Sequential study of antigen persistence and concomitant inflammatory reactions relative to side-effects and growth of Atlantic salmon (Salmo salar L.) following intraperitoneal injection with oil-adjuvanted vaccines

The persistence of antigens at the injection site (area around pyloric caeca and spleen), concomitant inflammatory reaction and granuloma development were monitored at 3, 6 and 12 months following intraperitoneal injection with multivalent, oil-adjuvanted vaccines in Atlantic salmon. Parallel assessment of side-effect profiles and growth rate were also performed. Antigen persistence was examined by use of a monoclonal antibody that recognises Aeromonas salmonicida lipopolysaccharide in an immunohistochemical method for in situ identification of bacteria or bacterial fragments. The inflammatory reaction was monitored using standard histological techniques. The amount of persistent antigens and size of inflammation/adhesions were estimated semi-quantitatively. A steady decrease in the quantity of antigens at the injection site was observed from 3 to 12 months. Antigens were consistently found in inflamed tissues located in the pancreatic region. The size of inflammation increased during the first 6 months but declined thereafter. These findings suggest that persistent antigens at the injection site may act as inflammatory stimulants that induce and perpetuate the inflammatory reaction, eventually leading to adverse side-effects.     

The contribution of Aeromonas salmonicida extracellular products to the induction of inflammation in Atlantic salmon (Salmo salar L.) following vaccination with oil-based vaccines

Intraperitoneal injection of Atlantic salmon with oil-based vaccines often results in severe side effects. Aeromonas salmonicida subspecies salmonicida, a primary antigen in the vaccines, produces extracellular products (ECPs) that are included in the formulation but the role of ECPs in inducing side effects is not well understood. In the present study, we evaluated the contribution of ECPs to early inflammatory reactions since early events determine the outcome of inflammation. Five groups of Atlantic salmon pre-smolts were injected intraperitoneally with one of the following preparations: (1) A. salmonicida water-in-oil (w/o) containing standard amounts of ECPs; (2) A. salmonicida (w/o) with ECPs concentrated five times; (3) A. salmonicida (w/o) without ECPs (ECPs were removed by washing and re-suspension of the bacteria prior to formulation); (4) w/o only (without antigens), and (5) physiological saline. Tissue sections of the injection site (pyloric caeca and surrounding areas) were collected at monthly intervals for 4 months in phosphate buffered formalin and processed for light microscopy. Computer-assisted microscopy with the help of Image Pro analysis program was used to measure the area of inflammation on H&E stained sections. Differential cell counts of leucocytes involved in the inflammatory reaction were also done based on morphology. Overall results show that fish injected with vaccines containing concentrated amounts of ECPs displayed a higher average area of inflammation compared to all other groups. In contrast, washed preparations induced mild reactions compared to vaccines containing either standard or concentrated ECPs. Mild, non-persistent reactions were observed in the group injected with oil adjuvant only. Neutrophils were persistent in inflammations induced by all preparations except w/o only. No inflammatory reactions were observed in the group injected with PBS. The results suggest that ECPs are pro-inflammatory in Atlantic salmon. It is anticipated that ECPs are more readily exposed to inflammatory cells than the bacterial cells themselves during early stages of inflammation because of their orientation at the water-oil interface. The results indicate that ECPs of A. salmonicida play an important role in the induction of early inflammatory reactions. It is also documented that the combination of antigens with oil adjuvants, and not the adjuvants alone, is the inducer of strong inflammatory reactions in Atlantic salmon.     

Concurrent injection of a rhabdovirus-specific DNA vaccine with a polyvalent,oil-adjuvanted vaccine delays the specific anti-viral immune response in Atlantic salmon,Salmo salar L.

