CD4+ T-cell responses to foot-and-mouth disease virus in vaccinated cattle.

We have performed a series of studies to investigate the role of CD4(+) T-cells in the immune response to foot-and-mouth disease virus (FMDV) post-vaccination. Virus neutralizing antibody titres (VNT) in cattle vaccinated with killed FMD commercial vaccine were significantly reduced and class switching delayed as a consequence of rigorous in vivo CD4(+) T-cell depletion. Further studies were performed to examine whether the magnitude of T-cell proliferative responses correlated with the antibody responses. FMD vaccination was found to induce T-cell proliferative responses, with CD4(+) T-cells responding specifically to the FMDV antigen. In addition, gamma interferon (IFN-γ) was detected in the supernatant of FMDV antigen-stimulated PBMC and purified CD4(+) T-cells from vaccinated cattle. Similarly, intracellular IFN-γ could be detected specifically in purified CD4(+) T-cells after restimulation. It was not possible to correlate in vitro proliferative responses or IFN-γ production of PBMC with VNT, probably as a consequence of the induction of T-independent and T-dependent antibody responses and antigen non-specific T-cell responses. However, our studies demonstrate the importance of stimulating CD4(+) T-cell responses for the induction of optimum antibody responses to FMD-killed vaccines.

Assessment of T-dependent and T-independent immune responses in cattle using a B cell ELISPOT assay.

Understanding the mechanisms that maintain protective antibody levels after immunisation is important for vaccine design. In this study, we have determined the kinetics of plasma and memory B cells detectable in the blood of cattle immunised with model T-dependent or T-independent antigens. Immunisation with the T-D antigen resulted in an expansion of TNP-specific plasma cells post-TNP primary and booster immunisations, which was associated with increased titres of TNP-specific IgG antibodies. Although no TNP-specific memory B cells were detected in the T-D group following the primary immunisation, we detected an increase in the number of TNP-specific memory B cells post-TNP boost. In contrast, no TNP-specific plasma or memory B cells were detected after primary or secondary immunisation with the T-I antigen. We then investigated if immunisation with a third party antigen (tetanus toxin fragment C, TTC) would result in a bystander stimulation and increase the number of TNP-specific plasma and memory B cells in the T-D and/or T-I group. TTC immunisation in the T-D group resulted in a small increase in the number of TNP-specific plasma cells post-TTC primary immunisation and boost, and in an increase in the number of TNP-specific memory B cells post-TTC boost. This bystander effect was not observed in the animals previously immunised with the T-I antigen. In conclusion, the present study characterised for the first time the B cell response in cattle to immunisation with T-D and T-I antigens and showed that bystander stimulation of an established T-D B cell memory response may occur in cattle.

Immune responses in pigs vaccinated with adjuvanted and non-adjuvanted A(H1N1)pdm/09 influenza vaccines used in human immunization programmes.

Following the emergence and global spread of a novel H1N1 influenza virus in 2009, two A(H1N1)pdm/09 influenza vaccines produced from the A/California/07/09 H1N1 strain were selected and used for the national immunisation programme in the United Kingdom: an adjuvanted split virion vaccine and a non-adjuvanted whole virion vaccine. In this study, we assessed the immune responses generated in inbred large white pigs (Babraham line) following vaccination with these vaccines and after challenge with A(H1N1)pdm/09 virus three months post-vaccination. Both vaccines elicited strong antibody responses, which included high levels of influenza-specific IgG1 and haemagglutination inhibition titres to H1 virus. Immunisation with the adjuvanted split vaccine induced significantly higher interferon gamma production, increased frequency of interferon gamma-producing cells and proliferation of CD4(-)CD8(+) (cytotoxic) and CD4(+)CD8(+) (helper) T cells, after in vitro re-stimulation. Despite significant differences in the magnitude and breadth of immune responses in the two vaccinated and mock treated groups, similar quantities of viral RNA were detected from the nasal cavity in all pigs after live virus challenge. The present study provides support for the use of the pig as a valid experimental model for influenza infections in humans, including the assessment of protective efficacy of therapeutic interventions.

