Hydroponic Nutrient Solution Temperature Impacts Tulane Virus Persistence over Time.

Controlled environment agriculture (CEA), or indoor agriculture, encompasses non-traditional farming methods that occur inside climate-controlled structures (e.g., greenhouses, warehouses, high tunnels) allowing for year-round production of fresh produce such as leaf lettuce. However, recent outbreaks and recalls associated with hydroponically grown lettuce contaminated with human pathogens have raised concerns. Few studies exist on the food safety risks during hydroponic cultivation of leaf lettuce; thus, it is important to identify contributing risk factors and potential mitigation strategies to prevent foodborne transmission via hydroponically grown produce. In this study, the concentration of infectious Tulane virus (TV), a human norovirus surrogate, in hydroponic nutrient solution at 15 °C, 25 °C, 30 °C, and 37 °C was determined over a duration of 21 days to mimic the time from seedling to mature lettuce. The mean log PFU reduction for TV was 0.86, 1.80, 2.87, and ≥ 3.77 log10 at 15 °C, 25 °C, 30 °C, and 37 °C, respectively, at the end of the 21-day period. Similarly, average decimal reduction values (D-values) of TV at 15 °C, 25 °C, 30 °C, and 37 °C were 48.0, 11.3, 8.57, and 7.02 days, respectively. This study aids in the (i) identification of possible food safety risks associated with hydroponic systems specifically related to nutrient solution temperature and (ii) generation of data to perform risk assessments within CEA leaf lettuce operations to inform risk management strategies for the reduction of foodborne outbreaks, fresh produce recalls, and economic losses.

Culture and differentiation of rabbit intestinal organoids and organoid-derived cell monolayers.

Organoids emulate many aspects of their parental tissue and are therefore used to study pathogen-host interactions and other complex biological processes. Here, we report a robust protocol for the isolation, maintenance and differentiation of rabbit small intestinal organoids and organoid-derived cell monolayers. Our rabbit intestinal spheroid and monolayer cultures grew most efficiently in L-WRN-conditioned medium that contained Wnt, R-spondin and Noggin, and that had been supplemented with ROCK and TGF-ß inhibitors. Organoid and monolayer differentiation was initiated by reducing the concentration of the L-WRN-conditioned medium and by adding ROCK and Notch signalling inhibitors. Immunofluorescence staining and RT-qPCR demonstrated that our organoids contained enterocytes, enteroendocrine cells, goblet cells and Paneth cells. Finally, we infected rabbit organoids with Rabbit calicivirus Australia-1, an enterotropic lagovirus that-like many other caliciviruses-does not grow in conventional cell culture. Despite testing various conditions for inoculation, we did not detect any evidence of virus replication, suggesting either that our organoids do not contain suitable host cell types or that additional co-factors are required for a productive infection of rabbit organoids with Rabbit calicivirus Australia-1.

Comparison of cell-based and PCR-based assays as methods for measuring infectivity of Tulane virus.

In this study, we used Tulane virus (TV) as a surrogate for HuNoV to evaluate for correlation between two cell-based assays and three PCR-based assays. Specifically, the cell-based plaque and TCID50 assays measure for infectious virus particles, while the PCR-based RNase exposure, porcine gastric mucin in-situ-capture qRT-PCR (PGM-ISC-qRT-PCR), and antibody in-situ-capture qRT-PCR (Ab-ISC-qRT-PCR) assays measure for an amplicon within encapsidated viral genome. Ten batches of viral stocks ranging from 3.41 × 10(5) to 6.67 × 10(6) plaque forming units (PFUs) were used for side by side comparison with PFU as a reference. The results indicate that one PFU was equivalent to 6.69 ± 2.34 TCID50 units, 9.75 ± 10.87 RNase-untreated genomic copies (GCs), 2.87 ± 3.05 RNase-treated GCs, 0.07 ± 0.07 PGM-ISC-qRT-PCR GCs, and 0.52 ± 0.39 Ab-ISC-qRT-PCR GCs. We observed that while the cell-based assays were consistent with each other, the TCID50 assay was more sensitive than the plaque assay. In contrast, the PCR-based assays were not always consistent with the cell-based assays. The very high variations in GCs as measured by both ISC-RT-qPCR assays made them difficult to correlate against the relatively small variations (<20-fold) in the PFUs or TCID50 units as measured by the cell-based assays.

