Medical Diagnosis 医学诊断, 2016, 6(4), 89-93 Published Online December 2016 in Hans. /journal/md /10.12677/md.2016.64016
文章引用: 刘博, 王智, 刘一雄, 范林妮. 不同肿瘤染体的扩增分析[J]. 医学诊断, 2016, 6(4): 89-93. The Analysis of Chromosome Amplification in Different Tumors
Bo Liu 1*, Zhi Wang 1, Yixiong Liu 2#, Linni Fan 2#
1
Seventh Company, Second Battalion, First Brigade, The Fourth Military Medical University, Xi’an Shaanxi 2School of Basic Medical Sciences, The Fourth Military Medical University, Xi’an Shaanxi
Received: Dec. 2nd , 2016; accepted: Dec. 20th , 2016; published: Dec. 23rd , 2016
Copyright © 2016 by authors and Hans Publishers Inc. This work is licensed under the Creative Commons Attribution International License (CC BY).
/licenses/by/4.0/
Abstract
As more and more scientific research scholars focus on the tumor gene, the relationship between chromosome amplification and malignant tumors has been revealed and validated. By discussing the chromosome variation in different malignant tumors, this paper reveals the rule of common chromosome mutations, concisely provides the new detection methods and clinical therapeutic targets and helps the application of new technologies and drugs. Keywords
Chromosome, Tumors, Amplification
不同肿瘤染体的扩增分析
刘 博1*,王 智1,刘一雄2#,范林妮2#湛江师范学院附属中学
1
第四军医大学,一旅二营七连,陕西 西安 2第四军医大学基础部,陕西 西安
收稿日期:2016年12月2日;录用日期:2016年12月20日;发布日期:2016年12月23日
太阳能浴室*第一作者。
#通讯作者。
刘博等
摘要
随着越来越多的科研学者将肿瘤关注的重点投入到基因方面,染体扩增与恶性肿瘤的关系不断被揭示和验证。本文通过探讨不同恶性肿瘤中染体变异情况,揭示了常见染体突变的规律,同时简洁地为临床上新的检测方法和靶点提供了依据。有助于新技术和新药物的应用开展。
关键词
染体,肿瘤,扩增
1. 引言
近年来我国有越来越多的学者将精力投入到肿瘤研究上,在流行病、病因、基础、诊断与等方面的研究均取得了可喜的成绩。特别是在基因水平上进行了深入的研究。大量文献表明肿瘤的发生与癌基因激活和抑癌基因失活有密切关系。而染体拷贝数变异在肿瘤的发生发展过程中起到了一个重要事件。染体扩增可导致癌基因表达上调,而染体缺失可导致抑癌基因表达缺失。DNA异倍体是染体异常的表型,也是细胞癌变的特征指标,与恶性肿瘤的异常增殖相关[1],一般来说在染体水平鉴定循环肿瘤细胞(CTC)更为客观及准确。不同实体瘤存在不同的染体异常情况,具体分析说明如下:
2. 乳腺癌2013年5月10日
乳腺癌患者中8号及17号染体异常表达情况较为普遍,阳性率较高[2] [4],并且同位于其上的c-myc/HER2/TOP2A等基因及乳腺癌Ki67/ER/病理分型等临床指标密切相关[3],针对8/17号染体倍体 情况的分析,可以给予乳腺癌临床诊治判断提供有效的依据。
