Capsid-associated Protein Research Articles

A Unique Role of the Human Cytomegalovirus Small Capsid Protein in Capsid Assembly.

ABSTRACTMorphogenesis of herpesvirus particles is highly conserved; however, the capsid assembly and genome packaging of human cytomegalovirus (HCMV) exhibit unique features. Examples of these include the essential role of the small capsid protein (SCP) and the existence of the β-herpesvirus-specific capsid-associated protein pp150. SCP and pp150, as well as the UL77 and UL93 proteins, are important capsid constituents, yet their precise mechanism of action is elusive. Here, we analyzed how deletion of the open reading frames (ORFs) encoding pUL77, pUL93, pp150, or SCP affects the protein composition of nuclear capsids. This was achieved by generating HCMV genomes lacking the respective genes, combined with a highly efficient transfection technique that allowed us to directly analyze these mutants in transfected cells. While no obvious effects were observed when pUL77, pUL93, or pp150 was missing, the absence of SCP impeded capsid assembly due to strongly reduced amounts of major capsid protein (MCP). Vice versa, when MCP was lacking, SCP became undetectable, indicating a mutual dependence of SCP and MCP for establishing appropriate protein levels. The SCP domain mediating stable MCP levels could be narrowed down to a C-terminal helix known to convey MCP binding. Interestingly, an SCP-EGFP (enhanced green fluorescent protein) fusion protein which also impaired the production of infectious progeny acted in a different manner, as capsid assembly was not abolished; however, SCP-EGFP-harboring capsids were devoid of DNA and trapped in paracrystalline nuclear structures. These results indicate that SCP is essential in HCMV because of its impact on MCP levels and reveal SCP as a potential target for antiviral inhibitors.

Structure of human cytomegalovirus virion reveals host tRNA binding to capsid-associated tegument protein pp150

Under the Baltimore nucleic acid-based virus classification scheme, the herpesvirus human cytomegalovirus (HCMV) is a Class I virus, meaning that it contains a double-stranded DNA genome—and no RNA. Here, we report sub-particle cryoEM reconstructions of HCMV virions at 2.9 Å resolution revealing structures resembling non-coding transfer RNAs (tRNAs) associated with the virion’s capsid-bound tegument protein, pp150. Through deep sequencing, we show that these RNA sequences match human tRNAs, and we built atomic models using the most abundant tRNA species. Based on our models, tRNA recruitment is mediated by the electrostatic interactions between tRNA phosphate groups and the helix-loop-helix motif of HCMV pp150. The specificity of these interactions may explain the absence of such tRNA densities in murine cytomegalovirus and other human herpesviruses.

Structural Perspectives of Beak and Feather Disease Virus and Porcine Circovirus Proteins.

Circoviruses represent a rapidly expanding group of viruses that infect both vertebrate and invertebrate hosts. Members are responsible for diseases of veterinary and economic importance, including postweaning multisystemic wasting syndrome in pigs, and beak and feather disease (BFD) in birds. These viruses are associated with lymphoid depletion and immunosuppressive conditions in infected animals leading to systemic illness. Circoviruses are small nonenveloped DNA viruses containing a single-stranded circular genome, encoding two major proteins: the capsid-associated protein (Cap), comprising the entirety of the viral capsid, and the replication-associated protein (Rep). Cap is the only protein component of the virion and plays crucial roles throughout the virus replication cycle, including viral attachment, cell entry, genome uncoating, and packaging of newly formed viral particles. Rep mediates recognition of replication origin motifs in the viral genome sequence and is responsible for endonuclease activity enabling nicking of the circular DNA and initiation of rolling-circle replication (RCR). Porcine circovirus 2 (PCV2) was the first circovirus capsid structure to be solved at atomic resolution using X-ray crystallography. The structure revealed an assembly comprising 60 monomeric subunits to form virus-like particles. Each Cap monomer harbors a canonical viral jelly roll domain composed of two, four-stranded antiparallel β-sheets. Crystal structures of two distinct macromolecular assemblies from BFD virus Cap were also resolved at high resolution. In these structures, the exposure of the N-terminal arginine-rich motif, responsible for DNA binding and nuclear localization is reversed. Additional structural investigations have also elucidated a PCV2 type-specific neutralizing epitope, and interaction between the PCV2 capsid and polymers such as heparin. In this review, we provide a snapshot of the structural and functional aspects of circovirus proteins.

