Host cell-specific growth advantage of pseudorabies virus with a deletion in the genome sequences encoding a structural glycoprotein.

Several attenuated strains of pseudorabies virus contain genomes that carry a deletion in their short unique (Us) component. The sizes of the deletions are different in the various attenuated strains; the deletions may include part of one of the inverted repeats as well as part of the Us region of the genome. In most cases, the deletion includes the gene encoding the glycoprotein gI. The attenuated strains with a deletion in their S component have a common history of having been cultivated in chicken embryo fibroblasts (CEF). We show here that passage of wild-type virus in CEF promotes the emergence of populations of virions with a deletion in their S component. The emergence of these mutants is the result of their growth advantage over the wild type and is related to the lack of expression of gI, as shown by the following. (i) The Norden strain (which has a deletion in the Us) was marker rescued to restore an intact Us. The nonrescued Norden strain had a growth advantage over the rescued Norden strain in CEF. (ii) Passage of wild-type (gI+) virus in CEF but not in rabbit kidney or pig kidney cells resulted invariably in the emergence of virions whose genomes had a deletion in the S component. (iii) Passage of a gI- mutant in CEF did not result in the emergence of such virions. The emergence of virions with a deletion in their S component thus appears to be linked to gI expression. We conclude that gI is deleterious to the growth of pseudorabies virus in CEF and that this effect is cell type specific.     

Deletions in the genomes of pseudorabies virus vaccine strains and existence of four isomers of the genomes

As part of a study designed to identify the genes responsible for the virulence of pseudorabies virus, we have mapped the genomes of two independently derived vaccine strains (Bartha and Norden) by restriction enzyme analysis. The structures of these genomes have been compared with that of the genome of a laboratory strain previously mapped, of restriction fragments which had been cloned. The genome of the Bartha strain was found to be very similar to that of other pseudorabies virus strains, except that a deletion of approximately 2.7 X 10(6) daltons was found in the unique short (US) region. This deletion was also observed in the genome of the Norden vaccine strain but was not observed in the genomes of any other pseudorabies virus strains that have been studied (more than 20). The genome of the Norden strain differs from that of other pseudorabies virus strains in several other respects as well. The most important difference is that in contrast to all other pseudorabies virus strains analyzed to date, which contain a type 2 herpesvirus DNA molecule (in which the US region only inverts itself relative to the unique long [UL] region), the genome of the Norden strain is a type 3 molecule in which both the US and the UL regions of the genome invert themselves, giving rise to four isomeric forms of the genome. The ability of the UL region to invert itself is probably related to the fact that a sequence normally present in all other pseudorabies virus strains at the end of the UL only is found also in inverted form at the junction of the UL and the internal inverted repeat in the Norden strain.     

Proteins specified by the short unique region of the genome of pseudorabies virus play a role in the release of virions from certain cells.

Two pseudorabies virus vaccine strains (Bartha and Norden) that have a similar deletion in the short unique (Us) region of the genome have been identified previously (B. Lomniczi, M. L. Blankenship, and T. Ben-Porat, J. Virol. 49:970-979, 1984). These strains do not code for the glycoprotein gI, a glycoprotein that has been mapped on the wild type virus genome by T. C. Mettenleiter, N. Lukacs, and H. J. Rziha (J. Virol. 53:52-57, 1985) to the sequences deleted from the vaccine strain. Restoration of these deleted sequences to the Bartha strain genome restores to the virus the ability to specify the gI glycoprotein. The Bartha vaccine strain grows as well as wild-type virus in pig kidney and in rabbit kidney (RK) cells, but is not released efficiently from and forms small plaques in RK cells. The rescued Bartha 43/25a strain (which has an intact Us) is released considerably more efficiently than the Bartha vaccine strain, but less efficiently than wild-type virus from RK cells; it also forms larger plaques on RK cells than does the parental Bartha vaccine strain. The Norden vaccine strain, which has a deletion in the Us, is released better from RK cells than is the Bartha strain, but not as well as is wild-type virus. We conclude that whereas the sequences in the Us that are deleted from the Bartha and Norden strain genomes specify functions that play a role in the release of virions from some cell types, at least one other function (which is defective in the Bartha strain but not in the Norden strain) also affects release of virus from these cells. Since restoration to the Bartha strain of an intact Us restores to the virus both the ability to grow in chicken brains (B. Lomniczi, S. Watanabe, T. Ben-Porat, and A. S. Kaplan, J. Virol. 52:198-205, 1984) and to be released from RK cells, the possibility that the lack of virulence of the Bartha vaccine strain may be related to its limited release from some target cells is discussed.     

