PROTEIN MARKERS FOR DETECTING LIVER CANCER AND METHOD FOR IDENTIFYING THE MARKERS THEREOF

Abstract

The present invention relates to the diagnosis of liver cancer. It discloses the use of protein ERBB3 and protein IGFBP2 in the diagnosis of liver cancer. It relates to a method for diagnosis of liver cancer from a liquid sample, derived from an individual by measuring ERBB3 protein and IGFBP2 protein in the sample. Measurement of ERBB3 protein and IGFBP2 protein can, e.g., be used in the early detection or diagnosis of liver cancer.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a division of U.S. patent application Ser. No. 12/831,447, filed on Jul. 7, 2010, titled Protein Markers for Detecting Liver Cancer and Method for Identifying the Markers Thereof, listing Sen-Yung Hsieh as inventor.

FIELD OF THE INVENTION

The present invention relates to protein markers for detecting liver cancer, also called hepatoma, in plasma or serum and a method for detecting liver cancer thereof. The present invention also relates to a method for identifying a novel marker in plasma/serum for detecting liver cancer. In particular, the present invention relates to protein markers expressed in tissue interstitial fluid and a method for identifying novel marker in a tissue interstitial fluid for detecting liver cancer. Especially, the present invention relates to plasma/serums ERBB3 and IGFBP2 protein markers used for detecting liver cancer precisely.

BACKGROUND OF THE INVENTION

Cancer remains a major public health challenge despite progress in detection and therapy. Whole blood, serum, plasma, or nipple aspirate fluid are the most widely used sources of sample in clinical routine. Conventionally, researchers try to find valuable markers from plasma/serum to detect liver cancer. However, up to 90 percentage of the plasma/serum are composed by 6 constant serum proteins, and 99 percentage are composed by about 20 constant proteins. The metabolic and the physiological conditions could be represented in whole blood, serum or plasma. Some specific proteins with diagnosis values are secreted into whole blood, serum or plasma, but they always present in a trace amount and are hard to be found. Therefore, an urgent clinical need exists to improve the method to identify biomarkers for the diagnosis of liver cancer from plasma/serum.

Some researchers tried to find tumor markers from hepatocellular carcinoma (hereinafter may be referred to as “liver cancer”, “hepatoma” or “HCC”) tissue or cell culture media. However, neither tumor tissues nor cell culture media of hepatocellular carcinoma has been proved to be an adequate source for identifying new serum markers for hepatoma. In contrast, the tissue interstitial fluid is the media between tumor cells and the circulation, and tumor interstitial fluid represents the microenvironment that tumor cells inhabit. Tumor markers shed into circulation may also be generated by interaction of tumor cells with its microenvironment. It is, therefore, tempting to examine whether tumor interstitial fluid is the source for discovery of serum biomarkers.

So far, some markers, including alpha-fetoprotein (AFP), alpha-fetoprotein lectin fraction-L3 fraction, PIVKA-II, AFU and GPC3, have conventionally been employed for liver cancer diagnosis. However, results obtained from detecting by the foregoing tumor markers often show false-positive or false-negative, so that their functions of detection are limited clinically. Despite the large and ever growing list of candidate protein markers in the field of liver cancer, to date clinical/diagnostic utility of these molecules is not known. In order to be of clinical utility, a new diagnostic marker as a single marker should be at least as good as the best single marker known in the art. Or, a new marker should lead to a progress in diagnostic sensitivity and/or specificity either if used alone or in combination with one or more other markers, respectively.

Therefore, there is a keen need in the art to develop a new tumor marker for clinical diagnosis and increase the precision of diagnosis. It was the task of the present invention to investigate whether a new marker can be identified which may aid in liver cancer diagnosis. Surprisingly, it has been found that use of the marker ERBB3 or IGFBP2 can at least partially overcome the problems known from the state of the art.

SUMMARY OF THE INVENTION

The present invention therefore relates to a novel protein marker ERBB3 for detecting liver cancer.

The present invention therefore relates to a novel protein marker IGFBP2 for detecting liver cancer.

The present invention therefore relates to a method for the detection of liver cancer comprising the steps of a) providing a liquid sample obtained from an individual, b) contacting said sample with a specific binding agent for ERBB3 or IGFBP2 under conditions appropriate for formation of a complex between said binding agent and ERBB3 or IGFBP2, and c) correlating the amount of complex formed in (b) to the detection of liver cancer.

