Cholesterol Dependence of Pseudorabies Herpesvirus Entry

Lipid rafts are special microdomains in the plasma membrane. They are enriched in sphingolipids and cholesterol, playing critical roles in many biological processes. The purpose of this study is to analyze the requirement of cholesterol, a crucial component of lipid rafts for cell infection by pseudorabies virus (PrV). Cholesterol of plasma membrane or viral envelope was depleted with methyl-beta-cyclodextrin (MβCD), and the infectivity of three strains of PrV was determined with plaque assays. The effect of adding cholesterol to MβCD-treated cells and viruses on cell infection was analyzed. Furthermore, effect of post-adsorption cholesterol depletion on PrV infection was investigated. We show that cholesterol depletion of either the plasma membrane or the viral membrane by MβCD significantly impaired the infectivity of PrV strains Kaplan, Becker, and Bartha K-61. The virus was shown to have lower cholesterol content and to respond to lower MβCD concentrations. Exogenous cholesterol added to either MβCD-treated cells or virions partially restored the virus infectivity. Optimal PrV infection requires cholesterol in viral and plasma membranes.     

Ribonuclease Sensitivity of Semliki Forest Virus Nucleocapsids

Treatment of Semliki Forest virus nucleocapsids with pancreatic ribonuclease (1 mug/ml, 37 C) digests the ribonucleic acid to acid-soluble fragments; the nucleocapsid protein forms a rapidly sedimenting aggregate.     

Pseudorevertants of a Semliki Forest Virus Fusion-Blocking Mutation Reveal a Critical Interchain Interaction in the Core Trimer

