Classical swine fever virus marker vaccine strain CP7_E2alf: Shedding and dissemination studies in boars

Over the last decade, pestivirus chimaera CP7_E2alf has proven to be a most promising marker vaccine candidate against classical swine fever (CSF). To provide further background data for the risk assessment towards licensing and release, especially on presence of the vaccine chimaera in faeces, urine, and organs of the male reproductive tract, supplementary studies were carried out under controlled laboratory conditions. In detail, the shedding and dissemination pattern of Suvaxyn^® CSF Marker (“CP7_E2alf”) was assessed in 12 adult boars after single intramuscular vaccination with a tenfold vaccine dose. Four and seven days post vaccination, six animals were subjected to necropsy and triplicate samples were obtained from reproductive and lymphatic organs as well as urine, faeces, blood, and several additional organs and matrices. The sampling days were chosen based on pre-existing data that indicated the highest probability of virus detection. Upon vaccination, neither local nor systemic adverse effects were observed in the experimental animals. It was confirmed that primary replication is restricted to the lymphatic tissues and especially the tonsil. While viral genome was detectable in several samples from lymphatic tissues at four and seven days post vaccination, infectious virus was only demonstrated at four days post vaccination in one tonsil sample and one parotid lymphnode. Sporadic detection at a very low level occurred in some replicates of liver, lung, bone marrow, and salivary gland samples. In contrast, viral genome was not detected in any sample from reproductive organs and accessory sex glands, in faeces, urine, or bile.The presented data on the dissemination of the vaccine virus CP7_E2alf in adult boars are supplementing existing safety and efficacy studies and indicate that the use of the vaccine is also safe in reproductive boars.     

First assessment of classical swine fever marker vaccine candidate CP7_E2alf for oral immunization of wild boar under field conditions

Oral vaccination against classical swine fever (CSF) is a potent tool to control disease outbreaks in wild boar. So far, vaccination campaigns have been carried out using live attenuated vaccines that do not allow serological differentiation of infected from vaccinated animals (DIVA). Although this drawback is acceptable for wild boar, the use of marker vaccines would facilitate studies on disease and vaccination dynamics. Recently, the CSF marker vaccine candidate CP7_E2alf was assessed for oral immunization under laboratory conditions. Promising results prompted efforts to study the vaccine candidate under field conditions and in bait formulation. In this context, two oral vaccination campaigns were carried out with CP7_E2alf bait vaccines in two areas called ‘faunistic-hunting farms’ in the region of Umbria, Italy. One campaign was conducted using single vaccination, the second with the routinely employed double vaccination strategy. Both campaigns were carried out before concerted hunting actions were performed. Bait uptake, vaccine virus detection and antibody responses were assessed along with inspections upon gutting. As a comparator, seven wild boar were hand-fed with baits under laboratory conditions. In the field, bait uptake ranged from 63.7% to 98.7%, whereas antibody prevalence reached only 33.3–35.1%. The marker serology showed a strong influence of sample quality on the test outcome with a total of 85% of samples being classified correctly. Vaccine virus was not detectable. Under hand feeding conditions, six out of seven wild boar took up at least one bait, and five of them showed detectable antibody levels seven weeks after vaccination. These results were supplemented by stability tests. Appropriate stability of vaccine virus was shown both under field and laboratory conditions. In total, most results were in line with our expectations. However, optimization of the DIVA assay has to be attempted in the future.     

