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First published online January 30, 2009
Journal of Experimental Biology 212, 461-470 (2009)
Published by The Company of Biologists 2009
doi: 10.1242/jeb.022814
Evidence for cranial endothermy in the opah (Lampris guttatus)
1 Department of Biological Science, California State University Fullerton,
Fullerton, CA 92834, USA
2 NOAA Fisheries, Southwest Fisheries Science Center, 8604 La Jolla Shores
Drive, La Jolla, CA 92037, USA
3 Joint Institute for Marine and Atmospheric Research, University of
Hawaii/Ecosystems and Oceanography Division, NOAA Fisheries, 2570 Dole Street,
Honolulu, HI 96822, USA
4 Center for Scientific Computation in Imaging and Center for Functional
Magnetic Resonance Imaging, University of California, San Diego, La Jolla, CA
92093, USA
Author for correspondence (e-mail:
kdickson{at}fullerton.edu)
Accepted 25 November 2008
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Key words: adipose tissue, citrate synthase, counter-current heat exchange, cranial endothermy, extraocular muscle, Lampris guttatus, lateral rectus, magnetic resonance imaging, moonfish, opah, regional endothermy, retia, superior rectus, temperature
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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; Carey et al.,
1985; Block and Finnerty,
1994; Dickson and Graham,
2004). Cranial endothermy, the ability to maintain elevated eye
and/or brain temperatures, has evolved by convergence in lamnid sharks (Family
Lamnidae), billfishes (Families Xiphiidae and Istiophoridae), tunas (Family
Scombridae) and possibly in the butterfly mackerel (Family Scombridae) making
cranial endothermy the most widespread form of regional endothermy in fishes
(Stevens and Fry, 1971;
Linthicum and Carey, 1972;
Carey, 1982;
Schaefer, 1984;
Block and Carey, 1985;
Schaefer, 1985;
Block, 1991;
Block et al., 1993;
Sepulveda et al., 2007). Most
of these fish species can migrate long distances, make extensive vertical
excursions within the water column and experience a wide range of rapidly
changing seawater temperatures (Carey et
al., 1971; Carey and Lawson,
1973; Carey et al.,
1981; Carey, 1990;
Josse et al., 1998;
Dagorn et al., 2000;
Schaefer and Fuller, 2002;
Musyl et al., 2003;
Brill et al., 2005;
Schaefer et al., 2007). In
addition, these species are pelagic predators, have large eyes and rely on
vision to seek and capture active prey. It has been hypothesized that cranial
endothermy improves the ability to forage in cold, dark waters in two ways.
First, it buffers the central nervous system from rapid changes in ambient
temperature (Carey, 1982;
Block, 1987b;
Carey, 1990;
Block et al., 1993;
Block and Finnerty, 1994).
Second, maintaining elevated cranial temperatures improves the ability to
resolve intermittent visual stimuli by an increase in the flicker fusion
frequency (Fritsches et al.,
2005), enhancing the ability to track fast moving prey. Cranial
endothermy probably evolved to allow fishes to forage successfully in deep
cool waters and thus expand their thermal niche and forage base
(Block et al., 1993).
Cranial endothermy requires a metabolic heat source and a mechanism to
retain that heat and is achieved by different means in the different fish
groups. The heat source in billfishes and the butterfly mackerel consists of
specialized heater tissue derived from the superior rectus and the lateral
rectus extraocular muscles, respectively
(Block, 1987a;
Finnerty and Block, 1992).
These heater tissues are composed of modified muscle cells that lack
contractile filaments, are densely packed with mitochondria and have an
extensive sarcoplasmic reticulum and a high oxidative capacity
(Block, 1991;
Tullis et al., 1991). Heat
production in heater cells is associated with the ATP-dependent cycling of
Ca2+ across the sarcoplasmic reticulum membrane
(Block, 1987a;
Block, 1991). The only other
species known to have modified extraocular muscle is the slender tuna
(Allothunnus fallai), the most basal tuna, in which portions of the
superior, inferior, medial and lateral rectus muscles are fused to form a
putative heater tissue located ventral to the brain
(Sepulveda et al., 2007). In
the other tuna species, there is no evidence of modified extraocular muscle
(Block et al., 1982;
Block, 1990;
Sepulveda et al., 2007), and
contraction of the extraocular muscles
(Block and Finnerty, 1994) or
active metabolism within the brain (Block,
1987b; Block et al.,
1982) have been proposed as possible sources of heat for cranial
endothermy in those species. In lamnid sharks, heat produced within the
slow-oxidative myotomal muscle is transferred to the cranial area via
the unique red muscle vein and the myelonal vein
(Block and Carey, 1985;
Carey et al., 1985;
Wolf et al., 1988;
Alexander, 1998;
Tubbesing and Block, 2000). In
addition, contraction of extraocular muscles may also contribute to heat
production in these sharks (Wolf et al.,
1988; Alexander,
1998).