例如8号染体的异常表达是浸润性导管癌的不良预后相关[4]。而在17号染体的倍体分析中,与病理分级/ER表达/Nottingham指数等多种不良预后预测因子显著相关[3] [5] [6]。在方面,多中心临床试验证实在CEP17多体情况下CEF方案组患者获益明显强于CMF组[7]。对于TOP2A基因调控的蒽环类药物方面,CEP17多体情况下同蒽环类药敏性可获得提升[3] [8]。在靶向预测方面,在IHC 方法HER 3+情况下,CEP17非多体的患者对于单纯靶向方案不敏。
3. 肺癌
肺癌患者中8号染体异常表达情况较为普遍,呈现较高比例的非整倍体性[9];生存方面分析显示:CEP8非整倍体比例同生存期呈负相关(显著性差异),即CEP8扩增比例大,5年生存期短[10];同时,位于8号染体上的c-myc基因扩增表达提示预后差,同时两种(CMYC扩增/P53缺失)同转移相关。而CEP8的扩增同位于其上的c-myc及P53的表达呈正相关,故CEP8的扩增与CEP17的缺失具有指导预后及转移的作用[11]。8号染体扩增的CTC在不同分期的非小细胞肺癌患者中均有相对较高比例的表达,同时在以正常人及肺部良性疾病患者的对照组中,呈现较高的特异性,与其他肺癌相关瘤标对比,基于8号染体扩增的CTC检测的灵敏性优于瘤标检测;在对接受化疗的晚期非小细胞肺癌患者前、后的CTC检测数目变化考察中,结果显示:CTC评价疗效结果显示出与影像学的高度一致性;同时以CTC基线值及变化值为考量因素,则对患者的PFS有更精准的预测[12]。
刘博等4. 肝癌
肝癌患者中1号及8号染体呈现高比例的异常表达[13];其中1号染体尤其是位于1号染体上的三体情况较为普遍且在正常肝组织与良性病灶中无异常,显示出较高的特异性[14]。
同时,基于FISH技术考察1/8号染体在于高/中/低分化程度的肝细胞癌中的分布情况。结果显示随着病理去分化程度的上升,1/8号染体倍体数目呈现明显的上升趋势(p≤ 0.0002),提示染体不稳定性(chromosomal instability, CIN)程度随病理分化程度的下降而提升[15]。
5. 结直肠癌
结直肠癌患者中呈现不同比例的7号、8号染体扩增情况[16]。7号染体多体现象显示出与MET 和MACC1高表达相关[17]。而在肝转移患者中往往呈现7号染体高频异常,8号染体出现缺失、增益、扩增等现象[16]。
6. 卵巢癌
卵巢癌患者中8号染体扩增表达在晚期浆液性卵巢癌患者中呈现高表达,早期浆液性中则表达较少[18]。8号染体上的c-myc有无扩增与年龄及预后相关,其中c-myc扩增与卵巢子宫内膜异位的恶性转化相关[19]。8号染体扩增型CTC在浆液性及非浆液性卵巢癌患者中均有不同比例的表达,同时C
TC 数目与CA125水平存在相关性,且较之CA125,灵敏性更高[20]。
7. 胰腺癌
胰腺癌患者中8号染体存在不同比例的扩增及缺失现象[21]。针对胰腺导管癌的研究显示:8号染体上的c-myc基因的表达在胰腺癌侵袭过程中呈现下降的现象,结果指出c-myc扩增可能与胰腺导管癌早期发生发展有关,而与局部肿瘤的侵袭性相关性不大[22]。以8号染体扩增为鉴别标识的CTC的检测研究中显示:不同分期的胰腺癌患者均有较高的CTC检出率;对接受手术的胰腺癌患者的随访显示:术后CTC阳性患者有更差的预后生存[23]。
8. 胃癌
胃癌患者中的17号染体多体同肿瘤位置/远端转移/姑息手术效果/术后并发症存在显著相关性。其中的HER2扩增与低度浸润/高分化呈现极高相关性[24]。在进展期胃癌患者中,无论是前还是后8号染体扩增的CTC均有较高的检出率。对接受化疗的AGC患者分别于前、后分别进行CTC检测结果显示:PR的患者前8号染体三体所占比例最低。后:PR和SD的患者8号染体四体及多体比例都明显下降,而PD患者中却上升。提示8号染体三体存在原始性耐药,而四体与多体与用药敏感性及获得性耐药相关[25]。
随着越来越多的学者将肿瘤研究的关注点转移到基因水平,人们对肿瘤的检测和也上升了一个新的高度。目前已有很多基因ALK, HER2, EGFR等靶向药物投入临床,在提高肿瘤病人的生存期和改善预后等方面取得十分积极的成果。另一方面,现代医学诊疗手段特别是病理分子技术的日渐成熟已经为肿瘤疾病的诊治提供了新的依据和方法。诸如FISH技术,以及基于FISH原理的CTCS和肿瘤相关的巨噬样细胞(CAMLS)均普遍运用于临床检测。虽然目前分子诊断还不能取代传统的组织活检,但是新技术的运用大大提高了临床病理报告的准确性和可靠性。每一项新技术的出现和普及都要经过一个较长的过程,但是笔者相信随着对于染体的研究更加深入成熟,在此基础上衍生出来的技术和手段终将会成为人类攻克肿瘤的一大利器。
刘博等
参考文献(References)
[1]王彦. 多倍体细胞与肿瘤关系的研究进展[J]. 国际妇产科学杂志, 2010, 37(6): 420-422.
