|
| |
|
|
|
|
||||
| Home Help Feedback Subscriptions Archive Search Table of Contents | ||||
First published online June 29, 2007
Journal of Experimental Biology 210, 2574-2584 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.004028
Cardiac remodelling in rainbow trout Oncorhynchus mykiss Walbaum in response to phenylhydrazine-induced anaemia
Department of Biological Sciences, 8888 University Drive, Simon Fraser University, Burnaby, BC, V5A 1S6, Canada
* Author for correspondence at present address: Department of Zoology and Faculty of Land and Food Systems, 6270 University Boulevard, University of British Columbia, Vancouver, BC, V6T 1Z4, Canada (e-mail: farrellt{at}interchange.ubc.ca)
Accepted 2 May 2005
 |
Summary |
|---|
 TOP Summary IntroductionMaterials and methodsResultsDiscussionReferences |
|---|
) was continuously
monitored following a single PHZ injection to examine the initial cardiac
response to anaemia. Contrary to expectations, acute anaemia did not produce
an immediate, proportionate increase in routine
. In fact,
did not increase significantly until
Hct had decreased to 10%, suggesting that rainbow trout may initially rely on
venous oxygen stores to compensate for a reduced arterial oxygen-carrying
capacity. Thus, we conclude that myocardial oxygenation, acclimation
temperature and cardiac work load could all influence anaemia-induced cardiac
remodelling in rainbow trout.
Key words: cardiac remodelling, compact myocardium, anaemia, temperature acclimation, heart
|
Introduction |
|---|
|
TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
|---|
) among fishes is unusually large among vertebrates. This
interspecific variability can be linked directly to both cardiac workload and
volume output of the heart. For example, while the large ventricle in tuna
supports a high cardiac output () and
a high ventral aortic blood pressure
(Farrell, 1991;
Brill and Bushnell, 2001), the
proportionally similarly sized ventricle of haemoglobin-free Antarctic icefish
supports an equally high but only a
low ventral aortic blood pressure
(Axelsson, 2005).
Fish hearts also show remarkable plasticity
(Gamperl and Farrell, 2004).
For salmonids, cardiac remodelling (changes in mass, geometry and composition)
(Smits et al., 1991) occurs in
response to exercise-training (Hochachka,
1961; Greer-Walker and
Emerson, 1978), sexual maturation
(Franklin and Davie, 1992b;
Davie and Thorarensen, 1997;
Clark and Rodnick, 1999), acute
anaemia (McClelland et al.,
2005) and cold acclimation
(Farrell et al., 1988;
Graham and Farrell, 1989;
Taylor et al., 1996). In fact,
sexual maturation in male rainbow trout Oncorhynchus mykiss imparts a
very strong remodelling signal that can double relative ventricular mass
(rMV) (Franklin and
Davie, 1992b; Clark and
Rodnick, 1999). By comparison, cold-acclimation, exercise-training
and acute anaemia can increase rMV by 10–50%
(Hochachka, 1961;
Greer-Walker and Emerson,
1978; Farrell et al.,
1988; Graham and Farrell,
1989; Davie and Thorarensen,
1997; McClelland et al.,
2005). In addition to ventricular enlargement, the relative
proportions of the two muscle types in the salmonid ventricle (outer compact
and inner spongy myocardium) can change during cardiac remodelling. For
example, the percentage of outer compact myocardium in the ventricle increases
preferentially during sexual maturation and warm acclimation
(Tota et al., 1983;
Farrell et al., 1988;
Graham and Farrell, 1992;
Clark and Rodnick, 1998), as
well as during the early stages of growth in Atlantic salmon Salmo
salar (Poupa et al.,
1974). Ventricular geometry can also change, for example salmonids
respond to a culture environment with a more rounded (see
Gamperl and Farrell, 2004) and
smaller ventricle (Graham and Farrell,
1989) compared with their wild counterparts.
Here we perform the first comprehensive characterisation of the nature,
extent and timing of ventricular remodelling in rainbow trout during chronic
anaemia and therefore extend a previous acute study in which
phenylhydrazine-induced anaemia produced a 30% increase in
rMV (McClelland et
al., 2005). Given that rMV doubles with
chronic anaemia in juvenile rats and sexual maturation in rainbow trout
(Poupa et al., 1974;
Franklin and Davie, 1992b;
Clark and Rodnick, 1999), we
suspect that the full extent of anaemia-induced ventricular remodelling has
yet to be established for rainbow trout. We also performed the first direct
measurements of during acute anaemia.
This was important for two reasons. Foremost, previous studies have relied on
the Fick Principle to estimate
(Cameron and Davis, 1970;
Holeton, 1971;
Wood et al., 1979). Second,
while anaemia reduced arterial oxygen-carrying capacity sixfold, this was
accompanied by only a threefold increase in the estimated
(Cameron and Davis, 1970).
Therefore, we wished to determine whether the initial increase in
was proportionate to the initial
decline in haematocrit (Hct).
|
Materials and methods |
|---|
|
TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
|---|
, Hct and haemoglobin concentration
([Hb]) to a single injection of phenylhydrazine hydrochloride (PHZ) on rainbow
trout Oncorhynchus mykiss Walbaum was conducted at the University of
British Columbia. Rainbow trout were obtained from Aquafarm JV (Fort Langley,
BC, Canada) and held in indoor fiberglass tanks with flow-through
dechlorinated municipal water at 6°C for several months prior to the
study. Body mass (Mb; mean ± s.e.m.) was
1045±113 g, fork length (FL) was 40.1±1.5 cm and the
condition factor [(Mb/FL3)100] was
1.51±0.07 (N=5 fish). Studies of chronic anaemia, using repeated injections of PHZ, focused on cardiac remodelling and recovery from anaemia in both warm- and cold-acclimated rainbow trout. Rainbow trout were obtained from Sun Valley Trout Hatchery (Mission, BC, Canada) and held at Simon Fraser University in indoor fiberglass tanks with flow-through, dechlorinated municipal water. The study with warm-acclimated fish took place from August through October, when the water temperature during the experimental anaemia period averaged 17.6°C (ranging between 17.0°C and 18.3°C), followed by a seasonal decrease from 15°C to 12°C during the last 4 weeks of the experiment while the fish were recovering from anaemia. Mb was 135.9±2.9 g, FL was 21.1±0.1 cm and condition factor was 1.43±0.02 (N=144 fish). The study with cold-acclimated fish took place from February through April, when the water temperature averaged 6.4°C (ranging between 6.0°C and 7.0°C). Mb was 96.6±2.6 g, FL was 19.1±0.2 cm and condition factor was 1.35±0.02 (N=90 fish).
