JP2016048270A - Marker for differentiation of epithelial ovarian cancer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To develop and provide a marker for differentiation of epithelial ovarian cancer capable of inexpensively, simply, and minimally invasively detecting the epithelial ovarian cancer at high proper-diagnosis rate, and to develop and provide a method for determining an affection of the epithelial ovarian cancer using the marker.SOLUTION: A fragment having glycoprotein secreted by an epithelial ovarian cancer cell and formed by adding a sugar chain to an asparagine residue at a specific position or having the sugar chain is provided as a marker for differentiation of epithelial ovarian cancer. A method for determining an affection of the epithelial ovarian cancer using the glycoprotein is also provided.SELECTED DRAWING: None

Description

The present invention relates to a glycoprotein for epithelial ovarian cancer differentiation marker or a fragment thereof having a sugar chain, and a method for determining morbidity of epithelial ovarian cancer using the same.

Ovarian cancer is the second most common gynecologic cancer after breast cancer. Ovarian cancer is difficult to detect early because there are almost no subjective symptoms at the early stage of onset, and symptoms are often already advanced at the time of detection. Therefore, the prognosis is poor and mortality is the highest among gynecological cancers.

As for ovarian cancer, surface epithelial / interstitial tumors (epithelial ovarian cancer) that are generated from ovarian surface epithelial cells, germ cell tumors that are generated from embryonic cells, and the like are known. Of these, epithelial ovarian cancer accounts for about 90% of all ovarian cancers, especially in middle-aged and older people after their 40s. Therefore, if epithelial ovarian cancer can be detected early, the mortality from ovarian cancer can be reduced.

However, epithelial ovarian cancer, like uterine cancer, cannot be examined by an endoscope or directly collected from outside. Therefore, laparotomy is also required for direct examination and cytology. In addition, early detection by palpation is difficult and usually overlooked only after symptoms progress and the ovaries enlarge. Echo examination, MRI, CT, etc. are relatively effective for early detection, but the examination itself is large and the examination cost is high, and the accuracy of benign and malignant diagnosis is not necessarily high.

In recent years, tumor markers have attracted attention from the above background. A tumor marker is a substance produced by cancer cells, or a substance produced by cells in response to cancer cells, and the amount in body fluids such as serum reflects tumor mass, tissue type, and malignancy (prognosis). Therefore, it can be a discriminator for cancer determination or the like. Since examination from body fluid is possible, there are advantages such as low invasiveness, simple examination, and relatively low cost.

To date, as a tumor marker for epithelial ovarian cancer, CA125, CA602, CA13
Various cancer-related antigens such as 0, CA72-4, CA546, CA19-9, and STN are known (Non-Patent Documents 1 to 6).
). However, each tumor marker is based on the difference in the expression level in serum between healthy subjects and patients with epithelial ovarian cancer, that is, the amount of protein expression, and such proteins are usually small even in normal cells. Therefore, epithelial ovarian cancer specificity is low. Therefore, the false positive rate and false negative rate were high, and it was difficult to say that the correct diagnosis rate as a tumor marker was high.
Moreover, these tumor markers are mainly used for prognosis of epithelial ovarian cancer, and tumor markers that contribute to the early detection of primary cancer have not been obtained yet.

Bast R.C.Jr. et al., 1983, N. Engl.J. Med., 309: 883-887 Suzuki M. et al., 1990, Nippon Gan Chiryo Gakkai Shi ,. 25: 1454-1460 Inaba N. et al., 1989, Nippon Gan Chiryo Gakkai Shi, 24: 2426-2435 Ohuchi N. et al., 1988, Gan To Kagaku Ryoho, 15 2767-2772 Nozawa S. et al., 1996, Nippon Rinsho, 54: 1665-1673 Charpin C. et al., 1982, Int. J. Gynecol. Pathol., 1: 231-245

The present invention is an epithelial ovarian cancer differential marker capable of detecting epithelial ovarian cancer from body fluid, cells or peritoneal lavage fluid at a low cost, in a simple and minimally invasive manner and with a high accuracy rate, and the same The purpose is to develop and provide a method for determining the incidence of epithelial ovarian cancer.

It is known that the composition, structure, and addition position of sugar chains added to proteins secreted from cells are controlled based on the expression balance of sugar chain-related genes and vary according to cell differentiation. In addition, the composition and structure of sugar chains vary depending on the degree of cancer progression. Therefore, glycoproteins found in specific cancer cells can be used as disease pathological index markers including tumor markers. In recent years, search for sugar chain-related tumor markers based on such (glyco) proteomics has been actively pursued.

In order to solve the above-mentioned problems, the present inventors have searched for epithelial ovarian cancer differential markers using a lectin microarray method and glycoproteomics. As a result, a novel glycoprotein group or glycopeptide group having a specific structure in epithelial ovarian cancer could be identified. It was also revealed that the presence or absence of epithelial ovarian cancer can be determined using these glycoprotein groups or glycopeptide groups. Furthermore, it was also found that the tissue type of epithelial ovarian cancer can be inferred according to a part of the glycoprotein group or glycopeptide group. The present invention is based on these findings and provides the following.

(1) A glycoprotein for epithelial ovarian cancer differential marker, wherein a sugar chain is added to at least one asparagine residue at the sugar addition position shown in Table 1 in the amino acid sequence of the protein shown in Table 1.

(2) The glycoprotein for epithelial ovarian cancer differentiation marker according to (1), wherein the sugar chain is a sugar chain containing a fucose-modified sugar chain and / or terminal N-acetylgalactosamine.

(3) The glycoprotein for differential marker for epithelial ovarian cancer according to (1) or (2), wherein the sugar chain binds to AAL lectin and / or WFA lectin.

(4) The epithelial ovarian cancer differential marker according to any one of (1) to (3), wherein the epithelial ovarian cancer is at least one of clear cell tumor, mucinous tumor, serous tumor and endometrioid tumor Glycoprotein.

(5) The glycoprotein for epithelial ovarian cancer differentiation marker according to (4), wherein the protein is type 6 collagen α1 and the epithelial ovarian cancer is a clear cell tumor or serous tumor.

(6) The glycoprotein fragment for epithelial ovarian cancer differentiation marker according to any one of (1) to (5), which contains at least one asparagine residue having a sugar chain added at the sugar addition position shown in Table 1.

(7) One or more glycoproteins for epithelial ovarian cancer differentiation markers according to any one of (1) to (5) and / or one or more epitheliums according to (6) from a sample collected from a subject. Detecting a glycoprotein fragment for sex ovarian cancer differentiation marker, and, if the glycoprotein for epithelial ovarian cancer differentiation marker and / or its glycoprotein fragment is detected, the subject suffers from epithelial ovarian cancer A method for determining the incidence of epithelial ovarian cancer, comprising the step of determining that the patient is present.

(8) The detection step includes a glycoprotein enrichment step and a protein detection step.
The method according to 7).

(9) The glycoprotein for differentiation marker for epithelial ovarian cancer and / or a glycoprotein fragment thereof is detected using one or more sugar chain probes that bind to the sugar chain, (7) or (8) Method.

(10) The method according to (9), wherein the sugar chain probe is a lectin, an antibody, or a phage antibody.
(11) The method according to (10), wherein the lectin is AAL or WFA.

(12) The method according to any one of (7) to (11), wherein the sample is a body fluid, a cell, or a peritoneal washing solution.

