JP2011173800A - Peptide composition inducing oral immunological tolerance and method for preparing the same - Google Patents
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Abstract
Description
本発明は、経口免疫寛容を効果的に誘導するペプチド組成物およびその調製方法に関する。より詳細には、特定の分子量以下のペプチドを有し、牛乳アレルギーの治療・予防に有用な経口免疫寛容を誘導するペプチド組成物およびその調製方法に関する。 The present invention relates to a peptide composition that effectively induces oral immune tolerance and a method for preparing the same. More specifically, the present invention relates to a peptide composition having a peptide having a specific molecular weight or less, which induces oral immune tolerance useful for the treatment and prevention of milk allergy, and a method for preparing the same.
一般に生体は異種(非自己)抗原に対しては免疫反応を示すが、自己を構成する抗原に対しては免疫反応を示さない。しかし、本来は異種抗原であっても免疫反応を示さない場合があり、この現象は免疫寛容と呼ばれている。また、経口摂取して腸管を経由して体内に吸収された抗原に関しては、免疫反応における応答性が著しく低下することから、この現象は特に、経口免疫寛容と呼ばれている。 In general, a living body shows an immune response against a heterologous (non-self) antigen, but does not show an immune response against an antigen constituting the self. However, even a heterologous antigen may not show an immune response, and this phenomenon is called immune tolerance. In addition, with respect to an antigen that is orally ingested and absorbed into the body via the intestinal tract, this phenomenon is particularly called oral tolerance because the responsiveness in the immune reaction is significantly reduced.
この経口免疫寛容の作用機序として、現在、クローナルアナジー・クローナルデリーション・アクティブサプレッションという3つの制御機構が働いているとされている。クローナルアナジーとは、免疫細胞が抗原に対して不応答化することを指し、アナジー状態になるリンパ球がCD4+T細胞であることが確認されている(非特許文献1参照)。また、クローナルデリーションとは、抗原に反応するT細胞がアポトーシスを起こして消失する現象を指し、アクティブサプレッションにおいては、抗炎症性サイトカインであるIL−10を産生する調節性T細胞が大きな役割を果たしていることが知られている(非特許文献2参照)。従って、経口免疫寛容の作用機序にはT細胞が大きく関わっているとされている。さらに、近年においてはアレルギー疾患の発症には、ヘルパーT細胞のサブクラスと制御性T細胞とのバランスが重要であるとも言われている(非特許文献3参照)。 As the mechanism of action of oral tolerance, it is said that three control mechanisms, clonal anergy, clonal deletion, and active suppression, are currently working. Clonal anergy means that immune cells become unresponsive to an antigen, and it has been confirmed that lymphocytes that enter an anergy state are CD4 + T cells (see Non-Patent Document 1). In addition, clonal deletion refers to a phenomenon in which T cells that respond to an antigen undergo apoptosis and disappear. In active suppression, regulatory T cells that produce IL-10, an anti-inflammatory cytokine, play a major role. It is known that this is achieved (see Non-Patent Document 2). Therefore, T cells are considered to be greatly involved in the mechanism of oral immune tolerance. Furthermore, in recent years, it has also been said that the balance between helper T cell subclasses and regulatory T cells is important for the development of allergic diseases (see Non-Patent Document 3).
健常者においては、このようなT細胞を中心とした反応制御機構により経口免疫寛容が成立しているため、牛乳を摂取しても生体に不利益な免疫反応は惹起されない。しかし、牛乳アレルギー患者においてはT細胞による抗原に対する経口免疫寛容が成立しておらず、摂取した牛乳にアレルギーの引き金となるB細胞反応性が残存している場合には、様々なアレルギー症状が惹起され、アナフィラキシーショック等の重篤な症状を引き起こし死に至る場合もある。
そこで、牛乳アレルギー患者に対し、経口免疫寛容を誘導することによって牛乳アレルギーを予防・治療しようとする試みがなされており、牛乳たんぱく質加水分解物を利用したものが開示されてきた(特許文献1および2参照)。
In healthy individuals, oral immune tolerance is established by such a reaction control mechanism centered on T cells, so that even if milk is ingested, an immune reaction unfavorable to the living body is not induced. However, in patients with milk allergy, oral tolerance to antigens by T cells has not been established, and if all the ingested milk still has B cell reactivity that triggers allergies, various allergic symptoms may occur. And cause serious symptoms such as anaphylactic shock and may result in death.
Thus, attempts have been made to prevent or treat milk allergy by inducing oral immune tolerance in milk allergy patients, and those utilizing milk protein hydrolysates have been disclosed (Patent Document 1 and 2).
しかし、牛乳たんぱく質加水分解物を利用する場合においても、経口免疫寛容を誘導するにはいくつかの問題点がある。牛乳たんぱく質加水分解物はアレルギー症状の惹起を避けるために、B細胞反応性が消失していること、または低減されていることが重要となる。牛乳たんぱく質加水分解物は、アレルゲンとなる牛乳中に含まれるβ−ラクトグロブリン(以下β−LGとする)やカゼイン等の牛乳たんぱく質を酵素によって分解し、低分子のペプチドとしたものであるが、酵素反応の条件によって、B細胞反応性の消失に加えて、さらに免疫寛容を誘導するために重要なT細胞反応性も消失してしまうことが多いという問題があった。 However, even when using a milk protein hydrolyzate, there are several problems in inducing oral tolerance. It is important that the milk protein hydrolyzate has lost or reduced B cell reactivity in order to avoid causing allergic symptoms. The milk protein hydrolyzate is a low molecular weight peptide obtained by enzymatically degrading milk proteins such as β-lactoglobulin (hereinafter referred to as β-LG) and casein contained in milk as an allergen, Depending on the conditions of the enzyme reaction, in addition to the loss of B cell reactivity, there is also a problem that T cell reactivity, which is important for inducing immune tolerance, often disappears.