Regardless of the heat source, the high heat capacity of water and use of
gills for gas exchange necessitate mechanisms that reduce both conductive and
convective heat loss to the environment and that conserve heat within the
cranial region. To reduce conduction, the eyes and brain of billfishes and
tunas, but not lamnid sharks, are insulated by a layer of adipose tissue
(Carey, 1982;
Wolf et al., 1988;
Block, 1990;
Fritsches et al., 2005;
Sepulveda et al., 2007). To
reduce convection of heat to the gills, vascular counter-current heat
exchangers (retia mirabilia) perfuse the cranial region in all fish species
with cranial endothermy but retia morphology differs among the fish groups.
Billfishes and tunas have paired carotid retia composed of arteries branching
primarily from the carotid arteries and veins that eventually empty into the
anterior cardinal vein (Linthicum and
Carey, 1972; Carey,
1982; Block, 1986;
Block, 1990;
Sepulveda et al., 2007). In
the butterfly mackerel, the putative counter-current heat exchanger perfusing
the lateral rectus muscle is more posterior, branching from the lateral dorsal
aorta (Block, 1991). The lamnid
sharks have paired orbital retia, each made of an arterial plexus branching
from the highly coiled pseudobranchial and efferent hyoidean arteries
surrounded by warm blood within the orbital venous sinus
(Block and Carey, 1985;
Carey et al., 1985;
Alexander, 1998;
Tubbesing and Block, 2000).
The red muscle vein supplies warm blood to the orbital sinus via the
myelonal vein (Wolf et al.,
1988; Tubbesing and Block,
2000).
These heat production and conservation mechanisms allow cranial
temperatures to be elevated above ambient water temperature by an amount that
varies by species and with water temperature. Cranial temperatures measured in
decked fishes representing the different taxonomic groups ranged from 0.4 to
15.5°C above water temperature
(Stevens and Fry, 1971;
Linthicum and Carey, 1972;
Carey, 1982;
Block and Carey, 1985;
Block, 1987b;
Carey, 1990;
Block, 1991;
Sepulveda et al., 2007). The
highest temperatures have been observed in giant Atlantic bluefin, Thunnus
thynnus (Linthicum and Carey,
1972) and in swordfish, Xiphias gladius, in which cranial
temperatures elevated 13°C above water temperature were recorded during
deep dives using acoustic telemetry
(Carey, 1990). Unfortunately,
measurements of cranial temperature in free-swimming fishes are scarce.
Previous studies have noted that the opah or moonfish [Lampris
guttatus (Brünnich 1788) Order Lampridiformes] possesses vascular
modifications within the cranial region that are suggestive of endothermy
(Block, 1986;
Block, 1987b). L.
guttatus is a large epipelagic–mesopelagic predator, reaching sizes
of 144 kg, with large eyes (Polovina et
al., 2008). It shares certain anatomical adaptations with the
endothermic billfishes, tunas and lamnid sharks, including a large muscular
heart, well-developed pyloric ceca and a large relative locomotor muscle mass
(Rosenblatt and Johnson, 1976)
(H.D., unpublished). Based on catch data, the geographical range of opah
extends from temperate through to tropical waters in both hemispheres
(Gon, 1990). A recent study of
11 opah tagged with pop-up archival tags off of Hawaii showed that opah
consistently move vertically within the depth range of 50–400 m,
encountering water temperatures ranging from 8 to 22°C and reach a maximum
depth of 736 m (Polovina et al.,
2008). Stomach content data show that opah feed on squid and
fishes (Palmer, 1986;
Polovina et al., 2008). Thus,
like the other cranial endotherms, L. guttatus experiences a broad
range of ambient temperatures, forages on fast moving prey in cool deep waters
and would benefit from regional endothermy.
The purpose of this study was to test for cranial endothermy in the opah. In order to establish cranial endothermy, one must measure elevated cranial temperatures and identify both a heat source and a mechanism to conserve heat in the cranial region. In this study, we measured elevated cranial temperatures in live opah caught by commercial long-liners and used dissections, light and electron microscopy, biochemical analyses and magnetic resonance imaging (MRI) to identify and describe the potential heat sources and heat retention mechanisms in L. guttatus.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Measurement of cranial temperatures
A total of 121 opah were caught between 2002 and 2006 during commercial
long-line fishing operations in the central Pacific Ocean off of the main
Hawaiian Islands between 18–30 deg. N and 136–153 deg. W.
