The herpes simplex virus amplicon: a new eucaryotic defective-virus cloning-amplifying vector

We have employed repeat units of herpes simplex virus (HSV) defective genomes to derive a cloning-amplifying vector (amplicon) that can replicate in eucaryotic cells in the presence of standard HSV helper virus. The design of the HSV amplicon system is based on the previous observation that cotransfection of cells with helper virus DNA and seed monomeric repeat units of HSV defective genomes results in the regeneration of concatemeric defective genomes composed of multiple reiterations of the seed repeats. Cotransfection of cells with helper virus DNA and chimeric repeat units containing bacterial plasmid pKC7 DNA resulted in the generation of defective genomes composed of reiterations of the seed HSV-pKC7 repeats. These chimeric defective genomes were packaged into virus particles and could be propagated in virus stocks, with the most enriched passages containing more than 90% chimeric defective genomes. Furthermore, monomeric chimeric repeat units could be transferred back and forth between bacteria and eucaryotic cells. A derivative vector constructed so as to contain several unique restriction enzyme sites could be potentially employed in the introduction of additional viral or eucaryotic DNA sequences into eucaryotic cells.     

Herpes simplex virus amplicon: effect of size on replication of constructed defective genomes containing eucaryotic DNA sequences.

Previous studies (R. R. Spaete and N. Frenkel, Cell 30:295-304, 1982) have documented the potential use of defective virus vectors (amplicons) derived from herpes simplex virus for the efficient introduction of foreign DNA sequences into eucaryotic cells. Specifically, cotransfection of cells with helper virus DNA and cloned amplicons (8 to 10 kilobases [kb]) containing bacterial plasmid DNA sequences linked to a set of herpes simplex virus cis-acting propagation signals (a replication origin and a cleavage-packaging signal) resulted in the generation of virus stocks containing packaged defective genomes that consisted of uniform head-to-tail reiterations of the chimeric seed amplicon sequences. The chimeric defective genomes could be stably propagated in virus stocks and could thus be used to efficiently infect cells. We now report on additional studies designed to propagate relatively large sets of eucaryotic DNA sequences within chimeric packaged defective genomes. These studies have utilized a 12-kb chicken DNA sequence encoding the chicken ovalbumin gene and cloned by Lai et al. (Proc. Natl. Acad. Sci. U.S.A. 77:244-248, 1980) in the plasmid pOV12. Virus stocks derived from cells cotransfected with helper virus DNA and chimeric amplicons (overall size of 19.8 kb, of which 12 kb corresponded to the chicken DNA) contained defective genomes composed of reiterations of the 19.8-kb seed amplicon sequences. However, in addition to the authentically sized repeat units, defective genomes in the derivative virus stocks contained smaller repeat units representing deleted versions of the seed 19.8-kb amplicons. The recombinational events leading to the formation of deleted repeats did not appear to occur at unique sites, as shown by comparative analyses of multiple, independently generated virus series propagated from separate transfections. In contast, seed amplicons ranging in size from 11 to 15 kb and containing subsets of the 12-kb chicken DNA sequences replicated efficiently and could be stably propagated in virus stocks. The results of these studies suggest the existence of size restrictions (up to 15 kb) on the efficient replication of seed herpes simplex virus amplicons.     

