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First published online March 12, 2009
Journal of Experimental Biology 212, 934-944 (2009)
Published by The Company of Biologists 2009
doi: 10.1242/jeb.027680
Nervous and humoral control of cardiac performance in the winter flounder (Pleuronectes americanus)
Ocean Sciences Centre, Memorial University, St John's, Canada, NL A1C 5S7
* Author for correspondence (e-mail: kgamperl{at}mun.ca)
Accepted 20 January 2009
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Key words: beta-adrenoreceptors, binding affinity, catecholamines, flatfish, heart, teleost
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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;
Axelsson et al., 1990;
Taylor et al., 1999) and, in
elasmobranchs, nervous control of the heart is mainly attributed to the degree
of cholinergic vagal tonus (Taylor et al.,
1999; Agnisola et al.,
2003). In most teleosts, the heart is innervated by both
inhibitory parasympathetic fibres, running in the vagus nerve, and
postganglionic sympathetic fibres, reaching the heart directly or via
the vagus (Donald and Campbell,
1982; Laurent et al.,
1983; Farrell and Jones,
1992). Humoral adrenergic stimulation of the heart is also
generally important and is mediated by catecholamines released from the
chromaffin tissue into the circulatory system
(Gamperl et al., 1994c;
Reid et al., 1998). Resting
levels of plasma catecholamines [adrenaline (A) and noradrenaline (NA)] are
usually less than 10 nmol l–1. However, in response to severe
stress, the concentration of circulating catecholamines can increase
dramatically (i.e. to levels in excess of 300 nmol l–1),
promoting metabolic and circulatory adjustments to cope with increasing
energetic demands (Randall and Perry,
1992; Gamperl et al.,
1994c; Perry and Gilmour,
1999).
Interestingly, the potential for catecholamines to modulate cardiac
performance varies with the severity and type of stressor, and among species.
For instance, in Atlantic cod (Gadus morhua), A and NA concentrations
increase by 11.5-fold and 5.6-fold, respectively, at this species' critical
swimming speed (Ucrit)
(Butler et al., 1989), whereas
no change in plasma catecholamine concentrations was found when cod were swum
at only two-thirds of Ucrit
(Axelsson and Nilsson, 1986).
Increases in A and NA, of 46-fold and 11.5-fold, respectively, were reported
in rainbow trout (Oncorhynchus mykiss) after 10 min of chasing
(Tang and Boutilier, 1988),
while chasing till exhaustion can raise A and NA by as much as 92-fold and
20-fold, respectively (Perry et al.,
1996). Circulating catecholamine concentrations also differ
greatly between fish species and, in general, species with a more active
lifestyle exhibit greater increases in plasma catecholamine levels when
exposed to stressors as compared with benthic/sluggish species. Thus, it is
not surprising that maximum A and NA levels in the sea raven
(Hemitripterus americanus; a North Atlantic benthic species) after 1
min of air exposure followed by 1 min of chasing are only 
8 nmol
l–1 (Vijayan and Moon,
1994), and that A and NA levels are only 30 and 37 nmol
l–1, respectively, in the starry flounder [Platichthys
stellatus (Milligan and Wood,
1987)] after 10 min of chasing. By contrast, the A concentration
in rainbow trout can be as high as 275 nmol l–1 after being
chased to exhaustion (Perry et al.,
1996), and circulating A concentrations of 565 nmol
l–1 have been found in Atlantic cod after exposure to severe
acute hypoxia (L. H. Petersen and A.K.G., unpublished data).
Flatfishes (order Pleuronectiformes) are unique because, in contrast to
most teleosts, electrophysiological and histochemical studies suggest that
adrenergic cardiac innervation is absent
(Cobb and Santer, 1973;
Donald and Campbell, 1982;
Ask, 1983). Furthermore,
flounder appear to have a limited humoral adrenergic stress response
(Milligan and Wood, 1987), a
characteristic probably related to their benthic and inactive lifestyle
(Pereira et al., 1999). Given
the lack of cardiac sympathetic innervation and the low post-stress
circulating catecholamine levels reported, and that neurohormonal control of
flatfish cardiac function has never been directly studied, it is not clear how
this taxa regulates cardiac function. Thus, the purpose of this study was to
determine how in vivo cardiovascular function is regulated in the
winter flounder (Pleuronectes americanus Walbaum 1792) by nervous and
humoral mechanisms. To accomplish this a number of experiments were
undertaken: (1) a series of neural and humoral antagonists were used to
determine the contribution of autonomic innervation and circulating
catecholamines to the control of in vivo heart function; (2) maximal
post-stress circulating catecholamines were measured in the flounder following
two different stressors (a 60 s net stress and a 90 s chase); (3) in
vivo dose–response curves for catecholamines (A and NA) were
produced to examine the ability of circulating catecholamines to stimulate the
winter flounder heart; and (4) flounder ventricular β-adrenoreceptors
were typed and quantified, to better understand how β-adrenoreceptors
relate to, and mediate, the effects of catecholamines on the heart of this
species.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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In vivo experiments
Surgery
Fish were anaesthetized (average mass 0.46±0.13 kg) in seawater
containing methane sulfonic acid of m-aminobenzoate (MS-222; 0.25 g
l–1), and then transferred to a surgical table, where their
gills were irrigated with chilled (4°C) and oxygenated seawater
containing 0.1 g l–1 MS-222.
Implantation of flow probe
Implantation of the blood flow probe was performed as previously described
by Crocker et al. (Crocker et al.,
2000) for white sturgeon, with some modifications. In this
procedure, the gills and operculum were retracted using umbilical tape (Baxter
Healthcare Corporation, Deerfield, IL, USA) which was passed from a hole
behind the fourth gill arch into the opercular cavity, the ventral aorta was
exposed through a small incision (0.5 cm) in the isthmus without
disrupting the pericardium, and a flow probe (1.5RB, Transonic Systems;
Ithaca, NY, USA) was placed loosely around the vessel. Finally, after
verifying the quality of the cardiac output signal, the probe lead was sutured
to the eyed side of the fish using 3–0 silk (American Cyanamid Company,
Pearl River, NY, USA) at three locations.
Cannulation of caudal artery
Cannulation of the caudal artery for the measurement of dorsal aortic
pressure was performed as previously described by Cech and Rowell
(Cech and Rowell, 1976) with
modifications. Briefly, a 2 cm long incision was made, just below the lateral
line at about one third of the animal's length from the tail. The skin and
underlying muscle tissue were then retracted to expose the caudal artery which
lies between the haemal arches, and a heparinized cannula (PE 50, Clay Adams,
Parsippany, NJ, USA; 80 cm long, volume 0.2 ml) with indwelling 14 gauge piano
wire was inserted into the vessel. Finally, after removing the indwelling
wire, and pushing the cannula approximately 8 cm anteriorly into the artery,
the incision was closed with a continuous suture, and the cannula was filled
with heparinized saline 
181.3 mmol l–1 NaCl, 5.0 mmol
l–1 KCl, 2.30 mmol l–1
CaCl2·2H2O, 1.99 mmol l–1
MgSO4·6H2O, 2.58 TES acid
{N-[Tris(hydroxymethyl)methyl]-2-aminoethanesulfonic acid} and 7.33
mmol l–1 sodium TES base
{N-[Tris(hydroxymethyl)methyl]-2-aminoethanesulfonic acid sodium
salt} with 100 i.u. ml–1 heparin
, and sutured to the
fish's dorsal surface at two locations. There was minimal bleeding during
cannula implantation, and the cannula was flushed regularly with heparinized
saline to prevent clot formation.
