Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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

The expression of Ha-ras and fes oncogenes was investigated with the immunohistochemical method in formalin-fixed, paraffin-embedded tissue specimens of 147 lung carcinomas. Positive immunoperoxidase reactions for Ha-ras p21 were found in 80.5% of the adenocarcinomas, 39.5% of the squamous cell carcinomas, 21.4% of the large cell carcinomas, and 15.4% of the small cell carcinomas; those for fes P85 were found in 51.2% of the adenocarcinomas, 26.3% of the squamous cell carcinomas, 35.7% of the large cell carcinomas, and 15.4% of the small cell carcinomas. Both Ha-ras p21 and fes P85 were expressed most frequently and most strongly in adenocarcinoma. In addition, adenocarcinoma showed significantly higher incidence of concomitant expression of Ha-ras p21 and fes P85 as compared with other histologic types of lung cancer. Thus, the authors suggest that the cooperative effects of Ha-ras and fes oncogenes are especially important in the carcinogenesis of adenocarcinoma. In adenocarcinoma, the incidence and grade of Ha-ras p21 expression increased with the degree of histologic differentiation, suggesting that Ha-ras oncogene might be related to cellular differentiation. Papillary adenocarcinoma showed more frequent Ha-ras p21 expression in comparison with acinar adenocarcinoma. In well- or moderately differentiated adenocarcinoma, the incidence and grade of Ha-ras p21 immunoreactivity in the cases with poor prognosis were significantly higher than in those with good prognosis if other major prognostic factors were equivalent in the two groups. The authors propose that the expression of Ha-ras p21 may be one of the useful prognostic factors in such carcinomas.
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PMID:Clinical and histopathologic evaluation of the expression of Ha-ras and fes oncogene products in lung cancer. 131 Aug 87

We screened 77 non-small-cell lung cancer (NSCLC) cell lines for mutations of the p53 gene using a single-strand conformation polymorphism (SSCP) assay. We found that 57 cell lines (74%) had mutations of the p53 gene. Three cell lines had a deletion of the p53 gene. Of the remaining 54 cell lines, 49 cell lines were sequenced and 52 mutations were confirmed. In contrast to previously published p53 mutations in other human tumors, the p53 gene mutations in NSCLC were diverse with regard to the location and nature of the mutations. The region corresponding to codons 144-166, which is outside the evolutionarily conserved regions, was a frequent site of p53 gene mutations in NSCLC. The presence of a p53 gene mutation was not associated with age, sex, histological types, culture site, treatment intent, presence of prior cytotoxic treatment, neuroendocrine differentiation, median culture time or patient survival. The prevalence of p53 mutations in cell lines with ras mutations did not differ from that in cell lines without ras mutations. However, p53 gene mutations in NSCLC cell lines with ras mutations tended to cluster in exon 8, suggesting the presence of a functional domain of the p53 gene relating to interaction with the ras gene. We conclude that p53 and ras mutations are frequent and apparently independent genetic alterations which play different roles in the pathogenesis, progression and prognosis of NSCLC.
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PMID:p53 gene mutations in non-small-cell lung cancer cell lines and their correlation with the presence of ras mutations and clinical features. 131 Oct 61

The three ras genes code for proteins with a putative role in cellular signal transduction. They belong to a larger family of small guanosine-triphosphate (GTP)-binding proteins. The ras proteins acquire transforming activity when amino acids are substituted at one of a few specific sites, as a result of a point mutation in the gene. In about one third of adenocarcinomas of the lung, a K-ras mutation is present in codon 12 of the gene. Patients with early stages of K-ras mutation-positive tumors have a very unfavorable prognosis, even if apparently radical resection of the tumor has taken place. K-ras mutations are very rare among nonsmokers, and it is reasonable to assume that carcinogens in tobacco smoke directly cause the mutation. The types of ras mutations found in lung cancer are different from those in gastrointestinal malignancies. Colon cancer is mainly associated with mutations leading to substitution of the normal glycine at amino acid position 12 of K-ras by either valine or aspartic acid, and mutations in N-ras are not exceptional. In contrast, the predominant mutation in lung cancer leads to substitution of cysteine in codon 12. Several other members of the ras gene superfamily are also expressed in human lung cancer, but a possible relationship with lung tumorigenesis remains to be established.
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PMID:The ras gene family in human non-small-cell lung cancer. 132 34

The 5-year survival of lung cancer patients is about 30% in Japan. One of the reasons for the poor prognosis seems to be drug resistance. It has been reported that certain types of oncogenes, such as ras, myc and fos, may play an important role in drug resistance. The myc protein forms a sequence-specific DNA-binding complex with Max and may act as a transcription factor; thus, it may be possible that myc family oncogenes are involved in DNA synthesis and repair processes mediating drug resistance. We report here that L-myc oncogene may be involved in the transition from drug-sensitive to drug-resistant phenotype of a certain small cell lung cancer cell line.
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PMID:[Relationship between drug resistance and oncogenes in lung cancer cell lines]. 133 94