Innocuousness and safety of classical swine fever marker vaccine candidate CP7_E2alf in non-target and target species

Chimeric pestivirus CP7_E2alf is a promising live marker vaccine candidate against classical swine fever. Prior to a possible application in the field, several safety aspects have to be addressed. Due to the fact that CP7_E2alf is based on a bovine viral diarrhea virus backbone, its behavior in ruminants is of particular interest. In the framework of this study, its innocuousness in non-target species was addressed by inoculation of calves, young goats, lambs, and rabbits. To this means, high titres of CP7_E2alf were applied orally to three animals of each species. Additional animals were left as unvaccinated contact controls. During the study, all animals remained clinically healthy, and neither fever nor leukopenia were observed. Virus could not be isolated from purified white blood cells or from nasal or faecal excretions. Moreover, none of the animals (inoculated or contact control) seroconverted.In the target species, innocuousness, shedding and transmission of vaccine virus was addressed in different animal trials that were carried out primarily for the purpose of efficacy, potency or duration of immunity studies. In all experiments, CP7_E2alf proved to be completely safe for the vaccinees and unvaccinated contact controls. Furthermore, no shedding or transmission was detected in any of the experiments. Even after parental vaccination, vaccine virus genome was barely detectable in blood or organ samples of vaccinated animals. Thus, CP7_E2alf can be regarded as completely safe for both target and non-target species.     

Modified live marker vaccine candidate CP7_E2alf provides early onset of protection against lethal challenge infection with classical swine fever virus after both intramuscular and oral immunization

Due to the vast economic consequences of classical swine fever (CSF) outbreaks, emergency vaccination plans are under discussion in European Union Member States. However, animals vaccinated with the conventional C-strain vaccine are subject to trade restrictions. To ease these restrictions, potent marker vaccines are required. One promising candidate is the chimeric pestivirus CP7_E2alf. For emergency vaccination in a CSF outbreak scenario, early onset of immunity is required. Here, the studies performed with a CP7_E2alf virus stock produced under good manufacturing conditions (GMP) are reported. In challenge experiments, CP7_E2alf induced full clinical protection 1 week after intramuscular vaccination, and 2 weeks after oral immunization. Furthermore, even after application of diluted vaccine preparations complete protection could be achieved if challenge infection was carried out 4 weeks after vaccination. In conclusion, GMP-produced CP7_E2alf proved to be a suitable marker vaccine candidate – also for emergency vaccination – both after intramuscular and oral application.     

Efficacy of marker vaccine candidate CP7_E2alf in piglets with maternally derived C-strain antibodies

Marker vaccines offer the possibility to differentiate classical swine fever (CSF) infected from CSF vaccinated animals based on serology and their implementation will ensure free trade with pigs. Therefore, new generations of promising marker vaccines have been developed, among them the chimeric vaccine CP7_E2alf. However, in populations previously vaccinated with live attenuated vaccines like the C-strain, passive immunity through maternal antibodies can interfere with efficacy of CP7_E2alf vaccination. Therefore, the efficacy of CP7_E2alf was examined in piglets from sows vaccinated once intramuscularly with C-strain vaccine 4 weeks before farrowing. Thus, these piglets were vaccinated intramuscularly with CP7_E2alf at the age of 5 or 8 weeks. Subsequently, the piglets and their mock-vaccinated littermate controls were challenged 2 weeks post vaccination with highly virulent Classical swine fever virus (CSFV) strain “Koslov”.     

Diagnostic procedures after completion of oral immunisation against classical swine fever in wild boar

The purpose of this paper is to define diagnostic procedures for wild boar after the completion of oral immunisation against classical swine fever (CSF). Epidemiological analysis of CSF in wild boar in Germany demonstrated that it is vital to carry out virological investigations on all animals found dead, sick or involved in traffic accidents. In principle, this should ensure an effective and prompt diagnosis of CSF. In addition, a defined number of wild boar, especially young animals < or = 6 months old, should also be tested for CSF virus to guarantee a high confidence level in the virological monitoring. Which animals should be examined serologically depends on the age class investigated, the season in which vaccination was stopped and the period of time since completion of vaccination. Therefore, different serological procedures have been defined for different situations during the first three years after completion of oral immunisation.     