Bovine plasmacytoid dendritic cells are the major source of type I interferon in response to foot-and-mouth disease virus in vitro and in vivo.

Type I interferons (alpha/beta interferons [IFN-α/ß]) are the main innate cytokines that are able to induce a cellular antiviral state, thereby limiting viral replication and disease pathology. Plasmacytoid dendritic cells (pDCs) play a crucial role in the control of viral infections, especially in response to viruses that have evolved mechanisms to block the type I IFN signal transduction pathway. Using density gradient separation and cell sorting, we have highly enriched a population of bovine cells capable of producing high levels of biologically active type I IFN. These cells represented less than 0.1% of the total lymphocyte population in blood, pseudoafferent lymph, and lymph nodes. Phenotypic analysis identified these cells as bovine pDCs (CD3(-) CD14(-) CD21(-) CD11c(-) NK(-) TCRδ(-) CD4(+) MHC II(+) CD45RB(+) CD172a(+) CD32(+)). High levels of type I IFN were generated by these cells in vitro in response to Toll-like receptor 9 (TLR-9) agonist CpG and foot-and-mouth disease virus (FMDV) immune complexes. In contrast, immune complexes formed with UV-inactivated FMDV or FMDV empty capsids failed to elicit a type I IFN response. Depletion of CD4 cells in vivo resulted in levels of type I IFN in serum early during FMDV infection that were significantly lower than those for control animals. In conclusion, pDCs interacting with immune-complexed virus are the major source of type I interferon production during acute FMDV infection in cattle.

Hsp110-mediated enhancement of CD4+ T cell responses to the envelope glycoprotein of members of the family Flaviviridae in vitro does not occur in vivo.

The use of heat shock proteins (HSP) to enhance activation of the immune response to chaperoned antigen is being explored for immunotherapy. Hsp110 chaperones large protein substrates more effectively than Hsp70, offering the potential to use complex antigens containing multiple epitopes in HSP-based vaccines. In this study, we investigated the ability of recombinant bovine Hsp110 to chaperone E2 glycoprotein, the major envelope protein of bovine viral diarrhea virus (BVDV) and the dominant target of neutralizing antibodies. Hsp110 formed complexes with E2, as demonstrated by immunoprecipitation. When monocytes from BVDV-immunized cattle were stimulated with these complexes and incubated with autologous CD4(+) T cells, enhanced levels of proliferation were observed. To determine the ability of these complexes to improve immunogenicity in vivo, cattle were vaccinated with either Hsp110-E2 complex or E2 only, combined with Quil-A adjuvant. In contrast to the in vitro data, cellular and humoral responses to E2 were greater in the E2-only vaccination group, indicating that complex formation had actually reduced the immunogenicity of E2. This study highlights the need for further understanding of the means by which HSP complexes are endocytosed and processed in vivo to enable the design of successful vaccine strategies.

Longevity of protection in cattle following immunisation with emergency FMD A22 serotype vaccine from the UK strategic reserve.

To determine the longevity of protective immunity following a single administration of emergency vaccine, and establish whether the immune response could be enhanced by increasing the antigen payload even further, cattle were vaccinated with an A22 Iraq vaccine containing either 1x antigen payload (field dose) or 5x antigen payload. Six months post-immunisation all cattle received a homologous virus challenge. The magnitude of the virus neutralising antibody response elicited was consistent with the response to similarly formulated A serotype vaccines with a PD(50) greater than 32. All the vaccinated cattle, regardless of antigen payload, were protected from clinical disease following challenge although some cattle in both groups became sub-clinically infected. We conclude that immunisation with a single inoculation of vaccine from the UK emergency reserve can protect cattle from clinical disease for at least 6 months post-vaccination and that a boost may be unnecessary in an outbreak situation. Some animals may become sub-clinically infected but this is likely to be dependent on the severity of challenge. The study confirmed that a booster at 21 days post-vaccination was not necessary to maintain a cell-mediated response in cattle for 6 months. No increased benefits were recognised by increasing the antigen payload of this vaccine 5x.

