Proteolytic processing of the Sindbis virus membrane protein precursor PE2 is nonessential for growth in vertebrate cells but is required for efficient growth in invertebrate cells.

We have shown previously that processing of the Sindbis virus envelope protein precursor PE2 to envelope protein E2 is not required for virus maturation in cultured vertebrate fibroblast cells and that unprocessed PE2 can be incorporated into infectious virus in place of E2 (J. F. Presley and D. T. Brown, J. Virol. 63:1975-1980, 1989; D. L. Russell, J. M. Dalrymple, and R. E. Johnston, J. Virol. 63:1619-1629, 1989). To better understand the role of this processing event in the invertebrate vector portion of the alphavirus life cycle, we have examined the maturation of Sindbis virus mutants defective in PE2 processing in cultured mosquito cells. We found that although substantial amounts of structural proteins PE2, E1, and C were produced in infected mosquito (aedine) cell lines, very little infectious virus was released. When the period of infection was extended, plaque size variants appeared, some of which exhibited a restored ability to grow in mosquito cells. The nucleotide sequences of two such variants were determined. These variants contained point mutations that restored PE2 cleavage, indicating a genetic linkage between failure to cleave PE2 and failure to grow in mosquito cells.     

The evolution of human influenza A viruses from 1999 to 2006: A complete genome study

Background

The genus Alphavirus includes several potentially lethal human viruses. Additionally, species such as Sindbis virus and Semliki Forest virus are important vectors for gene therapy, vaccination and cancer research, and important models for virion assembly and structural analyses. The genome encodes nine known proteins, including the small '6K' protein. 6K appears to be involved in envelope protein processing, membrane permeabilization, virion assembly and virus budding. In protein gels, 6K migrates as a doublet – a result that, to date, has been attributed to differing degrees of acylation. Nonetheless, despite many years of research, its role is still relatively poorly understood.

Results

We report that ribosomal -1 frameshifting, with an estimated efficiency of ~10–18%, occurs at a conserved UUUUUUA motif within the sequence encoding 6K, resulting in the synthesis of an additional protein, termed TF (TransFrame protein; ~8 kDa), in which the C-terminal amino acids are encoded by the -1 frame. The presence of TF in the Semliki Forest virion was confirmed by mass spectrometry. The expression patterns of TF and 6K were studied by pulse-chase labelling, immunoprecipitation and immunofluorescence, using both wild-type virus and a TF knockout mutant. We show that it is predominantly TF that is incorporated into the virion, not 6K as previously believed. Investigation of the 3' stimulatory signals responsible for efficient frameshifting at the UUUUUUA motif revealed a remarkable diversity of signals between different alphavirus species.

Conclusion

Our results provide a surprising new explanation for the 6K doublet, demand a fundamental reinterpretation of existing data on the alphavirus 6K protein, and open the way for future progress in the further characterization of the 6K and TF proteins. The results have implications for alphavirus biology, virion structure, viroporins, ribosomal frameshifting, and bioinformatic identification of novel frameshift-expressed genes, both in viruses and in cellular organisms.     

Translation of Sindbis virus mRNA: effects of sequences downstream of the initiating codon.

One incentive for developing the alphavirus Sindbis virus as a vector for the expression of heterologous proteins is the very high level of viral structural proteins that accumulates in infected cells. Although replacement of the structural protein genes by a heterologous gene should lead to an equivalent accumulation of the heterologous protein, the Sindbis virus capsid protein is produced at a level 10- to 20-fold higher than that of any foreign protein. Chimeric mRNAs which contain the first 275 nucleotides of the Sindbis virus 26S mRNA fused to the lacZ gene are also translated at the higher level. The enhancing sequences, located downstream of the AUG codon that initiates translation of the capsid protein, have a predicted hairpin-like structure; deletions in this region destroy the activity. These sequences enhance translation in infected cells but have the opposite effect in uninfected cells. Furthermore, translation of this RNA in infected cells is suppressed by a second viral RNA lacking the hairpin-like structure, but translation of the latter RNA is not affected. We propose that the hairpin-like structure presents a barrier to the movement of the ribosomes during translation of mRNA. In infected cells, under conditions in which this mRNA is essentially the only RNA being translated, a slowdown in the transit of the ribosomes gives factors present at low concentrations a chance to bind to the translation complex and permits a high level of functional complexes to be formed. In uninfected cells and in infected cells translating two different viral subgenomic mRNAs, a pause in the movement of the ribosomes along the RNA is no longer an advantage, because the required factors are now usurped by other translation complexes.     

