated four knockout lines using CRISPR-Cas9, which selectively reduced the expression of a specific subgroup of the 13 kDa prolamins. These four mutant rice lines also showed the compensatory expression of glutelins and non-targeted prolamins and were accompanied by low grain weight, altered starch content, and atypically-shaped starch granules and protein bodies. Transcriptome analysis identified 746 differentially expressed genes associated with 13 kDa prolamins during development. Correlation analysis revealed negative associations between genes in Pro13a-I and those in Pro13a-II and Pro13b-I/II subgroups. Furthermore, alterations in the transcription levels of 9 ER stress and 17 transcription factor genes were also observed in mutant rice lines with suppressed expression of 13 kDa prolamin. Our results provide profound insight into the functional role of 13 kDa rice prolamins in the regulatory mechanisms underlying rice seed development, suggesting their promising potential application to improve nutritional and immunological value.

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Seed Storage Protein, Functional Diversity and Association with Allergy

Cited by 12 publications

References 144 publications

Nutrition in chronic inflammatory conditions: Bypassing the mucosal block for micronutrients

Nutrition in chronic inflammatory conditions: Bypassing the mucosal block for micronutrients

An Overview of Fruit Allergens: Structural, Functional, Phylogenetical, and Clinical Aspects

Compensatory Modulation of Seed Storage Protein Synthesis and Alteration of Starch Accumulation by Selective Editing of 13 kDa Prolamin Genes by CRISPR-Cas9 in Rice

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