JPWO2004028561A1 - Immune response induction method - Google Patents

Abstract

The present invention relates to a vaccine antigen and adjuvant combination. Specifically, the vaccine antigen and interferon α as a mucosal adjuvant are administered transmucosally from the same administration route at the same time or with a time difference. Such transmucosal administration can effectively induce both antigen-specific blood antibodies and antigen-specific mucosal secretion antibodies against various vaccine antigens.

Description

The present invention provides a method for effectively inducing both antigen-specific blood antibodies and antigen-specific mucosal secretory antibodies against various vaccine antigens, vaccine composition, mucosal adjuvant, combination of vaccine antigen and mucosal adjuvant, The present invention also relates to a mucosal adjuvant for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen containing interferon α as an active ingredient.
More specifically, the present invention is a method for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen using the vaccine antigen and an adjuvant of the vaccine antigen,
(1) transmucosal administration of vaccine antigen,
(2) using interferon α as an active ingredient of an adjuvant,
(3) a method comprising administering the adjuvant with the vaccine antigen simultaneously or at a time interval; and (4) transmucosal administration of the adjuvant with the vaccine antigen by the same administration route; The present invention relates to vaccine compositions, mucosal adjuvants, combinations of vaccine antigens and mucosal adjuvants, mucosal immune response activation methods using mucosal adjuvants, and the like.

Vaccines are broadly divided into two types: live vaccines that use live infectious pathogens and non-infectious inactivated vaccines that inactivate pathogens and their toxins, and most of them have been used as injections. ing. It is well known that injectable vaccines delivered to the circulatory system induce a systemic immune response.
Although live vaccines can acquire the immune response ability closest to innate immunity, it is difficult to control the pathogenicity of the vaccine strain, and there are concerns about safety to the human body such as reversion of toxicity due to mutation in vivo. Has been. Inactivated vaccines are safer than live vaccines, but generally have low immunogenicity and are not sufficiently effective in inducing secreted antibodies, making them difficult to put into practical use. Therefore, a substance that promotes immunity induction against vaccine antigens, that is, an adjuvant, for example, an adjuvant containing an inorganic salt slightly used for humans such as aluminum hydroxide, aluminum phosphate and calcium phosphate as an active ingredient, IL-2,4 , 12 and various immune adjuvants such as cytokines such as interferon γ have been developed ([Patent Document 1] [Non-Patent Document 1], [Non-Patent Document 2], [Non-Patent Document 3]). However, these induce the systemic immune response by using injections, and do not achieve induction on the mucosal surface.
Many infectious agents enter the living body through mucous membranes that cover the surface of organs that are in direct contact with the outside world, such as nasal mucosa, oral mucosa, lung mucosa, gastrointestinal mucosa, and vaginal mucosa. Therefore, it is considered that the activation of immunity by antigen-specific immune response in the mucous membrane can more effectively prevent invasion of infectious pathogens. From this point of view, research on "mucosal vaccine", which is transmucosally administered to the above mucosa by oral, nasal, pulmonary, transvaginal, etc., as a next-generation vaccine that replaces conventional injection vaccines It has become to. According to the latest approach, “mucosal vaccine” simultaneously induces not only systemic immune response but also mucosal immune response, which induces IgA antibody in the mucosa, for example IgA antibody in stool Although it is not yet known in detail about the mechanism of action, IgA-producing progenitor cells specific for pathogens that have invaded on mucosal tissues are not limited to other parts of the body, depending on blood flow. It has also been known that IgA antibodies are secreted in multiple ways at mucosal sites other than the invading site as well as at the invading site, and enter the bloodstream to produce IgG.
In the transmucosal administration of vaccines, the immunogenicity of the vaccine itself is low, and attempts have been made to use adjuvants administered together with vaccines administered transmucosally, that is, “mucosal adjuvants”.
Possibility as a mucosal adjuvant in cholera toxin, Escherichia coli heat-labile toxin, gram-negative bacterium-derived lipopolysaccharide, etc. has been studied, but there are concerns about safety regardless of transmucosal administration, and it has not been put into practical use.
Furthermore, from the viewpoint of safety, cytokines and the like have been studied, and it has been reported that IL-12 and interferon β have a mucosal adjuvant action ([Patent Document 2] and [Patent Document 3]).
[Patent Document 2] discloses a method for enhancing mucosal immunity by intranasally administering IL-12. In this document, the effective dose of IL-12 is described as 0.5 μg / kg-150 μg / kg. On the other hand, when 1 μg of IL-12 was administered intranasally for 6 consecutive days in mice, 50% of mice died ([Non-Patent Document 4]). Moreover, the above-mentioned preferable dosage and the report that the bioavailability at the time of nasal administration of IL-12 in mice is 10% to 20% (subcutaneous injection and intraperitoneal administration at the time of injection) [[Non-patent Document 5] , [Non-patent document 6]), and in human clinical trial results of IL-12 subcutaneous administration, side effects were reported at a dose of 0.03 μg / kg-0.5 μg / kg ([Non-patent document 7]). Yes. Considering the above, when using IL-12 as a mucosal adjuvant, problems still remain in terms of safety. IL-12 is a cytokine that has been used in human clinical trials for the purpose of anticancer agents and the like, but has not yet been put to practical use due to its toxicity.
On the other hand, [Patent Document 3] describes an invention relating to a vaccine in which interferon β is administered as an adjuvant by administration through the nasal cavity, oral cavity and pharyngeal mucosa with respect to an antigen administered simultaneously or separately. Specifically, anti-tetanus toxoid antibody titer (IgG) in the serum when nasal administration of tetanus toxoid as an antigen and interferon β as an adjuvant is higher than that in the control group. It describes that it has a production enhancing action and can be achieved in a very small amount.
In addition, when interferon β is administered as an antiviral agent or anticancer agent, it has been reported that the expression of proteinuria, which is one of side effects, occurs more frequently than when interferon α is administered ([Non-Patent Document 8]). ).
In this way, while cytokines are being investigated as mucosal adjuvants, interferon αs, which are one of the cytokines with abundant human use, have mucosal adjuvant action, and can be used as mucosal adjuvants, and the adjuvant action is excellent Until now, it has not been known at all that interferon α can induce both antigen-specific blood antibody and antigen-specific mucosal secretory antibody against vaccine antigen when mucosal adjuvant is used.
Japanese Patent Publication No. 8-32633 WO99 / 44635 international publication pamphlet JP 2000-154148 A M.M. Takahashi et al, Drug Delivery System, Vol. 14 R. K. Gupta et al, Vaccine, Vol. 13 H. P. A. Hughes, Veterinary Immunology and Immunopathology, Vol. 63 Victor C. H. et al, International Immunopharmacology, 3 (2003), 801-809. Prosper N. B. et al, Advanced Drug Delivery Reviews, 51 (2001), 71-79. Mariarosaria M. et al, The Journal of Immunology, 162 (1999), 114-121. Victoria C. et al, Journal of Hepatology, 32 (2000), 317-324. Kuramomoto I. et al, Liver, 33 (1992), 517-523.

