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First published online March 27, 2009
Journal of Experimental Biology 212, 1131-1139 (2009)
Published by The Company of Biologists 2009
doi: 10.1242/jeb.028324
Muscle plasticity of Inuit sled dogs in Greenland
1 Department of Biology II, University of Munich (LMU), 82152
Planegg-Martiensried, Germany
2 College of Veterinary Medicine, University of Georgia, Athens, GA 30602,
USA
3 Botany and Zoology Department, University of Stellenbosch, Matieland 7602,
South Africa
* Author for correspondence (e-mail: gerth{at}bio.lmu.de)
Accepted 22 January 2009
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Key words: exercise, muscle ultrastructure, nutrition
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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) have
coined the term "life-cycle staging" for flexible responses of
animals in seasonally fluctuating environments.
Most studies that have analyzed seasonal changes of activity and food
supply in arctic and boreal mammals describe an abundance of food during
summer resulting in seasonal obesity, and famine during winter
(Lohuis et al., 2007;
Mustonen et al., 2004;
Nieminen et al., 2004). Inuit
sled dogs (Canis lupus familiaris L.) differ from this model. During
summer when sledding is impossible, they live chained to rocks with an
intermittent food supply, and so cannot build up fat deposits for the winter
season. During winter they receive more food, but this is also the period of
maximal work load and low-temperature challenge. Therefore, studies on wild
animals living in the same climate zone cannot be extrapolated to Inuit sled
dogs. However, sled dogs may serve as an interesting model to tease apart the
seasonal effects of activity, food supply and temperature on physiology and
internal organ structure. Furthermore, Inuit sled dogs are easily accessible
for repeated measurements of the same individuals in summer and winter. All
individuals in a team live and work under the same conditions, ensuring
uniformity within the experimental group.
Inuit sled dogs are the only domestic animal of traditional Inuit and were essential to the survival of these people for more than 1000 years. The working relationship between dogs and the Inuit is currently losing its importance and, in many places, people no longer hunt using dog sleds. We worked with dogs that are still used by active hunters in the northernmost settlement of Greenland, and compare these dogs with those kept for recreational activities in Western Greenland.
While being used as draft animals during winter and spring, sled dogs are fed regularly and more frequently. During summer and fall, the dogs are permanently chained to rocks and fed only one to three times per week. Because in North Greenland the dogs receive high energy food throughout the year, they remain in a balanced energy budget. In West Greenland the dogs receive low energy food during summer, accumulating an energy deficit. During winter, higher energy food permits balancing of their energy budget.
We used the above differences in husbandry conditions as an experimental
framework within which to explore the effects of exercise level, food supply
and temperature on dog locomotor muscles. Activity (exercise) and nutrition
are the strongest known determinants of skeletal muscle shape and size, which
change fast and reversibly (Boonyarom and
Inui, 2006; Hoppeler and
Flück, 2002; Pette,
2001). To explore the separate effects of these two determinants
on muscle morphology, we compared a suite of variables between seasons (summer
and winter) and food supply, represented by two different locations (the West
with low food supply versus the North with adequate food supply).
These variables were muscle fiber diameter, capillary network and supply area,
and myofibril ultrastructure (sarcomere shape, myofilament alignment and the
sarcoplasmatic compartment), measured on biopsy samples using light and
transmission electron microscopy.
First, to explore the combined effects of exercise and temperature, we
compared muscle samples from summer with muscle samples from winter within
each location. We hypothesized that while dogs were resting in summer, their
muscle fibers would be atrophied relative to the winter condition. And in
contrast to other arctic mammals, which downregulate muscle size in winter as
a result of starvation (Josefsen et al.,
2007), we expected Inuit dogs to upregulate their skeletal muscle
size in response to increased work load, sufficient food supply and cold
acclimatization. Such upregulation of muscle size is presumably based on
changes in fiber size and architecture.
