The autonomous parvovirus MVM encodes two nonstructural proteins in addition to its capsid polypeptides

Viruses and Cajal Bodies: A Critical Cellular Target in Virus Infection?

Nuclear bodies (NBs) are dynamic structures present in eukaryotic cell nuclei. They are not bounded by membranes and are often considered biomolecular condensates, defined structurally and functionally by the localisation of core components. Nuclear architecture can be reorganised during normal cellular processes such as the cell cycle as well as in response to cellular stress. Many plant and animal viruses target their proteins to NBs, in some cases triggering their structural disruption and redistribution. Although not all such interactions have been well characterised, subversion of NBs and their functions may form a key part of the life cycle of eukaryotic viruses that require the nucleus for their replication. This review will focus on Cajal bodies (CBs) and the viruses that target them. Since CBs are dynamic structures, other NBs (principally nucleoli and promyelocytic leukaemia, PML and bodies), whose components interact with CBs, will also be considered. As well as providing important insights into key virus-host cell interactions, studies on Cajal and associated NBs may identify novel cellular targets for development of antiviral compounds.

Protein Myristoylation Plays a Role in the Nuclear Entry of the Parvovirus Minute Virus of Mice

Being nonpathogenic to humans, rodent parvoviruses (PVs) are naturally oncolytic viruses with great potential as anti-cancer agents. As these viruses replicate in the host cell nucleus, they must gain access to the nucleus during infection. The PV minute virus of mice (MVM) and several other PVs transiently disrupt the nuclear envelope (NE) and enter the nucleus through the resulting breaks. However, the molecular basis of this unique nuclear entry pathway remains uncharacterized. In this study, we used MVM as a model to investigate the molecular mechanism by which PVs induce NE disruption during viral nuclear entry. By combining bioinformatics analyses, metabolic labeling assays, mutagenesis, and pharmacological inhibition, we identified a functional myristoylation site at the sequence ⁷⁸GGKVGH⁸³ of the unique portion of the capsid protein VP1 (VP1u) of MVM. Performing proteolytic cleavage studies with a peptide containing this myristoylation site or with purified virions, we found tryptophan at position 77 of MVM VP1u is susceptible to chymotrypsin cleavage, implying this cleavage exposes G (glycine) 78 at the N-terminus of VP1u for myristoylation. Subsequent experiments using inhibitors of myristoylation and cellular proteases with MVM-infected cells, or an imaging-based quantitative NE permeabilization assay, further indicate protein myristoylation and a chymotrypsin-like activity are essential for MVM to locally disrupt the NE during viral nuclear entry. We thus propose a model for the nuclear entry of MVM in which NE disruption is mediated by VP1u myristoylation after the intact capsid undergoes proteolytic processing to expose the required N-terminal G for myristoylation. IMPORTANCE Rodent parvoviruses (PVs), including minute virus of mice (MVM), have the ability to infect and kill cancer cells and thereby possess great potential in anti-cancer therapy. In fact, some of these viruses are currently being investigated in both preclinical studies and clinical trials to treat a wide variety of cancers. However, the detailed mechanism of how PVs enter the cell nucleus remains unknown. In this study, we for the first time demonstrated a chemical modification called "myristoylation" of a MVM protein plays an essential role in the nuclear entry of the virus. We also showed, in addition to protein myristoylation, a chymotrypsin-like activity, which may come from cellular proteasomes, is required for MVM to get myristoylated and enter the nucleus. These findings deepen our understanding on how MVM and other related PVs infect host cells and provide new insights for the development of PV-based anti-cancer therapies.

Parvovirus nonstructural protein 2 interacts with chromatin-regulating cellular proteins

Autonomous parvoviruses encode at least two nonstructural proteins, NS1 and NS2. While NS1 is linked to important nuclear processes required for viral replication, much less is known about the role of NS2. Specifically, the function of canine parvovirus (CPV) NS2 has remained undefined. Here we have used proximity-dependent biotin identification (BioID) to screen for nuclear proteins that associate with CPV NS2. Many of these associations were seen both in noninfected and infected cells, however, the major type of interacting proteins shifted from nuclear envelope proteins to chromatin-associated proteins in infected cells. BioID interactions revealed a potential role for NS2 in DNA remodeling and damage response. Studies of mutant viral genomes with truncated forms of the NS2 protein suggested a change in host chromatin accessibility. Moreover, further studies with NS2 mutants indicated that NS2 performs functions that affect the quantity and distribution of proteins linked to DNA damage response. Notably, mutation in the splice donor site of the NS2 led to a preferred formation of small viral replication center foci instead of the large coalescent centers seen in wild-type infection. Collectively, our results provide insights into potential roles of CPV NS2 in controlling chromatin remodeling and DNA damage response during parvoviral replication.

Parvoviruses are small, nonenveloped DNA viruses, that besides being noteworthy pathogens in many animal species, including humans, are also being developed as vectors for gene and cancer therapy. Canine parvovirus is an autonomously replicating parvovirus that encodes two nonstructural proteins, NS1 and NS2. NS1 is required for viral DNA replication and packaging, as well as gene expression. However, very little is known about the function of NS2. Our studies indicate that NS2 serves a previously undefined important function in chromatin modification and DNA damage responses. Therefore, it appears that although both NS1 and NS2 are needed for a productive infection they play very different roles in the process.

Establishment of a rescue system for porcine parvovirus using a seamless cloning method

In this study, we describe a novel and rapid method for the construction of a full-length infectious clone (pPPV). The constructed clone contained an engineered EcoRv site that served as a genetic marker and was shown to be infectious when transfected into a monolayer of PK-15 cells. The rescued virus (rPPV) of the infectious clone was found to be indistinguishable from wild-type virus BQ in terms of its biological properties. The generation of this PPV infectious clone provides a potentially powerful tool with which to elucidate the molecular pathogenesis of PPV.

Minute Virus of Canines NP1 Protein Governs the Expression of a Subset of Essential Nonstructural Proteins via Its Role in RNA Processing

Parvoviruses use a variety of means to control the expression of their compact genomes. The bocaparvovirus minute virus of canines (MVC) encodes a small, genus-specific protein, NP1, which governs access to the viral capsid gene via its role in alternative polyadenylation and alternative splicing of the single MVC pre-mRNA. In addition to NP1, MVC encodes five additional nonstructural proteins (NS) that share an initiation codon at the left end of the genome and which are individually encoded by alternative multiply spliced mRNAs. We found that three of these proteins were encoded by mRNAs that excise the NP1-regulated MVC intron immediately upstream of the internal polyadenylation site, (pA)p, and that generation of these proteins was thus regulated by NP1. Splicing of their progenitor mRNAs joined the amino termini of these proteins to the NP1 open reading frame, and splice site mutations that prevented their expression inhibited virus replication in a host cell-dependent manner. Thus, in addition to controlling capsid gene access, NP1 also controls the expression of three of the five identified NS proteins via its role in governing MVC pre-mRNA splicing.IMPORTANCE The Parvovirinae are small nonenveloped icosahedral viruses that are important pathogens in many animal species, including humans. Minute virus of canine (MVC) is an autonomous parvovirus in the genus Bocaparvovirus It has a single promoter that generates a single pre-mRNA. NP1, a small genus-specific MVC protein, participates in the processing of this pre-mRNA and so controls capsid gene access via its role in alternative internal polyadenylation and splicing. We show that NP1 also controls the expression of three of the five identified NS proteins via its role in governing MVC pre-mRNA splicing. These NS proteins together are required for virus replication in a host cell-dependent manner.

