DNA and RNA from Uninfected Vertebrate Cells Contain Nucleotide Sequences Related to the Putative Transforming Gene of Avian Myelocytomatosis Virus

The avian carcinoma virus MC29 (MC29V) contains a sequence of approximately 1,500 nucleotides which may represent a gene responsible for tumorigenesis by MC29V. We present evidence that MC29V has acquired this nucleotide sequence from the DNA of its host. The host sequence which has been incorporated by MC29V is transcribed into RNA in uninfected chicken cells and thus probably encodes a cellular gene. We have prepared radioactive DNA complementary to the putative MC29V transforming gene (cDNA(mc) (29)) and have found that sequences homologous to cDNA(mc) (29) are present in the genomes of several uninfected vertebrate species. The DNA of chicken, the natural host for MC29V, contains at least 90% of the sequences represented by cDNA(mc) (29). DNAs from other animals show significant but decreasing amounts of complementarity to cDNA(mc) (29) in accordance with their evolutionary divergence from chickens; the thermal stabilities of duplexes formed between cDNA(mc) (29) and avian DNAs also reflect phylogenetic divergence. Sequences complementary to cDNA(mc) (29) are transcribed into approximately 10 copies per cell of polyadenylated RNA in uninfected chicken fibroblasts. Thus, the vertebrate homolog of cDNA(mc) (29) may be a gene which has been conserved throughout vertebrate evolution and which served as a progenitor for the putative transforming gene of MC29V. Recent experiments suggest that the putative transforming gene of avian erythroblastosis virus, like that of MC29V, may have arisen by incorporation of a host gene (Stehelin et al., personal communication). These findings for avian erythroblastosis virus and MC29V closely parallel previous results, suggesting a host origin for src (D. H. Spector, B. Baker, H. E. Varmus, and J. M. Bishop, Cell 13:381-386, 1978; D. H. Spector, K. Smith, T. Padgett, P. McCombe, D. Roulland-Dussoix, C. Moscovici, H. E. Varmus, and J. M. Bishop, Cell 13:371-379, 1978; D. H. Spector, H. E. Varmus, and J. M. Bishop, Proc. Natl. Acad. Sci. U.S.A. 75:4102-4106, 1978; D. Stehelin, H. E. Varmus, J. M. Bishop, and P. K. Vogt, Nature [London] 260:170-173, 1976), the gene responsible for tumorigenesis by avian sarcoma virus. Avian sarcoma virus, avian erythroblastosis virus, and MC29V, however, induce distinctly different spectra of tumors within their host. The putative transforming genes of these viruses share no detectable homology, although sequences homologous to all three types of putative transforming genes occur and are highly conserved in the genomes of several vertebrate species. These data suggest that evolution of oncogenic retroviruses has frequently involved a mechanism whereby incorporation and perhaps modification of different host genes provides each virus with the ability to induce its characteristic tumors.     

Chromosomal localisation of the human homologues to the oncogenes erbA and B.

Avian erythroblastosis virus (AEV) induces acute erythroleukemia and sarcomas in vivo and it transforms erythroblasts and fibroblasts in vitro. The virus has two host cell-derived genes, v-erbA and v-erbB. The latter encodes the oncogenic capacity of the virus, whereas v-erbA enhances the erythroblast transforming effects of v-erbB while being unable to induce neoplasms independently. Recently, human cellular homologues of these viral erb genes have been isolated. The chromosomal locations of two of these genes have been determined using EcoRI-digested DNA prepared from human-mouse somatic cell hybrids. The human c-erbA1 gene has been assigned to chromosome 17 and is located between 17p11 and 17q21. The human c-erbB sequence has been assigned to chromosome 7 and is located between 7pter and 7q22. Thus, in the human genome these genes are on two separate chromosomes. No evidence for the involvement of the human c-erb genes in neoplasia has been found.     

Ubiquitin is a heat shock protein in chicken embryo fibroblasts.

Clones containing heat-inducible mRNA sequences were selected from a cDNA library prepared from polyadenylated RNA isolated from heat-shocked chicken embryo fibroblasts. One recombinant DNA clone, designated clone 7, hybridized to a 1.2-kilobase RNA that was present in normal cells and increased fivefold during heat shock. Clone 7 also hybridized to an RNA species of 1.7 kilobases that was present exclusively in heat-shocked cells. In vitro translation of mRNA hybrid selected from clone 7 produced a protein product with a molecular weight of approximately 8,000. Increased synthesis of a protein of similar size was detected in chicken embryo fibroblasts after heat shock. DNA sequence analysis of clone 7 indicated its protein product has amino acid sequences identical to bovine ubiquitin. In addition, clone 7 contains tandem copies of the ubiquitin sequences contiguous to each other with no untranslated sequences between them. We discuss some possible roles for ubiquitin in the heat shock response.     

