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First published online June 29, 2006
Journal of Experimental Biology 209, 2678-2685 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02317
Mitochondrial proton leak rates in the slow, oxidative myotomal muscle and liver of the endothermic shortfin mako shark (Isurus oxyrinchus) and the ectothermic blue shark (Prionace glauca) and leopard shark (Triakis semifasciata)
1 Department of Biological Science, California State University Fullerton,
Fullerton, CA 92834, USA
2 Marine Biology Research Division and Center for Marine Biotechnology and
Biomedicine, Scripps Institution of Oceanography, University of California,
San Diego, La Jolla, CA 92093-0204, USA
Author for correspondence (e-mail:
kdickson{at}fullerton.edu)
Accepted 9 May 2006
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Summary |
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Key words: elasmobranch, endothermy, liver, mitochondria, mitochondrial density, muscle, proton conductance, proton leak, shark, thermogenesis
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Introduction |
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;
Else and Hulbert, 1981;
Else and Hulbert, 1985;
Else et al., 2004b).
Endothermic vertebrates also have higher membrane sodium conductances, higher
mitochondrial membrane proton conductances, and membrane phospholipids with a
greater percentage of unsaturated fatty acids, leading Hulbert and Else to
propose the `membranes as pacemakers of metabolism' theory
(Else and Hulbert, 1987;
Hulbert and Else, 1989;
Hulbert and Else, 1990;
Hulbert and Else, 1999;
Hulbert and Else, 2000;
Brand et al., 1991;
Brand et al., 1994b;
Else et al., 2004a;
Else et al., 2004b). The
higher mitochondrial proton conductances in endothermic species are due to
higher rates of basal proton leak across the inner mitochondrial membrane,
which represents 20-30% of resting metabolic rate
(Brand, 1990;
Brand et al., 1991;
Brand et al., 1994a;
Brookes et al., 1998). Brand
et al. recently showed that 55-65% of basal proton leak can be attributed to
the presence of adenine nucleotide translocase, an inner mitochondrial
membrane protein (Brand et al.,
2005). In rats, basal proton leak accounts for 25% and 50% of
resting metabolism in hepatocytes and skeletal muscle, respectively, for 22%
and 34% of oxygen consumption in working liver and skeletal muscle,
respectively, and for 20-25% of whole animal basal metabolic rate
(Brand, 1990;
Brand et al., 1994a;
Rolfe and Brand, 1996;
Rolfe et al., 1999).
Basal proton leak has been implicated in the evolution of endothermy in
birds and mammals because liver mitochondrial proton leak rates are higher in
endothermic vertebrates than in comparably sized ectotherms of the same
preferred body temperature [e.g. rat and pigeon versus the bearded dragon, a
desert lizard (Brand et al.,
1991; Brand et al.,
1994b; Brookes et al.,
1998) (for a review, see
Stuart et al., 2001)]. Our
goal was to extend these studies to fishes, to determine whether mitochondrial
proton leak rates are greater in endothermic fishes than in related
ectothermic species and thereby may contribute to regional endothermy. We
compared the endothermic shortfin mako shark with the ectothermic blue shark
and leopard shark. The shortfin mako shark is an active, pelagic predator that
maintains the temperature of the slow, oxidative (red) locomotor muscle, the
cranial region and the viscera, including the liver, elevated above ambient
seawater temperature (for reviews, see
Carey et al., 1985;
Bernal et al., 2001a;
Carlson et al., 2004). Like
the mako, the blue shark is an epipelagic predator that swims continuously and
makes vertical movements throughout the day, presumably for feeding
(Sciarrotta and Nelson, 1977;
Carey and Scharold, 1990;
Sepulveda et al., 2004;
Weng et al., 2005). The
leopard shark is less active and inhabits shallower water, where it feeds
primarily on benthic prey such as worms, clams, crabs and shrimp but also on
both pelagic and demersal fishes (Russo,
1975; Talent,
1976; Webber and Cech,
1998). We tested the hypothesis that rates of proton leak in red
locomotor muscle and liver mitochondria are higher in the endothermic shortfin
mako shark than in the ectothermic blue and leopard sharks.