Immediately after fish were brought aboard and before the fish were processed
by the fishermen, individuals were placed on their right side, their condition
was noted (dead or alive), FL was measured to the nearest mm, they were sexed
and tissue temperatures were recorded. A waterproof, heavy-duty
K-type thermocouple thermometer (HI 9063, Hanna Instruments,
Póvoa de Varzim, Portugal) and a 12 cm thermocouple probe were used to
obtain temperatures within the cranial region near the brain and in the deep,
fast-twitch, glycolytic myotomal muscle tissue anterior to the pectoral fin.
Because the temperature at catch depth is unknown, myotomal muscle temperature
was used as a proxy for ambient temperature, as has been done in previous
studies (Carey et al., 1971;
Linthicum and Carey, 1973; Bernal and
Sepulveda, 2005). There is no evidence that temperatures of the
myotomal or pectoral fin locomotor muscles can be elevated significantly above
ambient temperature in the opah (Carey et
al., 1971; Rosenblatt and
Johnson, 1976). The magnitude of cranial temperature elevation or
cranial thermal excess (Tx) was calculated for each
individual as the difference between maximal cranial temperature and myotomal
muscle temperature, as in previous studies
(Carey et al., 1971; Linthicum
and Carey, 1973; Bernal and Sepulveda,
2005).
Identification and characterization of a heat source in the opah
Gross anatomy of the cranial region and relative size of the extraocular muscles
Ten opah heads were dissected to identify cranial tissues that may
contribute to heat production or heat retention. Characteristics used during
dissections to identify potential heat sources for cranial endothermy included
position within the cranial cavity (near the brain and optic nerve), relative
size and the redness of the tissue. How red in color a muscle tissue appears
results from the presence of myoglobin and blood and serves as a relative
indicator of tissue aerobic capacity and associated heat production.
The masses of each extraocular muscle and the eyeball were measured in eyes dissected from seven of the opah heads. The whole eyeball and the attached extraocular muscles were removed and all visible fat was dissected away. Each extraocular muscle was separated from the eye and weighed individually (to the nearest 0.01 g), and the mass of each extraocular muscle was expressed as a percentage of total eye mass (eyeball with optic nerve and sum of all muscles). In addition, the masses of all six extraocular muscles were summed and total extraocular muscle mass, expressed as a percentage of total eye mass, was calculated for the opah and compared with values obtained in the same manner from an active ectothermic teleost species, the chub mackerel (Scomber japonicus, Family Scombridae).
Extraocular muscle histology
Light microscopy and transmission electron microscopy (TEM) were used to
determine if any of the six extraocular muscles of the opah are modified to
form specialized heater tissue as in billfishes, butterfly mackerel and
slender tuna. Muscle transverse sections were removed from proximal (near the
origin of the muscle on the skull), middle and distal (near the insertion on
the eyeball) positions along the lateral rectus extraocular muscle, from the
middle and proximal portions of the medial rectus and superior rectus
extraocular muscles and from the middle portion of the three other extraocular
muscles. These samples were fixed in 10% phosphate-buffered formalin, embedded
in paraffin, sectioned and stained with hematoxylin and eosin (Harris
Histology Services, Tustin, CA, USA).
Tissue samples used for TEM analysis were collected from three opah captured by long-line fishing operations between Oregon and Hawaii. Samples from all six extraocular muscles (approximately 12x12 mm) were removed immediately after each fish was euthanized and were fixed in 2% glutaraldehyde and 2% formaldehyde in 0.1 mol l–1 cacodylate buffer, pH 7.4 at 4°C for 1.5–2.0 h. Specimens were then stored cold in approximately 0.5% glutaraldehyde and 0.5% formaldehyde in 0.1 mol l–1 cacodylate buffer for four weeks until they were sent to California State University Fullerton (CSUF). From the surface of each 12x12 mm sample, small tissue samples (1x3 mm) were removed and washed three times in buffer (0.1 mol l–1 sodium phosphate buffer, pH 7.2 at room temperature) for 30 min. The tissues were fixed in 2% osmium tetroxide in buffer, dehydrated in a graded ethanol series and embedded in epoxy blocks with the long axis of the muscle fibers parallel to the long axis of the block. Ultrathin sections (80 nm thick) were cut using an ultramicrotome and a diamond knife, mounted onto copper TEM grids, stained with 3% uranyl acetate and 1.5% lead citrate and examined with a Hitachi H7000 TEM at CSUF.
