TP53 gene deletion in esophageal cancer tissues of patients and its clinical significance

  • Authors:
    • Madiniyet Niyaz
    • Abdugheni Turghun
    • Zhang Hai Ping
    • Zhang Zhu
    • Ilyar Sheyhedin
    • Cai Ren
    • Idiris Awut
  • View Affiliations

  • Published online on: November 1, 2012     https://doi.org/10.3892/mmr.2012.1162
  • Pages: 122-126
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Abstract

The aim of this study was to examine TP53 gene deletion in esophageal cancer (EC) tissues obtained from patients and to evaluate its clinical significance. Forty surgical specimens from patients with esophageal squamous cell carcinoma were examined for TP53 gene deletion using the fluorescence in situ hybridization (FISH) technique. Thirty-two male and 8 female patients were enrolled, with an average age of 56 years. TP53 gene deletion was significantly higher in poorly-differentiated EC cases compared to well-differentiated cases (P=0.028). The TP53 gene deletion rate was also significantly higher in the group with lymph node metastasis compared to the group without lymph node metastasis (P=0.0313). The TP53 gene deletion rate was shown to be correlated with the level of differentiation and lymph node metastasis in EC; it may therefore be an important molecular marker for evaluating the condition of EC in patients.

Introduction

Esophageal cancer (EC) is one of the most common gastrointestinal cancers in the world and there is a clear regional and ethnic difference in terms of its incidence rate and etiology factors (1). The incidence of EC has been as high as 68.88/100,000 among the Kazakhs living in the Xinjiang Uyghur Autonomous Region (Northwest region of China). In China, the histopathological type of EC is different from that found in Europe and America and majority of cases are squamous cell carcinomas. EC is related to the activation of multiple genes and is a multi-step process. Oncogene activation and tumor suppressor gene inactivation are the basis for the development of molecular genetics. Currently, the p53 gene is the most important tumor suppressor gene and is located on human chromosome 17p13.1, which regulates the cell cycle and induces cell apoptosis (2,3).

Fluorescence in situ hybridization (FISH) is a cytogenetic technique that has gradually developed in recent years, involving the use of fluorescent labeled DNA probes to detect cell changes within the chromosome (4). Several studies have demonstrated that p53 gene deletion is important in the development and progression of EC (57). However, reports on the p53 gene deletion associated with Xinjiang Kazakh EC patients are absent.

In this study, we used FISH to detect TP53 gene deletion in 40 esophageal carcinoma cases in Kazakh patients, in order to analyze its clinical significance in evaluating patients’ prognosis based on molecular pathology.

Patients and methods

From October 2010 to December 2011, 40 Kazakh EC patients were admitted to the Department of Thoracic Surgery, First Affiliated Hospital of Xinjiang Medical University, and underwent surgical resection. There were 32 male and 8 female patients, with an average age of 56 years (ranging from 31 to 82). None of the patients had received any preoperative radiotherapy, chemotherapy or other special treatment.

Pathological diagnosis confirmed esophageal squamous cell carcinoma in 40 cases post-operatively, including well-differentiated tumors in 14 cases, moderately differentiated tumors in 12 cases and poorly differentiated tumors in 14 cases (Table I). Ten samples of normal esophageal tissues (>5 cm from the tumor) were collected as normal controls. Informed consent was obtained from all patients.

Table I

Results of p53 and CEP17 by FISH.

Table I

Results of p53 and CEP17 by FISH.

Copy no.

CaseAge (years)Gender0
p53/CEP17
1
p53/CEP17
2
p53/CEP17
3
p53/CEP17
4
p53/CEP17
FISH
153M3/035/060/262/340/40Deletion
265M4/033/040/3015/458/25Deletion
345M5/023/058/5413/281/18Normal
454F1/021/051/6221/306/8Normal
550M3/035/056/794/112/10Deletion
651F0/025/074/771/120/11Normal
741M4/021/069/725/151/13Normal
863M5/011/084/680/180/14Normal
946M0/018/076/716/210/8Normal
1056M9/036/053/462/390/15Deletion
1168M10/040/049/671/190/14Deletion
1263M14/044/033/519/410/8Deletion
1366M4/010/063/4816/217/8Normal
1471M5/042/150/483/360/15Deletion
1544M3/030/060/694/293/2Deletion
1663M5/040/049/516/280/21Deletion
1771M7/044/048/681/200/12Deletion
1852M10/031/041/5213/155/33Deletion
1945M11/045/039/615/300/9Deletion
2070M0/019/058/6614/319/3Normal
2152F3/025/045/5920/287/13Normal
2237F2/024/069/604/241/16Normal
2356M5/036/041/5016/342/16Deletion
2456M2/039/054/603/212/19Deletion
2560F2/038/035/4625/390/15Deletion
2664F3/040/042/4115/530/6Deletion
2754F4/041/033/5222/200/28Deletion
2866M4/035/041/5620/300/14Deletion
2951M3/030/050/6710/237/10Deletion
3045M5/023/058/4913/301/21Normal
3158M3/044/150/452/411/13Deletion
3270M0/040/055/425/360/22Deletion
3364F4/020/063/4912/321/19Normal
3450M1/028/047/5022/342/16Normal
3562M0/025/068/706/171/13Normal
3652M3/033/058/626/360/2Deletion
3750M3/021/070/706/220/8Normal
3848M4/019/058/5115/394/10Normal
3960M5/021/074/600/260/14Normal
4060M3/020/057/5020/370/13Normal