Recovery from anaesthesia was initiated after surgery by artificially
ventilating the fish with aerated, anaesthetic-free water. Once ventilatory
activity had returned, the fish were placed into an opaque 45l cooler supplied
with aerated 8°C seawater and filled with 5 cm of sand. The flounder
were then allowed to recover for at least 24 h prior to experimentation.
Experimental procedures
Neural control of cardiac function
Following the recovery period, cardiac output
(
), dorsal aortic pressure
(PDA) and heart rate (fH) were
recorded for 1 h. After this initial recording period, a series of drugs were
injected every 1 h 30 min in the following order: 1.2 mg kg–1
atropine sulphate (muscarinic receptor antagonist); 10 mg
kg–1 bretylium tosylate (adrenergic nerve blocker), 213
µgkg–1 (RS)-atenolol (β1-adrenoreceptor
antagonist) and 250 µgkg–1 ICI 118551 hydrochloride
(β2-adrenoreceptor antagonist). These drug concentrations were
selected based on previous fish studies
(Smith et al., 1985;
Altimiras et al., 1997;
van Heeswijk et al., 2005),
and all drugs were injected slowly (over approx. 15 s) through the caudal
artery in a concentrated form using a 1 ml kg–1 carrier
volume of saline. This initial injection was followed by an injection of
enough saline (0.3 ml) to ensure complete delivery of the drug into the
animal.
Chasing and net stress
In order to determine maximal post-stress circulating catecholamines and
haematocrit levels, two groups of flounder were used in which no surgical
procedure was performed. One group of flounder (N=8) was held in a
net for 60 s, while another group (N=8) was chased to exhaustion
prior to sampling. In the chasing procedure, each fish was caught individually
from their holding tanks using a net and chased immediately in a rectangular
tank (1 mx1 mx0.5 m) for 90 s using a small wooden prod.
Immediately after these procedures were finished, blood samples were taken
from the flounder (0.6–0.9 ml) for the measurement of post-stress
haematocrit and plasma catecholamine (A and NA) levels by caudal puncture.
For the measurement of catecholamines, the blood was immediately placed into a chilled 1.5 ml Eppendorf centrifuge tube, and centrifuged at 10,000 g for 30 s to obtain plasma. The plasma was then pipetted into a 1.0 ml cryovial containing glutathione and EDTA (5 µl of 0.2 mol l–1 glutathione and 5 µl of 0.2 mol l–1 EDTA per 100 µl of plasma), and immediately frozen in liquid N2. All plasma samples were then stored at –80°C until analysis.
Catecholamine dose–response curves
To assess the sensitivity of the flounder cardiovascular system to
circulating catecholamines, dose–response curves for A and NA were
generated from in vivo measurements. As described above, fish
(N=7) were implanted with a ventral aortic flow probe and a caudal
artery cannula, and then allowed to recover for approx. 24 h. After recovery,
, PDA and
fH were recorded for 1 h, and then each fish was given a
series of five 1 ml kg–1 saline injections. Each saline
injection was separated by 1 h to assess the potential effects of
haemodilution on the flounder's cardiovascular function, and thus discern sham
injection effects from drug effects (see below). Subsequent to the saline
injections, the flounder were allowed to recover for 18 h, after which they
were injected with 0.1 and 0.05 (dose 1), 0.15 and 0.075 (dose 2), 0.2 and 0.1
(dose 3), 0.3 and 0.15 (dose 4), and finally 0.4 and 0.2
µgkg–1 (dose 5) of A and NA, respectively. These
injections were given at 1 h intervals (an inter-injection period that allowed
cardiovascular variables to return to resting values), and all doses of A and
NA were injected slowly (over approx. 15 s) through the caudal artery in a
concentrated form using a 1 ml kg–1 carrier volume of saline.
These concentrations were selected based on the maximum concentrations of A
(21 nmol l–1) and NA (14 nmol l–1) found in
winter flounder after chasing, and the relationship between injected dose and
plasma A levels established by Gamperl et al.
(Gamperl et al., 1994b) for
rainbow trout at similar temperatures. Cardiovascular variables and
PDA were measured for 10 min before and 45 min after each
injection. Blood samples were also taken prior to the first injection (0.5 ml)
and 2 min after the last injection (0.8 ml) for the determination of plasma A
and NA concentrations induced by the injection of 0.4 and 0.2
µgkg–1 (dose 5) of A and NA, respectively. Immediately
upon collection, blood samples were processed using the same protocol as in
the chasing and net stress experiments.
Data analysis
Instrumentation for cardiovascular measurements
Dorsal aortic pressure (PDA, in kPa) was measured using
a Gould Statham pressure transducer (Model P23 ID, Oxnard, CA, USA) that was
calibrated daily against a static water column, where zero pressure (0 kPa)
was set equal to the water level in the experimental chamber. Cardiac output
(; ml min–1
kg–1) was monitored by connecting the flow probe lead to a
small animal blood flow meter (Model T206, Transonic® Systems, Ithaca, NY,
USA). Both pressure and flow signals were amplified and filtered using a Model
MP100A-CE data acquisition system (BIOPAC Systems, Santa Barbara, CA, USA),
and analyzed and stored using AcqKnowledge Software (BIOPAC Systems,
Santa Barbara, CA, USA) installed on a 300 MHz Toshiba laptop computer.
Calculation of cardiovascular parameters
Cardiovascular function was continuously monitored throughout the `neural
control of cardiac function' and `dose–response curve' experiments by
measuring and
PDA. Heart rate (fH; beats
min–1) was calculated by measuring the number of systolic
peaks during 20–30 s intervals. Mass specific stroke volume
(VS; ml kg–1), was calculated as:
VS=cardiac output (ml min–1
kg–1)/heart rate (beats min–1). Systemic
vascular resistance (Rsys; kPa ml–1 kg
min) was calculated as: dorsal aortic pressure (kPa)/cardiac output (ml
min–1 kg–1).
The `intrinsic' (after the administration of all drugs)
fH (fHint; beats
min–1), cholinergic tonus (%fHch; %) and
adrenergic tonus (%fHad; %) were calculated for the winter
flounder heart as described by Axelsson
(Axelsson, 1988):
 | (1) |
 | (2) |
Catecholamine analysis
The plasma catecholamines, adrenaline (A) and noradrenaline (NA), were
measured using high performance liquid chromatography (HPLC; Bioanalytical
Systems, West Lafayette, IN, USA) with electrochemical detection (LC
Epsilon® detector, model E5, Bioanalytical Systems) after extraction with
alumina (Woodward, 1982). For
amine separation, a reverse phase column (ODS, 3.0 mm i.d.x10 cm long, 3
µm pore size, model MF 8954) was used in conjunction with an aqueous mobile
phase (containing per litre: 7.088 g monochloroacetic acid, 186.1 mg
Na2EDTA·2H2O, 15 ml acetonitrile and 232.3 mg
sodium octyl sulphate, pH 3.00–3.05), pumped (PM 80, BAS) at a flow rate
of 1 ml min–1. DHBA (3,4-dihydroxybenzylamine) was used as an
internal standard for all plasma samples and catecholamine standards. The
recovery of DHBA (3,4-dihydroxybenzylamine) from the alumina was in the order
of 50–80%, and was used to determine individual plasma catecholamine
concentrations. The output from the detector was collected and analysed using
a computer running ChromGraph Control and ChromGraph Report version 2.30
software (Bioanalytical Systems).
