Replication of and protein synthesis by TT viruses.

The host cells and the events in the cells during Torque teno (TT) virus infection are at present unknown. Replicating TT virus DNA has been detected in liver, in peripheral blood mononuclear cells (PBMC), and in bone marrow. By alternative splicing this small virus generates three mRNA species, from which by alternative translation initiation at least six proteins are produced. The functions of the proteins are not yet fully understood. However, functions associated with, e.g., DNA replication, immunomodulation, and apoptosis have been suggested to reside in the multifunctional proteins of anelloviruses.

Detection of rat parvovirus type 1 and rat minute virus type 1 by polymerase chain reaction.

Two newly recognized parvovirus species, rat parvovirus 1 (RPV-1) and rat minute virus 1 (RMV-1), were recently identified in naturally infected rats. In this study, two polymerase chain reaction (PCR) assays were developed to specifically detect RPV-1 and RMV-1. The RPV-1 PCR assay amplified the expected 487-bp deoxyribonucleic acid (DNA) fragment only in the presence of RPV-1 DNA; the RMV-1 PCR assay amplified the expected 843-bp product only from RMV-1 DNA, not from other rodent parvoviruses. The RPV-1 and the RMV-1 PCR assays detected approximately 18 and 70 copies of DNA template, respectively. These two PCR assays were shown to be sensitive, specific and rapid methods for detecting RPV-1 and RMV-1 infections in rats. These assays may also be valuable for evaluation of biological specimens for parvovirus contamination.

The NS2 protein generated by the parvovirus minute virus of mice is degraded by the proteasome in a manner independent of ubiquitin chain elongation or activation.

The NS2 protein generated by the parvovirus minute virus of mice is very labile, having a half-life during infection of approximately 90 min. The degradation of NS2 is blocked by proteasome inhibitors but is likely ubiquitin independent: NS2 does not form detectable higher molecular weight ubiquitin-containing conjugates, and NS2 degradation requires neither ubiquitin chain elongation nor intracellular ubiquitin activation. We have also identified a region in the carboxyl half of NS2 that is required for its proteasome-mediated degradation.

Adeno-associated virus RNAs appear in a temporal order and their splicing is stimulated during coinfection with adenovirus.

We have used a quantitative RNase protection assay to characterize the relative accumulation and abundance of individual adeno-associated virus type 2 (AAV) RNAs throughout the course of AAV-adenovirus coinfections and preinfections. We have demonstrated that there is a previously unrecognized temporal order to the appearance of AAV RNAs. First, unspliced P5-generated transcripts, which encode Rep78, were detectable prior to the significant accumulation of other AAV RNAs. Ultimately, as previously demonstrated, P19-generated products accumulated to levels greater than those generated from P5, and P40-generated transcripts predominated in the total RNA pool. Second, the percentage of each class of AAV RNA that was spliced increased during infection, and the degree of this increase was different for the P5/P19 products than for those generated by P40. At late times postcoinfection, approximately 90% of P40 products, but only approximately 50% of RNAs generated by P5 and P19, were seen to be spliced; thus, the AAV intron was removed to different final levels from these different RNA species. We have shown that each of the AAV RNAs is quite stable; the majority of each RNA species persisted 6 h after treatment with actinomycin D. Quantification of the accumulation of individual AAV RNAs, over intervals during which degradation was negligible, allowed us to infer that at late times during infection the relative strength of P5, P19, and P40 was approximately 1:3:18, respectively, consistent with the steady-state accumulated levels of the RNAs generated by each promoter. All AAV RNAs exited to the cytoplasm with similar efficiencies in the presence or absence of adenovirus; however, adenovirus coinfection appeared to stimulate total splicing of AAV RNAs and the relative use of the downstream intron acceptor. Our results confirm and extend previous observations concerning the appearance and processing of AAV-generated RNAs.

Recombination within the nonstructural genes of the parvovirus minute virus of mice (MVM) generates functional levels of wild-type NS1, which can be detected in the absence of selective pressure following transfection of nonreplicating plasmids.

