Allergenicity of peanut allergens and its dependence on the structure

Covalent conjugation with dietary flavonoids Rutin and Isoschaftoside ameliorates intestinal barrier dysfunction and inflammation induced by Peanut allergy protein Arah 3 and enhances their antioxidant properties

Food allergies, particularly those caused by peanut allergens e.g. Arah 3, are a significant health concern. This study aimed to screen flavonoids with high affinity to Arah 3 by molecular docking, and to evaluate the effects of the Arah 3-flavonoid conjugates on intestinal barrier permeability and inflammation using cell models, and on their antioxidant activities by chemical assays. Computer simulation showed that rutin and isoschaftoside had better affinity and stability with Arah 3. Characterization results exhibited that conjugates were formed by covalent bonding and protein folding reduced significantly. Arah 3-induced intestinal barrier dysfunction was significantly improved after binding with rutin and isoschaftoside. The levels of IL-6, IL-8 and MCP-1 decreased by about 15.61 %, 17.94 % (11.23 %) and 16.17 %, respectively, after conjugation with isoschaftoside (rutin). The antioxidant capacities of two conjugates were significantly enhanced. This study may provide new insights into the effects of flavonoids on the adverse effects of Arah 3.

Allergenicity of Alternative Proteins: Reduction Mechanisms and Processing Strategies

The increasing popularity of alternative proteins has raised concerns about allergenic potential, especially for plant-, insect-, fungal-, and algae-based proteins. Allergies arise when the immune system misidentifies proteins as harmful, triggering IgE-mediated reactions that range from mild to severe. Main factors influencing allergenicity include protein structure, cross-reactivity, processing methods, and gut microbiota. Disruptions in gut health or microbiota balance heighten risks. Common allergens in legumes, cereals, nuts, oilseeds, single-cell proteins, and insect-based proteins are particularly challenging, as they often remain stable and resistant to heat and digestion despite various processing techniques. Processing methods, such as roasting, enzymatic hydrolysis, and fermentation, show promise in reducing allergenicity by altering protein structures and breaking down epitopes that trigger immune responses. Future research should focus on optimizing these methods to ensure that they effectively reduce allergenic risks while maintaining the nutritional quality and safety of alternative protein products.

Allergenicity Reduction of Shrimp (Penaeus vannamei) via Fucoidan-Mediated Covalent Modification: Insights from Epitope Modifying Effect

Covalent modification is an effective strategy for reducing allergenicity to individual allergens, but there are few studies on this strategy modifying specific amino acids within epitopes under the influence of food matrix. This study used fucoidan to covalently modify shrimp (Penaeus vannamei) and combined mass spectrometry and bioinformatics techniques to explore epitope modification. The results showed that lower concentrations (<2.50%) of fucoidan facilitated the covalent modification reaction and effectively modified amino acid sites in the loop regions of allergens, including lysine, asparagine, and methionine. In contrast, higher concentrations (>5.00%) of fucoidan hindered the reaction and modified amino acid sites in the helix regions of allergens, including asparagine, lysine, and methionine. The RBL-2H3 cells model confirmed that modification of hemocyanin epitopes was the main reason for reduced allergenicity. Overall, fucoidan-mediated covalent modification can effectively modify various allergenic epitopes in shrimp, which is a potential strategy to reduce shrimp allergenicity.

