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.     

Genetic basis of the neurovirulence of pseudorabies virus.

Lomniczi et al. (J. Virol. 49:970-979, 1984) have shown previously that two attenuated vaccine strains of pseudorabies virus have a similar deletion in the short unique (US) region of the genome. The region which is deleted normally codes for several translationally competent mRNAs. As expected, these mRNAs are not formed in the cells infected with the vaccine strains. The function specified by these mRNAs is thus not necessary for growth in cell culture. Using intracerebral inoculation of 1-day-old chicks as a test system, we have attempted to determine whether a gene within the region that is missing from the attenuated strains specifies functions that are required for the expression of virulence. An analysis of recombinants between the Bartha vaccine strain and a virulent pseudorabies virus strain (having or lacking a thymidine kinase gene [TK+ or TK-]) revealed the following. None of the recombinant plaque isolates that were either TK- or which had a deletion in the US was virulent. Not all recombinant plaque isolates which were both TK+ and had an intact US were virulent. These results indicate that both thymidine kinase activity and an intact US were necessary but not sufficient for the expression of virulence. Marker rescue experiments involving cotransfection of the Bartha strain DNA and a restriction fragment spanning the region of the genome that was missing from the Bartha strain resulted in the isolation of virions to which an intact US had been restored. These virions were not virulent but had an improved ability to replicate in the brains of chicks compared with that of the parental nonrescued Bartha strain. Our results show that genes in the US region, which are missing from the Bartha strain, were necessary for virulence but that this strain was also defective in other genes required for the expression of virulence. Thus, the virulence of pseudorabies virus, as measured by intracerebral inoculation into chicks, appears to be controlled multigenically.     

Genome location and identification of functions defective in the Bartha vaccine strain of pseudorabies virus.

We have shown previously (Lomniczi et al., J. Virol. 52:198-205, 1984) that the Bartha vaccine strain of pseudorabies virus has a deletion in the short unique (Us) region of its genome--a deletion that is related to the absence of virus virulence. This strain is, however, also defective in other genes involved in virulence. We show here that virulence can be restored by marker rescue of the Bartha strain to which an intact Us has been restored (but not to the parental Bartha strain) by sequences derived from approximate map units 0.460 and 0.505 of the wild-type virus genome. No difference in the ability to grow in cell culture was observed between parental Bartha, Bartha 43/25a (Bartha to which an intact Us has been restored), or the doubly rescued Bartha strains. However, only the doubly rescued Bartha strain was virulent for both chickens and pigs and replicated to high titers when inoculated directly into the brains of chickens. The sequences that could restore virulence to the Bartha 43/25a strain encode four genes, all of which are involved in processes leading to the assembly of nucleocapsids. Since these sequences rescue virulence, it appears that a function that plays a role in nucleocapsid assembly is defective in the Bartha strain and that this defect contributes to the lack of virulence of this virus.     

Role of glycoprotein gIII of pseudorabies virus in virulence.

Deletion mutants of pseudorabies virus unable to express glycoprotein gIII, gI, or gp63 or double and triple mutants defective in these glycoproteins were constructed, and their virulence for day-old chickens inoculated intracerebrally was determined. Mutants of wild-type pseudorabies virus defective in glycoprotein gIII, gI, or gp63 were only slightly less virulent (at most, fivefold) for chickens than was the wild-type virus. However, mutants defective in both gIII and gI or gIII and gp63 were avirulent for chickens, despite their ability to grow in cell culture in vitro to about the same extent as mutants defective in gIII alone (which were virulent). These results show that gIII plays a role in virulence and does so in conjunction with gI or gp63. The effect of gIII on virulence was also shown when the resident gIII gene of variants of the Bartha vaccine strain (which codes for gIIIB) was replaced with a gIII gene derived from a virulent wild-type strain (which codes for gIIIKa); gIIIKa significantly enhanced the virulence of a variant of the Bartha strain to which partial virulence had been previously restored by marker rescue. Our results show that viral functions that play a role in the virulence of the virus (as measured by intracerebral inoculation of chickens) may act synergistically to affect the expression of virulence and that the ability of the virus to grow in cell culture is not necessarily correlated with virulence.     

