Viral DNA sequences from incomplete particles of human adenovirus type 7

Large pools of empty viral capsids accumulate in cells infected by subgroup B human adenoviruses. Such infected cells also yield DNA-containing incomplete particles in larger quantities than cells infected with serotypes representing other adenovirus subgroups. DNA isolated from carefully purified classes of Ad7 incomplete particles was analyzed by restriction endonuclease cleavage, gel electrophoresis and electron microscopy. At least 90% of the DNA molecules in each sample consisted of sequences that extended from the left end of the viral genome map by variable lengths toward the right end. The average length of DNA is linearly related to the average buoyant density of the incomplete particles from which the DNA is isolated. The results indicate that each capsid contains one DNA molecule. There is also a specific association of the left end of the viral genome with assembled or assembling capsids. The characteristic distributions of Ad7 incomplete particles may result from intracellular pools of assembly intermediates in which the incompletely packaged DNA has been fragmented in vivo or by shear during preparative procedures.     

Encapsidation of adenovirus 16 DNA is directed by a small DNA sequence at the left end of the genome

We have identified a DNA sequence in adenovirus type 16 which contains recognition signals for encapsidation of the viral DNA. The sequence acts in cis to direct the encapsidation of DNA from the end of the viral genome where it is located. The sequence is normally contained in the first 390–400 bp of the left end of the genome. The location was determined by analyzing a series of spontaneous mutants of Ad16 which carried reduplications of 200 to >500 bp of left end sequences at the right end of the genome, thus giving rise to enlarged inverted terminal repetitions (ITR). In plaque-purified (PP) Ad16 prototype virus the subgenomic DNA found in incomplete virus particles exclusively represents left end sequences. When the reduplication mutants were analyzed, we found that a reduplication of about 390 bp enabled subgenomic DNA molecules containing the right end to be encapsidated into incomplete particles as well. A reduplication of about 290 bp, however, did not allow subgenomic DNA containing the right end to be encapsidated. The difference in encapsidation described could not be attributed to an asymetric DNA replication in the mutants, since subgenomic DNA originating from both ends of the genome was produced in equal amounts in the infected cells. We conclude that an essential part of the encapsidation sequence must be located between 290 and 390 bp from the left end of the Ad16 genome.     

Molecular structure of adeno-associated virus variant DNA

When lysates of human cells, infected jointly with the defective parvovirus, adeno-associated virus (AAV), and a helper adenovirus, are banded to equilibrium in CsCl buoyant density gradients, virus particles of various densities are obtained. Infectious AAV particles mainly band at a density of 1.41 g/cm3 with a minor component at 1.45 g/cm3. Noninfectious AAV particles band at densities between 1.41 and 1.32 g/cm3. We have analyzed, by mapping with site-specific endodeoxyribonucleases, the molecular structure of the variant AAV DNA molecules obtained from these light density particles. The size of variant DNA molecules ranged from 100 to 3% of genome length. In general, the variant DNAs are deleted for internal regions but retain the genome termini. Some of the variant DNAs appear to be cross-linked, spontaneously renaturing molecules having structures analogous to replicating forms of AAV DNA.     

Synthesis of defective viral DNA in HeLa cells infected with adenovirus type 3.

Virus-specific DNA fragments that are shorter than the full-length viral genomes have been isolated from HeLa cells productively infected with adenovirus type 3. A number of predominant size classes could be detected by gel electrophoresis and hybridization, and the array of sizes was similar or identical to the selection in DNA purified from incomplete particles of this serotype (E. Daniell, J. Virol. 19:685-708, 1976). A large fraction of these short DNA molecules contained long inverted terminal repetitions, as did DNA molecules from incomplete particles. Restriction analysis showed that these subgenomic molecules consist of sequences from the two molecular ends of the normal genome. These results suggest that the predominance of left-hand end fragments seen in packaged incomplete DNAs results from selective packaging, whereas the predominance of certain size classes of intracellular viral DNA is a function of prepackaging events. The incomplete DNAs were generated at all times during viral DNA replication, and the yield relative to complete DNA did not seem to vary significantly with time or multiplicity of infection or when the virus was propagated on different human cell types.     