Semliki Forest virus (SFV) is an enveloped alphavirus that infects cells by a low-pH-triggered membrane fusion reaction mediated by the viral E1 protein. E1 inserts into target membranes and refolds to a hairpin-like homotrimer containing a central core trimer and an outer layer composed of domain III and the juxtamembrane stem region. The key residues involved in mediating E1 trimerization are not well understood. We recently showed that aspartate 188 in the interface of the core trimer plays a critical role. Substitution with lysine (D188K) blocks formation of the core trimer and E1 trimerization and strongly inhibits virus fusion and infection. Here, we have isolated and characterized revertants that rescued the fusion and growth defects of D188K. These revertants included pseudorevertants containing acidic or polar neutral residues at E1 position 188 and a second-site revertant containing an E1 K176T mutation. Computational analysis using multiconformation continuum electrostatics revealed an important interaction bridging D188 of one chain with K176 of the adjacent chain in the core trimer. E1 K176 is completely conserved among the alphaviruses, and mutations of K176 to threonine (K176T) or isoleucine (K176I) produced similar fusion phenotypes as D188 mutants. Together, our data support a model in which a ring of three salt bridges formed by D188 and K176 stabilize the core trimer, a key intermediate of the alphavirus fusion protein.Enveloped viruses contain a phospholipid bilayer that surrounds and protects the viral genome until fusion of the virus and host membranes delivers the genome into the cytoplasm. Fusion is mediated by transmembrane fusion proteins in the virus envelope. Viruses have evolved specific mechanisms to trigger membrane fusion upon interaction with the host cell (15, 42). For example, the fusion protein of the human immunodeficiency virus is triggered by receptor and coreceptor binding, while alphaviruses such as Semliki Forest virus (SFV) and flaviviruses such as dengue virus are triggered by exposure to acidic pH. The fusion trigger initiates the conversion of the fusion protein from the metastable prefusion state to the more energetically stable postfusion state (14, 15). The energy released during the refolding of the membrane fusion protein drives the merger of the viral and host membranes.Alphaviruses take advantage of the low-pH environment of the endocytic pathway to trigger membrane fusion during entry (37). E1 is the fusion protein and forms heterodimers with the E2 protein on the virus surface. These heterodimers are organized into trimers (E2/E1)₃ to form the icosahedral glycoprotein shell (21, 30, 43). Alphaviruses bind to cell surface receptors and are internalized by clathrin-mediated endocytosis and delivered to endosomes (16). Here, low pH induces E1/E2 heterodimer dissociation, E1 insertion into endosomal membranes, and the refolding of E1 to the final postfusion homotrimer conformation (16, 37). The resultant membrane fusion releases the viral RNA genome into the cytoplasm to initiate virus replication. During replication the envelope glycoproteins are translated in the endoplasmic reticulum (ER), processed through the cellular secretory pathway, and delivered to the plasma membrane, where budding of virus particles occurs (20).The alphavirus membrane fusion protein E1 and the flavivirus membrane fusion protein E are structurally related. These proteins are often referred to as class II fusion proteins to distinguish them from the class I proteins (exemplified by influenza hemagglutinin [HA] and HIV gp41) and the class III proteins (exemplified by vesicular stomatitis virus G and baculovirus gp64) (reviewed in references 15, 19, and 42). Class II fusion proteins such as the SFV E1 protein are composed almost exclusively of β-sheets organized into three domains (DI to DIII) (22, 35). There is a central DI that connects to the elongated DII containing the hydrophobic fusion loop at the tip. The other side of DI connects to DIII, followed by the stem and transmembrane domain that anchors the protein to the viral membrane. Unlike the class I and class III proteins, the alphavirus and flavivirus fusion proteins are dimers in the prefusion state and homotrimers in the postfusion state. During the prefusion to postfusion transition, DIII moves approximately 37 Å toward the target membrane-inserted fusion loop. The resulting hairpin-like conformation brings the viral and host membranes together to mediate membrane fusion (4, 13, 31) (see Fig. ​Fig.11 for the SFV E1 homotrimer structure).Open in a separate windowFIG. 1.Location of revertants in the E1 trimer. (A) The crystal structure of the postfusion E1* homotrimer (PDB entry 1RER) is shown with two chains in light gray and one chain colored as follows: DI in red, DII in yellow, DIII in blue, the fusion loop in green, the DI-DIII linker in black, and the N-terminal region of the stem in purple. The C-terminal stem connects to the transmembrane domain (neither of these is present in the crystal structure). The E1 residues discussed in this work are labeled and are represented as sticks highlighted with colors for clarity. D188 on the g-h loop in DII is shown in cyan, K176 on the DII β-strand f is in pink, and P14 on the DI β-strand C₀ is in orange. (B) A view of the central trimer interface (fusion loops pointing toward the viewer) showing the positions of D188 and K176 in the crystal structure, with colors as in panel A but with oxygen shown in red and nitrogen in blue on the stick structures. A holmium atom (not shown) is coordinated by the three inwardly pointing D188 residues. This figure was prepared using PyMol (9).Alphavirus membrane fusion is a necessary step for virus infection and occurs rapidly and efficiently with a threshold pH of ∼6.2 (reviewed in reference 16). Mutations that block trimerization prevent virus fusion and infection (18, 29). Similarly, chemical inhibition of trimerization inhibits fusion in a virus-liposome system (8). Fusion and infection are also specifically inhibited by the addition of exogenous DIII, which binds a trimeric intermediate of E1 and prevents fold-back of endogenous DIII and formation of the final postfusion trimer (25).Although formation of the E1 homotrimer is crucial to membrane fusion, little is known about the residues that regulate the overall process and steps of trimerization. The dramatic effects of local environment on the pK_a of ionizable residues make it difficult to predict the key players that initiate and drive E1 refolding, despite the fact that it takes place in a physiological window between pH values of ∼5 and 7 (37). The postfusion structures of E1 and E show that DI and DII comprise the central region of the trimer and that DIII and the stem pack against this core to form the outer layer of the trimer (4, 13, 31). It was recently shown that a truncated version of SFV E1 containing only DI and DII forms a stable core trimer with biochemical features similar to those of the full-length trimer (38). This result suggests that important interactions exist within the alphavirus core trimer.Inspection of the E1 postfusion structure identified a conserved aspartate residue, D188, located in the central trimer interface. This residue was shown to play an important role in the initial events of trimerization (29). Mutation of D188 to lysine (D188K) blocks virus fusion and infection and prevents stable trimers from forming while having no effect on E2/E1 heterodimer dissociation or E1 membrane insertion. Here, we have selected and characterized viable revertants of the D188K mutant and used them to identify an important interaction of D188 with a lysine residue on the adjoining E1 chain. This ring of salt bridges acts to stabilize the E1 core trimer and helps to drive formation of an extended trimer intermediate.(The data in this paper are from a thesis to be submitted by C. Y. Liu in partial fulfillment of the requirements for a Ph.D. in the Graduate Division of Medical Sciences, Albert Einstein College of Medicine, Yeshiva University, New York, NY.)     