Direct Evolution of Matrix-Resistant Circular Bivalent DNA Aptamers for Ara h1

Peanut allergenic protein Ara h1 is a serious food allergen due to its potentially life-threatening effects, and its accurate detection holds significant importance. While several selections were previously reported to isolate DNA aptamers for Ara h1, little success was achieved for binding in a complex food matrix. In this work, circular bivalent aptamers for Ara h1 were obtained by employing a dumbell-shaped DNA library with dual random domains for selection. The highest affinity aptamer, named as CB-APT1, exhibited a dissociation constant (Kd) of 36.3 nM, as determined by microscale thermophoresis. Notably, a similar binding affinity was observed even in a complex matrix that contained 80% w/w total peanut proteins. Further analysis indicates that each random domain acts as a unique binding moiety, working together to enhance the overall affinity. Subsequently, a label-free fluorescent aptasensor was developed for Ara h1, which demonstrated a low detection limit of 1.3 nM and performed well, even in food samples. Our evolution-based approach for developing circular bivalent DNA aptamers does not rely on structural information on the target protein, making it applicable to a wide range of protein targets. We believe this strategy can be leveraged to generate a diverse set of high-quality circular bivalent DNA aptamers that are both stable and functional in real biological samples, thus enhancing the practical applications of DNA aptamers in real-world applications.

Screening Human IgE Epitopes on α-Lactalbumin and Developing Specific Detection Tools for Enhanced Allergen Detection in Food Matrices

Food proteins undergo significant structural changes during various processing methods; however, key epitopes often exhibit resistance to damage and modification. Recently, we developed a sensitive sandwich enzyme-linked immunosorbent assay (Epi-mAbs-sELISA) based on IgE linear epitope peptides. This method enables the quantitative detection of alpha-lactalbumin (ALA) for the assessment of food allergenicity. We determined that antibodies developed from IgE linear epitopes possess higher affinity. Ultimately, the optimized Epi-mAbs-sELISA presented in this study demonstrated a wide linear detection range (30.52 ng/mL to 125 μg/mL), a low detection limit (1.122 ng/mL), and excellent precision, with an internal determination relative standard deviation of 9.23% and an external determination relative standard deviation of 9.89%. The recoveries across various food matrices ranged from 81.9% to 111.9%, surpassing the sensitivity and detection range of commercial ELISA kits. The application of this testing method to processed food samples confirmed its ability to detect undeclared ALA residues, thereby mitigating potential safety issues for patients with milk allergies.

Combined processing technologies: Promising approaches for reducing Allergenicity of food allergens

Food allergy is a severe threat to human health. Although processing technologies are widely used to reduce allergenicity, hypoallergenic foods produced by a single processing technology cannot satisfy consumer demands. Combined processing technology (CPT) is a promising strategy for efficiently producing high-quality hypoallergenic foods. This paper reviews the effects of CPT on the allergenicity of food allergens from three aspects: physical-biochemical CPT, biochemical-biochemical CPT, and physical-physical CPT. The synergistic mechanisms, strengths, and limitations of these technologies were discussed. It was found that CPT is generally more effective than single-processing technologies. Physical-biochemical CPT is the most widely studied and well-established because physical and biochemical processing technologies complement each other and effectively disrupt conformational and linear epitopes. Biochemical-biochemical CPT primarily disrupts linear epitopes, but most methods are time-consuming. Physical-physical CPT is the least studied; they mainly disrupt conformational epitopes and only rarely affect linear epitopes.

Screening, identification, and application of aptamers against allergens in food matrices

Food allergies have become one of the most pressing issues in food safety and public health globally along with their incidence increasing in recent years. The reliable recognition of allergens from different sources, especially food-hidden allergens, is essential for preventing and controlling food allergies. Recently, aptamers, as emerging recognition elements, have gained considerable attention in food allergy, especially in the detection of food allergens. This review systematically summarizes the latest progress in screening, identification, and application of aptamers against food allergens over the past five years. We first introduce a brief overview of food allergy and aptamers, followed by a detailed focus on the aptamers' research against different food allergens broadly based on the major categories of the Big-8 allergens: highlighting the newly screened aptamers and their applied systematic evolution of ligands by exponential enrichment (SELEX) strategies, and emphasizing their practical applications including aptasensors, allergy inhibitors, or affinity adsorptions. Finally, the remaining challenges and future exploitations faced by aptamers in food allergens are comprehensively discussed and depicted. This review holds the promise of inspiring a broader range of researchers to gain an in-depth understanding of food allergy assisted by aptamer recognition and to facilitate improved biochemical analyses and successful application.

