Human adenovirus-vectored foot-and-mouth disease vaccines: establishment of a vaccine product profile through in vitro testing

Next generation, foot-and-mouth disease (FMD) molecular vaccines based on replication deficient human adenovirus serotype 5 viral vectored delivery of FMD capsid genes (AdFMD) are being developed by the United States Dept. of Homeland Security and industry partners. The strategic goal of this program is to develop AdFMD licensed vaccines for the USA National Veterinary Stockpile for use, if needed, as emergency response tools during an FMD outbreak. This vaccine platform provides a unique opportunity to develop a set of in vitro analytical parameters to generate an AdFMD vaccine product profile to replace the current lot release test for traditional, inactivated FMD vaccines that requires FMDV challenge in livestock. The possibility of an indirect FMD vaccine potency test based on a serological alternative was initially investigated for a lead vaccine candidate, Adt.A24. Results show that serum virus neutralization (SVN) based serology testing for Adt.A24 vaccine lot release is not feasible, at least not in the context of vaccine potency assessment at one week post-vaccination. Thus, an in vitro infectious titer assay (tissue culture infectious dose 50, TCID50) which measures FMD infectious (protein expression) titer was established. Pre-validation results show acceptable assay variability and linearity and these data support further studies to validate the TCID50 assay as a potential potency release test. In addition, a quantitative physiochemical assay (HPLC) and three immunochemical assays (Fluorescent Focus-Forming Unit (FFU); tissue culture expression dose 50 (TCED50); Western blot) were developed for potential use as in vitro assays to monitor AdFMD vaccine lot-to-lot consistency and other potential applications. These results demonstrate the feasibility of using a traditional modified-live vaccine virus infectivity assay in combination with a set of physiochemical and immunochemical tests to build a vaccine product profile that will ensure the each AdFMD vaccine lot released is similar to a reference vaccine of proven clinical safety and efficacy.

Pathogenicity and molecular characterization of emerging porcine reproductive and respiratory syndrome virus in Vietnam in 2007

In 2007, Vietnam experienced swine disease outbreaks causing clinical signs similar to the 'porcine high fever disease' that occurred in China during 2006. Analysis of diagnostic samples from the disease outbreaks in Vietnam identified porcine reproductive and respiratory syndrome virus (PRRSV) and porcine circovirus type 2 (PCV-2). Additionally, Escherichia coli and Streptococcus equi subspecies zooepidemicus were cultured from lung and spleen, and Streptococcus suis from one spleen sample. Genetic characterization of the Vietnamese PRRSV isolates revealed that this virus belongs to the North American genotype (type 2) with a high nucleotide identity to the recently reported Chinese strains. Amino acid sequence in the nsp2 region revealed 95.7-99.4% identity to Chinese strain HUN4, 68-69% identity to strain VR-2332 and 58-59% identity to strain MN184. A partial deletion in the nsp2 gene was detected; however, this deletion did not appear to enhance the virus pathogenicity in the inoculated pigs. Animal inoculation studies were conducted to determine the pathogenicity of PRRSV and to identify other possible agents present in the original specimens. Pigs inoculated with PRRSV alone and their contacts showed persistent fever, and two of five pigs developed cough, neurological signs and swollen joints. Necropsy examination showed mild to moderate bronchopneumonia, enlarged lymph nodes, fibrinous pericarditis and polyarthritis. PRRSV was re-isolated from blood and tissues of the inoculated and contact pigs. Pigs inoculated with lung and spleen tissue homogenates from sick pigs from Vietnam developed high fever, septicaemia, and died acutely within 72 h, while their contact pigs showed no clinical signs throughout the experiment. Streptococcus equi subspecies zooepidemicus was cultured, and PRRSV was re-isolated only from the inoculated pigs. Results suggest that the cause of the swine deaths in Vietnam is a multifactorial syndrome with PRRSV as a major factor.

Inactivation of viruses by aziridines

Ethyleneimine (EI) and N-acetylethyleneimine (AEI) have been shown to inactivate viruses belonging to most of the families described by the International Committee for the Taxonomy of Viruses. The mechanism by which they inactivate the viruses has not been established. In this paper, experiments with foot-and-mouth disease virus (FMDV) and poliovirus are described which indicate that the inactivating lesion is on the RNA.

