Patent Description:
Cancer is a serious disease that accounts for a major cause of death. However, therapeutic needs therefor have not yet been met In recent years, in order to overcome the problem of conventional chemotherapy that causes damage even to normal cells, studies have been intensively conducted regarding cancer therapy using molecularly targeted drugs, in which a drug targeting a specific molecule that is expressed specifically in a cancer cell is designed, and the therapy is then carried out using the drug.

CDH3 is a cell surface antigen that has been identified as a target thereof. CDH3 is a membrane protein that has been discovered as a molecule that is calcium-dependently associated with hemophilic cell adhesion (<NPL>). A protein, which has cadherin repeats consisting of approximately <NUM> amino acid residues having high homology to one another, is referred to as a "cadherin superfamily," and CDH3 is a main member of the cadherin superfamily.

An increase in the expression of CDH3 in certain types of cancer cells has been reported Thus, cancer therapy, in which an antibody against cancer cells with higher expression of CDH3 in cancer tissues than in normal tissues is used, has been studied (<CIT> and <CIT>).

A large number of antibody drugs have already been placed on the market as molecular-targeted drugs, and a majority of the drugs have antibody-dependent cellular cytotoxicity (ADCC) as a principal mode of action. However, their drug effects are not necessarily sufficient, and thus, technology development is proceeding towards the achievement of a stronger antitumor effect.

An effective means for enhancing the antitumor ability of an antibody is the binding of the antibody to a drug having strong toxicity (toxin). If toxin alone were administered to a patient, it would also affect normal tissues, and thereby, it could not be an effective therapeutic means. However, as a result of the binding of the toxin to an antibody that binds to a tumor cell-specific antigen, the toxin is able to achieve a capacity of killing only tumor cells, while it does not affect normal tissues. Such a drug is referred to as an antibody drug conjugate (ADC). That is to say, a toxin shows no toxicity in a state in which it binds to an antibody. However, when a certain type of antibody binds to a target antigen, it is incorporated into the cell thereof and is then decomposed by a lysosome. Accordingly, the certain type of antibody, to which a toxin binds, is incorporated into the cell, and it is then decomposed therein, so that the toxin is released. As a result, the toxin is expressed only in a specific cell, and the cell is then killed by the effect thereof.

Examples of a drug ingredient used in ADC include bacterial protein toxins such as diphtheria toxin, vegetable protein toxins such as ricin, and low-molecular-weight toxins such as auristatin, maytansinoid or calichemicin and the derivatives thereof.

In ADC, a drug that binds to an antibody circulates in the blood and then accumulates in a target tumor, and thereafter, it exhibits its drug effects. The release of a drug in sites other than tumor sites (the release from the antibody) is not necessarily preferable because it is likely to cause side effects. That is, a drug that binds to an antibody is preferably designed such that it is removed from the antibody after it has been incorporated into a cell. In recent years, from the aforementioned viewpoint, a drug (T-DM1) in which a toxin binds to trastuzumab via a non-cleavable linker (SMCC) has been developed by Genentech. Clinical tests have been carried out on the developed drug, and extremely high clinical effects have been obtained. In addition, an antibody drug conjugate, in which an antibody is bound to a drug ingredient via a cleavable linker, has been developed. For example, the development of an antibody drug conjugate, in which a drug is bound to a HuN901 antibody via a disulfide linker (SPP), that targets cancer expressing NCAM antigen, has been promoted by ImmunoGen.

As described above, the concept of cancer therapy using ADC is known. In the present technical field, there is a demand for other drugs for therapy of various cancers such as lung cancer and colon cancer. An example of a drug that is particularly useful for this purpose is a drug conjugate comprising an anti-CDH3 antibody, which has significantly low toxicity but has advantageous therapeutic effectiveness. These and other restrictions and previous problems can be solved by the present invention.

It is an object to be solved by the present invention to provide a drug conjugate comprising an anti-CDH3 antibody that efficiently kills cancer cells expressing CDH3.

As a result of intensive studies directed towards achieving the aforementioned object, the present inventors have found that an immune complex formed by binding an antibody against CDH3 to a chemotherapeutic agent shows strong cellular cytotoxicity against a cancer cell line that expresses CDH3, thereby completing the present invention, which is described in the claims.

Specifically, according to the present invention, there is provided an immune complex formed by binding an antibody against CDH3 or a fragment thereof having CDH3 binding ability to a chemotherapeutic agent.

Preferably, in the immune complex of the present invention, the antibody against CDH3 or the fragment thereof having CDH3 binding ability shows cytotoxicity against CDH3-expressing cells.

Preferably, the antibody against CDH3 is produced by antibody-producing cells that are obtained from immunocytes, to which CDH3 or a CDH3-expressing cell has been administered as an immunogen.

Preferably, the antibody is a human antibody.

Preferably, the antibody comprises the amino acid sequences shown in SEQ ID NOs <NUM>, <NUM> and <NUM> as H chains thereof, and comprises the amino acid sequences shown in SEQ ID NOs. <NUM>, <NUM> and <NUM> as L chains thereof.

Preferably, the antibody comprises the amino acid sequences shown in SEQ ID NOs. <NUM>, <NUM> and <NUM> as H chains thereof, and comprises the amino acid sequences shown in SEQ ID NOs. <NUM>, <NUM> and <NUM> as L chains thereof.

Preferably, the antibody has an H chain consisting of an amino acid sequence having sequence identity of at least <NUM>% with the above described amino acid sequences of the H chains of the aforementioned antibody of the present invention.

Preferably, the CDH3 is the CDH3 of a mammal.

Preferably, the CDH3 is selected from the CDH3s of primates.

Preferably, the CDH3 is selected from the CDH3s of human.

Preferably, the CDH3 is expressed on the surface of a cell.

Preferably, the antibody fragment having CDH3 binding ability is Fab, F(ab')<NUM>, or scFv.

The chemotherapeutic agent is the cytotoxic substance DM1.

Preferably, <NUM> to <NUM> DM1s are bound to a single molecule of the antibody against CDH3 or the fragment thereof having CDH3 binding ability.

The antibody against CDH3 or the fragment thereof having CDH3 binding ability is bound to the chemotherapeutic agent via a linker.

Preferably, the antibody against CDH3 or the fragment thereof having CDH3 binding ability is bound to the chemotherapeutic agent via an intramolecular disulfide bond in the Fc region of the antibody.

Preferably, the antibody against CDH3 or the fragment thereof having CDH3 binding ability is bound to the chemotherapeutic agent as a result of genetic engineering modification of the Fc region of the antibody.

The linker used to bind the antibody against CDH3 or the fragment thereof having CDH3 binding ability to the chemotherapeutic agent is a divalent reactive crosslinking reagent.

