Putative domain-domain interactions in the vesicular stomatitis virus L polymerase protein appendage region.

UNLABELLED: The multidomain polymerase protein (L) of nonsegmented negative-strand (NNS) RNA viruses catalyzes transcription and replication of the virus genome. The N-terminal half of the protein forms a ring-like polymerase structure, while the C-terminal half encoding viral mRNA transcript modifications consists of a flexible appendage with three distinct globular domains. To gain insight into putative transient interactions between L domains during viral RNA synthesis, we exchanged each of the four distinct regions encompassing the appendage region of vesicular stomatitis virus (VSV) Indiana serotype L protein with their counterparts from VSV New Jersey and analyzed effects on virus polymerase activity in a minigenome system. The methyltransferase domain exchange yielded a fully active polymerase protein, which functioned as well as wild-type L in the context of a recombinant virus. Exchange of the downstream C-terminal nonconserved region abolished activity, but coexchanging it with the methyltransferase domain generated a polymerase favoring replicase over transcriptase activity, providing strong evidence of interaction between these two regions. Exchange of the capping enzyme domain or the adjacent nonconserved region thought to function as an "unstructured" linker also abrogated polymerase activity even when either domain was coexchanged with other appendage domains. Further probing of the putative linker segment using in-frame enhanced green fluorescent protein (EGFP) insertions similarly abrogated activity. We discuss the implications of these findings with regard to L protein appendage domain structure and putative domain-domain interactions required for polymerase function. IMPORTANCE: NNS viruses include many well-known human pathogens (e.g., rabies, measles, and Ebola viruses), as well as emerging viral threats (e.g., Nipah and Hendra viruses). These viruses all encode a large L polymerase protein similarly organized into multiple domains that work in concert to enable virus genome transcription and replication. But how the unique L protein carries out the multiplicity of individual steps in these two distinct processes is poorly understood. Using two different approaches, i.e., exchanging individual domains in the C-terminal appendage region of the protein between two closely related VSV serotypes and inserting unrelated protein domains, we shed light on requirements for domain-domain interactions and domain contiguity in polymerase function. These findings further our understanding of the conformational dynamics of NNS L polymerase proteins, which play an essential role in the pathogenic properties of these viruses and represent attractive targets for the development of antiviral measures.

Asymmetric packaging of polymerases within vesicular stomatitis virus.

Vesicular stomatitis virus (VSV) is a prototypic negative sense single-stranded RNA virus. The bullet-shape appearance of the virion results from tightly wound helical turns of the nucleoprotein encapsidated RNA template (N-RNA) around a central cavity. Transcription and replication require polymerase complexes, which include a catalytic subunit L and a template-binding subunit P. L and P are inferred to be in the cavity, however lacking direct observation, their exact position has remained unclear. Using super-resolution fluorescence imaging and atomic force microscopy (AFM) on single VSV virions, we show that L and P are packaged asymmetrically towards the blunt end of the virus. The number of L and P proteins varies between individual virions and they occupy 57 ± 12 nm of the 150 nm central cavity of the virus. Our finding positions the polymerases at the opposite end of the genome with respect to the only transcriptional promoter.

Insertion of enhanced green fluorescent protein in a hinge region of vesicular stomatitis virus L polymerase protein creates a temperature-sensitive virus that displays no virion-associated polymerase activity in vitro.

The RNA-dependent RNA polymerase of viruses belonging to the order Mononegavirales is part of a large multifunctional L protein that also catalyzes viral mRNA capping and cap methylation. The L protein of this diverse group of agents displays six blocks of conserved sequences. The precise relationship between these conserved regions and individual functions is largely unknown, except for "domain" VI that clearly encodes a viral mRNA cap methylase. The L protein of morbilliviruses (family Paramyxoviridae) was reported to tolerate insertion of the enhanced green fluorescent protein (EGFP) in a region just upstream of domain VI. Recombinant viruses with this insertion grow well in cell culture but are highly attenuated in animal hosts. We show here that the L protein of vesicular stomatitis virus (VSV), the prototype of the Rhabdoviridae family, also tolerates insertion of EGFP at a similar site. The modified protein (L(EGFP)) and the resultant recombinant virus both demonstrated a sharp temperature-sensitive phenotype for polymerase activity, with reduced activity at 37 degrees C and no activity at 37.5 degrees C. Neither translation nor methylation of mutant virus transcripts was affected at 37 degrees C. Curiously, mutant virus grown at permissive temperature contained about threefold-less L protein than the wild-type virus did and displayed no virion-associated polymerase activity in vitro. These findings support the notion that a flexible "hinge" region separates the cap methylase domain of L proteins from upstream functions and open up a number of avenues for studies of L-protein function in the more-tractable VSV model system.

Overproduction of double-stranded RNA in vesicular stomatitis virus-infected cells activates a constitutive cell-type-specific antiviral response.