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Materials and methods |
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Isolation of mitochondria
Mitochondria were isolated following methods similar to those described
previously for sharks (Moyes et al.,
1990; Ballantyne et al.,
1992). Tissue samples were minced on ice and homogenized in buffer
(140 mmol l-1 KCl, 10 mmol l-1 EGTA, 5 mmol
l-1 MgCl2, 500 mmol l-1 sucrose, 20 mmol
l-1 Hepes buffer, pH 7.3 at 20°C) containing 2% defatted bovine
serum albumin (BSA) using a TeflonTM-glass homogenizer powered by an
electrical drill press running at approximately 200 r.p.m. The homogenate was
centrifuged at 1000 g for 4 min at 4°C to remove cellular
particulates, and any visible fat in the supernatant was removed. The
supernatant was then filtered through several layers of cheesecloth and
centrifuged at 9500 g for 10 min at 4°C. The resulting
pellet containing the mitochondria was washed twice in approximately 25 ml of
homogenization buffer, and the final mitochondrial pellet was re-suspended in
approximately 0.5-1.0 ml of 2% BSA homogenization buffer. Protein
concentration of each mitochondrial suspension was measured with the Biuret
assay using BSA as the standard and blanks containing 2% BSA homogenization
buffer.
Prior to proton leak assays, the respiratory control ratio (RCR) of the
isolated mitochondria was measured. The RCR is defined as the ratio of
ADP-stimulated respiration rate (state 3) to non-stimulated respiration rate
(state 4) (Chance and Williams,
1956). In the present study, RCRs were measured in the presence of
0.29 mmol l-1 ADP with succinate (4 mmol l-1) as the
oxidative substrate and in the absence of oligomycin, and proton leak assays
were run only on isolated mitochondria with an RCR value of 
2.
Measurement of mitochondrial proton leak rates
Proton leak was measured using methods developed by Brand (e.g.
Brand et al., 1991;
Brand et al., 1994a;
Brand et al., 2003). We used a
common measurement temperature of 20°C for all samples because it
approximated the average water temperature in which the sharks were captured
and because red muscle and visceral temperatures in mako sharks of the size
studied are 17-27°C when swimming in water temperatures of 17-20°C
(Bernal et al., 2001b;
Sepulveda et al., 2004).
Respiration rate and membrane potential were measured simultaneously using a
thermostatically controlled polarographic oxygen electrode system (Rank
Brothers Ltd, Bottisham, Cambridgeshire, UK) and a triphenylmethyl-phosphonium
(TPMP+) electrode, respectively. Mitochondria were incubated at a
concentration of 1 mg of mitochondrial protein per ml of assay buffer [150
mmol l-1 KCl, 5 mmol l-1 K2HPO4,
400 mmol l-1 urea, 200 mmol l-1 trimethylamine Noxide,
50 mmol l-1 sucrose, 1 mmol l-1 EGTA, 1 mmol
l-1 MgCl2,3 mmol l-1 Hepes buffer, 0.5% BSA,
pH 7.3 at 20°C], and the following reagents were added in succession using
Hamilton syringes: 5 µmol l-1 rotenone, 1 µg ml-1
oligomycin, 0.1 µmol l-1 nigericin, 5 µmol l-1
TPMP+ (in increments of 1 µmol l-1), 4 mmol
l-1 succinate, up to 8 mmol l-1 malonate and 0.2 µmol
l-1 carbonyl cyanide p-trifluoromethoxyphenylhydrazone
(Brand et al., 1991;
Brand et al., 2003).
Mitochondrial proton leak rates (nmol H+ min-1
mg-1 protein) were calculated from respiration rates by assuming a
ratio of six protons for each oxygen atom consumed
(Hafner and Brand, 1991) and
oxygen solubility of 521 nmol O ml-1 for a 150 mmol l-1
KCl medium at 20°C (Reynafarje et al.,
1985). To calculate membrane potentials, the concentrations of
TPMP+ inside and outside the mitochondria were quantified with a
TPMP+ electrode calibrated during each assay with 1 µmol
l-1 additions of TPMP+ up to 5 µmol l-1.
