Peng T, Shen HM, Liu ZM, Yan LN, Peng MH, Li LQ, Liang RX, Wei ZL, Halliwell B, Ong CN. Oxidative DNA damage in peripheral leukocytes and its association with expression and polymorphisms of hOGG1: A study of adolescents in a high risk region for hepatocellular carcinoma in China. World J Gastroenterol 2003; 9(10): 2186-2193 [PMID: 14562375 DOI: 10.3748/wjg.v9.i10.2186]
Corresponding Author of This Article
Dr. Tao Peng, Department of Hepatobiliary Surgery, First Affiliated Hospital of Guangxi Medical University, Nanning, 530021, Guangxi Zhuang Autonomous Region, China. pengpang@hotmail.com
Article-Type of This Article
Liver Cancer
Open-Access Policy of This Article
This article is an open-access article which was selected by an in-house editor and fully peer-reviewed by external reviewers. It is distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited and the use is non-commercial. See: http://creativecommons.org/licenses/by-nc/4.0/
World J Gastroenterol. Oct 15, 2003; 9(10): 2186-2193 Published online Oct 15, 2003. doi: 10.3748/wjg.v9.i10.2186
Oxidative DNA damage in peripheral leukocytes and its association with expression and polymorphisms of hOGG1: A study of adolescents in a high risk region for hepatocellular carcinoma in China
Tao Peng, Zhi-Ming Liu, Min-Hao Peng, Le-Qun Li, Department of Hepatobiliary Sugery, First Affiliated Hospital of Guangxi Medical University, Nanning, 530021, Guangxi Zhuang Autonomous Region, China
Han-Ming Shen, Choon Nam Ong, Department of Community, Occupational and Family Medicine, National University of Singapore, Singapore
Lu-Nan Yan, Department of General Surgery, First Affiliated Hospital of West China University of Medical Sciences, Chengdu, 610041, Sichuan Zhuang Autonomous Region, China
Ren-Xiang Liang, Zong-Liang Wei, Fusui Cancer Research Institute, Fusui County, 532100, Guangxi Province, China
Barry Halliwell, Department of Biochemistry, National University of Singapore, Singapore
ORCID number: $[AuthorORCIDs]
Author contributions: All authors contributed equally to the work.
Supported by the Guangxi Natural Sciences Grant, No.GKZ9912028 and No.GKJ0236030, Guangxi Educational Committee Grant, No. GZBH 2000-272, Guangxi Health Ministry Medicine Grant, No. Z2001087 and Singapore Science Grant, No.R-186-000-044-213
Correspondence to: Dr. Tao Peng, Department of Hepatobiliary Surgery, First Affiliated Hospital of Guangxi Medical University, Nanning, 530021, Guangxi Zhuang Autonomous Region, China. pengpang@hotmail.com
Telephone: +86-771-5352400
Received: July 12, 2003 Revised: July 17, 2003 Accepted: July 24, 2003 Published online: October 15, 2003
Abstract
AIM: To study the oxidative DNA damage to adolescents of hepatocellular carcinoma (HCC) families in Guangxi Zhuang Autonomous Region, China.
METHODS: Peripheral leukocytes’ DNA 7,8-dihydro-8-oxoguanine (8-oxoG) and repair enzyme hOGG1 were quantified by flow-cytometry. hOGG1-Cys326Ser single nucleotide polymorphism (SNP) was distinguished by polymerase chain reaction-single strand conformational polymorphism (PCR-SSCP) assay.
RESULTS: There was a positive correlation between 8-oxoG and repair enzyme hOGG1 expression (P < 0.001). HCC children (n = 21) in Fusui county had a higher level of hOGG1 (P < 0.01) and a lower level of 8-oxoG (P < 0.05) than the controls (n = 63) in Nanning city. Children in Nanning exposed to passive-smoking had a higher hOGG1 expression (P < 0.05) than the non-exposers. 8-oxoG and hOGG1 were negatively correlated with body mass index, while hOGG1 was positively correlated with age. There was a peak of 8-oxoG level nearby the 12 year point. Individuals with the hOGG1 326Ser allele had a significantly marginal higher concentration of leukocyte 8-oxoG level than hOGG1 326Cys allele.
CONCLUSION: This is the first report using flow-cytometry to simultaneously quantify both the DNA oxidative damage and its repairing enzyme hOGG1. The results provide new insights towards a better understanding of the mechanisms of oxidative stress in a population highly susceptible to hepatocarcinogenesis.
Key Words: $[Keywords]
Citation: Peng T, Shen HM, Liu ZM, Yan LN, Peng MH, Li LQ, Liang RX, Wei ZL, Halliwell B, Ong CN. Oxidative DNA damage in peripheral leukocytes and its association with expression and polymorphisms of hOGG1: A study of adolescents in a high risk region for hepatocellular carcinoma in China. World J Gastroenterol 2003; 9(10): 2186-2193
Reactive oxygen species (ROS) possess a high reactivity of a variety of biological molecules, among which, DNA is one of the most important targets[2]. Oxidative DNA damage, caused by either endogenous or exogenous source of ROS, has been linked to aging, chronic degenerative diseases, inflammatory diseases and cancers[3-6]. Among various types of DNA base modifications induced by ROS attack, 7,8-dihydro-8-oxoguanine (8-oxoG) has been the most widely studied and is considered as a key biomarker of oxidative DNA damage[7]. Leaving unrepaired, 8-oxoG is highly mutagenic because of its propensity to mispair with adenine during DNA replication, ultimately yielding GC to TA transversion[8].