Recombination within the coding region of the nonstructural genes of minute virus of mice (MVM), which generates functional levels of wild-type NS1, was observed in the absence of selective pressure following cotransfection of nonreplicating plasmids. P38 activity was used as a measure of recombinant NS1 production, which, together with direct detection of recombinant-generated products by RT-PCR, allowed an estimation of recombination efficiency. In addition, we show that very low levels of wild-type NS1 were able to significantly transactivate P38. Given that recombination following cotransfection can generate NS1 at these levels, our observations have implications for the study of parvoviral genetics, the construction of recombinant parvoviral vectors for gene therapy applications, and perhaps other systems using cotransfection of plasmids that share homologous sequences.

A premature termination codon in either exon of minute virus of mice P4 promoter-generated pre-mRNA can inhibit nuclear splicing of the intervening intron in an open reading frame-dependent manner.

How premature translation termination codons (PTCs) mediate effects on nuclear RNA processing is unclear. Here we show that a PTC at nucleotide (nt) 385 in the NS1/2 shared exon of P4-generated pre-mRNAs of the autonomous parvovirus minute virus of mice caused a decrease in the accumulated levels of doubly spliced R2 relative to singly spliced R1, although the total accumulated levels of R1 plus R2 remained the same. The effect of this PTC was evident within nuclear RNA, was mediated by a PTC and not a missense transversion mutation at this position, and could be suppressed by improvement of the large intron splice sites and by mutation of the AUG that initiated translation of R1 and R2. In contrast to the PTC at nt 385, the reading frame-dependent effect of the PTC at nt 2018 depended neither on the initiating AUG nor the normal termination codon for NS2; however, it could be suppressed by a single nucleotide deletion mutation in the upstream NS1/2 common exon that shifted the 2018 PTC out of the NS2 open reading frame. This suggested that there was recognition and communication of reading frame between exons on a pre-mRNA in the nucleus prior to or concomitant with splicing.

Inclusion of the NS2-specific exon in minute virus of mice mRNA is facilitated by an intronic splicing enhancer that affects definition of the downstream small intron.

Alternative splicing of pre-mRNAs plays a critical role in maximizing the coding capacity of the small parvovirus genome. The small-intron region of minute virus of mice (MVM) pre-mRNAs undergoes an unusual pattern of overlapping alternative splicing, using two donors, D1 and D2, and two acceptors, A1 and A2, within a region of 120 nucleotides, that governs the steady-state ratios of the various viral mRNAs. In a previous report we demonstrated that a complex interaction between both donor and acceptor sequences, as well as the constraints of size, defines the small intron and governs its alternative splicing. We also identified a G-rich intronic splicing enhancer sequence (IES) that appeared to function as both an intron- and an exon-defining element. In this report we further examined the components that govern MVM small-intron splicing. In fully processed wild-type mRNAs, A1 is used preferentially over A2. In this report, we show that in the context of the wild-type small intron the position of the downstream acceptor A2 was preferred, and the primary sequence of A1 must be stronger for it to be utilized at wild-type efficiency. Use of A2 in generation of the minor spliced forms D2/A2 required the IES because of a weak A2 polypyrimidine tract and because of the relative strength of A1. The small size of the intron and the relative position of the IES were also shown to play a critical role in donor and acceptor site selection. Finally, we have further characterized how the IES functions as an intronic enhancer of upstream exon definition. When the small intron was expanded, upstream exon inclusion was dependent upon the position of the IES. Within the context of the small intron, alterations of the small intron that overcame the requirement for the IES for splicing to A2 also permitted wild-type levels of upstream exon inclusion in the absence of the IES, suggesting that, in its natural context, the IES facilitates upstream exon inclusion by affecting small-intron definition.

A premature termination codon interferes with the nuclear function of an exon splicing enhancer in an open reading frame-dependent manner.

