The present invention relates to a cell capable of co-expressing target antigen and CD1d, a cell capable of co-expressing target antigen and CD1d and having an ability to immunoactivate the target antigen, a method of producing them, an immunoinducer for a target antigen, and the like.
NKT cell is a cell constituting a lymphocyte lineage simultaneously having the characteristics of both T cell and NK cell, which is activated by an antigen present on MHC class I-like molecule CD1d, and shows actions such as an antitumor action and the like. Examples of the antigen (CD1d ligand) present on CD1d, which strongly activates NKT cells, include glycolipid α-galactosylceramide α-GalCer). Primary NKT cell is stimulated by an antigen presenting cell (APC) loaded with an antigen such as α-GalCer and the like, and can differentiate•proliferate. Examples of such APC include macrophage, immature or mature dendritic cell (DC) and the like. Of these, the present inventors previously reported that mature DC pulsed with α-GalCer strongly activates NKT cells.
Heretofore, as an immunotherapy by NKT cell, administration of NKT cell activated by dendritic cell presenting CD1d ligand has clinically been tried. In addition, the present inventors reported that an antigen specific T cell immunity induction occurs as an adjuvant effect of a CD1d ligand by administration of the CD1d ligand to a mouse model.
Known literatures in the field of the invention by the present inventors include the following.
Non-patent reference 1 describes that, in a mouse model, a mature DC pulsed with α-GalCer can strongly activate IFN-γ-producing NKT cells, and that an NKT cell thus induced shows an antitumor effect.
Non-patent reference 2 describes that, in an experiment using a human sample, a mature DC pulsed with α-GalCer can strongly activate IFN-γ producing NKT cells, and that macrophage and immature dendritic cell can also activate NKT cells.
Non-patent reference 3 describes that when a dendritic cell captures an antigen during activation of NKT cells, the dendritic cell becomes mature, and can induce an antigen specific T cell.
Non-patent reference 4 describes that, in maturation of dendritic cells by NKT cells, IFN-γ and TNF-α, as well as CD40 signal are important.
Non-patent reference 5 describes that human NKT cells activated in vitro can kill CD1d expression target presenting α-GalCer.
Non-patent reference 6 describes that CD1d is expressed on B cell leukemia cell line, and can mediate presentation of α-GalCer to NKT cells.
Non-patent reference 7 describes that, in activation of NKT cells, antigen specific T cells cannot be induced without maturation of dendritic cells and antigen uptake by the cells.
Non-patent reference 8 describes that administration of antigen during activation of NKT cells by the administration of α-GalCer induces an antigen specific immune response.
However, a method enabling simultaneous induction of NKT cell activation and T-cell immune response to tumors, which is earnestly desired for the establishment of an immunotherapy of tumors, has not been developed as yet.
Accordingly, an object of the present invention is to provide a method simultaneously inducing NKT cell activation and T-cell immune response to tumors.
The present inventors unexpectedly and surprisingly found that a tumor cell pulsed with a CD1d ligand induces a very strong immune response specific to the tumor cell, particularly simultaneous activation of NK/NKT cells and T-cell immune response. The present inventors have further conducted intensive studies and found that the above-mentioned antitumor immune response is dependent on CD1d expressed in tumor cell, and the like. Based on the above findings, the present inventors have concluded that a tumor antigen and CD1d co-expressing cell, which is pulsed with a CD1d ligand, can induce a very strong immune response specific to the tumor cell, particularly, simultaneous activation of NK/NKT cells and T-cell immune response. Such methodology is considered widely applicable not only to immunotherapy of tumor but also immunotherapy of cells and organisms expressing a specific target antigen, for example, virus-infected cells and pathogens (e.g., virus). An idea of using a target antigen and CD1d co-expressing cell, which is pulsed with a CD1d ligand, for the induction of immunity to the target antigen (including product containing the target antigen) is not described or suggested in the above-mentioned prior art references.
The present inventors have completed the present invention based on the above.
That is, the present invention provides the following invention and the like.
[1] A method of preparing a cell co-expressing a target antigen and CD1d, which is capable of activating immunity to the target antigen, comprising treating the target antigen and CD1d co-expressing cell with a CD1d ligand in a culture medium.
[2] The method of the above-mentioned [1], further comprising preparing the target antigen and CD1d co-expressing cell by the preliminary step (a) or (b) below:
(a) treating a cell such that the target antigen and CD1d will co-express in an object cell or expression of the target antigen and/or CD1d will be enhanced in the target antigen and CD1d co-expressing cell, whereby the target antigen and CD1d co-expressing cell is obtained; or
(b) recovering the target antigen and CD1d co-expressing cell (or naturally co-expressing cell) from a biological sample obtained from an individual to give the target antigen and CD1d co-expressing cell.
[3] The method of the above-mentioned [1], wherein the target antigen is a tumor antigen or a pathogenic antigen.
[4] A method of preparing a tumor cell or a virus-infected cell capable of activating immunity to the tumor cell, or virus or the virus-infected cell, comprising treating the tumor cell or the virus-infected cell, which expresses CD1d, with a CD1d ligand in a culture medium.
[5] The method of the above-mentioned [4], wherein the tumor cell is a solid tumor cell or a tumor cell in a hematopoietic tissue.
[6] A method of preparing a cell co-expressing a target antigen and CD1d, comprising treating a cell such that the target antigen and CD1d will co-express in an object cell or expression of the target antigen and/or CD1d will be enhanced in the target antigen and CD1d co-expressing cell.
[7] A method of preparing a tumor cell or a virus-infected cell, which expresses CD1d, or in which expression of CD1d is enhanced, comprising transforming the tumor cell or the virus-infected cell with a vector that expresses at least CD1d.
[8] A method of identifying the target antigen and CD1d co-expressing cell, comprising measuring the expression of a target antigen and/or CD1d in an object cell.
[9] The method of the above-mentioned [8], wherein the object cell is a tumor cell or virus-infected cell obtained from an individual.
[10] A target antigen and CD1d co-expressing cell capable of activating immunity to the target antigen.
[11] The cell of the above-mentioned [10], wherein the target antigen is a tumor antigen or a pathogenic antigen.
[12] A tumor cell or a virus-infected cell that expresses CD1d, which is capable of activating immunity to the tumor cell, or virus or the virus-infected cell.
[13] The cell of the above-mentioned [12], which is transformed with a vector that expresses at least the target antigen or a vector that expresses at least CD1d.
[14] An immunoinducer to a target antigen, comprising a target antigen and CD1d co-expressing cell capable of activating immunity to the target antigen.