(13) The method according to any one of (7) to (12), wherein the epithelial ovarian cancer is at least one of a clear cell tumor, a mucinous tumor, a serous tumor, and an endometrioid tumor.

According to the epithelial ovarian cancer differentiation marker and the epithelial ovarian cancer incidence determination method of the present invention, body fluid,
The presence or absence of epithelial ovarian cancer can be easily determined from cells or peritoneal lavage fluid in a relatively inexpensive and minimally invasive manner with a high accuracy rate.

The selection result of a probe lectin is shown. RMUG-S, RMG-I, RMG-II, RMG-V, and RTSG are cultured cells derived from epithelial ovarian cancer, Colo205 and Colo201 are derived from colon cancer, and KATO III is derived from gastric cancer. A shows the result of WFA lectin, which is a selected probe lectin, and B shows the result of similarly selected AAL lectin. It is a Western blotting diagram showing the presence of type 6 collagen α1 (COL6α1) glycoprotein in peritoneal lavage fluid collected from two clear cell adenocarcinoma patients, endometrioid adenocarcinoma patients, serous adenocarcinoma patients and gastric cancer patients. The peritoneal lavage fluid was subjected to AAL lectin column chromatography, and the glycoprotein binding to the AAL lectin was enriched and separated, and then detected with an anti-COL6α1 antibody. It is a Western blotting diagram showing the presence of LOXL2 (lysyl oxidase-like 2) glycoprotein in peritoneal lavage fluid collected from two clear cell adenocarcinoma patients, endometrioid adenocarcinoma patients, serous adenocarcinoma patients and gastric cancer patients. The peritoneal washing was subjected to WFA lectin column chromatography, and the glycoprotein binding to the WFA lectin was enriched and separated, and then detected with an anti-LOXL2 antibody. FIG. 2 is a Western blotting diagram showing the presence of ceruloplasmin (CP) glycoprotein in peritoneal lavage fluid collected from two clear cell adenocarcinoma patients, endometrioid adenocarcinoma patient, serous adenocarcinoma and one gastric cancer patient. The peritoneal washing solution was subjected to WFA lectin column chromatography to enrich and separate the glycoprotein binding to the WFA lectin, and then detected with an anti-CP antibody. It is a Western blotting diagram showing the presence of F12 (blood coagulation factor factor XII) glycoprotein in peritoneal lavage fluid collected from two patients each of clear cell adenocarcinoma, endometrioid adenocarcinoma, serous adenocarcinoma and gastric cancer . The peritoneal washing was subjected to WFA lectin column chromatography, and the glycoprotein binding to WFA lectin was enriched and separated, and then detected with anti-F12 antibody. FIG. 3 is a Western blotting diagram showing the presence of SERPING1 glycoprotein in peritoneal lavage fluid collected from two clear cell tumor patients, endometrioid tumor patients, serous tumor patients, and gastric cancer patients. The peritoneal lavage fluid was subjected to WFA lectin column chromatography, and the glycoprotein binding to WFA lectin was enriched and separated, and then detected with anti-SERPING1 antibody.

1. Epithelial ovarian cancer differential marker glycoprotein and fragment thereof having a sugar chain The first embodiment of the present invention is the epithelial ovarian cancer differential marker glycoprotein described in Table 1 and a glycoprotein fragment thereof.

1-1. Glycoprotein for differentiation marker of epithelial ovarian cancer “Glycoprotein for differentiation marker of epithelial ovarian cancer” of the present embodiment is a glycoprotein represented by protein numbers # 1 to 262 in Table 1 above, and each amino acid sequence In Table 1, a sugar chain peculiar to epithelial ovarian cancer was added at least to the asparagine residue at the position indicated by “glycosylation position” in Table 1 (the position of the starting amino acid residue (starting methionine) is 1). It is a glycoprotein. For example, in the case of protein # 1 in Table 1, collagen type VI alpha 1 (hereinafter referred to as “COL6α1”) in which a sugar chain is added to at least the 212th asparagine residue in the amino acid sequence. ). Table 1
In the case where a plurality of sugar chain addition positions are described for one protein, it is sufficient that at least one of them is sugar chain added. For example, protein # 2
When two asparagine residues at positions 270 and 311 are described, such as biglycan, or the complement component 4 (C4) binding protein α chain of protein # 15 (complement co
mponent 4 binding protein alpha chain), when two asparagine residues at positions 506 and 528 are described, the present invention can be used as long as at least one asparagine residue is added with a sugar chain. Is sufficient as a glycoprotein for differentiation marker of epithelial ovarian cancer. In the present specification, hereinafter, a protein to which a sugar chain is added is represented as “glycoprotein”, and a protein portion serving as a base other than the sugar chain is represented as “core protein”.

“Gi (ID)” in the table indicates the ID number of the core protein in the glycoprotein of the present embodiment. When a plurality of gi (ID) are registered in one core protein, they are all listed in the table. In addition, when a plurality of isoforms exist in one core protein, their gi (ID) is described together with the isoform number. When the glycosylation position from the starting amino acid residue changes between isoforms due to mRNA splicing etc.,
The glycosylation position corresponding to each isoform is described.

The sugar chain added to the asparagine residue of the glycoprotein of the present embodiment is not particularly limited as long as it is a sugar chain peculiar to epithelial ovarian cancer. Here, “sugar chain peculiar to epithelial ovarian cancer” is, for example,
Sugar chain with fucose modification (fucosylation) and / or terminal N-acetylgalactosamine (NA
cetylgalactosamine: hereinafter referred to as “GalNAc”). These sugar chains can be identified by a lectin, antibody or phage antibody that specifically recognizes and binds to each sugar chain. For example, in the case of a sugar chain accompanied by fucose modification (fucosylation), AAL lectin derived from Aleuria aurantia or LCA lectin derived from lentil (Lens culinaris) that specifically binds thereto. In the case of terminal GalNAc,
A WFA lectin derived from Wisteria floribunda that specifically binds to it.

In Table 1, the glycoprotein for epithelial ovarian cancer differentiation marker that has been confirmed to bind to AAL lectin or WFA lectin is indicated by “◯”, and the unidentified glycoprotein is indicated by “−”.

“Epithelial ovarian cancer” is known to have a tissue type mainly composed of clear cell tumor, mucinous tumor, endometrioid tumor and serous tumor. The glycoprotein for epithelial ovarian cancer differentiation marker of the present embodiment,
At least one of these tissue types can be differentiated. For example, in Table 1, lysyl oxidase-like 2 (LOXL2) glycoprotein represented by protein # 28, ceruloplasmin (CP) glycoprotein represented by protein # 35, blood coagulation factor XI represented by protein # 68
Serpin peptidase inhibitor clade G (C1 inhibitor) mem shown by factor I (F12) glycoprotein and protein # 42
ber 1; SERPING1) Glycoprotein can distinguish all histological types of clear cell tumors, mucinous tumors, endometrioid tumors and serous tumors (see Example 2 below). That is, these glycoproteins can serve as epithelial ovarian cancer differentiation markers useful for differentiating whether or not a subject suffers from epithelial ovarian cancer regardless of the tissue type. On the other hand, in Table 1, protein # 1
The type 6 collagen α1 (COL6α1) glycoprotein represented by can differentiate between clear cell tumors and serous tumors (see Example 2 below). Clear cell tumor is a histological type that is more frequent in Japan than Western countries, and has a poorer prognosis than serous tumor, and at the same time, endometriosis is similar to endometrioid tumors. It is known that merger frequency is high (Yoshikawa H. et al., 2000,
Gynecol. Obstet., 1: 11-17). Therefore, COL6α1 glycoprotein can be a marker that can distinguish whether or not the tissue type of epithelial ovarian cancer that has developed in association with endometriosis is a clear cell tumor. In addition, since clear cell tumors have a high recurrence rate and are resistant to chemotherapy, strict follow-up is required even for cases resected by early detection. Therefore, markers that can surround clear cell tumors, such as COL6α1 glycoprotein, can be very useful epithelial ovarian cancer differentiation markers.