Alternative methods to determine infectivity of Tulane virus: a surrogate for human nororvirus.

Culturable animal caliciviruses are widely-used as surrogates for human norovirus (HuNoV). The infectivity of a culturable virus was traditionally determined by plaque assay and/or 50% tissue culture infectious dose (TCID50) assay, both of which are time-consuming and labor-intensive. Molecular approaches, such as quantitative real time RT-PCR (qRT-PCR) and RT-PCR, could be used for detection of the viral genome but yet fail to determine the infectivity of a virus. In this study, we evaluated different assays for determination of infectivity of Tulane virus (TV), a surrogate for HuNoV. The infectivity of TV was measured by RNase exposure assay, RT-PCR assays, cellular-receptor-mediated capture qRT-PCR assay, receptor-mediated in situ capture qRT-PCR assay, cell-culture-mediated amplification qRT-PCR, and confirmed by TCID50 assay. RNase exposure assay was only useful for measuring TV inactivation caused by heat. Short template RT-PCR assay did not reflect inactivation status of TV. Partial reduction in viral RNA signal could be measured by long-template RT-PCR only when TV was inactivated by thermal or chlorine treatments at full-inactivation levels. Cellular-receptor-mediated capture qRT-PCR exhibited low sensitivity and specificity for the evaluation of virus infectivity. The in situ capture qRT-PCR assay could be used to evaluate virus inactivation deriving from damage to viral capsid caused by heat and chlorine. The cell-culture-mediated amplification qRT-PCR could be used as an alternative method to rapidly determine the infectivity of TV.

Inactivation of the Tulane virus, a novel surrogate for the human norovirus.

Human noroviruses (HuNoVs) are the major cause of nonbacterial gastroenteritis epidemics. The culturable feline calicivirus and murine norovirus have been used extensively as surrogates to study HuNoV biology, as HuNoV does not grow in vitro. Additional efforts to identify new surrogates are needed, because neither of these common surrogates are truly intestinal pathogens. The newly described Tulane virus (TV) is a typical calicivirus, it is isolated from macaque stools, is cultivable in vitro, and recognizes human histo-blood group antigens. Therefore, TV is a promising surrogate for HuNoVs. In this study, we evaluated the resistance or stability of TV under various physical and environmental conditions by measuring a 50% reduction of tissue culture infective dose (TCID50) by using a TV cell culture system. Due to the nature of this virus, it is hard to produce a high-titer stock through tissue culture. In our study, the maximal reduction in virus titers was 5D (D = 1 log) in heat-denaturation and EtOH experiments, and 4D in UV, chlorine, and pH-stability experiments. Therefore in this study, we defined the inactivation of TV as reaching a TCID50/ml of 0 (a 4- to 5-D reduction in TCID50, depending on the detection limit). TV was inactivated after incubation at 63 °C for 5 min, incubation at 56 °C for 30 min (5D), exposure to 60 mJ/cm2 of UVC radiation (4D), or incubation at 300 ppm of free chlorine for 10 min (4D). TV was shown to be stable from pH 3.0 to 8.0, though an obvious reduction in virus titer was observed at pH 2.5 and 9.0, and was inactivated at pH 10.0 (4D). TV was resistant to a low concentration of EtOH (40% or lower) but was fully inactivated (5D) by 50 to 70% EtOH after a short exposure (20 s). In contrast, quantitative real-time PCR was unable to detect, or poorly detected, virus titer reductions between treated and untreated samples described in this study.

Norovirus surrogate survival on spinach during preharvest growth.

Produce can become contaminated with human viral pathogens in the field through soil, feces, or water used for irrigation; through application of manure, biosolids, pesticides, and fertilizers; and through dust, insects, and animals. The objective of this study was to assess the survival and stability of human noroviruses and norovirus surrogates (Murine norovirus [MNV] and Tulane virus [TV]) on foliar surfaces of spinach plants in preharvest growth conditions. Spinach plants were housed in a biocontrol chamber at optimal conditions for up to 7 days and infectivity was determined by plaque assay. Virus inoculation location had the largest impact on virus survival as viruses present on adaxial leaf surfaces had lower decimal reduction time (D values) than viruses present on abaxial leaf surfaces. Under certain conditions, spinach type impacted virus survival, with greater D values observed from survival on semi-savoy spinach leaves. Additional UVA and UVB exposure to mimic sunlight affected virus survival on adaxial surfaces for both semi-savoy and smooth spinach plants for both viruses. Human GII norovirus inoculated onto semi-savoy spinach had an average D value that was not statistically significant from MNV and TV, suggesting that these surrogates may have similar survival on spinach leaves compared with human noroviruses. An understanding of the behavior of enteric viruses on spinach leaves can be used to enhance growers' guidelines and for risk assessment with certain growing conditions.