Subgenomic mRNA of Aura alphavirus is packaged into virions.

Purified virions of Aura virus, a South American alphavirus related to Sindbis virus, were found to contain two RNA species, one of 12 kb and the other of 4.2 kb. Northern (RNA) blot analysis, primer extension analysis, and limited sequencing showed that the 12-kb RNA was the viral genomic RNA, whereas the 4.2-kb RNA present in virus preparations was identical to the 26S subgenomic RNA present in infected cells. The subgenomic RNA is the messenger for translation of the viral structural proteins, and its synthesis is absolutely required for replication of the virus. Although 26S RNA is present in the cytosol of all cells infected by alphaviruses, this is the first report of incorporation of the subgenomic RNA into alphavirus particles. Packaging of the Aura virus subgenomic mRNA occurred following infection of mosquito (Aedes albopictus C6/36), hamster (BHK-21), or monkey (Vero) cells. Quantitation of the amounts of genomic and subgenomic RNA both in virions and in infected cells showed that the ratio of genomic to subgenomic RNA was 3- to 10-fold higher in Aura virions than in infected cells. Thus, although the subgenomic RNA is packaged efficiently, the genomic RNA has a selective advantage during packaging. In contrast, in parallel experiments with Sindbis virus, packaging of subgenomic RNA was not detectable. We also found that subgenomic RNA was present in about threefold-greater amounts relative to genomic RNA in cells infected by Aura virus than in cells infected by Sindbis virus. Packaging of the Aura virus subgenomic RNA, but not those of other alphaviruses, suggests that Aura virus 26S RNA contains a packaging signal for incorporation into virions. The importance of the packaging of this RNA into virions in the natural history of the virus remains to be determined.     

Superinfection exclusion of alphaviruses in three mosquito cell lines persistently infected with Sindbis virus.

Three Aedes albopictus (mosquito) cell lines persistently infected with Sindbis virus excluded the replication of both homologous (various strains of Sindbis) and heterologous (Aura, Semliki Forest, and Ross River) alphaviruses. In contrast, an unrelated flavivirus, yellow fever virus, replicated equally well in uninfected and persistently infected cells of each line. Sindbis virus and Semliki Forest virus are among the most distantly related alphaviruses, and our results thus indicate that mosquito cells persistently infected with Sindbis virus are broadly able to exclude other alphaviruses but that exclusion is restricted to members of the alphavirus genus. Superinfection exclusion occurred to the same extent in three biologically distinct cell clones, indicating that the expression of superinfection exclusion is conserved among A. albopictus cell types. Superinfection of persistently infected C7-10 cells, which show a severe cytopathic effect during primary Sindbis virus infection, by homologous virus does not produce cytopathology, consistent with the idea that cytopathology requires significant levels of viral replication. A possible model for the molecular basis of superinfection exclusion, which suggests a central role for the alphavirus trans-acting protease that processes the nonstructural proteins, is discussed in light of these results.     

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.     

Heterologous interference in Aedes albopictus cells infected with alphaviruses.