34. Development and Validation of Identity and Homogeneity Assays for AAV Preparations

Adeno-associated virus (AAV) vectors have emerged as key clinical candidates for gene therapy. Yet, the efficiency and safety of these 20-25 nm biological nanoparticles remain difficult to harmonize across pre-clinical studies due to the limitations of current analytical tools. The presence of residual DNA, protein contaminants, empty particles and VP subunits resulting from incomplete capsid assembly are variables that can strongly modulate the reliability of in vivo data and that, therefore, need to be closely monitored in AAV research laboratories. In this work, 70 AAV preparations, obtained with various production (baculo/Sf9 and triple transfection system) and purification (iodixanol gradient and double cesium-chloride gradient) techniques were analyzed using a thermal shift assay based on the fluorescent dye Sypro® Orange. The fluorescence fingerprint obtained did not only allow to discriminate various AAV serotypes based on their capsid melting temperatures, but also enabled to probe the homogeneity and purity of AAV vector preparations, investigated in parallel using dynamic light scattering (DLS) and polyacrylamide gel electrophoresis. In particular, a double fluorescence transition indicated the presence of capsid-associated protein contaminants whereas a high initial fluorescence background correlated with the presence of free protein contaminants and capsid subunits, possibly resulting from capsid degradation during vector purification or storage. The variability, sensitivity and precision of this assay were further investigated in two different AAV research laboratories. This simple, fast (analysis of 94 preps in ~6 hrs) and low-cost assay emerges as a relevant tool for characterization of AAV vector preparations and will help to increase the reliability of in vivo gene transfer studies.

Expression of immunogenic structural proteins of cyprinid herpesvirus 3 in vitro assessed using immunofluorescence.

Cyprinid herpesvirus 3 (CyHV-3), also called koi herpesvirus (KHV), is the aetiological agent of a fatal disease in carp and koi (Cyprinus carpio L.), referred to as koi herpesvirus disease. The virus contains at least 40 structural proteins, of which few have been characterised with respect to their immunogenicity. Indirect immunofluorescence assays (IFAs) using two epitope-specific monoclonal antibodies (MAbs) were used to examine the expression kinetics of two potentially immunogenic and diagnostically relevant viral antigens, an envelope glycoprotein and a capsid-associated protein. The rate of expression of these antigens was determined following a time-course of infection in two CyHV-3 susceptible cell lines. The results were quantified using an IFA, performed in microtitre plates, and image analysis was used to analyse confocal micrographs, enabling measurement of differential virus-associated fluorescence and nucleus-associated fluorescence from stacks of captured scans. An 8-tenfold increase in capsid-associated protein expression was observed during the first 5 days post-infection compared to a ≤2-fold increase in glycoprotein expression. A dominant protein of ~100 kDa reacted with the capsid-associated MAb (20F10) in western blot analysis. This band was also recognised by sera obtained from carp infected with CyHV-3, indicating that this capsid-associated protein is produced in abundance during infection in vitro and is immunogenic to carp. Mass spectrometry carried out on this protein identified it as a previously uncharacterised product of open reading frame 84. This abundantly expressed and immunogenic capsid-associated antigen may be a useful candidate for KHV serological diagnostics.Electronic supplementary materialThe online version of this article (doi:10.1186/s13567-015-0297-6) contains supplementary material, which is available to authorized users.

Dual ATPase and GTPase activity of the replication-associated protein (Rep) of beak and feather disease virus