Second, The capillary network is one of the determinants of peripheral gas
and substrate exchange, dictating the metabolic capacity of muscle tissue. The
network is thus optimized to supply muscle metabolic demand
(Baba et al., 1995;
Hoppeler and Kayar, 1988), and
adjusts to chronic electrical stimulation
(Reichmann et al., 1985) or
exercise. This being so, we expected that increased exercise would result in
increased capillarization and a reduced capillary supply area in dogs in
winter.
Third, we assessed the effects of food supply on exercised and resting
muscle by comparing muscle samples between winter and summer, within each
location (North and West Greenland) separately. In anorectic humans, loss of
muscle bulk and muscle fiber atrophy are the most prominent effects of
self-induced prolonged fasting (Lindboe et
al., 1982). McLoughlin et al.
(McLoughlin et al., 2000) also
reported changes in blood plasma parameters in anorectic patients, including
elevated levels of aspartate aminotransferase (AST), an enzyme associated with
the transfer of nitrogen-containing groups between amino acids. Changes in the
blood chemistry of sled dogs competing in a long distance race include
significant increases of AST and creatine kinase (CK), indicating severe
muscle breakdown (Burr et al.,
1997). Here, we tried to clarify whether the seasonal changes in
living conditions of the sled dogs result in similar changes of blood plasma
parameters.
Although sled dogs offer an apparently unique and repeatable opportunity to study flexible responses of individual Arctic mammals to fluctuating conditions, our `experimental' framework of seasonal and locational comparisons has certain constraints. A full cross-over design is not possible because of local traditions and physiological realities: `experimental' groups cannot be reversed as dogs can neither work in summer nor fast in winter while working. It is beyond their physiological scope to work during summer or fast in winter while working. Moreover, biopsy sampling must be limited to a degree that dogs are not impaired and life of the hunters is not at risk.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Temperature recording
Environmental (air) temperatures close to the living area of the dog teams
were recorded every 10 min throughout the fieldwork period using i-Button data
loggers with an on-chip direct-to-digital temperature converter with 11-Bit
(0.0625°C) resolution (DS2422 temperature/data logger, Maxim Integrated
Products, USA). Mean daily temperatures were pooled for each season and
location. Statistical analyses were done using SigmaStat 3.5 (Systat Software
GmbH, Germany). Differences between seasons and between locations were
assessed using Kruskal–Wallis one-way ANOVA on ranks, followed by
pairwise multiple comparisons using Dunn's method.
Dog husbandry
The sex ratio in Inuit sled dog teams is artificially skewed towards one or
two bitches per 10 male dogs. Females can be gravid or have puppies throughout
the year. Therefore, and to avoid inflation of variances as a result of female
reproductive status, we investigated only male dogs. A team of 12 male dogs
(age between 2 and 4 years), was studied in July/August 2005 and in
February/March 2006 in Qeqertarsuaq. In July/August 2007 and in February/March
2008 a total of 10 male dogs (age between 2 and 10 years) belonging to two
different dog teams of active Inuit hunters were studied in Qaanaaq. In
winter, the dogs pulled sleds once or twice per week in Qeqertarsuaq, and
three to four times per week in Qaanaaq, but remained chained to their places
for the remaining time. The feeding regime followed local practice. During
winter, the dogs in Qeqertarsuaq received a daily meal (approximately
150–700 g per dog) of dried fish or frozen seal meat. In Qaanaaq, the
dogs were fed every other day (meal size: about 2 kg per dog). The food
consisted of thawed and heated walrus and seal meat. During hunting trips, the
dogs were fed daily with commercially available food for sled dogs (Nukik
Polar, A/S Arovit Petfood, Esbjerg, Denmark). Throughout the summer, the dogs
were constantly chained to rocks. In Qeqertarsuaq, they were each fed
2.5–3.6 kg of fresh fish in a single meal every fourth day. In Qaanaaq,
each received 1–2 kg of walrus and seal meat from the previous hunting
period every second to third day. Although the total amount of food received
per 4-day period did not differ much between winter and summer, the quality
and energy content of the food did differ. In Qeqertarsuaq, the average daily
energy intake in winter was 4134±934 kJ per dog, but only
3603±388 kJ during summer. In Qaanaaq, the quality of the dog food did
not differ between seasons. Daily energy intake was about 5900 kJ per dog in
summer and 11800 kJ per dog in winter (J.M.S., N.G. and S.J., unpublished
data).