Comparing human norovirus surrogates: murine norovirus and Tulane virus.

Viral surrogates are widely used by researchers to predict human norovirus behavior. Murine norovirus (MNV) is currently accepted as the best surrogate and is assumed to mimic the survival and inactivation of human noroviruses. Recently, a new calicivirus, the Tulane virus (TV), was discovered, and its potential as a human norovirus surrogate is being explored. This study aimed to compare the behavior of the two potential surrogates under varying treatments of pH (2.0 to 10.0), chlorine (0.2 to 2,000 ppm), heat (50 to 75°C), and survival in tap water at room (20°C) and refrigeration (4°C) temperatures for up to 30 days. Viral infectivity was determined by the plaque assay for both MNV and TV. There was no significant difference between the inactivation of MNV and TV in all heat treatments, and for both MNV and TV survival in tap water at 20°C over 30 days. At 4°C, MNV remained infectious over 30 days at a titer of approximately 5 log PFU/ml, whereas TV titers decreased significantly by 5 days. MNV was more pH stable, as TV titers were reduced significantly at pH 2.0, 9.0, and 10.0, as compared with pH 7.0, whereas MNV titers were only significantly reduced at pH 10.0. After chlorine treatment, there was no significant difference in virus with the exception of at 2 ppm, where TV decreased significantly compared with MNV. Compared with TV, MNV is likely a better surrogate for human noroviruses, as MNV persisted over a wider range of pH values, at 2 ppm of chlorine, and without a loss of titer at 4°C.

Recovery of infectious virus by transfection of in vitro-generated RNA from tulane calicivirus cDNA.

Tulane virus (TV) is a newly reported calicivirus that was isolated from stool samples of captive rhesus macaques from the Tulane National Primate Research Center (TNPRC). The virus has been cultivated successfully in LLC-MK2 rhesus monkey kidney cells. Its complete genomic sequence suggests that TV represents a new genus and is evolutionarily more closely related to Norovirus than to any other genus of Caliciviridae. In this study, we demonstrated that RNA transcripts made in vitro from the full-length genomic cDNA of TV were infectious upon transfection into permissive LLC-MK2 cells. The recombinant virus exhibited plaque morphologies and growth kinetics similar to those of the wild-type virus in this cell line. Capping was required for TV RNA infectivity. Although a subgenomic RNA has been detected in TV-transfected cells, a separate subgenomic RNA transcript was not required for the initial transfection to establish the replication. Transfection of truncated RNA lacking open reading frame 2 (ORF2) and ORF3 or TV-norovirus chimeric RNA resulted in abortive replication without the production of infectious progeny viruses, indicating that both ORFs are essential for the replication of TV. A heterologous insertion at the 5' end of the genome also hampered viral replication, suggesting that an authentic 5' end of the genome is critical for replication. The availability of the complete genomic sequence and the reverse genetics system described herein make TV a valuable model for studying calicivirus pathogenesis and replication.

Vectorial entry and release of hepatitis A virus in polarized human hepatocytes.

Hepatitis A virus (HAV) is an enterically transmitted virus that replicates predominantly in hepatocytes within the liver before excretion via bile through feces. Hepatocytes are polarized epithelial cells, and it has been assumed that the virus load in bile results from direct export of HAV via the apical domain of polarized hepatocytes. We have developed a subclone of hepatocyte-derived HepG2 cells (clone N6) that maintains functional characteristics of polarized hepatocytes but displays morphology typical of columnar epithelial cells, rather than the complex morphology that is typical of hepatocytes. N6 cells form microcolonies of polarized cells when grown on glass and confluent monolayers of polarized cells on semipermeable membranes. When N6 microcolonies were exposed to HAV, infection was restricted to peripheral cells of polarized colonies, whereas all cells could be infected in colonies of nonpolarized HepG2 cells (clone C11) or following disruption of tight junctions in N6 colonies with EGTA. This suggests that viral entry occurs predominantly via the basolateral plasma membrane, consistent with uptake of virus from the bloodstream after enteric exposure, as expected. Viral export was also found to be markedly vectorial in N6 but not C11 cells. However, rather than being exported from the apical domain as expected, more than 95% of HAV was exported via the basolateral domain of N6 cells, suggesting that virus is first excreted from infected hepatocytes into the bloodstream rather than to the biliary tree. Enteric excretion of HAV may therefore rely on reuptake and transcytosis of progeny HAV across hepatocytes into the bile. These studies provide the first example of the interactions between viruses and polarized hepatocytes.