The linker is selected from the group consisting of N-succinimidyl <NUM>-(maleimidomethyl)cyclohexanecarboxylate (SMCC), N-succinimidyl-<NUM>-(N-maleimidomethyl)-cyclohexane-<NUM>-carboxy-(<NUM>-amidocaproate) (LC-SMCC).

Preferably, the linker is cleaved by protease.

Preferably, the linker comprises val-cit.

Moreover, according to the present invention, there is provided a pharmaceutical composition for treating cancer characterized by overexpression of CDH3, which comprises the immune complex of the present invention.

Preferably, the pharmaceutical composition of the present invention has anticancer action.

Preferably, the cancer is selected from among colorectal cancer, non-small-cell lung cancer, breast cancer, cancer of the head and neck, ovarian cancer, lung cancer, invasive bladder cancer, pancreatic cancer, metastatic brain tumor, thyroid cancer, squamous cell carcinoma of the head and neck, squamous cell carcinoma of the esophagus, squamous cell carcinoma of the lung, squamous cell carcinoma of the skin, melanoma, mammary cancer, pulmonary adenocarcinoma, squamous cell carcinoma of the uterine cervix, squamous cell carcinoma of the pancreas, squamous cell carcinoma of the colon, squamous cell carcinoma of the stomach, prostatic cancer, osteosarcoma, and soft tissue sarcoma.

The immune complex formed by binding an anti-CDH3 antibody to a chemotherapeutic agent, which is provided by the present invention, shows stronger cellular cytotoxicity against cancer cell lines that express CDH3, than an antibody to which a chemotherapeutic agent is not bound. Therefore, it is anticipated that when the immune complex of the present invention is administered to a patient having cancer cells that express CDH3, it will exhibit high anticancer action thereon. That is to say, the immune complex of the present invention is useful as an anticancer agent.

Hereinafter, the present invention will be described more in detail.

The immune complex of the present invention is provided as a drug conjugate comprising an anti-CDH3 antibody that efficiently kills cancer cells.

As an antigen used to produce the antibody of the present invention, CDH3 or a partial peptide thereof can be used. As an example, a soluble CDH3 protein or the like can be used, but the examples of the antigen are not limited thereto.

The antibody used in the present invention is a monoclonal antibody. The antibody of the present invention can be produced by any one of various methods. The method for producing the antibody is well known in the present technical field [see, for example,<NPL>)].

To produce a polyclonal antibody, CDH3 or a partial peptide thereof is administered as an antigen to a mammal such as a rat, a mouse or a rabbit. The amount of an antigen per animal is <NUM> to <NUM> if an adjuvant is not used, and is <NUM> to <NUM>µg when an adjuvant is used. Examples of an adjuvant used herein include a Freund's complete adjuvant (FCA), a Freund's incomplete adjuvant (FIA), and an aluminum hydroxide adjuvant. Immunization is mainly carried out by injecting the antigen into the vein, subcutis, abdominal cavity, etc. In addition, immunization intervals are not particularly limited, and the immunization is carried out <NUM> to <NUM> times, and more preferably <NUM> to <NUM> times, at intervals of several days to several weeks, and preferably at intervals of <NUM> to <NUM> weeks. Thereafter, six to sixty days after the final immunization, an antibody titer is measured by enzyme-linked immunosorbent assay (ELISA), enzyme immunoassay (EIA), radio immunoassay (RIA), etc. On the day on which the animal exhibits the greatest antibody titer, blood is collected, and antiserum is then obtained. When purification of an antibody from the antiserum is needed, the antibody can be purified by selecting an appropriate method from known methods such as an ammonium sulfate fractionation method, ion exchange chromatography, gel filtration and affinity chromatography, or by a combined use of these methods.

To produce a monoclonal antibody, first of all, CDH3 or a partial peptide thereof is administered as an antigen to a mammal such as a rat, a mouse or a rabbit. The amount of an antigen per animal is <NUM> to <NUM> if an adjuvant is not used, and is <NUM> to <NUM>µg when an adjuvant is used. Examples of such an adjuvant used herein include a Freund's complete adjuvant (FCA), a Freund's incomplete adjuvant (FIA), and an aluminum hydroxide adjuvant. Immunization is mainly carried out by injecting the antigen into the vein, subcutis or abdominal cavity. In addition, immunization intervals are not particularly limited, and the immunization is carried out <NUM> to <NUM> times, and more preferably <NUM> to <NUM> times, at intervals of several days to several weeks, and preferably at intervals of <NUM> to <NUM> weeks. Thereafter, one to sixty days, and preferably one to fourteen days after the final immunization, antibody-producing cells are collected. Examples of the antibody-producing cells include splenic cells, lymph node cells, and peripheral blood cells. Among these cells, splenic cells or local lymph node cells are preferable.

To obtain cell fusion hybridomas, cell fusion of antibody-producing cells with myeloma cells is carried out. As myeloma cells to be fused with antibody-producing cells, commercially available cells that have been established from animals such as mice can be used. As an established cell line used herein, a cell line, which has drug selectivity, cannot survive in a HAT selection medium (containing hypoxanthine, aminopterin and thymidine) in an unfused state, and can survive therein only in a state in which it is fused with antibody-producing cells, is preferable. Examples of the myeloma cells include mouse myeloma cell lines such as P3X63-Ag. U1 (P3U1) or NS-<NUM>.

Subsequently, the aforementioned myeloma cells are fused with antibody-producing cells. For cell fusion, antibody-producing cells (<NUM> × <NUM><NUM> to <NUM> × <NUM><NUM> cells/ml) are mixed with myeloma cells (<NUM> × <NUM><NUM> to <NUM> × <NUM><NUM> cells/ml) in an animal cell culture medium containing no serum, such as DMEM or a RPMI-<NUM> medium (wherein the cell ratio between the antibody-producing cells and the myeloma cells is preferably <NUM> : <NUM>), and a fusion is then carried out in the presence of a cell fusion promoter. As a cell fusion promoter, polyethylene glycol with a mean molecular weight of <NUM> to <NUM> Daltons or the like can be used. In addition, antibody-producing cells may also be fused with myeloma cells using a commercially available cell fusion apparatus that utilizes electrical stimulation (e.g. electroporation).

After completion of the cell fusion treatment, hybridomas of interest are selected from the resulting cells. As a selection method, a cell suspension is appropriately diluted, for example, with a fetal bovine serum-containing RPMI-<NUM> medium, and the resulting cell suspension is inoculated at a cell density of approximately <NUM> × <NUM><NUM> cells/well on a microtiter plate. Thereafter, a selection medium is added to each well, and a culture is then carried out, while exchanging the selection medium with a fresh one, as appropriate. As a result, cells growing approximately <NUM> days after initiation of the culture in the selection medium can be obtained as hybridomas.