Epizootic vesicular disease in captive California sea lions

An epizootic of vesicular disease occurred in a group of semi-domesticated California sea lions (Zalophus californianus) during the months of April and May 1997. Ten castrated mature male sea lions, ages 12 to 19 yr, were housed in three adjacent open-ocean net enclosures in San Diego Bay (California, USA). Four animals (40%) developed oral and extremity vesicles, anorexia, and were reluctant to perform learned behaviors. One animal developed vesicles but maintained a normal appetite and behavior. The remaining animals showed no clinical signs of infection. Virus (designated FADDL 7005) was isolated from four of the five animals that developed vesicles. Serum antibody titers to FADDL 7005, a previously untyped calicivirus, were demonstrated in animals that showed any combination of clinical signs and in two animals that did not show any clinical signs. No virus was isolated from five fecal samples collected from four of the group animals. Clinical signs lasted 4 to 20 days in affected animals. All affected animals recovered from infection. An experimental swine was inoculated with FADDL 7005 and developed vesicular disease, which was transmitted to another experimental swine upon contact. It is proposed that FADDL 7005 is a new San Miguel sea lion virus.

Structural differences between foot-and-mouth disease and poliomyelitis viruses influence their inactivation by aziridines

Inactivation of foot-and-mouth disease virus (FMDV) and poliovirus by ethyleneimine (EI) and N-acetylethyleneimine (AEI) has been studied at 25 degrees and at 37 degrees C and in different ionic conditions. FMDV is inactivated rapidly in 100 mM Tris pH 7.6 by each reagent at both temperatures. Poliovirus is also inactivated rapidly in 100 mM Tris by EI at both temperatures and by AEI at 37 degrees C. However, it is inactivated much more slowly by AEI at 25 degrees C; but if the virus is first incubated overnight at 2 degrees C with AEI before transferring to 25 degrees C inactivation then proceeds rapidly. Moreover, the rate of inactivation at 25 degrees C is markedly increased if the virus is suspended in 1 mM Tris. We had interpreted these differences as being due to the greater penetrability of poliovirus (i) in 100 mM Tris at 37 degrees C compared with 25 degrees C and (ii) at lower ionic strength. This interpretation has been confirmed by electron microscopy of FMDV and poliovirus particles stained with phosphotungstic acid. At the elevated temperature, poliovirus had an average diameter of 34+/-0. 21 nm and the stain outlined the nucleic acid core and the individual subunits, whereas at 25 degrees C it averaged 28+/-0.13 nm and the stain did not penetrate the particle. This study also showed that the particle diameter alters with changes in buffer concentration, being 28+/-0.13 nm in 100 mM Tris, 31+/-0.16 nm in 10 mM Tris and 34+/-0.21 nm in 1 mM Tris. The changes in poliovirus are reversible as addition of 1/10 volume of 1 M Tris to the virus in 1 mM Tris resulted in the return of the diameter to 28+/-0.13 nm. FMDV, on the other hand, was less sensitive to osmotic differences as its particle diameter only varied by 7% over the 100-fold change in buffer concentration compared with the 22% change observed for poliovirus.

Strategy for producing new foot-and-mouth disease vaccines that display complex epitopes

Widely used inactivated vaccines for foot-and-mouth disease (FMD) induce protective immunity, but vaccine production plants and residual virus in the vaccine itself have been implicated in disease outbreaks. The structure of the FMD virion has been determined, and although much of the surface of the viral particle is produced by complex folding of the three surface-exposed capsid proteins (VP1-3), some surface regions representing important linear epitopes can be mimicked by recombinant proteins or synthetic peptides. Vaccine candidates based on these products stimulate immune responses to foot-and-mouth virus (FMDV), but do not always protect livestock from disease. The basis of protective immunity to FMDV has been explored using genetic engineering to produce antigenic chimeras of the virus. Studies with these chimeras have shown that a strong and protective immune response can be generated in livestock to epitopes outside the sequential epitopes incorporated into previous subunit vaccine candidates. Genetic engineering of the virus has also been used to demonstrate that changes within the sequence encoding an arginine-glycine-aspartic acid (RGD) sequence in VP1 abrogate virus binding to cells in culture, confirming the role of RGD as the receptor binding site. Based on this information, genetically stable viruses which cannot bind to cells have been created by deleting the nucleotides coding the RGD sequence. The receptor binding site-deleted viruses have been shown to be non-infectious in tissue culture, mice, and swine. Cattle vaccinated with these viruses are protected from disease when challenged with virulent FMDV, demonstrating that they could serve as the basis for safer FMD vaccines.

