Mosaic evolution of the severe acute respiratory syndrome coronavirus.
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Severe acute respiratory syndrome (SARS) is a deadly form of pneumonia caused by a novel coronavirus, a viral family responsible for mild respiratory tract infections in a wide variety of animals including humans, pigs, cows, mice, cats, and birds. Analyses to date have been unable to identify the precise origin of the SARS coronavirus. We used Bayesian, neighbor-joining, and split decomposition phylogenetic techniques on the SARS virus replicase, surface spike, matrix, and nucleocapsid proteins to reveal the evolutionary origin of this recently emerging infectious agent. The analyses support a mammalian-like origin for the replicase protein, an avian-like origin for the matrix and nucleocapsid proteins, and a mammalian-avian mosaic origin for the host-determining spike protein. A bootscan recombination analysis of the spike gene revealed high nucleotide identity between the SARS virus and a feline infectious peritonitis virus throughout the gene, except for a 200- base-pair region of high identity to an avian sequence. These data support the phylogenetic analyses and suggest a possible past recombination event between mammalian-like and avian-like parent viruses. This event occurred near a region that has been implicated to be the human receptor binding site and may have been directly responsible for the switch of host of the SARS coronavirus from animals to humans. (+info)
Conserved C-terminal threonine of hepatitis C virus NS3 regulates autoproteolysis and prevents product inhibition.
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Inspection of over 250 hepatitis C virus (HCV) genome sequences shows that a threonine is strictly conserved at the P1 position in the NS3-NS4A (NS3-4A) autoproteolysis junction, while a cysteine is maintained as the P1 residue in all of the putative trans cleavage sites (NS4A-4B, NS4B-5A, and NS5A-5B). To understand why T631 is conserved at the NS3-4A junction of HCV, a series of in vitro transcription-translation studies were carried out using wild-type and mutant (T631C) NS3-4A constructs bearing native, truncated, and mutant NS4A segments. The autocleavage of the wild-type junction was found to be dependent on the presence of the central cofactor domain of NS4A (residues 21 to 34). In contrast, all NS3-4A T631C mutant proteins underwent self-cleavage even in the absence of the cofactor. Subgenomic replicons derived from the Con1 strain of HCV and bearing the T631C mutation showed reduced levels of colony formation in transfection studies. Similarly, replicons derived from a second genotype 1b virus, HCV-N, demonstrated a comparable reduction in replication efficiency in transient-transfection assays. These data suggest that the threonine is conserved at position 631 because it serves two functions: (i) to slow processing at the NS3-4A cleavage site, ensuring proper intercalation of the NS4A cofactor with NS3 prior to polyprotein scission, and (ii) to prevent subsequent product inhibition by the NS3 C terminus. (+info)
Novel insect picorna-like virus identified in the brains of aggressive worker honeybees.
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To identify candidate genes involved in the aggressive behavior of worker honeybees, we used the differential display method to search for RNAs exclusively detected in the brains of aggressive workers that had attacked a hornet. We identified a novel, 10,152-nucleotide RNA, termed Kakugo RNA. Kakugo RNA encodes a protein of 2,893 amino acid residues that shares structural features and sequence similarities with various picorna-like virus polyproteins, especially those from sacbrood virus, which infects honeybees. The Kakugo protein contains several domains that correspond to the virion protein, helicase, protease, and RNA-dependent RNA polymerase domains of various picorna-like virus polyproteins. When the worker bee tissue lysate was subjected to sucrose density gradient centrifugation, Kakugo RNA, except for the material at the bottom, was separated into two major peaks. One of the peaks corresponded to the position of Kakugo mRNA, and the other corresponded to the position of the poliovirus virion. These results suggest that the Kakugo RNA exists as an mRNA-like free RNA and virion RNA in the honeybee. Furthermore, injection of the lysate supernatant from the attacker heads into the heads of noninfected bees resulted in a marked increase in Kakugo RNA. These results demonstrate that Kakugo RNA is a plus-strand RNA of a novel picorna-like virus and that the brains of aggressive workers are infected by this novel virus. Kakugo RNA was detected in aggressive workers but not in nurse bees or foragers. In aggressive workers, Kakugo RNA was detected in the brain but not in the thorax or abdomen, indicating a close relation between viral infection in the brain and aggressive worker behaviors. (+info)
Virus-host cell interactions during hepatitis C virus RNA replication: impact of polyprotein expression on the cellular transcriptome and cell cycle association with viral RNA synthesis.
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Considerable controversy surrounds the impact of hepatitis C virus (HCV) protein expression on viability of host cells and regulation of the cell cycle. Both promotion of cellular proliferation and apoptosis have been observed in different experimental systems. To determine whether expression of the entire complement of HCV proteins in the context of ongoing viral RNA replication significantly alters the host cell transcriptome and cell cycle regulatory processes, we carried out high-density oligonucleotide microarray studies and analyzed cell cycle distributions and S-phase entry in Huh7 cell clones harboring selectable, full-length, replicating HCV RNAs that express the entire genotype 1b, HCV-N polyprotein, and clonally related cells in which all viral RNA was eliminated by prior treatment with alpha interferon. Oligonucleotide microarray analyses revealed only subtle, coordinated differences in the mRNA profiles of cells containing replicating viral RNA and their interferon-cured progeny, with variation between different cell clones having a greater influence on the cellular transcriptome than the presence or absence of replicating HCV RNA. Flow cytometric analysis demonstrated no significant differences in cell cycle distribution among populations of asynchronously growing cells of both types. Cell lines containing replicating viral RNA and their interferon-cured progeny were able to reenter the cell cycle similarly after transient G(1) arrest. In contrast, although viral protein expression and genome replication did not alter cell cycle control in these cells, HCV genome replication was highly dependent on cellular proliferation, with viral RNA synthesis strongly decreased in poorly proliferating, confluent, or serum-starved cells and substantially enhanced in the S phase of the cell cycle. (+info)
A programmed -1 ribosomal frameshift signal can function as a cis-acting mRNA destabilizing element.