Extraocular muscle aerobic heat production capacity
Samples of each extraocular muscle were used to quantify the activity of
the citric acid cycle enzyme citrate synthase (CS) as an index of tissue
mitochondrial density and aerobic heat production capacity. For CS assays,
muscle samples were homogenized on ice with a ground-glass homogenizer in 2
mmol l–1 ethylene diamine tetra-acetic acid, 80 mmol
l–1 imidazole buffer, pH 6.6 at 20°C and centrifuged in a
high-speed, refrigerated centrifuge at 12,000x g for 10
min. The supernatant containing soluble enzymes was removed for measurements
of CS activity using a Hewlett-Packard 8452A diode-array spectrophotometer
(Palo Alto, CA, USA) and assay procedures used in previous studies of other
fishes (Dickson et al., 1993;
Dickson, 1996). Assays were
run at 20°C in a final volume of 2.0 ml containing 0.5 mmol
l–1 oxaloacetate, 0.10 mmol l–1 acetyl
Co-enzymeA, 0.10 mmol l–1 5,5'-dithiobis(2-nitrobenzoic
acid), 2.0 mmol l–1 MgCl2 and 80 mmol
l–1 Tris buffer, pH 8.0 at 20°C. Enzyme assays were
carried out under saturating substrate conditions, as determined in
preliminary studies. Enzyme activities are expressed as micromoles of
substrate converted to product min–1 (international units)
per gram wet mass of muscle tissue (units g–1).
From five opah captured on long-line off of Hawaii, the left eye along with attached extraocular muscles was removed, placed into liquid nitrogen immediately after capture, sent to CSUF on dry ice and stored at –80°C for up to two months. Each eye was thawed, and small samples from each extraocular muscle were removed from a position approximately one-third along the length of the muscle from its insertion on the eyeball for CS assays. However, these eyes did not include the proximal portions of the extraocular muscles. Samples of the proximal and distal regions of the lateral rectus muscle, as well as the pectoral fin and myotomal muscles, of one opah were collected immediately after the fish was captured by long-line and euthanized, frozen immediately in liquid nitrogen and stored at –80°C. An additional five opah were chilled on ice for up to six days on a Chesapeake Fish Company commercial fishing vessel, after which the heads were brought to CSUF where extraocular muscle samples were removed and stored at –80°C for up to two weeks. From these five fish, samples for CS assays were taken from each extraocular muscle at a position approximately one-third along the length from its insertion onto the eyeball, from the proximal and distal portions of the lateral rectus muscle and from the proximal portion of the superior rectus muscle.
Normally, enzyme activities are quantified in tissue samples that are frozen immediately and stored at –80°C to minimize protein degradation. However, because all other attempts to obtain –80°C frozen extraocular muscle samples from opah were unsuccessful, it was necessary to use chilled muscle samples to obtain enough CS activity measurements, particularly for the proximal region of the lateral rectus muscle. To test the validity of using those samples, both lateral rectus extraocular muscles were removed from five chub mackerel immediately after the fish were caught by hook and line and euthanized. One muscle was immediately frozen at –80°C whereas the other was chilled on ice for six days before being frozen at –80°C. These two sets of samples were handled in the same way that the different opah extraocular muscle samples had been handled prior to running CS assays. The CS activities of the two sets of lateral rectus muscle samples from the chub mackerel (28.0±5.7 and 25.0±3.9 units g–1, means±s.d., for frozen and chilled samples, respectively) did not differ significantly (paired t-test; P>0.05). Likewise, in the opah, the mean CS activities for each extraocular muscle for which both chilled and frozen samples were obtained did not differ significantly (two-sample t-test; P>0.05). Therefore, the chilled and frozen data sets for opah were combined.
Identification and characterization of heat retention mechanisms in the opah
Possible mechanisms to retain heat in the cranial and orbital region were
investigated in gross dissections of opah heads. We looked for adipose tissue
that would insulate the cranial and orbital region and reduce conduction to
the surrounding seawater. In addition, a hypothesized counter-current heat
exchange system, which perfuses several of the extraocular muscles and would
reduce convective heat loss, was identified. The origin of the blood vessels
that form this putative heat exchanger were traced in dissections.
Characteristics used to identify the putative counter-current heat exchanger
included numerous arteries and veins adjacent to one another with a high
surface area of contact. To confirm that the putative counter-current heat
exchanger was composed of adjacent arteries and veins, samples were fixed in
10% phosphate-buffered formalin, embedded in paraffin, sectioned and stained
with hematoxylin and eosin at Harris Histology. Histological sections were
examined by light microscopy, and arteries and veins were distinguished by the
thickness of the blood vessel wall; one sample was also stained for elastin
and one with trichome stain to confirm the identification of the blood
vessels. In addition, samples of the fat found in dissections to insulate the
cranial region were fixed in phosphate-buffered formalin and sent to Harris
Histology to be embedded in paraffin, sectioned and stained with hematoxylin
and eosin.
