Absolute values of ras p21 defined by direct binding liquid competition radioimmunoassays

Several distinct and high-conserved genes comprise the ras gene family of rodents and humans, i.e., rodent Harvey and Kirsten, and human Harvey, Kirsten and neuroblastoma. Transformation, either by a point-mutation resulting in a change in one amino acid of the 21 kDa ras gene product (p21), or by increased expression of ras p21, has been demonstrated to be mediated by members of this gene family. We report here the development of direct binding liquid competition radioimmunoassays for the detection and quantitation of the ras oncogene and proto-oncogene products. Using these radioimmunoassays and ras p21 purified from Escherichia coli containing the full-length T24 mutant human Harvey ras gene protein product as a standard, we have defined the actual amount of ras p21 per micrograms of total cellular protein, or per cell, in various ras transformed and 'normal' mammalian cell lines. One of the radioimmunoassays developed is group-specific, since the antigenic determinant recognized is shared by both the point-mutated and proto-forms of Harvey, Kirsten and neuroblastoma members of the ras gene family, while the second may be termed type-selective, since it recognizes an antigenic determinant localized primarily on the Harvey ras p21. Both radioimmunoassays are interspecies, since they detect a ras p21 antigenic determinant common to cells of human and rodent origin. These studies thus describe the first means for defining absolute values of any oncogene or proto-oncogene protein product. The assays described, when used in combination with specific c-DNA probes to define specific ras proto-oncogenes or point-mutated oncogenes being expressed, will now permit truly quantitative analyses of ras p21 expression in experimental cell culture systems, animal models and human biopsy material.     

Analysis of ras oncogene products by two-dimensional gel electrophoresis: evidence for protein families with distinctive molecular forms

Protein products of the ras family of oncogenes were immunoprecipitated by an anti-p21 monoclonal antibody, separated by two-dimensional gel electrophoresis and subsequently detected by western immunoblot analysis using the same anti-p21 monoclonal antibody as a probe. Using this method, a 21 kDa oncogene protein (p21) was detected and characterized in cell lines containing Harvey (Ha), Kirsten (Ki), neuroblastoma (N), or cellular (proto) ras genes. The ras gene products from all cell types occurred with multiple forms differing in size, charge or in both parameters. Transforming ras oncogene proteins occurred in easily identifiable groups that were different from each other in molecular weight and charge, were distinctive for each ras gene type and were different from cellular ras equivalents. Similar, but not identical, family groups occurred in different cell types containing the same oncogene. The reproducible occurrence of unpredicted p21 forms suggests that previously unreported post-translational processing steps may be associated with the synthesis of certain oncogene products. This immunoprecipitation/two-dimensional gel/western blot technique is a simple method for the identification and characterization of p21 gene products.     

Regional chromosomal localization of N-ras, K-ras-1, K-ras-2 and myb oncogenes in human cells

The identification of transforming genes in human tumor cells has been made possible by DNA mediated gene transfer techniques. To date, it has been possible to show that most of these transforming genes are activated cellular analogues of the ras oncogene family. To better understand the relationship between these oncogenes and other human genes, we have determined their chromosomal localization by analyzing human rodent somatic cell hybrids with molecularly cloned human proto-oncogene probes. It was possible to assign N-ras to chromosome 1 and regionally localize c-K-ras-1 and c-K-ras-2 to human chromosomes 6pter-q13 and 12q, respectively. These results along with previous studies demonstrate the highly dispersed nature of ras genes in the human genome. Previous reports indicated that the c-myb gene also resides on chromosome 6. It has been possible to sublocalize c-myb to the long arm of chromosome 6 (q15-q21). The non-random aberrations in chromosomes 1, 6 and 12 that occur in certain human tumors suggest possible etiologic involvement of ras and/or myb oncogenes in such tumors.     

