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.     

Inverted terminal repetition in adeno-associated virus DNA: independence of the orientation at either end of the genome

Complementary strands of adeno-associated virus DNA labeled with 32P at the 5' ends were separated and then self-annealed to form single-stranded circles stabilized by hydrogen bonds between the complementary sequences in the inverted terminal repetitions. We have previously shown that there are two distinct sequences in the terminal repetition which represent an inversion of the first 125 nucleotides (E. Lusby et al., J. Virol. 34:402-409, 1980; I. S. Spear et al., Virology 24:627-634, 1977). Base pairing between terminal sequences of the same orientation leads to a normal double helical structure. If sequences of the opposite orientation pair, an aberrant secondary structure is formed. HpaII digestion of the self-annealed, single-stranded circles led to labeled terminal fragments that corresponded both to those generated from termini of a normal double helical structure and those generated from an aberrant terminal secondary structure. Thus, the orientation of the terminal repetition at one end of the genome is not influenced by the orientation at the other end.     

Nucleotide sequence analysis of DNA replication origins of the small Bacillus bacteriophages: evolutionary relationships

The ends of the small Bacillus phage genomes serve as origins and termini of their DNA replication. We have determined nucleotide sequences at the termini of four different phage DNAs and compared them with those of phi 29 DNA which has been described previously. A high degree of homology was found at the extreme ends of DNAs from phi 29, phi 15 (group A), M2Y and Nf (group B). 17 bp at the far left of the DNAs are identical. A highly conserved dodecanucleotide sequence, CCATTTCCCCAT, was also found in the righthand terminus of all these phage DNAs, at positions 27-38 from the end. Nucleotide sequences of phage GA-1 are not very similar to those of the other phages. Examination of the 5'-terminal and 3'-terminal sequences of all the phages suggests that stable 'panhandle' structures are unlikely to be formed via base pairing of both ends. However, thermodynamically more stable panhandle structures might be formed by displaced single-stranded DNA, although this requires rather large loops.     

Evaluation of DNA homology of Marek's disease virus, herpesvirus of turkeys and Epstein-Barr virus under varied stringent hybridization conditions

Marek's disease virus (MDV) showed only 0.3-0.6% homology in DNA sequence with herpesvirus of turkeys (HVT) at Tm-24.4 degrees C in spite of its antigenic similarity to the latter. Southern blot hybridization under stringent conditions showed that the homology between MDV and HVT is located in the restricted portion of these viral genomes. At Tm-49.6 degrees C, which permits the detection of homology with one base mismatch in three between the MDV and HVT DNAs, sequences with weak homology were found to be distributed over most of these viral genomes. No homology was detected between Epstein-Barr virus and either MDV or HVT DNA.     

Characterization of avian myeloblastosis-associated virus DNA intermediates.

The major species of unintegrated linear viral DNA identified in chicken embryonic fibroblasts infected with either the avian myeloblastosis-associated viruses (MAV-1, MAV-2) or the standard avian myeloblastosis virus complex (AMV-S) has a mass of 5.3 X 10(6) daltons. An additional minor DNA component observed only in AMV-S-infected cells has a mass of 4.9 X 10(6) daltons. The unintegrated linear viral DNAs and integrated proviruses of MAV-1 and MAV-2 have been analyzed by digestion with the restriction endonucleases EcoRI and HindIII. MAV-2 lacks a HindIII site present in MAV-1. These fragments have been compared to those generated by EcoRI and HindIII digestion of linear viral DNAs of AMV-S. Restriction enzyme digestion of AMV-S viral DNA produced unique fragments not found with either MAV-1 or MAV-2 viral DNAs. The major viral component present in AMV-S stocks has the HindIII restriction pattern of MAV-1. Restriction enzyme analysis of the 5.3 X 10(6)-dalton unintegrated MAV viral DNAs and their integrated proviruses suggests that the DNAs have a direct terminal redundancy of approximately 0.3 megadaltons and integrate colinearly with respect to the unintegrated linear DNA.     

Sequence-specific interaction with the viral AL1 protein identifies a geminivirus DNA replication origin.

