Unusually High Mortality in Waterfowl Caused by Highly Pathogenic Avian Influenza A(H5N1) in Bangladesh.

Mortality in ducks and geese caused by highly pathogenic avian influenza A(H5N1) infection had not been previously identified in Bangladesh. In June-July 2011, we investigated mortality in ducks, geese and chickens with suspected H5N1 infection in a north-eastern district of the country to identify the aetiologic agent and extent of the outbreak and identify possible associated human infections. We surveyed households and farms with affected poultry flocks in six villages in Netrokona district and collected cloacal and oropharyngeal swabs from sick birds and tissue samples from dead poultry. We conducted a survey in three of these villages to identify suspected human influenza-like illness cases and collected nasopharyngeal and throat swabs. We tested all swabs by real-time RT-PCR, sequenced cultured viruses, and examined tissue samples by histopathology and immunohistochemistry to detect and characterize influenza virus infection. In the six villages, among the 240 surveyed households and 11 small-scale farms, 61% (1789/2930) of chickens, 47% (4816/10 184) of ducks and 73% (358/493) of geese died within 14 days preceding the investigation. Of 70 sick poultry swabbed, 80% (56/70) had detectable RNA for influenza A/H5, including 89% (49/55) of ducks, 40% (2/5) of geese and 50% (5/10) of chickens. We isolated virus from six of 25 samples; sequence analysis of the hemagglutinin and neuraminidase gene of these six isolates indicated clade 2.3.2.1a of H5N1 virus. Histopathological changes and immunohistochemistry staining of avian influenza viral antigens were recognized in the brain, pancreas and intestines of ducks and chickens. We identified ten human cases showing signs compatible with influenza-like illness; four were positive for influenza A/H3; however, none were positive for influenza A/H5. The recently introduced H5N1 clade 2.3.2.1a virus caused unusually high mortality in ducks and geese. Heightened surveillance in poultry is warranted to guide appropriate diagnostic testing and detect novel influenza strains.

Real-time RT-PCR assay to differentiate clades of H5N1 avian influenza viruses circulating in Vietnam.

Continued circulation and geographical expansion of highly pathogenic avian influenza H5N1 virus have led to the emergence of numerous clades in Vietnam. Although viral RNA sequencing and phylogenetic analysis are the gold standard for H5N1 HA clade designation, limited sequencing capacity in many laboratories precludes rapid H5N1 clade identification and detection of novel viruses. Therefore, a Taqman real-time RT-PCR assay for rapid differentiation of the four major H5N1 clades detected in Vietnam was developed. Using HA sequence alignments of clades 1.1, 2.3.2.1, 2.3.4, and 7 viruses, primers and FAM-labeled probes were designed to target conserved regions characteristic of each clade. The assay was optimized and evaluated using circulating clades of H5N1 collected in Vietnam from 2007 to 2012 and shown to be both sensitive and specific for the differentiation of the four H5N1 clades. The assay provides a useful tool for screening of large specimen collections for HA gene sequencing and phylogenetic analysis and for the rapid identification of molecular clade signatures to support outbreak investigations and surveillance activities. Finally, this assay may be useful to monitor for the emergence of novel or variant clades of H5N1 in Vietnam in the future or in other countries where these particular clades may circulate.

Canine H3N8 influenza virus infection in dogs and mice.

An H3N8 influenza virus closely related to equine influenza virus was identified in racing greyhound dogs with respiratory disease in 2004 and subsequently identified in shelter and pet dogs. Pathologic findings in dogs spontaneously infected with canine influenza virus were compared with lesions induced in beagle and mongrel dogs following experimental inoculation with influenza A/canine/Florida/43/2004. BALB/c mice were inoculated with canine influenza virus to assess their suitability as an experimental model for viral pathogenesis studies. All dogs inoculated with virus developed necrotizing and hyperplastic tracheitis and bronchitis with involvement of submucosal glands as well as mild bronchiolitis and pneumonia. Viral antigen was identified in bronchial and tracheal epithelial cells of all dogs and in alveolar macrophages of several dogs. Many dogs that were spontaneously infected with virus also developed bacterial pneumonia, and greyhound dogs with fatal spontaneous infection developed severe pulmonary hemorrhage with hemothorax. Virus-inoculated BALB/c mice developed tracheitis, bronchitis, bronchiolitis, and mild pneumonia in association with viral antigen in airway epithelial cells and in type 2 alveolar epithelial cells. Virus was not detected in extrarespiratory sites in any animals. The results indicate that canine influenza virus infection consistently induces acute tracheitis and bronchitis in dogs. Mice may be a useful model for some pathogenesis studies on canine influenza virus infection.