Engineering large viral DNA genomes using the CRISPR‐Cas9 system

Manipulation of viral genomes is essential for studying viral gene function and utilizing viruses for therapy. Several techniques for viral genome engineering have been developed. Homologous recombination in virus‐infected cells has traditionally been used to edit viral genomes; however, the frequency of the expected recombination is quite low. Alternatively, large viral genomes have been edited using a bacterial artificial chromosome (BAC) plasmid system. However, cloning of large viral genomes into BAC plasmids is both laborious and time‐consuming. In addition, because it is possible for insertion into the viral genome of drug selection markers or parts of BAC plasmids to affect viral function, artificial genes sometimes need to be removed from edited viruses. Herpes simplex virus (HSV), a common DNA virus with a genome length of 152 kbp, causes labialis, genital herpes and encephalitis. Mutant HSV is a candidate for oncotherapy, in which HSV is used to kill tumor cells. In this study, the clustered regularly interspaced short palindromic repeat‐Cas9 system was used to very efficiently engineer HSV without inserting artificial genes into viral genomes. Not only gene‐ablated HSV but also gene knock‐in HSV were generated using this method. Furthermore, selection with phenotypes of edited genes promotes the isolation efficiencies of expectedly mutated viral clones. Because our method can be applied to other DNA viruses such as Epstein–Barr virus, cytomegaloviruses, vaccinia virus and baculovirus, our system will be useful for studying various types of viruses, including clinical isolates.     

A genetic test for expression of a functional herpes simplex virus DNA-binding protein from a transfected plasmid.

The major DNA-binding protein, ICP8, encoded by herpes simplex virus is localized to the infected cell nucleus where it plays a role in viral DNA replication and control of viral gene expression. To identify the parts of the ICP8 protein that are important for its localization and functions, we have developed a system to test the ability of recombinant plasmids to express functional ICP8. A recombinant plasmid containing the wild-type ICP8 gene was transfected into cells. The cells were later infected with a temperature-sensitive ICP8 mutant virus at the nonpermissive temperature. Sufficient wild-type ICP8 was expressed from the transfected plasmid to complement the replication of the mutant virus. This provides a genetic system to test the properties of ICP8 expressed from mutagenized plasmids without the establishment of a stable cell line or the reintroduction of the ICP8 gene into the herpes simplex virus genome.     

Plasmids containing mouse rDNA do not recombine with cellular ribosomal genes when introduced into cultured mouse cells.

We have examined the fate of plasmids containing a segment of a mouse rDNA repeat after they were introduced by transfection into cultured mouse cells. In addition to the rDNA segment, the plasmids contained the thymidine kinase gene from herpes simplex virus 1 to allow for selection of the plasmid after transfection into thymidine kinase-deficient mouse cells. Thus far, no cases of homologous recombination between transfected plasmid DNAs and host cell sequences have been documented. We reasoned that the high repetition frequency of the rRNA genes in the mouse genome (200 copies per diploid cell) might create a favorable situation for obtaining homologous recombination events between the plasmids containing rDNA and host cell rDNA sequences. The plasmids were introduced into cells in both the presence and the absence of carrier DNA and both as covalently closed circles and linear molecules. The sites of plasmid integration in the genomes of various cell lines were examined by DNA restriction digests and hybridization, molecular cloning, and nuclear fractionation. In the seven cell lines examined, there was no evidence that the plasmids had integrated into the rRNA gene clusters of the cell. Thus, the apparent absence of site-specific integration of cloned DNAs introduced into mammalian cells does not appear to be due simply to the small target presented by most host cell sequences.     

Herpes simplex virus induces the replication of foreign DNA.

Plasmids containing the simian virus 40 (SV40) DNA replication origin and the large T gene are replicated efficiently in Vero monkey cells but not in rabbit skin cells. Efficient replication of the plasmids was observed in rabbit skin cells infected with herpes simplex virus type 1 (HSV-1) and HSV-2. The HSV-induced replication required the large T antigen and the SV40 replication origin. However, it produced concatemeric molecules resembling replicative intermediates of HSV DNA and was sensitive to phosphonoacetate at concentrations known to inhibit the HSV DNA polymerase. Therefore, it involved the HSV DNA polymerase itself or a viral gene product(s) which was expressed following the replication of HSV DNA. Analyses of test plasmids lacking SV40 or HSV DNA sequences showed that, under some conditions, HSV also induced low-level replication of test plasmids containing no known eucaryotic replication origins. Together, these results show that HSV induces a DNA replicative activity which amplifies foreign DNA. The relevance of these findings to the putative transforming potential of HSV is discussed.     

Isolation of cis-acting vaccinia virus DNA fragments promoting the expression of herpes simplex virus thymidine kinase by recombinant viruses.

