The Propagation, Quantification, and Storage of Vesicular Stomatitis Virus.

Vesicular stomatitis virus (VSV) is the prototypical member of the Rhabdoviridae family of negative-sense single-stranded RNA viruses. This virus has been used as a powerful model system for decades and is currently being used as a vaccine platform and an oncolytic agent. Here, we present methods to propagate, quantitate, and store VSV. We also review the proper safety protocol for the handling of VSV, which is classified as a Biosafety Level 2 pathogen by the United States Centers for Disease Control and Prevention. © 2020 Wiley Periodicals LLC. Basic Protocol 1: Generation, purification, and storage of vesicular stomatitis virus stocks Basic Protocol 2: Quantification of vesicular stomatitis virus by plaque assay Support Protocol: Propagation of Vero cells.

Examination of vesicular stomatitis virus-induced morphology changes in individual Vero cells by QMod microscopy.

Viral infection of cultured cells induces changes in the biophysical characteristics of the affected cells. Advanced microscopic cameras such as Ovizio's QMod, coupled with the appropriate software, can measure a variety of characteristics on a per-cell basis. We have employed this system to monitor the progression of vesicular stomatitis virus infection in Vero cells and to describe the cellular changes associated with advancing vesicular stomatitis virus infection. The measurements of cellular characteristics are operator-independent, and the goal is to establish a robust method to mathematically determine viral infection levels in a given sample. This will provide a means to measure viral titer in a faster and less subjective way than manual reading of plaque assays or tissue culture infectious dose 50 assays.

Attomolar detection of virus by liquid coplanar-gate graphene transistor on plastic.

The direct method of detecting a virus with extremely low concentration is recommended for the diagnosis of viral disease. In this study, coplanar-gate graphene field-effect transistors (GFETs) were built on flexible polyethylene terephthalate substrates for the attomolar detection of a virus. The GFETs exhibited a very low detection limit of 47.8 aM with relatively low source/drain voltage due to aqueous dielectric media which stabilizes viruses and antibodies for specific bonding. The antibody as a probe molecule was decorated on a graphene surface using 1-pyrenebutanoic acid succinimidyl ester that had previously been immobilized on a graphene surface. The Dirac point voltage shifted downward after dropping the virus solution, due to the electrostatic gating effect of graphene in the antigen (namely, virus)-antibody complex. The virus detection platform used in this study is expected to be beneficial for direct diagnosis in saline environments, since the performances of GFETs were not significantly affected by the presence of Na+ and Cl-. Furthermore, since our flexible and transparent virus sensors can be used in a wearable device, they provide a simple and fast method for diagnosing viruses.

Rapid quantification of vesicular stomatitis virus in Vero cells using Laser Force Cytology.

The ability to rapidly and accurately determine viral infectivity can help improve the speed of vaccine product development and manufacturing. Current methods to determine infectious viral titers, such as the end-point dilution (50% tissue culture infective dose, TCID50) and plaque assays are slow, labor intensive, and often subjective. In order to accelerate virus quantification, Laser Force Cytology (LFC) was used to monitor vesicular stomatitis virus (VSV) infection in Vero (African green monkey kidney) cells. LFC uses a combination of optical and fluidic forces to interrogate single cells without the use of labels or antibodies. Using a combination of variables measured by the Radiance™ LFC instrument (LumaCyte), an infection metric was developed that correlates well with the viral titer as measured by TCID50 and shortens the timeframe from infection to titer determination from 3 days to 16 h (a 4.5 fold reduction). A correlation was also developed between in-process cellular measurements and the viral titer of collected supernatant, demonstrating the potential for real-time infectivity measurements. Overall, these results demonstrate the utility of LFC as a tool for rapid infectivity measurements throughout the vaccine development process.

Switchable aptamers for biosensing and bioseparation of viruses (SwAps-V).

