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Query: UMLS:C0178874 (tumor progression)
 40,807 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Human prostate carcinogenesis has been viewed as a multi-step process involving progression from low histologic grade, small, latent carcinoma to large, higher grade, metastasizing carcinoma. However, recent data suggest that a variety of pathogenetic pathways may exist. The precise etiology and pathogenesis of human prostate cancer remain largely undefined. It is difficult to investigate stages in the development of human prostate cancer, but some animal models provide opportunities in this regard. Short-term treatment of rats with chemical carcinogens produces a low incidence (5-15%) of prostate cancer, provided that prostatic cell proliferation is enhanced during carcinogen exposure. Chronic treatment with testosterone also produces a low prostate carcinoma incidence. A high carcinoma incidence can only be produced by chronic treatment with testosterone following administration of carcinogens such as N-methyl-N-nitrosourea (MNU) and 3,2'-dimethyl-4-aminobiphenyl (DMAB). Testosterone markedly enhances prostate carcinogenesis even at doses that do not measurably increase circulating testosterone. Thus, testosterone is a strong tumor promoter for the rat prostate. All such MNU- or DMAB-initiated and/or testosterone-promoted tumors are adenocarcinomas; most originate from the dorsolateral and anterior, but not ventral, prostate lobes. These tumors share a number of important characteristics with human prostate cancer. A high frequency (70%) of activation of the K-ras gene by a G35 to A mutation occurs in these carcinomas. Another high incidence prostate carcinogenesis model, representing a different pathogenetic pathway, involves chronic administration of estradiol-17 beta to rats in combination with low-dose testosterone. The resulting carcinomas are low-grade and originate exclusively from periurethral ducts of the dorsolateral and anterior prostate. While it is unknown whether testosterone is a tumor promoter in this system, preliminary studies indicate the formation of a DNA adduct in the target tissue, which suggests that estradiol-17 beta acts as a tumor initiating agent in this system. The high incidence models mentioned earlier are adequate for the study of chemoprevention of prostatic carcinogenesis. Analysis of shifts in the relative incidence of metastasizing carcinoma, grossly apparent but not-metastasizing carcinoma, microscopic-size carcinoma, and carcinoma in situ or atypical hyperplasia may allow study of the modifying effects of potential chemopreventive agents on tumor progression in these animal models of prostatic carcinogenesis.
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PMID:Animal models for the study of prostate carcinogenesis. 128 79

Tumorigenesis is a multistep process involving mutations of dominantly acting proto-oncogenes and mutations and loss-of-function mutations of tumor suppressor genes. Some of these mutations may be inherited, but most of them are acquired. Models for the sequential steps of the genetic changes involved in tumor development have been proposed for certain cancers, such as colon cancer. In the case of ovarian cancer, relatively little is known about the genetic events associated with the initiation or subsequent progression and metastases of the tumor. Cytogenetic analysis has revealed a high incidence of both structural and numerical chromosome changes, and the extent of these changes seems to increase with tumor progression. Oncogene activations of the proto-oncogenes K-ras, c-myc and c-erbB-2 have been found more frequently in aggressive ovarian tumors and may be associated with poor survival. Tumor-specific allele loss involving putative tumor suppressor genes has been observed for loci at chromosomes 11p, 17p, and 17q,--loci commonly deleted in other cancers too. A relatively high incidence of allelic loss on chromosome 6q appears to be specific to ovarian carcinoma. Familial breast/ovarian cancer has been suggested to map to chromosome 8q. Recently we have found a germ-line mutation in the tumor suppressor gene p53 in a family with breast- and ovarian cancers, indicating that this is the predisposing gene in this family. Genetic changes important for the etiology of ovarian cancers seem to involve both somatic mutations of oncogenes and somatic or germ-line inactivation of tumor suppressor genes.
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PMID:Oncogenesis in ovarian cancer. 150 89