The inventors of the present invention have conducted intensive research on methods for effectively inducing both antigen-specific blood antibodies and antigen-specific mucosal secretory antibodies against various vaccine antigens, and selection of mucosal adjuvants that can be used at that time. As a result, interferon alphas that are usually used as antiviral agents have a mucosal adjuvant action, and are also excellent as an adjuvant, and vaccine antigens when interferon alphas are used as a mucosal adjuvant. It was found that both antigen-specific antibodies against blood and antigen-specific mucosal secretory antibodies can be induced. Furthermore, when interferon α is used as a mucosal adjuvant, antigen-specific blood antibodies and antigen-specific mucosal surface secretion against various vaccine antigens are administered when the mucosal adjuvant is administered by the same administration route as the transmucosal administration route of the vaccine antigen. It has been found that both antibodies can be effectively induced and the present invention has been completed.
That is, the present invention
"A method for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen using the vaccine antigen and an adjuvant of the vaccine antigen,
(1) transmucosal administration of vaccine antigen,
(2) using interferon α as an active ingredient of an adjuvant,
(3) a method comprising administering the adjuvant with the vaccine antigen simultaneously or at a time interval, and (4) a method comprising transmucosal administration of the adjuvant by the same administration route as the vaccine antigen. About.
In addition, the present invention also includes “a vaccine antigen and interferon αs as a mucosal adjuvant, and these vaccine antigen and mucosal adjuvant are administered transmucosally from the same administration route at the same time or with a time difference, and then the vaccine antigen. The present invention relates to a vaccine composition that induces both antigen-specific blood antibodies against and antigen-specific mucosal secretory antibodies.
Furthermore, the present invention provides a “mucosal adjuvant for inducing both an antigen-specific blood antibody against a vaccine antigen and an antigen-specific mucosal secretory antibody, comprising interferon α as an active substance of the mucosal adjuvant, In addition, the present invention relates to a mucosal adjuvant in which the mucosal adjuvant is transmucosally administered by the same administration route as the administration route of the vaccine antigen at the same time or with a time difference from the vaccine antigen.
Furthermore, the present invention provides a combination of a vaccine antigen and a mucosal adjuvant for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against the vaccine antigen, wherein the mucosal adjuvant is an active substance. As a combination, and the mucosal adjuvant is transmucosally administered by the same administration route as the administration route of the vaccine antigen at the same time or at a time difference from the vaccine antigen.
In addition, the present invention relates to “a mucosal adjuvant for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen comprising interferon αs” as an active ingredient, or “an antigen against a vaccine antigen”. Use of interferon alphas to produce mucosal adjuvants to induce both specific blood antibodies and antigen-specific mucosal secretory antibodies, or "antigen-specific blood antibodies and antigen-specific mucosa against vaccine antigens" Contains interferon alpha as an active ingredient for subjects who need to induce both secretory antibodies and enhance their immunity, at the same time as the vaccine antigen or at the same time as the vaccine antigen. It also relates to a method of stimulating mucosal immune response comprising administering a mucosal adjuvant
The “interferon α” referred to in the present invention is also called leukocyte type interferon, and various natural type interferon α produced by macrophages, genes such as Escherichia coli, yeast, insect cells, animal-derived cells incorporating these interferon α genes. Any of recombinant interferon α obtained by purifying the recombinant product and consensus interferon α having a consensus sequence of various interferon α, such as interferon alfacon-1, can be used. Although not particularly limited, commercially available interferon αs that are ensured in safety are preferred in consideration of safety to the human body.
The term “vaccine antigen” as used in the present invention mainly means a protein or peptide antigen. For example, a vaccine antigen comprising a protein or peptide made from a protective antigen against infectious microorganisms such as influenza hemagglutinin A, etc. Can be mentioned. That is, it is not particularly limited as long as it is an infectious microorganism, virus-derived protein or peptide component that can be a vaccine target. Among these, inactivated toxin proteins produced by infectious microorganisms, such as inactivated vaccines inactivated tetanus toxoid, pertussis vaccine, live vaccine, etc., specifically polio, rubella, measles , Rabies, influenza, HIV, hepatitis A vaccine and the like. Furthermore, the vaccine which produced the target antigen by techniques, such as gene recombination, for example, a Lyme disease vaccine, a hepatitis B vaccine, etc. can be mention | raise | lifted. It is also possible to include live vaccine antigens. For example, polio vaccine, rotavirus vaccine, cholera vaccine, tetanus vaccine, diphtheria vaccine, typhoid vaccine, E. coli. Coli. Vaccine, varicella vaccine, influenza vaccine, H.V. Pylori vaccine and the like. These vaccine antigens can be used alone or in combination of two or more as required.