All fish were fed a maintenance diet of trout pellets (Aquafeed Limited; Chilliwack, BC, Canada) and were kept on a seasonal light:dark cycle. The experimental protocols were approved by the respective Animal Care Committees at Simon Fraser University and the University of British Columbia in accordance with the Canadian Council on Animal Care.
Considerations for PHZ injections
An intraperitoneal injection of 10.0–12.5 µg PHZ
g–1 Mb causes a well-characterized
transient haemolytic anaemia in fish, with haematocrit decreasing by
75–80% within 2–4 days (Smith
et al., 1971; Chudzik and
Houston, 1983; McClelland et
al., 2005). Recovery occurs within a week at a high temperature,
but not necessarily at low temperatures
(Cameron and Davis, 1970;
Byrne and Houston, 1988;
McClelland et al., 2005). We
are unaware of any study that has induced chronic anaemia with repeated PHZ
injections. Therefore, we conducted a pilot study with three rainbow trout to
evaluate the erythropoietic response to weekly PHZ injections (10 µg
g–1 dissolved in 100 µl kg–1
Mb of physiological saline). Hct partially recovered with
weekly PHZ injections and the sensitivity to PHZ decreased following several
injections, requiring PHZ dosage to be doubled to create a comparable decrease
in Hct. Given the concern that weekly injections could cause undue stress and
the need to progressively increase the PHZ dosage, we used a bi-weekly
injection protocol and doubled the PHZ dosage, as needed, to generate a state
of functional anaemia for 1–2 months (i.e. overall Hct was <18% but
fluctuated). Hct values for normocythemic rainbow trout are reported to range
from 17% to 44% (Wells and Weber,
1991), but rainbow trout are functionally anaemic when Hct is
<22% (based on a depression of swimming performance)
(Gallaugher et al., 1995).
Experimental protocols
Effects of acute anaemia on cardiac output
, Hct and [Hb] were monitored in
rainbow trout before and for up to 4 days following a single injection of PHZ.
Fish were prepared for these experiments by placing a Transonic flowprobe
(Transonic Systems, Ithaca, NY, USA) on the ventral aorta
(Farrell and Clutterham, 2003)
to measure . This method makes a small
incision in the isthmus anterior of the pericardium, thereby leaving the
pericardium intact. Also, a polyethylene (PE50) cannula was inserted into the
dorsal aorta for blood sampling. Fish were placed in mesh tubes within a 200 l
tank to recover and restrict activity. Following a 24 h recovery period,
and heart rate
(fH) were recorded on Labview software (National
Instruments, Ottawa, Ontario, Canada) for 10 min in the morning, and then
again at noon and in late afternoon. Cardiac stroke volume
(VS) was calculated from
and fH
measurements. Cardiovascular variables were averaged for each 10 min period
and these data were pooled to generate a value representative of the
normocythemic, routine cardiac status of each fish (excluding data
measurements for visibly active fish during the recording period). Following
the final recording for normocythemic fish, a blood sample (200 µl) was
withdrawn from the cannula into a heparinized syringe and replaced with 200
µl of heparinized physiological saline. Hct was determined (as described
below) and the remaining blood was frozen in heparinized vials for later [Hb]
determination by standard cyanmethaemoglobin assay (Sigma Diagnostics, St
Louis, USA). Fish were lightly anaesthetized in 0.1 g l–1 of
buffered MS-222 (0.1 g l–1 sodium bicarbonate and 0.1 g
l–1 tricaine methanosulfonate) and quickly injected
intra-peritoneally with PHZ (20 µg g–1
Mb in 100 µl kg–1
Mb in physiological saline). The injection procedure
lasted less than 2 min. Cardiac variables, [Hb] and Hct were monitored for up
to 4 days while Hct decreased. At the termination of the experiment, fish were
euthanized by anaesthetic overdose and the ventricle excised and measured (see
below).
Effects of chronic anaemia in warm-acclimated fish
There were four experimental treatment groups of warm-acclimated (17°C)
rainbow trout: sham-injected fish; PHZ-treated fish; chased sham-injected
fish; and chased PHZ-treated fish. Each group of fish was placed into an
adjacent 140 l tank for 2 weeks prior to starting injection and chasing
protocols. Fish were injected bi-weekly over an 8-week period (on four
occasions) and were then allowed to recover for a further 4 weeks. Each fish
was individually netted and anaesthetized in 0.1 g l–1 of
buffered MS-222, weighed and injected intra-peritoneally with either PHZ (10
µg g–1 Mb in 100 µl
kg–1 Mb) or physiological saline (100
µl kg–1 Mb of physiological saline).
Because anaemic fish could respond differently to the stress of handling than
normocythemic fish, two of the groups (PHZ-injected and sham-injected) were
additionally chased daily to deliberately increase their level of stress and
activity. The chasing protocol followed the procedures described by Perry et
al. (Perry et al., 1996). Fish
were individually netted, placed in a separate tank, where they were chased
with a net (and with additional prodding as needed because the fish quickly
became accustomed to the net), before being placed into a holding tank while
the remainder of the group was chased. Chasing was intended to increase
cardiac work and not necessarily exhaust the fish, therefore it lasted either
2 min or until the fish became refractory to prodding. This protocol was
approximately five-times shorter than routine protocols used to induce
complete exhaustion (Milligan,
1996). Anaemic fish were notably less willing (or able) than
normocythemic fish to swim vigorously for 2 min.
