Nucleotide sequence of acceptor site and termini of integrated avian endogenous provirus ev1: integration creates a 6 bp repeat of host DNA

Nucleotide sequences of the murine retrovirus Friend SFFVp long terminal repeats: identification of a structure with extensive dyad symmetry 5' to the TATA box

The two long terminal repeats (LTRs) of the integrated provirus of the polycythemia strain of the Friend spleen focus forming virus have been sequenced. Each of the identical LTRs is 514 nucleotides long and together confer on the provirus the features of a transposable element. They are terminated by perfect 11 base-pair inverted repeats, and the entire provirus is flanked by an apparent duplication of host DNA four nucleotides long. The assumed transcription regulatory sequences (Hogness-Goldberg box, CAAT box, polyadenylation signal) can be identified within the LTRs, as well as a region of an imperfect inverted repeat which extends from approximately 140 to 270 nucleotides 5' from the point of transcription initiation. This sequence may form a hairpin-type structure which might have some function in the promotion of transcription.

Form and function of retroviral proviruses

Retroviruses have proved to be useful reagents for studying genetic and epigenetic (such as regulatory) changes in eukaryotic cells, for assessing functional and structural relationships between transposable genetic elements, for inducing insertional mutations, including some important in oncogenesis, and for transporting genes into eukaryotic cells, either after natural transduction of putative cellular oncogenes or after experimental construction of recombinant viruses. Many of these properties of retroviruses depend on their capacity to establish a DNA (proviral) form of their RNA genomes as a stable component of host chromosomes, in either somatic or germinal cells.

Infectivity and structure of molecular clones obtained from two genetically transmitted Moloney leukemia proviral genomes

The Mov-2 and Mov-10 substrains of mice, each carrying Moloney leukemia virus (= M-MuLV) in their germ line at the Mov-2 and Mov-10 locus, respectively, do occasionally at a later age (Mov-2) or not at all (Mov-10) activate infectious virus. The M-MuLV proviruses with flanking mouse sequences corresponding to the Mov-2 and Mov-10 locus, respectively, were molecularly cloned. Restriction enzyme analysis revealed no major deletions or insertions in the proviral genomes of the Mov-2 and Mov-10 locus. Both cloned DNAs induced XC plaques in a transfection assay. The specific infectivity, however, was very low and 3T3 cells transfected with the Mov-2 or Mov-10 clone did not produce infectious virus. Removing part of the 5' cellular sequences from the Mov-10 clone did not increase the infectivity. The results suggest that the M-MuLV integrated at the Mov-2 and Mov-10 locus carry a mutation which prevents synthesis of infectious virus but permits XC plaque induction by partial genome expression or synthesis of non-infectious particles.

Long terminal repeat of murine retroviral DNAs: sequence analysis, host-proviral junctions, and preintegration site

The nucleotide sequence of the long terminal repeat (LTR) of three murine retroviral DNAs has been determined. The data indicate that the U5 region (sequences originating from the 5' end of the genome) of various LTRs is more conserved than the U3 region (sequences from the 3' end of the genome). The location and sequence of the control elements such as the 5' cap, "TATA-like" sequences, "CCAAT-box," and presumptive polyadenylic acid addition signal AATAAA in the various LTRs are nearly identical. Some murine retroviral DNAs contain a duplication of sequences within the LTR ranging in size from 58 to 100 base pairs. A variant of molecularly cloned Moloney murine sarcoma virus DNA in which one of the two LTRs integrated into the viral DNA was also analyzed. A 4-base-pair duplication was generated at the site of integration of LTR in the viral DNA. The host-viral junction of two molecularly cloned AKR-murine leukemia virus DNAs (clones 623 and 614) was determined. In the case of AKR-623 DNA, a 3- or 4-base-pair direct repeat of cellular sequences flanking the viral DNA was observed. However, AKR-614 DNA contained a 5-base-pair repeat of cellular sequences. The nucleotide sequence of the preintegration site of AKR-623 DNA revealed that the cellular sequences duplicated during integration are present only once. Finally, a striking homology between the sequences flanking the preintegration site and viral LTRs was observed.