These calibrations also confirmed that the electrodes responded in a Nernstian
fashion. The concentration of TPMP+ inside the mitochondria was
determined by subtracting the amount of TPMP+ remaining outside the
mitochondria (measured directly by the TPMP+ electrode) from the
total amount of TPMP+ present. The membrane potential was
calculated using the Nernst equation, the concentrations of TPMP+
inside and outside the mitochondria and a correction factor of 0.4 for
nonspecific mitochondrial TPMP+ binding
(Brookes et al., 1998). For
each tissue sample, proton leak rate was measured in triplicate and average
values were calculated. Mean values for each tissue in each species were then
calculated.
Average mitochondrial proton leak rates for the three species were plotted
as a function of membrane potential (mV) for each tissue, and we assessed
similarities and differences in proton leak rate curves by the overlap or
non-overlap of standard error bars, as has been done in other studies (e.g.
Brand et al., 1991;
Brookes et al., 1998;
Hulbert et al., 2002). In
addition, to compare proton conductances (proton leak at a given membrane
potential), we fit a second-order polynomial to the data for each individual
(Origin 7.5 software; RockWare Inc., Golden, CO, USA) to estimate the proton
leak rate at a membrane potential of 160 mV. This value was selected because
it is sub-maximal for all shark species in this study, is encompassed by all
proton leak curves and has been used previously to compare proton conductances
in terrestrial and aquatic vertebrates (e.g.
Brookes et al., 1998;
Hulbert et al., 2002).
We used one-way analysis of variance (ANOVA), along with a power analysis, to test for interspecific differences in mean red muscle and liver mitochondrial proton leak rates at 160 mV, and paired t-tests to test for differences between the two tissues in each species (Minitab, version 12; Minitab Inc., State College, PA, USA). ANOVA was used to test for interspecific differences in state 3 respiration rates, state 4 respiration rates and state 4 membrane potentials (obtained from proton leak assays after the addition of succinate); if significant differences were found, Scheffe's method was used for multiple comparisons analysis (Minitab, version 12). A significance level of P=0.05 was used in all statistical analyses.
Estimates of tissue mitochondrial density by transmission electron microscopy
Although we were primarily interested in whether red muscle or liver
mitochondria of endothermic sharks are specialized for thermogenesis, the
contribution of a given tissue to heat production is also affected by the
tissue's mitochondrial density and its contribution to the total body mass.
The relative mass of red muscle and liver (as a percentage of body mass) have
been measured in the three shark species
(Bone and Roberts, 1969;
Kohler et al., 1996;
Gruber and Dickson, 1997;
Mollet et al., 1999). However,
of the tissues studied, mitochondrial content has been measured only in the
red muscle of the mako shark (Bernal et
al., 2003a). Therefore, we used transmission electron microscopy
(TEM) to estimate mitochondrial densities in samples of both tissues from each
of the three shark species.
Small tissue samples were dissected from sharks immediately after they were euthanized and prepared for TEM. Tissues were fixed in 2% formaldehyde and 2% glutaraldehyde in TEM buffer (280 mmol l-1 NaCl, 6 mmol l-1 KCl, 5 mmol l-1 CaCl2, 3 mmol l-1 MgCl2, 0.5 mmol l-1 Na2SO4, 0.41 mmol l-1 MgSO4, 250 mmol l-1 sodium cacodylate and 200 mmol l-1 sucrose, pH 7.2 at room temperature) and post-fixed in 2% osmium tetroxide in TEM buffer before being embedded in epon araldite blocks. Ultra-thin sections (90 nm thick) stained with 3% uranyl acetate and 1.5% lead citrate were scanned with the TEM to find transverse sections of whole muscle fibers or representative areas of liver tissue. Electron micrographs were taken at 2000 or 2500x magnification, and the point-contact method was used to determine mitochondrial densities within an entire muscle fiber cross-section or within a rectangular area of liver cells using the Scion Image Analysis Program (version 1.62; Scion Corp., Frederick, MO, USA). Mitochondrial densities were expressed as a percentage of cross-sectional area occupied by mitochondria, which is equivalent to the volume percentage of the muscle fiber or liver tissue that is occupied by mitochondria, or VV(mt,f), if a uniform distribution of mitochondria is assumed. ANOVA was used to test for interspecific differences in red muscle and liver mitochondrial densities (Minitab, version 12).
