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M Sakamoto,
A Kondo,
K Kawasaki,
T Goto, H Sakamoto,
K Miyake,
Y Koyamatsu,
T Akiya,
H Iwabuchi,
T Muroya,
K Ochiai,
T Tanaka,
Y Kikuchi,
Y Tenjin
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ABSTRACT: Gene expression profiles were analyzed by using cDNA microarray for a cisplatin-sensitive cell line (KF), and three- and thirty-fold cisplatin-resistant ovarian cancer cell lines (KFr and KFrP200) both showing no p53 mutation within exon 5, 6, 7, 8 and no pglycoprotein overexpression. Expression of GST-pi mRNA increased as the level of resistance to cisplatin became high. Microarray analysis revealed that DNA repair associated genes, i.e., XRCC5, XRCC6, ERCC5, hMLH1 were over-expressed in three-fold cisplatin-resistant cell line, KFr as compared to cisplatin-sensitive parental cell line, KF. Apoptosis inhibitors, i.e., IGFR type I and II were over-expressed, and apoptosis inducer, i.e., caspase 3 and BAK were underexpressed in highly cisplatin-resistant cell line, KFrP200 as compared to KFr. As for clinical cases, cDNA microarray was used to compare gene expression profiles directly between two groups, i.e., the chemotherapy (CAP) sensitive group (n = 2) and the resistant group (n = 2). Six genes such as beta tubulin, high-mobility group (nonhistone chromosomal) protein 1, connective tissue growth factor, insulin-like growth factor binding protein 2, alpha tubulin, and RAS-related gene were overexpressed in CAP therapy resistance group, whereas seven genes such as CD9 antigen, alpha-2-macroglobulin, caveolin 2, interleukin 1 receptor antagonist, Rho GTPase activating protein 1, reticulon 3, cyclin-dependent kinase 10, keratin 7 were underexpressed in CAP therapy resistance group. By increasing clinical case number and gene number of microarray to be used in the analysis of expression profile of gene cluster affecting anticancer drug resistance and sensitivity of the ovarian cancer, it would be possible to apply microarray analysis to personalization of chemotherapy such as selection of effective chemotherapy protocol and prediction of therapeutic effect in the near future.
Human Cell 01/2002; 14(4):305-15. · 1.27 Impact Factor
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Y Suehiro,
M Sakamoto,
K Umayahara,
H Iwabuchi, H Sakamoto,
N Tanaka,
N Takeshima,
K Yamauchi,
K Hasumi,
T Akiya,
H Sakunaga,
T Muroya,
F Numa,
H Kato,
Y Tenjin,
T Sugishita
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ABSTRACT: Genetic abnormalities were detected by comparative genomic hybridization (CGH) in 12 ovarian clear cell adenocarcinomas. DNA sequence copy number abnormalities (CNAs) occurring in more than 20% of the cancers included increased copy numbers of 8q11-q13, 8q21-q22, 8q23, 8q24-qter, 17q25-qter, 20q13-qter and 21q22-qter and reduced copy numbers of 19p. Increases in copy numbers of 8q11-q13, 8q21-q22, 8q23 and 8q24-qter occurred more frequently in disease-free patients than in recurrent/non-surviving patients (p < 0.05). However, increases in copy numbers of 17q25-qter and 20q13-qter occurred more frequently in recurrent/non-surviving patients than in disease-free patients (p < 0.05). Furthermore, increases in copy numbers of 17q25-qter and 20q13-qter occurred together (p < 0.05). Additionally, there were negative correlations between increases in copy numbers of 8q21-q22 and 17q25-qter, and between 8q21-q22 and 20q13-qter (p < 0.05). It appears that ovarian clear cell adenocarcinomas can be classified into two subtypes, one being cancer with an increase in copy numbers of 8q and the other being cancer with increases in copy numbers of 17q25-qter and 20q13-qter.
Oncology 06/2000; 59(1):50-6. · 2.27 Impact Factor
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M Sakamoto,
K Umayahara, H Sakamoto,
K Kawasaki,
Y Suehiro,
T Kunugi,
T Akiya,
H Iwabuchi,
H Sakunaga,
T Muroya,
Y Kikuchi,
T Sugishita,
Y Tenjin,
J W Gray,
T Tanaka
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ABSTRACT: One of the most important clinical issues in cancer chemotherapy is the presence of intrinsic resistance or the appearance of acquired resistance against chemotherapy. As for intrinsic resistance, we had to perform direct chemo-sensitivity testing, or had to rely on the knowledge empirically acquired from randomized clinical trials. However, molecular or genetic markers associated with chemo-sensitivity have been reported recently. For example, inactivation of p53 or GML gene has been reported to be associated with chemo-resistance. Overexpression of topo-isomerase I has been reported to be associated with chemo-sensitivity to Topo I inhibitor. Overexpression of Thymidine Phosphorylase has been found to be associated with chemo-sensitivity to prodrug of 5-FU. By checking the status of such chemo-sensitivity markers prior to chemotherapy, it would be possible to predict the chemotherapeutic effect and even the necessity of the chemotherapy in the near future. In this article, we review the chemo-sensitivity markers reported so far, and methodology contributing to the discovery of new chemo-sensitivity markers. As a clinical study, 11 cases of ovarian cancer with high sensitivity to cisplatin-based chemotherapy and 29 cases of ovarian cancer with chemoresistance were analyzed by Comparative Genomic Hybridization (CGH). Copy number decrease in Xp, and copy number increase in 19q were observed in 13, 12 out of 29 resistant cases (45, 41%) and zero, 1 out of 11 sensitive cases (0, 9%), suggesting that -Xp and +19q were likely to be a genetic event associated with intrinsic drug-resistance (p = 0.006, 0.05, respectively). This effort should contribute to the discovery of new chemo-sensitivity and resistance markers.
Gan to kagaku ryoho. Cancer & chemotherapy 11/1998; 25(12):1819-31.
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ABSTRACT: Comparative Genomic Hybridization (CGH) is a powerful new method which allows genome-wide mapping of regions with DNA sequence copy number changes (both increases and decreases) in a single experiment without previous knowledge of the locations of the regions of abnormality. CGH is based on in situ hybridization of differentially labeled total genomic tumor DNA and normal DNA to normal human metaphase chromosomes. After hybridization copy number variations among the sequences in the tumor DNA are detected by measuring the tumor/normal fluorescence intensity ratio for each locus in the target chromosomes. Many previously unknown chromosomal regions with relative copy number changes have been detected in various tumors by CGH. Some changes have been identified as genetic markers associated with biological and clinico-pathological characteristics (i.e., histopathological grade, and clinical outcome). We review the published CGH articles and discuss briefly on current progress in CGH analysis to ovarian and uterine cervical cancer in our laboratory.
Nippon rinsho. Japanese journal of clinical medicine 05/1996; 54(4):933-43.