Effects of inhibitors of glycoprotein processing on the synthesis and biological activity of the erb B oncogene.

Three glycoprotein-processing inhibitors were used to resolve whether correct glycosylation was required for the oncogenic activity of erb B. The two glucosidase-I inhibitors, 1-deoxynojirimycin and 2,5-dihydroxymethyl 3,4-dihydroxypyrrolidine, arrested processing of v-erb B at the immature 68-kd form whereas, in the presence of the alpha-mannosidase-II inhibitor (swainsonine), cells synthesised an abnormally processed 70-kd form of v-erb B. Transport of incorrectly processed v-erb B to the cell surface was, however, unaffected, suggesting that correct processing is not a prerequisite for intracellular routing of v-erb B. Two systems were used to assess whether incorrectly processed erb B could maintain the transformed state. The first asked whether inhibitor treatment would release temperature-sensitive avian erythroblastosis virus (AEV) transformed erythroblasts kept at the viral permissive temperature from the erb B-induced block in differentiation, as seen when cells are normally shifted to the non-permissive temperature. The second tested the ability of AEV-transformed fibroblasts to grow in soft agar. In both systems, all three processing inhibitors did not alter the transformed phenotype suggesting that correct carbohydrate processing is not required for the transforming activity of erb B. In addition, none of the three processing inhibitors were found to have any effect on the normal maturation of bone marrow CFU-E or induced differentiation of temperature-sensitive AEV-transformed erythroblasts.     

The sequence and expression of the divergent beta-tubulin in chicken erythrocytes

We report here the complete sequence of a highly divergent chicken erythrocyte beta-tubulin, c beta 6, which appears to represent a major exception to the observation that the primary sequences and sites of expression of beta-tubulin isotypes are conserved within vertebrates. The amino acid sequence was deduced from overlapping cloned cDNAs identified in a chicken erythroblast cDNA library contained in the expression vector, lambda gt11. Compared with other chicken beta-tubulins, among which the maximum sequence divergence is only 8%, c beta 6-tubulin is more hydrophobic, contains seven fewer net negative charges, and exhibits a surprising 17% overall divergence in its amino acid sequence. DNA and RNA blot analyses show that c beta 6-tubulin is present as a single gene copy in the chicken genome and is specifically expressed in the bone marrow. Comparisons of RNA blots and immunoblots of various cells and tissues confirm that this beta-tubulin isotype is contained specifically in erythrocytes and thrombocytes and accounts for 75% of the beta-tubulin mRNA species contained in developing erythroblasts. Interestingly, c beta 6-tubulin exhibits 18% amino acid sequence divergence relative to MB1, the analogous hematopoietic beta-tubulin contained in mouse.     

Deletion mapping of Sindbis virus DI RNAs derived from cDNAs defines the sequences essential for replication and packaging

Defective-interfering (DI) genomes of a virus contain sequence information essential for their replication and packaging. They need not contain any coding information and therefore are a valuable tool for identifying cis-acting, regulatory sequences in a viral genome. To identify these sequences in a DI genome of Sindbis virus, we cloned a cDNA copy of a complete DI genome directly downstream of the promoter for the SP6 bacteriophage DNA dependent RNA polymerase. The cDNA was transcribed into RNA, which was transfected into chicken embryo fibroblasts in the presence of helper Sindbis virus. After one to two passages the DI RNA became the major viral RNA species in infected cells. Data from a series of deletions covering the entire DI genome show that only sequences in the 162 nucleotide region at the 5' terminus and in the 19 nucleotide region at the 3' terminus are specifically required for replication and packaging of these genomes.     

Structure and erythroid cell-restricted expression of a chicken cDNA encoding a novel zinc finger protein of the Cys+His class

We report the cloning, sequence analysis and expression pattern of chGfi, a zinc finger protein (Zfp)-encoding cDNA that was isolated from a cDNA library constructed with RNA from avian erythroblastosis virus (AEV)-transformed primary chicken erythroblasts. The 1387-bp-long chGfi cDNA encodes a full-length 337-amino-acid (aa) protein that contains six zinc fingers (Zf) of the 2Cys+2His class at its C-terminus. Immunoblotting experiments with extracts from bone marrow cells detected a 38-kDa protein that corresponds to the M_r of 38 690 calculated for the protein deduced from chGfi. The chGfi protein is most homologous to the rat Gfi-1 showing a sequence similarity of 92% over the Zf region and only two exchanges within the N-terminal 19 aa that constitute the Gfi-1 repressor domain. Expression of chGfi is only detected in transformed primary erythroblasts, in erythroid cells of the primitive and definitive lineage and in bone marrow cells. chGfi activity does not vary significantly during differentiation of transformed primary erythroblasts of the definitive lineage. No chGfi expression is detected in cells of the myeloid and lymphoid lineages or in a total of nine different organs of adult origin. Our results indicate that chGfi expression is restricted to erythroid cells of the primitive and definitive lineage.     