[2]Tse, C.H., Hwang, H.C., Goldstein, L.C., Kandalaft, P.L., Wiley, J.C., Kussick, S.J. and Gown, A.M. (2011) Deter-
mining True HER2 Gene Status in Breast Cancers with Polysomy by Using Alternative Chromosome 17 Reference
Genes: Implications for Anti-HER2 Targeted Therapy. Journal of Clinical Oncology, 29, 4168-4174.
/10.1200/JCO.2011.36.0107
[3]Tibau, A., López-Vilaró, L., Pérez-Olabarria, M., Vázquez, T., Pons, C., Gich, I., et al. (2014) Chromosome 17 Cen-
tromere Duplication and Responsiveness to Anthracycline-Based Neoadjuvant Chemotherapy in Breast Cancer. Neop-
lasia, 16, 861-867. /10.2014.08.012
[4]Afify, A. and Mark, H.F.L. (1997) Fluorescence in Situ Hybridization Assessment of Chromosome 8 Copy Number in
Stage I and Stage II Infiltrating Ductal Carcinoma of the Breast. Cancer Genetics and Cytogenetics, 97, 101-105.
/10.1016/S0165-4608(96)00361-5
[5]Watters, A.D., Going, J.J., Cooke, T.G. and Bartlett, J.M.S. (2003) Chromosome 17 Aneusomy Is Associated with
Poor Prognostic Factors in Invasive Breast Carcinoma. Breast Cancer Research and Treatment, 77, 109-114.随行夹具
/10.2014.08.012
[6]Krishnamurti, U.,Hammers, J.L., Atem, F.D., Storto, P.D. and Silverman, J.F. (2009) Poor Prognostic Significance of
Unamplified Chromosome 17 Polysomy in Invasive Breast Carcinoma. Modern Pathology, 22, 1044-1048.
/10.1038/modpathol.2009.61
[7]Pritchard, K.I., Munro, A., O’Malley, F.P., Tu, D.S., Li, X., Levine, M.N., et al. (2012) Chromosome 17 Centromere
(CEP17) Duplication as a Predictor of Anthracycline Response: Evidence from the NCIC Clinical Trials Group (NCLC
CTG) MA.5 Trial. Breast Cancer Research and Treatment, 131, 541-551. /10.1007/s10549-011-1840-4
[8]Bartlett, J.M., Munro, A.F., Dunn, J.A., McConkey, C., Jordan, S., Twelves, C.J., et al. (2010) Predictive Markers of
Anthracycline Benefit: A Prospectively Planned Analysis of the UK National Epirubicin Adjuvant Trial (NEAT/
BR9601). The Lancet Oncology, 11, 266-274. /10.1016/S1470-2045(10)70006-1
[9]李璐. 肺癌染体非整倍体的间期核荧光原位杂交研究[D]: [博士学位论文]. 北京: 中国协和医科大学, 2007.
[10]Kubokura H., et al. (2001) Relations of the c-myc Gene and Chromosome 8 in Non-Small Cell Lung Cancer: Analysis
by Fluorescence in Situ Hybridization. Annals of Thoracic and Cardiovascular Surgery, 7, 197-203.
[11]Yakut, T., Egeli, U. and Gebitekin, C. (2003) Investigation of c-Myc and p53 Gene Alterations in the Tumor and Sur-
基因工程抗体
gical Borderline Tissues of NSCLC and Effects on Clinicopathologic Behavior: By the FISH Technique. Lung, 181,
245-258. /10.1007/s00408-003-1026-x
[12]Chen, Y.Y. and Xu, G. (2014) Effect of Circulating Tumor Cells Combined with Negative Enrichment and
CD45-FISH Identification in Diagnosis, Therapy Monitoring and Prognosis of Primary Lung Cancer. Medical Oncol-
ogy, 31, 240. /10.1007/s12032-014-0240-0
[13]Wilkens, L., et al. (2001) Diagnostic Impact of Fluorescence in Situ Hybridization in the Differentiation of Hepatocel-
lular Adenoma and Well-Differentiated Hepatocellular Carcinoma. Journal of Molecular Diagnostics, 3, 68-73.