BackgroundPsittacine beak and feather disease affects parrots resulting in an immunosuppressive disease that is often characterized by an abnormal shape and growth of the animal’s beak, feathers, and claws. Beak and feather disease virus (BFDV) is a single-stranded circular DNA virus and is classified as a member of the Circoviridae family. Two major open reading frames (ORFs) are known to encode the replication-associated (Rep) protein and the capsid-associated (Cap) protein. MethodsThe Rep and Cap genes of BFDV were fused with tags and then expressed and purified, respectively. Both the ATPase and GTPase activities of the recombinant Rep protein are measured. The substrate and ion preference, the optimal conditions, the effects of ATPase and GTPase inhibitors and the presence of Cap protein on the ATPase and GTPase activity of the Rep protein are examined. Finally, the effects of the Walker A motif, the Walker B motif, and a novel GYDG motif of the Rep protein on the ATPase and GTPase activities are studied by various mutants. ResultsThe recombinant Rep protein could display ATPase activity and GTPase activity. The Rep protein was able to hydrolyze both deoxyribonucleotides and ribonucleotides. Among nucleoside triphosphates and deoxynucleoside triphosphates, the substrate preference orders were found to be ATP>GTP>CTP≥UTP and dATP>dGTP>dTTP>dCTP, respectively. Both the ATPase and GTPase activity of the BFDV Rep protein required magnesium ions and the presence of calcium ions significantly inhibited the ATPase and GTPase activity of the Rep protein. The optimal temperatures for ATPase activity and GTPase activity were both 56 °C, while their optimal pH values were both pH 7.5. Both the ATPase activity and GTPase activity of the BFDV Rep protein were significantly down-regulated by polynucleotides and the dsDNA of 36 bp (located in origin of replication) of BFDV genome. The ATPase activity of the BFDV Rep protein was found to be more sensitive to sodium azide than sodium orthovanadate and N-ethylmaleimide. Linoleic acid more strongly inhibited the GTPase activity of the Rep protein than dynasore. This suggested the Rep protein of BFDV should be classified as an F-type ATPase and polyunsaturated fatty acid-sensitive GTPase. In the presence of 10 ng of the Cap protein, the ATPase activity and GTPase activity of the BFDV Rep protein were significantly increased. Furthermore, the BFDV Rep protein contains the Walker A motif, the Walker B motif and a novel GYDG motif. Both the ATPase activity and the GTPase activity of various deletion and site-directed mutants of the Rep protein affecting these motifs were significantly reduced, suggesting all the three motifs contribute to the ATPase and GTPase activities; specifically. In addition, the ATPase activity and GTPase activity of the deletion mutants of the Rep protein were reversed in the presence of the Cap protein. This is the first example of dual ATPase and GTPase activity being reported in the Rep protein of BFDV.

Structural determination of importin alpha in complex with beak and feather disease virus capsid nuclear localization signal

Circoviruses represent a rapidly increasing genus of viruses that infect a variety of vertebrates. Replication requires shuttling viral molecules into the host cell nucleus, a process facilitated by capsid-associated protein (Cap). Whilst a nuclear localization signal (NLS) has been shown to mediate nuclear translocation, the mode of nuclear transport remains to be elucidated. To better understand this process, beak and feather disease virus (BFDV) Cap NLS was crystallized with nuclear import receptor importin-α (Impα). Diffraction yielded structural data to 2.9Å resolution, and the binding site on both Impα and BFDV Cap NLS were well resolved. The binding mechanism for the major site is likely conserved across circoviruses as supported by the similarity of NLSs in circovirus Caps. This finding illuminates a crucial step for infection of host cells by this viral family, and provides a platform for rational drug design against the binding interface.

Differential expression of two isolates of beak and feather disease virus capsid protein in Escherichia coli

Expression of recombinant beak and feather disease virus (BFDV) capsid-associated protein (Cap) has relied on inefficient techniques that typically produce low yields or use specialized expression systems, which greatly increase the cost and expertise required for mass production. An Escherichia coli system was used to express recombinant BFDV Cap derived from two isolates of BFDV, from a Long-billed Corella (Cacatua tenuirostris) and an Orange-bellied parrot (OBP; Neophema chrysogaster). Purification by affinity and size exclusion chromatography was optimized through an iterative process involving screening and modification of buffer constituents and pH. A buffer containing glycerol, β-mercaptoethanol, Triton X-100, and a high concentration of NaCl at pH 8 was used to increase solubility of the protein. The final concentration of the corella-isolated BFDV protein was fifteen- to twenty-fold greater than that produced in previous publications using E. coli expression systems. Immunoassays were used to confirm the specific antigenicity of recombinant Cap, verifying its validity for use in continued experimentation as a potential vaccine, a reagent in diagnostic assays, and as a concentrated sample for biological discoveries.

