Role of Cholesterol Pathways in Norovirus Replication

Norwalk virus (NV) is a prototype strain of the noroviruses (family Caliciviridae) that have emerged as major causes of acute gastroenteritis worldwide. I have developed NV replicon systems using reporter proteins such as a neomycin-resistant protein (NV replicon-bearing cells) and a green fluorescent protein (pNV-GFP) and demonstrated that these systems were excellent tools to study virus replication in cell culture. In the present study, I first performed DNA microarray analysis of the replicon-bearing cells to identify cellular factors associated with NV replication. The analysis demonstrated that genes in lipid (cholesterol) or carbohydrate metabolic pathways were significantly (P < 0.001) changed by the gene ontology analysis. Among genes in the cholesterol pathways, I found that mRNA levels of hydroxymethylglutaryl-coenzyme A (HMG-CoA) synthase, squalene epoxidase, and acyl-CoA:cholesterol acyltransferase (ACAT), ACAT2, small heterodimer partner, and low-density lipoprotein receptor (LDLR)-related proteins were significantly changed in the cells. I also found that the inhibition of cholesterol biosynthesis using statins (an HMG-CoA reductase inhibitor) significantly increased the levels of NV proteins and RNA, whereas inhibitors of ACAT significantly reduced the replication of NV in replicon-bearing cells. Up- or downregulation of virus replication with these agents significantly correlated with the mRNA level of LDLR in replicon-bearing cells. Finally, I found that the expression of LDLR promoted NV replication in trans by transfection study with pNV-GFP. I conclude that the cholesterol pathways such as LDLR expression and ACAT activity may be crucial in the replication of noroviruses in cells, which may provide potential therapeutic targets for viral infection.Human noroviruses are now the leading cause of food- or waterborne gastroenteritis illnesses responsible for more than 60% of outbreaks (10). It has been estimated that noroviruses cause 23 million cases of illness, 50,000 hospitalizations, and 300 deaths each year in the United States alone (19). Molecular epidemiological studies have confirmed a global distribution of these viruses (13). The major public health concern with human noroviruses is their ability to cause large outbreaks in group settings such as schools, restaurants, summer camps, military units, hospitals, nursing homes, and cruise ships. Human noroviruses are currently classified as NIAID category B priority pathogens (category B bioterrorism agents). Noroviruses generally cause mild to moderate gastroenteritis, but the disease can be severe to life-threatening in the young, the elderly, and immunocompromised patients. During the last decade, noroviruses have gained media attention for causing large-scale outbreaks of gastroenteritis on cruise ships, in nursing homes, etc. Although noroviruses do not multiply in food or water, they can cause large outbreaks because as few as 10 to 100 virions are sufficient to cause illness in a healthy adult (12). Recent reports of noroviral gastroenteritis outbreaks among hurricane Katrina evacuees underscores the importance of preventive and therapeutic measures for noroviruses to promote public health (32). However, no vaccines or antivirals are currently available for the prevention or treatment of norovirus disease in humans, which is largely due to the absence of a cell culture system for human noroviruses. The recent development of replicon-bearing cells for Norwalk virus (NV) (7) has made possible the study of NV replication in cells and the discovery of antivirals. We recently demonstrated that the system provides an excellent platform for screening small molecules for antivirals (3, 7). We also reported another NV replicon system with reporter genes (green fluorescent protein [GFP] or luciferase) to study virus replication (4).As a component of membrane structures and a precursor for the steroid hormones and bile acids, cholesterol is one of the most essential biological molecules in the body (8). Cholesterol levels are maintained by controlling both de novo synthesis (major) and dietary uptake (minor) of cholesterol (8). De novo synthesis of cholesterol is subject to complex regulatory controls by various enzymes such as 3-hydroxy-3-methyl glutaryl-coenzyme A (HMG-CoA) reductase and acyl-CoA:cholesterol acyltransferase (ACAT) (1, 8, 21). The synthesis of bile acids from cholesterol is also tightly controlled and represents an important factor the cholesterol homeostasis (14, 22, 23). In the present study, I first performed DNA microarray analysis of replicon-bearing cells to identify cellular factors associated with NV replication. Analysis showed genes in lipid (cholesterol) or carbohydrate metabolic pathways were significantly (P < 0.001) changed by the gene ontology analysis. Because it has been shown that bile acids are essential for the replication of porcine enteric calicivirus (PEC) in cells (6) and important natural modulators of cholesterol pathways, I was particularly interested in potential regulation genes in the cholesterol pathways. I demonstrate here that the modulation of the cholesterol pathways via inhibitors of HMG-CoA reductase or ACAT led to either up- or downregulation of the replication of NV. I also show that the expression level of low-density lipoprotein receptor (LDLR) was positively correlated with NV replication in cells. These studies suggest that the cholesterol pathway is crucial for norovirus replication and provide potential therapeutic targets for noroviral infection.     