そこで、B細胞反応性を消失または低減しつつ、T細胞反応性を維持したペプチドを得るために、pHや温度、時間などの分解酵素における適度な反応条件の検討が望まれている。特に、食品添加物用の酵素は試験研究に供する目的において使用される酵素試薬とは異なり、高度に精製されておらず、様々な活性を持った複数の酵素による混合物であることが多い。したがって、pHや温度などの緒条件によって各酵素の活性および酵素同士の相互作用が異なり、生じる分解物も多岐に渡るという問題がある。
特許文献1に示された牛乳たんぱく質加水分解物については、このような分解酵素の反応条件についての検討が全くなされておらず、特定の酵素反応条件で実験されていないため、効率的に経口免疫寛容を誘導するようなペプチドが得られているとは考えられない。
Therefore, in order to obtain a peptide that maintains T cell reactivity while eliminating or reducing B cell reactivity, examination of appropriate reaction conditions for degrading enzymes such as pH, temperature, and time is desired. In particular, enzymes for food additives, unlike enzyme reagents used for the purpose of conducting research, are not highly purified and are often a mixture of a plurality of enzymes having various activities. Therefore, there is a problem in that the activity of each enzyme and the interaction between enzymes differ depending on the conditions such as pH and temperature, and the resulting degradation products are diverse.
The milk protein hydrolyzate disclosed in Patent Document 1 has not been studied at all for the reaction conditions of such a degrading enzyme and has not been tested under specific enzyme reaction conditions. It is unlikely that a peptide that induces tolerance has been obtained.
また、特許文献1および2には、経口免疫寛容を誘導したとする報告がされているが、マウスを用いた実験による結果である。一般に、経口免疫寛容の誘導されやすさに関しては動物の種類によって差があると言われており、特にマウスやラット等のげっ歯類は誘導されやすいとされている。特に、前述の様に経口免疫寛容の成立にはT細胞が非常に重要な役割を果たしているが、T細胞の認識する部位に関してはマウスの系統によってさえ異なることが報告されている(非特許文献4および5参照)。したがって、マウスにおいて経口免疫寛容が誘導されてもヒトで誘導されるとは限らないため、ヒトにおけるT細胞反応性を証明する必要があるといえる。 In addition, Patent Documents 1 and 2 report that induction of oral immune tolerance has been reported, but these are the results of experiments using mice. In general, it is said that there is a difference in the ease of induction of oral immune tolerance depending on the type of animal, and rodents such as mice and rats are particularly likely to be induced. In particular, as described above, T cells play a very important role in the establishment of oral tolerance, but it has been reported that the site recognized by T cells varies depending on the mouse strain (non-patent document). 4 and 5). Therefore, even if oral tolerance is induced in mice, it is not necessarily induced in humans, so it can be said that it is necessary to prove T cell reactivity in humans.
一方、本発明者らはヒトにおけるT細胞反応性を証明したペプチドを開発し、開示しているが(特許文献3参照)、経口免疫寛容の対象となるたんぱく質をβ−LGのみに限定していたため、β−LG以外の牛乳たんぱく質に対してアレルギーを持つアレルギー患者においては利用できないという問題があった。
近年、β−LGとともにカゼインも牛乳の主要なアレルゲンであるという報告(非特許文献6参照)がなされており、通常市販されている乳製品のほとんどにカゼインが含まれている。したがって、β−LGのみに対して免疫寛容を誘導したとしても、カゼインに対する経口免疫寛容が誘導されていなければ、結局牛乳アレルギー患者は乳製品を摂取できないことになる。
また、カゼインの加水分解物を用いた抗アレルギー材が特許文献4に開示されているが、単純に抗原の体内への移行を防ぐだけであり、経口免疫寛容を誘導するような効果は認められておらず、カゼインに対して経口免疫寛容を誘導できる牛乳たんぱく質加水分解物は得られていない。
そこで従来法では解決できなかった、B細胞反応性を限りなく低減させ、一方でT細胞反応性を有し、ヒトにおいて牛乳由来のたんぱく質であるカゼインに対して経口免疫寛容を誘導できるペプチドの開発が望まれていた。
On the other hand, although the present inventors developed and disclosed the peptide which proved the T cell reactivity in a human (refer patent document 3), the protein used as the object of oral tolerance is limited only to (beta) -LG. Therefore, there is a problem that it cannot be used in allergic patients who are allergic to milk proteins other than β-LG.
In recent years, it has been reported that casein as well as β-LG is a major allergen of milk (see Non-Patent Document 6), and casein is contained in most of the dairy products that are usually marketed. Therefore, even if immune tolerance is induced only to β-LG, if allergic tolerance to casein is not induced, a milk allergy patient will eventually be unable to take dairy products.
Further, although an antiallergic material using a casein hydrolyzate is disclosed in Patent Document 4, it merely prevents the transfer of an antigen into the body, and an effect of inducing oral tolerance is recognized. No milk protein hydrolyzate has been obtained that can induce oral tolerance to casein.
Therefore, the development of a peptide that can reduce B cell reactivity as much as possible but that has T cell reactivity and can induce oral tolerance to casein, which is a protein derived from milk in humans, which could not be solved by conventional methods. Was desired.
本発明は、IgEを介してアナフィラキシーショック等の重篤な症状を引き起こすB細胞反応性が消失または低減され、かつ少量の抗原で長期に免疫寛容を誘導できるT細胞反応性を有する、ヒトにおいて牛乳アレルギー、特に牛乳由来のたんぱく質であるカゼインに対するアレルギーの治療・予防に供することのできるペプチド組成物およびその調製方法を確立し、提供することを課題とする。 The present invention relates to milk in humans that has T cell reactivity that is capable of inducing immune tolerance for a long time with a small amount of antigen, and B cell reactivity that causes severe symptoms such as anaphylactic shock via IgE is lost or reduced. It is an object of the present invention to establish and provide a peptide composition that can be used for the treatment and prevention of allergies, particularly allergies to casein, which is a protein derived from milk.
