Summary Lassa fever virus (LASV) causes thousands of deaths yearly and is a biological threat agent, for which there is no vaccine and limited therapy1. The nucleoprotein (NP) of LASV plays essential roles in viral RNA synthesis and immune suppression2-6, the molecular mechanisms of which are poorly understood. Here, we report the crystal structure of LASV NP at 1.80 Angstrom resolution, which reveals N- and C-domains with structures unlike any of the reported viral NPs7-10. The N domain folds into a novel structure with a deep cavity for binding the m7GpppN cap structure that is required for viral RNA transcription, whereas the C domain contains 3′-5′ exoribonuclease activity involved in suppressing interferon induction. This is the first X-ray crystal structure solved for an arenaviral NP, which reveals its unexpected functions and suggests unique mechanisms in cap binding and immune evasion. These findings provide great potential for vaccine and drug development.
The early steps of HIV-1 infection, such as uncoating, reverse transcription, nuclear import, and transport to integration sites are incompletely understood. Here, we imaged nuclear entry and transport of HIV-1 replication complexes in cell lines, primary monocyte-derived macrophages (MDMs) and CD4 + T cells. We show that viral replication complexes traffic to and accumulate within nuclear speckles and that these steps precede the completion of viral DNA synthesis. HIV-1 transport to nuclear speckles is dependent on the interaction of the capsid proteins with host cleavage and polyadenylation specificity factor 6 (CPSF6), which is also required to stabilize the association of the viral replication complexes with nuclear speckles. Importantly, integration site analyses reveal a strong preference for HIV-1 to integrate into speckle-associated genomic domains. Collectively, our results demonstrate that nuclear speckles provide an architectural basis for nuclear homing of HIV-1 replication complexes and subsequent integration into associated genomic loci.
Genotype and Subtype Profiling of PSI-7977 as a Nucleotide Inhibitor of Hepatitis C Virus
PSI-7977, a prodrug of 2=-F-2=-C-methyluridine monophosphate, is the purified diastereoisomer of PSI-7851 and is currently being investigated in phase 3 clinical trials for the treatment of hepatitis C. In this study, we profiled the activity of PSI-7977 and its ability to select for resistance using a number of different replicon cells. Results showed that PSI-7977 was active against genotype (GT) 1a, 1b, and 2a (strain JFH-1) replicons and chimeric replicons containing GT 2a (strain J6), 2b, and 3a NS5B polymerase. Cross-resistance studies using GT 1b replicons confirmed that the S282T change conferred resistance to PSI-7977. Subsequently, we evaluated the ability of PSI-7977 to select for resistance using GT 1a, 1b, and 2a (JFH-1) replicon cells. S282T was the common mutation selected among all three genotypes, but while it conferred resistance to PSI-7977 in GT 1a and 1b, JFH-1 GT 2a S282T showed only a very modest shift in 50% effective concentration (EC 50 ) for PSI-7977. Sequence analysis of the JFH-1 NS5B region indicated that additional amino acid changes were selected both prior to and after the emergence of S282T. These include T179A, M289L, I293L, M434T, and H479P. Residues 179, 289, and 293 are located within the finger and palm domains, while 434 and 479 are located on the surface of the thumb domain. Data from the JFH-1 replicon variants showed that amino acid changes within the finger and palm domains together with S282T were required to confer resistance to PSI-7977, while the mutations on the thumb domain serve to enhance the replication capacity of the S282T replicons. Hepatitis C virus (HCV) currently infects more than 170 million people worldwide and is the leading cause of chronic liver disease and liver transplantation in the United States. HCV is a single plus-strand RNA virus about 9.6 kb in genome size and contains one open reading frame that encodes 10 structural and nonstructural (NS) proteins. The structural proteins (core, E1, and E2), which constitute the viral capsid and envelope proteins, are located at the amino terminus, followed by p7, which oligomerizes to form an ion channel critical for viral assembly, and the nonstructural proteins (NS2, NS3, NS4A, NS4B, NS5A, and NS5B), which are responsible for viral replication (35). Recently, two antiviral agents have been approved, in combination with pegylated alpha interferon and ribavirin (Peg-IFN/RBV), to treat patients infected with genotype (GT) 1 HCV. Both of these compounds, boceprevir (Victrelis) and telaprevir (Incivek), target the NS3/4A protease and inhibit HCV replication by blocking processing of NS3, NS4A/B, and NS5A/B (25, 33). These treatments showed improvement over Peg-IFN/RBV; however, patients may develop additional side effects corresponding to each of these antiviral compounds (4). Furthermore, viral resistance against these compounds has emerged both in vitro and in vivo as a result of the high genetic diversity of HCV and error-prone nature of the HCV NS5B RNA-dependent RNA polymerase (12). Therefore, research...
