Efficient multiplication of a Semliki Forest virus chimera containing Sindbis virus spikes

A novel three-plasmid packaging system for chimeric SFV/SIN VRPs derived from Semliki Forest virus and Sindbis virus as a candidate gene delivery vector

Semliki Forest virus (SFV) viral replicon particles (VRPs) have been frequently used in various animal models and clinical trials. Chimeric replicon particles offer different advantages because of their unique biological properties. We here constructed a novel three-plasmid packaging system for chimeric SFV/SIN VRPs. The capsid and envelope of SIN structural proteins were generated using two-helper plasmids separately, and the SFV replicon contained the SFV replicase gene, packaging signal of SIN, subgenomic promoter followed by the exogenous gene, and 3' UTR of SIN. The chimeric VRPs carried luciferase or eGFP as reporter genes. The fluorescence and electron microscopy results revealed that chimeric VRPs were successfully packaged. The yield of the purified chimeric VRPs was approximately 2.5 times that of the SFV VRPs (1.38 × 107 TU/ml vs. 5.41 × 106 TU/ml) (p < 0.01). Furthermore, chimeric VRPs could be stored stably at 4°C for at least 60 days. Animal experiments revealed that mice immunized with chimeric VRPs (luciferase) had stronger luciferase expression than those immunized with equivalent amount of SFV VRPs (luciferase) (p < 0.01), and successfully expressed luciferase for approximately 12 days. Additionally, the chimeric VRPs expressed the RBD of SARS-CoV-2 efficiently and induced robust RBD-specific antibody responses in mice. In conclusion, the chimeric VRPs constructed here met the requirements of a gene delivery tool for vaccine development and cancer therapy.

Dissecting the Role of E2 Protein Domains in Alphavirus Pathogenicity

Alphaviruses represent a diverse set of arboviruses, many of which are important pathogens. Chikungunya virus (CHIKV), an arthritis-inducing alphavirus, is the cause of a massive ongoing outbreak in the Caribbean and South America. In contrast to CHIKV, other related alphaviruses, such as Venezuelan equine encephalitis virus (VEEV) and Semliki Forest virus (SFV), can cause encephalitic disease. E2, the receptor binding protein, has been implicated as a determinant in cell tropism, host range, pathogenicity, and immunogenicity. Previous reports also have demonstrated that E2 contains residues important for host range expansions and monoclonal antibody binding; however, little is known about what role each protein domain (e.g., A, B, and C) of E2 plays on these factors. Therefore, we constructed chimeric cDNA clones between CHIKV and VEEV or SFV to probe the effect of each domain on pathogenicity in vitro and in vivo. CHIKV chimeras containing each of the domains of the E2 (ΔDomA, ΔDomB, and ΔDomC) from SFV, but not VEEV, were successfully rescued. Interestingly, while all chimeric viruses were attenuated compared to CHIKV in mice, ΔDomB virus showed similar rates of infection and dissemination in Aedes aegypti mosquitoes, suggesting differing roles for the E2 protein in different hosts. In contrast to CHIKV; ΔDomB, and to a lesser extent ΔDomA, caused neuron degeneration and demyelination in mice infected intracranially, suggesting a shift toward a phenotype similar to SFV. Thus, chimeric CHIKV/SFV provide insights on the role the alphavirus E2 protein plays on pathogenesis.

IMPORTANCE

Chikungunya virus (CHIKV) has caused large outbreaks of acute and chronic arthritis throughout Africa and Southeast Asia and has now become a massive public health threat in the Americas, causing an estimated 1.2 million human cases in just over a year. No approved vaccines or antivirals exist for human use against CHIKV or any other alphavirus. Despite the threat, little is known about the role the receptor binding protein (E2) plays on disease outcome in an infected host. To study this, our laboratory generated chimeric CHIKV containing corresponding regions of the Semliki Forest virus (SFV) E2 (domains A, B, and C) substituted into the CHIKV genome. Our results demonstrate that each domain of E2 likely plays a critical, but dissimilar role in the viral life cycle. Our experiments show that manipulation of E2 domains can be useful for studies on viral pathogenesis and potentially the production of vaccines and/or antivirals.