The HL-60 transforming sequence: a ras oncogene coexisting with altered myc genes in hematopoietic tumors

The oncogene of the HL-60 human promyelocytic leukemia cell line has been passed serially through NIH/3T3 mouse fibroblasts. Oncogene-specific probes prepared from the resulting tertiary transfectants by molecular cloning have been used to show that loss of the transfected oncogene from NIH/3T3 cells correlates with reversion to nontransformed morphology. Analysis of cells transfected by the oncogenes of other tumors and tumor cell lines indicates that the transforming gene of the HL-60 leukemia cell line is closely related to oncogenes of a Burkitt's lymphoma, an acute myelogenous leukemia, an adenocarcinoma of the colon, a neuroblastoma, and two sarcomas. This oncogene is distantly related to the viral oncogenes of Kirsten and Harvey sarcoma viruses. It has been termed N-ras. The active N-ras oncogene coexists with altered versions of the myc oncogene in the HL-60 and AW Ramos human tumors. This suggests a multistep mechanism involving both ras and myc genes in the creation of these tumors.     

A monoclonal antibody reactive with an activated ras protein expressing valine at position 12

Activated ras transforming genes have been described in a variety of neoplasms and encode 21,000-Dalton (p21) proteins with amino acid substitutions at positions 12, 13, and 61. In this report we describe a monoclonal antibody designated DWP that reacts specifically with synthetic dodecapeptides containing valine at position 12, to a lesser extent with peptides containing cysteine at position 12 and not with peptides containing glycine, arginine, serine, aspartic acid, glutamic acid or alanine at the same position. Western blot and immunoperoxidase studies showed that DWP specifically reacts with activated rasH or rasK proteins in NIH cells transformed by DNA from the human carcinoma cells that encode valine at position 12. DWP did not react with normal p21s encoding glycine at position 12, nor with activated p21s encoding aspartic acid, glutamic acid, arginine, serine, or cysteine at position 12. A survey of human tumor cell lines demonstrated that DWP reacted with the human bladder carcinoma cell line T24 but not with human tumor cell lines previously shown to contain other activating mutations at positions 12 or 61. DWP and perhaps additional antibodies that specifically react with alterations at positions 12 or 61 of the ras protein may be valuable in determining the presence and frequency of activated ras proteins in human malignancy.     

Crystallization of human c-H-ras oncogene products

There is compelling evidence that cancer develops as a consequence of genetic changes (probably multiple) in some members of a selected set of cellular genes. DNA isolated from a variety of tumors, but not normal tissues, possesses the ability to malignantly transform non-tumorigenic cells. Many oncogenes responsible for such transformation have been isolated from transformed cell lines and animal and human tumors induced spontaneously, by virus, by chemical, or by radiation. The most commonly found transforming genes isolated from human tumor cells by DNA transfection assay are the ras gene family (c-H-ras, c-K-ras and N-ras). We report crystallization of several human c-H-ras oncogene proteins.     

Activation of a human c-K-ras oncogene

The human lung carcinomas PR310 and PR371 contain activated c-K-ras oncogenes. The oncogene of PR371 was found to present a mutation at codon 12 of the first coding exon which substitutes cysteine for glycine in the encoded p21 protein. We report here that the transforming gene of PR310 tumor contains a mutation in the second coding exon. An A----T transversion at codon 61 results in the incorporation of histidine instead of glutamine in the c-K-ras gene product. By constructing c-K-ras/c-H-ras chimeric genes we show that this point mutation is sufficient to confer transforming potential to ras genes, and that a hybrid ras gene coding for a protein mutant at both codons 12 and 61 is also capable of transforming NIH3T3 cells. The relative transforming potency of p21 proteins encoded by ras genes mutant at codons 12, 61 or both has been analyzed. Our studies also show that the coding exons of ras genes, including the fourth, can be interchanged and the chimeric p21 ras proteins retain their oncogenic ability in normal rodent established cell lines.     

Behavior of myc and ras oncogenes in transformation of rat embryo fibroblasts.

The requirements for transformation of rat embryo fibroblasts (REFs) by transfected ras and myc oncogenes were explored. Under conditions of dense monolayer culture, neither oncogene was able to transform REFs on its own. However, the introduction of a ras oncogene together with a selectable neomycin resistance marker into REFs allowed killing of the normal nontransfected cells and the outgrowth of colonies of ras transformants, 10% of which survived crisis and became tumorigenic. These cells expressed greater than 10-fold-higher levels of ras p21 than tumorigenic cells cotransfected with ras and myc oncogenes. The myc oncogene similarly was unable to induce tumorigenic conversion of REFs unless especially refractile colonies of oncogene-bearing cells, produced by use of a cotransfected selectable marker, were picked and subcultured. Tumorigenic conversion of REFs by single transfected oncogenes appears to require special culture conditions and high levels of gene expression.     