Thereafter, the presence or absence of an antibody of interest in a culture supernatant of the growing hybridomas is screened. The screening of hybridomas may be carried out according to an ordinary method, and the type of the screening method is not particularly limited. For instance, an aliquot of the culture supernatant of the growing hybridomas contained in the well is collected, and it is then subjected to enzyme immunoassay, radioimmunoassay or the like, so that hybridomas that produce an antibody binding to CDH3 can be screened. The fused cells are cloned according to limiting dilution or the like, and thus, hybridomas can be finally established as cells that produce a monoclonal antibody.

As a method of collecting a monoclonal antibody from the established hybridomas, an ordinary cell culture method, an ascites extraction method or the like can be adopted. In the cell culture method, hybridomas are cultured in an animal cell culture medium, such as a <NUM>% fetal bovine serum-containing RPMI-<NUM> medium, an MEM medium or a serum-free medium, under common culture conditions (e.g. <NUM> and <NUM>% CO<NUM>) for <NUM> to <NUM> days, and thereafter, an antibody is obtained from the culture supernatant.

In the ascites extraction method, approximately <NUM> × <NUM><NUM> hybridomas are administered into the abdominal cavity of an animal of the same species as a mammal, from which the myelomas have been obtained, so as to allow large quantities of hybridomas to grow therein. Then, one or two weeks later, ascites is collected. When purification of an antibody is required in the aforementioned antibody collection methods, known methods, such as ammonium sulfate precipitation, ion exchange chromatography, gel filtration and affinity chromatography, are selected as appropriate, or these methods are used in combination, so as to purify the antibody.

The type of the antibody of the present invention is not particularly limited. Any one of a mouse antibody, a human antibody, a rat antibody, a rabbit antibody, a sheep antibody, a camel antibody, a bird antibody and the like, or recombinant antibodies that have been artificially modified for purposes such as a reduction in heterogenic antigenicity to humans, such as a chimeric antibody or a humanized antibody, may be employed. The recombinant antibody can be produced by known methods. The chimeric antibody is an antibody consisting of the variable regions of the heavy and light chains of an antibody from a mammal other than a human, such as a mouse antibody, and the constant regions of the heavy and light chains of a human antibody. Such a chimeric antibody can be obtained by ligating DNA encoding the variable region of a mouse antibody to the DNA encoding the constant region of a human antibody, then inserting this ligate into an expression vector, and then introducing the vector into a host, so that the chimeric antibody can be generated. A humanized antibody is obtained by transplanting the complementarity determining region (CDR) of an antibody from a mammal other than a human, such as a mouse antibody, into the complementarity determining region of a human antibody, and a general recombination technique has been known. Specifically, a DNA sequence designed to ligate the CDR of a mouse antibody to the framework region (FR) of a human antibody is synthesized from several oligonucleotides produced to have some overlapped portions at the termini thereof according to a PCR method. The obtained DNA is ligated to DNA encoding the constant region of a human antibody, and the thus ligated DNA is then inserted into an expression vector. This expression vector is introduced into a host, so that a humanized antibody can be generated (<CIT>, <CIT>, etc.).

Among host cell systems used for protein expression, many antibody-producing host cell systems are derived from mammals. The manufacturers may preferentially determine a specific host cell system most suitable for a gene product to be expressed. Examples of a common host cell system include, but are not limited to, a CHO-derived cell line (a Chinese hamster ovary cell line), CV1 (a monkey kidney system), COS (a derivative of CV1 to an SV40T antigen), SP2/<NUM> (mouse myelomas), P3x63-Ag3. <NUM> (mouse myelomas), <NUM> (human kidney), and 293T (a derivative of <NUM> to an SV40T antigen). Such a host cell system is available from commercial facilities or the American Tissue Culture Collection (ATCC), or also from institutions that have published some publications.

Preferably, the host cell system is either a CHO-derived cell line comprising defective expression of a dgfr gene, or SP2/<NUM>. (see <NPL>, and<NPL>, respectively. ) Most preferably, the host cell system is DHFR-deficient CHO.

Transfection of a plasmid into a host cell can be achieved by any given technique. Specific examples of such a transfection method include, but are not limited to, transfection (including a calcium phosphate method, a DEAE method, lipofection, and electroporation), a method of introducing DNA utilizing an envelope such as Sendai virus, microinjection, and infection using viral vectors such as retrovirus or adenovirus. (see <NPL>) Introduction of a plasmid into a host by electroporation is most preferable.

Moreover, a method of obtaining a human antibody has also been known. For example, human lymphocytes are sensitized with a desire antigen or a cell expressing such a desired antigen in vitro, and the sensitized lymphocytes are then fused with human myeloma cells, such as U266, so as to obtain a desired human antibody having an activity of binding to an antigen (see <CIT>)). Also, a desired human antibody can be obtained by immunizing a transgenic animal having all repertoires of human antibody genes with a desired antigen (see <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, and <CIT>). Moreover, a technique of obtaining a human antibody by panning using a human antibody library has also been known. For example, the variable region of a human antibody used as a single-chain antibody (scFv) is allowed to express on the surface of phages according to a phage display method, and a phage binding to an antigen can be then selected. By analyzing the selected phage gene, a DNA sequence encoding the variable region of a human antibody binding to the antigen can be determined. If the DNA sequence of the scFv binding to the antigen could be determined, it would be possible to produce a suitable expression vector based on the determined sequence and to obtain a human antibody using the expression vector. These methods have already been well known, and <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, and <CIT> can be referred.

These antibodies may be any one of a monovalent antibody, a divalent antibody and a polyvalent antibody, as long as they are capable of recognizing CDH3. The antibodies may also be low-molecular-weight antibodies such as an antibody fragment, or modified antibodies. Moreover, the antibodies may also be antibody fragments or low-molecular-weight antibodies, such as Fab, Fab', F (ab')<NUM>, Fv, ScFv (single chain Fv) or Diabody, with which an Fc portion is fused. In order to obtain such antibodies, genes encoding these antibodies may be constructed, and they may be then each introduced into expression vectors, and they may be then allowed to express in suitable host cells.

It is also possible to bind various types of molecules such as polyethylene glycol (PEG) to these antibodies and then to use them. Such modified antibodies can be obtained by performing a chemical modification on the obtained antibody. It is to be noted that the method of modifying antibodies is known to a person skilled in the art.

In the immune complex of the present invention, a chemotherapeutic agent is allowed to further bind to the aforementioned antibody, so that the immune complex can be used as a cytotoxic agent. The immune complex of the present invention is allowed to come into contact with, for example, cancer cells that express CDH3, so as to damage the cancer cells.

A preferred embodiment of the immune complex of the present invention includes what is called ADC, in which a cytotoxic substance such as a drug is bound to an antibody.