[15] A composition comprising a target antigen and CD1d co-expressing cell capable of activating immunity to the target antigen, and an adjuvant.
[16] A pharmaceutical agent comprising a target antigen and CD1d co-expressing cell capable of activating immunity to the target antigen.
[17] A pharmaceutical agent of the above-mentioned [16], which is a therapeutic agent of a solid tumor, a tumor in a hematopoietic tissue or infections.
[18] A target antigen and CD1d co-expressing cell, which is treated to co-express a target antigen and CD1d, or enhance expression of target antigen and/or CD1d.
[19] The cell of the above-mentioned [18], which is any of (a)-(e) below:
(a) a naturally CD1d-expressing cell transformed with a vector that expresses at least a target antigen;
(b) a naturally target antigen-expressing cell transformed with a vector that expresses at least CD1d;
(c) a cell transformed with 1 or 2 vectors that express at least a target antigen and CD1d;
(d) a naturally CD1d-expressing cell having a target antigen introduced thereinto; and
(e) a cell transformed with a vector that expresses at least CD1d, and having a target antigen introduced thereinto.
[20] The cell of the above-mentioned [18], which is any of (a)-(e) below:
(a) a CD1d expressing antigen presenting cell transformed with a vector that expresses at least a target antigen;
(b) a tumor cell or a virus-infected cell transformed with a vector that expresses at least CD1d;
(c) a CD1d expressing antigen presenting cell, or a tumor cell or a virus-infected cell, which is transformed with 1 or 2 vectors that express at least a target antigen and CD1d;
(d) a CD1d expressing antigen presenting cell having a target antigen introduced thereinto; and
(e) a CD1d expressing antigen presenting cell, or a tumor cell or a virus-infected cell, which is transformed with a vector that expresses at least CD1d, and having a target antigen introduced thereinto.
[21] A target antigen and CD1d co-expression vector, comprised of a first polynucleotide encoding a target antigen, a second polynucleotide encoding CD1d, and a promoter functionally linked to the polynucleotides.
[22] A kit comprising any of (a)-(o) below:
(a) a combination of (a1) a vector that expresses at least a target antigen (except CD1d), and (a2) a vector that expresses at least CD1d (except target antigen);
(b) a combination of (b1) a target antigen-expressing cell, and (b2) a vector that expresses at least CD1d;
(c) a combination of (c1) a CD1d-expressing cell, and (c2) a vector that expresses at least a target antigen;
(d) a combination of (d1) a vector that expresses at least CD1d, and (d2) a target antigen;
(e) a combination of (e1) a CD1d-expressing cell, and (e2) a target antigen;
(f) a combination of (f1) a CD1d ligand, and (f2) a vector that expresses at least a target antigen;
(g) a combination of (g1) a CD1d ligand, and (g2) a target antigen-expressing cell;
(h) a combination of (h1) a CD1d ligand, and (h2) a target antigen;
(i) a combination of (i1) a CD1d ligand, and (i2) a target antigen and CD1d co-expressing cell;
(j) a combination of (j1) a CD1d ligand, (j2) a target antigen-expressing cell, and (j3) a vector that expresses at least CD1d;
(k) a combination of (k1) a CD1d ligand, (k2) a CD1d-expressing cell, and (k3) a vector that expresses at least a target antigen;
(l) a combination of (l1) a CD1d ligand, and (l2) 1 or 2 vectors that express at least a target antigen and CD1d;
(m) a combination of (m1) a CD1d ligand, (m2) a vector that expresses at least CD1d, and (m3) a target antigen;
(n) a combination of (n1) a CD1d ligand, (n2) a CD1d-expressing cell, and (n3) a target antigen; and
(o) a combination of (o1) a target antigen expression measuring means selected from the group consisting of an antibody, a nucleic acid probe and two or more primers, and
(o2) a CD1d expression measuring means selected from the group consisting of an antibody, a nucleic acid probe and two or more primers.
[23] A method of inducing immunity, comprising administering an effective amount a target antigen and CD1d co-expressing cell capable of activating immunity to the target antigen, to a test subject in need thereof.
[24] The method of the above-mentioned [23], wherein an effective amount of the target antigen and CD1d co-expressing cell and an adjuvant.
[25] Use of a target antigen and CD1d co-expressing cell capable of activating immunity to the target antigen, for the production of an immunoinducer.
[26] The use of the above-mentioned [25], wherein a target antigen and CD1d co-expressing cell capable of activating immunity to the target antigen, and an adjuvant are used.
The present invention provides a predetermined cell (e.g., a target antigen and CD1d co-expressing cell) puled with a CD1d ligand. Such co-expressing cell pulsed with a CD1d ligand has an ability to activate the immunity to the target antigen.
CD1d ligand refers to a substance presented on a CD1d expression antigen presenting cell (APC), which can activate NKT cells. Examples of “CD1d ligand” include α-GalCer (α-galactosylceramide), α-C-GalCer (α-C-galactosylceramide), iGB3 (isoglobotrihexosylceramide), GD3 (ganglioside 3), GSL-1 (α-linked glucuronic acid), GSL-1′SA (galacturonic acid), with preference given to α-GalCer and α-C-GalCer. The cell of the present invention presents CD1d ligand on the cell surface via CD1d, and can activate NKT cells.
The present invention also provides, from among predetermined cells that can be pulsed with CD1d ligand, a novel cell. The present inventors first found that a predetermined cell (e.g., a target antigen and CD1d co-expressing cell) pulsed with a CD1d ligand is highly useful for immunotherapy. For example, as the target antigen and CD1d co-expressing cell, cells including mouse-derived melanoma cell line B16 and mouse-derived T lymphoma cell line EL4 are already present. Without such finding by the present inventors, however, there is no motivation to intentionally produce a target antigen and CD1d co-expressing cell that can be used for the method developed by the present inventors. Therefore, the target antigen and CD1d co-expressing cell produced in this way may be novel. For example, the novel cell thus produced may be a cell treated such that a target antigen and/or CD1d will be expressed or expression of a target antigen and/or CD1d will be enhanced.