Association of sindbis virus capsid protein with phospholipid membranes and the E2 glycoprotein: implications for alphavirus assembly

A late stage in assembly of alphaviruses within infected cells is thought to be directed by interactions between the nucleocapsid and the cytoplasmic domain of the E2 protein, a component of the viral E1/E2 glycoprotein complex that is embedded in the plasma membrane. Recognition between the nucleocapsid protein and the E2 protein was explored in solution using NMR spectroscopy, as well as in binding assays using a model phospholipid membrane system that incorporated a variety of Sindbis virus E2 cytoplasmic domain (cdE2) and capsid protein constructs. In these binding assays, synthetic cdE2 peptides were reconstituted into phospholipid vesicles to simulate the presentation of cdE2 on the inner leaflet of the plasma membrane. Results from these binding assays showed a direct interaction between a peptide containing the C-terminal 16 amino acids of the cdE2 sequence and a Sindbis virus capsid protein construct containing amino acids 19-264. Additional experiments that probed the sequence specificity of this cdE2-capsid interaction are also described. Further binding assays demonstrated an interaction between the 19-264 capsid protein and artificial vesicles containing neutral or negatively charged phospholipids, while capsid protein constructs with N-terminal truncations displayed either little or no affinity for such vesicles. The membrane-binding property of the capsid protein suggests that the membrane may play an active role in alphavirus assembly. The results are consistent with an assembly process involving an initial membrane association, whereby an association with E2 glycoprotein further enhances capsid binding to facilitate membrane envelopment of the nucleocapsid for budding. Collectively, these experiments elucidate certain requirements for the binding of Sindbis virus capsid protein to the cytoplasmic domain of the E2 glycoprotein, a critical event in the alphavirus maturation pathway.

Budding of alphaviruses

Alphaviruses are small highly ordered enveloped RNA viruses, which replicate very efficiently in the infected cell. They consist of a nucleocapsid (NC) and a surrounding membrane with glycoproteins. In the NC the positive single stranded RNA genome of the virus is enclosed by a T=4 icosahedral shell of capsid (C) proteins. The glycoproteins form a second shell with corresponding symmetry on the outside of the lipid membrane. These viruses mature by budding at the plasma membrane (PM) of the infected cell and enter into new cells by acid-triggered membrane fusion in endosomes. The viral glycoprotein consists of two subunits, E1, which carries the membrane fusion function, and E2, which suppresses this function until acid activation occurs. In the infected cell the RNA replication and transcription are confined to the cytoplasmic surface of endosome-derived vesicles called cytopathic vacuoles type I (CPV I). These structures are closely associated with membranes of the endoplasmic reticulum (ER), thereby creating a microenvironment for synthesis of viral proteins, assembly of the glycoproteins and formation of genome-C complexes. The budding process of the virus is initiated by C-glycoprotein interactions, possibly already before the glycoproteins arrive at the PM. This might involve a premade, ordered NC or a less ordered form of the genome-C complex. In the latter case, the interactions in the glycoprotein shell provide the major driving force for budding. The nature of the C-glycoprotein interaction has been resolved at atomic resolution by modelling. It involves hydrophobic interactions between a Tyr-X-Leu tripeptide in the internal tail of the E2 subunit and a pocket on the surface of the C protein. When the virus enters the endosome of a new cell the acid conditions trigger rearrangements in the glycoprotein shell, which result in the dissociation of the interactions that drive budding and a concomitant activation of the membrane fusion function in the E1 subunit.

Lectin-mediated retention of p62 facilitates p62-E1 heterodimerization in endoplasmic reticulum of Semliki Forest virus-infected cells

The Semliki Forest virus (SFV) spike subunits p62 and E1 are made from a common coding unit in the order p62-E1. The proteins are separated by the host signal peptidase upon translocation into the endoplasmic reticulum (ER). Shortly thereafter, p62 and E1 form heterodimers. Heterodimerization preferentially occurs between subunits derived from the same translation product, so-called cis heterodimerization. As the p62 protein has the capacity to leave the ER in the absence of E1, it has been postulated that there exists a retention mechanism for the p62 protein, putatively at or near the translocon, in the ER in order to promote cis heterodimerization (B. U. Barth and H. Garoff, J. Virol. 71:7857-7865, 1997). Here we show that there exists such a mechanism, that it is at least in part mediated by the ER chaperones calnexin and calreticulin, and that the retention is important for efficient cis heterodimerization.