The MVMp P4 promoter is a host cell-type range determinant in vivo

The protoparvovirus early promoters, e.g. P4 of Minute Virus of Mice (MVM), play a critical role during infection. Initial P4 activity depends on the host transcription machinery only. Since this is cell-type dependent, it is hypothesized that P4 is a host cell-type range determinant. Yet host range determinants have mapped mostly to capsid, never P4. Here we test the hypothesis using the mouse embryo as a model system. Disruption of the CRE element of P4 drastically decreased infection levels without altering range. However, when we swapped promoter elements of MVM P4 with those from equivalent regions of the closely related H1 virus, we observed elimination of infection in fibroblasts and chondrocytes and the acquisition of infection in skeletal muscle. We conclude that P4 is a host range determinant and a target for modifying the productive infection potential of the virus - an important consideration in adapting these viruses for oncotherapy.

Molecular characterization of the small nonstructural proteins of parvovirus Aleutian mink disease virus (AMDV) during infection

Aleutian mink disease virus (AMDV) is the only member in genus Amdovirus of the family Parvoviridae. During AMDV infection, six species of viral transcripts are generated from one precursor mRNA through alternative splicing and alternative polyadenylation. In addition to the large non-structural protein NS1, two small non-structural proteins, NS2 and NS3, are putatively encoded (Qiu J, et al., 2006. J. Virol. 80 654-662). However, these two proteins have not been experimentally demonstrated during virus infection, and nothing is known about their function. Here, we studied the nonstructural protein expression profile of AMDV, and for the first time, confirmed expression of NS2 and NS3 during infection, and identified their intracellular localization. More importantly, we provided evidence that both NS2 and NS3 are necessary for AMDV replication.

Chipmunk parvovirus is distinct from members in the genus Erythrovirus of the family Parvoviridae

The transcription profile of chipmunk parvovirus (ChpPV), a tentative member of the genus Erythrovirus in the subfamily Parvovirinae of the family Parvoviridae, was characterized by transfecting a nearly full-length genome. We found that it is unique from the profiles of human parvovirus B19 and simian parvovirus, the members in the genus Erythrovirus so far characterized, in that the small RNA transcripts were not processed for encoding small non-structural proteins. However, like the large non-structural protein NS1 of the human parvovirus B19, the ChpPV NS1 is a potent inducer of apoptosis. Further phylogenetic analysis of ChpPV with other parvoviruses in the subfamily Parvovirinae indicates that ChpPV is distinct from the members in genus Erythrovirus. Thus, we conclude that ChpPV may represent a new genus in the family Parvoviridae.

Activation of an antiviral response in normal but not transformed mouse cells: a new determinant of minute virus of mice oncotropism

Parvovirus minute virus of mice (MVMp) is endowed with oncotropic properties so far ascribed only to the dependency of the virus life cycle on cellular factors expressed during S phase and/or modulated by malignant transformation. For other viruses oncotropism relies on their inability to circumvent type I interferon (IFN)-induced innate antiviral mechanisms, the first line of defense triggered by normal cells against viral infections. These agents propagate, therefore, preferentially in transformed/tumor cells, which often lack functional antiviral mechanisms. The present study aimed at investigating whether antiviral processes also contribute to MVMp oncotropism. Our results demonstrate that in contrast to MVMp-permissive transformed mouse A9 fibroblasts, freshly isolated normal counterparts (mouse embryonic fibroblasts [MEFs]) mount, through production and release of type I IFNs upon their infection, an antiviral response against MVMp lytic multiplication. Pretreatment of MEFs with a type I IFN-beta-neutralizing antibody, prior to MVMp infection, inhibits the virus-triggered antiviral response and improves the fulfillment of the MVMp life cycle. Our results also show that part of the A9 permissiveness to MVMp relies on the inability to produce type I IFNs upon parvovirus infection, a feature related either to an A9 intrinsic deficiency of this process or to an MVMp-triggered inhibitory mechanism, since stimulation of these cells by exogenous IFN-beta strongly inhibits the parvovirus life cycle. Taken together, our results demonstrate for the first time that parvovirus infection triggers an innate antiviral response in normal cells and suggest that the MVMp oncotropism depends at least in part on the failure of infected transformed cells to mount such a response.

Molecular characterization of infectious clones of the minute virus of canines reveals unique features of bocaviruses

Minute virus of canines (MVC) is a member of the genus Bocavirus in the family Parvoviridae. We have molecularly cloned and sequenced the 5'- and 3'-terminal palindromes of MVC. The MVC genome, 5,404 nucleotides (nt) in length, shared an identity of 52.6% and 52.1% with that of human bocavirus and bovine parvovirus, respectively. It had distinct palindromic hairpins of 183 nt and 198 nt at the left-end and right-end termini of the genome, respectively. The left-end terminus was also found in two alternative orientations (flip or flop). Both termini shared extensive similarities with those of bovine parvovirus. Four full-length molecular clones constructed with different orientations of the left-end terminus proved to be infectious in Walter Reed canine cell/3873D (WRD) canine cells. Both MVC infection and transfection of the infectious clone in WRD cells revealed an identical RNA transcription profile that was similar to that of bovine parvovirus. Mutagenesis of the infectious clone demonstrated that the middle open reading frame encodes the NP1 protein. This protein, unique to the genus Bocavirus, was essential for MVC DNA replication. Moreover, the phospholipase A2 motif in the VP1 unique region was also critical for MVC infection. Thus, our studies revealed important information about the genus Bocavirus that may eventually help us to clone the human bocavirus and study its pathogenesis.

Hypoxic-response elements in the oncolytic parvovirus Minute virus of mice do not allow for increased vector production at low oxygen concentration

Vectors derived from the autonomous parvovirus Minute virus of mice, MVM(p), are promising tools for the gene therapy of cancer. The validation of their in vivo anti-tumour effect is, however, hampered by the difficulty to produce high-titre stocks. In an attempt to increase vector titres, host cells were subjected to low oxygen tension (hypoxia). It has been shown that a number of viruses are produced at higher titres under these conditions. This is the case, among others, for another member of the family Parvoviridae, the erythrovirus B19 virus. Hypoxia stabilizes a hypoxia-inducible transcription factor (HIF-1alpha) that interacts with a 'hypoxia-responsive element' (HRE), the consensus sequence of which ((A)/(G)CGTG) is present in the B19 and MVM promoters. Whilst the native P4 promoter was induced weakly in hypoxia, vector production was reduced dramatically, and adding HRE elements to the P4 promoter of the vector did not alleviate this reduction. Hypoxia has many effects on cell metabolism. Therefore, even if the P4 promoter is activated, the cellular factors that are required for the completion of the parvoviral life cycle may not be expressed.

