Amplification and sequence analysis of DNA flanking integrated proviruses by a simple two-step polymerase chain reaction method.

We describe a two-step polymerase chain reaction method that can be used for the amplification of cellular DNA sequences adjacent to an integrated retroviral provirus. The technique involves a partly degenerate, arbitrary primer that will hybridize in the provirus-flanking cellular DNA. By using this primer in combination with a biotinylated provirus-specific primer, a provirus-cellular DNA junction fragment can be isolated from the nonspecific amplification products by using streptavidin-coated magnetic beads. A second amplification employing a nested provirus-specific primer and a biotinylated nondegenerate primer derived from the partly degenerate primer followed by purification with streptavidin-coated beads enhances the specificity and the efficiency of recovery of a fragment(s) containing the unknown flanking sequences. In addition to being relevant in studies of viral integration sites, the method should be generally useful to analyze DNA sequences either upstream or downstream from a known sequence.     

Circles with two tandem LTRs are precursors to integrated retrovirus DNA

Infection of susceptible cells by retroviruses results in the synthesis of linear DNA with two long terminal repeats (LTRs), circular DNA with a single LTR, and circular DNA with two tandem LTRs. To determine which of these unintegrated molecules serves as the precursor to the provirus, we inserted into a retrovirus vector a 49 bp fragment containing the junction formed by in vivo blunt-end ligation of two LTRs. Infection of chicken embryo fibroblasts with virus recovered from this vector and subsequent characterization of the proviral DNA revealed that efficient integration can occur from this introduced junction sequence. Therefore, circular DNA with two tandem LTRs is a precursor to the provirus.     

Rearrangements in the long terminal repeat of extra mouse mammary tumor proviruses in T-cell leukemias of mouse strain GR result in a novel enhancer-like structure.

Male GR mice develop T-cell leukemia at low frequency late in life. These leukemia cells invariably contain large amounts of mouse mammary tumor virus (MMTV) RNA and MMTV proteins and have extra MMTV proviruses integrated in their DNA. We show here that the extra MMTV proviruses are all derived from the endogenous MMTV provirus associated with the Mtv-2 locus and that the T-cell leukemias are clonal with respect to the acquired MMTV proviruses. The extra MMTV proviruses in six transplantable T-cell leukemia lines studied had rearranged, shortened long terminal repeats (LTRs); each T-cell leukemia, however, had a different LTR rearrangement within its extra MMTV provirus. The alteration within the extra LTRs of T-cell leukemia line 42 involved deletion of 453 nucleotides and generation of a tandem repeat region consisting of regions flanking the deletion. This alteration generated a sequence similar to the adenovirus enhancer core sequence. The viral RNAs in the T-cell leukemias contained corresponding alterations in their U3 regions. These results demonstrate that expression of MMTV in T-cell leukemias of GR mice may be the consequence of the generation of a novel enhancer, which could also stimulate expression of any adjacent cellular oncogene.     

Identification of the avian myeloblastosis virus genome. II. Restriction endonuclease analysis of DNA from lambda proviral recombinants and leukemic myeoblast clones.

Two lambda proviral DNA recombinants were characterized with a number of restriction endonucleases. One recombinant contained a complete presumptive avian myeloblastosis virus (AMV) provirus flanked by cellular sequences on either side, and the second recombinant contained 85% of a myeloblastosis-associated virus type 1 (MAV-1)-like provirus with cellular sequences adjacent to the 5' end of the provirus. Comparing the restriction maps for the proviral DNAs contained in each lambda hybrid showed that the putative AMV and MAV-1-like genomes shared identical enzyme sites for 3.6 megadaltons beginning at the 5' termini of the proviruses with respect to viral RNA. Two enzyme sites near the 3'-end of the MAV-1-like provirus were not present in the putative AMV genome. We also examined a number of leukemic myeloblast clones for proviral content and cell-provirus integration sites. The presumptive AMV provirus was present in all the leukemic myeloblast clones regardless of the endogenous proviral content of the target cells or the AMV pseudotype used for conversion. Multiple cellular sites were suitable for integration of the putative AMV genome and the helper genomes. The proviral genomes were all integrated colinearly with respect to linear viral DNA.     