To minimize 8-oxoG accumulation within genomes, this lesion is subjected to DNA repair primarily through the base excision repair pathway[9]. A key component of this pathway in eukaryotes is OGG1, a DNA glycosylase/β-lyase that recognizes 8-oxoG opposite cytosine[10]. Inactivation of the OGG1 gene generates a mutator phenotype characterized by GC-TA transversions in yeast[10]. Analysis of the human OGG1 gene (hOGG1) and its transcripts in normal and tumoral tissues has revealed alternative splicing, polymorphisms and somatic mutations[11]. The repair effectiveness of OGG1 may be modulated by gene polymorphisms. A Cys326Ser substitution in exon 7 has been the most extensively studied. The Cys326 isoform is postulated to exhibit reduced 8-oxoG repair activity[12], increase susceptibility to squamous cell carcinoma of lung cancer[13,14], otolaryngeal cancer[15] and esophageal cancer[16], nevertheless, controversy still remains[17-21].
Dietary aflatoxin exposure[22,23] and hepatitis infection[24,25] are two well known risk factors in liver carcinogenesis, which involves ROS generation and oxidative DNA damage. A synergistic effect of aflatoxin B1 (AFB1) and hepatitis virus B (HBV) may be involved in the hepatocellular carcinoma (HCC) formation, and may be responsible for the predominance of one hotspot GC→TA transversion in the p53 gene of affected individuals[22,23].
HCC is the third most common cause of cancer death in China[26], and the main killer in a south-western province, Guangxi Zhuang Autonomous Region[27]. The age-standardized mortality of HCC for males and females in this province was 32.5/100000 and 8.5/100000, respectively[1], accounting for 50% and 25% of all the cancer deaths in this region in men and women, respectively[1]. Thus far, dietary AFB1 exposure[28] and HBV infection[1] are the well documented risk factors for the extraordinarily high prevalence of HCC in this area. Our earlier data[29,30] together with that of Stern et al[31] have highlighted a frequency of 36%-73% of p53-249 codon mutation in HCCs in this region, which is consistent with the notion that, the p53-249 hot-spot mutation is a fingerprint of AFB1 contamination, and possibly synergistic with HBV infection in hepatocarcinogenesis[22].
In the present study, on the assumption that environmental carcinogens may impose oxidative stress on the residents living in Guangxi Zhuang Autonomous Region, we examined the level of 8-oxoG and hOGG1 expression in leukocytes of a random sample of adolescents aged 4-18 in an area of Guangatxi exposed to a high level of aflatoxin and high risk of HCC, using a newly developed flow cytometry method. Furthermore, we examined the relationship between DNA damage and genetic polymorphisms of oxidative damage repair gene hOGG1.
MATERIALS AND METHODS
Study subjects
This collaborative study by the Guangxi University and Fusui Cancer Institute was part of a community-based health survey in the Nanning region of Guangxi Zhuang Autonomous Region, conducted during April to June 2001. Based on the local cancer registry from 1974 to 1999, the HCC incidence rate in this region ranged from 32 to 97 per 100000 for males and 4.27 to 17.32 per 100000 for females, respectively. The aims of the study were explained in detail prior to the survey. From a total of 472 informed residents, 162 adults and 123 adolescents (60.4% response rate) participated in on a voluntary basis.
After written consents were obtained from all the individuals or children’s parent/guidance. Ten-milliliter venous blood was collected with heparin as anticoagulant. Buffy-coat and plasma separated soon after collection, and kept in liquid-nitrogen during transportation, and stored at -80 °C till analysis. Body weight, height, age, gender, occupation, alcohol and smoking habit and family history of hepatitis infections were also recorded using a structured questionnaire approved by the Guangxi Medical University. Plasma of all subjects was screened to differentiate HBV, HCV, HDV, HEV and HGV infections. 25.6% (73/285) subjects were positive of HV infection (63/HBV (+), 1/HBV&HCV (+), 1/HCV (+), 4/HBV&HDV (+), 2/HEV (+), 2/HBV&HGV (+)). These cases were excluded, in order to rule out the possibility of influence from hepatitis viruse infection[24,25]. Furthermore, subjects with known exposure to known environmental or occupational hazards (such as cigarette smoking, alcohol or pesticides), as well as those who were currently under medication or known to have a chronic illness were also excluded. Fifty-six boys and 28 of girls aged from 4 to 18 (mean ± SD, 11.45 ± 3.0 years) born and grown up in this region met the above mentioned criteria, and were selected for this investigation.