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.     

Identification of Marek''s disease virus nuclear antigen in latently infected lymphoblastoid cells.

A new Marek's disease virus (MDV) nuclear antigen (MDNA) was identified in two MDV-transformed T-lymphoblastoid cell lines, MKT-1 and MSB-1, derived from chickens bearing tumors induced by MDV. This MDNA was not detected in MSB-1 cells maintained in iododeoxyuridine, which activates the latent MDV genome. Moreover, it was not found in chicken embryo fibroblasts undergoing productive and cytolytic infection with MDV. Expression of MDNA is not related to strain pathogenicity in chickens, because chicken embryo fibroblasts productively infected with the pathogenic RBIB strain or the nonpathogenic CV-1 strain of MDV did not express this antigen. DNA-protein immunoprecipitation studies revealed that MDNA bound to two sites in the 190,00-base-pair (bp) MDV genome. One of these loci identified by MDNA obtained from MKT-1 and MSB-1 cells corresponded to a 476-bp segment within the short unique region of BamHI-A MDV DNA. A second locus located in a 280-bp segment within the short inverted repeat region of BamHI-A was also identified by MDNA from MSB-1 cells but not by MDNA obtained from MKT-1 cells. Analyses of the nucleotide sequence by DNase digestion showed that MDNA protected a 60-bp segment spanning a 22-bp palindromic sequence of the short unique region and a 103-bp sequence encompassing a 32-bp palindrome in the short inverted repeat region of BamHI-A MDV DNA.     

A deletion at the UL/IR junction reduces pseudorabies virus neurovirulence.

A recombinant pseudorabies virus (PRV), designated LLT beta delta 2, which contains a 3-kbp deletion spanning the junction of the unique long and internal repeat sequences was constructed. Compared with the parental strain and a virus rescued for the deleted sequences, LLT beta delta 2 exhibited similar replication characteristics in tissue culture. When inoculated intranasally in swine, LLT beta delta 2 was significantly reduced in virulence and did not produce neurological signs characteristic of PRV infection. LLT beta delta 2 replicated efficiently at the site of inoculation and in peripheral nervous tissues, but replication was restricted in the central nervous system. These results indicate the presence of a PRV neurovirulence determinant in the vicinity of the junction.     

Nuclear factors that bind to the enhancer region of nondefective Friend murine leukemia virus.

Nondefective Friend murine leukemia virus (MuLV) causes erythroleukemia when injected into newborn NFS mice, while Moloney MuLV causes T-cell lymphoma. Exchange of the Friend virus enhancer region, a sequence of about 180 nucleotides including the direct repeat and a short 3'-adjacent segment, for the corresponding region in Moloney MuLV confers the ability to cause erythroid disease on Moloney MuLV. We have used the electrophoretic mobility shift assay and methylation interference analysis to identify cellular factors which bind to the Friend virus enhancer region and compared these with factors, previously identified, that bind to the Moloney virus direct repeat (N. A. Speck and D. Baltimore, Mol. Cell. Biol. 7:1101-1110, 1987). We identified five binding sites for sequence-specific DNA-binding proteins in the Friend virus enhancer region. While some binding sites are present in both the Moloney and Friend virus enhancers, both viruses contain unique sites not present in the other. Although none of the factors identified in this report which bind to these unique sites are present exclusively in T cells or erythroid cells, they bind to three regions of the enhancer shown by genetic analysis to encode disease specificity and thus are candidates to mediate the tissue-specific expression and distinct disease specificities encoded by these virus enhancer elements.     

Structure of Marek's disease virus DNA: detailed restriction enzyme map.