上記課題を解決するために、牛乳由来のたんぱく質であるカゼインを、たんぱく質加水分解酵素による分解処理ならびに限外ろ過膜による分画処理する方法を鋭意検討した。その結果、本発明者らは酵素活性が最も高い条件、いわゆる至適条件下で酵素反応を行うと分解が進みすぎて、T細胞反応性が減弱してしまうことを確認した。そこで、敢えて至適条件を外した条件下で適切な分解反応を調節したところ、B細胞反応性が消失または低減され、かつ免疫寛容を誘導するために重要なT細胞反応性を有するペプチドが得られることを見出し、本発明を完成するに至った。 In order to solve the above-mentioned problems, the present inventors have intensively studied a method for decomposing a casein, which is a protein derived from milk, with a protein hydrolase and a fractionation with an ultrafiltration membrane. As a result, the present inventors have confirmed that when the enzyme reaction is carried out under the condition with the highest enzyme activity, so-called optimum conditions, the decomposition proceeds too much and the T cell reactivity is attenuated. Thus, when an appropriate degradation reaction was adjusted under conditions other than the optimal conditions, a peptide having T cell reactivity important for inducing immune tolerance was obtained by eliminating or reducing B cell reactivity. As a result, the present invention has been completed.
すなわち、本発明は次の(1)〜(11)のペプチド組成物またはその調製方法等に関する。
(1)牛乳由来のたんぱく質であるカゼインをBacillus licheniformis由来のアルカリ性エンド型たんぱく質分解酵素でpH9.5〜10.5、温度50〜60℃、反応温度2〜4時間分解する経口免疫寛容誘導能を有するペプチド組成物。
(2)たんぱく質分解酵素の分解条件が、pH10、温度55℃、反応時間4時間であることを特徴とする上記(1)に記載の経口免疫寛容誘導能を有するペプチド組成物。
(3)牛乳由来のたんぱく質であるカゼインをAspergillus melleus由来のアルカリ性エンド型たんぱく質分解酵素でpH7.5〜8.5、温度25〜35℃、反応時間2〜4時間分解した経口免疫寛容誘導能を有するペプチド組成物。
(4)たんぱく質分解酵素の分解条件が、pH8.0、温度30℃、反応時間4時間であることを特徴とする上記(3)に記載の経口免疫寛容誘導能を有するペプチド組成物。
(5)上記(2)または(4)に記載のペプチド組成物を分子量10,000の限外ろ過膜で処理し、その透過物として得られることを特徴とする経口免疫寛容誘導能を有するペプチド組成物。
(6)上記(1)〜(5)のいずれか1項に記載されたペプチド組成物を有効成分として含む経口免疫寛容誘導剤。
(7)牛乳由来のたんぱく質であるカゼインをBacillus licheniformis由来のアルカリ性エンド型たんぱく質分解酵素でpH9.5〜10.5、温度50〜60℃、反応温度2〜4時間分解する経口免疫寛容誘導能を有するペプチド組成物の調製方法。
(8)たんぱく質分解酵素の分解条件が、pH10、温度55℃、反応時間4時間であることを特徴とする上記(7)に記載の経口免疫寛容誘導能を有するペプチド組成物の調製方法。
(9)牛乳由来のたんぱく質であるカゼインをAspergillus melleus由来のアルカリ性エンド型たんぱく質分解酵素でpH7.5〜8.5、温度25〜35℃、反応時間2〜4時間分解した経口免疫寛容誘導能を有するペプチド組成物の調製方法。
(10)たんぱく質分解酵素の分解条件が、pH8.0、温度30℃、反応時間4時間であることを特徴とする上記(9)に記載の経口免疫寛容誘導能を有するペプチド組成物の調製方法。
(11)上記(7)または(9)に記載のペプチド組成物の調製方法であって、さらにペプチド組成物を分子量10,000の限外ろ過膜で処理し、その透過物として得られることを特徴とする経口免疫寛容誘導能を有するペプチド組成物の調製方法。
That is, the present invention relates to the following peptide compositions (1) to (11) or a preparation method thereof.
(1) Casein, which is a protein derived from milk, has the ability to induce oral tolerance by degrading with alkaline endoproteinase derived from Bacillus licheniformis at a pH of 9.5 to 10.5, a temperature of 50 to 60 ° C., and a reaction temperature of 2 to 4 hours. A peptide composition comprising:
(2) The peptide composition having the ability to induce oral tolerance according to (1) above, wherein the degradation conditions of the proteolytic enzyme are pH 10, temperature 55 ° C., reaction time 4 hours.
(3) The ability to induce oral tolerance by degrading casein, which is a protein derived from milk, with alkaline endo-protease derived from Aspergillus melleus at pH 7.5-8.5, temperature 25-35 ° C., reaction time 2-4 hours A peptide composition comprising:
(4) The peptide composition having the ability to induce oral tolerance according to (3) above, wherein the degradation conditions of the proteolytic enzyme are pH 8.0, temperature 30 ° C., and reaction time 4 hours.
(5) A peptide having the ability to induce oral tolerance characterized by being obtained as a permeate by treating the peptide composition according to (2) or (4) above with an ultrafiltration membrane having a molecular weight of 10,000 Composition.
(6) An oral tolerance inducer comprising the peptide composition according to any one of (1) to (5) as an active ingredient.
(7) The ability to induce oral tolerance by degrading casein, which is a protein derived from milk, with an alkaline endoproteinase derived from Bacillus licheniformis at a pH of 9.5 to 10.5, a temperature of 50 to 60 ° C., and a reaction temperature of 2 to 4 hours. A method for preparing a peptide composition.
