Pseudotyping Lentiviral Vectors: When the Clothes Make the Virus.

Delivering transgenes to human cells through transduction with viral vectors constitutes one of the most encouraging approaches in gene therapy. Lentivirus-derived vectors are among the most promising vectors for these approaches. When the genetic modification of the cell must be performed in vivo, efficient specific transduction of the cell targets of the therapy in the absence of off-targeting constitutes the Holy Grail of gene therapy. For viral therapy, this is largely determined by the characteristics of the surface proteins carried by the vector. In this regard, an important property of lentiviral vectors is the possibility of being pseudotyped by envelopes of other viruses, widening the panel of proteins with which they can be armed. Here, we discuss how this is achieved at the molecular level and what the properties and the potentialities of the different envelope proteins that can be used for pseudotyping these vectors are.

Viral Macrodomains: Unique Mediators of Viral Replication and Pathogenesis.

Viruses from the Coronaviridae, Togaviridae, and Hepeviridae families ​all contain genes that encode a conserved protein domain, called a macrodomain; however, the role of this domain during infection has remained enigmatic. The recent discovery that mammalian macrodomain proteins enzymatically remove ADP-ribose, a common post-translation modification, from proteins has led to an outburst of studies describing both the enzymatic activity and function of viral macrodomains. These new studies have defined these domains as de-ADP-ribosylating enzymes, which indicates that these viruses have evolved to counteract antiviral ADP-ribosylation, likely mediated by poly-ADP-ribose polymerases (PARPs). Here, we comprehensively review this rapidly expanding field, describing the structures and enzymatic activities of viral macrodomains, and discussing their roles in viral replication and pathogenesis.

Rio Negro virophage: Sequencing of the near complete genome and transmission electron microscopy of viral factories and particles

ABSTRACT Rio Negro virophage (RNV) was co-isolated with a strain of mimivirus named sambavirus, from Brazilian Amazon. We report the near complete genome sequence of RNV, the first virophage isolated in Brazil. We also present new microscopical data demonstrating that RNV particles have similar dimensions to that described to sputnik virophages.

Comparison of complete polyprotein sequences of two isolates of salmon alphavirus (SAV) type I and their behaviour in a salmonid cell line.

Salmon pancreas disease virus is an alphavirus (family Togaviridae) affecting mainly Atlantic salmon (Salmo salar L.). Both polyprotein sequences of the Scottish isolate (SAV4640) were determined and compared with those of Irish isolate SAVF93-125. High amino acid sequence similarity (99.4 %) was found. Six amino acid deletions were found in the E2 gene of SAV4640. SAVF93-125 demonstrated a high viral load in culture despite high Mx expression. Approximately 50 % of cells infected with SAVF93-125 exhibited a cytopathic effect by day 8. SAV4640 successfully entered the cells, inducing 10,500-fold higher Mx expression at day 2 compared to SAVF93-25; however, no replication was observed based on results of the nsP1 qRT-PCR.

Phylogeographical structure and evolutionary history of two Buggy Creek virus lineages in the western Great Plains of North America.

Buggy Creek virus (BCRV) is an unusual arbovirus within the western equine encephalitis complex of alphaviruses. Associated with cimicid swallow bugs (Oeciacus vicarius) as its vector and the cliff swallow (Petrochelidon pyrrhonota) and house sparrow (Passer domesticus) as its amplifying hosts, this virus is found primarily in the western Great Plains of North America at spatially discrete swallow nesting colonies. For 342 isolates collected in Oklahoma, Nebraska, Colorado and North Dakota, from 1974 to 2007, we sequenced a 2076 bp region of the 26S subgenomic RNA structural glycoprotein coding region, and analysed phylogenetic relationships, rates of evolution, demographical histories and temporal genetic structure of the two BCRV lineages found in the Great Plains. The two lineages showed distinct phylogeographical structure: one lineage was found in the southern Great Plains and the other in the northern Great Plains, and both occurred in Nebraska and Colorado. Within each lineage, there was additional latitudinal division into three distinct sublineages. One lineage is showing a long-term population decline. In comparing sequences taken from the same sites 8-30 years apart, in one case one lineage had been replaced by the other, and in the other cases there was little evidence of the same haplotypes persisting over time. The evolutionary rate of BCRV is in the order of 1.6-3.6x10(-4) substitutions per site per year, similar to that estimated for other temperate-latitude alphaviruses. The phylogeography and evolution of BCRV could be better understood once we determine the nature of the ecological differences between the lineages.

Retinoblastoma protein purification and transduction of retina and retinoblastoma cells using improved alphavirus vectors.