Avian erythroblastosis virus produces two mRNA''s.

We analyzed the viral mRNA's present in fibroblast nonproducer clones transformed by avian erythroblastosis virus. Two size classes of mRNA (28 to 30S and 22 to 24S) were identified by solution hybridization with both complementary DNA strong stop and complementary DNA made against the unique sequences of avian erythroblastosis virus. Based upon the kinetics of hybridization with complementary DNA made against the unique sequences of avian erythroblastosis virus, we estimated that there were 400 to 500 copies of the 28 to 30S RNA per cell and 200 to 250 copies of the 22 to 24S RNA per cell. Both RNA species were packaged in the virion. In vitro translation of the 28 to 30S virion RNA yielded a 75,000-dalton protein which was the 75,000-dalton gag-related polyprotein found in avian erythroblastosis virus-transformed cells. In vitro translation of the 22 to 24S virion RNA yielded two proteins (46,000 and 48,000 daltons). This indicates that there may be two genes in avian erythroblastosis virus, one coding for the 75,000-dalton gag-related polyprotein and the second coding for the 46,000- or 48,000-dalton protein or both.     

Characterization of c-lil, a chicken cellular sequence associated with a stock of B77 avian sarcoma virus.

Using biochemical methods, we have shown that a new specific sequence, v-lil, is associated with a given stock of B77 avian sarcoma virus (clone 9). We prepared a DNA complementary to v-lil sequences, using substractive hybridizations, and investigated the properties of this sequence. v-lil has a genetic complexity of ca. 2,000 nucleotides and is not present in various stocks of avian sarcoma virus, avian leukosis virus, or defective leukemia virus. v-lil is not associated with B77 avian sarcoma virus isolated from the original tumor and thus has been acquired by in vitro passage of the virus on chicken embryo fibroblasts. A search for the origin of the v-lil sequence among the DNAs of different avian species has shown that a similar sequence, c-lil, is present in normal chicken DNA (1 to 2 copies per haploid genome). c-lil is not highly conserved but is present in the DNA of all chickens from the genus Gallus. The c-lil sequence is transcribed at a low level (1 to 3 copies per cell) in normal chicken embryo fibroblasts. The biological function, if any, of v-lil or its cellular equivalent has yet to be determined.     

Cell-free translation of avian erythroblastosis virus RNA

Avian erythroblastosis virus (AEV) RNA rescued from nonproducer cells by superinfection with a helper virus is translated into three polypeptides in the messenger-dependent rabbit reticulocyte lysate. A 75,000 molecular weight polypeptide (P75AEV) is synthesized from 28S RNA and is encoded by the 5' section of the AEV RNA, including gag-related and AEV-specific sequences. The P75AEV synthesized in infected cells and the P75AEV synthesized in the cell-free system are electrophoretically identical. A 44,000 molecular weight polypeptide (P44AEV) is synthesized from 20-24S RNA, apparently from the 3' section of the AEV-specific RNA sequence. A minor 37,000 molecular weight polypeptide (P37AEV) is synthesized from 20S AEV RNA. A comparison is drawn between the cell-free products of MC29 and AEV RNAs.     

Homology between avian oncornavirus RNAs and DNA from several avian species.

3H-labeled 35S RNA from avian myeloblastosis virus (AMV), Rous associated virus (RAV)-0, RAV-60, RAV-61, RAV-2, or B-77(w) was hybridized with an excess of cellular DNA from different avian species, i.e., normal or leukemic chickens, normal pheasants, turkeys, Japanese quails, or ducks. Approximately two to three copies of endogenous viral DNA were estimated to be present per diploid of normal chicken cell genome. In leukemic chicken myeloblasts induced by AMV, the number of viral sequences appeared to have doubled. The hybrids formed between viral RNA and DNA from leukemic chicken cells melted with a Tm 1 to 6 C higher than that of hybrids formed between viral RNA and normal chicken cell DNA. All of the viral RNAs tested, except RAV-61, hybridized the most with DNA from AMV-infected chicken cells, followed by DNA from normal chicken cells, and then pheasant DNA. RAV-61 RNA hybridized maximally (39%) with pheasant DNA, followed by DNA from leukemic (34%), and then normal (29%) chicken cells. All viral RNAs tested hybridized little with Japanese quail DNA (2 to 5%), turkey DNA (2 to 4%), or duck DNA (1%). DNA from normal chicken cells contained only 60 to 70% of the RAV-60 genetic information, and normal pheasant cells lacked some RAV-61 DNA sequences. RAV-60 and RAV-61 genomes were more homologous to the RAV-0 genome than to the genome of RAV-2, AMV, or B-77(s). RAV-60 and RAV-61 appear to be recombinants between endogenous and exogenous viruses.     