1-2. Glycoprotein fragment for epithelial ovarian cancer differentiation marker “Glycoprotein fragment for epithelial ovarian cancer differentiation marker” in this embodiment refers to an oligopeptide or polypeptide comprising a part of the glycoprotein for epithelial ovarian cancer differentiation marker. A fragment containing at least one asparagine residue at the glycosylation position shown in Table 1 in the amino acid sequence, and the asparagine residue in the above-mentioned “1-1. Glycoprotein for differentiation marker of epithelial ovarian cancer” A sugar chain peculiar to the described epithelial ovarian cancer is added.

The length of the amino acid of the glycoprotein fragment for epithelial ovarian cancer differentiation marker is not particularly limited, but is preferably 5 to 100 amino acids, 8 to 80 amino acids, or 8 to 50 amino acids.

When the glycoprotein for differentiation marker for epithelial ovarian cancer and the glycoprotein fragment for the marker are collectively expressed, they are hereinafter referred to as “epithelial ovarian cancer differentiation marker”.

Specific examples of glycoprotein fragments for epithelial ovarian cancer differentiation markers include SEQ ID NOs: 1 to 38.
Examples thereof include glycopeptides consisting of the amino acid sequence shown in FIG. 8, wherein a sugar chain peculiar to epithelial ovarian cancer is added to the asparagine residue corresponding to the glycosylation position shown in Table 1. The exemplified glycopeptide is an IGOT described later when identifying the epithelial ovarian cancer differential marker glycoprotein of the present embodiment.
It is a glycoprotein fragment for an epithelial ovarian cancer differentiation marker obtained by the method, and it is possible to differentiate whether or not all are affected by epithelial ovarian cancer. In the amino acid sequence shown in Table 1, the underlined asparagine residue (N) indicates an asparagine residue to which a sugar chain is added. Here, when there are a plurality of underlined asparagine residues in the amino acid sequence shown in Table 1, if at least one of the asparagine residues is sugar chain added, It is sufficient as a glycoprotein fragment for differentiation marker of epithelial ovarian cancer.

2. Epithelial ovarian cancer incidence determination method The second embodiment of the present invention is an epithelial ovarian cancer incidence determination method.
The method of this embodiment includes a detection step and a determination step. Hereinafter, each process will be specifically described.

2-1. Detection Step The “detection step” refers to one or more glycoproteins for epithelial ovarian cancer differentiation marker described in the first embodiment and / or one or more glycoprotein fragments thereof from a sample collected from a subject, ie, epithelial properties. This is a step of detecting an ovarian cancer differentiation marker. This process further includes a glycoprotein enrichment step and a protein detection step as necessary.

As used herein, “subject” refers to a person who is subjected to a test, that is, a person who provides a sample to be described later. The subject may be either a patient having some disease or a healthy person.
Preferred are those who may be suffering from epithelial ovarian cancer or epithelial ovarian cancer patients.

The “sample” is collected from the subject and used in the determination method of the present embodiment, and corresponds to, for example, a body fluid, a cell (including a cell extract), or a peritoneal washing solution.

“Body fluid” refers to a liquid biological sample collected directly from a subject. Examples include blood (including serum, plasma and interstitial fluid), lymph, ascites, pleural effusion, sputum, cerebrospinal fluid, tears, nasal discharge, saliva, urine, vaginal fluid, semen and the like. Preferably, it is a body fluid such as blood, lymph, ascites or a peritoneal lavage fluid using physiological saline. Body fluid and peritoneal lavage fluid may be used after pre-treatment such as dilution or concentration or addition of a blood coagulation inhibitor such as heparin, if necessary, collected from the subject. It may be used as it is without any pretreatment. In the case of cells, the extract may be obtained after disruption by a method known in the art. Cell extract preparation methods are described, for example, in McMamee MG 1989, Biotechniques.
7: 466-475 and Johnson BH et al., 1994, Biotechnology (NY), 12: 1357-1360, and the like. The body fluid or the peritoneal washing solution may be collected based on a known method in the field. For example, in the case of blood or lymph, a known blood collection method may be followed. Specifically, in the case of peripheral blood, it can be collected by injection into a peripheral vein or the like.
For ascites or abdominal cavity lavage fluid, collection by puncture suction avoiding the intestinal tract under the guide of transabdominal ultrasonic tomography, or about 100 mL of physiological saline is injected into the abdominal cavity at the time of laparotomy, and a syringe is used from the Douglas fossa Can be collected by aspiration. Furthermore, if it is a cell, the cell which should be used for a test | inspection should just be surgically extract | collected from an appropriate organ or tissue.

The body fluid and the peritoneal lavage fluid may be used immediately after collection, or may be used after being stored for a certain period by freezing and then subjected to processing such as thawing as necessary. In this embodiment, when using serum or peritoneal lavage fluid, the detection of epithelial ovarian cancer differentiation marker is usually 10 μL to 1 μm.
A capacity of 00 μL is sufficient.

The epithelial ovarian cancer differentiation marker to be detected in this step may be any of the epithelial ovarian cancer differentiation markers shown in Table 1 above. One kind of epithelial ovarian cancer differentiation marker may be detected, or two or more kinds of epithelial ovarian cancer differentiation markers can also be detected. In the detection of an individual epithelial ovarian cancer differential marker, if it is detected that at least one of the asparagine residues at the glycosylation position shown in Table 1 is glycosylated in the glycoprotein for epithelial ovarian cancer differential marker Good.

The method for detecting the epithelial ovarian cancer differential marker may be any method as long as it is a known method capable of detecting a glycoprotein, and is not particularly limited. For detection, one or more sugar chain probes that bind to the sugar chain of an epithelial ovarian cancer differentiation marker can be used.

In the present specification, the “sugar chain probe” refers to a discriminator that specifically recognizes and binds to a specific sugar chain and / or complex carbohydrate such as a glycoprotein. For example, lectin, antibody or phage antibody can be mentioned. When the sugar chain probe is a lectin, examples of the lectin that can be used in this step include AAL lectin, LCA lectin, and WFA lectin.

As a specific detection method, for example, a glycoprotein enrichment step for selectively enriching a glycoprotein having the sugar chain using a sugar chain probe that specifically binds to a sugar chain of an epithelial ovarian cancer differentiation marker; A method combining a protein detection step of detecting using an antibody specific for the core protein or the like can be used. More specifically, for example, as follows.

Glycoprotein enrichment step: peritoneal lavage fluid or body fluid obtained from a subject (eg, serum)
Using a glycan probe that specifically binds the glycoprotein group contained therein to the glycan of the glycoprotein, for example, a lectin (hereinafter referred to as “lectin A” for convenience). To separate.

Protein detection step: Subsequently, a part other than the sugar chain that specifically binds to lectin A in the epithelial ovarian cancer differentiation marker to be detected, such as an antibody that specifically recognizes the core protein, such as an anti-antibody Detection is performed using a core protein antibody (in the present specification, for the sake of convenience, hereinafter referred to as “antibody B”).