Maximum amounts of 42S and 26S single-stranded viral RNA and viral structural proteins were synthesized in Aedes albopictus cells at 24 h after Sindbis virus infection. Thereafter, viral RNA and protein syntheses were inhibited. By 3 days postinfection, only small quantities of 42S RNA and no detectable 26S RNA or structural proteins were synthesized in infected cells. Superinfection of A. albopictus cells 3 days after Sindbis virus infection with Sindbis, Semliki Forest, Una, or Chikungunya alphavirus did not lead to the synthesis of intracellular 26S viral RNA. In contrast, infection with snowshoe hare virus, a bunyavirus, induced the synthesis of snowshoe hare virus RNA in both A. Ablpictus cells 3 days after Sindbis virus infection and previously uninfected mosquito cells. These results suggested that at 3 days after infection with Sindbis virus, mosquito cells restricted the replication of both homologous and heterologous alphaviruses but remained susceptible to infection with a bunyavirus. In superinfection experiments the the alphaviruses were differentiated on the basis of plaque morphology and the electrophoretic mobility of their intracellular 26S viral RNA species. Thus, it was shown that within 1 h after infection with eigher Sindbis or Chikungunya virus, A. albopictus cells were resistant to superinfection with Sindbis, Chikungunya, Una, and Semliki Forest viruses. Infected cultures were resistant to superinfection with the homologous virus indefinitely, but maximum resistance to superinfection with heterologous alphaviruses lasted for approximately 8 days. After that time, infected cultures supported the replication of heterologous alphaviruses to the same extent as did persistently infected cultures established months previously. However, the titer of heterologous alphavirus produced after superinfection of persistently infected cultures was 10- to 50-fold less than that produced by an equal number of previously uninfected A. albopictus cells. Only a small proportion (8 to 10%) of the cells in a persistently infected culture was capable of supporting the replication of a heterologous alphavirus.     

Mutating conserved cysteines in the alphavirus e2 glycoprotein causes virus-specific assembly defects

There are 80 trimeric, glycoprotein spikes that cover the surface of an alphavirus particle. The spikes, which are composed of three E2 and E1 glycoprotein heterodimers, are responsible for receptor binding and mediating fusion between the viral and host-cell membranes during entry. In addition, the cytoplasmic domain of E2 interacts with the nucleocapsid core during the last stages of particle assembly, possibly to aid in particle stability. During assembly, the spikes are nonfusogenic until the E3 glycoprotein is cleaved from E2 in the trans-Golgi network. Thus, a mutation in E2 potentially has effects on virus entry, spike assembly, or spike maturation. E2 is a highly conserved, cysteine-rich transmembrane glycoprotein. We made single cysteine-to-serine mutations within two distinct regions of the E2 ectodomain in both Sindbis virus and Ross River virus. Each of the E2 Cys mutants produced fewer infectious particles than wild-type virus. Further characterization of the mutant viruses revealed differences in particle morphology, fusion activity, and polyprotein cleavage between Sindbis and Ross River virus mutants, despite the mutations being made at corresponding positions in E2. The nonconserved assembly defects suggest that E2 folding and function is species dependent, possibly due to interactions with a virus-specific chaperone.     

Alphavirus nucleocapsid protein contains a putative coiled coil alpha-helix important for core assembly

The alphavirus nucleocapsid core is formed through the energetic contributions of multiple noncovalent interactions mediated by the capsid protein. This protein consists of a poorly conserved N-terminal region of unknown function and a C-terminal conserved autoprotease domain with a major role in virion formation. In this study, an 18-amino-acid conserved region, predicted to fold into an alpha-helix (helix I) and embedded in a low-complexity sequence enriched with basic and Pro residues, has been identified in the N-terminal region of the alphavirus capsid proteins. In Sindbis virus, helix I spans residues 38 to 55 and contains three conserved leucine residues, L38, L45, and L52, conforming to the heptad amino acid organization evident in leucine zipper proteins. Helix I consists of an N-terminally truncated heptad and two complete heptad repeats with beta-branched residues and conserved leucine residues occupying the a and d positions of the helix, respectively. Complete or partial deletion of helix I, or single-site substitutions at the conserved leucine residues (L45 and L52), caused a significant decrease in virus replication. The mutant viruses were more sensitive to elevated temperature than wild-type virus. These mutant viruses also failed to accumulate cores in the cytoplasm of infected cells, although they did not have defects in protein translation or processing. Analysis of these mutants using an in vitro assembly system indicated that the majority were defective in core particle assembly. Furthermore, mutant proteins showed a trans-dominant negative phenotype in in vitro assembly reactions involving mutant and wild-type proteins. We propose that helix I plays a central role in the assembly of nucleocapsid cores through coiled coil interactions. These interactions may stabilize subviral intermediates formed through the interactions of the C-terminal domain of the capsid protein and the genomic RNA and contribute to the stability of the virion.     