(8) The method for preparing a peptide composition having the ability to induce oral tolerance according to (7) above, wherein the degradation conditions of the proteolytic enzyme are pH 10, temperature 55 ° C. and reaction time 4 hours.
(9) Casein, which is a protein derived from milk, has an ability to induce oral tolerance by degrading with alkaline endo-protease derived from Aspergillus melleus at pH 7.5-8.5, temperature 25-35 ° C., reaction time 2-4 hours. A method for preparing a peptide composition.
(10) The method for preparing a peptide composition having the ability to induce oral tolerance according to (9) above, wherein the degradation conditions of the proteolytic enzyme are pH 8.0, temperature 30 ° C., and reaction time 4 hours. .
(11) A method for preparing a peptide composition as described in (7) or (9) above, wherein the peptide composition is further treated with an ultrafiltration membrane having a molecular weight of 10,000 and obtained as a permeate. A method for preparing a peptide composition having the ability to induce oral tolerance.
乳幼児に多く認められる食物アレルギーの原因のひとつとして、食品たんぱく質の一部が消化酵素の分解を受けずに腸管から吸収され、生体免疫系を刺激してアレルギーを発症させることが指摘されている。この点に関して、本発明のペプチド組成物はその平均分子量が低いため、もとの未分解の乳たんぱく質の有する抗原性が非常に低減されており、牛乳アレルギー患者の治療に用いることができる。また、本ペプチド組成物は経口免疫寛容誘導能に関しては非常に高いため、生体の有する潜在的なアレルギー防御機構を十分に活性化できる。
したがって、本発明のペプチド組成物は新しいアレルギー低減化および予防と治療を目的とした食品素材あるいは経口免疫寛容誘導材として有用である。
It has been pointed out that one of the causes of food allergies commonly observed in infants is that a part of food proteins is absorbed from the intestinal tract without being digested by digestive enzymes and stimulates the immune system to cause allergies. In this regard, since the peptide composition of the present invention has a low average molecular weight, the antigenicity of the original undegraded milk protein is greatly reduced and can be used for the treatment of patients with milk allergies. Moreover, since this peptide composition is very high regarding oral immune tolerance induction ability, it can fully activate the potential allergic defense mechanism of the living body.
Therefore, the peptide composition of the present invention is useful as a food material or an oral tolerance tolerance inducer for the purpose of new allergy reduction, prevention and treatment.
本発明の「経口免疫寛容誘導能を有するペプチド組成物」とは、カゼインをたんぱく質分解酵素で酵素分解することによって得られる、B細胞反応性が消失または低減されており、かつT細胞反応性を有するペプチドを含む組成物のことをいう。
本発明のペプチド組成物を得るために用いるカゼインは、牛乳由来のカゼインであればいずれのものも用いることができるが、特にカゼインを高含有する酸カゼインまたはカゼインナトリウム、およびそれらに準ずるより純度の高いものを用いることが望ましい。
The “peptide composition having the ability to induce oral tolerance” according to the present invention means that B cell reactivity obtained by enzymatic degradation of casein with a proteolytic enzyme is lost or reduced, and T cell reactivity is increased. It refers to a composition containing a peptide having it.
The casein used for obtaining the peptide composition of the present invention may be any casein derived from milk, but particularly acid casein or sodium casein containing a high amount of casein, and a purer equivalent thereto. It is desirable to use a high one.
本発明の「経口免疫寛容誘導能を有するペプチド組成物」は、上述したカゼインをたんぱく質加水分解酵素で処理し、低分子ペプチド化することで調製することができる。
たんぱく質加水分解酵素は、ペプチド結合を加水分解する酵素であればいずれのものも用いることができるが、本発明に用いる酵素は微生物由来のアルカリ性エンド型たんぱく質分解酵素、特に微生物のBacillus licheniformisまたはAspergillus melleus由来のアルカリ性エンド型たんぱく質分解酵素が好ましい。これらの酵素は市販のものや独自に調製したいずれの酵素も用いることができるが、例えば、Bacillus licheniformis由来のアルカリ性エンド型たんぱく質分解酵素として、アルカラーゼ(ノボ社)やAspergillus melleus由来のアルカリ性エンド型たんぱく質分解酵素として、プロテアーゼP3SD(天野エンザイム社)等を用いることができる。
The “peptide composition having the ability to induce oral tolerance” of the present invention can be prepared by treating the casein described above with a protein hydrolase to form a low molecular peptide.
Any protein hydrolase can be used as long as it is an enzyme that hydrolyzes a peptide bond. However, the enzyme used in the present invention is an alkaline endoprotease derived from microorganisms, particularly Bacillus licheniformis or Aspergillus melleus of microorganisms. The derived alkaline endoproteolytic enzyme is preferred. These enzymes can be either commercially available or any of the enzymes originally prepared. For example, alkaline endoproteins derived from Bacillus licheniformis include alkaline endoproteins derived from Alcalase (Novo) or Aspergillus melleus. As a degrading enzyme, protease P3SD (Amano Enzyme) or the like can be used.