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For each shark species, the proton leak curve for red muscle mitochondria is higher than that for liver mitochondria (Fig. 3) and would be considered different by the criterion of nonoverlapping error bars. Only in the blue shark was the proton leak rate at 160 mV significantly higher in red muscle than in liver (paired t-tests; P=0.86 for mako shark; P=0.02 for blue shark; P=0.07 for leopard shark).
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Mitochondrial respiration rates and membrane potentials
The average state 3 and state 4 respiration rates, state 4 membrane
potentials and RCR values of red muscle and liver mitochondria for the three
shark species are summarized in Table
2. In red muscle mitochondria, state 3 and state 4 respiration
rates and state 4 membrane potentials were significantly higher in the mako
shark than in the two ectothermic species (ANOVA, P<0.01). In
liver mitochondria, the mako shark had significantly higher state 3 and state
4 respiration rates than the leopard shark, and both the mako shark and blue
shark had significantly higher state 4 membrane potentials than the leopard
shark (ANOVA, P
0.02).
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Estimates of tissue mitochondrial density and total tissue proton leak
The average red muscle and liver mitochondrial densities for each shark
species are summarized in Table
1, and Fig. S1 in the supplementary material shows examples of the
individual muscle fibers and liver samples analyzed. The mako shark and the
leopard shark have significantly higher red muscle mitochondrial densities
than the blue shark (ANOVA, P<0.01). In liver, mitochondrial
densities are significantly greater in the mako shark and blue shark than in
the leopard shark (ANOVA, P<0.01).
We combined the tissue mitochondrial density data with the mitochondrial
proton leak rates at a membrane potential of 160 mV
(Table 1) to estimate proton
leak rate per g of tissue, assuming that the amount of protein per
mitochondrial volume and tissue densities do not differ interspecifically. For
interspecific comparisons of total proton leak rates within the red muscle,
proton leak rate per g of red muscle was multiplied by published values of
relative red muscle mass (as a percentage of body mass) in the three species:
means ± s.e.m. of 2.01±0.07% (N=8) for I.
oxyrinchus; 2.65±0.56% (N=4) for P. glauca;
2.06±0.19% (N=3) for T. semifasciata
(Bernal et al., 2003a). These
calculations indicate that total proton leak rate in the red muscle is not
elevated in the mako shark relative to the two ectothermic species. Total red
muscle proton leak in the mako shark is approximately 1.1 times that in the
blue shark and is 25% lower than that in the leopard shark. However, proton
leak per g of liver in the endothermic mako shark would be approximately 1.9
times that in both ectothermic species. Compared with the shortfin mako shark,
the blue shark had a lower mitochondrial proton conductance but a similar
mitochondrial density in the liver, whereas the leopard shark had a similar
proton conductance but lower mitochondrial density
(Table 1). These interspecific
differences would be reflected in total liver proton leak rates because the
relative liver masses in the three species overlap: 1.2-17.9% (mean ±
s.e.m. of 6.7±0.25%; N=161) for female I. oxyrinchus
(Mollet et al., 1999);
5.1-10.7% (8.4±1.0%; N=6) for P. glauca
(Bone and Roberts, 1969);
3.49-5.44% (4.48±0.23%; N=8) for T. semifasciata
(Gruber and Dickson,
1997).