The “vaccine composition” referred to in the present invention means a composition prepared by adding various excipients exemplified below as vaccine antigens and preparing them by various preparation techniques. Similarly, the “mucosal adjuvant” referred to in the present invention can also include compositions containing interferon α as an active ingredient, added with various excipients, and prepared by various preparation techniques.
In addition, the “combination of vaccine antigen and mucosal adjuvant” can include a composition containing both, but is not necessarily in the form of a composition. A vaccine preparation and a mucosal adjuvant may exist separately, for example, kit preparations prepared and used at the time of use.
The single dose of interferon α used as an adjuvant in the present invention is not particularly limited as long as it is less than the minimum dose generally used as an injection, but it should be used in the range of 0.5 to 5 million IU. preferable. More preferably, it is used in the range of 0.5 to 500,000 IU, and particularly preferably in the range of 0.5 to 10,000 IU.
The administration method for inducing the mucosal immune response of the present invention is not particularly limited as long as it is an administration method via the mucosa. For example, transmucosal administration represented by nasal administration, oral administration, pulmonary administration, vaginal administration and the like can be mentioned, and the purpose is absorption and action in the mucosa or in the lymphoid tissue present in the mucosa. “Nasal administration” means administration to the nostril, and examples of the preparation include nasal drops and sprays. “Oral administration” means general oral, buccal and pharyngeal administration, and preparations include, for example, powders, fine granules, granules, tablets, capsules, pills, elixirs and syrups. , Lozenges, sublingual tablets, buccal tablets, intraoral quick disintegrating tablets and the like. “Pulmonary administration” means administration to the respiratory tract, and examples of the preparation include inhalants and sprays. “Vaginal administration” means administration to the vagina, and examples of the preparation include vaginal suppositories, vaginal tablets, sprays and the like.
In the administration, it is necessary to administer the vaccine antigen and interferon α to the same mucosa. However, any administration of pre-administration, co-administration, or post-administration is possible as long as they are the same mucosa. “Pre-administration” means administration of vaccine antigen after administration of interferon αs in advance. “Simultaneous administration” means that a vaccine antigen and interferon αs are simultaneously administered to the mucosa, and may be administered as a composition containing at least the vaccine antigen and interferon αs, or as separate compositions. You may administer simultaneously. “Post-administration” means that interferon α is administered after the vaccine antigen is administered in advance. “At a time difference” means any one of the above “pre-administration” and “post-administration” at the time of administration, and the difference in administration time is 1 minute to 12 hours, preferably 5 minutes to 6 hours, It is preferably 5 minutes to 4 hours.
Appropriate pharmaceutically acceptable pharmaceutical additives can be blended with interferon αs or vaccine antigens to form separate compositions. The “combination product” in the present invention means a combination of a composition containing the interferon α and the vaccine antigen or a composition containing the vaccine antigen, and does not mean that both are combined into one composition.
In addition, it is possible to prepare a composition containing at least both interferon α and vaccine antigen by blending an appropriate pharmaceutically acceptable pharmaceutical additive.
The composition ratio of the vaccine antigen and interferon α in the composition containing both is difficult to set uniformly because of the activity of the vaccine antigen used, etc., and should not be interpreted in a limited way, The vaccine antigen ratio is 0.01-55% W / W of the total composition, preferably 0.05-50% W / W, more preferably 0.1-45% W / W, and the ratio of interferon αs. The total composition can be 0.01-5% W / W, preferably 0.05-4% W / W, more preferably 0.1-2.5% W / W.
The “antigen-specific blood antibody” of the present invention means an immunoglobulin induced in blood produced only for a specific antigen. Generally, it is known that there are five types of classes (IgM, IgG, IgA, IgD, IgE) due to the difference in the amino acid sequence of the H chain. Among them, the IgG antibody is the main in acquired immunity, and is the most abundant immunoglobulin in blood. The “antigen-specific mucosal secretory antibody” means an immunoglobulin secreted on the mucosal surface produced only for a specific antigen. It is generally known that it is mainly a secretory IgA antibody. IgA antibodies usually form dimers, are secreted to the mucosal surface via receptors present in mucosal epithelial cells such as the respiratory tract, intestinal tract, and salivary glands, and are widely distributed on the mucosal surface. Therefore, regarding “antigen-specific blood antibody” and “antigen-specific mucosal secretory antibody” of the present invention, IgG present in blood and IgA present in mucosa (eg, stool IgA) are measured, respectively. And