Quail (Coturnix japonica) protamine, full-length cDNA sequence, and the function and evolution of vertebrate protamines

Using the chicken protamine gene as a probe, we have isolated and sequenced several positive clones from a quail testis cDNA library which reveal the complete sequence for the quail protamine cDNA. The predicted amino acid sequence for the quail protamine contains the N-terminal tetrapeptide ARYR present in the N-terminal region of the mammalian protamines as well as several conserved motifs and arginine clusters. In addition the size of the quail protamine (56 amino acids) is closer to that of mammals (50 amino acids) than that of the chicken (61 amino acids). Altogether this data strongly suggests the existence of an avian-mammalian protamine gene line during evolution. Southern blot analysis suggests a small number of copies (2) per haploid genome (similar to that of chicken). The reported quail protamine cDNA sequence is the second avian protamine for which the amino acid sequence is available so far and provides new insights into vertebrate protamine function and evolution.     

Cell transformation by a virus containing a molecularly constructed gag-erbB fused gene.

A provirus DNA that contains a gag-erbB fused gene as the sole and transforming gene was molecularly constructed from plasmid pSRA2 containing the entire genome of Rous sarcoma virus and pAE7.7 containing the entire genome of an avian erythroblastosis virus (AEV), AEV-H. A virus containing the gag-erbB fused gene (GEV) was recovered from chicken embryo fibroblasts transfected with the proviral DNA and a helper virus DNA. GEV could transform chicken embryo fibroblasts as efficiently as could AEV-H. Anti-erbB and anti-gag sera immunoprecipitated a protein with a molecular weight of about 110,000 from GEV-transformed cells. The erbB and gag-erbB fused-gene products in AEV-H- and GEV-transformed cells were analyzed.     

Sequence complexity of poly(A) RNA fromPhysarum polycephalum

Summary Poly(A) RNA from S phase, G₂ phase and starved macroplasmodia of Physarum contain mRNA sequences which when translated in vitro, yield similar patterns of polypeptides after fluorography.Reassociation of nick-translated DNA (Cot) allows the isolation of highly labeled single copy DNA which, after saturation hybridization with poly(A) RNA, gives values of 23% for growth and 17% for starvation.Homologous cDNA/poly(A) RNA hybridization reactions (Rot) indicate that 22–28% of the genome is transcribed during growth and 12% during starvation and that about half of the cDNA reacts with 0.1% of the genome and could represent 50–80 RNA species, each present in about 1,000 copies per nucleus. Up to 25,000 different RNA species, 1–5 copies each per nucleus, are estimated to be present during growth, and about 15,000 during starvation. Heterologous cDNA/poly(A) RNA hybridization reactions (Rot) indicate that the RNA sequences in S and G₂ phase of the cell cycle are similar, with RNA sequences being more abundant in G₂ phase.During starvation about 25% of the sequences present during growth cannot be detected and those sequences present during growth have become diluted during starvation.     

Species specificity and developmental patterns of expression of the beta amyloid precursor protein (APP) gene in brain, liver and choroid plexus in birds.

1. Human APP cDNA hybridized to a 3.5 kb mRNA in liver and brain RNA from chickens, pigeons, quail and ducks as well as in RNA from choroid plexus of chicken and quail. In contrast to all other species hitherto examined a 1.6 kb mRNA hybridizing to APP cDNA was found in abundant amounts in RNA from chicken and quail livers. 2. In the chicken, before hatching, the levels of APP mRNA in total RNA from liver and choroid plexus were higher than those in RNA from liver and choroid plexus of adults. However, RNA from the rest of the brain of chicken embryos contained less APP mRNA than RNA from brain of adults. 3. In the chicken, between 10 and 40 days after hatching, APP mRNA levels in RNA from liver were higher than adult levels, APP mRNA levels in RNA from choroid plexus were similar to adult levels and APP mRNA levels in RNA from the rest of brain were below the adult levels.