• 復(fù)旦大學(xué)附屬中山醫(yī)院、肝癌研究所(上海200032);

目的  在全基因組范圍內(nèi)篩選肝細(xì)胞癌候選診斷指標(biāo)。
方法  采用基因芯片技術(shù)比較40例肝細(xì)胞癌腫瘤標(biāo)本及其鄰近無瘤肝組織之間基因表達(dá)譜的差異,尋找與肝細(xì)胞癌發(fā)生、發(fā)展相關(guān)的基因。基因芯片由美國國立衛(wèi)生院癌癥研究所制定,每張芯片有9 984個點,含9 180個基因?;蛐酒瑢嶒灢捎秒p色熒光直接標(biāo)記法,每例患者的肝細(xì)胞癌組織總RNA 200 μg用綠色熒光素Cy5-dUTP標(biāo)記,其相應(yīng)的無瘤肝組織總RNA 100 μg用紅色熒光素Cy3-dUTP標(biāo)記?;旌虾笈c芯片上的基因進(jìn)行雜交。對基因芯片資料進(jìn)行統(tǒng)計分析以尋找肝細(xì)胞癌組織與無瘤肝組織之間表達(dá)有差異的基因。
結(jié)果  用非先導(dǎo)分層聚類分析法進(jìn)行篩選,發(fā)現(xiàn)有10個基因在80%以上的肝細(xì)胞癌組織中的表達(dá)水平明顯高于(2倍或2倍以上)其相應(yīng)的無瘤肝組織,包括ESTs、Homo sapiens cDNA FLJ、原鈣粘連素-α 9(protocadherinalpha 9)、KPNA2、RPS20、SNRPE、CDKN2A、UBD、MDK和ANXA2基因。這些基因與多種腫瘤相關(guān),他們可能在肝細(xì)胞癌發(fā)生、發(fā)展過程中也發(fā)揮非常重要的作用。
結(jié)論  進(jìn)一步研究這些基因的功能可能篩選出新的肝細(xì)胞癌診斷指標(biāo)。

引用本文: 邢戌健,賈戶亮,張磊,葉青海. 基因芯片技術(shù)在肝細(xì)胞癌候選診斷指標(biāo)篩選中的應(yīng)用. 中國普外基礎(chǔ)與臨床雜志, 2007, 14(1): 23-27. doi: 復(fù)制

版權(quán)信息: ?四川大學(xué)華西醫(yī)院華西期刊社《中國普外基礎(chǔ)與臨床雜志》版權(quán)所有,未經(jīng)授權(quán)不得轉(zhuǎn)載、改編