Classical swine fever (hog cholera) in wild boar in Europe

Classical swine fever (CSF) is of increasing concern in Europe where wild boar appear to play an important epidemiological role. In most parts of the continent, demographic trends are on the increase, due to improvement in game management. As a result of higher densities, populations become more susceptible to various infectious diseases, among which CSF is cause for particular concern. Wild boar do not appear to be a classic reservoir in most cases, but nevertheless may perpetuate foci of infection over the long term, constituting a real threat for the pig farming industry. Since the infection does not appear to spread easily in natural populations of free-ranging wild boars, control of the disease may be feasible. However, most of the appropriate measures, such as banning hunting, are not considered acceptable. Consequently, the expertise of wildlife disease specialists is required to help solve the problem when it occurs.     

Efficacy of Suvaxyn CSF Marker (CP7_E2alf) in the presence of pre-existing antibodies against Bovine viral diarrhea virus type 1

Classical swine fever (CSF) is still one of the most important viral diseases of pigs worldwide and outbreaks are notifiable to the OIE. The different control options also include (emergency) vaccination, preferably with a vaccine that allows differentiation of infected from vaccinated animals (DIVA principle). Recently, the chimeric pestivirus “CP7_E2alf” (Suvaxyn® CSF Marker, Zoetis) was licensed as live attenuated marker vaccine by the European Medicines Agency (EMA). In the context of risk assessments for an emergency vaccination scenario, the question has been raised whether pre-existing anti-pestivirus antibodies, especially against the vaccine backbone Bovine viral diarrhea virus type 1 (BVDV-1), would interfere with “CP7_E2alf” vaccination and the accompanying DIVA diagnostics.To answer this question, a vaccination-challenge-trial was conducted with Suvaxyn® CSF Marker and the “gold-standard” of live-modified CSF vaccines C-strain (RIEMSER® Schweinepestvakzine) as comparator. Pre-existing antibodies against BVDV-1 were provoked in a subset of animals through intramuscular inoculation of a recent field isolate from Germany (two injections with an interval of 2 weeks). Twenty-seven days after the first injection, intramuscular vaccination of pre-exposed and naïve animals with either “CP7_E2alf” or C-strain “Riems” was performed. Seven days later, all vaccinated animals and two additional controls were oro-nasally challenged with highly virulent CSF virus (CSFV) strain Koslov.It was demonstrated that pre-existing BVDV-1 antibodies do not impact on the efficacy of live attenuated vaccines against CSF. Both C-strain “Riems” and marker vaccine “CP7_E2alf” were able to confer full protection against highly virulent challenge seven days after vaccination. However, slight interference was seen with serological DIVA diagnostics accompanying the vaccination with CP7_E2alf. Amended sample preparation and combination of test systems was able to resolve most cases of false positive reactions. However, in such a co-infection scenario, optimization and embedding in a well-defined surveillance strategy is clearly needed.     

Chimeric (marker) C-strain viruses induce clinical protection against virulent classical swine fever virus (CSFV) and reduce transmission of CSFV between vaccinated pigs