Saccharomyces cerevisiae synthesizes proteins related to the p21 gene product of ras genes found in mammals.

A family of normal vertebrate genes and oncogenes has been called the ras gene family. The name ras was assigned to this gene family based on the species of origin of the viral oncogenes of the rat-derived Harvey and Kirsten murine sarcoma viruses. There are now three known functional members of the ras gene family, and genes homologous to ras genes have been detected in the DNA of a wide variety of mammals and in Drosophila melanogaster. Prior experiments have detected proteins coded for by ras genes in a large number of normal cells, cell lines, and tumors. We report here the detection of ras-related proteins in D. melanogaster, a result predicted by the earlier detection of ras-related genes in the Drosophila genome. We also report for the first time the detection of ras-related proteins in a single-cell eucaryocyte, Saccharomyces cerevisiae. These proteins, approximately 30K in size, are recognized by both a monoclonal antibody which binds to the p21 coded for by mammalian ras genes and a polyclonal rat serum made by transplanting a v-Ha-ras-induced tumor in Osborne-Mendel rats. The p21 of v-Ha-ras and the 30K proteins from S. cerevisiae share methionine-labeled peptides as detected by two-dimensional tryptic peptide maps. The results indicate that S. cerevisiae synthesizes ras-related proteins. A genetic analysis of the function of these proteins for yeast cells may now be possible.     

RAS enzyme-linked immunoblot assay discriminates p21 species: a technique to dissect gene family expression

The members of the RAS gene family of protooncogenes are of implied biological significance in oncogenesis. The precise role of these genes is unclear. One difficulty has been the inability to discriminate the individual p21 protein products of various ras genes in cell lines, de novo human tumors, and related normal tissues. In this report, specific proteins of the human c-Ha-ras-1, c-Ki-ras-2, and c-N-ras genes have been detected and discriminated by the differential use of various antisera recognizing these p21s. This enzyme-linked immunoblot assay utilizes a double antibody system in which monoclonal antibodies are initially used to immunoprecipitate the p21ras proteins. Immunoprecipitates are then subjected to one-dimensional Western blot analysis utilizing other antibodies raised against p21s, coupled with nonradiolabeled enzyme-linked colorimetric detection. By direct detection, the specific products of the three human ras genes can be discriminated. In addition, we describe the generation and characterization of a new anti-p21c-N-ras-specific antibody. The simultaneous expression into protein of multiple ras genes is unequivocally demonstrated in both homogeneous cell lines and heterogeneous human tissues. This new technique is also applicable for discrimination of the protein products of other gene families.     

Activation of ras and myc proto-oncogenes in human breast carcinoma and neuroblastoma

DNA from human breast carcinoma (SK-BR-3) and neuroblastoma (LA-N-1) cell lines are capable of inducing foci of transformed NIH 3T3 cells after DNA-mediated gene transfer. The blot hybridization analysis of DNA from primary and secondary NIH 3T3 transformants identified additional sequences homologous to the c-Ha-ras 1 oncogene, and revealed amplification of nucleotide sequences homologous to the v-myc oncogene. Restriction fragments of the amplified myc-related sequences correspond to c-myc (SK-BR-3) and N-myc (LA-N-1) loci of the human genome. The results show that active Ha-ras oncogenes can coexist with altered myc oncogenes in breast carcinomas and neuroblastomas. This suggests that a multi-step mechanism involves both ras and myc genes and their cooperation in the development of these tumors.     

