Immune Response and Partial Protection against Heterologous Foot-and-Mouth Disease Virus Induced by Dendrimer Peptides in Cattle.

Synthetic peptides mimicking protective B- and T-cell epitopes are good candidates for safer, more effective FMD vaccines. Nevertheless, previous studies of immunization with linear peptides showed that they failed to induce solid protection in cattle. Dendrimeric peptides displaying two or four copies of a peptide corresponding to the B-cell epitope VP1 [136-154] of type O FMDV (O/UKG/11/2001) linked through thioether bonds to a single copy of the T-cell epitope 3A [21-35] (termed B2T and B4T, resp.) afforded protection in vaccinated pigs. In this work, we show that dendrimeric peptides B2T and B4T can elicit specific humoral responses in cattle and confer partial protection against the challenge with a heterologous type O virus (O1/Campos/Bra/58). This protective response correlated with the induction of specific T-cells as well as with an anamnestic antibody response upon virus challenge, as shown by the detection of virus-specific antibody-secreting cells (ASC) in lymphoid tissues distal from the inoculation point.

Systemic Foot-and-Mouth Disease Vaccination in Cattle Promotes Specific Antibody-Secreting Cells at the Respiratory Tract and Triggers Local Anamnestic Responses upon Aerosol Infection.

UNLABELLED: Foot-and-mouth disease (FMD) is a highly contagious viral disease affecting biungulate species. Commercial vaccines, formulated with inactivated FMD virus (FMDV), are regularly used worldwide to control the disease. Here, we studied the generation of antibody responses in local lymphoid tissues along the respiratory system in vaccinated and further aerosol-infected cattle. Animals immunized with a high-payload monovalent FMD vaccine developed high titers of neutralizing antibodies at 7 days postvaccination (dpv), reaching a plateau at 29 dpv. FMDV-specific antibody-secreting cells (ASC), predominantly IgM, were evident at 7 dpv in the prescapular lymph node (LN) draining the vaccination site and in distal LN draining the respiratory mucosa, although in lower numbers. At 29 dpv, a significant switch to IgG1 was clear in prescapular LN, while FMDV-specific ASC were detected in all lymphoid tissues draining the respiratory tract, mostly as IgM-secreting cells. None of the animals (n = 10) exhibited FMD symptoms after oronasal challenge at 30 dpv. Three days postinfection, a large increase in ASC numbers and rapid isotype switches to IgG1 were observed, particularly in LN-draining virus replication sites already described. These results indicate for the first time that systemic FMD vaccination in cattle effectively promotes the presence of anti-FMDV ASC in lymphoid tissues associated with the respiratory system. Oronasal infection triggered an immune reaction compatible with a local anamnestic response upon contact with the replicating FMDV, suggesting that FMD vaccination induces the circulation of virus-specific B lymphocytes, including memory B cells that differentiate into ASC soon after contact with the infective virus. IMPORTANCE: Over recent decades, world animal health organizations as well as national sanitary authorities have supported the use of vaccination as an essential component of the official FMD control programs in both endemic and disease-free settings. Very few works studied the local immunity induced by FMD vaccines at the respiratory mucosa, and local responses induced in vaccinated animals after aerosol infection have not been described yet. In this work, we demonstrate for the first time that systemic FMD vaccination (i) induced the early presence of active antigen-specific ASC along the respiratory tract and (ii) prompted a rapid local antibody response in the respiratory mucosa, triggered upon oronasal challenge and congruent with a memory B-cell response. This information may help to understand novel aspects of protective responses induced by current FMD vaccines as well as to provide alternative parameters to establish protection efficiency for new vaccine developments.

Heterogeneity in the Antibody Response to Foot-and-Mouth Disease Primo-vaccinated Calves.

