Cloning of Herpesvirus saimiri DNA fragments representing the entire L-region of the genome

Purified particles of Herpesvirus saimiri, a potent tumor-eliciting virus of primates, contain genomic DNA molecules (145-170 kb) consisting of a unique L-DNA region (112 kb) which is flanked by variable stretches of repetitive sequences (H-DNA). Restriction fragments representing the entire L-DNA of H. saimiri strain No. 11 were cloned in plasmid and bacteriophage vectors. The internal fragments of L-DNA generated by the enzymes EcoRI and KpnI were inserted into plasmid pACYC184, cosmid pJC81, or bacteriophage lambda derivative Charon 4A. The terminal parts of L-DNA, including the junctions between repetitive DNA and unique sequences, were cloned between the cleavage sites for KpnI and SmaI in the plasmid vector pWD7, which was constructed for this purpose. Molecular cloning allowed us to confirm and modify, in part, the existing cleavage maps of H. saimiri DNA. It provides a basis for future studies on virus replication and oncogenic transformation.     

Construction of replication-competent Herpesvirus saimiri deletion mutants

DNA fragments derived from the left end of Herpesvirus saimiri 11 L-DNA were cloned in Escherichia coli by using vector pBR322. Deletions were introduced within a cloned 7.4-kilobase-pair sequence by using restriction endonucleases that cut once or twice within this sequence. Permissive owl monkey kidney-cultured cells were transfected with parental strain 11 viral DNA plus cloned DNA with specific sequences deleted. By screening the progeny of these transfections with a limiting-dilution spot hybridization assay, we isolated recombinant viruses containing deletions in this region. A contiguous 4.5-kilobase-pair sequence representing 4.1% of the coding capacity of the virus was found to be unnecessary for virus replication in cultured cells. These deletion mutants will allow us to test whether sequences in this region are required for the lymphoma-inducing capacity of H. saimiri. These same procedures should also allow us to introduce foreign DNA sequences into this region for studying their expression.     

Selectable recombinant herpesvirus saimiri is capable of persisting in a human T-cell line.

Strategies were developed to insert the neo resistance marker into the junction between L DNA and the right terminal repetitive H DNA of herpesvirus saimiri. Recombinant viruses were selectable in permissive epithelioid cultures. The human T-cell line Jurkat could be infected persistently with the Neor virus; the cells contained episomal viral DNA in high copy number. This selectable vector should be generally applicable for gene expression in human T cells.     

Deletion mutants of herpesvirus saimiri define an open reading frame necessary for transformation.

Analysis of a 5,549-base-pair sequence at the left end of herpesvirus saimiri unique (L-) DNA revealed two open reading frames and genes for five small nuclear U RNAs (herpesvirus saimiri U RNAs). Replication-competent deletion mutants were constructed in order to assess the importance of these genetic features for transformation by this oncogenic herpesvirus. Although not required for replication, one of the open reading frames was found to be required for immortalization of marmoset T lymphocytes into continuously growing cell lines. The protein predicted by this reading frame (STP; saimiri transformation-associated protein) has a highly hydrophobic stretch of 26 amino acids sufficient for a membrane-spanning domain near its carboxy terminus; this domain is immediately preceded by a sequence appropriate for formation of a metal-binding domain (His X2 His X6 Cys X2 Cys, where Xs are other amino acids). One of two poly(A)+ RNAs that could encode STP is bicistronic, while the other has a long 5' untranslated region (approximately 1.5 kilobases). Although some analogies can be drawn between STP and LMP (lymphocyte membrane protein) of Epstein-Barr virus, STP is not related in sequence to LMP.     

Arrangement of repetitive sequences in the genome of herpesvirus Sylvilagus.

Herpesvirus sylvilagus is a lymphotropic (type gamma) herpesvirus of cottontail rabbits (Sylvilagus floridanus). Analysis of virion DNA of herpesvirus sylvilagus has revealed that the genome consists of one stretch of about 120 kilobase pairs of internal, unique DNA flanked by a variable number of 553-base-pair tandem repeats. The G + C content of the repetitive DNA is extremely high (83%), as determined by sequencing. The organization of the herpesvirus sylvilagus genome is, therefore, similar to that of the primate lymphotropic viruses herpesvirus saimiri and herpesvirus ateles.     

Structure of nonintegrated, circular Herpesvirus saimiri and Herpesvirus ateles genomes in tumor cell lines and in vitro-transformed cells.