Radon increases the risk of lung cancer in smoking and non-smoking underground miners. To investigate the mutational spectrum associated with exposure to high levels of radon, we sequenced exons 5-9 of the p53 tumour suppressor gene and codons 12-13 of the Ki-ras protooncogene in 19 lung cancers from uranium miners exposed to radon and tobacco smoke. Mutations were not found in Ki-ras, but 9 p53 mutations, including 2 deletions, were found in 7 patients by direct DNA sequencing after polymerase chain reaction amplification of DNA from formalin-fixed, paraffin-embedded tissue. In tumours from 5 patients, the mutation produced an aminoacid change and an increased nuclear content of p53 protein. The tumours with either a stop codon or frame-shift deletion in the p53 gene were negative by immunohistochemistry. None of the mutations were G:C to T:A transversions in the coding strand of the p53 gene, which are the most frequent base substitutions associated with tobacco smoking, and none were found at the hotspot codons described in lung cancer. The observed differences from the usual lung cancer mutational spectrum may reflect the genotoxic effects of radon.
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PMID:Mutations of p53 and ras genes in radon-associated lung cancer from uranium miners. 134 94

It seems increasingly likely that an important mechanism of action of certain workplace carcinogens in contributing to occupational carcinogenesis may be via the activation of cellular oncogenes, which then cause an expression of mutated forms or increased amounts of their oncoprotein products. Two prototypical models of this mechanism may be the ras oncogene and its p21 protein and the neu oncogene and its p185 protein. Both are known to be activated by exposure to common occupational carcinogens, and both are known to occur frequently in human tumors, including those of occupational concern such as lung cancer. Knowledge of their mechanisms of action may lead to new opportunities for preventing occupational cancer.
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PMID:Oncogenes and oncoproteins in occupational carcinogenesis. 135 42

The rapid pace of research in the genetics of human cancer will predictably render any review of the topic out of date by the time of its publication. Prospects for the near future will likely include the identification of a chromosome 3p gene(s) linked with the development of familial renal cancer and, perhaps, also lung cancer. In addition, the availability from the Human Genome Project of an increasing number of well-characterized markers will accelerate the search for additional human recessive oncogenes. Many questions still remain about the etiology of lung cancer and how to apply this information for patient care. For example, identification of the cell of origin for small cell and non-small cell lung cancers will facilitate our understanding of the development of these tumors and improve the possibilities for future preventive strategies. In addition, we now realize that these cancers arise from the sequential accumulation of multiple genetic mutations (Table 3; Fig. 1). Therefore, a central question is which of these targets are essential for the process of carcinogenesis, and whether there is a critical temporal order for this process with a defined premalignant phase in a discrete field of bronchial tissue. In addition, are there genetically inherited susceptibilities to the development of lung cancer (either directly or via variabilities in carcinogen metabolism) that could be accurately identified in the general population? Finally, is there a rate-limiting mutation and will the genetic correction of this defect suffice to restore growth regulation, or will the replacement of multiple gene products be required for tumor suppression? We are already witnessing the beginnings of the use of molecular diagnostic markers as a research tool for assigning prognostic information. The expression of neuroendocrine markers in non-small cell lung cancer has recently been applied as an indicator of the potential response to combination chemotherapy [15]. Similar methods are being applied to the expression of tumor suppressor genes or the presence of somatic mutations in dominant oncogenes such as the ras gene. However, the clinical benefit of this prognostic information with currently available treatment programs is still uncertain.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Oncogenes in human lung cancer. 136 67

Mutational activation of ras oncogenes is frequently encountered in human tumors. For unexplained reasons, K-ras mutations are predominantly found in pancreatic cancer, colorectal cancer and adeno-carcinoma of the lung, N-ras is predominantly found in a subset of acute leukemias and in myelodysplastic syndromes, while H-ras mutations are rare. In most tumors, ras mutations are not clearly associated with specific clinical or biological features, but in lung cancer, childhood lymphoblastic leukemia and possibly in myelodysplastic syndromes ras mutations may predict a poor prognosis. Accumulating evidence suggests that exposure to chemical carcinogens is responsible for many ras mutations in humans.
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PMID:ras and human tumors. 142 Nov 68

We studied the prevalence of point mutations in ras oncogenes (K-ras and N-ras) in DNA from white blood cells and tumor tissue from 36 untreated patients with non-small-cell lung cancer, all of whom were smokers or ex-smokers. We observed somatic K-ras mutations in one-third of the lung carcinomas studied but no N-ras mutation. K-ras codon 12 mutations were found more frequently in adenocarcinomas than in the other histopathological subtypes studied. More than 60% (10/16) of the lung adenocarcinomas had a codon 12 mutation, most of which were G to T transversions. No mutations was found in white blood cell DNA. Two polymerase chain reaction screening methods, oligonucleotide hybridization and denaturing gradient gel electrophoresis (DGGE), were used to detect the mutations. The oligonucleotide method appears to be more sensitive than DGGE, but DGGE proved to be a reliable nonradioactive method for rapid screening of point mutations in genes relevant to carcinogenesis.
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PMID:Detection of ras gene mutations in human lung cancer: comparison of two screening assays based on the polymerase chain reaction. 148 47

Accumulating evidence indicates that lung cancer arises due to multiple genetic changes in both dominant oncogenes, such as ras, and tumor suppressor genes, such as p53. In this report we examined whether the wild-type p53 gene is able to suppress in vitro and/or in vivo cellular growth of lung cancer cell lines which carry multiple genetic abnormalities. Introduction of a wild-type p53 complementary DNA expression vector into lung cancer cell lines carrying either a homozygous deletion (NCI-H358) or a missense mutation (NCI-H23) in the p53 gene greatly suppressed tumor cell growth. In contrast, p53 expression vectors bearing lung cancer derived mutations affecting single amino acids had lost this growth suppressing ability.
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PMID:Wild-type but not mutant p53 suppresses the growth of human lung cancer cells bearing multiple genetic lesions. 155 36


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