Abstract
AIM: To disclose geographic differences in genetic changes involved in gallbladder carcinogenesis between two distinct high-incidence areas of Japan and Hungary.
METHODS: We examined 42 cases of gallbladder carcinoma: 22 Japanese and 20 Hungarian cases. p53 mutations at exons 5 to 8 and K-ras mutations at codon 12 were tested by direct sequencing. Microsatellite instability was determined from fluorescent dye-labeled PCR amplifications of five-microsatellite markers (BAT-25, BAT-26, D2S123, D5S346, and D17S250).
RESULTS: Mutations of p53 were detected in 11 of 22 Japanese cases and 6 of 18 Hungarian cases (11/22 vs 6/18, P = 0.348). Transition at CpG sites was found in none of 11 Japanese cases and 2 of 6 Hungarian cases; the difference was marginally significant (0/11 vs 2/6, P = 0.110). K-ras mutations were detected in only one of the Hungarian cases. Eight of 19 (42.1%) Japanese cases were MSI-high (presence of novel peaks in more than one of the five loci analyzed), whereas only 1 of 15 (6.7%) Hungarian cases was MSI-high (P = 0.047).
CONCLUSION: It appears that the p53 mutations and MSI differ in patients with gallbladder carcinoma between two distinct high-incidence areas. Geographic variation might exist in the process of gallbladder carcinogenesis.
Keywords: Gallbladder, Gallbladder Neoplasms, K-ras, Microsatellite instability, p53
INTRODUCTION
Although considerable progress has been made regarding the molecular pathogenesis of human neoplasms such as colorectal carcinoma[1,2], pancreatic carcinoma[3,4], and breast carcinoma[5,6], there is only limited information about the genetic changes involved in gallbladder carcinogenesis[7,8]. Gallbladder carcinoma shows striking geographic and ethnic variation[9,10]. The high-incidence areas are scattered throughout the world: Latin America, Eastern Europe, northern India, and Japan[9–13]. The highest mortality rate of gallbladder carcinoma in the world, 35 per 100 000 inhabitants, is found in Southern Chile[9]. Japanese standardized mortality rates for gallbladder carcinoma were world’s second highest for males and fifth highest for females in 1996 with a steady increase in incidence (up to 5 per 100 000)[9,10,14]. On the other hand, Zatonski reported that Hungarian mortality rates of this tumor were the highest in Europe (4 per 100 000 males and 7 per 100 000 females)[13]. This marked geographic variation implies that a combination of genetic and environmental etiologic factors affects the process of carcinogenesis of the gallbladder[10]. Previously, we revealed the geographic variation of gallbladder carcinogenesis between Japan and Chile (a representative of Latin American countries), both of which were known as distinct high-incidence countries, in terms of the p53 mutational spectra[14]. Only a few other investigators also have reported such geographic and ethnic differences in genetic changes of this tumor[15–17]. Thus, there has been a paucity of evidence regarding the geographic diversity of genetic changes involved in gallbladder carcinogenesis.
The aim of this study was to disclose geographic differences in genetic changes involved in gallbladder carcinogenesis by comparing gallbladder carcinomas from two distinct high-incidence areas, Japan and Hungary (a representative country of Eastern Europe), in terms of p53 mutations, K-ras mutations, and microsatellite instability (MSI).
MATERIALS AND METHODS
Tissue specimens
From 1982 to 1996, 22 patients with gallbladder carcinoma underwent a resection at Niigata University General Hospital and its affiliated institutions in Niigata Prefecture; the surgical specimens were collected and stored (Japanese cases). All the patients were Japanese. The Japanese cases in this study were identical with the Japanese cases in our previous study[14]. From 1982 to 2001, 20 patients with gallbladder carcinoma underwent a resection in hospitals in Budapest, Hungary; the surgical specimens were collected and stored (Hungarian cases) through the courtesy of a Hungarian oncologist (I.L.) and surgical pathologist (Z.S.). All the patients were residents in Budapest. Both the Japanese cases and the Hungarian cases (a total of 42 cases) formed the basis of this retrospective study. All of the patients gave informed consent for pathologically examining the specimens. No patient in this series was diagnosed with anomalous union of the pancreatic and biliary ducts (AUPBD), and had a family history suggestive of hereditary nonpolyposis colorectal cancer (HNPCC).
