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Query: UMLS:C0242379 (lung cancer)
71,905 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rapid advances in cancer gene therapy are driven by an explosive development of gene transfer technology and a strong demand for effective alternatives to unsatisfactory conventional cancer therapies. Discovery of the genetic basis of cancer has indicated that cancer is a disease of genes. Among a variety of approaches to gene therapy of cancer, anti-oncogene and tumor suppressor gene therapy of cancer are the two strategies that aim at correcting genetic disorders of cancer. The potential effectiveness of these approaches is promised by their precise targeting at the mechanisms of the disease. Successful examples of human lung cancer animal models by applying anti-K-ras retrovirus and recombinant p53 adenovirus are reviewed. Future development of these approaches towards clinical application is also discussed.
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PMID:Anti-oncogene and tumor suppressor gene therapy--examples from a lung cancer animal model. 772 23

Tobacco smoke contains many mutagenic and carcinogenic chemicals. Both whole tobacco smoke and extracts induce tumors in experimental animals. Work with carcinogen-macromolecule adducts provided evidence for the action of specific chemicals. Molecular epidemiology studies suggested that point mutations in tumor-suppressor genes (e.g., p53) and oncogenes (e.g., ras) may be specific both for the type of tumor and for the critical environmental exposure. The consistency among investigations on oncogene/tumor-suppressor gene mutations in lung cancer (and other tobacco-related cancers) in smokers is highly suggestive, although we still lack information about the time sequence between exposure, gene mutation, and cancer onset. Current work that deserves emphasis includes investigations revealing that lungs of smokers contain benzo[a]pyrene diol-epoxide-guanine DNA adducts, which are in accordance with the type of mutations found in K-ras or p53 genes (G to T transversions). In addition, DNA in human exfoliated bladder cells showed a derivative of 4-aminobiphenyl as a main adduct; there was also an association between smoking habits (amount and type of tobacco) and the levels of both DNA adducts and hemoglobin adducts formed by aromatic amines. Increasing evidence indicates that genetically based metabolic polymorphisms exert a role in modulating individual susceptibility to the action of tobacco carcinogens. Overall, the weight of evidence strongly supports the causal nature of the association between smoking and cancer and falsifies Fisher's hypothesis that the association was due to confounding by genetic predisposition.
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PMID:Tobacco and cancer: epidemiology and the laboratory. 773 63

Reported estimates of ras mutation prevalence in lung adenocarcinoma of 15-24% may be underestimates because of the insensitivity of the assays used. We have devised a rapid, non-radioactive assay for ras mutations, which detects 1 mutant allele/10(3) normal alleles and have used it to study DNA isolated from 53 lung tumor samples (including 28 adenocarcinomas) previously analyzed by PCR/allele specific oligonucleotide hybridization, which is less sensitive. We detected mutations in 13 of 28 samples, including 7 not detected by PCR/allele specific oligonucleotide hybridization. We also found ras mutations in 14 of 25 previously unstudied samples (56%). Our results indicate that the prevalence of K-ras codon 12 mutations in lung adenocarcinoma is higher than previously reported; thus, ras mutations may be more clinically useful as molecular markers for lung cancer than has been appreciated.
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PMID:Increased prevalence of K-ras oncogene mutations in lung adenocarcinoma. 788 50

We investigated preneoplastic lesions associated with lung cancer to determine at what stage in lung carcinogenesis K-ras mutations appear. We selected six archival lung cancer resection cases that had ras mutations. We precisely microdissected 74 relevant areas from paraffin-embedded sections. K-ras mutations at codons 12, 13, and 61 were determined by the designed restriction fragment length polymorphism method using mismatched nested primers and confirmed by direct sequencing. All samples of invasive and metastatic cancers had K-ras mutations, as did four of five lesions of noninvasive cancer. Mutations were detected in only 1 of 12 dysplastic lesions and were absent from hyperplastic and normal-appearing cells. In all cases, the specific point mutations and the mutational pattern in the tumors, metastases, and the corresponding noninvasive lesions were identical. These results indicate that K-ras mutations arise relatively late in the pathogenesis of lung cancer and may be associated with the appearance of the malignant phenotype.
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PMID:K-ras mutations are a relatively late event in the pathogenesis of lung carcinomas. 795 6