Norwalk virus RNA is infectious in mammalian cells

Human noroviruses are positive-sense RNA viruses and are the leading cause of epidemic acute viral gastroenteritis in developed countries. The absence of an in vitro cell culture model for human norovirus infection has limited the development of effective antivirals and vaccines. Human histo-blood group antigens have been regarded as receptors for norovirus infection, and expression of the α(1,2) fucosyltransferase gene (FUT2) responsible for the secretor phenotype is required for susceptibility to Norwalk virus (NV) infection. We report for the first time that transfection of NV RNA, isolated from stool samples from human volunteers, into human hepatoma Huh-7 cells leads to viral replication, with expression of viral antigens, RNA replication, and release of viral particles into the medium. Prior treatment of the RNA with proteinase K completely abolishes RNA infectivity, suggesting a key role of an RNA-protein complex. Although overexpression of the human FUT2 gene enhances virus binding to cells, it is not sufficient to allow a complete viral infection, and viral spread from NV-transfected cells to naïve cells does not occur. Finally, no differences in NV RNA replication are observed between Huh-7 and Huh-7.5.1 cells, which contain an inactivating mutation in retinoic acid-inducible gene I (RIG-I), suggesting that the RIG-I pathway does not play a role in limiting NV replication. Our results strongly suggest that the block(s) to NV replication in vitro is at the stage of receptor and/or coreceptor binding and/or uncoating, either because cells lack some specific factor or activation of cellular antiviral responses independent of RIG-I inhibits virus replication.The human pathogen Norwalk virus (NV) is the prototype strain of the Norovirus genus in the family Caliciviridae. Noroviruses are responsible for the majority of outbreaks of nonbacterial gastroenteritis in developed countries, and it is estimated that they have a significant impact in developing countries as well. Although human noroviruses were originally identified more than 30 years ago, our understanding of their replication cycle and mechanisms of pathogenicity has been limited because these viruses are noncultivatable in established cell lines and a small animal model to study viral infection is not available. Only recently, it has been reported that both genogroup I (GI) and GII strains of human noroviruses can be passaged several times with limited replication in a differentiated three-dimensional cell culture system derived from a human small intestinal cell line (40). In addition, gnotobiotic pigs can support replication of a human norovirus GII strain, with occurrence of mild diarrhea and virus shedding and immunofluorescent detection of both structural and nonstructural proteins in enterocytes (10). Although these results are promising, it remains unclear whether these systems are robust enough to be widely used to efficiently propagate human noroviruses in vitro, and the factors responsible for the block(s) of viral replication using standard cell culture systems remain unknown.The NV genome is a positive-sense, polyadenylated, single-stranded RNA molecule of 7.7 kb and contains three open reading frames (ORFs): ORF1 encodes a nonstructural polyprotein, and ORF2 and ORF3 encode the major and minor capsid proteins, VP1 and VP2, respectively (14, 24). Due to the lack of an in vitro system to propagate human noroviruses, features of their life cycle have been inferred from studies using other animal caliciviruses that can grow in mammalian cell cultures. A 3′ coterminal polyadenylated subgenomic RNA is produced within infected cells, and it is believed that both genomic and subgenomic RNAs are covalently linked to the nonstructural protein VPg at their 5′ ends. Upon infection of cells, nonstructural proteins are expressed from genomic RNA and form an RNA replication complex, which generates new genomic RNA molecules as well as subgenomic RNAs encoding VP1 and VP2. After expression of the structural proteins from subgenomic RNA molecules, the capsid is assembled and viral RNA encapsidated prior to progeny release. Some of these features have been confirmed using recombinant systems to express the native NV genome in mammalian cells by using vaccinia virus expression systems (2, 25).Studies with human volunteers have shown that some individuals are either repeatedly susceptible or resistant to NV infection (36) and led to the identification of a genetically determined factor that predicts a person''s susceptibility to infection and disease (19, 30). Binding experiments using recombinant NV virus-like particles (VLPs) demonstrated attachment of VLPs to surface epithelial cells of the gastroduodenal junction on biopsies from secretors but not to cells from nonsecretors, showing that the expression pattern of ABH histo-blood group antigens may influence susceptibility to NV (32). The gene responsible for the secretor phenotype encodes an α(1,2)fucosyltransferase (FUT2) that produces H antigens on the surface of epithelial cells and in mucosal secretions (27). Since it was observed that transfection of the FUT2 gene into nonpermissive cells enhances NV binding (31), it has been hypothesized that H antigens or related blood group antigens may function as a receptor for NV.The main goal of our study was to understand the molecular basis of the restricted growth of NV in cultured cells by transfecting wild-type NV RNA into human cells. Our studies show for the first time that transfection of wild-type NV RNA isolated from human stool samples can lead to the production of viral particles, indicating that wild-type NV RNA is infectious and replicates. However, a block to NV spread to other cells in the culture remains, indicating that the block(s) exists at the cell entry and/or uncoating steps.     

