质谱法分析烘焙对花生过敏原Ara h 1潜在致敏性的影响

为研究烘焙对花生过敏原Ara h 1潜在致敏性的影响,采用高离液序列盐溶液从鲜花生和烘焙花生中提取总蛋白,通过十二烷基硫酸钠-聚丙烯酰胺凝胶电泳分析烘焙前后蛋白条带变化情况,并对其中的花生主要过敏蛋白Ara h 1条带进行质谱和Swiss-Model模型分析.十二烷基硫酸钠-聚丙烯酰胺凝胶电泳结果显示,烘焙花生蛋白出现...     

Reduction of major peanut allergens Ara h 1 and Ara h 2, in roasted peanuts by ultrasound assisted enzymatic treatment

This study investigated the effects of ultrasound, enzyme concentration and enzyme treatment time on soluble protein and major allergenic proteins (Ara h 1 and Ara h 2) of roasted peanut kernels. A 3-factor, five-level orthogonal experimental design was implemented with various ultrasonication times, concentrations of trypsin or α-chymotrypsin and treatment times. The total soluble proteins were determined by the Bicinchoninic acid (BCA) method, Ara h 1 and Ara h 2 were evaluated by SDS–PAGE and sandwich ELISA. The IgE-binding of peanut extracts was analysed by a competitive inhibition ELISA. Results indicate that ultrasound treatment, followed by protease digestion of peanuts, significantly increased the solubility of peanut protein and decreased the concentrations of Ara h 1 and Ara h 2. The sequential treatment of peanuts by ultrasonication–trypsin–alpha chymotrypsin, resulted in maximum reductions of Ara h 1/Ara h 2, and lowest IgE-binding. This study provides an approach to significantly reduce allergenic proteins in peanut product.     

Allergenicity of roasted peanuts treated with a non-human digestive protease

Peanut allergy is a severe and lifelong type of food allergy triggered by allergenic proteins and peptides in peanuts. This study investigated the effects of ultrasound-assisted alcalase treatment on the concentrations of major allergenic proteins (Ara h 1 and Ara h 2) in roasted peanut kernels and the allergenicity of treated peanut extracts. Peanut kernels were sonicated for 1 h in buffer solution, incubated with different amount of alcalase for various time, then vacuum dried. The variations of Ara h 1 and Ara h 2 contents in soluble and insoluble portions of peanuts treatments were evaluated by sandwich ELISA and SDS-PAGE, respectively. The in vitro IgE-binding capacity of treated peanut extracts was determined by a competitive inhibition ELISA using pooled plasma of 10 peanut allergic patients. Samples with lower in vitro IgE-binding were used for human skin prick tests (SPTs) in peanut allergic individuals. Results indicate that alcalase digestion of sonicated peanuts significantly increased protein solubility while decreasing Ara h 1 and Ara h 2 concentrations in both soluble and insoluble portions of peanuts relative to untreated peanuts. The maximum reductions of Ara h 1 and Ara h 2 levels were obtained following 3 hour digestion with alcalase at concentrations of 4.54 and 6.05 U/100 g. Samples obtained under these conditions showed the lowest in vitro IgE-binding and caused the least allergic response in human SPTs. The current study suggests that the allergenic potential of peanuts could be reduced by postharvest processing such as ultrasound-assisted enzymatic treatment of peanuts kernels.     

