Immune responses to food

IF 7.5 2区 医学 Q1 IMMUNOLOGY
Cathryn R. Nagler
{"title":"Immune responses to food","authors":"Cathryn R. Nagler","doi":"10.1111/imr.13397","DOIUrl":null,"url":null,"abstract":"<p>The enormous variety of antigens present in food is not ignored by the immune system. Dietary antigens are recognized as foreign, and tolerance must be induced. The regulation of both mucosal and systemic non-responsiveness to dietary antigens is therefore a basic physiological process which has drawn experimental interest for many years. Indeed, the first report on the induction of non-responsiveness by a fed antigen was published over one hundred years ago.<span><sup>1</sup></span> Since that time it has become clear that, in keeping with the need to maintain tolerance to dietary antigens, the oral route of antigen administration is uniquely suited to inducing antigen specific non-responsiveness. Experiments in the late 1980s highlighted the practical benefits of oral antigen administration by demonstrating that intragastric delivery of autoantigens, prior to peripheral immunization, protected against the development of autoimmunity in mice.<span><sup>2, 3</sup></span> This finding was subsequently confirmed in a large variety of animal models of autoimmune, allergic, and inflammatory disease, as well as in models of transplant rejection.<span><sup>4</sup></span> The generalizability of the observation that oral administration of antigen can protect against the development of antigen-induced systemic disease became the foundation for immunotherapeutic trials of orally administered antigens for several human diseases including rheumatoid arthritis, multiple sclerosis, Type 1 diabetes, autoimmune uveitis and food allergy.<span><sup>5</sup></span> However, unlike the murine models where the autoantigens were well defined and administered before disease was induced, the clinical trials attempted to modulate established tissue damage in settings in which the autoantigens were both complex and poorly characterized. It was not surprising, then, when these initial trials met with limited success. Both the murine and human studies succeeded, however, in stimulating interest in understanding the mechanisms by which orally administered antigens induce systemic nonresponsiveness to subsequent antigen challenge.</p><p>Early work by Weiner and colleagues described high and low dose oral tolerance mediated by deletion or anergy/suppression and a novel subset of TGF-β secreting “Th3” cells.<span><sup>6, 7</sup></span> The doses designated as high and low were somewhat arbitrarily defined. The identification of transcription factors that specify CD4 T cell differentiation did not reveal a Th3 subset, but did show that the production of TGF-β by innate immune cells is an important fate specifying cytokine for both Th17 cells and peripherally induced Foxp3<sup>+</sup> regulatory T cells (Tregs).<span><sup>8</sup></span> With the discovery of Foxp3<sup>+</sup> Tregs, attention switched to the role of food antigen specific Tregs induced in the context of the dietary vitamin A metabolite retinoic acid in gut draining lymph nodes. It was even suggested that oral tolerance was entirely attributable to retinoic acid.<span><sup>9</sup></span> Subsequent work showed that the presence of both TGF-β and retinoic acid in the mesenteric lymph node was critical to induce Tregs with homing receptors that allowed them to migrate back to the small intestinal lamina propria and expand under the influence of IL-10.<span><sup>10</sup></span> In recent years, interest in understanding immune responses to food has been propelled by the skyrocketing prevalence of food allergies.<span><sup>11</sup></span> In this volume we review the current understanding of the mechanisms regulating non-responsiveness to food and explore how that knowledge is informing new therapeutic approaches to prevent or treat food allergies and other pathologic responses to dietary antigens.</p><p>Miranda-Waldetario and Curotto de Lafaille begin by reviewing the historical perspective mentioned above and providing up-to-date insights on the different antigen presenting cells/cellular compartments central to the induction of food antigen specific Tregs.<span><sup>12</sup></span> A specific subset of RORγt<sup>+</sup> expressing food antigen specific Fox3<sup>+</sup> Tregs, induced primarily in the draining duodenal lymph node, is critical for tolerance to dietary antigens. Both these authors and Cheifetz and Knoop emphasize that a unique developmental window (and mucosal microenvironment) in early life is critical for inducing non-responsiveness to food.<span><sup>13</sup></span> The animal model data described is in keeping with the current understanding that early life introduction of allergenic foods is essential to the induction of tolerance. When the prevalence of life-threatening peanut allergies started to climb in the U.S., the American Academic of Pediatrics (AAP) issued guidance which advised pregnant women and breast-feeding mothers to avoid peanut consumption and to withhold peanuts from their children until the age of 3.<span><sup>14</sup></span> This turned out to be exactly the wrong advice. In the landmark Learning About Early Prevention (LEAP) study, Lack and colleagues noted that peanut allergy was much more common in children living in the U.K. than children from the same ethnic background living in Israel. They observed that children in Israel (but not the U.K.) were fed a peanut containing snack in early life. A randomized clinical trial clearly demonstrated that early introduction of peanuts reduced the risk of subsequent peanut allergy.