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Nonsense-mediated mRNA decay (NMD) directs rapid degradation of premature termination codon (PTC)-containing mRNAs, e.g. those containing frameshift mutations. Many viral mRNAs encode polycistronic messages where programmed -1 ribosomal frameshift (-1 PRF) signals direct ribosomes to synthesize polyproteins. A previous study, which identified consensus -1 PRF signals in the yeast genome, found that, in contrast to viruses, the majority of predicted -1 PRF events would direct translating ribosomes to PTCs. Here we tested the hypothesis that a -1 PRF signal can function as a cis-acting mRNA destabilizing element by inserting an L-A viral -1 PRF signal into a PGK1 reporter construct in the 'genomic' orientation. The results show that even low levels of -1 PRF are sufficient to target the reporter mRNA for degradation via the NMD pathway, with half-lives similar to messages containing in-frame PTCs. The demonstration of an inverse correlation between frameshift efficiency and mRNA half-lives suggests that modulation of -1 PRF frequencies can be used to post-transcriptionally regulate gene expression. Analysis of the mRNA decay profiles of the frameshift-signal- containing reporter mRNAs also supports the notion that NMD remains active on mRNAs beyond the 'pioneer round' of translation in yeast. (+info)
Uncleaved NS2-3 is required for production of infectious bovine viral diarrhea virus.
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Despite increasing characterization of pestivirus-encoded proteins, functions for nonstructural (NS) proteins NS2, NS2-3, NS4B, and NS5A have not yet been reported. Here we investigated the function of bovine viral diarrhea virus (BVDV) uncleaved NS2-3. To test whether NS2-3 has a discrete function, the uncleaved protein was specifically abolished in two ways: first by inserting a ubiquitin monomer between NS2 and NS3, and second by placing an internal ribosome entry site between the two proteins (a bicistronic genome). In both cases, complete processing of NS2-3 prevented infectious virion formation without affecting RNA replication. We tested the hypothesis that uncleaved NS2-3 was involved in morphogenesis by creating a bicistronic genome in which NS2-3 was restored in the second cistron. With this genome, both uncleaved NS2-3 expression and particle production returned. We then investigated the minimal regions of the polyprotein that could rescue an NS2-3 defect by developing a trans-complementation assay. We determined that the expression of NS4A in cis with NS2-3 markedly increased its activity, while p7 could be supplied in trans. Based on these data, we propose a model for NS2-3 action in virion morphogenesis. (+info)
Polyprotein processing: cis and trans proteolytic activities of Sesbania mosaic virus serine protease.
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Sesbania mosaic virus (SeMV) polyprotein was shown to undergo proteolytic processing when expressed in E. coli. Mutational analysis of the proposed catalytic triad residues (H181, D216, and S284) present in the N-terminal serine protease domain of the polyprotein showed that the protease was indeed responsible for this processing. Analysis of the cleavage site mutants confirmed the cleavage between protease-viral protein genome linked (VPg) and VPg-RNA-dependent RNA polymerase (RdRP) at E(325)-T(326) and E(402)-T(403) sites, respectively. An additional suboptimal cleavage at E(498)-S(499) site was also identified which resulted in the further processing of RdRP to 10- and 52-kDa proteins. Thus, the protease has both E-T and E-S specificities. The polyprotein has a domain arrangement of protease-VPg-p10-RdRP, which is cleaved by the protease. The purified serine protease was also active in trans and cleaved the polyprotein at the same specific sites. These results demonstrate that the serine protease domain is responsible for the processing of SeMV polyprotein both in cis and in trans. (+info)
The last C-terminal residue of VP3, glutamic acid 257, controls capsid assembly of infectious bursal disease virus.
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Infectious bursal disease virus (IBDV) is a nonenveloped virus with an icosahedral capsid composed of two proteins, VP2 and VP3, that derive from the processing of the polyprotein NH(2)-pVP2-VP4-VP3-COOH. The virion contains VP1, the viral polymerase, which is both free and covalently linked to the two double-stranded RNA (dsRNA) genomic segments. In this study, the virus assembly process was studied further with the baculovirus expression system. While expression of the wild-type polyprotein was not found to be self-sufficient to give rise to virus-like particles (VLPs), deletion or replacement of the five C-terminal residues of VP3 was observed to promote capsid assembly. Indeed, the single deletion of the C-terminal glutamic acid was sufficient to induce VLP formation. Moreover, fusion of various peptides or small proteins (a green fluorescent protein or a truncated form of ovalbumin) at the C terminus of VP3 also promoted capsid assembly, suggesting that assembly required screening of the negative charges at the C terminus of VP3. The fused polypeptides mimicked the effect of VP1, which interacts with VP3 to promote VLP assembly. The C-terminal segment of VP3 was found to contain two functional domains. While the very last five residues of VP3 mainly controlled both assembly and capsid architecture, the five preceding residues constituted the VP1 (and possibly the pVP2/VP2) binding domain. Finally, we showed that capsid formation is associated with VP2 maturation, demonstrating that the protease VP4 is involved in the virus assembly process. (+info)