The surgical specimens were fixed in formalin and embedded in paraffin. One or two representative sections of each specimen were used for DNA analysis. Histopathological findings were described according to the tumor-node-metastasis (TNM) staging system[18].
DNA preparation
Five serial slices 10-μm thick were cut from each represen-tative histologic section and deparaffinized. Cancer tissue in each slice was dissected under microscopic guidance as described previously[14]. Non-neoplastic tissue in each slice was used as a source of constitutional DNA. DNA was extracted using a DNA Isolator PS Kit (Wako Pure Chemical Industries, Ltd., Osaka, Japan) as described previously[14].
Analysis of p53 mutations
p53 mutations at exons 5 to 8 were tested by nested polymerase chain reaction (PCR) and direct sequencing as described previously[14].
Analysis of K-ras mutations
K-ras mutations at codon 12 were tested by nested PCR, PCR-restriction fragment length polymorphism, and direct sequencing as described elsewhere[19].
Analysis of MSI
Fluorescent dye-labeled PCR amplification was performed using the five microsatellite markers (BAT-25, BAT-26, D2S123, D5S346, and D17S250) recommended by the National Cancer Institute workshop[20,21]. Fluorescent dye-labeled and unlabeled primers were obtained (Applied Biosystems Japan Ltd., Tokyo, Japan); the 5' oligonucleotide was end-labeled with 6FAM (BAT-25, D2S123), VIC (BAT-26, D17S250), or NED (D5S346) fluorescent dyes. Amplification by PCR was performed using the Temp Control System PC-700 (ASTEC Co., Ltd., Fukuoka, Japan) in 30-μL reaction volumes containing 100 ng of DNA, 0.75 U of AmpliTaq Gold (Applied Biosystems Japan Ltd.), and 10 pmol of each primer. The cycling profile was: denaturation at 95°C for 2 min, annealing at 55°C for 40 s and extension at 72°C for 40 s followed by a 7-min final extension step. A 1.0-μL aliquot of each fluorescent dye-labeled PCR product was combined with 12 μL of formamide and 0.5 μL of the GENESCAN 350 [ROX] size standard (Applied Biosystems Japan Ltd.) and analyzed on an ABI PRISM 310 Genetic Analyzer using GeneScan Analysis Software (Applied Biosystems Japan Ltd.). MSI experiments were repeated twice to exclude the possibility of a false positive result due to PCR amplification artifacts in an independent PCR reaction. The sequencing results were verified by a second independently generated PCR product.
The presence of MSI was determined from the PCR amplifications of the five-microsatellite markers. Microsatellite instability was defined as the presence of novel peaks that were not found in non-neoplastic tissue (Figure 1). A tumor was defined as having high microsatellite instability (MSI-high) if more than one of the five loci analyzed showed unequivocal instabilities; a tumor was defined as having low microsatellite instability (MSI-low) if only one locus showed instability; and a tumor was defined as microsatellite stable if no microsatellite instability was found. In this study, MSI-low tumors and microsatellite-stable tumors were categorized together into one group (MSI-low/none), as proposed by recent authors[16,22].
Statistical analysis
Fisher's exact test was used to compare the frequencies of genetic alterations between the two groups. All statistical evaluations were performed using the SPSS 11.5J software package (SPSS Japan Inc., Tokyo, Japan). All tests were two-sided and a P value < 0.05 was considered statistically significant.
RESULTS
p53 mutation
Mutations of p53 at exons 5 to 8 were detected in 11 of 22 (50.0%) Japanese cases and 6 of 18 (33.3%) Hungarian cases (P = 0.348; Table 1). Among the 17 cases with p53 mutations, transversion was found in 4 of 11 Japanese cases and 1 of 6 Hungarian cases (P = 0.600). Transition at CpG sites was found in none of 11 Japanese cases and 2 of 6 Hungarian cases; the difference was marginally significant (P = 0.110).