Mannheimia (Pasteurella) haemolytica leukotoxin binding domain lies within amino acids 1 to 291 of bovine CD18.

Previously, we identified bovine CD18 as the receptor for leukotoxin secreted by Mannheimia (Pasteurella) haemolytica. In this study, we constructed bovine-murine CD18 chimeras to locate the leukotoxin binding domain on CD18. Leukotoxin specifically lysed transfectants expressing bovine CD18 fragment encompassing amino acids 1 to 291, indicating that leukotoxin binding domain lies within amino acids 1 to 291 of bovine CD18.

Induction of specific CD8+ memory T cells and long lasting protection following immunization with Salmonella typhimurium expressing a lymphocytic choriomeningitis MHC class I-restricted epitope.

Numerous studies have shown the potential of Salmonella typhimurium as a vector for delivery of heterologous proteins for vaccination against other pathogens. Earlier studies showed that the inefficient elicitation of MHC class I-restricted responses could limit the use of S. typhimurium as a heterologous antigen delivery vector for vaccination. We recently developed an approach to overcome this limitation by using a bacterial-encoded specialized protein secretion system, termed type III, to deliver proteins into the class I antigen presenting pathways. Thus, peptides of interest fused to proteins bearing the type III secretion signal, which can elicit protective CTL responses. Because protective immunity is usually assessed a few weeks after vaccination, there is a paucity of information regarding duration of protective immunity induced by this system. We show here that mice immunized orally with S. typhimurium vectors expressing a MHC class I-restricted epitope of the lymphocytic choriomeningitis virus (LCMV) nucleoprotein developed specific antiviral CTL responses. CD8+ T cells were found to be necessary for this CTL activity against targets presenting the LCMV epitope. The survival of mice challenged with lethal doses of LCMV 60 or 135 days after vaccination was as complete as the survival of mice challenged 2 weeks after immunization with the same vectors. By demonstrating their ability to induce prolonged protective immunity after oral delivery, S. typhimurium vectors have met an essential requirement in support of their development as vectors for heterologous vaccination.

Functional analysis of PA binding by influenza a virus PB1: effects on polymerase activity and viral infectivity.

Influenza A virus expresses three viral polymerase (P) subunits-PB1, PB2, and PA-all of which are essential for RNA and viral replication. The functions of P proteins in transcription and replication have been partially elucidated, yet some of these functions seem to be dependent on the formation of a heterotrimer for optimal viral RNA transcription and replication. Although it is conceivable that heterotrimer subunit interactions may allow a more efficient catalysis, direct evidence of their essentiality for viral replication is lacking. Biochemical studies addressing the molecular anatomy of the P complexes have revealed direct interactions between PB1 and PB2 as well as between PB1 and PA. Previous studies have shown that the N-terminal 48 amino acids of PB1, termed domain alpha, contain the residues required for binding PA. We report here the refined mapping of the amino acid sequences within this small region of PB1 that are indispensable for binding PA by deletion mutagenesis of PB1 in a two-hybrid assay. Subsequently, we used site-directed mutagenesis to identify the critical amino acid residues of PB1 for interaction with PA in vivo. The first 12 amino acids of PB1 were found to constitute the core of the interaction interface, thus narrowing the previous boundaries of domain alpha. The role of the minimal PB1 domain alpha in influenza virus gene expression and genome replication was subsequently analyzed by evaluating the activity of a set of PB1 mutants in a model reporter minigenome system. A strong correlation was observed between a functional PA binding site on PB1 and P activity. Influenza viruses bearing mutant PB1 genes were recovered using a plasmid-based influenza virus reverse genetics system. Interestingly, mutations that rendered PB1 unable to bind PA were either nonviable or severely growth impaired. These data are consistent with an essential role for the N terminus of PB1 in binding PA, P activity, and virus growth.

Microparticle-mediated RNA immunization against bovine viral diarrhea virus.

