电压门控性氯离子通道ClC-2对非小细胞肺癌的作用及表达意义

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英文题名：The Role of Voltage-gated Chloirde Channel ClC-2on Non-small-cell Lung Cancer and Significance of the Expression of ClC-2 作者：许哲男 论文级别：硕士 学科专业名称：胸外科学 中文关键词：ClC-2 ; 非小细胞肺癌 ; 半定RT-PCR ; Westernblot ; 免疫化学 英文关键词：clc-2 ; non-small-cell lung cancer ; semi-quantitative RT-PCR ; Western blot 英文关键词：immunochemistry 学位年度：2012 导师：韩振国 学科代码：100210 学位授予单位：吉林大学 论文提交日期：2012-05-01

摘要

目的：通过观察肺癌发生、侵袭及转移时氯通道ClC-2在人非小细胞肺癌中的表达情况，探讨ClC-2在非小细胞肺癌中的表达及临床意义
     方法：实验分为对照组(癌旁正常肺组织)和实验组(肺良性病组、肺鳞癌组和肺腺癌组),应用半定量RT-PCR及Westernblot，免疫组化等方法检测各组ClC-2mRNA、ClC-2蛋白表达水平及观察ClC-2在细胞及组织中的表达和分布差异。并对ClC-2在非小细胞肺癌中的表达情况进行初步分析。
     结果：每实验组中ClC-2mRNA和ClC-2蛋白均一定的表达。基因产物ClC-2mRNA表达水平上与对照组及肺良性病组相比，非小细胞肺癌组的ClC-2mRNA表达量明显增多，肺良性病组比对照组略表达增多。ClC-2蛋白表达量在非小细胞肺癌及肺良性病组均比对照组表达增多。通过免疫组织化学法也证实ClC-2在非小细胞肺癌中广泛、大量地分布。
     结论：三种实验方法均证实了ClC-2在非小细胞肺癌中过表达。提示ClC-2作为电压门控性性离子通道，通过各种机制在临床肺癌发生、侵袭及转移，肺部疾病发生过程中起重要作用。ClC-2可能成为临床治疗非小细胞肺癌的新分子靶点，深入研究ClC-2与肺癌发生、发展关系中提供新的思路。
Objective:
     To investigate the role of voltage-gated chloride channel clc-2on non-small-cell lung cancer and the significance of the expression of it, we examine the gene expression of chloride channel clc-2in human non-small-cell lung cancer during occurrence, invasion and metastasis.
     Materials and Methods:
     Samples involved in this research were divided into four groups. They are:①Pulmonary adenocarcinoma;②squamous lung carcinomas;③Pulmonary tuberculosis;④ormal lung tissue besides lung cancer. The groups of non-small-cell lung cancer and benign pulmonary diseases are the experimental groups. The group of normal lung tissue beside lung cancer is the control group. In each experiment, group①and group②comply with the same principles of gender, pathological T staging and the degree of differentiation. The rest groups were selected at random for the comparison and analysis within those groups. From the results of semi-quantitative RT-PCR, Western blot and immunohistochemistry analysis, the expressions of clc-2mRNA and clc-2protein was determined, and difference in the the expression and distribution of clc-2among different kinds of cells and tissues were also assessed. Furthermore, we preliminary analysed the expression of clc-2in non-small-cell lung cancer cells. The48cases of pathological materials applied in this research were collected from freshly frozen tissues stored after surgical resection(2009.05-2010.08) from tissue library of Bethune no.3hospital in Jilin University. These cases have clearly postoperative pathologic diagnosis. The patients who provided specimens didn't undergo preoperative systemic anticancer therapies such as radiotherapy and chemotherapy.
     Results:
     The mRNA level of clc-2in non-small-cell lung cancer cells:The result of RT-PCR detection showed that both referencing GAPDH gene band and clc-2gene were observed among all these tissue groups. The mRNA is reversely transcribed to cDNA with primers which have clc-2specific activity. Then PCR was carried out. The result indicates that an obvious specific fragment with length of250-500bp can be seen in group①and group②while the fragments shown in group③and group④is weak. Then we got the relative content by calculating the ratio of the content of the product of target gene in samples and GAPDH. It shows that the clc-2expression in non-small-cell lung cancer groups dramatically increases compared with other groups.
     The expression of clc-2protein in non-small-cell lung cancer cells:From Westernblot, a referencing P-Actin and an obviously specific clc-2protein band at98KD were both observed among all the tissue groups. The expression of clc-2protein in group①,②and③are higher than group④. Among the3groups, the expression of group②was highest and the difference between expression level in group①and in group③was statistically insignificant. Furthermore, the expression of clc-2protein in group④is fewer than experimental group. There is a certain degree of expression of chloride channel clc-2in each group.
     Immunohistochemistry analysis and the difference in the expression and distribution of clc-2protein:The immunohistochemistry analysis indicates that clc-2protein in group①and②were over-expressed, while that in group③and④were comparatively lower. The expression of clc-2in non-small-cell lung cancer cells of group②is distinctly higher than that in group①.
     The data mentioned above all confirm that clc-2is over-expressed in non-small-cell lung cancer cells. This reveals that clc-2plays an important role in the process of occurrence, invasion and metastasis of clinical lung cancer and the development of pulmonary disease as a voltage-gated ion channel through various mechanisms, clc-2may be a new molecular target for the clinical treatment of non-small-cell lung cancer, and it may provide the new approach to further study the association of clc-2with the pathogenesis and development issues that involved in lung cancer.
     Conclusion:
     The expression of clc-2mRNA, the genetic derivative of clc-2protein, in the non-small-cell lung cancer cells was significantly higher than that in normal lung tissues and tissues with benign pulmonary diseases.
     The expression of clc-2protein is higher in tissues with benign pulmonary diseases and malignancies than normal lung tissues. The results show that the expression of clc-2protein in squamous lung carcinomas is highest while difference between the pulmonary adenocarcinoma group and the group with benign pulmonary diseases was statistically insignificant.
     The immunohistochemistry analysis reveals that clc-2is widely distributed in non-small-cell lung cancer cells in a great amount. While only a few can be found in the group with benign pulmonary diseases and normal lung tissues. Furthermore, it is indicated that the expression of clc-2protein in squamous carcinomas group is higher than that in adenocarcinoma group.
     Taken together, these data suggest that chloride channel2(clc-2) plays a regulatory role as a voltage-gated ion channel in the process of occurrence, invasion and metastasis of non-small-cell lung cancer from gene and protein levels.

