Partial cross protection against Ichthyophthirius multifiliis in Gyrodactylus derjavini immunized rainbow trout (original) (raw)
Related papers
Diseases of Aquatic Organisms, 2006
Rainbow trout Oncorhynchus mykiss Walbaum, 1792 fingerlings were vaccinated by intraperitoneal (i.p.) injection using live theronts of the skin parasitic ciliate Ichthyophthirius multifiliis Fouquet, 1876 at 2 temperatures (12 and 20°C), and protection against challenge infections was subsequently evaluated by bath exposure to live theronts. Vaccination conferred a relative protection (evaluated as the decrease in the number of established theronts) at 12°C and almost complete immunity at 20°C. Significantly increased immobilisation titers (using plasma immobilisation of live theronts) were found in immunised fish at Week 2 and 4 post-vaccination. Lysozyme activity of plasma from vaccinated fish increased from Week 1 to 4. Both immobilisation titers and lysozyme activity were significantly higher at 20°C. This study demonstrated that live theronts are good candidates for an antigen source for development of effective vaccines against white spot disease in this fish host, and further indicated that the protection of rainbow trout against I. multifiliis infection is highly temperature dependent and may be associated with both adaptive and innate response mechanisms.
Journal of Fish Diseases, 2004
Abstract During an infection with the parasitic ciliate Ichthyophthirius multifiliis, expression of genes encoding complement factor C3, inducible nitric oxide synthase (iNOS), immunoglobulin (IgM) and major histocompatibility complex (MHC-II) was examined in the skin, head kidney and spleen of rainbow trout using semi-quantitative reverse transcriptase-polymerase chain reaction. Induction of C3 transcription levels was evident in the skin and spleen showing extra-hepatic production of C3. MHC-II and IgM levels were increased in both head kidney and skin suggesting a production of antibodies at the site of infection, as well as in the lymphoid organs. iNOS expression was only increased briefly in the skin during the infection. These data suggest that complement is involved in immune reactions against I. multifiliis and that mucosal antibodies might be produced at the site of infection.
Immune response of channel catfish to ciliary antigens of Ichthyophthirius multifiliis
Developmental and Comparative Immunology, 1988
Channel catfish were rendered immune to the protozoan pathogen, Ichthyophthirius multifiliis, by exposure to sublethal infections. Sera from test animals were then screened for antibodies against the parasite using enzyme-linked immunoassays. Ichthyophthirius cilia were blotted onto nitrocellulose filters and reacted with catfish sera, followed by rabbit anti-catfish Ig antibodies coupled to horseradish peroxidase. Subsequent color development revealed the presence of anti-ciliary antibodies in a number of fish tested. Reactions appeared to be highly specific; little cross-reactivity was seen in equivalent assays with heterologous cilia from Tetrahymena. Ciliary antigens were associated predominantly with a membrane polypeptide fraction isolated from intact cilia by phase separation in solutions of the nonionic detergent, Triton X-114. The relative levels of anti-ciliary antibodies in sera from individual fish were quantitated by photometric scanning of immunoblot assays. A strong correlation (P<.03) was found between antibody levels and the ability of sera to agglutinate live parasites in vitro.
Fish & Shellfish Immunology, 2007
Vaccination of channel catfish with either of two serotypes of the parasitic ciliate Ichthyophthirius multifiliis conferred protection against challenge infection by either serotype. Fish were vaccinated by intracoelomic injection with live theronts of isolate G5 (serotype D) or isolate G12 (a new serotype), which express different surface immobilisation antigens. Vaccination with live G12 theronts conferred complete protection against subsequent challenge by both serotypes while vaccination with G5 theronts elicited only partial protection against both serotypes. Vaccination with trophont lysates did not protect against challenge infection. Sera from vaccinated fish were tested in immobilisation assays, ELISAs, and Western blots. Serum antibodies recognised only immobilisation antigens of the serotype used for vaccination in immobilisation assays or on Western blots. No antigens common to both serotypes were identified by Western blots. In contrast, serum antibodies bound antigens in cell lysates from both serotypes by ELISA, demonstrating that antibodies recognising both serotypes are produced in response to infection, which presumably confer observed cross-serotype protection.