Thereby, an epithelial ovarian cancer differentiation marker having a sugar chain that specifically binds to the target lectin A can be detected. In addition, the order of the enrichment step and detection step of glycoprotein and core protein is not ask | required. For example, after the protein enrichment step in which the core protein is enriched with the antibody B, the target glycoprotein may be detected with a sugar chain probe (eg, lectin A) (glycoprotein detection step).

Or a specific antibody against an epithelial ovarian cancer differential marker having a sugar chain that specifically binds to lectin A, and using the antibody having both the sugar chain part and the protein part as an epitope as a target epithelial ovary A method for detecting a cancer differentiation marker can also be used. In this method, the target epithelial ovarian cancer differentiation marker contained in the peritoneal lavage fluid or serum obtained from the subject, that is, the epithelial ovarian cancer differentiation marker having a sugar chain that specifically binds to lectin A is one step. It is convenient because it can be detected by

The above method comprises a column or array on which lectin A is immobilized, and means for detecting an epithelial ovarian cancer differential marker, more specifically, an antibody against the epithelial ovarian cancer differential marker, preferably binding specifically to lectin A. Lectin-antibody sandwich ELISA using a monoclonal antibody or a polyclonal antibody specific for an epithelial ovarian cancer differentiation marker having a sugar chain
Antibody overlay / lectin array method, lectin overlay / antibody array method, mass spectrometry (high performance liquid chromatography / mass spectrometry (LC-MS), high performance liquid chromatograph / tandem mass spectrometry (LC-MS / MS), gas chromatography mass) Analytical methods (GC-MS), gas chromatograph tandem mass spectrometry (GC-MS / MS), capillary electrophoresis mass spectrometry (CE-MS) and ICP mass spectrometry (ICP-MS) included), immunological Measurement method, enzyme activity measurement method, capillary electrophoresis method, colloidal gold method, radioimmunoassay method, latex agglutination immunoassay method, fluorescent immunoassay method, Western blotting method, immunohistochemistry method, surface plasmon resonance method (SPR method) Alternatively, it can be achieved by a quartz crystal microbalance (QCM) method or the like. These methods are all known methods, and may be performed in accordance with ordinary methods in the field. As a specific example, a lectin-antibody sandwich ELISA method, an antibody overlay / lectin array method, and a lectin overlay / antibody array method will be described below.

The basic principle of the lectin-antibody sandwich ELISA method is the same as that of the sandwich ELISA method using two kinds of antibodies, and only one antibody in the sandwich ELISA method is replaced with a lectin. Therefore, this technique can also be applied to automation using an existing automatic immunodetection device. The only thing to consider is the reaction between the antibody used in the sandwich and the lectin. The antibody has at least two N-linked sugar chains. Therefore, when the lectin used recognizes the sugar chain on the antibody, background noise due to the binding reaction occurs during sandwich detection. In order to suppress the generation of the noise signal, a method of introducing a modification into the sugar chain part on the antibody or a method of using only a Fab that does not contain a sugar chain part can be considered. Examples of methods for modifying the sugar chain moiety include Chen S. et al., 2007, Nat. Methods, 4: 437-44 and Comunale MA et al., 2009, J.
Proteome Res., 8: 595-602, etc., and methods using Fab include, for example, Matsumoto H. et.
al., 2010, Clin. Chem. Lab. Med., 48: 505-512.

The antibody overlay lectin array method uses a lectin array. A lectin array is a glycan probe in which multiple types of lectins with different specificities are immobilized in parallel (arrayed) on a single substrate, and how many lectins are present in the complex carbohydrate to be analyzed. It is possible to analyze all the interactions at the same time. The principle and basics of lectin microarray technology are described in, for example, Kuno A. et al. 2005, Nat. Methods 2: 851-856. In addition, a lectin array in which 45 types of lectins are immobilized on a base is commercially available as LecChip from GP Bioscience, and may be used. In the antibody overlay / lectin array method, a fluorescent group or the like is indirectly introduced into a subject's sample via an antibody, and a multi-analyte can be easily and quickly analyzed using a lectin array. For specific methods, see Kuno A. et al, 2009, Mol. Cell Proteomics 8: 99-108.
, Hirabayashi, et al., 2007, Extra number of experimental medicine "Cancer diagnostic research approaching from molecular level-Challenge to clinical application-
"Yodosha, Vol 25 (17): 164-171, Kaoru Kuno et al., 2008, Gene Medicine, MOOK11, pp.34-39,
See Medical Do).

For example, since the sugar chain part of the glycoprotein in the sample of the subject is specifically recognized by the lectin on the lectin microarray, the test glycoprotein is applied to the core protein part by overlaying it. It is possible to detect specifically and with high sensitivity without labeling or highly purifying.

The lectin overlay / antibody microarray method is a method using an antibody array in which antibodies against a core protein are immobilized (arrayed) in parallel on a substrate such as a glass substrate instead of the lectin microarray in the antibody overlay / lectin array method. The basic principle remains the same, just by reversing the relationship between the lectin and the antibody in the antibody overlay lectin array method. However, it is necessary to determine in advance as many antibodies as possible against the epithelial ovarian cancer differential marker to be examined and the lectin for detecting the sugar chain change.

In the various detection methods described above, polyclonal antibodies and / or monoclonal antibodies that specifically recognize the epithelial ovarian cancer differentiation marker or its core protein to be used can be used if they are commercially available. But if it ’s not readily available,
For example, it can be prepared by the following method.

First, an anti-epithelial ovarian cancer differential marker glycopeptide polyclonal antibody can be prepared using methods well known in the art. Specifically, an adjuvant is added to glycoprotein or glycopeptide for epithelial ovarian cancer differentiation marker for antigen to be detected. As the antigen, an epithelial ovarian cancer differential marker glycopeptide containing a sugar chain binding site (asparagine) may be synthesized and used. Examples of the adjuvant include Freund's complete adjuvant, Freund's incomplete adjuvant, and the like, and these can also be used as a mixture. An antibody-producing animal can be simultaneously inoculated with the antigen together with an adjuvant to boost antibody production. In addition, this peptide is commercially available as keyhole limpet hemocyanin (keyhole li
mpet hemocyanin (KLH) or the like may be covalently bound to the antibody-producing animal. At this time, granulocyte-macrophage colony stimulating factor
ing factor, GM-CSF) can be administered simultaneously to boost antibody production. Antibody-producing animals to inoculate antigens are mammals such as mice, rats, horses, monkeys, rabbits, goats,
Sheep can be used. Any method can be used for immunization as long as it is an existing method, but it is mainly carried out by intravenous injection, subcutaneous injection, intraperitoneal injection or the like. Immunization intervals are not particularly limited, and immunization is performed at intervals of several days to several weeks, preferably at intervals of 4 to 21 days.

After 2-3 days from the final immunization day, whole blood is collected from the immunized animal, serum is separated, and a polyclonal antibody can be prepared.

For example, an anti-epithelial ovarian cancer marker glycopeptide monoclonal antibody can be prepared by the method of Keller & Milstein (Nature 256: 495-497 (1975)). For example,
Prepared by preparing hybridomas by cell fusion of antibody-producing cells obtained from animals immunized with antigen and myeloma cells, and selecting clones that produce anti-epithelial ovarian cancer differentiation marker glycopeptide monoclonal antibodies from the resulting hybridomas can do.