Forty-two endometrial carcinomas of various stages of progression were analyzed to search for loss of chromosomal regions and for point mutations of ras genes and amplification of Int-2 gene. This approach is particularly favorable for observation of genetic events and their significance in the process of neoplastic conversion by considering the clinico-pathological characteristics of each tumor. At least 3 genetic events, including 18q, 17p deletions, and point mutations at codon 12 of the K-ras gene, are implicated in the development of endometrial carcinomas. Likely targets for allelic losses on chromosomes 18q and 17p are the DCC gene and the p53 gene sequences, respectively. Overall numbers of allelic losses in individual tumors appeared to increase in case of advanced stage tumors, thereby indicating the association of allelic loss accumulation with tumor progression. The genetic features seen in 2 juvenile-type adenocarcinomas and 2 clear-cell carcinomas suggested the possibility that etiological factors providing selective pressure for particular mutation sub-sets during carcinogenesis are probably heterogeneous.
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PMID:Chromosomal deletions and K-ras gene mutations in human endometrial carcinomas. 156 44

Current research indicates a role for several oncogenes in radiation-induced carcinogenesis in vivo and cell transformation in vitro. Certain oncogenes are probably also involved in some cases of human cancer caused by exposure to nonionizing radiation and may play a mechanistic role in the phenomenon of radioresistance seen in later stages of tumor progression. The mechanisms of oncogene activation seen in radiation-induced tumors include point mutations, gene amplification, and changes in gene expression. Genetic factors associated with target species, strain, and tissue type play an important role in determining the specific nature of oncogene activation by radiation exposure. Using the rat skin as a model for cancer induction by ionizing radiation, we found concurrent activation of K-ras and c-myc oncogenes in end-stage tumors. Amplification of the myc gene proved to occur during a late stage of tumor progression and is not an early initiating event resulting from the direct action of radiation on target cells. The importance of tissue specificity, tumor cell heterogeneity, and physical characteristics of the radiation exposure are discussed.
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PMID:Oncogenes and radiation carcinogenesis. 177

Five intraductal papillary neoplasms of the pancreas were analyzed for the presence of the Ras gene mutations. Three (60%) of the five neoplasms showed point mutations at K-ras codon 12. This incidence of the mutations was rather low compared with that found with ordinary pancreatic adenocarcinoma. The presence of the mutations did not correlate with the severity of cellular atypia, but was apparently related to the size of the tumor. The two neoplasms that had no mutations were smaller than the others that had mutations. The analysis suggested that Ras gene mutation is not the first genetic alteration of tumor progression, but that it occurs during the development of neoplasms of the pancreas.
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PMID:Ras gene mutations in intraductal papillary neoplasms of the pancreas. Analysis in five cases. 184 53

The inherited cancer-inducing disease familial polyposis coli (FPC) provides an excellent model not only for studying tumor progression in colorectal cancer but also for elucidating molecular mechanisms in general oncogenesis. This paper reviewed recent remarkable progresses of molecular mechanisms in colorectal tumorigenesis. This is concerned with the various kinds of genetic alterations that accumulate in the development from normal mucosa to adenoma, and then to adenocarcinoma in comparison with FPC and sporadic cases. This review included also information on the localization of FPC major gene. These observations indicate that in cases of colorectal tumorigenesis several genetic alterations may be involved, including activation of K-ras gene, deregulated expression of c-myc gene or c-fos gene and inactivation of tumor suppressor genes such as p53 and DCC genes, as well as the loss of heterozygosity. The observation suggest that adenomas will have undergone several gene or chromosome mutations before reaching to the fully malignant state. Therefore, DNA diagnosis for colorectal tumors in the clinical level may contribute to more accurate prognosis and better results for further therapy.
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PMID:[Diagnosis of colorectal cancer from DNA level]. 184 82