Vaccines are commonly used in salmonid aquaculture as a method of disease prevention. Although there is a substantial amount of published research regarding the immunological and physiological effects following the injection of different polyvalent vaccines and DNA vaccines, there are no published reports examining the physiological and immunological effects of concurrent vaccine injection, which is the situation encountered in aquaculture. Using key immunological parameters such as lysozyme activity and specific antibody titres we examined the short-term activation of the immune response of cultured Atlantic salmon (Salmo salar L.) following concurrent injection with a traditional, polyvalent, oil-adjuvanted vaccine (AV) and an IHNV-specific DNA vaccine (DV). Our results indicate that different aspects of the innate and adaptive immune responses are influenced in either a positive or negative manner. While concurrent vaccine injection elicited an increase in lysozyme activity, changes in antibody titre (Ab) were antigen specific. The production of anti-Aeromonas salmonicida Abs was significantly greater in the combined vaccine group at 296 degree days post-vaccine injection (dd pvi), while the production of anti-Listonella anguillarum Abs was significantly greater at 106 dd pvi in the combined vaccine group. Of even greater interest was the apparent delay in production of IHNV-specific neutralizing antibodies (NAb) when the DV was injected concurrently with the polyvalent AV. The results indicated that concurrent injection of a polyvalent oil-AV and a DV can be beneficial to the production of antibodies; however, the specific anti-viral response may be delayed.     

The association between metabolic rate,immune parameters,and growth performance of rainbow trout,Oncorhynchus mykiss (Walbaum), following the injection of a DNA vaccine alone and concurrently with a polyvalent,oil-adjuvanted vaccine

This research demonstrates a significant increase in routine metabolic rate (RMR) following injection of a DNA vaccine concurrently with a polyvalent, oil-adjuvanted vaccine. The increase in RMR was transient and associated with increased activity of both the non-specific and specific immune responses. Rainbow trout (Oncorhynchus mykiss) were injected with a DNA vaccine (DV), a commercially available polyvalent, oil-adjuvanted vaccine (AV), or the two vaccines in combination and sampled at 203, 305, and 406 days (dd) post-vaccine injection (pvi) for RMR and key immune parameters (serum lysozyme activity, serum neutralization antibody titres). The RMR of fish that received both the DV and the AV was significantly higher at 203 dd pvi, compared to fish from all other treatment groups which included the control, the AV, and the DV groups. The increased RMR corresponded to elevated levels of serum lysozyme activity and an earlier seroconversion of virus-specific neutralizing antibodies. To determine if growth performance was affected by the transient increase in RMR, specific growth rate (SGR), percent daily weight gain (WG), and feed conversion ratio (FCR) were determined at 798, 1204, and 1610 dd pvi. Although fish in all three vaccine groups showed significant increases in SGR and WG at 798 and 1610 dd pvi compared to the control group, the overall weight of the fish was not different at the end of the experiment. In summary, this study shows that concurrent injection of a DV and an AV transiently increases the RMR of rainbow trout and changes the manner in which the immune response occurs, but does not affect the overall growth performance of the fish.     

Vaccination-induced systemic autoimmunity in farmed Atlantic salmon

Over half of the salmon consumed globally are farm-raised. The introduction of oil-adjuvanted vaccines into salmon aquaculture made large-scale production feasible by preventing infections. The vaccines that are given i.p. contain oil adjuvant such as mineral oil. However, in rodents, a single i.p. injection of adjuvant hydrocarbon oil induces lupus-like systemic autoimmune syndrome, characterized by autoantibodies, immune complex glomerulonephritis, and arthritis. In the present study, whether the farmed salmon that received oil-adjuvanted vaccine have autoimmune syndrome similar to adjuvant oil-injected rodents was examined. Sera and tissues were collected from vaccinated or unvaccinated Atlantic salmon (experimental, seven farms) and wild salmon. Autoantibodies (immunofluorescence, ELISA, and immunoprecipitation) and IgM levels (ELISA) in sera were measured. Kidneys and livers were examined for pathology. Autoantibodies were common in vaccinated fish vs unvaccinated controls and they reacted with salmon cells/Ags in addition to their reactivity with mammalian Ags. Diffuse nuclear/cytoplasmic staining was common in immunofluorescence but some had more specific patterns. Serum total IgM levels were also increased in vaccinated fish; however, the fold increase of autoantibodies was much more than that of total IgM. Sera from vaccinated fish immunoprecipitated ferritin and approximately 50% also reacted with other unique proteins. Thrombosis and granulomatous inflammation in liver, and immune-complex glomerulonephritis were common in vaccinated fish. Autoimmunity similar to the mouse model of adjuvant oil-induced lupus is common in vaccinated farmed Atlantic salmon. This may have a significant impact on production loss, disease of previously unknown etiology, and future strategies of vaccines and salmon farming.     