Determination of DNA 8-oxoguanine and hOGG1 in leukocytes
Prior to the investigation, extensive experiments were conducted to optimize the antibody/probe titers and the amount of cells to be used for flow cytometry. It was found that reproducible data could be achieved with 40 µL-buffy coat (around 0.8-1.1 × 106 WBC). The buffy-coat was first transferred from -80 °C to 4 °C, gently thawed for 4 h, and then shifted to room temperature till completely thawed. Forty micro liters buffy-coat were counted for leukocytes using a hemocytometer, and another 40 µL buffy-coat was transferred into an Eppendorf tube containing 1 mL of PBS with 1% paraformaldehyde, stood on ice for 30 min. After washed twice with PBS, Cells were then fixed in ice-cool 70% ethanol and kept at -20 °C till staining.
8-oxoG was stained by a Biotrin OxyDNA Assay Kit (Fluorescein isothiocyanate, FITC-conjugated probe, Biotrin Int. Ltd., Dublin, Ireland.) according to the manufacturer’s protocol with some minor modifications[32,33]. For hOGG1 staining, first antibody (1st Ab, goat-anti-hOGG1) was obtained from Santa Cruz Biotech, Inc (California, U.S.A.) (goat polyclonal antibody, against a peptide mapping at the amino terminus of OGG1 of human origin, reacts with all OGG1 splice variants of human origin). The second antibody (2nd Ab, R-phycoerythrin, PE-conjugated rabbit anti-goat IgG) was purchased from Sigma-Aldrich Inc., (St. Louis, MO, USA). Before staining, the cells were treated by Biotrin Blocking Solution at 37 °C for 60 min. After washed with Biotrin Washing Solution, the cells were first incubated with 1st Ab (goat-anti-hOGG1, 1:100 in 3% FBS/PBS), followed by a mixture of Biotrin 8-oxoG probe (FITC-conjugate, 1:10 dilution) and 2nd Ab (rabbit-anti-goat, PE conjugate, 1:400 dilution) in the Biotrin Washing Solution at 37 °C in the dark for 60 min per step. The cells were then re-suspended and quantified by a flow cytometer (Coulter Epics Elite Flow Cytometer, Coulter Corporation, Miami, USA), at 488 nm excitation and 525 nm (FITC), 578 nm (PE) emission, respectively. Blood from a healthy adult volunteer was included and served as an internal control. Data were analyzed using the WinMDI2.8 software (http: //facs.scripps.edu/software.html). 8-oxoG and hOGG1 levels were determined as percentage of positive-staining-cells (oxoGP, hOGG1P) and mean of relative fluorescence intensity (RFI for oxoGI, hOGG1I) of 10000 cells counted by the flow cytometer[34]. To eliminate possible batch-to-batch variations, all the samples were analyzed at the same batch by the same cytometer.
Genotyping of hOGG1 Cys326Ser single nucleotide polymorphism (SNP)
PCR-SSCP analysis of hOGG1 Cys326Ser SNP was modified from a technique described by Kohno et al[12]. DNA extracted from leukocytes using phenol-chloroform method was amplified by PCR. The primers used were 5’-actgt-cacta-gtctc-accag-3’ (forward) and 5’-tgaat-tcgga-aggtg-cttgg-ggaat-3’ (reverse) (Research Biolabs Pte., Ltd., Singapore). PCR polymerase and dNTP were from Finnzymes (ESPOO, Finland). Twenty-µL PCR reaction mixture contained 2 µL 10 × PCR-buffer, 1.5 mM MgCl2, 0.1 mM dNTP, 0.5 µM of each primer, 1 U Finnzyme polymerase and -100 ng of sample DNA. PCR reaction on a thermocycler (Biometra TGradient, Göttingen, Germany) began with pre-incubation at 94 °C for 5 min, followed by 30 cycles of denaturation at 94 °C for 30 s, annealing at 54 °C for 30 s, and elongation at 72 °C for 30 s. PCR products were diluted with 4 volumes of loading buffer (0.5 × TBE, 0.05% bromophenol blue, 0.05% xylene cyanol, 20 mM methylmercury hydroxide), heat-denatured at 85 °C for 5 min and rapidly cooled on ice before loading. Twenty microliters of each sample were separated on 10% non-denaturing polyacrylamide gels with or without 5% glycerol. Electrophoresis was conducted at 200 V constant for 5 h at 4-5 °C. Silver staining followed Forsberg et al[35]. Genotype of each band-pattern was confirmed by a subsequent sequencing in a commercial laboratory (Research Biolabs Pte., Ltd, Singapore) using BigDyeTM Terminator kits on a ABI PRISM® 377-96 DNA Sequencer. A blank was inserted into each batch PCR to monitor PCR contamination, and for each sample, at least one independent repeat of PCR-SSCP assay was done.
Statistical analysis
All analyses were performed using the SPSS 10.0 program (Chicago, USA). Two cases were excluded from flow cytometry assays because of inadequate leukocytes. The frequency distributions of 8-oxoGP, 8-oxoGI, hOGG1P and hOGG1I skewed to the right while body mass index (BMI) skewed to the left. In order to obtain acceptable fit to the normal distribution and stabilize the variance, 8-oxoGI, hOGG1I and BMI were log-transformed while 8-oxoGP and hOGG1P were transformed by the formula: log ((100 + X)/(100 - X)). Non-parameter Mann-Whitney test and one-way ANOVA were used to examine the influence of gender and hOGG1 genotype on the four biomarkers, respectively. A partial correlation was calculated to examine the closeness of relationship between continuous variables (biomarkers, age and BMI). Multiple linear regressions were conducted to examine the influence of risk factors on the four biomarkers, respectively. A two-tailed P value < 0.05 was considered significant.