Infectious transcripts from the full-length infectious clone of the NADL strain of bovine viral diarrhea virus (BVDV) were used to vaccinate cattle and sheep against BVDV. In vitro synthesized RNA delivered by microparticle bombardment with a Helios Gene Gun initiated replication of BVDV and consequently induced humoral immunity against type I BVDV (serum neutralization titers, SNT > 2(12)) and type II BVDV (SNT > 2(7)). The quality and long-term stability of the RNA-carrier complexes was assessed by microparticle bombardment of tissue culture monolayers. The RNA cartridges were found to be stable for at least 8 months upon storage. This is the first report on successful RNA vaccination of large ruminants.

Bovine viral diarrhea virus induced apoptosis correlates with increased intracellular viral RNA accumulation.

Non-cytopathic (NCP) and cytopathic (CP) parent-daughter pairs are often isolated from cattle with bovine viral diarrhea virus (BVDV) induced mucosal disease. Alignment of these pair genomes revealed that genetic changes in CP BVDV involve the NS2-3 coding region and correlate with expression of NS3. However, additional mutations are present elsewhere in the genomes of these natural pairs, precluding unambiguous mapping of this function to the NS2-3 region. To evaluate this phenomenon in identical genetic backgrounds, we have constructed an NCP isogenic pair of the NADL by deletion of the cIns from NS2 region. The levels of viral protein synthesis in infected cells revealed no marked difference between the CP and the isogenic NCP BVDV mutant. In contrast, RNA accumulation in cells infected with CP virus was up to 25 times higher than that in cells infected with NCP BVDV. No significant difference in growth kinetics and viral yields were observed between the CP BVDV and the isogenic NCP pair. Analyses of additional NCP/CP parent-daughter field BVDV isolates revealed a similar pattern of macromolecular synthesis, suggesting the generality of this phenomenon. These results implicate increased levels of RNA accumulation in CP BVDV infected cells, along with the production of NS3 as potential contributors to viral cytopathogenicity.

Presence of bovine viral diarrhea virus (BVDV) E2 glycoprotein in VSV recombinant particles and induction of neutralizing BVDV antibodies in mice.

We generated a recombinant vesicular stomatitis virus (VSV-E2) encoding the bovine viral diarrhea virus (BVDV) E2 glycoprotein with the VSV-G protein signal peptide. Infection of BHK21 cells with VSV-E2 induced the synthesis of a recombinant E2 (rE2) that comigrated with authentic BVDV-E2 in PAGE-SDS gels. Non-reducing immunoblots showed that rE2 is a disulfide bond-linked homodimer with at least 10-fold higher avidity for conformation-dependent anti-BVDV-E2 antibodies than its reduced monomeric counterpart. Immunofluorescence microscopy also showed that rE2 was transported to the plasma membrane of infected cells and analysis of purified particles demonstrated that dimeric rE2 was incorporated into VSV-E2 virions in approximately 1:10 ratio with respect to the G glycoprotein. BALB/c mice inoculated intranasally with VSV-E2 doses of up to 10(7) plaque forming units (pfu) showed no symptoms of viral-induced disease and developed a specific BVDV neutralizing response that lasted for at least 180 days post inoculation.

Generation and characterization of a hepatitis C virus NS3 protease-dependent bovine viral diarrhea virus.

Unique to pestiviruses, the N-terminal protein encoded by the bovine viral diarrhea virus (BVDV) genome is a cysteine protease (Npro) responsible for a self-cleavage that releases the N terminus of the core protein (C). This unique protease is dispensable for viral replication, and its coding region can be replaced by a ubiquitin gene directly fused in frame to the core. To develop an antiviral assay that allows the assessment of anti-hepatitis C virus (HCV) NS3 protease inhibitors, a chimeric BVDV in which the coding region of Npro was replaced by that of an NS4A cofactor-tethered HCV NS3 protease domain was generated. This cofactor-tethered HCV protease domain was linked in frame to the core protein of BVDV through an HCV NS5A-NS5B junction site and mimicked the proteolytic function of Npro in the release of BVDV core for capsid assembly. A similar chimeric construct was built with an inactive HCV NS3 protease to serve as a control. Genomic RNA transcripts derived from both chimeric clones, P(H/B) (wild-type HCV NS3 protease) and P(H/B(S139A)) (mutant HCV NS3 protease) were then transfected into bovine cells (MDBK). Only the RNA transcripts from the P(H/B) clone yielded viable viruses, whereas the mutant clone, P(H/B(S139A)), failed to produce any signs of infection, suggesting that the unprocessed fusion protein rendered the BVDV core protein defective in capsid assembly. Like the wild-type BVDV (NADL), the chimeric virus was cytopathic and formed plaques on the cell monolayer. Sequence and biochemical analyses confirmed the identity of the chimeric virus and further revealed variant viruses due to growth adaptation. Growth analysis revealed comparable replication kinetics between the wild-type and the chimeric BVDVs. Finally, to assess the genetic stability of the chimeric virus, an Npro-null BVDV (BVDV-Npro in which the entire Npro coding region was deleted) was produced. Although cytopathic, BVDV-Npro was highly defective in viral replication and growth, a finding consistent with the observed stability of the chimeric virus after serial passages.