Table 1.
Case No | Age (yr) | Sex |
Histology1 |
p53 mutation |
K-ras mutation |
Microsatellite instability | ||
Type | Grade | Exon/codon | Base change | Base change | ||||
Japanese cases | ||||||||
1 | 71 | F | PAP | G1 | None | - | None | BAT25, BAT26 |
2 | 74 | F | AD | G1 | Exon 5/codon 132 | AAG to GAG | None | BAT25, D2S123 |
3 | 62 | F | PAP | G1 | None | - | None | BAT25 |
4 | 76 | F | AD | G1 | Exon 6/codon 193 | CAT to AAT | None | BAT25, BAT26 |
5 | 78 | F | AD | G2 | Exon 5/codon 140 | ACC to ATC | None | ND |
Exon 5/codon 166 | TCA to ACA | |||||||
6 | 70 | F | AD | G1 | Exon 8/codon 276 | GCC to CCC | None | None |
7 | 71 | F | AD | G1 | None | - | None | BAT26, D2S123 |
8 | 79 | F | AD | G1 | None | - | None | None |
9 | 66 | F | PAP | G1 | None | - | None | None |
10 | 60 | F | PAP | G1 | None | - | None | None |
11 | 80 | M | PAP | G1 | None | - | None | BAT26 |
12 | 63 | M | PAP | G1 | Exon 8/codon 294 | GAG to GAA | None | BAT25, BAT26 |
13 | 49 | F | PAP | G1 | None | - | None | D2S123 |
14 | 71 | M | AD | G2 | Exon 8/codon 280 | AGA to AAA | None | BAT25, D2S123 |
15 | 70 | M | AD | G1 | Exon 7/codon 238 | TGT to CGT | None | ND |
16 | 53 | M | AD | G1 | None | - | None | None |
17 | 79 | F | AD | G3 | Exon 8/codon 271 | GAG to AAG | None | None |
18 | 62 | M | AD | G3 | Exon 6/codon 205 | TAT to TGT | None | None |
19 | 61 | M | AD | G1 | None | - | None | D17S250, D2S123 |
20 | 69 | M | AD | G2 | Exon 7/codon 231 | ACC to ATC | None | BAT25, D17S250 |
21 | 58 | F | AD | G2 | Exon 5/codon 160 | ATG to GTG | None | ND |
Exon 6/codon 220 | TAT to AAT | |||||||
22 | 76 | F | AD | G3 | None | - | None | None |
Hungarian cases | ||||||||
23 | 71 | M | AD | G2 | Exon 7/codon 249 | AGG to ACG | None | BAT26 |
24 | 69 | F | AD | G3 | Exon 6/codon 213 | CAG to CGG | None | None |
25 | 69 | F | AD | G2 | None | - | None | None |
26 | 76 | F | AD | G2 | None | - | None | None |
27 | 61 | F | AD | G3 | None | - | None | None |
28 | 58 | F | AD | G3 | None | - | None | BAT25 |
29 | 69 | F | AD | G3 | None | - | None | None |
30 | 75 | F | PAP | G1 | None | - | None | None |
31 | 66 | F | AD | G3 | None | - | None | None |
32 | 65 | F | AD | G1 | Exon 6/codon 219 | CCC to TCC | None | ND |
33 | 61 | F | AD | G3 | ND | - | None | ND |
34 | Unknown | F | PAP | G1 | Exon 5/codon 138 | GCC to GCT | None | BAT25, D17S250 |
Exon 5/codon 167 | CAG to CAA | |||||||
Exon 5/codon 170 | ACG to ACA | |||||||
35 | Unknown | F | PAP | G1 | Exon 5/codon 158 | CGC to TGC | GGT to AGT | ND |
Exon 6/codon 223 | CCT to TCT | |||||||
36 | Unknown | F | AD | G3 | Exon 6/codon 210 | AAC to AAT | None | ND |
Exon 7/codon 228 | GAC to AAC | |||||||
37 | Unknown | F | AD | G2 | ND | - | None | ND |
38 | 53 | F | AD | G3 | None | - | None | None |
39 | 72 | Unknown | AD | G1 | None | - | None | None |
40 | 69 | M | AD | G1 | None | - | None | BAT26 |
41 | 57 | F | AD | G1 | None | - | None | None |
42 | 74 | F | AD | G1 | None | - | None | BAT25 |
According to the tumor-node-metastasis (TNM) staging system[18]. PAP: Papillary carcinoma; AD: Adenocarcinoma; ND: Not detected; G1: Well differentiated; G2: Moderately differentiated; G3: Poorly differentiated.
