The herpes simplex virus type 1 U(L)17 gene encodes virion tegument proteins that are required for cleavage and packaging of viral DNA

Previous studies have suggested that the U(L)17 gene of herpes simplex virus type 1 (HSV-1) is essential for virus replication. In this study, viral mutants incorporating either a lacZ expression cassette in place of 1,490 bp of the 2,109-bp U(L)17 open reading frame [HSV-1(deltaU(L)17)] or a DNA oligomer containing an in-frame stop codon inserted 778 bp from the 5' end of the U(L)17 open reading frame [HSV-1(U(L)17-stop)] were plaque purified on engineered cell lines containing the U(L)17 gene. A virus derived from HSV-1(U(L)17-stop) but containing a restored U(L)17 gene was also constructed and was designated HSV-1(U(L)17-restored). The latter virus formed plaques and cleaved genomic viral DNA in a manner indistinguishable from wild-type virus. Neither HSV-1(deltaU(L)17) nor HSV-1(U(L)17-stop) formed plaques or produced infectious progeny when propagated on noncomplementing Vero cells. Furthermore, genomic end-specific restriction fragments were not detected in DNA purified from noncomplementing cells infected with HSV-1(deltaU(L)17) or HSV-1(U(L)17-stop), whereas end-specific fragments were readily detected when the viruses were propagated on complementing cells. Electron micrographs of thin sections of cells infected with HSV-1(deltaU(L)17) or HSV-1(U(L)17-stop) illustrated that empty capsids accumulated in the nuclei of Vero cells, whereas DNA-containing capsids accumulated in the nuclei of complementing cells and enveloped virions were found in the cytoplasm and extracellular space. Additionally, protein profiles of capsids purified from cells infected with HSV-1(deltaU(L)17) compared to wild-type virus show no detectable differences. These data indicate that the U(L)17 gene is essential for virus replication and is required for cleavage and packaging of viral DNA. To characterize the U(L)17 gene product, an anti-U(L)17 rabbit polyclonal antiserum was produced. The antiserum reacted strongly with a major protein of apparent Mr 77,000 and weakly with a protein of apparent Mr 72,000 in wild-type infected cell lysates and in virions. Bands of similar sizes were also detected in electrophoretically separated tegument fractions of virions and light particles and yielded tryptic peptides of masses characteristic of the predicted U(L)17 protein. We therefore conclude that the U(L)17 gene products are associated with the virion tegument and note that they are the first tegument-associated proteins shown to be required for cleavage and packaging of viral DNA.     

Herpes simplex virus DNA cleavage and packaging: association of multiple forms of U(L)15-encoded proteins with B capsids requires at least the U(L)6, U(L)17, and U(L)28 genes

The U(L)15 gene of herpes simplex virus (HSV) is one of several genes required for the packaging of viral DNA into intranuclear B capsids to produce C capsids that become enveloped at the inner nuclear membrane. A rabbit antiserum directed against U(L)15-encoded protein recognized three proteins with apparent Mrs of 79,000, 80,000, and 83,000 in highly purified B capsids. The 83,000-Mr protein was detected in type C capsids and comigrated with the product of a U(L)15 cDNA transcribed and translated in vitro. The 83,000- and 80,000-Mr proteins were readily detected in purified virions. Inasmuch as (i) none of these proteins were detectable in capsids purified from cells infected with HSV-1(deltaU(L)15), a virus lacking an intact U(L)15 gene, and (ii) corresponding proteins in capsids purified from cells infected with a recombinant virus [HSV-1(R7244), containing a 20-codon tag at the 3' end of U(L)15] were decreased in electrophoretic mobility relative to the wild-type proteins, we conclude that the proteins with apparent Mrs of 83,000, 80,000, and 79,000 are products of U(L)15 with identical C termini. The 79,000-, 80,000-, and 83,000-Mr proteins remained associated with B capsids in the presence of 0.5 M guanidine HCl and remained detectable in capsids treated with 2.0 M guanidine HCl and lacking proteins associated with the capsid core. These data, therefore, indicate that U(L)15-encoded proteins are integral components of B capsids. Only the 83,000-Mr protein was detected in B capsids purified from cells infected with viruses lacking the U(L)6, U(L)17, or U(L)28 genes, which are required for DNA cleavage and packaging, suggesting that capsid association of the 80,000- and 79,000-Mr proteins requires intact cleavage and packaging machinery. These data, therefore, indicate that capsid association of the 80,000- and 79,000-Mr U(L)15-encoded proteins reflects a previously unrecognized step in the DNA cleavage and packaging reaction.     