There is a widespread interest in the development of aptamer-based affinity chromatographic methods for purification of biomolecules. Regardless of the many advantages exhibited by aptamers when compared to other recognition elements, the lack of an efficient regeneration technique that can be generalized to all targets has encumbered further integration of aptamers into affinity-based purification methods. Here we offer switchable aptamers (SwAps) that have been developed to solve this problem and move aptamer-based chromatography forward. SwAps are controlled-affinity aptamers, which have been employed here to purify vesicular stomatitis virus (VSV) as a model case, however this technique can be extended to all biologically significant molecules. VSV is one oncolytic virus out of an arsenal of potential candidates shown to provide selective destruction of cancer cells both in vitro and in vivo. These SwAps were developed in the presence of Ca(2+) and Mg(2+) ions where they cannot bind to their target VSV in absence of these cations. Upon addition of EDTA and EGTA, the divalent cations were sequestered from the stabilized aptameric structure causing a conformational change and subsequently release of the virus. Both flow cytometry and electrochemical impedance spectroscopy were employed to estimate the binding affinities between the selected SwAps and VSV and to determine the coefficient of switching (CoS) upon elution. Among fifteen sequenced SwAps, four have exhibited high affinity to VSV and ability to switch upon elution and thus were further integrated into streptavidin-coated magnetic beads for purification of VSV.

Outbreaks of Vesicular stomatitis Alagoas virus in horses and cattle in northeastern Brazil.

The current article describes outbreaks of vesicular stomatitis (VS) in horses and cattle in Paraiba and Rio Grande do Norte states, northeastern Brazil, between June and August 2013. The reported cases affected 15-20 horses and 6 cattle distributed over 6 small farms in 4 municipalities, but additional data indicated the involvement of a large number of animals on several farms. The disease was characterized by blisters; eruptive lesions in coronary bands, lips, mouth, and muzzle; salivation; claudication and loss of condition. Swollen lower limbs and lips, and ulcerated and erosive areas in the lips and muzzle were observed in some horses. A necrotizing vesiculopustular dermatitis and stomatitis was observed histologically. Vesicular stomatitis virus was isolated from the vesicular fluid of a horse lesion and shown to be serologically related to the VS Indiana serogroup (VSIV) by virus neutralization. Convalescent sera of affected horses and cattle, and from healthy contacts, harbored high levels of neutralizing antibodies against the isolated virus (named VSIV-3 2013SaoBento/ParaibaE). Genomic sequences of VSIV subtype 3 (Vesicular stomatitis Alagoas virus) were amplified by reverse transcription polymerase chain reaction out of clinical specimens from a cow and a horse from different farms. Nucleotide sequencing and phylogenetic analysis of the phosphoprotein gene indicated that the 2 isolates were derived from the same virus and clustered them in VSIV-3, along with VS viruses identified in southeastern and northeastern Brazil in the last decades. Thus, the present report demonstrates the circulation of VSIV-3 in northeastern Brazil and urges for more effective diagnosis and surveillance.

Development and laboratory evaluation of two lateral flow devices for the detection of vesicular stomatitis virus in clinical samples.

Two lateral flow devices (LFD) for the detection of vesicular stomatitis (VS) virus (VSV), types Indiana (VSV-IND) and New Jersey (VSV-NJ) were developed using monoclonal antibodies C1 and F25VSVNJ-45 to the respective VSV serotypes. The performance of the LFDs was evaluated in the laboratory on suspensions of vesicular epithelia and cell culture passage derived supernatants of VSV. The collection of test samples included 105 positive for VSV-IND (92 vesicular epithelial suspensions and 13 cell culture antigens; encompassing 93 samples of subtype 1 [VSV-IND-1], 9 of subtype 2 [VSV-IND-2] and 3 of subtype 3 [VSV-IND-3]) and 189 positive for VSV-NJ (162 vesicular epithelial suspensions and 27 cell culture antigens) from suspected cases of vesicular disease in cattle and horses collected from 11 countries between 1937 and 2008 or else were derived from experimental infection and 777 samples that were either shown to be positive or negative for foot-and-mouth disease (FMD) virus (FMDV) and swine vesicular disease virus (SVDV) or else collected from healthy cattle or pigs and collected from 68 countries between 1965 and 2011. The diagnostic sensitivity of the VSV-IND (for reaction with VSV-IND-1) and VSV-NJ LFDs was either similar or identical at 94.6% (VSV-IND) and 97.4% (VSV-NJ) compared to 92.5% and 97.4% obtained by the reference method of antigen ELISA. The VSV-IND LFD failed to react with viruses of VSV-IND-2 and 3, while the VSV-NJ device recognized all VSV-NJ virus strains. The diagnostic specificities of the VSV-IND and VSV-NJ LFDs were 99.1% and 100, respectively, compared to 99.6% and 99.8% for the ELISA. Reactions with FMDV which can produce indistinguishable syndromes clinically in cattle, pigs and sheep and SVDV (vesicular disease in pigs) did not occur. These data illustrate the potential for the LFDs to be used next to the animal for providing rapid and objective support to veterinarians in their clinical judgment of vesicular disease and for the subtype (VSV-IND-1) and type-specific (VSV-NJ) pen-side diagnosis of VS and differential diagnosis from FMD.