本発明の「経口免疫寛容誘導能を有するペプチド組成物の調製方法」として、カゼインをたんぱく質加水分解酵素で処理し、低分子ペプチド化するには、牛乳由来のたんぱく質を基質としてこれにたんぱく質加水分解酵素を加えて、所定のpH、温度で必要時間加水分解することが挙げられる。
例えば、カゼインをBacillus licheniformis由来のアルカリ性エンド型たんぱく質分解酵素でpH9.5〜10.5、温度50〜60℃、反応温度2〜4時間分解することで、B細胞反応性が消失または低減されており、かつT細胞反応性を有するペプチド組成物を得ることができる。この調製においては、さらに、たんぱく質分解酵素の分解条件が、基質濃度5%、pH10.0、温度55℃、4時間であることが望ましく、より抗原性の高い高分子物質を除去するために分子量が10,000の限外ろ過膜を用いて精製する事が特に望ましい。
または、カゼインをAspergillus melleus由来のアルカリ性エンド型たんぱく質分解酵素でpH7.5〜8.5、温度25〜35℃、反応時間2〜4時間分解することで、B細胞反応性が消失または低減されており、かつT細胞反応性を有するペプチド組成物を得ることができる。
この調製においては、さらに、たんぱく質分解酵素の分解条件が、基質濃度5%、pH8.0、温度30℃、4時間であることが望ましく、より抗原性の高い高分子物質を除去するために分子量が10,000の限外ろ過膜を用いて精製する事が特に望ましい。
As a method for preparing a peptide composition having the ability to induce oral tolerance according to the present invention, casein is treated with a protein hydrolase and converted into a low molecular weight peptide by using a protein derived from milk as a substrate and subjecting it to protein hydrolysis. An enzyme may be added and hydrolyzed at a predetermined pH and temperature for a required time.
For example, by degrading casein with an alkaline endoproteolytic enzyme derived from Bacillus licheniformis at pH 9.5 to 10.5, temperature 50 to 60 ° C., reaction temperature 2 to 4 hours, B cell reactivity is lost or reduced. And a peptide composition having T cell reactivity can be obtained. In this preparation, it is desirable that the degradation conditions of the proteolytic enzyme are a substrate concentration of 5%, pH of 10.0, temperature of 55 ° C., 4 hours, and molecular weight in order to remove higher antigenic macromolecular substances. It is particularly desirable to purify using a 10,000 ultrafiltration membrane.
Alternatively, by degrading casein with an alkaline endoprotease derived from Aspergillus melleus at pH 7.5 to 8.5, temperature 25 to 35 ° C., reaction time 2 to 4 hours, B cell reactivity is lost or reduced. And a peptide composition having T cell reactivity can be obtained.
In this preparation, it is preferable that the degradation conditions of the proteolytic enzyme are a substrate concentration of 5%, pH 8.0, temperature of 30 ° C., 4 hours, and molecular weight in order to remove higher antigenic macromolecular substances. It is particularly desirable to purify using a 10,000 ultrafiltration membrane.
本発明で得られる「経口免疫寛容誘導能を有するペプチド組成物」は、B細胞反応性が消失または低減されており、かつT細胞反応性を有することが、牛乳アレルギー患者T細胞において基質であるカゼインと同程度の反応性を示していること、および牛乳アレルギー患者血清を用いたIgE−ウェスタンブロット法により、IgE反応性の消失が示されていることから確認されている。 The “peptide composition having the ability to induce oral tolerance” obtained by the present invention is a substrate in milk allergy T cells that have lost or reduced B cell reactivity and have T cell reactivity. It has been confirmed from the fact that it shows the same level of reactivity as casein and the disappearance of IgE reactivity by IgE-Western blotting using serum from milk allergy patients.
従って、本発明によって得られる「経口免疫寛容誘導能を有するペプチド組成物」は、B細胞反応性が低減しているため抗原性が低く、かつ免疫寛容誘導能は未分解の牛乳由来たんぱく質と同等に優れており、さらにペプチド態であるために耐熱性等の加工特性に優れているため、新規のアレルギー予防・治療食品素材として、単独または清涼飲料水、ミネラルウォーター、茶などの各種飲料、クッキー、ビスケット、煎餅等の菓子類、または育児用調製粉乳、パン、ゼリー、口腔清涼菓子などの食品とともに自由に使用することができる。
また、「経口免疫寛容誘導剤」の有効成分として使用することができる。本発明の「経口免疫寛容誘導剤」は、本発明によって得られる「経口免疫寛容誘導能を有するペプチド組成物」を有効成分として含む「経口免疫寛容誘導剤」であればいずれのものも含まれる。例えば、「経口免疫寛容誘導能を有するペプチド組成物」をそのまままたはその他の成分と組み合わせたものを、錠剤、顆粒剤、カプセル剤、粉剤、溶液剤など所望する剤型に製剤化した「経口免疫寛容誘導剤」などが挙げられる。これは経口投与用食品として経口免疫寛容誘導および/またはそのための補助的処置として用いることもできる。
本発明によって得られる「経口免疫寛容誘導能を有するペプチド組成物」は本来食品として用いることができるものであるため安全性に問題は無く、その用量も適宜で良い。
以下に実施例および試験例を示し、さらに本発明を詳細に説明する。
Therefore, the “peptide composition having the ability to induce oral tolerance” obtained by the present invention has low antigenicity due to the reduced B cell reactivity, and the ability to induce tolerance is equivalent to that of undegraded milk-derived protein. As a new allergy prevention / treatment food material, it can be used alone or as a beverage for beverages such as soft drinks, mineral water, and tea, and cookies. , Biscuits, rice crackers and other confectionery, or infant formula milk, bread, jelly, oral refreshing confectionery and other foods.
Moreover, it can be used as an active ingredient of an “oral immune tolerance inducer”. The “oral immune tolerance inducer” of the present invention includes any “oral immune tolerance inducer” that contains the “peptide composition having the ability to induce oral tolerance” obtained by the present invention as an active ingredient. . For example, “oral immunity” in which “peptide composition having ability to induce oral tolerance” as it is or in combination with other ingredients is formulated into a desired dosage form such as a tablet, granule, capsule, powder, solution, etc. Tolerance inducers "and the like. It can also be used as a food for oral administration as an induction of oral tolerance and / or as a supplementary treatment therefor.
Since the “peptide composition having the ability to induce oral tolerance” obtained by the present invention can be originally used as a food, there is no problem in safety, and the dosage may be appropriate.
Examples and test examples are shown below, and the present invention is further described in detail.