Homology Modelling and Structural Comparisons of Capsid-Associated Proteins from Circoviruses Reveal Important Virus-Specific Surface Antigens

Circoviridae represent a growing family of small animal viruses. Some of these viruses have veterinary and medical importance, although, a vast amount of these newly discovered viruses have unknown effects on their hosts. The capsid-associated protein (Cap) of circoviruses is of interest because of its role in viral structure, immune evasion, host cell entry, and nuclear shuttling of viral components. The structure of the porcine circovirus 2 (PCV2) Cap has been solved and offered insight to these functions. Based on the crystallographic PCV2 Cap structure, models from circoviruses isolated from avian, fish, and mammalian hosts have been constructed and analyzed to better understand the roles of these proteins in the virus family. A high degree of conservation is observed in the models, however, the surface antigens differ among viruses. This is likely a reflection of the small genome harbored by circoviruses, and therefore the requirement of their few proteins to carry out specific vital functions, while maintaining enough variation to successfully infect their hosts. Here we describe the putative structures of a range of Cap proteins from circoviruses based on the crystallographic determination of porcine Cap, identifying key regions for function and inhibition of crystal formation.

Novel Mode of Phosphorylation-triggered Reorganization of the Nuclear Lamina during Nuclear Egress of Human Cytomegalovirus

The nucleocytoplasmic egress of viral capsids is a rate-limiting step in the replication of the human cytomegalovirus (HCMV). As reported recently, an HCMV-specific nuclear egress complex is composed of viral and cellular proteins, in particular protein kinases with the capacity to induce destabilization of the nuclear lamina. Viral protein kinase pUL97 and cellular protein kinase C (PKC) play important roles by phosphorylating several types of nuclear lamins. Using pUL97 mutants, we show that the lamin-phosphorylating activity of pUL97 is associated with a reorganization of nuclear lamin A/C. Either pUL97 or PKC has the potential to induce distinct punctate lamina-depleted areas at the periphery of the nuclear envelope, which were detectable in transiently transfected and HCMV-infected cells. Using recombinant HCMV, which produces green fluorescent protein-labeled viral capsids, the direct transition of viral capsids through these areas could be visualized. This process was sensitive to an inhibitor of pUL97/PKC activity. The pUL97-mediated phosphorylation of lamin A/C at Ser(22) generated a novel binding motif for the peptidyl-prolyl cis/trans-isomerase Pin1. In HCMV-infected fibroblasts, the physiological localization of Pin1 was altered, leading to recruitment of Pin1 to viral replication centers and to the nuclear lamina. The local increase in Pin1 peptidyl-prolyl cis/trans-isomerase activity may promote conformational modulation of lamins. Thus, we postulate a novel phosphorylation-triggered mechanism for the reorganization of the nuclear lamina in HCMV-infected cells.

The UL25 Gene Product of Herpes Simplex Virus Type 1 Is Involved in Uncoating of the Viral Genome

Studies on the herpes simplex virus type 1 UL25-null mutant KUL25NS have shown that the capsid-associated UL25 protein is required at a late stage in the encapsidation of viral DNA. Our previous work on UL25 with the UL25 temperature-sensitive (ts) mutant ts1204 also implicated UL25 in a role at very early times in the virus growth cycle, possibly at the stage of penetration of the host cell. We have reexamined this mutant and discovered that it had an additional ts mutation elsewhere in the genome. The ts1204 UL25 mutation was transferred into wild-type (wt) virus DNA, and the UL25 mutant ts1249 was isolated and characterized to clarify the function of UL25 at the initial stages of virus infection. Indirect immunofluorescence assays and in situ hybridization analysis of virus-infected cells revealed that the mutant ts1249 was not impaired in penetration of the host cell but had an uncoating defect at the nonpermissive temperature. When ts1249-infected cells were incubated initially at the permissive temperature to allow uncoating of the viral genome and subsequently transferred to the restrictive temperature, a DNA-packaging defect was evident. The results suggested that ts1249, like KUL25NS, had a block at a late stage of DNA packaging and that the packaged genome was shorter than the full-length genome. Examination of ts1249 capsids produced at the nonpermissive temperature revealed that, in comparison with wt capsids, they contained reduced amounts of UL25 protein, thereby providing a possible explanation for the failure of ts1249 to package full-length viral DNA.