The present invention also relates to a method for identifying a marker for detecting liver tumor in plasma/serum, comprising:

obtaining fresh tissues of liver cancer and non-cancer liver tissues from patients with liver cancer, cutting the tissues and washing by PBS solution twice, culturing the cut tissues in an incubator for 10 minutes, and then precipitating by centrifugation at 1000-2000 rpm/min for 2-5 minutes to obtain cell pellets and removing the contaminations;

re-suspending the cell pellets in PBS solution, culturing the suspended cells in PBS solution in the incubator for 60 minutes, precipitating by centrifugation at 1000-2000 rpm/min for 2-5 minutes to remove cell pellets and obtain a crude tissue interstitial fluid;

centrifugating the crude tissue interstitial fluids by centrifugation at 5000-15000 rpm/min for 15-30 minutes to remove undissolved cell matrix and obtain a pure tissue interstitial fluid;

comparing the difference of the protein components between the tissue interstitial fluids obtained from the liver cancer tissues and non-cancer liver tissues by proteomic methods, then identifying the relatively high-content proteins in tissue fluids of the liver cancer cells, and listing those relatively high-content proteins as candidate biomarkers for hepatoma detection;

detecting the candidate biomarkers in serum by ELISA and measuring the concentrations of the candidate markers, and

analyzing the concentrations difference by student t-test analysis and Receiver Operating Characteristic curve (ROC curve) to check the function of the candidate biomarkers.

The candidate biomarkers were further used to detect serum samples obtained from liver cancer patients and non-liver cancer patients by ELISA and ROC curve. When area under curve values (AUC values) of the candidate markers in serums are greater than 90%, the protein is classified as suitable markers for hepatoma detection.

Comparing with the conventional method of detecting liver cancer, it is hard to find a suitable marker from serum for detecting liver cancer by the conventional methods. The present invention provides a novel ERBB3 protein and a novel IGFBP2 protein as markers for liver cancer detection. ERBB3 protein and IGFBP2 protein are found from tissue interstitial fluids and have been proven their powerful functions in identifying liver cancers. Detection by the concentrations of ERBB3 protein and IGFBP2 protein in patients' serum/plasma or whole blood could increase the sensitivity of liver cancer diagnosis.

As a skilled artisan will appreciate, any such diagnosis is made in vitro. The patient sample is discarded afterwards. The patient sample is merely used for the in vitro diagnostic method of the invention and the material of the patient sample is not transferred back into the patient's body. Typically, the sample is a liquid sample.

A specific binding agent preferably is an antibody reactive with ERBB3 or IGFBP2. The term antibody refers to a polyclonal antibody, a monoclonal antibody, fragments of such antibodies, as well as to genetic constructs comprising the binding domain of an antibody. Any antibody fragment retaining the above criteria of a specific binding agent can also be used.

In a preferred embodiment the method according to the present invention is practiced with serum as liquid sample material.

In a further preferred embodiment the method according to the present invention is practiced with plasma as liquid sample material.

In a further preferred embodiment the method according to the present invention is practiced with whole blood as liquid sample material.

In a further preferred embodiment the method according to the present invention is practiced with tissue interstitial fluid of liver as liquid sample material.

Whereas application of routine proteomics methods to tissue interstitial fluid obtained from tissue samples, leads to the identification of many potential marker candidates for the tissue selected, the inventors of the present invention have been able to surprisingly detect both or one of ERBB3 and IGFBP2 in a bodily fluid sample. Even more surprising they have been able to demonstrate that the presence of ERBB3 and IGFBP2 in such liquid sample obtained from an individual can be correlated to the diagnosis of liver cancer.

Antibodies to ERBB3 and IGFBP2 with great advantages can be used in established procedures, e.g., to detect liver cancer cells in situ, in biopsies, or in immunohistological procedures.

Preferably, an antibody to ERBB3 is used in a qualitative (ERBB3 present or absent) or quantitative (ERBB3 amount is determined) immunoassay.

Preferably, an antibody to IGFBP2 is used in a qualitative (IGFBP2 present or absent) or quantitative (IGFBP2 amount is determined) immunoassay.

Measuring the level of protein ERBB3 or IGFBP2 has proven very advantageous in the field of liver cancer. Therefore, in a further preferred embodiment, the present invention relates to use of protein ERBB3 or/and IGFBP2 as a marker molecule in the diagnosis of liver cancer from a liquid sample obtained from an individual.