Peanut allergen (Ara h 1) detection in foods containing chocolate

Inadvertent exposure to peanut in foods poses health risks for peanut-allergic individuals that can be reduced by improving detection systems for allergen contaminants in food products and manufacturing processes. Detection of peanut in chocolate has been especially difficult. We report the optimization of conditions for measuring a major peanut allergen, Ara h 1, in chocolate with the use of a two-site monoclonal antibody sandwich enzyme-linked immunosorbent assay. Ara h 1 was extracted from peanut in the presence or absence of chocolate with phosphate buffer, salt, and three dried milks (goat, soy, or nonfat) (0 to 25% wt/vol) for 15 min at 60 degrees C or for 2.5 h at room temperature. The best conditions for Ara h 1 extraction in the presence of chocolate were 5% nonfat dry milk for 2.5 h at room temperature. Spiking experiments of chocolate with peanut confirmed improvement of the extraction: Ara h 1 was detected in extractions of 0.16 to 0.33% peanut in chocolate. Interestingly, the best conditions for Ara h 1 extraction were different for peanut alone than with chocolate, regarding time, temperature, and percentage of nonfat dry milk in the extraction buffer. In chocolate with peanut foods, the total Ara h 1 values were 10-fold higher than when products were extracted with phosphate buffer alone and could be up to 400-fold higher for individual foods. The dramatic improvement of Ara h 1 extraction should allow specific allergen monitoring in chocolate-containing food products and assessment of Ara h 1 exposure.     

Proteolytic processing of the peanut allergen Ara h 3

The allergen Ara h 3 has been purified recently from peanuts. In contrast to recombinant Ara h 3, a 60 kDa single-chain polypeptide, the allergen isolated from its native source is extensively proteolytically processed. The characteristic proteolytic processing for 11S plant storage proteins of the glycinin family is observed for Ara h 3 yielding an acidic and a basic subunit, bound by a disulfide bridge. In addition to this, proteolytic truncation is observed for the acidic subunit but not for the basic subunit of Ara h 3. A series of Ara h 3 polypeptides ranging from 13-45 kDa was separated by sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and each band was digested by trypsin. Peptides related to the bands were identified and a scheme positioning the different polypeptides in the Ara h 3 sequence has been constructed. Peptide analysis showed sequence heterogeneity at two positions indicating the presence of multiple genes encoding variant, but highly homologous Ara h 3 proteins. The pool of Ara h 3 polypeptides from its native source illustrated that allergen from the peanut is much more complex than the recombinant protein used for epitope mapping experiments. From several Ara h 3 truncation products one or more immunoglobulin E (IgE) binding sites had been removed. Characterization of the allergenicity of Ara h 3 should therefore also include IgE-binding studies with peanut-derived Ara h 3, providing the high degree of variation in the Ara h 3 protein structure, as this is what peanut-allergic individuals are confronted with.     

基于表位预测的花生过敏原Ara h 6 免疫交叉反应性研究

为了探讨花生过敏原Ara h 6 与其他同源蛋白之间的交叉反应,通过各种生物信息数据库(Genbank,DiscoTope)以及网络工具及软件(BLAST,NPS@和Protean,Clustal x,PyMOL),开展基于表位预测的Ara h 6交叉免疫反应性研究。结果表明：肽段AA10～15、45～48、53～60、116～118 区域可能是Ara h 6 的线性表位优势区域;Ara h 6 的构象型表位优势区有4 个,它们存在的区域为AA1～13、35～51、53～59、89～105;基于线性表位预测的15 种蛋白质与Ara h 6 可能具有交叉反应性,其中4 种(Ara i 6,conglutin,Ara d 6 和conglutin 8)发生交叉反应的概率为100%;基于构象型表位预测的17 种蛋白质与Ara h 6 可能具有交叉反应性,其中4 种(Ara i 6,conglutin,Ara d 6 和conglutin 8)发生交叉反应的概率为100%。本结果对进一步了解Ara h 6 的过敏性以及指导开展食品中Ara h 6 的免疫学检测具有重要作用。     

Effects of twin-screw extrusion of peanut flour on in vitro digestion of potentially allergenic peanut proteins

Partially defatted peanut flour was processed in a twin-screw extruder. Resulting extrudates were dried, ground, and incubated with simulated gastric fluid for various time periods. Soluble protein content of the resulting digesta was measured after 10% trichloroacetic acid treatment to evaluate the digestibility. In vitro digestion using pepsin increased the solubility of peanut protein in 10% trichloroacetic acid solution from 2 to 6% to 65 to 75%. Four strong IgE-binding subunits (65, 22, 17, and 14 kDa) were found with immunoblotting in peanut proteins extracted from unextruded peanut flour; no IgE-binding bands were observed in extrudates. The 65-kDa (putative Ara h 1) subunit was insolubilized during extrusion, and its IgE-binding property was susceptible to in vitro digestion. Following extrusion cooking, no IgE-binding bands were detected by immunoblotting, including the strongly IgE-binding 14-kDa fraction, a strong IgE-binding band from native peanut protein that is stable in pepsin. The 22- and 17-kDa (putative Ara h 2) subunits retained a small amount of IgE-binding potential and became susceptible to pepsin hydrolysis after extrusion.     