Examples of the chemotherapeutic agent used in the present invention include duocarmycin, analogs and derivatives of duocarmycin, CC-<NUM>, duocarmycin analogs comprising CBI as a main ingredient, duocarmycin analogs comprising MCBI as a main ingredient, duocarmycin analogs comprising CCBI as a main ingredient, doxorubicin, doxorubicin conjugates, morpholino-doxorubicin, cyanomorpholino-doxorubicin, dolastatin, dolastatin-<NUM>, combretastatin, calicheamicin, maytansine, maytansine analogs, DM1, DM2, DM3, DM4, DMI, auristatin E, auristatin EB (AEB), auristatin EFP (AEFP), monomethyl auristatin E (MMAE), monomethyl auristatin F (MMAF), <NUM>-benzoyl valeric acid AE ester (AEVB), tubulysin, disorazole, epothilone, paclitaxel, docetaxel, SN-<NUM>, topotecan, rhizoxin, echinomycin, colchicine, vinblastine, vindesine, estramustine, cemadotin, eryuterobin, methotrexate, methopterin, dichloromethotrexate, <NUM>-fluorouracil, <NUM>-mercaptopurine, cytosine arabinoside, melphalan, ryuroshin, Liu rosiglitazone Dine, actinomycin, daunorubicin, daunorubicin conjugates, mitomycin C, mitomycin A, carminomycin, aminopterin, tallysomycin, podophyllotoxin, podophyllotoxin derivatives, etoposide, etoposide phosphate, vincristine, taxol, taxol taxotere retinoic acid, butyric acid, N<NUM>-acetyl spermidine and camptothecin, but the examples are not limited thereto.

The ADC of the present invention can be produced by binding the above-described chemotherapeutic agent DM1 to an antibody according to a known method. The antibody may be directly bound to the chemotherapeutic agent via their linking group or the like, or they may be indirectly bound to each other via a linker or another substance.

Examples of the linking group used when the chemotherapeutic agent is directly bound to the antibody include a disulfide bond using an SH group and a bond mediated by maleimide. For instance, an intramolecular disulfide bond in the Fc region of the antibody and the disulfide bond of a drug are reduced, and they are then bound to each other via a disulfide bond. Moreover, there is also a method involving mediation of maleimide. Furthermore, as an alternative method, there is also a method of introducing cysteine into an antibody by genetic technology.

It is also possible to indirectly bind the antibody to the chemotherapeutic agent via another substance (linker). The linker desirably has one or two or more types of functional groups that react with the antibody, or with the chemotherapeutic agent, or with both of them. Examples of such a functional group include an amino group, a carboxyl group, a mercapto group, a maleimide group, and a pyridinyl group.

Examples of the linker described herein include N-succinimidyl <NUM>-(maleimidomethyl)cyclohexanecarboxylate (SMCC), N-succinimidyl-<NUM>-(N-maleimidomethyl)-cyclohexane-<NUM>-carboxy-(<NUM>-amidocaproate) (LC-SMCC), κ-maleimidoundecanoic acid N-succinimidyl ester (KMUA), γ-maleimide butyric acid N-succinimidyl ester (GMBS), ε-maleimidocaproic acid N-hydroxysuccinimide ester (EMCS), m-maleimide benzoyl-N-hydroxysuccinimide ester (MBS), N-(α-maleimidoacetoxy)-succinimide ester (AMAS), succinimidyl-<NUM>-(β-maleimidopropionamide)hexanoate (SMPH), N-succinimidyl <NUM>-(p-maleimidophenyl)butyrate (SMPB), N-(p-maleimidophenyl)isocyanate (PMPI), <NUM>-maleimidocaproyl (MC), maleimidopropanoyl (MP), p-aminobenzyloxycarbonyl (PAB), N-succinimidyl <NUM>(<NUM>-pyridylthio)pentanoate (SPP). N-succinimidyl(<NUM>-iodo-acetyl)aminobenzoate (SLAB), and N-succinimidyl (<NUM>-(<NUM>-pyridylthio)butanoate (SPDB), but the examples are not limited thereto. In addition, this linker may be a peptide linker such as valine-citrulline (Val-Cit) or alanine-phenylalanine (ala-phe), or the aforementioned linkers may be combined with one another, as appropriate, and may be then used. SMCC as well as LC-SMCC are according to the invention.

With regard to the method of binding a chemotherapeutic agent to an antibody, binding can be carried out according to the methods described, for example, in <NPL>), <NPL>),<NPL>), <NPL>), or <CIT>.

Another embodiment of the present invention includes what is called immunotoxin, in which a toxin is bound to an antibody in a chemical or genetic technology.

Examples of the toxin used in the present invention include diphtheria toxin A chain, Pseudomonas endotoxin, ricin chain, deglycosylated ricin A chain, gelonin, and saporin.

Since the immune complex of the present invention exhibits high cellular cytotoxicity, it can be used as a cytotoxic agent. Moreover, the antibody of the present invention can be used as a therapeutic agent for diseases, in which CDH3 is highly expressed The cytotoxic agent and therapeutic agent for such CDH3 highly expressing diseases of the present invention are able to damage cancer cells by allowing them to come into contact with, for example, cancer cells that express cadherin. Examples of the human CDH3 highly expressed disease include colorectal cancer, non-small-cell lung cancer, breast cancer, cancer of the head and neck, ovarian cancer, lung cancer, invasive bladder cancer, pancreatic cancer, metastatic brain tumor, thyroid cancer, squamous cell carcinoma of the head and neck, squamous cell carcinoma of the esophagus, squamous cell carcinoma of the lung, squamous cell carcinoma of the skin, melanoma, mammary cancer, pulmonary adenocarcinoma, squamous cell carcinoma of the uterine cervix, squamous cell carcinoma of the pancreas, squamous cell carcinoma of the colon, squamous cell carcinoma of the stomach, prostatic cancer, osteosarcoma, and soft tissue sarcoma.

The immune complex of the present invention is appropriately combined with a pharmaceutically acceptable carrier, excipient, diluent and the like, as necessary, so that it can be used as a pharmaceutical composition. The pharmaceutical composition of the present invention can be formulated in the form of an injection, for example. The administration amont of the pharmaceutical composition of the present invention depends on the degree of symptoms, age and body weight of a patient, administration method, and the like. The weight of the antibody serving as an active ingredient is generally in the range of approximately <NUM> ng to approximately <NUM>/kg body weight.

The present invention will be more specifically described in the following examples. However, these examples are not intended to limit the scope of the present invention.

In order to obtain a cell line used in screening for an anti-CDH3 antibody, CHO cells expressing the full-length CDH3 were established.