The details of one or more embodiments of the technology are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the technology will be apparent from the description and drawings, and from the claims. All cited patents, and patent applications and references (including references to public sequence database entries) are incorporated by reference in their entireties for all purposes.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a scheme showing steps performing in accordance with the present invention.

FIG. 2A is a picture showing a two-dimensional gel electrophoresis (2-DE) of Example 1 in accordance with the present invention.

FIG. 2B is a picture showing a two-dimensional differential fluorescence gel electrophoresis (2-D DICE) condition of Example 1 in accordance with the present invention.

FIG. 3 is a picture showing results of normal tissue interstitial fluid and tumor tissue interstitial fluid on a biochip.

FIG. 4 is a chart showing different concentrations of ERBB3 proteins obtained from different tissues.

FIG. 5A is a chart showing ROC curve of serum ERBB3 discriminating hepatoma from non-hepatoma controls in the discovery group in accordance with the present invention.

FIG. 5B is a chart showing ROC curve of serum ERBB3 discriminating hepatoma from non-hepatoma controls in the validation group in accordance with the present invention.

FIG. 5C is a chart showing ROC curve of serum ERBB3 discriminating hepatoma from non-hepatoma controls in the discovery and validation groups in accordance with the present invention.

FIG. 6 is a chart showing different IGFBP2 concentrations in Example 1 obtained from different tissues.

FIG. 7A is a chart showing ROC curve of serum IGFBP2 discriminating hepatoma from non-hepatoma controls in the discovery group in accordance with the present invention.

FIG. 7B is a chart showing ROC curve of serum IGFBP2 discriminating hepatoma from non-hepatoma controls in the validation group in accordance with the present invention.

FIG. 7C is a chart showing ROC curve of serum IGFBP2 discriminating hepatoma from non-hepatoma controls in the discovery and validation groups in accordance with the present invention.

FIG. 8A is a chart showing ROC curve of serum ERBB3, AFP, or combined ERBB3 and AFP in discriminating hepatoma from non-hepatoma controls in one of the present embodiment in accordance with the present invention.

FIG. 8B is a chart showing ROC curve of serum IGFBP2, AFP, or combined IGFBP2 and AFP in discriminating hepatoma from non-hepatoma controls in one of the present embodiment in accordance with the present invention.

FIG. 8C is a chart showing ROC curve of serum IGFBP2, ERBB3, or combined IGFBP2 and ERBB3 in discriminating hepatoma from non-hepatoma controls in one of the present embodiment in accordance with the present invention.

FIG. 8D is a chart showing ROC curve of serum ERBB3, IGFBP2, AFP, or combined ERBB3, IGFBP2, and AFP in discriminating hepatoma from non-hepatoma controls in one of the present embodiment in accordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The following examples illustrate the invention without limiting its scope.

The present invention relates to a method for the detection of liver cancer, comprising the steps of:

a) providing a liquid sample obtained from an individual,

b) contacting said sample with an antibody specific for at least one of ERBB3 protein (SEQ ID NO:2) and IGFBP2 protein (SEQ ID NO: 4) under conditions appropriate for formation of a complex between said antibody and at least one of said proteins, and

c) correlating an amount of the complex formed in (b) to the detection of liver cancer.

With reference to FIG. 1, the method for obtaining the novel ERBB3 and IGFBP2 protein markers for hepatoma detection comprises the steps of:

Step 1 (11) Obtaining liver cancer tissues and non-cancer liver tissues from individuals respectively:

cutting the obtained liver cancer tissues and the non-cancer liver tissues into 1×1×3 mm³ pellets,

washing the above pellets by PBS solution twice,

incubating the cell pellets by PBS solution at 37° C., 10% CO₂ incubator for 10 minutes,

centrifuging the cultured cell pellets at 1000 to 2000 rpm/min for 2 to 5 minutes to remove the contaminations on liver cancer tissues and non-cancer liver tissues,

Step 2 (12) Separating tissues and tissue interstitial fluid by low speed centrifugation:

culturing the cell pellets by PBS at 37° C., 10% CO₂ incubator for 60 minutes,

centrifuging the cultured broth at 1000-2000 rpm/min for 2-5 minutes to separate tissues and tissue interstitial fluid, and avoiding cell crack,

Step 3 (13) Removing the dissolved matrix by high speed centrifugation,

centrifuging the cultured broth by 5000-15000 rpm/min for 15-30 minutes to increase the purification and the sensitivity of the tissue interstitial fluid,

Step 4 (14) Finding candidate biomarkers for hepatoma detection:

comparing protein pattern obtained from liver cancer tissues and non-cancer liver tissues to select possible protein markers, said protein patterns may be performed such as 2-DE or antibody arrays,

identifying and listing the candidate biomarkers which are present in relatively high concentration and are highly different in the protein pattern of the liver cancer and non-cancer liver tissues.

