Carotenoid utilization in rainbow trout (Oncorhynchus mykiss Walbaum) and
Atlantic salmon (Salmo salar L.) has been investigated with respect to tissue
distribution of carotenoids and the role of the liver on the bioavailability of the
lipid soluble carotenoids, astaxanthin and canthaxanthin.
Species-specific and tissue-specific accumulations were noted for astaxanthin and
canthaxanthin in the rainbow trout and Atlantic salmon, possibly indicating
fundamental differences in their utilization in these species. The liver and the
kidney were revealed to be the major tissues involved in carotenoid metabolism in
both rainbow trout and Atlantic salmon. Apparent digestibilities (-96% and -30%
for rainbow trout and Atlantic salmon, respectively) and flesh carotenoid
retentions (-12% and -5.4% for rainbow trout and Atlantic salmon, respectively)
differed significantly between species, suggesting that rainbow trout are more
efficient depositors of carotenoids within the flesh.
Isolated rainbow trout liver perfusion experiments revealed small differences in
the uptake of astaxanthin and canthaxanthin. Uptake of astaxanthin in both
synthetically-derived and serum-derived models showed saturable uptake
mechanism that occurred earlier than for canthaxanthin. These results can
potentially offer an explanation for the better utilization of astaxanthin in rainbow
trout, where the liver reduces the bioavailability of canthaxanthin through
continued uptake. Results show a low hepatic extraction ratio (0.03-0.07), in line
with published post-prandial elimination rates.
Neither astaxanthin nor canthaxanthin significantly induced hepatic or renal
xenobiotic-metabolizing enzymes in the rainbow trout, contrary to published
reports in rats and mice. This may imply fundamental species-specific differences
in the metabolic pathways for these carotenoids.
Histochemical investigations revealed that both carotenoids significantly impacted
liver structure, resulting in higher levels of total lipids and mucopolysaccharides.
This is thought to be due to their antioxidant functions and their provitamin A
activity. Carotenoid-treated fish also had higher levels of glycogen phosphorylase
in liver sections, providing the first evidence in fish for the possibility of
glucuronidation of their metabolites.
The present investigations demonstrate the liver to be a major organ in carotenoid
metabolism, and consequently affects carotenoid distribution and availability. In
addition, carotenoid supplementation significantly affects liver structure and may
potentially enhance its function. Furthermore, these investigations have provided
new avenues of investigation into the use of isolated organ perfusions for
biochemical nutrition research, and expanded the knowledge of liver physiology
and biochemistry.
Date of Award | 2001 |
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Original language | English |
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Awarding Institution | |
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PHYSIOLOGICAL AND BIOCHEMICAL FACTORS AFFECTING CAROTENOID UTILIZATION IN SALMONID FISH
PAGE, G. I. (Author). 2001
Student thesis: PhD