Structure of the Abelson murine leukemia virus genome and the homologous cellular gene: studies with cloned viral DNA

Circular double-stranded DNA produced after infection of mouse cells with Abelson murine leukemia virus (A-MuLV) was isolated and cloned in the phage vector Charon 21A. The resulting clones of the A-MuLV genome show homology to the ends of Moloney MuLV and to a 3.5 kb central region containing sequences unique to Abelson virus. A 2.3 kb restriction fragment containing only A-MuLV-specific sequences was subcloned in the plasmid vector pBR322 and used as a probe for the cellular gene that had been acquired by the virus. DNA from all inbred mouse lines examined contains an identical region of homology spread out over 11 to 20 kb. The cellular gene contains intervening sequences which are lacking in the viral genome. Rat, Chinese hamster, rabbit, chicken and human DNA also show homology to the viral probe.     

Integration and excision of SV40 DNA from the chromosome of a transformed cell

The single insertion of SV40 DNA present in the genome of the 14B line of transformed rat cells has been cloned in procaryotic vectors. Analysis of the clones reveals a complex arrangement of viral sequences in which a small tract of DNA is inverted with respect to the major insertion. The nucleotide sequences at the two junctions show sharp transitions between cellular and viral sequences. The sequences which flank the viral insertion have been used as probes to clone the corresponding genomic sequences from the DNA of untransformed rat cells. Analysis of the structure of these clones shows that a rearrangement of cellular sequences has occurred, presumably as a consequence of integration. When 14B cells are fused with uninfected simian cells a heterogeneous set of low molecular weight superhelical DNAs containing viral sequences is generated. These have been cloned in procaryotic vectors and their structures have been analyzed. All of them span the origin of SV40 DNA replication and are colinear with various segments of the integrated viral DNA and its flanking sequences. The shorter molecules contain part of the integrated viral genome and cellular sequences from one side of the insertion. They were therefore generated by recombination between the viral DNA and its flanking cellular sequences. The longer molecules contain cellular sequences from both sides of the insertion as well as an entire copy of the integrated viral DNA. They were therefore generated by recombination between the flanking cellular sequences. These results argue strongly against the involvement of specific excision enzymes, and rather are discussed in terms of a model involving replication of the integrated viral DNA followed by recombination for release of integrated viral sequences.     

Arrangement of Integrated Avian Sarcoma Virus DNA Sequences Within the Cellular Genomes of Transformed and Revertant Mammalian Cells

We have examined the arrangement of integrated avian sarcoma virus (ASV) DNA sequences in several different avian sarcoma virus transformed mammalian cell lines, in independently isolated clones of avian sarcoma virus transformed rat liver cells, and in morphologically normal revertants of avian sarcoma virus transformed rat embryo cells. By using restriction endonuclease digestion, agarose gel electrophoresis, Southern blotting, and hybridization with labeled avian sarcoma virus complementary DNA probes, we have compared the restriction enzyme cleavage maps of integrated viral DNA and adjacent cellular DNA sequences in four different mouse and rat cell lines transformed with either Bratislava 77 or Schmidt-Ruppin strains of avian sarcoma virus. The results of these experiments indicated that the integrated viral DNA resided at a different site within the host cell genome in each transformed cell line. A similar analysis of several independently derived clones of Schmidt-Ruppin transformed rat liver cells also revealed that each clone contained a unique cellular site for the integration of proviral DNA. Examination of several morphologically normal revertants and spontaneous retransformants of Schmidt-Ruppin transformed rat embryo cells revealed that the internal arrangement and cellular integration site of viral DNA sequences was identical with that of the transformed parent cell line. The loss of the transformed phenotype in these revertant cell lines, therefore, does not appear to be the result of rearrangement or deletions either within the viral genome or in adjacent cellular DNA sequences. The data presented support a model for ASV proviral DNA integration in which recombination can occur at multiple sites within the mammalian cell genome. The integration and maintenance of at least one complete copy of the viral genome appear to be required for continuous expression of the transformed phenotype in mammalian cells.     

Integrated structures of duck hepatitis B virus DNA in hepatocellular carcinoma.