Cholesterol is required in the exit pathway of Semliki Forest virus

The enveloped alphavirus Semliki Forest virus (SFV) infects cells via a membrane fusion reaction triggered by low pH. For fusion to occur cholesterol is required in the target membrane, as demonstrated both in in vitro fusion assays and in vivo for virus infection of a host cell. In this paper we examine the role of cholesterol in postfusion events in the SFV life cycle. Cholesterol-depleted insect cells were transfected with SFV RNA or infected at very high multiplicities to circumvent the fusion block caused by the absence of cholesterol. Under these conditions, the viral spike proteins were synthesized and transported to the site of p62 cleavage with normal kinetics. Surprisingly, the subsequent exit of virus particles was dramatically slowed compared to cholesterol-containing cells. The inhibition of virus production could be reversed by the addition of cholesterol to depleted cells. In contrast to results with SFV, no cholesterol requirement for virus exit was observed for the production of either the unrelated vesicular stomatitis virus or a cholesterol-independent SFV fusion mutant. Thus, cholesterol was only critical in the exit pathway of viruses that also require cholesterol for fusion. These results demonstrate a specific and unexpected lipid requirement in virus exit, and suggest that in addition to its role in fusion, cholesterol is involved in the assembly or budding of SFV.     

Inactivation of Semliki Forest Virus in aerosols.

Purified Semliki forest virus in aerosols is inactivated rapidly at 40% and above 70% relative humidity. At all humidities tested the decay of virus infectivity runs parallel with the decrease in hemagglutination activity, whereas the biological integrity of the virus ribonucleic acid is preserved. Also, free infectious ribonucleic acid is stable after spraying at all relative humidities. Evidence is presented for the hypothesis that above 20% relative humidity, virus inactivation in aersols is mainly due to surface-dependent factors, damaging the virus coat.     

Recombinant protein production using the Semliki Forest Virus expression system

We report here the successful scale up of transient recombinant protein expression to litre scale using Semliki Forest Virus System. The expression of bacterial β-galactosidase was initially compared in BHK and CHO cells and the conditions for optimal infection of BHK cells were identified. 10% FCS in a medium at pH 6.9 and infection in small volumes were found to be optimal. A high MOI results in an increased recombinant protein yield. Stirring does not affect the infection process. Finally we applied these optimal conditions to the production of a microsomal enzyme, human cyclooxygenase-2 in suspension spinners. Five independant productions at the 1 litre scale yielded reproducible substantial amounts of recombinant protein (16 mg microsomal protein 10⁹ cells⁻¹) with an average specific activity of 3942 ± 765 pg PGE₂ μg⁻¹ microsomal protein 5 min⁻¹. This revised version was published online in July 2006 with corrections to the Cover Date.     