Specific and natural antibody response of cod juveniles vaccinated against Vibrio anguillarum

The purpose of the present study was to study specific and natural antibody levels in individual cod juveniles before and after being vaccinated against Vibrio anguillarum. Different vaccine preparations and vaccination regimes, i.e. bathing, dipping, i.p. injection or combination of treatments were employed and the performance of different groups to bath challenge by the bacterium tested. Antibody responses to V. anguillarum antigens in groups vaccinated by bathing and/or dipping were negligible, while responses were observed in i.p. injected fish. Fish receiving i.p. injection in addition to bathing, showed significant antibody response. Both groups showed increased levels of natural antibodies while levels were low in other groups. Fish bathed or dipped showed higher mortality when challenged than untreated fish, while fish that received a second vaccination showed the best protection. It was not ascertained whether there is a long term difference between the effects of immersion versus i.p. injection as a booster method. Levels of antibodies against V. anguillarum antigens or natural antibodies in groups with the lowest mortalities show that neither could have been used to predict protection given by the vaccines tested.     

Prostaglandin-induced regression of porcine corpora lutea maintained by estrogen.

Corpora lutea were marked with suture in 24 crossbred gilts on day 7 to 9 of the estrous cycle (first day of estrus equals 0). All gilts were injected with 5 mg of estradiol benzoate (EB) daily from day 10 to 15 to extend the lifespan of corpora tutea, then the gilts were randomly assigned to two groups. On day 20, the 12 gilts of Group 1 were injected with 10 mg PGF-2ALPHA, and the 12 gilts of Group 2 were injected with saline. Ovaries were recovered 10 to 13 days after PGF-2ALPHA or saline injection. Ten gilts in Group 1 displayed estrus 5 plus or minus 0.7 days after PGF-2ALPHA injection, but only two gilts in Group 2 displayed estrus during the experimental period. In gilts that displayed estrus, all marked CL had regressed. Marked CL were still present in all 12 gilts that failed to exhibit estrus during the experimental period. These results show that in the pig, PGF-2ALPHA caused regression of CL that were maintained beyond the normal luteal phase of the estrous cycel by EB treatment.     

Safety of intradermal injection of monosodium urate crystals as a vaccine carrier in volunteers

Monosodium urate (MSU) crystals are known to induce gouty arthritis, but also evoke specific cell immunity and work as an adjuvant by delivering several kinds of binding proteins, including idiotypic cancer vaccine peptides into dendritic cells. To investigate the potency of MSU crystals as a cancer vaccine carrier in vivo, this preclinical study examined whether intradermal injection of MSU crystals was safe for healthy adults. Subjects comprised 12 volunteers. Four different dose levels of MSU crystals were injected as follows: 2 μg (n = 3), 20 μg (n = 3), 200 μg (n = 3), or 2000?μg (n = 3). At 24 hours after administration, documented erythema was seen around the injection site in a dose-dependent manner, particularly in all adults with MSU dose ≥200 μg. However, redness was limited to the grade I level of the National Cancer Institute toxicity criteria. Serum uric acid levels did not show any change before and after injection. Moreover, neither gouty arthritis nor tophi developed in any volunteers, indicating that intradermal injection of MSU crystals did not induce systemic inflammation at the doses that evoked significant local inflammation. These findings suggest that intradermal injection of MSU crystals is fundamentally safe and should be made available for clinical trials using MSU-crystal-conjugated cancer vaccines.     