<span><sup>15</sup></span> The AAP guidelines were reversed in 2019 to recommend that peanut containing products be introduced to all infants by 6 months of age.<span><sup>16</sup></span></p><p>Tregs are not the only T cell subset responsive to dietary antigens. Berin and colleagues review a spectrum of aberrant immune responses to food including Th2 driven IgE-mediated food allergy, the less common non-IgE, Th2 mediated inflammation seen in eosinophilic esophagitis (EoE) and the as yet poorly understood inflammation characteristic of food protein induced enterocolitis (FPIES).<span><sup>17</sup></span> Only two types of stimuli elicit an IgE response-helminthic parasites and allergens. Given its deleterious effects for the host in allergic disease, Rahman and Wesemann explore the fascinating question of why IgE emerged in mammals at all.<span><sup>18</sup></span> They discuss potential evolutionary origins in protection against toxins and parasites and newer information on dietary quality control. They examine the mechanisms regulating the development of IgE secreting plasma cells, affinity and memory of the IgE response and the implications of these features for effective immunotherapy. IgE is not the only food specific Ig isotype. IgA is produced in large quantities in the gut and usually associated with responses to toxins, pathogens or commensal bacteria. Siniscalco et al. investigate the induction of food specific IgA, a largely unappreciated aspect of the immune response to food.<span><sup>19</sup></span> They report that T cell requirements for food specific IgA differ from those of IgE. It is not yet clear whether the induction of food specific IgA represents a counter-regulatory response to the induction of IgE; data thus far do not correlate food specific IgA with antigen specific non-responsiveness.</p><p>The role of neuroimmune regulation in both homeostasis and disease is an area of intense and growing interest in the broader immunology community. Matatia et al. delve into this exciting new field with the hypothesis that dysregulated neuroimmune circuits drive allergic disease.<span><sup>20</sup></span> They review the organization of the central and peripheral nervous systems and how components of each integrate with immune cells at barrier surfaces. They suggest that sensory neurons sense allergens and directly contribute to allergic immunity. A second review reports that histamine released by mast cell degranulation induced by a localized food specific IgE response is sensed by colonic neurons to trigger the abdominal pain associated with irritable bowel syndrome.<span><sup>21</sup></span></p><p>The mother–child dyad plays a critical role in immune homeostasis in early life. The next set of reviews examines this interaction from the perspective of the newborn's response to food. Breast milk is the ideal infant food in its provision of nutrients important for infant growth and protection. Immune cells and proteins in breast milk support the nascent infant immune system.<span><sup>22</sup></span> Oyoshi and colleagues emphasize the protection afforded by the transfer of maternal antibodies.<span><sup>23</sup></span> Data from a neonatal mouse model reveal that detergent containing products can promote sensitization to food in mice with mutations in skin barrier genes which are also exposed to environmental allergens. Maternal supplementation with α-tocopherol (vitamin E) can block this response in genetically susceptible neonates.<span><sup>24</sup></span></p><p>It is clear that gene–environment interactions contribute to the pathogenesis of food allergy. Frischmeyer-Guerrerio et al. explore how immunologic and genetic factors intersect to elicit allergic responses to food, with particular emphasis on the role of TGF-β in driving atopy in both patients with Loeys-Dietz syndrome and a murine model of this disease.<span><sup>25</sup></span> Nocerino et al. review current approaches to disease modification in cow's milk allergy, one of the most common (and earliest onset) pediatric food allergies.<span><sup>26</sup></span> Monogenic disorders can also reveal novel insights into the immunoregulatory pathways that control tolerance to dietary antigens in both food allergy and celiac disease.<span><sup>27</sup></span> Light and Nagler provide evidence in support of the hypothesis that 21st century lifestyle factors have, collectively, resulted in a loss of diversity in the commensal microbiome and the depletion of allergy protective intestinal bacteria. They propose that, in addition to food antigen specific Tregs, a bacteria-induced barrier protective response is required to induce tolerance to food and prevent food allergy. They describe the microbiome and its metabolites and examine novel microbiome-modulating approaches to prevent or treat allergic responses to food.<span><sup>28</sup></span> We close with a synthesis from Chatila and colleagues which describes a central role for host–microbe interactions in early life as a series of mucosal immune checkpoints that regulate the induction of oral tolerance, and its abrogation in food allergy.<span><sup>29</sup></span></p><p>CRN is a co-founder of ClostraBio, Inc.</p>","PeriodicalId":178,"journal":{"name":"Immunological Reviews","volume":"326 1","pages":"5-7"},"PeriodicalIF":7.5000,"publicationDate":"2024-09-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/imr.13397","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Immunological Reviews","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/imr.13397","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"IMMUNOLOGY","Score":null,"Total":0}
引用次数: 0

