Fish holding and screening

Fish rearing and experiments were conducted at the Station Expérimental Mixte IFREMER-INRA (Sizun, France). Rainbow trout Oncorhynchus mykiss Walbaum eggs, from a spring spawning strain, were fertilised on April 16^th 2002 and emergent fry started feeding on May 29^th 2002. In July, fish were moved to outdoor rearing tanks supplied with aerated ambient temperature freshwater, diverted from a nearby spring. On January 10^th 2003 (water temperature=7.0°C), six batches of 100 fish were successively transferred to a 3 m diameter circular tank, in which plastic meshing delimited a swimming ring (inner circumference=8.5 m; width=0.8 m), and left undisturbed for 15 min. By manipulating the valve that controlled the water supply to the tank, water velocity was progressively raised (within 15 min) from 0.2 to 1.2 m s^-1, as measured using a flowmeter (Marsh-McBirney 200, Frederick, MD, USA). Fish swam against this current until they fatigued and fell back against a mesh screen just upstream of the water inflow. The first ten fish to fatigue (termed poor swimmers) among the 100 fish were removed from the tank, anaesthetised, their length and body mass measured (Table 1), and a Passive Integrated Transponder (PIT-tag) inserted into the peritoneal cavity. The glass PIT tags (8 mm long and 2.12 mm diameter) were purchased from ORDICAM DSC (Ordicam, Rambouillet, France) and were read using a Planete 128 DSC reader (Ordicam) at 134.2 kHz. The water current was maintained and fatigued fish removed until the last 10 fish (termed good swimmers) reached exhaustion. Good swimmers were also fitted with a PIT tag. Poor swimmers fatigued within 10-15 min, while good swimmers avoided the back grid for 45-60 min. This procedure was repeated for each batch of 100 fish. The resulting 120 fish were then mixed in two outdoor holding tanks (12 m³) until September 2003, when biometrics of all the fish were remeasured (Table 1) and the experiments performed. No mortality occurred during the 9-month growing period, during which fish were fed twice a day ad libitum with commercial feed (BioMar, Brande, Denmark). The rearing temperature followed the normal seasonal changes in the spring water and ranged between 7°C in winter and 18°C in summer.

In vivo swimming studies

In vivo studies were performed on six poor swimmers of mean (± s.e.m.) mass 1204±105 g and fork length 419±11 mm, and six good swimmers with a mean mass 1030±62 g and forklength 419±10 mm. The water temperature was 16±0.4°C during these experiments. Fish were anaesthetised in 0.1 mg l^-1 MS-222 buffered with 0.1 mg l^-1 NaHCO₃ before being transferred to an operating table, where their gills were irrigated with aerated water containing diluted anaesthetic (0.05 mg l^-1 MS-222 and NaHCO₃). The ventral aorta was exposed via an incision in the cleithrum, a Transonic flow probe (Transonic Systems, Ithaca, NY, USA) placed around it and the incision closed with silk sutures. The dorsal aorta (DA) was then cannulated using the technique described by Soivio et al. (1975). Following surgery, fish were transferred to individual opaque PVC chambers, where they recovered for 48 h in a continuous flow of normoxic water. The DA cannula was flushed daily with heparinised (10 IU l^-1) Cortland's saline (Wolf, 1963). Following this recovery period, trout were carefully transferred, without air-exposure, into a water-filled plastic bag and then into a swimming respirometer, where they recovered for at least 4 h while swimming gently against a water velocity of 30 cm s^-1.

The U_crit swimming tests were performed using two Brett-type swim-tunnel respirometers, designed to exercise individual fish in a non-turbulent water flow with a uniform velocity profile (Steffensen et al., 1984). One respirometer constructed of PVC has been described in detail previously (McKenzie et al., 2001). The second was of a similar design and size, but constructed in stainless steel, with a total water volume of 48 l and a swim chamber with a square cross-sectional area of 290 cm². Water flow was generated by a thermo plastic composite propeller downstream of the swim chamber, attached to a variable speed, low inertia, brushless servo-motor (Ultact II, Phase Motion Control S.R.L., Milan, Italy), calibrated to deliver water velocities in cm s^-1 and swimming speeds in body lengths s^-1 (BL s^-1). The respirometer was thermostatted by immersion in a large outer stainless steel tank that received a flow of aerated water. In both respirometers, swimming speeds were corrected for the solid blocking effect of the fish, as described by Bell and Terhune (1970).

