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原癌基因(proto-oncogene)的激活和/或抑癌基因(tumor suppressor gene)的缺失和灭活是恶性肿瘤发生、发展的分子生物学基础.P53基因是迄今为止发现的与人类肿瘤相关性最高的抑癌基因,其第一个被发现的家族成员P73基因作为候选的抑癌基因受到学者们的广泛关注.本文对P73基因在人类肿瘤中的表达及意义作一综述. 相似文献
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P53肿瘤抑制基因的研究与进展 总被引:8,自引:0,他引:8
P53肿瘤抑制基因的研究与进展徐清,汤雪明(上海第二医科大学细胞生物学实验室200025)P53基因是目前癌基因和抑癌基因研究中最引人注目的新星。1981年Weinbery等人首先报道人癌基因分离成功,癌基因的研究成为肿瘤研究的热点“’11986年人... 相似文献
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作者对52例人脑原发性肿瘤和5例正常人脑DNA中c-myc、L-myc、Nmyc、erbB、c-fos、sis及Ha-ras等七种癌基因的扩增和重排进行了研究,发现多数胶质瘤中有c-myc、L-myc、erbB及c-fos等癌基因的扩增,少数胶质瘤和脑膜瘤中发现myc家族癌基因的限制性酶切区带位置有多态性变化;同时还观察到原发性脑瘤中存在两种或两种以上癌基因的扩增和重排现象。作者对癌基因与人脑原发性肿瘤的关系进行了讨论。 相似文献
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膀胱癌H-ras基因点突变和ras癌基因产物P21的表达 总被引:2,自引:0,他引:2
应用聚合酶链反应(PCR)技术结合地高辛化寡核甘酸探针杂交以及免疫组织化学方法,检测人膀眈癌组织中H-ras癌基因第12位密码子点突变和基因产物P21蛋白的表达.58例膀胱癌组织中有23例出现H-ras基因的点突变,36例P21蛋白表达阳性,5例正常膀胱组织未见点突变和P21蛋白阳性表达.本组膀胱癌第12位密码子点突变和P21阳性表达水平呈正相关,多发生在肿瘤临床T2-T4期和分化差的肿瘤,并且与膀胱癌的预后有关、提示H-ras癌基因点突变和P21蛋白阳性表达是膀胱癌的晚期表现,并在膀胱癌的发生,发展及预后中起着重要作用. 相似文献
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目的探讨口腔鳞癌中癌基因c]myc、c-erbB2和抗癌基因p16、p53四种基因mRNA的表达及其作用.方法用原位杂交和图像分析相结合的方法对30例口腔鳞癌和5例正常口腔粘膜中癌基因c-myc、c-erbB2和抗癌基因p16、p53的mRNA表达进行了定性、定位和定量研究.结果口腔鳞癌中c-myc、c-erbB2、p16和p53四种基因的mRNA表达率依次为83.3%、70%、93.3%和80%;统计分析发现,这四种基因的mRNA表达在不同性别、肿瘤部位、肿瘤分化程度、肿瘤浸润或转移状况、复发性间均无显著性差异(P>0.05);c-myc和p16 mRNA表达间具有明显的相关性(P<0.001).结论c-myc、c-erbB2、p53和p16这四种癌基因或抗癌基因的mRNA表达在口腔鳞癌发生发展中都具有重要作用,c-myc和p16 mRNA表达间具有一定的内在联系. 相似文献
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在大部分的肿瘤中都发现有癌基因的活化,癌基因的活化被认为是导致肿瘤发生的重要原因.然而,在野生型细胞内,癌基因的活化可以诱导细胞衰老,称为癌基因诱导的细胞衰老(oncogene-induced senescence, OIS),从而抑制进一步的肿瘤发生.因而,癌基因的活化具有诱导衰老或肿瘤的双向性.DNA损伤调控反应(DNA damage checkpoint response, DDR)是细胞应对DNA损伤时感应损伤,从而延迟或阻滞细胞周期进程的一种分子信号传递通路,是诱导细胞衰老的重要机制.癌基因的活化可以引发DNA损伤信号的产生,从而激活DDR,诱导细胞衰老.在DDR异常时,癌基因的激活可引发DNA的过度复制与细胞的过度增殖,并导致基因组不稳定性的积累,最终导致肿瘤发生.DDR的完整性决定了癌基因诱导的双向性.DDR在癌基因诱导中的重要作用,提示了保持和恢复DDR的完整性可以作为肿瘤预防和治疗的新方向. 相似文献
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Oncomine 是目前世界上最大的癌基因芯片数据库和综合数据挖掘平台之一,该数据库整合了GEO、TCGA和已发表文献来源的RNA和DNA-seq数据。数据库目前含有715个基因表达数据集(datasheet)、86 733个人体肿瘤组织和正常组织样本的信息,且有新的数据不断更新。Oncomine 数据库囊括的肿瘤类型有19种,包括:膀胱癌、脑/中枢神经系统肿瘤、乳腺癌、宫颈癌、结直肠癌、食管癌、胃癌、头/颈肿瘤、肾癌、白血病、肝癌、肺癌、淋巴瘤、黑色素瘤、骨髓瘤、卵巢癌、胰腺癌、前列腺癌、肉瘤。本文就如何利用Oncomine数据库,进行肿瘤组织中癌基因表达差异性分析以及基因共表达分析、癌基因在肿瘤组织中的表达及拷贝数分析、多组研究数据集的荟萃分析(meta analysis)、以及癌基因表达与患者生存率关系等进行分析。通过该数据库可以对肿瘤癌基因进行研究前的筛查,有利于发现新的肿瘤生物标记物或治疗靶点,为临床科学研究奠定一定的理论基础。 相似文献
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HER-2/neu癌基因在许多肿瘤,如乳腺癌、卵巢癌、非小细胞肺癌等肿瘤中高表达,在肿瘤的发生与发展中起重要作用,与肿瘤的转化、转移、复发、预后差、患者生存期缩短有关。HER-2/neu在乳腺癌过度表达率约为20%~30%,编码蛋白P185HER2属生长因子受体家族,抗P185HER2单克隆抗体(Herceptin)作为靶向药物已临床应用治疗HER2/neu高表达乳腺癌。 相似文献
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In five kinds of tumors, total 128 specimens were analyzed by RAPD (random amplified polymorphic DNA) PCR with nine 10-base arbitrary primers for detecting instabilities of DNA and chromosome and screening new molecular markers coupled to putative or unknown oncogenes and/or tumor suppressor genes. Bands representing instabilities have been recovered and purified from agarose and cloned into pCAPs vector, and further labeled by DIG as probes for analysis of Southern blot, Northern blot and Sequencing. Results revealed that sample 5 and 3 of the gastric cancers showed the highest genomic changes and the average detectability in five sorts of cancers was up to at least 40% (42.2%-49.4%), and that there were significant differences in the ability of each primer to detect genomic instability, which ranged from 27% to 68%. Despite the highest detectability of genetic instability (68%) in tumor tissues, primer 2 could produce stable profiles of DNA bands in normal tissue genome with good reproducibility. On the contrary, primer 8 was of the lowest one (27%). Band B of single copy found to be allelic losses in gastric