Molecular characterization of the Akvr-1 restriction gene: a defective endogenous retrovirus-borne gene identical to Fv-4r.

A dominant restriction allele, Akvr-1r, from California wild mice (Mus musculus domesticus) confers resistance to exogenous ecotropic murine leukemia virus (MuLV) infection. The presence of an ecotropic MuLV envelope-related glycoprotein in uninfected virus-resistant cells suggests that viral interference is a possible mechanism for this resistance. We molecularly cloned the ecotropic MuLV envelope-related sequence from the genomic DNA of a wild mouse homozygous for the Akvr-1r locus. The cloned provirus was defective and contained a C-terminal end of the pol gene, a complete envelope gene, and a 3' long terminal repeat. The presence of this provirus was directly correlated with Akvr-1r-mediated virus resistance in cell cultures and hybrid mice. The Akvr-1r provirus restriction map and partial DNA sequence were identical to those of the Fv-4r allele, an ecotropic MuLV resistance locus from Japanese feral mice (M. musculus molossinus), which was previously shown to be allelic with the Akvr-1r gene. The 3' host flanking sequences of Fv-4r and Akvr-1r also had identical restriction maps. These findings indicate that Akvr-1r and Fv-4r are the same gene. It was probably acquired by interbreeding of these feral species in recent times. Conservation of this locus might be favored by the useful function that it performs in protection against ecotropic MuLV infection endemic in both populations of wild mice.     

Tumorigenesis by mouse mammary tumor virus: Evidence for a common region for provirus integration in mammary tumors

We have prepared specific probes for unique-sequence cellular DNA adjacent to each of the newly integrated proviruses in tumors induced by mouse mammary tumor virus (MMTV). The use of such probes to screen a large number of independent mammary tumors in the BR6 strain of mouse has indicated that in at least 17 out of the 40 tumors examined so far, an MMTV provirus has integrated into a common chromosomal domain. A 10 kb Eco RI fragment of single copy DNA from this region has been isolated and partially characterized by restriction enzyme mapping. Of the proviruses located within this fragment in different tumors, all but one are complete, in the same orientation, and clustered within about 3 kb of cellular DNA. These findings are consistent with an insertional mutagenesis model for tumorigenesis by MMTV, in which the integration of a provirus in a particular region of cellular DNA may activate a neighboring oncogene. The region we describe here appears to be different from that reported for mammary tumors in the C3H strain of mouse.     

Construction of a full-length human T cell leukemia virus type I genome from MT-2 cells containing multiple defective proviruses using overlapping polymerase chain reaction

Human T cell leukemia virus type I (HTLV-I), the etiological agent of adult T cell leukemia, integrates into the host genome as a provirus. Multiple defective copies of the integrated provirus are often present in the host genome. For this reason it is difficult to clone the intact provirus from HTLV-I-infected cells using conventional techniques. Here, we used overlapping polymerase chain reaction (PCR) to construct a full-length provirus of HTLV-I directly from an HTLV-I-transformed cell line, MT-2, which contains multiple defective proviruses. First, four overlapping proviral HTLV-I fragments (1.4-3.9 kb each) were constructed from genomic MT-2 DNA using PCR. Next, the complete HTLV-I proviral DNA (9 kb) was generated from these fragments using asymmetric PCR and cloned into a plasmid vector. 293 T cells transfected with this plasmid produced virus-like particles, and we show that these particles are capable of infecting a human T cell line. We propose that this cloning technique constitutes a powerful tool for constructing infectious molecular clones from cells of patients infected with HTLV-I or other viruses.     

Restriction endonuclease mapping of the proviral DNA of the exogenous RIII murine mammary tumor virus