The bipartite geminiviruses such as tomato golden mosaic virus (TGMV) and squash leaf curl virus (SqLCV) have two single-stranded circular genomic DNAs, the A and B components, thought to be replicated from double-stranded circular DNA intermediates. Although it has been presumed that the origin sequences for viral replication are located in the highly conserved 200-nucleotide common region (CR) present in both genomic components and that the viral-encoded AL1 protein interacts with these sequences to effect replication, there has been no evidence that this is in fact so. We have investigated these questions, demonstrating selectivity and sequence specificity in this protein-DNA interaction. Simple component switching between the DNAs of TGMV and SqLCV and analysis of replication in leaf discs showed that whereas the A components of both TGMV and SqLCV promote their own replication and that of their cognate B component, neither replicates the noncognate B component. Furthermore, using an in vivo functional replication assay, we found that cloned viral CR sequences function as a replication origin and direct the replication of nonviral sequences in the presence of AL1, with both circular single-stranded and double-stranded DNA being synthesized. Finally, by the creation of chimeric viral CRs and specific subfragments of the viral CR, we demonstrated sequence-specific recognition of the replication origin by the AL1 protein, thereby localizing the origin to an approximately 90-nucleotide segment in the AL1 proximal side of the CR that includes the conserved geminiviral stem-loop structure and approximately 60 nucleotides of 5' upstream sequence. By deletional analysis, we further demonstrated that the conserved stem-loop structure is essential for replication. These studies identify the functional viral origin of replication within the CR, demonstrating that sequence-specific recognition of this origin by the AL1 protein is required for replication.     

Heterogeneity of Epstein-Barr virus. III. Comparison of a transforming and a nontransforming virus by partial denaturation mapping of their DNAs.

The DNAs of a transforming and a nontransforming Epstein-Barr virus strain, B95-8 AND P3HR-1, were compared by partial denturation mapping. B95-8 viral DNA showed a homogeneous denaturation pattern. In contrast, P3HR-1 viral DNA was heterogeneous, containing at least two classes of molecules, classified into groups A and B and present in a ratio of about 2:1 to 3:1. No evidence could be obtained that molecules from both groups A and B contain identical sequences present in different orientations as described for herpes simplex viral DNA. The majority of sequences present in B95-8 and in P3HR-1 viral DNA group A could be correlated by assuming that different sequences, about 12,000 base pairs long, were inserted or deleted, respectively, at different position of both viral genomes.     

DNA of herpesvirus pan, a third member of the Epstein-Barr virus-Herpesvirus papio group

The DNA of herpesvirus pan, a primate B-lymphotropic herpesvirus, shares about 40% well-conserved sequence relatedness with Epstein-Barr virus (EBV) and herpesvirus papio DNAs. Labeled cloned fragments from the EBV recombinant DNA library were cross hybridized to blots of EcoRI, XbaI, and BamHI restriction endonuclease fragments of herpesvirus pan DNA to identify and map homologous sequences in the herpesvirus pan genome. Regions of colinear homology were demonstrated between 6 x 10(6) daltons and 108 x 10(6) daltons in the DNAs. The structural organization of herpesvirus pan DNA was similar to the format of Epstein-Barr virus and herpesvirus papio DNAs. The DNA consists of two domains of largely unique sequence complexity, a segment US of 9 x 10(6) daltons and a segment UL of 88 x 10(6) daltons. US and UL are separated by a variable number of tandem repetitions of a sequence IR (2 x 10(6) daltons). There was homology between DNA which mapped at 26 to 28 x 10(6) daltons and 93 to 95 x 10(6) daltons in UL. The terminal reiteration component, TR, of herpesvirus pan DNA and sequences which mapped to the left of 6 x 10(6) daltons and to the right of 108 x 10(6) daltons had no detectable homology with the corresponding regions of Epstein-Barr virus DNA.     

Possible mechanism of adenovirus generation from a cloned viral genome tagged with nucleotides at its ends

The entire cloned human adenovirus type 5 (Ad5) genome is known to be able to generate infectious virus after transfection into 293 cells when the both ends of the genome are exposed by digestion with appropriate restriction enzymes. However, when one or both ends of the genome are tagged with nucleotides and are not intact, whether the tagged end of the viral genome was remained tagged or corrected to be intact during the generation of viral clones has been unclear and, if such oligonucleotide removal occurs, how does the virus remove these tagged sequences and thereby restore its proper structure? Here, we show in our semi‐quantitative study that the generation efficiency of virus clones decreases depending on the length of nucleotide tags at the both ends and that both the oligonucleotide tags were precisely removed during virus generation with restoration of the proper terminal sequences. Interestingly the viral genome of which one end was tagged, while the other was attached about 12‐kb sequences, did generate intact viral clones at a reduced but significant efficiency. From these results, we here propose a possible mechanism whereby the terminal‐protein‐deoxycytidine complex enters from the enzyme‐cleaved end and reaches deoxyguanine at the initiating position of DNA synthesis in vivo. A replication origin at one end, embedded deeply in double‐stranded DNA, can be activated by two cycles of one‐directional full‐length DNA synthesis initiated by the other exposed replication origin about 30 kilobases away. We also describe new cassette cosmids which can use not only PacI but also BstBI for construction of an adenovirus vector, without reducing construction efficiency.     