The structure of integrated viral DNA in a hepatocellular carcinoma of a duck from Chi-tung county in China was analyzed. Three different clones of integrated viral DNA, lambda DHS 6-1, lambda DHS 6-2, and lambda DHE 6-2, were obtained from the neoplastic portion of the liver by molecular cloning. One of the three clones, lambda DHS 6-1, showed inverted repetition of integrated viral DNA with chromosomal flanking sequences. Another clone, lambda DHS 6-2, showed a head-to-head configuration of the core and surface gene regions of duck hepatitis B virus (DHBV) DNA. The virus-chromosome junctions were often located near direct repeat 1 or 2 of DHBV DNA in three independent clones. Nucleotide sequences at the virus-virus junctions in two clones, lambda DHS 6-1 and 6-2, indicated the possible rearrangement of chromosomal DNA and recombination of viral DNA. DHBV DNA appears to be integrated into the genome of hepatocytes in a manner similar to that of human and woodchuck hepatitis viruses. Thus, the duck system may serve as a useful animal model for the study of human hepatocarcinogenesis.     

Introduction of double-strand breaks into the genome of mouse cells by expression of a rare-cutting endonuclease.

To maintain genomic integrity, double-strand breaks (DSBs) in chromosomal DNA must be repaired. In mammalian systems, the analysis of the repair of chromosomal DSBs has been limited by the inability to introduce well-defined DSBs in genomic DNA. In this study, we created specific DSBs in mouse chromosomes for the first time, using an expression system for a rare-cutting endonuclease, I-SceI. A genetic assay has been devised to monitor the repair of DSBs, whereby cleavage sites for I-SceI have been integrated into the mouse genome in two tandem neomycin phosphotransferase genes. We find that cleavage of the I-SceI sites is very efficient, with at least 12% of stably transfected cells having at least one cleavage event and, of these, more than 70% have undergone cleavage at both I-SceI sites. Cleavage of both sites in a fraction of clones deletes 3.8 kb of intervening chromosomal sequences. We find that the DSBs are repaired by both homologous and nonhomologous mechanisms. Nonhomologous repair events frequently result in small deletions after rejoining of the two DNA ends. Some of these appear to occur by simple blunt-ended ligation, whereas several others may occur through annealing of short regions of terminal homology. The DSBs are apparently recombinogenic, stimulating gene targeting of a homologous fragment by more than 2 orders of magnitude. Whereas gene-targeted clones are nearly undetectable without endonuclease expression, they represent approximately 10% of cells transfected with the I-SceI expression vector. Gene targeted clones are of two major types, those that occur by two-sided homologous recombination with the homologous fragment and those that occur by one-sided homologous recombination. Our results are expected to impact a number of areas in the study of mammalian genome dynamics, including the analysis of the repair of DSBs and homologous recombination and, potentially, molecular genetic analyses of mammalian genomes.     

Organization of sequences related to U6 RNA in the human genome.

Small nuclear RNAs were isolated from human placenta and fractionated into individual molecular species. They were then iodinated with 125I and used as probes to screen the human genome. Of 2 x 10(4) recombinant phage clones screened, 22 clones hybridized with U6 RNA, suggesting that there were about 200 copies of this sequence family per haploid genome. Southern blots of these cloned DNAs digested with several restriction enzymes gave the following results: 1, each clone had only one fragment that carried the U6 sequence, 2, the lengths of these fragments varied from clone to clone. These observations indicate that U6 sequences exist as dispersed middle repetitive DNA, and that the sequences surrounding these loci vary. Two of the loci and their flanking regions were subcloned into plasmid and sequenced. Both of the loci showed microheterogeneity of mainly A/G and T/C, but had closely related sequences to U6 RNAs of rat or mouse. The divergence of the flanking regions begins immediately outside the loci. The implication on the microheterogeneity of the U6-related sequences is discussed.     

Titration of integrated simian virus 40 DNA sequences, using highly radioactive, single-stranded DNA probes.

Nick-translated simian virus 40 (SV40) [32P]DNA fragments (greater than 2 X 10(8) cpm/micrograms) were resolved into early- and late-strand nucleic acid sequences by hybridization with asymmetric SV40 complementary RNA. Both single-stranded DNA fractions contained less than 0.5% self-complementary sequences; both included [32P]-DNA sequences that derived from all regions of the SV40 genome. In contrast to asymmetric SV40 complementary RNA, both single-stranded [32P]DNAs annealed to viral [3H]DNA at a rate characteristic of SV40 DNA reassociation. Kinetics of reassociation between the single-stranded [32P]DNAs indicated that the two fractions contain greater than 90% of the total nucleotide sequences comprising the SV40 genome. These preparations were used as hybridization probes to detect small amounts of viral DNA integrated into the chromosomes of Chinese hamster cells transformed by SV40. Under the conditions used for hybridization titrations in solution (i.e., 10- to 50-fold excess of radioactive probe), as little as 1 pg of integrated SV40 DNA sequence was assayed quantitatively. Among the transformed cells analyzed, three clones contained approximately one viral genome equivalent of SV40 DNA per diploid cell DNA complement; three other clones contained between 1.2 and 1.6 viral genome equivalents of SV40 DNA; and one clone contained somewhat more than two viral genome equivalents of SV40 DNA. Preliminary restriction endonuclease maps of the integrated SV40 DNAs indicated that four clones contained viral DNA sequences located at a single, clone-specific chromosomal site. In three clones, the SV40 DNA sequences were located at two distinct chromosomal sites.     