Structure and immunogenicity of experimental foot-and-mouth disease and poliomyelitis vaccines

The physico-chemical properties and immunogenicity of experimental vaccines against foot-and-mouth disease (FMD) and poliomyelitis, prepared by treatment of the viruses with N-acetylethyleneimine (AEI), formaldehyde or neutral red, have been studied. None of these reagents affects the rate of sedimentation of the particles or their reaction with antibody against the major immunogenic sites. FMD vaccines prepared by inactivation with AEI or neutral red, behaved like the untreated virus, in that they were disrupted on lowering the pH below 7. The RNA of the AEI-inactivated virus was degraded into slowly sedimenting molecules. Unlike AEI-inactivated virus, from which all the RNA could be extracted with phenol-SDS, the recovery from the neutral red inactivated virus was variable and was sometimes as low as 40%; this RNA gave a heterogenous profile in sucrose gradients. The capsid proteins in the AEI preparation migrated in SDS-PAGE to the same positions as those of untreated virus, but in the neutral red preparation there was evidence of cross-linking. In contrast, the formaldehyde-inactivated vaccine was stable below pH 7 and the RNA could not be released by extraction with phenol-SDS at pH 5, because the capsid proteins had become cross-linked and/or linked to the RNA. As with foot-and-mouth disease virus (FMDV), poliovirus which had been inactivated with formaldehyde did not release its RNA on extraction with phenol-SDS and the capsid proteins were also cross-linked. Surprisingly, although AEI cleaved the viral RNA slowly in situ, the virus was no longer infectious after 6 h. Neutral red did not reduce the infectivity of the virus. All of the preparations gave similar levels of neutralizing antibody after a single inoculation. The high levels obtained with the formaldehyde-inactivated vaccines have implications for the processing of fixed particles by the antigen-presenting cells.

African swine fever virus structural protein p72 contains a conformational neutralizing epitope

We have previously described a monoclonal antibody (mAb 135D4) to an unidentified 70- to 72-kDa African swine fever virus (ASFV) protein that exhibited high levels of neutralizing activity against various virulent ASFV isolates. Here, we identify the reactive ASFV protein as the major virus structural protein p72. In vitro-translated products of the p72 protein gene were specifically immunoprecipitated by mAb 135D4. Immunoprecipitation of a nested set of truncated p72 in vitro translation products defined the region between amino acid residues 400 and 404 as necessary for mAb 135D4 reactivity. Five partially overlapping peptides (15mers) covering residues 388-446 failed to react with mAb 135D4, suggesting the conformational dependence of the epitope. Supporting this interpretation, larger in vitro translation products representing residues 56-282, 159-361, 360-508, and 507-646 also failed to react with mAb 135D4. Consistent with its involvement in virus neutralization, immunoelectromicroscopy, using a rabbit antiserum against mAb 135D4-purified p72, located the protein on the surface of unenveloped virus particles.

Characterization of virulence variants of African horsesickness virus

There are three clinicopathologic syndromes associated with African horsesickness (AHS) virus infection in horses. These different forms of AHS (pulmonary, cardiac, and fever forms) vary in the organs affected, the severity of lesions, time of onset of clinical signs and mortality rates. We have studied the effects of infection with three cell culture passaged variants of AHS virus in naive North American horses. One of these viruses, AHS/4SP, consistently caused the pulmonary form of AHS with rapid onset of severe pulmonary edema and 100% mortality. A second variant, AHS/9PI, resulted in signs and lesions typical of the cardiac form of AHS: pericardial effusion, subendocardial hemorrhage and widespread subcutaneous edema. Mortality was approximately 70%. The third variant, AHS/4PI, produced mild to subclinical disease in horses, usually expressed only as transient mild fever. No mortality occurred in horses due to infection with AHS/4PI. All surviving infected animals did, however, seroconvert with both neutralizing and ELISA-reactive antibodies. The results of these studies indicate clearly that in naive horses the form of disease expressed is a property of the AHS virus inoculum.