Specifically, antibody production cells are collected 2 to 3 days after the final immunization in the production of the polyclonal antibody. Examples of antibody-producing cells include spleen cells, lymph node cells, and peripheral blood cells.

As myeloma (myeloma) cells to be fused with antibody-producing cells, cell lines derived from various animals such as mice, rats and humans and generally available to those skilled in the art are used. As the cell line to be used, those that have drug resistance and have the property that they cannot survive in a selective medium (for example, HAT medium) in an unfused state but can survive only in a fused state. An 8-azaguanine resistant strain is generally used, and this cell strain is deficient in hypoxanthine-guanine-phosphoribosyltransferase and cannot grow in hypoxanthine / aminopterin / thymidine (HAT) medium.

Myeloma cells are various cell lines already known, such as P3 (P3x63Ag8.653) (Kearney JF
et al., 1979, J. Immunol., 123: 1548-1550), P3x63Ag8U.1 (Yelton DE et al., 197
8, Curr. Top. Microbiol. Immunol., 81: 1-7), NS-1 (Kohler G. et al., 1976, Eur. J.
Immunol., 6: 511-519), MPC-11 (Margulies DH et al., 1976, Cell, 8: 405-415), SP
2/0 (Shulman M. et al., 1978, Nature, 276: 269-270), FO (de St. Groth SF et al.,
1980, J. Immunol. Methods, 35: 1-21), S194 (Trowbridge IS 1978, J. Exp. Med., 14
8: 313-323), R210 (Galfre G. et al., 1979, Nature, 277: 131-133) and the like are preferably used.

Next, the myeloma cell and the antibody-producing cell are fused. Cell fusion, MEM, DME
M, RPMI-1640 medium and other animal cell culture mediums, and commercially available cloning or cell fusion mediums with myeloma cells and antibody-producing cells in a mixing ratio of 1: 1 to 1:10 Bottom, 30
It is performed by contacting at ˜37 ° C. for 1 to 15 minutes. To promote cell fusion,
Fusion promoters and fusion viruses such as polyethylene glycol having an average molecular weight of 1,000 to 6,000, polyvinyl alcohol, or Sendai virus can be used. Alternatively, antibody-producing cells and myeloma cells can be fused using a commercially available cell fusion device utilizing electrical stimulation (for example, electroporation).

The target hybridoma is selected from the cells after cell fusion treatment. Examples of the method include a method utilizing selective growth of cells in a selective medium. That is, after the cell suspension is diluted with an appropriate medium, it is plated on a microtiter plate, and a selective medium (HAT) is added to each well.
Medium, etc.) is added, and then the culture is carried out with appropriate selection medium exchange. As a result, growing cells can be obtained as hybridomas.

Hybridoma screening is performed by limiting dilution, fluorescence excitation cell sorter, or the like, and finally a monoclonal antibody-producing hybridoma is obtained. Examples of a method for collecting a monoclonal antibody from the obtained hybridoma include a normal cell culture method and ascites formation method.

2-2. Judgment process The "judgment process" is a process in which, when an epithelial ovarian cancer differentiation marker is detected from a sample collected from a subject in the detection process, the subject is judged to be suffering from epithelial ovarian cancer. is there.

The determination of the detection of the epithelial ovarian cancer differentiation marker may be made based on whether or not the target epithelial ovarian cancer differentiation marker has been detected as a result of the detection method described in the detection step. When the specificity of the epithelial ovarian cancer differentiation marker such as a sugar chain probe is high and no cross-reactivity is observed (when the determinant is an antibody), accurate judgment is made only by the presence or absence of this detection. Can do.

On the other hand, if the specificity of the determinant is relatively low and glycoproteins other than the epithelial ovarian cancer differentiation marker to be detected are detected, that is, if the detection background is relatively high, the presence or absence of detection It is not possible to make an accurate judgment. In this case, the detection amount of the subject epithelial ovarian cancer differentiation marker in the subject may be determined based on a statistically significant difference compared to that of a healthy person. Here, the “healthy person” is a person who is apparently not suffering from epithelial ovarian cancer, preferably a healthy person not suffering from a disease, more preferably a person whose biological condition is close to the subject, For example, gender, age, weight, constitution (allergies, etc.), medical history,
Those who have the same or similar conditions for childbirth.

As the detection amount, the quantitative result of the epithelial ovarian cancer differential marker by the detection method described in the detection step can be used. At this time, if a known protein that is expected to have no quantitative difference between the sample of the subject and the healthy subject is used as an internal control, the quantitative result of the subject and the healthy subject can be corrected. The quantity can be obtained. Examples of such a protein for internal control include albumin.

“Statistically significant” means that when the quantitative difference of the epithelial ovarian cancer differential marker that is the detection target contained in the sample collected from each of the subject and the healthy subject is statistically processed, Means that there is a significant difference. Specifically, for example, the risk rate (significance level) is 5%, 1%, or 0.
The case where it is smaller than 1% is mentioned. The test method for statistical processing is not particularly limited as long as a known test method capable of determining the presence or absence of significance is appropriately used. For example, Student's t-test method and multiple comparison test method can be used (Suzuki ▼ Completion ▲, Basics of Statistics, Atsushi Nagata et al.
Statistical multiple comparison basis). Specifically, “statistically significant difference” means that in multi-analyte analysis, a value that can separate patients and healthy individuals so that the sensitivity and specificity set by the conventional method are optimal. And is higher or lower than the cut-off value.

Specific methods for determining the morbidity of epithelial ovarian cancer by detecting an epithelial ovarian cancer differentiation marker include, for example, the following methods.

When the glycoprotein for differentiation marker for epithelial ovarian cancer according to any one of Table 1 and / or its glycoprotein fragment, that is, the marker for differentiation of epithelial ovarian cancer is detected alone,
If it is determined that the subject who provided the sample has epithelial ovarian cancer that can be differentiated by the epithelial ovarian cancer differentiation marker, and it is not detected, it can be differentiated at least by the epithelial ovarian cancer differentiation marker No epithelial ovarian cancer is determined. Specifically, for example, when the LOXL2 glycoprotein represented by protein # 28 in Table 1 is detected in a sample, the subject provided with the sample can be determined to have epithelial ovarian cancer. . In addition, when the COL6α1 glycoprotein represented by protein # 1 in Table 1 is detected in a sample, the subject who provided the sample has or may have a clear cell tumor or serous tumor. It can be determined to be high.

Even when two or more kinds of epithelial ovarian cancer differentiation markers listed in Table 1 are used for detection, the subject who provided the sample suffers from epithelial ovarian cancer that can be differentiated by each epithelial ovarian cancer differentiation marker. If it is not detected, it is determined that the patient is not affected by at least epithelial ovarian cancer that can be differentiated by the epithelial ovarian cancer differentiation marker. Specifically, for example, the LOXL2 glycoprotein represented by protein # 28 and the CP glycoprotein represented by protein # 35 in Table 1 are used as epithelial ovarian cancer differentiation markers, and each can be detected. If the test subject has provided the sample, it can be determined that the subject is suffering from or very likely to have epithelial ovarian cancer. On the other hand, if LOXL2 glycoprotein was detected but CP glycoprotein could not be detected, the detection result of LOXL2 glycoprotein was false positive, or the detection result of CP glycoprotein was false negative, and other epithelia were detected. It can be determined that redetection is required, such as attempting to detect a sex ovarian cancer differentiation marker. Further, the COL6α1 glycoprotein represented by the LOXL2 glycoprotein and protein # 1 was detected as an epithelial ovarian cancer differentiation marker, and if both were detected, the subject who provided the sample was epithelial. In the case of suffering from ovarian cancer and accompanying endometriosis, the tissue type can be determined to be clear cell tumor.
On the other hand, if LOXL2 glycoprotein was detected but COL6α1 glycoprotein was not detected, the subject who provided the sample suffered from epithelial ovarian cancer, but the tissue type was clear cell tumor. Alternatively, it can be determined that the tumor is not a serous tumor. In this way, by detecting two or more epithelial ovarian cancer differentiation markers, false positive rate and false negative rate are lower than when detecting epithelial ovarian cancer differentiation markers alone, and more accurate differentiation And the presence or absence of epithelial ovarian cancer, as well as differentiation of the tissue type is possible, which is preferable as the epithelial ovarian cancer incidence determination method of the present embodiment.