Fish were injected at weeks 0, 2, 4 and 6. Following the first PHZ
injection, fish displayed a yellow discolouration of the body, as previously
reported by Smith et al. (Smith et al.,
1971). The first two PHZ injections were at a dose of 10 µg
g–1 Mb, while the last two were 20 µg
g–1 Mb. Following week 8, fish were
allowed a 4-week recovery period without any Hct sampling or chasing. Final
sampling occurred at week 12. There were 13 mortalities among the anaemic fish
(six PHZ-treated fish and seven chased PHZ-treated fish) during the first 3
weeks of the experiment, but none thereafter. One sham-injected fish jumped
from its tank and died. A water supply problem prematurely terminated the
entire chased PHZ-treated group just prior to week 12, precluding any data for
the recovery of this group.
Effects of chronic anaemia in cold-acclimated fish
The PHZ and sham injections with cold-acclimated fish (6°C) replicated
those performed on warm-acclimated fish. However, given that chasing produced
no additive effects in warm-acclimated fish and that significant cardiac
remodelling had occurred after 4 weeks of anaemia (see Results), animal care
considerations required us to reduce fish usage by eliminating the chased fish
groups and restrict the chronic anaemic period to 4 weeks followed by a 4-week
recovery period. Sample size was increased to N=10 fish per sample
date per test group. Fish were sampled at weeks 0 (pre-treatment control), 4
and 8. In view of the sham injection eliciting a modest cardiac response in
warm-acclimated fish, we also included an untreated group of fish that were
not handled whatsoever, except for blood and tissue sampling. One fish died
following the first PHZ injection.
Tissue sampling procedures during the chronic studies
Fish were sacrificed for cardiac and blood samples at the same time as the
injections were performed, i.e. at weeks 0 (pre-treatment control), 2, 4, 6
and 8, and at the termination of the experiment, i.e. weeks 8 and 12. To
monitor Hct between injections, blood was sampled 3–7 days later. On
days when cardiac tissue was sampled, fish from each group were individually
netted and anaesthetized. A blood sample (100 µl) was withdrawn by caudal
puncture and Hct determinations (Readacrit centrifuge, Becton Dickinson, NJ,
USA) were made in triplicate. Given the large number of fish used in the
study, the difficulty of maintaining an indwelling cannula clot-free much
beyond a week, and the unknown chronic effects of heparin on cardiac
remodelling and erythopoiesis, we opted to obtain blood by caudal puncture.
While this blood sampling method can increase Hct due to red blood cell
swelling and splenic release of red blood cells
(Perry and Gilmour, 1996), the
effect is small relative to the level of experimental anaemia that was induced
and represented a consistent overestimate of Hct throughout the study.
Following blood sampling, fish were euthanized by cervical dislocation,
weighed and measured. The ventricle, spleen and gonads were removed through a
mid-ventral incision along the abdomen between the pelvic and pectoral
girdles. The ventricle was blotted dry, wet mass determined to a precision of
0.1 mg and placed into 70% ethanol for later dissection. The spleen was
weighed immediately and discarded, while gonads were inspected for sexual
maturity. As peak anaemic response is reported to occur 2–3 days
following PHZ injection (Smith et al.,
1971; Chudzik and Houston,
1983; Byrne and Houston,
1988; McClelland et al.,
2005), three fish were individually netted and anaesthetized as a
sub-sample from each treatment group to monitor the Hct after the PHZ
injection. The blood sample was replaced with 100 µl of heparinized saline
(100 IU ml–1), the fish was marked with a pectoral fin clip
to prevent repeated sampling of any individual, revived and returned to the
tank.
The ventricle was separated into its compact and spongy myocardial layers
using blunt dissection under a dissection microscope, a simple procedure after
tissue fixation with ethanol because of the presence of a thin fibrous
membrane between the two tissue layers
(Poupa and Carlsten, 1973;
Farrell et al., 2007).
Separated tissue samples were then desiccated to a constant mass (3 days at
65°C) and weighed to a precision of 0.1 mg. Compact myocardial mass was
expressed as a percentage of the total dry mass of the ventricle. Percentage
water content of the ventricle was determined from the difference between the
wet and dry masses. Relative ventricular and myocardial masses (both wet and
dry) are reported as a percentage of body mass.
Statistical analysis
All data are reported as a mean ± standard error of the mean
(s.e.m.). In the cardiac remodelling experiments, comparisons with the
pre-treatment control for each treatment group were analyzed by ANOVA and a
Dunnett's post-hoc test. Time-matched comparisons between PHZ-treated
fish and sham-injected and untreated control fish also used ANOVA.
Cardiorespiratory variables during acute anaemia were compared using
repeated-measures ANOVA and a Tukey–Kramer multiple-range test. The
level of significance for all statistical analyses was P<0.05. All
statistical analyses were conducted using JMP 5.0 software (SAS Institute
Inc., Cary, NC, USA), except the repeated-measures ANOVA, which was conducted
on SigmaStat 3.0 software (SPSS, Chicago, IL, USA).
|
Results |
|---|
|
TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
|---|
and Hct are summarized in
Fig. 1 and
Table 1. There was a linear
correlation between [Hb] and Hct over a wide range of Hct values
(Fig. 1 inset). However,
did not increase proportionally as
Hct decreased (Fig. 1). While
Hct and [Hb] were reduced sixfold at the termination of these acute
recordings, had barely doubled
(Table 1). In fact,
did not increase significantly until
Hct fell below 10% (Table 1)
and the increase in lagged behind the
decrease in Hct during the first 40 h of anaemia. In some individuals, Hct
decreased by as much as 50% within 9 h of the PHZ injection without a major
increase in
(Fig. 1). Anaemia did not alter
fH (Table
1) and the final compensatory increase in
was through increased
VS, which would have increased ventricular stretch because
rainbow trout increase VS by increasing end-diastolic
volume rather than decreasing end-systolic volume
(Franklin and Davie, 1992a).
The rMV was 0.146±0.010% and the percentage of
compact myocardium was 40.1±1.5%.
|
|
Effects of chronic anaemia on warm-acclimated trout
Haematology
For sham-injected, warm-acclimated fish, Hct averaged 33.2±1.1%
(N=49 fish; Fig. 2)
for the entire 12-week experiment. Daily chasing had no significant effect on
this Hct (31.1±1.0%; N=49 fish; bi-weekly data are not shown).
