Interaction of virally coded protein and a cell cycle-regulated cellular protein with the bovine parvovirus left terminus ori

The Role of the Human Bocavirus (HBoV) in Respiratory Infections

The human bocavirus is one of the most common respiratory viruses and occurs in all age groups. Because Koch’s postulates have been fulfilled unintendedly, it is currently accepted that the virus is a real pathogen associated with upper and lower respiratory tract infections causing clinical symptoms ranging from a mild common cold to life-threatening respiratory diseases. In order to exclude a viremia, serological analysis should be included during laboratory diagnostics, as acute and chronic infections cannot be differentiated by detection of viral nucleic acids in respiratory specimen alone due to prolonged viral shedding. Besides its ability to persist, the virus appears to trigger chronic lung disease and increases clinical symptoms by causing fibrotic lung diseases. Due to the lack of an animal model, clinical trials remain the major method for studying the long-term effects of HBoV infections.

Respiratory infections of the human bocavirus

The human bocavirus is one of the most common respiratory viruses and occurs in all age groups. It is associated with upper and lower respiratory tract infections, and causes clinical symptoms from the mild common cold to life threatening respiratory diseases. Besides its ability to persist the virus appears to trigger chronic lung disease and increase the clinical symptoms, while being a putative trigger for fibrotic lung diseases.

Laboratory diagnostics should include serological diagnostics in order to rule out a viremia because due to prolonged viral shedding acute and chronic infections cannot be differentiated on the detection of viral nucleic acids in respiratory specimen alone.

Although Koch’s postulates cannot be formally fulfilled due to the lack of an animal model and the chance for clinical trials with volunteers are limited due to the long term effects of HBoV infections, there is no doubt that the virus is a serious pathogen and requires attention.

The aim of the chapter is to present an overview of our current knowledge on respiratory infections with the human bocavirus, and to provide basic and essential information on clinical features, molecular diagnostics, and epidemiologic challenges arising with this pathogen.

The DNA replication, virogenesis and infection of canine minute virus in non-permissive and permissive cells

Canine minute virus (CnMV), a kind of autonomous parvovirus, is a member of genus bocavirus in parvovirdae family. In our previous study, we constructed and obtained infectious clones of CnMV, analyzed genome characteristics, RNA transcription profile, and revealed some molecular mechanisms of cytopathic effect of target cells. The purpose of this study was to investigate DNA replication, virogenesis and infectious tropism of CnMV in non-permissive and permissive cells. We demonstrated that the genomic DNA of CnMV, besides WRD cells, could replicate significantly in some non-permissive cells (CrFK, EBtR and COS-7) following transfection with infectious clone of CnMV, pI-MVC. Moreover, by using Western blotting and immunofluorescence, we found that the NS1 protein of CnMV was obviously expressed in both 293, CrFK, EBtR and COS-7 cells transfected with pI-MVC. Meanwhile, two-rounds of reinfection on WRD cells (blind passage) of the transfected cell lysates in CrFK, EBtR and COS-7 cells tranfected with pI-MVC showed that pI-MVC could produce infectious virions in these types of non-permissive cells. Furthermore, it is confirmed that CnMV only infected WRD cells (permissive cells for CnMV), could not infect any non-permissive cells including CrFK, EBtR, COS-7, HK293, A549 and A9 cells. Taken together, for the first time, we have demonstrated that bocavirus CnMV DNA could replicate and form infectious progeny virus in some non-permissive cells. And what is more, unlike other parvoviruses, CnMV did not infect some non-permissive cells, although the DNA replication of CnMV occurred in these cells.