Multiple whole bacterial antigens in polyvalent vaccine may result in inhibition of specific responses in rainbow trout (Oncorhynchus mykiss)

The goal of fish vaccination today is to protect fish against multiple bacterial fish pathogens simultaneously using polyvalent vaccines. However, many immunological processes such as antigenic cross-reaction, antigenic competition, affinity maturation and antigen-induced suppression may affect the specificity, avidity and level of antibodies. Consequently, the biological function of antibodies may be markedly different from that predicted by conventional serologic tests. Here, we investigated the effects of vaccination and composition of vaccine on the plasma antibody levels, biological function of antibodies in opsonophagocytosis as well as the effects of vaccination on the blood leucocyte counts. Rainbow trout were vaccinated with saline or with two different polyvalent, mineral oil-adjuvanted vaccines. Vaccine 1 contained Aeromonas salmonicida, Listonella anguillarum and both Th and Fd serotypes of Flavobacterium psychrophilum antigens and vaccine 2 contained A. salmonicida, L. anguillarum and only Fd serotype of Fl. psychrophilum. The antibody-mediated opsonophagocytosis was determined as the respiratory burst (RB) activity of blood monocytes and granulocytes against the tested bacterial antigens. Three weeks after vaccination both vaccine groups and the control group showed increased RB activity against all bacterial strains. However, the increase in RB activities was non-specific and originated from the increased number of circulating granulocytes and monocytes. On the other hand, at 6 weeks post-vaccination both specific antibodies and antibody-dependent opsonophagocytosis appeared in both vaccine groups. However, the composition of the vaccine had a marked effect on the magnitude of specific responses. The Fd+Th vaccine enhanced the target specific opsonophagocytosis, to a lesser extent than the Fd vaccine. Both polyvalent vaccines appeared to mainly affect the numbers of circulating monocytes and our results suggest that the monocytes play a more significant role than the granulocytes in antibody-dependent opsonophagocytosis. Our results also suggest that the presented opsonophagocytic assay is an advantageous method to predict vaccine efficiency and that the number, and properties, of bacterial antigens in polyvalent vaccines should be carefully selected in order to avoid inhibitory effects of antigens on the specific response of fish.     

A sequential study of incomplete Freund's adjuvant-induced peritonitis in Atlantic cod

Development of diagnostic and prophylactic methodologies is dependent on knowledge of the host’s defence system and reaction to different vaccine adjuvants. Here we present a sequential morphological study of peritonitis and inflammatory cell processing of incomplete Freund’s adjuvant (IFA) in intraperitoneally injected Atlantic cod. The peritoneal tissue responses were characterised using necropsy, histology and electron microscopy. An extensive inflammatory response as characterised by leukocyte morphology and contents of enzymes, presence of apoptotic cells and IFN-γ-expressing cells was observed. Three days post injection, IFA droplets were surrounded by different types of inflammatory cells and two different patterns could be discerned. The first was characterised by flattened and concentrically arranged interdigitating cells connected by desmosomes and with macrophage-like cells (MLCs) predominant in the periphery. The second type possessed four stratified layers with an inner layer containing many apoptotic MLCs; a second layer containing flattened and shrunken cells and outer layers comprising moderately flattened cells and an outermost layer of mononuclear cells expressing IFN-γ. Oil was detected both inside and outside MLCs. The two types of processes, of which the second was clearly stratified, were similar to those observed in other teleosts, indicating a variety of reaction modes or alternatively sequential process development. The numerous dead MLCs contributed to inflammation.     