PURPOSE: To develop and use improved Semliki Forest vectors (SFVs) for functional and structural analyses of the retinoblastoma protein (RB) in developing retina and retinoblastoma cells. METHODS: Virus was harvested from cells transfected with replicon and helper plasmids. Combinations of producer and target cells were tested for optimal virus production and protein expression. The replicon was improved by adding an expanded multiple cloning site, translational enhancer, and FLAG and HIS10 epitope and affinity tags. Affinity chromatography was used to purify beta-galactosidase or RB. RB function was assessed through interaction with E2F1. The efficacy of SFV as a retinal delivery system was tested on mouse explants and cultured human retinoblastoma cells. RESULTS: The optimal producer and target cell lines were an HEK-293 derivative (Phoenix Eco) and BHK-21, respectively. Stable expression of structural proteins in the BHK-21 helper line simplified virus production and amplified virus yield 100-fold. The translational enhancer improved expression three- to eightfold. Full-length, functional RB was produced without the truncated products characteristic of bacterially produced RB and was purified using the affinity tags. SFVs efficiently transduced mouse retinal explants and multiple hard-to-transduce retinoblastoma tumor lines. CONCLUSIONS: This study describes a simple, rapid, SFV vector system to produce recombinant proteins, such as RB, in mammalian cells. These SFV vectors represent an efficient approach to purification of proteins and protein complexes and transduction of retinal or retinoblastoma cells for the purpose of in vivo analysis of protein functions.

Detection of Ockelbo virus RNA in skin biopsies by polymerase chain reaction.

A sensitive assay based on the polymerase chain reaction for the detection of Ockelbo virus RNA was developed. Two primer pairs from the gene coding for the E2 glycoprotein were chosen. By use of a nested strategy for the primers, as few as 1 to 10 PFU could be detected. The amplified products were visualized as bands of appropriate size on ethidium bromide-stained agarose gels. The primer pairs allowed amplification of several Ockelbo and Sindbis virus isolates but discriminated between these and other alphaviruses. Ockelbo virus RNA was detected in 4 of 10 skin biopsy specimens collected during the acute stage of the disease. The identities of the amplified products were confirmed by restriction endonuclease cleavage. Acute- and convalescent-phase sera as well as lymphocytes collected during the convalescent phase were negative by the polymerase chain reaction. No infectious virus could be recovered from any of the specimens.

The Coronaviridae now comprises two genera, coronavirus and torovirus: report of the Coronaviridae Study Group.

At the April 1992, mid-term meeting of the International Committee on Taxonomy of Viruses (ICTV) a proposal from the Coronaviridae Study Group (CSG) to include the torovirus genus in the Coronaviridae was accepted. Following another proposal, the arterivirus genus was removed from the Togaviridae but not assigned to another family. The arteriviruses have some features in common with the Coronaviridae but also have major differences. After much debate, culminating in September 1992, it was decided that the CSG would not recommend inclusion of arterivirus in the Coronaviridae. It was agreed that (a) the nomenclature used for coronavirus genes, mRNAs and polypeptides (Cavanagh et al., 1990) should be used for toroviruses, (b) that the small (about 100 amino acids) membrane-associated protein, which is distinct from the integral membrane glycoprotein M, associated with virions of infectious bronchitis (Liu & Inglis, 1991) and transmissible gastroenteritis (Godet et al., 1992) coronaviruses would be referred to by the acronym sM (lower case 's') and (c) that 'pol' (polymerase) should be used as a working term for gene 1, which comprises open reading frames (ORFs) 1a and 1b in both genera of the Coronaviridae.

A nested set of eight RNAs is formed in macrophages infected with lactate dehydrogenase-elevating virus.

Total RNA was extracted from primary cultures of mouse macrophages isolated from 10-day-old mice 6 to 12 h postinfection with lactate dehydrogenase-elevating virus (LDV). Poly(A)+ RNA was extracted from spleens of 18-h LDV-infected mice. The RNAs were analyzed by Northern (RNA) blot hybridization with a number of LDV-specific cDNAs as probes. A cDNA representing the nucleocapsid protein (VP-1) gene located at the 3' terminus of the viral genome (E. K. Godeny, D. W. Speicher, and M. A. Brinton, Virology 177:768-771, 1990) hybridized to viral genomic RNA of about 13 kb plus seven subgenomic RNAs ranging in size from about 1 to about 3.6 kb. Two other cDNA clones hybridized only to the four or five largest subgenomic RNAs, respectively. In contrast, two cDNAs encoding continuous open reading frames with replicase and zinc finger motifs hybridized only to the genomic RNA. The replicase motif exhibited 75% amino acid identity to that of the 1b protein of equine arteritis virus (EAV) and 44% amino acid identity to those of the 1b proteins of coronaviruses and Berne virus. Combined, the results indicate that LDV replication involves formation of a 3'-coterminal-nested set of mRNAs as observed for coronaviruses and toroviruses as well as for EAV, with which LDV shares many other properties. Overall, LDV, like EAV, possesses a genome organization resembling that of the coronaviruses and toroviruses. However, EAV and LDV differ from the latter in the size of their genomes, virion size and structure, nature of the structural proteins, and symmetry of the nucleocapsids.