Parvovirus infection-induced cell death and cell cycle arrest

The cytopathic effects induced during parvovirus infection have been widely documented. Parvovirus infection-induced cell death is often directly associated with disease outcomes (e.g., anemia resulting from loss of erythroid progenitors during parvovirus B19 infection). Apoptosis is the major form of cell death induced by parvovirus infection. However, nonapoptotic cell death, namely necrosis, has also been reported during infection of the minute virus of mice, parvovirus H-1 and bovine parvovirus. Recent studies have revealed multiple mechanisms underlying the cell death during parvovirus infection. These mechanisms vary in different parvoviruses, although the large nonstructural protein (NS)1 and the small NS proteins (e.g., the 11 kDa of parvovirus B19), as well as replication of the viral genome, are responsible for causing infection-induced cell death. Cell cycle arrest is also common, and contributes to the cytopathic effects induced during parvovirus infection. While viral NS proteins have been indicated to induce cell cycle arrest, increasing evidence suggests that a cellular DNA damage response triggered by an invading single-stranded parvoviral genome is the major inducer of cell cycle arrest in parvovirus-infected cells. Apparently, in response to infection, cell death and cell cycle arrest of parvovirus-infected cells are beneficial to the viral cell lifecycle (e.g., viral DNA replication and virus egress). In this article, we will discuss recent advances in the understanding of the mechanisms underlying parvovirus infection-induced cell death and cell cycle arrest.

The cell cycle: a review

The cell cycle is a complex process that involves numerous regulatory proteins that direct the cell through a specific sequence of events culminating in mitosis and the production of two daughter cells. Central to this process are the cyclin-dependent kinases (cdks), which complex with the cyclin proteins. These proteins regulate the cell's progression through the stages of the cell cycle and are in turn regulated by numerous proteins, including p53, p21, p16, and cdc25. Downstream targets of cyclin-cdk complexes include pRb and E2F. The cell cycle can be altered to the advantage of many viral agents, most notably polyomaviruses, papillomaviruses, and adenoviruses. The cell cycle often is dysregulated in neoplasia due to alterations either in oncogenes that indirectly affect the cell cycle or in tumor suppressor genes or oncogenes that directly impact cell cycle regulation, such as pRb, p53, p16, cyclin D1, or mdm-2. The cell cycle has become an intense subject of research in recent years. This research has led to the development of techniques useful for the determination of the effects of drugs and toxins on the cell cycle. Any drug or toxin with DNA damaging ability would be expected to alter cell cycle progression, and therefore, the cell cycle should be considered in the design of studies using such chemicals. With the appropriate techniques, cell cycle alterations may also be detected in tissue sections. Because of the ubiquitous nature of the cell cycle, it deserves consideration in the design and interpretation of studies in a wide variety of disciplines.

Cellular protein interactions with herpes simplex virus type 1 oriS

The herpes simplex virus type 1 (HSV-1) origin of DNA replication, oriS, contains an AT-rich region and three highly homologous sequences, sites I, II, and III, identified as binding sites for the HSV-1 origin-binding protein (OBP). In the present study, interactions between specific oriS DNA sequences and proteins in uninfected cell extracts were characterized. The formation of one predominant protein-DNA complex, M, was demonstrated in gel shift assays following incubation of uninfected cell extracts with site I DNA. The cellular protein(s) that comprises complex M has been designated origin factor I (OF-I). The OF-I binding site was shown to partially overlap the OBP binding site within site I. Complexes with mobilities indistinguishable from that of complex M also formed with site II and III DNAs in gel shift assays. oriS-containing plasmid DNA mutated in the OF-I binding site exhibited reduced replication efficiency in transient assays, demonstrating a role for this site in oriS function. The OF-I binding site is highly homologous to binding sites for the cellular CCAAT DNA-binding proteins. The binding site for the CCAAT protein CP2 was found to compete for OF-I binding to site I DNA. These studies support a model involving the participation of cellular proteins in the initiation of HSV-1 DNA synthesis at oriS.

Cellular protein interactions with herpes simplex virus type 1 oriS

The herpes simplex virus type 1 (HSV-1) origin of DNA replication, oriS, contains an AT-rich region and three highly homologous sequences, sites I, II, and III, identified as binding sites for the HSV-1 origin-binding protein (OBP). In the present study, interactions between specific oriS DNA sequences and proteins in uninfected cell extracts were characterized. The formation of one predominant protein-DNA complex, M, was demonstrated in gel shift assays following incubation of uninfected cell extracts with site I DNA. The cellular protein(s) that comprises complex M has been designated origin factor I (OF-I). The OF-I binding site was shown to partially overlap the OBP binding site within site I. Complexes with mobilities indistinguishable from that of complex M also formed with site II and III DNAs in gel shift assays. oriS-containing plasmid DNA mutated in the OF-I binding site exhibited reduced replication efficiency in transient assays, demonstrating a role for this site in oriS function. The OF-I binding site is highly homologous to binding sites for the cellular CCAAT DNA-binding proteins. The binding site for the CCAAT protein CP2 was found to compete for OF-I binding to site I DNA. These studies support a model involving the participation of cellular proteins in the initiation of HSV-1 DNA synthesis at oriS.