Chemicals
Components of the saline were purchased from Fisher Scientific (Fairlawn,
NJ, USA), with the exception of TES salt, which was purchased from Sigma
Chemical Co. (St Louis, MO, USA). MS-222 was purchased from Syndel
Laboratories (Vancouver, BC, Canada). Atropine sulphate salt, bretylium
tosylate, (RS)-atenolol, ICI 118551 hydrochloride, (±) timolol,
adrenaline bitartrate, noradrenaline bitartrate and all chemicals used in
catecholamine extraction and analysis were also purchased from Sigma Chemical
Company.
In vitro experiments
Cardiac β-adrenoreceptors
The punch-technique for the measurement of ventricular
β-adrenoreceptors was performed as previously described by Gamperl et al.
(Gamperl et al., 1994a) for
rainbow trout. Flounder (average mass 0.55±0.03 kg) were killed by a
blow to the head, and the heart was quickly removed and allowed to beat for
approximately 1 min in cold (0–2°C) saline to remove erythrocytes
from the ventricular lumen. The ventricle was then quickly removed, cut in
half and frozen (in 2 min) onto the tissue chopper (McIlwain tissue
chopper, Brinkmann, Mississauga, ON, Canada) stage before being sliced into
400 µm thick cross sections. The tissue slices were then placed in a
Sylgard-coated tissue culture dish filled with ice-chilled saline, and
ventricular tissue punches (2 mm diameter, 0.9–1.25 mg) were taken from
the slices using a sample corer (Fine Science Tools, Vancouver, BC, Canada).
Finally, individual punches were placed in separate wells of a tissue culture
plate (Becton Dickinson and Company, Franklin Lakes, NJ, USA), with each well
containing 500 µl of saline.
β-Adrenergic receptor density and affinity were measured by incubating the punches in varying concentrations (0.05–2 nmol l–1) of the hydrophilic β-antagonist [3H]CGP-12177 (specific activity 37 Ci mmol–1; Amersham Biosciences, Amersham, Bucks, UK) for 2 h. Non-specific binding (NSB) was measured in the presence of 10–5 mol l–1 timolol (β-adrenoreceptor antagonist), and was subtracted from total counts to determine specific binding. To express Bmax (i.e. the density of β-adrenoreceptors on the cell surface) as fmol µg–1 protein, the protein content of representative punches was determined using a Bradford protein assay (Coomassie Plus, Pierce Biotechnology, Rokford, IL, USA) with bovine serum albumin (ICN Biomedical, Aurora, OH, USA) as a standard. During the incubation period all tissue culture plates were kept on ice (i.e. at 0°C) and covered with aluminium foil to prevent the photodegradation of [3H]CGP and its competitors. Following incubation, aliquots of buffer were removed to determine the free concentration of [3H]CGP-12177, and the tissue punches were washed twice in ice-chilled saline and placed into 7 ml scintillation vials containing 5 ml of Ecolume (ICN Canada, Montreal, QC, Canada). All scintillation vials were shaken and allowed to sit for at least 18 h prior to counting. Radioactivity was quantified using a liquid scintillation counter (Packard Tri-Carb 2100TR; Meriden, CT, USA). For the determination of [3H]CGP-binding specificity (i.e. the construction of competition curves), punches were incubated with 1.5 nmol l–1 [3H]CGP and with various concentrations (10–4–10–9mol l–1) of atenolol (β1-adrenoreceptor antagonist) or ICI 118551 (β2-adrenoreceptor antagonist).
The small size of the winter flounder ventricle required the pooling of tissue punches from two individuals to construct each binding curve. To assess the specific binding of [3H]CGP-12177 to ventricular β-adrenoreceptors, a total of eight binding curves were obtained and each ligand concentration had three (only at 0.05 nmol l–1) to six replicates. For both atenolol and ICI 118551 competition curves, a total of six curves were constructed and each competitor concentration had five to six replicates.
Statistical analyses
The reported variables are expressed as means ± standard error of
the mean (s.e.m.). Univariate general linear models were used to test for
significant differences between the saline and drug injection groups and
between the saline and catecholamine injection groups. When a significant
difference between groups was detected, one-way ANOVAs were performed to test
for differences between values obtained with saline and corresponding
drug/catecholamine injections, and contrasts were performed to test for
significant differences within groups. Differences between circulating
catecholamine concentrations measured at rest, and after net stress, chasing
and catecholamine dose 5 were assessed using one-way ANOVAs.
Saturation-binding curves for CGP were analysed, and values for
Kd ([3H]CGP dissociation constant; in nmol
l–1) and Bmax (fmol
µg–1 protein) were determined using Scatchard plots as
described by Zivin and Waud (Zivin and
Waud, 1982). Competition curves were fitted, and IC50
values (i.e. the concentration of ligand that reduced [3H]CGP
binding by 50%) were determined using SigmaPlot Software for Windows version
10.0 (Systat Software, Chicago, IL, USA). All statistical analyses were
performed using SPSS software for Windows version 15.0 (SPSS, Chicago, IL,
USA) and P<0.05 was used as the level of statistical
significance.
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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remained constant at approx. 10 ml min–1
kg–1 following atropine injection
(Fig. 2). Interestingly,
bretylium administration did not result in a decrease in
fH, but a further increase to 40 beats
min–1, and had no significant effects on either
VS or . Finally,
none of the measured cardiac parameters were affected by the injection of the
β1- and β2-adrenoreceptor blockers (atenolol
and ICI 118551, respectively). Based on the changes in fH
following administration of the various drugs, intrinsic
fH, and cholinergic and adrenergic nervous tones were
calculated to be 40.9 beats min–1, 26.1% and –11.9%,
respectively (Table 1).
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PDA increased from 3.03 to 3.37 kPa (by 11%) following
atropine injection and, because was
unchanged by administration of this pharmacological blocker, it was clear that
this change in PDA was directly related to an
atropine-induced increase in systemic vascular resistance
(Rsys increasing from 0.32 to 0.35 kPa
ml–1 kg min). Neither PDA nor
Rsys were affected by bretylium, atenolol or ICI 118551
(Fig. 2).
Net stress and chasing
Resting plasma levels of A and NA were both approx. 5 nmol
l–1, resulting in a A:NA ratio of approx. 1.1. The 90 s chase
resulted in slightly higher post-stress levels of catecholamines than the 60 s
net stress (A, 20.7±5.1 vs 15.0±7.0; NA,
14.0±5.0 vs 11.6±3.4), however, these differences were
not significant (P=0.52 for A and P=0.70 for NA). This lack
of a statistical difference was also true for A:NA ratios, which were 2.0 and
1.3 following the 90 s chase and 60 s net stressors, respectively
(Table 2).
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Catecholamine dose–response curves
In these experiments, we were aiming for maximum circulating catecholamine
concentrations of approx. 25 nmol l–1 adrenaline and 14 nmol
l–1 noradrenaline based on the injection of 0.4
µgkg–1 A and 0.2 µgkg–1 NA (dose 5).
The plasma levels achieved with this dose at 2 min post-injection were 13.7
nmol l–1 for NA but only 11.5 nmol l–1 for
A. Although this was an increase over resting levels of only 8.5 and 7 nmol
l–1, respectively, these values were significantly different
from resting levels, and not significantly different from catecholamine
concentrations measured after chasing and net stress
(Table 2).