Survival of Mycobacterium avium, Legionella pneumophila, Escherichia coli, and caliciviruses in drinking water-associated biofilms grown under high-shear turbulent flow.

Most of the bacteria in drinking water distribution systems are associated with biofilms. In biofilms, their nutrient supply is better than in water, and biofilms can provide shelter against disinfection. We used a Propella biofilm reactor for studying the survival of Mycobacterium avium, Legionella pneumophila, Escherichia coli, and canine calicivirus (CaCV) (as a surrogate for human norovirus) in drinking water biofilms grown under high-shear turbulent-flow conditions. The numbers of M. avium and L. pneumophila were analyzed with both culture methods and with peptide nucleic acid fluorescence in situ hybridization (FISH) methods. Even though the numbers of pathogens in biofilms decreased during the experiments, M. avium and L. pneumophila survived in biofilms for more than 2 to 4 weeks in culturable forms. CaCV was detectable with a reverse transcription-PCR method in biofilms for more than 3 weeks. E. coli was detectable by culture for only 4 days in biofilms and 8 days in water, suggesting that it is a poor indicator of the presence of certain waterborne pathogens. With L. pneumophila and M. avium, culture methods underestimated the numbers of bacteria present compared to the FISH results. This study clearly proved that pathogenic bacteria entering water distribution systems can survive in biofilms for at least several weeks, even under conditions of high-shear turbulent flow, and may be a risk to water consumers. Also, considering the low number of virus particles needed to result in an infection, their extended survival in biofilms must be taken into account as a risk for the consumer.

Surrogates for the study of norovirus stability and inactivation in the environment: aA comparison of murine norovirus and feline calicivirus.

Human noroviruses (NoVs) are the leading cause of food- and waterborne outbreaks of acute nonbacterial gastroenteritis worldwide. As a result of the lack of a mammalian cell culture model for these viruses, studies on persistence, inactivation, and transmission have been limited to cultivable viruses, including feline calicivirus (FCV). Recently, reports of the successful cell culture of murine norovirus 1 (MNV-1) have provided investigators with an alternative surrogate for human NoVs. In this study, we compared the inactivation profiles of MNV-1 to FCV in an effort to establish the relevance of MNV-1 as a surrogate virus. Specifically, we evaluated (i) stability upon exposure to pH extremes; (ii) stability upon exposure to organic solvents; (iii) thermal inactivation; and (iv) surface persistence under wet and dry conditions. MNV-1 was stable across the entire pH range tested (pH 2 to 10) with less than 1 log reduction in infectivity at pH 2, whereas FCV was inactivated rapidly at pH values < 3 and > 9. FCV was more stable than MNV-1 at 56 degrees C, but both viruses exhibited similar inactivation at 63 and 72 degrees C. Long-term persistence of both viruses suspended in a fecal matrix and inoculated onto stainless steel coupons were similar at 4 degrees C, but at room temperature in solution, MNV-1 was more stable than FCV. The genetic relatedness of MNV-1 to human NoVs combined with its ability to survive under gastric pH levels makes this virus a promising and relevant surrogate for studying environmental survival of human NoVs.

Ice as a reservoir for pathogenic human viruses: specifically, caliciviruses, influenza viruses, and enteroviruses.

Hundreds of isolates of viable bacteria and fungi have been recovered from ancient ice and permafrost. Evidence supports the hypothesis that viral pathogens also are preserved in ice repositories, such as glaciers, ice sheets, and lake ice. Proof may depend upon narrowing the search by applying specific criteria, which would target candidate viruses. Such criteria include viral pathogens likely to occur in great abundance, likely to be readily transported into ice, and then participate in ongoing disease cycles suggestive of their having been deposited in and subsequently released from ice. Caliciviruses, influenza A, and some enteroviruses appear to satisfy all three criteria. Environmental ice appears to be an important abiotic reservoir for pathogenic microbes. World health and eradication of specific pathogens could be affected by this huge reservoir.