The general health of all dogs was assessed by repeated physical exams performed following standard procedures by a veterinarian. All dogs assessed in Qeqertarsuaq were underweight in summer and winter. They were heavily infested by intestinal parasites during the summer months and suffered from periodic diarrhea. (J.M.S., N.G. and S.J., unpublished data). The dogs studied in Qaanaaq were in good condition in summer and in winter.
Size measurements
Dog body masses were measured using a hanging scale (Kern CH 50K100, Kern
and Sohn GmbH, Balingen, Germany; precision: 0.1 kg) mounted on a carrying
rod. Dogs were placed in a sling that supported the chest and belly while two
people lifted the sling. Head length from the tip of the nose to the caudal
tip of the crista sagittalis was used as an estimate of body size that was
independent of body mass. The measuring tape was placed directly onto the dogs
head and followed the outline of the head. Height was measured at the withers
using a measuring rod.
Ultrasonography
For non-invasive measurements of muscle thickness, we used a portable
ultrasonography machine equipped with a broadband 7.5–10 MHz linear
scanner head (Titan, SonoSite, Bothell, WA, USA)
(Starck et al., 2001). A 0.5%
aqueous solution of a polyacrylic acid (sodium polymer PNC 430, Spinnrad,
Norderstedt, Germany) was applied as acoustic coupling gel. The thickness of
the shoulder muscle, m. supraspinatus, was measured precisely halfway along
the spina scapulae on the dogs' left side while standing
(Fig. 1). The measuring track
(Fig. 2A) was arranged parallel
to the spina scapulae so that the ultrasonograph image covered the widest
dimension of the m. supraspinatus. Muscle thickness of portions of m. triceps
brachii and m. brachialis lateral to the humerus of standing dogs was measured
halfway along the humerus (Fig.
2B). The thickness of the hind leg muscles was measured from the
lateral side halfway along the femur while dogs were standing
(Fig. 2C). These measurements
included parts of the m. biceps femoris as well as parts of the m. vastus
lateralis of the m. quadriceps femoris. The axis of the ultrasound probe was
positioned perpendicular to the spina scapulae at the shoulder and
perpendicular to humerus and femur. At each location we took multiple images
per session, and each dog was scanned for at least four repeated sessions. The
daily averages of multiple measurements were pooled to obtain averages of all
values for each dog, and compared within each location between seasons using
one way ANOVA with season as fixed factor. Statistical analyses were performed
using SPSS version 12.0.1. (SPSS, Chicago, IL, USA).
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Biopsy sampling
A 14 gauge spring-loaded side-cutting needle with a sampling notch of 1.5
cm (Temno; Allegiance Healthcare, McGaw Park, IL, USA) was used for needle
biopsy sampling of the m. adductor magnus. Biopsies were taken from standing
dogs in the field under local Lidocaine anesthesia (1–1.5 ml per dog
Xylocain 2% local infiltration; AstraZeneca, Wedel, Germany), except in winter
2006, when they were obtained from dogs in lateral recumbency while under full
anesthesia for other procedures. We took focused biopsy samples from the
caudal mid-belly region of the m. adductor magnus. We took three biopsies from
one incision site. This procedure minimized a possible negative effect of
biopsy sampling on dog performance. An extensive random sampling as described
by Mayhew (Mayhew, 2008) was
neither possible nor intended. Care was taken to obtain cross-sectional
samples at a 90 deg. angle to the muscle fibers. After biopsy sampling all
dogs received subcutaneous Carprofen injections for analgesia (4 mg
kg–1 Rimadyl, Pfizer GmbH, Karlsruhe, Germany). Bacterial
inflammation was suppressed by a single subcutaneous dose of
amoxicillin/clavulanic acid (10 mg kg–1; Synulox RTU; Pfizer
GmbH, Karlsruhe, Germany).
