Colorectal Cancer Open Access
Copyright ©The Author(s) 2004. Published by Baishideng Publishing Group Inc. All rights reserved.
World J Gastroenterol. Nov 1, 2004; 10(21): 3127-3131
Published online Nov 1, 2004. doi: 10.3748/wjg.v10.i21.3127
An integrated approach to the detection of colorectal cancer utilizing proteomics and bioinformatics
Jie-Kai Yu, Cancer Institute, the Second Affiliated Hospital of Zhejiang University Medical College, Hangzhou 310009, Zhejiang Province, China
Jie-Kai Yu, College of Life Science of Zhejiang University, Hangzhou 310029, Zhejiang Province, China
Jie-Kai Yu, Hangzhou Genomics Institute, Hangzhou 310008, Zhejiang Province, China
Yi-Ding Chen, Department of Oncology, the Second Affiliated Hospital of Zhejiang University Medical College, Hangzhou 310009, Zhejiang Province, China
Shu Zheng, Cancer Institute, Zhejiang University, Hangzhou 310009, Zhejiang Province, China
Author contributions: All authors contributed equally to the work.
Supported by the Major State Basic Research Development Program of China 973 program, No. G1998051200
Correspondence to: Shu Zheng, Cancer Institute, Zhejiang University, Hangzhou 310009, Zhejiang Province, China. zhengshu@mail.hz.zj.cn
Telephone: +86-571-87783868 Fax: +86-571-87214404
Received: April 9, 2004
Revised: May 2, 2004
Accepted: May 9, 2004
Published online: November 1, 2004

Abstract

AIM: To find new potential biomarkers and to establish patterns for early detection of colorectal cancer.

METHODS: One hundred and eighty-two serum samples including 55 from colorectal cancer (CRC) patients, 35 from colorectal adenoma (CRA) patients and 92 from healthy persons (HP) were detected by surface-enhanced laser desorption/ionization mass spectrometry (SELDI-MS). The data of spectra were analyzed by bioinformatics tools like artificial neural network (ANN) and support vector machine (SVM).

RESULTS: The diagnostic pattern combined with 7 potential biomarkers could differentiate CRC patients from CRA patients with a specificity of 83%, sensitivity of 89% and positive predictive value of 89%. The diagnostic pattern combined with 4 potential biomarkers could differentiate CRC patients from HP with a specificity of 92%, sensitivity of 89% and positive predictive value of 86%.

CONCLUSION: The combination of SELDI with bioinformatics tools could help find new biomarkers and establish patterns with high sensitivity and specificity for the detection of CRC.


INTRODUCTION

Colorectal cancer (CRC) is one of the most common malignant tumors that threaten people’s health[1-5]. At present, CRC is one of the three leading causes of worldwide cancer mortality and the second leading cause of cancer-related deaths in the Western world[6,7]. The prognosis of CRC is strongly related to early diagnosis. CRC patients diagnosed in early stage have a five-year survival post-operation of over 80%, but in the advanced stage the five-year survival is lower than 40%. So, early diagnosis is very important to improve the prognosis of CRC[8].

Recently serum tumor markers, such as carcinoembryonic antigen (CEA), are commonly used to detect CRC for the advantages of less pain and accessibility. However all the existing biomarkers have a low diagnostic sensitivity in CRC (sensitivity of 23% with CEA[9]). New biomarkers with a high sensitivity and specificity to detect CRC in early stage are urgently needed. A novel proteomic approach for the detection of cancer which is called surface enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF MS), and ProteinChip technology, have been developed. SELDI-TOF MS coupled with bioinformatics approach has successfully found new biomarkers and achieved high sensitivity and specificity for the diagnosis of cancers of bladder[10], prostate[11-14], ovary[15,16], breast[17,18], liver[19], neck[20], lung[21,22] , pancreas[23].

The aim of this study was to find the potential biomarkers in CRC and to establish the patterns to diagnose CRC.

MATERIALS AND METHODS
Samples

A total of 182 serum samples were obtained from the serum banks of the Cancer Institute of the Second Affiliated Hospital of Zhejiang University Medical College. The cancer group consisted of 55 serum samples from CRC patients at different clinical stages: Dukes’ A (n = 8), Dukes’ B (n = 22), Dukes’ C (n = 13), Dukes’ D (n = 12). The median age of CRC patients was 57 years (range, 31-84 years). The two non-cancer control groups included 35 serum samples from patients with colorectal adenoma (CRA) and 92 serum samples from healthy persons (HP). They were age and sex matched with cancer group. Diagnoses were pathologically confirmed, and specimens were obtained before treatment. All samples were stored at -80 °C.