Inactivation of caliciviruses.

The viruses most commonly associated with food- and waterborne outbreaks of gastroenteritis are the noroviruses. The lack of a culture method for noroviruses warrants the use of cultivable model viruses to gain more insight on their transmission routes and inactivation methods. We studied the inactivation of the reported enteric canine calicivirus no. 48 (CaCV) and the respiratory feline calicivirus F9 (FeCV) and correlated inactivation to reduction in PCR units of FeCV, CaCV, and a norovirus. Inactivation of suspended viruses was temperature and time dependent in the range from 0 to 100 degrees C. UV-B radiation from 0 to 150 mJ/cm(2) caused dose-dependent inactivation, with a 3 D (D = 1 log(10)) reduction in infectivity at 34 mJ/cm(2) for both viruses. Inactivation by 70% ethanol was inefficient, with only 3 D reduction after 30 min. Sodium hypochlorite solutions were only effective at >300 ppm. FeCV showed a higher stability at pH <3 and pH >7 than CaCV. For all treatments, detection of viral RNA underestimated the reduction in viral infectivity. Norovirus was never more sensitive than the animal caliciviruses and profoundly more resistant to low and high pH. Overall, both animal viruses showed similar inactivation profiles when exposed to heat or UV-B radiation or when incubated in ethanol or hypochlorite. The low stability of CaCV at low pH suggests that this is not a typical enteric (calici-) virus. The incomplete inactivation by ethanol and the high hypochlorite concentration needed for sufficient virus inactivation point to a concern for decontamination of fomites and surfaces contaminated with noroviruses and virus-safe water.

[Disinfection of caliciviruses at 20 and 10 degrees C]. / Desinfektion von Caliciviren bei Temperaturen von 20 und 10 degrees C.

Five disinfectants, Venno FF super, Venno Vet 1 super, Venno Oxygen, M&Enno-Veterinär B neu und Neopredisan 135-1, were tested to evaluate their efficacy against caliciviruses at 20 and 10 degrees C. As model test virus served feline calicivirus type F9 (FCV F9). All disinfectants were tested according to Guidelines of the German Veterinary Association (DVG). The investigations were performed in suspension tests and germ carrier tests. The suspension tests were carried out without and with protein load. As protein was used foetal calf serum at the concentration of 40%. Venno FF super showed less protein dependence, however a considerable temperature dependence. This matter can be corrected by increase of concentration on 2%. Venno Vet 1 super was without protein especially effective. The losses on the effectiveness through low temperature and protein load can be annulled also here by increase of concentration. Venno Oxygen was more effective in the comparison to that here named both preparations. The effects of temperature can be corrected by extension of reaction time. The most effective preparation was M&Enno Veterinär B neu. The disinfection occurred at 20 degrees C with 0.5% solution within 120 min and at 10 degrees C with 1.0% solution within 60 min. The fifth disinfectant Neopredisan was in suspension tests without protein load and carrier tests with gauze at 20 and 10 degrees C relative convincing but in germ carrier tests with poplar wood, no complete disinfection could be achieved within tested concentrations and reaction times.

Cell-culture propagation of porcine enteric calicivirus mediated by intestinal contents is dependent on the cyclic AMP signaling pathway.

Enteric caliciviruses are emerging pathogens in humans and animals, but they do not replicate in cell culture except for the porcine enteric calicivirus (PEC) Cowden strain. The PEC Cowden strain grows in pig kidney (LLC-PK) cells, but only in the presence of intestinal contents (IC) from uninfected gnotobiotic pigs in the medium. In this study, we investigated the relationship between IC and growth of Cowden PEC. Pretreatment of cells or the virus with IC or transfection of viral RNA into cells did not induce virus growth unless the medium was supplemented with IC. Among modulators of cell signal transduction, the G protein uncoupler, suramin, adenylate cyclase (AC) inhibitor, MDL-12,330A, and the cAMP-dependent protein kinase (PKA) inhibitor, N-(2-[bromocinnamulamino]ethyl)-5-isoquinolinesulfonamide (NBEI) inhibited the effect of IC on virus growth for up to 72 h. These data indicate that PEC virus replication may be dependent on an initial cAMP signaling pathway induced by IC.