Host responses against the fish parasitizing ciliate Ichthyophthirius multifiliis
Veterinary Parasitology, 2001
Recent studies have shown that fish are able to mount protective immune responses against various parasites. One of the best characterized parasite-host system in this context is the ciliate Ichthyophthirius multifiliis (Ich) parasitizing a range of freshwater fishes. Both specific and non-specific host defence mechanisms are responsible for the protection of fish against challenge infections with this ciliate. The specific humoral components comprise at least specific antibodies. The non-specific humoral elements included are the alternative complement pathway and probably lectins. Cellular factors involved in the specific response are B-cells and putative T-cells. The non-specific effector cells recognized are various leukocytes. In addition, goblet-cells and mast cells (EGC-cells) may have a function. The NCC-cell (suggested analogue to NK-cells in mammals) seems to play a role in the non-specific response. This well documented protective response in freshwater fishes against Ich has urged the development of anti-parasitic vaccines. Indeed, such products based on formalin killed parasites have been developed and found to offer the vaccinated host a satisfactory protection. However, the collection of parasites for vaccine production is extremely laborious. It involves keeping infected fish due to the fact that in vitro propagation of the parasite is still insufficiently developed. Gaining knowledge of amino acid sequences and its encoding DNA-sequences for the protective antigens (i-antigens) in the parasite was a major breakthrough. That achievement made it possible to produce a recombinant protein in E. coli and preliminary results indicated a certain protection of fish vaccinated with this product. Recent work has shown that the free-living and easily cultivated ciliate Tetrahymena can be transformed and express the i-antigen. This path seems to be promising for future development of vaccines against Ich. A novel approach in fish is the development of DNA-vaccines. Successful DNA-vaccination trials have been conducted in fish against viral infections and the technology also makes it possible to develop a DNA-vaccine against Ich. Other approaches to immuno-protection against Ich have been the use of heterologous vaccines. Thus, both bath and injection vaccination using live or killed (un-transformed) Tetrahymena has been reported to offer treated fish a certain level of protection. Such protection could be explained
PLOS ONE
Infection of rainbow trout with the parasitic ciliate Ichthyopthirius multifiliis induces differential responses in gills, skin and spleen. A controlled experimental infection was performed and expression of immune-relevant genes in skin, gills, and spleen were recorded by qPCR at day 1 and 8 after parasite exposure. Infection induced a marked reaction involving regulation of innate and adaptive immune genes in rainbow trout at day 8 post-infection. The expression level of a total of 22 out of 24 investigated genes was significantly higher in gills compared to skin reflecting the more sensitive and delicate structure of gills. Especially proinflammatory cytokines IL-6, IL-17 C1, regulatory cytokines IL-4/13A, IL-10, TGFβ, complement factor C5, chemokines CK10, CK12, acute phase proteins (precerebellin, hepcidin) and immunoglobulins (IgM, IgT) displayed differential expression levels. The spleen, a central immune organ with no trace of the parasite, showed elevated expression of IgM, IgT, complement factor C5 and chemokine CK10 (compared to skin and gills directly exposed to the parasite), indicating an interaction between the infected surface sites and central immune organs. This communication could be mediated by chemokines CK10 and CK12 and cytokine IL-4/13A and may at least partly explain the establishment of a systemic response in rainbow trout against the parasite.
In vitro response of Ichthyophthirius multifiliis to sera from immune channel catfish
J Fish Biol, 1987
Sera from channel catfish rendered immune to the protozoan pathogen Ichihyophrhiriuvmuliifliis were screened for activity against live parasites. Cells in the infective stage (tomites) were incubated in doubling dilutions of immune and pre-immune sera from fish that had been immunized by exposure to sublethal infections. When examined by light microscopy, tomites were found to agglutinate in the presence of immune sera. While the stength of individual sera varied, agglutination ofcells occurred at dilutions as high as 1: 128. Cells showed little tendency to agglutinate in pre-immune sera, and virtually no effects were seen with dilutions ofpre-immune sera greater than 1: 16. Agglutination was usually accompanied by release of mucus from cells, and while tomites appeared to be immobilized, their cilia continued to beat. Low dilutions of immune sera appeared to be toxic. Similar effects on tomites were seen with rabbit antisera prepared against Ichthyophthirius cilia. The involvement of humoral antibodies in agglutination and protective immunity is discussed.
Diseases of Aquatic Organisms, 2008
Rainbow trout Oncorhynchus mykiss were immunised by intra-peritoneal injection using a live vaccine based on Ichthyophthirius multifiliis (Ich) theronts, which previously has shown protection against white spot disease. Samples were taken pre-vaccination and on Day 1, 7, 21 and 28 post-immunisation (p.i.). Expression of immune relevant genes in the liver, spleen and head kidney was monitored by qPCR. To describe the immune reaction following this immunisation, a series of genes encoding cytokines, complement factors, immunoglobulins and acute phase reactants were studied. Genes encoding acute phase reactants in the liver were up-regulated with serum amyloid A (SAA) as the most pronounced with a 2299-fold increase at 24 h p.i. Hepcidin and pre-cerebellin were also up-regulated in the liver 24 h p.i., by 7-and 4-fold, respectively. Complement factors C3, C5 and factor B (Bf) were up-regulated in the spleen and the head kidney 24 h and 28 d p.i. Genes encoding immunoglobulins were not up-regulated, but a specific low titer IgM response (titer 25) against parasite antigens was detected by a modified ELISA 4 wk p.i. KEY WORDS: Vaccine · White spot disease · Fish · Immune response Resale or republication not permitted without written consent of the publisher Editorial responsibility: Dieter Steinhagen,