RESULTS
Levels of 8-oxoG and hOGG1
Figure 1a to 1d show the images of leukocytes stained for 8-oxoG and hOGG1 under laser confocal microscope. The mean levels of the four biomarker parameters in male and female children are summarized in Table 1. The positive-staining cell percentage of 8-oxoG and hOGG1 ranged between 45%-99% and 44%-98%, respectively. It was noted that the majority (> 72%) of cases had over 90% positive-staining leukocytes for both 8-oxoG and hOGG1. The data suggested that between male and female children, there was no significant difference in both 8-oxoG and hOGG1 expressed either as percentage or fluorescent intensity.
Figure 1 Representative images of leukocytes stained by 8-oxoG-FITC probes (green) and hOGG1-PE complex (red) under laser confocal microscopy.
The bottom-right figure demonstrated that some of the leukocytes were simultaneously stained with both FITC and PE complex.
Table 1 Level of biomarkers in male and female children.
8-oxoGP (%)
8-oxoGI (RFI)
hOGG1 (%)
hOGG1 (RFI)
Double staining percentage (%)
Male (n = 54)
94.55 (89.14, 94.16)b
61.74 (58.02, 73.57)
93.29 (88.39, 93.11)
110.50 (100.39, 125.07)
86.76 (81.10, 86.90)
Female (n = 28)
94.98 (90.03, 95.17)
69.91 (60.28, 78.83)
91.78 (88.31, 92.86)
102.51 (85.39, 116.24)
87.10 (81.14, 87.79)
Pa
0.469
0.323
0.577
0.225
0.822
Association between 8-oxoG, hOGG1, age and BMI
Table 2 reveals that there were significant correlations between 8-oxoG level and hOGG1 expression even after adjustment of age and BMI. Furthermore, a positive correlation was seen between age and hOGG1 expression, either measured as percentage or intensity. In contrast, a negative correlation was noted between BMI and 8-oxoGP, and between BMI and hOGG1P. These associations remained significant even when BMI or age was adjusted. These data suggested that age and BMI could independently influence the levels of oxidative damage and hOGG1 gene expression.
Table 2 Partial Correlation between biomarkers, age and BMI.
8-oxoGP (%)
8-oxoGI (RFI)
hOGG1P (%)
hOGG1I (RFI)
Double staining percentage (%)
8-oxoGP (%)a
0.6987 (0.000)f
0.8333 (0.000)f
0.5299 (0.000)f
0.9553 (0.000)f
8-oxoGI (RFI)a
0.4843 (0.000)f
0.5155 (0.000)f
0.7075 (0.000)f
hOGG1P (%)a
0.6727 (0.000)f
0.8482 (0.000)f
hOGG1I (RFI)a
0.6528 (0.000)f
Ageb
0.1832 (0.102)
-0.0326 (0.773)
0.3332 (0.002)f
0.2316 (0.037)e
0.1655 (0.140)
BMIb
-0.3339 (0.002)f
-0.0983 (0.383)
-0.3111 (0.005)f
-0.0415 (0.713)
-0.2285 (0.0040)f
Agec
0.2414 (0.031)e
-0.0204 (0.858)
0.3954 (0.000)f
0.2390 (0.033)e
0.2015 (0.073)
BMId
-0.3663 (0.001)f
-0.0950 (0.402)
-0.3779 (0.001)f
-0.0735 (0.517)
-0.2552 (0.022)e
Association between biomarkers and hOGG1 Cys326Ser SNP
The median levels and 95% confidence interval (95%CI) of the four biomarker parameters of their respective hOGG1 Cys326Ser SNP genotype are presented in Table 3. Children with hOGG1 Cys326Ser heterozygote were found to have a higher level of 8-oxoG than those with Cys/Cys homozygote, although statistical significance was observed only in 8-oxoG intensity. Also, comparison of subgroup Cys/Cys vs. (Cys/Ser + Ser/Ser) revealed similar results (data not shown).
Table 3 Association between biomarkers and hOGG1-326 SNP (Oneway ANOVA).
To explore possible interactions of risk factors, a linear regression was then conducted for the four biomarkers, respectively (Table 4). Based on the multiple regression analysis against 8 variables, hOGG1 expression level increased with aging, leaner children had a lower level of 8-oxoG, and hOGG1 326Ser allele had an increasing effect on 8-oxoG level while a reducing effect on hOGG1 expression. However, the 8 factors listed in Table 4 explained only less than 50% of the entire variations, suggesting that other oxygen radical-forming factors might be involved.
Table 4 Multiple regression models of predictors on levels of oxidative DNA damage biomarkers.