[試料]
本発明の実施例および比較例においては次の試料を用いた。
1.カゼイン
1)カゼインナトリウム(たんぱく質含量90%、フォンテラ社)
2)酸カゼイン(たんぱく質含量90%、フォンテラ社)
2.酵素
1)アルカラーゼ(Bacillus licheniformis由来、ノボ社、表示活性 2.4AU/g)
2)プロテアーゼP3SD(Aspergillus melleus由来、天野エンザイム社、たん白消化力 30,000u/g以上)
3)プロテアーゼNSD(Bacillus subtilis由来、天野エンザイム社、たん白消化力 150,000u/g以上)
4)プロテアーゼASD(Aspergillus oryzae由来、天野エンザイム社、たん白消化力 10,000u/g以上)
5)フレーバーザイム(Aspergillus oryzae由来、ノボ社、表示活性 1000LAPU/g)
6)ニュートラーゼ(Bacillus amyloliquefaciens由来、ノボ社、表示活性 0.8AU/g)
[sample]
The following samples were used in the examples and comparative examples of the present invention.
1. Casein 1) Sodium caseinate (protein content 90%, Fontera)
2) Acid casein (protein content 90%, Fontera)
2. Enzyme 1) Alcalase (Derived from Bacillus licheniformis, Novo, display activity 2.4 AU / g)
2) Protease P3SD (derived from Aspergillus melleus, Amano Enzyme, protein digestibility 30,000 u / g or more)
3) Protease NSD (from Bacillus subtilis, Amano Enzyme, protein digestion power 150,000 u / g or more)
4) Protease ASD (derived from Aspergillus oryzae, Amano Enzyme, protein digestion power 10,000 u / g or more)
5) Flavorzyme (derived from Aspergillus oryzae, Novo, display activity 1000 LAPU / g)
6) Neutase (from Bacillus amyloliquefaciens, Novo, display activity 0.8 AU / g)
[実施例1]
カゼインナトリウム5gをイオン交換水100mlに50mg/mlの濃度で溶解した。水酸化ナトリウムにてpHを10に調整した後、たんぱく質1g当たりアルカラーゼ10mgを添加し、55℃で4時間反応させた。反応終了後、100℃で10分間加熱し、酵素分解ペプチド組成物を得た。この酵素分解ペプチド組成物をペプチド1含有組成物とした。
[実施例2]
酸カゼイン10kgをイオン交換水100Lに100mg/mlの濃度で溶解した。水酸化ナトリウムにてpHを10に調整した後、たんぱく質1g当たりアルカラーゼ20mgを添加し、55℃で2時間反応させた。反応終了後、120℃で3秒間加熱し、酵素分解ペプチド組成物を得た。この酵素分解ペプチド組成物をペプチド2含有組成物とした。
[実施例3]
カゼインナトリウム25kgをイオン交換水500Lに50mg/mlの濃度で溶解した。水酸化ナトリウムにてpHを10に調整した後、たんぱく質1g当たりアルカラーゼ10mgを添加し、55℃で4時間反応させた。反応終了後、120℃で3秒間加熱し、酵素分解ペプチド組成物を得た。さらに、平均分画分子量10,000の限外ろ過膜にて分画して保持物を得た。この酵素分解ペプチド組成物をペプチド3含有組成物とした。
[実施例4]
カゼインナトリウム5gをイオン交換水100mlに50mg/mlの濃度で溶解した。水酸化ナトリウムにてpHを8.0に調整した後、たんぱく質1g当たりプロテアーゼP3SD10mgを添加し、30℃で4時間反応させた。反応終了後、100℃で10分間煮沸し、酵素分解ペプチド組成物を得た。この酵素分解ペプチド組成物をペプチド4含有組成物とした。
[実施例5]
酸カゼイン5kgをイオン交換水100Lに50mg/mlの濃度で溶解した。水酸化ナトリウムにてpHを8.0に調整した後、たんぱく質1g当たりプロテアーゼP3SD10mgを添加し、30℃で2時間反応させた。反応終了後、120℃で3秒間加熱し、酵素分解ペプチド組成物を得た。この酵素分解ペプチド組成物をペプチド5含有組成物とした。
[実施例6]
酸カゼイン10kgをイオン交換水200Lに50mg/mlの濃度で溶解した。水酸化ナトリウムにてpHを8.0に調整した後、たんぱく質1g当たりプロテアーゼP3SD20mgを添加し、30℃で4時間反応させた。反応終了後、120℃で3秒間加熱し、酵素分解ペプチド組成物を得た。さらに、平均分画分子量10,000の限外ろ過膜にて分画して保持物を得た。この酵素分解ペプチド組成物をペプチド6含有組成物とした。
[Example 1]
5 g of sodium caseinate was dissolved in 100 ml of ion exchange water at a concentration of 50 mg / ml. After adjusting the pH to 10 with sodium hydroxide, 10 mg of alcalase per 1 g of protein was added and reacted at 55 ° C. for 4 hours. After completion of the reaction, the mixture was heated at 100 ° C. for 10 minutes to obtain an enzyme-degraded peptide composition. This enzyme-decomposed peptide composition was defined as a peptide 1-containing composition.
[Example 2]
10 kg of acid casein was dissolved in 100 L of ion-exchanged water at a concentration of 100 mg / ml. After adjusting the pH to 10 with sodium hydroxide, 20 mg of alcalase per gram of protein was added and reacted at 55 ° C. for 2 hours. After completion of the reaction, the mixture was heated at 120 ° C. for 3 seconds to obtain an enzyme-degraded peptide composition. This enzyme-decomposed peptide composition was defined as a peptide-2 containing composition.
[Example 3]
25 kg of sodium caseinate was dissolved in 500 L of ion exchange water at a concentration of 50 mg / ml. After adjusting the pH to 10 with sodium hydroxide, 10 mg of alcalase per 1 g of protein was added and reacted at 55 ° C. for 4 hours. After completion of the reaction, the mixture was heated at 120 ° C. for 3 seconds to obtain an enzyme-degraded peptide composition. Furthermore, fractionation was performed with an ultrafiltration membrane having an average fractional molecular weight of 10,000 to obtain a retentate. This enzyme-decomposed peptide composition was defined as a peptide 3-containing composition.