Nucleotide sequences at recombinational junctions present in pseudorabies virus variants with an invertible L component

The genome of pseudorabies virus (PrV) consists of two components--a noninvertible long (L) and an invertible short (S) component. The S component is bracketed by inverted repeats. In some variant strains of PrV (which have a selective growth advantage in certain cell lines), a sequence normally present at the left end of the L component has been translocated to the right end of the L component next to the inverted repeat. Consequently, these strains have acquired a genome with an L component that is bracketed by inverted repeats and that also inverts. We have determined the restriction maps and have analyzed the nucleotide sequences of those parts of the genome of three strains with invertible L components that contain the translocated segment of DNA. The results were as follows. The translocated fragments were derived in all cases from the extreme left end of the L component only. The sizes of the translocated fragments were similar, ranging from 1.3 to 1.4 kilobase pairs. The junction between the L and S components in these strains was the same as that in standard viral concatemeric DNA. The translocation of sequences from the left end of the genome next to the inverted repeats was always accompanied by a deletion of sequences from the right end of the L component. The sizes of the deleted fragments varied considerably, ranging from 0.8 to 2.3 kilobase pairs. Sequence homology at the points of recombination, i.e., at the junction between the right end and the left end of the L component, existed sometimes but not always. A model depicting how a virus with a class 2 genome (such as PrV) may acquire a genome with characteristics of a class 3 genome (such as herpes simplex virus) is presented.     

火鸡疱疹病毒在鸡胚成纤维细胞上有效代次的测定及其免疫原性恢复的研究

本试验证明,火鸡疱疹病毒(HVT)FC126株在鸡胚成纤维细胞(CEF)传55代的病毒,仍有预防马立克氏病(MD)的效力,至第70代效力明显下降。若将HVT CEF第35代病毒复归火鸡连续传4代,能明显恢复其免疫原性,用C细胞传代则有效代次可达到75代。因而,此方法能有效地解决免疫原性下降的种毒的更新问题。本试验还为该种毒和疫苗的有效代次的使用范围提供了可靠依据。     

The ability of pseudorabies virus to grow in different hosts is affected by the duplication and translocation of sequences from the left end of the genome to the UL-US junction.

Pseudorabies virus is a herpesvirus which has a class 2 genome. However, under certain growth conditions it acquires a genome with class 3-like characteristics. In these variants, the leftmost sequences of the long (L) component of the viral genome have been duplicated and translocated to the right of the L component next to the short (S) component, resulting in an L component that is bracketed by inverted repeats. Consequently, the L component can invert and is found in two orientations relative to the S component. The translocation is accompanied invariably by a deletion of sequences that are normally present in the wild-type genome at the right end of the L component. The virion variants with an invertible L component have a growth advantage over wild-type virus in chicken embryo fibroblasts and chickens; they also have a growth disadvantage in mice or rabbit kidney cells. The changed growth characteristics of the variants reside entirely in the changed structure of the junction between the S and L components. Replacement of that region of the DNA with wild-type sequences restores the wild-type phenotype. To determine whether the modified growth characteristics of the variants are related to the translocation or to the deletion, mutants that have a deletion or that have a deletion as well as a translocation similar to those observed in the variants were constructed, and the growth characteristics of these mutants were determined. We show that the modified growth characteristics of the mutants with an invertible L component can be attributed to the translocation of the leftmost terminal sequences of the genome next to the inverted repeat; they are not related to the deletion of the sequences normally present at the right end of the L component. The translocation of the leftmost 325 bp of the genome is sufficient to confer upon the virus the modified cell-type-specific growth characteristics. Furthermore, the modified growth characteristics are contingent upon the presence of 68 bp spanning the internal junction between the L and S components.     

分子克隆化禽网状内皮组织增生症病毒传染性及其前病毒全基因组序列研究

利用脂质体转染技术,将含有SNV株禽网状内皮组织增生症病毒 （REV）前病毒全基因组cDNA克隆质粒转染鸡胚成纤维细胞（CEF）.用对REV的单克隆抗体和抗REV env-gp90的鼠血清作间接免疫荧光反应,在原始的转染细胞及随后传代的细胞中均显示病毒特异性抗原.而且,在连续传代细胞中的阳性率明显升高.用REV特异性引物对进一步传代后的细胞基因组作PCR,也检测出REV基因组.这些结果均表明所得到的分子克隆化病毒具有传染性,因而也进一步证明所用的质粒克隆包含有具感染性的全病毒基因组.对该全基因组cDNA克隆进行酶切所获得的数个亚克隆进行测序,并将序列进行拼接,完成了REV全基因组序列.REV的这个传染性克隆将有助于进一步研究REV的分子生物学特性.     