Structure of the Ockelbo virus genome and its relationship to other Sindbis viruses.

Ockelbo virus was first isolated in 1982 in Sweden. It is the causal agent of disease in humans characterized by arthritis, rash, and fever and is antigenically very closely related to Sindbis virus. We have determined the nucleotide and translated amino acid sequences of the prototype Ockelbo virus isolate (82-5) to determine the relatedness of Ockelbo virus to Sindbis virus at the genomic level and clarify the taxonomic position of Ockelbo virus within the alphavirus genus. The numbers of nucleotides and of translated amino acids in each region of the Ockelbo virus genome were exactly the same as those for the prototype AR339 strain of Sindbis virus except for three small deletions and insertions in the C-terminal half of nsP3 and for three single nucleotide insertions and deletions in the 3' untranslated region. Overall there were 672 nucleotide differences (5.7% divergence), resulting in 97 amino acid changes (2.6% divergence), between the two viruses: more than 85% of the nucleotide changes were silent. Only the C-terminal domain of nsP3 and the E2 glycoprotein showed a higher degree of amino acid substitution than the overall average. The former domain is not conserved among alphaviruses, and the latter is primarily responsible for antigenic variation. Sequence analysis of 420 nucleotides at the 3' end of a number of other Sindbis-like alphaviruses, including Karelian fever virus and South African, Indian, and Australian isolates of Sindbis virus, demonstrated that Ockelbo virus is more closely related to South African strains of Sindbis virus than it is to the prototypic Egyptian AR339 strain. Thus the South African strains, which have caused epidemic disease in humans, may have been introduced into Northern Europe by man or by migratory birds to establish Ockelbo disease there. The Indian and Australian strains form a distinct branch of the evolutionary tree and differ from prototypic AR339 Sindbis virus in 17% of the nucleotides sequenced.

Computer analysis suggests a role for signal sequences in processing polyproteins of enveloped RNA viruses and as a mechanism of viral fusion.

We have used a computer program to scan the entire sequence of viral polyproteins for eucaryotic signal sequences. The method is based on that of von Heijne (1). The program calculates a score for each residue in a polyprotein. The score indicates the resemblance of each residue to that at the cleavage site of a typical N-terminal eucaryotic signal sequence. The program correctly predicts the known N-terminal signal sequence cleavage sites of several cellular and viral proteins. The analysis demonstrates that the polyproteins of enveloped RNA viruses--including the alphaviruses, flaviviruses, and bunyaviruses--contain several internal signal-sequence-like regions. The predicted cleavage site in these internal sequences are often known cleavage sites for processing of the polyprotein and are amongst the highest scoring residues with this algorithm. These results indicate a role for the cellular enzyme signal peptidase in the processing of several viral polyproteins. Not all high-scoring residues are sites of cleavage, suggesting a difference between N-terminal and internal signal sequences. This may reflect the secondary structure of the latter. Signal sequences were also found at the N-termini of the fusion proteins of the paramyxoviruses and the retroviruses. This suggests a mechanism of viral fusion analogous to that by which proteins are translocated through the membranes of the endoplasmic reticulum at synthesis.

Polyadenylic acid sequences in the genomic RNA of the togavirus of simian hemorrhagic fever.

Since serologic studies have failed to relate the togavirus simian hemorrhagic fever (SHF) virus to any currently accepted genus within the Togaviridae family, the presence of polyadenylic acid [poly(A)] in the genomic RNA was analyzed in view of the different content reported for the two major genera of that family: alphaviruses where poly(A) is 40 to 120 nucleotides long and flavivirus where poly(A) is considered to be absent. Oligo(dT)-cellulose chromatography of whole genomic RNA from purified SHF virus revealed that about 36% of the molecules contained segments of poly(A) of sufficient length to bind to oligo(dT)-cellulose. However, a reproducible fraction of the RNAs did not bind to oligo(dT)-cellulose, indicating little or no poly(A) present. When analyzed by electrophoresis under denaturing conditions, both the binding and nonbinding molecules were similar in size. In addition, no polyuridylic acid [poly(U)] was detected in SHF virus genomic RNA. After digestion of the genomic RNA with pancreatic and T1 ribonucleases, the resultant resistant polynucleotide sedimented by ultracentrifugation between tRNA and 5 S RNA. Base composition analysis of these polynucleotides detected only adenosinic residues. A mean length of 76 +/- 2 nucleotides for these poly(A) sequences of SHF virus RNA was established by electrophoresis under denaturing conditions. Thus, together with previous morphological as well as biochemical findings, the presence of a poly(A) sequence is further evidence that SHF virus has distinctive characteristics which differentiates it from the two major subgroups of togavirus.