4 resultados para G-banding karyotype
em DigitalCommons@The Texas Medical Center
Resumo:
To investigate the hypothesis that increased malignant potential correlates with increased levels of genetic instability, the following parameters of instability were measured: (1) spontaneous mutation rates for ouabain resistance in murine cell lines of different malignant potentials, (2) the background prevalence of 6-thioguanine (6-TG) resistance in clone 4 (highly metastatic) and clone 19 (poorly metastatic) of the K1735 murine melanoma, (3) the prevalence of ouabain resistant variants in three murine cell lines and their variants after exposure to the mutagen MNNG, (4) the rate of generation of major karyotypic abnormalities in B16 F1 (poorly metastatic) and B16 F10 (highly metastatic) murine melanoma, and (5) analysis of the G-banded karyotypes of cloned B16 F1 and B16 F10 melanoma.^ No correlation of increased spontaneous mutation rates with increased malignant potential was found in repeated experiments with three murine cell lines and their variants of different malignant potential. The background prevalence of g-TG resistance was not significantly different for the poorly and highly metastatic clones of K1735 melanoma. The studies with MNNG-induced mutation showed no increased sensitivity of the highly metastatic variants of the three murine cell lines to mutagenesis. Neither did the rate of generation of major karyotypic abnormalities correlate with malignant potential. However, certain karyotypic differences were demonstrated after G-banding of the B16 F1 and F10 melanomas.^ One hypothesis which is consistent with these results is that the rate of generation of genetic abnormalities need not be strongly related to the degree of malignant potential. An increased prevalence of genetic changes may merely reflect the accumulation of abnormalities while their rate of production remains constant. The presence of specific nonrandom changes likely is the main determinant of malignant potential rather than the rate of production of random changes. ^
Resumo:
Microcell-mediated chromosome transfer is a method of gene transfer which allows for the introduction of single or small groups of intact chromosomes into recipient host cells. Microcell transfer was first performed by Fournier and Ruddle using rodent microcells and various recipient cells. Expansion of this technology to include the transfer of normal human genetic material has been hindered because large micronucleate populations from diploid human cells have been unobtainable. This dissertation research describes, however, the methods for production of micronuclei in 40-60% of normal human fibroblasts. Once micronucleate cells were obtained, they were enucleated by centrifugation in the presence of Cytochalasin B; the microcells were then purified and fused to recipient mouse (LMTK('-)) cells using a new fusion protocol employing polyethylene glycol containing phytohemagglutinin. Microcell clones were isolated from the HAT selection system. Alkaline Giemsa staining performed on these hybrids indicated the presence of a single human chromosome in each of seven microcell clones from three separate experiments. That chromosome was further identified by G banding analysis to be human chromosome #17, which codes for thymidine kinase. The time course for production of these hybrids from fusion to karyotypic analysis was 6 weeks. The viability of the transferred human genetic material was assessed by electrophoretic isozyme analysis.^ Subsequent experiments were performed in an attempt to optimize the transfer frequency for the thymidine kinase gene using this system. Results indicated that the frequency could be increased from < 1 x 10('-6) in initial experiments to 2 x 10('-5) in the latest experiment. Analyses were also conducted to determine the number of chromosomes per isolated microcell as well as to investigate the stability of the transferred human chromosome in the mouse genome. ^
Resumo:
This case control study was conducted to assess the association between lung cancer risk, mutagen sensitivity (a marker of cancer susceptibility), and a putative lung carcinogen, wood dust exposure. There were 165 cases (98 African-Americans, 67 Mexican-Americans) with newly diagnosed, previously untreated lung cancer, and 239 controls, frequency-matched on age, sex, and ethnicity.^ Mutagen sensitivity ($\ge$1 break/cell) was associated with a statistically significant elevated risk for lung cancer (odds ratio (OR) = 4.1, 95% confidence limits (CL) = 2.3,7.2). Wood dust exposure was also a significant predictor of risk (OR = 2.8, 95% CL = 1.2,6.6) after controlling for smoking and mutagen sensitivity. When stratified by ethnicity, wood dust exposure was a significant risk factor for African-Americans (OR = 4.0, 95% CL = 1.4,11.5), but not for Mexican-Americans (OR = 1.5, 95% CL = 0.3,7.1). Stratified analysis suggested a greater than multiplicative interaction between wood dust exposure and both mutagen sensitivity and smoking.^ The cases had significantly more breaks on chromosomes 4 and 5 than the controls did with ORs of 4.9 (95% CL = 2.0, 11.7) and 3.9 (95% CL = 1.6, 9.3), respectively. Breaks at 4p14, 4q27, 4q31, 5q21-22, 5q31, and 5q33 were significantly more common in lung cancer patients than in controls. Lung cancer risk had a dose-response relationship with breaks on chromosomes 4 and 5. Cigarette smoking had a strong interaction with breaks on chromosomes 2, 4, and 5.^ In a molecular cytogenetic study, using chromosome painting and G-banding, we showed that: (1) the proportion of chromosome 5 abnormalities surviving as chromosome-type aberrations remained significantly higher in cells of lung cancer cases (14%) than in controls (5%) (P $<$ 0.001). However, no significant differences were detected in chromosome 4 abnormalities between cases and controls; (2) the proportion of chromosome 5q13-22 abnormalities was 5.3% in the cases and 0.7% in the controls (P $<$ 0.001). 5q13-22 regions represented 40% of all abnormalities on chromosome 5 in the cases and only 14% in the controls.^ This study suggests that mutagen sensitivity, wood dust exposure, and cigarette smoking were independent risk factors for lung cancer, and the susceptibility of particular chromosome loci to mutagenic damage may be a genetic marker for specific types of lung cancer. ^
Resumo:
Double minutes (dm) are small chromatin particles of 0.3 microns diameter found only in the metaphase cells of human and murine tumors. Dm are unique cytogenetic structures since their numbers per cell show wide variation. At cell division, dm are retained despite the lack of centromeres. In squash preparations, dm show clustering often in association with chromosomes. Human carcinoma cell line SW613-S18 was found to have large numbers of dm and biological characteristics favorable for mitotic synchronization and chromosome isolation experiments.^ S18 cells were synchronized to mitosis with metabolic and mitotic blocking compounds. Mitotic cells were lysed to release chromosomes and dm from the mitotic spindle and the resulting suspensions were fractionated to enrich for dm. The DNA in enriched fractions was characterized. The reassociation kinetics of dm-DNA driven with placental human DNA was similar to the reassociation curve of labeled placental DNA under similar conditions. In situ hybridization of dm-DNA to tumor and normal metaphase cells showed grain localization over the entire karyotype. Dm-DNA was shown by pulse chase DNA replication experiments to replicate during early and mid S-phase of the cell cycle, but not in late S-phase. In addition, BrdUrd incorporation studies showed that dm-DNA replicates only once during the S-phase. Premature chromosome condensation studies suggest the basis of numerical heterogeneity of dm is nondisjunction, not anomalous or unscheduled DNA replication.^ These data and previous cytochemical banding studies of dm in SW613-S18 indicate that dm-DNA is chromosomal in origin. No evidence of gene amplification was found in the DNA reassociation data. It is likely that dm-DNA represents the pale-staining G-band regions of the human karyotype in this cell line. ^