脂质过氧化物对花生过敏原致敏性的影响

目的 阐明加工过程中脂质过氧化物对花生过敏蛋白Ara h 1结构和过敏原性的影响。方法 通过十二烷基硫酸钠聚丙烯酰胺凝胶电泳技术,圆二色谱法和内源荧光光谱法研究不同脂质过氧化物[2,2-偶氮二(2-甲基丙基咪)二盐酸盐(2,2’-azobis(2-methylpropanimidamide)dihydrochloride,AAPH)和丙烯醛]对花生过敏蛋白Ara h 1的结构影响,进一步采用免疫印迹技术、酶联免疫法,模拟胃液消化和细胞模型分析其过敏原性的变化。结果 脂质过氧化物修饰后的花生过敏蛋白Ara h 1二级结构变得更无序,内源荧光强度降低;花生过敏蛋白Arah1的免疫球蛋白E结合能力、消化稳定性和释放活性介质能力均降低。结论 在花生加工过程中脂质过氧化物能够改变花生过敏蛋白的结构,降低其过敏原性。     

花生过敏患者血清中抗Ara h1的IgG与IgE分离纯化研究

Ara h1是花生的一种主要致敏原蛋白,能够使花生过敏患者产生特异的IgG与IgE,从而导致花生过敏症状。Ara h1与其特异IgG和IgE的结合是导致花生致敏的一个重要原因。本研究利用Protein A亲和层析柱与Ara h1作为配体的亲和层析柱纯化抗Ara h1的IgG与IgE。高纯度的抗Ara h1特异IgG与IgE对探讨研究其与Ara h1之间相互作用具有重要意义。     

Development of an epitope-specific analytical tool for the major peanut allergen Ara h 2 using a high-density multiple-antigenic peptide strategy

Using the major peanut allergen Ara h 2 as an example, an analytical tool enabling the determination of immunoglobulin E (IgE)-epitopes in processed food allergens was developed. We synthesized a multiple-antigenic peptide (MAP) of the IgE-reactive linear epitope 3 (amino acid positions 27-36) of Ara h 2 and raised a monospecific antiserum against this epitope to obtain a positive control for future epitope resolved diagnostics. First, a MAP of epitope 3, having a molecular mass of 7770 Da, was synthesized, purified, and its structure confirmed by liquid chromatography-mass spectrometry (electrospray ionization) (LC-MS(ESI)), matrix assisted laser desorption/ionization-time of flight (MALDI-TOF), and Edman sequencing. The MAP was then used to raise high titer antibodies in rabbits using the adjuvant Titermax and to characterize the specificity of IgE from allergenic patients sensitized to Ara h 2. The antiserum exclusively detects Ara h 2 in crude peanut extract with a titer of 10(7) by Western blot and reacts specifically with epitope 3 shown by epitope mapping for a library of solid-phase-bound synthetic 15-mer peptides covering the entire sequence of Ara h 2. Such IgE-reactive epitopes are of high analytical relevance as they could constitute the basis for epitope-specific detection systems for use in quality control in the food industry or for forensic purposes in cases of fatal reactions to otherwise undetected peanut proteins.     

