Identification of three genes nonessential for growth in cell culture near the right terminus of the unique sequences of long component of herpes simplex virus 1

"Non-Essential" Proteins of HSV-1 with Essential Roles In Vivo: A Comprehensive Review

Viruses encode for structural proteins that participate in virion formation and include capsid and envelope proteins. In addition, viruses encode for an array of non-structural accessory proteins important for replication, spread, and immune evasion in the host and are often linked to virus pathogenesis. Most virus accessory proteins are non-essential for growth in cell culture because of the simplicity of the infection barriers or because they have roles only during a state of the infection that does not exist in cell cultures (i.e., tissue-specific functions), or finally because host factors in cell culture can complement their absence. For these reasons, the study of most nonessential viral factors is more complex and requires development of suitable cell culture systems and in vivo models. Approximately half of the proteins encoded by the herpes simplex virus 1 (HSV-1) genome have been classified as non-essential. These proteins have essential roles in vivo in counteracting antiviral responses, facilitating the spread of the virus from the sites of initial infection to the peripheral nervous system, where it establishes lifelong reservoirs, virus pathogenesis, and other regulatory roles during infection. Understanding the functions of the non-essential proteins of herpesviruses is important to understand mechanisms of viral pathogenesis but also to harness properties of these viruses for therapeutic purposes. Here, we have provided a comprehensive summary of the functions of HSV-1 non-essential proteins.

Selective degradation of mRNAs by the HSV host shutoff RNase is regulated by the UL47 tegument protein

Herpes simplex virus 1 (HSV-1) encodes an endoribonuclease that is responsible for the shutoff of host protein synthesis [virion host shutoff (VHS)-RNase]. The VHS-RNase released into cells during infection targets differentially four classes of mRNAs. Thus, (a) VHS-RNase degrades stable cellular mRNAs and α (immediate early) viral mRNAs; (b) it stabilizes host stress response mRNAs after deadenylation and subsequent cleavage near the adenylate-uridylate (AU)-rich elements; (c) it does not effectively degrade viral β or γ mRNAs; and (d) it selectively spares from degradation a small number of cellular mRNAs. Current evidence suggests that several viral and at least one host protein (tristetraprolin) regulate its activity. Thus, virion protein (VP) 16 and VP22 neutralize the RNase activity at late times after infection. By binding to AU-rich elements via its interaction with tristetraprolin, the RNase deadenylates and cleaves the mRNAs in proximity to the AU-rich elements. In this report we show that another virion protein, UL47, brought into the cell during infection, attenuates the VHS-RNase activity with respect to stable host and viral α mRNAs and effectively blocks the degradation of β and γ mRNAs, but it has no effect on the processing of AU-rich mRNAs. The properties of UL47 suggest that it, along with the α protein infected cell protein 27, attenuates degradation of mRNAs by the VHS-RNase through interaction with the enzyme in polyribosomes. Mutants lacking both VHS-RNase and UL47 overexpress α genes and delay the expression of β and γ genes, suggesting that overexpression of α genes inhibits the downstream expression of early and late genes.

A leucine zipper motif of a tegument protein triggers final envelopment of human cytomegalovirus

The product of the human cytomegalovirus (HCMV) UL71 gene is conserved throughout the herpesvirus family. During HCMV infection, protein pUL71 is required for efficient virion egress and is involved in the final steps of secondary envelopment leading to infectious viral particles. We found strong indications for oligomerization of pUL71 under native conditions when recombinant pUL71 was negatively stained and analyzed by electron microscopy. Oligomerization of pUL71 during infection was further verified by native and reducing polyacrylamide gel electrophoresis (PAGE). By in silico analyses of the pUL71 sequence, we noticed a basic leucine zipper (bZIP)-like domain, which might serve as an oligomerization domain. We demonstrated the requirement of the bZIP-like domain for pUL71 oligomerization by coimmunoprecipitation and bimolecular fluorescence complementation using a panel of pUL71 mutants. These studies revealed that the mutation of two leucine residues is sufficient to abrogate oligomerization but that intracellular localization of pUL71 was unaffected. To investigate the relevance of the bZIP domain in the viral context, recombinant viruses carrying mutations identical to those in the panel of pUL71 mutants were generated. bZIP-defective viral mutants showed impaired viral growth, a small-plaque phenotype, and an ultrastructural phenotype similar to that of the previously described UL71 stop mutant virus. The majority of virus particles within the viral assembly compartment exhibited various stages of incomplete envelopment, which is consistent with the growth defect for the bZIP mutants. From these data we conclude that the bZIP-like domain is required for oligomerization of pUL71, which seems to be essential for correct envelopment of HCMV.

The anti-interferon activity of conserved viral dUTPase ORF54 is essential for an effective MHV-68 infection

Gammaherpesviruses such as KSHV and EBV establish lifelong persistent infections through latency in lymphocytes. These viruses have evolved several strategies to counteract the various components of the innate and adaptive immune systems. We conducted an unbiased screen using the genetically and biologically related virus, MHV-68, to find viral ORFs involved in the inhibition of type I interferon signaling and identified a conserved viral dUTPase, ORF54. Here we define the contribution of ORF54 in type I interferon inhibition by ectopic expression and through the use of genetically modified MHV-68. ORF54 and an ORF54 lacking dUTPase enzymatic activity efficiently inhibit type I interferon signaling by inducing the degradation of the type I interferon receptor protein IFNAR1. Subsequently, we show in vitro that the lack of ORF54 causes a reduction in lytic replication in the presence of type I interferon signaling. Investigation of the physiological consequence of IFNAR1 degradation and importance of ORF54 during MHV-68 in vivo infection demonstrates that ORF54 has an even greater impact on persistent infection than on lytic replication. MHV-68 lacking ORF54 expression is unable to efficiently establish latent infection in lymphocytes, although it replicates relatively normally in lung tissues. However, infection of IFNAR−/− mice alleviates this phenotype, emphasizing the specific role of ORF54 in type I interferon inhibition. Infection of mice and cells by a recombinant MHV-68 virus harboring a site specific mutation in ORF54 rendering the dUTPase inactive demonstrates that dUTPase enzymatic activity is not required for anti-interferon function of ORF54. Moreover, we find that dUTPase activity is dispensable at all stages of MHV-68 infection analyzed. Overall, our data suggest that ORF54 has evolved anti-interferon activity in addition to its dUTPase enzymatic activity, and that it is actually the anti-interferon role that renders ORF54 critical for establishing an effective persistent infection of MHV-68.

Human gammaherpesviruses, Kaposi's sarcoma-associated herpesvirus and Epstein-Barr virus, are the cause of several malignancies, especially in patients immunocompromised due to HIV infection. The study of these human gammaherpesviruses is difficult due to their inability to replicate in cell culture and the lack of a small-animal model. Murine gammaherpesvirus-68 is a genetically and biologically similar virus that is utilized as a mouse model because it offers such advantages as the ability to replicate in cell culture, a manipulatable genome, and infection of mice. In this study, we have identified viral open reading frame 54 (ORF54) as an inhibitor of innate immunity, specifically of the type I interferon response. Although ORF54 is a conserved viral dUTPase, we found that its anti-interferon activity does not require its enzymatic activity. Through infection of cells and mice, we define the critical role of ORF54 in establishing persistent latent infection of MHV-68 by inducing the degradation of the type I interferon receptor. Our studies provide new insights into the far reaching effects of type I interferon signaling and the dual role of ORF54. This work could aid in the development of vaccine strategies to gammaherpesvirus infection.