Predictors in the model
Double staining percentage (%)
8-oxoGP
8-oxoGI
hOGG1P
hOGG1I
Betab
P
Beta
P
Beta
P
Beta
P
Beta
P
8-oxoGP
0.463
0.000c
8-oxoGI
0.521
0.000c
131.226
0.000c
hOGG1P
0.922
0.000c
hOGG1I
0.411
0.000c
6.591E-02
0.008c
Age
0.090
0.201
-0.139
0.108
-0.075
0.426
2.532E-02
0.001c
3.069
0.018c
Gender
-0.027
0.693
-0.081
0.336
-0.106
0.253
0.058
0.474
0.104
0.262
BMI
-0.046
0.496
-0.055
0.511
-1.048E-02
0.050c
-0.053
0.516
0.037
0.696
hOGG1 326SNP
0.056
0.427
0.103
0.029c
2.370E-03
0.000c
-0.112
0.166
-15.684
0.006c
Constant
0.480
0.000
6.969E-02
0.705
1.601
0.000
0.401
0.001
-133.512
0.001
R2(F)d
0.667 (79.227)e
0.470 (35.033)e
0.377 (15.729)e
0.509 (40.875)e
0.386 (16.369) e
DISCUSSION
Population-based researches can provide new clues to etiology of a disease. The unique epidemiology of high mortality rate of HCC in Guangxi Zhuang Autonomous Region, China has provided an ideal population model for the study of oxidative DNA damage and corresponding repair mechanism[1]. Although aflatoxin exposure was not measured in the present study, our earlier reports and others have shown that the dietary intake of aflatoxin in the local residents was high[28,36]. Furthermore, it has been well established that AFB1 causes rapid ROS formation and leads to DNA oxidative damage, which plays a critical role in hepato-carcinogenesis[22]. The subjects of the present study came from a typical HCC high risk community. In order to rule out the possibility of influence from hepatitis virus infection and other potential environmental and occupational factors, such as pesticides, cigarette smoking and alcohol, we have limited the present study to 82 children under the age of 18 with no known liver diseases or other medical history.
Methodology of quantification for oxidative DNA damage
Immunohistochemistry-based approaches have been widely used for the quantification of DNA adducts in various tissues[37], as well as in in-situ[38,39] or urinary[40] 8-oxoG quantification. On the other hand, flow cytometry technology allows multi-parameter analyses of heterogeneous cell population, in which immunophenotyping of both surface and cytoplasmic antigens, DNA analysis and functional evaluations are combined. Subsets of cells can be identified and characterized by patterns of maturation antigens and staining intensity[41]. This report is the first study thus far utilizing flow cytometry for simultaneous quantification of both 8-oxoG and a high risk population of HCC as a model. Compared to the immuno-quantification of 8-oxoG using visualized counting of positive-staining cells, the flow cytometry approach we used, has the following advantages. The assessment is more objective compared to other methods as the scoring is not operator dependent, both the number of positive-staining cells and fluorochrome intensity could be quantified simultaneously, the sample required (-1 × 106 cells) is much less, compared to other traditional methods, and high-throughput (it can handle as many as 100 samples per batch, thus eliminating possible batch to batch variations).
Prior to the present investigation, attention was paid during the pilot study to standardize and validate the instrumentation and methodology. Factors such as specificity and performance of the reagents, staining intensity, spectral overlap, and instrument compensation were carefully evaluated[41]. The overall indication is that the flow cytometry determinations of 8-oxoG and hOGG1 are of high reliability. The reproducibility is generally over 90% with batch-to batch variation of less than 10%. As for the actual samples from Guangxi, a substantial proportion of leukocytes was found to be positively-stained for both 8-oxoG and hOGG1. These values are much higher compared to normal healthy subjects from Singapore of about 20% to 40% (Tao et al, unpublished data). Table 2 clearly demonstrates that there were significant correlations between 8-oxoG level and hOGG1 expression, either expressed as percentage or chromophore intensity. Even after confounding factors such as age and BMI were adjusted, there were still significant associations between oxidative damage and hOGG1 expression in leukocytes (Table 2). This finding supports that normal cells have certain defensive mechanism against ubiquitous oxidative DNA damage[9], and hOGG1 works as a housekeeping gene, ubiquitously expressed during cell cycle[42].
Although inter-individual variations of hOGG1 are genetically determined, the present data and several earlier studies suggest that its expression could be influenced by endogenous formation of ROS or environmental carcinogens. Increased 8-oxoG repair activity has been shown to increase in smoker’s leukocytes[43] and in lung cells exposed to asbestos[44]. Quantitative assessment of hOGG1 expression in peripheral blood cells can provide information on exposure to environmental carcinogens[45]. The present study has clearly demonstrated that hOGG1 in leukocytes, expressed either in percentage or fluorescence intensity, can indicate the oxidative damage in an HCC high risk population, suggesting that hOGG1 is a useful biomarker for monitoring oxidative stress, in addition to 8oxoG.