Examples of pharmaceutically acceptable pharmaceutical additives include salts, surfactants, saccharides, amino acids, organic acids, other water-soluble substances, and the like, and these additives are one or two kinds. The above can be added. Specific salts include potassium L-glutamate, sodium L-glutamate, sodium edetate, sodium caprylate, sodium carbazochrome sulfonate, sodium carboxymethylcellulose, sodium citrate, calcium gluconate, sodium gluconate, magnesium gluconate, Sodium metasulfobenzoate, sodium monohydrogen phosphate, sodium dihydrogen phosphate, dipotassium phosphate, potassium dihydrogen phosphate, aluminum chloride, potassium chloride, calcium chloride, sodium chloride, sodium acetate, sodium carbonate, sodium bicarbonate, etc. Examples of sugars include D-sorbitol, D-mannitol, inositol, xylitol, dextran, glucose, maltose, lactose, sucrose, and the like. Examples of amino acids include methionine, aspartic acid, alanine, arginine, glycine, cysteine, taurine, histidine, phenylalanine, glutamic acid, and lysine. Other water-soluble substances include ascorbic acid, human serum albumin, and chondroitin. Examples include sodium sulfate, gelatin, gelatin hydrolyzate, and heparin sodium. Surfactants, organic acids and the like can also be added. Specific surfactants include sorbitan sesquioleate, sorbitan fatty acid ester, polyoxyethylene (160) polyoxypropylene (30) glycol, polyoxyethylene sorbitan monolaurate, polyoxyethylene castor oil, polyoxyethylene cured Castor oil, polyoxyethylene hydrogenated castor oil 50, polyoxyethylene hydrogenated castor oil 60, polysorbate 20, polysorbate 80, macrogol 400, macrogol 4000, macrogol 600, and the like. Examples of organic acids include oleic acid, thio Examples include glycolic acid and lactic acid. Moreover, you may add pH adjusting agents, such as hydrochloric acid and sodium hydroxide, and osmotic pressure adjusting agents, such as sodium chloride, as needed.
In addition, pharmaceutical additives other than those described above that are pharmaceutically acceptable can be added. For example, excipients such as potato starch, wheat starch, rice starch, corn starch, crystalline cellulose, binders such as hydroxypropylmethylcellulose, hydroxypropylcellulose, methylcellulose, gum arabic, carboxymethylcellulose, carboxymethylcellulose calcium, croscarmellose sodium Swelling agents such as stearic acid, calcium stearate, magnesium stearate, talc, magnesium aluminate metasilicate, calcium hydrogen phosphate, anhydrous calcium hydrogen phosphate, hydrous silicon dioxide, light anhydrous silicic acid, dry water Fluidizers such as aluminum oxide gel, colorants such as yellow ferric oxide, red ferric oxide, zein, hydroxypropylmethylcellulose, hydroxypro Coating agents such as cellulose, fragrances such as 1-menthol, mint oil, fennel oil, preservatives such as sodium sorbate, potassium sorbate, methyl parabenzoate, ethyl parabenzoate, citric acid, succinic acid, fumar One or more buffering agents such as acid, tartaric acid, magnesium oxide, zinc oxide, magnesium hydroxide, phosphoric acid, boric acid or salts thereof are selected in appropriate amounts.
The above-mentioned additives are not limited to those exemplified, and the blending amount thereof is not particularly limited as long as it is usually used by a person skilled in the art and does not impair the effects of the present invention.
Further, other adjuvants such as aluminum phosphate, aluminum hydroxide, calcium phosphate and the like can be included within the range not impeding the effects of the present invention.
When preparing a composition, it can be easily prepared as an aqueous solution by adding and mixing interferon α to a conventionally used vaccine. Moreover, what added additives, such as an excipient | filler and a stabilizer as needed, to a vaccine antigen liquid and interferon alpha aqueous solution can also be pulverized using methods, such as spray drying and freeze-drying. The composition comprising the vaccine antigen and interferon α thus obtained can be used for transmucosal administration as it is. If necessary, the vaccine composition of the present invention may be encapsulated in a carrier such as Drug Delivery System (DDS) technology, for example, liposome, nanosphere or microsphere, biodegradable carrier, mucoadhesive carrier, and used. Is possible. Specifically, a vaccine antigen and interferon α encapsulated in a microsphere composed of biodegradable polymer such as PLGA, a mucoadhesive microsphere composed of hyaluronic acid, chitin, etc., vaccine antigen and interferon a composition enclosing α. Also, efficient and effective administration techniques for mucosal lymphoid tissues, such as M cells existing in the gastrointestinal mucosal lymphoid tissues, targeting techniques to Peyer's patches, specifically M cell-specific lectins and antibodies on the surface It is also possible to use a technique of encapsulating vaccine antigen and interferon α using a microsphere having a molecule as a carrier. In addition, it is also possible to apply a technique that utilizes a detoxified bacterium or virus itself as a carrier, such as inactivated Salmonella that has been reported in recent years.
The present invention is also useful as a method for inducing a mucosal immune response not only for humans but also for animals. When used for animals, it is preferable to use interferon α of the corresponding animal species, but there is no particular limitation. For animals in which human interferon α exhibits cross-reactivity, that is, reactivity to human interferon α, human-type interferon α may be used.

  EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated further, this invention is not limitedly interpreted by these Examples.

考察 表１に示されるように、すべての週においてインターフェロンα併用群は比較対照例１と比較して有意に高いＯＶＡ特異的血中ＩｇＧ価を示した。本結果から、ワクチンをインターフェロンαと併用して経鼻投与することより全身性免疫応答を効果的に誘導できることが示された。Ovalbumin (hereinafter referred to as OVA) widely used in the literature as a model antigen is used, and the method of Yamamoto et al. (S. Yamamoto et al, Proc. Natl. Acad. Sci. USA, Vol. 94, 1997) is used. Mice were administered nasally accordingly. As the mice, 4 or 5 C57BL mice (male, 8 weeks old) were used per group. As interferon α, mouse interferon αA was prepared, and the antigen (OVA was 100 μg / animal) was administered at a single dose of 1.5 μg (6500 U) / animal. All administrations were performed nasally, and after the first administration, blood was collected at 3 weeks, 4 weeks, and 6 weeks after the first administration, 3 weeks, 1 week, and 2 weeks. The supernatant was collected by centrifugation for minutes. The OVA-specific antibody titer (blood IgG) in these serum samples was measured by ELISA (Table 1).
Comparative Example 1
C57BL mice (male, 8 weeks old) were assigned to 5 mice per group, and OVA was administered at a single dose of 100 μg / mouse. All administrations were performed nasally, and after the first administration, blood was collected at 3 weeks, 4 weeks, and 6 weeks after the first administration, 3 weeks, 1 week, and 2 weeks. The supernatant was collected by centrifugation for minutes. The OVA-specific antibody titer (blood IgG) in these serum samples was measured by ELISA (Table 1).

