Comparison of the trans-activation capabilities of the human T-cell leukemia virus type I and II chi proteins

The mechanism of cellular transformation by the human T-cell leukemia viruses (HTLVs) is thought to involve a novel retrovirus gene known as chi. The chi gene is essential for HTLV replication and acts by enhancing transcription from the viral long terminal repeat. By using the HTLV type I and II chi gene-coding regions inserted into a highly efficient expression vector, we directly compared the efficiencies of the two chi proteins to trans activate the HTLV type I and II long terminal repeats. We demonstrate that the two chi proteins have different patterns of trans activation. The patterns were highly reproducible in all mammalian cells tested. A different pattern of activation was observed in avian cells. These results suggest that the mechanism of trans activation involves specific cellular factors that are highly conserved throughout mammalian species but different in avian cells. Understanding the mechanism of trans activation by the chi gene product may provide insights into mechanisms of cellular transformation by HTLV.

Studies of the human c-myb gene and its product in human acute leukemias

The myb gene is the transforming oncogene of the avian myeloblastosis virus (AMV); its normal cellular homolog, c-myb, is conserved across a broad span of evolution. In humans, c-myb is expressed in malignant hematopoietic cell lines and in primary hematopoietic tumors. Partial complementary DNA clones were generated from blast cells of patients with acute myelogenous leukemia. The sequences of the clones were compared to the c-myb of other species, as well as the v-myb of AMV. In addition, the carboxyl terminal region of human c-myb was placed in an expression vector to obtain protein for the generation of antiserum, which was used to identify the human c-myb gene product. Like v-myb, this protein was found within the nucleus of leukemic cells where it was associated with the nuclear matrix. These studies provide further evidence that c-myb might be involved in human leukemia.

Identification and characterization of the protein encoded by the human N-myc oncogene

The human N-myc gene is related to the c-myc proto-oncogene, and has been shown to have transforming potential in vitro. Many studies have reported amplification of N-myc in human neuroblastoma and retinoblastoma cell lines. In primary tumors, amplification of the gene was found to correlate directly with behavior of the tumor. Specific restriction fragments of a partial complementary DNA clone of N-myc from LA-N-5 human neuroblastoma cells were placed into a bacterial expression vector for the purpose of producing antigens representative of the N-myc protein. Rabbits immunized with these antigens produced antisera that recognized a protein of 62-64 kilodaltons in neuroblastoma cells. By several criteria, this protein appears to be part of the same proto-oncogene family as the c-myc protein. Moreover, the antisera to fragments of this protein were capable of histochemically identifying malignant cells in clinical specimens.

Organ specific expression of ras oncoproteins during growth and development of the rat

Expression of proteins encoded by the ras proto-oncogenes was examined in extracts from normal rat organs using anti-ras p21 antibodies generated against synthetic peptides. The highest level of ras p21 was found in brain (cerebrum) and was predominantly of c-Ha-ras origin. Levels of brain ras p21 did not vary from the newborn period of 3 months of age. Moderate levels of ras p21s were detected in lung, spleen and thymus. In contrast to the p21 in brain, these levels varied with the age of the rats and were encoded by other members of ras proto-oncogene family (Ki-ras or N-ras). This organ specific expression of different ras genes might be related to developmental control of gene expressions.

Expression of p21 ras oncoproteins in human cancers

The expression of proteins encoded by ras oncogenes was examined in 52 fresh human tumors of 19 different types using antibodies generated to different peptide domains of ras proteins of molecular weight 21,000 (p21). Proteins related to ras genes were detected in 90% of tested tumors. In 21% of tumors there were high levels of ras p21 of greater than 40% of the level in a Harvey murine sarcoma virus transformed cell line. Predominance of either cellular Ha-ras or other ras p21s was found in 20 and 14% of tumors, respectively, and predominance of p21 other than Ha-ras was frequent in breast cancers. Abnormal electrophoretic mobility of p21 was observed in two cancers, and a novel rapidly migrating ras p21 was found in a rare malignant fibrohistiocytoma.

