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SCLC Cell Line (sclc + cell_line)

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Medical Sciences100%

Selected Abstracts

Functional analysis of lung tumor suppressor activity at 3p21.3

GENES, CHROMOSOMES AND CANCER, Issue 12 2006
Arja ter Elst
The early and frequent occurrence of deletions at 3p21.3 in lung cancer has led to the consideration of this chromosomal region as a lung cancer (LUCA) critical region with tumor suppressor activity. We covered this 19 genes-containing region with overlapping P1 artificial chromosomes (PACs), in which genes are likely accompanied by their own promoters or other regulatory sequences. With these PACs we transfected cells from a small cell lung cancer (SCLC) cell line which readily caused tumors in nude mice. Per PAC we selected two cell clones with a low number of PAC copies integrated at a single genomic site. The selected clones were s.c. injected into nude mice to investigate whether the integrated genes suppressed the tumor-inducing capacity of the original SCLC cell line. We could demonstrate PAC-specific gene expression in the transfected cells. All of the PAC integration sites were different. It appeared that introduction of a PAC or even an empty PAC vector causes some chromosomal instability, which in principle may either promote or inhibit cell growth. However, both cell clones with integration of the same PAC from the centromeric part of the LUCA region in different genomic sites were the sole pair of clones that caused smaller tumors than did the original SCLC cell line. This suggests that rather than the induced chromosomal instability, the DNA sequence of that PAC, which in addition to two protein-encoding genes contains at least one potential miRNA gene, is responsible for the tumor suppressor activity. © 2006 Wiley-Liss, Inc. [source]

Similar chromosomal changes in cisplatin and oxaliplatin-resistant sublines of the H69 SCLC cell line are not associated with platinum resistance

GENES, CHROMOSOMES AND CANCER, Issue 12 2006
Britta Stordal
Small cell lung cancer (SCLC) initially responds well to DNA damaging drugs such as cisplatin, however this is transitory as resistance normally develops. To investigate whether changes in chromosomal copy number caused by platinum drug treatment contributes to platinum resistance, we have analyzed H69 SCLC cells and two low-level platinum-resistant sublines, H69CIS200 and H69OX400, derived by cisplatin and oxaliplatin treatment, respectively. Affymetrix 10K SNP array showed that cisplatin and oxaliplatin have independently caused similar changes including loss of segments 6q21-qter and 13pter-13q.14.11 and duplication of chromosome 21. Interestingly, despite using equally cytotoxic doses of drug in the development of the cell lines, oxaliplatin caused three times more chromosomal changes than cisplatin. The resistant cell lines lose their resistant phenotype after 3 months of drug-free culture. The revertant cell lines, denoted H69CIS200-S and H69OX400-S, were also analyzed by Affymetrix array to determine if chromosomal changes associated with resistance remain after the resistant phenotype is lost. In the H69OX400-S many of the changes observed in the resistant cells were absent suggesting that they contributed to the resistant phenotype including: loss of 1q23.3-qter, 10q11.23, and 19q13.12-q13.2 and duplication of segments 6p21.2-p12.3, 16q12.1-16q13, 16q21-q23.1, and 19q12. However, out of the similar changes induced by cisplatin and oxaliplatin, both the loss of 6q21-qter and gain of 21 were still present in the H69CIS200-S and H69OX400-S cells. This suggests that cisplatin and oxaliplatin induced similar changes due to inherent vulnerabilities in the H69 cells rather than changes associated with platinum resistance. © 2006 Wiley-Liss, Inc. [source]

Gain of a region on 7p22.3, containing MAD1L1, is the most frequent event in small-cell lung cancer cell lines

GENES, CHROMOSOMES AND CANCER, Issue 1 2006
Bradley P. Coe
Small-cell lung cancer (SCLC) is a highly aggressive lung neoplasm, which accounts for 20% of yearly lung cancer cases. The lack of knowledge of the progenitor cell type for SCLC precludes the definition of a normal gene expression profile and has hampered the identification of gene expression changes, while the low resolution of conventional genomic screens such as comparative genomic hybridization (CGH) and loss of heterozygosity analysis limit our ability to fine-map genetic alterations. The recent advent of whole genome tiling path array CGH enables profiling of segmental DNA copy number gains and losses at a resolution 100 times that of conventional methods. Here we report the analysis of 14 SCLC cell lines and six matched normal B-lymphocyte lines. We detected 7p22.3 copy number gain in 13 of the 14 SCLC lines and 0 of the 6 matched normal lines. In 4 of the 14 cell lines, this gain is present as a 350 kbp gene specific copy number gain centered at MAD1L1 (the human homologue of the yeast gene MAD1). Fluorescence in situ hybridization validated the array CGH finding. Intriguingly, MAD1L1 has been implicated to have tumor-suppressing functions. Our data suggest a more complex role for this gene, as MAD1L1 is the most frequent copy number gain in SCLC cell lines. © 2005 Wiley-Liss, Inc. [source]

Expression of PAX 3 alternatively spliced transcripts and identification of two new isoforms in human tumors of neural crest origin

INTERNATIONAL JOURNAL OF CANCER, Issue 2 2004
Craig J. Parker
Abstract The developmental gene PAX 3 is expressed in the early embryo in developing muscle and elements of the nervous system, including the brain. Since no one has investigated the expression of the isoforms of PAX 3 in the neuroectodermal tumors melanoma and small cell lung cancer (SCLC), we have carried out a comprehensive screening for the expression of the isoforms PAX 3a,e using RT-PCR in human melanoma cell lines, primary human ocular and secondary cutaneous melanomas. We have identified 2 new isoforms of PAX 3, g and h, which we have isolated, cloned and sequenced. Sets of primers for each isoform were designed and their specificity was confirmed by sequence analysis of the products. The isoforms PAX 3a,e were detected in all human cutaneous melanoma cell lines (8/8), but only PAX 3c (1/2) and PAX 3d (2/2) in ocular melanoma cell lines. The same PAX 3 isoforms were detected in more than 80% of human cutaneous melanomas: PAX 3a and b (15/17), PAX 3c (14/17), PAX 3d (16/17) and PAX 3e (15/17). In contrast the results for 7 SCLC cell lines were PAX 3a (0/7), PAX 3b (1/7), PAX 3c (3/7), PAX 3d (6/7), PAX 3e (2/7); 8/8 cutaneous melanoma cell lines and 8/8 ocular melanoma tissues, together with 14/17 cutaneous melanoma tissues screened, expressed the new isoform PAX 3g. All 8 cutaneous melanoma cell lines expressed PAX 3h, but it was not detectable in any of the tumor tissues (0/20). Neither of the 2 ocular melanoma cell lines expressed the 2 new isoforms. Comparison of the different amplicon staining intensities on a gel suggests that PAX 3c and PAX 3d are the predominant transcripts expressed, with relatively low expression of PAX 3e and PAX 3h. We propose that these and the 2 new isoforms we have discovered may be important in oncogenesis and differential diagnosis of melanomas or SCLC. © 2003 Wiley-Liss, Inc. [source]