In the present specification, a target antigen and CD1d co-expressing cell pulsed with a CD1d ligand, as well as a novel cell co-expressing a target antigen and CD1d are sometimes collectively abbreviated as, where necessary, “the cell of the present invention”. When, from among the cells of the present invention, a target antigen and CD1d co-expressing cell pulsed with a CD1d ligand is particularly intended, it may be as abbreviated as, where necessary, “pulsed cell of the present invention” (which means a cell that may have an ability to activate the immunity to the target antigen). Moreover, when, from among the cells of the present invention, a novel cell co-expressing a target antigen and CD1d is particularly meant, it may be abbreviated as, where necessary, “non-pulsed cell of the present invention” (which means a cell that can acquire an ability to activate immunity to the target antigen after being pulsed with a CD1d ligand, but cannot have an ability to activate immunity to the target antigen since it is not pulsed with CD1d ligand).
The cell of the present invention may be isolated and/or purified. Isolation and purification can be performed by a method known per se.
The cell of the present invention may also be derived from any animal species. Examples of such animal species include mammals such as human, monkey, chimpanzee, dog, cat, horse, bovine, swine, sheep, goat, mouse, rat, guinea pig, hamster, rabbit and the like, with preference given to a cell derived from human from the aspect of clinical application.
The cell of the present invention may be a cell type derived from any tissue. Examples of such tissue include stomach, small intestine (e.g., duodenum, jejunum, ileum, colon), large intestine, rectal, lung, pancreas, kidney, liver, thymus, spleen, thyroid gland, adrenal gland, prostate, ovary, uterus, bone marrow, skin, and peripheral blood. The cell of the present invention may also be a particular cell type in the above-mentioned tissues or a cell type in a tissue other than the above-mentioned tissues. Examples of such cell type include epithelial cell, endothelial cell, epidermal cell, interstitial cell, fibroblast, adipocyte, mammary cell, mesangial cell, pancreatic β cells, nerve cell, glial cell, immune cell (e.g., T cells, B cells, NK cell, NKT cell, macrophage, mast cell, neutrophil, basophil, eosinophils, monocyte), and precursor cells and stem cells of these cells.
Furthermore, the cell of the present invention may be a cell obtained from an animal (e.g., primary cultured cell) or a cell line. The cell line may be an existing cell line or a newly prepared cell line. The cell line can be produced by a method known per se.
More importantly, the cell of the present invention may be a cell that expresses both a target antigen and CD1d.
A target antigen is an antigen expressed on an abnormal cell or pathogen, and is not particularly limited as long as intracorporeal disappearance of the abnormal cell or pathogen, or a decrease in the amount of the abnormal cell or pathogen is expected due to an immune action targeting the antigen. Examples of the target antigen include tumor antigen and pathogenic antigen. The cell of the present invention can express one or more target antigens to the same target.
The tumor antigen may be an antigen of a solid tumor including epithelial and nonepithelial tumors, or a tumor in a hematopoietic tissue. While the solid tumor antigen is not particularly limited, for example, MART-1/Melan-A, Mage-1, Mage-3, gp100, tyrosinase, CEA, PSA, CA-125, erb-2, Muc-1, Muc-2, TAG-72, AES, FBP, C-lectin, NY-ESO-1, galectin-4/NY-CO-27, Pec60, HER-2/erbB-2/neu, telomerase, G250, Hsp105, point mutation ras oncogene, point mutation p53 oncogene and carcinoembryonic antigen can be mentioned (e.g., JP-A-2005-139118, JP-A-2004-147649, JP-A-2002-112780, JP-A-2004-222726). While the tumor (e.g., leukemia) antigen in a hematopoietic tissue is not particularly limited, for example, proteinase 3, WT-1, hTERT, PRAME, PML/RAR-a, DEK/CAN, cyclophilin B, TEL-MAL1, BCR-ABL, OFA-iLRP, Survivin, idiotype, Sperm protein 17, SPAN-Xb, CT-27 and MUC1 can be mentioned.
The pathogenic antigen may be a pathogenic virus antigen, a pathogenic microorganism antigen, or a pathogenic protozoan antigen. While a pathogenic virus antigen is not particularly limited, for example, GP-120, p17, GP-160 (which are HIVs), NP, HA (which are influenza viruses), HBs Ag, HBV envelope protein, core protein, polymerase protein, NS3, NS5 (which are hepatitis viruses), HSVdD (simple herpes virus), EBNA1, 2, 3A, 3B and 3C, LMP1 and 2, BZLF1, BMLF1, BMRF1, BHRF1 (which are EB viruses), Tax (HTLV-I), SARS-CoV spike protein (SARS virus), CMV pp 5, IE-1 (which are CMVs), E6, E7 proteins (which are HPVs) can be mentioned (e.g., JP-A-2004-222726). Examples of the pathogenic microorganism antigen include antigens expressed in pathogenic bacterium (e.g., chlamydiae, mycobacteria, Legionella) or pathogenic yeast (e.g., aspergillus, Candida). Examples of the pathogenic protozoan antigen include antigens expressed in malaria or schistosomemalaria.
CD1d is known to be a major histocompatible antigen (MHC)-like molecule that presents glycolipid rather than peptide. CD1d is expressed in antigen presenting cell (e.g., dendritic cell), epithelial cells in tissues in the intestine, liver and the like, some tumor cells (e.g., solid tumor cell, leukemia cell) and virus-infected cells.
The cell of the present invention may also be a normal cell or abnormal cell. The normal cell refers to a cell not in a pathogenic state. On the other hand, the abnormal cell refers to a cell in a pathogenic state. Examples of the abnormal cell include tumor cell and virus-infected cell. The tumor cell may be one corresponding to the aforementioned cell type. Examples of the virus-infected cell include the aforementioned cell type infected with a pathogenic virus. While the pathogenic virus is not particularly limited, for example, human immunodeficiency virus (HIV), hepatitis virus (e.g., type A, type B, type C, type D and type E hepatitis virus), influenza virus, simple herpes virus, West Nile fever virus, human papillomavirus, equine encephalitis virus and human T-cell leukemia virus (e.g., HTLV-I) can be mentioned.
The cell of the present invention may also be non-transformant or transformant. When used in the present specification, the transformation refers to an artificial transgenic manipulation, and the transformant means a cell produced by such artificial manipulation. Therefore, a cell produced by a non-artificial manipulation is treated as one not falling under a transformant in the present specification. To be more precise, when the cell of the present invention is a transformant, the cell of the present invention can be produced by transforming, as a host cell, a cell that does not express both a target antigen and CD1d, or a cell that naturally expresses one or both of the target antigen and CD1d, with a vector that expresses at least a target antigen, or a vector that expresses at least CD1d or 1 or 2 vectors that express at least a target antigen and CD1d (detail of the expression vector is described later). In transformation, the host cell may be any cell, and can be, for example, a normal cell or an abnormal cell (e.g., tumor cell such as leukemia cell and the like, virus-infected cell), or a cell non-naturally expressing a target antigen and CD1d, a cell naturally expressing a target antigen, a cell naturally expressing CD1d, or a cell naturally expressing a target antigen and CD1d.