Plus- and minus-end directed microtubule motors bind simultaneously to herpes simplex virus capsids using different inner tegument structures

Many viruses depend on host microtubule motors to reach their destined intracellular location. Viral particles of neurotropic alphaherpesviruses such as herpes simplex virus 1 (HSV1) show bidirectional transport towards the cell center as well as the periphery, indicating that they utilize microtubule motors of opposing directionality. To understand the mechanisms of specific motor recruitment, it is necessary to characterize the molecular composition of such motile viral structures. We have generated HSV1 capsids with different surface features without impairing their overall architecture, and show that in a mammalian cell-free system the microtubule motors dynein and kinesin-1 and the dynein cofactor dynactin could interact directly with capsids independent of other host factors. The capsid composition and surface was analyzed with respect to 23 structural proteins that are potentially exposed to the cytosol during virus assembly or cell entry. Many of these proteins belong to the tegument, the hallmark of all herpesviruses located between the capsid and the viral envelope. Using immunoblots, quantitative mass spectrometry and quantitative immunoelectron microscopy, we show that capsids exposing inner tegument proteins such as pUS3, pUL36, pUL37, ICP0, pUL14, pUL16, and pUL21 recruited dynein, dynactin, kinesin-1 and kinesin-2. In contrast, neither untegumented capsids exposing VP5, VP26, pUL17 and pUL25 nor capsids covered by outer tegument proteins such as vhs, pUL11, ICP4, ICP34.5, VP11/12, VP13/14, VP16, VP22 or pUS11 bound microtubule motors. Our data suggest that HSV1 uses different structural features of the inner tegument to recruit dynein or kinesin-1. Individual capsids simultaneously accommodated motors of opposing directionality as well as several copies of the same motor. Thus, these associated motors either engage in a tug-of-war or their activities are coordinately regulated to achieve net transport either to the nucleus during cell entry or to cytoplasmic membranes for envelopment during assembly.

Many viruses, particularly neurotropic alphaherpesviruses such as herpes simplex virus (HSV), require an intact microtubule network for efficient replication and pathogenesis. In living cells, host and viral cargo show rapid reversals in transport direction, suggesting that they can recruit motors of opposing directionality simultaneously. To elucidate the molecular mechanisms for specific motor-cargo recognition, it is necessary to characterize the surface of such cargos. We established a cell-free system that reconstitutes the binding of native, mammalian microtubule motors to intact tegumented HSV capsids. Our data suggest that the inbound motor dynein and the outbound motor kinesin-1 bind directly and independently of other host factors to the inner tegument that coats the capsids during cytosolic transport. Identifying viral receptors for the hosts' transport machinery will provide us on the one hand with new potential targets for antiviral therapy. On the other hand, such viral protein domains could be added to viral vectors or even to artificial nano carriers designed to deliver therapeutic genes or molecules to the nucleus or other subcellular destinations.

The capsid protein encoded by U(L)17 of herpes simplex virus 1 interacts with tegument protein VP13/14

The U(L)17 protein (pU(L)17) of herpes simplex virus 1 (HSV-1) likely associates with the surfaces of DNA-containing capsids in a heterodimer with pU(L)25. pU(L)17 is also associated with viral light particles that lack capsid proteins, suggesting its presence in the tegument of the HSV-1 virion. To help determine how pU(L)17 becomes incorporated into virions and its functions therein, we identified pU(L)17-interacting proteins by immunoprecipitation with pU(L)17-specific IgY at 16 h postinfection, followed by mass spectrometry. Coimmunoprecipitated proteins included cellular histone proteins H2A, H3, and H4; the intermediate filament protein vimentin; the major HSV-1 capsid protein VP5; and the HSV tegument proteins VP11/12 (pU(L)46) and VP13/14 (pU(L)47). The pU(L)17-VP13/14 interaction was confirmed by coimmunoprecipitation in the presence and absence of intact capsids and by affinity copurification of pU(L)17 and VP13/14 from lysates of cells infected with a recombinant virus encoding His-tagged pU(L)17. pU(L)17 and VP13/14-HA colocalized in the nuclear replication compartment, in the cytoplasm, and at the plasma membrane between 9 and 18 h postinfection. One possible explanation of these data is that pU(L)17 links the external face of the capsid to VP13/14 and associated tegument components.

A UL47 gene deletion mutant of bovine herpesvirus type 1 exhibits impaired growth in cell culture and lack of virulence in cattle

Tegument protein VP8 encoded by the U(L)47 gene of bovine herpesvirus type 1 (BHV-1) is the most abundant constituent of mature virions. In the present report, we describe the characterization of U(L)47 gene-deleted BHV-1 in cultured cells and its natural host. The U(L)47 deletion mutant exhibited reduced plaque size and more than 100-fold decrease in intracellular and extracellular viral titers in cultured cells. Ultrastructural observations of infected cells showed normal maturation of BHV-1 virions in the absence of VP8. There was no evidence for a change in immediate-early gene activator function of VP16 in the U(L)47 deletion mutant virus-infected cells, since bovine ICP4 mRNA and protein levels were similar to those in the wild-type and revertant virus-infected cells throughout the course of infection. Whereas VP16, glycoprotein C (gC), gB, and VP5 were expressed to wild-type levels in the U(L)47 deletion mutant-infected cells, the gD and VP22 protein levels were significantly reduced. The reduction in gD protein was associated with increased turnover of the protein. Furthermore, some of the analyzed early and late proteins were expressed with earlier kinetics in the absence of VP8. Extracellular virions of the U(L)47 deletion mutant contained reduced amounts of gD, gB, gC, and VP22 but similar amounts of VP16 compared to those of wild-type or revertant virus particles. In addition, the U(L)47 gene product was indispensable for BHV-1 replication in vivo, since no clinical manifestations or viral shedding were detected in the U(L)47 deletion mutant-infected calves, and the virus failed to induce significant levels of humoral and cellular immunity.

Utilization of microsatellite polymorphism for differentiating herpes simplex virus type 1 strains

The herpes simplex virus type 1 (HSV-1) genome is a linear double-stranded DNA of 152 kpb. It is divided into long and short regions of unique sequences termed U(L) and U(S), respectively, and these are flanked by regions of inverted internal and terminal repeats. Microsatellites are short tandem repeats of 1- to 6-nucleotide motifs; they are often highly variable and polymorphic within the genome, which raises the question of whether they may be used as molecular markers for the precise differentiation of HSV-1 strains. In this study, 79 different microsatellites (mono-, di-, and trinucleotide repeats) in the HSV-1 complete genome were identified by in silico analysis. Among those microsatellites, 45 were found to be distributed in intergenic or noncoding inverted repeat regions, while 34 were in open reading frames. Length polymorphism analysis of the PCR products was used to investigate a set of 12 distinct HSV-1 strains and allowed the identification of 23 polymorphic and 6 monomorphic microsatellites, including two polymorphic trinucleotide repeats (CGT and GGA) within the UL46 and US4 genes, respectively. A multiplex PCR method that amplified 10 polymorphic microsatellites was then developed for the rapid and accurate genetic characterization of HSV-1 strains. Each HSV-1 strain was characterized by its own microsatellite haplotype, which proved to be stable over time in cell culture. This relevant innovative tool was successfully applied both to confirm the close relationship between sequential HSV-1 isolates collected from patients with multiple recurrent infections and to investigate putative nosocomial infections.