In a companion paper (D. Ostertag, T. M. Hoblitzell-Ostertag, and J. Perrault, J. Virol. 81:492-502, 2007), we provided indirect evidence that cell-type-specific growth restriction of the vesicular stomatitis virus (VSV) polR mutants may be due to enhanced production of double-stranded RNA (dsRNA). We show here that polR growth in mouse L-929 cells was rescued by vaccinia virus coinfection and that sole expression of the vaccinia virus dsRNA-binding E3L protein, via coinfection with an engineered VSV minigenome, also restored polR growth. Expression of dsRNA-binding protein NS1A or NS1B from influenza virus, but not C protein from Sendai virus, which does not bind dsRNA, likewise effected polR rescue. The N-terminal dsRNA-binding domain of NS1A, only 73 amino acids in length, but not a full-size mutant NS1A lacking dsRNA-binding activity, restored polR growth. Both key aspects of polR growth restriction, namely inhibition of genome replication and release of low-infectivity virus particles, were countered by expression of the dsRNA-binding proteins. We tested the effects of overproducing dsRNA in wild-type VSV infections by coinfecting cells with a VSV recombinant expressing the sense strand of the enhanced green fluorescent protein gene (VSV-GFP) and one expressing the antisense strand (VSV-PFG). These coinfections mimicked all aspects of polR restriction, including host range, lack of effect on transcription, reduced virus particle infectivity, and insensitivity to inhibition of host gene transcription or dsRNA-activated protein kinase activity. We conclude that, for some cell types, overproduction of dsRNA during VSV infection triggers an immediate and constitutive host cell antiviral effector response independent of interferon induction or signaling.

Cell-type-specific growth restriction of vesicular stomatitis virus polR mutants is linked to defective viral polymerase function.

Vesicular stomatitis virus polR mutants synthesize defective RNA replication products in vitro and display growth restriction in some cultured cells (J. L. Chuang, R. L. Jackson, and J. Perrault, Virology 229:57-67, 1997). We show here that a recombinant virus carrying the polR N protein mutation (R179H) yielded approximately 100-fold- and approximately 40-fold-lower amounts of infectious virus than the wild type in mouse L-929 and rat 3Y1 cells, respectively, but only approximately 3-fold less in hamster BHK cells. Virus genome accumulation was inhibited 6- to 10-fold in restricting cells, but transcription was not affected. No defect in encapsidation of replication products was detected, but virus protein accumulation was reduced two- to threefold in both restricting and nonrestricting cells. polR virus particles released from the latter were 5- to 10-fold less infectious than the wild type but showed no difference in protein composition. Phosphorylation of the alpha subunit of eukaryotic translation initiation factor 2 (eIF-2alpha) was enhanced approximately 3-fold in polR versus wild-type virus-infected L-929 cells, but neither inhibition of host gene transcription nor inhibition of double-stranded RNA (dsRNA)-activated protein kinase showed significant effects on restriction. Conditioned medium studies revealed no evidence for secretion of antiviral factors from restricting cells. We conclude that the block in polR growth is due to the combined effect of reduced genome replication and lower infectivity of released virus particles and may be due to overproduction of dsRNA. An accompanying paper (D. Ostertag, T. M. Hoblitzell-Ostertag, and J. Perrault, J. Virol. 81:503-513, 2007) provides compelling evidence for the role of dsRNA in this unique restriction phenomenon.

Antitrypanosomal activity of 5'-deoxy-5'-(iodomethylene)adenosine and related 6-N-cyclopropyladenosine analogues.

Treatment of the 6-N-cyclopropyl-2',3'-di-O-isopropylideneadenosine 5'-aldehyde with sulfone-stabilized phosphonate or fluorophosphonate reagents followed by stannyldesulfonylations and subsequent iodo- or protiodestannylation gave 6-N-cyclopropyl-5'-deoxy-5'-(iodomethylene)adenosine 8b or its 5'-fluoromethylene analogue 11. Treatment of the 5'-aldehyde with hydroxylamine or dibromomethylene- or cyanomethylene-stabilized Wittig reagents and deprotections gave the oxime 4b, 5'-cyanomethylene 5b, and 5'-dibromomethylene 13b analogues. Dehydrobromination of 13b gave acetylenic compound 14b. From the tested 6-N-cyclopropyladenosine analogues modified at the 5' carbon, the 5'-iodomethylene 8b had the most potent activity against Trypanosoma brucei in vitro with an IC50 of 12 microg/mL. The IC50 value was 19 microg/mL for both the 5'-fluoromethylene 11 and the 5'-cyanomethylene 5b compounds. The (E)-5'-deoxy-5'-(iodomethylene)adenosine 2a, a known inhibitor of AdoHcy hydrolase not modified with a cyclopropyl ring at 6-amino group, also inhibited T. brucei with an IC50 of 9 microg/mL. In contrast to some other adenosine analogues modified at C5', the 6-N-cyclopropyladenosine analogues described here do not exhibit an inhibitory effect on AdoHcy hydrolase and displayed only marginal antiviral activity.