Multi-antigenic recombinant subunit vaccine against Lawsonia intracellularis: The etiological agent of porcine proliferative enteropathy.

Proliferative enteropathy, caused by Lawsonia intracellularis, represents a threat for swine industry. Current vaccines are effective but difficult to obtain and scaled up, because of demanding bacterial culture conditions. In this work, a subunit vaccine candidate against L. intracellularis was developed and its efficacy was evaluated in vivo, alone or co-formulated with pig recombinant IFN-α. The vaccine formulation contains three chimeric antigens: two outer membrane proteins and a secreted one, which were engineered by adding T epitopes using bioinformatics tools. After simultaneously expressing the three antigens in E. coli, its immunogenicity was tested in mice and pigs. Antigens co-formulated with porcine IFN-α were also assayed in the last species. Immune response was assessed by ELISA and qPCR, and histopathological studies of intestinal epithelial tissue were performed after challenge. Mice and pigs showed an increased IgG response against chimeric antigens. Particularly, there were significant differences in the antibody response when porcine IFN-α was co-administrated with L. intracellularis antigens. Besides, mRNAs from il12 and cd4 marker were detected during the first week after immunization of pigs, suggesting a Th1-type cellular immune response. The significant enhancement of oas2 gene expression indicates the effect exerted by porcine IFN-α. Post-mortem histopathological analysis post-challenge revealed damage only into epithelial cells of the gastrointestinal tract from animals of the negative control group. Injuries were related to atrophy of the intestinal villi, where a decrease of globet cells and a greater migration of lymphocytes were observed. Overall, our results demonstrated that the vaccine candidate elicited significant humoral and cellular immune responses. Besides, histopathological analysis suggested that vaccinated animals were protected against experimental L. intracellularis infection. This research constitutes a step forward to the generation of the first recombinant chimeric vaccine against L. intracellularis, representing a faster, easier and cost effective approach to counteract the porcine proliferative enteropathy.

Effectiveness of the E2-classical swine fever virus recombinant vaccine produced and formulated within whey from genetically transformed goats.

Subunit recombinant vaccines against classical swine fever virus (CSFV) are a promising alternative to overcome practical and biosafety issues with inactivated vaccines. One of the strategies in evaluation under field conditions is the use of a new marker E2-based vaccine produced in the milk of adenovirally transduced goats. Previously we had demonstrated the efficacy of this antigen, which conferred early protection and long-lasting immunity in swine against CSFV infection. Here, we have used a simpler downstream process to obtain and formulate the recombinant E2 glycoprotein expressed in the mammary gland. The expression levels reached approximately 1.7 mg/ml, and instead of chromatographic separation of the antigen, we utilized a clarification process that eliminates the fat content, retains a minor amount of caseins, and includes an adenoviral inactivation step that improves the biosafety of the final formulation. In a vaccination and challenge experiment in swine, different doses of the E2 antigen contained within the clarified whey generated an effective immune response of neutralizing antibodies that protected all of the animals against a lethal challenge with CSFV. During the immunization and after challenge, the swine were monitored for adverse reactions related to the vaccine or symptoms of CSF, respectively. No adverse reactions or clinical signs of disease were observed in vaccinated animals, in which no replication of CSFV could be detected after challenge. Overall, we consider that the simplicity of the procedures proposed here is a further step toward the introduction and implementation of a commercial subunit vaccine against CSF.

Evaluation of the immune response against immature viral particles of infectious pancreatic necrosis virus (IPNV): a new model to develop an attenuated vaccine.