The x gene is essential for HTLV replication

The human T-cell leukemia viruses (HTLV) are associated with T-cell malignancies in man and will transform normal human T cells in vitro. The mechanism of malignant transformation by HTLV is unknown but appears to be distinct from that of other classes of retroviruses, which induce malignant transformation through viral or cellular oncogenes. Recently a new gene, termed x, was identified in HTLV. This gene has been hypothesized to be the transforming gene of HTLV because of its conservation within the HTLV class of retroviruses. By in vitro mutagenesis of the HTLV-II x gene, it is now demonstrated that the presence of a functional x gene product is necessary for efficient HTLV transcription. Therefore, these studies provide direct evidence for an important function of the x gene in HTLV replication. The functional analogies between the x gene and transcriptional regulatory genes of some DNA viruses suggest that these viruses share similar mechanisms for cellular transformation.

Studies of the putative transforming protein of the type I human T-cell leukemia virus

The putative transforming protein of the type I human T-cell leukemia virus (HTLV-1) is a 40-kilodalton protein encoded by the X region and is termed p40XI. On the basis of both subcellular fractionation techniques and immunocytochemical analysis, it is now shown that p40XI is a nuclear protein with a relatively short half-life (120 minutes). It is synthesized de novo in considerable quantities in a human T-cell line infected with and transformed by the virus in vitro, and it is not packaged in detectable amounts in the extracellular virus.

Efficient generation of antibodies to oncoproteins by using synthetic peptide antigens

To examine the efficiency of generating protein-reactive antipeptide antibodies, 35 peptides encoded by retroviral or cellular oncogenes were used to immunize rabbits. Thirty-two peptides elicited antipeptide antibodies, of which 56% reacted with their respective oncoproteins. The length of the immunizing peptide was an important factor in generating antibodies reactive with native protein. Similar peptides differing in a single or a few amino acids could elicite antisera of markedly different reactivities.

Expression of cellular oncogenes during embryonic and fetal development of the mouse

Cellular oncogenes are conserved with great fidelity across a broad span of evolution. This avid conservation suggests possible roles in critical physiologic functions. Little, however, is known about their activity in normal cellular processes. In this study, we examined the expression pattern of eight cellular oncogenes during embryonic and fetal development of the mouse. Five of these genes (c-myc, c-erb, c-Ha-ras, c-src, and c-sis) were expressed at appreciable levels, and four were modulated in a consistent manner during the course of prenatal development.

Identification of the putative transforming protein of the human T-cell leukemia viruses HTLV-I and HTLV-II

The human T-cell leukemia viruses HTLV-I and HTLV-II are unique among the transforming retroviruses of vertebrates in their ability to transform human T cells in vitro and in their close association with human malignancies (T-cell lymphomas and leukemia). Their genomes are relatively simple, containing the genes gag, pol, env, and a 3' region termed "X." This 3' region may be responsible for the transforming potential of the viruses. The existence of proteins encoded by the 3' region has been postulated on the basis of multiple open reading frames. In the present study this region is shown to contain a gene encoding a protein of 40 kilodaltons in HTLV-I and 37 kilodaltons in HTLV-II. It is proposed that these proteins be called, respectively, p40xI and p37xII.

Oncogenes: implications for the diagnosis and treatment of cancer

Cellular oncogenes comprise a small family of genes, highly conserved throughout vertebrate evolution, that code for proteins with diverse functions including DNA binding, protein kinase, and cellular growth factor activities. Cellular oncogenes are important in certain aspects of the proliferation and differentiation of normal cells. Under some circumstances these genes may also induce malignant transformation of normal cells. Various mechanisms may underlie their involvement in carcinogenesis. Incorporation of all, or part of, cellular oncogenes into RNA tumor viruses, mutations in gene structure, or translocation of cellular oncogenes from one chromosome to another may all be associated with the induction of malignant change in cells. In some of these situations altered oncogene products are made. Knowledge about the biology of oncogenes may lead to improved techniques for cancer detection and perhaps new approaches to cancer treatment.