Herpes simplex virus protein UL11 but not UL51 is associated with lipid rafts

The UL11 and UL51 gene products of herpes simplex virus (HSV) are membrane-associated tegument proteins that are incorporated into the HSV virion. UL11 and UL51 are conserved throughout the herpesvirus family. Both UL11 and UL51, either singly or in combination, are involved in virion envelopment and/or egress. Both proteins are fatty acylated: UL11 is both acylated by myristoic and palmitoic acids and UL51 is monoacylated by palmitoic acid. Using confocal microscopy and sucrose gradient fractionations in transfected or HSV-infected cells, we found that HSV-2 UL11 but not UL51 was associated with lipid rafts. The dual acylation of UL11 was necessary for lipid raft association, as mutations in the myristoylation or palmitoylation sites prevented lipid raft association. These differences in lipid raft association may contribute to the functional differences between UL11 and UL51.

Herpes simplex virus type 1 UL51 protein is involved in maturation and egress of virus particles

The UL51 gene of herpes simplex virus type 1 (HSV-1) encodes a phosphoprotein whose homologs are conserved throughout the herpes virus family. Recently, we reported that UL51 protein colocalizes with Golgi marker proteins in transfected cells and that targeting of UL51 protein to the Golgi apparatus depends on palmitoylation of its N-terminal cysteine at position 9 (N. Nozawa, T. Daikoku, T. Koshizuka, Y. Yamauchi, T. Yoshikawa, and Y. Nishiyama, J. Virol. 77:3204-3216, 2003). However, its role in the HSV replication cycle was unknown. Here, we generated UL51-null mutants (FDL51) in HSV-1 to uncover the function of UL51 protein. We show that the mutant plaques were much smaller in size and that maximal titers were reduced nearly 100-fold compared to wild-type virus. Electron microscopy indicated that the formation of nucleocapsids was not affected by the deletion of UL51 but that viral egress from the perinuclear space was severely compromised. In FDL51-infected cells, a large number of enveloped nucleocapsids were observed in the perinuclear space, but enveloped mature virions in the cytoplasm, as well as extracellular mature virions, were rarely detected. These defects were fully rescued by reinsertion of the UL51 gene. These results indicate that UL51 protein is involved in the maturation and egress of HSV-1 virus particles downstream of the initial envelopment step.

Nuclear localizations of the herpes simplex virus type 1 tegument proteins VP13/14, vhs, and VP16 precede VP22-dependent microtubule reorganization and VP22 nuclear import

Herpes simplex virus type 1 (HSV-1) induces microtubule reorganization beginning at approximately 9 h postinfection (hpi), and this correlates with the nuclear localization of the tegument protein VP22. Thus, the active retention of this major virion component by cytoskeletal structures may function to regulate its subcellular localization (A. Kotsakis, L. E. Pomeranz, A. Blouin, and J. A. Blaho, J. Virol. 75:8697-8711, 2001). The goal of this study was to determine whether the subcellular localization patterns of other HSV-1 tegument proteins are similar to that observed with VP22. To address this, we performed a series of indirect immunofluorescence analyses using synchronously infected cells. We observed that tegument proteins VP13/14, vhs, and VP16 localized to the nucleus as early as 5 hpi and were concentrated in nuclei by 9 hpi, which differed from that seen with VP22. Microtubule reorganization was delayed during infection with HSV-1(RF177), a recombinant virus that does not produce full-length VP22. These infected cells did not begin to lose microtubule-organizing centers until 13 hpi. Repair of the unique long 49 (UL49) locus in HSV-1(RF177) yielded HSV-1(RF177R). Microtubule reorganization in HSV-1(RF177R)-infected cells occurred with the same kinetics as HSV-1(F). Acetylated tubulin remained unchanged during infection with either HSV-1(F) or HSV-1(RF177). Thus, while alpha-tubulin reorganized during infection, acetylated tubulin was stable, and the absence of full-length VP22 did not affect this stability. Our findings indicate that the nuclear localizations of tegument proteins VP13/14, VP16, and vhs do not appear to require HSV-1-induced microtubule reorganization. We conclude that full-length VP22 is needed for optimal microtubule reorganization during infection. This implies that VP22 mainly functions to reorganize microtubules later, rather than earlier, in infection. That acetylated tubulin does not undergo restructuring during VP22-dependent, virus-induced microtubule reorganization suggests that it plays a role in stabilizing the infected cells. Our results emphasize that VP22 likely plays a key role in cellular cytopathology during HSV-1 infection.

Functional analysis of the pseudorabies virus UL51 protein

Homologs of the UL51 protein of herpes simplex virus have been identified in all herpesvirus subfamilies, but until now, no function has been assigned to any of them. To investigate function of the UL51 gene product of the alphaherpesvirus pseudorabies virus (PrV), we isolated and analyzed a mutant lacking the major part of the open reading frame, PrV-DeltaUL51F, and a rescuant. One-step growth analysis of PrV-DeltaUL51F revealed only slightly reduced titers, but plaque size was notably diminished and reached only approximately 30% the plaque size of wild-type PrV. Ultrastructurally, intracytoplasmic capsids were found in large numbers either without envelope or in different stages of envelopment, indicating that secondary envelopment in the cytoplasm was less efficient. However, neuroinvasion in the mouse trigeminal pathway after intranasal infection was only slightly delayed. A PrV UL11 mutant also showed a defect in secondary envelopment (M. Kopp, H. Granzow, W. Fuchs, B. G. Klupp, E. Mundt, A. Karger, and T. C. Mettenleiter, J. Virol. 77:5339-5351, 2003). Since both proteins are part of the viral tegument and are predicted to be membrane associated, they may serve similar, possibly redundant functions during viral morphogenesis. Therefore, we also isolated a mutant simultaneously lacking UL51 and UL11. This mutant exhibited further reduced plaque size compared to the single-deletion mutants, but viral titers were comparable to those for the UL11 mutant. In electron microscopic analyses, the observed defect in secondary envelopment was similar to that found in the UL11 single-deletion mutant. In conclusion, both conserved tegument proteins, either singly or in combination, are involved in virion morphogenesis in the cytoplasm but are not essential for viral replication in vitro and in vivo.