Increased levels of B1 and B2 SINE transcripts in mouse fibroblast cells due to minute virus of mice infection

Minute virus of mice (MVM), an autonomous parvovirus, has served as a model for understanding parvovirus infection including host cell response to infection. In this paper, we report the effect of MVM infection on host cell gene expression in mouse fibroblast cells (LA9 cells), analyzed by differential display. Somewhat surprisingly, our data reveal that few cellular protein-coding genes appear to be up- or downregulated and identify the murine B1 and B2 short interspersed element (SINE) transcripts as being increased upon MVM infection. Primer extension assays confirm the effect of MVM infection on SINE expression and demonstrate that both SINEs are upregulated in a roughly linear fashion throughout MVM infection. They also demonstrate that the SINE response was due to RNA polymerase III transcription and not contaminating DNA or RNA polymerase II transcription. Furthermore, expression of MVM NS1, the major nonstructural protein, by transient transfection also leads to an increase in both murine SINEs. We believe this is the first time that the B1 and B2 SINEs have been shown to be altered by viral infection and the first time parvovirus infection has been shown to increase SINE expression. The increase in SINE transcripts caused by MVM infection does not appear to be due to an increase in either of the basal transcription factors TFIIIC110 or 220, in contrast to that which has been shown for other viruses.

Interaction between parvovirus NS2 protein and nuclear export factor Crm1 is important for viral egress from the nucleus of murine cells

A mutation that disrupts the interaction between the NS2 protein of minute virus of mice and the nuclear export factor Crm1 results in a block to egress of mutant-generated full virions from the nucleus of infected murine cells. These mutants produce wild-type levels of monomer and dimer replicative DNA forms but are impaired in their ability to generate progeny single-stranded DNA in restrictive murine cells in the first round of infection. The NS2-Crm1 interaction mutant can be distinguished phenotypically from an NS2-null mutant and reveals a role for the Crm1-mediated export pathway at a late step in viral infection.

Divergent replication kinetics of two phenotypically different parvoviruses of rats

Rat virus (RV) is an important infectious agent of laboratory rats because of its high prevalence and capacity to disrupt research. Additionally, RV infection serves as a model for characterizing virus-host interactions during acute, persistent and prenatal infection. Our research has examined the pathogenesis of two RV strains, RV-UMass and RV-Y. RV-UMass is more pathogenic, causes a higher level of persistent infection and transmits to the foetus after oronasal inoculation of the pregnant dam. To determine in vitro distinctions between the strains that may account for these differences and to provide a benchmark for characterizing virus replication in vivo, synchronized in vitro replication of both RV strains was defined and compared. The results demonstrated that RV replication has replicative intermediates, virus transcripts and proteins similar to those reported for the prototype parvovirus, minute virus of mice. However, the replicative cycle of RV-UMass was 12 h compared with 24 h for RV-Y, and RV-UMass and RV-Y differed in kinetics of virus DNA replication, transcription and protein accumulation. Additionally, in situ analysis correlated well with kinetics data as determined by Southern and Northern blot analysis. Sequence comparisons between the strains also determined coding differences that may contribute to phenotypic differences.

Nonstructural protein-2 and the replication of canine parvovirus

The nonstructural protein-2 (NS2) of canine parvovirus (CPV) is produced from the left-hand open reading frame of the viral genome and contains 87 amino-terminal amino acids in common with nonstructural protein 1 (NS1) joined to 78 amino acids from an alternative open reading frame. In the minute virus of mice parvovirus NS2 plays a role in controlling capsid protein assembly and translation in a host-specific manner. The predicted NS2 of CPV is divergent from the proteins of the rodent parvoviruses, and the protein and its functions have not been described. We characterized the large and the small splices of CPV using reverse transcriptase-PCR, NS2 was identified using anti-peptide antibodies against the predicted C-terminal sequence and also by expressing the protein from a plasmid vector. The protein could be detected at low levels in the nucleus and the cytoplasm of a proportion of CPV-infected cells, as well as in cells transfected with the expression plasmid. Virus genomes were prepared with mutations in the splice donor or acceptor sites of the NS2-specific intron or with three different termination codons in the NS2-unique exon. Both splice donor and acceptor mutations resulted in the use of previously cryptic splice sites, and the virus containing the splice donor mutation replicated inefficiently. However, the other four mutant viruses were all viable and replicated efficiently in cat and dog cells, and two mutant viruses that were tested appeared to assemble their capsids in the same manner as did the wildtype. After inoculation of dogs an NS2 mutant virus with a termination codon in the NS2-unique exon replicated to titers similar to those seen for wildtype CPV in several tissues examined.

Inhibition of parvovirus minute virus of mice replication by a peptide involved in the oligomerization of nonstructural protein NS1

The large nonstructural protein NS1 of the minute virus of mice and other parvoviruses is involved in essential steps of the viral life cycle, such as DNA replication and transcriptional regulation, and is a major contributor to the toxic effect on host cells. Various biochemical functions, such as ATP binding, ATPase, site-specific DNA binding and nicking, and helicase activities, have been assigned to NS1. Homo-oligomerization is a prerequisite for a number of proteins to be fully functional. In particular, helicases generally act as homo-oligomers. Indirect evidence of NS1 self-association has been recently obtained by a nuclear cotransport assay (J. P. Nüesch and P. Tattersall, Virology 196:637-651, 1993). In order to demonstrate the oligomerizing property of NS1 in a direct way and localize the protein region(s) involved, the yeast two-hybrid system was used in combination with deletion mutagenesis across the whole NS1 molecule, followed by high-resolution mapping of the homo-oligomerization domain by a peptide enzyme-linked immunosorbent assay method. This study led to the identification of a distinct NS1 peptide that contains a bipartite domain involved in NS1 oligomerization. Furthermore, this isolated peptide was found to act as a specific competitive inhibitor and suppress NS1 helicase activity in vitro and parvovirus DNA replication in vivo, arguing for the involvement of NS1 oligomerization in these processes. Our results point to drug targeting of oligomerization motifs of viral regulatory proteins as a potentially useful antiviral strategy.

Minute virus of mice infection modifies cellular transcription elongation

Our previous observations indicated that upon infection with minute virus of mice (MVM), Ehrlich ascites cells lose a transcription elongation activity which is essential for the readthrough of the MVM attenuator. This was monitored by the ability of extracts from uninfected but not from infected cells to support readthrough of the P4 attenuator when added to partially purified transcription elongation complexes. We have investigated the nature of this change in transcription elongation following MVM infection. In this communication, we show that infection of Ehrlich ascites cells with MVM leads to a general shift in the length of nascent mRNA synthesized in isolated nuclei and separated by sucrose gradients. Furthermore, infection leads to attenuation of transcription of the cellular gene c-fos but not c-myc. We show biochemical evidence to support a model by which, following MVM infection, there is a functional reduction in the activity of a TFIIS-like general transcriptional elongation activity.

A cellular repressor regulates transcription initiation from the minute virus of mice P38 promoter

We previously reported that the P38 promoter of minute virus of mice (MVM) is trans activated by the viral nonstructural protein, NS1, through an interaction with a downstream promoter element designated DPE. In this communication we report the identification of a distinct downstream promoter element which inhibits transcription from the P38 promoter in vitro, in the absence of the DPE. Removal of 34 bp from the region between +95 and +129 downstream from the P38 initiation start site relieved inhibition of transcription in whole-cell extract. Inhibition was also relieved by the addition, to the transcription reaction, of excess DNA fragments which span the putative inhibiting element. This indicated the involvement of a trans-acting factor, in inhibition of transcription from the P38. Gel retardation experiments demonstrated the specific binding of a cellular protein to the inhibitory element. This P38 inhibitory element shows spacing and orientation dependence as well as promoter specificity. The regulation of viral transcription by a cellular repressor may play an important role in obtaining a fine temporal order of viral gene expression during the course of infection.