Novel rearrangements of herpes simplex virus DNA sequences resulting from duplication of a sequence within the unique region of the L component.

We constructed insertion mutants of herpes simplex virus type 1 that contained a duplication of DNA sequences from the BamHI-L fragment (map units 0.706 to 0.744), which is located in the unique region of the L component (UL) of the herpes simplex virus type 1 genome. The second copy of the BamHI-L sequence was inserted in inverted orientation into the viral thymidine kinase gene (map units 0.30 to 0.32), also located within UL. A significant fraction of the progeny produced by these insertion mutants had genomes with rearranged DNA sequences, presumably resulting from intramolecular or intermolecular recombination between the BamHI-L sequences at the two different genomic locations. The rearranged genomes either had an inversion of the DNA sequence flanked by the duplication or were recombinant molecules in which different regions of the genome had been duplicated and deleted. Genomic rearrangements similar to those described here have been reported previously but only for herpes simplex virus insertion mutants containing an extra copy of the repetitive a sequence. Such rearrangements have not been reported for insertion mutants that contain duplications of herpes simplex virus DNA sequences from largely unique regions of the genome. The implications of these results are discussed.     

Cloning and structural analysis of the snap-back DNA of Pharbitis nil

We isolated and cloned DNA fragments that exist as inverted-repeat structures in the genome of Pharbitis nil. The method used exploited the fact that if inverted repeat DNA is present in the DNA fragment, intramolecular double-stranded structures can be partly formed within single-stranded DNA molecules after denaturation and rapid renaturation of the fragment. The rapidly renaturing DNA fragments (termed snap-back DNA) were isolated by hybroxylapatite column chromatography and treatment with mungbean nuclease and were cloned into the pUC9 vector. Four snap-back DNA members out of thousands of independent clones obtained were characterized with respect to the reiteration frequency and the nucleotide sequences. When used as probes in Southern hybridization experiments, some of the members identified restriction fragment length polymorphism among the cultivars, suggesting that these sequences might be fluid in the genome. One of the four clones has regions of nucleotide sequence homology to those of inverted-repeat regions in the transposon Taml of Antirrhinum majus.     

Cloning of a DNA fragment from the left-hand terminus of the adenovirus type 2 genome and its use in site-directed mutagenesis.

The HpaI E fragment (0-4.5 map units) of adenovirus type 2 (Ad2) DNA was cloned in the plasmid vector pBR322. Excision of the viral insert with PstI and XbaI generated a fragment which comigrated with Ad2 XbaI-E (0-3.8 map units), and this fragment was ligated to the 3.8-100 fragment generated by XbaI cleavage of the DNA of the Ad5 mutant, dl309 (N. Jones and T. Shenk, Cell 17:683-689, 1979). Transfection with the ligation products resulted in the production of progeny virus which was able to replicate on both HeLa and line 293 cells, demonstrating the biological activity of the sequences rescued from the plasmid. Small deletions were introduced around the SmaI site (map position 2.8) within the cloned viral insert, and the altered DNA sequences were reintroduced into progeny virus as described above. The mutant viruses grew well on line 293 cells but plaqued with greatly reduced efficiency on HeLa cells, exhibiting a host range phenotype similar to previously described mutants with lesions located within this region of the genome. When plasmid-derived left-end fragments containing pBR322 DNA sequences to the left of map position 0 were ligated to the 3.8-100 fragment of dl309 DNA, the infectivity of the ligation products was not reduced. However, all progeny viruses examined yielded normal-size restriction enzyme fragments from their left-hand ends, indicating that the bulk of the pBR322 DNA sequences are removed either prior to or as a consequence of the replication of the transfecting DNA molecules.     