Premature translation termination codon (PTC)-mediated effects on nuclear RNA processing have been shown to be associated with a number of human genetic diseases; however, how these PTCs mediate such effects in the nucleus is unclear. A PTC at nucleotide (nt) 2018 that lies adjacent to the 5' element of a bipartite exon splicing enhancer within the NS2-specific exon of minute virus of mice P4 promoter-generated pre-mRNA caused a decrease in the accumulated levels of P4-generated R2 mRNA relative to P4-generated R1 mRNA, although the total accumulated levels of P4 product remained the same. This effect was seen in nuclear RNA and was independent of RNA stability. The 5' and 3' elements of the bipartite NS2-specific exon enhancer are redundant in function, and when the 2018 PTC was combined with a deletion of the 3' enhancer element, the exon was skipped in the majority of the viral P4-generated product. Such exon skipping in response to a PTC, but not a missense mutation at nt 2018, could be suppressed by frame shift mutations in either exon of NS2 which reopened the NS2 open reading frame, as well as by improvement of the upstream intron 3' splice site. These results suggest that a PTC can interfere with the function of an exon splicing enhancer in an open reading frame-dependent manner and that the PTC is recognized in the nucleus.

CA- and purine-rich elements form a novel bipartite exon enhancer which governs inclusion of the minute virus of mice NS2-specific exon in both singly and doubly spliced mRNAs.

The alternatively spliced 290-nucleotide NS2-specific exon of the parvovirus minute virus of mice (MVM), which is flanked by a large intron upstream and a small intron downstream, constitutively appears both in the R1 mRNA as part of a large 5'-terminal exon (where it is translated in open reading frame 3 [ORF3]), and in the R2 mRNA as an internal exon (where it is translated in ORF2). We have identified a novel bipartite exon enhancer element, composed of CA-rich and purine-rich elements within the 5' and 3' regions of the exon, respectively, that is required to include NS2-specific exon sequences in mature spliced mRNA in vivo. These two compositionally different enhancer elements are somewhat redundant in function: either element alone can at least partially support exon inclusion. They are also interchangeable: either element can function at either position. Either a strong 3' splice site upstream (i.e., the exon 5' terminus) or a strong 5' splice site downstream (i.e., the exon 3' terminus) is sufficient to prevent skipping of the NS2-specific exon, and a functional upstream 3' splice site is required for inclusion of the NS2-specific exon as an internal exon into the mature, doubly spliced R2 mRNA. The bipartite enhancer functionally strengthens these termini: the requirement for both the CA-rich and purine-rich elements can be overcome by improvements to the polypyrimidine tract of the upstream intron 3' splice site, and the purine-rich element also supports exon inclusion mediated through the downstream 5' splice sites. In summary, a suboptimal large-intron polypyrimidine tract, sequences within the downstream small intron, and a novel bipartite exonic enhancer operate together to yield the balanced levels of R1 and R2 observed in vivo. We suggest that the unusual bipartite exonic enhancer functions to mediate proper levels of inclusion of the NS2-specific exon in both singly spliced R1 and doubly spliced R2.

Amino acids 16-275 of minute virus of mice NS1 include a domain that specifically binds (ACCA)2-3-containing DNA.

GST-NS1 purified from Escherichia coli and insect cells binds double-strand DNA in an (ACCA)2-3-dependent fashion under similar ionic conditions, independent of the presence of anti-NS1 antisera or exogenously supplied ATP and interacts with single-strand DNA and RNA in a sequence-independent manner. An amino-terminal domain (amino acids 1-275) of NS1 [GST-NS1(1-275)], representing 41% of the full-length NS1 molecule, includes a domain that binds double-strand DNA in a sequence-specific manner at levels comparable to full-length GST-NS1, as well as single-strand DNA and RNA in a sequence-independent manner. The deletion of 15 additional amino-terminal amino acids yielded a molecule [GST-NS1(1-275)] that maintained (ACCA)2-3-specific double-strand DNA binding; however, this molecule was more sensitive to increasing ionic conditions than full-length GST-NS1 and GST-NS1(1-275) and could not be demonstrated to bind single-strand nucleic acids. A quantitative filter binding assay showed that E. coli- and baculovirus-expressed GST-NS1 and E. coli GST-NS1(1-275) specifically bound double-strand DNA with similar equilibrium kinetics [as measured by their apparent equilibrium DNA binding constants (KD)], whereas GST-NS1(16-275) bound 4- to 8-fold less well.