Nonintegrated, circular DNA molecules of Herpesvirus saimiri and Herpesvirus ateles were found in five lymphoid cell lines originating from tumor tissues or established by in vitro immortalization of T lymphocytes. The arrangement of unique (L) and repetitive (H) DNA sequences in circular viral genomes was analyzed by partial denaturation mapping followed by visualization with an electron microscope. Three types of circular viral DNA structures were found. (i) The virus-producing cell line RLC, which is derived from an H. ateles-induced rabbit lymphoma, contains circular viral genomes which consist of a single L-DNA and a single H-DNA region, both the same length as in virion DNA. (ii) The circular viral genomes of the nonproducer cell lines H1591 and A1601, in vitro transformed by H. saimiri and H. ateles, respectively, have deletions in the unique L-DNA region and larger H-DNA regions. Cell line A1601 lacks about 8% of virion L-DNA, and H1591 cells lack about 40% of viral L-DNA information. (iii) The nonproducing H. saimiri tumor cell lines 1670 and 70N2 harbor viral genomes with two L-DNA and two H-DNA regions, respectively. Both types of circular molecules have a long and a short L-segment. The sequence arrangements of circular DNA molecules from H. saimiri-transformed cell lines were compared with those of linear virion DNA by computer alignment of partial denaturation histograms. The L-DNA deletion in cell line H1591 was found to map in the right half of the virion DNA. Comparison of the denaturation patterns of both L regions of cell lines 1670 and 70N2 identified the short L regions as subsets of the long L regions. Thus, circular viral DNA molecules of all four nonproducer cell lines represent defective genomes.     

Herpesvirus saimiri DNA in a lymphoid cell line established by in vitro transformation.

A lymphoid T-cell line (H1591) was established by infecting peripheral blood mononuclear cells from a cotton top marmoset with Herpesvirus saimiri OMI. Analysis of these in vitro-immortalized cells revealed nonintegrated, covalently closed circular viral DNA molecules in high multiplicities with substantial rearrangements and large deletions in their L-DNA (unique) regions. One subline, designated H1591 Er, contained circular viral DNA with one stretch of H-DNA (repetitive) and one of L-DNA; the L-DNA segment consisted of a linear fusion of a 53.2-kilobase-pair piece of L-DNA (left half of L-DNA) with a 15.2-kilobase-pair L-DNA fragment from the right end of the L-DNA region. The other subline, H1591 S, contained two short regions of L-DNA, each derived from the extreme ends of virion L-DNA. Both L-DNA regions of H1591 S cells contained inverted repetitions (15.0 +/- 0.2 and 9.1 +/- 4.7 kilobase pairs). The extensive deletions of L-DNA sequences in cell line H1591 indicate that at least 73% of the genetic information in H. saimiri is not required to maintain the persistence of viral DNA and the state of transformation in lymphoid T-cells.     

Herpesvirus saimiri DNA in tumor cells--deleted sequences and sequence rearrangements.

Herpesvirus saimiri DNA in continuous lymphoblastoid cell lines obtained from viral induced tumors in marmosets has been analyzed by gel electrophoresis of restricted DNA. Southern transfer to nitrocellulose filters, and hybridization to 32P-labeled viral DNA or DNA fragments. The viral DNA fragments EcoRI-G, -H, -D, and -I, KpnI-A, and BamHI-D and -E were not detected in Southern transfers of DNA from the nonproducing 1670 cell line. For each restriction endonuclease, a new fragment appeared, consistent with a 13.0-megadalton deletion of viral DNA sequences. This deletion encompassed 35 to 48 +/- 0.6 megadaltons from the left end of the unique DNA region. A sequence arrangement map is presented for the major population of H. saimiri DNA sequences in the 1670 cell line. Although H. saimiri DNA in the nonproducing 70N2 cell line can be distinguished from viral DNA in the 1670 cell line by several criteria, the same sequences were found to be deleted in the major population of viral DNA molecules. Unlike 1670 and 70N2 cells, restricted DNA from the virus-producing cell lines 77/5 and 1926 contained all of the DNA fragments present in the parental virion DNA. DNA from 1670, 70N2, and 77/5 cells contained additional viral DNA fragments that did not comigrate with any virion DNA fragments. Most of these unexplained fragments were confined to or highly enriched in partially purified circular or linear DNA fractions. DNA from tumor cells taken directly from a tumor-bearing animal contained viral DNA indistinguishable from the parental virion DNA by the assay conditions used. These results indicate that viral DNA sequence rearrangements can occur upon cultivation of tumor cells in vitro and that excision of DNA sequences from the viral genome may play a role in establishing the nonproducing state of some tumor cell lines.     