Purified virion DNA (120 X 10(6) molecular weight [MW]) of Marek's disease virus strain GA was cleaved with BamHI restriction endonuclease, and 27 out of the 29 fragments were cloned into bacterial plasmids. Restriction maps for BamHI, BglI, and SmaI endonucleases were constructed. The genomic structure of Marek's disease virus DNA was found to be similar to that of herpes simplex virus types 1 and 2. A long unique region (75 X 10(6) MW, located at 10 X 10(6) to 85 X 10(6) MW [10-85] from the left end of the genome), which was subdivided into segment 1 (22 X 10(6) MW, located at 10-32) and segment 2 (51 X 10(6) MW, located at 34-85) by direct repeats (32-34), was flanked by a long terminal region (10 X 10(6) MW, located at 0-10) and a long inverted region (10 X 10(6) MW, located at 85-95). A short unique region (8 X 10(6) MW, located at 103-111) was flanked by a short terminal region (8 X 10(6) MW, located at 111-119) and a short inverted region (8 X 10(6) MW, located at 95-103). The direct repeat fragments (0.9 X 10(6) could be isolated by cleavage with SmaI. The right terminal end was found to be heterogenous .     

The genome of a very virulent Marek's disease virus

Here we present the first complete genomic sequence, with analysis, of a very virulent strain of Marek's disease virus serotype 1 (MDV1), Md5. The genome is 177,874 bp and is predicted to encode 103 proteins. MDV1 is colinear with the prototypic alphaherpesvirus herpes simplex virus type 1 (HSV-1) within the unique long (UL) region, and it is most similar at the amino acid level to MDV2, herpesvirus of turkeys (HVT), and nonavian herpesviruses equine herpesviruses 1 and 4. MDV1 encodes 55 HSV-1 UL homologues together with 6 additional UL proteins that are absent in nonavian herpesviruses. The unique short (US) region is colinear with and has greater than 99% nucleotide identity to that of MDV1 strain GA; however, an extra nucleotide sequence at the Md5 US/short terminal repeat boundary results in a shorter US region and the presence of a second gene (encoding MDV097) similar to the SORF2 gene. MD5, like HVT, encodes an ICP4 homologue that contains a 900-amino-acid amino-terminal extension not found in other herpesviruses. Putative virulence and host range gene products include the oncoprotein MEQ, oncogenicity-associated phosphoproteins pp38 and pp24, a lipase homologue, a CxC chemokine, and unique proteins of unknown function MDV087 and MDV097 (SORF2 homologues) and MDV093 (SORF4). Consistent with its virulent phenotype, Md5 contains only two copies of the 132-bp repeat which has previously been associated with viral attenuation and loss of oncogenicity.     

The region of the herpes simplex virus type 1 LAT gene that is colinear with the ICP34.5 gene is not involved in spontaneous reactivation.

The goal of this report was to determine if the region of the LAT gene that is colinear with ICP34.5 (kb 6.2 to 7.1 of LAT) is involved in spontaneous reactivation of herpes simplex virus type 1. We inserted one copy of the ICP34.5 gene into the unique long region of a herpes simplex virus type 1 (strain McKrae) mutant lacking both copies of ICP34.5 (one in each viral long repeat) and the corresponding 917-nucleotide colinear portion of LAT (kb 6.2 to 7.1). Rabbits were ocularly infected with this mutant, and spontaneous reactivation relative to that for the wild-type virus and the original mutant was measured. As we previously reported, the original ICP34.5-deleted virus (d34.5) was significantly impaired for spontaneous reactivation and virulence (G. C. Perng, R. L. Thompson, N. M. Sawtell, W. E. Taylor, S. M. Slanina, H. Ghiasi, R. Kaiwar, A. B. Nesburn, and S. L. Wechsler, J. Virol. 69:3033-3041, 1995). In contrast, we report here that restoration of one copy of ICP34.5 at a distant location completely restored the wild-type level of in vivo spontaneous reactivation, despite retention of the deletion in LAT (spontaneous reactivation rate = 0.3 to 1.4% for the ICP34.5 deletion mutant, 7.7 to 19.6% for the wild type, and 9 to 16.1% for virus with one copy of ICP34.5). Thus, the 917-nucleotide region of LAT from kb 6.2 to 7.1 was not involved in the LAT function required for wild-type spontaneous reactivation. We also found that restoration of a single ICP34.5 gene in a novel location did not restore wild-type virulence (rabbit death rate = 0% [0 of 15] for the original ICP34.5 deletion mutant, 8% [2 of 24] for the single-copy IPC34.5 virus, and 52% [14 of 27] for wild-type virus; P < 0.001 for one versus two copies of ICP34.5). It is likely that either two gene doses of ICP34.5 or its location in the long repeat is essential for full functionality of ICP34.5's virulence function. Furthermore, the ability of the single-copy ICP34.5 virus to reactivate at wild-type levels despite being significantly less virulent than wild-type virus separates the spontaneous reactivation phenotype from the virulence phenotype.     