Pooling these two data sets yielded a control Hct of 32.1±0.8%
(N=98 fish) for the 12-week experiment.
|
Similar to the acute anaemia experiment, a PHZ injection depressed Hct with a partial recovery after 2 weeks (Fig. 2). Bi-weekly PHZ injections then resulted in an 8-week period of anaemia such that Hct averaged 17.7±2.0% (N=49 fish) for PHZ-treated fish during this treatment period. Again, chasing had no significant effect on Hct of PHZ-treated fish (17.0±2.1%; N=37 fish; data are not shown). Pooling these two data sets yielded an Hct of 17.4±1.8% for PHZ-treated fish (N=86 fish), a value almost half the control Hct (P<0.05).
The recovery period (between weeks 8 and 12) resulted in Hct reaching 28.6±1.7% (N=6 fish) in PHZ-treated fish, a value that was not significantly different (P>0.05) from the control Hct at week 12 (29.0±1.6%; N=6 fish; Fig. 2; Table 2). Similar results were obtained for the chased fish groups (data are not shown). These recovery values at week 12 were marginally 10% lower (P<0.05) than the Hct at the outset of the experiment.
|
Ventricular remodelling
PHZ injections in warm-acclimated fish resulted in significant
(P<0.05) increases in rMV at all bi-weekly
sample dates when compared with sham-injected fish
(Table 2). In fact, by the
second week of anaemia, rMV was 40% greater than
sham-injected fish. After 8 weeks of chronic anaemia, rMV
was 58% greater than the sham-injected fish and 84% greater than the
pre-treatment control fish (Fig.
3A). Compared with the pre-treatment control value of
0.086±0.002%, sham injections significantly (P<0.05)
increased rMV at week 4 (by 20%) but at no other time
(Fig. 3A). As with Hct, chasing
of anaemic fish had no significant effect on rMV of either
sham-injected or PHZ-treated fish (data not shown).
|
Cardiac water content remained unchanged throughout treatment and recovery [87.8±0.2% and 87.2±0.2% for PHZ-treated (N=30 fish) and sham-injected (N=30 fish) groups, respectively] compared with pre-treatment control fish (87.6±0.6%; N=6 fish). As a result, a significant (P<0.05) linear relationship existed between wet rMV and dry rMV (Fig. 3B). Thus, alterations in ventricular water content cannot explain the considerable ventricular remodelling observed with chronic PHZ-induced anaemia. In fact, the changes in dry rMV (Fig. 4) paralleled those observed for wet rMV, increasing significantly (P<0.05) by 40% after 8 weeks of chronic anaemia and being unchanged in sham-injected fish. Chasing fish had no effect the responses of dry rMV (data not shown).
|
Effects of chronic anaemia on cold-acclimated fish
Haematology
For cold-acclimated fish, PHZ injection significantly (P<0.05)
decreased Hct from 38.6±1.1% to 12.0±2% after 3 days, and Hct
averaged 8.8±1.9% for the 4-week period. In untreated and sham-injected
fish, Hct remained unchanged except for a modest 10% decrease
(P<0.05) at week 8. Hct recovered almost fully in PHZ-treated fish
(28.1±1.5%) after the 4–week recovery period, but was about 20%
lower than the final Hct for sham-injected and untreated fish
(Table 3). This incomplete and
reduced rate of recovery for Hct was a clear difference between the
cold-acclimated and warm-acclimated fish.
|
While splenic mass increased significantly (P<0.05) after 4 weeks in the untreated and sham-injected groups, this increase was significantly larger in anaemic fish and represented a doubling of splenic mass compared with the outset of the experiment (Table 3). Consistent with a lag in the recovery of Hct, the enlarged splenic mass persisted in the PHZ-treated fish during recovery (Table 3).
Ventricular remodelling
For sham-injected fish, rMV increased
(P<0.05) by 18% after 4 weeks compared with the outset of the
experiment, but returned to the control level during the 4-week recovery
period (Fig. 5A). For
PHZ-treated fish, rMV increased 17% more than
sham-injected controls (P<0.05) and was 35% larger
(P<0.05) than the pre-treatment control fish
(Fig. 5A). This PHZ-induced
ventricular enlargement persisted during the recovery period
(Fig. 5A). For untreated
control fish, both wet and dry rMV remained unchanged
during the experiment (Fig. 5A
and Fig. 6).
|
|
In cold-acclimated anaemic fish, ventricular remodelling after 4 weeks was largely accounted for by a significant (P<0.05) increase in compact myocardium (Fig. 6). As a result, the percentage of compact myocardium significantly (P<0.05) increased from 29.4±1.8% to 37.0±1.5% after 4 weeks of anaemia (Table 3). Consequently, while cold-acclimated rainbow trout normally have a lower (P<0.05) percentage of compact myocardium than warm-acclimated rainbow trout (32.2 and 37.3%, respectively), chronic anaemia eliminated this difference.
|
Discussion |
|---|
|
TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
|---|
), including fish
(Cameron and Wohlschlag, 1969;
Cameron and Davis, 1970;
Jones, 1971;
Smith and Jones, 1982;
Chudzik and Houston, 1983;
Houston and Keen, 1984;
Murad et al., 1990;
Marinsky et al., 1990;
Gilmour and Perry, 1996;
McClelland et al., 2005). PHZ
causes oxidative haemolysis of red blood cells and, despite its widespread
usage in piscine studies, has no reported side effects
(Cameron and Wohlschlag, 1969;
Cameron and Davis, 1970;
Smith et al., 1971;
Chudzik and Houston, 1983;
Houston and Keen, 1984;
Murad et al., 1990;
Marinsky et al., 1990;
Gilmour and Perry, 1996;
McClelland et al., 2005),
other than those directly related to the anaemia itself. A single study on
anaemic rats reported that the observed increase in coronary flow during
cardiac contractions following PHZ treatment was prevented by an antioxidant,
as well as reducing focal lesions in the muscle and the degree of hypertrophy
(Meerson and Evsevieva, 1985).
Also in rats, a single PHZ injection caused leukocytosis, perhaps as a result
of a PHZ stimulation of lymphoid blastogenesis, which then could have served
to more rapidly remove from the circulation red blood cells whose membranes
had been damaged by PHZ (Dornfest et al.,
1990). In view of this information, we assume here that the
cardiac remodelling was in response to chronic anaemia and side-effects were
minimal.