and colon cancers according to RFLP analysis was of a novel sequence and registered by Gen-Bank (Accession Number AF151005). Therefore the genetic instabilities often concentrated on some special locuses of chromosome e.g. repetitive sequences etc. and coupled to carcinogenesis. It was impossible or difficult to get great achievements for cancer treatments with the procedure of gene therapy only to one oncogene or one tumor suppressor gene because the extensive DNA variations occurred during the progression of tumor. RAPD assay connected with other techniques was a good tool for the detection of genomic instabilities and direct screening of some new molecular markers related to tumor suppressor genes or oncogenes. 相似文献
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Fan B Dachrut S Coral H Yuen ST Chu KM Law S Zhang L Ji J Leung SY Chen X 《PloS one》2012,7(4):e29824
Background
Genomic instability with frequent DNA copy number alterations is one of the key hallmarks of carcinogenesis. The chromosomal regions with frequent DNA copy number gain and loss in human gastric cancer are still poorly defined. It remains unknown how the DNA copy number variations contributes to the changes of gene expression profiles, especially on the global level.Principal Findings
We analyzed DNA copy number alterations in 64 human gastric cancer samples and 8 gastric cancer cell lines using bacterial artificial chromosome (BAC) arrays based comparative genomic hybridization (aCGH). Statistical analysis was applied to correlate previously published gene expression data obtained from cDNA microarrays with corresponding DNA copy number variation data to identify candidate oncogenes and tumor suppressor genes. We found that gastric cancer samples showed recurrent DNA copy number variations, including gains at 5p, 8q, 20p, 20q, and losses at 4q, 9p, 18q, 21q. The most frequent regions of amplification were 20q12 (7/72), 20q12–20q13.1 (12/72), 20q13.1–20q13.2 (11/72) and 20q13.2–20q13.3 (6/72). The most frequent deleted region was 9p21 (8/72). Correlating gene expression array data with aCGH identified 321 candidate oncogenes, which were overexpressed and showed frequent DNA copy number gains; and 12 candidate tumor suppressor genes which were down-regulated and showed frequent DNA copy number losses in human gastric cancers. Three networks of significantly expressed genes in gastric cancer samples were identified by ingenuity pathway analysis.Conclusions
This study provides insight into DNA copy number variations and their contribution to altered gene expression profiles during human gastric cancer development. It provides novel candidate driver oncogenes or tumor suppressor genes for human gastric cancer, useful pathway maps for the future understanding of the molecular pathogenesis of this malignancy, and the construction of new therapeutic targets. 相似文献14.
DNA diversity among clinical isolates of Helicobacter pylori detected by PCR-based RAPD fingerprinting. 总被引:60,自引:2,他引:58 
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下载免费PDF全文 N Akopyanz N O Bukanov T U Westblom S Kresovich D E Berg 《Nucleic acids research》1992,20(19):5137-5142
The RAPD (or AP-PCR) DNA fingerprinting method was used to distinguish among clinical isolates of Helicobacter pylori, a bacterium whose long term carriage is associated with gastritis, peptic ulcers and gastric carcinomas. This method uses arbitrarily chosen oligonucleotides to prime DNA synthesis from genomic sites to which they are fortuitously matched, or almost matched. Most 10-nt primers with > or = 60% G + C yielded strain-specific arrays of up to 15 prominent fragments, as did most longer (> or = 17-nt) primers, whereas most 10-nt primers with 50% G+C did not. Each of 64 independent H. pylori isolates, 60 of which were from patients in the same hospital, was distinguishable with a single RAPD primer, which suggests a high level of DNA sequence diversity within this species. In contrast, isolates from initial and followup biopsies were indistinguishable in each of three cases tested. 相似文献