Experimental infection of calves with bovine viral diarrhea virus genotype II (NY-93).

To ascertain the virulence of bovine viral diarrhea virus (BVDV) genotype II, isolate NY-93 was inoculated intranasally into 3 calves, 2 of which were treated with a synthetic glucocorticoid prior to and after virus inoculation. Anorexia, fever (up to 42 C), dyspnea, and hemorrhagic diarrhea developed 6 days after intranasal inoculation with BVDV NY-93. The condition of all calves deteriorated further until the end of the study on day 14 postinoculation. The most significant postmortem macroscopic changes in all calves were limited to the gastrointestinal tract and consisted of moderate to severe congestion of the mucosa with multifocal hemorrhages. Microscopic lesions found in the gastrointestinal tract were similar to those observed in mucosal disease, including degeneration and necrosis of crypt epithelium and necrosis of lymphoid tissue throughout the ileum, colon, and rectum. The basal stratum of the epithelium of tongue, esophagus, and rumen had scattered individual necrotic cells. Spleen and lymph nodes had lymphocytolysis and severe lymphoid depletion. Severe acute fibrinous bronchopneumonia was present in dexamethasone-treated calves. Abundant viral antigen was detected by immunohistochemistry in the squamous epithelium of tongue, esophagus, and forestomachs. BVDV antigen was prominent in cells of the media of small arteries and endothelial cells. The presence of infectious virus in tissues correlated with an absence of circulating neutralizing antibodies. These findings highlight the potential of BVDV genotype II to cause severe disease in normal and stressed cattle.

Genetic analysis of the internal ribosome entry segment of bovine viral diarrhea virus.

Pestiviruses and hepaciviruses are atypical members of the Flaviviridae due to their unique biological properties, including the utilization of internal ribosome entry for translation initiation. In contrast to internal initiation in picornaviruses, which depends on numerous canonical initiation factors, the mode of internal ribosome entry in pestiviruses and hepaciviruses resembles prokaryotic translation initiation. To identify functionally important elements within the bovine viral diarrhea virus (BVDV) internal ribosome entry segment (IRES), we carried out a mutational analysis of the 5' untranslated region (5' UTR) of BVDV cloned in the intercistronic region of a bicistronic reporter plasmid. IRES function was assessed in a bicistronic transcript by inserting the 5' 901 nucleotides of BVDV genome, which correspond to the 385 nucleotides of the 5' UTR and 515 nucleotides of the open reading frame (ORF) encoding for Npro and 4 amino acids from the capsid protein. The resulting Npro-luciferase fusion encoded by the 3' cistron was cleaved efficiently to release the luciferase reporter. In vivo translation analyses showed that stem-loops Ia and Ib in the 5' UTR were completely dispensable for efficient translation, whereas stem-loop IIIe and the hairpin end of IIIb were only partially required. In contrast, deletions or insertions in any of other four stem-loop structures, including domains II, IIIa, IIIc, and IIId, caused nearly 10-fold reductions of in vivo IRES activity. The tolerance of structural modifications within the distal portion of domain IIIb and IIIe correlated with a low level of sequence conservation in these regions among pestiviruses. The 5' boundary of the IRES resides at the 5' end of stem-loop II near nucleotide 75. The 3' of the IRES extends into the 5' end of the polyprotein ORF because removal of the Npro coding region reduced translation by 21%.

Influence of host species on the evolution of the nonstructural (NS) gene of influenza A viruses.