Histology
Muscle biopsies were preserved in 2.5% glutaraldehyde in 0.1 mol
l–1 phosphate buffer at pH 7.4 and stored at 4°C until
processing for histology. Embedding followed standard protocols for
transmission electron microscopy. Biopsy samples were carefully oriented for
later longitudinal and cross-sections. First, samples were washed in phosphate
buffer, then postfixed in 1% osmium tetroxide in 0.1 mol l–1
phosphate buffer (pH 7.4) for 2 h, and dehydrated in a graded series of
ethanol and pure acetone. Following dehydration, samples were embedded in
epoxy resin (Epon, Carl Roth GmbH, Karlsruhe, Germany). Semithin sections of
500 nm thickness were stained with Rüdeberg solution (Methylene
Blue–Thionin). Ultrathin sections of 60 nm thickness were counterstained
with uranyl acetate and lead citrate. We used a Zeiss EM 10 transmission
electron microscope to examine the sections.
Histological morphometry
When sectioning, careful attention was paid to obtain cross-sections and
longitudinal sections of the samples. For cross-sectional morphometry we
measured only fibers that showed no indication of oblique sectioning, i.e.
elongated fiber diameter with an orientation in one direction. For
longitudinal morphometry, we used only fibers that were running across the
entire length of the section without major change in shape. To obtain
quantitative measures of muscle architecture, we (1) measured the smallest
diameter of all myofibers per section (100–150 myofibers per dog), (2)
counted the number of fibers per area (myofiber density), and (3) measured the
extracellular distance between myofibers. As a measure of capillarization, we
(1) counted the number of capillaries surrounding each myofiber, and (2)
counted the number of capillaries per unit area (capillary density). Because
capillaries supply more than one fiber, we (3) calculated a capillary-to-fiber
ratio by dividing the number of capillaries per mm2 by the number
of fibers per mm2. (4) The capillary supply area was determined as
a circle with the radius being half the mean intercapillary distance around
the capillary. To obtain a random selection of measuring points for the
distance between myofibers (µm), a grid of five lines was laid over
longitudinal sections. Measuring points were defined where grid lines crossed
intercellular space. We used SigmaScanPro (version 5, Jandel Scientific, SPSS
Inc., Chicago, USA) for morphometry of semithin sections in longitudinal and
transversal alignment to the fibers. Two-way ANOVAs with season and location
of the dogs as fixed factors were performed and pairwise comparisons
(Holm–Sidak method, overall significance level=0.05) applied to detect
differences between groups.
Myofiber ultrastructure
The histological examination of ultrastructure was based on TEM images of
longitudinal sections through myofibers. Of course, morphometry of myofiber
ultrastructure is affected by a cascade of factors ranging from biopsy
sampling under non-standard conditions in the field (e.g. extremely low
temperatures during winter) and lack of precise stereological information of
biopsy sampling position (no ultrasound control possible), to dehydration and
embedding artifacts during standard TEM-histology (see
Zumstein et al., 1983). Thus,
morphometric measurements on myofiber ultrastructure are semi-quantitative and
need to be interpreted with caution. We applied three different qualitative
and quantitative measures to analyze the ultrastructure of muscle fibers.
1 is
typical for straight or convex sarcomere, indicating a normal structure of the
myofilaments. We measured the M/Z ratio of all fully visible sarcomeres on
each TEM-image and then calculated the percentage of the sarcomere that were
either normal or concave. Because sample size differs between years and
locations it is always given with the results. We ran a two-way ANOVA to test
for effects of season and location as fixed factors on the measure of
sarcomere shape. When the model was significant, pairwise multiple comparisons
(Holm–Sidak method) were made to recognize significant differences
between groups.