Expression of cellular oncogenes in human malignancies

Cellular oncogenes have been implicated in the induction of malignant transformation in some model systems in vitro and may be related to malignancies in vivo in some vertebrate species. This article describes a study of the expression of 15 cellular oncogenes in fresh human tumors from 54 patients, representing 20 different tumor types. More than one cellular oncogene was transcriptionally active in all of the tumors examined. In 14 patients it was possible to study normal and malignant tissue from the same organ. In many of these patients, the transcriptional activity of certain oncogenes was greater in the malignant than the normal tissue. The cellular fes (feline sarcoma) oncogene, not previously known to be transcribed in mammalian tissue, was found to be active in lung and hematopoietic malignancies.

Transcription of c-onc genes c-rasKi and c-fms during mouse development

We investigated the expression of cellular sequences c-rasKi and c-fms, which are homologous to the oncogenes of Kirsten rat sarcoma virus and the McDonough strain of feline sarcoma virus, during murine development and in a variety of mouse tissues. The c-rasKi gene was found to be transcribed into two mRNA species of approximately 2.0 and 4.4 kilobases, whereas a single c-fms-related transcript of approximately 3.7 kilobases was identified. The c-rasKi gene appeared to be expressed ubiquitously, since similar levels of transcripts were observed in embryos, fetuses, extraembryonal structures, and a variety of postnatal tissues. In contrast, significant expression of c-fms was found to be confined to the placenta and extraembryonal membranes (i.e., combined yolk sac and amnion). The concentration of c-fms transcripts in the placenta increased approximately 15-fold (relative to day-7 to day-9 conceptuses) during development before reaching a plateau at day 14 to 15 of gestation. The time course of cfms expression in the extraembryonal membranes appeared to parallel the stage-specific pattern observed in the placenta. The level of c-fms transcripts in the extraembryonal tissues reached a level which was approximately 20- to 50-fold greater than that in the fetus. These findings suggest that the c-fms gene product may play a role in differentiation of extraembryonal structures or in transport processes occurring in these tissues. Our results indicate that the c-onc genes analyzed in the present study exert essentially different functions during mouse development.

Insertion of new genetic information into bone marrow cells of mice: comparison of two selectable genes

A system for insertion of new genetic information into mouse hematopoietic cells is described. Two selectable genes were examined: herpesvirus thymidine kinase and a mutant mouse dihydrofolate reductase. The DHFR system appears to be superior in terms of the frequency and stability of gene insertion and expression in hematopoietic tissues. About 70% of mice had indirect (karyotypic) evidence of gene insertion; of these, about 60% (three of five) had stable expression of the inserted mutant DHFR. In contrast, only 13% of mice demonstrated stable karyotypic transformation by HSVtk, and of those with stable transformation five of seven showed persistent viral gene sequences in hematopoietic tissues.

Hemolytic anemia induced by murine erythroblastosis virus: possible mechanisms of hemolysis and effects of an interferon inducer

Murine erythroblastosis virus (MuEV), also called murine leukemia virus-Kirsten, is a member of the murine type-C-RNA leukemia-sarcoma group of oncogenic viruses. Like other members of this group, MuEV can elicit both a hemolytic disorder and an oncogenic response. Neonatal rats infected with MuEV succumb to this hemolytic disorder unless they are treated with the synthetic double-stranded polyribonucleotide, polyinosinic-polycytidylic acid (poly I-poly C). Animals receiving poly I-poly C had markedly reduced levels of virus reproduction as measured by bioassay and electron microscopy. The proliferation of erythroblasts after MuEV infection in animals not receiving poly I-poly C appeared to be an erythropoietin-dependent compensatory response to hemolysis. The hemolysis itself seemed to require virus reproduction in the cell types affected. Administration of poly I-poly C to MuEV-infected rats inhibited virus reproduction and thus may circumvent the hemolytic disease syndrome. The ultrastructure of the virus and of the virus reproduction was also studied.