The injection of A and NA resulted in dose-dependent changes in
cardiovascular parameters, with fH decreasing, and
and VS
increasing, by a maximum of 15, 30 and 27%, respectively
(Fig. 3). However, because
significant increases in (by 9%) and
VS (by 24%), and decreases in fH (by
13%), were also associated with the injection of saline
(Fig. 3), values were expressed
as a percentage change from pre-injection, after subtracting the
increase/decrease associated with saline injection. When this was done
(Fig. 4), it was clear that the
maximum post-injection increases in cardiovascular function were mainly an
injection artefact. For instance, of the 27% increase in
VS reported after catecholamine injection, only 6% was
actually due to the effects of A and NA on this cardiovascular parameter. In a
similar fashion, only 10% of the increase in
could be attributed to the direct
effects of the injected catecholamines
(Fig. 4). In contrast
PDA increased by 22% with the injection of A and NA, and
this change was measured at the lowest catecholamine dose (0.1
µgkg–1 A and 0.05 µgkg–1 NA);
increasing the dose by fourfold having only a marginal additional influence on
PDA.
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0.86 (range=0.86–0.99;
Fig. 5B), with non-specific
binding ranging from 14.6 to 30.9% of total binding
(Fig. 5A). When the binding
data were converted into fmol mg–1 protein based on punch
protein content (28.1±4.4 µgmg–1 tissue), the
β-adrenoreceptor density (Bmax) and ligand binding
affinity (Kd) for the winter flounder myocardium were
determined to be 252.8±45.6 fmol mg–1 protein and
1.02±0.11 nmol l–1, respectively. Although atenolol
(β1-antagonist) was unable to displace [3H]CGP from
the flounder's ventricular β-adrenoreceptors, the
β2-antagonist ICI 118551 decreased [3H]CGP binding
beginning at approx. 10–7 mol l–1; the
IC50 value for ICI 118551 was 1.91x10–6 mol
l–1 (Fig.
5C).
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|
DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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), resting
cardiovascular variables in this study (at 8°C) correspond well with
previous research on 10°C-acclimated winter flounder. For instance,
Joaquim et al. (Joaquim et al.,
2004), made the first direct measurements of cardiac function in
flatfish, and reported resting VS and
values at 10°C of 0.47 ml
kg–1 and 15.5 ml min–1 kg–1
(compared with 0.39 ml kg–1 and 10.4 ml
min–1 kg–1 in the present study).
Furthermore, several authors have reported fH and
PDA values of approx. 35 beats min–1 and
3.5 kPa, respectively, at 10°C (Cech
et al., 1976; Cech et al.,
1977; Joaquim et al.,
2004), values very similar to those measured in this study (27.5
beats min–1 and 2.9 kPa at 8°C, respectively). By
contrast, resting cardiovascular values for the flounder are generally lower
than reported for more active species. This is not surprising, however, as
significant inter-specific variation exists in cardiac function, and in
general, active fishes have higher values for resting
and VS than
benthic forms. For instance, in the rainbow trout, resting
can range from 18 to 30.9 ml
min–1 kg–1 and VS from
0.29 to 0.6 ml kg–1 (at 9–12°C)
(Gamperl et al., 1994e;
Thorarensen et al., 1996;
Brodeur et al., 2001). The
chinook salmon (Oncorhynchus tshawytscha) has resting values for
of 35.8 ml min–1
kg–1 and for VS of 0.63 ml
kg–1 at 9–10°C
(Gallaugher et al., 2001), and
and VS values of
27.5–35.5 ml min–1 kg–1 and 0.61 ml
kg–1 have been reported for the Atlantic salmon (Salmo
salar) at 9–12°C (Perry and
McKendry, 2001; Dunmall and
Schreer, 2003). However, the bottom dwelling lingcod [Ophiodon
enlongatus; of 5.9–10.9 ml
min–1 kg–1; VS of
0.13–0.37 ml kg–1 at 9–13°C:
(Stevens et al., 1972;
Farrell, 1981)] and the sea
raven [H. americanus; of
18.8 ml min–1 kg–1 and
VS of 0.51 ml kg–1 at 6–8°C;
(Axelsson et al., 1989)] have
similar resting cardiovascular values as reported here for the flounder.
Neurohormonal control of cardiac function
Atropine induced a 42% increase in fH, and based on
this change in fH we calculated that the cholinergic
contribution to resting heart rate at 8°C was 26.1%. This degree of
cholinergic tonus is equivalent to that reported for other teleosts at similar
temperatures (see Table 1). For
instance, the eel pout (Zoarces viviparous) has a resting cholinergic
tonus of 18.9% (Axelsson et al.,
1987) and cholinergic tonus on the cod heart is between 21.3 and
37.7% at 10–12°C (Altimiras et
al., 1997; Axelsson,
1988).
Surprisingly, bretylium caused an additional positive chronotropic effect
in the winter flounder that lasted for at least 1 h post-injection, and this
resulted in a negative resting adrenergic tonus (–11.9%). This finding
is in clear contrast to most previous studies on fish which have reported
values for resting adrenergic tonus from 13% for the sea bream
(Sparus aurata) and cod (Altimiras
et al., 1997) to 67.1% for the eel pout
(Axelsson et al., 1987)
(Table 1). Furthermore, the
positive chronotropic effect induced by bretylium was not expected since
earlier studies suggest that pleuronectids lack myocardial adrenergic
innervation. For example, fluorescent histochemical studies in the greenback
flounder (Rhombosolea tapirina) failed to find adrenergic cardiac
nerves, and in isolated heart preparations from this species, stimulation of
the vagus nerve had both negative inotropic and chronotropic effects
(Donald and Campbell, 1982).
In addition, in isolated plaice (Pleuronectes platessa) hearts,
electrophysiological studies revealed that only cholinergic fibres run in the
cardiac branch of the vagus, and that bretylium had no effect on
fH in vagally-stimulated isolated hearts
(Cobb and Santer, 1973).
However, there are several potential explanations for the increase in
fH seen in the winter flounder following the injection of
bretylium. First, unlike other pleuronectids, this species might have cardiac
sympathetic innervation, and thus the positive chronotropic effect could be
the result of an initial release of catecholamines from sympathetic nerve
endings. This bretylium sympathomimetic effect has been demonstrated in both
sand flathead (Platycephalus bassensis) isolated heart preparations
(Donald and Campbell, 1982)
and in Atlantic cod in situ heart preparations
(Axelsson, 1988). Second, it is
possible that the flounder has cardiac 
-adrenoreceptors, and that basal
adrenergic tone has a negative chronotropic influence in this species. In this
scenario, bretylium would have increased heart rate by inhibiting
catecholamine release from adrenergic nerve terminals. Such an inhibitory
adrenergic effect, caused by the stimulation of -adrenoreceptors, has
been demonstrated in the hearts of the perch [Perca fluviatilis, 15
and 24°C (Tirri and Ripatti,
1982)] and eel [Anguilla anguilla, 8°C
(Peyraud-Waitzenegger et al.,
1980)]. Nonetheless, previous studies have not found any evidence
of -adrenoreceptors in atrial preparations from the rainbow trout and
flounder (P. flesus) at 8°C
(Ask, 1983), and thus, it is
unlikely that -adrenoreceptors were playing a significant role in the
regulation of cardiac function in the winter flounder at 8°C. Third, as in
mammals (Heissenbuttel and Bigger,
1979; Fallen,
1998), bretylium administration could have caused an initial
catecholamine release from peripheral adrenergic nerve terminals into the
circulation, elevating fH. This explanation, however, also
seems unlikely as catecholamines are rapidly cleared from the circulation of
fishes (Gamperl et al., 1994b)
and no significant increase in plasma catecholamines was found in the cod
after bretylium injection (Axelsson and
Nilsson, 1986). Furthermore, our dose–response curves show
that the flounder heart is not very responsive to circulating catecholamines
(e.g. see Figs 3 and
4), and that blocking the
flounder's β-adrenoreceptors with atenolol and ICI 118551 did not
mitigate the positive chronotropic effect associated with bretylium injection
(Fig. 2). Unfortunately, at
present, we cannot provide a definitive answer as to why bretylium induced a
positive chronotropic effect in the flounder heart.