Norwalk virus nonstructural protein p48 forms a complex with the SNARE regulator VAP-A and prevents cell surface expression of vesicular stomatitis virus G protein

Norwalk virus (NV), a reference strain of human calicivirus in the Norovirus genus of the family Caliciviridae, contains a positive-strand RNA genome with three open reading frames. ORF1 encodes a 1,789-amino-acid polyprotein that is processed into nonstructural proteins that include an NTPase, VPg, protease, and RNA-dependent RNA polymerase. The N-terminal protein p48 of ORF1 shows no significant sequence similarity to viral or cellular proteins, and its function in the human calicivirus replication cycle is not known. The lack of sequence similarity to any protein in the public databases suggested that p48 may have a unique function in the NV replication cycle or, alternatively, may perform a characterized function in replication by a unique mechanism. In this report, it is shown that p48 displays a vesicular localization pattern in transfected cells when fused to the fluorescent reporter EYFP. A predicted transmembrane domain at the C terminus of p48 was not necessary for the observed localization pattern, but this domain was sufficient to redirect localization of EYFP to a fluorescent pattern consistent with the Golgi apparatus. A yeast two-hybrid screen identified the SNARE regulator vesicle-associated membrane protein-associated protein A (VAP-A) as a binding partner of p48. Biochemical assays confirmed that p48 and VAP-A interact and form a stable complex in mammalian cells. Furthermore, expression of the vesicular stomatitis virus G glcyoprotein on the cell surface was inhibited when cells coexpressed p48, suggesting that p48 disrupts intracellular protein trafficking.     

Secretory pathway antagonism by calicivirus homologues of Norwalk virus nonstructural protein p22 is restricted to noroviruses