Organization of type C viral DNA sequences endogenous to baboons: analysis with cloned viral DNA.

Unintegrated linear and circular forms of baboon endogenous type C virus M7 DNA were prepared from M7-infected cells by chromatography on hydroxyapatite columns, and the circular DNAs were purified in cesium chloride-ethidium bromide equilibrium density gradients. The circular DNAs were linearized by digestion with EcoRI, which had a unique site on the viral DNA. The linearized DNA was then inserted into lambda gtWES. lambda B at the EcoRI site and cloned in an approved EK2 host. Molecularly cloned full-length M7 DNA was restricted with BamHI, and the resulting five subgenomic fragments were then subcloned individually in plasmid pBR322. The organization and sites of integration of the approximately 100 copies of M7 DNA sequences endogenous to baboons were investigated by digesting the DNA with restriction enzymes and identifying the virus-specific fragments by hybridization to labeled probes made by using the molecularly cloned full-length and subgenomic fragments of the viral DNA. We found that most of the endogenous sequences had sizes and organizations similar to those of the unintegrated viral DNA and therefore approximately similar to the RNA of the infectious virus. A few of the multiple sequences had deletions in the 3' end (envelope region), and some of the sequences either lacked or contained modified BamHI restriction sites on the 5' end of the viral DNA. The endogenous viral DNA sequences were nontandem, uninterrupted, and colinear with the DNA of the infectious virus, and they were integrated at different sites in the baboon DNA, like the M7 proviral DNA sequences acquired upon infection.     

Effect of nucleotide analogs on the cleavage of DNA by the restriction enzymes AluI, DdeI, HinfI, RsaI, and TaqI

The cleavage of specific DNA sequences by the restriction endonucleases AluI, DdeI, HinfI, RsaI, and TaqI has been studied by monitoring the effect of various nucleotide modifications on the rate of DNA digestion. Bacteriophage fd DNA was completely substituted in one strand with a single nucleotide analog, using an in vitro primed DNA synthesis reaction on a single-stranded viral DNA template. Twelve deoxynucleotide analogs were incorporated into these DNA substrates: 2-aminopurine, 2,6-diaminopurine, deoxytubercidin, deoxyuridine, 5-bromodeoxyuridine, 5-allylamine deoxyuridine, 5-biotinyl deoxyuridine, deoxypseudouridine, deoxyinosine, 8-azadeoxyguanosine, 5-iododeoxycytidine, and 5-bromodeoxycytidine. The restriction enzymes tested varied considerably in their ability to digest hemi-substituted DNAs containing these modified nucleotides. Structural alterations in the base pairs immediately adjacent to the phosphodiester bonds cleaved by the enzyme reduced the rate of enzyme activity most dramatically, and in most cases more than a single determinant on each base pair altered activity. Interactions with nucleotides outside the recognition site seem to have little importance in the binding or catalytic activity of these enzymes.     

Conservation and progressive methylation of Epstein-Barr viral DNA sequences in transformed cells.

The structure of intracellular viral DNA from a number of cell lines arising by clonal transformation of human lymphocytes in vitro with Epstein-Barr virus was analyzed. Intracellular viral DNAs were partially purified and digested with several restriction endonucleases, and the products of digestion were separated by electrophoresis in agarose gels. The viral fragments were detected by transferring the DNA from the gel to nitrocellulose sheets, hybridizing radiolabeled recombinant vectors carrying fragments of viral DNA to those transfers, and visualizing the hybrids by autoradiography. These analyses indicated that: (i) regions of repetitious viral DNA do undergo expansion and contraction although one size predominates; (ii) novel sequence arrangements appear in the intracellular viral DNA of different clones but are not found in clones analyzed serially and propagated extensively; (iii) the viral DNA is increasingly methylated upon cell propagation. We have not identified a transformed cell phenotype or a viral phenotype that segregates with the observed progressive methylation. We have not detected in Epstein-Barr viral plasmids analogs of the gross rearrangements of viral DNAs observed after lytic infections with high multiplicities of papova-, adeno-, or herpes simplex viruses.     