As mentioned above, the β1 and
β2-adrenergic blockers atenolol and ICI 118551 had no effect
on resting cardiovascular function in the winter flounder. This result
indicates that neither circulating or endogenous catecholamines support
resting cardiac function in this species of flatfish. This result is
surprising given that other fish species that lack cardiac innervation (e.g.
myxinoids), or whose vagus is composed solely of cholinergic nerves (most
elasmobranchs), rely heavily on circulating and endogenous catecholamines for
the modulation of cardiac function
(Axelsson et al., 1990;
Johnsson et al., 1996;
Agnisola et al., 2003).
However, it is consistent with the findings of other aspects of our
investigation into the mechanisms controlling cardiac function in this
species. Specifically, we show that the flounder heart is not very sensitive
to increases in circulating catecholamines achieved by bolus injections of A
and NA (Figs 3 and
4), and that
β-adrenoreceptors in the flounder heart have a very low affinity
(Kd for [3H]CGP 12177 of 1.02 nmol
l–1).
Intrinsic heart rate in the flounder was calculated to be 40.9 beats
min–1 at 8°C. This value is similar to the intrinsic
fH reported for the cod [36.6 beats
min–1, 10–12°C,
(Axelsson, 1988)], and is in
the middle of the range of values reported by Axelsson et al.
(Axelsson et al., 1987) for
seven different teleost species at 11–12°C; i.e. from approx. 30
beats min–1 for the tadpole fish (Ranice raninus) to
as high as 60 beats min–1 in the five-bearded rockling
(Ciliata mustela).
Plasma catecholamine levels following net stress and chasing
The low resting levels of plasma catecholamines found in the winter
flounder (A and NA concentrations of 4.6 and 5.1 nmol l–1,
respectively) are comparable to values reported for other teleosts, and
indicate that our fish had recovered fully from surgery. For example, resting
levels of A and NA in cod are reported to range from 2.5–4 and 4–5
nmol l–1, respectively
(Axelsson and Nilsson, 1986;
Butler et al., 1989), and
circulating catecholamine concentrations in resting rainbow trout are also
<5 nmol l–1 [2.2–2.6 nmol l–1 for A
and 2.7–3.3 nmol l–1 for NA
(Milligan and Wood, 1987;
Tang and Boutilier,
1988)].
When the flounder was exposed to net stress, plasma A and NA concentrations
increased by 3.2-fold and 2.2-fold, respectively. These increases were very
similar to those recorded after the flounder was chased to exhaustion
(elevations in plasma A levels by 4.5-fold and in NA by 2.7-fold;
Table 2), but are considerably
lower than those recorded for many other teleosts. For example, after 90 s of
chasing, plasma A and NA levels measured in the winter flounder were 20.7 and
14 nmol l–1, respectively, whereas, using a similar chasing
protocol, I. Costa and A.K.G. (unpublished data) found values as high as 188
(A) and 47 nmol l–1 (NA) in cod and 148 (A) and 149 nmol
l–1 (NA) in capelin (Table
3). Our results for the winter flounder are consistent with those
for the starry flounder following a 10 min chase to exhaustion [A to 30
and NA to 37 nmol l–1
(Milligan and Wood, 1987)] and
for the sea raven (H. americanus) after 1 min of air exposure
followed by 1 min of chasing [total catecholamine levels 16 nmol
l–1 (Vijayan and Moon,
1994)], and add support to the notion that benthic/sluggish
species have low post-stress circulating catecholamine levels. However, we
must also caution that this is only a generalization and that exceptions do
exist; I. Costa and A.K.G. (unpublished data) found total plasma catecholamine
levels of 48 nmol l–1 for the active swimming Atlantic
rainbow smelt (Osmerus mordax mordax), a value only approximately
one-half of that measured in the benthic dwelling eel pout (Macrozoarces
americanus; 58 nmol l–1 A and 41 nmol
l–1 NA; Table
1).
|
Catecholamine dose–response curves and cardiac β-adrenoreceptors
The bolus administration of A and NA, at doses (up to 0.4
µgkg–1 A and 0.2 µgkg–1 NA) that
resulted in circulating catecholamine concentrations typical of post-chase
levels, did not affect flounder cardiovascular function
(Fig. 4). This result agrees
with recent experiments on cod where in vivo cardiac function was
only marginally influenced at A doses below 4 µgkg–1 (L.
H. Petersen and A.K.G., unpublished data), and where in situ hearts
only showed marginal improvements in maximum pumping capacity and power output
even when exposed to 200 nmol l–1 A (G. J. Lurman, L. H.
Petersen, H. O. Portner and A.K.G., unpublished). However, it contrasts with
the results of Gamperl et al. (Gamperl et
al., 1994d) for the rainbow trout where the injection of A at
doses as low as 0.2 µgkg–1 increased
and VS by approx.
33%. This diminished adrenergic sensitivity in flounder, as compared with
rainbow trout, hearts is clearly not due to a reduced number of cardiac
β-adrenoreceptors, as β-adrenoreceptor density in the flounder
ventricle (Bmax, 252.8 fmol mg–1 protein)
is the highest ever reported for a teleost species, and six- to 12-fold higher
than reported for the rainbow trout (23–40 fmol mg–1
protein) (Gamperl et al.,
1994a; Olsson et al.,
2000). A more likely explanation is that the injected
concentrations were not sufficient to stimulate the flounder heart. This
conclusion is based on two pieces of evidence: (1) flounder (P.
flesus) ventricular strips at 10°C respond to 1 µmol
l–1 of A by increasing contractile force by approx. 120%
(Lennard and Huddart, 1992);
and (2) although the density (Bmax) of ventricular
β-adrenoreceptors is very high compared with other teleosts, their
binding affinity for [3H]CGP is 1.02 nmol l–1.
This latter value is approx. 3–10 times greater than that measured for a
variety of other fish species [0.13–0.36 nmol l–1
(Olsson et al., 2000)].