ABSTRACT: BACKGROUND: Our previous report that the Norwalk virus nonstructural protein p22 is an antagonist of the cellular secretory pathway suggests a new aspect of norovirus/host interaction. To explore conservation of function of this highly divergent calicivirus protein, we examined the effects of p22 homologues from four human and two murine noroviruses, and feline calicivirus on the secretory pathway. FINDINGS: All human noroviruses examined induced Golgi disruption and inhibited protein secretion, with the genogroup II.4 Houston virus being the most potent antagonist. Genogroup II.6 viruses have a conserved mutation in the mimic of an Endoplasmic Reticulum export signal (MERES) motif that is highly conserved in human norovirus homologues of p22 and is critical for secretory pathway antagonism, and these viruses had reduced levels of Golgi disruption and inhibition of protein secretion. p22 homologues from both persistent and nonpersistent strains of murine norovirus induced Golgi disruption, but only mildly inhibited cellular protein secretion. Feline calicivirus p30 did not induce Golgi disruption or inhibit cellular protein secretion. CONCLUSIONS: These differences confirm a norovirus-specific effect on host cell secretory pathway antagonism by homologues of p22, which may affect viral replication and/or cellular pathogenesis.     

Predictive Model for Inactivation of Feline Calicivirus, a Norovirus Surrogate, by Heat and High Hydrostatic Pressure

Noroviruses, which are members of the Caliciviridae family, represent the leading cause of nonbacterial gastroenteritis in developed countries; such norovirus infections result in high economic costs for health protection. Person-to-person contact, contaminated water, and foods, especially raw shellfish, vegetables, and fruits, can transmit noroviruses. We inactivated feline calicivirus, a surrogate for the nonculturable norovirus, in cell culture medium and mineral water by heat and high hydrostatic pressure. Incubation at ambient pressure and 75°C for 2 min as well as treatment at 450 MPa and 15°C for 1 min inactivated more than 7 log₁₀ PFU of calicivirus per ml in cell culture medium or mineral water. The heat and pressure time-inactivation curves obtained with the calicivirus showed tailing in the logarithmic scale. Modeling by nth-order kinetics of the virus inactivation was successful in predicting the inactivation of the infective virus particles. The developed model enables the prediction of the calicivirus reduction in response to pressures up to 500 MPa, temperatures ranging from 5 to 75°C, and various treatment times. We suggest high pressure for processing of foods to reduce the health threat posed by noroviruses.     

Hepatitis C virus non-structural proteins in the probable membranous compartment function in viral genome replication

The molecular mechanism of hepatitis C virus(HCV) RNA replication is still unknown. Recently, a cell culture system in which the HCV subgenomic replicon is efficiently replicated and maintained for a long period in Huh-7 cells has been established. Taking advantage of this replicon system, we detected the activity to synthesize the subgenomic RNA in the digitonin-permeabilized replicon cells. To elucidate how and where this viral RNA replicates in the cells, we monitored the activity for HCV RNA synthesis in the permeabilized replicon cells under several conditions. We obtained results suggesting that HCV replication complexes functioning to synthesize the replicon RNA are protected from access of nuclease and proteinase by possible cellular lipid membranes. We also found that a large part of the replicon RNA, including newly synthesized RNA, was present in such a membranous structure but a large part of each NS protein was not. A small part of each NS protein that was resistant to the proteinase action was shown to contribute sufficiently to the synthesis of HCV subgenomic RNA in the permeabilized replicon cells. These results suggested that a major subcellular site of HCV genome replication is probably compartmentalized by lipid membranes and that only a part of each NS protein forms the active replication complex in the replicon cells.     

La, PTB, and PAB proteins bind to the 3(') untranslated region of Norwalk virus genomic RNA

Noroviruses are human enteric caliciviruses for which no cell culture is available. Consequently, the mechanisms and factors involved in their replication have been difficult to study. In an attempt to analyze the cis- and trans-acting factors that could have a role in NV replication, the 3(')-untranslated region of the genome was studied. Use of Zuker's mfold-2 software predicted that NV 3(')UTR contains a stem-loop structure of 47 nts. Proteins from HeLa cell extracts, such as La and PTB, form stable complexes with this region. The addition of a poly(A) tail (24 nts) to the 3(')UTR permits the specific binding of the poly(A) binding protein (PABP) present in HeLa cell extracts, as well as the recombinant PABP. Since La, PTB, and PABP are important trans-acting factors required for viral translation and replication, these RNA-protein interactions may play a role in NV replication or translation.     