[i] CEP17, centromere of chromosome 17; FISH, fluorescence in situ hybridization.

Touch preparations of cells were made on glass slides from fresh specimens and air-dried overnight at room temperature and then stored at −80°C ready for FISH. The same specimens were stained with hematoxylin and eosin (H&E) for pathological evaluation. FISH detection was followed by Nakamura’s improved Vysis protocol (8). Direct fluorochrome-labeled centromeric probes were used for enumeration of different chromosomes. Spectrum orange-labeled and spectrum green-labeled probes for the TP53 and centromere of chromosome 17 (CEP17) were purchased from the manufacturer (Vysis, Inc., Downers Grove, IL, USA).

Cells were denatured with 70% formamide and then washed twice in standard saline citrate (SSC) at 74°C and at room temperature, respectively, for 2 min in a water bath. The slides were then dehydrated through a graded ethanol series (70, 85 and 100%, each for 2 min). We then applied 10 μl of hybridization solution containing 1 μl of each of the DNA probes, 7 μl of hybridization buffer and 1 μl of double distilled water. This was covered with a cover slip and sealed with rubber cement. Following incubation for 16 h at 42°C in a humidity-controlled chamber, the slides were washed with an SSC solution for 5 min at 74°C and at room temperature for 2 min. Then 5 μl diamidinophenylindole (DAPI, II) was applied to each spot and covered with a cover slip. The slides were observed under a fluorescence microscope that was connected to a cooled charge-coupled device camera. According to the kit instructions, under a fluorescence microscope, a special image acquisition and analysis system (Leica Microsystems, Ltd., Germany) was used for the signal count. In total, 100 nuclei were observed to obtain the number of p53 gene signals, such as 1 or 0; when nucleus fluorescence was >30%, we determined p53 gene deletion.

Microsoft Social Sciences 15.0 software (SPSS software, Chicago, IL, USA) was used for statistical analysis. The corrected χ2 test or the Scheffe method were used for univariate analysis of data from each group. P<0.05 was considered to indicate a statistically significant difference.

Results

Orange (TP53) and green (CEP17) fluorescence signals were detected in all EC specimens. CEP17 hybridization signals were larger and brighter than TP53 gene signals. The representative FISH models included: normal, 2 intranuclear orange signals and 2 intranuclear green signals; partial deletion, ≥2 intranuclear green signals and 1 intranuclear orange signal; complete deletion, ≥2 intranuclear green signals and 0 orange signals (Fig. 1). Table I shows the TP53 gene deletion in the 40 esophageal carcinoma cases.

Table II shows the correlation between clinicopathological factors and TP53 deletion. Statistical analysis indicated that there were no significant correlations among TP53 gene deletion rate, age and gender (P>0.05). TP53 gene deletion rates were 28% (4/14) and 78% (11/14) in well-differentiated and poorly-differentiated EC, respectively (P=0.028). TP53 gene deletion rates were 38% (7/18) and 72% (16/22) in the lymph node metastasis and no lymph node metastasis groups, respectively (P=0.0313). A high frequency of CEP17 hyperdisomy was detected.

Table II

Correlation between p53 gene deletion and clinicopathological factors.

Table II

Correlation between p53 gene deletion and clinicopathological factors.

Clinicopathological parametersCasep53 deletionP-value
Age (years)
 <501130.0695
 ≥502919
Gender
 Male32190.4745
 Female83
Differentiation
 Well-differentiated1440.028
 Moderately differentiated127
 Poorly differentiated1411
Lymph node metastasis
 No metastasis1870.0313
 Metastasis2216

Discussion

The causes of EC are complicated. At present, EC is considered as a multi-factor, polygenic variant, multi-staged disease. The variation of correlated proto-oncogenes and tumor suppressor genes is the key to tumorigenesis and development. Deletion of the tumor suppressor gene is the major mode of variation (9).