Characterization of chimeric full-length molecular clones of Aleutian mink disease parvovirus (ADV): identification of a determinant governing replication of ADV in cell culture

The ADV-G strain of Aleutian mink disease parvovirus (ADV) is nonpathogenic for mink but replicates permissively in cell culture, whereas the ADV-Utah 1 strain is highly pathogenic for mink but replicates poorly in cell culture. In order to relate these phenotypic differences to primary genomic features, we constructed a series of chimeric plasmids between a full-length replication-competent molecular clone of ADV-G and subgenomic clones of ADV-Utah 1 representing map units (MU) 15 to 88. After transfection of the plasmids into cell culture and serial passage of cell lysates, we determined that substitution of several segments of the ADV-Utah 1 genome (MU 15 to 54 and 65 to 73) within an infectious ADV-G plasmid did not impair the ability of these constructs to yield infectious virus in vitro. Like ADV-G, the viruses derived from these replication-competent clones caused neither detectable viremia 10 days after inoculation nor any evidence of Aleutian disease in adult mink. On the other hand, other chimeric plasmids were incapable of yielding infectious virus and were therefore replication defective in vitro. The MU 54 to 65 EcoRI-EcoRV fragment of ADV-Utah 1 was the minimal segment capable of rendering ADV-G replication defective. Substitution of the ADV-G EcoRI-EcoRV fragment into a replication-defective clone restored replication competence, indicating that this 0.53-kb portion of the genome, wholly located within shared coding sequences for the capsid proteins VP1 and VP2, contained a determinant that governs replication in cell culture. When cultures of cells were studied 5 days after transfection with replication-defective clones, rescue of dimeric replicative form DNA and single-stranded progeny DNA could not be demonstrated. This defect could not be complemented by cotransfection with a replication-competent construction.

Protein species of the parvovirus minute virus of mice strain MVMp: involvement of phosphorylated VP-2 subtypes in viral morphogenesis

The pattern of induced protein species of the prototype strain of the parvovirus minute virus of mice was determined in permissive A9 mouse fibroblast cells by high-resolution two-dimensional gel electrophoresis. Identities of the viral proteins in the gels were assigned by probing two-dimensional blots with antisera raised against either purified capsids (recognizing VP-1 and VP-2) or specific coding regions of the nonstructural proteins (NS-1 and NS-2) expressed as beta-galactosidase fusion products in bacteria. All viral proteins showed posttranslational modifications, phosphate being a common substituent. The NS-1 protein migrated as a basic polypeptide in the pI range of 7.4 to 7.8 with multiple stages of modification and as a likely minor but hyperphosphorylated component in the neutral region of the gel. The NS-2 isoforms were resolved at a pI value close to 5.5 as three groups of unevenly phosphorylated polypeptides, each composed of at least two protein species. Both VP-1 and VP-2 structural polypeptides were induced as heterogeneous phosphoproteins. The major VP-2 protein could be resolved in the form of a consistent pattern of three abundant (a to c), two intermediate (d and e), and one meager (f) neutral isoelectric focusing species or subtypes. This posttranslational modification precedes and is uncoupled from viral assembly, and all of the VP-2 subtypes are packaged into empty capsids at the induced stoichiometry. However, intracellular full virions harbored additional phosphorylated subtypes (g to l) and a subtle rearrangement in the whole VP-2 composition, while mature virions purified from lysed cultures lacked these subtypes, coordinately with the emergence of six neutral VP-3 subtypes. Thus, the virion coat undergoes a chemical transition entailed by genome encapsidation, in which phosphates seem to play a major role, triggering the preferential proteolytic cleavage of the more acidic VP-2 subtypes to VP-3. Parvoviruses, with small coding capacity, may regulate some morphogenetic steps, such as assembly, genome encapsidation, and maturation, by posttranslational modifications of their structural proteins.

NS2 is required for efficient translation of viral mRNA in minute virus of mice-infected murine cells

Detailed analysis of five NS2 mutants of the autonomous parvovirus minute virus of mice (MVMp) has revealed the following. At low multiplicities of infection, NS2 mutants killed NB324K cells as well as wild-type (wt) MVM did and grew to high titers, while in contrast they grew poorly and did not readily kill murine A9 cells. Following CaPO4 transfection of murine fibroblasts, NS2 mutant infectious clones generated approximately 10-fold less monomer replicative-form DNA than wt and no detectable progeny single-stranded DNA. On nonmurine semipermissive NB324K cells, however, these mutant plasmid clones generated near wt levels of all replicative DNA forms. After infection of highly synchronized murine fibroblasts by NS2 mutant virus at inputs equivalent to those of the wt, mutant monomer replicative-form DNA was decreased 5- to 10-fold compared with that of the wt, and progeny single-stranded DNA accumulation was decreased to an even greater extent. Both total and cytoplasmic NS2 mutant RNA was decreased, but the amount of total viral mRNA generated, relative to accumulated viral DNA in the same experiments, was similar to that seen in wt infection. The accumulation of virus-generated proteins was also decreased in NS2 mutant infection; however, the magnitude of this decrease, compared with that of wt infections, was significantly greater than the concomitant decrease in mutant-generated levels of accumulated cytoplasmic RNA, and this effect was most dramatic for VP2. There was no such disparity between the relative accumulation of mutant-generated RNA and protein in cells permissive for the growth of these mutants. These results suggest that translation of MVM viral RNA is specifically reduced in NS2 mutant infection of restrictive cells. Because the affected viral proteins are required for the efficient production of viral replicative DNA forms, these results reveal a fundamental, although perhaps not the only, role for NS2 in parvovirus infection.

Expression of functional parvoviral NS1 from recombinant vaccinia virus: effects of mutations in the nucleotide-binding motif

The gene encoding the major replicative protein, NS1, of minute virus of mice (MVM) was transferred into a recombinant vaccinia virus vector in place of the vaccinia thymidine kinase gene. The NS1 gene was placed under control of a bacteriophage T7 promoter and expressed in cells coinfected with another recombinant vaccinia virus, vTF7-3, which encodes the T7 RNA polymerase. Expression of NS1 was further enhanced by the presence of a 5' untranslated region, derived from encephalomyocarditis virus, which allows efficient cap-independent translation. This system was used to produce and analyze wild-type NS1 and two mutant forms of the protein, NS1K405R and NS1K405M, in which the highly conserved lysine codon located in the putative purine triphosphate binding site of NS1 was changed to arginine and methionine, respectively. Full-length NS1 was expressed efficiently in both human and mouse cells infected with each of the three recombinant viruses, and in each case the NS1 was rapidly and efficiently translocated into the nucleus. Wild-type NS1 expressed in this way was biologically active. It was able to trans-activate an MVM P38 promoter located in a host chromosomal site, whereas the two mutant forms of NS1 showed no significant activity in this assay, and it was capable of resolving palindromic junction fragments cloned from multimeric MVM replicative form DNA molecules. These substrates, representing MVM genomic left-end:left-end and right-end:right-end fusions, were resolved in a DNA synthesis-dependent in vitro reaction supplemented with nuclear extracts containing recombinant wild-type NS1. Neither of the two mutant forms of the polypeptide had any detectable activity in this assay.