Two live recombinant vaccines (Flc9 and Flc11) against classical swine fever (CSF) were evaluated for their capacity to reduce transmission of virulent CSF virus (CSFV) among vaccinated pigs. In Flc9 the 5' terminal half of the E2 gene of the C-strain, a CSFV vaccine strain, was exchanged with the homologous gene of the bovine viral diarrhoea virus (BVDV) strain 5250, the E(rns) gene was exchanged likewise in the chimeric Flc11 virus. Both recombinant vaccines induce an antibody response in pigs that can be distinguished from that induced after a wild-type CSFV infection. Four experiments were performed to estimate the reproduction ratio R after different vaccination-challenge intervals. Each group consisted of ten pigs [specified pathogen free (SPF) pigs or conventional pigs] that were vaccinated once, intramuscularly, either with Flc9 or Flc11 virus or that were not vaccinated. Vaccinated and susceptible pigs were challenged intranasally with the virulent CSFV strain Brescia or Behring, 1, 2 or 4 weeks after vaccination. Whether contact-pigs became infected was determined using a CSFV specific E2 (Flc9) or E(rns) (FLc11) antibody ELISA. In the unvaccinated control groups, virus secretion started from day 2 to 4 after inoculation and all contact pigs became infected. Contact pigs became infected in the group of pigs (SPF or conventional) vaccinated once with Flc9 virus and challenged 1-, 2- or 4-weeks later. The estimates of the R in the groups challenged at 1-, 2- and 4-weeks after vaccination were 0.38, 0 and 0.75, respectively. Contact infected pigs were not detected (R=0) in any of the groups of pigs, vaccinated with Flc11, only SPF pigs were used. In order to achieve a statistical significance of R within the vaccinated groups each of the experiments has to be repeated at least once. The R of pigs vaccinated with Flc11 virus and challenged at 1- or 2-weeks after vaccination was however significantly lower that the reproduction ratio of the unvaccinated groups (P=0.013). The R of pigs vaccinated with Flc9 virus and challenged at 1 (conventional pigs) or 2 weeks (SPF pigs) after vaccination was significantly lower that the reproduction ratio of the unvaccinated groups (P=0.013). In conclusion, both chimeric viruses Flc9 and Flc11 provided good clinical protection against a challenge with virulent CSFV at 1 or 2 weeks after vaccination. Further experiments should be carried out to study more aspects of the efficacy of these recombinant viruses before they can be used as a marker vaccine under field circumstances.     

An experimental marker vaccine and accompanying serological diagnostic test both based on envelope glycoprotein E2 of classical swine fever virus (CSFV)

Envelope glycoprotein E2 is the most immunogenic protein of classical swine fever virus (CSFV). In a proposed model of the antigenic structure of E2, the N-terminal half of E2 forms two independent structural antigenic units, A and BC. E2 without transmembrane region (E2-TMR) is expressed and secreted into the medium of insect cells by use of the baculovirus expression system. The immune response induced by E2 protects pigs against CSFV. Recently, we showed that the protective immune response to a homologous CSFV challenge can be induced by a single unit, A or BC, of E2. An indirect blocking ELISA, or complex trapping blocking assay (CTB) based on both units is routinely used worldwide for serological diagnosis of CSFV infections. Here we show that E2-TMR is secreted into the medium as a homodimer. This E2 homodimer was used to develop a CTB detecting antibodies directed against one immunogenic unit of E2. Thus, the protective immune response induced by E2 containing one unit was not detected with a modified CTB based on the other unit, whereas immune responses induced by a variety of low virulent CSFV strains were detected with such a modified CTB. These results indicate that a deletion E2 protein in combination with a modified CTB are feasible as CSF marker vaccine and accompanying differentiating diagnostic test.     

Efficient priming against classical swine fever with a safe glycoprotein E2 expressing Orf virus recombinant (ORFV VrV-E2)

An increasing demand in livestock animal husbandry for intervention or emergency vaccination strategies requires a rapid onset of protection linked to prevention of infectious agent spread. Using the new recombinant parapoxvirus (PPV) Orf virus (ORFV) as a vaccine expressing the CSFV E2 glycoprotein we demonstrate that a single intra-muscular application confers solid protection. In the prime only concept, multi-site application of the vector vaccine turned out to be superior to single-site application as no pyrexia occurred after virulent CSFV challenge and CSFV neutralizing serum antibodies regularly were detectable before challenge. Vector virus vaccinated swine were able to cope with the lymphocyte and in particular B-cell depression in peripheral blood after challenge showing no clinical signs and no viremia. Early after challenge CSFV-specific IFN gamma production (IFN-gamma) and high neutralizing serum antibody titers clearly differentiated na?ve from vaccinated and protected animals. After CSFV challenge neutralizing serum antibodies titers in vector vaccinated swine were significantly higher than those in sera from live attenuated vaccine primed animals. Horizontal challenge virus transmission was prevented under strict sentinel isolation before mingling but not in next-door stables separated by a wooden barrier at the day of challenge. The presence of CSFV-specific pre-challenge serum antibodies although in low titers is a good prognostic parameter for solid protection after ORFV vector vaccination even when a significant CSFV-specific IFN-gamma production was not detectable before challenge. A heterologous prime-boost regimen as a combination of prime with baculovirus-expressed glycoprotein E2 followed by boost with the parapoxvirus vector turned out to be a better immune stimulant than a homologous prime/boost with the modified live CSFV vaccine. A similar beneficial effect became evident when the challenge infection mimicked the booster vaccination after a single PPV vector prime.     