Comparison of RNA extraction methods to augment the sensitivity for the differentiation of vesicular stomatitis virus Indiana1 and New Jersey.

Two methods for the extraction of RNA of vesicular stomatitis virus (VSV) Indiana1 and New Jersey and their simultaneous amplification by one-step polymerase chain reaction using reverse transcriptase were evaluated. A guanidine-thiocyanate-based RNA extraction (Qiagen RNeasy Mini Kit, Qiagen, Valencia, CA ) followed by column-based purification coupled with one-step RT-PCR proved to be a simple, safe, practicable, and reliable tool for rapid, highly sensitive, and specific differential diagnosis of both types of VSV in cell lysate and spiked tissue samples as compared with the tri-phasic extraction method (Tri-reagent method). When RNA was extracted either from VSV cell culture stock or from VSV spiked bovine lymph nodes by using Qiagen RNeasy Mini Kit, the detection limit in the multiplex RT-PCR was as low as 0.505 to 2.84 TCID(50) for VSV-IND and VSV-NJ, respectively. The multiplex RT-PCR consistently detected VSV-IND and NJ RNA in as little as 0.1-1.0 fg of total RNA from spiked BHK-21 cell suspension when Qiagen RNeasy mini kit was used. The multiplex RT-PCR assay was capable of detecting both types of VSV in a one-step reaction tube. The minimum sensitivity of this assay in various experiments was 0.1683 TCID(50) (IND), 0.0946 TCID(50) (NJ), and 0.057 fg (IND and NJ) per 2 µl PCR sample, which is significantly more sensitive than reported previously (0.28-2.8 TCID50/1 µl). So the present study improved the sensitivity of previously reported multiplex RT-PCR for the detection and differentiation of VSV-IND and VSV-NJ in a single assay.

Label-free multiplexed virus detection using spectral reflectance imaging.

We demonstrate detection of whole viruses and viral proteins with a new label-free platform based on spectral reflectance imaging. The Interferometric Reflectance Imaging Sensor (IRIS) has been shown to be capable of sensitive protein and DNA detection in a real time and high-throughput format. Vesicular stomatitis virus (VSV) was used as the target for detection as it is well-characterized for protein composition and can be modified to express viral coat proteins from other dangerous, highly pathogenic agents for surrogate detection while remaining a biosafety level 2 agent. We demonstrate specific detection of intact VSV virions achieved with surface-immobilized antibodies acting as capture probes which is confirmed using fluorescence imaging. The limit of detection is confirmed down to 3.5 × 10(5)plaque-forming units/mL (PFUs/mL). To increase specificity in a clinical scenario, both the external glycoprotein and internal viral proteins were simultaneously detected with the same antibody arrays with detergent-disrupted purified VSV and infected cell lysate solutions. Our results show sensitive and specific virus detection with a simple surface chemistry and minimal sample preparation on a quantitative label-free interferometric platform.

Improvement and optimization of a multiplex real-time reverse transcription polymerase chain reaction assay for the detection and typing of Vesicular stomatitis virus.