Terminal regions of the NS-1 protein of the parvovirus minute virus of mice are involved in cytotoxicity and promoter trans inhibition

The nonstructural (NS) transcription unit of minute virus of mice (MVMp) encodes proteins that are involved in viral DNA replication and in the regulation of homologous and heterologous promoters. Moreover, it has been shown that NS-protein accumulation is toxic for transformed cells. With the aim of identifying the NS-protein function(s) responsible for cytotoxicity, point mutations and deletions were introduced in the NS-protein-coding sequence of MVMp. This strategy indicated that in transformed human NBE cells, the NS-1 protein is indispensable for MVMp DNA replication, trans activation of the late parvoviral promoter P38, trans inhibition of the long terminal repeat promoter of the Rous sarcoma virus, and cytotoxicity. Moreover, some mutations led to the dissociation of the replicative and regulatory functions of the NS-1 protein and showed that cytotoxicity correlated with the latter, more particularly with the capacity to trans inhibit the heterologous promoter. The NS-1 sequences required for cytotoxicity were found to be restricted to the amino- and carboxy-terminal portions of the protein. Although the cytotoxicities of NS-1 extremities were weak when the extremities were tested separately, the cytotoxicities were comparable to that of the full protein when the extremities were fused. Interestingly, an overall negative charge can be predicted from the NS-1 sequence over about 100 amino acids at both ends. The conservation of this charge distribution among the NS proteins of different parvoviruses suggests that NS-1 may bear some similarities to acidic transcriptional activators.

The pathogenesis of infection with minute virus of mice depends on expression of the small nonstructural protein NS2 and on the genotype of the allotropic determinants VP1 and VP2

Neonatal C3H/He mice were oronasally inoculated with similar doses of four genotypes of minute virus of mice (MVM). MVMp, a fibroblast-specific variant, caused an asymptomatic infection. MVM(1035), a chimera which had the allotropic determinant of virulent MVMi inserted onto an MVMp background, caused a lethal infection and renal papillary infarcts, the hallmark of MVMi infection. MVMi(NS2-1990), the virulent lymphocyte-specific variant mutated to eliminate NS2 synthesis, was infectious but caused an asymptomatic infection. Sequential virus titration, histology, in situ hybridization with a full-length MVMi genomic probe, and immunohistochemistry for viral capsid antigen were used to compare the pathogenesis of infection with the four MVM genotypes. Infectious virus was recovered from multiple organs of mice infected with MVMi, MVMp, and MVM(1035) but not from mice infected with MVMi(NS2-1990). MVMp titers were lower than MVMi titers in all organs except the intestine. MVM(1035) titers were higher than MVMi titers in all organs except the blood. MVMp was localized to connective tissue elements of the intestine, to cells in mesenteric lymph nodes, and rarely to cells in other organs. MVM(1035) was localized to multiple organs and shared the same target cells, endothelium, lymphoid cells, and hematopoietic cells, as MVMi. MVM(1035) also replicated in external germinal cells of the cerebellum and smooth muscle cells of the stomach and colon, which were not targets of MVMi or MVMp infection. MVMi(NS2-1990) replicated to a limited degree in some MVMi target organs.

Characterization of linker insertion and point mutations in the NS-1 gene of minute virus of mice: effects on DNA replication and transcriptional activation functions of NS-1

The NS-1 gene of minute virus of mice encodes a multifunctional protein required for replication of the viral genome and for transcriptional regulation of the two MVM promoters. To study the localization of activities required for DNA replication and transactivation of the capsid gene promoter, insertion and point mutations were introduced into the NS-1 gene. The mutant NS-1 genes were expressed in COS-7 cells by using an SV 40 promoter driven NS-1 expression vector. The ability of the mutant proteins to complement a replication defective NS-1 mutant of the infectious MVM plasmid pMM984 and to activate transcription from the capsid gene promoter in chloramphenicol acetyl transferase expression assays was determined. Two point mutations Ser-249 to Ala and Lys-250 to Gln and a one amino acid insertion between Asp-606 and Leu-607 had no effect on viral DNA replication and transactivation activities. Six independent insertions of between 2 and 12 amino acids inhibited the DNA replication activity of NS-1 between 20- and at least 100-fold. There was no apparent correlation between the extent of inhibition of parvoviral DNA replication and the location of the mutations. The transcriptional activation function of NS-1 was inhibited between 1.5- and at least 20-fold and was therefore overall relatively less sensitive to mutagenesis than was its DNA replication function. An exception to this was a 5 amino acid insertion between Tyr-543 and Gln-544 that abolished transactivation as well as the ability of NS-1 to complement viral DNA replication.

The block to transcription elongation at the minute virus of mice attenuator is regulated by cellular elongation factors

We have previously reported that both in vivo and in vitro, RNA polymerase II pauses or prematurely terminates transcription at a specific attenuation site located 142 to 147 nucleotides downstream from the P4 promoter of minute virus of mice (MVM). In this report, we show that an in vitro block to transcription elongation in HeLa whole-cell extract occurs at elevated KCl concentrations (0.2 to 1.5 M) but not at the standard KCl concentration (50 mM). Briefly initiated transcription complexes, devoid of dissociated elongation factors by passage through a Sephacryl S-1000 column at 0.3 M KCl, were allowed to elongate the briefly initiated nascent RNA, and a block to transcription elongation at the attenuation site was observed independently of the KCl concentration at the time of elongation. Moreover, the block to elongation was overcome by the addition, during elongation, to the column of purified complexes of whole-cell extract from EA cells but not from MVM-infected EA cells or HeLa cells. The general transcription factors IIF and IIX were also shown to alleviate this block to transcription elongation. On the basis of these results, we suggest that the block to elongation at the MVM attenuation site observed late in MVM infection results, at least in part, from the inactivation of the general transcription elongation factors.

The block to transcription elongation at the minute virus of mice attenuator is regulated by cellular elongation factors

We have previously reported that both in vivo and in vitro, RNA polymerase II pauses or prematurely terminates transcription at a specific attenuation site located 142 to 147 nucleotides downstream from the P4 promoter of minute virus of mice (MVM). In this report, we show that an in vitro block to transcription elongation in HeLa whole-cell extract occurs at elevated KCl concentrations (0.2 to 1.5 M) but not at the standard KCl concentration (50 mM). Briefly initiated transcription complexes, devoid of dissociated elongation factors by passage through a Sephacryl S-1000 column at 0.3 M KCl, were allowed to elongate the briefly initiated nascent RNA, and a block to transcription elongation at the attenuation site was observed independently of the KCl concentration at the time of elongation. Moreover, the block to elongation was overcome by the addition, during elongation, to the column of purified complexes of whole-cell extract from EA cells but not from MVM-infected EA cells or HeLa cells. The general transcription factors IIF and IIX were also shown to alleviate this block to transcription elongation. On the basis of these results, we suggest that the block to elongation at the MVM attenuation site observed late in MVM infection results, at least in part, from the inactivation of the general transcription elongation factors.

Monoclonal antibodies to the major nonstructural nuclear protein of minute virus of mice

Monoclonal antibodies were raised against a bacterial fusion protein containing amino acids 364 to 623 of the major nonstructural protein, NS-1, of minute virus of mice (MVMp), an autonomous parvovirus. By immunoblot analyses, these antibodies all recognized an 83-kDa protein in MVM-infected mouse fibroblast cells. Indirect immunofluorescence studies showed that five of the six react against a nuclear protein in MVM-infected mouse cells resulting in discrete foci of fluorescence. These foci do not correspond with the nucleoli, the site of MVM DNA replication. The epitopes of the antibodies were mapped using carboxy-terminal deleted bacterial fusion proteins derived from the plasmid encoding the original antigen and showed that four distinct epitopes were recognized by the different antibodies. A 25-amino-acid peptide was used in competition ELISAs to confirm the location of the epitope recognized by two antibodies CE10 and AC6. Preliminary characterization of an NS-1/NS-2 fusion protein synthesized in insect cells using a baculovirus expression vector showed that this fusion protein is also localized within the nucleus; however, in contrast, the full-length NS-1 polypeptide is located within the cytoplasm.