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Cancers have a clonal origin, yet their chromosomes and genes are non-clonal or heterogeneous due to an inherent genomic instability. However, the cause of this genomic instability is still debated. One theory postulates that mutations in genes that are involved in DNA repair and in chromosome segregation are the primary causes of this instability. But there are neither consistent correlations nor is there functional proof for the mutation theory. Here we propose aneuploidy, an abnormal number of chromosomes, as the primary cause of the genomic instability of neoplastic and preneoplastic cells. Aneuploidy destabilizes the karyotype and thus the species, independent of mutation, because it corrupts highly conserved teams of proteins that segregate, synthesize and repair chromosomes. Likewise it destabilizes genes. The theory explains 12 of 12 specific features of genomic instability: (1) Mutagenic and non-mutagenic carcinogens induce genomic instability via aneuploidy. (2) Aneuploidy coincides and segregates with preneoplastic and neoplastic genomic instability. (3) Phenotypes of genomically unstable cells change and even revert at high rates, compared to those of diploid cells, via aneuploidy-catalyzed chromosome rearrangements. (4) Idiosyncratic features of cancers, like immortality and drug-resistance, derive from subspecies within the 'polyphyletic' diversity of individual cancers. (5) Instability is proportional to the degree of aneuploidy. (6) Multilateral chromosomal and genetic instabilities typically coincide, because aneuploidy corrupts multiple targets simultaneously. (7) Gene mutation is common, but neither consistent nor clonal in cancer cells as predicted by the aneuploidy theory. (8) Cancers fall into a near-diploid (2 N) class of low instability, a near 1.5 N class of high instability, or a near 3 N class of very high instability, because aneuploid fitness is maximized either by minimally unstable karyotypes or by maximally unstable, but adaptable karyotypes. (9) Dominant phenotypes, because of aneuploid genotypes. (10) Uncertain developmental phenotypes of Down and other aneuploidy syndromes, because supply-sensitive, diploid programs are destabilized by products from aneuploid genes supplied at abnormal concentrations; the maternal age-bias for Down's would reflect age-dependent defects of the spindle apparatus of oocytes. (11) Non-selective phenotypes, e.g., metastasis, because of linkage with selective phenotypes on the same chromosomes. (12) The target, induction of genomic instability, is several 1000-fold bigger than gene mutation, because it is entire chromosomes. The mutation theory explains only a few of these features. We conclude that the transition of stable diploid to unstable aneuploid cell species is the primary cause of preneoplastic and neoplastic genomic instability and of cancer, and that mutations are secondary. 相似文献
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Tumorigenesis can be viewed as an imbalance between the mechanisms of cell-cycle control and mutation rates within the genes. Genomic instability is broadly classified into microsatellite instability (MIN) associated with mutator phenotype, and chromosome instability (CIN) recognized by gross chromosomal abnormalities. Three intracellular mechanisms are involved in DNA damage repair that leads to mutator phenotype. They include the nucleotide excision repair (NER), base excision repair (BER) and mismatch repair (MMR). The CIN pathway is typically associated with the accumulation of mutations in tumor suppressor genes and oncogenes. Defects in DNA MMR and CIN pathways are responsible for a variety of hereditary cancer predisposition