The cell of the present invention may also be a target antigen-introduced cell or a target antigen-unintroduced cell. When used in the present specification, introduction of a target antigen means an artificial target antigen transfer operation, and an introduced cell of a target antigen means a cell produced by such an artificial operation. Therefore, a cell produced by a non-artificial operation is treated as one not falling under an introduced cell of a target antigen in the present specification. To be more precise, when the cell of the present invention is an introduced cell of a target antigen, the cell of the present invention may be produced by incorporating a target antigen into, as a host cell, a cell that does not express both the target antigen and CD1d, or a cell that naturally expresses both or one of the target antigen and CD1d.
The cell of the present invention may also be a cell derived from an antigen presenting cell (APC) or non-APC, each being naturally-occurring. Examples of the naturally-occurring APC include dendritic cell, macrophage, B cell, Langerhans cell and activated T cell. Hence, the cell of the present invention may be a naturally-occurring APC or non-APC harboring an incorporated target antigen or transformed with a vector that expresses at least a target antigen, a vector that expresses at least CD1d, or 1 or 2 vectors that express at least a target antigen and CD1d.
The cell of the present invention may also be a cell derived from an antigen presenting cell expressing CD1d (CD1d-expressing APC) or non-CD1d-expressing APC, each being naturally-occurring. The CD1d-expressing APC refers to a cell capable of activating NKT cells, which has CD1d on the cell surface thereof. Examples of the CD1d-expressing APC include dendritic cell, macrophage and B cell. Hence, the cell of the present invention may be a naturally-occurring CD1d expressing APC or non-CD1d-expressing APC harboring an incorporated target antigen or transformed with a vector that expresses at least a target antigen, a vector that expresses at least CD1d, or 1 or 2 vectors that express at least a target antigen and CD1d.
As the cell of the present invention, moreover, a cell derived from an individual to be immunized with a cell (syngeneic to subject of administration), a cell derived from another individual allogeneic to an individual to be immunized with a cell (cell allogeneic to subject of administration), or a cell derived from an individual heterogeneous to an individual to be immunized with a cell (heterogeneous to subject of administration) can be used. Since the object is induction of T-cell immune response to a tumor antigen of oneself, a syngeneic cell is preferable.
The pulsed cell of the present invention is, as mentioned below, useful as a pharmaceutical agent, an immunity activator and the like. The non-pulsed cell of the present invention is useful, for example, for the production of the pulsed cell of the present invention.
The present invention provides a method for preparing the cell of the present invention.
In one embodiment, the preparation method of the present invention can be a method for preparing the non-pulsed cell of the present invention. The preparation method of the non-pulsed cell of the present invention may include treating a cell such that the target antigen and CD1d will be co-expressed in the object cell, or expression of the target antigen and/or CD1d will be enhanced in the target antigen and CD1d co-expressing cell.
For example, when the preparation method of the present invention includes treatment of a cell such that the target antigen and CD1d will be co-expressed in the object cell, the object cell may be a cell that does not express both the target antigen and CD1d, or a cell that expresses only one of the target antigen and CD1d.
In addition, when the preparation method of the present invention includes treatment of a cell such that the expression of the target antigen and/or CD1d will be enhanced in the target antigen and CD1d co-expressing cell, the expression of the target antigen and/or CD1d can be enhanced to the degree that the treatment effect of the immunotherapy using the cell of the present invention is sufficiently increased.
The treatment in the preparation method of the present invention may be transformation or an operation to introduce a target antigen. To be more precise, the preparation method of the present invention may include (a) transforming a CD1d-expressing cell with a vector that expresses at least a target antigen, (b) transforming a target antigen-expressing cell with a vector that expresses at least CD1d, (c) transforming a cell with 1 or 2 vectors that express at least a target antigen and CD1d, (d) incorporating a target antigen itself into a CD1d-expressing cell, or (e) transforming a cell with a vector that expresses at least CD1d, and incorporating the target antigen itself into the cell, or (f) incorporating a target antigen itself into a cell, and transforming the cell with a vector that expresses at least CD1d. The transformation of the cell can be performed by a method known per se such as a lipofection method, a calcium phosphate precipitation method, an electroporation method and the like. The introduction of the target antigen into the cell can be performed, for example, using hyperosmotic shock, electroporation, liposome or a fusion protein of a signal peptide, which enables intracellular uptake, and a target antigen.
In the aforementioned preparation method, the CD1d-expressing cells in (a) and (d) may be a cell that expresses CD1d and does not express a target antigen, or a cell that expresses both a target antigen and CD1d. The target antigen-expressing cell in (b) may be a cell that expresses a target antigen and does not express CD1d, or a cell that expresses both a target antigen and CD1d. The cells in (c), (e) and (f) may be a cell that does not express both a target antigen and CD1d, a cell that expresses a target antigen and does not express CD1d, a cell that expresses CD1d and does not express a target antigen, or a cell that expresses both a target antigen and CD1d.
In another embodiment, the preparation method of the present invention may be a preparation method of the pulsed cell of the present invention. The preparation method of the pulsed cell of the present invention may include treating a target antigen and CD1d co-expressing cell with a CD1d ligand in a culture medium. By such a treatment, the CD1d ligand is presented on the target antigen and CD1d co-expressing cell, and the co-expressing cell can acquire an ability to activate immunity to the target antigen.
The culture medium can be prepared using, as a basal medium, a medium used for culturing animal cells. Examples of the basal medium include MEM medium, DMEM medium, αMEM medium, Ham's medium, RPMI1640 medium, Fischer's medium, and a mixed medium thereof. The culture medium can contain, for example, serum (e.g., FCS), serum replacement (e.g., knockout Serum Replacement (KSR)), fatty acid or lipid, amino acid, vitamin, growth factor, cytokine, antioxidant, 2-mercaptoethanol, pyruvic acid, buffering agent, inorganic salts and the like. Other culture conditions such as culture temperature, CO2 concentration and the like can be set as appropriate. While the culture temperature is not particularly limited, for example, it is about 30-40° C., preferably about 37° C. The CO2 concentration is, for example, about 1-10%, preferably about 5%. Other conditions such as the number of cells to be cultured, concentrations of various factors and the like can be appropriately set by methods known per se.