K-ras gene point mutation is a highly frequent event in human malignancy. About one third of non-small cell lung cancer (NSCLC) patients harbor K-ras gene point mutational activations. This study investigates the prevalence of K-ras mutation in autopsy tumors with NSCLC, and the correlation of K-ras gene point mutations between primary tumors and metastases in NSCLC. Formalin-fixed, paraffin-embedded tissue sections of 15 primary lung tumors and their metastases, (obtained from autopsy), were examined for the presence of point mutations in K-ras gene codon 12, 13 and 61 by oligodeoxynucleotide hybridization analysis of DNA fragments, amplified by polymerase chain reaction (PCR). K-ras gene point mutations were detected in five cases of lung carcinoma, of which four were adenocarcinomas and one was squamous cell carcinoma. In each of these cases, identical K-ras gene mutations were found in the DNA of both the primary tumor and its corresponding distant metastases. Activating K-ras base-substitutions correlate well between the primary tumor and its corresponding metastases in NSCLC. In the negative cases where no K-ras mutation was found in the primary tumors, no newly acquired K-ras mutation appeared in the metastases. Our study indicates that K-ras point mutation serves as a stable tumor marker in NSCLC.
Lung Cancer 1994 Jul
PMID:K-ras gene point mutation: a stable tumor marker in non-small cell lung carcinoma. 808 2

We present a case with metachronous double lung cancers proved by molecular analysis. A male patient first had lung cancer discovered when he was 67 years old, and a second lung cancer was found when he was 71 years old. Pathologically, the first cancer was moderately to well differentiated adenocarcinoma and the second cancer was well differentiated adenocarcinoma. These findings suggested that the second cancer was not metastasis from the first lung cancer but a second primary lung cancer. According to the PCR and oligonucleotide mutation specific dot blot hybridization, the first lung cancer had a GGT to GTT mutation, while the second lung cancer had a GGT to TGT mutation at codon 12 of the K-ras gene. These results thus prove that these tumors were metachronous double cancers.
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PMID:Different site mutation of the K-ras gene in a patient with metachronous double lung cancers. 813 84

To investigate the role of tobacco smoking and asbestos fibers in the etiology of human lung cancer, we examined the activating point mutations in the K-ras oncogene in DNA samples from 49 patients. Mutations were found more often in tissue from adenocarcinomas (12/21) than in tissue from tumors other than nonadenocarcinomas of the lung (3/28). Among the adenocarcinoma patients, asbestos exposure was predictive of K-ras mutation (odds ratio, 4.9; 95% confidence interval, 0.7-34.3); in patients with other types of lung cancer, the relation appeared to be an inverse one, but the numbers were small. The proportion of heavy smokers (over 50 pack-years) was 60% among people with K-ras mutations and 35% among the K-ras-negative subjects, suggesting that smoking causes K-ras mutations. If mutations in K-ras genes are caused by smoking, asbestos would act as a promoting agent by conferring selective growth conditions for clonal expansion on these mutated cells. Asbestos may favor recruitment of (initiated) K-ras mutation-positive cells in the multistage process of carcinogenesis by stimulating cellular growth.
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PMID:Interaction between smoking and asbestos in human lung adenocarcinoma: role of K-ras mutations. 814 15