Transin mRNA encodes a secreted metalloprotease which is transcriptionally induced in Rat-1 cells by epidermal growth factor (EGF) and a number of oncogenes. A role for transin in tumor progression is suggested by its overexpression in malignant and metastatic tumors compared to their benign counterparts. In an effort to elucidate mechanisms by which elevated transin expression may be inhibited, it has been determined that both transforming growth factor type beta 1 (TGF beta 1) and increased levels of intracellular cyclic 5'-adenosine monophosphate (cAMP) inhibit EGF and oncogene induction of transin mRNA. The inhibition of transin mRNA occurred at the level of transcription as demonstrated by nuclear run-on assays. EGF binding studies in Rat-1 cells showed no significant effect of cAMP or TGF beta 1 on EGF receptor number or affinity. We have also examined the effects of cAMP and TGF beta 1 on oncogene-induced transin using Rat-1 cells transformed by temperature-sensitive mutants of v-src and K-ras oncogenes. Both inhibitors prevented the induction of transin RNA as well as decreased the levels of transin once elevated at the permissive temperature. Despite the similarities in the actions of TGF beta 1 and cAMP on transin gene expression, TGF beta 1 treatment did not significantly elevate intracellular cAMP levels, thus making it unlikely that cAMP is a second messenger system for TGF beta 1 action. These studies suggest that the inhibitory effects of cAMP and TGF beta 1 occur by distinct pathways at the level of gene regulation.
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PMID:Transforming growth factor beta 1 and cAMP inhibit transcription of epidermal growth factor- and oncogene-induced transin RNA. 284 55

47 tumor samples, 45 of which were obtained at thoracotomy for non-small cell lung cancer were examined for mutational activation of the oncogenes H-ras, K-ras, and N-ras. A novel, highly sensitive assay based on oligonucleotide hybridization following an in vitro amplification step was employed. ras gene mutations were present in nine of 35 adenocarcinomas of the lung (all K-ras), in two of two lung metastases of colorectal adenocarcinomas (1 x K-ras, 1 x N-ras) and in one adenocarcinoma sample obtained at autopsy (H-ras). All K-ras and H-ras mutations were in either position 1 or 2 of codon 12, while the N-ras mutation was in position 2 of codon 61. The potential clinical significance of K-ras activation was analyzed using the combined results of this and of our earlier study (S. Rodenhuis et al., New Engl. J. Med., 317: 929-935, 1987). Lung adenocarcinomas with K-ras mutations tended to be smaller and were less likely to have spread to regional lymph nodes at presentation. With a median follow up of 10 months, survival data are still immature. None of six adenocarcinomas of nonsmokers had a K-ras mutation and only one of four who had stopped smoking more than 5 years before. We conclude that mutational K-ras activation is present in about a third of adenocarcinomas of the lung and that the mutational event may be a direct result of one or more carcinogenic ingredients of tobacco smoke. Studies involving larger numbers of patients are required to confirm the association of K-ras activation with smoking and the inverse relation with tumor progression.
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PMID:Incidence and possible clinical significance of K-ras oncogene activation in adenocarcinoma of the human lung. 304 48

We have surveyed a panel of induced murine lymphomas for c-ras gene mutations. The K-ras gene seems to be preferentially activated in our system, and there are at least two examples of concomitant K- and N-ras gene mutations in the same tumor. This indicates that in some cases additional ras mutations may contribute to tumorigenesis and is evidence for a role of ras activation in tumor progression.
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PMID:Concomitant K- and N-ras gene point mutations in clonal murine lymphoma. 329 Jun 53

N- and K-ras oncogene mutations represent the most frequent molecular lesions in plasma cell dyscrasias. They are not randomly distributed since they are detectable in multiple myeloma (MM) (9-31%) and plasma cell leukemia (PCL) (30%), and not in monoclonal gammopathy of undetermined significance (MGUS) and solitary plasmacytoma (SP). Codons 12, 13 and 61 of N- and K-ras genes have been found mutated. Mutations affecting codon 61 of N-ras gene are the most frequent finding. A heterogeneous pattern of mutations is described with a prevalence of purine-pyrimidine transversions. Ras gene mutations have been predominantly detected in myelomas characterized by an advanced stage disease, and adverse prognostic parameters. These findings suggest that ras mutations represent a late molecular lesion and may be implicated in tumor progression rather than tumor initiation.
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PMID:N- and K-ras oncogenes in plasma cell dyscrasias. 785 96


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