Human immunodeficiency virus type 1 Vif- mutant particles from restrictive cells: role of Vif in correct particle assembly and infectivity

Disruption of the vif gene of human immunodeficiency virus (HIV) type 1 affects virus infectivity to various degrees, depending on the T-cell line used. We have concentrated our studies on true phenotypic Vif- mutant particles produced from CEMx174 or H9 cells. In a single round of infection, Vif- virus is approximately 25 (from CEMx174 cells) to 100 (from H9 cells) times less infectious than wild-type virus produced from these cells or than the Vif- mutant produced from HeLa cells. Vif- virions recovered from restrictive cells, but not from permissive cells, are abnormal both in terms of morphology and viral protein content. Notably, they contain much reduced quantities of envelope proteins and altered quantities of Gag and Pol proteins. Although wild-type and Vif- virions from restrictive cells contain similar quantities of viral RNA, no viral DNA synthesis was detectable after acute infection of target cells with phenotypically Vif- virions. To examine the possible role of Vif in viral entry, attempts were made to rescue the Vif- defect in H9 cells by pseudotyping Vif+ and Vif- HIV particles with amphotropic murine leukemia virus envelope. Vif- particles produced in the presence of HIV envelope could not be propagated when pseudotyped. In contrast, when only the murine leukemia virus envelope was present, significant propagation of Vif- HIV particles could be detected. These results demonstrate that Vif is required for proper assembly of the viral particle and for efficient HIV Env-mediated infection of target cells.     

Herpes simplex virus type 1 alkaline nuclease is required for efficient processing of viral DNA replication intermediates

Mutations in the alkaline nuclease gene of herpes simplex type 1 (HSV-1) (nuc mutations) induce almost wild-type levels of viral DNA; however, mutant viral yields are 0.1 to 1% of wild-type yields (L. Shao, L. Rapp, and S. Weller, Virology 195:146-162, 1993; R. Martinez, L. Shao, J.C. Bronstein, P.C. Weber, and S. Weller, Virology 215:152-164, 1996). nuc mutants are defective in one or more stages of genome maturation and appear to package DNA into aberrant or defective capsids which fail to egress from the nucleus of infected cells. In this study, we used pulsed-field gel electrophoresis to test the hypothesis that the defects in nuc mutants are due to the failure of the newly replicated viral DNA to be processed properly during DNA replication and/or recombination. Replicative intermediates of HSV-1 DNA from both wild-type- and mutant-infected cells remain in the wells of pulsed-field gels, while free linear monomers are readily resolved. Digestion of this well DNA with restriction enzymes that cleave once in the viral genome releases discrete monomer DNA from wild-type virus-infected cells but not from nuc mutant-infected cells. We conclude that both wild-type and mutant DNAs exist in a complex, nonlinear form (possibly branched) during replication. The fact that discrete monomer-length DNA cannot be released from nuc DNA by a single-cutting enzyme suggests that this DNA is more branched than DNA which accumulates in cells infected with wild-type virus. The well DNA from cells infected with wild-type and nuc mutants contains XbaI fragments which result from genomic inversions, indicating that alkaline nuclease is not required for mediating recombination events within HSV DNA. Furthermore, nuc mutants are able to carry out DNA replication-mediated homologous recombination events between inverted repeats on plasmids as evaluated by using a quantitative transient recombination assay. Well DNA from both wild-type- and mutant-infected cells contains free U(L) termini but not free U(S) termini. Various models to explain the structure of replicating DNA are considered.     