syndromes including hereditary non-polyposis colorectal carcinoma (HNPCC), Bloom syndrome, ataxia-telangiectasia, and Fanconi anaemia. While there are many genetic contributors to CIN and MIN, there are also epigenetic factors that have emerged to be equally damaging to cell-cycle control. Hypermethylation of tumor suppressor and DNA MMR gene promoter regions, is an epigenetic mechanism of gene silencing that contributes to tumorigenesis. Telomere shortening has been shown to increase genetic instability and tumor formation in mice, underscoring the importance of telomere length and telomerase activity in maintaining genomic integrity. Mouse models have provided important insights for discovering critical pathways in the progression to cancer, as well as to elucidate cross talk among different pathways. This review examines various molecular mechanisms of genomic instability and their relevance to cancer. 相似文献
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Megha Rajaram Jianping Zhang Tim Wang Jinyu Li Cem Kuscu Huan Qi Mamoru Kato Vladimir Grubor Robert J. Weil Aslaug Helland Anne-Lise Borrenson-Dale Kathleen R. Cho Douglas A. Levine Alan N. Houghton Jedd D. Wolchok Lois Myeroff Sanford D. Markowitz Scott W. Lowe Michael Zhang Alex Krasnitz Robert Lucito David Mu R. Scott Powers 《PloS one》2013,8(6)
One of the key questions about genomic alterations in cancer is whether they are functional in the sense of contributing to the selective advantage of tumor cells. The frequency with which an alteration occurs might reflect its ability to increase cancer cell growth, or alternatively, enhanced instability of a locus may increase the frequency with which it is found to be aberrant in tumors, regardless of oncogenic impact. Here we’ve addressed this on a genome-wide scale for cancer-associated focal deletions, which are known to pinpoint both tumor suppressor genes (tumor suppressors) and unstable loci. Based on DNA copy number analysis of over one-thousand human cancers representing ten different tumor types, we observed five loci with focal deletion frequencies above 5%, including the A2BP1 gene at 16p13.3 and the MACROD2 gene at 20p12.1. However, neither RNA expression nor functional studies support a tumor suppressor role for either gene. Further analyses suggest instead that these are sites of increased genomic instability and that they resemble common fragile sites (CFS). Genome-wide analysis revealed properties of CFS-like recurrent deletions that distinguish them from deletions affecting tumor suppressor genes, including their isolation at specific loci away from other genomic deletion sites, a considerably smaller deletion size, and dispersal throughout the affected locus rather than assembly at a common site of overlap. Additionally, CFS-like deletions have less impact on gene expression and are enriched in cell lines compared to primary tumors. We show that loci affected by CFS-like deletions are often distinct from known common fragile sites. Indeed, we find that each tumor tissue type has its own spectrum of CFS-like deletions, and that colon cancers have many more CFS-like deletions than other tumor types. We present simple rules that can pinpoint focal deletions that are not CFS-like and more likely to affect functional tumor suppressors. 相似文献
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Common fragile sites predispose to specific chromosomal breakage associated with deletion, amplification, and/or translocation in certain forms of cancer. Chromosomal fragile sites not only are susceptible to DNA instability in cancer cells, but may also be associated with genes that contribute to the neoplastic process. FRA7G is a common fragile site containing the candidate tumor suppressor genes CAV1, CAV2, and TESTIN (TES). The human gastric cancer cell line GTL-16 has an amplification of this genomic region and was used to seek evidence for the suppressor candidacy of one of these genes. Our results demonstrate that CAV1, CAV2, and TESTIN are coamplified with the MET oncogene and overexpressed in GTL-16. Somatic mutation was not detected in the coding regions of these genes, although they were each overexpressed. The results show that CAV1, CAV2, and TESTIN are not tumor suppressor genes in this gastric cancer. 相似文献