Role of a structural glycoprotein of pseudorabies in virus virulence.

The virulence of deletion mutants of pseudorabies virus defective in the expression of glycoprotein gI, gp63, or both was tested in 1-day-old chickens and young pigs. In the absence of expression of gI, the virulence of a fully virulent laboratory strain, PrV(Ka), for 1-day-old chickens was reduced approximately fourfold. Inactivation of glycoprotein gp63 appeared also to affect the virulence of PrV(Ka) only slightly, as did inactivation of both gI and gp63. The level of reduction in virulence, however, was considerably more marked in Bartha 43/25aB4, a less virulent virus strain. Inactivation of the expression of gI in Bartha 43/25aB4 reduced virulence for chickens at least 100-fold. The results obtained when the virulence of the mutants for pigs was determined were compatible with those obtained for chickens. These results indicate that gI plays a role in virulence, but that it does so in conjunction with at least one other viral function (a function that is defective in Bartha 43/25aB4).     

Insertions in the gG gene of pseudorabies virus reduce expression of the upstream Us3 protein and inhibit cell-to-cell spread of virus infection

The alphaherpesvirus Us4 gene encodes glycoprotein G (gG), which is conserved in most viruses of the alphaherpesvirus subfamily. In the swine pathogen pseudorabies virus (PRV), mutant viruses with internal deletions and insertions in the gG gene have shown no discernible phenotypes. We report that insertions in the gG locus of the attenuated PRV strain Bartha show reduced virulence in vivo and are defective in their ability to spread from cell to cell in a cell-type-specific manner. Similar insertions in the gG locus of the wild-type PRV strain Becker had no effect on the ability of virus infection to spread between cells. Insertions in the gG locus of the virulent NIA-3 strain gave results similar to those found with the Bartha strain. To examine the role of gG in cell-to-cell spread, a nonsense mutation in the gG signal sequence was constructed and crossed into the Bartha strain. This mutant, PRV157, failed to express gG yet had cell-to-cell spread properties indistinguishable from those of the parental Bartha strain. These data indicated that, while insertions in the gG locus result in decreased cell-to-cell spread, the phenotype was not due to loss of gG expression as first predicted. Analysis of gene expression upstream and downstream of gG revealed that expression of the upstream Us3 protein is reduced by insertion of lacZ or egfp at the gG locus. By contrast, expression of the gene immediately downstream of gG, Us6, which encodes glycoprotein gD, was not affected by insertions in gG. These data indicate that DNA insertions in gG have polar effects and suggest that the serine/threonine kinase encoded by the Us3 gene, and not gG, functions in the spread of viral infection between cells.     

Complete Genome Sequence of a Recombinant Marek's Disease Virus Field Strain with One Reticuloendotheliosis Virus Long Terminal Repeat Insert

Marek''s disease virus (MDV) Chinese strain GX0101, isolated in 2001 from a vaccinated flock of layer chickens with severe tumors, was the first reported recombinant MDV field strain with one reticuloendotheliosis virus (REV) long terminal repeat (LTR) insert. GX0101 belongs to very virulent MDV (vvMDV) but has higher horizontal transmission ability than the vvMDV strain Md5. The complete genome sequence of GX0101 is 178,101 nucleotides (nt) and contains only one REV-LTR insert at a site 267 nt upstream of the sorf2 gene. Moreover, GX0101 has 5 repeats of a 217-nt fragment in its terminal repeat short (TRS) region and 3 repeats in internal repeat short (IRS) region, compared to the other 10 strains with only 1 or 2 repeats in both TRS and IRS.     