/10.1016/S1525-1578(10)60654-X
[14]Nasarek, A., Werner, M., Nolte, M., Georgii, A. and Klempnauer, J. (1995) Trisomy 1 and 8 Occur Frequently in He-
patocellular Carcinoma but Not in Liver Cell Adenoma and Focal Nodularhyperplasis. A Fluorescence in Situ Hybri-
saxsdization Study. Virchows Archiv, 427, 373-378. /10.1007/BF00199385
[15]Wilkens, L., et al. (2004) Induction of Aneuploidy by Increasing Chromosomal Instability during Dedifferentiation of
Hepatocellular Carcinoma. Proceedings of the National Academy of Sciences of the United States of America, 101,
1309-1314. /10.1073/pnas.0305817101
[16]Sayagués, J.M., et al. (2010) Intratumoural Cytogenetic Heterogeneity of Sporadic Colorectal Carcinomas Suggests
Several Pathways to Liver Metastasis. Journal of Pathology, 221, 308-319. /10.1002/path.2712
[17]Galimi, F., et al. (2011) Genetic and Expression Analysis of MET, MACC1, and HGFin Metastatic Colorectal Cancer:
Response to Met Inhibitionin Patient Xenografts and Pathologic Correlations. Clinical Cancer Research, 17, 3146-
3156. /10.1158/1078-0432.CCR-10-3377
[18]Hu, J., Khanna, V., Jones, M.M.W. and Surti, U. (2002) Genomic Imbalances in Ovarian Borderline Serous and Mu-
cinous Tumors. Cancer Genetics and Cytogenetics, 139, 18-23. /10.1016/S0165-4608(02)00603-9
[19]Darcy, K.M., et al. (2009) Prognostic Relevance of c-MYC Gene Amplification and Polysomy for Chromosome 8 in
Suboptimally-Resected, Advanced Stage Epithelial Ovarian Cancers: A Gynecologic Oncology Group Study. Gyneco-
logic Oncology, 114, 472-479. /10.2009.05.012
[20]Ning, N., et al. (2014) Improvement of Specific Detection of Circulating Tumor Cells Using Combined CD45 Staining
刘博等
and Fluorescence in Situ Hybridization. Clinica Chimica Acta, 433, 69-75. /10.a.2014.02.019 [21]Zojer, N., et al. (1998) Chromosomal Imbalances in Primary and Metastatic Pancreatic Carcinoma as Detected by In-
terphase Cytogenetics: Basic Findings and Clinical Aspects. British Journal of Cancer, 77, 1337-1342.
/10.1038/bjc.1998.223
[22]Schleger, C., Verbeke, C., Hildenbrand, R., Zentgraf, H. and Bley, U. (2002) C-MYC Activation in Primary and Me-
tastatic Ductal Adenocarcinoma of the Pancreas: Incidence, Mechanisms, and Clinical Significance. Modern Pathology, 15, 462-469. /10.1038/modpathol.3880547
[23]Zhang, Y., et al. (2015) Patterns of Circulating Tumor Cells Identified by CEP8, CK and CD45 in Pancreatic Cancer.
International Journal of Cancer, 136, 1228-1233. /10.1002/ijc.29070
[24]Ciesielski, M., et al. (2014) The HER2 Gene and HER2 Protein Status and Chromosome 17 Polysomy in Gastric Can-
cer Cells in Own Material. Applied Immunohistochemistry & Molecular Morphology,23, 113-117.
/10.1097/PAI.0000000000000070
[25]Li, Y., et al. (2014) Clinical Significance of Phenotyping and Karyotyping of Circulating Tumor Cells in Patients with
Advanced Gastric Cancer. Oncotarget, 5, 6594-6602. /10.18632/oncotarget.2175
期刊投稿者将享受如下服务:
1. 投稿前咨询服务(QQ、、邮箱皆可)
2. 为您匹配最合适的期刊
3. 24小时以内解答您的所有疑问
4. 友好的在线投稿界面
5. 专业的同行评审
6. 知网检索
7. 全网络覆盖式推广您的研究
投稿请点击:/Submission.aspx
期刊邮箱:
豫公网安备41160202000603
站长QQ:729038198
关于我们
投诉建议