The 6-kilodalton membrane protein of Semliki Forest virus is involved in the budding process.

Alphavirus genomes encode a small hydrophobic protein of 6 kDa (the 6K protein) that is expressed as part of a large polyprotein containing the sequences of the two virus transmembranal glycoproteins which form the spikes of the infectious particle. Although made in amounts equivalent to those of the glycoproteins, very little of the 6K protein is found in secreted infectious virions. The role of this protein in virus replication and structure has been studied by use of a variety of mutationally altered forms of 6K, which yield phenotypically distinct viruses. A complete deletion of the gene encoding the 6K protein (delta 6K) of Semliki Forest Virus (SFV) has been constructed from an SFV infectious cDNA and the transcribed RNA-produced progeny virus that closely resembled the normal virus (P. Liljeström, S. Lusa, D. Huylebroeck, and H. Garoff, J. Virol. 65:4107-4113, 1991). Further studies of this mutant have now been performed, and they show that growth of delta 6K has a strong dependency on its host cell, varying from 2 to 50% of the rate of formation of the wild-type SFV. Mammalian cells are much more defective than insect and avian cells in replication of the delta 6K mutant. This mutant is not defective in formation and transport of the glycoproteins or in production of nucleocapsids, which accumulate at the plasma cell membrane in infected BHK cells. The major defect, thus, is in the final assembly and budding of new virus. In BHK cells infected with the delta 6K strain, a relatively large fraction of the total infectious virus formed can be recovered by osmotic lysis of exhaustively washed cells. Infectious SFV totally lacking 6K is identical to wild-type SFV in the early stages of virus replication, i.e., binding and uptake. The particles themselves are more thermolabile than those of wild-type SFV, suggesting that the 6K protein may be a part of the structure of wild-type virus or that the slower budding leads to an altered configuration of the trimeric spikes. These data support other studies that implicate the 6K protein as an important but nonessential component in the assembly and budding of the alphavirus particle, perhaps by affecting the packing of the glycoproteins and their interactions with membrane lipid.     

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.     

Characterization of a small, nonstructural viral polypeptide present late during infection of BHK cells by Semliki Forest virus.

BHK cells, late in infection with Semliki Forest virus, were found to contain a small virus-specific polypeptide not found in the mature virion. This polypeptide had an apparent molecular weight of 6,000 and is referred to here as the 6K protein. No [2-3H]mannose was incorporated into 6K, and hence it does not appear to be a glycoprotein. This protein appears to be a primary translation product of the subgenomic 26S mRNA, which encodes the viral structural proteins. The genes encoding the viral structural proteins are arranged on the message in the order of 5'-C-E3-E2-E1-3'. We have found that the gene coding for 6K is located to the 3' side of the gene encoding E2. Subcellular fractionation of pulse-labeled cells infected with Semliki Forest virus demonstrated that 6K, like the viral glycoproteins p62 and E1, was present predominantly in the rough microsomal membrane fraction. 6K appears to be analogous, therefore, to the nonstructural 4.2K protein present in cells infected with Sindbis virus.     