Genome organization of herpesvirus aotus type 2.

Herpesvirus aotus type 2, a virus commonly found in owl monkeys without overt disease, has a similar genome structure to the oncogenic herpesviruses of nonhuman primates (herpesvirus saimiri, herpesvirus ateles). Virion DNA of herpesvirus aotus type 2 (M-DNA) has an unique 110-kilobase-pair region of low G + C content (40.2%, L-DNA), inserted between stretches of repetitive H-DNA (68.7% G + C, about 41 kilobase pairs per molecule) that are variable in length. A minority of virions contain defective genomes that consist of repetitive H-DNA only. The H-DNA is composed of various types of repeat units that are related in sequence with each other. The two dominant types of repeats (2.3 and 2.7 kilobase pairs) were cloned and compared by restriction enzyme cleavages and partial nucleotide sequencing. They are homologous in at least 1.3 kilobase pairs. The two forms of repeat units are randomly arranged and oriented in tandem. Reassociation kinetics did not allow detection of sequence homologies between H- and L-DNA of herpesvirus aotus type 2 and the respective sequences of oncogenic primate herpesviruses.     

Nucleotide sequence at the site of junction between adenovirus type 12 DNA and repetitive hamster cell DNA in transformed cell line CLAC1.

The hamster cell line CLAC1 originated from a tumor induced by injecting human adenovirus type 12 (Ad12) into newborn hamsters. Each cell contained about 12 copies of viral DNA colinearly integrated at two or three different sites. We have cloned and sequenced a DNA fragment comprising the site of junction between the left terminus of Ad12 DNA and cellular DNA. The first 174 nucleotides of Ad12 DNA were deleted at the site of junction. Within 40 nucleotides, there were one tri-, two tetra-, one penta-, and one heptanucleotide which were identical in the 174 deleted viral nucleotides and the cellular sequence replacing them. In addition, there were patch-type homologies ranging from octa- to decanucleotides between viral and cellular sequences. There is no evidence for a model assuming adenovirus DNA to integrate at identical cellular sites. The cellular DNA sequence corresponding to the junction fragment was cloned also from BHK21 (B3) hamster cells and sequenced. Up to the site of linkage with viral DNA, this middle repetitive cellular DNA sequence was almost identical with the equivalent sequence from CLAC1 hamster cells. Taken together with the results of previously published analyses (11, 12), the data suggest a model of viral (foreign) DNA integration by multiple short sequence homologies. Multiple sets of short patch homologies might be recognized as patterns in independent integration events. The model also accounts for the loss of terminal viral DNA sequences.     

Isolation, localization, and physical mapping of a highly polymorphic locus on human chromosome 11q13.

A highly polymorphic repetitive sequence, D11S533, was isolated by oligonucleotide hybridization from an arrayed chromosome 11q-specific cosmid library. The DNA sequence of this element was determined and found to consist of a repetitive degenerate hexanucleotide sequence [T(Pu)T(Pu)T(Pu)]n extending over 438 bp. Southern blot analysis demonstrated that this element is relatively unique in the human genome. This sequence can be detected by amplification using the polymerase chain reaction (PCR) with oligonucleotide primers complementary to unique sequences flanking the repetitive element. This sequence displays a high degree of polymorphism, and analysis of 15 individuals demonstrated at least 10 alleles ranging in size from 300 to 900 bp. Fluorescence in situ hybridization was used to localize this sequence to 11q13 (FLpter 0.60 +/- 0.02). Pulsed-field gel electrophoresis and the isolation of yeast artificial chromosomes established the long-range physical map surrounding the locus. Because various alleles of this polymorphic sequence can be easily detected by PCR amplification, this probe has potential usefulness in genetic linkage mapping as well as identity testing.     