Each trout was exposed to progressive water velocity increments of 10 cm s^-1 every 30 min, until fatigue. Fish were considered to be fatigued when they were unable to remove themselves from the posterior screen of the swimming chamber despite gentle encouragement with a sudden increase in water velocity. Measurements of oxygen uptake (Ṁ_O2) were collected at each swimming speed, as described in McKenzie et al. (2001). These measurements were used to derive: (i) the notional metabolic rate of the immobile fish (IMR); (ii) the maximum metabolic rate of activity (AMR) during swimming (this occurred at speeds approaching U_crit); and (iii) net aerobic scope relative to IMR (McKenzie et al., 2003a). Critical swimming speed was calculated in both absolute (cm s^-1) and relative (BL s^-1) terms, as described by Brett (1964). Three fish from each experimental group swam in each of the two respirometers. Prior to actual experiments, preliminary U_crit tests were run on four, non-instrumented trout (two good swimmers, two poor swimmers) in both the PVC and steel respirometers. There were no systematic differences in either Ṁ_O2 or swimming performance linked to a particular respirometer (mean ± s.e.m.): AMR was 181±39 μmol kg^-1 min^-1 in the PVC tunnel and 195±37 μmol kg^-1 min^-1 in the steel tunnel, while U_crit was 2.45±0.28 BL s^-1 in the PVC tunnel and 2.40±0.21 BL s^-1 in the steel tunnel.

Measurements of cardiac output (Q̇) were made at each swimming speed. Data from the flow probe were acquired and displayed real-time on a PC with LabVIEW software (Axelsson et al., 2002). Measurements of dorsal aortic blood pressure (Pda) were also made at each speed by connecting the saline-filled DA cannula to a physiological pressure transducer (Statham P23XL, Statham Instruments, Oxnard, CA, USA), with the amplified (Gould Universal amplifier, Gould Instruments, Valley View, OH, USA) signal then acquired and displayed on the PC with LabVIEW software (Axelsson et al., 2002). Heart rate (fh) was calculated automatically from the flow probe signal, and used to derive cardiac stroke volume (Vs) (Gallaugher et al., 2001). Total systemic vascular resistance (R_sys) during swimming was calculated from the measurements of Q̇ and Pda (Gallaugher et al., 2001). Maximum values for Q̇, fh and Vs were identified from the cardiovascular measurements made at each swimming speed, as was the minimum value for R_sys. These extreme values always occurred at speeds near U_crit.

Arterial blood samples (100 μl) were collected from the DA cannula (and replaced with an equal volume of saline) at swimming speeds of 40 cm s^-1 and 80 cm s^-1, as well as just prior to fatigue (i.e. at U_crit). Arterial blood total O₂ content (Ca_O2) was measured using the method of Tucker (1967), as described in McKenzie et al. (2003b). The measurements of Ca_O2 and maximum Q̇ (see above) were then used to calculate maximum rates of arterial blood O₂ transport (Ṫ_O2), as described by Gallaugher et al. (2001).

In vitro perfused heart studies

The in vitro studies were performed on 15 fish (good swimmers: body mass=1148±63 g, ventricular mass=0.87±0.07 g; poor swimmers: body mass=1106±59 g, ventricular mass=0.92±0.08 g). The in situ heart preparation used to assess maximum cardiac performance has been described in detail by Farrell et al. (1986) and included the modifications outlined by Farrell et al. (1988). Briefly, fish were anaesthetised, transferred to an operating sling where their gills were irrigated with aerated buffered anaesthetic at 4°C, and injected with 0.6 ml of heparinised (100 IU ml^-1) saline via the caudal vessels. A stainless steel input cannula was secured into the sinus venosus through a hepatic vein and perfusion begun immediately with oxygenated saline containing a tonic level of adrenaline (5 nmol l^-1 adrenaline). Silk threads were used to occlude any remaining hepatic veins and the ducti Cuvier. A stainless steel output cannula was advanced into the ventral aorta until the tip was in the bulbus arteriosus and tied firmly in place. These procedures, which were completed in 15-20 min, isolated the heart in terms of saline input and output, while leaving the pericardium intact. The preparation was then immersed in a saline-filled, temperature-controlled organ bath at 16°C, where the input and output cannulae were attached to constant pressure heads. The heart was perfused with an oxygenated physiological saline (Farrell et al., 1988) and filling (input) pressure of the heart was adjusted to give a routine Q̇ of 25 ml min^-1 kg^-1 body mass. Mean output pressure was set at ∼5 kPa to simulate routine in vivo mean ventral aortic blood pressures (Stevens and Randall, 1967). The heart maintained this control level of performance for a period of 15-20 min before the assessment protocol began.