The major capsid protein VP2 of minute virus of mice (MVM) can form particles which bind to the 3'-terminal hairpin of MVM replicative-form DNA and package single-stranded viral progeny DNA

The capsids of minute virus of mice (MVM) consist of two closely related proteins, VP1 and VP2. We inactivated the VP1 gene in an infectious clone of MVM DNA by frameshift mutation. After transfection of mutated DNA, capsids consisting of VP2 only were made. They can package negative-strand DNA, and they specifically bind MVM 3'-terminal hairpin DNA.

The minor capsid protein VP1 of the autonomous parvovirus minute virus of mice is dispensable for encapsidation of progeny single-stranded DNA but is required for infectivity

The two capsid proteins of minute virus of mice, VP1 and VP2, are generated from a single large open reading frame by alternate splicing of the capsid gene mRNA. Examination of the replication of a series of mutants that express only VP1, only VP2, or neither capsid protein demonstrates that VP2 is necessary for the accumulation and encapsidation of virus progeny single-stranded DNA. VP1 is dispensable for these functions but is required to produce an infectious virion. Virus that lacks VP1 binds to cells as efficiently as wild-type minute virus of mice but fails to initiate a productive infection. Because neither capsid protein is required for viral-DNA replication, these results suggest that virus lacking VP1 is blocked at a step during virus entry, subsequent to cell binding and prior to the initiation of DNA replication.

Nucleolin forms a specific complex with a fragment of the viral (minus) strand of minute virus of mice DNA

Nucleolin, a major nucleolar protein, forms a specific complex with the genome (a single-stranded DNA molecule of minus polarity) of parvovirus MVMp in vitro. By means of South-western blotting experiments, we mapped the binding site to a 222-nucleotide motif within the non-structural transcription unit, referred to as NUBE (nucleolin-binding element). The specificity of the interaction was confirmed by competitive gel retardation assays. DNaseI and nuclease S1 probing showed that NUBE folds into a secondary structure, in agreement with a computer-assisted conformational prediction. The whole NUBE may be necessary for the interaction with nucleolin, as suggested by the failure of NUBE subfragments to bind the protein and by the nuclease footprinting experiments. The present work extends the previously reported ability of nucleolin to form a specific complex with ribosomal RNA, to a defined DNA substrate. Considering the tropism of MVMp DNA replication for host cell nucleoli, these data raise the possibility that nucleolin may contribute to the regulation of the parvoviral life-cycle.

Characterization of the stage(s) in the virus replication cycle at which the host-cell specificity of the feline parvovirus subgroup is regulated in canine cells

Feline panleukopenia virus (FPLV), mink enteritis virus (MEV), and canine parvovirus (CPV) are classified as a host-range variants. They show different host-range specificity in vivo and host-cell specificity in vitro. For instance, FPLV and MEV cannot grow or can grow only inefficiently in canine cell lines such as MDCK and the canine fibroma cell line A72. Here we have studied the mechanism(s) by which the different cell tropism is mediated in vitro. When FPLV or MEV was inoculated to A72 cells, viral DNA replicated slightly, few viral-antigen-positive cells were detected, and the culture fluid contained the threshold level of infectivity. On the other hand, when an infectious molecular clone of MEV (pMEV) was introduced into A72 cells, viral DNA replicated efficiently, and the culture fluid of pMEV-transfected cells contained much higher infectivities than that of MEV-infected cells. In spite of the restrictive growth in A72 cells, MEV could bind to A72 cells as efficiently as CPV. No detectable viral RNA was produced in MEV-infected A72 cells. In contrast, efficient viral transcription occurred in pMEV-transfected A72 cells. These results suggest that the restrictive infections of MEV and FPLV in A72 cells are not mediated by the attachment of the virus to the cells or by the events occurring after the viral transcription. It appears to be caused by the stage(s) in the virus replication cycle, which exists between a postadsorptional step required for virus penetration and the initiation of viral transcription.

