Your search keyword '"*SALMONIDAE diseases"' showing total 2 results

1. Piscirickettsia salmonis : characterisation, infection and immune response in salmonid fish

Author

McCarthy, Una, Thompson, Kimberly Dawn, Ellis, Tony, and Adams, Alexandra

Subjects

639.3756, Salmonidae Diseases, Furunculosis

Abstract

The pathogen Piscirickettsia salmonis, has been isolated from all species of salmonid and has been found in Chile, Canada, Ireland, Norway and Scotland. Rickettsia-like organisms from European sea bass (Dicentrarchus labrax) were found to share common antigens with the P. salmonis type-strain, LF-89 using the indirect fluorescent antibody test (IFAT) and immunohistochemistry (IHC). In addition, the DNA sequences of the 16S rDNA and 16S-23S internal transcribed spacer region (ITS) were compared with those published for P. salmonis strains and showed that the sea bass piscirickettsia-like organism (SBPLO) was another strain of P. salmonis, closely related to the salmonid pathogens. The ability of P. salmonis to survive and replicate within head kidney (HK) macrophages of rainbow trout infected in vitro was demonstrated using transmission electron microscopy (TEM) at various times post-infection (p.i.). However, macrophages derived from fish vaccinated against P. salmonis appeared to clear in vitro infection more rapidly than macrophages from naive fish. Polymerisation of filamentous actin within the cytoplasm of the host cell is used by some mammalian rickettsiae to achieve intercellular spread by actin-based motility (ABM). Both TEM and confocal microscopy were used to investigate possible actin tail formation by P. salmonis. No evidence of tail formation was found. Respiratory burst (RB) by P. salmonis was measured following exposure of rainbow trout HK macrophages to the organisms in vitro. Because of background stimulation of the RB by growth media and debris from the CHSE-214 cells used to culture P. salmonis, it was not possible to detect any effect of the pathogen on the burst. Schering Plough Aquaculture has developed a recombinant vaccine against P. salmonis. The ability of the vaccine to elicit a memory response against P. salmonis was investigated by measuring three different immune responses: a) the expression of iNOS was measured by reverse transcription polymerase chain reaction (RT-PCR) to detect mRNA levels or by the Greiss reaction to quantify the end-products of nitric oxide metabolism in the serum. Increased iNOS expression was not detected in rainbow trout kidney or serum following vaccination/challenge with P. salmonis. However, iNOS expression was detected in gill tissue from naive trout which suggests that expression may be constitutive in this tissue. b) the production of macrophage activating factor (MAF) by lymphocytes from vaccinated trout, following stimulation in vitro with P. salmonis, was measured by the ability of supernatants from these cells to prime elevated RB in naive macrophages. No difference in priming ability between supernatants from vaccinated and non-vaccinated fish was detected. However, macrophages among the immune leukocytes used to produce the MAF supernatants did exhibit elevated RB compared with macrophages from non-immune fish, suggesting that vaccination had produced a population of lymphocytes capable of priming activation of macrophages. c) by screening individual sera concurrently against the rickettsial and CHSE antigen preparations, the antibody response to P. salmonis could be detected specifically and was found to increase significantly in immunised fish by 6 weeks post-vaccination. Specificity of the response was demonstrated by screening the sera against Aeromonas salmonicida.

Published

2005

2. Host parasite interactions between Ichthyobodo necator (Henneguy 1883) and farmed Salmonids

Author

Robertson, Derek Arthur

Subjects

639.8, Salmonidae Diseases, Salmonidae Parasites

Abstract

The literature on Ichthyobodo necator is reviewed. The prevalence and intensity of Ichthyobodo infestations on farmed salmonids was investigated on three farms over a period of two years. The infestations were found to be markedly age dependent. Peak infestations and related mortalities occurred in the first eight weeks after first feeding. Both mortalities and infestations declined to zero shortly after this period with no chemotherapy. Ichthyobodo reappeared on 0+ and appeared for the first time on I+ fish after a drop of water temperatures to less than 10*C. Many of the 1+ fish had started to mature. It is suggested that some form of host defence mechanism operates which limits the Ichthyobodo infestations in farmed salmonids. The sequential pathology of Ichthyobodo infestations of the skin of 0+ and 1+ salmon and rainbow trout was studied. Areas of greatest shelter from water currents were found to be most commonly infested and no parasites were found attached to the epidermis on the head of the fish. The parasite caused hyperplasia of the malphigian cells and exhaustion of the goblet cells below infestations, followed by spongiosis of the underlying epidermis. The epidermal plaque then sloughed off leaving a single layer of cells attached to the basement membrane. Cell kinetic studies showed that Ichthyobodo caused the cells immediately below infestations to divide, a markedly different pattern from that of normal teleost epidermal cell proliferation. The possibility that the parasite secretes some form of digestive enzyme is postulated. In areas where sloughing had occurred, the remaining malphigian cells were seen to be in the process of division. Various endocrinological aspects of Ichthyobodo infestations were investigated. Three corticosteroids and one androgen were injected or implanted into 1 year old rainbow trout. Implantations of hydrocortisone led to very heavy ichthyobodo infestations. Radio immune assays showed that the level of cortisol and testosterone in the serum of implanted fish was similar to that which would occur when salmonids mature. There appears to be a clear link between cortisol levels in the serum and Ichthyobodo infestation. The host response to Ichthyobodo is discussed and it is concluded that cortisol may suppress the host's defence mechanism to Ichthyobodo.

Published

1983