An improvement to a previously reported real-time reverse transcription polymerase chain reaction (real-time RT-PCR) assay for the detection of Vesicular stomatitis virus (VSV) is described. Results indicate that the new assay is capable of detecting a panel of genetically representative strains of VSV present in North, Central, and South America. The assay is specific for VSV and allows for simultaneous differentiation between Vesicular stomatitis Indiana virus and Vesicular stomatitis New Jersey virus. This real-time RT-PCR is able to detect current circulating strains of VSV and can be used for rapid diagnosis of VSV and differentiation of VSV from other vesicular diseases, such as foot-and-mouth disease.

Field evaluation of a multiplex real-time reverse transcription polymerase chain reaction assay for detection of Vesicular stomatitis virus.

Sporadic outbreaks of vesicular stomatitis (VS) in the United States result in significant economic losses for the U.S. livestock industries because VS is a reportable disease that clinically mimics foot-and-mouth disease. Rapid and accurate differentiation of these 2 diseases is critical because their consequences and control strategies differ radically. The objective of the current study was to field validate a 1-tube multiplexed real-time reverse transcription polymerase chain reaction (real-time RT-PCR) assay for the rapid detection of Vesicular stomatitis New Jersey virus and Vesicular stomatitis Indiana virus strains occurring in Mexico and North and Central America. A comprehensive collection of 622 vesicular lesion samples obtained from cattle, horses, and swine from throughout Mexico and Central America was tested by the real-time RT-PCR assay and virus isolation. Overall, clinical sensitivity and specificity of the real-time RT-PCR were 83% and 99%, respectively. Interestingly, VS virus isolates originating from a specific region of Costa Rica were not detected by real-time RT-PCR. Sequence comparisons of these viruses with the real-time RT-PCR probe and primers showed mismatches in the probe and forward and reverse primer regions. Additional lineage-specific primers and a probe corrected the lack of detection of the missing genetic lineage. Thus, this assay reliably identified existing Mexican and Central American VS viruses and proved readily adaptable as new VS viruses were encountered. An important secondary result of this research was the collection of hundreds of new VS virus isolates that provide a foundation from which many additional studies can arise.

Rapid diagnosis of vesicular stomatitis virus in Ecuador by the use of polymerase chain reaction

Vesicular Stomatitis (VS) is a viral disease that has a great impact in animal health, as infected animals present marked decrease in meat and milk production. Its presence is a limiting factor for international animal trade. Besides the damage in the livestock productivity, such disease assumes an important role in animal health programs since it is clinically indistinguishable from Foot-and-Mouth Disease. The diagnosis of the VS has been made, mainly, through Complement Fixation, ELISA and Virus Neutralization tests, assays that allow not only for viral detection but also for differentiation of the two serotypes described for Vesicular Stomatitis Virus (VSV): New Jersey (NJ) and Indiana (Ind). In this work, a molecular diagnostic approach, the polymerase chain reaction performed after reverse transcription (RT - PCR), based on the specific partial amplification of NS gene of VSV was used, as an alternative method for the detection of the virus. A total of 10 VSV reference samples and 12 specimens collected from animals with clinical signs of vesicular disease obtained from field episodes in Ecuador were tested. The method allowed for the specific partial amplification of the region coding for protein P, both for VSV serotypes New Jersey (642 bp) and Indiana 1 (614 bp). The results were compatible with data obtained by Complement Fixation test and the identity of the amplified products was confirmed by nucleotide sequencing.