Herpes simplex virus 1 recombinants with noninverting genomes frozen in different isomeric arrangements are capable of independent replication.

Herpes simplex virus 1 genome consists of two covalently linked components, L and S, that invert relative to each other to yield four equimolar isomeric populations designated P (prototype), Is (inversion of S component), Il (inversion of L component), and Ils (inversion of L and S components) differing in the orientation of the two components. Previous studies have yielded recombinant genomes frozen in the P isomeric arrangement, reinforcing suggestions that the four isomers may not be functionally equivalent. We report the isolation of recombinants produced by insertional mutagenesis with alpha TK mini-Mu that are frozen in Is and Ils arrangements. Thus, all isomeric forms of herpes simplex virus DNA appear to be capable of independent replication and must be considered as functionally equivalent.     

Molecular basis for interference of defective interfering particles of pseudorabies virus with replication of standard virus.

Serial passage of pseudorabies virus (PrV) at high multiplicity yields defective interfering particles (DIPs), but the sharp cyclical increases and decreases in titer of infectious virus that are observed upon continued passage at high multiplicity of most DIPs of other viruses are not observed with DIPs of PrV (T. Ben-Porat and A. S. Kaplan, Virology 72:471-479). We have studied the dynamics of the interactions of the virions present in a population of DIPs to assess the cis functions for which the genomes of the DIPs are enriched. The defective genomes present in one population of DIPs, [PrV(1)42], replicate preferentially over the nondefective genomes present in that virion population at early stages of infection, indicating that the DIP DNA is enriched for sequences that can serve as origins of replication at early stages of infection. This replicative advantage of the DIP DNA is transient and disappears at later stages of infection. The defective DNA does not appear to be encapsidated preferentially over the nondefective DNA present in this virion population, which might indicate that it is not enriched for cleavage-encapsidation sites. However, the nondefective DNA in the DIP virion population has become modified and has acquired reiterations of sequences originating from the end of the unique long (UL) region of the genome. Furthermore, both the infectious and defective genomes present in the DIP population compete for encapsidation more effectively than do the genomes of standard PrV. These results indicate that the defective genomes in the population of virions studied are enriched not only for an origin of replication but probably also for sequences necessary for efficient cleavage-encapsidation. Furthermore, the nondefective genomes present in this population of DIPs have also been modified and have acquired the ability to compete with the defective genomes for cleavage-encapsidation.     

Structural organization of the termini of the L and S components of the genome of pseudorabies virus.

The sequences of several hundred nucleotides around the junctions between the L and S components in concatemeric DNA and in mature virion DNA were ascertained. The two ends of the mature genome (which are joined in concatemeric DNA) show no sequence homology. Several directly repeated elements are present near both ends of the genome. Furthermore, the last 82 nucleotides at the left end of the L component (and of the genome) are repeated in inverted form (inverted repeat within the L component [IRL]) approximately 350 to 600 nucleotides downstream (depending on the virus isolate) bracketing the UL2 component. A comparison between the sequences at the right and left ends of the L component of the genome showed patchy homology, probably representing a vestigial inverted repeat bracketing the L component (IRL). Furthermore, less than 5% of the genomes have an L component that is in the orientation opposite to that of most of the viral genomes, indicating that the vestigial IRL that brackets the UL sequence may be sufficient to mediate inversion of the L component in some of the genomes. On the other hand, the UL2 component, which is bracketed by a perfect IRL, does not invert to a greater extent than does the L component (if it inverts at all). Analysis of the nucleotide sequence at the concatemeric junction of three different pseudorabies virus isolates showed almost complete sequence conservation. The sequence and organization of the repeated elements in the different isolates were almost identical, despite their different histories and origins. The high degree of conservation of these repeated elements implies that they may fulfill an essential function in the life cycle of the virus.     

Appearance of Defective Virions in Clones of Reovirus

Virus obtained from five plaques of reovirus was serially passaged in L cells. Defective virions arose in each clone by the seventh passage. Such defective virions lacked the largest of the 10 segments of the double-stranded ribonucleic acid genome.     

