The overall theme of this thesis has been the study of the effects of well known and
potentially novel stressors on fish health and how some of these may be modulated
by dietary supplements of micronutrients, using both in vitro and in vivo analysis. In
vitro experiments with cultured fish cells (EPC-A1, GFSk-S1) evaluated the potential
of niacin and selenium to reduce cytotoxicity and genomic instability (DNA damage)
induced by ultraviolet radiation exposure, following assay validation with reference
toxins. Whilst cytotoxicity was determined by the neutral red retention (NRR) assay,
genomic stability was evaluated by either a standard or modified version of the single
cell gel electrophoresis (SCGE) or 'Comet' assay. Niacin as nicotinamide (NAM)
significantly reduced levels of UVB induced DNA damage (single strand breaks).
Selenium supplements, as sodium selenite or seleno-L-methionine also showed a
protective effect against H202, UVA and UVB induced cytotoxicity and oxidative DNA
damage. An additional in vitro study was carried out to identify environmental
nanoparticles as a potential novel source of stress for fish. Titanium dioxide (Ti02)
nanoparticle exposure to GFSk-81 cells caused dose-dependent increases in
cytotoxicity (NRR assay) and oxidative DNA damage (Comet assay). These effects
were exacerbated by combined exposures of Ti02 with UVA. Electron spin resonance
(ESR) and spin trapping suggested that Ti02 induced oxidative stress may be
primarily due to the production of hydroxyl radicals (OH).
Two in vivo experiments were carried out in order to evaluate the effects of husbandry
stress (netting and confinement stress) on antioxidant capacity, immune function and
genomic stability in trout (Oncorhynchus mykiss) and carp (Cyprinus carpio) , In both
studies on trout and carp, certain health parameters were shown to be sensitive to
husbandry stress, and may be useful biomarkers of stress in future studies. Total
antioxidant capacity (TAC) was reduced in both carp and trout after stress.
Respiratory burst capacity of blood leukocytes was also affected by stress but
differently in carp than in trout. In carp, husbandry stress apparently stimulated the
production of free radicals by leukocytes whereas in trout it was suppressed. In trout,
stress was also shown to increase oxidative DNA damage, as measured by the
Comet assay. Health parameters that appeared not to be significantly affected by
husbandry stress in this study include SOD activity, ALP activity, red blood cell fragility
and complement activity (for carp only).
In the second experiment on carp, a 10 week feeding trial was also conducted prior to
stress induction to evaluate the potential modulatory effects of selenium, zinc and
vitamin E on any husbandry induced stress effects observed. Health parameters
were also evaluated pre stress in order to elicit any effects of micronutrient
supplementation on health parameters in unstressed fish. Selenium supplementation
significantly increased glutathione peroxidase activity post stress, but not pre stress,
indicating an increased requirement of selenium in stressed fish. No other differences
were observed between dietary treatments for any parameter measured either pre
stress or post stress, indicating that levels of selenium, zinc and vitamin E were
probably sufficient in the control diet.
Further work is needed to enhance our understanding on the interaction between, and
the role of, stress and dietary micronutrients in fish health using a suite of assays to
monitor all aspects of fish health, both in vitro and in vivo.
Date of Award | 2008 |
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Original language | English |
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Awarding Institution | |
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The role of stress and dietary micronutrients in fish health
Reeves, J. F. (Author). 2008
Student thesis: PhD