Nucleotide sequence of the 5' noncoding region and part of the gag gene of Rous sarcoma virus

Several functions of the retrovirus genome involve structural features in the vicinity of its 5' terminus. In an effort to further elucidate the relationship between structure and function in retrovirus RNA, we have determined the sequence of the first 1,010 nucleotides at the 5' end of the genome of Rous sarcoma virus by using the Maxam-Gilbert method to sequence suitable domains in cloned Rous sarcoma virus DNA. The results (i) locate the initiation codon for the gag gene of Rous sarcoma virus 372 nucleotides from the 5' end of viral RNA; (ii) demonstrate that this codon is preceded by three methionine codons that are apparently not used in translation; (iii) sustain previous conclusions that the principal site to which ribosomes bind on the Rous sarcoma virus genome in vitro does not contain the initiation codon for gag; (iv) permit deduction of the amino acid sequence of a viral structural protein, p19; (v) confirm the amino-terminal sequence of Pr76gag; and (vi) substantiate the identification of a splice donor site described in the accompanying manuscript (Hackett et al., J. Virol., 41:527-534, 1982).

Genetic recombination in avian retroviruses

The avian retroviruses--and probably other retroviruses as well--undergo a variety of recombinational events with relatively high efficiency. An understanding of the molecular basis of these events should provide insight into the important biological properties these agents exhibit when they become integrated into somatic or germ-line host cells, when they exchange genetic information among themselves, or when they transduce host cell genes. In this article we review molecular models for homologous recombination, against a background of the other types of recombination events that are typical of these viruses. It seems probable that the retroviruses will provide useful models for analysis of a variety of DNA rearrangements known to occur in eukaryotic cells.

Structure of the baboon endogenous virus genome: nucleotide sequences of the long terminal repeat

The entire nucleotide sequence of the long terminal repeat (LTR) of baboon endogenous virus (BaEV) M7 was determined, which consisted of 554 base pairs (bp). At both ends of the LTR, 13 bp sequences, AAATGAAAAGTAA and TGATTCTAACATC, were detected to be inverted repeats. The structure with these inverted repeats resembles those of other retroviruses and transposable elements. a Hogness box, TATAAAA, and a putative poly(A)-addition signal, AGTAAA, were present within the right-hand half of the LTR, where the initiation and termination of the viral RNA synthesis seems to occur in the integrated BaEV genome. The primer-binding site of at least 14 bp long was found just outside of the LTR where the strong stop DNA started, and the primer for reverse transcription in BaEV seemed to be tRNAPro. Several structural features are commonly detected in the LTRs of BaEV and other retroviruses. Our studies suggest that BaEV has evolved from a common ancestor with other mammalian type C viruses. Close relationships between BaEV and a feline endogenous virus, RD114, are demonstrated.

Structure and evolution of goat gamma-, beta C- and beta A-globin genes: three developmentally regulated genes contain inserted elements

We have determined the complete nucleotide sequence of the goat fetal (gamma), preadult (beta C) and adult (beta A) globin genes. In contrast to other globin genes expressed in different stages of development, these three genes are highly homologous (approximately 90%) in both their coding and noncoding regions. The only major difference between them results from elements inserted into their large introns: gamma contains a 247 bp insertion, beta A contains a 318 bp insertion, and beta C contains both a 252 bp insertion and a 60 bp deletion. Based on comparisons of these three genes to each other and to two goat globin pseudogenes, psi beta X and psi beta Z, we conclude that gamma, beta A and beta C have diverged relatively recently, and that the two gene pairs psi beta X - beta C and psi beta Z-beta A arose via a block duplication of an ancestral pseudogene-functional gene pair. Moreover, as opposed to the human fetal genes (G gamma and A gamma), the goat gamma gene appears to be a true beta-like gene that has fetal-specific function. The insertions in gamma, beta A and beta C contain sequence features characteristic of transposon-like elements, and appear to be represented in multiple copies throughout the genome.

