Viral Hepatitis Open Access
Copyright ©The Author(s) 2004. Published by Baishideng Publishing Group Inc. All rights reserved.
World J Gastroenterol. Aug 15, 2004; 10(16): 2327-2329
Published online Aug 15, 2004. doi: 10.3748/wjg.v10.i16.2327
New serum biomarkers for detection of HBV-induced liver cirrhosis using SELDI protein chip technology
Xiao-Dong Zhu, Wei-Jiang Liang, Po Tien, Department of Molecular Virology, Institute of Microbiology, Chinese Academy of Sciences, Beijing 100080, China
Wei-Hua Zhang, Yang Xu, Ciphergen Biosystems, Inc., Beijing, China
Cheng-Lin Li, Department of Pathology, Beijing You’an Hospital, Beijing 100054, China
Author contributions: All authors contributed equally to the work.
Supported by the Major State Basic Research Development Program of China (973 Program), No. 2001CB510001
Correspondence to: Professor Po Tien, Department of Molecular Virology, Institute of Microbiology, Chinese Academy of Sciences, Zhongguancun Beiyitiao, Beijing 100080, China. tienpo@sun.im.ac.cn
Telephone: +86-10-62554247 Fax: +86-10-62622101
Received: December 12, 2003
Revised: January 2, 2004
Accepted: February 18, 2004
Published online: August 15, 2004

Abstract

AIM: To find new serum biomarkers for liver cirrhosis (LC) in chronic carriers of hepatitis B virus (HBV).

METHODS: Surface enhanced laser desorption/ionization time-of-flight (SELDI-TOF) mass spectrometry was used to discover biomarkers for differentiating HBV induced LC from non-cirrhotic cohorts. A training population of 25 patients with HBV-induced LC, 20 patients with HCC, and 25 closely age-matched healthy men, was studied.

RESULTS: Two biomarkers with Mr 7772 and 3933 were detected in sera of non-cirrhotic cohorts, but not in patients with HBV-induced LC. A sensitivity of 80% for all LC patients, a specificity of 81.8% for all non-cirrhotic cohorts and a positive predictive value of 75% for the study population were obtained.

CONCLUSION: These two serum biomarkers for HBV-induced LC might be used for diagnosis and assessment of disease progression.


INTRODUCTION

Liver cirrhosis (LC), the end-stage of liver fibrosis, is generally irreversible. Patients with LC caused by chronic infection of HBV are at high risks of hepatocellular carcinoma and high death rate[1,2]. Although some serum assays are on the way to differentiate chronic HBV infection or LC from HCC, pretreatment liver biopsy has been considered as the “gold standard” for assessing the grade of liver injury and stage of liver fibrosis. Clinicians relying on liver biopsy are able to correctly diagnose the stage of fibrosis or presence of cirrhosis in 80% patients[3]. However, liver biopsy can be associated with significant expense, manpower issues, and risk of patient injury. As a result, we still need to identify noninvasive tests that could replace liver biopsy.

Protein profiles might reflect the pathological state of HBV infection. The relationship between protein profile and disease progression could be achieved by analyzing the complex serum proteomic patterns[4,5]. We used a protein biochip surface-enhanced laser desorption/ionization time-of-flight (SELDI-TOF) mass spectrometry coupled with an artificial intelligence learning algorithm to differentiate HBV induced LC from non-cirrhosis cohorts. A blinded test was used to determine the sensitivity and specificity of the established pattern.

MATERIALS AND METHODS
Samples

Of the 107 serum samples selected, 40 were from patients with HBV-induced LC and 30 from patients with HCC from You’an Hospital, Beijing, China, 37 from healthy men provided by Center of Cancer Prevention and Treatment, Zhongshan University, China. All HBV infected patients with LC were examined by ELISA and were HBeAg positive in serum. The final diagnoses were pathologically confirmed and specimens were obtained before treatment. All samples were fresh and stored at -70 °C and closely age-matched.