Three dimensional visualization using magnetic resonance imaging
To visualize and document the 3 dimensional arrangement of the tissues
within the cranial region, one opah head was studied using MRI. MRI data were
acquired over a portion of the opah head on a 3.0T SIGNA General Electric
(Milwaukee, WI, USA) clinical scanner and a standard quadrature head radio
frequency receive coil at the Keck Center for Functional Magnetic Resonance
Imaging, University of California San Diego. The following MRI parameters were
used: transverse orientation; T1-weighted 3-D fast spoiled gradient recalled
echo acquisition; flip angle of 10 deg.; echo time TE=3.288 ms; repetition
time TR=7.864 ms; full k-space acquisition; 20 cm field of view; in plane
image matrix of 256x256; 124 slices with 1.0 mm slice thickness; and
31.25 kHz bandwidth. Data were processed using Amira software (Mercury
Computer Systems, Chelmsford, MA, USA) to determine the shape and relative
geometry of the extraocular muscles, brain, skull and surrounding adipose
tissue. Segmentation analysis differentiated the various tissue volumes on the
basis of their intrinsic T1-weighted image intensities. The segmented volumes
allowed both quantitative measures of tissue volume and 3 dimensional
visualization of the relative positions of the cranial tissues.
Statistical analyses
Minitab (v. 12; Minitab, State College, PA, USA) was used for all
statistical analyses. Data were examined for normality
(Kolmogorov–Smirnov test) and homogeneity of variance (Bartlett's and
Levene's tests) and data that did not meet the assumption of homogeneity of
variance were log- or square root-transformed. To test for significant
differences between cranial temperature and myotomal muscle temperature, we
used a paired t-test. To test for significant relationships between
cranial temperature and both fish FL and muscle temperature, we used Pearson
product–moment correlation coefficients. General Linear Model Analysis
of Variance (ANOVA) was used to test for differences among the extraocular
muscle samples in CS activity or relative mass. If a significant difference
was found, Tukey's pairwise comparison test was used to identify significant
differences among the individual muscles. To test for differences between opah
and chub mackerel in extraocular muscle mass as a percentage of total eye
mass, a two-sample t-test was used. A significance level of
=0.05 was used in all statistical analyses. Unless stated otherwise,
all values are means±1 s.d.
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Identification and characterization of potential heat sources in the opah
Based on dissections and MRI imaging of the cranial and orbital region, the
proximal region of the lateral rectus muscle (PLRM) was identified as the most
likely heat source for cranial endothermy in the opah. The PLRM is positioned
adjacent to the brain, is composed of muscle fibers that are darker red in
color than those of the distal region of the lateral rectus muscle (DLRM) and
the other extraocular muscles (Fig.
2A) and is perfused by a putative counter-current heat exchanger
(described below). The lateral rectus extraocular muscle originates on the
anterior side of the basioccipital bone within the posterior portion of the
myodome and inserts on the eyeball opposite the medial rectus muscle. The
superior rectus extraocular muscle also originates on the anterior side of the
basioccipital bone and inserts dorsally on the eyeball between the lateral
rectus and superior oblique extraocular muscles. The other extraocular muscles
– the medial rectus (MRM), superior rectus (SRM), inferior rectus (IRM),
superior oblique (SOM) and inferior oblique (IOM) – are composed of
muscle fibers that are less red in color than the PLRM
(Fig. 2A). The MRM and IRM
originate on the basisphenoid bone whereas the SOM and IOM originate on the
pterosphenoid bone. Dissections and MRI imaging
(Fig. 3) also revealed that the
PLRM is adjacent to the brain and well insulated by fat (approximately 2.5 cm
thick as determined from MRI), which is made up of white adipose tissue, as
documented by light microscopy (not shown). The thick mass of fat overlies the
thin opisthotic (intercalary) bone that overlies the PLRM and lies between the
PLRM and the gill cavity (Fig.
3). The PLRM is separated from the brain by a thin layer of bone
associated with the braincase.
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Relative size of the extraocular muscles
The mean relative extraocular muscle mass as a percentage of total eye mass
(eyeball and extraocular muscle mass) in the opah (40.1±2.3%,
N=7) was significantly higher than that in the ectothermic chub
mackerel (12.9±2.1%, N=5) (t-test,
P=0.0001). In opah and chub mackerel, the LRM is significantly larger
(mass as a percentage of total eye mass) than all other extraocular muscles
(ANOVA, P<0.05), and the MRM is significantly larger than the SRM,
IRM, SOM and IOM (ANOVA, P<0.05)
(Table 1). The relative mass of
each individual muscle is significantly greater in opah than in chub mackerel
(two-sample t-tests, P<0.05).