Infectious pancreatic necrosis virus (IPNV) is a worldwide problem affecting both freshwater and seawater fish. Vaccines developed against IPNV are not as efficient in the field as they are in tests. Moreover, research in the development of vaccines against IPNV has often shown that vaccines can stimulate the immune response of fish antibodies but do not protect efficiently against IPNV. In fact, sometimes dead infected fish show high antibody titers against IPNV. This suggests that the magnitude of total antibodies stimulated by the vaccine is not necessarily related to the level of protection against IPN, suggesting that a new method is needed to evaluate vaccine stimulation of the immune system. We propose in vitro evaluation of the non-specific cytotoxic cells (NCC) of the innate immune response, in addition to humoral specific response. Moreover, it is necessary to develop innovative methods to improve fish vaccines. In this work, IPNV replicative intermediaries (provirus) were used to inject rainbow trout fry, which is the most vulnerable state to IPNV. To evaluate the immune response triggered by this vaccine, NCC and total and neutralizing antibodies against IPNV and the provirus were determined. Results indicated that NCC activity in rainbow trout fry is triggered by IPNV infection. Both IPNV and the provirus stimulate humoral and NCC immune response in rainbow trout fry. Although the total antibodies triggered by the provirus were half of that triggered by IPNV infection, the number of neutralizing antibodies was similar in the two treatments. This suggests that the ratio of neutralizing antibodies is higher among the antibodies stimulated by provirons than among those stimulated by IPNV infection. Thus, immature provirus is sufficient to activate immune response and is a good candidate as an attenuated vaccine in rainbow trout fry. In addition, neutralizing antibodies, together with non-specific cytotoxic activity, are a more suitable strategy to evaluate new vaccines than humoral immune response alone.

Infectivity study of Streptococcus phocae to seven fish and mammalian cell lines by confocal microscopy.

Streptococcus phocae is a beta-haemolytic bacterium that causes systemic infections in Atlantic salmon, Salmo salar L., cultured in southern Chile and also in seals. In this study, the host-pathogen interaction between S. phocae and seven types of cell lines (fish and mammalian) was examined using an indirect fluorescent antibody and confocal microscopy (CM). Chinook salmon embryo (CHSE-214), epithelioma papulosum cyprini (EPC), salmon head kidney (SHK-1) and Atlantic salmon kidney were used as the fish cell lines, while human cervix epithelial adenocarcinoma (HeLa), African green monkey kidney fibroblast (Cos-7) and mouse leukaemic monocyte macrophage (Raw 264.7) were included as mammalian cell lines. Streptococcus phocae type strain ATCC 51973(T) and isolates LM-08-Sp and P23 were selected as representatives from the salmon and seal host, respectively. For the CM examination, monolayers seeded on round coverslips were studied at 2- and 20-h post-inoculation (pi). The results showed that there is no common infectivity pattern between the three S. phocae strains at 2-h pi and the cell lines tested, regardless of the source of isolation (seal or salmon). All S. phocae strains could internalize and were found inside the fish and mammalian cell cytoplasm after 20-h pi. Regardless of the cells studied (fish or mammal) and incubation (2 and 20 h), S. phocae was never observed inside the nuclei. Seal and salmon isolates showed the highest number of bacteria entering into the primate cell lines (HeLa and Cos-7) from 2-h pi, while ATCC 51973(T) was not found outside or inside the HeLa and Cos-7 cells.

Bioinformatic analysis of the genome of infectious salmon anemia virus associated with outbreaks with high mortality in Chile.

The infectious salmon anemia virus (ISAV), an orthomyxovirus, is the major cause of outbreaks of high mortality rates in salmon in Chile. It has been proposed that the virulence of ISAV isolates lies mainly in hemagglutinin-esterase and fusion glycoproteins. However, based on current information, the contribution of other viral genes cannot be ruled out. To study this, we isolated and determined the complete coding sequence of two high-prevalence Chilean isolates associated with outbreaks of high mortality rates: ISAV752_09 and ISAV901_09. These isolates were compared to 15 Norwegian isolates that exhibit differences in their virulence. For this purpose, we performed bioinformatic analyses of (i) functional domains, (ii) specific mutations, (iii) Bayesian phylogenetics, and (iv) structural comparisons between ISAV and influenza virus glycoproteins by using molecular modeling. Phylogenetic analysis shows two genogroups for each protein, one of them containing the Chilean isolates. The gene sequence of the polymerase complex and nucleoprotein indicated that they are closely related to homologues from highly pathogenic Norwegian viruses. Notably, seven of the eight mutations that are present only in the Chilean isolates are on the polymerase complex and nucleoprotein. Structural modeling of hemagglutinin-esterase shows patches of variable residues on its surface. Fusion protein modeling shows that insertions are flexible regions that could affect proteolytic processing, increasing either the accessibility or the number of recognition sites for specific proteases. We found antigenic drift processes related to insertion into the isolated segment 5 of the ISAV752_09. Our results confirm the European origin of Chilean isolates to be the result of reassortments from Norwegian ancestors.