In order to insert the full-length human CDH3 DNA shown in SEQ ID NO. <NUM> into a mammalian expression vector pEF4/myc-HisB (Invitrogen), the DNA was digested with two types of restriction enzymes, KpnI (TAKARA BIO INC. ) and XbaI (TAKARA BIO INC. ), at <NUM> for <NUM> hour. Thereafter, the resulting DNA was inserted into the pEF4/myc-HisB that had also been digested with KpnI and Xbal according to an ordinary method using T4 DNA ligase (Promega), thereby obtaining an expression vector, pEF4-CDH3-myc-His.

On the day before transfection, CHO cells (<NUM> × <NUM><NUM>) were inoculated on a dish with a diameter of <NUM> in accordance with the protocols included with FuGENE (registered trademark) <NUM> Transfection Reagent (Roche Diagnostics), and they were then cultured overnight. Thereafter, <NUM>µg of the expression vector pEF4-CDH3-myc-His and <NUM>µL of the FuGENE <NUM> reagent were mixed into <NUM>µL of a serum-free RPMI1640 medium (SIGMA-ALDRICH), and the obtained mixture was then left at room temperature for <NUM> minutes. Thereafter, the mixture was added to the cell culture, so as to perform transfection. Two days after the transfection, cloning was carried out by limiting dilution using a selective reagent (Zeocin (registered trademark)).

The cloning and selection of CDH3 full-length expression CHO were carried out by a Western blotting method using Anti-c-Myc Monoclonal Antibody (SANTA CRUZ BIOTECHNOLOGY). As a result, a CDH3 full-length expression CHO cell line (EXZ1501) having a high expression level and a high growth rate was obtained. The measurement results obtained by examining the reactivity of this cell line with a commercially available anti-CDH3 antibody (R & D SYSTEMS) by flow cytometry are shown in <FIG>.

In order to be used as an immunogen in the production of an anti-CDH3 antibody, a soluble CDH3 (sCDH3) protein, in which its C-terminal transmembrane region and the subsequent regions were deleted, was prepared.

Using full-length CDH3 cDNA as a template, a PCR reaction was carried out employing a forward primer (SEQ ID NO. <NUM>: CGCGGTACCATGGGGCTCCCTCGT) and a reverse primer (SEQ ID NO. <NUM>: CCGTCTAGATAACCTCCCTTCCAGGGTCC) that had been designed to amplify a region corresponding to the CDH3 extracellular region (which corresponded to positions <NUM>-<NUM> of SEQ ID NO. <NUM>; hereinafter referred to as "sCDH3 cDNA"). KOD-Plus (Toyobo Co. ) was used in the reaction, and the reaction was carried out under reaction conditions consisting of <NUM> cycles of <NUM>-<NUM> seconds, <NUM>° C-<NUM> seconds, and <NUM>° C-<NUM> seconds.

Thereafter, a gel fragment containing an approximately <NUM>-kbp band that was a size of interest was cut out in agarose gel electrophoresis, and using QIA (registered trademark) Quick Gel Extraction Kit (QIAGEN), sCDH3 cDNA of interest was obtained.

In order to insert this sCDH3 cDNA into an expression vector pEF4/myc-HisB, the DNA was digested with two types of restriction enzymes KpnI and XbaI, and it was then inserted into pEF4/myc-HisB that had also been digested with KpnI and Xbal according to an ordinary method using T4 DNA ligase, so as to obtain an expression vector pEF4-sCDH3-myc-His.

On the day before transfection, CHO cells (<NUM> × <NUM><NUM>) were inoculated on a dish with a diameter of <NUM> in accordance with the protocols included with the FuGENE <NUM> Transfection Reagent, and they were then cultured overnight. Thereafter, <NUM>µg of the expression vector pEF4-CDH3-myc-His and <NUM>µL of the FuGENE <NUM> reagent were mixed into <NUM>µL of a serum-free RPMI1640 medium (SIGMA-ALDRICH), and the obtained mixture was then left at room temperature for <NUM> minutes. Thereafter, the mixture was added to the cell culture, so as to perform transfection. Two days after the transfection, cloning was carried out by limiting dilution using a selective reagent (Zeocin).

Soluble CDH3-expressing CHO cells were selected according to a Western blot method using an anti-c-Myc monoclonal antibody (SANTA CRUZ BIOTECHNOLOGY). It was attempted to select a cell line, which was able to secrete a large amount of soluble CDH3 into the culture supernatant and which was able to grow favorably. As a result, a soluble CDH3-expressing CHO cell line (EXZ1702) was obtained. Using three roller bottles each having a culture area of <NUM>,<NUM><NUM>, the selected soluble CDH3-expressing CHO cell line (EXZ1702) was cultured for <NUM> hours in <NUM> of a serum-free medium CHO-S-SFM-II (Invitrogen) per roller bottle. Thereafter, a culture supernatant was recovered. A soluble CDH3 protein was obtained from the recovered culture supernatant according to affinity chromatography using HisTrap (registered trademark) HP column (GE Healthcare Biosciences) and gel filtration chromatography using Superdex (registered trademark) <NUM> pg column (GE Healthcare Biosciences).

<NUM>µg of a soluble CDH3 protein dissolved in a normal saline and Titer-MAX Gold (registered trademark) (TiterMax) were mixed in equal volumes. The obtained mixture was injected into the abdominal cavity and subcutis of each MRL/lpr mouse (Japan SLC, Inc. ), so as to carry out initial immunization. The second immunization and the subsequent immunizations were carried out by mixing a soluble CDH3 protein (protein amount: <NUM>µg) that had been prepared in the same manner as described above with Titer-MAX gold and then injecting the obtained mixture into the abdominal cavity and subcutis of the mouse. Three days after the final immunization, splenic cells were aseptically prepared from the mouse, and the splenic cells were then fused with mouse myeloma cells SP2/O-Ag14 or P3-X63-Ag8. <NUM> according to an ordinary method (polyethylene glycol method).

An anti-CDH3 antibody was selected by flow cytometry using a CHO cell line (EXZ1501) expressing full-length CDH3.

Specifically, the CHO cell line (EXZ1501) that expressed full-length CDH3 was treated with <NUM> EDTA-PBS, so that it was removed from the culture plate. Thereafter, the cells were suspended in a FACS solution to a cell density of <NUM> × <NUM><NUM> cells/mL. This cell suspension was inoculated on a <NUM>-well plate to an amount of <NUM>µL/well, and a culture supernatant of hybridomas was then added thereto, so that they were reacted at <NUM>° C for <NUM> minutes. Thereafter, the reaction solution was washed with a FACS solution (<NUM>µL/well) two times, and AlexaFluor <NUM>-labeled anti-mouse IgG-goat F(ab')<NUM> (Invitrogen) was then added. Then, the mixture was reacted at <NUM>° C for <NUM> minutes. Thereafter, the reaction solution was washed with a FACS solution two times, and it was then subjected to flow cytometry, so as to select hybridomas that were reacted with the CDH3-expressing CHO cells.