猪伪狂犬病毒鲁A株TK基因的序列测定及其结构功能与进化分析

对猪伪狂犬病毒鲁A株(PRV LA株)TK基因进行了克隆和序列测定,并分析比较了该序列与PRV NIA-3株、Ea株、SH以及HSV-1和VZV的同源性,结果表明:在全长1048bp的DNA序列中,包括着一个963bp的开放阅读框(ORF),可编码320个氯基酸组成的多肽;在整个TK基因的ORF内,PRV LA株与PRV NIA-3株、PRV Ea株、PRV SH株、HSV-1、VZV的TK基因比较,核苷酸的同源性分别为98.9%、99.5%、99.3%、36.4%、39.1%,氨基酸的同源性分别为98.4%、99.7%、98.7%、36.6%、37.2%.PRV LA株TK具有疱疹病毒胸苷激酶催化结构域的保守氨基酸共有序列和亚结构域特征序列.将PRV-LA TK、人类和小鼠的胸苷酸激酶、人类脱氧胞苷激酶、人类腺苷酸激酶的对应于这两个亚结构域的氨基酸用DNA Star分析的进化树表明,疱疹病毒的TK与人类和小鼠的胸苷酸激酶的亲缘关系比与人类脱氧胞嘧啶激酶的亲缘关系更近,因此疱疹病毒的TK基因在进化上可能起源于宿主细胞的胸苷酸激酶基因.     

A novel bacterial virulence gene in Listeria monocytogenes required for host cell microfilament interaction with homology to the proline-rich region of vinculin.

The ability of Listeria monocytogenes to move within the cytosol of infected cells and their ability to infect adjacent cells is important in the development of infection foci leading to systemic disease. Interaction with the host cell microfilament system, particularly actin, appears to be the basis for propelling the bacteria through the host cell cytoplasm to generate the membraneous protrusions whereby cell-to-cell spread occurs. The actA locus of L.monocytogenes encodes a 90 kDa polypeptide that is a key component of bacterium-host cell microfilament interactions. Cloning of the actA gene allowed the identification of its gene product and permitted construction of an isogenic mutant strain defective in the production of the ActA polypeptide. Sequencing of the region encoding the actA gene revealed that it was located region encoding the actA gene revealed that it was located between the metalloprotease (mpl) and phosphatidylcholine-specific phospholipase C (plcB) genes. Within the cytoplasm of the infected cells, the mutant strain grew as microcolonies, was unable to accumulate actin following escape from the phagocytic compartment and was incapable of infecting adjacent cells. It was also dramatically less virulent, demonstrating that the capacity to move intracellularly and spread intercellularly is a key determinant of L.monocytogenes virulence. Like all other virulence factors described for this microorganism, expression of the ActA polypeptide is controlled by the PrfA regulator protein. The primary sequence of this protein appeared to be unique with no extended homology to known protein sequences. However, an internal repeat sequence showed strong regional homology to a sequence from within the hinge region of the cytoskeletal protein vinculin.     

Role of pseudorabies virus glycoprotein gI in virus release from infected cells.

The Bartha vaccine strain of pseudorabies virus has a deletion in the short unique (Us) region of its genome which includes the genes that code for glycoproteins gI and gp63 (E. Petrovskis, J. G. Timmins, T. M. Gierman, and L. E. Post, J. Virol. 60:1166-1169, 1986). Restoration of an intact Us to the Bartha strain enhances its ability to be released from infected rabbit kidney cells and increases the size of the plaques formed on these cells (T. Ben-Porat, J. M. DeMarchi, J. Pendrys, R. A. Veach, and A. S. Kaplan, J. Virol. 57:191-196, 1986). To determine which gene function plays a role in virus release from rabbit kidney cells, deletions were introduced into the genomes of both wild-type virus and the "rescued" Bartha strain (Bartha strain to which an intact Us had been restored) that abolish the expression of either the gI gene alone or both gI and gp63 genes. The effect of these deletions on the phenotype of the viruses was studied. Deletion mutants of wild-type virus defective in either gI or gI and gp63 behave like wild-type virus with respect to virus release and plaque size on rabbit kidney cells. Deletion of gI from the rescued Bartha strain, however, strongly affects virus release and causes a decrease in plaque size. We conclude that gI affects virus release but that at least one other viral function also affects this process. This function is defective in the Bartha strain but not in wild-type virus; in its absence gI is essential to efficient release of the virus from rabbit kidney cells.