Maturation Defects in Temperature-sensitive Mutants of Sindbis Virus

Temperature-sensitive mutants of Sindbis virus, which synthesize viral ribonucleic acid (RNA) but not mature virus at the nonpermissible temperature, were selected for the study of viral maturation. Of these, three mutants which complement each other genetically were used. Two major proteins, the nucleocapsid and membrane proteins, located, respectively, in the viral nucleoid and membrane, were found in intact virions. In cells infected with wild-type Sindbis virus, four distinct types of viral RNA with sedimentation coefficients of 40S, 26S, 20S, and 15S were detected in constant distribution. The 20S RNA was ribonuclease-resistant, whereas the other types were ribonuclease-sensitive. The 40S RNA, identical to that obtained from the virion, was found associated with nucleocapsid protein as a subviral particle, which was assumed to be the nucleoid. Viral materials from cells infected with the mutants under nonpermissive conditions were compared with those from cells infected with wild-type virus, in terms of (i) the distribution of the different types of RNA, (ii) the association of infectious viral RNA into subviral particles, and (iii) the ability of infected cells to hemadsorb goose erythrocytes. According to these criteria, each of the three mutants demonstrated different maturation defects. Defective nucleocapsid proteins and membrane proteins may each account for one of the above mutants. The thrid mutant may have defects in a minor structural protein or possibly a maturation protein which is involved in the assembly of Sindbis virus.     

Defective transport of Sindbis virus glycoproteins in End4 mutant Chinese hamster ovary cells.

Mutant V.24.1, a temperature-sensitive derivative of Chinese hamster ovary cells, defines the End4 complementation group of mutants selected for resistance to protein toxins and has defective lysosomes at the restrictive temperature (P. A. Colbaugh, M. Stookey, and R. K. Draper, J. Cell Biol. 108:2211-2219, 1989). We have investigated the biosynthesis of Sindbis virus envelope glycoproteins in V.24.1 cells. When the cells were infected at the restrictive temperature, the envelope glycoproteins E1 and E2 were undetectable on the cell surface and proteolytic processing of the precursor protein pE2 to envelope protein E2 did not occur. Protein retained intracellularly was sensitive to endoglycosidase H and, by immunofluorescence localization, appeared to accumulate in the endoplasmic reticulum. We conclude that the genetic defect in V.24.1 cells impairs the transport of Sindbis virus glycoproteins, apparently at the level of export from the endoplasmic reticulum.     

Imaging of the Alphavirus Capsid Protein during Virus Replication

Alphaviruses are enveloped viruses with highly organized structures. The nucleocapsid (NC) core contains a capsid protein lattice enclosing the plus-sense RNA genome, and it is surrounded by a lipid bilayer containing a lattice of the E1 and E2 envelope glycoproteins. Capsid protein is synthesized in the cytoplasm and particle budding occurs at the plasma membrane (PM), but the traffic and assembly of viral components and the exit of virions from host cells are not well understood. To visualize the dynamics of capsid protein during infection, we developed a Sindbis virus infectious clone tagged with a tetracysteine motif. Tagged capsid protein could be fluorescently labeled with biarsenical dyes in living cells without effects on virus growth, morphology, or protein distribution. Live cell imaging and colocalization experiments defined distinct groups of capsid foci in infected cells. We observed highly motile internal puncta that colocalized with E2 protein, which may represent the transport machinery that capsid protein uses to reach the PM. Capsid was also found in larger nonmotile internal structures that colocalized with cellular G3BP and viral nsP3. Thus, capsid may play an unforeseen role in these previously observed G3BP-positive foci, such as regulation of cellular stress granules. Capsid puncta were also observed at the PM. These puncta colocalized with E2 and recruited newly synthesized capsid protein; thus, they may be sites of virus assembly and egress. Together, our studies provide the first dynamic views of the alphavirus capsid protein in living cells and a system to define detailed mechanisms during alphavirus infection.     

Enhancement of the interferon-induced double-stranded RNA-dependent protein kinase activity by Sindbis virus infection and heat-shock stress

In extracts of FL cells that were infected with Sindbis virus or treated with heat-shock stress, dsRNA-dependent phosphorylation of 77K protein was markedly increased. The 77K phosphoprotein was indistinguishable from the autophosphorylated and activated form of interferon (IFN)-induced dsRNA-dependent protein kinase (PK-I) by two-dimensional gel electrophoresis, and was immunologically related to P68 (Galabru, J. and Hovanessian, A., J. Biol. Chem. 262, 15538 (1987], the HeLa cell counterpart of PK-I. Immunoblotting experiments using monoclonal antibody against PK-I revealed that control cell extracts contained a substantial amount of PK-I protein, although they showed no measurable PK-I activity even when dsRNA was added. The amount of PK-I protein did not increase during a transient dsRNA-dependent enhancement of PK-I activity caused by Sindbis virus infection and heat-shock stress. This implies that the conversion of PK-I protein from a dsRNA-unresponsive form to a responsive form may be important in the regulation of PK-I activity. A similar mode of PK-I regulatory mechanism was operative in the early stages of IFN treatment, although after a prolonged treatment a net synthesis of the PK-I protein did take place.     