Integration site of polyoma virus DNA in the inducible LPT line of polyoma-transformed rat cells

The structure of the polyoma virus (Py) integration site in the inducible LPT line of Py-transformed rat cells was determined by biochemical methods of gene mapping. LPT cell DNA was digested with various restriction enzymes. The digestion products were electrophoresed in agarose gels and transferred onto nitrocellulose sheets by Southern blotting. Fragments containing viral or cell DNA sequences, or both, were identified by hybridization with Py DNA or with a cloned flanking cell DNA probe. Cleavage of LPT DNA with enzymes that restrict the Py genome once generated linear Py DNA molecules and two fragments containing both cell and viral DNA sequences. Cleavage of LPT DNA with enzymes which do not restrict Py DNA generated series of fragments whose lengths were found to differ by increments of a whole Py genome; the smallest fragment in each series was found to be longer than the viral genome. These data indicate that LPT cultures contain Py insertions of various lengths integrated into the same chromosomal site in all the cells. The length heterogeneity of the viral insertions is due to the presence of 0, 1, 2, 3. . . Py genomes arranged in a direct tandem repeat within invariable sequences of viral DNA. Double-digestion experiments were also carried out with the above enzymes and with enzymes that cleave the Py genome at multiple sites. The data obtained in these experiments were used to construct a physical map of the integration site. This map showed that the early region of the virus remained intact even in the smallest insertion (which contains no whole duplicated genomes), whereas the late region was partially duplicated and split during integration. The smallest insertion is colinear with the Py physical map over a region including the entire Py genome and at least a part of the duplicated segment. This structure could give rise to nondefective circular viral DNA molecules by single homologous recombination events. Similar recombination events may occur at a higher frequency in the longer insertions, which include longer regions of homology, and may yield many more free viral genomes. The presence of these insertions in LPT cells could thus be one of the factors which account for the high inducibility of the LPT line.     

Multimeric forms of herpes simplex virus type 2 glycoproteins.

Molecular clones of closed circular DNA molecules of a mink cell focus-inducing murine leukemia virus (MCF-13 MuLV) were generated. Closed circular DNA molecules isolated from a Hirt extraction of recently infected NIH/3T3 cells were inserted at their unique EcoRI site into lambda gtWES.lambda B. Restriction endonuclease analysis of inserts of two clones indicated that they represented intact MCF-13 MuLV genomes. One viral insert contained two large terminal repeat sequences, and the other contained only one. A 300-base-pair DNA fragment located in the envelope region of the MCF-13 MuLV genome was determined to be related to xenotropic MuLV sequences.     

Alterations in the number of rRNA operons within the Bacillus subtilis genome

Deletions and additions of rRNA gene sets in Bacillus subtilis were observed by Southern hybridizations using cloned radiolabeled rDNA sequences. Of the ten rRNA gene sets found in B. subtilis 168M or NCTC3610, one was deleted in strains possessing the leuB1, ilvC1, argA2 and pheA1 mutations. Among EcoRI restriction fragments of genomic DNA products, a 2.9-kb 23S rRNA homolog was missing. In HindIII digest, both 5.5- and 5.1-kb hybrid bands were lost with 16S and 23S probes, respectively. Similarly, genomic DNAs digested with SmaI showed the absence of both 2.1- and 2.0-kb fragments that hybridized to 16S and 5S sequences, respectively, in wild-type genomes. In contrast, B. subtilis strain 166 and its derivatives displayed a gain of a 3.3-kb HindIII fragment homologous to 16S rRNA. Transforming the ilvC1 and leuB1 mutations into new genetic backgrounds revealed in some clones the concomitant introduction of the ribosomal defect. Transformations with the slightly heterologous donor DNA from strain W23 yielded some Leu+ and Arg+ transformants with altered hybridization patterns when probed with cloned sequences. We propose that the deletion of the rRNA operon occurred in the ilv-leu gene cluster of the B. subtilis genome as a result of unequal recombination between redundant sequences.     

Chromosomal translocation and inverted duplication associated with integrated hepatitis B virus in hepatocellular carcinomas.

Integrated hepatitis B virus (HBV) DNA is found in hepatocellular carcinomas which develop in HBV carriers. Presented here are the results of analyses of four integrants that show chromosomal rearrangements associated with the integrated HBV DNA. Two clones (p4 and C15) were found to have large inverted repeating structures, each consisting of HBV genome along with flanking cellular sequences. The structure must have arisen by duplication of the primary integrant, including the flanking cellular DNA, followed by recombination within the viral DNA. One of the two viral arms in each clone joins to the other viral arm at the "cohesive end region." Two clones (DA2-2 and DA2-6) were found to have integrated HBV sequences, each flanked by cellular DNAs from different chromosomes (chromosome X joined to 17 and chromosome 5 joined to 9). They must be the products of cellular DNA translocations using the integrated HBV DNA as the switch point. The viral DNA in each clone is a continuous stretch of a single virus genome with one end in the cohesive end region. These complex structures seem to have been produced by activation of the cohesive end of an integrant viral genome, followed by its recombination with another chromosomal DNA.     

Mechanisms of spiroplasma genome variation associated with SpV1-like viral DNA inferred from sequence comparisons.