Gender and oxidative DNA damage
Based on the epidemiological data obtained earlier in other parts of China as well as in Guangxi Zhuang Autonomous Region, the occurrence of HCC is predominant in men, the ratio of male to female is 4-6:1[1]. However, in the present study, we did not observe any difference in either 8oxoG or hOGG1 level between male and female children (Table 1). According to Loft et al[46], adult healthy men aged 40 to 60 excreted 29% (10%-48%) more 8-oxoG in urine than women. Nevertheless, DNA damage, measured as either percentage of DNA migrated in COMET tail[47] or 8-oxoG excretion in urine[48], was not associated with gender in other two adult populations. In healthy individuals, there was no difference in hOGG1 activity due to gender by means of an 8-oxoG-containing oligonucleotide assay[17]. Since this was a children-based study, further evidences from adult subjects are required to elucidate the role of gender-related factors in hepatocarcinogenesis in this population.
Age, BMI and oxidative DNA damage
An inversed relationship between BMI and urinary excretion of 8-oxoG in adults has been documented[46,49], and was postulated to be due to a higher metabolic rate in lean persons[46]. In the present study, similarly, we observed a negative correlation between BMI and 8-oxoGP, and between BMI and hOGG1P (Table 2), which was consistent with that in previous reports. There was also a positive correlation between hOGG1 level and age, which was not consistent with that of 8-oxoG (Figure 2, Table 2). This age-dependent increase of hOGG1 in children has never been reported elsewhere. The results indicated that, the age-dependent increase of hOGG1 level can not simply be explained by metabolic rate and BMI.
Using COMET assay to study DNA damage of children in Mexico City, Calderon-Garciduenas[50] showed that there was an age-dependent increase in the percentage of nasal cells with COMET tails > 10 microns, implying a dose response relationship between exposure to environment pollutants and increase of age. Drury[51] in a preliminary study of 15 children observed an increase of mean 8-OHdG excretion in urine with postnatal age (r = 0.80, P < 0.0001). Nevertheless, the author argued that these changes could also be due to changes in the activity of the enzyme responsible for 8-OHdG excision. According to Bogdanov[52], however, neonates of 50-60 d had a higher 8-OHdG excretion in urine (13.39 ± 0.082 ng/mg creatinine, n = 150) than children aged 3-9 (4.62 ± 0.091 ng/mg creatinine, n = 32). So far no report about hOGG1 expression in children is available. Therefore it is not known whether this age-dependency is attributed to growth-related increase of metabolism or dietary increase (accumulation) of exposure to aflatoxin or other hazards, or both. Further studies with a larger population should be able to provide more insights in this preliminary observation.
hOGG1-Cys326Ser SNP and oxidative DNA damage
DNA repair enzyme OGG1 is a DNA glycosylase/AP lyase that has been hypothesized to play an important role in preventing carcinogenesis by repairing oxidative damage to DNA. Specifically, it can efficiently repair 8-oxoG, a major base lesion produced by ROS and formed by endogenous metabolism or exposure to environmental oxidizing agents or genotoxic compounds[10]. In this study we have analyzed the variants of hOGG1-Cys326Ser in 84 children and the results showed that the frequency of hOGG1-Cys326 allele of 54.8% was similar to that reported by Sugimura[13] and Takezaki[53] conducted in two other Chinese populations (54.5% to 60.7%). In the present investigation, individuals with the hOGG1 326Ser allele rather than hOGG1 326Cys allele, had a significantly higher concentration of leukocyte 8-oxoG level (Table 3 and Table 4).
Kohn et al[12] first described a reduced repair activity of hOGG1-Cys326 protein in a complementation assay system. Nevertheless, this observation was not supported by another study using cell homogenates-cleavage system[17]. A recent study by Janssen et al[17] found that DNA repair activity of OGG1 in human lymphocytes was not dependent on the Ser326Cys variants. Paralleling to the results of functional studies, population studies on hOGG1-326 polymorphism and cancer susceptibility thus far were also not conclusive[17-21]. It is however important to note that the proportion of homozygous Ser-Ser individuals is the highest in Melanesians (74.5%), and German (57.1%), lower in Australian Caucasians (40%), Japanese (27.7%) and even lower in Chinese (12%)[13].
Since the 8-oxoG level measured in a tissue at time is an integration of a number of parameters including the level of ROS, tissue redox status, cellular antioxidant defense mechanism and DNA repair system[21], our data suggest that the role of hOGG1 SNP, if any, in modulating 8-oxoG level of individuals, may be diluted by other confounders. On the other hand, it is believed that hOGG1 may not be the only gene associated with oxidative damage. An alternative DNA oxidative damage repair pathway to minimize the effects of 8-oxoG in genomes has also been reported recently[54]. Carefully designed studies considering these confounders however, are obviously needed to verify this observation.
From the data obtained in this study, it is concluded that, oxidative damage is significantly correlated with the DNA damage repair enzyme hOGG1, there are positive associations between oxidative damage, repair enzyme hOGG1 and age, while there are reverse relationships between oxidative damage and body mass indexes, and polymorphism of hOGG1 variant appears to influence 8-oxoG level in peripheral leukocytes, but only at a marginal strength. These findings provide some new insights into a better understanding of the complex etiology and molecular events that could lead to the development of HCC. Further study should take into consideration of both long term environment exposure and genetic susceptibility in a larger population.
ACKNOWLEDGEMENT
We are grateful to Prof. Chia SE and Dr. Dong F for their statistical advice and critical comments on the manuscript. We are also grateful to Ong HY and Ong YB for their technical support (Department of Community, Occupational and Family Medicine, National University of Singapore, Singapore.).