Although unusual, a very low receptor affinity for stress hormones is not
unique amongst fishes. For example, gill cortisol receptors in the chub
(Leuciscus cephalus) have a Kd eightfold higher
than those in rainbow trout, probably to compensate for the extremely high
levels of cortisol found in the blood of this species [at rest, five- to
10-fold higher than trout (Pottinger et
al., 2000)]. Why the β-adrenoreceptors on the flounder
ventricle have such a high Kd is not obvious from the
research conducted here (but see below), especially given that resting plasma
concentrations of A and NA are low, and typical of those measured in other
teleosts. However, it is possible that the high Kd value
of flounder heart β-adrenoreceptors is related to this species' life
history. The flounder has a benthic and inactive lifestyle
(Pereira et al., 1999), a
limited aerobic capacity (Duthie,
1982; Lefrançois and
Claireaux, 2003; Priede and
Holliday, 1980), generally swims intermittently
(He, 2003), and appears to
find even slow swimming very demanding
(Joaquim et al., 2004). Thus,
it is reasonable to assume that the flounder's adrenergic and cardiovascular
systems are not designed to respond to chasing/exercise, an unlikely situation
for the flounder in its natural environment. Interestingly, flounder typically
bury themselves several cm deep (i.e. up to 10–15 cm) in soft sediments
(sand and mud), and under these conditions gill ventilation may be difficult
(Cech et al., 1977;
Nonnotte and Kirsch, 1978) and
very low oxygen concentrations may be encountered
(Fletcher, 1975;
Duthie, 1982;
Pereira et al., 1999). In
experiments using in situ heart preparations, Mendonça et al.
(Mendonça et al., 2007)
reported that the winter flounder heart has a maximum VS
(2.3 ml g–1 ventricle) significantly greater than the cod
(1.3) and the Atlantic salmon (1.4), and suggested that this elevated maximum
VS might be important under conditions of severe hypoxia.
This hypothesis is supported by recent in vivo data (P.C.M. and
A.K.G., unpublished data) showing that flounder acclimated to 8°C
increased VS by 40% when the water O2
saturation was lowered from 30 to 20%, and thus it is probable that severe
hypoxia is the type of stress/challenge that would promote a release of
catecholamines from the chromaffin cells large enough to stimulate flounder
myocardial β-adrenoreceptors. In fact, this idea is supported by recent
research on Atlantic cod showing that circulating catecholamine levels during
severe hypoxia [A 350 nmol l–1 and NA 60 nmol
l–1 at 13% water O2 saturation (L. H. Petersen and
A.K.G., unpublished)] are approximately twice those following exhaustive
exercise (A of 188 nmol l–1, NA of 47 nmol
l–1; I. Costa and A.K.G., unpublished data), and that maximal
adrenergic stimulation offsets the adverse effects of hypoxia, and the
concomitant effects of hyperkalemia and acidosis, on performance of in
situ trout heart at 10°C (Hanson
et al., 2006).
Based on the inability of the β1-antagonist atenolol to
displace [3H]CGP (β-adrenergic antagonist) from flounder's
ventricular β-adrenoreceptors, and the IC50 value for the
β2-antagonist ICI 118551 (1.91x10–6 mol
l–1), it appears that winter flounder ventricular
β-adrenoreceptors are predominantly of the β2 subtype.
This conclusion contrasts with the previously held belief that the flounder
heart has equal affinity for A and NA (Ask,
1983), but agrees with Cobb and Santer
(Cobb and Santer, 1973) who
showed that the isolated heart of the flounder P. platessa is more
sensitive to A than to NA, and with Gamperl et al.
(Gamperl et al., 1994a) who
characterized the ventricular β-adrenoreceptors of the rainbow trout
heart as β2. Nonetheless, the high Kd
measured for these receptors (1.02 nmol l–1 CGP) is difficult
to reconcile with previous studies on fish which report Kd
values in the range of 0.1–0.4 nmol l–1
(Gamperl et al., 1994a;
Olsson et al., 2000). One
possible explanation for the high Kd value measured for
β-adrenoreceptors of the flounder heart is that they are functionally
uncoupled from adenylate cyclase
(Hausdorff et al., 1990).
However, we feel that this is unlikely as resting levels of circulating
catecholamines in the flounder are typical of those measured in other
teleosts, the repeated injection of catecholamines into rainbow trout does not
alter cardiac β-adrenoreceptor affinity
(Gamperl et al., 1994a) and
exposure to β-adrenoreceptor agonists for more than a month only resulted
in an increase in the Kd of rainbow trout muscle
β-adrenoreceptors of 2-fold [from 0.2 to 0.5 nmol
l–1 (Lortie et al.,
2004)]. A more probable explanation for the high
Kd value reported here for flounder cardiac
β-adrenoreceptors is that the flounder heart has a significant population
of β3-adrenoreceptors. These receptors have been found in the
hearts of both the rainbow trout
(Nickerson et al., 2003) and
European eel (Imbrogno et al.,
2006), and are activated at higher catecholamines concentrations
than β1/β2-adrenoreceptors
(Gauthier et al., 2007).
Furthermore, in trout erythrocytes, β3-adrenoreceptor binding
properties resemble β2-adrenoreceptors more than
β1 (Nickerson et al.,
2003), and consequently the displacement of [3H]CGP by
ICI 118551 in the flounder heart (see Fig.
5C) may be related to the presence of β2 and/or
β3 subtypes. β3-receptor stimulation induces
negative inotropic effects in most mammals (e.g. see
Gauthier et al., 1999;
Gauthier et al., 2007) and in
the eel (Imbrogno et al.,
2006), and it has been recently shown by Imbrogno et al.
(Imbrogno et al., 2006) and
Angelone et al. (Angelone et al.,
2008) that stimulation of β3-adrenoreceptors
mediates negative inotropy and lusitropy (i.e. their stimulation allows the
heart to relax slower) through the induction of endothelial nitric oxide
synthase-derived nitric oxide signalling. Whether these receptors also exist
in the flounder heart, and what role they might play in mediating cardiac
function in this species, can only be answered through further research.
However, it has been suggested that these receptors play a `protective role'
by preventing excessive β1/β2 stimulation of
the mammalian myocardium (Gauthier et al.,
2007; Angelone et al.,
2008).
Perspectives
This study provides valuable new insights into the nervous and humoral
control of cardiac function in the winter flounder. For example, our results
indicate that neural and humoral adrenergic mechanisms do not support resting
cardiac performance in 8°C-acclimated flounder, and that increases in
plasma catecholamines associated with net stress and chasing are not
sufficient to stimulate cardiac β-adrenoreceptors. They also show that
although the flounder ventricle is populated with an unusually large number of
β-adrenoreceptors, these receptors have a very low binding affinity.
These results are not easily explained on the basis of what is known about
cardiovascular control/physiology in other fishes, but appear to fit well with
the winter flounder's life history and other data on aspects of this species'
cardiac function (e.g. Joaquim et al.,
2004; Mendonça et al.,
2007). Furthermore, they lead to several testable hypotheses.
Specifically, we propose that this species' muted cardiac response to
catecholamine stimulation is related to the existence of a significant
population of myocardial β3-adrenoreceptors, that circulating
catecholamines only reach concentrations capable of stimulating these
receptors under conditions such as severe hypoxia (e.g. when flounder are
buried in soft sediments), and that β3-adrenoreceptor
stimulation promotes negative inotropism and lusitropism that balances the
positive stimulation provided by β2-receptors.
LIST OF ABBREVIATIONS
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Footnotes |
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References |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Agnisola, C., Randall, D. and Taylor, E. (2003). The modulatory effects of noradrenaline on vagal control of heart rate in the dogfish, Squalus acanthias. Physiol. Biochem. Zool. 76,310 -320.[CrossRef][Medline]
Altimiras, J., Aissaoui, A., Tort, L. and Axelsson, M. (1997). Cholinergic and adrenergic tones in the control of heart rate in teleosts: how should they be calculated? Comp. Biochem. Physiol. 118A,131 -139.[CrossRef][Medline]
Angelone, T., Filice, E., Quintieri, A., Imbrogno, S., Recchia, A., Pulerà, E., Mannarino, C., Pellegrino, D. and Cerra, M. (2008). β3-adrenoreceptors modulate left ventricular relaxation in the rat heart via NO-cGMP-PKG pathway. Acta Physiol. 193,229 -239.[CrossRef]
Ask, J. (1983). Comparative aspects of adrenergic receptors in the hearts of lower vertebrates. Comp. Biochem. Physiol. 76A,543 -552.[Medline]
Axelsson, M. (1988). The importance of nervous
and humoral mechanisms in the control of cardiac performance in the Atlantic
cod Gadus morhua at rest and during non-exhaustive exercise.