Polyclonal hypergammaglobulinemia and autoantibody production induced by vaccination in farmed Atlantic salmon

The introduction of oil-adjuvanted vaccines in salmon aquaculture made large-scale production feasible by reducing the impact of infections. Vaccines given intraperitoneally (ip) contain oil adjuvant such as mineral oil. However, in rodents, a single ip injection of adjuvant hydrocarbon oil induces lupus-like systemic autoimmune syndrome. We have recently reported that autoimmune disease in farmed salmon, characterized by production of various autoantibodies, immune complex glomerulonephritis, liver thrombosis, and spinal deformity, are previously unrecognized side effects of vaccination. In the present study, we examined whether vaccination-induced autoantibody production in farmed Atlantic salmon is a mere result of polyclonal B-cell activation. Sera were collected from 205 vaccinated and unvaccinated Atlantic salmon (experimental, 7 farms) and wild salmon. Total IgM levels and autoantibodies to salmon blood cell (SBC) extract in sera were measured by ELISA and the relationship between hypergammaglobulinemia and autoantibody production was analyzed. Comparison of endpoint titers vs levels/units using a single dilution of sera in detection of autoantibodies to SBC showed near perfect correlation, justifying the use of the latter for screening. Both total IgM and anti-SBC antibodies are increased in vaccinated salmon compared with unvaccinated controls, however, they do not always correlate well when compared between groups or between individuals, suggesting the involvement of antigen-specific mechanisms in the production of anti-SBC autoantibodies. The primary considerations of successful vaccine for aquaculture are cost-effectiveness and safety. Vaccination-induced autoimmunity in farmed Atlantic salmon may have consequences on future vaccine development and salmon farming strategy. Evaluation for polyclonal hypergamamglobulinemia and autoimmunity should be included as an important trait when vaccine efficacy and safety are evaluated in future.     

Immunogenicity and Cross Protective Ability of the Central VP2 Amino Acids of Infectious Pancreatic Necrosis Virus in Atlantic Salmon (Salmo salar L.)

Infectious pancreatic necrosis virus (IPNV) is a member of the family Birnaviridae that has been linked to high mortalities in juvenile salmonids and postsmolt stages of Atlantic salmon (Salmo salar L.) after transfer to seawater. IPN vaccines have been available for a long time but their efficacy has been variable. The reason for the varying immune response to these vaccines has not well defined and studies on the importance of using vaccine trains homologous to the virulent field strain has not been conclusive. In this study we prepared one vaccine identical to the virulent Norwegian Sp strain NVI-015 (NCBI: 379740) (T₂₁₇A₂₂₁T₂₄₇ of VP2) and three other vaccine strains developed using the same genomic backbone altered by reverse genetics at three residues yielding variants, T₂₁₇T₂₂₁T₂₄₇, P₂₁₇A₂₂₁A₂₄₇, P₂₁₇T₂₂₁A₂₄₇. These 4 strains, differing in these three positions only, were used as inactivated, oil-adjuvanted vaccines while two strains, T₂₁₇A₂₂₁T₂₄₇ and P₂₁₇T₂₂₁A₂₄₇, were used as live vaccines. The results show that these three residues of the VP2 capsid play a key role for immunogenicity of IPNV vaccines. The virulent strain for inactivated vaccines elicited the highest level of virus neutralization (VN) titers and ELISA antibodies. Interestingly, differences in immunogenicity were not reflected in differences in post challenge survival percentages (PCSP) for oil-adjuvanted, inactivated vaccines but clearly so for live vaccines (TAT and PTA). Further post challenge viral carrier state correlated inversely with VN titers at challenge for inactivated vaccines and prevalence of pathology in target organs inversely correlated with protection for live vaccines. Overall, our findings show that a few residues localized on the VP2-capsid are important for immunogenicity of IPNV vaccines.     