引文

[1]陈万青,张思维,邹小农.中国肺癌发病死亡的估计和流行趋势研究[J],中国肺癌杂志,2010,5(5)：488-493.[2]Parkin DM,Bray F,Ferlay J,et al.Global Cancer Statistics2002[J].CA Cancer JClin,2005,55(2):74-108.[3]Hatta S, Sakamoto J, Horio Y. Ion channels and diseases. Med El ectron Microse.2002,35:117-126.[4]Heyneman LE,Herndon JE,Goodman PC,et al.Stage distribution in parients with a small (<3cm) primary nonsmall cell caicinoma:implication for lung carcinoma screening[J].Cancer,2001;92:3051-3055[5]徐昌文,吴善芳,孙燕.肺癌.第2版.上海科学技术出版社.1993.61[6]Shah A, Swain WA, Richardson D, et al. Phospho-akt expression is associated with a favorable outcome in non small cell lung cancer[J]. Clin Cancer Res.2005Apr15;11(8):2930-2936.[7]Jentsch TJ, St einmeyer K, Schwarz G. Primary s true ture of Torpedo-marmorata chloride channel is olated by e xpression cloning in Xenopus-oocytes[J]. Nature,1990,34810514.[8]Nilius B et al. Amazing chloride channels:an overview. ActaPhysiol Scand,2003,177:119-147[9]Cassel Met al. Confronting fusion protein-based membraneprotein topology mapping with reality:the Escherichia coliClcA H+/C-exchange transporter. J Mol Biol,2008,381:860-866[10]Dutzler R. A structural perspective on C1C channel andtransporter function. FEBS,2007,581:2839-2844.[11]Dutzler R.The structural basis of C1C chloride channel function.Trends Neurosci,2004,27:315-320[12]Dutzler R et al. X-ray structure of a C1C chloride channel at3.0Areveals??the molecular basis of anion selectivity. Nature,2002,415:287-294[13]MINDELL J A, MADUKE M, MILLER C, et al. Project-ion structure of a C1C-type chloride channel at6.5Aresolution [J]. Nature,2001,409:219-223.2[14]NIEMEYER MI, YUSEF Y R, CORNEJO I, et al. Fun-ctional evaluation of human CLC-2chloride channel mu-tations associated with idiopathic generalized epilepsies [J]. Physiol Genomics,2004,19(1):74-83.[15]Zifarelli G et al. Intracellular regulation of human C1C-5byadenine nucleotides. EMBO,2009,10:1111-1116[16]Meyer S et al. Nucleotide recognition by the cytoplasmicdomain of the human chloride transporter C1C-5. Nat StructMol Biol,2007,14:60-67[17]SCHMIDT-ROSE T, JENTSCH T J. Transminbrane top-ology of a C1C chloride channel [J]. Proc Natl Acad SciUSA,1997,94(14):7633-7638.[18]Jentsch TJ et al. Molecular structure and physiological functionof chloride channels. Physiol Rev,2002,82:503-568[19]Zuniga L, et al. The voltage-dependent C1C-2chloride channelhas a dual gating mechanism. J Physiol,2004,555:671-682[20]郭晓强.ClC型氯离子通道.生理科学进展,2005,36：58-60[21]Estevez Ret al. Conservation of chloride channel structurerevealed by an inhibitor binding site in C1C-1. Neuron,2003,38:47-59[22]Lang F, FE llerM, Lang KS, et al. I on channels in cell prolifera-tion and apoptotic cell death[J]. J Membr Bi ol,2005,205(3):1472157.[23]Guan YY, Wang GL, Zhou JG. The C1C-3Cl-channel in cell vol-ume regulation, proliferation and apop tosis in vascular smooth mus-cle cells[J]. Trends Pharmacol Sci,2006,27(6):2902296.[24]Dai YP, Bongal on S, Hatton WJ, et al. C1C-3chl oride channel is up??regulated by hypertr ophy and inflammation in rat and canine pul-monary artery[J]. Br J Pharmacol,2005,145(1):5214.