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  2. 2.  Zhou XD, Tang ZY, Yang BH, et al. Experience of 1 000 patients who underwent hepatectomy for small hepatocellular carcinoma [J]. Cancer, 2001; 91(8)∶1479.
  3. 3.  Taketa K. Alpha-fetoprotein: reevaluation in hepatology [J]. Hepatology, 1990; 12(6)∶1420.
  4. 4.  Mackay A, Jones C, Dexter T, et al. cDNA microarray analysis of genes associated with ERBB2 (HER2/neu) overexpression in human mammary luminal epithelial cells [J]. Oncogene, 2003; 22(17)∶2680.
  5. 5.  Taniwaki M, Daigo Y, Ishikawa N, et al. Gene expression profiles of small-cell lung cancers: molecular signatures of lung cancer [J]. Int J Oncol, 2006; 29(3)∶567.
  6. 6.  Welsh JB, Zarrinkar PP, Sapinoso LM, et al. Analysis of gene expression profiles in normal and neoplastic ovarian tissue samples identifies candidate molecular markers of epithelial ovarian cancer [J]. Proc Natl Acad Sci USA, 2001; 98(3)∶1176.
  7. 7.  Young AN, Amin MB, Moreno CS, et al. Expression profiling of renal epithelial neoplasms: a method for tumor classification and discovery of diagnostic molecular markers [J]. Am J Pathol, 2001; 158(5)∶1639.
  8. 8.  Hegde P, Qi R, Gaspard R, et al. Identification of tumor ma-rkers in models of human colorectal cancer using a 19,200-element complementary DNA microarray [J]. Cancer Res, 2001; 61(21)∶7792.
  9. 9.  Iacobuzio-Donahue CA, Maitra A, Shen-Ong GL, et al. Disc-overy of novel tumor markers of pancreatic cancer using global gene expression technology [J]. Am J Pathol, 2002; 160(4)∶1239.
  10. 10.  Xiao SY, Wang HL, Hart J, et al. cDNA arrays and immunohistochemistry identification of CD10/CALLA expression in hepatocellular carcinoma [J]. Am J Pathol, 2001; 159(4)∶1415.
  11. 11.  Pergolizzi JV Jr, Auster M, Conaway GL, et al. Cryosurgery for unresectable primary hepatocellular carcinoma: a case report and review of literature [J]. Am Surg, 1999; 65(5)∶402.
  12. 12.  Nobata S, Shinozawa T, Sakanishi A. Truncated midkine induces transformation of cultured cells and short latency of tumorigenesis in nude mice [J]. Cancer Lett, 2005; 219(1)∶83.
  13. 13.  Koide N, Hada H, Shinji T, et al. Expression of the midkine gene in human hepatocellular carcinomas [J]. Hepatogastroenterology, 1999; 46(30)∶3189.
  14. 14.  Ikematsu S, Yano A, Aridome K, et al. Serum midkine levels are increased in patients with various types of carcinomas [J]. Br J Cancer, 2000; 83(6)∶701.
  15. 15.  Ikematsu S, Okamoto K, Yoshida Y, et al. High levels of urinary midkine in various cancer patients [J]. Biochem Biophys Res Commun, 2003; 306(2)∶329.
  16. 16.  Filipenko NR, MacLeod TJ, Yoon CS, et al. Annexin A2 is a novel RNA-binding protein [J]. J Biol Chem, 2004; 279(10)∶8723.
  17. 17.  Laumonnier Y, Syrovets T, Burysek L, et al. Identification of the annexin A2 heterotetramer as a receptor for the plasmin-induced signaling in human peripheral monocytes [J]. Blood, 2006; 107(8)∶3342.
  18. 18.  Gillette JM, Chan DC, Nielsen-Preiss SM. Annexin 2 expression is reduced in human osteosarcoma metastases [J]. J Cell Biochem, 2004; 92(4)∶820.
  19. 19.  Tatenhorst L, Rescher U, Gerke V, et al. Knockdown of annexin 2 decreases migration of human glioma cells in vitro [J]. Neuropathol Appl Neurobiol, 2006; 32(3)∶271.
  20. 20.  Yoon SY, Kim JM, Oh JH, et al. Gene expression profiling of human HBV- and/or HCV-associated hepatocellular carcinoma cells using expressed sequence tags [J]. Int J Oncol, 2006; 29(2)∶315.
  21. 21.  Dorr SN, Schlicker MN, Hansmann IN. Genomic structure of karyopherin alpha 2 (KPNA2) within a low-copy repeat on chromosome 17q23-q24 and mutation analysis in patients with Russell-Silver syndrome [J]. Hum Genet, 2001; 109(5)∶479.
  22. 22.  Teng SC, Wu KJ, Tseng SF, et al. Importin KPNA2, NBS1, DNA Repair and Tumorigenesis [J]. J Mol Histol, 2006; [Epub ahead of print].
  23. 23.  Dahl E, Kristiansen G, Gottlob K, et al. Molecular profiling of laser-microdissected matched tumor and normal breast tissue identifies karyopherin alpha 2 as a potential novel prognostic marker in breast cancer [J]. Clin Cancer Res, 2006; 12(13)∶3950.
  24. 24.  Winnepenninckx V, Lazar V, Michiels S, et al. Gene expression profiling of primary cutaneous melanoma and clinical outcome [J]. J Natl Cancer Inst, 2006; 98(7)∶472.