5'-terminal deletions are a common feature of endogenous retrovirus loci located on chromosome 1 of White Leghorn chickens

My previous studies demonstrated that chromosome 1 has all five of the endogenous retrovirus loci associated with nonexpression of viral proteins (gs- chf-) in White Leghorn chickens. The current study was done to localize the two defective endogenous retrovirus loci, ev3 and ev6, to determine whether nonexpression of the viral loci on chromosome 1 is a transcriptional prerequisite or a result of an underlying structural defect. The structure of ev6 is every similar to that of two other gs- chf- -associated loci, ev4 and ev5; all three contain a 5'-terminal deletion that eliminates the viral transcriptional promoter. Unlike the gs- chf- -associated loci, ev6 apparently uses an adjacent cell promoter to produce high levels of viral glycoprotein. The ev6 locus was located on the long arm of chromosome 1 by in situ hybridization, thus indicating that transcription of an endogenous retrovirus locus on chromosome 1 can occur. However, the 5'-terminal deletion in several viral loci on chromosome 1, but not on other chromosomes, suggests that the deletion may result from the events that generate or maintain these loci in the White Leghorn population. The additional finding of ev3, which has an internal deletion, on a microchromosome suggests that the mechanism that produced deletions in many chromosome 1 loci is specific for the 5' terminus.

Direct repeats flank three small nuclear RNA pseudogenes in the human genome

We previously demonstrated that pseudogenes complementary to the small nuclear RNAs U1, U2 and U3 are dispersed and abundant in the human genome. Here we report that three pseudogenes (U1.101, U2.13 and U3.5) are flanked by perfect short direct repeats of 16 to 19 base pairs. In all three pseudogenes. the upstream direct repeat abuts a DNA sequence corresponding to the 5' end of the mature snRNA; in U2.13 and U3.5, the downstream direct repeat immediately follows the truncated 3' end of the snRNA sequence, whereas in U1.101, the downstream direct repeat is separated from the 3, end of the full-length snRNA sequence by a short A-rich region. We consider the direct repeats to be an indication that these three pseudogenes were created by insertion of snRNA information into a new chromosomal locus. To explain why the upstream repeat abuts a DNA sequence complementary to the 5' end of the mature snRNA, we propose a model for insertion that uses a reverse transcript of the snRNA as an intermediate. Furthermore, we note similarities between the structure of all three pseudogene loci and the Alu family of middle repetitive DNA sequences. These similarities suggest that some Alu family sequences are mobile genetic elements that can transpose to new chromosomal loci using as an intermediate a cDNA copy of an RNA transcribed from the Alu family element by RNA polymerase III.

Clonal analysis of the integration and expression of endogenous avian retroviral DNA acquired by exogenous viral infection

Rous-associated virus-0 is one of several endogenous avian retroviruses that are transmitted vertically and that can be isolated from different inbred lines of chickens. These viruses, referred to here as induced-leukosis viruses bearing a subgroup E glycoprotein (ILV-E), are all closely related. Clonal populations of fibroblasts from line 15B and line 100 inbred chickens have been examined for the presence and expression of exogenously acquired ILV-E sequences. Restriction enzyme analysis of uniform populations of line 15B fibroblasts, prepared by cloning cells either before or after infection with ILV-E, indicates that viral sequences were inserted at multiple sites within the cell genome. Analysis of 49 clonal populations of line 100 fibroblasts containing between one and five copies of exogenous ILV-E sequences demonstrated that each clone was characterized by a unique set of viral DNA insertions within the cell genome. The expression of the exogenous ILV-E sequences within these fibroblast clones was examined by using reverse transcriptase activity as a measure of virus production. Some clones produced an amount of virus equivalent to that produced by an equal number of the uncloned ILV-E-infected parental fibroblasts. Other clones produced 5- to 10-fold less virus. Still other clones produced no detectable virus at all. Among nine clones derived from cells containing a single copy of the ILV-E provirus, the level of virus production differed more than 100-fold. DNA from these clones was analyzed with several different restriction endonucleases to characterize the location and arrangement of the ILV-E sequences. All nine clones consisted of cells that appeared to contain a complete provirus inserted (i) in a different site within the cellular DNA and (ii) in an orientation that was colinear with the viral genomic RNA. It was observed that several cleavage sites potentially affected by methylation were equally available for cleavage in all clones regardless of the level of viral production.