Subcellular localization of herpes simplex virus type 1 UL51 protein and role of palmitoylation in Golgi apparatus targeting

The herpes simplex virus type 1 (HSV-1) UL51 gene products are virion-associated phosphoproteins with apparent molecular masses of 27, 29, and 30 kDa in HSV-1-infected cells. In this study, we have investigated the intracellular localization and distribution of UL51 protein both in infected cells and in transfected cells expressing only UL51. We found that this protein colocalized closely with Golgi marker proteins such as the Golgi-58K protein and GM130 in transfected cells expressing only UL51. However, in infected cells, the UL51 protein localized to the juxtanuclear region but only partially colocalized with the Golgi maker proteins. Mutant protein analysis revealed that the N-terminal 15 amino acid residues of the UL51 protein sufficed for this Golgi localization property. The UL51 protein redistributed on addition of brefeldin A. This was prevented by pretreatment with 2-deoxyglucose and sodium azide, which results in ATP depletion, but not by pretreatment with NaF and AlCl(3), which activates heterotrimeric G proteins. Moreover, we found that palmitoylation of the UL51 protein through the N-terminal cysteine at position 9 was necessary for its Golgi localization. Protease digestion analysis suggested that the UL51 protein localized on the cytoplasmic face of the membrane in UL51-transfected cells, while in infected cells it localized mainly to the inside of cytoplasmic vesicles and/or the viral envelope. Transmission immunoelectron microscopy revealed an association of UL51 protein-specific labeling with cytoplasmic virions and also with some membranous structure. We infer from these observations that internalization of UL51 protein into the cytoplasmic vesicle and/or virion may occur in association with viral envelopment in HSV-infected cells.

Identification and characterization of the pseudorabies virus tegument proteins UL46 and UL47: role for UL47 in virion morphogenesis in the cytoplasm

Proteins encoded by the UL46 and UL47 genes of herpes simplex virus type 1 (HSV-1) constitute major components of the viral tegument. However, their functions have so far not been elucidated in detail. By use of monospecific antisera directed against bacterially expressed glutathione-S-transferase fusion proteins, the homologous UL46 and UL47 proteins of the alphaherpesvirus pseudorabies virus (PrV) were identified in virus-infected cells and in virions. The PrV UL46 gene product of 693 amino acids (aa) exhibits an apparent molecular mass of 95 kDa, whereas the UL47 product of 750 aa was identified as a 97-kDa protein. Both are present in purified virions, correlating with their role as tegument proteins. Immunofluorescence analysis by confocal laser scan microscopy showed that late in infection the UL46 product is detectable in the cytoplasm, whereas the UL47 product was observed to be diffuse in the cytoplasm and speckled in the nucleus. Virus mutants lacking either the UL46 or the UL47 gene or both were isolated on noncomplementing cells, demonstrating that these genes either singly or in combination are not required for productive viral replication. However, plaque sizes were decreased. Interestingly, in one-step growth analysis, UL47 deletion mutants exhibited an approximately 10-fold decrease in final titers, whereas the UL46 deletion mutant was not affected. This finding correlated with ultrastructural observations which showed unimpaired virion morphogenesis in the absence of the UL46 protein, whereas in the absence of the UL47 protein intracytoplasmic aggregates of partially tegumented capsids were observed. In summary, we identified the PrV UL46 and UL47 proteins and show that the UL47 protein plays an important role in virion assembly in the cytoplasm.

Of the three tegument proteins that package mRNA in herpes simplex virions, one (VP22) transports the mRNA to uninfected cells for expression prior to viral infection

An earlier report has shown that herpes simplex virus 1 virions package RNA. Experiments designed to reveal the identity of the virion proteins capable of binding the RNA and to show whether the mRNA carried in the newly infected cells was expressed showed the following: (i) (32)P-labeled riboprobe generated by in vitro transcription of the U(S)8.5 ORF bound three proteins identified as the products of U(S)11, U(L)47, and U(L)49 (VP22) genes. (ii) Viral RNA was bound to U(L)47 or U(S)11 proteins immune precipitated from cells transduced with baculoviruses expressing U(L)47 or U(S)11 and then superinfected with HSV-1 under conditions that blocked DNA synthesis and assembly of virions. (iii) Virions were purified from cells transduced with a baculovirus encoding a U(S)8.5 protein fused to green fluorescent protein and superinfected with an HSV-1 mutant lacking the U(S)8-12 genes. HEp-2 cells infected with these virions expressed the chimeric protein in approximately 1% of infected cells. (iv) In mixed cultures, untreated Vero cells acquired the mRNA encoding the green fluorescent-U(S)8.5 chimeric protein from HEp-2 cells doubly transduced with the genes encoding VP22 and the chimeric protein. The transfer was RNase sensitive and VP22 dependent, indicating that the RNA encoded by the chimeric gene was transferred to Vero cells as mRNA. We conclude that (i) three virion proteins are capable of binding RNA; (ii) the packaged RNA can be expressed in newly infected cells; and (iii) the U(L)47 protein was earlier reported to shuttle from nucleus to the cytoplasm and may transport RNA. VP22 thus appears to be a member of a new class of viral proteins whose major function is to bind and transport infected cell mRNA to uninfected cells to create the environment for effective initiation of infection.

Transcriptional and translational expression kinetics of the bovine herpesvirus 1 UL51 homologue gene

We characterized the expression kinetics of the transcript and protein generated from the bovine herpesvirus 1 (BHV1) homologue of the herpes simplex virus 1 (HSV1) UL51 gene. The BHV1 UL51 ORF, located at positions 7236-->7967 of the viral genome, generated a major 1.05 kb transcript accumulating at very low abundance as soon as 3 h post-infection (p.i.), after which its levels increased to reach a plateau from 6 to 12 h p.i., and then slowly decreased up to 24 h p.i. As determined by S1 nuclease protection assays, UL51 transcription initiated at two distinct sites located at 191 and 196 bases upstream from the initiation codon, corresponding to positions 7045 and 7040 of the viral genome, respectively. Western blotting of BHV1-infected protein cell lysates, using a BHV1-specific antiserum generated against a recombinant protein expressed in Escherichia coli, detected a 28 kDa protein of the expected size (24985 Da) whose expression kinetics followed that of its transcript. As evidenced by in situ immunofluorescence assays, the protein mainly localized to the cytoplasm and the perinuclear region of infected cells. In contrast to HSV1 UL51 which is classified as a gamma2 gene, BHV1 UL51 belongs to viral genes of the gamma1 class as expression of its transcript is partially dependent on viral DNA synthesis.

CD8 CTL from genital herpes simplex lesions: recognition of viral tegument and immediate early proteins and lysis of infected cutaneous cells

HSV-2 causes chronic infections. CD8 CTL may play several protective roles, and stimulation of a CD8 response is a rational element of vaccine design for this pathogen. The viral Ags recognized by CD8 T cells are largely unknown. It has been hypothesized that HSV inhibition of TAP may favor recognition of virion input proteins or viral immediate early proteins. We tested this prediction using HSV-specific CD8 CTL clones obtained from genital HSV-2 lesions. Drug and replication block experiments were consistent with specificity for the above-named classes of viral proteins. Fine specificity was determined by expression cloning using molecular libraries of viral DNA, and peptide epitopes recognized at nanomolar concentrations were identified. Three of four clones recognized the viral tegument proteins encoded by genes UL47 and UL49. These proteins are transferred into the cytoplasm on virus entry. Processing of the tegument Ag-derived epitopes was TAP dependent. The tegument-specific CTL were able to lyse HLA class I-appropriate fibroblasts after short times of infection. Lysis of keratinocytes required longer infection and pretreatment with IFN-gamma. Another clone recognized an immediate early protein, ICP0. Lymphocytes specific for these lesion-defined epitopes could be reactivated from the PBMC of additional subjects. These data are consistent with an influence of HSV immune evasion genes upon the selection of proteins recognized by CD8 CTL in lesions. Tegument proteins, identified for the first time as Ags recognized by HSV-specific CD8 CTL, are rational candidate vaccine compounds.