The p53 gene is currently thought to be the most important tumor suppressor gene and more than 50% of tumors are associated with its abnormality. p53 genetic mutation is important in the development of EC. Studies have indicated that patients with p53 genetic mutation had poorer prognosis and greater malignancy (10,11). Multiple studies have proven that p53 genetic mutation is an independent and reliable biological parameter for evaluating the disease prognosis (12,13). Due to p53 gene deletion or abnormality, cells with injured DNA enter into S stage, resulting in changes to hereditary characteristics, chromosomal aberration and, ultimately, carcinomatous change.

FISH is a technique using fluorescently labeled single-chain nucleotide DNA probes, based on the base complementarity principle, to form double-stranded nucleic acid with complementary single chain nucleotides by specific binding, and to detect cell chromosome changes and definite gene copy number changes in order to diagnose malignant cells. FISH is capable of detecting all types of cytogenetic changes, including aneusomy, amplification and deletion. Recently, FISH has been used in the diagnosis of hematologic malignancy, lung, breast and renal cancer, and it is a technique with high sensitivity and specificity (4,1417).

In the past, there were limitations in the detection of mutant p53 protein by immunohistochemical methods since viral infection and stress may also produce p53 protein aggregation, and therefore samples may have contained both mutant and wild-type variants. Several studies found that the p53 protein positive rate was lower than that observed using PCR-SSCP detection, which indicates that p53 mutation or abnormality in the malignant tumor is much higher than that shown by immunohistochemisty detection in real situations (18). The sensitivity of FISH is similar to isotope hybridization in situ, but the space resolution and gene mapping accuracy is higher; therefore, FISH plays a significant role in tumor studies (8,18,19).

In this study, FISH was applied using double-color DNA probes (fluorescent orange-labeled LSI TP53 probe and fluorescent green-labeled CEP17 probe) to detect TP53 gene deletion in Kazakh esophageal squamous cell cancer patients (7,20).

In the normal controls, in over 90% of nuclei, CEP17 and TP53 genes displayed 2 signals, indicating that FISH was successful in our study (data not shown). Among 40 EC cases, the mean TP53 gene deletion rate was 55% (22/40), and 28% (4/14), 58% (7/12) and 78% (11/14) in well-differentiated, moderately differentiated and poorly differentiated cases, respectively. This indicates that the TP53 gene deletion rate is correlated with the level of differentiation; the higher the differentiation, the higher the TP53 deletion rate. Moreover, the TP53 gene deletion rate also correlated with lymph node metastasis (P=0.0313). Similar studies support our results (21,22).

Our study used FISH to detect the TP53 gene in Kazakh patients with EC, and the results show for the first time that the TP53 gene deletion rate is correlated with the level of differentiation and lymph node metastasis in ECs, and may be an important molecular biological marker for evaluating the condition of ECs in Kazakh patients. Further study on the post-operative life span of these patients is required to confirm the correlation of TP53 gene deletion and EC prognosis.

Acknowledgements

This study was funded by the Xinjiang Uyghur Autonomous Region Key Discipline and Specialties Foundation (2010-09), and the First Affiliated Hospital of Xinjiang Medical Univeristy Research Award Foundation (2012-YFY-27). Special thanks to the Department of Hematology of the First Affiliated Hospital of Xinjiang Medical University for technical support.

Abbreviations:

FISH

fluorescence in situ hybridization

EC

esophageal cancer

CEP17

centromere of chromosome 17

SSC

standard saline citrate

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Spandidos Publications style
Niyaz M, Turghun A, Ping ZH, Zhu Z, Sheyhedin I, Ren C and Awut I: TP53 gene deletion in esophageal cancer tissues of patients and its clinical significance. Mol Med Rep 7: 122-126, 2013.
APA
Niyaz, M., Turghun, A., Ping, Z.H., Zhu, Z., Sheyhedin, I., Ren, C., & Awut, I. (2013). TP53 gene deletion in esophageal cancer tissues of patients and its clinical significance. Molecular Medicine Reports, 7, 122-126. https://doi.org/10.3892/mmr.2012.1162
MLA
Niyaz, M., Turghun, A., Ping, Z. H., Zhu, Z., Sheyhedin, I., Ren, C., Awut, I."TP53 gene deletion in esophageal cancer tissues of patients and its clinical significance". Molecular Medicine Reports 7.1 (2013): 122-126.
Chicago
Niyaz, M., Turghun, A., Ping, Z. H., Zhu, Z., Sheyhedin, I., Ren, C., Awut, I."TP53 gene deletion in esophageal cancer tissues of patients and its clinical significance". Molecular Medicine Reports 7, no. 1 (2013): 122-126. https://doi.org/10.3892/mmr.2012.1162