Early interaction of canine calicivirus with cells is the major determinant for its cell tropism in vitro.

Canine calicivirus (CaCV) No. 48 strain isolated from a dog with fatal diarrhea is known to be able to replicate in MDCK and primary dog kidney cells. In this study, two new canine cell lines, MCM-B2 and MCA-B1, were determined to be permissive for CaCV No. 48, whereas other cell lines, including one canine cell line, A-72, were non-permissive. Flow cytometric analysis indicated that CaCV No. 48 binds efficiently to the permissive cells and to some degree also to Vero cells that are non-permissive for the virus, but does not bind to the other non-permissive cells tested. Both the permissive and non-permissive cells could be transfected with genomic RNA from CaCV No. 48, resulting in the appearance of CPE, production of capsid antigen and release of infectious progeny. These results suggested that the early interaction of the virus with cells, probably by binding to a virus receptor on the cell membrane, is the major determinant of CaCV No. 48 cell tropism in vitro.

Expression and self-assembly of Grimsby virus: antigenic distinction from Norwalk and Mexico viruses.

A cDNA obtained from Grimsby virus (GRV), a Norwalk-like virus, purified from a stool sample of a symptomatic adult associated with a gastroenteritis outbreak in the United Kingdom, was used to obtain the complete nucleotide sequence of the second open reading frame (ORF2). The ORF2 sequence of GRV predicts a capsid of 539 amino acids (aa) which exhibits aa identities of 96% to Lordsdale virus, 67% to Mexico virus (MXV), and 43% to Norwalk virus (NV). The GRV capsid protein was expressed in insects cells by using a recombinant baculovirus, and the resulting virus-like particles (VLPs) possessed a protein with an apparent molecular weight of 58,000. Hyperimmune antisera raised against purified GRV, MXV, and NV VLPs were tested in an indirect enzyme-linked immunosorbent assay (ELISA) against GRV, NV, and MXV VLPs, revealing that GRV is antigenically distinct from both NV and MXV. The antigenic specificity of the GRV-hyperimmune antiserum was confirmed in an antigen capture ELISA using GRV-, NV-, or MXV-containing fecal specimens. The expression of the GRV capsid protein has, for the first time, allowed the antigenic comparison of three distinct recombinant Norwalk-like viruses.

A strain of calicivirus isolated from lions with vesicular lesions on tongue and snout.

In December 1992, 17 African lions and 7 Siberian tigers in a Safari park in Japan became sick with characteristic clinical symptoms of acute vesicular formations on tongue and snout. The disease was highly contagious since all of these animals showed similar symptoms within two days after the onset of the first case. Swabs were taken from affected animals in rubbing tongues, snouts and some from rectums. Cytopathic viruses were isolated on CRFK cell culture by virological tests. The physicochemical property of a representative virus strain, named Arthur/L, isolated from a male lion was identified as a member of Caliciviridae. However, seroneutralization test indicated that this virus strain was antigenically distinct from Japanese isolates of feline caliciviruses used for comparison. Viral capsid proteins of the present isolate, Arthur/L, and of a feline calicivirus, strain FC7, were compared in an electrophoresis in SDS-PAGE gel. The major viral capsid polypeptide of them were proved to be significantly different in molecular weight. The polypeptide of FC7 was estimated to be ca. 63 KDa whereas that of Arthur/L consisted of 2 components of ca. 65 and 62 KDa. The viral proteins of these two strains were also proved to be distinct by an immunoblotting test.

Adaptation of the viral haemorrhagic disease virus of rabbits to the DJRK cell strain.

Liver emulsion of rabbits which had died of viral haemorrhagic disease (VHD) was inoculated onto DJRK cell culture. After two passages, specific cytopathic effect was observed. Immunofluorescence was found in the nucleus at the early stage of infection and later also in the cytoplasm. The virus propagated in cell culture at the fifth, tenth and sixteenth passages was found to cause typical VHD. Electron microscopy showed that there were numerous virions in the infected cells. The cultured virus, inactivated with formaldehyde, could elicit haemagglutination inhibition antibodies in the inoculated rabbits and protect them against the challenge of virulent VHD virus.