Protein chip array analysis

Three different chip chemistries (cationic, anionic, and Cu metal binding, Ciphergen Biosystems, Inc, Fremont, CA) were tested to determine which provided the best serum profiles in terms of number and resolution of protein peaks. It showed that WCX2 weak cationic chip gave the best result. A total of 10 μL of each sample was diluted into 20 μL with U9 buffer (1 × PBS, 9 mol/L urea, 1% CHAPS) and mixed. The mixing step was repeated several times on ice for a total of 30 min. An eight-spot WCX chip was washed with 50 mmol/L sodium acetate (pH 4.0) twice. Then sodium acetate buffer was added to U9-treated sample to make a further 1:13 dilution. The diluted serum mixture (100 μL) was applied to a protein chip array and incubated for 1 h on a shaker. After washing with the same sodium acetate buffer three times followed by a quick water rinse, 0.5 μL of saturated sinapinic acid (SPA) solution was applied onto each spot and allowed to air-dry. Then chips were performed on Protein Biological System II(c) mass spectrometer reader (PBSII, Ciphergen Biosystems, Inc).

Bioinformatics and biostatistics

Classification model was built up with Biomarker Pattern’s Software (BPS, Ciphergen Biosystems, Inc). Training data set consisted of 70 serum samples (25 from patients with LC, 20 from patients with liver cancer, and 25 from healthy individuals). A classification tree was set up to divide the data set into two bins based on the intensities of peaks. At each bin a peak intensity threshold was set. If the peak intensity of a sample was lower than or equal to the threshold, this sample would go to the left-side bin. Otherwise, the sample would go to the right-side bin. The process would go on until a blind sample entered a final bin, either labeled at Con (control sample) or LC (LC serum). Peaks selected by the process to form the model were the ones that yielded the least classification error when they were combined to use.

Data set from double-blind trials consisted of 37 serum samples (15 from patients with LC, 10 from patients with liver cancer, and 12 from healthy individuals) and was used to test the model.

Specificity and sensitivity were respectively calculated as the proportion of the number of non-cirrhotic samples correctly identified to the total number of non-cirrhotic samples. Positive predictive value gives the probability of disease if a test result is positive.

RESULTS
Evaluation of SELDI protein chip

As various chip array chemistries provided different serum protein profiles in terms of number and resolution of protein peaks, WCX2, SAX2 and IMAC3-Cu metal binding chip arrays were tested, respectively. WCX2 binding chip was observed to give the best results. To demonstrate the reproducibility of the mass spectra, 8 independently obtained spectra of a serum sample of a healthy man were performed by between-run assay. We calculated that the coefficient of variance for seven selected M/Z peaks whose relative intensities were above 25 with the highest amplitude < 10%. As shown in Figure 1, serum spectra from patients and healthy men do not show large variations. Therefore, small variations between different sample groups could be used for biomarker discovery. SELDI-TOF spectra of randomly selected serum samples of patients with HBV induced LC, patients with HCC, and healthy individuals are shown in Figures 1 and 2. Two proteins of Mr 7 772 and 3 933 were down-regulated in LC or up-regulated in non-cirrhotic group (healthy/HCC).

Figure 1
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Figure 1 SELDI-TOF mass spectra. Spectra 1-4 from HBV-induced LC patients, 5-8 from healthy men, and 9-12 from HCC patients. A biomarker of Mr 7772 was present in non-cirrhotic group, but not in LC serum samples.
Figure 2
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Figure 2 SELDI-TOF mass spectra. Spectra 1-4 from HBV in-duced LC patients, 5-8 from healthy men, and 9-12 from HCC patients. A biomarker of Mr 3933 was present in non-cirrhotic group, but not in LC serum samples.
Data analysis

Peak labeling was performed with Biomarker Wizard of Ciphergen ProteinChip software 3.1.1. The peak intensities were then transferred to Biomarker Pattern’s software. Totally 35 peaks from Mr 2000 to 30000 were selected to construct the classification model. Figure 3 shows the tree structure and sample distribution. Two peaks, Mr 7772 and 3933, were chosen to set up the decision tree, respectively. At Node 1, samples of Mr 7772 with peak intensities lower than or equal to 7.514 went to Terminal Node 1, which had 9 control samples and 21 LC samples. Otherwise, samples entered Node 2, which had 40 samples. At Node 2, samples of Mr 3933 with peak intensities lower than or equal to 8.217 went to Terminal Node 2, which had 1 control sample and 3 LC samples. The other samples entered Terminal Node 3, which had 35 control samples and l LC sample. The model identified 70 samples, 36 in control and 34 in LC, and yielded a sensitivity of 96% and specificity of 77.8%. When the double-blind sample data set was used to challenge the model, the model predicted a sensitivity of 80% and specificity of 81.8%. The positive predictive value was 75%.