Yeh FS, Mo CC, Luo S, Henderson BE, Tong MJ, Yu MC. A serological case-control study of primary hepatocellular carcinoma in Guangxi, China.Cancer Res. 1985;45:872-873.
[PubMed] [DOI][Cited in This Article: ]
Halliwell B. Effect of diet on cancer development: is oxidative DNA damage a biomarker?Free Radic Biol Med. 2002;32:968-974.
[PubMed] [DOI][Cited in This Article: ]
De Flora S, Izzotti A, Randerath K, Randerath E, Bartsch H, Nair J, Balansky R, van Schooten F, Degan P, Fronza G. DNA adducts and chronic degenerative disease. Pathogenetic relevance and implications in preventive medicine.Mutat Res. 1996;366:197-238.
[PubMed] [DOI][Cited in This Article: ][Cited by in Crossref: 115][Cited by in F6Publishing: 106][Article Influence: 3.9][Reference Citation Analysis (0)]
Brozmanová J, Dudás A, Henriques JA. Repair of oxidative DNA damage--an important factor reducing cancer risk. Minireview.Neoplasma. 2001;48:85-93.
[PubMed] [DOI][Cited in This Article: ]
Kohno T, Shinmura K, Tosaka M, Tani M, Kim SR, Sugimura H, Nohmi T, Kasai H, Yokota J. Genetic polymorphisms and alternative splicing of the hOGG1 gene, that is involved in the repair of 8-hydroxyguanine in damaged DNA.Oncogene. 1998;16:3219-3225.
[PubMed] [DOI][Cited in This Article: ][Cited by in Crossref: 308][Cited by in F6Publishing: 331][Article Influence: 12.7][Reference Citation Analysis (0)]
Le Marchand L, Donlon T, Lum-Jones A, Seifried A, Wilkens LR. Association of the hOGG1 Ser326Cys polymorphism with lung cancer risk.Cancer Epidemiol Biomarkers Prev. 2002;11:409-412.
[PubMed] [DOI][Cited in This Article: ]
Xu J, Zheng SL, Turner A, Isaacs SD, Wiley KE, Hawkins GA, Chang BL, Bleecker ER, Walsh PC, Meyers DA. Asso-ciations between hOGG1 sequence variants and prostate cancer susceptibility.Cancer Res. 2002;62:2253-2257.
[PubMed] [DOI][Cited in This Article: ]
Wikman H, Risch A, Klimek F, Schmezer P, Spiegelhalder B, Dienemann H, Kayser K, Schulz V, Drings P, Bartsch H. hOGG1 polymorphism and loss of heterozygosity (LOH): significance for lung cancer susceptibility in a caucasian population.Int J Cancer. 2000;88:932-937.
[PubMed] [DOI][Cited in This Article: ][Cited by in F6Publishing: 3][Reference Citation Analysis (0)]
Hanaoka T, Sugimura H, Nagura K, Ihara M, Li XJ, Hamada GS, Nishimoto I, Kowalski LP, Yokota J, Tsugane S. hOGG1 exon7 polymorphism and gastric cancer in case-control studies of Japanese Brazilians and non-Japanese Brazilians.Cancer Lett. 2001;170:53-61.
[PubMed] [DOI][Cited in This Article: ][Cited by in Crossref: 41][Cited by in F6Publishing: 47][Article Influence: 2.0][Reference Citation Analysis (0)]
Moriya K, Nakagawa K, Santa T, Shintani Y, Fujie H, Miyoshi H, Tsutsumi T, Miyazawa T, Ishibashi K, Horie T. Oxidative stress in the absence of inflammation in a mouse model for hepatitis C virus-associated hepatocarcinogenesis.Cancer Res. 2001;61:4365-4370.
[PubMed] [DOI][Cited in This Article: ]
National Cancer Control Office. Atlas of Cancer Mortality in The People's Republic of China. Nanjing Institute of Geography.China Map Press Shanghai. 1979;.
[PubMed] [DOI][Cited in This Article: ]
Huang TR, Yu JH, Zhang ZHQ. Analysis on epidemic feature and secular trend of primary liver cancer in Guangxi.Guangxi Medical J. 2000;22:677-679.
[PubMed] [DOI][Cited in This Article: ]
Wang JS, Huang T, Su J, Liang F, Wei Z, Liang Y, Luo H, Kuang SY, Qian GS, Sun G. Hepatocellular carcinoma and aflatoxin exposure in Zhuqing Village, Fusui County, People's Republic of China.Cancer Epidemiol Biomarkers Prev. 2001;10:143-146.
[PubMed] [DOI][Cited in This Article: ]
Peng T, Li LQ, Lin JL, Lu YF, Wu S, Liang ST, Xiao Q, Liao QH. p53 gene 249codon mutation in recurrent hepatocellular carci-noma from Guangxi province.Chinese J General Surgery. 2000;15:17.
[PubMed] [DOI][Cited in This Article: ]
Deng Z, Pan L, Ma Y. [Sequence alterations in p53 gene of hepatocellular carcinoma from high aflatoxin risk area in Guangxi].Zhonghua Zhongliu Zazhi. 1997;19:18-21.