<Example 1: Selection of epithelial ovarian cancer differentiation marker>
1. Selection of probe lectins by lectin microarray using culture supernatant (method)
(1) Preparation of epithelial ovarian cancer, gastric cancer, and colon cancer cell line culture supernatants 90% of five epithelial ovarian cancer cell lines (RMG-I, RMG-II, RTSG, RMG-V, RMUG-S) HamF12, 10% F
Using BS (PS ⁺ ) medium and as a non-epithelial ovarian cancer cell line, one type of gastric cancer cell line (KATOII
I) and two types of colon cancer cell lines (Colo201, Colo205) were cultured using 90% RPMI-1640 and 10% FBS (PS ⁺ ) medium, respectively. Here, RMG-I, RMG-V, RMUG-S, RMG-II, and RTSG are cultured in a 14 cm diameter dish until they become 80-90% confluent, and the FBS-containing medium is not added after aspiration removal. medium (FBS ^-, PS ^-) after washing 7 times with 10 mL / dish, the same medium 30mL
And cultured for 48 hours. For KATOIII, Colo201, and Colo205, diameter 14c
Prepare 1 x 10 ⁷ cells per m dish, add 10 mL of the above additive-free medium, and suspend and centrifuge (1000 r
After washing with supernatant removal (7 pm, 5 minutes, room temperature) 7 times, seeding was carried out on a 14 cm dish, and 30 mL of an additive-free medium was added and cultured for 48 hours. After incubation, the supernatant was collected by centrifugation (1000 rpm, 5 minutes, room temperature), and the collected supernatant was centrifuged again (3000 rpm, 5 minutes, room temperature) to collect the supernatant and stored frozen at −80 ° C. The stored sample should be thawed before use and filtered using a 0.46 μm filter.
Used for the following analysis.

(2) Selection of probe lectin by lectin microarray The above-prepared culture supernatant was concentrated and desalted using 2-D Clean-Up kit (GE), and the resulting precipitate was redissolved in 20 μL of PBS. Micro BCA protein assay for protein concentration in each culture supernatant
After measurement using a kit (Pierce), dilute 10 times with PBS, collect 100 ng of total protein, prepare 10 μL with PBSTx (PBS containing 1% Triton X-100), and then add 20 ng of fluorescent label Reagent (Cy
3-SE, GE) was added and reacted at room temperature for 1 hour. After the reaction, 90 μL of glycine-containing buffer was added, and the mixture was further reacted at room temperature for 2 hours to inactivate the excess labeling reagent, which was then applied to a lectin microarray as a fluorescently labeled glycoprotein solution. The lectin microphone alloarray used was one in which 43 different lectins were immobilized in three spots. In order to optimize the comparative analysis of the binding signals obtained, four dilution series were prepared and analyzed for each sample. The binding reaction to lectin was performed at 20 ° C. for 12 hours. After the reaction, the sample solution on the array was removed, washed 3 times with a dedicated buffer, and then the signal intensity was measured using a lectin microarray scanner (GlycoStation ™ Reader 1200) manufactured by GP Bioscience. After calculating the true value minus the background value, calculate the average value between the three spots of each lectin,
The relative signal value was determined by setting the maximum signal intensity for all lectins as a reference value, and the following statistical processing was performed. After converting the calculated relative values into common constants, signal pattern analysis using the cluster analysis method and principal component analysis method is used for epithelial ovarian cancer and non-epithelial ovarian cancer (stomach cancer and colon cancer).
It was confirmed that it was divided into two groups. Next, WFA lectin that can confirm a significant difference between these two groups was extracted by t-test. At the same time, AAL lectins in which high signals were detected in all samples subjected to lectin microarray analysis were extracted. These WFA lectin and AAL lectin were selected as probes to be used thereafter.

(result)
FIG. 1 shows the binding signal intensities of glycoproteins derived from each cancer cell line and the two types of lectins extracted by the above steps. FIG. 1A shows the WFA lectin, and FIG. 1B shows the AAL lectin. As shown in this figure, the WFA lectin showed a high signal in the epithelial ovarian cancer cell line, while the signal in the colon cancer cell line and gastric cancer cell line, which are non-epithelial ovarian cancer cell lines, was low.
AAL lectin showed a high signal in the epithelial ovarian cancer cell line and non-epithelial ovarian cancer cell line, while the signal in the gastric cancer cell line (KATOIII) was low. WFA lectin and AAL
Lectin had a low signal for RMUG-S, one of the epithelial ovarian cancer cell lines,
This is based on the result of the entire analysis of the glycoprotein as a selection of the probe lectin by this experiment, and does not show the behavior related to the lectin binding property of individual glycoproteins as in the examples. As described above, it has been clarified that WFA lectin and AAL lectin can be probe lectins that bind to sugar chains of glycoproteins secreted by epithelial ovarian cancer cell lines.

2. Selection of glycopeptide markers by glycoproteomics (IGOT-LC / MS method)
(1) Preparation of peptide sample A sample protein was prepared from the culture supernatant of the epithelial ovarian cancer cell line and the peritoneal lavage fluid. The culture supernatant of the epithelial ovarian cancer cell line is 1. Prepared according to the method described in (1). The peritoneal lavage fluid was collected from the Aichi Cancer Center Central Hospital at the time of surgery.
Seven cases (56-77y) (3 clear cell carcinoma patients, stage IIIC-IV; endometrioid adenocarcinoma 1 stage, stage IV; serous adenocarcinoma 3 cases, IIIC-IV) were used. Culture supernatant of 3.6-7.6mg total protein (1260-3300mL)
In addition, add trichloroacetic acid (TCA, 100% saturated aqueous solution) to the peritoneal lavage fluid (0.3 to 300 mL) of 8.2 to 15.4 mg total protein to a final concentration of 10%, and cool the protein for 10 to 60 minutes on ice. Precipitated. The precipitate was collected by high-speed centrifugation at 4 ° C., suspended in ice-cold acetone, and TCA was removed by washing twice. To the resulting precipitate, a solubilization buffer (0.5M Tris-
Hydrochloric acid buffer (pH 8-8.5), 7M guanidine hydrochloride, 10mM EDTA), protein concentration 5
The sample protein was dissolved by adding to ˜10 mg / mL. As another method, the culture supernatant and the peritoneal washing solution were respectively concentrated at 4 ° C. using an ultrafiltration membrane having a molecular weight of 10,000 cut, and a solubilized buffer solution was added thereto and filtered again to obtain a sample protein.