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Extraocular muscle histology
Microscopic inspection of the extraocular muscles in the opah provided no
evidence that these muscles are modified for heat production like the
specialized heater tissue of billfishes, butterfly mackerel and slender tuna.
When examined by light microscopy, longitudinally sectioned muscle fibers
within each of the extraocular muscles were striated. Transmission electron
micrographs of all opah extraocular muscles, including the PLRM
(Fig. 4), indicate that these
muscles are made up of normal striated muscle fibers containing
myofibrils.
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In one opah, the CS activity at 20°C of slow-twitch myotomal muscle (4.89 units g–1), fast-twitch myotomal muscle (1.59 units g–1) and red and white regions of the pectoral fin muscle (5.10 and 1.57 units g–1, respectively) were also measured. In this individual, PLRM CS activity was 27.2 units g–1, which is more than five times the highest CS activity measured in its locomotor muscles.
Identification and characterization of potential heat retention mechanisms in the opah
The proximal portion of the lateral rectus extraocular muscle in opah is
perfused by a putative counter-current heat exchange system composed of
numerous parallel blood vessels that were observed on the medial surface of
the LRM in dissections (Fig.
2B). The proximal portion of the superior rectus extraocular
muscle (PSRM) is also perfused by a putative counter-current heat exchange
system that is less extensive than that of the PLRM. The arterial vessels of
both systems originate from the carotid arteries. The efferent branchial
arteries carry cool oxygenated blood from the gills and empty into the dorsal
aorta that branches to form the paired dorsal aortas, which continue
anteriorly towards the head. The two carotid arteries branch from the right
and left dorsal aortas and enter the cranium through ostia (one ostium on each
side of the skull) in the thin opisthotic bone. Small arteries branch from
each carotid artery – some extend anteriorly and others extend
posteriorly (Fig. 2B). The
anterior branches of each carotid artery give off a series of small arteries
that supply blood to the distal portion of the lateral rectus muscle and to
the superior rectus, inferior rectus and medial rectus extraocular muscles of
each eye (Fig. 2B). From the
posterior branches of the carotid artery, a series of small arteries supply
blood to the proximal region of the lateral rectus muscle and form the
arterial part of a putative counter-current heat exchanger.
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In addition, a second putative counter-current heat exchange system was observed on the medial surface of the proximal region of the SRM. Parallel blood vessels branch from the anterior continuation of each carotid artery to perfuse the SRM (Fig. 2B). This putative counter-current heat exchange system is composed of adjacent arteries and veins along the medial surface of the PSRM but there are fewer blood vessels than observed in the proximal portion of the LRM.
There is no evidence of a counter-current heat exchange system perfusing the MRM or any of the other extraocular muscles. In these muscles, blood vessels are dispersed throughout the extraocular muscles and are not in contact with one another in multiple rows as required for effective counter-current heat exchange.
The blood vessels that make up the putative counter-current heat exchangers perfusing the proximal regions of the LRM and SRM would allow heat from the venous blood leaving these muscles to be transferred to the cool blood in the arteries, thereby reducing convective heat loss from the LRM and the SRM to the gills. In addition, conduction of heat to the surrounding seawater from the back of the eye and the proximal regions of both muscles is reduced by the presence of fat. The PLRM and PSRM are both insulated by a layer of white adipose tissue (approximately 2.5 cm thick) that overlies the thin opisthotic bone, which overlies the PLRM. The MRI clearly illustrates how the fat is positioned between the PLRM and the seawater within the gill cavity (Fig. 3A). In addition, the back of each eyeball is entirely surrounded by an approximately 1 cm thick layer of fat.
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|
DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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). Cranial temperatures in live opah were elevated by a mean of 2.1°C and by as much as 6.3°C when compared with myotomal muscle temperature (Fig. 1). Although one live opah had a cranial temperature lower than muscle temperature and several individuals were on or near the isothermal line, most had elevated cranial temperatures, with Tx values similar to those of some other fish species known to be cranial endotherms (Fig. 6). It might be possible for the Tx measured in the opah to result from more rapid rates of warming of the cranial region than of the core muscle as fish, which are caught below the thermocline, pass through the warm, mixed layer on their way to the surface. Opah are typically caught at depths of 265±73 m in 13.0±3.5°C water, where the surface temperature is approximately 18–27°C (D.R.H., unpublished). During retrieval of the long-line gear, opah spend approximately 7 min in the upper, mixed layer (D.R.H., unpublished). However, several lines of evidence argue against this possibility. First, the temperature data for live opah differ from that for dead opah. Even though there is some overlap and some dead opah had high Tx values, the live opah overall had significantly elevated cranial temperatures relative to core muscle temperature whereas the dead fish did not (Fig. 1). Second, only one live opah but 30 of the dead opah had Tx values less than 0°C, meaning that muscle temperature was actually greater than cranial temperature. Because opah are laterally compressed, the cranial region and the locomotor muscle in which core temperatures were measured are a similar distance from the body surface and should warm by conduction at comparable rates but the cranial area may warm more slowly due to the presence of insulating fat. Third, if absorption of heat from the environment explains the elevation of cranial temperatures in opah, then one would expect smaller individuals to have warmed faster than larger individuals and, thus, have a larger difference between cranial temperature and core muscle temperature. However, we found no significant effect of FL on cranial temperature or on Tx.