Recombinant TK- vaccinia viruses containing the pBR322 sequence inserted in either orientation within the coding sequence of the viral thymidine kinase gene were constructed. They were characterized by genomic analysis, hybridization studies, reversion to wild-type virus by in vivo recombination, and rescue from their genomes of plasmids which contained all or parts of the pBR322 sequence. TK- cells were infected with one of these recombinant viruses and then transfected with pools of chimeric plasmids composed of a cloned herpes simplex virus thymidine kinase gene which contained upstream inserts of different vaccinia DNA fragments prepared by restriction or sonication. Recombination between homologous pBR322 sequences within infected cells generated selectable recombinant viruses in which expression of the herpes simplex virus thymidine kinase gene was promoted by the upstream vaccinia insert. These viruses were characterized by genomic analysis, hybridization, and in vivo or in vitro phosphorylation of (5-[125I]deoxycytidine as a specific assay for the expressed herpes simplex virus thymidine kinase. Vaccinia DNA inserts were isolated conveniently for transfer to bacteria by rescuing appropriate plasmids from the genome of recombinant viruses. The sequence of 100 nucleotides adjacent to the upstream region of the herpes simplex virus gene was determined in nine different inserts measuring 0.17 to 1.07 kilobase pairs.     

Stimulation of expression of a herpes simplex virus DNA-binding protein by two viral functions.

We examined the expression and localization of herpesvirus proteins in monkey cells transfected with recombinant plasmids containing herpes simplex virus (HSV) DNA sequences. Low levels of expression of the major HSV DNA-binding protein ICP8 were observed when ICP8-encoding plasmids were introduced into cells alone. ICP8 expression was greatly increased when a recombinant plasmid encoding the HSV alpha (immediate-early) ICP4 and ICP0 genes was transfected with the ICP8 gene. Deletion and subcloning analysis indicated that two separate functions capable of stimulating ICP8 expression were encoded on the alpha gene plasmid. One mapped in or near the ICP4 gene, and one mapped in or near the ICP0 gene. Their stimulatory effects were synergistic when introduced on two separate plasmids. Thus, two separate viral functions can activate herpesvirus early gene expression in transfected cells.     

Both excision and replication of cloned autonomous parvovirus DNA require the NS1 (rep) protein.

When a bacterial plasmid containing the entire genome of LuIII virus except for the terminal 18 nucleotides from the right end is transfected into HeLa cells, the viral DNA is rescued and replicated, with production of infectious virus. This experimental system was used to examine the viral proteins and cis elements required for the excision and replication of viral DNA. The deletion of the entire NS1 gene provided a viral genome that was excised from the plasmid and replicated only when an NS1 gene was provided in trans. A frameshift mutation in the NS2 intron that truncates NS1 prevented excision and replication. Deletion of the left-end terminal inverted repeat or the right-end inverted repeat prevented excision of viral DNA from that end but not from the wild-type terminus. The viral terminus excised from the plasmid was protected from a processive degradation process, which began on the vector portion of the plasmid. The inhibitor of DNA polymerases alpha and delta, aphidicolin, blocked the excision reaction.     

Molecular cloning of herpes simplex virus type 2 DNA

Restriction enzyme HindIII digestion of the whole genome of herpes simplex virus type 2 strain 186 yielded 10 DNA fragments with molecular weights ranging from approximately 22 X 10(6) to 1.2 X 10(6), which were cloned into the HindIII site of bacterial plasmid pACYC 184. The cloned fragments were identified by hybridization to HSV-2 virus DNA and by double digestion with restriction endonucleases. The recombinant plasmids, even if they carried DNA sequences with molecular weights of more than 10(7), were efficiently replicated in E. coli HB101.     

Fragments from both termini of the herpes simplex virus type 1 genome contain signals required for the encapsidation of viral DNA.