Step 5 (15) Selecting candidate biomarkers for hepatoma detection proteins:

analyzing the candidate biomarkers by ELISA method and checking the concentrations of each candidate biomarker in cancer tissues and non-cancer tissues,

analyzing the concentrations obtained from the above sub-step by student t-test to identify the concentration of the biomarker with significant difference, and selecting the concentration of the biomarker with p value<0.01,

further analyzing the concentration with significant difference by ROC curve method and selecting the candidate biomarker with AUC value>90% as the biomarker for hepatoma detection.

In a preferred embodiment, the above selected markers were further analyzed by applying in the serum samples obtained from another liver cancer group and non-liver cancer group. The method may be performed by ELISA method and ROC curve method for getting their AUC values. When the AUC values>90%, the selected marker was confirmed to be a suitable marker for liver cancer detection.

As used herein, the term “non-liver cancer” refers to a patient that may have cirrhosis without liver cancer, chronic hepatitis or healthy individuals without liver cancer.

As used herein, “antibody” or “specific binding agent” includes immunoglobulin molecules and immunologically active determinants of immunoglobulin molecules, i.e., molecules that contain an antigen binding site which specifically binds (immunoreacts with) an antigen. Structurally, the simplest naturally occurring antibody (e.g., IgG) comprises four polypeptide chains, two copies of a heavy (H) chain and two of a light (L) chain, all covalently linked by disulfide bonds. Specificity of binding in the large and diverse set of antibodies is found in the variable (V) determinant of the H and L chains; regions of the molecules that are primarily structural are constant (C) in this set. Antibody includes polyclonal antibodies, monoclonal antibodies, whole immunoglobulins, and antigen binding fragments of the immunoglobulins.

In the diagnostic and prognostic assays of the invention, the antibody can be a polyclonal antibody or a monoclonal antibody and in a preferred embodiment is a labeled antibody.

In this exemplary method a Receiver Operating Characteristic curve (ROC curve) is generated. An ROC curve is a plot of test sensitivity (plotted on the y axis) versus its False Positive Rate (or 1—specificity) (plotted on the x axis). Each point on the graph is generated by using a different cut point. The set of data points generated from the different cut points is the empirical ROC curve. Lines are used to connect the points from all the possible cut points. The resulting curve illustrates how sensitivity and the FPR vary together. ROC is a standard statistical method used in the evaluation of a biomarker in disease diagnosis. This analysis determines the ability of a test to discriminate diseased cases from normal cases. The value of the area under the ROC curve is a measure of test accuracy.

EXAMPLE 1

Markers Selection

1-1 Sample Collection and Preparation

Step 1: Liver cancer tissues and non-cancer liver tissues were respectively collected from 10 patients with hepatoma received surgical resection of liver tumors. The contaminations on the liver cancer tissues and non-cancer liver tissues were removed by low speed centrifugation.

In a preferred embodiment of the present invention, liver cancer tissues and non-cancer liver tissues were obtained by surgical operation. The sizes of the tissues were cut as 1×1×3 mm, and then the cut tissues were cultured by PBS solution in an incubator at 37° C. and 10% CO₂ condition for 10 minutes. Then the culture broth was centrifuged at 1000-2000 rpm/min for 2-5 minutes for removing the contaminations on the tissues.

Step 2: Tissues and tissue interstitial fluid were separated by low speed centrifugation to obtain tissue interstitial fluid.

The cutting tissues were collected and further cultured by PBS solutions in an incubator at 37° C., 10% CO₂ condition for 60 minutes. Then the culture broths were centrifuged at 1000-2000 rpm/min for 2-5 minutes for removing cells to obtain a crude tissue interstitial fluid.

Step 3: The crude tissue interstitial fluid were centrifuged again to remove undissolved matrix by high speed centrifugation to obtain a pure tissue interstitial fluid.

To obtain pure tissue interstitial fluids respectively from liver cancer tissues and non-cancer liver tissues, the crude tissue interstitial fluids were centrifuged at 5000-15000 rpm/min for 15-30 minutes to remove the undissolved matrix and obtain a pure tissue interstitial fluid.