Recycled lithium battery nanomaterials as a sustainable nanofertilizer: Reduced peanut allergenicity and improved seed quality

The rapidly increasing amount of end-of-life lithium iron phosphate (LiFePO4) batteries has raised significant environmental concerns. This study offers a strategy for a paradigm shift by transforming this growing waste into a valuable resource by recycling discarded LiFePO4 batteries and safely integrating the materials into sustainable agriculture. We used five types of LiFePO4 (10, 50 mg kg-1) applied to soil planted with peanuts in a full-culture experiment. Our results show that addition of <50 mg kg-1 of recycled nano-LiFePO4 (rn-LiFePO4) has a multifaceted positive impact on peanut because of sustainable release of nutrients and nano-specific effects, not only enhancing photosynthesis and root growth but also increasing yield by 22 %-34 % while simultaneously elevating seed nutritional quality. Moreover, a remarkable reduction (up to 99.78 % at 10 mg kg-1 rn-LiFePO4) in the expression of allergen genes was evident following exposure to LiFePO4, which showed a significant negative correlation with Fe content in the seeds. The decreased peanut allergen gene expression was mediated by a downregulation of metabolites associated with protein digestion and absorption. Furthermore, rhizosphere soil immune system enhancement may indirectly enhance immune responses to peanut allergy. This study suggests the significant potential of nanoscale LiFePO4 recycled from Li battery, including enhancing crop yield quality and mitigating peanut allergy concerns while simultaneously addressing a growing waste stream of concern.

The effects of ultrasound-assisted glycation on the allergenicity and functional properties of peanut proteins

This study investigated the effects of ultrasound-assisted glycation on the allergenicity and functional properties of peanut proteins. Results showed that ultrasound-assisted glycation increased the degree of glycation reaction of peanut proteins significantly (P < 0.05). ELISA results indicated that the binding of peanut allergens with serum immunoglobulin G (IgG) and immunoglobulin E (IgE) was significantly decreased (P < 0.05). Furthermore, secondary structure analysis revealed a significant increase in β-sheet content, alongside decreases in α-helix, β-turn, and random coil contents (P < 0.05). In addition, intrinsic fluorescence intensity, surface hydrophobicity, and ultraviolet (UV) spectra intensity were diminished (P < 0.05), indicating notable changes in both secondary and tertiary structures of peanut proteins. Moreover, emulsification property, antioxidant activity and in vitro digestibility of peanut proteins showed the most obvious improvements following ultrasound-assisted glycation, and the solubility was increased while turbidity was decreased significantly (P < 0.05). In conclusion, this study demonstrated that ultrasound-assisted glycation not only effectively reduced the allergenicity of peanut allergens, but also improved the overall functional properties of peanut proteins, and the changes in sensitization and functional properties might be closely related to structural changes. This study will provide a theoretical basis for the development of peanut products.

Employing conductive porous hydrogen-bonded organic framework for ultrasensitive detection of peanut allergen Ara h1

Peanut allergy has garnered worldwide attention due to its high incidence rate and severe symptoms, stimulating the demand for the ultrasensitive detection method of peanut allergen. Herein, we successfully developed a novel electrochemical aptasensor for ultrasensitive detection Ara h1, a major allergenic protein present in peanuts. A conductive nickel atoms Anchored Hydrogen-Bonded Organic Frameworks (PFC-73-Ni) were utilized as excellent electrocatalysts toward hydroquinone (HQ) oxidation to generate a readable current signal. The developed electrochemical aptasensor offers wide linear range (1-120 nM) and low detection limit (0.26 nM) for Ara h1. This method demonstrated a recovery rate ranging from 95.00% to 107.42% in standard addition detection of non-peanut food samples. Additionally, the developed electrochemical method was validated with actual samples and demonstrated good consistency with the results obtained from a commercial ELISA kit. This indicates that the established Ara h1 detection method is a promising tool for peanut allergy prevention.