Lung cancer arises after a series of morphological changes, which take several years to progress from normal epithelium to invasive cancer. The morphological changes progress from hyperplasia, to metaplasia, to dysplasia, to carcinoma in situ, to invasive cancer and finally to metastatic cancer. Multiple molecular changes have been documented in lung cancers, both small cell (SCLC) and non-small cell (NSCLC) types. The number of changes has been estimated to be in double digits. How can so many changes develop in one cell? One possible explanation is the "field cancerization" theory, that states that all or much of the aerodigestive tract epithelium has been mutagenized, perhaps as the result of exposure to tobacco products or other carcinogens. The molecular changes include activation of dominant oncogenes (myc family, K-ras and HER/2/neu genes), as well as loss of recessive growth regulatory genes or anti-oncogenes (p53, and rb as well as unidentified gene or genes on chromosome 3). However, cytogenetic and molecular genetic studies indicate that multiple other specific sites of actual or potential DNA loss may be present in lung cancers. Many of the well characterized molecular changes may function as negative prognostic factors for survival in subsets of lung cancers. Other changes may include development of drug resistance, and production of growth factors and their receptors. It is tempting to associate specific molecular changes with specific morphological changes, as has been attempted in the colon. However, because of the difficulties in serially sampling the respiratory tract, only a modest amount of data has been collected to date. It appears that deletions of chromosome 3p, hyperproliferation and aneuploidy are early changes, while p53 mutations appear later in the preneoplastic cascade. Documentation of intermediate markers for lung cancer and prospective studies of their prognostic effects will be necessary for the design of rational chemoprevention trials.
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PMID:The molecular and cellular basis of human lung cancer. 816 65

In all normal cells, two type of genes, oncogenes and anti-oncogenes, are expressed and control cell proliferation and differentiation. Cell growth is stimulated by oncogenes and inhibited by anti-oncogenes. Cancerization involves loss of control due to defective gene expression either by overexpression of a normal protein (loss of quantitative control) or expression of an abnormal protein (loss of qualitative control). Several oncogenes have been identified. They include three oncogenes, c-myc, N-myc and L-myc, known to be overexpressed in small-cell carcinomas of the lung. Point mutations of the oncogene K-ras is found in 15 to 30% of adenoma carcinomas, especially in smokers. Loss of anti-oncogene function has also been described in processes leading to lung cancer. Chromosome abnormalities, for example the 3p14-23 deletion described in 1982, are found in 100% of small-cell carcinomas and in 50% of non-small-cell carcinomas. This deletion is never found in normal tissue. The gene involved has not yet been cloned. Other mutations or deletions include the RB gene, necessary for neuroendocrine differentiation, and the p53 gene which has undergone mutation in 50% of the non-small-cell carcinomas and 70% of the small-cell carcinomas. These acquired mutations are strongly associated with tobacco smoking. Oncogenes and anti-oncogenes play an important role in the complex step-wise process leading to cancerization. As tumour characterization becomes more precise and precancerous states better controlled, future treatments may relief on inhibiting tumoural growth by using drugs which would substitute for the lost effect of anti-oncogenes or inhibit activation of an oncogene. But at the present time, it is still difficult to define criteria predicting high risk of postoperative relapse or resistance and further studies investigating the correlation between genetic abnormalities and clinical staging and survival curves are required.
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PMID:[Oncogenes and anti-oncogenes in lung cancer]. 820 81

In order to know the involvement of multiple gene alterations in the pathogenesis of human lung cancer, we examined the genes of K-, H-ras (codons 12, 13, 61), p53(exons 5-9) and the retinoblastoma susceptibility gene (RB)(exons 20-22) using the polymerase chain reaction/single-strand conformation polymorphism method in 32 human lung cancer cell lines (5 squamous-cell carcinomas, 10 adenocarcinomas, 3 large-cell carcinomas, 14 small-cell carcinomas). In 18 non-small-cell lung cancer lines, gene alterations were found in 4 for K-ras (22%), none for H-ras (0%), 4 for p53 (22%) and none for the RB (0%) gene. In 14 small-cell lung cancer (SCLC) lines, no gene alterations were found in K-ras (0%), or H-ras (0%), but 6 were found for p53 (43%) and 3 for the RB (21%) gene. Coincident abnormalities of K-ras and p53, or K-ras and RB genes were not found in any cell lines, and those of the p53 and RB genes were found in only 2 SCLC lines. No association was observed between these three gene alterations and N-myc amplification. Although the above three genes may be involved to some extent in the pathogenesis of lung cancer, more factors are required for its development.
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PMID:Gene analysis of K-, H-ras, p53, and retinoblastoma susceptibility genes in human lung cancer cell lines by the polymerase chain reaction/single-strand conformation polymorphism method. 826 9

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