Step 4: Candidate biomarkers for hepatoma detection were selected.

The electropherograms of FIGS. 2A and 2B illustrate the unique 2-DE and 2-D DIGE patterns of the diseased (liver cancer) and normal (non-cancer liver) tissues. The representative images of two-dimensional gel electrophoresis (2-DE) (FIG. 2A) and two-dimensional differential fluorescence gel electrophoresis (2-D DIGE) (FIG. 2B). 2-DE was performed on immobilized pH 4-7 gradient strips, followed by the second-dimensional separation on 10-16% gradient polyacrylamide gels. For 2-DE, the separated proteins were stained with SYPRO Ruby. Images were captured, and relative volumes for each protein were normalized, matched across gels and determined with the aide of software analysis. For 2-D DIGE, equal amount of protein lysate from TIF (hepatoma interstitial fluid) and NIF (non-hepatoma interstitial fluid) were labeled with Cy3 and Cy5 dyes respectively, and vice versa, using the minimal labeling procedures. TIF and NIF were mixed together and then separated by 2-dimensional gel electrophoresis. Proteins with significant differentiation between TIF and NIF were selected for protein identification using mass spectrometry (matrix-assisted laser desorption/ionization time-of-flight/time-of-flight mass spectrometry, MALDI-TOF/TOF MS). Results showed that the concentrations of ERBB3 (v-erb-b2 erythroblastic leukemia viral oncogene homolog 3) protein and IGFBP2 (Insulin-like growth factor binding protein 2) protein in the tissue interstitial fluid of the liver cancer tissues were higher than them appeared in the tissue interstitial fluid of non-cancer liver tissues.

Furthermore, the tissue interstitial fluids obtained from liver cancer tissues and non-cancer liver tissues were also analyzed by Antibody Array (Human Cytokine Antibody Array G Series 2000, RayBiotech Inc.) method, comprising:

A. 100 mg tissue interstitial fluids were dropped on each reaction well of the array chip for reaction at room temperature for 2 hours.

B. The reaction wells were washed by washing solution for 5 times, and the blocking buffer was mixed well with antibodies which had linked with biotin.

C. The blocking buffer containing antibodies linked with biotin were added into each reaction wells at room temperature for 2 hours.

D. The blocking buffer containing antibodies linked with biotin were removed. Then the reaction wells were washed by washing solution for 5 times, and a diluted Cy3-conjugated streptavidin which was included in the kit were added for reacting in dark at room temperature for 2 hours.

E. The Cy3-conjugated streptavidin were removed and the reaction wells were washed again by washing solution for 5 times and dried in dark at room temperature.

F. With reference to FIG. 3, the results showed on the protein array were read by Confocal Scanner Chip Reader. The strength of fluorescence showed on the protein array was further analyzed by Gene Pix Pro 4.1 software. Results showed that both concentrations of ERBB3 protein and IGFBP2 protein in the tissue interstitial fluids of the cancer tissues were higher than the non-cancer tissues. ERBB3 protein and IGFBP2 protein were selected as candidate biomarkers for hepatoma detection.

Complete amino acid sequence of ERBB3 protein was shown as SEQ ID NO. 1, and nature amino acid sequence in human serum was shown as SEQ ID NO: 2. Sequence of SEQ ID NO: 2 is same as the sequence from the 20 to 643 amino acid sequence of SEQ ID NO: 1. Complete amino acid sequence of IGFBP2 was shown as SEQ ID NO: 3, and nature amino acid sequence in human serum was shown as SEQ ID NO: 4. Sequence of SEQ ID NO: 4 is same as the sequence from the 40 to 328 amino acid sequence of SEQ ID NO: 3.

Step 5: The candidate biomarkers were used for hepatoma detection

A. Detect the Concentrations of ERBB3 Protein and IGFBP2 Protein in Serum:

To measure the concentration of ERBB3 protein and IGFBP2 protein correctly, ELISA methods comprised human ErbB3 kit (DY348) and human IGFBP2 kit (DY674) (R&D Systems Europe, Ltd) were used. Human ErbB3 protein and human IGFBP2 proteins which were produced by genetic engineer technology were used as standard.