Enhanced quaternary stability of beta hemoglobin in 2 M-sodium chloride

End fragments of molecular weight 1 to 2.5 × 10⁶ were prepared from the DNA molecules of human adenovirus 2 and simian adenovirus SA-7. These end pieces were shown by DNA-DNA hybridization to contain only 15 to 30% of the sequences present in the entire genome. These data eliminate the possibility that adenovirus DNA molecules are circularly permuted.     

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.     

Structure of Herpesvirus saimiri genomes: arrangement of heavy and light sequences in the M genome.

Herpesvirus saimiri contains two species of DNA molecules. (i) The M genome is composed of 70% light (L) DNA (36% cytosine plus guanine; density in CsCl, 1.695 g/ml), which consists of unique sequences, and 30% heavy (H) DNA (71% cytosine plus guanine; density, 1.729 g/ml). (ii) The H genome contains heavy sequences exclusively. H sequences in M and H genomes cross-hybridize completely and are cleaved identically by restriction endonuclease R-Sma I into four classes of fragments with molecular weights of about 360,000, 300,000, 130,000 and 40,000, respectively. H sequences are chains of identical repeat units in tandem arrangement. The molecular weight of each repeat unit is about 830,000. L sequences have no cleavage site for endo R-Sma I H sequences are terminally arranged at both ends of the M genome, as seen by electron microscopy after partial denaturation. The length of the individual heavy ends varies between 21 mum and less than 1 mum, whereas the light region is uniform in size (35.3+/-0.35 mum). As a rule, molecules with a long heavy end at one side have a short heavy end at the other side, thus giving rise to a limited size heterogeneity. Orientation of M DNA molecules by the denaturation map of the light region shows that the longer heavy end may be located at the left or at the right side of the M genome.     

Replication of adenovirus mini-chromosomes

We have isolated adenovirus origins of DNA replication from both the right and left ends of the genome, which are functional on linear autonomously replicating mini-chromosomes. The mini-chromosomes contain two cloned inverted adenovirus termini and require non-defective adenovirus as a helper. Replicated molecules are covalently attached to protein, and DNA synthesis is initiated at the correct nucleotide even when the origins are not located at molecular ends. The activity of embedded origins leads to the generation of linear minichromosomes from circular or linear molecules. These observations therefore suggest that sequences within the adenovirus origin of replication position the protein priming event at the adenovirus terminus. Experiments investigating the regeneration of deleted viral inverted terminal repeat sequences show a sequence-independent requirement for inverted sequences in this process. This result strongly suggests that repair results from the formation of a panhandle structure by a displaced single strand. On the basis of these observations we propose a model for the generation of adenovirus mini-chromosomes from larger molecules.     

The origin of adenovirus DNA replication: minimal DNA sequence requirement in vivo.

Adenovirus mini-chromosomes which contain two cloned, inverted adenovirus termini replicate in vivo when supplied with non-defective adenovirus as a helper. This system has been used to define the minimum cis acting DNA sequences required for adenovirus DNA replication in vivo. Deletions into each end of the adenovirus inverted terminal repeat (ITR) were generated with Bal31 exonuclease and the resulting molecules constructed into plasmids which contained two inverted copies of the deleted ITR separated by the bacterial neomycin phosphotransferase gene. To determine the effect of the deletion in vivo plasmids cleaved to expose the adenovirus termini were co-transfected with adenovirus type 2 DNA into tissue culture cells. The replicative ability of the molecules bearing adenovirus termini was assayed by Southern blotting of extracted DNA which had been treated with DpnI, a restriction enzyme which cleaves only methylated and therefore unreplicated, input DNA. Molecules containing the terminal 45 bp of the viral genome were fully active whereas molecules containing only 36 bp were in-active in this assay. Therefore sequences required for DNA replication are contained entirely within the terminal 45 bp of the viral genome. Thus, both the previously described highly conserved region (nucleotides 9-18) and the binding site for the cellular nuclear factor I (nucleotides 19-48) are essential for adenovirus DNA replication in vivo.     

Rescue of functional replication origins from embedded configurations in a plasmid carrying the adenovirus genome.