The cell to be used for the preparation of the pulsed cell of the present invention is not particularly limited as long as it is a target antigen and CD1d co-expressing cell. As a target antigen and CD1d co-expressing cell, for example, a treated cell or an untreated cell can be used.
When a treated cell (e.g., transformant) is used as a target antigen and CD1d co-expressing cell, the preparation method of the present invention may include treatment of a cell such that the target antigen and CD1d will be co-expressed in the object cell or the expression of the target antigen and/or CD1d will be enhanced in the target antigen and CD1d co-expressing cell, and obtaining the target antigen and CD1d co-expressing cell. The methodology is the same as for the aforementioned preparation method of the present invention. The object cell may be a cell derived from an individual to be administered with the cell of the present invention (syngeneic cell), a cell derived from an individual allogeneic to an individual to be administered with the cell of the present invention (allogeneic cell), or a cell derived from an individual heterogeneous to an individual to be administered with the cell of the present invention (heterogeneous cell).
On the other hand, when an untreated cell (e.g., non-transformant) is used as a target antigen and CD1d co-expressing cell, the preparation method of the present invention may further include recovering the target antigen and/or CD1d co-expressing cell from a biological sample obtained from an individual to give the target antigen and CD1d co-expressing cell. Examples of the biological sample obtained from an individual include biological samples such as tumor mass, peripheral blood, liver, lymph node, spleen and the like. Examples of the cell obtained from an individual include abnormal cells such as tumor cells (e.g., leukemia cell), virus-infected cell and the like (the abnormal cell may be of the same type as the cell of the present invention). The individual may be of the same type as the aforementioned animal species. The individual may also be the same as or different from the individual to be administered with the cell of the present invention.
When an untreated cell (cell itself obtained from an individual) is used as a target antigen and CD1d co-expressing cell, it is possible to identify where necessary using a part of the biological sample containing the non-transformant whether or not the cell contained in the sample expresses both a target antigen and CD1d. The present invention also provides such identification method. The present inventors first found that a target antigen and CD1d co-expressing cell pulsed with a CD1d ligand is highly useful for an immunotherapy. Without such finding by the present inventors, there is no motivation to intentionally identify a target antigen and CD1d co-expressing cell (particularly, a co-expressing cell obtained from an individual) that can be used for the method developed by the present inventors. When a tumor is obtained as a biological sample, the tumor antigen is considered to be naturally expressed in a cell contained in the sample. In such a case, therefore, it is not always necessary to confirm expression of the tumor antigen in the identification method of the present invention, and confirmation only of the CD1d expression suffices. The same applies to other target antigens.
Therefore, the identification method of the present invention may include measurement of expression of CD1d or expressions of target antigen and CD1d in the object cell. Examples of the object cell include treated cell and untreated cell, and existing cell and novel cell. Examples of the object cell and/or a cell obtained from an individual include abnormal cells such as tumor cell, virus-infected cell and the like (the abnormal cell may be of the same type as the cell of the present invention).
The expression of the target antigen and CD1d can be measured by a method known per se and using, for example, plural primers (e.g., primer pair(s)) that can amplify target antigen and/or CD1d, nucleic acid probe that can detect target antigen and/or CD1d, or an antibody to target antigen and/or CD1d.
The preparation method of the present invention is useful, for example, for the preparation of the cell of the present invention having the above-mentioned various advantages. The identification method of the present invention is useful, for example, for screening for a cell necessary for preparation of the pulsed cell of the present invention.
When used in the present specification, a vector that expresses at least a target antigen means a vector that expresses a target antigen alone, or a vector that expresses a target antigen and other useful factors. Examples of the vector that expresses at least a target antigen include a target antigen expression vector and a target antigen and CD1d co-expression vector.
The vector that expresses at least CD1d means a vector that expresses a vector that expresses CD1d alone, and a vector that expresses CD1d and other useful factors. Examples of the vector that expresses at least CD1d include a CD1d expression vector and a target antigen and CD1d co-expression vector.
The 1 or 2 vectors that express at least a target antigen and CD1d means a single vector that expresses both a target antigen and CD1d, or a combination of a vector that expresses at least a target antigen and a vector that expresses at least CD1d. Examples of the 1 or 2 vectors that express at least a target antigen and CD1d include a target antigen and CD1d co-expression vector and a combination of a target antigen expression vector and a CD1d expression vector.
The present invention also provides such a co-expression vector.
The co-expression vector of the present invention may contain a first polynucleotide encoding a target antigen and a second polynucleotide encoding CD1d. The co-expression vector of the present invention may also contain a promoter functionally linked to the above-mentioned first and the second polynucleotides. The functional linkage of the promoter means that the promoter is bound to the polynucleotide in such a manner as to permit expression of a factor encoded by the polynucleotide under regulation.
To be more precise, the co-expression vector of the present invention may be a polycistronic mRNA expression vector. The polycistronic mRNA expression vector may contain a first polynucleotide and second polynucleotide conjugate, which enables expression of a target antigen and CD1d polycistronic mRNA, and a promoter functionally linked to the conjugate.
The co-expression vector of the present invention may also be a non-polycistronic mRNA expression vector. The non-polycistronic mRNA expression vector may contain a first polynucleotide and a first promoter functionally linked to the polynucleotide, as well as a second polynucleotide and a second promoter functionally linked to the polynucleotide.
The promoter to be used for a co-expression vector is not particularly limited as long as it can function in a cell to be introduced into. Examples thereof include virus promoters such as SV40 derived early promoter, cytomegalovirus LTR, Rous sarcoma virus LTR, MoMuLV derived LTR, adenovirus derived early promoter and the like, promoters of mammalian constituent protein gene such as β-actin gene promoter, PGK gene promoter, transferrin gene promoter and the like, and the like can be mentioned. In addition, a promoter specific to a cell to be introduced into may also be used. Examples of such promoter include abnormal cell specific promoters such as tumor cell specific promoter, virus-infected cell specific promoter (e.g., virus late promoter) and the like. Not only the co-expression vector of the present invention but also the expression vector to be used in the present invention can have such a promoter.
The co-expression vector preferably contains a transcription termination signal, i.e., terminator region, at the downstream of oligo(poly)nucleotide encoding a nucleic acid molecule. It may further contain a selection marker gene (gene imparting resistance to pharmaceutical agents (e.g., tetracycline, ampicillin, kanamycin, hygromycin, phosphinothricin), gene complementing auxotrophic mutation etc.) for selecting a transformed cell.