Injection of PHZ requires fish handling, which we controlled for by using
untreated fish, sham-injections and a parallel set of experiments in which
fish were additionally chased to increase the level of handling stress. Given
the large number of fish that were used, the long durations of the experiments
and the small size of many fish studied (<200 g), it was not feasible to
cannulate blood vessels to sample blood except in the acute experiments that
measured . Given that caudal puncture
can overestimate Hct compared with Hct values derived from cannulated fish
(Gallaugher and Farrell,
1998), the level of chronic anaemia we have reported here likely
overestimated the true Hct of the fish in a small and consistent manner.
The present study demonstrated that repeated PHZ injections can be used to
produce chronic anaemia, which was then associated with cardiac remodelling in
both warm- and cold-acclimated rainbow trout. An earlier study with
warm-acclimated rainbow trout demonstrated that a single injection of PHZ,
causing temporary anaemia (Hct=10%), increased rMV by 30%
after 2–4 weeks (McClelland et al.,
2005). In the present study we established that, after about 8
weeks of chronic anaemia, the ventricle of warm-acclimated rainbow trout was
enlarged by nearly 60%, i.e. twice the growth observed previously. Thus, the
present study suggests that the full extent of ventricular remodelling to
anaemia was not revealed in earlier studies. Whether more stable and longer
anaemic periods than used here would double rMV, as
reported for sexual maturation in male rainbow trout, will need further
study.
Absent from an earlier study
(McClelland et al., 2005) were
appropriate controls to eliminate the possibility of changes in cardiac water
content and injection effects accounting for the ventricular enlargement. In
the present study, we eliminated the possibility of significant changes in
cardiac water content affecting the estimate of ventricular enlargement based
solely on wet mass with the finding that there were similar changes in cardiac
dry and wet masses during ventricular remodelling. However, we did discover a
modest but significant sham-injection effect, which could mean that McClelland
et al. overestimated the extent of cardiac remodelling due to anaemia per
se (McClelland et al.,
2005). The nature of this sham injection effect on
rMV is unclear since chasing fish did not alter the
response to anaemia. Increased activity in mammals similarly has been shown
not to alter the response to anaemia
(Magosso and Ursino,
2004).
The stimulatory effect of cold-acclimation on rMV is
well recognized for rainbow trout (Farrell
et al., 1988; Graham and
Farrell, 1989; Taylor et al.,
1996) and other fishes (Kent
and Prosser, 1985; Tsukuda et
al., 1985; Goolish,
1987). McClelland et al.
(McClelland et al., 2005)
observed a 24% increase in rMV in rainbow trout during a
seasonal decrease in water temperature from 12°C to 2°C. However,
cold-acclimation also completely attenuated erythropoiesis in goldfish, since
Hct recovery was absent after several months at 7.5°C and yet took only
several days at 30°C (Chudzik and
Houston, 1983). The present study demonstrates that both
erythropoiesis and cardiac remodelling were attenuated by cold-acclimation
since equivalent PHZ injections in cold-acclimated fish resulted in a lower
average Hct 3 days following injection (8.8±1.9%) and a smaller
increase in rMV within 4 weeks (17% compared with
sham-injected fish) compared with warm-acclimated fish. In the present study
we showed that Hct completely recovered after 4 weeks in warm-acclimated fish,
but only partially recovered in cold-acclimated rainbow trout even though
splenic enlargement persisted. Attenuation of anaemia-induced cardiac
remodelling in cold-acclimated rainbow trout is a novel finding that was
surprising given that the level of anaemia was about twice that in
warm-acclimated fish. This diminished cardiac remodelling response could
reflect temperature-related reductions in whole animal metabolism and protein
synthesis (i.e. the ability to remodel tissues). Thus, it may take
cold-acclimated, anaemic rainbow trout more than 4 weeks to increase
rMV beyond 0.11%, or alternatively the anaemic signal may
not be strong enough for the ventricle to reach the rMV
(0.15%) observed for warm-acclimated rainbow trout.
Cardiac remodelling is thought to be of prime physiological importance to
compensate for changes in cardiac work
(Tota, 1983). Therefore, given
that the principle compensatory adjustment to anaemia in fishes is an
elevation of
(Cameron and Davis, 1970) with
blood pressure either remaining unchanged
(Cameron and Davis, 1970) or
decreasing (Wood et al.,
1979), chronic anaemia is an interesting experimental perturbation
to examine the physiological triggers for ventricular remodelling. These
triggers, with the exception of the role played by reproductive hormones
(testosterone and 17-
methyltestosterone)
(Davie and Thorarensen, 1997),
are poorly understood in fishes. Theoretically, anaemia-induced cardiac
remodelling could be triggered by increased cardiac flow work (through
increased ), increased cardiac stretch
(through increased cardiac stroke volume), reduced cardiac pressure work, or
some combination. However, direct measurements of
have never been measured in fish
during anaemia. Also, hypoxia could act as a potential trigger for
anaemia-induced cardiac remodelling because tissue oxygen extraction increases
appreciably during anaemia, lowering the venous oxygen tension encountered by
the heart (Wood et al., 1979),
while whole animal oxygen uptake and arterial oxygen saturation are maintained
(Cameron and Davis, 1970;
Wood et al., 1979;
Gilmour and Perry, 1996). The
present observations allow us to examine to what extent cardiac stretch and
cardiac hypoxia might have contributed to ventricular remodelling.
The present study is the first to directly measure the temporal lag between
the decrease in Hct and the compensatory increase in
. Hct had decreased to below 10% (i.e.
a threefold decrease in Hct) before
increased significantly. Moreover, the nearly twofold increase in
could not fully account for a sixfold
decrease in Hct after 4 days of anaemia. This finding is entirely consistent
with an earlier study using starry flounder, which showed that progressive
bleeding over a 4–14 day period did not trigger an increase in the Fick
estimate of until Hct fell below 5%
(Wood et al., 1979). Thus, the
increase in cardiac VS that was observed here during acute
anaemia (with no change in fH) is not only consistent with
earlier observations of acute anaemia in fish
(Cameron and Davis, 1970;
Wood et al., 1979) (but see
Holeton, 1971), but also
consistent with cardiac stretch (through an increase in end-diastolic volume)
being a trigger for remodelling. Mechanical stretch associated with
volume-loading of the heart through increasing
by VS is thought
to be major stimulus for ventricular remodelling in mammals
(Delcayre et al., 1988) and
fish (Clark and Rodnick, 1998).