K-ras mutation
K-ras mutations at codon 12 were detected in none of 22 Japanese cases and 1 of 20 Hungarian cases (P = 0.476) (Table 1).
MSI
Eight of 19 (42.1%) Japanese cases were MSI-high, whereas only one of 15 (6.7%) Hungarian cases was MSI-high; the difference was statistically significant (P = 0.047; Table 1).
Association between p53 mutation and MSI in gallbladder carcinoma
Both p53 mutation and MSI were analyzed successfully in 34 cases: 19 Japanese cases and 15 Hungarian cases (Table 1). When the cases were stratified into Japanese cases and Hungarian cases, p53 mutations were not associated significantly with MSI in both groups. In all 34 cases, p53 mutations were associated significantly with MSI (Table 2; P = 0.033).
Table 2.
MSI-high | MSI-low/none | P | ||
53 mutation | Present | 6 | 5 | 0.033 |
Absent | 3 | 20 |
MSI: Microsatellite instability.
DISCUSSION
Although earlier epidemiologic studies have suggested that the incidence of gallbladder carcinoma varies geographically or ethnically[9,10], there is a paucity of evidence regarding the geographic diversity of molecular changes associated with this tumor[7,8]. This prompted us to conduct the current study. In 1998, we reported that the p53 mutational spectra of gallbladder carcinoma differed considerably between Japan and Chile, both of which were known as high-incidence countries[14]. The current study first demonstrates that the process of gallbladder carcinogenesis differs in terms of p53 mutations and microsatellite instability between two distinct high-incidence areas: Japan and Hungary (a representative country of Eastern Europe).
Reported prevalences of p53 mutation for gallbladder carcinoma ranged from 31% to 70%[14,23–26], suggesting that p53 mutation plays an important role in the development of this tumor[8]. The prevalences of p53 mutation in this series (50% in Japanese cases and 33% in Hungarian cases) are comparable with the reported figures. In various malignancies, endogenous carcinogenesis is characterized by transitions at CpG sites, whereas transversions imply the presence of an exogenous mutational process[27–29]. In our previous study, the prevalence of transitions at CpG sites was significantly higher in the Chilean cases than in the Japanese cases[14]. In the current study, there was a trend toward a higher prevalence of transitions at CpG sites in the Hungarian cases. Taken together, these observations suggest that an endogenous mutational process contributed considerably to carcinogenesis of the gallbladder in the Chilean and Hungarian cases. In contrast, considering that there were no transitions at CpG sites and four transversions in the Japanese cases, it appears that exogenous mutations often happen during the process of carcinogenesis in the Japanese cases. Therefore, geographic variation might exist in carcinogenesis of the gallbladder among three distinct areas.
Reported prevalences of K-ras mutation for gallbladder carcinoma without AUPBD ranged from 0% to 17%[16,30–33], suggesting that frequency of K-ras mutation is relatively low in gallbladder carcinoma without AUPBD. This is consistent with our results: K-ras mutation was found in only one of the Hungarian cases. Taken together, most gallbladder carcinoma appears to develop from a K-ras-independent pathway.
Microsatellite instability, which represents replication errors, results from DNA mismatches due to environmental or hereditary factors and leads to genomic instability[34,35]. Reported prevalences of MSI-high for sporadic gallbladder carcinoma range from 0% to 10%[15,16,36–38], whereas the prevalence was high (42.1%) in our cases. This suggests that environmental or hereditary factors contribute to carcinogenesis of the gallbladder in some of our cases. In the current study, the prevalence of MSI-high was significantly higher in the Japanese cases than in the Hungarian cases. Considering that there were no patients with HNPCC in this series, the above finding suggests that the high prevalence of MSI-high in the Japanese cases may be due to environmental factors, which remain unknown.