Deletions in vaccine strains of pseudorabies virus and their effect on synthesis of glycoprotein gp63.

The pseudorabies virus vaccine strains Norden and Bartha each have been reported to have deletions in the small unique component of the genome (B. Lomniczi, M. L. Blankenship, and T. Ben-Porat, J. Virol. 49:970-979, 1984). The deletion in Norden was shown to delete the entire coding region for gI but not any of the coding sequences for gp63. However, gp63 in Norden-infected cells was only 36 kilodaltons, and a 44-kilodalton form of gp63 was released into the medium. In Bartha, the deletion removed the coding region for all but 89 amino acids of gp63, and no gp63 was detected in either Bartha-infected cells or medium.     

Heterogeneous RNA of the Prague strain of Rous sarcoma virus caused by undiluted passages.

The size of genomic RNA in PR-RSV A passaged in chick embryo fibroblasts (CEF) or quail embryo fibroblasts (QEF) was determined by gel electrophoresis. The results showed that 3 undiluted passages resulted in heterogeneity of RNA. The heterogeneity of the smaller incomplete RNAs in the virus stock was decreased by diluted passage or cloning, but RNA of the b subunit size and a subunit RNA of complete genome size were relatively stable. These heterogeneous RNAs were characterized by hybridization analysis. The RNAs from 4 peaks hybridized with both cDNAtotal and cDNAsrc to appreciable extents, indicating that they were derived from viral RNA and that at least some of them contained the src sequence. This finding and the failure to isolate a td mutant from the undiluted-passaged virus stock or from some subclones that had a and b subunits of RNA indicate that the td virus was only a minor constituent of the incomplete virus population caused by undiluted passages. Some viruses with incomplete RNA in the virus stock could produce foci with the aid of td B77 or RAV-60. The emergence of rd viruses by undiluted passages was indicated.     

Infectious virus replication in papillomas induced by molecularly cloned cottontail rabbit papillomavirus DNA.

The ability to obtain infectious papillomavirus virions from molecularly cloned DNA has not been previously reported. We demonstrate here that viral genomes isolated from a recombinant++ DNA clone of cottontail rabbit papillomavirus (CRPV) gave rise to infectious virus when inoculated into cottontail rabbit skin. Replication occurred in papillomas that formed at inoculation sites. Extract of a DNA-induced papilloma was serially passaged to naive rabbits with high efficiency. Complete virus was fractionated on cesium chloride density gradients, and papillomavirus particles were visualized by electron microscopy. CRPV DNA isolated from virions contained DNA sequence polymorphisms that are characteristic of the input CRPV-WA strain of virus, thereby proving that the newly generated virus originated from the molecularly cloned viral genome. These findings indicate that this will be a useful system in which to perform genetic analysis of viral gene functions involved in replication.     

Low-level inversion of the L component of pseudorabies virus is not dependent on sequence homology.

Pseudorabies virus has a class 2 genome in which the S component is found in two orientations relative to the L component. The L component is bracketed by sequences that are partially homologous; it is found mainly in one orientation, but a small proportion is inverted (J. M. DeMarchi, Z. Lu, G. Rall, S. Kuperschmidt, and T. Ben-Porat, J. Virol. 64:4968-4977, 1990). We have ascertained the role of the patchy homologous sequences bracketing the L component in its inversion. A viral mutant, vYa, from which the sequences at the right end of the L component were deleted was constructed. Despite the absence of homologous sequences bracketing the L component in vYa, its L component inverted to an extent similar to that of the L component in the wild-type virus. These results show the following. (i) The low-frequency inversion of the L component of PrV is not mediated by homologous sequences bracketing this component. (ii) Cleavage of concatemeric DNA at the internal junction between the S and L components is responsible for the appearance of the minority of genomes with an inverted L component in populations of pseudorabies virus. (iii) The signals present near or at the end of the S component are sufficient to allow low-frequency cleavage of concatemeric DNA; the sequences at the end of the L component are not essential for cleavage, although they enhance it considerably.     