Intron definition is required for excision of the minute virus of mice small intron and definition of the upstream exon.

Alternative splicing of pre-mRNAs plays a critical role in maximizing the coding capacity of the small parvovirus genome. The small-intron region of minute virus of mice (MVM) pre-mRNAs undergoes an unusual pattern of overlapping alternative splicing--using two donors (D1 and D2) and two acceptors (A1 and A2) within a region of 120 nucleotides--that determines the steady-state ratios of the various viral mRNAs. In this report, we show that the determinants that govern excision of the small intron are complex and are also required for efficient definition of the upstream exon. For the MVM small intron in its natural context, the two donors appear to compete for the splicing machinery: the position of D1 favors its usage, while the primary sequence of D2 must be more like the consensus sequence than is D1 to be used efficiently. We have genetically defined the branch points that are used for generation of the major and minor spliced forms and show that recognition of components of the small-intron acceptors is likely to be the dominant determinant in alternative small-intron excision. We have also identified a G-rich intronic enhancer sequence within the small intron that is essential for splicing of the minor form (D2 to A2) but not the major form (D1 to A1) of MVM mRNAs and is required for efficient definition of the upstream NS2-specific exon. In its natural context, the small intron appears to be excised by a mechanism consistent with intron definition. When the MVM small intron is expanded, various parameters of its excision are altered, indicating that critical cis-acting signals are context dependent. Relative use of the donors and acceptors is altered, and the upstream NS2-specific exon is no longer efficiently defined. The fact that definition of the upstream NS2-specific exon can be achieved by the MVM small intron in its natural context, but not when it is expanded, suggests that the multiple determinants that govern definition and excision of the small intron are required, in concert, for upstream exon definition. Our data are consistent with a model in which alternative splicing of the MVM P4-generated pre-mRNAs is governed by a hybrid of intron- and exon-defining mechanisms.

An Sp1-binding site and TATA element are sufficient to support full transactivation by proximally bound NS1 protein of minute virus of mice.

The minute virus of mice (MVM) P38 Sp1-binding site and TATA box, inserted in an otherwise heterologous plasmid background, could be transactivated to high levels by the MVM NS1 protein targeted proximally to these sequences, demonstrating that these core promoter regulatory elements are sufficient to support essentially wild-type levels of NS1-transactivated expression and suggesting that NS1 may act directly or indirectly with Sp1 and or elements of the general transcription machinery. Accordingly, we show that bacterially generated NS1 can interact strongly, independent of nucleic acid bridging, and most likely directly with Sp1 in vitro and can associate, in a nucleic acid-independent manner, with endogenous Sp1 as it exists in a complex transcriptionally active murine nuclear extract NS1 achieves the same fold activation of an isolated TATA element over its low basal level and can also be demonstrated to interact efficiently and specifically with the general transcription factors TBP and TFIIA (alpha, beta) in vitro.

Characterization of the minute virus of mice P38 core promoter elements.

While the minute virus of mice (MVM) P4 promoter, which drives the viral nonstructural genes, is highly active in the absence of viral proteins, P38, the capsid gene promoter, is strictly dependent on the viral nonstructural protein NS1. Once fully transactivated, however, P38 mediates twice the steady-state level of expression achieved by P4. In this report, we address the discrepancy between the ability of P38 to mediate very high levels of activated transcription yet only low levels of basal expression, and we investigate the determinants that govern P38 basal expression. The isolated P38 core promoter elements (the P38 Sp1-binding site and TATA element) are at least as transcriptionally competent as the analogous P4 promoter elements. Proximally positioning P4 enhancer factor-binding sequences (nucleotides [nt] 57 to 157) upstream of isolated P38 core transcription regulatory elements or upstream of a native, though abbreviated, P38 cassette (MVM nt 1938 to 2072) confers significant levels of expression to P38 in the absence of NS1, while the full left-end hairpin sequences (nt 1 to 133) elevate basal P38 activity to levels equivalent to P4 basal levels. In the context of the complete viral genome, however, proximally positioned enhancer sequences are unable to confer significant levels of expression to P38, suggesting that low P38 basal levels are a consequence not only of a lack of proximal enhancer elements but also of additional positional regulatory constraints which can be overcome by NS1.