Blood sampling
Blood was obtained from the cephalic vein of the left front leg using a
21-gauge needle, and spun down in heparinized 2 ml tubes at 3000
g for 10 min to gather plasma within 1 h after collection.
Care was taken to prevent the blood samples from freezing. The supernatant was
frozen immediately and stored at –20°C. Blood was sampled from dogs
in postabsorptive condition, in summer, this was at the end of a 4-day fasting
interval in Qeqertarsuaq, and in winter and both seasons in Qaanaaq, this was
24 h after feeding. Measured parameters were liver function and integrity
(aspartate aminotransferase (AST), alanine aminotransferase (ALT), alkaline
phosphatase (AP), urea, triglycerides, glucose, cholesterol and bilirubin);
kidney function [sodium (Na+), potassium (K+),
creatinine, urea, phosphate (PO 3–4)]; muscles and
bones [creatine kinase (CK), lactate dehydrogenase (LDH), calcium
(Ca2+), magnesium (Mg2+), triglyceride]; and digestion
(glucose, fructosamine and cholesterol). Additionally, we measured chloride
(Cl–), total protein, albumin and fatty acids (Qeqertarsuaq:
N=12 in summer, N=11 in winter; Qaanaaq: N=10 in
summer and winter).
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Size measurements
The body mass of dogs from Qeqertarsuaq averaged 27.3±2.7 kg during
winter, which is about 30% above the mean summer mass (19.1±1.6 kg).
The body mass of dogs from Qaanaaq did not differ between the seasons
(33.2±3.0 kg in winter, 33.7±2.7 kg in summer). A two-way ANOVA
with season and location as factors revealed significant differences for both
factors (season: d.f.=1, F=25.3, P<0.001; location:
d.f.=1, F=176.9, P<0.001). Interactions between the
factors were significant (d.f.=1, F=31.4, P<0.001), i.e.
location as a factor determined whether dogs differed in body mass between
seasons or not. Body mass differed between seasons in Qeqertarsuaq (difference
of means=8.2, t=7.8, P<0.001), but not in Qaanaaq. Dogs
from Qaanaaq (61.9±3.2 cm) were significantly taller than dogs from
Qeqertarsuaq (56.6±1.4 cm; d.f.=1, F=9.6, P=0.01).
However, the head length of the dogs did not differ between the study sites
(Table 1).
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Ultrasonography
Ultrasonography of dogs from Qeqertarsuaq showed that shoulder muscles were
on average 19% thicker during winter than during summer (d.f.=1,
F=50.4, P<0.0001)
(Fig. 1), foreleg muscles were
44% thicker during winter than during summer (d.f.=1, F=18.1,
P=0.0002), and hindleg muscles were 39% thicker during winter than
during summer (d.f.=1, F=175.5, P<0.0001). By contrast,
the thickness of shoulder and foreleg muscles of dogs from Qaanaaq did not
differ between seasons, but, their hindleg muscles were significantly (10%)
thicker during winter than during summer (d.f.=1, F=13.1,
P=0.004).
Histological morphometry
For both locations in winter, muscle fibers were packed tightly in clusters
surrounded by capillaries in a thin endomysium
(Fig. 3C,D,
Table 2). Light microscopy
showed numerous mitochondria clustered along the margin of each fiber next to
the capillaries. The intermyofibrillar space was partially filled with lipid
droplets. Distribution of lipids differed between fiber types, which cannot be
discriminated in standard light microscopy. Dogs from Qeqertarsuaq in summer
had rounded muscle fibers loosely packed in an endomysium with more space
between the fibers than in winter. The margin of each myofiber showed no
concentration of mitochondria and the intermyofibrillar space contained only
few lipid droplets (Fig. 3A).
By contrast, the muscle fibers of dogs from Qaanaaq sampled in summer
(Fig. 3B) did not differ much
from winter muscle. Although light microscopy is semi-quantitative, the margin
of the muscle fibers appeared to contain fewer mitochondria in summer than in
winter, and the intermyofibrillar space fewer lipid droplets.