A quantitative assessment of primary and secondary immune responses in cattle using a B cell ELISPOT assay.

The aim of the study was to build a comprehensive picture of the appearance in the blood stream of Ag-specific plasma cells and memory B cells in the bovine model. For this purpose, we have developed a method allowing the detection and quantification of both cell types within individual calves immunised with ovalbumin. During the primary response, we detected a burst of ovalbumin-specific plasma cells at days 6 and 7 post-immunisation, which was followed by the production of specific Ab, whereas a gradual increase of memory B cells was only detected from day 15. As expected, a boost immunisation performed 7 weeks later induced a quicker and stronger secondary response. Indeed, a burst of plasma cells was detected in the blood at days 3 and 4, which was followed by a strong increase in Ab titres. Furthermore, a burst of memory B cells, and not a gradual increase, was detected at days 5 and 6 post-boost immunisation. Importantly, we showed a strong correlation between the anti-ovalbumin-specific IgG titres detected 5 months after secondary immunisation and the plasma cell numbers detected in the blood at the peak response after secondary immunisation. The detection and quantification of plasma cells following an mmunisation/vaccination strategy could constitute a very effective means for predicting the magnitude and longevity of an Ab response.

Bovine viral diarrhea virus: prevention of persistent fetal infection by a combination of two mutations affecting Erns RNase and Npro protease.

Different genetically engineered mutants of bovine viral diarrhea virus (BVDV) were analyzed for the ability to establish infection in the fetuses of pregnant heifers. The virus mutants exhibited either a deletion of the overwhelming part of the genomic region coding for the N-terminal protease N(pro), a deletion of codon 349, which abrogates the RNase activity of the structural glycoprotein E(rns), or a combination of both mutations. Two months after infection of pregnant cattle with wild-type virus or either of the single mutants, the majority of the fetuses contained virus or were aborted or found dead in the uterus. In contrast, the double mutant was not recovered from fetal tissues after a similar challenge, and no dead fetuses were found. This result was verified with a nonrelated BVDV containing similar mutations. After intrauterine challenge with wild-type virus, mutated viruses, and cytopathogenic BVDV, all viruses could be detected in fetal tissue after 5, 7, and 14 days. Type 1 interferon (IFN) could be detected in fetal serum after challenge, except with wild-type noncytopathogenic BVDV. On days 7 and 14 after challenge, the largest quantities of IFN in fetal serum were induced by the N(pro) and RNase-negative double mutant virus. The longer duration of fetal infection with the double mutant resulted in abortion. Therefore, for the first time, we have demonstrated the essential role of both N(pro) and E(rns) RNase in blocking interferon induction and establishing persistent infection by a pestivirus in the natural host.

Isolation and purification of afferent lymph dendritic cells that drain the skin of cattle.

Dendritic cells (DCs) are central to the induction of immune responses and are a pivotal control point that determines the outcome of infectious challenge. Cannulation of afferent lymphatic vessels allows the isolation of large numbers of lymph DCs. First, lymph nodes that are draining the skin are surgically removed (takes approximately 1 h). Over a period of 6-8 weeks, afferent lymphatic vessels re-anastomose with the efferent duct, forming larger 'pseudoafferent' lymphatic vessels that can be surgically cannulated. Surgical cannulation takes 2 h to perform; daily maintenance of the catheter requires 30 min. Isolation of lymph cells requires 1 h and an additional 60-180 min to enrich or purify the DCs. The lymph can be harvested for up to 1 month, with relatively constant cell numbers and subset distribution throughout this period. This technique, although technically demanding, facilitates studies of DCs and other cells that traffic in the lymph in both the steady state and following antigenic exposure.