Proteinchip array analysis

Serum samples were thawed in ice and centrifuged at 3 000 r/m for 5 min at 4 °C, supernatants were retained. We added 90 µL of 5 g/L CHAPS (Sigma) (pH7.4) in PBS to 10 µL of each serum sample, and vortex-mixed them. The diluted samples were added to 100 µL Cibacron Blue 3GA (Sigma) (previously equilibrated with 5 g/L CHAPS three times) in a 96-well cell culture plate and agitated on a platform shaker at 4 °C for 60 min. After centrifuged at 1 000 r/m, 50 µL supernatant was sampled and further diluted by 150 µL 20 mmol/L HEPES (pH7.4) and applied to each well of a bioprocessor (Ciphergen Biosystems) containing hydrophobic surface (H4) chips previously activated with 20 mmol/L HEPES. The bioprocessor was then sealed and agitated on a platform shaker for 60 min at 4 °C. The excess serum mixtures were discarded, and the chips were washed three times with 20 mmol/L HEPES and 2 times with deionized water. The chips were then removed from the bioprocessor, air-dried. Before SELDI analysis, 0.5 µL of a saturated solution of α-cyano-4-hydroxycinnamic acid (CHCA) in 0.5 L/L acetonitrile and 5 mL/L trifluoroacetic acid was applied onto each chip twice, air-dried.

Chips were detected on the protein biological system II (PBS-II) plus a mass spectrometer reader (Ciphergen Biosystems). Data were collected by averaging 65 laser shots with an intensity of 135, a detector sensitivity of 7, a highest mass of 30 000 Da and an optimized range of 2 000-20 000 Da. Mass accuracy was calibrated to less than 0.1% using the all-in-one peptide molecular mass standard (Ciphergen Biosystems).

Bioinformatics analysis

The spectra intensities of all samples were normalized to the total ion current of m/z between 2 000 and 30 000 Da. The noise of spectra was filtrated and peaks were detected with an automatic peak detection pass using signal-to-noise ratio. Peak clusters were completed to cluster the peaks in different samples that had similar masses (defined by a mass window in 0.3% mass error). All these were performed using ProteinChip Software 3.1 (Ciphergen). The peak intensities were preprocessed by scaling all the data to the range[-1, 1].

The pattern recognition techniques were applied to diverse areas including prediction of cancer[24], gene microarray[25] and mass spectrometry[26]. We utilized a multi-layer perception (MLP) ANN with a scaled conjugate gradient (SCG) optimized back propagation algorithm for discriminating CRC from HP, and a linear support vector machine (SVM) for discriminating CRC from CRA. They were powerful tools for analysis of the complex data[14] derived from SELDI-MS.

Feature selection

We estimated the power of each peak in discriminating different group samples by integrating approaches such as t-test, receive option curve (ROC) and mean square error (MSE) of ANN.

The ANN used to calculate the MSE of each peak had 3 layers, with 1 node in input and output layer, 2 nodes in hidden. For each peak the ANN was trained with all the samples, performed 1 000 epochs to get the MSE respectively. The MSE was calculated as the difference between the target output and the ANN predictive value. The lower MSE value of the peak showed a higher relative importance value for their ability to accurately discriminate the different groups.

Integrated ANN classifier

The ANN established for discriminating different groups had 4 layers. Except output layer and input layer ANN also had 2 hidden layers each with 100 nodes. We randomly selected 1/3 of all the samples to be the blinded test set, and the remaining 2/3 samples for training, the procedure was repeated 10 times.

In the procedure of training ANN we used a cross-validation approach to reduce the risk of “over fit”[27]. The samples for training were randomly divided into 2 sets: 2/3 samples for training set and 1/3 samples for validation set. The random shuffling was redone 100 times. Thus 100 different ANNs were established to predict the blinded test set samples. The predictive values of the blinded test set samples were the average of all the predicted outputs of 100 ANNs.

SVM classifier

SVM is a new machine learning approach originally proposed and developed by Vladimir Vapnik. SVM applications were actively pursued in various areas recently, from genomics to face recognition[28,29]. SVM is powerful for small sample data. We used the linear SVM classifier and set the cost of the constrain violation (C) to 1. The 3-fold cross-validation approach was applied to estimate the accuracy of the classifier.

RESULTS
Bioinformatics analysis of CRC and HP data

After noise was filtrated by Ciphergen ProteinChip Software 3.1, there were 61 peaks detected for discriminating CRC from HP and 235 peaks for discriminating CRC from CRA. The peaks were between 2 k and 30 kDa. Peaks with an m/z < 2 kDa were mainly ion noise from the matrix and therefore excluded[10].