Augmentation of the Antibody Response of Atlantic Salmon by Oral Administration of Alginate-Encapsulated IPNV Antigens

The objective of the present study was to assess the effect of alginate-encapsulated infectious pancreatic necrosis virus antigens in inducing the immune response of Atlantic salmon as booster vaccines. One year after intraperitoneal injection with an oil-adjuvanted vaccine, post-smolts were orally boosted either by 1) alginate-encapsulated IPNV antigens (ENCAP); 2) soluble antigens (UNENCAP) or 3) untreated feed (control). This was done twice, seven weeks apart. Sampling was done twice, firstly at 7 weeks post 1^st oral boost and the 2^nd, at 4 weeks after the 2^nd oral boost. Samples included serum, head kidney, spleen and hindgut. Serum antibodies were analyzed by ELISA while tissues were used to assess the expression of IgM, IgT, CD4, GATA3, FOXP3, TGF-β and IL-10 genes by quantitative PCR. Compared to controls, fish fed with ENCAP had a significant increase (p<0.04) in serum antibodies following the 1^st boost but not after the 2^nd boost. This coincided with significant up-regulation of CD4 and GATA3 genes. In contrast, serum antibodies in the UNENCAP group decreased both after the 1^st and 2^nd oral boosts. This was associated with significant up-regulation of FOXP3, TGF-β and IL-10 genes. The expression of IgT was not induced in the hindgut after the 1^st oral boost but was significantly up-regulated following the 2^nd one. CD4 and GATA3 mRNA expressions exhibited a similar pattern to IgT in the hindgut. IgM mRNA expression on the other hand was not differentially regulated at any of the times examined. Our findings suggest that 1) Parenteral prime with oil-adjuvanted vaccines followed by oral boost with ENCAP results in augmentation of the systemic immune response; 2) Symmetrical prime and boost (mucosal) with ENCAP results in augmentation of mucosal immune response and 3) Symmetrical priming and boosting (mucosal) with soluble antigens results in the induction of systemic immune tolerance.     

Cell recruitment and cytokines in skin mice sensitized with the vaccine adjuvants: saponin, incomplete Freund's adjuvant, and monophosphoryl lipid A

Vaccine adjuvants are substances associated with antigens that are fundamental to the formation of an intense, durable, and fast immune response. In this context, the use of vaccine adjuvants to generate an effective cellular immune response is crucial for the design and development of vaccines against visceral leishmaniasis. The objective of this study was to evaluate innate inflammatory response induced by the vaccine adjuvants saponin (SAP), incomplete Freund's adjuvant (IFA), and monophosphoryl lipid A (MPL). After a single dose of adjuvant was injected into the skin of mice, we analyzed inflammatory reaction, selective cell migration, and cytokine production at the injection site, and inflammatory cell influx in the peripheral blood. We found that all vaccine adjuvants were able to promote cell recruitment to the site without tissue damage. In addition, they induced selective migration of neutrophils, macrophages, and lymphocytes. The influx of neutrophils was notable at 12 h in all groups, but at other time points it was most evident after inoculation with SAP. With regard to cytokines, the SAP led to production of interleukin (IL)-2, IL-6, and IL-4. IFA promoted production of tumor necrosis factor (TNF)-α, interferon (IFN)-γ, IL-6, IL-17, IL-4, and IL-10. We also observed that MPL induced high production of IL-2, TNF-α, and IFN-γ, in addition to IL-6, IL-17, and IL-10. In peripheral blood, values of certain cell populations in the local response changed after stimulation. Our data demonstrate that the three vaccine adjuvants stimulate the early events of innate immune response at the injection site, suggesting their ability to increase the immunogenicity of co-administered antigens. Moreover, this work provides relevant information about elements of innate and acquired immune response induced by vaccine adjuvants administered alone.     