A Single Amino Acid Change in the Nuclear Localization Sequence of the nsP2 Protein Affects the Neurovirulence of Semliki Forest Virus

The replicase protein nsP2 of Semliki Forest virus (SFV) has a ⁶⁴⁸RRR nuclear localization signal and is transported to the nucleus. SFV-RDR has a single amino acid change which disrupts this sequence and nsP2 nuclear transport. In BHK cells, SFV4 and SFV-RDR replicate to high titers, but SFV-RDR is less virulent in mice. We compared the replication of SFV4 and SFV-RDR in adult mouse brain. Both SFV4 and SFV-RDR were neuroinvasive following intraperitoneal inoculation. SFV4 spread rapidly throughout the brain, whereas SFV-RDR infection was confined to small foci of cells. Both viruses infected neurons and oligodendrocytes. Both viruses induced apoptosis in cultured BHK cells but not in the cells of the adult mouse brain. SFV-RDR infection of mice lacking alpha/beta interferon receptors resulted in widespread virus distribution in the brain. Thus, a component of the viral replicase plays an important role in the neuropathogenesis of SFV.     

Expression of Ligand-Gated Ion Channels with the Semliki Forest Virus Expression System

Abstract

Two types of ligand-gated ion channels were expressed with the Semliki Forest virus (SFV) expression system.The cDNAs for mouse serotonin 5-HT₃ receptor and rat and human purinoreceptor P_2x subtypes were introduced into the pSFV1 vector. In vitro transcribed RNAs were coelectroporated with pSFV-Helper2 RNA into BHK cells, where in vivo packaging resulted in high titer SFV-5-HT₃ and SFV-P_2x virus stocks. Infection of BHK, CHO and RJN cells resulted in high-level expression of recombinant receptors. Saturation binding analysis indicated the presence of more than 3 × 10⁶ 5-HT3 receptors per cell. Binding studies on isolated membranes yielded from 10 to 60 pmol of either 5-HT₃ or P_2x receptor per mg protein. Functional responses to the P_2x receptors were demonstrated in SFV-infected CHO cells by Ca²⁺ mobilization or by ⁴⁵Ca²⁺ influx. High amplitude electrophysiological responses were also detected for both SFV-5-HT₃ and SFV-P_2x infected CHO cells in whole-cell patch clamp recordings. To facilitate the purification procedure of SFV-expressed recombinant receptors a histidine tag was introduced at the C-terminus of the 5-HT₃ receptor. This 5-HT₃His receptor showed high levels of expression, specific binding and high amplitude electrophysiological responses. For large scale expression the BHK cells were adapted to suspension culture and were efficiently infected in a 11.5 liter fermentor culture with SFV-5-HT3His resulting in high-level expression, 52 pmol receptor per mg protein corresponding to 3.2 × 10⁶ receptors per cell.     

Shutoff on Neuroblastoma Cell Protein Synthesis by Semliki Forest Virus: Loss of Ability of Crude Initiation Factors to Recognize Early Semliki Forest Virus and Host mRNA's

A crude ribosomal wash containing the initiation factors of protein synthesis was isolated from mouse neuroblastoma cells 8 h after infection with Semliki Forest virus (SFV). The activity of this wash was compared with that of a wash from control cells in a cell-free protein-synthesizing “pH5” system, with early SFV mRNA (42S), late SFV mRNA (26S), encephalomyocarditis virus (EMC) mRNA, or neuroblastoma polyadenylated mRNA templates. A pronounced loss of activity (±80%) of the crude ribosomal wash from infected cells was observed with host mRNA (neuroblastoma polyadenylated mRNA) and early SFV mRNA, messengers which contain a cap structure at the 5′ terminus. However, these washes were only slightly less active in systems programmed with (noncapped) EMC mRNA and late SFV mRNA. Although late SFV mRNA (26S) is capped, the synthesis of late (= structural) proteins in infected lysates was insensitive to inhibition by cap analogs. Purified initiation factors eIF-4B (M_r, 80,000) and cap-binding protein (M_r, 24,000) from reticulocytes (but none of the others) were able to restore the activity of infected factors to about 90% of control levels in systems programmed with early SFV mRNA and host mRNA. These observations indicate that infection-exposed crude initiation factors have a decreased level of eIF-4B and cap-binding protein activity. However, after partial purification of these and other initiation factors from infected and control cells, we found no significant difference in activity when model assay systems were used. Furthermore, both eIF-4B and cap-binding protein from infected cells were able to restore the activity of these infection-exposed factors to the same level obtained when these factors isolated from control cells or reticulocytes were added. A possible mechanism for the shutoff of host cell protein synthesis is discussed.     