Nuclear localization and shuttling of herpes simplex virus tegument protein VP13/14

The herpes simplex virus type 1 gene UL47 encodes the tegument proteins referred to collectively as VP13/14, which are believed to be differentially modified forms of the same protein. Here we show that the major product of the UL47 gene during transient expression is VP14, suggesting that some feature of virus infection is required to produce VP13. We have tagged VP13/14 with green fluorescent protein and have demonstrated that the protein is targeted efficiently to the nucleus, where it often localizes in numerous punctate domains. Furthermore, we show that removal of the N-terminal 127 residues of the protein abrogates nuclear accumulation, and we have identified a 14-amino-acid peptide from this region that is sufficient to function as a nuclear targeting signal and transport a heterologous protein to the nucleus. This short peptide contains two runs of four arginine residues, suggesting that the VP13/14 nuclear localization signal may behave in a manner similar to that of the arginine-rich nuclear localization signals of the retrovirus transactivator proteins Tat, Rev, and Rex. In addition, by using heterokaryon assays, we show that VP13/14 is capable of shuttling between the nucleus and cytoplasm of the cell, a property that may be attributed to three leucine-rich stretches in the C-terminal half of the protein that again bear similarity to the nuclear export signals of Rev and Rex. This is the first demonstration of a tegument protein that is specifically targeted to the nucleus, a feature which may be relevant both during virus entry, when VP13/14 enters the cell as a component of the tegument, and at later times, when large amounts of newly synthesized VP13/14 are present within the cell.

Fluorescent tagging of herpes simplex virus tegument protein VP13/14 in virus infection

The cellular site of herpesvirus tegument assembly has yet to be defined. We have previously used a recombinant herpes simplex virus type 1 expressing a green fluorescent protein (GFP)-tagged tegument protein, namely VP22, to show that VP22 is localized exclusively to the cytoplasm during infection. Here we have constructed a similar virus expressing another fluorescent tegument protein, YFP-VP13/14, and have visualized the intracellular localization of this second tegument protein in live infected cells. In contrast to VP22, VP13/14 is targeted predominantly to the nuclei of infected cells at both early and late times in infection. More specifically, YFP-13/14 localizes initially to the nuclear replication compartments and then progresses into intense punctate domains that appear at around 12 h postinfection. At even later times this intranuclear punctate fluorescence is gradually replaced by perinuclear micropunctate and membranous fluorescence. While the vast majority of YFP-13/14 seems to be targeted to the nucleus, a minor subpopulation also appears in a vesicular pattern in the cytoplasm that closely resembles the pattern previously observed for GFP-22. Moreover, at late times weak fluorescence appears at the cell periphery and in extracellular virus particles, confirming that YFP-13/14 is assembled into virions. This predominantly nuclear targeting of YFP-13/14 together with the cytoplasmic targeting of VP22 may imply that there are multiple sites of tegument protein incorporation along the virus maturation pathway. Thus, our YFP-13/14-expressing virus has revealed the complexity of the intracellular targeting of VP13/14 and provides a novel insight into the mechanism of tegument, and hence virus, assembly.

Assembly of infectious Herpes simplex virus type 1 virions in the absence of full-length VP22

VP22, the 301-amino-acid phosphoprotein product of the herpes simplex virus type 1 (HSV-1) U(L)49 gene, is incorporated into the tegument during virus assembly. We previously showed that highly modified forms of VP22 are restricted to infected cell nuclei (L. E. Pomeranz and J. A. Blaho, J. Virol. 73:6769-6781, 1999). VP22 packaged into infectious virions appears undermodified, and nuclear- and virion-associated forms are easily differentiated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (J. A. Blaho, C. Mitchell, and B. Roizman, J. Biol. Chem. 269:17401-17410, 1994). As VP22 packaging-associated undermodification is unique among HSV-1 tegument proteins, we sought to determine the role of VP22 during viral replication. We now show the following. (i) VP22 modification occurs in the absence of other viral factors in cell lines which stably express its gene. (ii) RF177, a recombinant HSV-1 strain generated for this study, synthesizes only the amino-terminal 212 amino acids of VP22 (Delta212). (iii) Delta212 localizes to the nucleus and incorporates into virions during RF177 infection of Vero cells. Thus, the carboxy-terminal region is not required for nuclear localization of VP22. (iv) RF177 synthesizes the tegument proteins VP13/14, VP16, and VHS (virus host shutoff) and incorporates them into infectious virions as efficiently as wild-type virus. However, (v) the loss of VP22 in RF177 virus particles is compensated for by a redistribution of minor virion components. (vi) Mature RF177 virions are identical to wild-type particles based on electron microscopic analyses. (vii) Single-step growth kinetics of RF177 in Vero cells are essentially identical to those of wild-type virus. (viii) RF177 plaque size is reduced by nearly 40% compared to wild-type virus. Based on these results, we conclude that VP22 is not required for tegument formation, virion assembly/maturation, or productive HSV-1 replication, while the presence of full-length VP22 in the tegument is needed for efficient virus spread in Vero cell monolayers.

The non-essential UL50 gene of avian infectious laryngotracheitis virus encodes a functional dUTPase which is not a virulence factor

The DNA sequence of the infectious laryngotracheitis virus (ILTV) UL50, UL51 and UL52 gene homologues was determined. Although the deduced UL50 protein lacks the first of five conserved domains of the corresponding proteins of mammalian alphaherpesviruses, the ILTV gene product was also shown to possess dUTPase activity. The generation of UL50-negative ILTV mutants was facilitated by recombination plasmids encoding green fluorescent protein (GFP), and expression constructs of predicted transactivator proteins of ILTV (alphaTIF, ICP4) were successfully used to increase the infectivity of viral genomic DNA. A GFP-expressing UL50-deletion mutant of ILTV showed reduced cell-to-cell spread in vitro, and was attenuated in vivo. A similar deletion mutant without the foreign gene, however, propagated like wild-type ILTV in cell culture and was pathogenic in chickens. We conclude that the viral dUTPase is not required for efficient replication of ILTV in the respiratory tract of infected animals. The replication defect of the GFP-expressing ILTV recombinant is most likely caused by toxic effects of the reporter gene product, since spontaneously occurring inactivation mutants exhibited wild-type-like growth.