Typical reaction results obtained from the reactions of an antibody obtained from the aforementioned hybridomas with CDH3-expressing CHO cells (EXZ1501), with CHO cells as a parent cell line, and with a human bronchioalveolar carcinoma cell line NCI-H358 are shown in <FIG>. It was confirmed that all of the selected hybridomas reacted with CDH3-expressing CHO cells (EXZ1501) and NCI-H358, and did not react with CHO cells.

Samples were recovered from normal human tissues and various types of cancer tissues according to laser capture microdissection, and total RNA was then prepared from each sample according to an ordinary method using ISOGEN (NIPPON GENE CO. <NUM> ng each of RNA was subjected to gene expression analysis in accordance with Expression Analysis Technical Manual (Affymetrix) using GeneChip U-133B (Affymetrix). The mean value of the expression scores of all genes was set at <NUM>, and genes whose expression had been increased in cancer cells were then searched. As a result, it was found that the expression of CDH3 had a certain limit in normal human tissues, and that CDH3 was highly expressed in lung cancer, colon cancer, and pancreatic cancer (<FIG>). Moreover, the expression of CDH3 mRNA was examined in several pancreatic cancer tissues having different degrees of differentiation. As a result, regardless of the degree of differentiation, tissues in which high expression of CDH3 mRNA was observed were found (<FIG>).

In order to confirm the expression of the CDH3 protein in clinical cancer specimens, immunostaining was carried out using cancer specimen tissue arrays.

As such cancer specimen tissue arrays, pancreatic cancer (adenocarcinoma), lung cancer (adenocarcinoma), lung cancer (squamous cell carcinoma), and colon cancer (adenocarcinoma), manufactured by Shanghai Outdo Biotech Co. , were used.

A slide of each tissue array was subjected to a deparaffinization treatment, and was then activated in <NUM> Tris <NUM> EDTA (pH <NUM>) at <NUM> for <NUM> minutes. Endogenous peroxidase was deactivated using a blocking reagent included with ENVISION+ Kit (Dako), and it was then reacted with an anti-CDH3 antibody <NUM> (BD BIOSCIENCE) and with an anti-HBs antibody Hyb-<NUM> used as a negative control in a concentration of <NUM>µg/mL at <NUM> overnight. Thereafter, the antibody solution was washed out, and the reaction solution was then reacted with a polymer secondary antibody reagent included with ENVISION+ Kit at room temperature for <NUM> minutes. Thereafter, color development was carried out with a coloring reagent included with ENVISION+ Kit, and nuclear staining was then performed with a hematoxylin-eosin solution.

The results are shown in <FIG>. Cancer cells were stained with the anti-CDH3 antibody, but normal cells were not stained therewith.

Cytoplasmic RNA was isolated from mouse hybridoma cells producing the CDH3 antibody according to the method described in <NPL>) (wherein another TNE buffer (<NUM> Tris-HCl, pH <NUM>; <NUM>% NP-<NUM>; <NUM> NaCl; <NUM> EDTA, pH <NUM>) was used in the present operation, instead of the lysis buffer described in the aforementioned study paper). As a specific operation procedure, hybridoma cells (<NUM> × 10e<NUM>) was suspended in <NUM> of a TNE buffer to dissolve the cell membrane therein, and the cell nucleus was then removed by centrifugation. To approximately <NUM> of the obtained cytoplasm supernatant, <NUM> of an extraction buffer (<NUM> Tris-HCl, pH <NUM>; <NUM> NaCl; <NUM>% (w/v) SDS; <NUM> EDTA, pH <NUM>; <NUM> urea) was added. The obtained mixture was extracted with phenol and chloroform, and glycogen (Roche; Cat No. <NUM>) was then added as a carrier to the obtained RNA solution. The mixture was precipitated with ethanol. Subsequently, <NUM> to <NUM>µl of sterile distilled water was added to the RNA precipitate, resulting in a cytoplasmic RNA concentration of <NUM> to <NUM>µg/µl, so that the precipitate was dissolved therein.

In order to synthesize single-stranded cDNA, <NUM> to <NUM>µg of the above-prepared cytoplasmic RNA was added to a reaction solution containing <NUM> Tris-HCl, pH <NUM> (room temperature); <NUM> KCl; <NUM> MgCl<NUM>; <NUM> DTT, <NUM> ng of random primer, <NUM> dNTP, and <NUM> units of Superscript II (reverse transcriptase, Invitrogen) to prepare <NUM>µL of a reaction mixture, and the reaction mixture was then incubated at <NUM> for <NUM> minutes. The thus synthesized cDNA library was directly used as a template in a polymerase chain reaction (PCR) method.

Primers used in the experiments were all synthesized by Hokkaido System Science Co.

Using two types of primer sets, namely, (<NUM>) a DNA primer having homology with a FR1 portion at the <NUM>'-terminus, and <NUM> primer sets having homology with a J chain gene in a mouse L chain at the <NUM>'-terminus, and (<NUM>) primer sets having homology with an L chain signal portion at the <NUM>'-terminus (<NUM> primer sets), and a primer with a KC portion at the <NUM>'-terminus (KVL antisense primer), mouse immunoglobulin L chain variable region DNA was isolated from the cDNA by a polymerase chain reaction. The primer sequences are as follows.

With reference to "Phage Display A Laboratory Manual-, Barbas Burton Scott Silverman" PROTOCOL <NUM>, <NUM> types of sense primers and <NUM> types of reverse primers were synthesized by Hokkaido System Science Co.

VK sense (FR1 portion): A mixture of the following <NUM> primers was used as a VK sense primer.

These primers were prepared by modifying the nucleotide sequences based on the Mouse Ig-Primer Set of Novagen (Novagen; Merck, Cat. No. <NUM>-<NUM>), such that restriction sites were removed.

Using a primer having homology with a mouse H chain signal portion (<NUM> primer sets) at the <NUM>'-terminus and a primer having homology with a KC portion at the <NUM>'-terminus, or using <NUM> primer set having homology with a FR1 portion at the <NUM>'-terminus and two types of primer sets having homology with the constant region of a mouse H chain (IGHC) at the <NUM>'-terminus, mouse immunoglobulin H chain variable region DNA was isolated from the cDNA by a polymerase chain reaction. The primer sequences are as follows.

These primers were designed with reference to Table <NUM>. <NUM> shown in <NPL>.

This primer was designed by modifying the nucleotide sequence of the sense primer described in <NPL>.

This primer was designed by degenerating the nucleotide sequence such that it can anneal with all isoforms of mouse IgG
<NUM>'-CASCCCCATCDGTCTATCC-<NUM>' (Degeneracy <NUM>): SEQ ID NO.