Nonstructural proteins NS2 of minute virus of mice associate in vivo with 14-3-3 protein family members.

The nonstructural NS2 proteins of the prototype strain of minute virus of mice (MVMp) were previously shown to be involved in parvoviral DNA amplification as well as in efficient virus production in a host cell-specific manner (L. K. Naeger, N. Salomé, and D. J. Pintel, J. Virol. 67:1034-1043, 1993). NS2 polypeptides were also reported to participate in the cytotoxic activity of parvoviruses (C. Legrand, J. Rommelaere, and P. Caillet-Fauquet, Virology 195:149-155, 1993), for which transformed cells are preferential targets. To identify cellular partners of NS2 proteins, coimmunoprecipitation experiments were performed with various antibodies directed against the parvoviral products. Two cellular proteins with molecular masses of 30 and 32 kDa were found to associate in vivo with the NS2 polypeptides. From amino acid sequence homology, these NS2 partners were assigned to the 14-3-3 family of cellular proteins, showing at least partial identity with the epsilon and beta or zeta 14-3-3 isoforms. In agreement with this assignment, NS2-30/32-kDa protein immune complexes displayed an activating function for exoenzyme S in vitro, a hallmark of 14-3-3 polypeptides. Interactions with 14-3-3 proteins did not appear sufficient for NS2 functions, since they were not disrupted by NS2 C-terminal modifications that impaired virus replication. Binding of NS2 to 14-3-3 proteins was detected in various cells of mouse, rat, hamster, monkey, and human origin, irrespective of NS2 dispensability and host cell transformation or permissiveness. The ubiquitous 14-3-3 proteins were recently reported to associate with several other cellular or viral polypeptides involved in signal transduction and/or cell cycle regulation pathways (A. Aitken, Trends Biochem. Sci. 20:95-97, 1995). The NS2 products may connect with one of these pathways through their interaction with specific 14-3-3 polypeptides.

Molecular characterization of newly recognized rodent parvoviruses.

Several autonomous rodent parvoviruses distinct from the prototypic rodent parvoviruses have been isolated. These include variants of a mouse parvovirus (MPV), a hamster isolate designated hamster parvovirus (HaPV), and a variant strain of minute virus of mice (MVM) designated MVM-Cutter or MVM(c). In this study, the DNA sequence of the coding regions of the viral genome and the predicted protein sequences for each of these new isolates were determined and compared to the immunosuppressive and prototypic strains of MVM [MVM(i) and MVM(p)], the rodent parvovirus H-1, and LuIII, an autonomous parvovirus of uncertain host origin. Sequence comparisons showed that the MPV isolates were almost identical, HaPV was very similar to MPV, and MVM(c) was most similar to MVM(i) and MVM(p). Haemagglutination inhibition assays revealed that MPV and HaPV represent two serotypes distinct from previously characterized rodent parvovirus serotypes while MVM(c) belongs to the MVM serotype. Each of the newly isolated rodent parvoviruses was shown to encapsidate a predominantly negative-sense 5 kb DNA genome and to encode two nonstructural proteins (NS1 and NS2) and two structural viral proteins (VP1 and VP2). These studies indicate that MPV and HaPV are autonomous parvoviruses distinct from previously characterized parvoviruses and MVM(c) is a variant strain of MVM distinct from MVM(i) and MVM(p).

