Common and unique mechanisms of filamentous actin formation by viruses of the genus Orthorubulavirus.

We previously found that infection with human parainfluenza virus type 2 (hPIV-2), a member of the genus Orthorubulavirus, family Paramyxoviridae, causes filamentous actin (F-actin) formation to promote viral growth. In the present study, we investigated whether similar regulation of F-actin formation is observed in infections with other rubulaviruses, such as parainfluenza virus type 5 (PIV-5) and simian virus 41 (SV41). Infection with these viruses caused F-actin formation and RhoA activation, which promoted viral growth. These results indicate that RhoA-induced F-actin formation is important for efficient growth of these rubulaviruses. Only SV41 and hPIV-2 V and P proteins bound to Graf1, while the V and P proteins of PIV-5, mumps virus, and hPIV-4 did not bind to Graf1. In contrast, the V proteins of these rubulaviruses bound to both inactive RhoA and profilin 2. These results suggest that there are common and unique mechanisms involved in regulation of F-actin formation by members of the genus Orthorubulavirus.

Sumoylation of the P protein at K254 plays an important role in growth of parainfluenza virus 5.

The P protein of parainfluenza virus 5 (PIV5) is an essential cofactor of the viral RNA-dependent RNA polymerase. Phosphorylation of the P protein can positively or negatively regulate viral gene expression, depending on the precise phosphorylation sites. Sumoylation, a process of adding small ubiquitin-like modifier (SUMO) to proteins posttranslationally, plays an important role in regulating protein function. In this study, we have found that the P protein of PIV5 was sumoylated with SUMO1 in both transfected and infected cells. The K254 residue of the P protein is within a consensus sumoylation motif. Mutation of the P protein at K254 to arginine (P-K254R) reduced PIV5 minigenome activity, as well as the sumoylation level of the P protein. Incorporation of K254R into a recombinant PIV5 (rPIV5-P-K254R) resulted in a virus that grew to a lower titer and had lower levels of viral RNA synthesis and protein expression than wild-type PIV5, suggesting that sumoylation of the P protein at K254 is important for PIV5 growth. Biochemical studies did not reveal any defect of P-K254R in its interactions with viral proteins NP and L or formation of homotetramers. We propose that sumoylation of the P protein at K254 regulates PIV5 gene expression through a host protein.

Identification of a phosphorylation site within the P protein important for mRNA transcription and growth of parainfluenza virus 5.

The viral RNA-dependent RNA polymerase (vRdRp) of paramyxovirus consists of the large (L) protein and the phosphoprotein (P). P is heavily phosphorylated, and it is thought that the phosphorylation of P plays a role in regulating viral RNA synthesis. However, no phosphorylation site within the P protein in paramyxovirus has been identified as playing a positive role in viral RNA synthesis in virus infection. Using mass spectrometry analysis, the threonine residue at position 286 of P of parainfluenza virus 5 (PIV5) was found phosphorylated. Mutation of T286 to alanine (T286A), aspartic acid (T286D), or glutamic acid (T286E) reduced minigenome activity. Recombinant virus containing a mutation at the T286 position (rPIV5-P-T286A) grew slower than wild-type virus; viral mRNA synthesis and protein expression of rPIV5-P-T286A were delayed. Biochemical studies showed that the binding of NP or L protein with the P mutants or tetramer formation by the mutant P proteins was unaltered from that for wild-type P. While we failed to rescue rPIV5-P-T286E virus, several revertant viruses were obtained. All non-wild-type revertants had mutations at T286 and showed defects in both minigenome activity and viral growth. This is the first time that a phosphorylation site within the P protein in paramyxovirus has been found to play a positive role in viral mRNA synthesis and virus growth.

Viral morphogenesis and morphological changes in human neuronal cells following Tioman and Menangle virus infection.

Tioman virus (TioPV) and Menangle virus (MenPV) are two antigenically and genetically related paramyxoviruses (genus: Rubulavirus, family: Paramyxoviridae) isolated from Peninsular Malaysia (2001) and Australia (1997), respectively. Both viruses are potential zoonotic agents. In the present study, the infectivity, growth kinetics, morphology and morphogenesis of these two paramyxoviruses in a human neuronal cell (SK-N-SH) line were investigated. Sub-confluent SK-N-SH cells were infected with TioPV and MenPV at similar multiplicity of infection. These cells were examined by conventional and immunoelectron microscopy, and virus titres in the supernatants were assayed. Syncytia were observed for both infections in SK-N-SH cells and were more pronounced during the early stages of TioPV infection. The TioPV titre increased consistently (10(1)) every 12 h after infection. In MenPV-infected cells, cellular material was frequently observed within budding virions, and microfilaments and microtubules were abundant. Viral budding was common, and extracellular MenPVs tended to be more pleomorphic compared to TioPVs, which appeared to be more spherical in appearance. The MenPV cytoplasmic viral inclusion appeared to be comparatively smaller, loose and interspersed with randomly scattered circle-like particles, whereas huge tubule-like cytoplasmic inclusions were observed in TioPV-infected cells. Both viruses also displayed different cellular pathology in the SK-N-SH cells. The intracellular ultrastructural characteristics of these two viruses in infected neuronal cells may allow them to be differentiated by electron microscopy.

Substituted benzimidazoles with nanomolar activity against respiratory syncytial virus.