Structure of varicella-zoster virus DNA

Varicella-zoster virus (VZV) DNA was prepared from nucleocapsids and from enveloped virions of a laboratory strain (Ellen) and directly from the vesicle fluids of patients with zoster infections. VZV Ellen nucleocapsid DNA was cleaved with 11 different restriction endonucleases and electrophoresed in agarose gels. The restriction profiles of the nucleocapsid DNA were identical to those of the DNA recovered from purified virions, but differed from those of another VZV strain (KM). In vitro-labeled VZV K.M. DNA purified directly from vesicle fluid yielded a distinct restriction pattern which appeared to be unchanged after several tissue culture passages of the isolate from that fluid. Restriction endonuclease analysis (EcoRI or BglII) of VZV DNA revealed the presence of four cleavage fragments with a molar ratio of approximately 0.5. No individual fragments with molar ratios of 0.25 were noted. This observation suggests that the VZV genome may contain one invertible segment. Comparison of the electrophoretic migrations of VZV DNA fragments relative to those of DNAs of known size permitted calculation of the VZV genome size to be 72 X 10(6) to 80 X 10(6) daltons. These results were confirmed by electron microscopy which demonstrated a genome size of about 76 X 10(6) daltons for passaged and unpassaged VZV DNA. Electron microscopy also revealed that some of the DNA molecules recovered from nucleocapsids or directly from vesicle fluids were superhelical circles.     

A trial of somatic gene targeting in vivo with an adenovirus vector

We have constructed and evaluated the utility of a helper-dependent virus vector system that is derived from Human Cytomegalovirus (HCMV). This vector is based on the herpes simplex virus (HSV) amplicon system and contains the HCMV orthologs of the two cis-acting functions required for replication and packaging of HSV genomes, the complex HCMV viral DNA replication origin (oriLyt), and the cleavage packaging signal (the a sequence). The HCMV amplicon vector replicated independently and was packaged into infectious virions in the presence of helper virus. This vector is capable of delivering and expressing foreign genes in infected cells including progenitor cells such as human CD34+ cells. Packaged defective viral genomes were passaged serially in fibroblasts and could be detected at passage 3; however, the copy number appeared to diminish upon serial passage. The HCMV amplicon offers an alternative vector strategy useful for gene(s) delivery to cells of the hematopoietic lineage.     

Sequence of the genome ends and of the junction between the ends in concatemeric DNA of pseudorabies virus.

The nucleotide sequences of the termini of the mature pseudorabies virus genome and of the junction between these termini in concatemeric DNA were compared. To ensure conservation of unmodified 5' and 3' termini, the end fragments obtained directly (uncloned) from mature viral DNA were sequenced. The sequence obtained from 5' and 3' end labeling revealed that whereas the L terminus was blunt ended, the S terminus had a 2-base (GG) 3' overhang. The sequences spanning the junction between the termini present in concatemeric DNA was also determined and compared with that expected when the two ends of the mature DNA were juxtaposed. This comparison showed that in concatemeric DNA the ends of the mature genome had become joined by blunt-end ligation of one of the strands and that the 2-nucleotide gap on the other strand had been repaired. A significant degree of homology between the sequences spanning the junction between the ends of the varicella-zoster virus and pseudorabies virus genomes was found.     

Acquisition of an additional internal cleavage site differentially affects the ability of pseudorabies virus to multiply in different host cells.

The translocation of the 325 leftmost bp of the genome of pseudorabies virus (PrV) to the internal junction between the L and S components confers upon the virus a growth advantage relative to wild-type PrV in chicken embryo fibroblasts (CEFs) and chickens and a growth disadvantage in rabbit kidney (RK) cells and mice. To clarify the molecular basis for the species-specific growth characteristics of the translocation mutants, we have compared several parameters of the virus growth cycle in CEFs and RK cells infected with wild-type PrV and with translocation mutants. The salient findings are as follows. (i) The synthesis of early-late and late proteins is not as effective in CEFs as it is in RK cells, and these proteins, in particular, the major capsid proteins, accumulate less abundantly in CEFs than in RK cells. (ii) Cleavage of concatemeric DNA to genome-size molecules is also not as effective in CEFs as it is in RK cells. (iii) The internal junction present in translocation mutants is a functional cleavage site. (iv) In RK cells, translocation mutants are hypercleaved and a significant proportion of the total viral DNA is cleaved into subgenomic fragments. (v) In CEFs infected with translocation mutants, subgenomic fragments also accumulate but most of the viral DNA remains in concatemeric form. A model which postulates that the cell-specific growth advantage or disadvantage of the translocation mutants is related to the presence of a second cleavage site within their genomes and is affected by the efficiency of cleavage of concatemeric DNA in particular infected cell types is presented. The significance of these findings as they relate to the evolution of herpesviruses with class 2- and class 3-like genomes is discussed.