Abstract

The enormous variety of antigens present in food is not ignored by the immune system. Dietary antigens are recognized as foreign, and tolerance must be induced. The regulation of both mucosal and systemic non-responsiveness to dietary antigens is therefore a basic physiological process which has drawn experimental interest for many years. Indeed, the first report on the induction of non-responsiveness by a fed antigen was published over one hundred years ago.1 Since that time it has become clear that, in keeping with the need to maintain tolerance to dietary antigens, the oral route of antigen administration is uniquely suited to inducing antigen specific non-responsiveness. Experiments in the late 1980s highlighted the practical benefits of oral antigen administration by demonstrating that intragastric delivery of autoantigens, prior to peripheral immunization, protected against the development of autoimmunity in mice.2, 3 This finding was subsequently confirmed in a large variety of animal models of autoimmune, allergic, and inflammatory disease, as well as in models of transplant rejection.4 The generalizability of the observation that oral administration of antigen can protect against the development of antigen-induced systemic disease became the foundation for immunotherapeutic trials of orally administered antigens for several human diseases including rheumatoid arthritis, multiple sclerosis, Type 1 diabetes, autoimmune uveitis and food allergy.5 However, unlike the murine models where the autoantigens were well defined and administered before disease was induced, the clinical trials attempted to modulate established tissue damage in settings in which the autoantigens were both complex and poorly characterized. It was not surprising, then, when these initial trials met with limited success. Both the murine and human studies succeeded, however, in stimulating interest in understanding the mechanisms by which orally administered antigens induce systemic nonresponsiveness to subsequent antigen challenge.

Early work by Weiner and colleagues described high and low dose oral tolerance mediated by deletion or anergy/suppression and a novel subset of TGF-β secreting “Th3” cells.6, 7 The doses designated as high and low were somewhat arbitrarily defined. The identification of transcription factors that specify CD4 T cell differentiation did not reveal a Th3 subset, but did show that the production of TGF-β by innate immune cells is an important fate specifying cytokine for both Th17 cells and peripherally induced Foxp3+ regulatory T cells (Tregs).8 With the discovery of Foxp3+ Tregs, attention switched to the role of food antigen specific Tregs induced in the context of the dietary vitamin A metabolite retinoic acid in gut draining lymph nodes. It was even suggested that oral tolerance was entirely attributable to retinoic acid.9 Subsequent work showed that the presence of both TGF-β and retinoic acid in the mesenteric lymph node was critical to induce Tregs with homing receptors that allowed them to migrate back to the small intestinal lamina propria and expand under the influence of IL-10.10 In recent years, interest in understanding immune responses to food has been propelled by the skyrocketing prevalence of food allergies.11 In this volume we review the current understanding of the mechanisms regulating non-responsiveness to food and explore how that knowledge is informing new therapeutic approaches to prevent or treat food allergies and other pathologic responses to dietary antigens.