Isolation and identification of TL-DNA/plant junctions in Convolvulus arvensis transformed by Agrobacterium rhizogenes strain A4

We have constructed a Charon 4A phage library containing insert DNA isolated from a morning glory (Convolvulus arvensis) plant (clone 7) regenerated from a root organ culture incited by Agrobacterium rhizogenes, strain A4. Using a subcloned region of the Ri plasmid as ³²P-labeled probe, two lambda clones containing most of the 'left' T-DNA (TL) region were isolated. One of these lambda clones contains the left TL-DNA/plant junction, which was located by comparing nucleotide sequences from the appropriate regions of the Ri plasmid and this lambda clone. A 25-bp sequence found near this left TL-DNA/plant junction matches the 25-bp terminal sequence found at or near T-DNA/plant junctions of both nopaline- and octopine-type A. tumefaciens Ti plasmids. A possible location for the right Ri TL-DNA/plant junction in C. arvensis clone 7 was found by obtaining the nucleotide sequence surrounding its mapped location. Hybridization of plant DNA found adjacent to the left TL-DNA/plant junction against total C. arvensis DNA shows that this T-DNA integration occurred in a plant DNA region that does not contain highly repetitive DNA sequences. Nucleotide sequence analysis of 1004 bp of this plant DNA revealed no complete or partial open reading frames, but this plant DNA does have the potential to form various secondary structures which might play a role in the T-DNA integration event.     

Site specific insertion of a type I rDNA element into a unique sequence in the Drosophila melanogaster genome.

We describe a cloned segment of unique DNA from the Oregon R strain of Drosophila melanogaster that contains a short type I insertion of the kind principally found within rDNA. The predominant type I rDNA insertion is 5kb in length, but there are also a co-terminal sub-set of shorter type I elements that share a common right hand junction with the rDNA. The insertion that we now describe is another member of this sub-set. The right hand junction of the type I sequence with the unique DNA is identical to the right hand junction of the type I sequences with rDNA. There is no significant feature within the insertion sequence that could have determined the position of the left junction with the sequence into which it is inserted. Like the corresponding short type I insertions in rDNA, the insertion into the unique DNA is flanked on both sides by a duplicated sequence, which in this case is 10 base pairs long. The cloning of a sequence corresponding to the uninterrupted unique location was facilitated by the observation that the Karsnas strain of D. melanogaster contains only uninterrupted sequences of this kind. The duplicated sequence at the target site for the insertion is only present as a single copy in the uninterrupted DNA. The sequence of the target site for the insertion (ACTGTTCT) in the unique segment shows a striking homology to the target in rDNA (ACTGTCCC).     

Episomal Viral DNA in a Herpesvirus saimiri-Transformed Lymphoid Cell Line

The lymphoid cell line #1670 has been derived from the infiltrated spleen of a tumor-bearing marmoset monkey infected with Herpesvirus saimiri. The cells contain both types of H. saimiri DNA, unique light (L-) DNA (36% cytosine plus guanine) and repetitive heavy (H-) DNA (71% cytosine plus guanine), without producing infectious virus. Viral DNA was found to persist in these cells as nonintegrated circular DNA molecules. Closed circular superhelical viral DNA molecules were isolated by three subsequent centrifugation steps: (i) isopycnic centrifugation in CsCl, (ii) sedimentation through glycerol gradients, and (iii) equilibrium centrifugation in CsCl-ethidium bromide. The isolated circles had a molecular weight of 131.5 +/- 3.6 x 10(6). This is significantly higher than the molecular weight of linear DNA molecules isolated from purified H. saimiri virions (about 100 x 10(6)). Partial denaturation mapping of circular molecules from #1670 lymphoid cells showed uniform arrangement of H- and L-DNA sequences in all circles. All denatured molecules contained two L-DNA regions (molecular weights of 54.0 +/- 1.8 x 10(6) and 31.5 +/- 1.3 x 10(6)) and two H-DNA regions (molecular weight of 25.6 +/- 1.9 x 10(6) and 20.0 +/- 0.8 x 10(6)) of constant length. Maps of both L-regions suggested that the sequences of the shorter L-DNA region were a subset of those of the longer region. The sequences of both L-regions had the same orientation. Circular molecules from H. saimiri-transformed lymphoid cell line #1670 appeared to represent defective genomes, containing only 75% of the genetic information present in L-DNA of H. saimiri virions.     

A new moderately repetitive DNA sequence family of novel organization.

In cloning adenovirus homologous sequences, from a human cosmid library, we identified a moderately repetitive DNA sequence family consisting of tandem arrays of 2.5 kb members. A member was sequenced and several non-adjacent, 15-20 bp G-C rich segments with homology to the left side of adenovirus were discovered. The copy number of 400 members is highly conserved among humans. Southern blots of partial digests of human DNA have verified the tandem array of the sequence family. The chromosomal location was defined by somatic cell genetics and in situ hybridization. Tandem arrays are found only on chromosomes 4 (4q31) and 19 (q13.1-q13.5). Homologous repetitive sequences are found in DNA of other primates but not in cat or mouse. Thus we have identified a new family of moderately repetitive DNA sequences, unique because of its organization in clustered tandem arrays, its length, its chromosomal location, and its lack of homology to other moderately repetitive sequence families.     