Experimental non-transmissible marker vaccines for classical swine fever (CSF) by trans-complementation of E(rns) or E2 of CSFV

Three mutants with deletions in the E2 gene of the infectious DNA copy of the classical swine fever virus (CSFV) strain-C were constructed: one missing the B/C domain of CSFV-E2 between amino acids (aa) 693 and 746, one missing the A domain between aa 800 and 864, and one missing the complete E2 between aa 689 and 1062. All three CSFV-E2 deletion mutants were unable to generate viable virus, indicating that each of the antigenic domains of E2 is essential for viability of CSFV. To rescue the CSFV-E2 deletion mutants SK6 cell lines constitutively expressing glycoprotein E2 of CSFV were generated. The rescued viruses infected and replicated in SK6 cells as demonstrated by expression of viral proteins, but this primary infection did not result in reproduction of infectious virus. Thus, these E2 complemented viruses are considered non-transmissible. In previous experiments, we showed that simultaneous injection of E(rns) complemented virus (Flc23) via intradermal (ID), intramuscular (IM) or intranasal (IN) routes conferred protection to pigs against a lethal challenge with CSFV [J. Virol. 74 (2000) 2973]. Here, we evaluate different routes of application (ID, IM or IN) with E(rns) complemented virus Flc23 in order to find the best route for complemented CSFVs. Intradermal injection with Flc23 protected pigs against a lethal CSFV challenge, whereas intramuscular injection induced partial protection, and intranasal injection did not mediate a protective immune response in pigs at all. We used the intradermal route of vaccination to test the E2 complemented viruses. Vaccination of pigs via the intradermal route with the E2 complemented CSFVs also resulted in the induction of antibodies and in (partial) protection against CSFV challenge. Pigs vaccinated with E2 complemented virus Flc4 (deletion B/C domain) survived a lethal CSFV challenge, whereas partial protection was induced in pigs vaccinated with Flc47 (deletion E2) or Flc48 (deletion A domain) E2 complemented viruses. Serological data demonstrate that these E2 complemented mutant viruses are, in combination with well known diagnostic tests based on E2, potential marker vaccines for CSF.     

Development of an oral vaccine for immunisation of rainbow trout (Oncorhynchus mykiss) against viral haemorrhagic septicaemia

In the European Union Viral Haemorrhagic Septicaemia (VHS) eradication is still based on stamping out. Due to the lack of effective low cost vaccines immune prophylaxis is currently not used to combat VHS. This paper describes a new oral delivery method for immunisation of trout with attenuated virus. The vaccine consists of lyophilised virus surrounded by polyethylene glycol (PEG) and was extruded under low temperature. In the stomach of trout, the use of additional neutralising and adsorbing bases resulted in a neutral pH around the vaccine pellets, thus protecting the antigen against gastric acid. The in vivo efficacy of this delivery method was examined in three animal challenge experiments using an attenuated VHS virus (VHSV) strain as a vaccine. After vaccination, VHSV mRNA in gut, heart, kidney, spleen and blood was amplified by semi-nested PCR after RT-PCR. Indirect immune fluorescence test detected VHS vaccine virus in the gut. The expression of MHC class II, CD4 and CD8alpha mRNAs after oral vaccination was measured in gut using real-time RT-PCR. Antibody levels were measured by ELISA one week before vaccination and five weeks after vaccination. Animals were challenged six weeks after vaccination with highly virulent VHSV and mortality was recorded. The experiments showed that orally delivered vaccine virus was released from the vaccine preparation, penetrated the gut mucosa and led to higher expression levels of MHC class II and CD4 mRNAs when compared to control guts. VHSV antibodies were detected after oral vaccination. Immunisation with this new vaccine formulation was followed by a significant protection against VHSV. While the cumulative mortality in the non-vaccinated control group reached 70%, more than 75% of the orally vaccinated fish were protected upon challenge.     