Recombinant chimeric western and eastern equine encephalitis viruses as potential vaccine candidates

Chimeric cDNA clones, pMWE1000 and pMWE2000, differing by five nucleotides at their 5' termini, were constructed of the 5' two-thirds of the western equine encephalitis (WEE) virus genome (encoding nonstructural proteins) and the 3' one-third of the eastern equine encephalitis (EEE) virus genome (encoding structural proteins). The WEE virus sequences were derived from full-length cDNA clones, pWE1000 and pWE2000, which were isogenic except for five nucleotide differences at their 5' termini and were responsible for significant differences in mouse virulence. Each cDNA clone was placed downstream from a T7 promoter to allow in vitro transcription of full-length RNA. Transfection of BHK-21 cells with the chimeric RNA by electroporation gave rise to high-titer infectious virus. The in vitro characteristics of each chimera virus were determined by electrophoretic analysis of its structural proteins, plaque morphology, neutralization characteristics, replication kinetics, and rate of viral RNA synthesis. With the exception of plaque morphology, the in vitro characteristics of MWE1000 and MWE2000 were indistinguishable from the parental EEE virus. Subcutaneous inoculation of 5-week-old C57BL/6 mice with varying doses of MWE1000 or MWE2000 virus demonstrated that both chimeric viruses were significantly attenuated compared to the parental WEE virus (Cba 87) and EEE virus (PE-6). Animals infected with 10(5) PFU or more of either MWE1000 or MWE2000 were completely protected from lethal challenge with the virulent EEE virus, FL91-4679, but were not protected from virulent WEE virus Cba 87 challenge. Construction of viable virus chimeras often results in attenuated viruses that may hold promise as genetically engineered alphavirus vaccine candidates (R. J. Kuhn, D. E. Griffin, K. E. Owen, H. G. M. Niesters, and J. H. Strauss, 1996, J. Virol. 70, 7900-7909).

In vitro assembly of alphavirus cores by using nucleocapsid protein expressed in Escherichia coli

The production of the alphavirus virion is a multistep event requiring the assembly of the nucleocapsid core in the cytoplasm and the maturation of the glycoproteins in the endoplasmic reticulum and the Golgi apparatus. These components associate during the budding process to produce the mature virion. The nucleocapsid proteins of Sindbis virus and Ross River virus have been produced in a T7-based Escherichia coli expression system and purified. In the presence of single-stranded but not double-stranded nucleic acid, the proteins oligomerize in vitro into core-like particles which resemble the native viral nucleocapsid cores. Despite their similarities, Sindbis virus and Ross River virus capsid proteins do not form mixed core-like particles. Truncated forms of the Sindbis capsid protein were used to establish amino acid requirements for assembly. A capsid protein starting at residue 19 [CP(19-264)] was fully competent for in vitro assembly, whereas proteins with further N-terminal truncations could not support assembly. However, a capsid protein starting at residue 32 or 81 was able to incorporate into particles in the presence of CP(19-264) or could inhibit assembly if its molar ratio relative to CP(19-264) was greater than 1:1. This system provides a basis for the molecular dissection of alphavirus core assembly.

Mutations in the Sindbis virus capsid gene can partially suppress mutations in the cytoplasmic domain of the virus E2 glycoprotein spike