Subsequently, the sample protein was subjected to high-speed centrifugation at 4 ° C. to remove residues, and the resulting supernatant was recovered as an extract. After the dissolved oxygen was removed by aeration or blowing of nitrogen gas to the extract, dithiothreitol (DTT) in an amount equal to the protein weight was dissolved in a powder or a small amount of solubilization buffer and added. The reaction was allowed to proceed for 1-2 hours at room temperature in order to reduce disulfide bonds under nitrogen gas flow or atmosphere. Then 2 of protein weight for S-alkylation
. Five times the amount of iodoacetamide was added, and the mixture was allowed to react at room temperature for 1 to 2 hours. 50-100 after reaction
A double volume of buffer solution (10 mM ammonium bicarbonate buffer pH 8.6) was dialyzed at 4 ° C. as an external solution.
The external solution was changed 3 to 5 times to remove the denaturant (guanidine hydrochloride) and excess reagent. Although partial precipitation of proteins was observed by these operations, protein quantification was performed in a suspension without collecting them. 1/100 to 1/50 weight protein trypsin (sequence grade or higher) was added and digested at 37 ° C. overnight (about 16 hours). After confirming the progress of sufficient digestion by SDS-gel electrophoresis, the reaction was stopped by adding 5 mM final concentration of phenylmethanesulfonyl fluoride (PMSF). A solution consisting of the obtained protein fragment (peptide) was used as a sample peptide.

(2) Collection and purification of candidate glycopeptide After the sample peptide is applied to a column on which a probe lectin (AAL lectin and / or WFA lectin) is immobilized and washed, a method according to the specificity of the lectin, that is, AAL For the lectin, the glycopeptide was eluted using a buffer containing 5 mM fucose, and for the WFA lectin, a buffer containing 10 mM GalNAc. To the resulting glycopeptide solution, add an equal volume of ethanol and 4 volumes of 1-butanol, water: ethanol: 1-butanol (1: 1: 4 (v / v
)) And pre-equilibrated to a Sepharose column. After washing the column with the same equilibration solvent, 50
The glycopeptide was eluted using% ethanol (v / v). The glycopeptide fraction was transferred little by little to a microtube containing 2 μL of glycerol, and the glycopeptide fraction was concentrated by repeatedly removing water by vacuum centrifugation. A glycerol solution of the obtained purified glycopeptide was used as a glycopeptide sample.

(3) Glycotomy and glycosylation site-isotope-coded glycosylation site-s
pecific tagging method: IGOT method)
Of buffer required amount to the glycopeptide sample is added, the pressure was reduced centrifuged again concentrated and dissolved by adding labeled with stable isotopes oxygen -18 ⁽¹⁸ O) water (H ₂ ¹⁸ O) (glycerol concentration of 10 % Or less). Peptide-N-glycanase (Glyopeptidase F, PNGa) prepared with labeled water
se) was added and reacted at 37 ° C. overnight. This reaction asparagine glycosylation site is aspartic acid, water isotopic oxygen at that time ⁽¹⁸ O) is glycopeptide is labeled by being incorporated into the glycopeptide.

(4) LC / MS shotgun analysis of labeled peptide The reaction solution containing the glycopeptide labeled by the above IGOT method was diluted with 0.1% formic acid and subjected to LC / MS shotgun analysis. In order to detect with high resolution, high reproducibility, and high sensitivity, a nano LC system based on a direct nanoflow pump was used. The injected glycopeptide sample is once collected on a trap column (reverse phase C18 silica gel carrier) for desalting, washed,
Fritless micro column (inner diameter 150μm ×) in the shape of spray tip packed with the same resin
50 mL), and separated by the acetonitrile concentration gradient method. The eluate was ionized via an electrospray interface and introduced directly into the mass spectrometer. Mass spectrometry performed tandem mass spectrometry by collision induced dissociation (CID) while selecting up to two ions in a data dependent mode.

(5) Retrieval of candidate glycopeptides by MS / MS-ion search method Thousands of obtained MS / MS spectra were individually smoothed and centered to create a peak list. Based on this data, the detected glycopeptide was identified by the MS / MS ion search method using the protein amino acid sequence database. The search engine was Mascot from Matrix Science. Fragmentation method used (trypsin digestion), miscleavage capacity: 2, fixed modification: cysteine carbamidomethylation, variable modification: N-terminal amino group deamination (terminal glutamine) ), Oxidation (
Methionine), deamidation incorporating ¹⁸ O (asparagine: glycosylation site), MS spectrum tolerance: 500 ppm, MS / MS spectrum tolerance: 0.5 Da.

(6) Identification of glycoprotein for epithelial ovarian cancer differentiation marker The glycopeptide obtained from the search under the above conditions is subjected to the identification confirmation processing of (i) to (iv) below, and the saccharide satisfying all conditions Peptides were selected.
(I) The probability of identification (probability of coincidence: Expect value) is 0.05 or less.
(Ii) The number of fragment ions contributing to the identification is 4 or more.
(Iii) The error (ppm) is not significantly different from the systematic error (the mass error is 0.5 Da or less).
(Iv) The identified peptide has a consensus sequence and has fewer than that number of Asn modifications (conversion to Asp and incorporation of ¹⁸ O).

(result)
The selected glycopeptides are represented by SEQ ID NOs: 1 to 388 as “peptide sequences” in Table 1 above. Based on the amino acid sequences of these peptides, the entire amino acid sequence of the core protein in the glycoprotein for differential epithelial ovarian cancer marker was identified from the amino acid sequence database NCBI-Refseq. As a result, 262 types of glycoproteins for differentiation marker of epithelial ovarian cancer were identified. Table 1 shows the core protein names of glycoproteins for epithelial ovarian cancer differentiation markers.

<Example 2: Detection of epithelial ovarian cancer by epithelial ovarian cancer differentiation marker>
The detection of epithelial ovarian cancer using the epithelial ovarian cancer differentiation marker selected and identified in Example 1 was verified.
(Method)
(1) Fractionation of peritoneal lavage fluid using probe lectin 2 each of ovarian cancer patients with clear cell tumor, mucinous tumor, serous tumor and endometrioid tumor, and approximately 100 mL of physiological saline injected into the abdominal cavity at the time of surgery After collecting the peritoneal lavage fluid from the Douglas fossa using a syringe or the like, the peritoneal lavage fluid of 2 gastric cancer patients whose intraperitoneal progress was confirmed by qPCR was used. The concentration of the protein contained in each peritoneal washing solution was measured by the BCA method, and the total protein amount in each sample was adjusted to an equal amount, and then subjected to the following AAL lectin or WFA lectin fraction.

For AAL fractionation, 0.5 mL of AAL-agarose (Vector Laboratories) 2 mL Disposable poly
After filling a styrene column (Pierce) and washing with 10 times the amount of TBS (pH 8), make 500 μL.
Each abdominal cavity washing solution (0.25 mg total protein amount) prepared with TBS was used, and the sample was left at room temperature while remaining in the column and allowed to react overnight. Then collect the passing sample and place the column in 10 mL TB.
After washing with S, elution was performed with 1 mL of 50 mM fucose-TBS (fraction A-1). Further, the column was allowed to react at room temperature for 30 minutes, and then fractions were collected using 2.4 mL of the eluate (fraction A-2).
. Thereafter, the column was washed with 4 mL of TBS, and the whole collected fraction was passed through the column again, and the sample was allowed to stand at room temperature for 4 hours while remaining in the column. 10mL after reaction
The column was washed with TBS, and fractions were collected using 0.6 mL of the eluate (fraction A-3). further,
The column was allowed to react at room temperature for 30 minutes, and then fractions were collected using 1.4 mL of the eluate (fraction A-4). The A-1 to A-4 fractions were pooled as the AAL (+) fraction of the peritoneal washing solution.