The matrix (M) and nonstructural (NS) genes of influenza A viruses each encode two overlapping proteins. In the M gene, evolution of one protein affects that of the other. To determine whether or not this evolutionary influence operating between the two M proteins also occurs in the NS gene, we sequenced the NS genes of 36 influenza A viruses isolated from a broad spectrum of animal species (wild and domestic birds, horses, pigs, humans, and sea mammals) and analyzed them phylogenetically, together with other previously published sequences. These analyses enabled us to conclude the following host species-related points that are not found in the other influenza A virus genes and their gene products. (1) The evolution of the two overlapping proteins encoded by the NS gene are lineage-dependent, unlike the M gene where evolutionary constraints on the Ml protein affect the evolution of the M2 protein (Ito et al.. J. Virol. 65 (1991) 5491 5498). (2) The gull-specific lineage contained nonH13 gull viruses and the non-gull avian lineage contained H13 gull viruses, indicating that the gull-specific lineage does not link to the H13 HA subtype in the NS gene unlike findings with other genes. (3) The branching topology of the recent equine lineage (H7N7 viruses isolated after 1973 and H3N8) indicates recent introduction of the NS, M, and PB2 genes into horses from avian sources by genetic reassortment.

The matrix 1 protein of influenza A virus inhibits the transcriptase activity of a model influenza reporter genome in vivo.

The M1 protein of influenza virus inhibits the in vitro transcriptase activity of ribonucleoprotein cores from virions. This inhibitory activity is thought to be relevant in vivo because accumulation of M1 at the late stages of viral replication may be the cue to halt viral mRNA production. A model influenza reporter genome was used to explore the effect of M1 on the activity of the influenza virus transcriptase complex within cultured cells. Expression of M1 in cells bearing the model influenza virus reporter genome was accompanied by a reduction of CAT gene expression to 12% of control levels. Quantification of RNA by ribonuclease protection assay revealed that the influenza reporter genome mRNA levels in M1-expressing cells were reduced by approximately 74% compared with those of cells expressing a control protein. These findings are consistent with the proposed model in which M1 is responsible for limiting viral transcription during late stages of infection. By expressing truncated forms of M1, the inhibitory activity was found to reside within the amino-terminal half of the M1 protein. Two independent inhibitory domains were identified in this region: one between amino acid residues 1-90 and the other spanning residues 91-127.

Delivery of epitopes by the Salmonella type III secretion system for vaccine development.

Avirulent strains of Salmonella typhimurium are being considered as antigen delivery vectors. During its intracellular stage in the host, S. typhimurium resides within a membrane-bound compartment and is not an efficient inducer of class I-restricted immune responses. Viral epitopes were successfully delivered to the host-cell cytosol by using the type III protein secretion system of S. typhimurium. This resulted in class I-restricted immune responses that protected vaccinated animals against lethal infection. This approach may allow the efficient use of S. typhimurium as an antigen delivery system to control infections by pathogens that require this type of immune response for protection.

Induction of apoptosis and cleavage of poly(ADP-ribose) polymerase by cytopathic bovine viral diarrhea virus infection.

The Pestivirus bovine viral diarrhea virus (BVDV) causes the fatal diarrheal syndrome, mucosal disease, because of mutations in the viral genome which convert the common noncytopathic (ncp) BVDV into a cytopathic (cp) biotype. We examined the nature of the cytopathic effect of cp-BVDV in cultured bovine cells in order to accurately describe the process and to gain insight into the mechanism of cp-BVDV-induced cell death. The findings demonstrate that cells infected with cp-BVDV in vitro die by apoptosis, but cells infected with ncp-BVDV do not. Analysis of nuclear morphology by staining with fluorescent DNA dye and cpi-fluorescence microscopy showed chromatin condensation and margination in cells infected with cp-BVDV. Transmission electron microscopy (TEM) confirmed the condensation of chromatin, as well as cell shrinkage and generation of apoptotic bodies. The chromosomal DNA of cells infected with cp-BVDV undergoes fragmentation, generating the typical oligonucleosomal fragments commonly noted during apoptosis. The fragmented DNA was released from the nucleus to the cytoplasm, and eventually to the culture supernatant. Infection with cp-BVDV activates cellular proteases of the ICE family leading to cleavage of poly(ADP-ribose) polymerase (PARP), a nuclear enzyme implicated in genome maintenance. This demonstration that cp-BVDV kills cells by triggering apoptosis suggests the possibility that cp-BVDV is associated with a fatal disease by the acquisition of a new apoptosis-inducing activity. We consider BVDV to be an excellent model system for studies of the biological and medical relevance of apoptosis in viral infections.