A Estomatite Vesicular (EV) é uma enfermidade viral de grande impacto na saúde animal. O animal enfermo apresenta queda na produtividade em rebanho de carne e na produção leiteira, sendo um fator limitante para o comércio internacional de animais. Além dos danos à produtividade essa enfermidade assume importante papel nos programas de saúde animal por ser indistinguível clinicamente da Febre Aftosa. As técnicas para o diagnóstico da EV são, principalmente, a Fixação de Complemento, a ELISA e a Virusneutralização, testes que permitem a detecção viral e a diferenciação dos dois sorotipos descritos para o vírus da Estomatite Vesicular (VEV): New Jersey (NJ) e Indiana (Ind). Neste trabalho a metodologia molecular da reação em cadeia da polimerase após transcrição reversa (RT - PCR) baseada na amplificação parcial específica do gene NS do VEV foi utilizada como um método alternativo para a detecção do vírus. Um total de 10 amostras de referência do VEV e 12 espécimes coletados de animais com sinais clínicos de enfermidade vesicular obtidas de episódios de campo em Equador foi testado. O método permitiu a amplificação parcial da região que codifica para proteína P, tanto para NJ (642 pb) quanto para Ind (614 pb). Os resultados foram concordantes com os dados obtidos por Fixação de Complemento e a identidade dos produtos amplificados foi confirmada por meio de seqüenciamento nucleotídico.

Viral purging of haematological autografts: should we sneeze on the graft?

High-dose cytotoxic chemotherapy followed by autologous haematopoietic stem cell transplantation (ASCT) is extensively used for the treatment of many haematopoietic, as well as several epithelial cancers. Disease relapse may be the result of tumour contamination within autograft as evidenced by gene marking studies. The multiple purging strategies that have been described to date have not proven effective in most ASCT settings. This review addresses the possibility of using oncolytic viruses as a novel purging strategy. DNA viruses such as genetically engineered adenoviral vectors have widely been used to deliver either a prodrug-activating enzyme or express wild-type p53 selectively in tumour cells in ex vivo purging protocols. In addition, conditionally replicating adenoviruses that selectively replicate in tumour cells and herpes simplex virus type 1 are other DNA viruses that have been tested as ex vivo purging agents under laboratory conditions. Vesicular stomatitis virus (VSV) and reovirus are naturally occurring RNA viruses that appear to hold promise as purging agents under ex vivo and in vivo settings. Preclinical data demonstrate reovirus's purging potential against breast, monocytic and myeloma cell lines as well as patient-derived tumours of diffuse large B-cell lymphoma, chronic lymphocytic leukaemia, Waldenstrom macroglobulinemia and small lymphocytic lymphoma. In addition, VSV has shown effective killing of leukaemic cell lines and multiple myeloma patient specimens. Given the increasing interest in the utilization of viruses as purging agents, the following review provides a timely summary of the potential and the challenges of oncolytic viruses as purging modalities during ASCT.

Microarray-based molecular detection of foot-and-mouth disease, vesicular stomatitis and swine vesicular disease viruses, using padlock probes.

The World Organization for Animal Health (Office International des Epizooties, OIE) includes the diseases caused by foot-and-mouth disease virus (FMDV), swine vesicular disease virus (SVDV), and vesicular stomatitis virus (VSV), as "Diseases Notifiable to the OIE". Foot-and-mouth disease (FMD) outbreaks have severe economical as well as social effects and cannot be differentiated from the diseases caused by the other two viruses on the basis of clinical symptoms. Efficient laboratory techniques are therefore required for detection and identification of the viruses causing similar vesicular symptoms in swine. A rapid method is described using padlock probes and microarrays to detect simultaneously and differentiate the three viruses in a single reaction, as well as providing serotype information in cases of VSV infection. The padlock probe/microarray assay detected successfully and identified 39 cDNA samples of different origin representing the three viruses. The results were in complete agreement with identities and serotypes determined previously. This novel virus detection method is discussed in terms of usefulness and further development.

Quantitative multiplex assay for simultaneous detection of the Indiana serotype of vesicular stomatitis virus and HIV gag.