The YXXL sequences of a transmembrane protein of bovine leukemia virus are required for viral entry and incorporation of viral envelope protein into virions

The cytoplasmic domain of an envelope transmembrane glycoprotein (gp30) of bovine leukemia virus (BLV) has two overlapping copies of the (YXXL)2 motif. The N-terminal motif has been implicated in in vitro signal transduction pathways from the external to the intracellular compartment and is also involved in infection and maintenance of high viral loads in sheep that have been experimentally infected with BLV. To determine the role of YXXL sequences in the replication of BLV in vitro, we changed the tyrosine or leucine residues of the N-terminal motif in an infectious molecular clone of BLV, pBLV-IF, to alanine to produce mutated proviruses designated Y487A, L490A, Y498A, L501A, and Y487/498A. Transient transfection of African green monkey kidney COS-1 cells with proviral DNAs that encoded wild-type and mutant sequences revealed that all of the mutated proviral DNAs synthesized mature envelope proteins and released virus particles into the growth medium. However, serial passages of fetal lamb kidney (FLK) cells, which are sensitive to infection with BLV, after transient transfection revealed that mutation of a second tyrosine residue in the N-terminal motif completely prevented the propagation of the virus. Similarly, Y498A and Y487/498A mutant BLV that was produced by the stably transfected COS-1 cells exhibited significantly reduced levels of cell-free virion-mediated transmission. Analysis of the protein compositions of mutant viruses demonstrated that lower levels of envelope protein were incorporated by two of the mutant virions than by wild-type and other mutant virions. Furthermore, a mutation of a second tyrosine residue decreased the specific binding of BLV particles to FLK cells and the capacity for viral penetration. Our data indicate that the YXXL sequences play critical roles in both viral entry and the incorporation of viral envelope protein into the virion during the life cycle of BLV.     

Effect of mutations in the nucleocapsid protein (NCp7) upon Pr160(gag-pol) and tRNA(Lys) incorporation into human immunodeficiency virus type 1

COS-7 cells were transfected with DNAs containing mutations in the NCp7 sequences of human immunodeficiency virus. Selective incorporation into the virus of tRNA(Lys) was measured by two-dimensional polyacrylamide gel electrophoresis, and Pr160(gag-pol) incorporation into the virus was detected in Western blots of viral protein. Mutations tested included cysteine and histidine mutations in either of the Cys-His boxes, as well as mutations in the N- and C-terminal flanking regions and in the linker region between the two Cys-His boxes. Of 10 mutations tested, only 2 inhibited tRNA(Lys) incorporation: a P31L mutation in the linker region and a deletion which removed both Cys-His boxes and the linker region (deltaK14-T50). The P31L mutation prevents the incorporation of Pr160(gag-pol) into the virus. Cotransfection of COS cells with both P31L DNA and a plasmid coding only for unprocessed Pr160(gag-pol) resulted in the viral incorporation of Pr160(gag-pol) and the rescue of selective packaging of tRNA(Lys) into the virion. In the deltaK14-T50 mutant, Pr160(gag-pol) is incorporated into the virus. Selective tRNA(Lys) packaging is not rescued by cotransfection with a plasmid coding for Pr160(gag-pol) but is rescued by cotransfection with DNA coding for wild-type Pr55(gag). Since Pr55(gag) does not by itself selectively package tRNA(Lys), the deltaK14-T50 mutation may be affecting tRNA(Lys) binding to a cytoplasmic Pr55(gag)/Pr160(gag-pol) complex.     

The product of the herpes simplex virus type 1 UL25 gene is required for encapsidation but not for cleavage of replicated viral DNA

The herpes simplex virus type 1 (HSV-1) UL25 gene contains a 580-amino-acid open reading frame that codes for an essential protein. Previous studies have shown that the UL25 gene product is a virion component (M. A. Ali et al., Virology 216:278-283, 1996) involved in virus penetration and capsid assembly (C. Addison et al., Virology 138:246-259, 1984). In this study, we describe the isolation of a UL25 mutant (KUL25NS) that was constructed by insertion of an in-frame stop codon in the UL25 open reading frame and propagated on a complementing cell line. Although the mutant was capable of synthesis of viral DNA, it did not form plaques or produce infectious virus in noncomplementing cells. Antibodies specific for the UL25 protein were used to demonstrate that KUL25NS-infected Vero cells did not express the UL25 protein. Western immunoblotting showed that the UL25 protein was associated with purified, wild-type HSV A, B, and C capsids. Transmission electron microscopy indicated that the nucleus of Vero cells infected with KUL25NS contained large numbers of both A and B capsids but no C capsids. Analysis of infected cells by sucrose gradient sedimentation analysis confirmed that the ratio of A to B capsids was elevated in KUL25NS-infected Vero cells. Following restriction enzyme digestion, specific terminal fragments were observed in DNA isolated from KUL25NS-infected Vero cells, indicating that the UL25 gene was not required for cleavage of replicated viral DNA. The latter result was confirmed by pulsed-field gel electrophoresis (PFGE), which showed the presence of genome-size viral DNA in KUL25NS-infected Vero cells. DNase I treatment prior to PFGE demonstrated that monomeric HSV DNA was not packaged in the absence of the UL25 protein. Our results indicate that the product of the UL25 gene is required for packaging but not cleavage of replicated viral DNA.     