[PubMed] [DOI][Cited in This Article: ]
Stern MC, Umbach DM, Yu MC, London SJ, Zhang ZQ, Taylor JA. Hepatitis B, aflatoxin B(1), and p53 codon 249 mutation in hepatocellular carcinomas from Guangxi, People's Republic of China, and a meta-analysis of existing studies.Cancer Epidemiol Biomarkers Prev. 2001;10:617-625.
[PubMed] [DOI][Cited in This Article: ]
Lenka N, Lu ZJ, Sasse P, Hescheler J, Fleischmann BK. Quantitation and functional characterization of neural cells derived from ES cells using nestin enhancer-mediated targeting in vitro.J Cell Sci. 2002;115:1471-1485.
[PubMed] [DOI][Cited in This Article: ]
Forsberg L, de Faire U, Morgenstern R. Low yield of polymorphisms from EST blast searching: analysis of genes related to oxidative stress and verification of the P197L polymorphism in GPX1.Hum Mutat. 1999;13:294-300.
[PubMed] [DOI][Cited in This Article: ][Cited by in F6Publishing: 1][Reference Citation Analysis (0)]
Zhu JQ, Zhang LS, Hu X, Xiao Y, Chen JS, Xu YC, Fremy J, Chu FS. Correlation of dietary aflatoxin B1 levels with excretion of aflatoxin M1 in human urine.Cancer Res. 1987;47:1848-1852.
[PubMed] [DOI][Cited in This Article: ]
Saito S, Yamauchi H, Hasui Y, Kurashige J, Ochi H, Yoshida K. Quantitative determination of urinary 8-hydroxydeoxyguanosine (8-OH-dg) by using ELISA.Res Commun Mol Pathol Pharmacol. 2000;107:39-44.
[PubMed] [DOI][Cited in This Article: ]
Asami S, Hirano T, Yamaguchi R, Tomioka Y, Itoh H, Kasai H. Increase of a type of oxidative DNA damage, 8-hydroxyguanine, and its repair activity in human leukocytes by cigarette smoking.Cancer Res. 1996;56:2546-2549.
[PubMed] [DOI][Cited in This Article: ]
Kim HN, Morimoto Y, Tsuda T, Ootsuyama Y, Hirohashi M, Hirano T, Tanaka I, Lim Y, Yun IG, Kasai H. Changes in DNA 8-hydroxyguanine levels, 8-hydroxyguanine repair activity, and hOGG1 and hMTH1 mRNA expression in human lung alveolar epithelial cells induced by crocidolite asbestos.Carcinogenesis. 2001;22:265-269.
[PubMed] [DOI][Cited in This Article: ][Cited by in Crossref: 61][Cited by in F6Publishing: 63][Article Influence: 2.7][Reference Citation Analysis (0)]
Hanaoka T, Yamano Y, Hashimoto H, Kagawa J, Tsugane S. A preliminary evaluation of intra- and interindividual variations of hOGG1 messenger RNA levels in peripheral blood cells as determined by a real-time polymerase chain reaction technique.Cancer Epidemiol Biomarkers Prev. 2000;9:1255-1258.
[PubMed] [DOI][Cited in This Article: ]
Witherell HL, Hiatt RA, Replogle M, Parsonnet J. Helicobacter pylori infection and urinary excretion of 8-hydroxy-2-deoxyguanosine, an oxidative DNA adduct.Cancer Epidemiol Biomarkers Prev. 1998;7:91-96.
[PubMed] [DOI][Cited in This Article: ]
Kasai H, Iwamoto-Tanaka N, Miyamoto T, Kawanami K, Kawanami S, Kido R, Ikeda M. Life style and urinary 8-hydroxydeoxyguanosine, a marker of oxidative dna damage: effects of exercise, working conditions, meat intake, body mass index, and smoking.Jpn J Cancer Res. 2001;92:9-15.
[PubMed] [DOI][Cited in This Article: ][Cited by in Crossref: 129][Cited by in F6Publishing: 131][Article Influence: 5.7][Reference Citation Analysis (0)]
Calderon-Garciduenas L, Wen-Wang L, Zhang YJ, Rodriguez-Alcaraz A, Osnaya N, Villarreal-Calderon A, Santella RM. 8-hy-droxy-2'-deoxyguanosine, a major mutagenic oxidative DNA lesion, and DNA strand breaks in nasal respiratory epithelium of children exposed to urban pollution.Environ Health Perspect. 1999;107:469-474.
[PubMed] [DOI][Cited in This Article: ]
Bogdanov MB, Beal MF, McCabe DR, Griffin RM, Matson WR. A carbon column-based liquid chromatography electrochemical approach to routine 8-hydroxy-2'-deoxyguanosine measurements in urine and other biologic matrices: a one-year evaluation of methods.Free Radic Biol Med. 1999;27:647-666.
[PubMed] [DOI][Cited in This Article: ][Cited by in Crossref: 144][Cited by in F6Publishing: 149][Article Influence: 6.0][Reference Citation Analysis (0)]