Herpes simplex virus type 1 gene UL14: phenotype of a null mutant and identification of the encoded protein

Herpes simplex virus type 1 (HSV-1) gene UL14 is located between divergently transcribed genes UL13 and UL15 and overlaps the promoters for both of these genes. UL14 also exhibits a substantial overlap of its coding region with that of UL13. It is one of the few HSV-1 genes for which a phenotype and protein product have not been described. Using mass spectrometric and immunological approaches, we demonstrated that the UL14 protein is a minor component of the virion tegument of 32 kDa which is expressed late in infection. In infected cells, the UL14 protein was detected in the nucleus at discrete sites within electron-dense nuclear bodies and in the cytoplasm initially in a diffuse distribution and then at discrete sites. Some of the UL14 protein was phosphorylated. A mutant with a 4-bp deletion in the central region of UL14 failed to produce the UL14 protein and generated small plaques. The mutant exhibited an extended growth cycle at low multiplicity of infection and appeared to be compromised in efficient transit of virus particles from the infected cell. In mice injected intracranially, the 50% lethal dose of the mutant was reduced more than 30,000-fold. Recovery of the mutant from the latently infected sacral ganglia of mice injected peripherally was significantly less than that of wild-type virus, suggesting a marked defect in the establishment of, or reactivation from, latent infection.

Modified VP22 localizes to the cell nucleus during synchronized herpes simplex virus type 1 infection

The UL49 gene product (VP22) of herpes simplex virus types 1 and 2 (HSV-1 and HSV-2) is a virion phosphoprotein which accumulates inside infected cells at late stages of infection. We previously (J. A. Blaho, C. Mitchell, and B. Roizman, J. Biol. Chem. 269:17401-17410, 1994) discovered that the form of VP22 packaged into infectious virions differed from VP22 extracted from infected-cell nuclei in that the virion-associated form had a higher electrophoretic mobility in denaturing gels. Based on these results, we proposed that VP22 in virions was "undermodified" in some way. The goal of this study is to document the biological and biochemical properties of VP22 throughout the entire course of a productive HSV-1 infection. We now report the following. (i) VP22 found in infected cells is distributed in at least three distinct subcellular localizations, which we define as cytoplasmic, diffuse, and nuclear, as measured by indirect immunofluorescence. (ii) Using a synchronized infection system, we determined that VP22 exists predominantly in the cytoplasm early in infection and accumulates in the nucleus late in infection. (iii) While cytoplasmic VP22 colocalizes with the HSV-1 glycoprotein D early in infection, the nuclear form of VP22 is not restricted to replication compartments which accumulate ICP4. (iv) VP22 migrates as at least three unique electrophoretic species in denaturing sodium dodecyl sulfate-DATD-polyacrylamide gels. VP22a, VP22b, and VP22c have high, intermediate, and low mobility, respectively. (v) The relative distribution of the various forms of VP22 derived from infected whole-cell extracts varies during the course of infection such that low-mobility species predominate at early times and high-mobility forms accumulate later. (vi) The highest-mobility forms of VP22 partition with the cytoplasmic fraction of infected cells, while the lowest-mobility forms are associated with the nuclear fraction. (vii) Finally, full-length VP22 which partitions in the nucleus incorporates radiolabel from [32P]orthophosphate whereas cytoplasmic VP22 does not. Based on these results, we conclude that modification of VP22 coincides with its appearance in the nucleus during the course of productive HSV-1 infection.

The left border of the genomic inversion of pseudorabies virus contains genes homologous to the UL46 and UL47 genes of herpes simplex virus type 1, but no UL45 gene

The genome of pseudorabies virus (PrV) is collinear with the herpes simplex virus type 1 (HSV1) genome, except for an inversion in the unique long region, the right extremity of which resides within the BamHI fragment 9 and the left within the BamHI fragment 1. We previously sequenced the right border of the inversion which is situated next to the UL44-gC gene and found that it encodes the UL24, UL25, UL26 and UL26.5 gene counterparts of HSV1. We have now sequenced 5317 base pairs of the BamHI fragment 1, upstream of the UL27-gB gene. We found two open reading frames homologous to UL46 and UL47 of HSV1 yet UL45 was absent and replaced by a set of strictly repeated sequences. PrV UL46 and UL47 are transcribed into two 3' co-terminal messenger RNAs with early and late kinetics, respectively. Comparison of the PrV UL46 and UL47 protein sequences with their counterparts from alphaherpesviruses indicated a strong similarity. The genome is rearranged in this region with respect to HSV1 and the inversion must have taken place, on the left side, within the UL46-UL27 intergenic region. Thus, the inversion should include genes UL27 to UL44.

The pseudorabies virus UL51 gene product is a 30-kilodalton virion component

Positional homologs to the UL51 open reading frame of herpes simplex virus type 1 have been identified throughout the herpesvirus family. However, no respective protein has so far been described for any of the herpesviruses. With rabbit antisera directed against oligopeptides predicted to comprise antigenic regions of the deduced pseudorabies virus (PrV) UL51 protein, a polypeptide with a size of 30 kDa was identified in PrV-infected cell lysates and in purified virions. This molecular mass correlates reasonably well with the predicted mass of 25 kDa of the 236-amino-acid deduced UL51 protein. Antisera raised against peptides derived from different predicted antigenic regions all detected the 30-kDa protein in Western blot (immunoblot) analyses. Specificity was ascertained by peptide competition. Subcellular fractionation showed the presence of the UL51 protein mainly in the nucleus of infected cells. After separation of purified virion preparations into envelope and capsid, the PrV UL51 protein was detected in the capsid fraction. In summary, we identified the first herpesvirus UL51 protein and demonstrate that it represents a structural component of PrV virions.

Pseudorabies virus and equine herpesvirus 1 share a nonessential gene which is absent in other herpesviruses and located adjacent to a highly conserved gene cluster

We have determined the nucleotide sequence and transcriptional pattern of a group of open reading frames in the pseudorabies virus (PrV) genome located near the left end of the unique long region within BamHI 5' fragment at map positions 0.01 to 0.06. The 7,412-bp BamHI 5' fragment was found to contain five complete open reading frames and part of a sixth whose deduced amino acid sequences showed homology to the UL50 (partial), UL51, UL52, UL53, and UL54 gene products of herpes simplex virus type 1 (HSV-1) and corresponding genes identified in other alphaherpesviruses. Homologs to the UL55 and UL56 genes of HSV-1 were not detected. However, we identified a gene with homology only to the first open reading frame (ORF-1) of the equine herpesvirus 1 strain Ab4 (E. A. Telford, M. S. Watson, K. McBride, and A. J. Davison, Virology 189:304-316, 1992). Northern blot analyses revealed unique mRNAs for the UL51, UL54, and ORF-1 genes and a set of 3'-coterminal mRNAs for the UL52 to UL54 genes. A PrV mutant lacking ORF-1 was isolated after deletion of ORF-1 coding sequences and insertion of a lacZ expression cassette. The ORF-1- PrV mutant was able to productively replicate in noncomplementing cells to levels similar to those of wild-type PrV, proving that ORF-1 is not essential for replication of PrV in cell culture. The conservation of this gene between PrV and equine herpesvirus 1 documents the close evolutionary relationship between these animal herpesviruses and points to a possible function of the respective proteins in infection of the natural host.