In vitro generation and type-specific neutralization of a human papillomavirus type 16 virion pseudotype

We report a system for generating infectious papillomaviruses in vitro that facilitates the analysis of papillomavirus assembly, infectivity, and serologic relatedness. Cultured hamster BPHE-1 cells harboring autonomously replicating bovine papillomavirus type 1 (BPV1) genomes were infected with recombinant Semliki Forest viruses that express the structural proteins of BPV1. When plated on C127 cells, extracts from cells expressing L1 and L2 together induced numerous transformed foci that could be specifically prevented by BPV neutralizing antibodies, demonstrating that BPV infection was responsible for the focal transformation. Extracts from BPHE-1 cells expressing L1 or L2 separately were not infectious. Although Semliki Forest virus-expressed L1 self-assembled into virus-like particles (VLPs), viral DNA was detected in particles only when L2 was coexpressed with L1, indicating that genome encapsidation requires L2. Expression of human papillomavirus type 16 (HPV16) L1 and L2 together in BPHE-1 cells also yielded infectious virus. These pseudotyped virions were neutralized by antiserum to HPV16 VLPs derived from European (114/K) or African (Z-1194) HPV16 variants but not by antisera to BPV VLPs, to a poorly assembling mutant HPV16 L1 protein, or to VLPs of closely related genital HPV types. Extracts from BPHE-1 cells coexpressing BPV L1 and HPV16 L2 or HPV16 L1 and BPV L2 were not infectious. We conclude that (i) mouse C127 cells express the cell surface receptor for HPV16 and are able to uncoat HPV16 capsids; (ii) if a papillomavirus DNA packaging signal exists, then it is conserved between the BPV and HPV16 genomes; (iii) functional L1-L2 interaction exhibits type specificity; and (iv) protection by HPV virus-like particle vaccines is likely to be type specific.     

Abortive infection of the baculovirus Autographa californica nuclear polyhedrosis virus in Sf-9 cells after mutation of the putative DNA helicase gene

Homologous recombination between the Autographa californica nuclear polyhedrosis virus (AcNPV) genome and a 0.6-kbp-long DNA fragment derived from the putative DNA helicase gene of Bombyx mori nuclear polyhedrosis virus generates eh2-AcNPV, an expanded-host-range AcNPV mutant (S. Maeda, S.G. Kamita, and A. Kondo, J. Virol. 67:6234-6238, 1993). After inoculation at a high multiplicity of infection (MOI), eh2-AcNPV replicates efficiently in both the Sf-9 (AcNPV-permissive) and BmN (non-AcNPV-permissive) cell lines. In this study, we found that after the inoculation of Sf-9 cells at a low MOI (i.e., 1 and 0.1 PFU per cell), the release of eh2-AcNPV virions was dramatically reduced (approximately 900- and 10,000-fold, respectively, at 72 h postinoculation) compared with that of wild-type AcNPV. In addition, the titer of eh2-AcNPV determined by plaque assay on Sf-9 cells was approximately 200-fold lower than that determined by plaque assay on BmN cells. Analyses of gene expression and viral DNA replication after low-MOI eh2-AcNPV inoculation of Sf-9 cells indicated that viral early genes were expressed normally. However, DNA replication and late-gene expression were significantly reduced. These findings suggested that abortive infection occurred at the stage of viral DNA replication in nearly all low-MOI eh2-AcNPV-infected Sf-9 cells. In the larvae of Spodoptera frugiperda, the organism from which Sf-9 cells are derived, the infectivity of eh2-AcNPV was lower than that of AcNPV; however, abortive infection was not found.     