Assessment of in vivo viral replication of live attenuated recombinant vesicular stomatitis virus (rVSV) vaccine vector candidates encoding HIV gag requires comprehensive preclinical safety studies, and development of sensitive assays to monitor the outcome of vaccination of animals is important. In this study, two 2-step quantitative real-time RT-PCR assays were developed; a singleplex assay to detect VSV genomic RNA from ferrets inoculated intra-cranially (IC) or intra-nasally (IN) with either a wild-type (wt) virus or an attenuated rVSV vector engineered to express HIV gag protein, and a duplex assay to simultaneously detect VSV-N and HIV-gag mRNAs from cynomolgus macaques inoculated intra-thalamically (IT) with the same viruses. Using synthetic oligonucleotides as standards, the lower limit of detection of VSV-N and HIV-gag was 50 copies. Results showed high levels of wt VSV(IN) genomic RNA and mRNA in ferret and macaque tissues, respectively, and significantly lower levels of VSV genomic RNA and VSV-N and HIV-gag mRNAs in tissues from animals inoculated with the attenuated rVSV vector. These assays correlated with both the course of infection for these animals, and the infectious viral load measured by a standard plaque assay, and could be used to determine the safety profile of rVSV vaccine vectors.

Experimental vesicular stomatitis virus infection in horses: effect of route of inoculation and virus serotype.

Horses were inoculated with Vesicular stomatitis New Jersey and Indiana viruses by routes simulating contact and vector transmission. Clinical signs, lesions, antibody development, viral shedding and persistence, and viremia were monitored. Horses were infected with both viruses by all routes as confirmed by seroconversion. Salivation, primary lesions at inoculation sites, and secondary oral lesions were the most common clinical findings. Viral shedding was most often from the oral cavity, followed by the nasal cavity; titers were highest from oral cavity samples. Virus was rarely isolated from the conjunctival sac and never from feces or blood. Development of neutralizing antibody coincided with cessation of lesion development and detection of virus by isolation. Circulating virus-specific IgM, IgG, IgA, and neutralizing antibodies developed in most animals postinoculation (PI) days 6 to 12, depending on the route of inoculation. At postmortem (PI days 12 to 15), lesions were healing, were not vesicular, and did not contain detectable virus by isolation, reverse transcriptase polymerase chain reaction, or immunohistochemistry. Numerous infiltrating lymphocytes and plasma cells suggested that lesion resolution was partially due to local immunity. Detection of viral RNA from tonsil and lymph nodes of head at necropsy suggests that these tissues play a role in the pathogenesis of the disease; molecular techniques targeting these tissues may be useful for confirming infection in resolving stages of disease. The routes of inoculation used in this study reflect the diversity of transmission routes that may occur during outbreaks and can be used to further study contact and vector transmission, vaccine development, and clarify pathogenesis of the disease in horses.

Detection and serotype-specific differentiation of vesicular stomatitis virus using a multiplex, real-time, reverse transcription-polymerase chain reaction assay.

A multiplex, real-time reverse transcription-polymerase chain reaction (RT-PCR) assay was developed that allowed simultaneous detection and rapid differentiation of vesicular stomatitis virus strains--New Jersey (VSV-NJ) and Indiana 1, 2, and 3 (VSV-IN1-3). This assay involves use of a set of VSV universal primers located in the L gene that amplify VSV-IN1-3 and VSV-NJ using probes that allow differentiation of the major serotypes Indiana and New Jersey. The assay was evaluated using reference VSV, foot-and-mouth disease virus, swine vesicular disease virus, and vesicular exanthema of swine virus. To estimate diagnostic sensitivity, 159 epithelial samples collected between 1996 and 2002 from naturally infected cattle in Colombia were used. The assay cut off was calculated by testing RNA extracted from 150 virus-negative bovine tissues consisting of tongue, soft palate, muzzle, coronary band, and lymph node. All infected cattle were test positive for VS by results of real-time RT-PCR analysis; results for 156 of 159 (98.1%) agreed with the serotype determination from the complement-fixation test. Amplification did not occur in any of the negative bovine epithelial samples, allowing the cut-off values for the assay to be set. The real-time RT-PCR assay was documented to be sensitive and specific for the detection of VSV-NJ and VSV-IN (1-3) strains from field samples in a single reaction, thereby supporting use of this assay in the differential diagnosis of vesicular virus diseases in cattle.

An efficient helper-virus-free method for rescue of recombinant paramyxoviruses and rhadoviruses from a cell line suitable for vaccine development.