High-affinity laminin receptor is a receptor for Sindbis virus in mammalian cells.

Sindbis virus is an alphavirus with a very wide host range, being able to infect many birds and mammals as well as mosquitoes. We have isolated a monoclonal antibody that largely blocks virus binding to mammalian cells. This antibody was found to be directed against the C-terminal domain of the high-affinity laminin receptor, a 67-kDa protein present on the cell surface that binds with high affinity to basement membrane laminin and that is known to be important in development and in tumor invasion. This receptor is believed to be formed from a 295-amino-acid polypeptide that is modified in some unknown way after translation. The primary sequence of this 295-amino-acid protein is highly conserved among mammals. We found the hamster amino acid sequence to be identical to a mouse sequence and to differ at only two amino acids from a human sequence and at two amino acids from a bovine sequence. To verify the importance of the laminin receptor for infection by Sindbis virus, hamster cells were stably transfected with the gene encoding the 295-amino-acid protein under the control of a high-efficiency promoter. Such transfected hamster cells overexpressed the laminin receptor at the cell surface, bound severalfold more Sindbis virions than did the parental cells, and became infected by Sindbis virus with a higher efficiency. In contrast, cells transfected with the antisense gene expressed less laminin receptor on the surface and were less susceptible to the virus. Binding of the virus varied linearly with the amount of laminin receptor on the cell surface, whereas infectivity measured with a plaque assay varied with the 1.4 power of the receptor concentration, suggesting that interaction with more than one receptor aids virus penetration. By these criteria, the laminin receptor functions as the major receptor for Sindbis virus entry into mammalian cells. We also found that the anti-laminin receptor antibody partially blocked Sindbis virus binding to mosquito cells, suggesting that the laminin receptor is conserved in mosquitoes and functions as a Sindbis virus receptor in this host. The wide distribution of this highly conserved receptor may be in part responsible for the broad host range exhibited by the virus, which infects a wide range of mammals and birds as well as its mosquito vector and can infect many different tissues within these hosts.(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification of genes involved in the host response to neurovirulent alphavirus infection

Single-amino-acid mutations in Sindbis virus proteins can convert clinically silent encephalitis into uniformly lethal disease. However, little is known about the host gene response during avirulent and virulent central nervous system (CNS) infections. To identify candidate host genes that modulate alphavirus neurovirulence, we utilized GeneChip Expression analysis to compare CNS gene expression in mice infected with two strains of Sindbis virus that differ by one amino acid in the E2 envelope glycoprotein. Infection with Sindbis virus, dsTE12H (E2-55 HIS), resulted in 100% mortality in 10-day-old mice, whereas no disease was observed in mice infected with dsTE12Q (E2-55 GLN). dsTE12H, compared with dsTE12Q, replicated to higher titers in mouse brain and induced more CNS apoptosis. Infection with the neurovirulent dsTE12H strain was associated with both a greater number of host genes with increased expression and greater changes in levels of host gene expression than was infection with the nonvirulent dsTE12Q strain. In particular, dsTE12H infection resulted in greater increases in the levels of mRNAs encoding chemokines, proteins involved in antigen presentation and protein degradation, complement proteins, interferon-regulated proteins, and mitochondrial proteins. At least some of these increases may be beneficial for the host, as evidenced by the demonstration that enforced expression of the antiapoptotic mitochondrial protein peripheral benzodiazepine receptor (PBR) protects neonatal mice against lethal Sindbis virus infection. Thus, our findings identify specific host genes that may play a role in the host protective or pathologic response to neurovirulent Sindbis virus infection.