A vector to be the basic skeleton of a co-expression vector may be, for example, a plasmid or a virus vector (e.g., vector derived from virus such as adenovirus, retrovirus, adeno-associated virus, herpesvirus, vaccinia virus, poxvirus, polio virus, sindbis virus, Hemagglutinating Virus of Japan, lentivirus and the like).
The co-expression vector of the present invention is, like the aforementioned agent of the present invention, useful, for example, as a pharmaceutical agent, and for the activation of immune cells and preparation of the cell of the present invention.
The present invention provides an agent (or composition) containing the cell of the present invention.
The animal species to which the agent of the present invention is administered may be the same as the animal species from which the target antigen and CD1d co-expressing cell derives. Thus, the agent of the present invention can achieve immunization with a syngeneic, allogeneic or heterogeneous cell in the immunization with the cell of the present invention.
The agent of the present invention may contain, in addition to the cell of the present invention pulsed with a CD1d ligand, any carrier, for example, pharmaceutically acceptable carriers and/or adjuvant. Examples of the pharmaceutically acceptable carrier include, but are not limited to, diluents such as water, saline and the like, and the like. While the adjuvant is not particularly limited as long as it can enhance the antigenicity of the target antigen, for example, BCG, trehalose dimycolate (TDM), Merck65, AS-2, aluminum phosphate, aluminum hydroxide, keyhole limpet hemocyanin, dinitrophenol, dextran and TLR ligand (e.g., lipopolysaccharide (LPS), CpG) can be mentioned.
The agent of the present invention is useful, for example, as a pharmaceutical agent or reagent. To be more precise, the agent of the present invention is useful for the prophylaxis or treatment of neoplastic diseases or infections, or immunotherapy (e.g., activation of immunocytes such as NK/NKT cells, T cells and the like). Examples of the neoplastic diseases possibly prevented or treated by the agent of the present invention include tumors in the aforementioned tissues and cell types, such as solid tumor (e.g., epithelial tumor, non-epithelial tumor), and tumors in hematopoietic tissues. To be more precise, examples of the solid tumor possibly prevented or treated by the agent of the present invention include digestive cancer (e.g., gastric cancer, colon cancer, colorectal cancer, rectal cancer), lung cancer (e.g., small cell cancer, non-small cell cancer), pancreatic cancer, kidney cancer, liver cancer, thymus, spleen, thyroid cancer, adrenal gland, prostate cancer, urinary bladder cancer, ovarian cancer, uterine cancer (e.g., endometrial carcinoma, cervical cancer), bone cancer, skin cancer, sarcoma (e.g., Kaposi's sarcoma), melanoma, blastoma (e.g., neuroblastoma), adenocarcinoma, carcinoma planocellulare, non-carcinoma planocellulare, brain tumor, as well as recurrence and metastasis of these solid tumors. Examples of the tumor in the hematopoietic tissue possibly prevented or treated by the agent of the present invention include leukemia (e.g., acute myeloid leukemia (AML), chronic myelocytic leukemia (CML), acute lymphocytic leukemia (ALL), chronic lymphocytic leukemia (CLL), adult T cell leukemia (ATL), myelodysplastic syndrome (MDS)), lymphoma (e.g., T lymphoma, B lymphoma, Hodgkin's lymphoma), myeloma (multiple myeloma), as well as recurrence of these tumors. Examples of the infections possibly treated by the agent of the present invention include infections caused by the aforementioned pathogens.
The present inventors have also found at this time that a target antigen and CD1d co-expressing cell pulsed with a CD1d ligand can have an ability to simultaneously induce activation of NK/NKT cells and T-cell immune response. It is known that NK/NKT cells have MHC class I-non-expressing cell as a good target, and T cells have MHC class I-expressing cell as a good target. Accordingly, the agent of the present invention is advantageous in that an effect on various target antigen-expressing cells can be expected.
While the dose of the agent of the present invention varies depending on the kind of the pulsed cell of the present invention (pulsed with a CD1d ligand), expression levels of the target antigen and CD1d in the pulsed cell of the present invention, administration mode, severity of disease, animal species of the subject of administration, and acceptability, body weight, age and the like of the subject of administration and cannot be generalized, cells in a number that affords a desired immunoactivity can be appropriately administered.
The present invention also provides an agent for preparing a cell for inducing immunity to a target antigen, which contains a vector that expresses at least CD1d. The agent can be prepared and used according to the aforementioned preparation method of the present invention and the aforementioned agent of the present invention.
The present invention provides a kit containing the substance and/or cell disclosed in the present specification.
To be more precise, the kit of the present invention is largely divided into a kit containing, as an essential constituent component, an expression vector or a target antigen (kit I), a kit containing, as an essential constituent component, a CD1d ligand (kit II), and a kit containing, as an essential constituent component, an expression measurement means (kit III).
The kit I of the present invention may contain, for example, any of (a)-(e) below:
(a) a combination of (a1) a vector that expresses at least a target antigen, and (a2) a vector that expresses at least CD1d;
(b) a combination of (b1) a target antigen-expressing cell, and (b2) a vector that expresses at least CD1d;
(c) a combination of (c1) a CD1d-expressing cell, and (c2) a vector that expresses at least a target antigen;
(d) a combination of (d1) a vector that expresses at least CD1d, and (d2) a target antigen;
(e) a combination of (e1) a CD1d-expressing cell, and (e2) a target antigen.
The kit II of the present invention may contain, for example, any of (a)-(i) below:
(a) a combination of (a1) a CD1d ligand, and (a2) a vector that expresses at least a target antigen;
(b) a combination of (b1) a CD1d ligand, and (b2) a target antigen-expressing cell;
(c) a combination of (c1) a CD1d ligand, and (c2) a target antigen;
(d) a combination of (d1) a CD1d ligand, and (d2) a target antigen and CD1d co-expressing cell;
(e) a combination of (e1) a CD1d ligand, (e2) a target antigen-expressing cell, and (e3) a vector that expresses at least CD1d;
(f) a combination of (f1) a CD1d ligand, (f2) a CD1d-expressing cell, and (f3) a vector that expresses at least a target antigen;
(g) a combination of (g1) a CD1d ligand, and (g2) 1 or 2 vectors that express at least a target antigen and CD1d;
(h) a combination of (h1) a CD1d ligand, (h2) a vector that expresses at least CD1d, and (h3) a target antigen;
(i) a combination of (i1) a CD1d ligand, (i2) a CD1d-expressing cell, and (i3) a target antigen.