Two-Helper RNA System for Production of Recombinant Semliki Forest Virus Particles

Alphavirus expression systems based on suicidal virus particles carrying recombinant replicons have proven to be a very efficient way to deliver genes for heterologous protein expression. However, present strategies for production of such particles have biosafety limitations due to the generation, by RNA recombination, of replication-proficient viruses (RPVs). Here we describe a new packaging system for Semliki Forest virus (SFV) based on a the use of a two-helper system in which the capsid and spike proteins of the C-p62-6K-E1 polyprotein are expressed from two independent RNA molecules. The capsid gene contains a translational enhancer and therefore that sequence was also engineered in front of the spike sequence p62-6K-E1. A sequence coding for the foot-and-mouth disease virus 2A autoprotease was inserted in frame between the capsid translational enhancer and the spike genes. This allows production of the spike proteins at high levels with cotranslational removal of the enhancer sequence and normal biosynthesis of the spike complex. The autoprotease activity of the capsid protein was abolished by mutation, further increasing the biosafety of the system. Cotransfection of cells with both helper RNAs and an SFV vector replicon carrying the LacZ gene led to production of recombinant particles with titers of up to 8 × 10⁸ particles per 10⁶ cells. Extensive analysis failed to demonstrate the presence of any RPVs, emphasizing the high biosafety of the system based on two-helper RNAs.     

Formation and characterization of the trimeric form of the fusion protein of Semliki Forest Virus

Enveloped animal viruses infect cells via fusion of the viral membrane with a host cell membrane. Fusion is mediated by a viral envelope glycoprotein, which for a number of enveloped animal viruses rearranges itself during fusion to form a trimeric alpha-helical coiled-coil structure. This conformational change from the metastable, nonfusogenic form of the spike protein to the highly stable form involved in fusion can be induced by physiological activators of virus fusion and also by a variety of destabilizing conditions. The E1 spike protein subunit of Semliki Forest virus (SFV) triggers membrane fusion upon exposure to mildly acidic pH and forms a homotrimer that appears necessary for fusion. We have here demonstrated that formation of the E1 homotrimer was efficiently triggered under low-pH conditions but not by perturbants such as heat or urea, despite their induction of generalized conformational changes in the E1 and E2 subunits and partial exposure of an acid-specific E1 epitope. We used a sensitive fluorescence assay to show that neither heat nor urea treatment triggered SFV-liposome fusion at neutral pH, although either treatment inactivated subsequent low-pH-triggered fusion activity. Once formed, the low-pH-induced E1 homotrimer was very stable and was only dissociated under harsh conditions such as heating in sodium dodecyl sulfate. Taken together, these data, as well as protein structure predictions, suggest a model in which the less stable native E1 subunit specifically responds to low pH to form the more stable E1 homotrimer via conformational changes different from those of the coiled-coil type of fusion proteins.     

Human MxA Protein Confers Resistance to Semliki Forest Virus and Inhibits the Amplification of a Semliki Forest Virus-Based Replicon in the Absence of Viral Structural Proteins