The small nonstructural protein (NS2) of the parvovirus minute virus of mice is required for efficient DNA replication and infectious virus production in a cell-type-specific manner

Seven mutations which affect only the small nonstructural protein NS2 were introduced into the infectious clone of the autonomous parvovirus, minute virus of mice (MVM). The majority of these mutants were severely defective for replication following transfection of normal host murine A9 fibroblasts; however, all were found to replicate more efficiently and produce infectious virus in certain other cell types, including human NB324K. The isolation of viral stocks from NB324K cells permitted a more detailed analysis of the mutant defect on A9 cells. NS2 mutant NS2-2018 was shown to be approximately 10-fold deficient for viral monomer replicative-form DNA production within a single-burst cycle in infected A9 cells and produced a reduced amount of progeny single strand. Mutant NS2-2018 generated wild-type levels of monomer replicative-form DNA on NB324K cells but made reduced levels of progeny single strand and small plaques on these cells. The accumulation of NS1 is reduced late in NS2-2018 infection of A9 cells, but NS1 accumulates to wild-type levels late in NB324K cell infections. NS1 nuclear localization is not dependent on NS2 in A9 or NB324K cells. These results indicate that NS2 participates in MVM DNA replication and is required for efficient viral growth. The requirement for NS2 during MVM replication is also host cell specific. This requirement is significantly more pronounced in the normal host murine A9 cells than in certain other cell types, including NB324K.

Simultaneous identification of viral proteins and nucleic acids in cells infected with Aleutian mink disease parvovirus

A method combining in situ hybridization and immunohistochemistry was used to characterize cells infected with Aleutian mink disease parvovirus (ADV). Single-stranded RNA hybridization probes specific for obligate replicative intermediates and antisera specific for virion or non-structural proteins were employed. Crandell feline kidney cells in which the ADV-G strain of ADV was permissively replicating contained virion and non-structural proteins, large amounts of single stranded virion DNA, duplex replicative form (RF) DNA, and mRNA. Late in the infectious cycle, however, cells containing non-structural proteins but little nucleic acid were observed, probably representing cells in the end stage of viral cytopathology. Sections of lung prepared from mink kits infected with the ADV-Utah 1 strain were then examined. Alveolar type II cells permissively replicating ADV contained viral nucleic acids and proteins in patterns nearly identical to CRFK cells, suggesting that permissive ADV replication was similar in vitro and in vivo. Another population of ADV containing cells that had cytoplasmic virion antigen, but undetectable levels of non-structural protein was found in vivo. Furthermore, although virion DNA was present in the cytoplasm of these cells, RF DNA or mRNA could not be detected. These cells may have been alveolar macrophages sequestering viral particles.

Parvovirus replication

The members of the family Parvoviridae are among the smallest of the DNA viruses, with a linear single-stranded genome of about 5 kilobases. Currently the family is divided into three genera, two of which contain viruses of vertebrates and a third containing insect viruses. This review concentrates on the vertebrate viruses, with emphasis on recent advances in our insights into the molecular biology of viral replication. Traditionally the vertebrate viruses have been distinguished by the presence or absence of a requirement for a coinfection with a helper virus before productive infection can occur, hence the notion that the dependoviruses (adeno-associated viruses [AAV]) are defective. Recent data would suggest that not only is there a great deal of structural and genetic organizational similarity between the two types of vertebrate viruses, but also there is significant similarity in the molecular biology of productive replication. What differs is the physiological condition of the host cell that renders it permissive. Healthy dividing cells are permissive for productive replication by autonomous parvoviruses; such cells result in latent infection by dependoviruses. For a cell to become permissive for productive AAV replication, it must have been exposed to toxic conditions which activate a latent AAV genome. Such conditions can be caused by helper-virus infection or exposure to physical (UV light) or chemical (some carcinogens) agents. In this paper the molecular biology of replication is reviewed, with special emphasis on the role of the host and the consequences of viral infection for the host.

Alternate splicing in a parvoviral nonstructural gene links a common amino-terminal sequence to downstream domains which confer radically different localization and turnover characteristics

Minute virus of mice (MVM) encodes two groups of nonstructural proteins, the 83-kDa NS-1 polypeptides encoded from a contiguous sequence in the left half of the genome and the 25-kDa NS-2 polypeptides, which share a common amino-terminal domain with NS-1 but are multiply spliced. Peptide-specific antibodies were used to demonstrate that three alternatively spliced forms of NS-2 are synthesized when synchronized A9 cells are infected with the prototype strains of MVM, MVM(p), and that each of these species migrates as two bands on sodium dodecyl sulfate-gel electrophoresis, due to the presence of both phosphorylated and unphosphorylated forms. While most NS-1 molecules are located in the nucleus, all three species of NS-2 are predominantly cytoplasmic, and their phosphorylated forms are exclusively cytoplasmic. Although both NS-1 and NS-2 molecules are synthesized early in infection, all forms of NS-2 are synthesized and accumulate three to four times as NS-1 molecules, making them the predominant virally coded proteins in the cell at this time. Despite their common amino-terminal domain, NS-2 molecules turn over rapidly while NS-1 polypeptides persist for many hours. Apart from the fact that the three NS-2 gene products are synthesized in different molar amounts, we were unable to detect any differences in the expression, stability, distribution, or phosphorylation of the various molecular forms, suggesting that these latter characteristics are mediated by their common internal exon.

Cloning of minute virus of mice cDNAs and preliminary analysis of individual viral proteins expressed in murine cells

cDNAs corresponding to RNA from the autonomous parvovirus minute virus of mice were cloned into constitutive and inducible expression vectors. These clones generate viral NS2, VP1, and VP2 proteins individually. Initial examination of these clones by transient expression analysis and analysis of stably transformed murine cell lines inducibly expressing these constructs indicated that they will be useful tools for characterizing the function of individual minute virus of mice gene products.

A cis downstream element participates in regulation of in vitro transcription initiation from the P38 promoter of minute virus of mice

We report the use of a HeLa whole cell extract (WCE) runoff transcription system for the study of cis- and trans-acting elements, participating in the regulation of transcription initiation from the P38 promoter of the parvovirus minute virus of mice (MVM). Our initial studies with HeLa WCE indicated that transcription from the P38 promoter is very inefficient, compared with transcription from the P4 promoter. Supplementation of the HeLa WCE with WCE prepared from uninfected Ehrlich ascites cells enhanced transcription from the P38 promoter twofold, indicating a role for a cellular factor in transcription from the P38 promoter. Furthermore, supplementation with WCE prepared from MVM-infected Ehrlich ascites cells enhanced transcription from the P38 promoter about sixfold, indicating a role for a virally encoded or induced factor. Analyses of runoffs produced by transcription of DNA templates digested with various restriction enzymes defined a downstream promoter element (DPE) necessary for efficient transcription initiation from the P38 promoter. This element resides 282 to 647 base pairs 3' to the transcription initiation site, between the NarI site and the HindIII site (2287 to 2652, MVM numbering system). The virally encoded NS1 protein was shown by DNA precipitation to bind directly or indirectly through a cellular factor to the DPE. This interaction is suggested to be involved in the up regulation of the P38 promoter of MVM. Finally, with a DNase I protection assay performed on a fragment containing the DPE, we estimated the sequence involved in the binding of a factor present in uninfected and infected extracts. The correlation between the binding and transcription activation is discussed.