Function of human immunodeficiency virus type 1 nef gene product in virus replication

We comparatively analyzed the replication kinetics of wild-type (wt) and nef mutant human immunodeficiency virus type 1 (HIV-1) in several CD4-positive cell lines, in order to clarify the molecular function of Nef protein. The delayed growth of nef mutant virus was observed at the initial stage of replication in all cell lines examined. This phenomenon was greatly amplified in the absence of vpu gene. In order to determine the infection stage in viral replication cycle which is specifically affected on virus replication rate in the presence of the Nef protein, we first examined the difference between wt and nef mutant viruses in the virus production rate from transfected cells, and found that the both viruses were produced with equal efficiency. This result showed that Nef protein could be dispensable for virion production. Therefore, early infection stages were focused by single-round infection assay, and the nef mutant virus was found to be much less infectious than wt virus. This indicated that the effect of Nef protein was exhibited in the early phase of a virus replication cycle, during viral adsorption to integration. By entry assay using wt and nef mutant virions, it was revealed that the Nef protein was required for efficient viral entry. These data suggest that the Nef protein might play a role in efficient incorporation of the Env protein into the virions, leading to enhanced viral infectivity.     

Viruses and cells with mutations affecting viral entry are selected during persistent rotavirus infections of MA104 cells

To better understand mechanisms of persistent rotavirus infections of cultured cells, we established independent, persistently infected cultures of MA104 cells, using rotavirus strain SA11. The cultures were either passaged when the cells reached confluence or supplemented with fresh medium every 7 days. Viral titers in culture lysates varied from 10(4) to 10(7) PFU per ml during 350 days of culture maintenance. Trypan blue staining indicated that 72 to 100% of cells in the cultures were viable, and immunocytochemical staining using a monoclonal antibody directed against viral protein VP6 demonstrated that 38 to 63% of the cells contained rotavirus antigen. We tested the capacity of rotaviruses isolated from the persistently infected cultures (PI viruses) to infect cells cured of persistent infection. Although wild-type (wt) and PI viruses produced equivalent yields in parental MA104 cells, PI viruses produced greater yields than wt virus in cured cells, which indicates that viruses and cells coevolve during persistent rotavirus infections of MA104 cells. To determine whether mutations in viruses and cells selected during these persistent infections affect viral entry, we tested the effect of trypsin treatment of the viral inoculum on growth of wt and PI viruses. Trypsin pretreatment is required for postattachment penetration of rotavirus virions into cells. In contrast to the case with wt virus, PI viruses produced equivalent yields with and without trypsin pretreatment in parental MA104 cells. However, PI viruses required trypsin pretreatment for efficient growth in cured cells. These results indicate that mutant viruses and cells are selected during maintenance of persistent rotavirus infections of MA104 cells and suggest that mutations in each affect trypsin-dependent steps in rotavirus entry.     

Endoproteolytic processing of the ebola virus envelope glycoprotein: cleavage is not required for function

Proteolytic processing is required for the activation of numerous viral glycoproteins. Here we show that the envelope glycoprotein from the Zaire strain of Ebola virus (Ebo-GP) is proteolytically processed into two subunits, GP1 and GP2, that are likely covalently associated through a disulfide linkage. Murine leukemia virions pseudotyped with Ebo-GP contain almost exclusively processed glycoprotein, indicating that this is the mature form of Ebo-GP. Mutational analysis identified a dibasic motif, reminiscent of furin-like protease processing sites, as the Ebo-GP cleavage site. However, analysis of Ebo-GP processing in LoVo cells that lack the proprotein convertase furin demonstrated that furin is not required for processing of Ebo-GP. In sharp contrast to other viral systems, we found that an uncleaved mutant of Ebo-GP was able to mediate infection of various cell lines as efficiently as the wild-type, proteolytically cleaved glycoprotein, indicating that cleavage is not required for the activation of Ebo-GP despite the conservation of a dibasic cleavage site in all filoviral envelope glycoproteins.     