Effect of pH-Shift Treatment on IgE-Binding Capacity and Conformational Structures of Peanut Protein

Hypoallergenic processing is an area worthy of continued exploration. In the treatment of the peanut protein (PP), pH shift was applied by acidic (pH 1.0-4.0) and alkaline (pH 9.0-12.0) treatment, after which the pH was adjusted to 7.0. Following pH-shift treatment, PP showed a larger particle size than in neutral solutions. SDS-PAGE, CD analysis, intrinsic fluorescence, UV spectra, and surface hydrophobicity indicated the protein conformation was unfolded with the exposure of more buried hydrophobic residues. Additionally, the IgE-binding capacity of PP decreased after pH-shift treatment on both sides. Label-free LC-MS/MS results demonstrated that the pH-shift treatment induced the structural changes on allergens, which altered the abundance of peptides after tryptic digestion. Less linear IgE-binding epitopes were detected in PP with pH-shift treatment. Our results suggested the pH-shift treatment is a promising alternative approach in the peanut hypoallergenic processing. This study also provides a theoretical basis for the development of hypoallergenic food processing.

Combination of Structural Analysis and Proteomics Strategy Revealed the Mechanism of Ultrasound-Assisted Cold Plasma Regulating Shrimp Allergy

Allergic incidents of crustacean aquatic products occur frequently, and tropomyosin (TM) is the main allergen. Therefore, it is worthwhile to develop technologies to efficiently reduce the allergenicity of TM. In this study, ultrasound-assisted cold plasma (UCP) treatment was used to regulate shrimp allergy. The remarkable changes in TM structure were substantiated by alteration in secondary structure, reduction in sulfhydryl content, change in surface hydrophobicity, and disparity in surface morphology. The IgE and IgG binding ability of TM significantly decreased by 52.40% and 46.51% due to UCP treatment. In the Balb/c mouse model, mice in the UCP group showed most prominent mitigation of allergic symptoms, proved by lower allergy score, changes in levels of TM-specific antibodies, and restoration of Th1/Th2 cytokine imbalance. Using a proteomics approach, 439 differentially expressed proteins (DEPs) in the TM group (vs phosphate-buffered saline group) and 170 DEPs in the UCP group (vs TM group) were determined. Subsequent analysis demonstrated that Col6a5, Col6a6, and Epx were potential biomarkers of TM allergy. Moreover, Col6a5, Col6a6, Dcn, and Kng1 might be the target proteins of UCP treatment, while PI3K/Akt/mTOR might be the regulated signaling pathway. These findings proved that UCP treatment has great potential in reducing TM allergenicity and provide new insights into the development of hypoallergenic shrimp products.

IgE-Mediated Legume Allergy: A Pediatric Perspective

Legumes are an inexpensive and essential protein source worldwide. The most consumed legumes include peanuts, soybeans, lentils, lupines, peas, common bean and chickpeas. In addition, the food industry is growing interested in expanding the use of legumes to partially replace or substitute cereals. Legumes were described to cause IgE-mediated allergies, and their growing use may also increase the incidence of allergy. The epidemiology of legume allergy varies by region; peanuts and soybeans are the legumes most involved in food allergies in Western countries, whereas lentils, peas, and chickpeas are reported as culprit allergens mainly in the Mediterranean area and India. This review, edited by the Italian Society of Pediatric Allergology and Immunology, summarizes the scientific literature on legume allergy in children and proposes a diagnostic workup and therapeutic approach.