Antigen uptake and immunoglobulin production in Atlantic cod (Gadus morhua L.) after intraperitoneal injection of Vibrio anguillarum

Atlantic cod (Gadus morhua L.) were injected intraperitoneally with formalin-killed Vibrio anguillarum bacteria. Immunostaining revealed uptake of V. anguillarum antigens especially in the spleen after intraperitoneal (i.p.) administration. The uptake was time dependent in the interval 1-24 h. Most of the antigen uptake in the spleen was concentrated in areas around small blood vessels, while immunoglobulin producing cells were localised to some thick walled arteries. There was apparently little or no co-localisation of antigens and antibody producing cells. In the heart, some of the high endocardial endothelial cells of the atrium contained bacterial antigens and in head kidney some macrophage-like cells were stained. Very little antigen was found in the pigmented loose connective tissues of the peritoneum. In contrast, endothelial cells of the underlying blood vessels contained substantial amounts. In the heart, peritoneum and anterior kidney the number of antigen positive cells did not seem to change in the time interval 1-24 h. After i.p. immunisation with a mixture of V. anguillarum and Freunds complete adjuvant, the humoral immune response in Atlantic cod was low when tested 21, 42 and 105 days later. There was apparently no enhanced number of immunoglobulin synthesising cells caused by the antigen stimulation.     

Viral and bacterial diseases of Atlantic cod Gadus morhua, their prophylaxis and treatment: a review

This review summarises the state of knowledge of both viral and bacterial diseases of Atlantic cod Gadus morhua, and their diagnosis, prophylaxis and treatment. The most important losses have been at the larval and juvenile stages, and vibriosis has long been the most important bacterial disease in cod, with Listonella (Vibrio) anguillarum dominant among pathogenic isolates. Vaccination of cod against pathogens such as L. anguillarum and Aeromonas salmonicida clearly demonstrates that the cod immune system possesses an effective memory and appropriate mechanisms sufficient for protection, at least against some diseases. Well-known viruses such as the nodavirus that causes viral encephalopathy and retinopathy (VER), infectious pancreatic necrosis virus (IPNV) and viral haemorrhagic septicaemia virus (VHSV) have been isolated from Atlantic cod and can be a potential problem under intensive rearing conditions. No commercial vaccines against nodavirus are currently available, whereas vaccines against IPNV infections based upon inactivated virus as well as IPNV recombinant antigens are available. A number of investigations of the pharmacokinetic properties of antibacterial agents in cod and their efficacy in treating bacterial infections have been reviewed.     

Vaccine-associated systemic Rhodococcus erythropolis infection in farmed atlantic salmon Salmo salar

In 7 instances between 2000 and 2003, clinical investigation of populations of fresh- and seawater-reared, vaccinated, Atlantic salmon Salmo salar suffering total losses of between 0.1 and 35 % revealed infection with a Gram-positive rod-shaped bacterium. The isolations were geographically widespread, occurring in both Norway and Scotland. In all cases, a Gram-positive bacterium, subsequently identified as Rhodococcus erythropolis, was isolated in pure culture. Infections, although systemic, were focused within the peritoneal cavity. While initial attempts to reproduce the disease by intraperitoneal injection of unvaccinated Atlantic salmon failed, Koch's postulates were subsequently fulfilled in fish vaccinated with a commercially available oil-adjuvanted vaccine.     

Vibriosis vaccines based on various sero-subgroups of Vibrio anguillarum O2 induce specific protection in Atlantic cod (Gadus morhua L.) juveniles