Using the primers shown in Example <NUM>, a variable region in each of the L chain and H chain of an anti-CDH3 mouse monoclonal antibody was amplified by a PCR method employing DNA Engine (Peltier Thermal Cycler, MJ Research, Bio-Rad). The amplified DNA fragment was inserted into a subcloning vector pGEM (Promega), and the nucleotide sequence thereof was then determined using T7, SP6 universal primers.

Among the nucleotide sequences determined in Example <NUM>, sequences, in which a portion corresponding to CDR was converted to amino acids, are shown in Table <NUM>.

The nucleotide sequence of a variable region in each of the L chain and H chain of the chimeric anti-CDH3 antibody was searched on the IMGT/V-QUEST Search page (http: //imgt. fr/IMGT_vquest/vquest?livret=<NUM>&Option = mouseIg). As a result, it was confirmed that the antibody gene could be reliably cloned. Subsequently, genes each encoding the V regions of the L chain and H chain of the cloned anti-CDH3 antibody were prepared by designing a gene, in which a gene encoding a human Ck region was connected with a chimeric L chain expression vector and a gene encoding a human Cg1 region was connected with a chimeric H chain expression vector, and then performing the artificial synthesis of the thus designed, full-length L chain and H chain chimeric antibody genes by GenScript. Upon the artificial synthesis of the full-length genes, optimization of codon usage was carried out for the advantages of gene expression in CHO-producing cells (in accordance with the method described in <NPL>). Specifically, in the case of the L chain, a DNA sequence essential for efficient translation (<NPL>), a signal peptide of a mouse IGKV (k chain variable region) gene, a V region of the L chain of an anti-CDH3 antibody, and human KC (k chain constant region) were aligned in this order, and restriction enzyme sites (NheI on the <NUM>'-terminal side and EcoRI on the <NUM>'-terminal side) were then added to the both termini. A chimeric H chain was produced in the same manner as described above. The thus produced artificial synthetic genes were cleaved with NheI and EcoRI, and the gene fragments were then inserted into the NheI and EcoRI sites of the expression vector pCAGGS, so as to obtain an expression vector pCAGGS-IGK for an anti-CDH3 chimeric antibody L chain, and an expression vector pCAGGS-IGH for an anti-CDH3 chimeric antibody H chain.

To allow a genetically modified antibody gene to express at a high level in CHO cells, an expression vector was constructed by ligating the gene to a CMV promoter sequence and introducing a dihydrofolate reductase (dhfr) gene having a poly(A) signal in the vector.

To produce a cell line capable of stably expressing and producing a chimeric antibody, a pCAGGS expression vector, into which a dhfr gene had been incorporated, was constructed. Specifically, a CMV promoter and a dgfr gene having a poly(A) signal were introduced into transient expression vectors pCAGGS-IGH and pCAGGS-IGK. A CMV promoter, a mouse dgfr gene having a Kozak sequence, and a SV40 poly(A) signal were each amplified according to a PCR method. Thereafter, a mixture of these DNA were connected with one another according to the PCR method, and at the same time, HindIII sites were added to both termini, so as to obtain a gene fragment HindIII-CMV promoter-Kozak-dhfr-poly(A)-HindIII. This fragment was inserted into the HindIII site of pCAGGS-IGH or pCAGGS-IGK to obtain pCAGGS-IGH-CMVp-dhfr-A and pCAGGS-IGK-CMVp-dhfr-A. These expression vectors enabled chimeric antibody expression with a CAG promoter, and dgfr gene expression with a CMV promoter, and thus, they were able to efficiently produce chimeric antibodies by utilizing gene amplification.

CHO dhfr(-) cells (<NPL>) were used in simultaneous transformation with two types of plasmids (wherein a plasmid was cleaved with PvuI in an ampicillin resistance gene to form linear plasmids from a cyclic plasmid), namely, with a pCAGGS-IGK-CMV-dhfr-A vector used for expression of a chimeric anti-CDH3 L chain and a pCAGGS-IGH-CMV-dhfr-A vector used for expression of a chimeric anti-CDH3 H chain. Electroporation was carried out using Amaxa manufactured by LONZA. DNA (<NUM>/sample of each plasmid for the L chain and the H chain) was added to <NUM> of Amaxa electroporation CHO buffer containing <NUM> × 10e3 cells, and electric pulse was then given thereto.

The cells treated by electroporation were added to an Iscove's Modified Dulbecco Medium (IMDM), which contained <NUM>% dialyzed FBS and did not contain HT (H: hypoxanthine; T: thymidine). Three days after the gene transfection, the medium was replaced with IMDM, which contained <NUM>% dialyzed FBS and <NUM> L-glutamine, and did not contaibn HT. Thereafter, the transfected neo+ cells were selected with <NUM>/mL G418, and clones of a chimeric antibody production-positive cell line were obtained. Subsequently, gene amplification was carried out using the clones selected with G418. The gene was amplified in <NUM> rounds of methotrexate (MTX) (<NUM>, <NUM>), and a cell line capable of producing approximately <NUM> to <NUM> of chimeric CDH3 antibody per liter could be established.

A culture supernatant of the transfected CHO cells was measured by ELISA, and it was confirmed that a chimeric antibody had been produced. To detect the chimeric antibody, a plate was coated with goat anti-human IgG (H + L) (which had previously been absorbed against mouse, rabbit, bovine, and mouse IgG) (COSMO BIO: AQI, Cat. No. A-110UD). After blocking, the culture supernatant obtained from CHO cells capable of producing anti-CDH3 chimeric antibody was subjected to serial dilution, and was then added to each well. After the plate had been subjected to incubation and washing, goat anti-human IgG (H + L) (which had previously been absorbed against mouse, rabbit, bovine, and mouse IgG) - HRP (COSMO BIO: AQI, Cat No. A-110UD) was added to the plate. Following incubation and washing, a substrate buffer was added to the plate. Incubation was further carried out, the reaction was then terminated, and the absorbance at <NUM> was then measured. Purified human IgG was used as a standard.

An antibody having a combination of CDR sequences each shown in Table <NUM> was produced by the methods described in Examples <NUM> and <NUM>, and the binding activity thereof was evaluated by flow cytometry.

Individual cell lines that would become reaction targets (CHO cells, CHO cells forcibly expressing CDH3, and NCI-H358 cell line that had been confirmed to express CDH3 at a high level) were each treated with <NUM> EDTA-PBS, so that they were removed from a culture plate, and the cells were then suspended in a FACS solution to a cell density of <NUM> × <NUM><NUM> cells/mL. This cell suspension was inoculated on a <NUM>-well plate, resulting in an amount of <NUM>µL/well, and the purified chimeric antibody was then added to the plate to result in a concentration of <NUM> ug/mL, followed by performing a reaction at <NUM> for <NUM> minutes. Thereafter, the reaction mixture was washed with a FACS solution (<NUM>µL/well) two times, and <NUM>µg/ml AlexaFlour488-labeled anti-human IgG/goat F(ab')<NUM> (Invitrogen) was then added. The obtained mixture was reacted at <NUM> for <NUM> minutes. Thereafter, the reaction mixture was washed with a FACS solution two times, and was then subjected to flow cytometry. As a result, the chimeric antibody was found to have strong reactivity with a CDH3-expressing cell line (<FIG>).