Nucleotide sequence analysis of an infectious laryngotracheitis virus gene corresponding to the US3 of HSV-1 and a unique gene encoding a 67 kDa protein

The DNA sequence of 4005 nucleotides from the Kpnl O and part of Kpnl K fragments in the short unique region of infectious laryngotracheitis virus (ILTV) was determined. The sequence contained two complete and one partial open reading frames (ORFs). The partial ORF was open at the 5' end of the sequence and represented the NH2-terminal 118 amino acids (aa) of a polypeptide. Its partial predicted protein product exhibited significant homology to the US2 gene product of HSV-1 (herpes simplex virus type 1) and it homologs in other herpesviruses. ORF 2 is 471 aa long and could encode a protein of 53.8 kDa which shared aa homology with the protein kinases encoded by HSV-1 US3 and its gene homologs. Analysis of the ORF 2 aa sequence revealed domains characteristic of protein-serine/threonine (S/T) kinases of cellular and viral origin. The ORF 3 encoded a predicted protein of 601 aa (M(r) 67.5 kDa) which exhibited limited homology (18% overall identity) with the UL47 protein (major tegument protein) of HSV-1. Northern (RNA) blot hybridization and metabolic inhibitors were used to characterize the ILTV protein kinase and the 67K mRNAs. The data revealed that protein kinase is a gamma-1 gene encoding a 1.6 mRNa, while the 67K ORF is a gamma-2 gene encoding a 2 kb mRNA.

n-Butyrate, a cell cycle blocker, inhibits the replication of polyomaviruses and papillomaviruses but not that of adenoviruses and herpesviruses

Small DNA viruses are dependent on the interaction of early proteins (such as large T antigen) with host p53 and Rb to bring about the G1-to-S cell cycle transition. The large DNA viruses are less dependent on host regulatory genes since additional early viral proteins (such as viral DNA polymerase, DNA metabolic enzymes, and other replication proteins) are involved in DNA synthesis. A highly conserved domain of large T antigen (similar to the p53-binding region) exclusively identifies papovavirus, parvovirus, and papillomaviruses from all other larger DNA viruses and implies a conserved interaction with host regulatory genes. In this report, we show that 3 to 6 mM butyrate, a general cell cycle blocker implicated in inhibition of the G1-to-S transition, inhibits DNA replication of polyomavirus and human papillomavirus type 11 but not the replication of larger DNA viruses such as adenovirus types 2 and 5, herpes simplex virus type 1, Epstein-Barr virus, and cytomegalovirus, which all bypass the butyrate-mediated cell cycle block. This butyrate effect on polyomavirus replication is not cell type specific, nor does it depend on the p53 or Rb gene, as inhibition was seen in fibroblasts with intact or homozygous deleted p53 or Rb, 3T6 cells, keratinocytes, C2C12 myoblasts, and 3T3-L1 adipocytes. In addition, butyrate did not inhibit expression of polyomavirus T antigen. The antiviral effect of butyrate involves a form of imprinted state, since pretreatment of cells with 3 mM butyrate inhibits human papillomavirus type 11 DNA replication for at least 96 h after its removal. Butyrate, therefore, serves as a molecular tool in dissecting the life cycle of smaller DNA viruses from that of the larger DNA viruses in relation to the cell cycle.

Neuron-specific restriction of a herpes simplex virus recombinant maps to the UL5 gene

We have previously shown that, when compared with either parent, a herpes simplex virus type 1/herpes simplex virus type 2 intertypic recombinant (R13-1) is attenuated by 10,000-fold with respect to neurovirulence in mice. Despite this, after intracranial inoculation, R13-1 replicated to titers of 10(5) PFU per brain. We present evidence that the restriction is specific for replication in neurons and have taken a three-step approach in determining the basis of the attenuation by (i) characterizing cellular tropism of the virus in both central and peripheral nervous systems, (ii) defining where in the viral replication cycle the restriction is manifest, and (iii) identifying the genetic basis of the restriction through marker rescue analysis. Following inoculation into the animal, R13-1 viral antigens predominate in nonneuronal cells, and the block to replication in neurons was found to be beyond the level of adsorption and penetration. Despite the restricted replication within neurons, the virus established a latent infection in spinal ganglia and could be reactivated by in vitro cocultivation of the ganglia. In studies carried out in cell culture, R13-1 was found to replicate normally in mouse embryo fibroblasts and primary mouse glial cells but was restricted by 1,000-fold in primary mouse neurons and PC12 cells. R13-1 appeared to produce normal levels of early RNA in these cells, but production of DNA and late RNA was less than that of the wild type. Marker rescue analysis localized the fragment responsible for restoring neurovirulence to UL5, a component of the origin-binding complex implicated in replication of the viral genome. Our results with this virus, with a cell-specific restriction, suggest that a neuron-specific component is involved in viral replication.

The UL21 gene products of herpes simplex virus 1 are dispensable for growth in cultured cells

A viral deletion mutant (delta UL21) that lacked the sequences encoding 484 of the predicted first 535 amino acids of the UL21 open reading frame was genetically engineered and studied with respect to its phenotype in cells in culture. We report the following. (i) The replication of delta UL21 was identical to that of the parent herpes simplex virus 1 (HSV-1) strain F in Vero cells, but the yields were three- to fivefold lower than those of the parent virus in human embryonic lung cells. (ii) To characterize the UL21 protein, we immunized rabbits against a purified bacterial fusion protein consisting of glutathione S-transferase fused to the majority of the coding domain of the UL21 gene. Rabbit antiserum directed against the fusion protein recognized a broad band with an apparent M(r) of 62,000 to 64,000 in lysates of cells infected with HSV-1 strain F and in virions purified from the infected cell cytoplasm. This band was absent from lysates of mock-infected cells or cells infected with the delta UL21 virus. The band was significantly reduced in intensity in lysates of cells infected in the presence of phosphonoacetic acid, indicating that it is expressed as a late (gamma 1) gene. (iii) Immunofluorescence studies localized the UL21 antigen primarily in brightly staining granules in the cytoplasms of infected cells. Taken together, the data indicate that the UL21 protein is a virion component dispensable for all aspects of replication of HSV-1 in the cells tested. The electrophoretic mobility of the UL21 protein suggests that it is extensively modified posttranslationally.

Antigenic specificities of human CD4+ T-cell clones recovered from recurrent genital herpes simplex virus type 2 lesions

Lesions resulting from recurrent genital herpes simplex virus (HSV) infection are characterized by infiltration of CD4+ lymphocytes. We have investigated the antigenic specificity of 47 HSV-specific CD4+ T-cell clones recovered from the HSV-2 buttock and thigh lesions of five patients. Clones with proliferative responses to recombinant truncated glycoprotein B (gB) or gD of HSV-2 or purified natural gC of HSV-2 comprised a minority of the total number of HSV-specific clones isolated from lesions. The gC2- and gD2-specific CD4+ clones had cytotoxic activity. The approximate locations of the HSV-2 genes encoding HSV-2 type-specific CD4+ antigens have been determined by using HSV-1 x HSV-2 intertypic recombinant virus and include the approximate map regions 0.30 to 0.46, 0.59 to 0.67, 0.67 to 0.73, and 0.82 to 1.0 units. The antigenic specificity of an HLA DQ2-restricted, HSV-2 type-specific T-cell clone was mapped to amino acids 425 to 444 of VP16 of HSV-2 by sequential use of an intertypic recombinant virus containing VP16 of HSV-2 in an HSV-1 background, recombinant VP16 fusion proteins, and synthetic peptides. Each of the remaining four patients also yielded at least one type-specific T-cell clone reactive with an HSV-2 epitope mapping to approximately 0.67 to 0.73 map units. The antigenic specificities of lesion-derived CD4+ T-cell clones are quite diverse and include at least 10 epitopes. Human T-cell clones reactive with gC and VP16 are reported here for the first time.