Cellular DNA containing integrated murine mammary tumor virus (MuMTV) was isolated from FeI/C6 feline kidney cells and CCL64 mink lung cells infected with milkborne RIII MuMTV. By using restriction enzyme HpaI, intact RIII MuMTV provirus (length, 8.7 kilobases [kb]) was excised from the cellular DNA. Subsequent restriction endonuclease analysis of this HpaI fragment with KpnI, HindIII, EcoRI, BamHI, BglII, PstI, SstI, SalI, and XhoI enabled us to construct a map of the RIII virus genome. A comparison of this map with the maps of the GR and C3H MuMTV's revealed that there are greater sequence differences between the RIII virus and the GR and C3H MuMTV proviruses than there are between the GR and C3H proviruses. The following are features of the restriction map unique to the RIII provirus: the presence of three BamHI and two EcoRI cleavage sites, a HpaI cleavage site in the terminal 3'-5' repeat unit of the provirus, and the absence of an XhoI cleavage site. Another distinguishing feature of the RIII provirus is that the sizes of some of the restriction fragments produced by cleavage of the RIII provirus with PstI are different from the sizes of the fragments obtained by PstI cleavage of the GR and C3H proviruses. Like the GR proviral DNA, the RIII proviral DNA has three SstI (SacI) cleavage sites, whereas the C3H provirus has only two SstI sites. HpaI digestion of MuMTV-infected mink lung cell DNA revealed only one class of provirus (an 8.7-kb fragment); however, we observed several minor classes of RIII proviral DNA in addition to the major class of provirus DNA in infected cat kidney cells. PstI digestion of the HpaI 8.7-kb fragments from both feline and mink cells generated a 3.7-kb DNA fragment identical in size to a PstI-generated fragment that has been found in GR and C3H milkborne virus-infected cells. Although a fragment similar in size to the milkborne 3.7-kb PstI fragment has been found as an endogenous component in many C3H and GR mouse tissues, we did not observe such an endogenous fragment in the RIII mouse strain. Therefore, the 3.7-kb fragment may be useful as a marker for the milkborne RIII MuMTV provirus in RIII mice.     

Highly preferred targets for retrovirus integration

A central feature of retrovirus replication is integration of the provirus into host cell DNA, but the specificity of this step for cell target sequences has not been clarified. To investigate this issue, we developed a method for screening and comparing large numbers of unselected integration events. Using a replication-competent Rous sarcoma virus containing a bacterial suppressor tRNA gene as a selectable marker, we obtained collections of clones comprising integrated provirus together with host flanking sequences. Hybridization and sequence analysis of the flanking sequence reveals the presence of a number of strongly preferred integration targets. Within these targets, independent integration events occur at sites identical to the base.     

Differences between the endogenous and exogenous DNA sequences of Rous-associated virus-O.

DNA sequences related to the endogenous retrovirus of chickens, Rous-associated virus-O (RAV-O), have been examined using site-specific DNA endonuclease analysis of cellular DNA derived from line 15 and line 100 chickens. Individual embryos from both inbred lines were used as a source of embryonic fibroblasts from which cellular DNA was isolated. Analysis of DNA containing either endogenous RAV-O sequences alone or both endogenous and exogenous RAV-O sequences produced identical patterns of RAV-O-specific DNA fragments after digestion with the endonucleases Eco RI, Hind III, BgI II, Bam HI or Xho I. Similar analysis with endonucleases Hinc II or Hha I, however, produced several RAV-O-specific DNA fragments which were derived from cellular DNA containing both endogenous and exogenous RAV-O sequences but not from cellular DNA containing only endogenous sequences. Although some differences exist between the DNA fragments specific for the endogenous viral sequences of line 15 and line 100 cellular DNA, the DNA fragments specific for the exogenous viral sequences were identical between the two inbred lines. Cleavage of an unintegrated linear RAV-O DNA molecule with Hinc II or Hha I produced DNA fragments identical to those specific for the exogenously acquired RAV-O provirus. This suggests that these characteristic fragments contain no cellular DNA. The potential DNA junction fragments containing both viral and cellular DNA, identified after analysis of DNA that contains both endogenous and exogenous viral sequences, were identical to those observed after analysis of DNA containing only endogenous viral sequences. These results support the following conclusions. First, exogenous proviral sequences are integrated into chicken cell DNA following an interaction between viral and cellular DNA that is specific with respect to the virus and nonspecific with respect to the cell. Second, both the free linear RAV-O DNA intermediate and the newly integrated exogenous provirus contain specific endonuclease sites that are not found in endogenous RAV-O DNA sequences. These results suggest that the formation of the exogenous DNA provirus involves specific alteration of the endogenous viral DNA sequences before reinsertion of the sequences as the exogenous RAV-O DNA provirus. It is possible that newly integrated exogenous RAV-O sequences are characterized by specific differences in the pattern of base methylation and a limited sequence arrangement.     