超高效液相色谱-电喷雾质谱法检测花生 过敏原Ara h 2

目的建立烘培食品中花生过敏原Ara h 2的液相质谱联用定量检测方法。方法选择花生蛋白中的致敏蛋白Ara h 2作为目标蛋白,筛选出该致敏蛋白的特异肽,人工合成特异肽标准品和特异肽内标,从而建立直接检测花生致敏蛋白Ara h 2的准确定量方法。同时还对全国不同地区的20种花生中致敏蛋白Ara h 2的含量进行检测分析,初步统计得出致敏蛋白Ara h 2和花生蛋白的换算系数,并以Ara h 2作为生物标记物检测10种烘培食品中花生蛋白的残留量。结果花生样品中致敏蛋白Ara h 2的定量限为4.45μg/g,回收率在106.0%~107.8%之间。烘培食品中,定量限可达到6.23μg/g,回收率在107.0%~113.2%之间。结论本方法特异性强、灵敏度高、定量准确,具有良好的应用前景。     

Investigation on sequential extraction of peanut allergens for subsequent analysis by ELISA and 2D gel electrophoresis

A two-step sequential extraction method of peanut proteins was proposed with the aim to investigate the protein composition and allergen content of peanut samples. The extraction procedure reported is fully compatible with subsequent analysis by enzyme-linked immunosorbent assays (ELISA) as well as 2D gel electrophoresis (2D PAGE). This sequential extraction method was used to study three different peanut varieties and three different types of food processing. Peanuts were analysed for total protein content and the extraction efficiency of raw and processed peanuts was determined. The total protein content of the three peanut varieties was found to be comparable, but their extraction efficiency varies. The peanut extracts were characterised by employing three different ELISA test kits specific to either the allergens Ara h 1 or Ara h 2, or to soluble peanut proteins. The content of both Ara h 1 and Ara h 2 differed in the raw peanut extracts of the three varieties. However, thermal processing resulted in much larger changes in detectability. Blanching significantly increases the detectability of Ara h 2, whereas Ara h 1 detection remains almost unchanged. After roasting a clear decrease of detectability was observed for both Ara h 1 and Ara h 2, although the effect is more severe for Ara h 1. 2D PAGE was employed to compare the protein profiles and abundances of peanut extracts. Statistically relevant differences were observed for the two different protein fractions obtained by using the described method, showing the relevance of this two-step sequential extraction method.     

Peanut varieties with reduced Ara h 1 content indicating no reduced allergenicity

Peanut allergy is a major cause of food‐induced severe anaphylactic reactions. To date, no medical care is available to prevent and treat peanut allergy and therefore hypoallergenic peanut varieties are of considerable health political and economic interest. Major allergens that induce IgE‐responses in peanut‐sensitive patients are Ara h 1, Ara h 2 and Ara h 3/4. In order to identify hypoallergenic peanuts, commercially locally available peanut varieties were screened for their allergen content. Ara h 1‐deficient peanuts from Southeast Asia were identified by SDS‐PAGE, immunoblotting, inhibition assays and ELISA. 2‐D PAGE analyses demonstrated the different compositions of the tested extracts and revealed a number of variations of the allergen patterns of peanuts from different varieties. Mediator release experiments of these peanut extracts demonstrated similar allergenicities as compared with standard peanut extract. These results indicate that the allergenicity of peanuts with reduced Ara h 1 content might be compensated by the other allergens, and thus do not necessarily cause a reduction of allergenicity.     

阴离子交换层析法分离纯化花生主要过敏原Ara h1的研究

Ara h1蛋白是花生的主要过敏原蛋白。本研究从天然的花生提取花生蛋白质,通过硫酸铵分级沉淀及阴离子交换层析法纯化花生主要过敏原Ara h1。通过聚丙烯酰胺凝胶电泳分析蛋白纯度,结合免疫印迹实验对Ara h1免疫活性进行鉴定。结果表明：采用阴离子交换层析法纯化出的Ara h1纯度达到90%以上。得率为23.1%。免疫印迹实验表明,此方法纯化出来的Ara h1仍具有免疫原性,能跟花生过敏病人血清特异结合。     