[25]Wang LW, Chen LX, Jacob T. CLC-3exp ression in the cell cycleof nas opharyngeal carcinoma cells [J]. Acta Physiol ogica Sinica,2004,56(2):2302236.[26]OlsenML, Schade S, Lyons SA, et al. Expression of voltage-gatedchloride channels in human gli oma cells[J]. J Neurosci,2003,23(13):557225582.[27]LiM, Wang B, LinW. Cl-channel blockers inhibit cell prolifera-tion and arrest the cell cycle of human ovarian cancer cells [J].Eur J Gynaecol Oncol,2008,29(3):2672271.[28]J iang B, Hatt ori N, Liu B, et al. Suppression of cell proliferationwith inducti on of p21by Cl(-) channel bl ockers in human leuke-mic cells[J]. Eur J Pharmacol,2004,488(123):27234.[29]Zhang HN, Zhou JG, Qiu QY, et al. C1C-3chloride channel pre-vents apop tosis induced by thap sigargin in PC12cells[J]. Apop to-sis,2006,11(3):3272336.[30]LemonnierL, Shuba Y, Crep in A, et al. Bcl-2-dependentmodula-tion of s welling-activated Cl-current and C1C-3exp ression in hu-man prostate cancer ep ithelial cells [J]. Cancer Res,2004,64(14):484124848.[31]Cuddapah VA, Sontheimer H. Molecular interaction and functi onalregulation of C1C-3by Ca2+/calmodulin-dependent protein kinaseⅡ (CaMKⅡ) in human malignant glioma[J]. J Biol Chem,2010,285(15)11188211196.[32]LiM, Wang Q, LinW et al. Regulati on of ovarian cancer cell ad-hesion and invasion by chloride channels [J]. Int J GynecolCancer,2009,19(4):5262530.[33]Mao J, Chen L, Xu B, et al. Supp ressi on of C1C-3channel ex-pression??reduces migration of nasopharyngeal carcinoma cells[J].Biochem Pharmacol,2008,75(9):170621716.[34]Weylandt KH, NebrigM, Jansen-Rosseck N, et al. C1C-3exp res-sion enhances etoposide resistance by increasing acidification of thelate endocytic compart ment[J]. Mol Cancer Ther,2007,6(3):9792986.[35]YuWF, Zhao YL, Wang K, et al. Inhibition of cell proliferationand arrest of cell cycle progression by blocking chloride channels inhuman laryngeal cancer cell line Hep-2[J]. Neop lasma,2009,56(3):2242229.[36]Tang YB, Liu YJ, Zhou JG, et al. Silence of C1C-3chloride chan-nel inhibits cell proliferation and the cell cycle via G/S phase arrestin rat basilar arterial smooth muscle cells[J]. Cell Prolif,2008,41(5):7752785.[37]Jentsch TJ. CLC chloride channels and transporters from genes to protein structure, pathology and physiology [J]. Crit Rev Biochem Mol Biol,2008,43(1):3-36.[38]Cheng G,Ramanathan A,Shao Z,et al Chloride channel expres-sion and functional diversity in the immune cells of allergic diseases[J]. CurrMo-1Med,2008,8(5):401-407.[39]Sontheimer H.An unexpected role for ion channels in brain tumor-metastasis [J].Exp Biol Med (Maywood),2008,233(7):779-791.[40]Kunzelmanm K Ion channels and cancer[J]. J Membr Biol,2005,205(3):159-173.[41]T.FURUKAWA T,OGURA Y J,ZHENG H,et al.Phosphorylation and functional regulation of CIC-2chloride channels expressed in Xenopus oocytes by Mcyclin-dep-endent protein kinase [J]. J Physiol,2002,540:883-893.[42]陈丽新,王立伟,Tin JacobC1在鼻咽癌细胞调节性容积回缩中的作用[J].中国病理生理杂志,200218(5)：490-493