Emergence, natural history, and variation of canine, mink, and feline parvoviruses

This chapter discusses the emergence of canine parvovirus (CPV), the evidence concerning the previous emergence of mink enteritis virus (MEV) as the cause of a new disease in minks in the 1940s, and the mechanisms that determine the host ranges and other specific properties of the viruses of cats, minks, and dogs. The viruses are classified as the feline parvovirus subgroup of the genus Parvovirus, within the family Parvoviridae. Feline panleukopenia virus (FPV), MEV, and CPV are classified as “host range variants.” In addition to the viruses of cats, minks, and dogs, similar viruses naturally infect many species within the families Felidae, Canidae, Procyonidae, Mustelidae, and possibly the Viverridae. The differences in virulence for minks observed after inoculation of MEV or FPV suggests that there are subtle differences between FPV and MEV that have yet to be defined. Genetic mapping studies indicate that only three or four sequence differences between the FPV and CPV-2 isolates within the VP-1 lVP-2 gene determine all of the specific properties of CPV that have been defined: the pH dependence of hemagglutination, the CPV-specific epitope, and the host range for canine cells and dogs.

Characterization of replicative form DNA of the autonomous parvovirus mink enteritis virus

Characterization of replicative form (RF) DNA of mink enteritis virus (MEV) was carried out. Most of the RF DNA were bound to terminal protein but some were free from the protein. The protein-free RF DNA increased about 7 times from 30 to 50 hr post-infection, while the DNA with protein increased less. The molecules of the replicative intermediate which were partially single-stranded DNA and bound to terminal protein were present. Two terminal conformations, "extended" and "turnaround," were observed in both ends of both terminal protein-bound and protein-free RF DNA. The 5' end labeling revealed that 5' ends of protein-free RF DNA were not blocked to phosphorylation by an amino acid or an oligopeptide which attaches to 5' ends of proteolytically deproteinized RF DNA. Restriction analysis of incomplete RF DNA which was partially double-stranded DNA showed that extended conformation was dominant in such incomplete RF molecules.

A genome-linked copy of the NS-1 polypeptide is located on the outside of infectious parvovirus particles

The 5' ends of all newly synthesized single-stranded (s1) DNA genomes of the autonomous parvovirus minute virus of mice are covalently linked to the major virally coded nonstructural protein NS-1, but later in infection this association is disrupted, giving rise to an abbreviated form of single-stranded DNA designated s2. Both s1 and s2 forms are encapsidated and migrate in velocity gradients as 110S particles, and, as such, both appear to be infectious. Most virions are released from A9 cells as s1 particles, but the NS-1 molecules are located on the outside of the virion where they are accessible to both antibodies and enzymes. These polypeptides are cleaved from the encapsidated DNA by nucleolytic or proteolytic digestion, which can occur either in the culture medium or upon subsequent entry into further host cells. Since the s1 to s2 cleavage can be minimized by blocking viral reentry, it is likely that most of the processing occurs after entry into the host cell. Incoming virus is rapidly converted to the s2 form when it is used to infect new host cells, but in vitro removal of the NS-1 molecules with proteases or nucleases fails to influence the infectivity of s1 particles under normal culture conditions. Limited proteolysis of s1 particles with trypsin demonstrates that NS-1 is linked to the DNA via its amino-terminal domain. Analysis of the 5' ends of s1 and s2 forms indicates that there are approximately 24 externally located nucleotides linking the NS-1 molecules to the 5.1-kilobase nuclease-resistant DNA core of the virion.

Characterization of novel populations of MVM virions containing covalent DNA-protein complexes

Virions of minute virus of mice were purified by sedimentation in sucrose gradients and chromatography on DEAE-cellulose columns and shown to consist of single-stranded viral DNA and the viral capsid polypeptides VP-1 (83 kDa) and VP-2 (64.5 kDa). A 63-kDa polypeptide distinct from the viral capsid polypeptide VP-3 (61.4 kDa) was found in some virion preparations. Virions sedimented at 135 and 110 S. The genomic single strands associated with purified 135 and 110 S virions were covalently bound to a protein as judged by the anomalous electrophoretic mobility of the DNA in agarose gels at pH 12.5. The protein was removed from the DNA by Pronase but remained bound after heating at 98 degrees in the presence of 0.1% sodium dodecyl sulfate. Nuclease digestion of the purified DNA-protein complex released several polypeptides ranging in size from 58 to 65 kDa. Restriction enzyme analysis of the purified DNA protein complex following its conversion to a duplex RF DNA in vitro showed that the protein was attached to the 5' termini of the DNA.

Generation and characterization of a temperature-sensitive mutation in the NS-1 gene of the autonomous parvovirus minute virus of mice

In-phase single-codon insertion mutations were constructed in the open reading frames of the NS-1 and NS-2 genes of the autonomous parvovirus minute virus of mice. A viral mutant containing an isoleucine insertion exclusively within NS-1 between residues 229 and 230 was isolated that produced approximately 3 orders of magnitude fewer plaques at 39 degrees C than at 32 degrees C. Preliminary characterization of the mutant demonstrated that the NS-1 gene product is independently required for both genome amplification and the regulation of the temporal expression between the two viral transcription units during lytic infection.

The two transcription units of the autonomous parvovirus minute virus of mice are transcribed in a temporal order

Using quantitative RNase protection assays, we have monitored the appearance of mRNAs generated during lytic infection of tightly synchronized murine cells by the autonomous parvovirus minute virus of mice. Our results demonstrate that transcripts from the P4 promoter can be detected prior to those from the P39 promoter, providing direct evidence for a temporal order of expression between the two parvovirus promoters.

The NS-1 polypeptide of minute virus of mice is covalently attached to the 5' termini of duplex replicative-form DNA and progeny single strands

When A9 cells are infected with minute virus of mice, a small proportion of the virally coded NS-1 polypeptide becomes covalently attached to newly synthesized viral DNA. Antisera directed against NS-1 will specifically precipitate two forms of monomer duplex replicative-form DNA, multimeric duplex intermediates and progeny single strands, and restriction analysis of the duplex forms in these precipitates reveals that NS-1 is exclusively associated with extended-form conformers of the genomic termini. Pulse-labeled viral DNA, harvested at various times in a highly synchronized infection, can be almost quantitatively precipitated with any one of a series of antisera directed against different protein domains distributed throughout the NS-1 molecule but not with antibodies directed against other viral proteins. In each case the interaction with NS-1 can be shown to involve both termini of duplex DNA and single-strand forms, suggesting that in each case a full-length (83-kilodalton) copy of NS-1 is present. Precipitation of the replicating viral DNA with an antibody directed against a synthetic 16-amino-acid peptide containing the sequence at the extreme carboxy terminus of NS-1 can be quantitatively and specifically inhibited with the immunizing peptide in its unconjugated form, showing that the antibodies responsible for precipitating viral DNA are directed against the NS-1 sequence itself and not against a trace contaminant. Exonuclease digestion studies show that the association effectively blocks the 5' ends of the DNA molecules. Very little (less than 0.1%) of the newly synthesized [35S]methionine-labeled NS-1 made in highly synchronized cells during a 15-min pulse early in infection (6.25 to 6.5 h into the S phase) becomes associated with viral DNA immediately. However, pulse-chase experiments show that later in infection (10 to 13 h into the S phase), when viral DNA replication is reaching its peak, a few percent of the molecules in these preexisting pools of NS-1 do become covalently attached to the newly replicated DNA. Isolated viral DNA-protein complexes labeled with [35S]methionine in this way can be obtained by fractionation of the immunoprecipitated complexes on Sepharose CL4B in sodium dodecyl sulfate. Digestion of the purified complexes with nuclease releases an 83-kilodalton molecule which exactly comigrates with authentic NS-1 in sodium dodecyl sulfate-polyacrylamide gels.