The 61 qualified peaks detected from the two groups were ranked by the MSE values of ANN. We input the 61 peaks respectively. For each peak we trained the ANN with all the 147 healthy and CRC samples to give an MSE value. The top 15 peaks with lower MSE values were selected for further analysis (Figure 1). The t-test and ROC method confirmed the results with the same 15 peaks.

Figure 1
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Figure 1 MSE values of the top 15 peaks. A: m/z of peaks. B: MSE values of peaks.

To further select the set of candidate biomarkers, we used a stepwise approach in which many integrated ANNs were trained. The top 1 peak with the highest ability to predict the two groups (had the lowest MSE value) was selected as a single input to build the integrated ANN. We estimated the discriminating ability of this integrated ANN by the accuracy of blind test set. Next, the top 2 peaks were input to integrated ANN and the accuracy was calculated. The following peaks were added as input stepwise to train integrated ANN and the accuracy was calculated. In this way, the 15 models combining different peaks were built. The peaks input to the model with the highest accuracy were selected as the set of potential biomarkers. The top 4 peaks were finally selected as potential biomarkers, an accuracy of 92% was achieved. The accuracies of these 15 models are plotted in Figure 2 (A).

Figure 2
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Figure 2 Accuracies of different combinations of peaks. A: Accuracies of different combinations of peaks in the pattern discriminating CRC patients from HP. B: Accuracies of differ-ent combinations of peaks in the pattern discriminating CRC patients from CRA patients.

The m/z of the 4 candidate biomarkers were 5 911, 8 922, 8 944, 8 817 Da. These 4 peaks all appeared to highly express in CRC and lowly express in healthy persons, as shown in Figure 3 (A, B). Between the two groups, the P value of t-test (< 10-9) and the area under the ROC curve (> 8.0) showed statistical significance of all the 4 peaks. Table 1 shows the descriptive statistics of the 4 peaks.

Table 1 Descriptive data for the 4 potential biomarkers in the pattern discriminating CRC patients from HP (mean ± SD).
M/Z (Da)AUCHPCRC patients
5 9110.9080.824 ± 0.5042.763 ± 1.720
8 9220.8721.254 ± 0.7242.767 ± 1.445
8 9440.8280.999 ± 0.6262.651 ± 1.851
8 8170.8110.878 ± 0.6071.744 ± 0.940
AUC: Area under the carve.
Figure 3
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Figure 3 Spectra and gel maps of potential biomarkers. A: Spectra and gel maps of the peak with the m/z of 5 911 Da. B: Spectra and gel maps of the peak with the m/z of 8 922, 8 944, 8 817 Da. C: Spectra and gel maps of the peak with the m/z of 17 247 Da.

The 4 peaks were combined and evaluated by integrated ANN. We trained the integrated ANN with 89 samples and tested 49 samples. We randomly selected the test set 10 times, and each time 100 ANNs were built to predict the test set. So 1 000 ANNs were built up. Table 2 shows the results of this classifier. For the integrated ANN classifier, the estimated specificity in the blind test set was 92% with a 95% confidence interval of 89%-95%, the estimated sensitivity was 89% (85%-93%), the estimated positive predictive value was 86% (82%-90%).

Table 2 Predicted results of classifier for discriminating CRC patients from HP.
Test set (49 × 10)
Training set (98 × 10)
HPCRCHPCRC
HP (92 × 10)287255999
CRC (55 × 10)1915929343
Specificity (%)92 (287/(287 + 25))99 (599/(599 + 9))
Sensitivity (%)89 (159/(159 + 19))92 (343/(343 + 29))
Positive value (%)86 (159/(159 + 25))97 (343/(343 + 9))
Bioinformatics analysis of CRC and CRA data

The 235 qualified peaks detected from the two groups were ranked by the P values of t-test. The top 15 peaks were selected for further analysis. For these data we utilized the 3-fold cross-validation SVM classifier to select the potential biomarkers to build the model to predict the test sets. This approach randomly selected 1/3 of samples to be the blinded test set, and the remaining 2/3 samples to be the training set and the procedure was repeated 3 times. We still used stepwise method to add the peaks in the rank of P value one by one to be the input of 3-cross-validation SVM. The top 7 peaks with the highest accuracy (86.7%) were selected as final potential biomarkers to separate the two groups. Table 3 shows the descriptive data of the 7 peaks. Between the two groups, the P values of t-test (< 10-4) and the area under the ROC curve (> 7.0) showed the statistical significance of the 7 peaks. In the 7 peaks only the peak of 17 247 Da appeared to lowly express in CRC and highly express in CRA as shown in Figure 3C, others were highly expressed in CRC.