All the same, the initial cardiorespiratory response to anaemia was not an
increase in VS and yet ventricular remodelling occurred
rapidly (more than half of the ventricular enlargement occurred within 2
weeks; Fig. 3A).
Given that the increase in after 5
days of anaemia never fully accounted for the decrease in Hct in terms of
arterial oxygen transport {Note: Hct and [Hb] are linearly related
(Cameron and Wohlschlag, 1969);
present study} and whole animal oxygen uptake does not change during anaemia
[(Cameron and Wohlschlag, 1969;
Cameron and Davis, 1970;
Wood et al., 1979;
Gilmour and Perry, 1996) but
see Holeton (Holeton, 1971)
for CO-induced anaemia], we conclude that tissue oxygen extraction likely
increased threefold. This change would decrease venous oxygen tension
considerably. A large decrease in venous oxygen tension is a very important
consideration for any fish because the oxygen supply of spongy myocardium is
derived from venous blood. In fact, the anemia-induced decrease in venous
oxygen tension in anaemic flounder (Wood
et al., 1979) and rainbow trout
(Holeton, 1971) to around 1
kPa resulted in the venous oxygen tension approaching the predicted minimum
gradient for adequate oxygen delivery to ventricular trabeculae
(Davie and Farrell, 1991).
Furthermore, hypoxia has emerged as a principle stimulus evoking
erythropoiesis and haemoglobin accumulation in fish
(Tun and Houston, 1986).
Therefore, future studies should consider cardiac hypoxia as a potential
trigger for anaemic remodelling despite the expectation that mechanical
stretch is the major stimulus.
If chronic anaemia has the potential to create a chronic hypoxic condition
for the spongy myocardium, chasing fish may have exacerbated this problem by
periodically reducing venous oxygen tension
(Farrell and Clutterham, 2003)
even further. However, we did not observe disproportionate cardiac remodelling
in warm-acclimated rainbow trout, but then anaemic fish were more lethargic
than normocythemic fish. Similarly, a hypoxic signal in anaemic fish might
trigger disproportionate growth of the compact myocardium because the arterial
blood supply to the compact myocardium has a higher oxygen partial pressure.
Conversely, the lower myocardial oxygen demands of spongy myocardium, combined
with its higher activities of oxidative enzymes than compact myocardium
(Tota et al., 1983;
Gamperl et al., 1994), could
compensate for the different levels of hypoxia experienced by the compact and
spongy myocardia. Interestingly, cold-acclimated rainbow trout differed from
warm acclimated fish by disproportionately increasing the percentage of
compact myocardium from 29% to 37%. Therefore cold-acclimated fish reached the
percentage of compact myocardium normally associated with warm-acclimated
rainbow trout. Therefore, it is possible that the more severe anaemia (8% Hct
vs 17% Hct) in cold-acclimated fish compared with the warm-acclimated
fish triggered a hypoxic response, as well as a mechanical response in the
compact myocardium. Studies on molecular signals in cardiac tissues during
anaemia would provide greater insight in this matter.
Quantitatively, the compensatory changes associated with anaemia have
theoretical limits. Normocythemic rainbow trout can increase both routine
and tissue oxygen extraction by about
threefold without reaching either maximum
or compromising oxygen supply to the
spongy myocardium (Farrell,
1984; Farrell,
2002; Farrell and Clutterham,
2003). Thus, the maximum decrease in Hct could be as much as
ninefold before routine oxygen uptake becomes compromised. Previously, routine
tripled during severe anaemia in
rainbow trout and flounder (Cameron and
Davis, 1970; Holeton,
1971; Wood et al.,
1979). However, direct measurements of
are needed to verify these earlier
Fick estimates because some of the
values were unrealistically high (see
Cameron and Davis, 1970). Here,
routine (18.3 ml
min–1 kg–1) was comparable to literature
values for rainbow trout at similar water temperature (17.6–18.0 ml
min–1 kg–1)
(Kiceniuk and Jones, 1977;
Gamperl et al., 1994) and
nearly doubled with a sixfold decrease in Hct. Also, we do not know to what
extent the anaemia-induced reduction in venous oxygen tension might compromise
maximum . In perfused rainbow trout
hearts, hypoxia compromises maximum performance
(Hanson et al., 2006), and a
hot temperature increases the hypoxic threshold
(Hanson and Farrell, 2007).
Such constraints might help explain why PHZ injections caused some mortality
in warm- but not cold-acclimated rainbow trout, and made fish lethargic when
chased. Holeton (Holeton,
1977) similarly found that tolerance to anaemia was inversely
related to water temperature and Cameron and Davis
(Cameron and Davis, 1970) found
that extreme levels of anaemia compromised swimming activity, just as we saw
here with the chasing protocol.
While a reasonable upper limit can be placed on the compensatory changes to
anaemia for routine and tissue oxygen
extraction, the limit to cardiac plasticity in rainbow trout is less clear. A
doubling of rMV is certainly possible with sexual
maturation for male rainbow trout and rMV has reached
0.18–0.27% (Davie and Thorarensen,
1997; Clarke et al.,
2004). Also, implants of 17- methyltestosterone induced a
70% increase in ventricular mass and a 60% increase in atrial mass of mixed
sex juvenile rainbow trout [testosterone implants had a somewhat reduced
effect (Davie and Thorarensen,
1997)]. Why the hearts of both sexes respond to androgenic
implants and to anaemia (the present experiments also combined males and
females), but only male rainbow trout hearts respond to sexual maturation is
unclear. However, mature male rainbow trout are hypervolemic, have a resting
bradycardia and show systolic hypotension
(Clark and Rodnick, 1999).
Thus, for rainbow trout, mechanical factors (including stretch and afterload),
androgens and venous hypoxemia are all potential triggers for cardiac growth,
but how they interact is unclear even though it has been thought that anaemia
and androgens may have additive effects on cardiac remodelling
(Davie and Thorarensen, 1997).
Temperature clearly has a modulating influence.