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Morphometric measurement of muscle fiber diameter showed that this was always smaller in summer than in winter, and within each season, was smaller in Qeqertarsuaq than in Qaanaaq. A two-way ANOVA showed that the effects of season and location were highly significant but no interactions between factors were observed (season: d.f.=1, F=15.2, P<0.001; location: d.f.=1, F=12.6, P<0.001). At both locations, the myofiber density was significantly higher (d.f.=1, F=11.1, P=0.002) in summer than in winter. No differences were found for the location and no interaction was detected between season and location.
The distance between myofibers was largest in muscle samples from dogs from Qeqertarsuaq. When tested in a two-way ANOVA with season and location as the main effects, the model was highly significant (season: d.f.=1, F=12.7, P=0.001; location: d.f.=1, F=35.5, P<0.001). However, we detected a significant interaction between factors, thus an interpretation of the main factor would be difficult, i.e. the effect of season will depend on whether the dogs originate from Qeqertarsuaq (difference of means=2.8, t=5.0, P<0.001) or Qaanaaq (no significant difference).
The number of capillaries surrounding one fiber remained constant in summer and winter at both locations. Significantly more (d.f.=1, F=36.4, P<0.001) capillaries surrounded one fiber in Qaanaaq than in Qeqertarsuaq. The capillary density differed significantly between the seasons and between the locations (season: d.f.=1, F=9.5, P=0.004; location: d.f.=1, F=16.7, P<0.001), but no interaction was detected between the two factors. The capillary-to-fiber ratios calculated from the densities of capillaries and fibers were constant throughout the year, but significantly higher (d.f.=1, F=39.1, P<0.001) in Qaanaaq than in Qeqertarsuaq. No interactions between the two factors were detected.
Significant seasonal differences (d.f.=1, F=31.3, P<0.001) were found for the distance between neighboring capillaries, but no difference were observed for the factor `location' and no interaction between the factors. The area supplied by each capillary consequently differed significantly between seasons (d.f.=1, F=30.5, P<0.001), but not between areas, and no interactions between the factors were observed.
Sarcomere ultrastructure
In winter, the sarcomeres were full with a straight or convex outline
(Fig. 4C,D). The myofilaments
were densely packed in straight and parallel arrangement to each other and to
the long axis of the sarcomeres. Between the myofilaments numerous lipid
droplets were stored close to the intermyofibrillar mitochondria. This
ultrastructure of myofibrils holds for muscle samples from winter for both
locations.
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In summer, the ultrastructure of myofibrils of dogs from Qeqertarsuaq looked strikingly different (Fig. 4A). Many sarcomeres had a concave shape, so that the sarcoplasmatic compartment appeared dilated. The myofilaments were less dense and in disorganized arrangement within the sarcomeres. Many myofibrils were oriented oblique to the long axis of the sarcomere. Also, ramifications of sarcomeres were observed which did not occur during winter. The sarcomere structure of dogs from Qaanaaq (Fig. 4B) resembled the winter conditions, but myofilaments appeared to be less densely packed although in orderly arrangement.
In winter, 20% of the sarcomeres of dogs from Qeqertarsuaq but none from the dogs in Qaanaaq were classified as concave (Table 3) whereas in summer this increased to 71% and 20%, respectively. In winter, the myofilaments within the sarcomeres were aligned in parallel in 93% of the samples from Qeqertarsuaq and all samples from Qaanaaq. In summer in dogs from Qeqertarsuaq, the majority of sarcomeres (57%) contained myofilaments obliquely arranged to the long axis of the sarcomere. By contrast, in summer 90% of the sarcomeres of dogs from Qaanaaq contained myofilaments arranged parallel to the long axis of the sarcomere. We observed a dilatation of the sarcoplasmatic compartment in 13% of the TEM images of tissue samples from Qeqertarsuaq and none in the samples from Qaanaaq in winter condition. In summer, 50% of the samples from Qeqertarsuaq and 30% of the samples from Qaanaaq showed extended sarcoplasmatic compartments.