A 535 base pair DNA fragment which maps entirely within the IRS/TRS regions of the herpes simplex virus type 1 (HSV-1) genome and contains all the cis-acting signals necessary for it to function as an origin of viral DNA replication has previously been identified (N.D. Stow and E.C. McMonagle, Virology, in press). When BHK cells were transfected with circular plasmid molecules containing cloned copies of this DNA fragment, and superinfected with wt HSV-1 as helper, amplification of the input plasmid was detected. Two observations indicated that the amplified DNA was not packaged into virus particles. Firstly, when the transfected cells were disrupted the amplified DNA was susceptible to digestion by added DNase, and secondly, it was not possible to further propagate the DNA when virus from the cells was passaged. Fragments from the joint region and from both termini of the viral genome were inserted into origin-containing plasmids and the resulting constructs analysed. In all cases the inserted fragment allowed the amplified DNA to be further passaged, and a proportion to become resistant to digestion with DNase. These observations suggest that signals required for the encapsidation of HSV-1 DNA are located within DNA sequences shared by the inserted fragments and therefore lie within the reiterated 'a' sequence of the viral genome.     

Expression of cloned herpesvirus genes. I. Detection of nuclear antigens from herpes simplex virus type 2 inverted repeat regions in transfected mouse cells.

Three different recombinant plasmids containing the entire 15-kilobase L and S inverted repeat sequence of herpes simplex virus type 2 DNA have been introduced into cultured Ltk- or BSC cells by both the calcium and DEAE-dextran transfection procedures. In each case, after 24 h approximately 1% of the cells gave strongly positive nuclear staining when assayed by immunofluorescence with hyperimmune antisera made against early and immediate-early infected-cell polypeptides. The nuclear fluorescence pattern and intensity mimicked that observed within 2 to 3 h after infection of Ltk- cells with either herpes simplex virus type 1 or type 2 wild-type virus. Herpes simplex virus type 1 (KOStsB2)-infected Ltk- cells under nonpermissive conditions did not express these antigens in the nucleus. Therefore, we conclude that either one or both of the 185,000- and 110,000-molecular-weight immediate early proteins, or some other as yet unknown gene product encoded entirely within the inverted repeats, can be transiently expressed in large amounts in transfected cells in the absence of other viral genes or accompanying virion components. Permanent mouse cell lines derived from transfection with these plasmids by using the thymidine kinase coselection procedure did not express sufficient nuclear antigen to be detectable by immunofluorescence.     

Functional domains within the a sequence involved in the cleavage-packaging of herpes simplex virus DNA.

Newly replicated herpes simplex virus (HSV) DNA consists of head-to-tail concatemers which are cleaved to generate unit-length genomes bounded by the terminally reiterated a sequence. Constructed defective HSV vectors (amplicons) containing a viral DNA replication origin and the a sequence are similarly replicated into large concatemers which are cleaved at a sequences punctuating the junctions between adjacent repeat units, concurrent with the packaging of viral DNA into nucleocapsids. In the present study we tested the ability of seed amplicons containing specific deletions in the a sequence to become cleaved and packaged and hence be propagated in virus stocks. These studies revealed that two separate signals, located within the Ub and Uc elements of the a sequence, were essential for amplicon propagation. No derivative defective genomes were recovered from seed constructs which lacked the Uc signal. In contrast, propagation of seed constructs lacking the Ub signal resulted in the selection of defective genomes with novel junctions, containing specific insertions of a sequences derived from the helper virus DNA. Comparison of published sequences of concatemeric junctions of several herpesviruses supported a uniform mechanism for the cleavage-packaging process, involving the measurement from two highly conserved blocks of sequences (pac-1 and pac-2) which were homologous to the required Uc and Ub sequences. These results form the basis for general models for the mechanism of cleavage-packaging of herpesvirus DNA.     

Structure and origin of defective genomes contained in serially passaged herpes simplex virus type 1 (Justin).