A large ventricle, high VS and low Hct are features
normally found in other fishes. The haemoglobin-free notothenioids have an
exceedingly high rMV (0.4%)
(Tota et al., 1991;
Axelsson, 2005), which is
similar to that of small mammals. Other notothenioids such a Pagothenia
borchgrevenski maintain a low Hct, which can double during strenuous
exercise (Axelsson, 2005).
Thus, in an evolutionary context, anaemia, together with low temperature, may
have been contributing factors in shaping the variability seen in cardiac
morphology among fishes. Recently, Sidell and O'Brien suggested that the
unusual cardiorespiratory modifications seen in Antarctic fishes result from
NO-stimulated morphogenesis because there is no Hb to sequester NO
(Sidell and O'Brien, 2006).
Experiments are currently underway to test whether NO inhibitors restrict
cardiac enlargement in anaemic rainbow trout. Even so, flounder are similarly
characterized by a low Hct compared with rainbow trout, ranging from
4.3–34.6% (mean 20%, mode 26%) in wild populations
(Wood et al., 1979;
Cech et al., 1976) and although
they have an unusually large cardiac VS, their
rMV is about half that found in rainbow trout
(Joaquim et al., 2004).
Clearly, much remains to be discovered regarding the factors determining
genotypic and phenotypic variability in ventricular size among fishes, in
addition to determining the exact triggers and extent of cardiac remodelling
possible.
List of abbreviations
|
Acknowledgments |
|---|
|
References |
|---|
|
TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
|---|
Axelsson, M. (2005). The circulatory system and its control. In The Physiology of Polar Fishes (Fish Physiology Series). Vol. 22 (ed. A. P. Farrell and J. F. Steffensen), pp. 239-280. San Diego: Academic Press.[CrossRef]
Brill, R. W. and Bushnell, P. G. (2001). The cardiovascular system of tunas. In Tuna: Physiology, Ecology and Evolution (Fish Physiology Series). Vol.19 (ed. B. A. Block and E. D. Stevens), pp.79 -120. San Diego: Academic Press.[CrossRef]
Byrne, A. P. and Houston, A. H. (1988). Use of phenylhydrazine in the detection of responsive changes in haemoglobin isomorph abundances. Can. J. Zool. 66,758 -762.
Cameron, J. N. and Davis, J. C. (1970). Gas exchange in rainbow trout (Salmo gairdneri) with varying blood oxygen capacity. J. Fish. Res. Board Can. 27,1068 -1085.
Cameron, J. N. and Wohlschlag, D. E. (1969).
Respiratory response to experimentally induced anemia in the pinfish
(Lagadon rhomboids). J. Exp. Biol.
50,307
-317.
Cech, J. J., Bridges, D. W., Rowell, D. M. and Blazer, P. J. (1976). Cardiovascular responses of winter flounder, Pseudopleuronectes americanus (Walbaum), to acute temperature increase. Can. J. Zool. 54,1383 -1388.[Medline]
Chudzik, J. and Houston, A. H. (1983). Temperature and erythropoiesis in goldfish. Can. J. Zool. 61,1322 -1325.
Clark, R. J. and Rodnick, K. J. (1998). Morphometric and biochemical characteristics of ventricular hypertrophy in male rainbow trout (Oncorhynchus mykiss). J. Exp. Biol. 201,1541 -1552.[Abstract]
Clark, R. J. and Rodnick, K. J. (1999). Pressure and volume overloads are associated with ventricular hypertrophy in male rainbow trout. Am. J. Physiol. 277,R938 -R946.[Medline]
Clarke, J. J., Clark, R. J., McMinn, J. T. and Rodnick, K. J. (2004). Microvascular and biochemical compensation during ventricular hypertrophy in male rainbow trout. Comp. Biochem. Physiol. 139B,695 -703.[CrossRef][Medline]
Davie, P. S. and Farrell, A. P. (1991). The coronary and luminal circulations of the myocardium of fishes. Can. J. Zool. 69,1993 -2001.
Davie, P. S. and Thorarensen, H. (1997). Heart
growth in rainbow trout in response to exogenous testosterone and 17-
methyltestosterone. Comp. Biochem. Physiol.
117A,227
-230.
Delcayre, C., Samuel, J. L., Marcotte, F., Best-Bellepomme, C., Mercardier, J. J. and Rapaport, L. (1988). Synthesis of stress proteins in rat cardiac myocytes 2-4 days after imposition of hemodynamic overload. J. Clin. Invest. 82,460 -468.[Medline]
Dornfest, B. S., Bush, M. E., Lapin, D. M., Adu, S., Fulop, A. and Naughton, B. A. (1990). Phenylhydrazine as a mitogen and activator of lymphoid cells. Ann. Clin. Lab. Sci. 20,353 -370.[Abstract]
Farrell, A. P. (1984). A review of cardiac performance in the teleost heart: intrinsic and humoral regulation. Can. J. Zool. 62,523 -536.
Farrell, A. P. (1991). From hagfish to tuna: a perspective on cardiac function in fish. Physiol. Zool. 64,1137 -1164.
Farrell, A. P. (2002). Cardiorespiratory performance in salmonids during exercise at high temperature, insights into cardiovascular design limitations in fishes. Comp. Biochem. Physiol. 132A,797 -810.
Farrell, A. P. and Clutterham, S. M. (2003).
On-line venous oxygen tensions in rainbow trout during graded exercise at two
acclimation temperatures. J. Exp. Biol.
206,487
-496.
Farrell, A. P., Hammons, A. M., Graham, M. S. and Tibbits, G. F. (1988). Cardiac growth in rainbow trout, Salmo gairdneri. Can. J. Zool. 66,2368 -2373.
Farrell, A. P., Simonot, D. L., Seymour, R. S. and Clark, T. D. (2007). A novel technique for estimating the compact myocardium in fish reveals surprising results for an athletic air-breathing fish, the Pacific tarpon. J. Fish Biol. 71. In press.
Franklin, C. E. and Davie, P. S. (1992a).
Dimensional analysis of the ventricle of an in situ perfused trout
heat using echocardiography. J. Exp. Biol.
166, 47-60.
Franklin, C. E. and Davie, P. S. (1992b).