Vaccination with a single dose of a recombinant porcine adenovirus expressing the classical swine fever virus gp55 (E2) gene protects pigs against classical swine fever

A recombinant porcine adenovirus (rPAV) with the gp55 (E2) gene from the classical swine fever virus (CSFV) 'Weybridge' strain inserted into the right hand end of the PAV serotype 3 (PAV3) genome was constructed. Expression of gp55 was directed by the major late promoter and tri-partite leader sequences located and cloned from PAV3. No compensatory deletions of PAV DNA sequences were made. Vaccination of outbred pigs with a single dose of the recombinant virus (rPAV-gp55) resulted in complete protection from lethal challenge with CSFV. No adverse clinical signs were observed in vaccinated animals following administration of rPAV-gp55 and following challenge, no clinical signs of CSF were observed prior to, or at, post mortem. The insert made into the rPAV increased the genome length to 106.8% of wild type and therefore exceeded the expected maximum insert size for a stable recombinant by almost 2%. Thus rPAV-gp55 contains the largest stable insertion made into a non-deleted Mastadeno virus recombinant so far reported.     

Chimeric classical swine fever viruses containing envelope protein E(RNS) or E2 of bovine viral diarrhoea virus protect pigs against challenge with CSFV and induce a distinguishable antibody response

Three chimeric classical swine fever virus (CSFV)/bovine viral diarrhoea virus (BVDV) full-length DNA copies were constructed, based on the infectious DNA copy of the CSFV vaccine strain C. The antigenic region of E2 and/or the complete E(RNS) gene were replaced by the analogous sequence of BVDV II strain 5250. Viable chimeric virus Flc11, in which E(RNS) was replaced, was directly recovered from supernatant of SK6.T7 cells transfected with full-length DNA. Viable chimeric virus Flc9, in which E2 was replaced, resulted in recovery of virus only when SK6.T7 transfected cells were maintained for several passages. However, no virus could be recovered after replacement of both E(RNS) and E2, even after 10 cell passages. Both Flc9 and Flc11 grow in swine kidney cells (SK6), stably maintain their heterologous BVDV sequences and, as assessed by monoclonal antibody typing and radio-immunoprecipitation assays, express their heterologous proteins. Flc9 showed a slower growth rate on SK6 cells than Flc11 and wild-type Flc2 virus. Replacement of E(RNS) or E2 of C-strain-based chimeric viruses did not alter cell tropism compared to wild-type C-strain virus for SK6 and FBE cells. Both Flc9 and Flc11 induced E2 or E(RNS) antibodies, which could be discriminated from those induced after wild-type virus infection, even after repeated vaccination. Furthermore, pigs were completely protected against a lethal CSFV challenge. These results indicate the feasibility of introduction of marker antigens in a live-attenuated marker C-strain vaccine for CSFV.     

Recombinant classical swine fever (CSF) viruses derived from the Chinese vaccine strain (C-strain) of CSF virus retain their avirulent and immunogenic characteristics