Assembly and budding of alphaviruses are postulated to occur by protein-protein interactions between sites on the cytoplasmic domain of the transmembranal envelope E2 glycoprotein and on the surface of the nucleocapsid protein subunits. Genetic data to support this model have been obtained by isolating revertants of two slow-growth mutants of Sindbis virus and analyzing the sequences of the genes encoding their structural proteins. The slow-growth phenotypes of the mutants were previously shown to result from site-directed mutations of 2 amino acids in the sequence corresponding to the 33 amino acids at the carboxyl terminus of E2, which are localized to the cytoplasmic face of the plasma membrane. Putative revertants of these two mutants with faster growth rates were isolated by sequential passaging of virus grown on insect cells or chicken embryo fibroblasts. Sequence analysis of plaque-purified viruses that grew significantly better than the original mutant revealed that the original E2 mutation was present and that there were additional amino acid changes in the virus capsid. Two of the latter were introduced separately into the wild-type virus cDNA and into the genomes of the original mutants. The new strains of virus that contained both capsid and E2 mutations produced many more extracellular particles than those with the E2 mutations alone, indicating substantial suppression of the original E2 mutation. Both capsid mutations appear to be localized near a hydrophobic pocket of the capsid, which is postulated to be the site for docking of hydrophobic amino acids of the E2 cytoplasmic domain. This genetic study provides strong support for the current models of alphavirus assembly.

Specific interactions between retrovirus Env and Gag proteins in rat neurons

In this work we have studied the intracellular localization properties of the Gag and Env proteins of Moloney murine leukemia virus (MLV) and human immunodeficiency virus (HIV) in dorsal root ganglion (DRG) neurons of rat. These neurons form thick bundles of axons, which facilitates protein localization studies by immunofluorescence analyses. When such neuron cultures were infected with recombinant Semliki Forest virus particles carrying the gag genes of either retrovirus, the expressed Gag proteins were localized to both the somatic and the axonal regions of the DRG neurons. In contrast, the Env proteins were confined only to the somatic region. When the Gag and Env proteins were coexpressed, the Gag proteins were also excluded from the axons. This effect of the Env proteins was shown to be dependent on the concentration of the Gag proteins in the neuron and also to be specific for homologous pairs of retrovirus proteins. Therefore, the results suggest that there are specific interactions between the Env and the Gag proteins of MLV and HIV in the DRG neurons.

Chimeric measles viruses with a foreign envelope

Measles virus (MV) and vesicular stomatitis virus (VSV) are both members of the Mononegavirales but are only distantly related. We generated two genetically stable chimeric viruses. In MGV, the reading frames of the MV envelope glycoproteins H and F were substituted by a single reading frame encoding the VSV G glycoprotein; MG/FV is similar but encodes a G/F hybrid in which the VSV G cytoplasmic tail was replaced by that of MV F. In contrast to MG/FV, MGV virions do not contain the MV matrix (M) protein. This demonstrates that virus assembly is possible in the absence of M; conversely, the cytoplasmic domain of F allows incorporation of M and enhances assembly. The formation of chimeric viruses was substantially delayed and the titers obtained were reduced about 50-fold in comparison to standard MV. In the novel chimeras, transcription and replication are mediated by the MV ribonucleoproteins but the envelope glycoproteins dictate the host range. Mice immunized with the chimeric viruses were protected against lethal doses of wild-type VSV. These findings suggest that it is feasible to construct MV variants bearing a variety of different envelopes for use as vaccines or for gene therapeutic purposes.

Oligomerization-dependent folding of the membrane fusion protein of Semliki Forest virus

The spikes of alphaviruses are composed of three copies of an E2-E1 heterodimer. The E1 protein possesses membrane fusion activity, and the E2 protein, or its precursor form, p62 (sometimes called PE2), controls this function. Both proteins are, together with the viral capsid protein, translated from a common C-p62-E1 coding unit. In an earlier study, we showed that the p62 protein of Semliki Forest virus (SFV) dimerizes rapidly and efficiently in the endoplasmic reticulum (ER) with the E1 protein originating from the same translation product (so-called heterodimerization in cis) (B.-U. Barth, J. M. Wahlberg, and H. Garoff, J. Cell Biol. 128:283-291, 1995). In the present work, we analyzed the ER translocation and folding efficiencies of the p62 and E1 proteins of SFV expressed from separate coding units versus a common one. We found that the separately expressed p62 protein translocated and folded almost as efficiently as when it was expressed from a common coding unit, whereas the independently expressed E1 protein was inefficient in both processes. In particular, we found that the majority of the translocated E1 chains were engaged in disulfide-linked aggregates. This result suggests that the E1 protein needs to form a complex with p62 to avoid aggregation. Further analyses of the E1 aggregation showed that it occurred very rapidly after E1 synthesis and could not be avoided significantly by the coexpression of an excess of p62 from a separate coding unit. These latter results suggest that the p62-E1 heterodimerization has to occur very soon after E1 synthesis and that this is possible only in a cis-directed reaction which follows the synthesis of p62 and E1 from a common coding unit. We propose that the p62 protein, whose synthesis precedes that of the E1 protein, remains in the translocon of the ER and awaits the completion of E1. This strategy enables the p62 protein to complex with the E1 protein immediately after the latter has been made and thereby to control (suppress) its fusion activity.