Miranda-Waldetario and Curotto de Lafaille begin by reviewing the historical perspective mentioned above and providing up-to-date insights on the different antigen presenting cells/cellular compartments central to the induction of food antigen specific Tregs.12 A specific subset of RORγt+ expressing food antigen specific Fox3+ Tregs, induced primarily in the draining duodenal lymph node, is critical for tolerance to dietary antigens. Both these authors and Cheifetz and Knoop emphasize that a unique developmental window (and mucosal microenvironment) in early life is critical for inducing non-responsiveness to food.13 The animal model data described is in keeping with the current understanding that early life introduction of allergenic foods is essential to the induction of tolerance. When the prevalence of life-threatening peanut allergies started to climb in the U.S., the American Academic of Pediatrics (AAP) issued guidance which advised pregnant women and breast-feeding mothers to avoid peanut consumption and to withhold peanuts from their children until the age of 3.14 This turned out to be exactly the wrong advice. In the landmark Learning About Early Prevention (LEAP) study, Lack and colleagues noted that peanut allergy was much more common in children living in the U.K. than children from the same ethnic background living in Israel. They observed that children in Israel (but not the U.K.) were fed a peanut containing snack in early life. A randomized clinical trial clearly demonstrated that early introduction of peanuts reduced the risk of subsequent peanut allergy.15 The AAP guidelines were reversed in 2019 to recommend that peanut containing products be introduced to all infants by 6 months of age.16

Tregs are not the only T cell subset responsive to dietary antigens. Berin and colleagues review a spectrum of aberrant immune responses to food including Th2 driven IgE-mediated food allergy, the less common non-IgE, Th2 mediated inflammation seen in eosinophilic esophagitis (EoE) and the as yet poorly understood inflammation characteristic of food protein induced enterocolitis (FPIES).17 Only two types of stimuli elicit an IgE response-helminthic parasites and allergens. Given its deleterious effects for the host in allergic disease, Rahman and Wesemann explore the fascinating question of why IgE emerged in mammals at all.18 They discuss potential evolutionary origins in protection against toxins and parasites and newer information on dietary quality control. They examine the mechanisms regulating the development of IgE secreting plasma cells, affinity and memory of the IgE response and the implications of these features for effective immunotherapy. IgE is not the only food specific Ig isotype. IgA is produced in large quantities in the gut and usually associated with responses to toxins, pathogens or commensal bacteria. Siniscalco et al. investigate the induction of food specific IgA, a largely unappreciated aspect of the immune response to food.19 They report that T cell requirements for food specific IgA differ from those of IgE. It is not yet clear whether the induction of food specific IgA represents a counter-regulatory response to the induction of IgE; data thus far do not correlate food specific IgA with antigen specific non-responsiveness.

The role of neuroimmune regulation in both homeostasis and disease is an area of intense and growing interest in the broader immunology community. Matatia et al. delve into this exciting new field with the hypothesis that dysregulated neuroimmune circuits drive allergic disease.20 They review the organization of the central and peripheral nervous systems and how components of each integrate with immune cells at barrier surfaces. They suggest that sensory neurons sense allergens and directly contribute to allergic immunity. A second review reports that histamine released by mast cell degranulation induced by a localized food specific IgE response is sensed by colonic neurons to trigger the abdominal pain associated with irritable bowel syndrome.21

The mother–child dyad plays a critical role in immune homeostasis in early life. The next set of reviews examines this interaction from the perspective of the newborn's response to food. Breast milk is the ideal infant food in its provision of nutrients important for infant growth and protection. Immune cells and proteins in breast milk support the nascent infant immune system.22 Oyoshi and colleagues emphasize the protection afforded by the transfer of maternal antibodies.23 Data from a neonatal mouse model reveal that detergent containing products can promote sensitization to food in mice with mutations in skin barrier genes which are also exposed to environmental allergens. Maternal supplementation with α-tocopherol (vitamin E) can block this response in genetically susceptible neonates.24

It is clear that gene–environment interactions contribute to the pathogenesis of food allergy. Frischmeyer-Guerrerio et al. explore how immunologic and genetic factors intersect to elicit allergic responses to food, with particular emphasis on the role of TGF-β in driving atopy in both patients with Loeys-Dietz syndrome and a murine model of this disease.25 Nocerino et al. review current approaches to disease modification in cow's milk allergy, one of the most common (and earliest onset) pediatric food allergies.26 Monogenic disorders can also reveal novel insights into the immunoregulatory pathways that control tolerance to dietary antigens in both food allergy and celiac disease.27 Light and Nagler provide evidence in support of the hypothesis that 21st century lifestyle factors have, collectively, resulted in a loss of diversity in the commensal microbiome and the depletion of allergy protective intestinal bacteria. They propose that, in addition to food antigen specific Tregs, a bacteria-induced barrier protective response is required to induce tolerance to food and prevent food allergy. They describe the microbiome and its metabolites and examine novel microbiome-modulating approaches to prevent or treat allergic responses to food.28 We close with a synthesis from Chatila and colleagues which describes a central role for host–microbe interactions in early life as a series of mucosal immune checkpoints that regulate the induction of oral tolerance, and its abrogation in food allergy.29

CRN is a co-founder of ClostraBio, Inc.