Polypyrimidine Tract Binding Protein Functions as a Negative Regulator of Feline Calicivirus Translation

Background

Positive strand RNA viruses rely heavily on host cell RNA binding proteins for various aspects of their life cycle. Such proteins interact with sequences usually present at the 5′ or 3′ extremities of the viral RNA genome, to regulate viral translation and/or replication. We have previously reported that the well characterized host RNA binding protein polypyrimidine tract binding protein (PTB) interacts with the 5′end of the feline calicivirus (FCV) genomic and subgenomic RNAs, playing a role in the FCV life cycle.

Principal Findings

We have demonstrated that PTB interacts with at least two binding sites within the 5′end of the FCV genome. In vitro translation indicated that PTB may function as a negative regulator of FCV translation and this was subsequently confirmed as the translation of the viral subgenomic RNA in PTB siRNA treated cells was stimulated under conditions in which RNA replication could not occur. We also observed that PTB redistributes from the nucleus to the cytoplasm during FCV infection, partially localizing to viral replication complexes, suggesting that PTB binding may be involved in the switch from translation to replication. Reverse genetics studies demonstrated that synonymous mutations in the PTB binding sites result in a cell-type specific defect in FCV replication.

Conclusions

Our data indicates that PTB may function to negatively regulate FCV translation initiation. To reconcile this with efficient virus replication in cells, we propose a putative model for the function of PTB in the FCV life cycle. It is possible that during the early stages of infection, viral RNA is translated in the absence of PTB, however, as the levels of viral proteins increase, the nuclear-cytoplasmic shuttling of PTB is altered, increasing the cytoplasmic levels of PTB, inhibiting viral translation. Whether PTB acts directly to repress translation initiation or via the recruitment of other factors remains to be determined but this may contribute to the stimulation of viral RNA replication via clearance of ribosomes from viral RNA.     

Subgenomic Reporter RNA System for Detection of Alphavirus Infection in Mosquitoes

Current methods for detecting real-time alphavirus (Family Togaviridae) infection in mosquitoes require the use of recombinant viruses engineered to express a visibly detectable reporter protein. These altered viruses expressing fluorescent proteins, usually from a duplicated viral subgenomic reporter, are effective at marking infection but tend to be attenuated due to the modification of the genome. Additionally, field strains of viruses cannot be visualized using this approach unless infectious clones can be developed to insert a reporter protein. To circumvent these issues, we have developed an insect cell-based system for detecting wild-type sindbis virus infection that uses a virus inducible promoter to express a fluorescent reporter gene only upon active virus infection. We have developed an insect expression system that produces sindbis virus minigenomes containing a subgenomic promoter sequence, which produces a translatable RNA species only when infectious virus is present and providing viral replication proteins. This subgenomic reporter RNA system is able to detect wild-type Sindbis infection in cultured mosquito cells. The detection system is relatively species specific and only detects closely related viruses, but can detect low levels of alphavirus specific replication early during infection. A chikungunya virus detection system was also developed that specifically detects chikungunya virus infection. Transgenic Aedes aegypti mosquito families were established that constitutively express the sindbis virus reporter RNA and were found to only express fluorescent proteins during virus infection. This virus inducible reporter system demonstrates a novel approach for detecting non-recombinant virus infection in mosquito cell culture and in live transgenic mosquitoes.     

Combination of LC3 shRNA Plasmid Transfection and Genistein Treatment Inhibited Autophagy and Increased Apoptosis in Malignant Neuroblastoma in Cell Culture and Animal Models