The purpose of this study was to investigate the efficacy of three monovalent and a trivalent vibriosis dip vaccines in juvenile Atlantic cod (Gadus morhua L.), examine whether the responses were specific and study the expression of selected immune genes after dip vaccination. In addition, the study addressed whether the deviating isolates of Vibrio anguillarum serotype O2 belongs to another sero-subgroup than the previously established sero-subgroups O2a, O2b and O2c. Rabbit V. anguillarum serotype O2 antiserum adsorbed with V. anguillarum O2a O-antigen was shown, by both ELISA and immunoblotting, to still contain serotype O2 specific antibodies. Cod V. anguillarum serotype O2 antiserum reacted only with isolate of homologous serotype and not with heterologous sero-subgroups. This indicates that the deviating V. anguillarum O2 isolates represent a new sero-subgroup differing from sero-subgroup O2a. The monovalent vaccines included formalin inactivated cultures of V. anguillarum sero-subgroup O2a, O2b or serotype O2, while the trivalent vaccine contained all three sero-subgroups. Cod mounted high protection 7 weeks post dip vaccination with monovalent vaccines when challenged with homologous isolates and significantly lower when challenged with heterologous isolates, regardless of sero-subgroups. The trivalent vaccine resulted in efficient protection against all sero-subgroups tested. Dip vaccination of cod juveniles did not result in detectable antibody production or alteration in gene expression of the heavy chain of IgM and IgD. In the trivalent vaccine group expression of IFNγ and IL-12p40 were significantly up-regulated 3 days post vaccination. However, in groups vaccinated against V. anguillarum sero-subgroups O2b or O2, IL-12p40 and IFNγ gene expression were slightly increased 3 and 55 days post vaccination, respectively.     

Naked DNA vaccination of Atlantic salmon Salmo salar against IHNV

A naked plasmid DNA encoding the glycoprotein (pCMV4-G) of a 1976 isolate of infectious hematopoietic necrosis virus (IHNV) obtained from steelhead Oncorhynchus mykiss was used to vaccinate Atlantic salmon Salmo salar against IHNV. Eight weeks post-vaccination the fish were challenged with a strain of IHNV originally isolated from farmed Atlantic salmon undergoing an epizootic. Fish injected with the glycoprotein-encoding plasmid were significantly (p < 0.05) protected against IHNV by both immersion and cohabitation challenge. Survivors of the first challenges were pooled and re-challenged by immersion 12 wk after the initial challenge. Significant (p < 0.05) protection was observed in all of the previously challenged groups including those receiving the complete vaccine. Fish injected with the glycoprotein-encoding plasmid produced low levels of virus-neutralizing antibodies prior to the first challenge. Neutralizing antibodies increased in all groups after exposure to the IHNV. Passive transfer of pooled sera from pCMV4-G vaccinates and IHN survivors provided relative survivals of 40 to 100% compared to fish injected with sera collected from fish immunized with control vaccines or left unhandled. In this study, DNA vaccination effectively protected Atlantic salmon smolts against challenges with IHNV.     

Protection, immune responses and side effects in Atlantic salmon (Salmo salarL.) vaccinated against furunculosis by different procedures

In an experimental trial lasting approximately 6 months, 10 different vaccination regimes against furunculosis were studied in Atlantic salmon pre-smolts. Single and repeated administration of vaccine by the intraperitoneal (i.p.), immersion or oral route, and revaccination by combinations of these methods, were tested. In challenge assays initiated 8 and 16 weeks after vaccination, fish injected once with a trivalent vaccine, and fish injected twice with a monovalent vaccine, both containing aluminium phosphate as adjuvant, were moderately protected. Non-injection vaccination protocols consistently failed to protect the fish. Compared with unvaccinated fish, protected groups showed elevated antibody responses toAeromonas salmonicidaantigens throughout the study. Increasedin vitroproliferation of head kidney leucocytes from i.p. vaccinated fish was found 16 weeks after vaccination. The use of a polyvalent vaccine preparation, and revaccination by injection or the oral route improved both immune responses and survival, compared to a single inoculation of monovalent vaccine. In all groups subjected to i.p. administration of vaccine, minor to moderate intraperitoneal lesions were found. In conclusion, i.p. administration of adjuvanted vaccine, preferably in a polyvalent formulation, is the optimal method of inducing anti-furunculosis immunity in Atlantic salmon, and is apparently necessary for an effective immunoprophylaxis of salmonid fish against furunculosis.