Restriction enzyme and hybridization analyses have revealed that high-density DNA prepared from passage 15 of serially passaged herpes simplex virus type 1 (Justin) contains three major classes of modified viral DNA molecules, each composed of distinct but closely related types of repeate units. The DNA sequences within the three types of repeat units are colinear with the DNA sequences located at the right end (between coordinates 0.94 and 1.0) of the parental herpes simplex virus type 1 genome. Thus, the three types of repeat units each contain the entire repeat sequence (ac) (which brackets the unique sequences of the small [S] component of herpes simplex virus type 1 DNA) and differ only with respect to the amount of unique S sequences which they contain. The three classes of high-density DNA molecules were found to be stably propagated between passages 6 and 15 of this series.     

Resolution of linear minichromosomes with hairpin ends from circular plasmids containing vaccinia virus concatemer junctions

The junctions, separating unit-length genomes in intracellular concatemeric forms of vaccinia virus DNA, are duplex copies of the hairpin loops that form the ends of mature DNA molecules present in infectious virus particles. Circular E. coli plasmids with palindromic junction fragments were replicated in vaccinia virus-infected cells and resolved into linear minichromosomes with vector DNA in the center and vaccinia virus DNA hairpins at the two ends. Resolution did not occur when the concatemer joint was less than 250 bp or when plasmids were transfected into uninfected cells, indicating requirements for a specific DNA structure and viral trans-acting factors. These studies indicate that concatemers can serve as replicative intermediates and account for the generation of flip-flop sequence variation of the hairpins at the ends of the mature vaccinia virus genome.     

In vivo resolution of circular plasmids containing concatemer junction fragments from minute virus of mice DNA and their subsequent replication as linear molecules.

During replication of their linear, single-stranded DNA genomes, parvoviruses generate a series of concatemeric duplex intermediates. We have cloned, into Escherichia coli plasmids, junction fragments from these palindromic concatemers of minute virus of mice DNA spanning both the right end-to-right end (viral 5' to 5') and left end-to-left end (viral 3' to 3') fusions. When mouse cells were transfected with these circular plasmids and superinfected with minute virus of mice, the viral junctions were resolved and the plasmids replicated as linear chromosomes with vector DNA in their centers and viral DNA at their termini. Resolution did not occur when the concatemer joint was replaced by a different palindromic sequence or when the transfected cells were not superinfected, indicating the presence of latent origins of replication which could only be activated by a viral trans-acting factor(s). Moreover, the products of resolution and replication from the two termini were characteristically different. Analysis of individual terminal fragments showed that viral 5' (right-end) sequences were resolved predominantly into "extended" structures with covalently associated copies of the virally encoded NS-1 polypeptide, while bridges derived from the 3' (left) end resolved into both NS-1-associated extended termini and lower-molecular-weight "turn-around" forms in which the two DNA strands were covalently continuous. This pattern of resolution exactly coincides with that seen at the two termini of replicative-form intermediates in normal virus infections. These results demonstrate that the bridge structures are authentic substrates for resolution and indicate that the frequency with which extended versus turn-around forms of each terminus are generated is an intrinsic property of the telomere.     

Rescue of the adeno-associated virus genome from a plasmid vector: evidence for rescue by replication

In cultured cells, adeno-associated virus (AAV) replication requires coinfection with a helper virus, either adenovirus or herpesvirus. In the absence of helper virus coinfection AAV can integrate its genome site specifically into the AAVS1 region of chromosome 19. Upon subsequent infection with a helper virus, the AAV genome is released from chromosome 19 by a process termed rescue, and productive replication ensues. The AAV genome cloned into a plasmid vector can also serve to initiate productive AAV replication. When such constructs are transfected into cells and those cells are simultaneously or subsequently infected with a helper virus, the AAV genome is released from the plasmid. This process is thought to serve as a model for rescue from the human genomic site. In this report we present a model for rescue of AAV genomes by replication. A hallmark of this model is the production of a partially single-stranded and partially double-stranded molecule. We show that the AAV2 Rep 68 protein, together with the UL30/UL42 herpes simplex virus type 1 DNA polymerase and the UL29 single-strand DNA binding protein ICP8, is sufficient to efficiently and precisely rescue AAV from a plasmid in a way that is dependent on the AAV inverted terminal repeat sequence.