CDR-H1, H2 and H3 each indicate a CDR sequence constituting the H chain of each antibody. On the other hand, CDR-L1, L2 and L3 each indicate a CDR sequence constituting the L chain of each antibody.

DM1 SMe (<FIG>) was prepared as previously described in <CIT> and <CIT>.

- <NUM> of DM1 SMe dissolved in <NUM> uL of EtOH, <NUM> uL of a <NUM> potassium phosphate buffer (pH <NUM>), and <NUM> uL of a TCEP Solution (Bond Breaker, Thermo Fisher Scientific K. ) were mixed with one another, and the obtained mixture was then reacted in a nitrogen atmosphere at room temperature for <NUM> minutes or longer, so that the drug was reduced.

The reduced drug was purified by HPLC, and the solvent was then distilled away. The residue was dissolved in dimethylacetamide to a concentration of <NUM>/mL.

Sulfo-SMCC (PIERCE) was added to a <NUM>/mL anti-CDH3 chimeric antibody at a molar ratio of <NUM> : <NUM> or greater, and the obtained mixture was then reacted at <NUM> for <NUM> hour.

In order to remove an excessive amount of crosslinker, the reaction product was subjected to a desalination treatment with a desalination device that had been equilibrated with <NUM> potassium phosphate, <NUM> NaCl and <NUM> EDTA (pH <NUM>) (ZebaSpinColumn, Thermo Fisher Scientific K.

A <NUM>/mL maleimidated anti-CDH3 chimeric antibody was reacted with a reducing agent that was <NUM>-fold larger than the number of the bound maleimide groups in <NUM> potassium phosphate, <NUM> NaCl, and <NUM> EDTA (pH <NUM>) at room temperature overnight. Subsequently, an excessive amount of drug was removed from the reaction mixture by gel filtration.

The number of drugs bound per antibody was determined by measuring the absorbance at <NUM> and <NUM>. For the determination method, the absorption coefficients εAb<NUM> = <NUM>,<NUM>-<NUM>cm-<NUM>, εAb<NUM> = <NUM>,<NUM>-<NUM>cm-<NUM>, εDM1<NUM> = <NUM>,<NUM>-<NUM>cm-<NUM>, and εDM1<NUM> = <NUM>,<NUM>-<NUM>cm-<NUM> described in a non-patent literature (<NPL>) were utilized.

The cytotoxicity and specificity of a drug-bound antibody were evaluated, using a cell growth measurement reagent (Dojindo Laboratories, Cell counting assay kit-<NUM>) in which WST-<NUM> was used as a chromogenic substrate.

Specifically, a human breast cancer cell line HCC1954, in which high expression of CDH3 had been confirmed, was allowed to coexist with a drub-bound antibody (ADC) or with an antibody to which a drug was not bound (Naked) in any given amounts, and the obtained mixture was then incubated at <NUM> for <NUM> days in a <NUM>% CO<NUM> environment. Thereafter, the cell growth measurement reagent was added to the resultant, and the obtained mixture was then left. Subsequently, the absorbance A450/<NUM> was measured. The value of absorbance obtained from a well, to which only the cancer cell line had been added and no antibodies had been added, was set at <NUM>%, and the obtained relative value was indicated as a cell survival percentage (<FIG>). The antibody used in the figure was antibody No. <NUM>-17C. With regard to ADC, the number of drugs introduced into a single antibody was calculated by the method described in Example <NUM>. As a result, it was estimated that <NUM> drugs were introduced into a single molecule of antibody.

The cytotoxicity of the drug-bound antibody was evaluated using the obtained plurality of anti-CDH3 antibodies.

The measurement was carried out according to the method described in Example <NUM>. That is to say, a human breast cancer cell line HCC1954 was allowed to coexist with a drug-bound antibody (ADC), and the obtained mixture was then incubated at <NUM> for <NUM> days in a <NUM>% CO<NUM> environment. The concentration of the ADC during the incubation was set at <NUM> ug/mL. Thereafter, the cell growth measurement reagent was added to the resultant, and the obtained mixture was then left. Subsequently, the absorbance A450/<NUM> was measured. The value of absorbance obtained from a well, to which only the cancer cell line had been added and no antibodies had been added, was set at <NUM>%, and the obtained relative value was indicated as a cell survival percentage. The number of drugs introduced into a single molecule of antibody was calculated by the method described in Example <NUM> (Table <NUM>).

As a negative control antibody, an antibody, which had been confirmed not to react with HCC1954, was used.

The effect of a drug-bound antibody to reduce tumor in vivo was confirmed using xenograft models into which the breast cancer cell line HCC1954 had been transplanted. For administration of the antibody, an anti-asialo GM1 antibody (WAKO <NUM>-<NUM>) was dissolved in <NUM> of Otsuka Distilled Water, and <NUM> of Otsuka Saline was then added to the solution to a total amount of <NUM>. Thereafter, <NUM> uL of the obtained solution per mouse was intraperitoneally administered to a mouse. HCC1954 was cultured in an RPMI1640 medium that contained <NUM>% FBS, and the culture was then transplanted in an amount of <NUM> × <NUM><NUM> cells/mouse into the subcutis of the right abdominal wall of an SCID mouse (female, CLEA Japan, Inc.

An in vivo test was carried out on <NUM> mice in each group, and the <NUM>/kg antibody was administered into the caudal vein of each mouse. Administration of the antibody was started when the mean tumor diameter became <NUM> to <NUM><NUM>, and one week later, the same amount of antibody as described above was administered again. Thus, administration was carried out twice in total.

Antibodies with antibody numbers <NUM>-12C, <NUM>-23C and <NUM>-27C, as shown in the figure, were used. With regard to ADC, the number of drugs introduced into a single antibody was calculated by the method described in Example <NUM>. As a result, it was estimated that <NUM> to <NUM> drugs were introduced into a single molecule of antibody.

Claim 1:
An immune complex that can be formed by binding a monoclonal antibody against CDH3, or a fragment thereof having CDH3 binding ability, to DM1 via the divalent crosslinking reagent N-succinimidyl <NUM>-(maleimidomethyl)cyclohexanecarboxylate (SMCC) or N-succinimidyl-<NUM>-(N-maleimidomethyl)-cyclohexane-<NUM>-carboxy-(<NUM>-amidocaproate)(LC-SMCC), provided that a complex of an antibody produced by the cell of NITE BP-<NUM> or NITE BP-<NUM> with <NUM> or <NUM> DM1 via the SMCC linker is excluded.