Antibody for detecting ERBB3 protein in ELISA assay:

1. Capture antibody: an antibody which could bind to SEQ ID NO: 2 (R&D Systems, MAB 3481).

2. Detection antibody: a biotinylated monoclone antibody which could bind to SEQ ID NO: 2 (R&D Systems, BAM348).

ELISA antibody for IGFBP2 proteins:

1. Capture antibody: an antibody which could bind to SEQ ID NO: 4 (R&D Systems, MAB6741).

2. Detection antibody: a biotinylated antibody, goat IgG, which could bind to SEQ ID NO: 4 (R&D Systems, BAF674).

Steps for operation:

(a) Both capture antibodies were diluted to the concentration of 4 mg/ml, and added 100 μl to each reaction well at room temperature for reacting overnight;

(b) The obtained serum were diluted (the average dilution rate 10-100×), and 100 μl diluted serum were added into each reaction well at room temperature for 2 hours;

(c) The diluted serum were removed and the reaction wells were washed by wash solution, then 2 mg/ml of 100 μl biotinylated detection antibodies were added into each reaction wells at room temperature for 2 hours;

(d) The reaction wells were washed again, and streptavidin-HRP which was included in the kit was added and reacted in dark at room temperature for 20 minutes;

(e) The reaction wells were washed again, the subtracts which was also included in the kit were added for reaction at room temperature for 20 minutes;

(f) The data were read by microplate reader at 450 nm and 540 nm and corrected by 540 nm absorption as background value. After correction, the true absorption values were obtained. Then, the concentration of ERBB3 proteins and IGFBP2 proteins were evaluated by comparing with the concentration of standard samples.

Serum samples were collected from 113 liver cancer patients and 111 non-liver cancer patients (including 47 cirrhosis patients, 64 chronic hepatitis B) underwent the concentration of ERBB3 and IGFBP2 in serum samples for liver cancer detection.

With reference to FIGS. 4 to 6, the concentrations of serum ERBB3 protein and serum IGFBP2 protein in 113 liver cancer patients and 111 non-liver cancer patients were analyzed by student t-test to understand the difference. Results showed that false-positive values were less than 1/100 and p<0.01 were preliminarily selected for further analysis. The concentrations of serum ERBB3 proteins and serum IGFBP2 proteins, which showed a significant difference, were following analyzed by ROC curve analysis.

B. ROC Curve Analysis

To further understand whether ERBB3 protein and IGFBP2 protein were suitable for being markers for liver cancer detection, we provided another two group samples for each candidate markers for further check.

For IGFBP2 protein check experiment, there were 57 liver cancer patients and 35 non-liver cancer patients in Group I (taken as discovery group), and there were 56 liver cancer patients and 36 non-liver cancer patients in Group II (taken as validation group).

For ERBB3 protein check experiment, there were 56 liver cancer patients and 32 non-liver cancer but with hepatitis B patients in Group I (taken as discovery group), and there were 57 liver cancer patients and 32 non-liver cancer but with hepatitis B patients in Group II (taken as validation group). Results were shown in table 1 and table 2, respectively.

TABLE 1
Concentrations of IGFBP2 protein in serum
Group I (Discovery Group)	Group II (validation Group)
	Liver	Non-liver		Liver	Non-liver
	cancer	cancer		cancer	cancer
	patient	patient		patient	patient
	(ng/ml)	(ng/ml)		(ng/ml)	(ng/ml)
1	43.48484	37.16512915	1	101.4429	29.72011915
2	42.84814	27.8824984	2	67.78099	34.66665435
3	94.947	32.18498435	3	74.59434	29.72011915
4	51.20713	26.6626694	4	72.53931	26.6626694
5	94.23048	20.6265424	5	49.26238	20.02870635
6	102.898	36.538935	6	347.0552	25.4470416
7	113.2013	26.6626694	7	898.2424	26.6626694
8	66.43093	30.95045115	8	69.13526	38.42066835
9	47.32708	23.0283896	9	73.22327	36.538935
10	63.07414	31.5671926	10	61.07267	23.0283896
11	78.73277	12.352415	11	72.53931	19.4319206
12	175.1997	27.8824984	12	59.08066	32.8038264
13	99.99205	23.0283896	13	1059.827	40.3118544
14	32.80383	27.8824984	14	158.0795	23.0283896
15	29.72012	21.8253654	15	202.1783	29.72011915
16	73.22327	29.1065286	16	31.56719	31.5671926
17	118.4302	33.42371875	17	54.46938	42.21249315
18	150.8841	32.18498435	18	70.49373	21.22542875
19	61.73878	32.8038264	19	47.32708	25.4470416
20	58.41875	19.4319206	20	72.53931	35.91379115
21	176.8544	15.28382875	21	103.6272	21.22542875
22	84.30948	37.7923736	22	57.0981	21.22542875
23	46.04213	30.95045115	23	108.024	24.84080315
24	143.7737	14.6954454	24	49.90958	21.8253654
25	35.91379	36.538935	25	69.81397	21.22542875
26	37.16513	19.4319206	26	57.7579	28.49398835
27	116.183	21.22542875	27	35.91379	13.5218296
28	82.909	21.22542875	28	150.0898	26.05433035
29	792.7261	21.22542875	29	131.3431	22.42635235
30	76.65883	19.4319206	30	112.4586	30.95045115
31	115.436	67.7809926	31	142.9889	15.8732624
32	89.24425	14.10811235	32	283.8218	13.5218296
33	100.717	12.93659715	33	75.96962	30.33476
34	286.6897	17.64786515	34	38.42067	39.0500134
35	84.30948	15.8732624	35	162.1137	42.84814
36	43.48484		36	785.7038	15.28382875
37	77.34909		37	196.1848
38	75.96962		38	63.07414
39	80.12064		39	55.78164
40	47.32708		40	181.0094
41	55.12499		41	95.66457
42	42.21249		42	35.2897
43	37.79237		43	59.08066
44	31.56719		44	36.53894
45	35.2897		45	35.2897
46	32.18498		46	36.53894
47	147.7134		47	30.33476
48	49.26238		48	63.07414
49	38.42067		49	52.50888
50	40.31185		50	46.04213
51	65.75747		51	162.1137
52	70.49373		52	283.8218
53	42.21249		53	71.8564
54	55.78164		54	31.56719
55	61.73878		55	32.18498
56	42.84814		56	42.21249
57	42.21249

