posted on 2012-08-21, 00:00authored byPaulien
J. Mulder, Elisabeth Lie, Grethe
S. Eggen, Tomasz M. Ciesielski, Torunn Berg, Janneche U. Skaare, Bjørn
M. Jenssen, Eugen G. Sørmo
Thyroid hormones (THs) are essential for cellular metabolism,
somatic
growth and development, and reproduction. Mercury (Hg) entering aquatic
systems and accumulated as highly toxic methylmercury (MeHg) represents
a threat to wildlife and human health. Selenium (Se) is an essential
element critical for TH activation and regulation. In organisms, binding
of Hg in a Se–Hg complex results in a detoxification of Hg.
However, formation of Se–Hg complexes also affects Se bioavailability,
disrupting functions of Se-dependent enzymes, such as TH deiodinases,
which convert thyroxine (T4) to the physiologically active TH, triiodothyronine
(T3). The main aim of the present study was to investigate how tissue
Se:Hg molar ratios, tissue levels of Se and Hg, and other potential
TH disruptive contaminants (metals and organic chemical compounds)
affect plasma TH levels in free-ranging brown trout, Salmo trutta, from Lake Mjøsa (a Se-deprived
lake) and Lake Losna (a reference lake), Norway. Among the wide range
of potential TH disruptive pollutants investigated, tissue Se:Hg molar
ratios in muscle and liver were the most significant predictors of
plasma TH levels in the trout. Moreover, lower plasma levels of the
biological active hormone, T3, in the Lake Mjøsa trout co-occurred
with their low Se:Hg molar ratios. This suggests that Se availability
is impaired by Hg and results in altered selenoenzyme activities and
loss of optimal control of TH balance in free-ranging freshwater fish.