Purification and characterization of a DNA-pairing and strand transfer activity from mitotic Saccharomyces cerevisiae

An enzyme catalyzing homologous pairing of DNA chains has been extensively purified from mitotic yeast. The most highly purified fractions are enriched for a polypeptide with a molecular mass of approximately 120 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Protein-dependent pairing of single-stranded DNAs requires a divalent cation (Mg2+ or Ca2+) but proceeds rapidly in the absence of any nucleoside triphosphates. The kinetics of reassociation are extremely rapid, with more than 60% of the single-stranded DNA becoming resistant to S1 nuclease within 1 min at a ratio of 1 protein monomer/50 nucleotides. The results of enzyme titration and DNA challenge experiments suggest that this protein does not act catalytically during renaturation but is required stoichiometrically. The protein promotes formation of joint molecules between linear M13 replicative form DNA (form III) containing short single-stranded tails and homologous single-stranded M13 viral DNA. Removal of approximately 50 nucleotides from the ends of the linear duplex using either exonuclease III (5' ends) or T7 gene 6 exonuclease (3' ends) activates the duplex for extensive strand exchange. Electron microscopic analysis of product molecules suggests that the homologous circular DNA initially associates with the single-stranded tails of the duplexes, and the heteroduplex region is extended with displacement of the noncomplementary strand. The ability of this protein to pair and to promote strand transfer using either exonuclease III or T7 gene 6 exonuclease-treated duplex substrates suggests that this activity promotes heteroduplex extension in a nonpolar fashion. The biochemical properties of the transferase are consistent with a role for this protein in heteroduplex joint formation during mitotic recombination in Saccharomyces cerevisiae.     

Binding specificity of the two major DNA-binding proteins in human serum.

The two major DNA-binding proteins of human serum (DNA-binding protein 1 and DNA-binding protein 2) were shown to bind preferentially to single-stranded polynucleotides rich in guanine residues. Equilibrium competition experiments using a nitrocellulose filter assay system containing labeled human lymphocyte DNA and various competing natural and synthetic polynucleotides indicated that both proteins recognized sequences of bases containing a keto group in either position 6 (purines) or 4 (pyrimidines) and that these keto groups must be readily accessible for effective binding to occur. Guanine was shown to be the preferred nucleotide through inhibition experiments using a series of synthetic homopolymers and a series of bacterial DNAs of differing G + C content. The relationship between protein affinity and G + C content was shown to be directly proportional. The equilibrium constants for the binding of the human lymphocyte DNA by both proteins were on the order of 10(-6) M, and the length of the nucleotide sequence necessary for effective binding was found to be 12 to 18 bases using a series of oligomers of poly(dG).     

Epstein-Barr virus DNA. IX. Variation among viral DNAs from producer and nonproducer infected cells.

A comparative analysis of three Epstein-Barr virus DNAs from American patients with infectious mononucleosis (B95-8, Cherry, and Lamont) and four Epstein-Barr virus DNAs from African patients with Burkitt lymphoma (AG876, W91, Raji, and P3HR-1) indicated that the usual format of Epstein-Barr virus DNA includes a variable number of direct repeats of a 0.35 X 10(6)-dalton sequence (TR) at both ends of the DNA, a 9 X 10(6)-dalton sequence of largely unique DNA (Us), a variable number of repeats of a 2 X 10(6)-dalton sequence (IR), and a 89 X 10(6)-dalton sequence of largely unique DNA (UL). Within UL there was homology between DNA at 26 X 10(6) to 28 X 10(6) daltons and DNA at 93 X 10(6) to 95 X 10(6) daltons. The relative sequence order (TR, US, IR, UL, TR) did not vary among "standard" Epstein-Barr virus DNA molecules of each isolate. B95-8 DNA had an unusual deletion extending from 91 X 10(6) to 100 X 10(6) daltons, and P3HR-1 DNA had an unusual deletion extending from 23.5 X 10(6) to 26 X 10(6) daltons. There was sufficient variability among the EcoRI and BamHI fragments of the DNAs to identify each isolate specifically. However, we discerned no distinguishing features for the two geographic or pathogenic origins of the seven isolates. Three intracellular DNAs (Raji, Lamont, and Cherry) and one virion DNA (P3HR-1) were heterogenous in molecular organization and had subpopulations of rearranged or defective molecules. Some regions, particularly 59 X 10(6) to 63 X 10(6) daltons and sequences around TR, frequently participated in rearrangements. Restriction endonuclease maps of the standard and rearranged DNAs of the seven isolates are presented.