Characterization of equine infectious anemia virus dUTPase: growth properties of a dUTPase-deficient mutant

The putative dUTPase domain was deleted from the polymerase (pol) gene of equine infectious anemia virus (EIAV) to produce a recombinant delta DUpol Escherichia coli expression cassette and a delta DU proviral clone. Expression of the recombinant delta DUpol polyprotein yielded a properly processed and enzymatically active reverse transcriptase, as determined by immunoblot analysis and DNA polymerase activity gels. Transfection of delta DU provirus into feline (FEA) cells resulted in production of virus that replicated to wild-type levels in both FEA cells and fetal equine kidney cells. In contrast, the delta DU virus replicated poorly (less than 1% of wild-type levels) in primary equine macrophage cultures, as measured by reverse transcriptase assays. Preparations of delta DU virus contained negligible dUTPase activity, which confirms that virion-associated dUTPase is encoded in the pol gene region between the RNase H domain and integrase, as has been demonstrated previously for feline immunodeficiency virus (J. H. Elder, D. L. Lerner, C. S. Hasselkus-Light, D. J. Fontenot, E. Hunter, P. A. Luciw, R. C. Montelaro, and T. R. Phillips, J. Virol. 66:1791-1794, 1992). Our results suggest that virus-encoded dUTPase is dispensable for virus replication in dividing cells in vitro but may be required for efficient replication of EIAV in nondividing equine macrophages, the natural host cells for this virus.

Herpes simplex virus type 1 UL46 and UL47 deletion mutants lack VP11 and VP12 or VP13 and VP14, respectively, and exhibit altered viral thymidine kinase expression

The gene products of herpes simplex virus type 1 UL46 and UL47 enhance the efficiency of alpha TIF (VP16)-mediated alpha gene expression through an unknown mechanism of action. To further characterize the function of the UL46- and UL47-encoded proteins during virus infection, a series of isogenic herpes simplex virus type 1 strain F-derived UL46 and UL47 single-deletion mutants and a UL46/47 double-deletion mutant were constructed and compared with the wild type. Analysis of purified virions obtained from the UL46 deletion mutant showed for the first time that UL46 encoded the viron tegument phosphoproteins VP11 and VP12 (VP11/12). Similar analyses of the UL47 deletion mutants confirmed an earlier report by McLean et al. that UL47 also encoded two virion tegument phosphoproteins, VP13 and VP14 (VP13/14) (G. McLean, F. Rixon, N. Langeland, L. Haarr, and H. Marsden, J. Gen. Virol. 71:2953-2960, 1990). Kinetic analysis demonstrated a delay of approximately 2 h in the appearance of thymidine kinase (TK) activity in all of the UL46 and UL47 single-deletion mutants. In the UL46/47 double-deletion mutant, the delay in TK activity increased twofold, suggesting that the proteins encoded by UL46 and UL47 may act at the same level. Since the delay in TK expression occurred within the first 4 h of infection, the actions of VP11/12 and VP13/14 resulted from their virion association and not from their de novo synthesis as late (beta gamma and gamma) genes. Densitometric analysis of purified virions showed that the levels of VP11/12 and VP13/14 in the virion tegument were near the molar ratios of alpha TIF. On the basis of these observations, we predict that the abilities of UL46 and UL47 to enhance alpha TIF-mediated transcription could result from a stoichiometric association of VP11/12 and VP13/14 with alpha TIF within the infecting virion.

Herpes simplex virus type 1 dUTPase mutants are attenuated for neurovirulence, neuroinvasiveness, and reactivation from latency

Herpes simplex virus type 1 (HSV-1) encodes a dUTPase which has been shown to be dispensable for normal viral replication in cultured cells (S. J. Caradonna and Y. Cheng, J. Biol. Chem. 256:9834-9837, 1981; F. B. Fisher and V. G. Preston, Virology 148:190-197, 1986). However, the importance of this enzyme in vivo has not been determined. In this report, HSV-1 strain 17 syn+ and two isogenic engineered dUTPase-negative mutants were characterized in the mouse model. Both mutants replicated with wild-type kinetics and achieved wild-type titers in cultured cells. The mutants were 10-fold less neurovirulent than 17 syn+ following intracranial inoculation and more than 1,000-fold less virulent following footpad inoculation. The dUTPase- mutants replicated with wild-type kinetics in the footpad and entered and replicated efficiently in the peripheral nervous system of the mouse. However, their replication in the central nervous system was significantly reduced. The dUTPase- strains established latent infections but displayed a greatly reduced reactivation frequency in vivo. Neurovirulence, neuroinvasiveness, and reactivation frequency were all restored by recombination with wild-type dUTPase sequences. These results have important implications with regard to anti-herpesvirus therapeutic strategies.

The unique sequence of the herpes simplex virus 1 L component contains an additional translated open reading frame designated UL49.5

We present evidence for the existence of an additional herpes simplex virus 1 gene designated UL49.5. The sequence, located between genes UL49 and UL50, predicts a hydrophobic protein with 91 amino acids. Attempts to delete UL49.5 were not successful. To demonstrate that UL49.5 is expressed, we made two recombinant viruses. First, we inserted in frame an oligonucleotide encoding a 15-amino-acid epitope known to react with a monoclonal antibody. This gene, consisting of the authentic promoter and chimeric coding domain, was inserted into the thymidine kinase gene of wild-type virus and in infected cells expressed a protein which reacted with the monoclonal antibody. The second recombinant virus contained a 5' UL49.5-thymidine kinase fusion gene. The protein expressed by this virus confirmed that the first methionine codon of UL49.5 served as the initiating codon. The predicted amino acid sequence of UL49.5 is consistent with the known properties of NC-7, a small capsid protein whose gene has not been previously mapped. A homolog of UL49.5 is present in the genome of varicella-zoster virus, located between homologs of UL49 and UL50.

The open reading frames UL3, UL4, UL10, and UL16 are dispensable for the replication of herpes simplex virus 1 in cell culture

By means of insertion and deletion mutagenesis, we have constructed four herpes simplex virus 1 recombinants, each lacking most sequences encoding a different open reading frame. The deleted genes are located in the unique sequences of the long component and include those designated UL3, UL4, UL10, and UL16. The recombinant virus R7211 lacks 579 of the 696 bp of UL3. The recombinant virus R7217 lacks 307 of the 597 bp of the UL4 open reading frame. R7216 contains a 972-bp deletion within the 1,419-bp open reading frame of UL10, whereas R7210 lacks 988 bp of the 1,119-bp UL16 open reading frame. Growth curves indicated that the yields of these viruses in Vero and BHK cell cultures were only slightly reduced from or in some instances equivalent to that of the parent virus. The function of the gene products is not known. It is of interest to note that (i) the UL16 open reading frame maps entirely within the single intron of UL15 and (ii) on the basis of the extent and size of hydrophobic domains, the UL3 and UL10 gene products were predicted to be membrane proteins.