Foot-and-mouth disease (FMD) vaccines are routinely used as effective control tools in large regions worldwide and to limit outbreaks during epidemics. Vaccine-induced protection in cattle has been largely correlated with the FMD virus (FMDV)-specific antibodies. Genetic control of cattle immune adaptive responses has been demonstrated only for peptide antigens derived from FMDV structural proteins. Here, we quantify the heterogeneity in the antibody response of cattle primo-vaccinated against FMD and study its association with the genetic background in Holstein and Jersey sires. A total of 377 FMDV-seronegative calves (122 and 255 calves from 16 and 15 Holstein and Jersey sires, respectively) were included in the study. Samples were taken the day prior to primo-vaccination and 45 days post-vaccination (dpv). Animals received commercial tetravalent FMD single emulsion oil vaccines formulated with inactivated FMDV. Total FMDV-specific antibody responses were studied against three viral strains included in the vaccine, and antibody titres were determined by liquid-phase blocking ELISA. Three linear hierarchical mixed regression models, one for each strain, were formulated to assess the heterogeneity in the immune responses to vaccination. The dependent variables were the antibody titres induced against each FMDV strain at 45 dpv, whereas sire's 'breed' was included as a fixed effect, 'sire' was included as a random effect, and 'farm' was considered as a hierarchical factor to account for lack of independence of within herd measurements. A significant association was found between anti-FMDV antibody responses and sire's breed, with lower immune responses found in the Jersey sires' offspring compared with those from Holstein sires. No significant intrabreed variation was detected. In addition, farm management practices were similar in this study, and results of the serological assays were shown to be repeatable. It therefore seems plausible that differences in the immune response may be expected in the event of a mass vaccination campaigns.

Early adaptive immune responses in the respiratory tract of foot-and-mouth disease virus-infected cattle.

Foot-and-mouth disease (FMD) is a highly contagious viral disease which affects both domestic and wild biungulate species. This acute disease, caused by the FMD virus (FMDV), usually includes an active replication phase in the respiratory tract for up to 72 h postinfection, followed by hematogenous dissemination and vesicular lesions at oral and foot epithelia. The role of the early local adaptive immunity of the host in the outcome of the infection is not well understood. Here we report the kinetics of appearance of FMDV-specific antibody-secreting cells (ASC) in lymphoid organs along the respiratory tract and the spleen in cattle infected by aerosol exposure. While no responses were observed for up to 3 days postinfection (dpi), all animals developed FMDV-ASC in all the lymphoid organs studied at 4 dpi. Tracheobronchial lymph nodes were the most reactive organs at this time, and IgM was the predominant isotype, followed by IgG1. Numbers of FMDV-ASC were further augmented at 5 and 6 dpi, with an increasing prevalence in upper respiratory organs. Systemic antibody responses were slightly delayed compared with the local reaction. Also, IgM was the dominant isotype in serum at 5 dpi, coinciding with a sharp decrease of viral RNA detection in peripheral blood. These results indicate that following aerogenous administration, cattle develop a rapid and vigorous genuine local antibody response throughout the respiratory tract. Time course and isotype profiles indicate the presence of an efficient T cell-independent antibody response which drives the IgM-mediated virus clearance in cattle infected by FMDV aerosol exposure.

Enhancing DNA immunization by targeting ASFV antigens to SLA-II bearing cells.

One of the main criticisms to DNA vaccines is the poor immunogenicity that they confer on occasions, at least in large animals. Confirming this theory, immunization with plasmid DNA encoding two African swine fever virus genes in frame (pCMV-PQ), failed in inducing detectable immune responses in pigs, while it was successful in mice. Aiming to improve the immune responses induced in swine, a new plasmid was constructed, encoding the viral genes fused in frame with a single chain variable fragment of an antibody specific for a swine leukocyte antigen II (pCMV-APCH1PQ). Our results clearly demonstrate that targeting antigens to antigen professional cells exponentially enhanced the immune response induced in pigs, albeit that the DNA vaccine was not able to confer protection against lethal viral challenge. Indeed, a viremia exacerbation was observed in each of the pigs that received the pCMV-APCH1PQ plasmid, this correlating with the presence of non-neutralizing antibodies and antigen-specific SLA II-restricted T-cells. The implications of our discoveries for the development of future vaccines against African swine fever virus and other swine pathogens are discussed.

Detection and characterization of functional T-cell epitopes on the structural proteins VP2, VP3, and VP4 of foot and mouth disease virus O1 campos.