For the WFA fraction, 0.3 mL of WFA agarose (Vector Laboratories) is 2 mL
After filling and washing an isposable polystyrene column (Pierce), 500 μL of each peritoneal washing solution (2.5 mg total protein amount) prepared with TBS was allowed to react at room temperature for 30 minutes. After the reaction, the column was washed with 6 mL of TBS and then eluted with 0.18 mL of 200 mM lactose-TBS (fractionation).
W-1). Next, the column from which fraction W-1 was eluted was allowed to stand at room temperature for 30 minutes, and then the fraction was collected using 0.72 mL of the eluate (fraction W-2). The collected W-1 and W-2 fractions were pooled as the peritoneal washing WFA (+) fraction.

(2) Immunoblotting After the pooled samples were concentrated using Amicon Ultra-154 centrifugal filter units (10 kDa cutoff, Millipore), the glycoprotein for epithelial ovarian cancer differentiation marker obtained in Example 1 was used. Immunoblotting was performed using an antibody that specifically binds to the core protein.

Regarding the glycoprotein for epithelial ovarian cancer differentiation marker, among the 262 types shown in Table 1 obtained in Example 1, antibodies that specifically recognize the core protein are commercially available. Five species were selected. That is, in Table 1, protein # 1 type 6 collagen α1 protein (COL6α1), protein # 28 lysyl oxidase-like 2 protein (L
OXL2), Ceruloplasmin protein (CP) of the same protein # 35, SERP of the same protein # 42
ING1 protein and blood coagulation factor factor XII protein (F12) of protein # 68. Anti-COL6α1 polyclonal antibody (17023-1-AP: ProteinTech), anti-LOXL2 polyclonal antibody (GTX105085: GeneTex), anti-CP polyclonal antibody (A80-124A: Beth)
yl), anti-SERPING1 monoclonal antibody (3F4-1D9, H00000710-M01: Abnova) and anti-F12
An antibody (B7C9, GTX21007: GeneTex) was used. These antibodies can be used in Biotin Labeling Kit
Biotinylation was performed using —NH ₂ (Dojindo Laboratories). Biotinylation followed the attached protocol.

The AAL (+) or WFA (+) fraction of the peritoneal lavage fluid prepared in (1) above is added to the XV PANTERA SYSYTEM
After developing on SDS-PAGE using 10% acrylamide gel (Maruyuki Trading Co., Ltd.), 200mA, 90 minutes
Transferred to PVDF membrane (Bio-Rad). As a blocking agent, 5% skim milk or 5% BSA dissolved in PBST obtained by adding 0.1% Tween 20 to PBS was used. After blocking overnight at 4 ° C., washing was performed 3 times with PBST for 10 minutes. Subsequently, the biotinylated antibody was added as a primary antibody to the membrane and allowed to react at room temperature for 1 hour. Here, the anti-COL6α1 antibody was applied to the membrane to which the AAL (+) fraction was transferred, and the anti-LOXL2 antibody and anti-CP were applied to the membrane to which the WFA (+) fraction was transferred.
Antibody, anti-SERPING1 antibody and anti-F12 antibody were added respectively. After the reaction, the plate was again washed with PBST for 10 minutes three times, and then HRP-conjugated streptavidin (1: 3) as a secondary antibody for biotinylated antibody.
000 dilution, GE) for 1 hour at room temperature. After washing with PBST for 10 minutes three times, HRP enzyme reaction was performed using Western Lightning Chemiluminescence Reagent Plus (Perkin Elmer), and the signal was detected with Amersham Hyperfilm ECL (GE) for comparative analysis. It was.

(result)
The detection results of glycoproteins for each epithelial ovarian cancer differentiation marker in the peritoneal lavage fluid in the above cancer patients are shown in FIGS.

From the results shown in FIG. 2, COL6α1 was not detected from patients with gastric cancer, which is non-epithelial ovarian cancer. In the case of epithelial ovarian cancer patients, it was detected in clear cell adenocarcinoma patients and serous adenocarcinoma patients, but was hardly detected in endometrioid adenocarcinoma patients. That is, it has been clarified that COL6α1 can be a glycoprotein for differentiation marker of epithelial ovarian cancer that can be narrowed down to clear cell tumor or serous tumor among epithelial ovarian cancer. Like clear cell tumors, it is not detected in endometrioid tumors often associated with endometriosis, and can therefore be a marker glycoprotein that can enclose clear cell tumors in endometriosis-associated types It became clear.

From the results of FIGS. 3 to 6, LOXL2, CP, SERPING1 and F12 were detected from all histological types of epithelial ovarian cancer patients, but not from gastric cancer patients. Therefore,
It became clear that the glycoproteins of LOXL2, CP, SERPING1 and F12 can be used as glycoproteins for differentiation markers of epithelial ovarian cancer capable of differentiating epithelial ovarian cancer regardless of tissue type.

In addition, epithelial ovarian cancer was either tissue type-specific or non-specifically selected from all five of the glycoproteins for epithelial ovarian cancer differentiation markers listed in Table 1 obtained in Example 1. From the detection, it was shown that any of the glycoproteins shown in Table 1 can be a glycoprotein for epithelial ovarian cancer differentiation marker.

Claims (13)

A glycoprotein for epithelial ovarian cancer differentiation marker, wherein a sugar chain is added to at least one asparagine residue at the sugar addition position shown in Table 1 in the amino acid sequence of the protein shown in Table 1.

The glycoprotein according to claim 1, wherein the sugar chain is a sugar chain containing a fucose modification and / or a terminal N-acetylgalactosamine. The glycoprotein according to claim 1 or 2, wherein the sugar chain binds to an AAL lectin and / or a WFA lectin. The glycoprotein according to any one of claims 1 to 3, wherein the epithelial ovarian cancer is at least one of a clear cell tumor, a mucinous tumor, a serous tumor and an endometrioid tumor. The glycoprotein according to claim 4, wherein the protein is type 6 collagen α1 and the epithelial ovarian cancer is a clear cell tumor or a serous tumor. The glycoprotein fragment for epithelial ovarian cancer differentiation marker according to any one of claims 1 to 5, comprising at least one asparagine residue having a sugar chain added at the sugar addition position shown in Table 1. One or more glycoproteins for epithelial ovarian cancer differential markers according to any one of claims 1 to 5 and / or one or more protein fragments according to claim 6 are detected from a sample collected from a subject. And a method for determining the incidence of epithelial ovarian cancer, comprising the step of determining that the subject is suffering from epithelial ovarian cancer when the glycoprotein and / or the glycoprotein fragment is detected. 8. The detection step includes a glycoprotein enrichment step and a protein detection step.
The method described in 1. The method according to claim 7 or 8, wherein the glycoprotein for differentiation marker for epithelial ovarian cancer and / or a glycoprotein fragment thereof is detected using one or more sugar chain probes that bind to the sugar chain.   The method according to claim 9, wherein the sugar chain probe is a lectin, an antibody, or a phage antibody.   The method according to claim 10, wherein the lectin is AAL or WFA. The method according to any one of claims 7 to 11, wherein the sample is a body fluid, a cell, or a peritoneal washing solution. The method according to any one of claims 7 to 12, wherein the epithelial ovarian cancer is at least one of clear cell tumor, mucinous tumor, serous tumor and endometrioid tumor.

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