When the relationship between cranial temperature and myotomal muscle
temperature in opah is compared with similar data for other endothermic
fishes, the opah is most similar to the shortfin mako shark, Isurus
oxyrinchus, and overlaps with some of the tunas, including
Allothunnus fallai, which has specialized heater tissue
(Fig. 6). In shortfin mako and
porbeagle (Lamna nasus) sharks, Tx values ranged
from 0.7°C to 6.7°C, with a mean of 2.8°C
(Block and Carey, 1985). In
tunas, Tx values range from 1.5°C in the black
skipjack, Euthynnus lineatus, to 15.5°C in giant Atlantic
bluefin, Thunnus thynnus (Stevens
and Fry, 1971; Linthicum and
Carey, 1972; Schaefer,
1984; Schaefer,
1985; Sepulveda et al.,
2007). In all groups, Tx is greater at lower
ambient temperatures (Fig. 6)
suggesting the capacity to modulate Tx. Unfortunately,
static values do not indicate the extent to which cranial temperature may be
buffered from ambient temperature changes in vivo and
Tx will probably vary substantially throughout a dive, as
has been recorded by acoustic telemetry in the swordfish
(Carey, 1990).
Based on anatomical, histological and biochemical characteristics, we have provided evidence that the PLRM is the primary source of heat for cranial endothermy in the opah. The PLRM is in the center of the cranial cavity, adjacent to the brain and is the largest extraocular muscle. It is darker red in color and has a higher CS activity, indicating a higher capacity for aerobic heat production, than the distal lateral rectus extraocular muscle, the other extraocular muscles and the locomotor muscles.
We have also identified features that could function to retain the heat
produced by contraction of the PLRM. First, the numerous parallel arteries
branching from the carotid arteries, each surrounded by veins, should conserve
metabolic heat and minimize convection of heat to the gills. The diameters of
the heat exchanger blood vessels that we measured in one opah are similar to
those reported for the cranial heat exchangers in other species, including the
Atlantic bluefin tuna, Thunnus thynnus [80–120 µm for
arteries and 40–150 µm for veins
(Linthicum and Carey, 1972)],
the slender tuna, Allothunnus fallai [50–100 µm
(Sepulveda et al., 2007)], the
blue marlin, Makaira nigricans [100–300µm for arteries and
80–180µm for veins (Block,
1987a)] and the shortbill spearfish, Tetrapturus
angustirostris [100 µm for arteries and 60 µm for veins
(Block, 1987a)]. Second, the
fat layer overlaying the opisthotic bone reduces conductive heat loss from the
PLRM to the gill cavity. Third, the fat surrounding the back of the eyeball
provides further insulation. The position of the PLRM within the cranial
cavity would allow the heat generated by this muscle to warm the brain by
conduction across the thin layer of bone that lies in between them.
In addition to the PLRM, our evidence suggests that the PSRM may also contribute to cranial endothermy. The proximal portion of the SRM is ventral to the braincase and is perfused by a putative counter-current heat exchange system. However, the lower CS activity of the PSRM (Table 2), its smaller size (Table 1) and less developed heat exchanger indicate that the contribution of this muscle to cranial endothermy would be less than that of the PLRM. These same two muscles are modified as heater tissue in billfishes and the butterfly mackerel, respectively, most probably due to their proximity to the brain, optic nerve and eyes.
As the opah swims in the labriform locomotor mode, using the pectoral fins
rather than the axial muscle for routine propulsion
(Rosenblatt and Johnson,
1976), the head moves up and down with each swimming stroke.
Contraction and relaxation of the extraocular muscles most probably
compensates for this recoil, and one might expect that this compensation would
involve greater contractile activity in the superior and inferior extraocular
muscles. However, we propose that it is the lateral rectus that is most
important in elevating cranial temperature in the opah because it is the
largest of the extraocular muscles with the highest aerobic capacity, is
located beneath the brain and is perfused by a large putative heat
exchanger.