Mx proteins form a small family of interferon (IFN)-induced GTPases with potent antiviral activity against various negative-strand RNA viruses. To examine the antiviral spectrum of human MxA in homologous cells, we stably transfected HEp-2 cells with a plasmid directing the expression of MxA cDNA. HEp-2 cells are permissive for many viruses and are unable to express endogenous MxA in response to IFN. Experimental infection with various RNA and DNA viruses revealed that MxA-expressing HEp-2 cells were protected not only against influenza virus and vesicular stomatitis virus (VSV) but also against Semliki Forest virus (SFV), a togavirus with a single-stranded RNA genome of positive polarity. In MxA-transfected cells, viral yields were reduced up to 1,700-fold, and the degree of inhibition correlated well with the expression level of MxA. Furthermore, expression of MxA prevented the accumulation of 49S RNA and 26S RNA, indicating that SFV was inhibited early in its replication cycle. Very similar results were obtained with MxA-transfected cells of the human monocytic cell line U937. The results demonstrate that the antiviral spectrum of MxA is not restricted to negative-strand RNA viruses but also includes SFV, which contains an RNA genome of positive polarity. To test whether MxA protein exerts its inhibitory activity against SFV in the absence of viral structural proteins, we took advantage of a recombinant vector based on the SFV replicon. The vector contains only the coding sequence for the viral nonstructural proteins and the bacterial LacZ gene, which was cloned in place of the viral structural genes. Upon transfection of vector-derived recombinant RNA, expression of the β-galactosidase reporter gene was strongly reduced in the presence of MxA. This finding indicates that viral components other than the structural proteins are the target of MxA action.     

Electroporation-Mediated Delivery of Nucleolar Targeting Sequences from Semliki Forest Virus Nucleocapsid Protein

Abstract

Electroporation was used as a powerful and simple method to probe to the intracellular distribution and trafficking of signal sequences. By coupling synthetic peptides to carrier reporter groups, specific amino acid sequences responsible for nucleolar targeting of Semliki Forest virus (SFV) Core (C) protein were found out. In the N-terminal part of the C protein the sequences ⁶⁶KPKKKKTTKPKPKTQPKK^{83 92}KKKDKQADKKKKP¹⁰⁵ are able to situate BSA or KLH as reporter proteins in the nucleolus, suggesting that SFV C protein contains at least two independent nucleolar targeting sequences.     

B cells and antibodies in the pathogenesis of myelin injury in Semliki Forest Virus encephalomyelitis

To determine the contribution of B cells to brain myelin injury in Semliki Forest Virus (SFV) encephalomyelitis, normal C57BL/6 (B6) and B-cell-deficient (C57BL/6-tm1Cgn) B6 mice were infected with SFV. The peak of clinical disease, i.e., the time at which the greatest proportions of mice had moderate to severe clinical signs, appeared earlier in B6 mice [day 7 postinfection (pi)] than in B-cell-deficient mice (day 21 pi). By flow cytometry, no clear differences were found in the percentages of CD3(+)CD4(+) T cells in the brains of B6 and B-cell-deficient mice. However, by day 21 pi, percentages of CD3(+)CD8(+) T cells were greater in brains of B-cell-deficient than in those of B6 mice. On day 21 pi, percentages of CD19(+) B cells were maximal in B6 mice, but B cells were absent in B-cell-deficient mice at all time points. Sera obtained from B6 mice showed antibody responses to SFV, to SFV E2 peptides p137-151 and p115-133, and to peptides of myelin oligodendrocyte glycoprotein p18-32 and myelin basic protein (MBP) p64-75. Sera obtained from B-cell-deficient mice showed minimal or no reactivity to SFV, E2, or myelin peptides. CNS inflammatory and PAS-positive macrophage foci were maximal on days 7-14 pi in all mice. Additionally, B6 mice had brain white matter vacuolation, whereas B-cell-deficient mice did not. These data suggest that brain infiltrating B cells and anti-myelin antibodies contribute to myelin injury in SFV encephalomyelitis.     