J. Exp. Biol. 137,287
-301.
Axelsson, M. and Nilsson, S. (1986). Blood
pressure control during exercise in the Atlantic cod, Gadus morhua.J. Exp. Biol. 126,225
-236.
Axelsson, M., Ehrenstrom, F. and Nilsson, S. (1987). Cholinergic and adrenergic influence on the teleost heart in vivo. Exp. Biol. 46,179 -186.[Medline]
Axelsson, M., Driedzic, W., Farrell, A. and Nilsson, S. (1989). Regulation of cardiac output and gut blood flow in the sea raven, Hemitripterus americanus. Fish Physiol. Biochem. 64,315 -326.
Axelsson, M., Farrell, A. and Nilsson, S.
(1990). Effects of hypoxia and drugs on the cardiovascular
dynamics of the Atlantic hagfish Myxine glutinosa. J. Exp.
Biol. 151,297
-316.
Brodeur, J., Dixon, D. and McKinley, R. (2001). Assessment of cardiac output as a predictor of metabolic rate in rainbow trout. J. Fish Biol. 58,439 -452.[CrossRef]
Butler, P., Axelsson, M., Ehrenstrom, M. J. D. and Nilsson,
S. (1989). Circulating catecholamines and swimming
performance in the Atlantic cod, Gadus morhua. J. Exp.
Biol. 141,377
-387.
Cech, J. and Rowell, D. (1976). Vascular canulation method for flatfishes. Prog. Fish Cult. 38, 74-75.[CrossRef]
Cech, J. J., Bridges, D., Rowell, D. and Balzer, P. (1976). Cardiovascular responses of winter flounder, Pseudopleuronectes americanus (Walbaum), to acute temperature increase. Can. J. Zool. 54,1383 -1388.[Medline]
Cech, J., Rowell, D. and Glasgow, J. (1977). Cardiovascular responses of the winter flounder Pseudopleuronectes americanus to hypoxia. Comp. Biochem. Physiol. 57A,123 -125.
Cobb, J. and Santer, R. (1973).
Electrophysiology of cardiac function in teleosts: cholinergically mediated
inhibition and rebound excitation. J. Physiol.
230,561
-573.
Crocker, C., Farrell, A., Gamperl, A. and Cech, J. J. (2000). Cardiorespiratory responses of white sturgeon to environmental hypercapnia. Am. J. Physiol. 279,R617 -R628.
Donald, J. and Campbell, G. (1982). A comparative study of the adrenergic innervation of the teleost heart. J. Comp. Physiol. 147,85 -91.
Dunmall, K. and Schreer, J. (2003). A comparison of the swimming and cardiac performance of farmed and wild Atlantic salmon, Salmo salar, before and after gamete stripping. Aquaculture 220,869 -882.[CrossRef]
Duthie, G. (1982). The respiratory metabolism
of temperature-adapted flatfish at rest and during swimming activity and the
use of anaerobic metabolism at moderate swimming speeds. J. Exp.
Biol. 97,359
-373.
Fallen, E. (1998). Bretylium. Card. Electrophysiol. Rev. 2,164 -167.[CrossRef]
Farrell, A. (1981). Cardiovascular changes in
the lingcod (Ophiodon elongatus) following adrenergic and cholinergic drug
infusions. J. Exp. Biol.
91,293
-305.
Farrell, A. and Jones, D. (1992). The heart. In Fish Physiology, Vol. XII, Part A. (ed. W. Hoar, D. Randall and A. Farrell), pp. 1-88. San Diego, CA: Academic Press.
Fletcher, G. (1975). The effects of capture, "stress", and storage of whole blood on the red blood cells, plasma proteins, glucose, and electrolytes of the winter flounder (Pseudopleuronectes americanus). Can. J. Zool. 53,197 -206.[Medline]
Gallaugher, P., Thorarensen, H., Kiessling, A. and Farrell, A. (2001). Effects of high intensity exercise training on cardiovascular function oxygen uptake, internal oxygen transport and osmotic balance in chinook salmon (Oncorhynchus tshawytscha) during critical speed swimming. J. Exp. Biol. 204,2861 -2872.[Medline]
Gamperl, A., Wilkinson, M. and Boutilier, R. (1994a). Beta-adrenoreceptors in the trout (Oncorhynchus mykiss) heart characterization, quantification, and effects of repeated catecholamine exposure. Gen. Comp. Endocrinol. 95,259 -272.[CrossRef][Medline]
Gamperl, A., Vijayan, M. and Boutilier, R. (1994b). Epinephrine, norepinephrine, and cortisol concentrations in cannulated seawater-acclimated rainbow trout (Oncorhynchus mykiss) following black-box confinement and epinephrine injection. J. Fish Biol. 45,313 -324.[CrossRef]
Gamperl, A., Vijayan, M. and Boutilier, R. (1994c). Experimental control of stress hormone levels in fishes: techniques and applications. Rev. Fish Biol. Fish. 4, 215-255.[CrossRef]
Gamperl, A., Pinder, A. and Boutilier, R. (1994d). Effect of coronary ablation and adrenergic stimulation on in vivo cardiac performance in trout (Oncorhynchus mykiss). J. Exp. Biol. 186,127 -143.[Abstract]
Gamperl, A., Pinder, A., Grant, R. and Boutilier, R. (1994e). Influence of hypoxia and adrenaline administration on coronary blood flow and cardiac performance in seawater rainbow trout (Oncorhynchus mykiss). J. Exp. Biol. 193,209 -232.[Abstract]
Gauthier, C., Tavernier, G., Trochu, J., Leblais, V., Laurent,
K., Langin, D., Escande, D. and Le Marec, H. (1999).
Interspecies differences in the cardiac negative inotropic effects of
β3-adrenoreceptors agonists. J. Pharmacol. Exp.
Ther. 290,687
-693.
Gauthier, C., Sèze-Goismier, C. and Rozec, B. (2007). Beta 3-adrenoreceptors in the cardiovascular system. Clin. Hemorheol. Microcirc. 37,193 -204.[Medline]
Hanson, L., Obradovich, S., Mouniargi, J. and Farrell, A.
(2006). The role of adrenergic stimulation in maintaining maximum
cardiac performance in rainbow trout (Oncorhynchus mykiss) during
hypoxia hyperkalemia and acidosis at 10°C. J. Exp.
Biol. 209,2442
-2451.
Hausdorff, W., Caron, M. and Lefkowitz, R. (1990). Turning off the signal: desensitization of beta-adrenergic receptor function. FASEB J. 11,2881 -2889.
He, P. (2003). Swimming behaviour of winter flounder (Pleuronectes americanus) on natural fishing grounds as observed by an underwater video camera. Fish. Res. 60,507 -514.[CrossRef]
Heissenbuttel, R. and Bigger, J. J. (1979).
Bretylium tosylate: a newly available antiarrhythmic drug for ventricular
arrhythmias. Ann. Intern. Med.