Several arenaviruses can cause hemorrhagic fever diseases (VHFs) in humans, the pathogenic mechanism of which is poorly understood due to their virulent nature and the lack of molecular clones. A safe, convenient, and economical small animal model of arenavirus hemorrhagic fever is based on guinea pigs infected by the arenavirus Pichinde (PICV). PICV does not cause disease in humans, but an adapted strain of PICV (P18) causes a disease in guinea pigs that mimics arenavirus hemorrhagic fever in humans in many aspects, while a low-passaged strain (P2) remains avirulent in infected animals. In order to identify the virulence determinants within the PICV genome, we developed the molecular clones for both the avirulent P2 and virulent P18 viruses. Recombinant viruses were generated by transfecting plasmids that contain the antigenomic L and S RNA segments of PICV under the control of the T7 promoter into BSRT7-5 cells, which constitutively express T7 RNA polymerase. By analyzing viral growth kinetics in vitro and virulence in vivo, we show that the recombinant viruses accurately recapitulate the replication and virulence natures of their respective parental viruses. Both parental and recombinant virulent viruses led to high levels of viremia and titers in different organs of the infected animals, whereas the avirulent viruses were effectively controlled and cleared by the hosts. These novel infectious clones for the PICV provide essential tools to identify the virulence factors that are responsible for the severe VHF-like disease in infected animals.Arenaviruses are enveloped RNA viruses with single-stranded ambisense RNA genomes (6). The genomes of these viruses consist of two RNA segments, the large (L) segment of ϳ7.2 kb and the small (S) segment of ϳ3.4 kb (6). The L RNA segment encodes the viral polymerase L protein in a negative orientation and a small multifunctional Z protein in a positive sense. The S RNA segment encodes the nucleoprotein NP in a negative orientation and the envelope glycoprotein precursor GPC in a positive sense (6). The terminal 19 nucleotides (nt) from both ends of the segments are imperfectly complementary to each other and are predicted to form the panhandle structures that serve as the cis-acting elements required for viral RNA transcription and replication (15,23,24,33). A unique feature of the arenavirus genomic RNAs is the noncoding intergenic regions located between the two open reading frames (6). They range from 59 to 217 nt in length and are predicted to form one to three energetically stable stem-loop structures (6, 40) that are proposed to contribute to transcriptional termination. Currently, the only available molecular clone of arenavirus was developed for the prototype lymphocytic choriomeningitis virus (LCMV) (13,38). This system has served as an invaluable tool to study the biological functions of arenavirus proteins and RNA elements.
Arenaviruses cause severe hemorrhagic fever diseases in humans, and there are limited preventative and therapeutic measures against these diseases. Previous structural and functional analyses of arenavirus nucleoproteins (NPs) revealed a conserved DEDDH exoribonuclease (RNase) domain that is important for type I interferon (IFN) suppression, but the biological roles of the NP RNase in viral replication and host immune suppression have not been well characterized. Infection of guinea pigs with Pichinde virus (PICV), a prototype arenavirus, can serve as a surrogate small animal model for arenavirus hemorrhagic fevers. In this report, we show that mutation of each of the five RNase catalytic residues of PICV NP diminishes the IFN suppression activity and slightly reduces the viral RNA replication activity. Recombinant PICVs with RNase catalytic mutations can induce high levels of IFNs and barely grow in IFN-competent A549 cells, in sharp contrast to the wild-type (WT) virus, while in IFNdeficient Vero cells, both WT and mutant viruses can replicate at relatively high levels. Upon infection of guinea pigs, the RNase mutant viruses stimulate strong IFN responses, fail to replicate productively, and can become WT revertants. Serial passages of the RNase mutants in vitro can also generate WT revertants. Thus, the NP RNase function is essential for the innate immune suppression that allows the establishment of a productive early viral infection, and it may be partly involved in the process of viral RNA replication. IMPORTANCEArenaviruses, such as Lassa, Lujo, and Machupo viruses, can cause severe and deadly hemorrhagic fever diseases in humans, and there are limited preventative and treatment options against these diseases. Development of broad-spectrum antiviral drugs depends on a better mechanistic understanding of the conserved arenavirus proteins in viral infection. The nucleoprotein (NPs) of all arenaviruses carry a unique exoribonuclease (RNase) domain that has been shown to be critical for the suppression of type I interferons. However, the functional roles of the NP RNase in arenavirus replication and host immune suppression have not been characterized systematically. Using a prototype arenavirus, Pichinde virus (PICV), we characterized the viral growth and innate immune suppression of recombinant RNase-defective mutants in both cell culture and guinea pig models. Our study suggests that the NP RNase plays an essential role in the suppression of host innate immunity, and possibly in viral RNA replication, and that it can serve as a novel target for developing antiviral drugs against arenavirus pathogens.
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