Template RNA Length Determines the Size of Replication Complex Spherules for Semliki Forest Virus

The replication complexes of positive-strand RNA viruses are always associated with cellular membranes. The morphology of the replication-associated membranes is altered in different ways in different viral systems, but many viruses induce small membrane invaginations known as spherules as their replication sites. We show here that for Semliki Forest virus (SFV), an alphavirus, the size of the spherules is tightly connected with the length of the replicating RNA template. Cells with different model templates, expressed in trans and copied by the viral replicase, were analyzed with correlative light and electron microscopy. It was demonstrated that the viral-genome-sized template of 11.5 kb induced spherules that were ∼58 nm in diameter, whereas a template of 6 kb yielded ∼39-nm spherules. Different sizes of viral templates were replicated efficiently in trans, as assessed by radioactive labeling and Northern blotting. The replication of two different templates, in cis and trans, yielded two size classes of spherules in the same cell. These results indicate that RNA plays a crucial determining role in spherule assembly for SFV, in direct contrast with results from other positive-strand RNA viruses, in which either the presence of viral RNA or the RNA size do not contribute to spherule formation.     

Fatty Chains of Different Lipid Classes of Semliki Forest Virus and Host Cell Membranes

Semliki Forest virus was grown in BHK-21 cells. The major classes of phospho-and glycolipids of the virus were analyzed for the compositions of fatty acids, aldehydes, and sphingosine bases, and the major glycerophospholipids were analyzed for the relative proportions of alkenyl-acyl, alkyl-acyl, and diacyl forms. All viral lipid classes proved to be mixtures of several molecular species. Each class contained a characteristic mixture of fatty chains, which was different in all other classes. All viral lipid classes resembled their counterparts of the host plasma membrane and also those of the endoplasmic reticulum. The gangliosides of the virus and the plasma membrane proved to be similar even at the level of individual molecular species. The number of certain lipid molecules in an average virion was less than the number of the protein molecules.     

A Single Point Mutation in Nonstructural Protein NS2 of Bovine Viral Diarrhea Virus Results in Temperature-Sensitive Attenuation of Viral Cytopathogenicity