Malignant neuroblastoma is an extracranial solid tumor that usually occurs in children. Autophagy, which is a survival mechanism in many solid tumors including malignant neuroblastoma, deters the efficacy of conventional chemotherapeutic agents. To mimic starvation, we used 200 nM rapamycin that induced autophagy in human malignant neuroblastoma SK-N-BE2 and IMR-32 cells in cell culture and animal models. Combination of microtubule associated protein light chain 3 short hairpin RNA (LC3 shRNA) plasmid transfection and genistein (GST) treatment was tested for inhibiting rapamycin-induced autophagy and promoting apoptosis. The best synergistic efficacy caused the highest decrease in cell viability due to combination of 50 nM LC3 shRNA plasmid transfection and 25 µM GST treatment in rapamycin-treated SK-N-BE2 cells while combination of 100 nM LC3 shRNA plasmid transfection and 25 µM GST treatment in rapamycin-treated IMR-32 cells. Quantitation of acidic vesicular organelles confirmed that combination of LC3 shRNA plasmid transfection and GST treatment prevented rapamycin-induced autophagy due to down regulation of autophagy promoting marker molecules (LC3 II, Beclin 1, TLR-4, and Myd88) and upregulation of autophagy inhibiting marker molecules (p62 and mTOR) in both cell lines. Apoptosis assays showed that combination therapy most effectively activated mitochondrial pathway of apoptosis in human malignant neuroblastoma in cell culture and animal models. Collectively, our current combination of LC3 shRNA plasmid transfection and GST treatment could serve as a promising therapeutic strategy for inhibiting autophagy and increasing apoptosis in human malignant neuroblastoma in cell culture and animal models.     

Farnesyl-diphosphate farnesyltransferase 1 regulates hepatitis C virus propagation

To identify the novel genes involved in lipid metabolism and lipid droplet formation that may play important roles in Hepatitis C virus (HCV) propagation, we have screened the small interfering RNA library using cell culture derived HCV (HCVcc)-infected cells. We selected and characterized the gene encoding farnesyl-diphosphate farnesyltransferase 1 (FDFT1). siRNA-mediated knockdown of FDFT1 impaired HCV replication in both subgenomic replicon and HCVcc infected cells. Moreover, YM-53601, an inhibitor of FDFT1 enzyme activity, abrogated HCV propagation. HCV infection increased FDFT1 protein level but not FDFT1 mRNA level. These results suggest that HCV may modulate FDFT1 protein level to facilitate its own propagation.     

Characterization of chimeric full-length molecular clones of Aleutian mink disease parvovirus (ADV): identification of a determinant governing replication of ADV in cell culture.

The ADV-G strain of Aleutian mink disease parvovirus (ADV) is nonpathogenic for mink but replicates permissively in cell culture, whereas the ADV-Utah 1 strain is highly pathogenic for mink but replicates poorly in cell culture. In order to relate these phenotypic differences to primary genomic features, we constructed a series of chimeric plasmids between a full-length replication-competent molecular clone of ADV-G and subgenomic clones of ADV-Utah 1 representing map units (MU) 15 to 88. After transfection of the plasmids into cell culture and serial passage of cell lysates, we determined that substitution of several segments of the ADV-Utah 1 genome (MU 15 to 54 and 65 to 73) within an infectious ADV-G plasmid did not impair the ability of these constructs to yield infectious virus in vitro. Like ADV-G, the viruses derived from these replication-competent clones caused neither detectable viremia 10 days after inoculation nor any evidence of Aleutian disease in adult mink. On the other hand, other chimeric plasmids were incapable of yielding infectious virus and were therefore replication defective in vitro. The MU 54 to 65 EcoRI-EcoRV fragment of ADV-Utah 1 was the minimal segment capable of rendering ADV-G replication defective. Substitution of the ADV-G EcoRI-EcoRV fragment into a replication-defective clone restored replication competence, indicating that this 0.53-kb portion of the genome, wholly located within shared coding sequences for the capsid proteins VP1 and VP2, contained a determinant that governs replication in cell culture. When cultures of cells were studied 5 days after transfection with replication-defective clones, rescue of dimeric replicative form DNA and single-stranded progeny DNA could not be demonstrated. This defect could not be complemented by cotransfection with a replication-competent construction.     