Quantitative dissociation of archaeal virus SH1 reveals distinct capsid proteins and a lipid core

Viruses infecting archaeal cells are less well understood than those infecting eukaryotic and bacterial cells. Here we study the distribution of the structural proteins between the capsid and the membrane of icosahedral SH1 virus, an archaeal virus infecting extreme halophilic Haloarcula hispanica cells. General features such as morphology, linear dsDNA genome and presence of lipids suggest that it may belong to the recently proposed PRD1-adenovirus lineage of viruses. To investigate this we have initiated structural studies of the virion. Quantitative dissociation of SH1 by 3 M urea or by lowering the salt concentration identified a number of soluble capsid-associated proteins (VP2, VP3, VP4, VP6, VP7 and VP9). These released proteins left behind a particle, or lipid core, containing two major proteins VP10 and VP12 and viral phospholipids. VP1 was released from the lipid core in low ionic strength conditions but not with 3 M urea. Approximately half of the protein VP5 stayed with the lipid core and the other half was released. Analysis of the soluble capsid-associated proteins by their sedimentation and hydrodynamic properties suggests that the most abundant proteins, putative capsomers VP4 and VP7, form an intricate pattern of protein complexes. We also observed large differences in the sizes of the complexes determined by the two different methods suggesting an elongated overall structure for most of the capsid-associated proteins or protein complexes. This work verifies that there is an internal membrane vesicle residing inside the complex icosahedral capsid that is akin to the overall structure of PRD1-like viruses.

The Capsid-Associated UL25 Protein of the Alphaherpesvirus Pseudorabies Virus Is Nonessential for Cleavage and Encapsidation of Genomic DNA but Is Required for Nuclear Egress of Capsids

Homologs of the UL25 gene product of herpes simplex virus (HSV) have been identified in all three subfamilies of the Herpesviridae. However, their exact function during viral replication is not yet known. Whereas earlier studies indicated that the UL25 protein of HSV-1 is not required for cleavage of newly replicated viral DNA but is necessary for stable encapsidation (A. R. McNab, P. Desai, S. Person, L. Roof, D. R. Thompson, W. W. Newcomb, J. C. Brown, and F. L. Homa, J. Virol. 72:1060-1070, 1998), viral DNA packaging has recently been demonstrated to occur in the absence of UL25, although at significantly decreased levels compared to wild-type HSV-1 (N. Stow, J. Virol. 75:10755-10765 2001). To clarify the functional role of UL25 we analyzed the homologous protein of the alphaherpesvirus pseudorabies virus (PrV). PrV UL25 was found to be essential for viral replication, as a mutant virus lacking the UL25 protein required UL25-expressing cells for productive propagation. In the absence of the UL25 protein, newly replicated PrV DNA was cleaved and DNA-containing C-type capsids were detected in infected cell nuclei. However, although capsids were frequently found in close association with the inner nuclear membrane, nuclear egress was not observed. Consequently, no capsids were found in the cytoplasm, resulting in an inhibition of virion morphogenesis. In contrast, the formation of capsidless enveloped tegument structures (L particles) in the cytoplasm was readily observed. Thus, our data demonstrate that the PrV UL25 protein is not essential for cleavage and encapsidation of viral genomes, although both processes occur more efficiently in the presence of the protein. However, the presence of the PrV UL25 protein is a prerequisite for nuclear egress. By immunoelectron microscopy, we detected UL25-specific label on DNA-containing C capsids but not on other intranuclear immature or defective capsid forms. Thus, the PrV UL25 protein may represent the hitherto missing trigger that allows primary envelopment preferably of DNA-filled C capsids.

Composition of Pseudorabies Virus Particles Lacking Tegument Protein US3, UL47, or UL49 or Envelope Glycoprotein E

Proteins located in the tegument layer of herpesvirus particles play important roles in the replicative cycle at both early and late times after infection. As major constituents of the virion, they execute important functions in particular during formation of progeny virions. These functions have mostly been elucidated by construction and analysis of mutant viruses deleted in single or multiple tegument protein-encoding genes (reviewed in the work of T. C. Mettenleiter, Virus Res. 106:167-180, 2004). However, since tegument proteins have been shown to be involved in numerous protein-protein interactions, the impact of single protein deletions on the composition of the virus particle is unknown, but they could impair correct interpretation of the results. To analyze how the absence of single virion constituents influences virion composition, we established a procedure to assay relative amounts of virion structural proteins in deletion mutants of the alphaherpesvirus Pseudorabies virus (PrV) in comparison to wild-type particles. The assay is based on the mass spectrometric quantitation of virion protein-derived peptides carrying stable isotope mass tags. After deletion of the US3, UL47, UL49, or glycoprotein E gene, relative amounts of a capsid protein (UL38), a capsid-associated protein (UL25), several tegument proteins (UL36 and UL47, if present), and glycoprotein H were unaffected, whereas the content of other tegument proteins (UL46, UL48, and UL49, if present) varied significantly. In the case of the UL48 gene product, a specific increase in incorporation of a smaller isoform was observed after deletion of the UL47 or UL49 gene, whereas a larger isoform remained unaffected. The cellular protein actin was enriched in virions of mutants deficient in any of the tegument proteins UL47, UL49, or US3. By two-dimensional gel electrophoresis multiple isoforms of host cell-derived heat shock protein 70 and annexins A1 and A2 were also identified as structural components of PrV virions.

