First published online May 18, 2006
Journal of Experimental Biology 209, 2114-2128 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02241
Steroid-induced cardiac contractility requires exogenous glucose, glycolysis and the sarcoplasmic reticulum in rainbow trout
Richard S. Farrar*,
Pavan K. Battiprolu*,
Nicholas S. Pierson and
Kenneth J. Rodnick
Department of Biological Sciences, Idaho State University, Pocatello,
ID 83209-8007, USA
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Fig. 1. Experimental design involving additions of D-glucose, inotropes
and metabolic inhibitors to cardiac tissue in vitro. In all
experiments, ventricle strips from rainbow trout were incubated for 60 min in
either glucose or glucose-free media and electrically stimulated (0.5 Hz) at
14°C. (A) Glucose dose-response. Zero glucose reflects control ventricle
strips remaining in glucose-free media for the entire experiment. (B) Combined
effects of glucose (5 mmol l-1) and inotropes: T (0.3 µmol
l-1) in males; E2 (1 nmol l-1) in females; and Epi (1
µmol l-1) or Ca2+o (5 mmol l-1)
in both sexes. (C) Effects of inotropes mentioned above and caffeine (8 mmol
l-1), with and without glucose. (D) Effects of inotropes in
ventricle strips pretreated with inhibitors iodoacetate (IAA) (0.4 mmol
l-1) or ryanodine (10 µmol l-1). (E) Original
recording of isometric twitch force in ventricular muscle strips from a male
rainbow trout. After ventricle strips were stretched to optimal length (90%
Lmax) and after mechanical stabilization for 60 min,
glucose (5 mmol l-1) was added to one strip and the other remained
glucose-free (control) for 60 min. The extent of stored Ca2+ in the
sarcoplasmic reticulum was determined by post rest potentiation (PRP).
Stimulation of ventricle strips was discontinued for 5 min, prior to PRP
measurements. PRP was higher in glucose-treated ventricle strips when compared
with the corresponding glucose-free control. Values are means ± s.e.m.
(N=6-11 strips per group).
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Fig. 2. Effects of exogenous glucose on resting tension. In females, resting
tension was maintained in media containing 5 or 10 mmol l-1 glucose
but increased in glucose-free (0), 1 and 2 mmol l-1 glucose
conditions (dissimilar letters denote significant differences between
treatments, *P<0.05). There were no significant
differences in resting tension for males at all concentrations tested.
Immature females also showed higher resting tension compared with immature and
sexually maturing males at 0, 1 and 2 mmol l-1 glucose. Values are
means ± s.e.m. (N=8-26 strips per group).
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Fig. 3. Effects of exogenous glucose on twitch force (F). During the 60
min equilibration period, ventricle strips were incubated in the absence of
any exogenous substrate. In sexually maturing males, F increased
during the experimental period with 5 mmol l-1 glucose present,
compared with 0, 1, 2 and 10 mmol l-1 glucose, and was higher than
that in immature males and females at all concentrations tested. F
was also higher in immature males at 5 mmol l-1 glucose compared
with females and at all concentrations tested. In females, 5 mmol
l-1 glucose increased F compared with 0, 1 and 10 mmol
l-1 values. *P<0.05. Values are means
± s.e.m. (N=8-26 strips per group).
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Fig. 4. Effects of Ca2+ (5 mmol l-1), epinephrine (Epi; 1
µmol l-1), ethanol (EtOH), testosterone (T; 0.3 µmol
l-1) or 17ß-estradiol (E2; 1.0 nmol l-1), in the
presence (filled bars) or absence (open bars) of exogenous glucose (5 mmol
l-1), on performance of ventricle strips from males (A) and females
(B). All ventricle strips received exogenous glucose during the 60 min
equilibration period. There were only significant differences in ventricle
strips exposed to sex steroids. *P<0.05. Values are
means ± s.e.m. (N=7-9 strips per group).