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Our earlier studies using random amplified polymorphic DNA (RAPD) analysis have shown genetic instability in human lung cancer tissues. Here we have investigated the potential for genetic instability in silica- and cadmium chloride (CdCl2)-transformed BALB/c-3T3 cell lines. Non-transformed, transformed BALB/c-3T3 cells, and tumor cell lines (obtained by injecting nude mice with transformed cell lines) were analyzed for genomic changes. DNAs from 10 different transformed clones and their corresponding tumor cell lines were amplified individually by RAPD analysis using 10 arbitrary primers. DNA from non-transformed BALB/c-3T3 cells was used as a control to compare genetic alterations, if any, between non-transformed, transformed and tumor cell populations. PCR products from RAPD were electrophoretically separated on agarose gels and the banding profiles were visualized by ethidium bromide staining. Five of the 10 primers tested revealed genomic changes in silica-transformed cell lines when compared to non-transformed BALB/c-3T3 cells. Comparison of all 10 transformed and tumor cell lines showed varied degrees of genomic changes using all 10 primers. CdCl2-transformed cell lines displayed fewer genomic changes, only three of 10 primers showed a positive result. CdCl2-transformed cells and their corresponding tumor cell lines showed specific banding pattern differences in six of the 10 samples tested with six of the 10 primers. Changes in band intensity were the most commonly observed changes both in silica- and CdCl2-transformed and tumor cell lines. The results seem to indicate a progressive change in genomic rearrangements which may directly or indirectly be associated with progression of tumorigenesis. 相似文献
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Chromosome interstitial deletion (i.e., deletion of a chromosome segment in a chromosome arm) is a critical genetic event for the inactivation of tumor suppressor genes and activation of oncogenes leading to the carcinogenic conversion of human cells. The deletion at chromosome 9p21 removing the p16 tumor suppressor gene is a genetic alteration frequently observed in a variety of human cancers. Thus, structural analyses of breakpoints for p16 deletions in several kinds of human cancers have been performed to elucidate the molecular process of chromosome interstitial deletion consisting of formation of DNA double strand breaks (DSBs) and subsequent joining of DNA ends in human cells. The results indicated that DSBs triggering deletions in lymphoid leukemia are formed at a few defined sites by illegitimate action of the RAG protein complex, while DSBs in solid tumors are formed at unspecific sites by factors unidentified yet. In both types of tumors, the intra-nuclear architecture of chromatin was considered to affect the susceptibility of genomic segments of the p16 locus to DSBs. Broken DNA ends were joined by non-homologous end joining (NHEJ) repair in both types of tumors, however, microhomologies of DNA ends were preferentially utilized in the joining in solid tumors but not in lymphoid leukemia. The configuration of broken DNA ends as well as NHEJ activity in cells was thought to underlie the features of joining. Further structural analysis of other hot spots of chromosomal DNA breaks as well as the evaluation of the activity and specificity of NHEJ in human cells will elucidate the mechanisms of chromosome interstitial deletions in human cells. 相似文献