Table 3 Descriptive statistics for the 7 potential biomarkers in the pattern discriminating CRC patients from CRA patients (mean ± SD).
M/Z (Da)P value (× 10-5)CRA patientsCRC patients
17 2470.710.211 ± 0.1300.113 ± 0.100
18 4201.270.039 ± 0.0360.076 ± 0.040
5 9111.711.459 ± 0.9772.763 ± 1.720
9 2942.760.617 ± 0.3851.105 ± 0.563
4 6546.740.503 ± 0.4931.164 ± 0.943
21 6947.480.489 ± 0.1450.698 ± 0.267
21 74212.100.536 ± 0.1610.744 ± 0.282

We used 3-fold cross-validation SVM to combine the 7 peaks, and trained it with 60 samples. For the 3-fold cross-validation SVM, the estimated specificity in the blind test set (30 samples) was 83% with a 95% confidence interval of 79%-87%, the estimated sensitivity was 89% (86%-92%), the estimated positive predictive value was 89% (86%-92%). Table 4 shows our results for this classifier.

Table 4 Predicted results of classifier for discriminating CRC patients from CRA.
Test set (30 × 3)
Training set (60 × 3)
CRACRCCRACRC
CRA (35 × 3)2965614
CRC (55 × 3)6491694
Specificity (%)83 (29/(29 + 6))80 (56/(56 + 14))
Sensitivity (%)89 (49/(49 + 6))85 (94/(94 + 16))
Positive value (%)89 (49/(49 + 6))87 (94/(94 + 14))
DISCUSSION

CRC screening includes fecal occult blood test (FOBT), sigmoidoscopy, air-contrast barium enema examination, colonoscopy[30]. But they have not been commonly accepted due to costs, bowel preparation, sedation and perforation risks. Detection of serum tumor markers (such as CEA) is an inexpensive and facile screening method compared to others. However, all the existing biomarkers in serum lack sufficient sensitivity for screening and diagnosis of CRC[31-35]. In this study, we detected CEA values (cut-off value of CEA level of 5 ng/mL) of 182 serum samples (including 55 from CRC patients, 35 from CRA and 92 from HP which were also detected by SELDI), and a sensitivity of 47% was achieved in screening for CRC. The results also showed that CEA lacked sufficient sensitivity for screening and diagnosis of CRC.

Because of the multi-factorial nature of CRC, it is very clear that a combination of several markers would be necessary to effectively detect and diagnose CRC. SELDI-MS and the ProteinChip technology could provide the high-throughput proteomic profiling[36]. Coupled with sophisticated bioinformatics tools for complex data analysis they could find the “fingerprints” of CRC and build the diagnosis model.

One hundred and forty-seven CRC patients and HP were detected by SELDI-TOF-MS and the complex data were analyzed by integrated ANN, we found 4 potential biomarkers and achieved a specificity of 92% (89%-95%), sensitivity of 89% (85%-93%), positive predictive value of 86% (82%-90%). Ninety CRC and CRA patients were detected by SELDI-MS and analyzed by an SVM classifier. We found 7 potential biomarkers and achieved a specificity of 83% (79%-87%), sensitivity of 89% (86%-92%), positive predictive value of 89% (86%-92%).

Early detection remains one of the most urgent issues in CRC research[37]. Our two patterns could recognize early Dukes samples as efficiently as other Dukes samples. The biomarkers used in the final selection were not sensitive to different Dukes, stages of cancer patients. In almost all the patients with CRC, preceding lesions were asymptomatic adenomas[38]. So it is very important to discriminate the noncancer CRA patients from early CRC. We also achieved a high sensitivity and specificity model to recognize CRC and CRA patients.

We developed an integrated approach using bioinformatics and biostatics tools to analyze the large data of spectra. The ROC curve, t-test and MSE values were used to rank and select the peaks according to their contribution to the separation of two groups. To accurately estimate the sensitivity and specificity of the classifiers established by potential biomarkers, the test sets were randomly selected many times, independent of training sets each time.

The peak of 4 645 Da was identified as doubly charged forms of 9 294 Da by Ciphergen ProteinChip Software 3.1. The recognition of both the doubly charged and the singly charged forms of these peaks suggested their importance in discriminating the two diagnostic groups. The peak of 5 911 Da was selected as a potential biomarker in both the pattern discriminating CRC patients from HP and the pattern discriminating CRC from CRA patients. The expression of this biomarker increased step by step in HP, CRA and CRC patients as shown in Figure 3A. Therefore the peak of 5 911 Da may play an important role in the formation and progression of CRC.

In conclusion, SELDI-TOF-MS in combination with sophisticated bioinformatics tools could facilitate the discovery of new biomarkers and establish patterns with a high sensitivity and specificity for the detection of CRC.

Footnotes

Edited by Wang XL and Zhu LH Proofread by Xu FM

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