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; Ballantyne et al.,
1992). However, our measurements of state 3 and state 4
respiration rates by mako shark red muscle mitochondria are higher than those
reported by Ballantyne et al. under similar conditions (mean ± s.e.m.
of 21.74±3.25 nmol O min-1 mg-1 protein and
3.72±2.24 nmol O min-1 mg-1 protein,
respectively; N=3) (Ballantyne et
al., 1992) and were significantly higher than in the two
ectothermic shark species studied (Table
2). Red muscle mitochondrial respiration rates comparable to the
high rates we measured in the mako shark have been reported in active teleost
fishes, including the skipjack tuna, Katsuwonus pelamis
(Moyes et al., 1992), and blue
marlin, Makaira nigricans
(O'Brien and Block, 1996). Our
state 3 and state 4 respiration rate values for liver mitochondria from the
ectothermic sharks are similar to those reported for ectothermic teleost
fishes at 20°C with succinate as substrate (e.g.
Bagarinao and Vetter, 1990;
Brookes et al., 1998).
The greater respiration rates measured in red muscle mitochondria of the
mako shark relative to those of the two ectothermic sharks may reflect higher
electron transport chain activity (Rolfe
et al., 1994; Leary et al.,
2003), which may be related to higher aerobic requirements in the
active shortfin mako. If so, and if mako mitochondria maintain higher membrane
potentials than those of the ectothermic sharks, then in vivo proton
leak rates will parallel differences in state 4 respiration rates
(Table 2). As a result, in the
red muscle, in vivo rates of mitochondrial proton leak and heat
production in the mako shark would exceed those of the ectothermic species,
and in the liver would be greater in the mako shark and blue shark than in the
leopard shark. However, in vivo mitochondrial membrane potentials and
rates of oxygen consumption, proton leak and heat production are not known for
sharks.
The endothermic mako shark appears to have a higher proton leak rate per g
of liver than both ectothermic species, due to a lower proton conductance in
the blue shark and a lower liver mitochondrial content in the leopard shark.
Because the liver comprises a relatively large proportion of body mass in
sharks and is likely to contribute significantly to standard metabolic rate
(SMR), total liver proton leak may also correlate with SMR. The data available
on swimming energetics and SMR of active sharks are limited, due to logistical
problems associated with making these measurements on large pelagic fishes.
The SMR of one mako shark studied in a swimming tunnel at sea was estimated to
be 240 mg O2 kg-1 h-1 at 16-20°C
(Graham et al., 1990). This
value is higher than that of leopard sharks of similar size [mean ±
s.e.m., 91.7±13.9 mg O2 kg-1 h-1 at
14-18°C; N=7 (Scharold et
al., 1989)], but no SMR data are available for the blue shark.
The only other fish proton leak kinetics data of which we are aware are
from teleost fishes: mitochondrial proton leak has been quantified in rainbow
trout liver (Brookes et al.,
1998), myotomal muscle and heart
(Leary et al., 2003), as well
as in carp (Cyprinus carpio) liver and red muscle (K.A.D., J. Baca,
J. A. Buckingham and M. D. Brand, unpublished). When compared at the same
membrane potential, the proton leak rates measured for the three shark species
in this study are similar to those reported for the rainbow trout (mean red
muscle proton leak at 150 mV was 11.6, 17.2, 19.4 and 20.8 nmol H+
min-1 mg-1 protein in mako, blue and leopard sharks at
20°C and in rainbow trout at 15°C, respectively)
(Leary et al., 2003) but only
approximately half the values measured in carp (48.8 and 25.8 nmol
H+ min-1 mg-1 protein at 160 mV at 25°C
for carp red muscle and liver, respectively).