A herpes simplex virus DNA polymerase mutation that specifically attenuates neurovirulence in mice

Herpes simplex virus can infect the mammalian brain causing lethal encephalitis (neurovirulence). Previously, herpes simplex virus mutants that are attenuated for neurovirulence have exhibited defects in replication in brain and/or blocks to replication in neuronal cells. We investigated the attenuation of neurovirulence of mutant PAAr5, which exhibits resistance to antiviral drugs due to altered viral DNA polymerase. Following intracerebral inoculation of 7-week-old CD1 mice, PAAr5 was 30-fold attenuated for neurovirulence compared to its wild-type parent. A drug-sensitive virus derived by marker rescue with DNA polymerase gene sequences exhibited neurovirulence that was essentially indistinguishable from that of wild-type virus, demonstrating that attenuation was due to a polymerase mutation. PAAr5 replicated in brain similarly to wild-type virus unlike another polymerase mutant, 615.8, that exhibited a similar degree of attenuation. The attenuation of PAAr5 was not associated with altered particle to PFU ratios nor with any obvious reductions in viral antigen expression in neurons, spread, histopathology, or TUNEL staining suggestive of apoptotic cells. Thus PAAr5 differs from other mutants that are attenuated for neurovirulence. Understanding how a polymerase mutation specifically attenuates neurovirulence may shed light on how herpes simplex virus can cause lethal encephalitis.     

DNA repair enzyme uracil DNA glycosylase is specifically incorporated into human immunodeficiency virus type 1 viral particles through a Vpr-independent mechanism

The Vpr protein, encoded by the human immunodeficiency virus type 1 (HIV-1) genome, is one of the nonstructural proteins packaged in large amounts into viral particles. We have previously reported that Vpr associates with the DNA repair enzyme uracil DNA glycosylase (UDG). In this study, we extended these observations by investigating whether UDG is incorporated into virions and whether this incorporation requires the presence of Vpr. Our results, with highly purified viruses, show that UDG is efficiently incorporated either into wild-type virions or into Vpr-deficient HIV-1 virions, indicating that Vpr is not involved in UDG packaging. Using an in vitro protein-protein binding assay, we reveal a direct interaction between the precursor form of UDG and the viral integrase (IN). Finally, we demonstrate that IN-defective viruses fail to incorporate UDG, indicating that IN is required for packaging of UDG into virions.     

The a sequence is dispensable for isomerization of the herpes simplex virus type 1 genome

The herpes simplex virus type 1 (HSV-1) genome consists of two components, L (long) and S (short), that invert relative to each other during productive infection to generate four equimolar isomeric forms of viral DNA. Recent studies have indicated that this genome isomerization is the result of DNA replication-mediated homologous recombination between the large inverted repeat sequences that exist in the genome, rather than site-specific recombination through the terminal repeat a sequences present at the L-S junctions. However, there has never been an unequivocal demonstration of the dispensability of the latter element for this process using a recombinant virus whose genome lacks a sequences at its L-S junctions. This is because the genetic manipulations required to generate such a viral mutant are not possible using simple marker transfer, since the cleavage and encapsidation signals of the a sequence represent essential cis-acting elements which cannot be deleted outright from the viral DNA. To circumvent this problem, a simple two-step strategy was devised by which essential cis-acting sites like the a sequence can be readily deleted from their natural loci in large viral DNA genomes. This method involved initial duplication of the element at a neutral site in the viral DNA and subsequent deletion of the element from its native site. By using this approach, the a sequence at the L-S junction was rendered dispensable for virus replication through the insertion of a second copy into the thymidine kinase (TK) gene of the viral DNA; the original copies at the L-S junctions were then successfully deleted from this virus by conventional marker transfer. The final recombinant virus, HSV-1::L-S(delta)a, was found to be capable of undergoing normal levels of genome isomerization on the basis of the presence of equimolar concentrations of restriction fragments unique to each of the four isomeric forms of the viral DNA. Interestingly, only two of these genomic isomers could be packaged into virions. This restriction was the result of inversion of the L component during isomerization, which prevented two of the four isomers from having the cleavage and encapsidation signals of the a sequence in the TK gene in a packageable orientation. This phenomenon was exploited as a means of directly measuring the kinetics of HSV-1::L-S(delta)a genome isomerization. Following infection with virions containing just the two packaged genomic isomers, all four isomers were readily detected at a stage in infection coincident with the onset of DNA replication, indicating that the loss of the a sequence at the L-S junction had no adverse effect on the frequency of isomerization events in this virus. These results therefore validate the homologous recombination model of HSV-1 genome isomerization by directly demonstrating that the a sequence at the L-S junction is dispensable for this process. The strategy used to remove the a sequence from the HSV-1 genome in this work should be broadly applicable to studies of essential cis-acting elements in other large viral DNA molecules.     