Foot and mouth disease virus (FMDV) is the cause of a widespread infectious disease affecting cloven-hoofed animals. It is controlled by vaccination with immune-inactivated virus grown in tissue culture. However, peptide vaccines represent a safer alternative to the current virus-inactivated immunogens. Their design requires the identification and evaluation of the sequences recognized by T- and B-lymphocytes. Four structural proteins, VP1, VP2, VP3, and VP4, comprise the viral capsid of the FMDV, but only VP1 has been extensively studied regarding the existence of relevant T-cell epitopes. Here, we utilize a murine model to present a functional T-cell epitope mapping on the complete sequences of VP2, VP3, and VP4 of FMDV O1 Campos. We used two in vitro assays to describe 13 amino acid sequences, each one of them including at least one T-cell epitope. The in vivo T-cell helper function of these sequences was studied in an adoptive cell-transfer assay in mice. Immunization experiments with a fusion peptide containing one of the sequences characterized were also done comparing the helper activity of this sequence with other T-cell epitopes included in the major immunogenic region of VP1.

A 10-amino-acid linear sequence of VP1 of foot and mouth disease virus containing B- and T-cell epitopes induces protection in mice.

The area of foot and mouth disease virus (FMDV) comprising residues 140 and 160 of capsid protein VP1 has been used extensively as an immunogen in natural and experimental hosts. A detailed epitope mapping of this region, however, has not been reported. For this purpose a synthetic peptide containing the residues 135 to 160 (p135-160) of VP1 of FMDV O1 Campos was analyzed for its T- and B-cell epitopes. The p135-160 is highly immunogenic, either by itself or coupled to a carrier protein (BSA), elicits a long-lasting neutralizing antibody response in mice, and provides solid protection against virulent challenge. By using a set of synthetic 10mer overlapping peptides, which cover the entire sequence 135-160 of VP1, we have shown that at least four discrete B epitopes are regularly distributed along the peptide. Although immunization with each of the 10mers coupled with BSA as a carrier protein induced peptide-specific antibody responses, individually none of the 10mers was able to induce neutralizing antibodies. However, anti-135-160 antibodies sorted by immunoaffinity chromatography using each of the 10mers revealed the existence of at least four discrete neutralizing sites: one spanning residues 135-144, at least two more between residues 140 and 154, and another in the region 150-160. Moreover, T-cell epitopes were identified, both by antigen-dependent proliferation assays and by adoptive cell transfer. By both methods, a T-cell epitope was located in the area comprising residues 135-144; the cell transfer experiment, which seems to be more sensitive, also identified a second T-cell epitope between residues 150 and 160. Interestingly, when the region 135-144, which contains both B- and T-cell epitopes, was in a tandem repeat configuration it induced a strong neutralizing antibody response in mice and solid protection against the challenge.

Avridine and LPS from Brucella ovis: effect on the memory induced by foot-and-mouth disease virus vaccination in mice.

Foot-and-mouth disease is one of the more economically important diseases among meat-producing biungulate species. In contrast to natural infection, current foot-and-mouth disease virus (FMDV) vaccines, prepared with inactivated virus and adjuvants, elicit short-lived protection. The immunomodulating effect on FMDV vaccines of avridine and lipopolysaccharide of Brucella ovis (LPS) was tested in a murine model. The duration of immunity, protection, stimulation of immunocompetent cells producing a long-lasting secondary response and immunoglobulin (Ig) isotypes were examined. The incorporation of either immunomodulator into aqueous and oil vaccines induced a long-lasting specific antibody response. The neutralizing titres and protection were significantly higher than those observed in animals immunized with control vaccines. Data collected from repopulation assays indicated that the immunomodulators used participate in the activation of immune cell populations involved in long-lasting memory. This resulted in an efficient B-cell secondary response even in the absence of T cells, which were necessary for the stimulatory effect of the immunomodulators in donor mice. Avridine and LPS stimulated IgG1, IgG2a and IgG2b production, which was correlated with the improvement of the protection induced by these vaccines.