A variant of the adenovirus type 5 genome which lacks EcoRI sites has been cloned in a bacterial plasmid after the addition of EcoRI oligonucleotide linkers to its ends. Closed circular forms of the recombinant viral genome were not infectious upon their introduction into permissive eucaryotic cells. The linear genome released by digestion of the 39-kilobase recombinant plasmid (pXAd) with EcoRI produced infectious virus at about 5% of the level of wild-type controls. The viruses which arose were indistinguishable from the parental strain, and the normal termini of the viral genome had been restored. Marker rescue experiments demonstrate that provision of a DNA fragment with a normal viral end improves infectivity. When a small fragment carrying a wild-type left end (the 0 to 2.6% ClaI-B fragment) was ligated to ClaI-linearized pXAd, virus was produced with efficiencies comparable to a similar reconstitution of the two ClaI fragments of the wild-type genome. These viruses stably carry the left-end fragment at both ends, leaving the normal right end embedded in 950 base pairs of DNA. The embedded right origin is inactive. The consensus of the analyses reported here is that a free end is a necessary configuration for the sequences which make up the adenovirus origin of replication.     

Characterization of a Temperature-Sensitive Fiber Mutant of Type 5 Adenovirus and Effect of the Mutation on Virion Assembly

A temperature-sensitive, fiber-minus mutant of type 5 adenovirus, H5ts142, was biochemically and genetically characterized. Genetic studies revealed that H5ts142 was a member of one of the three apparent fiber complementation groups which were detected owing to intracistronic complementation. Recombination analyses showed that it occupied a unique locus at the right end of the adenovirus genetic map. At the nonpermissive temperature, the mutant made stable polypeptides, but they were not glycosylated like wild-type fiber polypeptides. Sedimentation studies of extracts of H5ts142-infected cells cultured and labeled at 39.5°C indicated that a limited number of the fiber polypeptides made at the nonpermissive temperature could assemble into a form having a sedimentation value of 6S (i.e., similar to the trimeric wild-type fiber), but that this 6S structure was not immunologically reactive. When H5ts142-infected cells were shifted to the permissive temperature, 32°C, fiber polypeptides synthesized at 39.5°C were as capable of being assembled into virions as fibers synthesized in wild type-infected cells; de novo protein synthesis was not required to allow this virion assembly. In H5ts142-infected cells incubated at 39.5°C, viral proteins accumulated and aggregated into particles having physical characteristics of empty capsids. These particles did not contain DNA or its associated core proteins. However, when the infected culture was shifted to 32°C, DNA appeared to enter the empty particles and complete virions developed. The intermediate particles obtained had the morphology of adenoviruses, but they contained less than unit-length viral genomes as measured by their buoyant density in a CsCl density gradient and the size of their DNA as determined in both neutral and alkaline sucrose gradients. The reduced size of the intermediate particle DNA was demonstrated to be the result of incompletely packaged DNA molecules being fragmented during the preparative procedures. Hybridization of labeled DNA extracted from the intermediate particles to filters containing restriction fragments of the adenovirus genome indicated that the molecular left end of the viral genome preferentially entered these particles.     

Viral DNA in transformed cells: II. A study of the sequences of adenovirus 2 DNA in nine lines of transformed rat cells using specific fragments of the viral genome

³²P-labeled adenovirus 2 DNA was treated with restricting endonuclease from Escherichia coli strain RY-13 (Yoshimori, 1972) (EcoRI) or restricting endonuclease from Hemophilus parainfluenzae (Hpa I) and the resulting fragments of DNA were separated by gel electrophoresis. The kinetics of renaturation of each of the fragments and of complete adenovirus 2 DNA were measured in the presence of DNA extracted from nine lines of adenovirus 2-transformed rat cells and from control cells. Six of the transformed cell lines contained viral DNA sequences homologous to two of the seven Hpa I⁴ fragments and to part of one of the six EcoRI fragments. From the order of the fragments formed by EcoRI and Hpa I on the adenovirus 2 map we conclude that these cell lines contain only the segment of viral DNA that stretches from the left-hand end to a point about 14% along the viral genome. Thus, any viral function expressed in transformed cells must be coded by this small section of viral DNA. The three remaining lines of adenovirus 2-transformed rat cells are more complicated and contain not only the sequences from the left-hand end of the viral DNA, but also other segments of the viral genome. However, no adenovirus 2-transformed rat cell contained DNA sequences homologous to the complete viral genome.     

Organization of shared and unshared sequences in the genomes of chicken endogenous and sarcoma viruses.