The kit III of the present invention may contain a means capable of measuring the expression of a target antigen, and a means capable of measuring the expression of CD1d. Examples of the means capable of measuring the expression of a target antigen include antibody, nucleic acid probe and plural primers (e.g., primer pair(s)).
The promoter used in an expression vector, a vector to be the basic skeleton and other factors for the kit of the present invention may be the same as those used for the co-expression vector of the present invention.
In (b) of the kit I of the present invention, and (b), (e) in the kit II of the present invention, the target antigen-expressing cell may be a cell that expresses a target antigen and does not express CD1d, or a cell that expresses both a target antigen and CD1d. In (c) of the kit I of the present invention, and (f) in the kit II of the present invention, the CD1d-expressing cell may be a cell that expresses CD1d and does not express a target antigen, or a cell that expresses both a target antigen and CD1d.
(a), (d) in the kit I of the present invention, and (a), (c), (g), (h) in the kit II of the present invention may contain any cell. Examples of such cell include a cell that does not express both the target antigen and CD1d, a cell that expresses the target antigen and does not express CD1d, a cell that expresses CD1d and does not express the target antigen, or a cell that expresses both a target antigen and CD1d.
The kit of the present invention may further contain the aforementioned adjuvant.
The kit of the present invention may also contain a reagent that can confirm activation of an immunocytes. Examples of the reagent that can confirm activation of immunocytes include a reagent for the measurement of the number of one or more immunocytes selected from the group consisting of NK cell, NKT cell and T cell, and a reagent for the measurement of a substance specific to the activated immunocyte.
The reagent for the measurement of the number of immunocytes may contain, for example, specific antibodies against cell surface markers (e.g., Vα24, Vβ11) of NK cell, NKT cell and T cell, or nucleic acid probes capable of detecting transcription products encoding the markers or plural primers (e.g., primer pair(s)) capable of amplifying them.
The reagent for the measurement of a substance specific to the activated immunocyte may contain, for example, antibodies against substances (e.g., IFN-γ, perforin, granzyme B) specific to activated NK cell, NKT cell or T cell, or nucleic acid probes capable of detecting transcription products encoding the substances or plural primers (e.g., primer pair(s)) capable of amplifying them.
The kit of the present invention is, like the aforementioned agent of the present invention, useful, for example, as a kit for a pharmaceutical agent, or a kit for activation of immunocyte, or a kit for the preparation or identification of the cell of the present invention.
The contents disclosed in any publication cited in the present specification, including patents and patent applications, are hereby incorporated in their entireties by reference, to the extent that they have been disclosed herein.
The present invention is explained in more detail in the following by referring to Examples, which are mere exemplifications and do not limit the scope of the present invention.
(Preparation of Tumor Cell Pulsed with α-GalCer)
As the tumor cell line pulsed with α-GalCer, mouse-derived melanoma cell line B16 and mouse-derived T lymphoma cell line EL4 were used. α-GalCer was added to B16 (2×104 cells/ml) or EL4 (1×105 cells/ml) to a concentration of 500 ng/ml, and the cells were cultured at 5% CO2, 37° C. As the culture medium, 10% FCS-containing RPMI (10 ml) was used. After culturing for 2 days, B16 or EL4 pulsed with α-GalCer was washed 4 times with PBS, and then collected.
(Preparation of Dendritic Cell Pulsed with α-GalCer)
Bone marrow cells were collected from the femur and shin bone of wild-type mice (C57BL/6, 6- to 8-week-old, female), and CD4, CD8, B220 or I-Ab positive cells were removed using antibodies and complements. The obtained cells were adjusted to 1×106 cells/ml with GM-CSF (10 ng/ml) and 5% FCS-containing RPMI, and cultured in a 24 well plate. The medium was changed every two days, and α-GalCer was added to 100 ng/ml on day 6. On day 7, LPS (100 ng/ml) was further added, and the dendritic cells were matured. The cells were collected on day 8, and washed with PBS.
The mononuclear cells were prepared from the spleen and liver. Spleen was removed from wild-type mice (C57BL/6, 6- to 8-week-old, female), filtered with a cell strainer, red blood cells were hemolyzed with ACK lysing buffer, and the mononuclear cells were washed to give spleen-derived mononuclear cells. In addition, the liver was removed from wild-type mice or Jα281 gene deficient mice (Vα14+NKT cell deficient mouse: e.g., see Fujii et al., The Journal of Experimental Medicine 198: 267-279 (2003), and Fujii et al., The Journal of Experimental Medicine 199: 1607-18 (2004)), filtered with a stainless mesh, and a mononuclear cell layer was separated using a percoll by the density gradient centrifugation method to give liver-derived mononuclear cells.
B16 melanoma cells were adjusted to 5×105/200 μl with PBS, and intravenously administered to mice (C57BL/6, 6- to 8-week-old, female) from the tail vein. After 2 weeks, the lung was removed from the mice and the number of metastatic B16 cells in the lung was measured.
B16 or EL4 pulsed with α-GalCer, or dendritic cell (control) pulsed with α-GalCer was co-cultured with a mononuclear cell (fraction containing NKT/NK cell) derived from the liver of a wild-type mouse or Ja281 gene deficient mouse (Va14+NKT cell deficient mouse), and the level of IFN-γ in the culture supernatant was measured by ELISA and using an anti-IFN-γ antibody. Since IFN-γ is a substance specifically produced by activated NKT/NK cells, the level of IFN-γ in the culture supernatant can be an index of activated NKT/NK cells. In addition, an experiment similar to the above was performed using B16 and EL4 into which a CD1d expression retrovirus vector (produced by using mouse CD1d gene (GenBank Accession No.: NM-007639) had been introduced).
As a result, the both of B16 and EL4 pulsed with α-GalCer activated NKT/NK cells (
From the foregoing, it has been clarified that tumor cells pulsed with a CD1d ligand activate NKT/NK cells in vitro in a CD1d expression level dependent manner.
B16 (5×105 cells) or dendritic cells (control, 1×106 cells) pulsed with α-GalCer were intravenously administered to mice (C57BL/6, 6- to 8-week-old, female) from the tail vein. Two days after the administration, the spleen was isolated from the mice, filtered with a cell strainer, red blood cells were hemolyzed with ACK lysing buffer, and the splenocytes were adjusted with 5% FCS-containing RPMI. (3×105 cells/well) was cultured for 16 hr in the presence of α-GalCer in the same manner as in Example 1 and the level of IFN-γ in the culture supernatant was measured by ELISPOT and using an anti-IFN-γ antibody. In addition, an experiment similar to the above was performed using B16 into which a CD1d expression retrovirus vector had been introduced.