Genomes of Spiroplasma citri strains have rearranged frequently during their evolution, partly due to multiple integrated sequences of spiroplasma viruses. To understand better the role of viral sequences in genome evolution, we examined available nucleotide sequences of viruslike elements in the S. citri chromosome. Comparison of integrated and nonintegrated sequences of spiroplasma virus SpV1-C74 DNA suggested that it is an encapsidated form of the circular transposition intermediate belonging to an insertion sequence (IS3) family member. One SpV1-C74 viral DNA fragment was identified as interrupting the remains of a DNA adenine modification methylase gene. A viral DNA insertion of SpV1-R8A2 B DNA had hallmarks of having suffered an internal deletion by a site-specific recombination system. Homologous recombination likely was responsible for several deletions within viral DNA. A homologous recombination event was inferred between part of a viral DNA insertion and a similar chromosomal sequence. Dispersed sequences from SpV1-like C4 open reading frames (ORFs) were identified as involved in a complex deletion-inversion event. Thus, SpV1-like sequences likely have altered spiroplasma genomes by inserting within active genes, destroying their function, by providing targets for site-specific recombination, by mediating deletions of sequences adjacent to their integration sites, and by providing targets for homologous recombination, leading to inversions.     

Molecular cloning of unintegrated visna viral DNA and characterization of frequent deletions in the 3' terminus

Visna viral DNA, like other retroviral DNA, exists in two circular forms in infected cells. The larger probably contains two copies of the LTR, the smaller, one copy. Recombinant DNA techniques were used to clone unintegrated circular visna viral DNA in the lambda WES . lambda B vector. Circular visna viral DNA was digested with the restriction enzyme SstI, which yields a 9.2-kb viral DNA fragment containing 90% of the viral genome colinear with the restriction map of linear viral DNA. This fragment extends from a site about 900 bp from the left (5') end of the viral DNA molecule, through the 3' region, including U3 and R sequences at its right (3') end. The recombinant clones isolated contain visna viral DNA inserts which range in size from 3.1 kb to 9.2 kb. All the clones contain the 5' region intact, but most had sustained deletions of varying lengths in the 3' terminal region of the cloned fragment.     

Structural organization and biological activity of molecular clones of the integrated genome of a BALB/c mouse sarcoma virus.

BALB/c mouse sarcoma virus (BALB-MSV) is a spontaneously occurring transforming retrovirus of mouse origin. The integrated form of the viral genome was cloned from the DNA of a BALB-MSV-transformed nonproducer NRK cell line in the Charon 9 strain of bacteriophage lambda. In transfection assays, the 19-kilobase-pair (kbp) recombinant DNA clone transformed NIH/3T3 mouse cells with an efficiency of 3 X 10(4) focus-forming units per pmol. Such transformants possessed typical BALB-MSV morphology and released BALB-MSV after helper virus superinfection. A 6.8-kbp DNA segment within the 19-kbp DNA possessed restriction enzyme sites identical to those of the linear BALB-MSV genome. Long terminal repeats of approximately 0.6 kbp were localized at either end of the viral genome by the presence of a repeated constellation of restriction sites and by hybridization of segments containing these sites with nick-translated Moloney murine leukemia virus long terminal repeat DNA. A continuous segment of at least 0.6 and no more than 0.9 kbp of helper virus-unrelated sequences was localized toward the 3' end of the viral genome in relation to viral RNA. A probe composed of these sequences detected six EcoRI-generated DNA bands in normal mouse cell DNA as well as a smaller number of bands in rat and human DNAs. These studies demonstrate that BALB-MSV, like previously characterized avian and mammalian transforming retroviruses, arose by recombination of a type C helper virus with a well-conserved cellular gene.     

Rescue of silent integrated polyoma genomes suggests homologous recombination between resident and transfected DNA fragments

Two defective polyoma virus genomes, deleted in the nucleotide sequences coding the N-termini of the tumor antigens, were introduced into Fisher 3T3 rat cells by DNA-mediated gene transfer (transfection). The resulting integrated genomes were incapable of conferring a transformed phenotype to the cells. However, after transfection of these lines with small polyoma fragments overlapping the deleted sequences, transformed clones were isolated. These clones were analyzed by Southern genomic blot hybridization and by isolation in E. coli of plasmids containing viral sequences excised following fusion with mouse polyoma growth-permissive cells. In all cases at least one intact copy of the early region of the polyoma genome was found. Furthermore, restriction sites adjacent to the initial inactive insertion remained unchanged in many of the transformed lines. These results show that functional restoration of the defective polyoma early region involves homologous recombination between the deleted viral genomes integrated in the cellular DNA and the transfecting viral fragments.