The mitochondrial density in mako shark red muscle measured in the present
study is higher than values reported by Bernal et al. for two individuals
(mean ± s.e.m. of 25.2±0.8 and 29.5±1.2 volume %)
(Bernal et al., 2003a),
possibly due to methodological differences. The relative values of red muscle
mitochondrial density in the three shark species studied correspond with
published red muscle citrate synthase activities: mean ± s.e.m. of
31.6±1.8 i.u. g-1 tissue (N=30) for I.
oxyrinchus; 22.3±6.3 (N=4) for P. glauca;
27.1±2.1 (N=7) for T. semifasciata
(Dickson et al., 1993;
Bernal et al., 2003b). This
finding confirms that citrate synthase activity is an index of mitochondrial
density in fish muscle.
Comparisons between red muscle and liver
When red muscle and liver proton leak curves were compared by examining the
overlap of standard error bars, as is typically done in published literature
(e.g. Brand et al., 1991;
Brookes et al., 1998;
Hulbert et al., 2002),
mitochondrial proton leak rates were higher in red muscle than in liver for
all three shark species studied. Mitochondrial proton leak rates were also
higher in skeletal muscle than in liver in both rats and carp
(Rolfe et al., 1994) (K.A.D.,
J. Baca, J. A. Buckingham and M. D. Brand, unpublished data). Rolfe et al.
suggested that the inner membrane of rat skeletal muscle mitochondria has a
greater surface area for proton leak to occur and contains lipids with a
higher unsaturation index (Rolfe et al.,
1994), which correlates with proton permeability
(Brand et al., 1991). Relative
to liver mitochondria, muscle mitochondria could contain more adenine
nucleotide translocase, which is responsible for a major fraction of basal
proton leak (Brand et al.,
2005). These parameters remain unexamined in shark red muscle and
liver mitochondria, and the basis for inter-tissue differences in
mitochondrial proton leak rates deserves further study.
Leary et al. argued that inter-tissue comparisons of proton leak rates
should be made on the basis of mitochondrial membrane surface area and that
the activity of cytochrome oxidase is a better measure of this variable than
is protein content (Leary et al.,
2003). When Leary et al. compared red muscle, fast-glycolytic
myotomal (white) muscle, and heart mitochondria of rainbow trout they found no
difference in proton leak kinetics when measured in nmol H+
min-1 mg-1 protein, but inter-tissue differences were
apparent when expressed as nmol H+ min-1
unit-1 of cytochrome oxidase activity
(Leary et al., 2003).
Therefore, future studies should quantify cytochrome oxidase activity, as well
as membrane phospholipid composition and adenine nucleotide translocase
content, to assess differences among tissues in mitochondrial proton leak
rates.
Conclusion
The objective of this study was to determine if high rates of mitochondrial
proton leak are associated with endothermy in sharks. We tested the hypothesis
that, because the shortfin mako shark is a regional endotherm, its red muscle
and liver mitochondria proton leak rates would be higher than those of the
ectothermic blue and leopard sharks. Based on our finding of no significant
interspecific differences in proton leak rates per mg of protein at 160 mV for
either tissue, it appears that mitochondria in the mako shark are not
specialized for thermogenesis by having a higher proton conductance. However,
it is possible that proton leak contributes to heat production for endothermy
in this species, if the measured state 4 respiration rates and membrane
potentials reflect the conditions under which the mitochondria operate in
vivo. In that case, mako shark mitochondria would have a higher proton
leak rate as a consequence of a higher driving force (membrane potential)
rather than as a result of a higher membrane permeability to protons.
Furthermore, we found that the total proton leak rate in the liver would be
greater in the mako shark than in both ectothermic species studied, suggesting
a possible role in endothermy or elevation of SMR. Future experiments to test
hypotheses about the role of mitochondrial proton leak in the evolution of
endothermy in fishes should focus on the teleost Family Scombridae because
both endothermic (tunas) and ectothermic species (mackerels, Spanish mackerels
and bonitos) exist within the same family and the metabolic rates in tunas are
known to be higher than in mackerels and bonitos
(Sepulveda and Dickson, 2000;
Korsmeyer and Dewar, 2001;
Sepulveda et al., 2003).
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Acknowledgments |
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Footnotes |
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* Present address: Pfleger Institute of Environmental Research, Oceanside, CA
92054, USA 
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References |
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