The nucleocapsid-binding spike subunit E2 of Semliki Forest virus requires complex formation with the E1 subunit for activity

Alphaviruses, such as Semliki Forest virus (SFV), mature by budding at the plasma membrane (PM) of infected cells and enter uninfected ones by a membrane fusion process in the endosomes. Both processes are directed by the p62/E2-E1 membrane protein heterodimer of the virus. The p62 protein, or its mature form E2, provides a cytoplasmic protein domain for interaction with the nucleocapsid (NC) of the virus, and the E1 protein functions as a membrane fusogen. We have previously shown that the p62/E2 protein of SFV controls the membrane fusion activity of E1 through its complex formation with the latter (A. Salminen, J. M. Wahlberg, M. Lobigs, P. Liljeström, and H. Garoff, J. Cell Biol. 116:349-357, 1992). In the present work, we show that the E1 protein controls the NC-binding activity of p62/E2. We have studied E1 expression-deficient SFV variants and shown that although the p62/E2 proteins can be transported to the PM they cannot establish stable NC associations.

Alphaviruses as expression vectors

Alphavirus vectors have been used for efficient high-level expression of a variety of topologically different proteins, allowing studies of protein transport, localization and functional activity in a broad range of host cells. Complex transmembrane proteins have been produced in large quantities through the establishment of scale-up technology. Alphavirus vectors have also shown promising potential in vaccine production and preliminary gene therapy applications.

Infectious particles derived from Semliki Forest virus vectors encoding murine leukemia virus envelopes

Semliki Forest virus vectors encoding murine leukemia virus (MLV) envelope protein with a truncated cytoplasmic tail generate submicrometer, cell-associated, membranous particles that transmit replication-competent vector RNA specifically to cells bearing the MLV receptor. Such "minimal" viruses could have applications as retroviral vaccines or in the study of virus evolution.

Sindbis virus replicons and Sindbis virus: assembly of chimeras and of particles deficient in virus RNA

Alphaviruses are a well-characterized group of positive-strand RNA viruses. The identification of cis-acting elements in their genomes and their replication strategy have made them useful as vectors for the expression of heterologous genes. In infected cells, the nonstructural proteins, required for replication and transcription of the viral genes, are translated from the genomic RNA; the structural proteins, the capsid protein that interacts with the RNA to form the nucleocapsid and the proteins embedded in the lipid envelope, are translated from a subgenomic mRNA and can be replaced by heterologous genes. Such modified genomes are self-replicating (replicons); they can be introduced into the cells by transfection and can also be packaged into extracellular particles with defective helper (DH) RNAs. The particular DH RNA determines how well it is replicated and to what extent it is packaged. One potential complication of this system has been that recombination between the replicon genome and the DH RNA may occur. The studies described here were designed to prevent recombination by expressing the capsid protein from one DH RNA and the virus membrane proteins from a second helper RNA. Recombination to yield a nonsegmented infectious virus genome would then require several independent crossover events. There is a translational enhancer located downstream of the initiating AUG in the RNA of the capsid gene that had to be conserved in the second helper to achieve high-level expression of the viral glycoproteins. For this reason, we modified the capsid protein gene in two ways: the first was to use the capsid protein gene from a different alphavirus, Ross River virus, and the second was to make deletions in that gene to maintain the translational enhancer in the RNA but to eliminate the positively charged region in the protein that should be essential for the specific and nonspecific interactions with RNA. Transfections with replicon RNA and the deleted chimeric DH RNA as the only helper resulted in the high-level production of particles that were almost completely devoid of RNA. The inclusion of a helper expressing an intact Sindbis virus capsid protein gene led to the production of high levels of packaged replicons. Recombinants were not detected even after several undiluted passages.