New approaches to animal vaccines utilizing genetic engineering

Control of infectious diseases in livestock is an important determinant in the success of a nation's effort to efficiently meet its need for animal products. Genetic engineering offers many new options in the design of animal vaccines. Monoclonal antibodies, DNA cloning, recombination, and transfection are examples of techniques that facilitate innovative strategies in antigen identification, production, and delivery. This article reviews the use of genetic engineering in the production of vaccines directed against foot-and-mouth disease virus and other important pathogens of animals. The advantages and disadvantages of vaccines produced through the use of genetic engineering are discussed.

Detection of bovine parvovirus proteins homologous to the nonstructural NS-1 proteins of other autonomous parvoviruses

Two nonstructural proteins of bovine parvovirus (BPV) with apparent molecular sizes of 75,000 and 83,000 daltons have been detected. The proteins were immunoprecipitated from lung cells infected with various isolates of BPV and from in vitro translations of infected cell mRNA. These proteins were expressed as nuclear phosphoproteins and were synthesized early in infection, before the peak of capsid protein synthesis. Early in infection, the 75-kilodalton-size species could be resolved into two bands of equal intensity, but later in infection, the lower-molecular-size form predominated. Antibodies directed against bacterial fusion proteins encoding amino acid sequences from a highly conserved region of the NS-1 polypeptides of two other parvoviruses, minute virus of mice and the human virus B19, gave specific nuclear fluorescence with BPV-infected cells, although the antibodies failed to immunoprecipitate any viral proteins. The noncapsid proteins appear to be homologous to the previously characterized NS-1 proteins of other autonomous parvoviruses.

Minute virus of mice (MVM) mRNAs predominantly polyadenylate at a single site

The polyadenylation sites for MVM(p) and MVM(i) mRNAs were determined by a quantitative hybridization-S1 protection assay. mRNAs produced by MVM(p) both early and late in infection of mouse A9 fibroblasts, and by MVM(p) and MVM(i) late in infection of human NB324K cells, polyadenylate predominantly at a single site, at nucleotide 4908 +/- 2 for MVM(p) and 4843 +/- 2 for MVM(i), shortly downstream of the final AATAAA in each viral genome. These results demonstrate that although the right-hand end of MVM has multiple AATAAA signals, and MVM(p) and MVM(i) vary significantly within this region, 3' end processing of viral mRNAs is not a prevalent mechanism for the regulation of MVM gene expression.

Study of canine parvovirus polypeptides by immunoblot analysis

The immunoblot analysis of canine parvovirus (CPV) polypeptides with 47 rat monoclonal antibodies (RH) has revealed four different types of reaction. Many of these antibodies do not recognize the electroblotted proteins. However, among these monoclonals that do react, 12 recognize all three viral polypeptides (VP67, VP70 and VP85), 3 recognize preferentially the VP85 and one is exclusively directed against VP70. Thus, three antigenic regions are proposed which correspond to domains of the CPV polypeptides. In addition, these results together with evidence for the biological activities of the monoclonals suggest that the C and N terminals of VP85 are exposed at the surface of the viral particle.

Characterization of the trans-activation-responsive element of the parvovirus H-1 P38 promoter

The parvovirus early protein NS1 positively regulates the expression of the P38 promoter for the viral capsid protein gene. We have examined the trans-activation of P38 by NS1 by using fusions of P38 to the reporter gene, chloramphenicol acetyltransferase (cat). Maximal trans-activation requires a small 5' cis element (tar) between -137 and -116. The tar element has activity in both orientations when 5' to the P38 promoter, but no activity has been detected 3' to the promoter. The wild-type P38 has a biphasic response to NS1 depending on the dosage of the NS1-expressing plasmid. Promoters lacking the tar also have a biphasic response that is reduced about 10-fold, and they can be inhibited by larger doses of the NS1 plasmid. Heterologous promoters from other viruses and the Harvey-ras oncogene promoter are inhibited by NS1. Truncated and internally deleted versions of NS1 lose the trans-activation, but some of them retain the inhibitory properties. Thus transactivation can be uncoupled from inhibition. The tar element has shown no activity with the heterologous simian virus 40 early promoter. In contrast, the P38 promoter responds to a heterologous enhancer, but the enhanced promoter loses activity to trans-activation by NS1. In summary, the P38 tar element has some of the properties of an enhancer with a high preference for a 5' position and a stringent requirement for the P38 promoter.

Characterization of capsid and noncapsid proteins of B19 parvovirus propagated in human erythroid bone marrow cell cultures

The major capsid and noncapsid proteins of the pathogenic parvovirus B19, propagated in vitro, were detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoprecipitation, and immunoblot of the erythroid fraction of infected human bone marrow cell cultures. There were two capsid proteins of 58 kilodaltons (kDa; the major species) and 84 kDa (the minor species). Newly synthesized capsid viral proteins were present in the supernatants of infected cultures. The major noncapsid protein of 77 kDa was localized to the nucleus.

Construction of a genetic switch for inducible trans-activation of gene expression in eucaryotic cells

The cotransfection of selectable marker genes and the gene for the nonstructural proteins NS1 and NS2 of the autonomous parvovirus H-1 failed to produce cell lines that constitutively expressed NS1. A plasmid, pP38NS1cat, was constructed that expressed the NS1-NS2 gene from the H-1 P38 coat protein promoter in place of the natural P4 promoter. The P38 promoter is constitutively weak and is trans-activated by NS1. Stable cell lines were isolated that contained pP38NS1cat that was constitutively silent, but inducible with exogenous NS1 by superinfection or by treatment with sodium butyrate. The cells that were induced for this self-stimulatory genetic circuit did not remain in the culture, suggesting that expression of NS1-NS2 is cytotoxic or that the expression is not sustained. The properties of these cell lines and an example of the construction of a cell line inducible for expression of the viral coat protein gene and the bacterial gene for chloramphenicol acetyltransferase (cat) are described.

Organization and nucleotide sequence of a densovirus genome imply a host-dependent evolution of the parvoviruses

The genome structure of a densovirus from a silkworm was determined by sequencing more than 85% of the complete genome DNA. This is the first report of the genome organization of an insect parvovirus deduced from the DNA sequence. In the viral genome, two large open reading frames designated 1 and 2 and one smaller open reading frame designated 3 were identified. The first two open reading frames shared the same strand, while the third was found in the complementary sequence. Computer analysis suggested that open reading frame 2 may encode all four structural proteins. The genome organization and a part of the nucleotide sequence were conserved among the insect densovirus, rodent parvoviruses, and a human dependovirus. These viruses may have diverged from a common ancestor.