Nucleocapsid protein zinc-finger mutants of simian immunodeficiency virus strain mne produce virions that are replication defective in vitro and in vivo

All retroviruses (except the spumaretroviruses) contain a nucleocapsid (NC) protein that encodes one or two copies of the Zn2+-finger sequence -Cys-X2-Cys-X4-His-X4-Cys-. This region has been shown to be essential for recognition and packaging of the genomic RNA during virion particle assembly. Additionally, this region has been shown to be involved in early infection events in a wide spectrum of retroviruses, including mammalian type C [e.g., murine leukemia virus (MuLV)], human immunodeficiency virus type 1 (HIV-1), Rous sarcoma virus, and other retroviruses. Mutations in the two Zn2+-fingers of the NC protein of simian immunodeficiency virus strain Mne [SIV(Mne)] have been generated. The resulting virions contained the normal complement of processed viral proteins with densities indistinguishable from wild-type SIV(Mne). All of the mutants had electron micrograph morphologies similar to those of immature particles observed in wild-type preparations. RNA packaging was less affected by mutations in the NC protein of SIV(Mne) than has been observed for similar mutants in the MuLV and HIV-1 systems. Nevertheless, in vitro replication of SIV(Mne) NC mutants was impaired to levels comparable to those observed for MuLV and HIV-1 NC mutants; replication defective NC mutants are typically 10(5)- to 10(6)-fold less infectious than similar levels of wild-type virus. One mutant, DeltaCys33-Cys36, was also found to be noninfectious in vivo when mutant virus was administered intravenously to a pig-tailed macaque. NC mutations can therefore be used to generate replication defective virions for candidate vaccines in the SIV macaque model for primate lentiviral diseases.     

In vivo and in vitro analysis of baculovirus ie-2 mutants

Upon transient expression in cell culture, the ie-2 gene of Autographa californica nuclear polyhedrosis virus (AcMNPV) displays three functions: trans activation of viral promoters, direct or indirect stimulation of virus origin-specific DNA replication, and arrest of the cell cycle. The ability of IE2 to trans stimulate DNA replication and coupled late gene expression is observed in a cell line derived from Spodoptera frugiperda but not in a cell line derived from Trichoplusia ni. This finding suggested that IE-2 may exert cell line-specific or host-specific effects. To examine the role of ie-2 in the context of infection and its possible influence on the host range, we constructed recombinants of AcMNPV containing deletions of different functional regions within ie-2 and characterized them in cell lines and larvae of S. frugiperda and T. ni. The ie-2 mutant viruses exhibited delays in viral DNA synthesis, late gene expression, budded virus production, and occlusion body formation in SF-21 cells but not in TN-5B1-4 cells. In TN-5B1-4 cells, the ie-2 mutants produced more budded virus and fewer occlusion bodies but the infection proceeded without delay. Examination of the effects of ie-2 and the respective mutants on immediate-early viral promoters in transient expression assays revealed striking differences in the relative levels of expression and differences in responses to ie-2 and its mutant forms in different cell lines. In T. ni and S. frugiperda larvae, the infectivities of the occluded form of ie-2 mutant viruses by the normal oral route of infection was 100- and 1,000-fold lower, respectively, than that of wild-type AcMNPV. The reduction in oral infectivity was traced to the absence of virions within the occlusion bodies. The infectivity of the budded form of ie-2 mutants by hemocoelic injection was similar to that of wild-type virus in both species. Thus, ie-2 mutants are viable but exhibit cell line-specific effects on temporal regulation of the infection process. Due to its effect on virion occlusion, mutants of IE-2 were essentially noninfectious by the normal route of infection in both species tested. However, since budded viruses exhibited normal infectivity upon hemocoelic injection, we conclude that ie-2 does not affect host range per se. The possibility that IE-2 exerts tissue-specific effects has not been ruled out.