Major peanut allergens are quickly released from peanuts when seeds are hydrated under specific conditions

Allergens release from their biological source is a critical step in allergic sensitization. We sought to investigate in vitro the role of hydration at 1:10 w/v without stirring and 1:5 w/v with and without stirring on the release of major and minor allergens from peanut kernels. We hypothesized that hydration plays a pivotal role in peanut allergens release, affecting major allergens predominantly, and that peanut-water ratio and stirring influence allergen diffusion. We found that major peanut allergen Ara h 1 was quickly released during hydration leading to a decrease in its content in the seed particularly at hydration performed at 1:5 w/v with stirring. Ara h 2 remained more preserved in the hydrated seed, while Ara h 3 showed no content decrease despite its important release into the hydration water. Minor allergens Ara h 8 and Ara h 9 have lower abundance in peanut leading to a reduction of their content in the seed after their diffusion into the water during hydration. The results also demonstrated that a higher seed-to-water ratio (1:5 w/v) and stirring had a more pronounced impact on allergen release.

Mass Spectrometry Analysis on the Breakage of Allergens in High-Molecular-Mass Polymer of Roasted Peanuts

Peanut allergy is a prevalent and concerning food allergy. Roasting can introduce structural changes to peanut allergens, affecting their allergenicity, but the structure on the primary structure is unclear. Here, the breakage sites were identified by mass spectrometry and software tools, and structural changes were simulated by molecular dynamics and displayed by PyMOL software. Results revealed that the appearance frequencies of L, Q, F, and E were high at the N-terminal of the breakage site, while S and E were dominant at the C-terminal. In the conformational structure, breakage sites were found close to disulfide bonds and the Cupin domains of Ara h 1 and Ara h 3. The breakage of allergens destroyed linear epitopes and might change the conformation of epitopes, which could influence peanuts' potential allergenicity.

Investigation of peanut allergen-procyanidin non-covalent interactions: Impact on protein structure and in vitro allergenicity

Interactions between plant polyphenols and food allergens may be a new way to alleviate food allergies. The non-covalent interactions between the major allergen from peanut (Ara h 2) with procyanidin dimer (PA2) were therefore characterized using spectroscopic, thermodynamic, and molecular simulation analyses. The main interaction between the Ara h 2 and PA2 was hydrogen bonding. PA2 statically quenched the intrinsic fluorescence intensity and altered the conformation of the Ara h 2, leading to a more disordered polypeptide structure with a lower surface hydrophobicity. In addition, the in vitro allergenicity of the Ara h 2-PA2 complex was investigated using enzyme-linked immunosorbent assay (ELISA) kits. The immunoglobulin E (IgE) binding capacity of Ara h 2, as well as the release of allergenic cytokines, decreased after interacting with PA2. When the ratio of Ara h 2-to-PA2 was 1:50, the IgE binding capacity was reduced by around 43 %. This study provides valuable insights into the non-covalent interactions between Ara h 2 and PA2, as well as the potential mechanism of action of the anti-allergic reaction caused by binding of the polyphenols to the allergens.

Peanut Allergenicity: An Insight into Its Mitigation Using Thermomechanical Processing

Peanuts are the seeds of a legume crop grown for nuts and oil production. Peanut allergy has gained significant attention as a public health issue due to its increasing prevalence, high rate of sensitization, severity of the corresponding allergic symptoms, cross-reactivity with other food allergens, and lifelong persistence. Given the importance of peanuts in several sectors, and taking into consideration the criticality of their high allergic potential, strategies aiming at mitigating their allergenicity are urgently needed. In this regard, most of the processing methods used to treat peanuts are categorized as either thermal or thermomechanical techniques. The purpose of this review is to provide the reader with an updated outlook of the peanut’s allergens, their mechanisms of action, the processing methods as applied to whole peanuts, as well as a critical insight on their impact on the allergenicity. The methods discussed include boiling, roasting/baking, microwaving, ultrasonication, frying, and high-pressure steaming/autoclaving. Their effectiveness in alleviating the allergenicity, and their capacity in preserving the structural integrity of the treated peanuts, were thoroughly explored. Research data on this matter may open further perspectives for future relevant investigation ultimately aiming at producing hypoallergenic peanuts.