Discussion As shown in Table 1, the interferon α combination group showed a significantly higher OVA-specific blood IgG titer compared to Comparative Example 1 at all weeks. From these results, it was shown that a systemic immune response can be effectively induced by nasally administering the vaccine in combination with interferon α.

考察
表２に示したように、実施例２は特に３週、４週において比較例３と比較して有意に高いＯＶＡ特異的糞便中ＩｇＡ価を示し、経鼻投与によるインターフェロンα併用により、消化管粘膜上に免疫応答を誘導した。本結果から、経鼻投与によるインターフェロンα併用により全身性免疫応答のみならず粘膜免疫応答も誘導出来ることが示された。In the same manner as in Example 1, C57BL mice (male, 8 weeks old) were grouped in 4 or 5 mice, and OVA was administered at a single dose of 100 μg / mouse. Interferon α was administered at the same time as the antigen at 1.5 μg / animal. All administrations are performed nasally, and after the first administration, 1 week, 2 weeks, a total of 3 nasal administrations, about 1 day from the previous day of 3 weeks, 4 weeks and 6 weeks counting from the first administration day Feces were collected. 250 mg of these stool samples were accurately weighed, 1 mL of Tris-HCl buffer (pH 7.4) was added and stirred, centrifuged at 3000 rpm for 15 minutes, and the supernatant was collected. The OVA-specific antibody titer (fecal IgA) in these supernatants was measured by ELISA (Table 2).
Comparative Example 2
C57BL mice (male, 8 weeks old) were assigned to 5 mice per group, and OVA was administered at a single dose of 100 μg / mouse. All administrations are performed nasally, and after the first administration, after three nasal administrations, one week and two weeks, three days from the first administration day, about one day from the previous day of the fourth week Collected. 250 mg of these stool samples were accurately weighed, 1 mL of Tris-HCl buffer (pH 7.4) was added and stirred, centrifuged at 3000 rpm for 15 minutes, and the supernatant was collected. The OVA-specific antibody titer (fecal IgA) in these supernatants was measured by ELISA (Table 2).

Discussion As shown in Table 2, Example 2 showed significantly higher OVA-specific fecal IgA titer than Comparative Example 3 at 3 weeks and 4 weeks, and digested with interferon α in combination with nasal administration. An immune response was induced on the ductal mucosa. From these results, it was shown that not only systemic immune response but also mucosal immune response can be induced by nasal administration in combination with interferon α.