Authentic and chimeric full-length genomic cDNA clones of bovine viral diarrhea virus that yield infectious transcripts.

Bovine viral diarrhea virus (BVDV) is the most insidious and devastating viral pathogen of cattle in the United States. Disease control approaches must be based on detailed knowledge of virus biology. To develop reverse-genetic systems to study the molecular biology of the virus, we first constructed a plasmid containing the entire genome of BVDV cloned as cDNA. Subsequently, we showed that infectious BVDV was produced by cells transfected with uncapped RNA transcribed in vitro from the cDNA clone. This result defined functional 5' and 3' termini in viral genomic RNA and established the biological importance of the proposed internal ribosome entry site element in the 5' untranslated region of the viral genome. BVDV rescued from the infectious cDNA clone has an in vitro phenotype similar to that of the wild-type parent, the National Animal Disease Laboratory strain of BVDV. A deletion of a single codon in the full-length genomic BVDV cDNA clone, encoding glutamic acid at position 1600, gave rise to sequence-tagged virus easily identified by restriction fragment length polymorphism analysis of reverse transcription-PCR amplicons. Suitability of the molecular clone of BVDV for genomic manipulations was shown by substitution of the major envelope glycoprotein E2/gp53 with that of the Singer strain, giving rise to a chimeric virus. The predicted change in antigenic structure of the chimeric virus could be readily identified with strain-specific monoclonal antibodies by neutralization and immunofluorescence assays. Immediate applications of this system include development of safe and effective live vaccine strains possessing predetermined defined attenuating mutations.

Identification of bovine viral diarrhea virus nonstructural polypeptide NS4B/P38.

The bovine pestivirus polyprotein is processed into at least 11 mature polypeptides. Previous studies with polyprotein region-specific antiserum raised against beta-galactosidase fusion proteins or synthetic peptides allowed the assignment of viral non-structural proteins to specific segments of the BVDV genome. However, the gene product from the NS4B/P38 region of the viral genome remained to be demonstrated directly. BVDV cDNA fragments predicted to encode part of NS4B/P38 (from codon 2521 to 2838 of the BVDV open reading frame) and a portion of NS5A/P58 (from codon 3008 to 3340) were expressed as glutathione S-transferase (GST) fusion proteins in Escherichia coli. Polyclonal rabbit antibodies prepared against each of the purified fusion proteins, GST-2521-2838 and GST-3008-3340, were used to immunoprecipitate viral polypeptides present in BVDV-infected cell lysates. Rabbit antiserum to GST-2521-2838 bound a polypeptide of 38 kDa identified as the mature NS4B/P38 polypeptide; while anti GST-3008-3340 lacked this specificity and bound NS5A/P58. Moreover, both antisera recognized a 96 kDa polypeptide, previously identified as a NS4B-NS5A/PP96 precursor. The function of the newly identified and highly conserved NS4B/P38 protein in viral replication remains to be determined.

Swine and ruminant pestiviruses require the same cellular factor to enter bovine cells.

Pestiviruses initiate infection of susceptible cells by receptor-mediated endocytosis. Cellular plasma membrane or endosomal molecules involved in translocation of these viruses into the cytosol have not been unequivocally identified. We reported previously that a mutant cell line derived from Madin-Darby bovine kidney (MDBK) cells, termed CRIB-1, was resistant to infection with bovine viral diarrhoea virus. CRIB-1 cells were also resistant to infection with classical swine fever virus and border disease virus of sheep, suggesting that entry of these three different pestiviruses into bovine cells requires a common cell membrane function. The resistance is pestivirus-specific: CRIB-1 cells were as susceptible as the parental MDBK cells to 14 other viruses of cattle and swine belonging to unrelated families. The resistance of CRIB-1 cells to pestivirus infection involves a block in virus entry since transfection of virus RNA or virus inoculation in the presence of PEG resulted in productive infection. Furthermore, quantitative analyses of the outcome of PEG-mediated infection of CRIB-1 cells indicated that the intracellular milieu was fully permissive for pestivirus replication. Binding studies revealed that virus attachment to CRIB-1 cells was not completely abrogated. These results indicate that entry of pestiviruses into MDBK cells depends on a common plasma membrane or endosomal function, which is lacking in CRIB-1 cells.