Two recombinant classical swine fever (CSF) viruses (Flc2, Flc3) transcribed from a DNA copy of the genome of the Chinese (C) strain, a CSF virus vaccine strain, were characterized in vivo in rabbits and pigs. Rabbits were inoculated intravenously with Flc2 or Flc3, the parent C-strain virus, a biologically cloned C-strain or CSF virus strain Brescia (C.1.1.1). After 24-96 h fever was detected in the rabbits inoculated with the different C-strain viruses. Apart from those in the control group, all the C-strain inoculated rabbits had developed CSF virus neutralizing antibodies 4 weeks later and were protected against a parent C-strain challenge. In the second experiment, pigs were inoculated with the parent C-strain or recombinant C-strain virus (Flc2 or Flc3) and then challenged after 4 weeks with the virulent CSF virus strain Brescia. None of the pigs showed clinical signs of classical swine fever after vaccination or challenge, whereas the control pigs developed clinical signs typical for acute CSF. Pigs inoculated with the different C-strain viruses were not viremic after inoculation or challenge, and CSF virus neutralizing antibodies were detected from day 14 onwards. The results from both experiments demonstrated that the two recombinant viruses had retained the biological and immunogenic properties of the parent C-strain in rabbits and pigs. We conclude that the full-length cDNA of the C-strain can serve as a matrix for further development of a live recombinant CSF virus marker vaccine.     

Vaccination-challenge studies with a Port Chalmers/73 (H3N2)-based swine influenza virus vaccine: Reflections on vaccine strain updates and on the vaccine potency test

The human A/Port Chalmers/1/73 (H3N2) influenza virus strain, the supposed ancestor of European H3N2 swine influenza viruses (SIVs), was used in most commercial SIV vaccines in Europe until recently. If manufacturers want to update vaccine strains, they have to perform laborious intratracheal (IT) challenge experiments and demonstrate reduced virus titres in the lungs of vaccinated pigs. We aimed to examine (a) the ability of a Port Chalmers/73-based commercial vaccine to induce cross-protection against a contemporary European H3N2 SIV and serologic cross-reaction against H3N2 SIVs from Europe and North America and (b) the validity of intranasal (IN) challenge and virus titrations of nasal swabs as alternatives for IT challenge and titrations of lung tissue in vaccine potency tests. Pigs were vaccinated with Suvaxyn Flu^® and challenged by the IT or IN route with sw/Gent/172/08. Post-vaccination sera were examined in haemagglutination-inhibition assays against vaccine and challenge strains and additional H3N2 SIVs from Europe and North America, including an H3N2 variant virus. Tissues of the respiratory tract and nasal swabs were collected 3 days post challenge (DPCh) and from 0–7 DPCh, respectively, and examined by virus titration. Two vaccinations consistently induced cross-reactive antibodies against European H3N2 SIVs from 1998–2012, but minimal or undetectable antibody titres against North American viruses. Challenge virus titres in the lungs, trachea and nasal mucosa of the vaccinated pigs were significantly reduced after both IT and IN challenge. Yet the reduction of virus titres and nasal shedding was greater after IT challenge. The Port Chalmers/73-based vaccine still offered protection against a European H3N2 SIV isolated 35 years later and with only 86.9% amino acid homology in its HA1, but it is unlikely to protect against H3N2 SIVs that are endemic in North America. We use our data to reflect on vaccine strain updates and on the vaccine potency test.     

A foot-and-mouth disease SAT2 vaccine protects swine against experimental challenge with a homologous virus strain,irrespective of mild pathogenicity in this species

FMDV serotype SAT2 is most frequently associated with outbreaks in ruminants. However, the risk of it spreading from cattle to pigs cannot be excluded. To assess the efficacy of an SAT2-type FMD inactivated vaccine against homologous challenge in pigs, a suitable challenge strain adapted to pigs was produced. After two passages in two pigs each, a FMDV stock of SAT2 challenge strain was produced. This material was used to infect two groups of five pigs. The first group being vaccinated 28 days before challenge and the other one left as an unvaccinated control. Clinical signs were recorded, virus shedding was assessed on mouth swabs, and neutralising antibody titres were determined. At least 80% of the vaccinated pigs were protected against clinical disease. Furthermore, no virus shedding was observed in any of the vaccinated pigs. This study shows that experimentally inoculated pigs can become infected with a SAT2 serotype. Furthermore, vaccination offers protection against generalisation and viral excretion, confirming the potential of vaccination as an important tool in the control of FMD in pigs.