Recovery of recombinant, negative-strand, nonsegmented RNA viruses from a genomic cDNA clone requires a rescue system that promotes de novo assembly of a functional ribonucleoprotein (RNP) complex in the cell cytoplasm. This is accomplished typically by cotransfecting permissive cells with multiple plasmids that encode the positive-sense genomic RNA, the nucleocapsid protein (N or NP), and the two subunits of the viral RNA-dependent RNA polymerase (L and P). The transfected plasmids are transcribed in the cell cytoplasm by phage T7 RNA polymerase (T7 RNAP), which usually is supplied by infection with a recombinant vaccinia virus or through use of a stable cell line that expresses the polymerase. Although both methods of providing T7 RNAP are effective neither is ideal for viral vaccine development for a number of reasons. Therefore, it was necessary to modify existing technology to make it possible to routinely rescue a variety of recombinant viruses when T7 RNAP was provided by a cotransfected expression plasmid. Development of a broadly applicable procedure required optimization of the helper-virus-free methodology, which resulted in several modifications that improved rescue efficiency such as inclusion of plasmids encoding viral glycoproteins and matrix protein, heat shock treatment, and use of electroporation. The combined effect of these enhancements produced several important benefits including: (1) a helper-virus-free methodology capable of rescuing a diverse variety of paramyxoviruses and recombinant vesicular stomatitis virus (rVSV); (2) methodology that functioned effectively when using Vero cells, a suitable substrate for vaccine production; and (3) a method that enabled rescue of highly attenuated recombinant viruses, which had proven refractory to rescue using published procedures.

Detection of three porcine vesicular viruses using multiplex real-time primer-probe energy transfer.

Rapid identification of the etiologic agent in infected animals is important for the control of an outbreak of vesicular disease in livestock. We have in the present study developed a multiplex real-time reverse transcription-PCR, based on primer-probe energy transfer (PriProET), for simultaneous detection and differentiation of three Office International des Epizooties (OIE) classified vesicular viruses: foot-and-mouth disease virus, vesicular stomatitis virus and swine vesicular disease, causing clinically indistinguishable vesicular diseases in swine. The multiplex assay consists of extraction of total RNA from clinical samples; reverse transcription to cDNA using random primers and one-tube real-time amplification of cDNA using multiplex PriProET with specific fluorescent-labelled primers and probes for detection of the three viruses from the vesicular disease complex. The probes are labelled with unique reporter fluorophores, which during amplification are excited by donor fluorophores incorporated in the 5' end of specific amplicons by primer extension. The sensitivity of the multiplex assay was approximately 100 TCID(50), which is 10-fold lower compared to the individual PriProET assays for the three vesicular viruses.

Inducible vesicular stomatitis virus (VSV) L cell line for packaging of recombinant VSV.

Recently, recombinant vesicular stomatitis viruses (VSV) have been developed as high-level expression vectors which serve as effective vaccine vectors in animals. An ideal approach for VSV vector production would be the development of stable packaging cell lines that can produce vector particles without transfection step. In this report, we describe generation of an inducible cell line that expresses the VSV polymerase gene (L) under the control of the reverse tetracycline-controlled transactivator (rtTA) system as a first step to make VSV-based packaging cell lines. Integrated polymerase (L) gene was controlled by an rtetR-dependent promoter in the rtTA-producing BHK cell line. When the cell lines were cultured in the presence of tet (tetracycline) or tetracycline derivative doxycycline, the recombinant VSV and wild type VSV were replicated, whereas in the absence of tet or tetracycline derivative doxycycline, the recombinant VSV was not replicated. Viral supernatants were harvested, diluted, and monitored by plaque assay for the presence of infectious VSV. Plaques of VSV containing an additional sequence encoding the EGFP protein allowed rapid detection of infection. Our results suggest wide applications of other surrogate viruses based on VSV. The availability of stable packaging cell lines represents a step toward the use of a VSV vector delivery system that can allow scale-up production of vector-stocks for gene therapy.