Biological activity of cloned retroviral DNA in microinjected cells

Avian retroviral DNA molecules that had been cloned from infected cells by using recombinant DNA techniques were microinjected into either uninfected chicken embryo fibroblasts (CEF) or CEF transformed by the envelope glycoprotein-deficient Bryan strain of Rous sarcoma virus [RSV(--)cells]. Retroviral DNA injected into RSV(--) cells directed transcription of envelope mRNA, which was then able to complement the RSV(--) env deficiency and promote the production of infectious transforming virus. The retroviral DNA also directed the production of fully infectious virus after injection into uninfected cells or RSV(--) cells. Virus production began within 3--4 hr after microinjections. When 100 DNA molecules per cell were injected, almost all injected cells produced infectious virus. As the number of injected molecules per cell was decreased, a corresponding decrease was observed in the number of cells that produced infectious virus. DNA injected into the cytoplasm was 1/50th to 1/10th as effective in virus production as DNA molecules injected into the nucleus. DNA molecules containing one or two tandem copies of the viral long terminal repeat were equally effective in virus production.

A Rous sarcoma virus provirus is flanked by short direct repeats of a cellular DNA sequence present in only one copy prior to integration

The Rous sarcoma virus (RSV)-transformed rat cell line RSV-NRK-2 contains a single complete RSV provirus. We have obtained recombinant lambda clones that contain both ends of the RSV provirus and the flanking rat sequences. The provirus is integrated in unique DNA and is present in only one of the two homologous chromosomes. The rat sequences into which the RSV provirus integrated were also cloned from the RSV-NRK-2 cell line. The sequences of the regions involved in the recombination event have been determined and compared. Our data suggest that, compared with the sequence of viral DNA in the large circular form of unintegrated viral DNA, the provirus lacks two base pairs at each end and that the provirus is flanked by a six-base-pair direct repeat of cellular DNA. This six-base-pair repeat was apparently created during the integration event because this sequence was present only once at the integration site before the provirus was inserted. A survey of eight other independent RSV transformed rat cell lines demonstrates that, in agreement with earlier results, the RSV proviruses have entered different segments of rat cell DNA. We have also determined the sequence of a second virus DNA-host cell DNA junction from a second RSV-transformed rat cell line (RSV-NRK-4) and find that there are no obvious similarities between the two integration sites or between the integration sites and the termini of viral DNA.

Molecular cloning and partial characterization of unintegrated linear DNA from gibbon ape leukemia virus

We have cloned the complete genome of an oncogenic primate retrovirus, the San Francisco isolate of gibbon ape leukemia virus, in a lambda phage vector. DNA sequence analysis and restriction endonuclease mapping of the inserted linear provirus demonstrated 9-base pair inverted repeats at its ends, flanking direct terminal repeats 470 base pairs in length. The (-) strong stop region of this DNA showed surprisingly low sequence homology to that of another gibbon ape leukemia virus isolate from an animal with similar disease. Analysis of the clone also revealed the terminal phosphate configuration of the linear provirus. The recombinant phage is suitable for direct use as a hybridization probe to detect homologous retroviral sequences in human cell lines.