145. Detection of the Primary Destabilizing Modification of Liquid-Formulated Adenoviral Vectors by Anion-Exchange High Performance Liquid Chromatography

Anion-exchange high performance liquid chromatography (AEX- HPLC) has been widely used to assess the quantity, quality and stability of adenoviral vectors investigated in pre-clinical and clinical gene therapy studies. We have developed an AEX-HPLC method to analyze liquid-stored adenoviral vectors for changes during long- term storage in a variety of formulations at 5° and 25°C. Applying orthogonal methods, we have determined that AEX-HPLC retention time (RT) correlates with changes in physical and functional properties of the virus during storage. Three virus species with distinct physical and biological properties are identifiable by the AEX-HPLC method: (A) the native intact virus population having no RT shift, (B) a population undergoing a gradual rate of RT shift, and (C) a population traversing a phase of rapid RT shift. We have characterized the physical attributes of representative preparations of these three species using reversed-phase (RP) HPLC and quantitative anti-fiber western blots (WB) for capsid-associated viral protein content, picogreen dye binding assay for dye-accessable viral dsDNA content, and electron microscopy. In addition, we assessed the biological activity of the viral species by a virus-cell attachment assay, transgene expression assay and plaque assay. Our results show species A and B to be virions with complete vertices, termed “intact-capsid virions (ICV),” and fully biologically functional. Species B, although intact and fully functional, displays a modified capsid surface charge of increasing acidity, suggestive of surface protein deamidation. Specie C, though still containing the viral DNA core, is devoid of fiber and penton base complex (penton), and has consequently lost its cell-attachment function, thus is non-infectious. Accordingly, specie C has been termed “penton-vacant virion (PVV).” In conclusion, the retention time attribute of AEX-HPLC is sufficient to differentiate native ICV, deamidated ICV, and PVV populations as they occur along the instability pathway of liquid-stored adenoviral vectors.

Human Cytomegalovirus Labeled with Green Fluorescent Protein for Live Analysis of Intracellular Particle Movements

Human cytomegalovirus (HCMV) replicates in the nuclei of infected cells. Successful replication therefore depends on particle movements between the cell cortex and nucleus during entry and egress. To visualize HCMV particles in living cells, we have generated a recombinant HCMV expressing enhanced green fluorescent protein (EGFP) fused to the C terminus of the capsid-associated tegument protein pUL32 (pp150). The resulting UL32-EGFP-HCMV was analyzed by immunofluorescence, electron microscopy, immunoblotting, confocal microscopy, and time-lapse microscopy to evaluate the growth properties of this virus and the dynamics of particle movements. UL32-EGFP-HCMV replicated similarly to wild-type virus in fibroblast cultures. Green fluorescent virus particles were released from infected cells. The fluorescence stayed associated with particles during viral entry, and fluorescent progeny particles appeared in the nucleus at 44 h after infection. Surprisingly, strict colocalization of pUL32 and the major capsid protein pUL86 within nuclear inclusions indicated that incorporation of pUL32 into nascent HCMV particles occurred simultaneously with or immediately after assembly of the capsid. A slow transport of nuclear particles towards the nuclear margin was demonstrated. Within the cytoplasm, most particles performed irregular short-distance movements, while a smaller fraction of particles performed centripetal and centrifugal long-distance movements. Although numerous particles accumulated in the cytoplasm, release of particles from infected cells was a rare event, consistent with a release rate of about 1 infectious unit per h per cell in HCMV-infected fibroblasts as calculated from single-step growth curves. UL32-EGFP-HCMV will be useful for further investigations into the entry, maturation, and release of this virus.