花生主要过敏原Ara h 1线性B细胞表位的预测及鉴定

花生过敏由于其高致敏率和致敏严重性而引起了人们的广泛关注。Ara h 1是花生中的主要过敏原,属于Cupin超家族,通过抗原表位识别结合免疫球蛋白E引发花生过敏。本研究采用生物信息学分析花生主要过敏原Cupin超家族Ara h 1线性B细胞表位氨基酸组成,及其与Ara h 1二级、三级结构之间关系,通过质谱分析Ara h 1氨基酸序列中的抗消化肽段,并分析抗消化肽段与预测线性B细胞表位的关系。结果表明,Ara h 1的线性B细胞表位富含亲水性氨基酸和带电氨基酸;其二级结构没有明显的分布规律,具有一定的回转折叠结构;分析Ara h 1三级结构发现,表位主要位于单体之间的疏水相互作用区域,部分表位埋入三聚体构象内部;Ara h 1抗消化序列与表位之间存在部分重叠。综上,质谱检测体外模拟胃肠道消化肽段并结合表位生物信息学分析可以作为鉴定Cupin超家族线性B细胞表位的新方法。     

离子交换层析法分离花生过敏原Ara h2的研究

为了制备出花生中重要过敏原Arah2,以生花生为材料,采用脱脂、离心、膜透析、离子交换层析等方法,纯化花生过敏原Arah2。结果显示,采用阴离子交换层析方法,制取的Arah2蛋白纯度达90%,得率为21.9%,该方法为过敏原Arah2的分离研究提供了可行的实验参数。     

中国花生致敏蛋白的识别

我国对花生过敏方面的研究很少。本实验利用中国常用花生品种识别鉴定了中国主要的致敏蛋白,比较了国内外花生品种致敏蛋白相对含量的差异,期望找到中国花生过敏发病率较低的原因,为临床食物过敏患者的治疗和低过敏花生品种的培育提供理论依据。研究结果表明:Ara h1和三条Ara h3多肽是中国主要的致敏蛋白,并发现了Ara h1的亚基,分子量为58kD的多肽。Ara h1和Ara h3的相对含量各品种之间差异显著,并且低于国外花生品种。因此中国花生主要致敏蛋白相对含量低可能是导致中国花生过敏发病率较低的主要原因。     

Boiling peanut Ara h 1 results in the formation of aggregates with reduced allergenicity

Scope : Roasting rather than boiling and Maillard modifications may modulate peanut allergenicity. We investigated how these factors affect the allergenic properties of a major peanut allergen, Ara h 1. Methods and results : Ara h 1 was purified from either raw (N‐Ara h 1) or roasted (R‐Ara h 1) peanuts. Boiling (100°C 15 min; H‐Ara h 1) resulted in a partial loss of Ara h 1 secondary structure and formation of rod‐like branched aggregates with reduced IgE‐binding capacity and impaired ability to induce mediator release. Glycated Ara h 1 (G‐Ara h 1) formed by boiling in the presence of glucose behaved similarly. However, H‐ and G‐Ara h1 retained the T‐cell reactivity of N‐Ara h 1. R‐Ara h 1 was denatured, comprised compact, globular aggregates, and showed no evidence of glycation but retained the IgE‐binding capacity of the native protein. Conclusion : Ara h 1 aggregates formed by boiling were morphologically distinct from those formed by roasting and had lower allergenic activity. Glycation had no additional effect on Ara h 1 allergenicity compared with heating alone. Taken together with published data on the loss of Ara h 2/6 from boiled peanuts, this supports the hypothesis that boiling reduces the allergenicity of peanuts.     

花生过敏原Ara h 2.02 二级结构和B 细胞抗原表位预测

为预测花生过敏原Ara h 2.02 的二级结构和B 细胞抗原表位,通过Genbank 数据库搜索到Ara h 2.02 基因,并推导出其相应的氨基酸序列,采用SOPMA 和DNAStar 软件预测该蛋白质的二级结构以及通过Jameson-Wolf 法、Kyte-Doolittle 法、Emini 法和Karplus-Schulz 法分别预测其抗原指数、亲水性、表面可性、柔韧性等参数,并综合分析预测该蛋白的B 细胞抗原表位。结果表明：在序列28～31、56～73、76～90、92、148、156～158、168～169 区域最可能是Ara h 2.02 蛋白的B 细胞抗原表位的优势区域。该结果将为寻找Ara h 2.02 的最佳优势表位提供支持,同时为该蛋白单克隆抗体的制备等研究提供理论依据。