Nonvirion protein of novirhabdovirus suppresses apoptosis at the early stage of virus infection

Viral hemorrhagic septicemia virus (VHSV) and infectious hematopoietic necrosis virus (IHNV) are members of the genus Novirhabdovirus within the Rhabdoviridae family, which can cause severe hemorrhagic disease in fresh- and saltwater fish worldwide. These viruses carry an additional nonvirion (NV) gene, which codes for the nonstructural NV protein that has been implicated to play a role in viral pathogenesis. To determine the precise biological function of this NV gene and its gene product, we generated NV-deficient and NV knockout recombinant VHSVs, using reverse genetics. Comparisons of the replication kinetics and markers for virus-induced apoptosis indicated that the NV-deficient and NV knockout mutant viruses induce apoptosis earlier in cell culture than the wild-type recombinant VHSV. These results suggest that the NV protein has an antiapoptotic function at the early stage of virus infection. Furthermore, we created a chimeric VHSV, in which the NV gene of VHSV was replaced by the IHNV NV gene, which was capable of suppressing apoptosis in cell culture. These results show that the NV protein of other members of Novirhabdovirus can restore the NV protein function. In this study, we also investigated the kinetics of VHSV replication during a single round of viral replication and examined the mechanism of VHSV-induced apoptosis. Our results show that VHSV infection induced caspases 3, 8 and 9 in cell culture.     

Survival of F-Specific RNA Coliphage, Feline Calicivirus, and Escherichia coli in Water: a Comparative Study

The relationship between the survival of enteric viral pathogens and their indicators (coliform bacteria and coliphages) is not well understood. We compared the survival rates of feline calicivirus (FCV), Escherichia coli, and a male-specific RNA coliphage MS2 at 4, 25, and 37°C for up to 28 days in dechlorinated water. The survival rates of E. coli and FCV, a surrogate of noroviruses (NV), had a high degree of correlation at 4 and 25°C, while MS2 phage survived significantly longer (P < 0.05) at these two temperatures. At 37°C, the survival rates for all three organisms were highly correlated. Decimal reduction values indicating the number of days needed for 90% reduction in titer (D values) decreased for all three organisms as storage temperatures increased. FCV had the shortest D value among all three organisms at all temperatures investigated. These findings indicate that F-specific RNA phages may be useful indicators of NV in the environment.     

Attachment and entry of recombinant Norwalk virus capsids to cultured human and animal cell lines.

Norwalk virus (NV) is the prototype strain of a group of noncultivable human caliciviruses responsible for epidemic outbreaks of acute gastroenteritis. While these viruses do not grow in tissue culture cells or animal models, expression of the capsid protein in insect cells results in the self-assembly of recombinant Norwalk virus-like particles (rNV VLPs) that are morphologically and antigenically similar to native NV. We have used these rNV VLPs to examine virus-cell interactions. Binding and internalization of VLPs to cultured human and animal cell lines were studied in an attempt to identify potentially susceptible cell lines for virus propagation in vitro and to determine if early events in the replication cycle were responsible for the narrow host range and restriction of virus growth in cell culture. Radiolabeled VLPs specifically bound to a saturable number of binding molecules on the cell surface of 13 cell lines from different origins, including human intestine (differentiated and undifferentiated Caco-2) and insect (Spodoptera frugiperda 9) ovary. Differentiated Caco-2 cells bound significantly more rNV VLPs than the other cell lines. Variations in the amount of bound VLPs among the different cell lines did not correlate with the tissue or species of origin. VLP binding was specific, as determined by competition experiments with unlabeled rNV VLPs; however, only 1.4 to 6.8% of the specifically prebound radiolabeled VLPs became internalized into cells. Blocking experiments using polygonal and monoclonal anti-rNV sera and specific antipeptide sera were performed to map the domains on rNV VLPs involved in binding to cells. One monoclonal antibody (NV8812) blocked binding of rNV VLPs to human and animal cell lines. The binding site of monoclonal antibody NV8812 was localized to the C-terminal 300 to 384 residues of the capsid protein by immunoprecipitation with truncated and cleaved forms of the capsid protein. These data suggest that the C-terminal region of the capsid protein is involved in specific binding of rNV VLPs to cells.