The maximum pumping ability of the heart was assessed first by measuring maximum Q̇ when filling pressure was increased (i.e. a Starling response) and then by increasing output pressure to 8 and 9 kPa to elicit an increase in cardiac power output while the heart continued to pump maximally. When rainbow trout swim, or when they are given an intra-arterial adrenaline injection, both Q̇ and diastolic ventral aortic pressure increase, but mean pressure rarely exceeds 8 kPa(Kiceniuk and Jones, 1977; Gamperl et al., 1994). The heart was then returned to the control perfusion conditions for a 15 min recovery and equilibration with a new adrenaline concentration (1 μmol l^-1) in the perfusate, which was then used to assess the effect of maximum adrenergic stimulation of the heart (see Mercier et al., 2000). The two adrenaline concentrations used (5 nmol l^-1 and 1 μmol l^-1) span the range for circulating catecholamine levels observed in resting and stressed trout, respectively (Milligan et al., 1989; Randall and Perry, 1992; Gamperl et al., 1994). An in-line Transonic flow probe (Transonic Systems, Ithaca, NY, USA) was used to record Q̇ (= ventral aortic flow in the output cannula). Pressures in the sinus venosus (input) and ventral aorta (output) were measured using DP6100 pressure transducers (Medizintechnik, Dusslingen, Germany), through saline-filled tubes placed at the tip of the cannulae. The pressure transducers were calibrated against a static water column for each preparation. Pressure and flow signals were amplified and filtered using a Model MP100A-CE data acquisition system (BIOPAC Systems Inc., Santa Barbara, CA, USA). The acquired signals were then analysed and stored using Acknowledge Software (BIOPAC Systems Inc., Santa Barbara, CA, USA) installed on a Dell laptop computer.

Myocardial power output (mW g^-1 ventricle mass) was calculated from the product of [Q̇ (ml min^-1)×(output-input pressure) (kPa)×(0.0167 min s^-1)]/ventricular mass (g)]. Ventricular mass was determined at the conclusion of the experiment when the cannulae were checked for correct positioning.

Physiological saline and chemicals

The physiological saline used for the perfused heart preparations (pH 7.8 at 15°C) contained (in mmol l^-1): NaCl 124, KCl 3.1, MSO₄.7H₂O 0.93, CaCl₂.2H₂O 2.52, glucose, 5.6 Tes salt 6.4 and Tes acid 3.6 (Keen and Farrell, 1994). The saline was equilibrated with 100% oxygen for at least 30 min prior to experimentation. The coronary artery, which supplies the outer compact myocardium of the ventricle, was not perfused and so oxygenated saline was used to ensure that a sufficient amount of oxygen diffused from the ventricular lumen to the compact myocardium. The oxygen gradient from the lumen to the myocardium of the perfused heart was at least 20-times greater than that in vivo. Preliminary experiments have shown that this rainbow trout heart preparation can perform maximally even when the oxygen tension is reduced to ∼8 kPa. Adrenaline bitartrate was purchased from Sigma-Aldrich (St Quentin-Fallavier, France).

Cardiac anatomy

In vivo cardiac morphology were assessed for an additional 9 fish per group (good swimmers: mass=1104±47 g, length=425±7 mm; poor swimmers: mass=1167±33 g, length=423±4 mm) using echo-Doppler imaging (Esaote-Pie Medical FalcoVet 100 scanner and 7.5 MHz probe, Fontenaysous-Bois, France; accuracy ±0.3 mm). Fish were lightly anaesthetised and placed in an operating sling where a hand-held probe provided a lateral image of the ventricle, bulbus arteriosus and ventral aorta. The image was stored and subsequently analysed. After calibration, the machine software allowed the measurement of ventricular height (H) and length (L), as well as the angle (α) subtended between the ventral aorta and the ventral surface of the ventricular wall (Fig. 1).

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Fig. 1.

A schematic diagram illustrating the measurements made during the echo-Doppler examination of the hearts. Ventricle length (L), ventricle width (W) and the angle (α) subtended between the ventral aorta and the ventral surface of the ventricular wall.

Data analysis and statistics

Comparisons between good and bad swimmers for single variables were performed using a Student t-test. The effect of swimming speed on in vivo variables was assessed and compared between the two groups using a two-way ANOVA with repeated measures. A probability less than 5% (P<0.05) was taken as the limit for statistical significance.

In vivo performance

Fish that swam poorly in the screening test had a significantly (27%) lower U_crit (both in absolute and relative terms) 9 months later (Table 2). Fig. 2 compares Ṁ_O2 and cardiovascular variables during the U_crit protocol for good and poor swimmers. There was no difference in derived IMR (Table 2). Oxygen uptake increased significantly with each increase in swimming speed in both groups, and at common speeds there were no significant differences between the good and poor swimmers (Fig. 2). However, the good swimmers achieved a significantly 19% higher AMR by achieving a higher U_crit and, consequently, had a significantly 24% higher aerobic scope (Table 2).

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Fig. 2.

A comparison of mean M_O2 and cardiovascular variables during sustained swimming in adult rainbow trout that had been screened as good or poor swimmers 9 months earlier. The mean values are shown only for those speeds at which measurements were collected for all of the animals in each group, i.e. up to 80 cm s^-1 in poor swimmers and up to 110 cm s^-1 in good swimmers. Values are means ± s.e.m., N=6. Asterisks above the abscissa denote a significant change in the variable relative to a swimming speed of 30 cm s^-1 within either the good (blue) or bad (red) swimmers. There were no significant differences in any variable when compared between good and bad swimmers at any common swimming speed.

