W.B. van Muiswinkel

IMMUNOGENETICS OF DISEASE RESISTANCE IN FISH : A COMPARATIVE APPROACH

The study of the genetic regulation of infectious disease resistance depends on the availability of inbred lines or selection lines of the species under investigation. The small numbers of such lines of fish has limited the strategy in teleosts to studies of associations between disease and immune/health traits. Attempts to correlate genetic differences in immune responsiveness with survival after experimental challenge with pathogenic bacteria have failed to define immune parameters that can substantially aid selection for genetic resistance to infectious diseases. Advantages and disadvantages of selection strategies as illustrated by mouse and chicken models are discussed. In this study we summarize the present situation in fish as well as our attempts to develop gynogenetic lines of carp for immunogenetic research.

Multiple acute temperature stress affects leucocyte populations and antibody responses in common carp, Cyprinus carpio L

Stress is a potential factor causing increased susceptibility of fish to pathogens. In this study, stress-induced immunological changes that may contribute to a decreased immune status were investigated. A 3 h drop in ambient water temperature of 9 degrees C was used as a relative mild and acute stress model for carp. Effects of this stressor on the dynamics of leucocyte populations were determined with specific monoclonal antibodies. The relative number of circulating B-lymphocytes in the total leucocyte population decreased significantly within 4 h after the onset of single or multiple cold shocks. This decrease was reversible, as B-lymphocyte numbers were restored within 24 h. Most probably, a redistribution of B-lymphocytes contributed to this phenomenon. In head kidney, an increase was measured in the relative number of B-lymphocytes. Granulocyte numbers showed opposite reactions: the percentage of granulocytes in the total leucocyte population nearly doubled in circulation and decreased significantly in the head kidney. This demonstrates that in vivo, a mild stressor differentially alters the distribution of leucocytes. In stressed carp, the percentage of apoptotic lymphocytes in blood is significantly higher compared with the unstressed animals. B-lymphocytes as well as Ig- lymphoid cells contributed to this increased apoptosis. Labelling of blood lymphocytes with a polyclonal antiserum against the glucocorticoid receptor also showed, besides B-lymphocytes, part of the Ig- lymphoid cell population to be glucocorticoid receptor positive. As the distribution of B-lymphocytes was substantially affected, the effect of temperature stress on T-lymphocyte-independent (trinitrophenyl-lipopolysaccharide) and T-lymphocyte-dependent (dinitrophenyl-keyhole limpet hemocyanin) humoral antibody responses was determined. Kinetics of the primary antibody response to the T-lymphocyte-independent antigen showed lower antibody titres in stressed carp during the onset of the immune response, implying a slower development of the antibody response against the T-lymphocyte-independent antigen.

Immune modulation by fish kinetoplastid parasites: A role for nitric oxide

Trypanoplasma borreli and Trypanosoma carassii are kinetoplastid parasites infecting cyprinid fish. We investigated the role of nitric oxide (NO) in immune modulation during T. borreli and T. carassii infection of carp. Phagocytic cells from different organs produced NO and serum nitrate levels increased, demonstrating that T. borreli activates NO production in vivo. In contrast, T. carassii did not induce NO production in vivo and inhibited LPS-induced NO production in vitro. Production of NO was detrimental to the host as T. borreli-infected carp treated with the inducible NO synthase inhibitor aminoguanidine had a higher survival than infected control carp. This detrimental effect can be explained (in part) by the toxicity of NO to cells in vitro as NO inhibited the proliferative response of blood and spleen leukocytes. Head-kidney phagocytes were resistant to the immunosuppressive effects of NO in vitro. The NO-inducing activity of T. borreli may be an adaptation developed to ensure survival and immune evasion in the fish host. Apparently, T. carassii has adopted another strategy by deactivating specific functions of phagocytes. Both strategies may ensure long-term survival of the parasite.

A history of fish vaccination. Science-based disease prevention in aquaculture

Disease prevention and control are crucial in order to maintain a sustainable aquaculture, both economically and environmentally. Prophylactic measures based on stimulation of the immune system of the fish have been an effective measure for achieving this goal. Immunoprophylaxis has become an important part in the successful development of the fish-farming industry. The first vaccine for aquaculture, a vaccine for prevention of yersiniosis in salmonid fish, was licensed in USA in 1976. Since then the use of vaccines has expanded to new countries and new species simultaneous with the growth of the aquaculture industry. This paper gives an overview of the achievements in fish vaccinology with particular emphasis on immunoprophylaxis as a practical tool for a successful development of bioproduction of aquatic animals.