[Example 4]
5 g of sodium caseinate was dissolved in 100 ml of ion exchange water at a concentration of 50 mg / ml. After adjusting the pH to 8.0 with sodium hydroxide, 10 mg of protease P3SD per 1 g of protein was added and reacted at 30 ° C. for 4 hours. After completion of the reaction, the mixture was boiled at 100 ° C. for 10 minutes to obtain an enzyme-degraded peptide composition. This enzyme-degraded peptide composition was defined as a peptide 4-containing composition.
[Example 5]
5 kg of acid casein was dissolved in 100 L of ion-exchanged water at a concentration of 50 mg / ml. After adjusting the pH to 8.0 with sodium hydroxide, 10 mg of protease P3SD per 1 g of protein was added and reacted at 30 ° C. for 2 hours. After completion of the reaction, the mixture was heated at 120 ° C. for 3 seconds to obtain an enzyme-degraded peptide composition. This enzyme-decomposed peptide composition was defined as a peptide-5-containing composition.
[Example 6]
10 kg of acid casein was dissolved in 200 L of ion-exchanged water at a concentration of 50 mg / ml. After adjusting the pH to 8.0 with sodium hydroxide, 20 mg of protease P3SD per 1 g of protein was added and reacted at 30 ° C. for 4 hours. After completion of the reaction, the mixture was heated at 120 ° C. for 3 seconds to obtain an enzyme-degraded peptide composition. Furthermore, fractionation was performed with an ultrafiltration membrane having an average fractional molecular weight of 10,000 to obtain a retentate. This enzyme-decomposed peptide composition was defined as a peptide 6-containing composition.
[比較例1〜14]
実施例1と同様に、カゼインナトリウム5gをイオン交換水100mlに50mg/mlの濃度で溶解した。水酸化ナトリウムにてそれぞれのpHに調整した後、たんぱく質1g当たりアルカラーゼ10mg、プロテアーゼP3SD10mg、プロテアーゼNSD10mg、プロテアーゼASD10mg、フレーバーザイム10mgまたはニュートラーゼ10mgをそれぞれ添加し、30〜65℃で4時間反応させた。反応終了後、100℃で10分間加熱し、酵素分解ペプチド組成物を得た。これをそれぞれ対照サンプル1含有組成物〜対照サンプル14含有組成物とした。
実施例1〜6および比較例1〜14の各ペプチド含有組成物および対照サンプル含有組成物の調製条件を表1にまとめて示した。
[Comparative Examples 1-14]
In the same manner as in Example 1, 5 g of sodium caseinate was dissolved in 100 ml of ion-exchanged water at a concentration of 50 mg / ml. After adjusting each pH with sodium hydroxide, 10 mg of Alcalase, 10 mg of protease P3SD, 10 mg of protease NSD, 10 mg of protease ASD, 10 mg of flavorzyme or 10 mg of neutraase were added per 1 g of protein and reacted at 30 to 65 ° C. for 4 hours. . After completion of the reaction, the mixture was heated at 100 ° C. for 10 minutes to obtain an enzyme-degraded peptide composition. These were designated as a control sample 1-containing composition to a control sample 14-containing composition.
Table 1 summarizes the preparation conditions of the peptide-containing compositions of Examples 1 to 6 and Comparative Examples 1 to 14 and the control sample-containing composition.
[試験例1]
実施例1で得られたペプチド1含有組成物ならびに比較例1の対照サンプル1含有組成物について、牛乳アレルギー患者より得られた血清を用いてリンパ球刺激試験を行い、免疫寛容誘導効果を調べた。
リンパ球刺激試験は、アレルギー患者血清より分離した末梢血単核球(PBMCs)を用いて評価した。すなわち、PBMCsと対照被験物質を37℃・5%CO2環境下で5日間培養し、培養終了16時間にPBMCsが細胞内に取り込んだ〔3H〕−サイミジン(1ウェル当たり 0.5μCi)量を、液体シンチレーションカウンターを用いて測定した。この細胞内に取り込んだ〔3H〕−サイミジン量からPBMCsの増殖能をStimulation Index(SI)として換算し、T細胞反応性の指標とした。培養は、96穴マイクロプレート(ロシェ社)に1ウェル当たり2×105の細胞および対象被験物質(20μg/ml)を加えて行った。培地にはRPMI1640(三光純薬)を用いた。
その結果、図1に示すようにペプチド1含有組成物は分解反応前の基質カゼインよりやや減弱したもののT細胞反応性を示しており、免疫寛容誘導効果が認められた。一方、対照サンプル1含有組成物は、基質カゼインと比べて著しくT細胞反応性が減弱していた。
[Test Example 1]
The peptide 1-containing composition obtained in Example 1 and the control sample 1-containing composition of Comparative Example 1 were subjected to a lymphocyte stimulation test using serum obtained from a milk allergic patient to examine the tolerance induction effect. .
The lymphocyte stimulation test was evaluated using peripheral blood mononuclear cells (PBMCs) isolated from the serum of allergic patients. That is, PBMCs and a control test substance were cultured for 5 days at 37 ° C. and 5% CO 2 , and the amount of [3H] -thymidine (0.5 μCi per well) taken up by the PBMCs into the cells at the end of the culture 16 hours. Measured using a liquid scintillation counter. From the amount of [3H] -thymidine incorporated into the cells, the proliferation ability of PBMCs was converted as Stimulation Index (SI), and used as an index of T cell reactivity. The culture was performed by adding 2 × 10 5 cells per well and a target test substance (20 μg / ml) to a 96-well microplate (Roche). RPMI1640 (Sanko Junyaku) was used as the medium.