TABLE 2
Concentrations of ERBB3 protein in serum
Group I (Discovery Group)	Group II (Validation Group)
	Liver	Non-liver		Liver	Non-liver
	cancer	cancer		cancer	cancer
	patient	patient		patient	patient
	(ng/ml)	(ng/ml)		(ng/ml)	(ng/ml)
1	819.626	136.066	1	768.546	1106.586
2	666.386	187.146	2	1023.946	289.306
3	1177.186	238.226	3	2505.266	289.306
4	2403.106	187.146	4	1381.506	340.386
5	1279.346	289.306	5	1892.306	187.146
6	921.786	136.066	6	1483.666	646.866
7	1483.666	289.306	7	1126.106	391.466
8	1534.746	62.346	8	921.786	62.346
9	870.706	442.546	9	2096.626	289.306
10	819.626	544.706	10	2249.866	136.066
11	1279.346	902.266	11	768.546	187.146
12	1075.026	187.146	12	870.706	62.346
13	1687.986	595.786	13	870.706	136.066
14	7306.786	136.066	14	1177.186	62.346
15	1687.986	271.84	15	972.866	238.226
16	819.626	271.84	16	1790.146	339.2
17	1228.266	372.88	17	1228.266	137.12
18	666.386	406.56	18	1841.226	305.52
19	1177.186	406.56	19	1177.186	69.76
20	2096.626	137.12	20	1075.026	69.76
21	972.866	810.72	21	1432.586	574.96
22	541.586	204.48	22	1279.346	103.44
23	1330.426	642.32	23	921.786	204.48
24	870.706	305.52	24	1841.226	36.08
25	1687.986	372.88	25	1126.106	473.92
26	768.546	271.84	26	1126.106	204.48
27	870.706	541.28	27	1177.186	238.16
28	972.866	137.12	28	1177.186	473.92
29	1432.586	204.48	29	1330.426	170.8
30	666.386	58.16	30	666.386	291.68
31	870.706	204.11	31	768.546	116.54
32	921.786	466.82	32	921.786	320.87
33	1381.506		33	666.386
34	1228.266		34	768.546
35	768.546		35	819.626
36	8685.946		36	921.786
37	1330.426		37	1023.946
38	717.466		38	870.706
39	1075.026		39	1177.186
40	1177.186		40	5825.466
41	1636.906		41	1177.186
42	819.626		42	1330.426
43	1177.186		43	768.546
44	717.466		44	1177.186
45	1841.226		45	972.866
46	972.866		46	972.866
47	972.866		47	768.546
48	1023.946		48	1075.026
49	819.626		49	819.626
50	1652.72		50	305.52
51	608.64		51	4650.24
52	507.6		52	1955.84
53	2730.48		53	1046.48
54	878.08		54	574.96
55	676		55	2797.84
56	1248.56		56	204.48
			57	271.84

The concentrations data shown in table 1 and table 2 were further described as follow:

(1) Results showed that ERBB3 proteins was a proper biomarker for liver cancer (hepatoma) detection

(i) With reference to FIG. 4, the ERBB3 protein concentration in serum in 113 liver cancer patients were higher than 47 cirrhosis without liver cancer patients (p<0.0001, student's t-test), and also higher than 64 chronic hepatitis B patients (p<0.0001, student's t-test).