The ras gene family and human carcinogenesis

It has been well established that specific alterations in members of the ras gene family, H-ras, K-ras and N-ras, can convert them into active oncogenes. These alterations are either point mutations occurring in either codon 12, 13 or 61 or, alternatively, a 5- to 50-fold amplification of the wild-type gene. Activated ras oncogenes have been found in a significant proportion of all tumors but the incidence varies considerably with the tumor type: it is relatively frequent (20-40%) in colorectal cancer and acute myeloid leukemia, but absent or present only rarely in, for example, breast tumors and stomach cancer. No correlation has been found, yet, between the presence of absence of an activated ras gene and the clinical or biological features of the malignancy. The activation of ras oncogenes is only one step in the multistep process of tumor formation. The presence of mutated ras genes in benign polyps of the colon indicates that activation can be an early event, possibly even the initiating event. However, it can also occur later in the course of carcinogenesis to initiate for instance the transition of a benign polyp of the colon into a malignant carcinoma or to convert a primary melanoma into a metastatic tumor. Apparently, the activation of ras genes is not an obligatory event but when it occurs it can contribute to both early and advanced stages of human carcinogenesis.     

Oncogene and tumor suppressor gene alterations in nasal tumors

The development of nasal tumors in humans and rodents is likely mediated through the accumulation of genetic alterations in genes that regulate cell proliferation, cell death and differentiation (oncogenes and tumor suppressor genes). By examination of the relationship between genetic alterations that are known to occur in human cancers with those induced in rodent tumors with defined carcinogenic exposures, biologically relevant mechanistic linkages of molecular events leading to tumors in rodents and humans can be established. Molecular genetic studies on nasal squamous cell carcinomas (SCC) in rats thus far have indicated the presence of oncogenes unrelated to the ras oncogene family and that p53 mutation occurs at a high frequency among the nasal SCC examined. The finding of p53 mutations in rat nasal SCC and the high prevalence of p53 mutations among human SCC, indicates that a common molecular alteration is shared between rodent and human SCC.     

Janus faces of ras: anti or pro-apoptotic?

Cell population homeostasis is a balance between cell proliferation on one hand and the rate of cell loss on the other hand. Normal tissue homeostasis requires the physiological deletion of cells by activation of apoptosis, a genetically determined program of autonomous cell death. ras is most probably the most important oncogene in human cancer. It is mutated in 30% of all tumors especially those of the gastrointestinal tract. In regulating apoptosis ras has many faces. it has both negative and positive effects depending on the stimulation and cell type. The responses of cells to ras signaling depends on the level of Ras expression, the activity of various pathways, and which of the cell cycle check points are functioning. New farnesyl transferase inhibitors and non-steroidal anti-inflammatory compounds may provide a new strategy for novel therapeutic modalities in the treatment of human cancer. The first clinical trials have been initiated, preliminary results are promising, although no firm results are yet available.     

Activated N-ras controls the transformed phenotype of HT1080 human fibrosarcoma cells

To investigate whether the activated N-ras oncogene of HT1080 human fibrosarcoma cells contributes to the expression of the transformed phenotype, we have isolated flat revertants. In two independent revertant lines, an increase in chromosomal ploidy occurred without a concomitant increase in the number of copies of the N-ras transforming allele. Immunoprecipitation confirms that the level of the mutant N-ras p21 gene product in the revertants is correspondingly lower than in HT1080. Analysis of sporadic tumors derived from the revertant cells reveals an increased dosage of the transforming allele. The revertants also retransform after transfection of cloned activated ras oncogenes. These results imply direct participation of an N-ras oncogene in maintaining the transformed phenotype of a human tumor cell line.     

甲胎蛋白对HeLa细胞N-ras、p53和p21~(ras)表达的促进作用

大量研究已证明甲胎蛋白 (alpha fetoprotein ,AFP)对肿瘤细胞的增殖具有调节作用 .为探讨AFP对细胞生长促进作用的分子机理 ,采用从人脐带血中提取的AFP作用于体外培养的HeLa细胞 ,用Northern印迹分析法分析不同作用时间时细胞N rasmRNA的表达以及用Western印迹分析法分析p5 3、p2 1ras的表达 .结果发现 ,在AFP(2 0mg L)作用后 ,HeLa细胞的N rasmRNA、p5 3蛋白质和p2 1ras蛋白质的表达量与对照组比较在 12h和 2 4h时都有明显增加 .AFP的作用均可被抗AFP单克隆抗体所拮抗 .实验结果提示 ,AFP对细胞生长的调节作用可能通过促进这些原癌基因的表达来实现 .