Primary structure of the herpesvirus saimiri genome.

This report describes the complete nucleotide sequence of the genome of herpesvirus saimiri, the prototype of gammaherpesvirus subgroup 2 (rhadinoviruses). The unique low-G + C-content DNA region has 112,930 bp with an average base composition of 34.5% G + C and is flanked by about 35 noncoding high-G + C-content DNA repeats of 1,444 bp (70.8% G + C) in tandem orientation. We identified 76 major open reading frames and a set of seven U-RNA genes for a total of 83 potential genes. The genes are closely arranged, with only a few regions of sizable noncoding sequences. For 60 of the predicted proteins, homologous sequences are found in other herpesviruses. Genes conserved between herpesvirus saimiri and Epstein-Barr virus (gammaherpesvirus subgroup 1) show that their genomes are generally collinear, although conserved gene blocks are separated by unique genes that appear to determine the particular phenotype of these viruses. Several deduced protein sequences of herpesvirus saimiri without counterparts in most of the other sequenced herpesviruses exhibited significant homology with cellular proteins of known function. These include thymidylate synthase, dihydrofolate reductase, complement control proteins, the cell surface antigen CD59, cyclins, and G protein-coupled receptors. Searching for functional protein motifs revealed that the virus may encode a cytosine-specific methylase and a tyrosine-specific protein kinase. Several herpesvirus saimiri genes are potential candidates to cooperate with the gene for saimiri transformation-associated protein of subgroup A (STP-A) in T-lymphocyte growth stimulation.     

Epstein-Barr virus DNA. X. Direct repeat within the internal direct repeat of Epstein-Barr virus DNA.

The 3,360-base-pair internal direct repeat (IR) in Epstein-Barr virus DNA separates the short and long unique DNA domains. IR has a single BamHI site. The juncture between the short unique domain and IR has been mapped by restriction endonucleases and is less than 2,600 nucleotides before the BamHI site in IR. The junction between IR and the long unique domain has been sequenced and is approximately 650 nucleotides after the BamHI site in IR. Thus, relative to the start of IR at the juncture with the short unique domain, the last repeat is at least 90 base pairs short of being complete. There is homology between the 250-nucleotide fragments to the left and the right of the unique BamHI site in IR. A 35-base-pair sequence of the left fragment is directly repeated within the right fragment, once fully and once partially. The implications of these findings are discussed.     

Herpesvirus ateles DNA and Its Homology with Herpesvirus saimiri Nucleic Acid

Analysis of the structural organization of Herpesvirus ateles DNA shows that two types of viral DNA molecules are encapsidated in virions: (i) M-genomes, which contain 74% light sequences (L-DNA, 38% guanine plus cytosine) and 26% highly repetitive heavy sequences (H-DNA, 75% guanine plus cytosine), and (ii) defective H-genomes, which consist exclusively of repetitive H-DNA. The structure of M-genomes from H. ateles consists of an L-DNA region of about 70 x 10(6) daltons inserted between H-DNA termini of variable length. M-genomes with a shorter H-DNA region at one end of the molecule have a long stretch of H-DNA at the other end, resulting in a total molecular weight of 89.8 +/- 8.5 x 10(6). Thus it resembles the structure of M-genomes of H. saimiri. H-DNA of the two independent H. ateles isolates, strains 810 and 73, reveals different patterns after cleavage with restriction endonuclease Sma I. H-DNA of H. ateles 810 appears to consist of identical tandem repeat units with a molecular weight of 1,035,000; the H-DNA repeat unit of strain 73 is shorter (930,000 molecular weight). Corresponding DNA sequences of the two H. ateles strains (810 and 73) are completely homologous in cross-hybridizations. However, a discrete nucleotide sequence divergence between these virus strains is detected by measuring melting temperatures (T(m)) of DNA hybrid molecules. Some homology exists between H. ateles and H. saimiri DNA. Hybridization of L-DNA from H. ateles with L-DNA from H. saimiri shows about a 35% homology between the respective L-DNA sequences; the resulting heteroduplex molecules show a decrease of T(m) by 13.5 degrees C, corresponding to about a 9% mismatching in cross-hybridizing parts of L-regions. Very little homology is found between H-DNA of H. ateles and H. saimiri.