Industrial applicability

  According to the present invention, induction of both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen is achieved using the vaccine antigen and an adjuvant of the vaccine antigen, which has a higher effect than before. A mucosal vaccine can be produced, and it is possible to provide a technique effective for prevention of infectious diseases.

Claims (27)

Vaccine antigens and interferon α as mucosal adjuvants, and these vaccine antigens and mucosal adjuvants are administered mucosally from the same administration route at the same time or at different times, and antigen-specific blood antibodies against vaccine antigen And a vaccine composition that induces both antigen-specific mucosal secretory antibodies. The vaccine composition according to claim 1, wherein the interferon αs are selected from natural interferon αs and recombinant interferon αs. The vaccine composition according to claim 1, wherein the amount of interferon α used is 0.5 to 5 million IU. The vaccine composition according to claim 1, wherein the vaccine antigen is a protein or peptide antigen. The vaccine composition according to claim 1, wherein the vaccine antigen and the adjuvant are administered simultaneously via transmucosal. 6. The vaccine composition according to claim 5, wherein the vaccine antigen and the adjuvant are in the form of simultaneous nasal mucosal administration. A mucosal adjuvant for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen, comprising interferon α as an active substance of the mucosal adjuvant, and the mucosal adjuvant comprising the vaccine A mucosal adjuvant that is administered transmucosally by the same administration route as the administration route of the vaccine antigen at the same time or at a time difference from the antigen. The mucosal adjuvant according to claim 7, wherein the interferon αs are selected from natural interferon αs and recombinant interferon αs. The mucosal adjuvant according to claim 7, wherein the amount of interferon α used is 0.5 to 5 million IU. The mucosal adjuvant according to claim 7, wherein when a protein or peptide antigen is used as a vaccine antigen, it is transmucosally administered by the same administration route as that of the vaccine antigen at the same time or with a time difference. The mucosal adjuvant according to claim 10, which is administered transmucosally simultaneously with a vaccine antigen. The mucosal adjuvant according to claim 11, which is administered in the nasal mucosa by the same route of administration as the vaccine antigen. A combination of a vaccine antigen and a mucosal adjuvant for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against the vaccine antigen, the mucosal adjuvant comprising interferon α as an active substance, And a combination wherein the mucosal adjuvant is administered transmucosally by the same administration route as the administration route of the vaccine antigen at the same time or with a time difference from the vaccine antigen. The combination according to claim 12, wherein the interferon α is selected from natural interferon α and recombinant interferon α. The combination according to claim 13, wherein the amount of interferon α used is 0.5 to 5 million IU. The combination according to claim 13, wherein the vaccine antigen is a protein or peptide antigen. The combination according to claim 13, wherein the vaccine antigen and the mucosal adjuvant are administered simultaneously via transmucosal. The combination according to claim 17, wherein the vaccine antigen and the mucosal adjuvant are administered through the same route of administration through the nasal mucosa. A mucosal adjuvant for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen containing interferon α as an active ingredient. Use of interferon alphas to produce mucosal adjuvants to induce both antigen-specific blood antibodies and antigen-specific mucosal secretory antibodies to vaccine antigens. To a subject who needs to induce both antigen-specific blood antibody and antigen-specific mucosal secretory antibody against vaccine antigen to enhance immunity, the vaccine antigen and the vaccine antigen A method for activating mucosal immune response, comprising administering a mucosal adjuvant containing interferon α as an active ingredient by the same administration route. A method for inducing both an antigen-specific blood antibody and an antigen-specific mucosal secretory antibody against a vaccine antigen using the vaccine antigen and an adjuvant of the vaccine antigen,
(1) transmucosal administration of vaccine antigen,
(2) using interferon α as an active ingredient of an adjuvant,
(3) A method comprising administering the adjuvant with the vaccine antigen simultaneously or at a time difference, and (4) transmucosal administration of the adjuvant with the vaccine antigen by the same administration route. The method according to claim 22, wherein the interferon αs are selected from natural interferon αs and recombinant interferon αs. The method according to claim 23, wherein the amount of interferon α used is 0.5 to 5 million IU. The method according to claim 23, wherein the vaccine antigen is a protein or peptide antigen. 24. The method of claim 23, wherein transmucosal administration is performed simultaneously. 27. The method of claim 26, wherein the method is for nasal mucosal administration.