Figure 3
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Figure 3 Tree structure and sample distribution. The root node and descendant nodes are indicated in gray, and the ter-minal nodes are shown in black. Peaks with Mr 7772 and 3933 were chosen to set up the decision tree.
DISCUSSION

HBV infection often leads to a prolonged active viral replication, HBV DNA integration and eventually LC[6]. About 55-85% of LC patients will develop hepatocellular carcinoma, which always has bad prognosis. It is estimated that HCC may be responsible for more than 1 million deaths annually and it is the fifth most frequent cause of cancer death worldwide[7]. Liver biopsy has remained the gold standard for identification of patients with liver diseases. However, the differential diagnosis between HCC and LC is sometimes difficult and new biochemical markers for HCC are required. In recent years, several non-invasive serum biomarkers have been considered to diagnose LC associated with HBV, including hyaluronic acid (HA)[8,9], type III procollagen peptide, laminin and type IV collagen[10].

Among the non-invasive serum biomarkers for liver fibrosis and cirrhosis, HA was reported to be the best marker for diagnosis[11]. HA with a molecular mass of several million is present in most tissues as a component of the extracellular matrix. Elevated levels of serum HA have been reported in various diseases including liver diseases. Increases in serum HA correspond to the progression of liver diseases, including viral and non-viral diseases. Ding et al demonstrated that the elevated serum HA levels were closely related to the severity of liver fibrosis, particularly in LC[12]. In addition, Procollagen III peptide, laminin, and type IV collagen with molecular masses of 45000, 400000 and 67000, respectively, are also extracellular matrix glycoproteins and have been reported to be correlated to necrosis and inflammation as well as fibrosis in patients with chronic hepatitis and LC[13]. However, the diagnostic value, i.e. sensitivity and specificity, of these markers for patients with cirrhosis has not been satisfactory so far. Use of multiple markers led to 90% sensitivity at most in diagnosing cirrhosis, but variable specificity was about 60%[14].

SELDI-TOF mass spectrometry is a recently described affinity-based mass spectrometric method that combines chromatography and mass spectrometry. This novel technology has been used for protein or peptide biomarker identification, biomolecular interactions and post-translational modifications. Protein chip technology has proven to be useful in the discovery of potential diagnostic markers for prostate[15-17], bladder[18], ovarian[19], breast[20-22], lung cancers[23], and pancreatic ductal adenocarcinoma. However, using it to discover new biomarkers of HBV induced diseases has not been addressed before. To identify potential biomarkers that can detect HBV induced LC, protein profiles of serum samples from LC patients were compared with those from the non-cirrhotic controls. Biomarker Pattern’s Software was used to identify two peaks differentially presented in control healthy and HCC serum samples compared with LC samples. The top-scored two peaks with Mr 7772 and 3933 were finally selected. These two proteins generated a sensitivity of 96% and specificity of 77.8%. It is difficult to find a good single marker associated with diseases because of the differences among patients’ age, gender, diet and genes. Furthermore, double-blind test was used to determine the sensitivity and specificity of the model. A sensitivity of 80%, specificity of 81.8% and positive predictive value of 75% for the study population were obtained when comparing LC versus non-cirrhotic (HCC/healthy men) groups. The low-molecular-mass serum proteins are apparently different from known non-invasive serum biomarkers for LC in many aspects and might be acceptable for diagnosis and assessment of HBV associated LC.

Footnotes

Co-first-authors: Xiao-Dong Zhu and Wei-Hua Zhang

Edited by Chen WW Proofread by Zhu LH and Xu FM

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