Swimming significantly increased Q̇ and, at any common speed, Q̇ was similar in both good and poor swimmers (Fig. 2). However, maximum Q̇ was significantly (30%) higher for the good swimmers (Table 2). fh and Vs increased significantly in both groups during swimming and in both groups the increase in Q̇ during swimming was predominantly a result of increased Vs rather than fh (Fig. 2). Nevertheless, the maximum values of fh and Vs were not significantly different between the good and poor swimmers (Table 2). Both groups of fish maintained Pda during exercise (Fig. 2), but the decrease in R_sys induced by exercise (Fig. 2) was significantly (35%) greater in good vs poor swimmers (Table 2).

The oxygen content of arterial blood did not differ significantly between good and poor swimmers and was unchanged during the exercise protocol when measured at 40 cm s^-1 and 80 cm s^-1, which was just prior to fatigue for the poor swimmers. The resting and two exercise values for Ca_O2 were averaged for each fish prior to calculating the group mean for Ca_O2 (Table 2). Maximum Ṫ_O2 was significantly (39%) higher in good swimmers compared with poor swimmers, as a direct result of the former group's higher maximum Q̇ (Table 2).

In vitro performance

Under tonic adrenergic stimulation, maximum Q̇ was not statistically different between the good and poor swimmers (48.0±2.7 ml min^-1 kg^-1 and 42.2±2.3 ml min^-1 kg^-1, respectively; Fig. 3). Maximum stimulation with adrenaline (1 μmol l^-1) significantly increased maximum Q̇ in both good and poor swimmers, but that increase was significantly greater in good swimmers than in poor swimmers (maximum Q̇ increased to 56.4±2.3 ml min^-1 kg^-1 and 45.9±1.9 ml min^-1 kg^-1, respectively). Under control (tonic adrenergic stimulation) conditions, fh was similar for good and poor swimmers, as was the modest elevation in fh produced by maximum adrenergic stimulation (an increase from 87.1±5.4 beats min^-1 to 100.9±3.9 beats min^-1 in poor swimmers and from 89.1±4.4 beats min^-1 to 97.5±2.8 beats min^-1 in good swimmers). Similarly, Vs was not statistically different between the two swim groups under tonic adrenergic stimulation (0.54±0.03 ml in good swimmers vs 0.49±0.03 ml in poor swimmers). However, under maximum adrenergic stimulation, Vs increased significantly in good swimmers (0.58±0.02 ml), whereas it decreased significantly in poor swimmers (0.46±0.03 ml). Thus, the maximum cardiac pumping ability of poor swimmers was significantly (26%) lower than that of good swimmers.

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Fig. 3.

Comparison of maximum cardiac performance of in situ perfused hearts from rainbow trout that had been screened as good or poor swimmers 9 months earlier. ^*A significant effect of increasing adrenaline (ADR) within a group; ^†significant difference (P<0.05) between two groups of fish under common conditions. Values are means ± s.e.m., N=8 good swimmers; N=7 poor swimmers.

Cardiac power output was calculated from the product of Q̇ and output pressure. The effect of increasing output pressure while the heart was pumping maximally is shown in Fig. 4. Overall, cardiac power output in good swimmers was significantly higher than in poor swimmers. When output pressure was progressively raised from 8 kPa to 9 kPa, power output was unchanged in good swimmers. In contrast, the same increase in output pressure from 8 kPa to 9 kPa in poor swimmers resulted in a significant decrease in power output from 4.77±0.97 mW g^-1 to 3.96±0.58 mW g^-1, which was 32% lower than the 5.97 mW g^-1 for good swimmers. Thus, the hearts from poor swimmers were less able to tolerate a high cardiac afterload compared with good swimmers, as well as having a lower maximum Q̇.

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Fig. 4.

Comparison of maximum power output as output pressure was raised in rainbow trout in situ perfused hearts from rainbow trout that had been screened as good or poor swimmers 9 months earlier. Both swim group and output pressure are significant determinants of power output (ANOVA; P<0.05) and no interaction between the factors was found. ^†Pairwise multiple comparisons confirmed the significant difference between good (blue) and poor (red) swimmers at the highest output pressure (9 kPa) as well as the significant drop in power output between 8 and 9 kPa in the poor swimmer group. Values are means ± s.e.m., N=8 good swimmers; N=7 poor swimmers.

Cardiac anatomy

The ventricle was significantly longer in good swimmers compared with poor swimmers, although there were no differences in ventricular width or the subtended angle (Table 3). As a result, the ventricular length to width ratio was smaller in the poor swimmers (Table 3).