The palindromic LTR-LTR junction of Moloney murine leukemia virus is not an efficient substrate for proviral integration.

We generated viral constructs to test the hypothesis that the major substrate on retroviral DNA that is utilized for proviral DNA integration is the palindromic sequence, termed the LTR-LTR junction, normally present in circular molecules formed by joining the two termini of linear proviral DNA. Recombinant viral genomes were built which carried a selectable marker and an extra copy of the LTR-LTR junction from a cloned circular provirus. The junction sequence in each case was positioned such that its use during integration would lead to an easily detected, aberrantly integrated proviral DNA. Analysis of DNA from cells infected with the virus constructs showed that the introduced junction sequence is used at least 1,000-fold less efficiently than the natural sequences at the ends of the genome. This suggests that a linear or more exotic DNA intermediate is most likely the true precursor for the integration reaction.     

Long terminal repeat (LTR)-derived recombination of retroviral DNA: sequence analyses of an aberrant clone of baboon endogenous virus DNA which carries an inversion from the LTR to the gag region.

Nucleotide sequences of a cloned proviral DNA of baboon endogenous virus M7 were analyzed, which carried an internal inversion. The inversion of 2.2 kilobase pairs was occurred between the junction of two tandem LTRs and a site locating in the p30 region of the gag gene. The ATAA sequence was a target for recombination generating the inversion, which was duplicated at both ends of the inverted segment. AAA and CA were lost at the 5'- and 3'-ends of the LTRs by the inversion, respectively. On both sides of the target sequence, long AG-rich stretches were detected, which may specify the site of recombination together with the target sequence. The characteristic base changes in the inversion are concluded to result from an illegitimate recombination associated with LTRs, as well as in case of provirus integration into the host cell DNA. We propose and discuss models to explain the processes of recombination to generate both inversion and integration.     

Structure of the provirus within NIH 3T3 cells transfected with Harvey sarcoma virus DNA.

NIH 3T3 cells transformed with unintegrated Harvey sarcoma virus (HSV) linear DNA generally acquired a complete HSV provirus. Infection of these transformed cells with Moloney murine leukemia helper virus was followed by release of infectious particles. The HSV provirus within these transfected cells was convalently joined to nonviral DNA sequences and was termed "cell-linked" HSV DNA. The association of this cell-virus DNA sequence with the chromosomal DNA of a transfected cell was unclear. NIH 3T3 cells could also become transformed by transfection with this cell-linked HSV DNA. In this case, the recipient cells generally acquired a donor DNA fragment containing both the HSV provirus and its flanking nonviral sequences. After cells acquired either unintegrated or cell-linked HSV DNA, the newly established provirus and flanking cellular sequences underwent amplifications to between 5 and 100 copies per diploid cell. NIH 3T3 cells transfected with HSV DNA may acquire deleted proviral DNA lacking at least 1.3 kilobase pairs from the right end of full-length HSV 6-kilobase-pair DNA (corresponding to the 3'-proximal portion of wild-type HSV RNA). Cells bearing such deleted HSV genomes were transformed, indicating that the viral transformation gene lies in the middle or 5'-proximal portion of the HSV RNA genome. However, when these cells were infected with Moloney murine leukemia helper virus, only low levels of biologically active sarcoma virus particles were released. Therefore, the 3' end of full-length HSV RNA was required for efficient transmission of the viral genome.     

Quantification of unintegrated HIV-1 DNA at the single cell level in vivo

In the nucleus of HIV-1 infected cells, unintegrated HIV-1 DNA molecules exist in the form of one and two LTR circles and linear molecules with degraded extremities. In tissue culture they are invariably more numerous than the provirus, the relative proportion of integrated to unintegrated forms varies widely from ～1:1 to 1:10 and even over 1:100. In vivo, this ratio is unknown. To determine it, single nuclei from two infected patients with a known provirus copy number were microdissected, HIV DNA was amplified by nested PCR, cloned and individual clones sequenced. Given the extraordinary sequence complexity, we made the assumption that the total number of distinct sequences approximated to real number of amplifiable HIV-1 DNA templates in the nucleus. We found that the number of unintegrated DNA molecules increased linearly with the proviral copy number there being on average 86 unintegrated molecules per provirus.