As a result, as shown in FIG. 1, the peptide 1-containing composition was slightly attenuated from the substrate casein before the degradation reaction, but showed T cell reactivity, and an immune tolerance inducing effect was observed. On the other hand, the control sample 1-containing composition was significantly reduced in T cell reactivity as compared with the substrate casein.
[試験例2]
実施例4で得られたペプチド4含有組成物ならびに比較例6の対照サンプル6含有組成物について、牛乳アレルギー患者より得られた血清を用いて試験例1と同様にリンパ球刺激試験を行い、免疫寛容誘導効果を調べた。
その結果、図2に示すようにペプチド4含有組成物は分解反応前の基質カゼインと同様のT細胞反応性を示しており、免疫寛容誘導効果が認められた。一方、対照サンプル6含有組成物は、基質カゼインと比べて著しくT細胞反応性が減弱していた。
比較例2〜5および7〜14の対照サンプル2含有組成物〜対照サンプル5含有組成物および対照サンプル7含有組成物〜対照サンプル14含有組成物においても、対照サンプル1含有組成物や対照サンプル6含有組成物と同様に、著しくT細胞が減弱していることが確認された。
[Test Example 2]
The peptide 4-containing composition obtained in Example 4 and the control sample 6-containing composition of Comparative Example 6 were subjected to a lymphocyte stimulation test in the same manner as in Test Example 1 using serum obtained from a milk allergic patient. The tolerance induction effect was examined.
As a result, as shown in FIG. 2, the peptide 4 containing composition showed the same T cell reactivity as the substrate casein before the degradation reaction, and an immune tolerance inducing effect was observed. On the other hand, the composition containing the control sample 6 had significantly reduced T cell reactivity as compared with the substrate casein.
In Comparative Examples 2 to 5 and 7-14, the control sample 2-containing composition to the control sample 5-containing composition and the control sample 7-containing composition to the control sample 14-containing composition are also used. Similar to the containing composition, it was confirmed that T cells were significantly attenuated.
[試験例3]
実施例1で得られたペプチド1含有組成物ならびに実施例4で得られたペプチド4含有組成物について、アナフィラキシーショックなどの即時型アレルギー症状を引き起こす可能性のあるIgEに対する反応性を、IgE−ウェスタンブロット法にて評価した。
まず、目的のたんぱく質を15〜25%グラジエントゲル(XV PANTERA Gel:DRC社)を用いて電気泳動し、i−blot system(インビトロジェン社)を用いてPVDF膜に転写した。その後、3%牛血清アルブミンを用いてブロッキングを行い、1次抗体および2次抗体でそれぞれ2時間反応させた後に発色させ、検出を行った。IgE−ウェスタンブロットの1次抗体は、アレルギー患者血清とプロテインGを混合した後、15000×g にて遠心分離した上清を10〜100倍希釈したものを用い、2次抗体としてはHRP−標識抗ヒトIgE抗ヤギ抗体を用いた。
その結果、図3に示すように両組成物ともにIgEに対する反応性は全く認められず、分解前反応前のカゼインと比べてB細胞反応性の著しい低減が認められた。
[Test Example 3]
About the peptide 1 containing composition obtained in Example 1, and the peptide 4 containing composition obtained in Example 4, the reactivity with respect to IgE which may cause an immediate allergic symptom, such as an anaphylactic shock, is IgE-Western. Evaluation was made by blotting.
First, the target protein was electrophoresed using a 15-25% gradient gel (XV PANTERA Gel: DRC) and transferred to a PVDF membrane using an i-blot system (Invitrogen). Thereafter, blocking was performed using 3% bovine serum albumin, and the color was developed after reacting for 2 hours with the primary antibody and the secondary antibody, respectively. The primary antibody of the IgE-Western blot was a mixture of serum from allergic patients and protein G, and then the supernatant obtained by centrifugation at 15000 × g was diluted 10 to 100 times. The secondary antibody was HRP-labeled Anti-human IgE anti-goat antibody was used.
As a result, as shown in FIG. 3, no reactivity to IgE was observed in both compositions, and a marked decrease in B cell reactivity was observed compared to casein before the degradation reaction.
本発明のペプチド組成物は平均分子量が低いため、もとの未分解の乳たんぱく質の有する抗原性が非常に低減されており、牛乳アレルギー患者の治療に用いることができる。また、本ペプチド組成物は経口免疫寛容誘導能が非常に高く、生体の有する潜在的なアレルギー防御機構を十分に活性化できる。したがって、本発明のペプチド組成物は新しいアレルギー低減化および予防と治療を目的とした食品素材あるいは経口免疫寛容誘導材として有用である。 Since the peptide composition of the present invention has a low average molecular weight, the antigenicity of the original undegraded milk protein is greatly reduced and can be used for the treatment of milk allergy patients. Further, the present peptide composition has a very high ability to induce oral tolerance, and can sufficiently activate the potential allergy defense mechanism of the living body. Therefore, the peptide composition of the present invention is useful as a food material or an oral tolerance tolerance inducer for the purpose of new allergy reduction, prevention and treatment.
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CN116794296A (en) * | 2023-08-15 | 2023-09-22 | 美维仕(北京)健康管理有限公司 | Method and kit for detecting sensitization of hydrolyzed formula food |
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CN114828864A (en) * | 2019-12-19 | 2022-07-29 | 国立研究开发法人国立成育医疗研究中心 | Agent for preventing allergy to eggs, and food composition containing same |
CN116794296A (en) * | 2023-08-15 | 2023-09-22 | 美维仕(北京)健康管理有限公司 | Method and kit for detecting sensitization of hydrolyzed formula food |
CN116794296B (en) * | 2023-08-15 | 2024-03-08 | 美维仕(北京)健康管理有限公司 | Method and kit for detecting sensitization of hydrolyzed formula food |
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