There are inverse relationships between p53 mutations and MSI in colorectal cancer[39,40]. Regarding gallbladder carcinoma, earlier authors have failed to identify such relationships between p53 mutations and MSI[16,38]. In this study, p53 mutations were associated significantly with MSI in all cases. When the cases were stratified into Japanese cases and Hungarian cases, no such associations between p53 mutation and MSI were found, probably due to the small sample size. Taken together, the above observations suggest that the pathway of carcinogenesis differs between the gallbladder and the colon and rectum.
The current study has limitations. Firstly, it was a retrospective analysis of a small number of patients. Secondly, DNA preparation from paraffin-embedded tissue sections was unsuccessful in some patients. Thirdly, only limited clinical information was available in the Hungarian cases to protect the patients’ privacy. To our knowledge, however, this study demonstrates more clearly the geographic diversity of gallbladder carcinogenesis than earlier reports[15–17].
In conclusion, it appears that the p53 mutations and MSI differ in patients with gallbladder carcinoma between two distinct high-incidence areas. Exogenous mutations and unknown environmental factors may play roles in gallbladder carcinogenesis in the Japanese cases, whereas the Hungarian cases are characterized by an endogenous mutational process. Thus, geographic variation might exist in the process of gallbladder carcinogenesis.
COMMENTS
Background
Although considerable progress has been made regarding the molecular pathogenesis of human neoplasms, there is only limited information about the genetic changes involved in gallbladder carcinogenesis. Gallbladder carcinoma shows striking geographic and ethnic variation, however there is a paucity of evidence regarding the geographic diversity of molecular changes associated with this tumor.
Research frontiers
In 1998, we reported that the p53 mutational spectra of gallbladder carcinoma differed considerably between Japan and Chile, both of which were known as high-incidence countries. Only a few other investigators also have reported such geographic and ethnic differences in genetic changes of this tumor. The aim of this study was to disclose geographic differences in genetic changes involved in gallbladder carcinogenesis by comparing gallbladder carcinomas from two distinct high-incidence areas, Japan and Hungary.
Innovations and breakthroughs
The current study first demonstrates that the p53 mutations and MSI differ in patients with gallbladder carcinoma between two distinct high-incidence areas: Japan and Hungary. Exogenous mutations and unknown environmental factors may play roles in gallbladder carcinogenesis in the Japanese cases, whereas the Hungarian cases are characterized by an endogenous mutational process. Thus, geographic variation might exist in the process of gallbladder carcinogenesis.
Applications
Gallbladder carcinoma is a highly lethal disease with a poor prognosis. Therefore, it would be very beneficial to identify the molecular mechanism responsible for this condition. Advances in the understanding of the genetic changes of this tumor will help in understanding the pathogenesis of this miserable disease.
Terminology
Microsatellite instability (MSI) is caused by a failure of the DNA mismatch repair system to repair errors that occur during the replication of DNA and is characterized by the accelerated accumulation of single nucleotide mutations and alterations in the length of simple, repetitive microsatellite sequences that occur ubiquitously throughout the genome. MSI is seen in most HNPCC tumors and proportion of nonhereditary colorectal tumors. The presence of MSI in tumor tissue is associated with certain unique clinical and pathological characteristics.
Peer review
This study aimed to determine the difference of some genetic changes involved in gallbladder carcinogenesis in high-prevalence areas of Japan and Hungary. This is a well written paper and has a nice finding. While it is simply an observational study, I think it is an important observation.
Acknowledgments
We thank Dr. Hiroki Shimizu for helpful advice, and Ayako Sato, Kazue Kobayashi, and Naoyuki Yamaguchi for technical assistance.
Footnotes
S- Editor Zhu LH L- Editor Negro F E- Editor Yin DH
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