Sexual maturity can double heart mass and cardiac power output in male rainbow
trout. J. Exp. Biol.
171,139
-148.
Gallaugher, P. and Farrell, A. P. (1998). Haematocrit and blood oxygen-carrying capacity. In Fish Respiration (Fish Physiology Series). Vol. 17 (ed. S. F. Perry and B. Tufts), pp. 185-227. San Diego: Academic Press.
Gallaugher, P., Thorarensen, H. and Farrell, A. P. (1995). Haematocrit in oxygen transport and swimming in rainbow trout (Oncorhynchus mykiss). Respir. Physiol. 102,279 -292.[CrossRef][Medline]
Gamperl, A. and Farrell, A. P. (2004). Cardiac
plasticity in fishes: environmental influences and intraspecfici differences.
J. Exp. Biol. 207,2539
-2550.
Gamperl, A., Pinder, A. and Boutlier, R. (1994). Effect of coronary ablation and adrenergic stimulation on in vivo cardiac performance in trout (Oncorhynchus mykiss). J. Exp. Biol. 186,127 -143.[Abstract]
Gilmour, K. M. and Perry, S. F. (1996). The effects of experimental anemia on CO2 excretion in vitro in rainbow trout, Oncorhynchus mykiss. Fish Physiol. Biochem. 15,83 -94.[CrossRef]
Goolish, E. M. (1987). Cold acclimation increases the ventricle size of carp, Cyprinus carpio. J. Therm. Biol. 12,203 -206.[CrossRef]
Graham, M. S. and Farrell, A. P. (1989). The effect of temperature acclimation and adrenaline on the performance of a perfused trout heart. Physiol. Zool. 62, 38-61.
Graham, M. S. and Farrell, A. P. (1992). Environmental influences on cardiovascular variables in rainbow trout, Oncorhynchus mykiss (Walbaum). J. Fish Biol. 41,851 -858.[CrossRef]
Greer-Walker, M. and Emerson, I. (1978). Sustained swimming speeds and myotomal muscle function in the trout, Salmo gairdneri. J. Fish Biol. 13,475 -481.[CrossRef]
Hanson, L. M. and Farrell, A. P. (2007). The hypoxic threshold for maximum cardiac performance in rainbow trout (Oncorhynchus mykiss) during simulated exercise conditions at 18°C. J. Fish Biol. In press.
Hanson, L. M., Obradovich, S., Mouniargi, J. and Farrell, A.
P. (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.
Hochachka, P. W. (1961). The effect of physical training on oxygen debt and glycogen reserves in trout. Can. J. Zool. 127,565 -587.
Holeton, G. F. (1971). Oxygen uptake and
transport by the rainbow trout during exposure to carbon monoxide.
J. Exp. Biol. 54,239
-254.
Holeton, G. F. (1977). Constancy of arterial blood pH during CO-induced hypoxia. Can. J. Zool. 55,1010 -1013.[Medline]
Houston, A. H. and Keen, J. E. (1984). Cadmium inhibition of erythropoiesis in goldfish, Carassius auratus. Can. J. Fish. Aquat. Sci. 41,1819 -1834.
Itano, H. A., Hosokawa, K. and Hirota, K. (1976). Induction of haemolytic anemia by substituted phenylhydrazines. Br. J. Haematol. 32, 99-104.[Medline]
Joaquim, N., Wagner, G. N. and Gamperl, A. K. (2004). Cardiac function and critical swimming speed of the winter flounder (Pleuronectes americanus) at two temperatures. Comp. Biochem. Physiol. 138A,277 -285.[CrossRef][Medline]
Jones, D. R. (1971). The effect of hypoxia and
anaemia on the swimming performance of rainbow trout (Salmo
gairdneri). J. Exp. Biol.
55,541
-551.
Kent, J. D. and Prosser, C. L. (1985). Protein hypertrophy in liver and heart following cold acclimatization and acclimation in channel catfish. Am. Zool. 25, 134.
Kiceniuk, J. W. and Jones, D. R. (1977). The
oxygen transport system in trout (Salmo gairdneri) during sustained
exercise. J. Exp. Biol.
69,247
-260.
Magosso, E. and Ursino, M. (2004). Modeling study of the acute cardiovascular response to hypocapnic hypoxia in healthy and anaemic subjects. Med. Biol. Eng. Comput. 42,158 -166.[CrossRef][Medline]
Marinsky, C. A., Houston, A. H. and Murad, A. (1990). Effect of hypoxia on haemoglobin isomorph abundances in rainbow trout, Salmo gairdneri. Can. J. Zool. 68,884 -888.
McClelland, G. B., Dalziel, A. C., Fragoso, N. M. and Moyes, C.
D. (2005). Muscle remodeling in relation to blood supply,
implications for seasonal changes in mitochondrial enzymes. J. Exp.
Biol. 208,515
-522.
Meerson, F. Z. and Evsevieva, M. E. (1985). Disturbances of the heart structure and function in chronic haemolytic anemia, their compensation with increased coronary flow, and their prevention with ionol, an inhibitor of lipid peroxidatoin. Adv. Myocardiol. 5,201 -211.[Medline]
Milligan, C. L. (1996). Metabolic recovery from exhaustive exercise in rainbow trout. Comp. Biochem. Physiol. 113A,51 -60.
Murad, A., Houston, A. H. and Samson, L. (1990). Hematological response to reduced oxygen-carrying capacity, increased temperature and hypoxia in goldfish, Carassius auratus L. J. Fish Biol. 36,289 -305.[CrossRef]
Perry, S. and Gilmour, K. (1996). Consequences of catecholamine release on ventilation and blood oxygen transport during hypoxia and hypercapnia in an elasmobranch Squalus acanthias and a teleost Oncorhynchus mykiss. J. Exp. Biol. 199,2105 -2118.[Abstract]
Perry, S., Reid, S. and Salama, A. (1996). The effects of repeated physical stress on the ß-adrenergic response of the rainbow trout red blood cell. J. Exp. Biol. 199,549 -562.[Abstract]
Poupa, O. and Carlsten, A. (1973). Experimental cardiomyopathies in poikilotherms. Recent Adv. Stud. Cardiac Struct. Metab. 2,321 -351.[Medline]