Analysis of mutations in adeno-associated virus Rep protein in vivo and in vitro

The adeno-associated virus (AAV) Rep protein is required for both viral DNA replication and transactivation of the AAV promoters. Here we report the effects of mutations in the rep gene on transcription and replication in vivo and terminal repeat binding and terminal resolution site (trs) endonuclease activities in vitro. In all, we examined 10 in-frame deletions and 14 amino acid substitution mutations at eight positions. The point mutations were targeted to regions that are highly conserved among the parvovirus nonstructural proteins and include the extended ATPase domain of the AAV Rep protein. The mutations identify at least two noncontiguous regions of Rep which are essential for terminal repeat binding (amino acids 134 to 242 and amino acids 415 to 490). Mutations in either region render the protein inactive for both DNA replication and transactivation. In addition, mutations within a putative ATPase region also cause defects in replication and transactivation in vivo as well as in the ATP-dependent trs endonuclease activity in vitro. These results suggest that Rep transactivates via a novel mechanism which may require both DNA binding and an enzymatic activity, namely, ATPase or DNA helicase activity.

Partial purification of adeno-associated virus Rep78, Rep52, and Rep40 and their biochemical characterization

We have used differential cell extraction and conventional chromatography to separate and partially purify the four adeno-associated virus (AAV) nonstructural proteins Rep78, Rep68, Rep52, and Rep40. In the cytoplasmic extracts Rep52 and Rep40 were present in greater abundance than Rep68 and Rep78, with Rep78 being the least abundant. In nuclear extracts the four Rep proteins were approximately equal in abundance. Regardless of the subcellular fraction examined, three of the Rep proteins (Rep78, Rep68, and Rep40) consisted of two protein species with slightly different mobilities during polyacrylamide gel electrophoresis. In contrast, Rep52 consisted of only one protein species. Both Rep78 and Rep68 were capable of binding efficiently to AAV terminal hairpin DNA substrates, but we could not detect site-specific DNA binding by Rep52 and Rep40. Like Rep68, Rep78 had both an ATP-dependent trs endonuclease and a DNA helicase activity. Both Rep78 and Rep68 cut the terminal AAV sequence at the same site (nucleotide 124). The binding, trs endonuclease, and DNA helicase activities comigrated during sucrose density gradient centrifugation with a mobility expected for a monomer of the protein, suggesting that the three biochemical activities were intrinsic properties of the larger Rep proteins. The chromatographic behavior and the DNA-binding properties of the four Rep proteins identified at least two domains within the rep coding region, an exposed hydrophobic domain within the C-terminal end (amino acids 578 to 621) and a region within the N terminus (amino acids 1 to 214) which was necessary for binding to the terminal repeat sequence. No site-specific nuclease activity was seen in the presence of nucleotide analogs ATP-gamma-S or AMP-PNP, suggesting that ATP hydrolysis was required for the endonuclease reaction. Furthermore, although ATP was the only cofactor which would support the trs endonuclease activity of Rep78, Rep68 nuclease activity was seen in the presence of several other nucleotide cofactors, including CTP, GTP, and UTP.

The minute virus of mice capsid specifically recognizes the 3' hairpin structure of the viral replicative-form DNA: mapping of the binding site by hydroxyl radical footprinting

The terminal hairpin structures of the DNA of minute virus of mice (MVM) are essential for viral replication. Here we show that the hairpin 3' terminus of MVM replicative-form DNA binds specifically to empty MVM capsids. Binding of the same terminal DNA sequence in its linear double-stranded (extended) conformation was not observed. After heat denaturation and quick cooling of 3'-terminal extended-form fragments, not only the virion strand but also the complementary strand was found to bind to the capsid, presumably because each strand re-formed a similar hairpin structure. No binding affinity for the capsid was found to be associated with hairpin or extended 5' termini or with any other region of the viral DNA. Hydroxyl radical footprinting analyses revealed three protected nucleotide stretches forming a binding site at the branch point of the two 3'-terminal hairpin arms looping out from the DNA stem (T structure). Single base changes within this site did not affect the binding. In band shift experiments, specific binding to the T structure was demonstrated for VPI but not for VP2.