As a result, the dendritic cells pulsed with α-GalCer induced α-GalCer reactive IFN-γ producing NKT cells (
From the foregoing, it has been clarified that tumor cells pulsed with a CD1d ligand activate NKT cells in vivo in an α-GalCer concentration dependent manner.
The antitumor effect of IFN-γ production by tumor cells pulsed with a CD1d ligand was examined. B16 or CD1d expression enhanced B16, or B16 pulsed with α-GalCer or CD1d expression enhanced B16 pulsed with α-GalCer (both at 5×105 cells) was intravenously administered to mice. Then, after 14 days from the administration, the lung was removed from the mice, and the antitumor effect was evaluated.
As a result, the metastatic model mice administered with B16 or CD1d expression enhanced B16 showed a tumor increase, but the tumor apparently disappeared in the model mice administered with B16 pulsed with α-GalCer or CD1d expression enhanced B16 pulsed with α-GalCer (
From the foregoing, it has been clarified that tumor cells pulsed with a CD1d ligand show an antitumor effect by an enhanced spontaneous immune response.
B16 (5×105 cell) was subcutaneously administered to the mouse (wild-type mouse) administered with CD1d expression enhanced B16 pulsed with α-GalCer, whose tumor was confirmed to have disappeared in Example 3. In addition, B16 (1×105 cells) was subcutaneously administered to a CD8 deficient mouse (purchased from Jackson Laboratory) administered with CD1d expression enhanced B16 pulsed with α-GalCer, and the tumor resistance of these mice was compared.
As a result, the wild-type mouse challenged with B16 showed resistance to the subcutaneously administered tumor. However, the tumor could not be eliminated in the CD8 deficient mouse (
From the foregoing, it has been clarified that the method developed by the present inventors can derive CTL to a tumor antigen expressed in the tumor.
To compare CD1d expression revels in various tumor cell lines, the CD1d expression levels in mouse-derived melanoma cell line B16, mouse-derived T lymphoma cell line EL4, mouse-derived plasma cell (B cell) line J558, mouse-derived monocytic leukemia cell line WEHI-3B, and these cell lines harboring a CD1d gene introduced by a retrovirus were measured by real time RT-PCR and flow cytometry.
As a result, the expression of CD1d mRNA was confirmed in all tumor cell lines, and the expression of CD1d mRNA in tumor cell lines, into which CD1d gene had been introduced, showed a remarkable increase (
From the foregoing, it has been clarified that these tumor cells express CD1d protein and that the expression of CD1d protein is remarkably enhanced in a cell having an introduced CD1d gene.
Then, whether or not CD1d-expressing tumor cell can be a target of activated NKT cells was considered. To be specific, a tumor cell was pulsed with α-GalCer for 48 hr, and labeled with 51Cr. After washing, the obtained tumor cell was co-cultured with liver-derived mononuclear cells, and the amount of released 51Cr was measured, based on which the cytotoxic activity was measured.
As a result, CD1d forcibly expressing tumor cell pulsed with α-GalCer released a higher amount of 51Cr than a tumor cell not pulsed with α-GalCer. This shows that a tumor cell pulsed with a CD1d ligand activates NKT cells, and then is killed as a target of the NKT cells.
From the foregoing, it has been clarified that a cell pulsed with a CD1d ligand can be a target of NKT cells.
Then, whether or not CD1d-expressing tumor cell can be a target of activated NKT cells was considered. To be specific, CD1d forcibly expressing EL4 pulsed with α-GalCer was labeled with CFSE (carboxyfluorescein succinimidyl ester) and administered to a mouse. After 10 hr, splenocytes were collected from the mouse, and CFSE uptake by dendritic cell was measured using a flow cytometer.
As a result, it has been confirmed that CD11c+ (particularly, CD11c+CD8a+) dendritic cell uptakes CFSE (
From the foregoing, it has been suggested that the administered tumor cell is killed by activation of NK/NKT cells, and the antigen is captured and presented by the adjacent dendritic cell, whereby the antitumor immunity can be achieved.
NKT cells are a cell group connecting natural immunity and acquired immunity via maturation of dendritic cells. In this study, it has been demonstrated that when a CD1d ligand is presented by a CD1d-expressing tumor, strong in vivo activation of IFN-γ producing NKT cells and NK cells can be sustained, that the tumor cell is killed by the activation of NK/NKT cells, and the antigen is captured and presented by the adjacent dendritic cell, and that the acquired immunity to the antigen can be later induced. Once the acquired immunity is induced, tumor immunity is input in the memory. In this way, a CD1d-expressing tumor cell pulsed with a ligand can induce natural immunity in the short run and acquired immunity in the long run, which is considered a highly effective method for the tumor immunotherapy in the future.
Hence, the achievements of the studies by the present inventors and the items derived from the achievements are as follows.
1) The present inventors successfully activated NK/NKT cells in vivo by using a tumor cell pulsed with a CD1d ligand in vitro. Single administration of a CD1d ligand conventionally employed activates NK/NKT cells only temporarily. However, the present method activates these cells in a sustained manner, which in turn enables production of IFN-γ on a long-term basis.
2) The present method can induce cytotoxic T cells to the tumor antigen expressed in the tumor. Therefore, the method can establish acquired immunity and memory immunity to the tumor.
3) NK/NKT cells and T cells were successfully further activated by strong expression of a CD1d molecule in a tumor cell by transgene, and pulsing with a CD1d ligand.
4) The present method is highly convenient since it can be easily performed once a tumor cell is harvested.
5) According to the method developed by the present inventors, not only an immunotherapy using tumor cells of leukemia and the like, but also an immunotherapy using virus-infected cells that express specific antigen like tumor cells and the like become possible.
In the present invention, a target antigen and CD1d co-expressing cell acquires, after pulsing with a CD1d ligand, an immunity activating ability for a target antigen. The thus-obtained cell is useful for the prophylaxis or treatment or immunotherapy of neoplastic diseases (e.g., solid tumor containing epithelial tumor or nonepithelial tumor, leukemia, lymphoma, myeloma) or infections (e.g., virus infections). The production method, identification method and kit of the present invention are useful for the preparation of such cells.
This application is based on a patent application No. 2006-045193 filed Feb. 22, 2006 in Japan, the contents of which are incorporated herein by this reference.
Number | Date | Country | Kind |
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2006-045193 | Feb 2006 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/053209 | 2/21/2007 | WO | 00 | 10/29/2008 |