Our results demonstrate that the opah's extraocular muscles are not
modified into specialized heater tissue as has been observed in billfishes,
butterfly mackerel and slender tuna. Microscopic observations of the opah PLRM
and PSRM indicate that these muscles are composed of normal striated muscle
fibers containing myofibrils, as are all other extraocular muscles. The
biochemistry supports the same conclusion. The modified heater tissues of
billfishes and butterfly mackerel have a much higher CS activity
(136–290 units g–1 at 25°C)
(Tullis et al., 1991) than the
PLRM of opah (17.4–67.6 units g–1 at 20°C). The
opah's PLRM CS activity is similar to that in highly aerobic fish muscles that
retain their contractile function. For example, the mean CS activity at
20°C in slow-oxidative myotomal muscle of endothermic tunas ranges from
43.4 to 69.8 units g–1 and that of ectothermic scombrids
ranges from 23.2 to 51.1 units g–1
(Dickson, 1996;
Korsmeyer and Dewar, 2001).
The lower CS activity in the distal region of the LRM
(Table 2) most probably results
from differences in fiber type composition along the length of the muscle
(Tullis and Block, 1997). Even
though the extraocular muscles are not modified as heater tissue, it is
possible that enough heat is produced by contraction of the PLRM and PSRM and
retained by the putative counter-current heat exchangers to maintain elevated
cranial temperatures in the opah. The same mechanism of retaining metabolic
heat produced by skeletal muscle contraction results in regional endothermy in
the cranial region of most tunas and in the axial musculature of tunas and
lamnid sharks.
A molecular phylogeny of acanthomorph teleost fishes
(Chen et al., 2003) shows that
the opah (Order Lampridiformes) is distantly related to billfishes, butterfly
mackerel and tunas, all of which are found in the Suborder Scombroidei, Order
Perciformes. Based on this phylogenetic relationship and the principle of
parsimony, cranial endothermy almost certainly evolved independently in the
opah. The putative counter-current heat exchanger in the opah is located
within the cranial cavity whereas the carotid rete of the Atlantic bluefin
tuna is located outside of the cranial cavity, on the posterior margin of the
prootic bone (Linthicum and Carey,
1972), suggesting the independent origin of these structures in
these two fish groups. The opah is the most basal teleost in which evidence of
cranial endothermy has been presented and may represent a first step in the
evolution of this trait. The opah has only a putative counter-current heat
exchanger and adipose tissue to conserve heat produced by contraction of the
LRM and SRM whereas all other fish species exhibiting cranial endothermy
either have a specialized heater tissue or also elevate slow-oxidative
locomotor muscle temperatures (Dickson and
Graham, 2004).
Cranial endothermy in opah would most probably allow for vertical niche
expansion. The opah, like almost all fish species with cranial endothermy, is
a large pelagic visual predator that moves vertically within the water column,
experiencing rapid temperature changes
(Carey et al., 1971;
Carey et al., 1981; Josse et
al., 1988; Dagorn et al.,
2000; Schaefer and Fuller,
2002; Fritsches et al.,
2003; Musyl et al.,
2003; Brill et al.,
2005; Fritsches et al.,
2005; Polovina et al.,
2008). The opah, like other fishes that make deep dives (e.g.
swordfish, thresher shark and bigeye tuna), is able to spend protracted
periods at depth below the thermocline where it is probably foraging in
association with the deep scattering layer
(Carey, 1990;
Dagorn et al., 2000;
Polovina, 2003;
Polovina et al., 2008). It has
been hypothesized that stable cranial temperatures in other fishes reduce the
effects of rapid ambient temperature change on the central nervous system and
that elevated retina and brain temperatures enhance the detection of
fast-moving prey (Carey, 1982;
Block, 1987b;
Carey, 1990;
Block and Finnerty, 1994;
Fritsches et al., 2005;
Van den Burg et al., 2005).
Recent studies in the swordfish showed that elevated cranial temperature
improves temporal resolution by increasing the flicker fusion frequency
(Fritsches et al., 2005).
Cranial endothermy may result in similar benefits in the opah but future
studies are needed to determine if temperature affects the flicker fusion
frequency and temporal resolution in this species. Additional studies are also
required to determine the extent to which cranial temperatures are elevated
and how much cranial temperature changes during dives in free-swimming
opah.
LIST OF ABBREVIATIONS
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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  K. Knight DEEP-DIVING OPAH HAVE HOT HEADS J. Exp. Biol., February 15, 2009; 212(4): iii - iii. [Full Text] [PDF]
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200–450 kg) Atlantic bluefin tuna
(Linthicum and Carey, 1972