Mice immunized with a subviral particle containing the Japanese encephalitis virus prM/M and E proteins are protected from lethal JEV infection

Extracellular subviral particles produced by HeLa cells infected with a recombinant vaccinia virus encoding the prM and E genes of Japanese encephalitis virus (JEV) were purified and characterized. These particles contained the JEV prM/M and E proteins embedded in a lipid bilayer, and RNA was not detected in particles using the polymerase chain reaction and primers recognizing a part of the JEV E gene. The particles were uniformly spherical with a 20-nm diameter and had 5-nm projections on their surface. Mice that received a single inoculation of the purified extracellular particles emulsified with Freund's complete adjuvant were fully protected against 4.9 x 10(5) LD50 of JEV. Comparison of the neutralizing and hemagglutination-inhibiting antibody titers and radioimmunoprecipitation data showed that immunization with the particles induced an immune response similar to that following inoculation with the recombinant vaccinia virus.

Persistent nonproductive infection of Epstein-Barr virus-transformed human B lymphocytes by human immunodeficiency virus type 1

We have studied the interaction of different strains of human immunodeficiency virus type 1 (HIV-1) with an Epstein-Barr virus-transformed human B-lymphocyte line, X50-7. Previously we found that some HIV-1 strains replicated rapidly and were exclusively cytolytic; others induced persistent noncytopathic infection associated with continued shedding of extracellular virus (K. Dahl, K. Martin, and G. Miller, J. Virol. 61:1602-1608, 1987). We now describe a third form of cell-virus relationship in which infection by strain IIIB is maintained in a highly cell-associated state in a small subpopulation (less than 2%) of X50-7 cells. Neither viral subcomponents nor infectious virus was detectable in culture supernatants; however, the carrier lines were fusogenic and HIV-1 could be recovered following prolonged cocultivation with susceptible cells. In these chronic carrier cultures, virions were not seen budding at the cell surface, but a few were found within cytoplasmic vesicles. HIV-1 infection of first- and second-generation cell subclones of the carrier cell line rapidly evolved from a productive to a cell-associated state. There were low levels of HIV DNA, and RNA in the fusogenic secondary clones, but most clones lacked HIV-1 DNA, failed to express HIV-1 RNA, and exhibited no properties associated with HIV-1 infection. The experiments indicate that HIV-1 can be sequestered in human B lymphocytes. The cell cloning experiments introduce the possibility that the HIV-1 provirus may be lost from some lymphocytes.

Host-parasite relationship of Leishmania mexicana mexicana and Lutzomyia abonnenci (Diptera: Psychodidae)

The life cycle of Leishmania mexicana mexicana in the gut of the sand fly, Lutzomyia abonnenci, was studied by light and electron microscopy. Development was suprapylarian with initial establishment of parasites in the bloodmeal (posterior midgut), and anterior migration of parasites to the cardia/stomodeal valve region beginning at 2.5 days post-infection. Flagellates were first observed in the esophagus at 3.5 days, in the posterior armature region of the pharynx at 5 days, and in the anterior pharynx at 7 days; but they were not detected in the cibarium or proboscis. Infection of the pylorus region of the hindgut and of the Malpighian tubules was also commonly observed. Three different morphological forms of L. m. mexicana developed in the gut: nectomonad promastigotes, short promastigotes, and paramastigotes. Nectomonads occurred primarily in the abdominal midgut after bloodmeal digestion, where they were oriented in longitudinal masses in the lumen, or interdigitated with epithelial microvilli via the flagellum. Short promastigotes found in the cardia/stomodeal valve region are described for the first time. These forms were smaller than nectomonads, showed an amplification of the kinetoplast, apposition of kinetoplast and nucleus, and were embedded in a gel-like matrix. To maintain position in the cardia, parasites commonly inserted the flagellum deep into microvilli or cytoplasm of the epithelium; adherence to the cuticular intima of the stomodeal valve was by flagellar modification and formation of hemidesmosome plaques. Paramastigotes occurred in the esophagus, were sometimes degenerated in appearance, and were attached via flagellar hemidesmosomes. Paramastigotes observed in the lumen of the pharynx were commonly degenerated and were not attached to the intima. L. m. mexicana was able to colonize the various gut habitats of Lu. abonnenci by a number of adaptations; this sand fly appears to be a suitable biological host for the parasite.