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Fig. 5. Effects of glycolytic inhibitor iodoactetate (IAA; 0.4 mmol l-1)
on immature male (A) and female (B) cardiac tissue. After a 15 min incubation
with IAA, ventricle strips were exposed to either increased Ca2+ (5
mmol l-1), testosterone (T; 0.3 µmol l-1),
17ß-estradiol (E2; 1 nmol l-1) or epinephrine (Epi; 1 µmol
l-1). Plus (+) and minus (-) denote presence and absence,
respectively, of specific compounds in the incubation medium. For immature
males and females, elevated Ca2+ or Epi, but not sex steroids,
increased twitch force when glucose (5 mmol l-1) was present.
*P<0.05. Values are means ± s.e.m.
(N=9-11 strips per group).
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Fig. 6. Effects of ryanodine (Ryn; 10 µmol l-1) in immature male (A)
and female (B) cardiac tissue. Ventricle strips were incubated with Ryn 15 min
prior to the addition of either increased Ca2+ (5 mmol
l-1), testosterone (T; 0.3 µmol l-1),
17ß-estradiol (E2; 1 nmol l-1) or epinephrine (Epi; 1 µmol
l-1). Plus (+) and minus (-) denote presence and absence,
respectively, of specific compounds in the incubation medium. For immature
males and females, elevated Ca2+ or Epi, but not sex steroids,
increased twitch force when glucose (5 mmol l-1) was present.
*P<0.05. Values are means ± s.e.m.
(N=6-8 strips per group).
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Fig. 7. Effects of various compounds (iodoacetate, (IAA; 0.4 mmol l-1);
ryanodine, (Ryn; 10 µmol l-1); caffeine (8 mmol l-1);
Ca2+ (5 mmol l-1); epinephrine (Epi; 1 µmol
l-1); testosterone (T; males; 0.3 µmol l-1); or
17ß-estradiol (E2; females; 1.0 nmol l-1) on post-rest
potentiation (PRP) in immature males (A) and females (B). In both sexes,
ventricle strips receiving glucose had higher PRP than strips without glucose
(*P<0.05). Control strips containing glucose also
exhibited higher PRP than all other treatments when glucose was present (a
denotes P<0.05). PRP for glucose-free, control strips were higher
than all other treatments (b denotes P<0.05). However, other than
control strips, no significance was observed between glucose vs
glucose-free treatments (P=0.34). Values are means ± s.e.m.
(N=6-11 strips per group).
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Fig. 8. Effects of caffeine (8 mmol l-1) on contractile performance of
cardiac tissue in the presence or absence of elevated Ca2+ (5 mmol
l-1), epinephrine (Epi; 1 µmol l-1), testosterone (T;
males; 0.3 µmol l-1) or 17ß-estradiol (E2; females; 1.0
nmol l-1). All ventricle strips were exposed to 5 mmol
l-1 glucose for 1 h prior to addition of caffeine. After a 15 min
exposure to caffeine, each strip received one of the inotropes. Within a sex
there were no differences between treatments; however, the increase in twitch
force was greater in immature males than females
(*P<0.05). Values are means ± s.e.m.
(N=7 strips per group).
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Fig. 9. The relationship between extracellular Ca2+ and contractile
force. Twitch force is expressed as a percentage of the difference between
maximum force development and baseline force at 1.5 mmol l-1
Ca2+ for (A) male and female ventricle strips receiving 5 mmol
l-1 glucose; (B) female ventricle strips, glucose vs
glucose-free and (C) male ventricle strips, glucose vs glucose-free.
In the presence of glucose, the EC50 for Ca2+-dependent
force production was lower in females than males (P<0.01).
Compared with tissue receiving glucose, glucose-free ventricle strips from
both sexes were less sensitive to Ca2+ (P<0.05) but sex
differences were not evident. Values are means ± s.e.m. (N=8-9
strips per curve).
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© The Company of Biologists Ltd 2006