(ii) With reference to FIG. 5A, the AUC values of Group I which had 56 liver cancer patients and 32 non-liver cancer but with hepatitis B patients was 97.7%.

(iii) With reference to FIG. 5B, the AUC values of Group II which had 57 liver cancer patients and 32 non-liver cancer but with hepatitis B patients was 96.1%.

(iv) With reference to FIG. 5C, analyzing by the cut-off value of Youden index, the sensitivity value for detecting liver cancer was 89.3% after combining Group I and Group II patient samples, and the specificity value was 99.7%. Similarly, by analyzing AFP in serum, the AUC values of the liver cancer patients and non-liver cancer patients were 91.5% after combining the two groups, but the AUC values of ERBB3 proteins only were 96.8%.

The above results showed that analyzed by the concentration of ERBB3 protein in serum is more sensitive than analyzed by AFP in serum. Therefore, it is powerful to use ERBB3 protein as a biomarker for detecting liver cancer.

(2) Results showed that IGFBP2 proteins was a proper biomarker for liver cancer (hepatoma) detection

(i) With reference to FIG. 6, the concentration of IGFBP2 protein in serum in 113 liver cancer patients were higher than 47 cirrhosis without liver cancer patients (p<0.001, student's t-test), and also higher than 64 chronic hepatitis B patients (p<0.001, student's t-test).

(ii) With reference to FIG. 7A, the AUC value of the serum in Group I which had 57 liver cancer patients and 35 hepatitis B without liver cancer patients were 96.4%.

(iii) With reference to FIG. 7B, the AUC value of the serum in Group II which had 56 liver cancer patients and 36 hepatitis B without liver cancer patients were 96.24%.

(iv) With reference to FIG. 7C, the AUC value was 96.2% after combing Group I and Group II patient samples. However, by detecting AFP in serum, the AUC values of the liver cancer patients and non-liver cancer patients were 71.5% after combining the two Groups. Therefore, detecting by the concentration of IGFBP2 in serum to identify liver cancer patients and non-liver cancer with hepatitis B patients were more sensitive and specificities than detecting by AFP values.

The above results showed that analyzed by the concentration of IGFBP2 protein in serum is more sensitive than analyzed by AFP values in serum. Therefore, it is powerful to use IGFPB2 protein as a biomarker for detecting liver cancer.

Combination detection of AFP, ERBB3 protein and IGFBP2 protein in serum to increase the sensitivity and specificity of liver cancer detection

(i) The AUC values of AFP, ERBB3 and IGFBP2 were 84.3%, 96.8% and 96.1%, respectively.

(ii) With reference to FIGS. 8A and 8B, the AUC values of AFP+ERBB3 and AFP+IGFBP2 were 96.9% and 94.5%, respectively. With reference to FIG. 8C, the AUC value of ERBB3+IGFBP2 was 98.5%. Furthermore, with reference to FIG. 8D, the AUC value of AFP+ERBB3+IGFBP2 was 99.1%. Therefore, to increase the sensitivity and specificity to almost 100%, it is very useful to combine AFP value, ERBB3 value and IGFBP2 value for diagnosis of hepatoma.

The present invention is not to be limited in scope by the specific embodiments described herein. Indeed, various modifications of the invention in addition to those described herein will become apparent to those skilled in the art from the foregoing description. Such modifications are intended to fall within the scope of the appended claims.

All patents, applications, publications, test methods, literature, and other materials cited herein are hereby incorporated by reference.

Claims

1. A method for detection of liver cancer, comprising steps of:

a) providing a liquid sample obtained from an individual,

b) contacting said sample with an antibody specific for at least one of IGFBP2 protein (SEQ ID NO: 4) under conditions appropriate for formation of a complex between said antibody and at least one of said proteins, and

c) correlating an amount of the complex formed in step d) to the detection of liver cancer.

2-3. (canceled)

4. The method according to claim 1 wherein the liquid sample is whole blood.

5-9. (canceled)