91,229
-238.
Imbrogno, S., Angelone, T., Adamo, C., Pulerà, E., Tota,
B. and Cerra, M. (2006). Beta3-adrenoceptor in the eel
(Anguilla anguilla) heart: negative inotropy and NO-cGMP-dependent
mechanism. J. Exp. Biol.
209,4966
-4973.
Joaquim, N., Wagner, G. and Gamperl, A. (2004). Cardiac function and critical swimming speed of the winter flounder (Pleuronectes americanus) at two temperatures. Comp. Biochem. Physiol. 138A,277 -285.[CrossRef][Medline]
Johnsson, M., Axelsson, M., Davison, W., Forster, M. and Nilsson, S. (1996). Effects of preload and afterload on the performance of the in situ perfused portal heart of the New Zealand hagfish Eptatretus cirrhatus. J. Exp. Biol. 199,401 -405.[Abstract]
Laurent, P., Holmgren, S. and Nilsson, S. (1983). Nervous and humoral control of the fish heart: structure and function. Comp. Biochem. Physiol. 76A,525 -542.
Lefrançois, C. and Claireaux, G. (2003). Influence of ambient oxygenation and temperature on metabolic scope and scope for heart rate in the common sole Solea solea. Mar. Ecol. Prog. Ser. 259,273 -284.[CrossRef]
Lennard, R. and Huddart, H. (1992). The effect of thermal stress and adrenaline on the dynamics of the flounder (Platichthys flesus) heart. Comp. Biochem. Physiol. 101C,307 -310.
Lortie, M., Arnason, T., Dugan, S., Nickerson, J. and Moon, T. (2004). The impact of feeding β2-adrenergic agonists on rainbow trout muscle β2-adrenoreceptors and protein synthesis. J. Fish Biol. 65,769 -787.[CrossRef]
Mendonça, P., Genge, A., Deitch, E. and Gamperl, A. (2007). Mechanisms responsible for the enhanced pumping capacity of the in situ winter flounder heart (Pseudopleuronectes americanus). Am. J. Physiol. 293,R2112 -R2119.
Milligan, C. and Wood, C. (1987). Regulation of
blood oxygen transport and red cell pHi after exhaustive activity in rainbow
trout (Salmo gairdneri) and Starry flounder (Platichthys
stellatus). J. Exp. Biol.
133,263
-282.
Nickerson, J., Dugan, S., Drouin, G., Perry, S. and Moon, T. (2003). Activity of the unique beta-adrenergic Na+/H+ exchanger in trout erythrocytes is controlled by a novel beta3-AR subtype. Am. J. Physiol. 285,R526 -R535.
Nonnotte, G. and Kirsch, R. (1978). Cutaneous respiration in seven sea-water teleosts. Respir. Physiol. 35,111 -118.[CrossRef][Medline]
Olsson, H., Yee, N., Shiels, H., Brauner, C. and Farrell, A. (2000). A comparison of myocardial beta-adrenoreceptor density and ligand binding affinity among selected teleost fishes. J. Comp. Physiol. 170,545 -550.
Pereira, J., Goldberg, R., Ziskowski, J., Berrien, P., Morse, W. and Johnson, D. (1999). Essential fish habitat source document: winter flounder, Pseudopleuronectes americanus, life history and habitat characteristics. NOAA Tech. Rep. NMFS.
Perry, S. and Gilmour, K. (1999). Respiratory and cardiovascular systems during stress. In Stress Physiology in Animals (ed. P. Balm), pp. 52-107. Sheffield: Sheffield Academic Press.
Perry, S. and McKendry, J. (2001). The relative roles of external and internal CO2 versus H+ in eliciting the cardiorespiratory responses of Salmo salar and Squalus acanthias to hypercarbia. J. Exp. Biol. 204,3963 -3971.[Medline]
Perry, S., Reid, S. and Salama, A. (1996). The effects of repeated physical stress on the beta-adrenergic response of the rainbow trout red blood cell. J. Exp. Biol. 199,549 -562.[Abstract]
Peyraud-Waitzenegger, M., Barthelemy, L. and Peyraud, C. (1980). Cardiovascular and ventilatory effects of catecholamines in unrestrained eels (Anguilla anguilla L.). J. Comp. Physiol. 138,367 -375.
Pottinger, T., Carrick, T. and Appleby, A. Y. W. E. (2000). High blood cortisol levels and low cortisol receptor affinity: is the chub, Leuciscus cephalus, a cortisol-resistant teleost? Gen. Comp. Endocrinol. 120,108 -117.[CrossRef][Medline]
Priede, I. and Holliday, F. (1980). The use of
a new tilting tunnel respirometer to investigate some aspects of metabolism
and swimming activity of the plaice (Pleuronectes platessa L.).
J. Exp. Biol. 85,295
-309.
Randall, D. and Perry, S. (1992). Catecholamines. In Fish Physiology, Vol. XII, Part B. (ed. W. Hoar, D. Randall and A. Farrell), pp.255 -300. San Diego, CA: Academic Press.
Reid, S., Bernier, N. and Perry, S. (1998). The adrenergic stress response in fish: control of catecholamine storage and release. Comp. Biochem. Physiol. 120C, 1-27.[CrossRef]
Smith, D., Nilsson, S., Wahlqvist, I. and Eriksson, B.
(1985). Nervous control of the blood pressure in the Atlantic
cod, Gadus morhua. J. Exp. Biol.
117,335
-347.
Stevens, D., Bennion, G., Randall, D. and Shelton, G. (1972). Factors affecting arterial pressures and blood flow from the heart in intact, unrestrained lingcod, Ophiodon elongatus.Comp. Biochem. Physiol. 43A,681 -695.[CrossRef][Medline]
Tang, Y. and Boutilier, R. (1988). Correlation between catecholamine release and degree of acidotic stress in trout. Am. J. Physiol. 255,R395 -R399.[Medline]
Taylor, E., Jordan, D. and Coote, J. (1999).
Central control of the cardiovascular and respiratory systems and their
interactions in vertebrates. Physiol. Rev.
79,855
-916.
Thorarensen, H., Gallaugher, P. and Farrell, A. (1996). Cardiac output in swimming rainbow trout, Oncorhynchus mykiss, acclimated to seawater. Physiol. Zool. 69,139 -153.
Tirri, R. and Ripatti, P. (1982). Inhibitory adrenergic control of heart rate of perch (Perca fluviatilis) in vitro. Comp. Biochem. Physiol. 73C,399 -401.[CrossRef][Medline]
van Heeswijk, J., Vianen, G., van den Thillart, G. and Zaagsma,
J. (2005). Beta-adrenergic control of plasma glucose and free
fatty acid levels in the air-breathing African catfish Clarias
gariepinus Burchell 1822. J. Exp. Biol.
208,2217
-2225.
Vijayan, M. and Moon, T. (1994). The stress response and the plasma disappearance of corticosteroid and glucose in a marine teleost, the sea raven. Can. J. Zool. 72,379 -386.[CrossRef]
Woodward, J. (1982). Plasma catecholamines in resting rainbow trout, Salmo gairdneri Richardson, by high pressure liquid chromatography. J. Fish. Biol. 21,429 -432.[CrossRef]
Zivin, J. and Waud, D. (1982). How to analyze binding, enzyme and uptake data: the simplest case, a single phase. Life Sci. 30,1407 -1422.[CrossRef][Medline]
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