For Bovine viral diarrhea virus (BVDV), the type species of the genus Pestivirus in the family Flaviviridae, cytopathogenic (cp) and noncytopathogenic (ncp) viruses are distinguished according to their effect on cultured cells. It has been established that cytopathogenicity of BVDV correlates with efficient production of viral nonstructural protein NS3 and with enhanced viral RNA synthesis. Here, we describe generation and characterization of a temperature-sensitive (ts) mutant of cp BVDV strain CP7, termed TS2.7. Infection of bovine cells with TS2.7 and the parent CP7 at 33°C resulted in efficient viral replication and a cytopathic effect. In contrast, the ability of TS2.7 to cause cytopathogenicity at 39.5°C was drastically reduced despite production of high titers of infectious virus. Further experiments, including nucleotide sequencing of the TS2.7 genome and reverse genetics, showed that a Y1338H substitution at residue 193 of NS2 resulted in the temperature-dependent attenuation of cytopathogenicity despite high levels of infectious virus production. Interestingly, TS2.7 and the reconstructed mutant CP7-Y1338H produced NS3 in addition to NS2-3 throughout infection. Compared to the parent CP7, NS2-3 processing was slightly decreased at both temperatures. Quantification of viral RNAs that were accumulated at 10 h postinfection demonstrated that attenuation of the cytopathogenicity of the ts mutants at 39.5°C correlated with reduced amounts of viral RNA, while the efficiency of viral RNA synthesis at 33°C was not affected. Taken together, the results of this study show that a mutation in BVDV NS2 attenuates viral RNA replication and suppresses viral cytopathogenicity at high temperature without altering NS3 expression and infectious virus production in a temperature-dependent manner.The pestiviruses Bovine viral diarrhea virus-1 (BVDV-1), BVDV-2, Classical swine fever virus (CSFV), and Border disease virus (BDV) are causative agents of economically important livestock diseases. Together with the genera Flavivirus, including several important human pathogens like Dengue fever virus, West Nile virus, Yellow fever virus, and Tick-borne encephalitis virus, and Hepacivirus (human Hepatitis C virus [HCV]), the genus Pestivirus constitutes the family Flaviviridae (8, 20). All members of this family are enveloped viruses with a single-stranded positive-sense RNA genome encompassing one large open reading frame (ORF) flanked by 5′ and 3′ nontranslated regions (NTR) (see references 8 and 28 for reviews). The ORF encodes a polyprotein which is co- and posttranslationally processed into the mature viral proteins by viral and cellular proteases. For BVDV, the RNA genome is about 12.3 kb in length and encodes a polyprotein of about 3,900 amino acids. The first third of the ORF encodes a nonstructural (NS) autoprotease and four structural proteins, while the remaining part of the genome encodes NS proteins which share many common characteristics and functions with the corresponding NS proteins encoded by the HCV genome (8, 28). NS2 of BVDV represents a cysteine autoprotease which is distantly related to the HCV NS2-3 protease (26). NS3, NS4A, NS4B, NS5A, and NS5B are essential components of the pestivirus replicase (7, 10, 49). NS3 possesses multiple enzymatic activities, namely serine protease (48, 52, 53), NTPase (46), and helicase activity (51). NS4A acts as an essential cofactor for the NS3 proteinase. NS5B represents the RNA-dependent RNA polymerase (RdRp) (22, 56). The functions of NS4B and NS5A remain to be determined. NS5A has been shown to be a phosphorylated protein that is associated with cellular serine/threonine kinases (44).According to their effects in tissue culture, two biotypes of pestiviruses are distinguished: cytopathogenic (cp) and noncytopathogenic (ncp) viruses (17, 27). The occurrence of cp BVDV in cattle persistently infected with ncp BVDV is directly linked to the induction of lethal mucosal disease in cattle (12, 13). Previous studies have shown that cp BVDV strains evolved from ncp BVDV strains by different kinds of mutations. These include RNA recombination with various cellular mRNAs, resulting in insertions of cellular protein-coding sequences into the viral genome, as well as insertions, duplications, and deletions of viral sequences, and point mutations (1, 2, 9, 24, 33, 36, 37, 42). A common consequence of all these genetic changes in cp BVDV genomes is the efficient production of NS3 at early and late phases of infection. In contrast, NS3 cannot be detected in cells at late time points after infection with ncp BVDV. An additional major difference is that the cp viruses produce amounts of viral RNA significantly larger than those of their ncp counterparts (7, 32, 50). While there is clear evidence that cell death induced by cp BVDV is mediated by apoptosis, the molecular mechanisms involved in pestiviral cytopathogenicity are poorly understood. In particular, the role of NS3 in triggering apoptosis remains unclear. It has been hypothesized that the NS3 serine proteinase might be involved in activation of the apoptotic proteolytic cascade (21, 55). Furthermore, it has been suggested that the NS3-mediated, enhanced viral RNA synthesis of cp BVDV and subsequently larger amounts of viral double-stranded RNAs may play a crucial role in triggering apoptosis (31, 54).In this study, we describe generation and characterization of a temperature-sensitive (ts) cp BVDV mutant whose ability to cause viral cytopathogenicity at high temperature is strongly attenuated. Our results demonstrate that a single amino acid substitution in NS2 attenuates BVDV cytopathogenicity at high temperature without affecting production of infectious viruses and expression of NS3 in a temperature-dependent manner.     

Production of Semliki Forest Virus from hamster kidney cells in deep culture vessels

The growth of Semliki Forest Virus in stirred culture vessels at volumes of 4 and 301. is described. Virus can be produced on a large scale in deep culture using industrial type vessels. Control of pH within close limits is important for maximum production of infective virus. With the parent, strain of SFV, virus yields were found to be influenced by an interference phenomenon which was apparently not due to interferon. Growth of a cloned strain of SFV obtained by serial selection of large plaques was not affected by this phenomenon. The cloned strain, when inoculated at a cell/virus input ratio of 1:1, gave maximum virus titers of 10¹⁰ p.f.u./ml., indicating an average yield of 10,000 p.f.u/BHK cell.