Molecular analysis of a recombinant M-MuLV/RaLV retrovirus

A replication-competent retrovirus was isolated from Rat1 cells after stable transfection of a defective Moloney murine leukemia virus (M-MuLV) provirus bearing mutations in two conserved cysteines of the TM protein. Immunoprecipitation of the viral proteins indicated the infectious virus is not related to M-MuLV. Electron microscopy of budding virions revealed a mammalian type C virus. The host range of the virus is limited to rat cells. N-terminal sequence analysis of the capsid-associated protein identified the virus to be related to rat leukemia virus (RaLV). Analysis of the cloned sequences indicated a recombinant provirus with a genetic organization in which the leader region and open reading frames of the endogenous RaLV are flanked by identical M-MuLV LTRs at both ends. These results highlight the effects of exogenous viral infection on endogenous viruses.

The Lymantria dispar nucleopolyhedrovirus contains the capsid-associated p24 protein gene.

During the course of investigations on a wild-type strain of Lymantria dispar multinucleocapsid nucleopolyhedrovirus (LdMNPV), a region of the viral genome was analyzed and found to contain 697 bp that is lacking in the sequenced strain (5-6) of LdMNPV (Kuzio et al., Virology 253, 17-34, 1999). The sequenced strain of LdMNPV contains a mutation in the 25 K few polyhedra (FP) gene, and exhibits the phenotype of a FP mutant. The additional sequence was located at approximately 81.4 map units within the viral genome, and was found in 10 different wild-type LdMNPV genotypic variants analyzed. Since the additional sequence wasfound in all wild-type virus strains analyzed, this sequence should be included in the representative LdMNPV genome. Sequence analysis of the genomic region containing the additional sequences revealed the presence of a homologue of the Autographa californica MNPV capsid-associated p24 gene (ORF 129). This gene, absent in LdMNPV isolate 5-6, is also present in the Orgyia pseudotsugata MNPV, Bombyx mori NPV, Spodoptera exigua MNPV, S. litura MNPV, Mamestra configurata MNPV, Helicoverpa armigera SNPV, H. zea SNPV, Buzura suppressaria SNPV, Xestia c-nigrum granulovirus, Plutella xylostella GV, and Cydia pomonella GV.

Herpes simplex virus encodes a virion‐associated protein which promotes long cellular processes in over‐expressing cells

Herpes simplex virus (HSV) possesses a number of accessory genes which are dispensable for replication in cell culture. A previous study showed that the UL21 gene product of HSV type 1 is a virion component that is not necessary for viral replication. The function of the gene product remains unknown. We found that the HSV-1 UL21 gene product, a capsid-associated tegument protein with an apparent molecular mass of 62 kDa, promotes the outgrowth of long cellular processes when it is over-expressed in non-neural cells. The UL21 protein co-localizes and physically associates with microtubules in the long processes. Analysis using mutant proteins implicates a proline-rich region in promotion of the processes. The results suggest that the UL21 protein, like tau and other MAPs, promotes the process by directly or indirectly interacting with microtubules and facilitates the intracellular transport of the virus.

A virally encoded chaperone specialized for folding of the major capsid protein of African swine fever virus.

It is generally believed that cellular chaperones facilitate the folding of virus capsid proteins, or that capsid proteins fold spontaneously. Here we show that p73, the major capsid protein of African swine fever virus (ASFV) failed to fold and aggregated when expressed alone in cells. This demonstrated that cellular chaperones were unable to aid the folding of p73 and suggested that ASFV may encode a chaperone. An 80-kDa protein encoded by ASFV, termed the capsid-associated protein (CAP) 80, bound to the newly synthesized capsid protein in infected cells. The 80-kDa protein was released following conformational maturation of p73 and dissociated before capsid assembly. Coexpression of the 80-kDa protein with p73 prevented aggregation and allowed the capsid protein to fold with kinetics identical to those seen in infected cells. CAP80 is, therefore, a virally encoded chaperone that facilitates capsid protein folding by masking domains exposed by the newly synthesized capsid protein, which are susceptible to aggregation, but cannot be accommodated by host chaperones. It is likely that these domains are ultimately buried when newly synthesized capsid proteins are added to the growing capsid shell.