对食物的免疫反应
免疫系统不会忽视食物中种类繁多的抗原。食物中的抗原被认为是外来的,必须诱导产生耐受性。因此,调节粘膜和全身对食物抗原的非反应性是一个基本的生理过程,多年来一直吸引着人们的实验兴趣。事实上,关于喂食抗原诱导非反应性的第一份报告发表于一百多年前。1 从那时起,人们就清楚地认识到,根据维持对饮食抗原耐受性的需要,口服抗原给药途径非常适合诱导抗原特异性非反应性。20 世纪 80 年代末的实验证明,在进行外周免疫之前,胃内给药自身抗原可防止小鼠自身免疫的发展,从而突出了口服抗原给药的实际益处。口服抗原可预防抗原诱发的全身性疾病,这一观察结果的普遍性为口服抗原治疗多种人类疾病(包括类风湿性关节炎、多发性硬化症、1 型糖尿病、自身免疫性葡萄膜炎和食物过敏)的免疫治疗试验奠定了基础5。然而,与自身抗原定义明确并在疾病诱发前给药的小鼠模型不同,临床试验试图在自身抗原既复杂又特征不明确的情况下调节已确定的组织损伤。因此,这些初步试验取得有限的成功也就不足为奇了。然而,小鼠研究和人体研究都成功地激发了人们对了解口服抗原诱导全身对后续抗原挑战无反应性的机制的兴趣。韦纳及其同事的早期研究描述了由缺失或过敏/抑制以及分泌 TGF-β 的新型 "Th3 "细胞亚群介导的高剂量和低剂量口服耐受。对指定 CD4 T 细胞分化的转录因子的鉴定并未发现 Th3 亚群,但确实表明先天性免疫细胞产生的 TGF-β 是 Th17 细胞和外周诱导的 Foxp3+ 调节性 T 细胞(Tregs)的重要命运指定细胞因子。9 随后的研究表明,肠系膜淋巴结中同时存在 TGF-β 和维甲酸对诱导具有归巢受体的 Tregs 至关重要,这种受体可使 Tregs 迁移回小肠固有层并在 IL-10 的影响下扩增10。Miranda-Waldetario 和 Curotto de Lafaille 首先回顾了上述历史观点,并就诱导食物抗原特异性 Tregs 的核心--不同的抗原呈递细胞/细胞区提供了最新见解12。RORγt+ 表达食物抗原特异性 Fox3+ Tregs 的特定亚群主要在十二指肠引流淋巴结中诱导,对饮食抗原的耐受性至关重要。这些作者以及 Cheifetz 和 Knoop 都强调,生命早期独特的发育窗口(和粘膜微环境)对于诱导对食物的无应答性至关重要13。当危及生命的花生过敏症在美国的发病率开始攀升时,美国儿科学会(AAP)发布了指南,建议孕妇和母乳喂养的母亲避免食用花生,并在孩子 3 岁前不要给他们吃花生。在具有里程碑意义的 "学习早期预防"(LEAP)研究中,莱克及其同事注意到,在英国生活的儿童中,花生过敏比在以色列生活的具有相同种族背景的儿童要常见得多。他们观察到,以色列儿童(而非英国儿童)对花生过敏的发生率比英国儿童高得多。
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来源期刊
Immunological Reviews
Immunological Reviews 医学-免疫学
CiteScore
16.20
自引率
1.10%
发文量
118
审稿时长
4-8 weeks
期刊介绍: Immunological Reviews is a specialized journal that focuses on various aspects of immunological research. It encompasses a wide range of topics, such as clinical immunology, experimental immunology, and investigations related to allergy and the immune system. The journal follows a unique approach where each volume is dedicated solely to a specific area of immunological research. However, collectively, these volumes aim to offer an extensive and up-to-date overview of the latest advancements in basic immunology and their practical implications in clinical settings.
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