The genome of the genetically transmitted endogenous C type virus of chickens, RAV-O, is closely related to that of Rous sarcoma virus (RSV). Nevertheless, these viruses differ widely in oncogenicity and regulation by the host cell. Competitive hybridization analysis of ¹²⁵I-labeled genomic RNA demonstrated that the genome of RAV-O lacks about 35% of the sequences of nondefective RSV which formed hybrids with proviral DNA from RSV-infected cells, and that the genome of transformation-defective deletion mutants of RSV (td RSV) lacks about 15% of these sequences. Conversely, about 12% of the RAV-O sequences forming hybrids with normal chicken cell DNA were not detected in the sarcoma virus. A technique was developed to map the location of these unshared sequences by competitive hybridization. The deletion in the genome of td RSV was seen to begin at about 0.2 and to end at about 0.05 of the genome length from the 3′ end of sarcoma virus RNA, confirming the results of other laboratories using the method of mapping RNAase TI resistance of oligonucleotides. The 35% of RSV sequences missing and/or diverged in the genome of RAV-O were concentrated within 40% of the sarcoma virus genome from the 3′ end, and most of this large section did not appear to form hybrids with chicken DNA under the conditions of these experiments. A low level of hybrid formation was, however, detected between uninfected chicken cellular DNA and a small fraction of the nucleotides in the region of the td deletion. Analysis of RAV-O 3′ end fragments demonstrated that the genomic sequences of RAV-O missing in RSV were concentrated at the 3′ end of the endogenous viral genome. We conclude that the sequence differences between endogenous and sarcoma viruses are largely concentrated in specific regions of the viral genome.     

Structure and function of adenovirus type 12 defective virions.

Purified human adenovirus type 12 preparations contain defective virions with a lighter density. These defective virions were isolated, and their biological functions and DNA were characterized. They can induce early and late antigens in infected cells and tumors in newborn hamsters with similar efficiency as complete virions. The majority of the DNA molecules from light virions contain deletions mapping near 16% from the left-hand end of the genome. Mechanisms for the generation of these molecules are discussed.     

Comparison of viral RNA sequences in adenovirus 2-transformed and lytically infected cells

The complementary strands of fragments of ³²P-labelled adenovirus 2 DNA generated by cleavage with restriction endonucleases EcoRI or Hpa1 were separated by electrophoresis. Saturation hybridization reactions were performed between these fragment strands and unlabelled RNA extracted from the cytoplasm of adenovirus 2-transformed rat embryo cells or from human cells early after adenovirus 2 infection. The fraction of each fragment strand complementary to RNA from these sources was measured by chromatography on hydroxylapatite. Maps of the viral DNA sequences complementary to messenger RNA in different lines of transformed cells and early during lytic infection of human cells were constructed.Five lines of adenovirus 2-transformed cells were examined. All contained the same RNA sequences, complementary to about 10% of the light strand of EcoRI fragment A. DNA sequences coding for this RNA were more precisely located using Hpa1 fragments E and C and mapped at the left-hand end of the genome. Thus any viral function expressed in all adenovirus 2-transformed cells, tumour antigen, for example, must be coded by this region of the viral genome. Two lines, F17 and F18, express only these sequences; two others, 8617 and REM, also contain mRNA complementary to about 7% of the heavy strand of the right-hand end of adenovirus 2 DNA; a fifth line, T2C4, contains these and many additional viral RNA sequences in its cytoplasm.The viral RNA sequences found in all lines of transformed cells are also present in the cytoplasm of human cells during the early phase of a lytic adenovirus infection. The additional cytoplasmic sequences in the 8617 and REM cell lines also correspond to “early” RNA sequences.     

Infectious circular DNA of human adenovirus type 5: regeneration of viral DNA termini from molecules lacking terminal sequences.

A series of plasmids containing the entire human adenovirus genome with viral DNA termini joined 'head to tail' has been isolated. Several plasmids were able to generate infectious virus following transfection of human cells in spite of having small deletions and rearrangements at the junctions of termini. One plasmid has lost 2 bp of DNA from one end of the viral genome and 11 bp from the other end yet produced viruses with complete wild-type sequences at both ends of the genome. We propose a model for replication of viral DNA off circular templates in which regeneration of terminal information involves translocation of primer and polymerase during initiation of DNA replication. The model suggests a novel mechanism for extension of the 5' ends of linear DNA molecules which could be applicable to chromosomal telomeres.     