Efficient transactivation of the minute virus of mice P38 promoter requires upstream binding of NS1.

The P38 promoter of the autonomous parvovirus minute virus of mice is strongly transactivated by the nonstructural protein NS1, a sequence-specific DNA-binding protein. In the context of the complete viral genome, the only unique cis-acting signals required for P38 transactivation by NS1 are the proximal Sp1 site and the TATA element. In the absence of additional upstream sequences, a dependence upon the NS1 binding site within the transactivation response region is observed. Addition of synthetic NS1 binding sites to transactivation response region deletion mutants can restore the ability of NS1 to transactivate P38, and NS1 transactivation has been directly correlated to its ability to bind upstream of the P38 promoter.

Expression of recombinant parvovirus NS1 protein by a baculovirus and application to serologic testing of rodents.

A recombinant baculovirus containing the NS1 gene of minute virus of mice was constructed. Optimal expression of the recombinant NS1 protein (rNS1) was achieved by infecting Trichoplusa ni High Five cells at a multiplicity of 10 and incubating them for 72 h postinfection. An enzyme-linked immunosorbent assay (ELISA) with rNS1 as the antigen was evaluated for serologic testing of laboratory rodents. The rNS1 ELISA proved to be a more sensitive method for the detection of antibodies to recently recognized rodent parvovirus species (mouse orphan parvovirus and rat orphan parvovirus) and prototypic parvovirus species (minute virus of mice, Kilham's rat virus, and H-1) than were conventional parvovirus ELISAs that use whole parvovirus virions.

Detection of newly recognized rodent parvoviruses by PCR.

Several autonomous parvovirus isolates distinct from the prototypic rodent parvoviruses have recently been identified. These include variants of a mouse orphan parvovirus (MOPV) and a hamster isolate designated hamster orphan parvovirus (HOPV). In this study, a PCR primer set specific for these newly identified rodent parvoviruses was designed on the basis of DNA sequence comparisons of these isolates with other autonomous parvoviruses. The specificity of the primer set was determined by testing viral preparations of seven different parvoviruses and eight other viruses known to infect rodents. The PCR assay amplified the expected 260-bp product only in the presence of DNA from MOPV, HOPV, or LuIII a parvovirus of unknown species origin. The assay was able to detect as little as 10 pg of MOPV viral DNA or 1 pg of HOPV viral DNA, and it was able to detect MOPV in tissues from naturally infected mice and HOPV in tissues from experimentally infected hamsters. In contrast, the 260-bp product was not amplified from tissues of MOPV-negative mice or mock-infected hamsters. Our findings indicate that this PCR assay provides a rapid, specific, and sensitive method for the detection of MOPV in mice, HOPV in hamsters, and MOPV and HOPV in cell culture systems and that it may also be useful for the detection of LuIII contamination of cell culture systems.

Efficient excision of the upstream large intron from P4-generated pre-mRNA of the parvovirus minute virus of mice requires at least one donor and the 3' splice site of the small downstream intron.

We have previously shown that efficient excision of the upstream large intron from P4-generated pre-mRNA of the autonomous parvovirus minute virus of mice depends upon at least the initial presence of sequences within the downstream small intron (Q. Zhao, R. V. Schoborg, and D. J. Pintel, J. Virol. 68:2849-2859, 1994). In this report, we show that the requirement of downstream small intron sequences is complex and that efficient excision of the upstream intron requires at least one small intron donor and the 3' splice site. In the absence of both small intron donors, a new spliced product is produced in which the intervening exon is skipped and the large intron donor at nucleotide 514 is joined to a small intron acceptor. Exon skipping caused by the loss of the two small intron donors can be overcome, and the excision of the large intron can be regained by mutations that improve the large intron polypyrimidine tract. These results are consistent with a model in which the binding of multiple splicing factors that assemble at both a downstream donor and acceptor facilitates the binding of splicing factors to the weak polypyrimidine tract of the upstream large intron, thereby defining the intervening exon and promoting excision of the upstream intron.