A cell-based assay was used to discover compounds inhibiting respiratory syncytial virus (RSV)-induced fusion in HeLa/M cells. A lead compound was identified and subsequent synthesis of >300 analogues led to the identification of JNJ 2408068 (R170591), a low molecular weight (MW 395) benzimidazole derivative with an EC(50) (0.16 nM) against some lab strains almost 100,000 times better than that of ribavirin (15 microM). Antiviral activity was confirmed for subgroup A and B clinical isolates of human RSV and for a bovine RSV isolate. The compound did not inhibit the growth of representative viruses from other Paramyxovirus genera, i.e. HPIV2 and Mumps Virus (genus Rubulavirus), HPIV3 (genus Respirovirus), Measles virus (genus Morbillivirus) and hMPV. Efficacy in cytopathic effect inhibition assays correlated well with efficacy in virus yield reduction assays. A concentration of 10nM reduced RSV production 1000-fold in multi-cycle experiments, irrespective of the multiplicity of infection. Time of addition studies pointed to a dual mode of action: inhibition of virus-cell fusion early in the infection cycle and inhibition of cell-cell fusion at the end of the replication cycle. Two resistant mutants were raised and shown to have single point mutations in the F-gene (S398L and D486N). JNJ 2408068 was also shown to inhibit the release of proinflammatory cytokines IL-6, IL-8 and Rantes from RSV-infected A549 cells.

Increased readthrough transcription across the simian virus 5 M-F gene junction leads to growth defects and a global inhibition of viral mRNA synthesis.

Recombinant simian virus 5 (rSV5) mutants containing substitutions in the M-F intergenic region were generated to determine the effect of increased readthrough transcription on the paramyxovirus growth cycle. We have previously shown, using an SV5 dicistronic minigenome, that replacement of the 22-base M-F intergenic region with a foreign sequence results in a template (Rep22) that directs very high levels of M-F readthrough transcription. An rSV5 containing the Rep22 substitution grew slower and to final titers that were 50- to 80-fold lower than those of wild-type (WT) rSV5. Cells infected with the Rep22 virus produced very low levels of monocistronic M and F mRNA, consistent with the M-F readthrough phenotype. Surprisingly, Rep22 virus-infected cells also displayed a global decrease in the accumulation of viral mRNA from genes located upstream and downstream of the M-F junction, and overall viral protein synthesis was reduced. Second-site revertants of the Rep22 virus that had regained WT transcription and growth properties contained a single base substitution that increased the M gene end U tract from four to eight residues, suggesting that the growth defects originated from higher-than-normal M-F readthrough transcription. Thus, the primary growth defect for the Rep22 virus appears to be in viral RNA synthesis and not in morphogenesis. A second rSV5 virus (G14), which contained a different foreign M-F intergenic sequence, grew to similar or slightly higher titers than WT rSV5 in some cell types and produced ~1.5- to 2-fold more mRNA and viral protein. The data support the hypothesis that inhibition of Rep22 virus growth is due to increased access by the polymerase to the 5' end of the genome and to the resulting overexpression of L protein. We propose that the elevated naturally occurring M-F readthrough which is characteristic of many paramyxoviruses serves as a mechanism to fine-tune the level of polymerase that is optimal for virus growth.

Incomplete replication of human parainfluenza virus type 4 in LLC-MK2 cells and in L929 cells.

Human parainfluenza virus type 4A (hPIV-4A) and type 4B (hPIV-4B) were tested for their ability to replicate in the monkey kidney LLC-MK2 cell line (MK2 cells) and the murine L929 cell line (L929 cells). These cells are normally non-permissive for replication of hPIV-4; however, treatment with acetylated trypsin led to virus replication in MK2 cells, but was less effective for L929 cells. Endogenously produced interferon (IFN) played no role in virus replication in L929 cells. Synthesis of virus-specific polypeptides was suppressed in L929 cells. Whereas NP-mRNA and HN-mRNA were detected in MK2 cells, no HN-mRNA was detected in L929 cells. These results indicate that hPIV-4 can infect both MK2 cells and L929 cells. In MK2 cells, when protease exists in the extracellular medium, hPIV-4 exhibits multistep growth. In L929 cells, however, the cause of incomplete replication might be lack of other unknown factors.

Establishment and characterisation of a porcine rubulavirus (LPMV) persistent infection in porcine kidney cells.

Porcine rubulavirus (LPMV) can establish persistent infections in porcine kidney cells. Cell cultures characterised at passages 25 and 65 demonstrated haemadsorption, formation of syncytia, and a slower growth rate. The nucleoprotein (NP) and haemagglutinin-neuraminidase (HN) protein were present in all cells, although not to the same extent as in wild type infected cells. Incubation of the cell cultures with virus neutralising antibodies could not cure them from the infection. The cells were resistant to LPMV high multiplicity superinfection, but lysed rapidly upon infection with VSV. These cells thus fulfilled the criteria of a true persistent infection. Viral particles were released into the medium from the persistently infected cells as measured by HA and infection of PK-15 cells with medium from the persistently infected cells. The infectious titer of the virus released from the persistently infected cells was 3 logs lower compared to wild type virus, the HN titer still being comparable. Virus released from the persistently infected cells was unable to cause a lytic infection in PK-15 cells, and showed a reduced ability to spread when compared to a LPMV lytic infection.