Size analysis and relationship of murine leukemia virus-specific mRNA''s: evidence for transposition of sequences during synthesis and processing of subgenomic mRNA.

Virus-specific mRNA from purified polyribosomes of mouse cells infected with Moloney murine leukemia virus (M-MuLV) was analyzed by electrophoresis in agarose gels, followed by hybridization of gel slices with M-MuLV-specific complementary DNA (cDNA). The size resolution of the gels was better than that of sucrose gradients used in previous analyses, and two virus-specific mRNA's of 38S and 24S were detected. The 24S virus-specific mRNA is predominantly derived from the 3' half of the M-MuLV genome, since cDNAgag(pol) (complementary to the 5' half of the M-MuLV genome) could not efficiently anneal with this mRNA. However, sequences complementary to cDNA synthesized from the extreme 5' end of M-MuLV 38S RNA (cDNA 5') are present in the 24S virus-specific mRNA, since cDNA 5' (130 nucleotides) efficiently annealed with this mRNA. The annealing of cDNA 5' was not due to repetition of 5' terminal nucleotide sequences at the 3' end of M-MuLV 38S RNA, since smaller cDNA 5' molecules (60 to 70 nucleotides), which likely lack the terminal repetition, also efficiently annealed with the 24S mRNA. The sequences in 24S virus-specific mRNA recognized by cDNA 5' are not present in 3' fragments of virion RNA that are the same length. Therefore, it appears that RNA sequences from the extreme 5' end of the M-MuLV genome may be transposed to sequences from the 3' half of the M-MuLV 38S RNA during synthesis and processing of the 24S virus-specific mRNA. These results may indicate a phenomenon similar to the RNA splicing processes that occur during synthesis of adenovirus and papovavirus mRNA's.     

Adenovirus type 12-induced rat tumor cells of neuroepithelial origin: persistence and expression of the viral genome.

Four cell lines derived from adenovirus type 12-induced rat brain tumors were studied. The polyploid cells displayed neuroepithelial characteristics and were transplantable into syngeneic rats and nude mice. In tissue culture the cells grew in monolayers and multilayers. A very high saturation density was reached, and the cells plated in agar and were easily agglutinated with low concentrations of concanavalin A. Between 2 and 11 copies of the viral genome per diploid cellular genome were detected by reassociation kinetics analysis in the different lines. The patterns of distribution of viral DNA sequences in these lines, as revealed by blot analysis, suggest colinear integration of the intact viral genome into the cellular DNA. The patterns of integration were stable after more than 15 months of prolonged tissue culture and after animal reimplantation. Integration patterns were identical in three of the tumor lines and different in another line. Viral sequences were transcribed. The extent of homology found toward adenovirus type 12 DNA in polyadenylated polysome-associated mRNA isolated from the tumor lines suggests that the early and some of the late genes of adenovirus type 12 DNA are transcribed in these tumor cells. Infectious virus was not rescuable from these lines.     

Cloning and physical mapping of enteric adenoviruses (candidate types 40 and 41)

We have studied the DNAs of fastidious enteric adenoviruses recovered from the stools of infants with gastroenteritis. By endonuclease analysis, the strains examined represent candidate adenovirus types 40 and 41, which are thought to comprise new adenovirus subgroups F and G. Cloning of DNA from representative enteric adenovirus isolates, together with hybridization and subcleavage analysis, permitted the mapping of restriction enzyme cleavage sites. Although the restriction profiles are different for the two strains, they appear to have several cleavage sites in common. Cross hybridization studies show considerable homology between the subgroup F and G strains but much less homology to adenovirus 2. In addition, regions on both ends of enteric adenovirus genomes (map units, 2.9 to 11.3 and 75 to 100) possess little or no homology to adenovirus 2. Restriction enzyme digests reveal submolar fragments that map to the terminal regions of the genome. Electron micrographic studies of denatured and renatured DNA strands suggest that the submolar fragments may derive from cleavage of defective molecules. Inverted terminal repeat sequences were shown to comprise 0 to 3.2% of the length of complete (greater than or equal to 22 megadaltons) enteric adenovirus DNA molecules but 4 to 69% of incomplete-length (less than 22-megadalton) molecules.