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An M/Z ratio <1, which is indicative of concave sarcomeres, was only found in summer in dogs from Qeqertarsuaq (0.87±0.11, N=9). M/Z ratios of 1 and higher (=straight or convex sarcomeres) were found in dogs from Qeqertarsuaq during winter (1.00±0.10, N=8), Qaanaaq during summer (1.03±0.12, N=10) and Qaanaaq during winter (1.10±0.06, N=8). When tested with a two-way ANOVA the M/Z ratio differed significantly between seasons (d.f.=1, F=8.9, P=0.006) and between locations (d.f.=1, F=14.4, P<0.001). No interactions between season and location were detected.
Blood plasma parameters
Most blood plasma values of dogs located in Qeqertarsuaq were within a
range that would not indicate pathologies. Only one dog showed permanently and
seriously elevated values indicative of hepatic dysfunction, i.e. elevated
values for ALT (measured: 2173 i.u. l–1 in summer, 2689 i.u.
l–1 in winter, reference: 16–91 i.u.
l–1 l), AST (only measured in winter: 243 i.u.
l–1, reference: 19–51 i.u. l–1), and
AP (measured: 1769 i.u. l–1 in summer, 201 i.u.
l–1 in winter, reference: 11–225 i.u.
l–1). Five out of 12 dogs showed elevated levels of creatine
kinase (measured: 653±579 units; reference: 33–351 units) in
winter samples. In Qaanaaq, blood plasma parameters of all dogs were within a
tolerance range for healthy dogs, whereas AP was above the reference value in
seven dogs during winter (measured: 653±579 i.u. l–1;
reference: 11–225 i.u. l–1). Also, four dogs showed
elevated urea levels during winter (measured: 13.6±2.6 mmol
l–1; reference: 3.3–8.3 mmol l–1).
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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The observed fluctuations in body mass of Inuit sled dogs located in Qeqertarsuaq compared with the constant body mass of dogs living in Qaanaaq show that the main factor for changes in muscle size during resting in summer is food supply and food quality. Other parameters, like temperature and activity level were similar at both locations. Because the dogs located in Qeqertarsuaq were lean throughout the year, and because all investigated muscles were significantly thicker in winter than in summer, we conclude that overall body mass differences of these dogs are mainly based on changes in muscle bulk.
Although Inuit sled dogs are a morphologically rather diverse breed, we found no difference in the length of the head of the dogs from the two study sites. Thus we feel confident that the dogs represent similar size classes, even though body mass and of height of the withers differ. Certainly, the breed is uniform throughout Greenland because it is protected by a strict prohibition of any other dog breed north of the Arctic Circle.
In Qeqertarsuaq, the average daily energy intake of dogs was
3603±388 kJ during summer and 4134±934 kJ during winter for dogs
in thermoneutral condition (N.G. and J.M.S., unpublished data). The summer
values are considerably below the values reported for Siberian Huskies (5021
kJ) and Labrador retrievers (5611 kJ) under thermoneutral conditions
(Finke, 1991). The dogs located
in Qaanaaq were in a balanced energy budget and maintained their weight during
summer, receiving about 5900 kJ day–1.
During winter, the daily energy budget of the dogs in Qaanaaq (11,800 kJ;
N.G. and J.M.S., unpublished data) was balanced, but, it was at the lower
margins of the range of values given by Orr
(Orr, 1966), i.e. between
10,500 kJ day–1 for a non-working dog and 21,000 kJ
day–1 for working sled dogs.
Racing sled dogs are known to have the highest sustained metabolic rates
(47,100 kJ day–1) of any mammal measured so far
(Hammond and Diamond, 1997;
Hinchcliff et al., 1997).
Histological morphometry and sarcomere ultrastructure
Many studies have analyzed ultrastructural changes of muscles in response
to endurance training, inactivity or fasting
(Flück, 2006;
Hamilton and Booth, 2000).
Lindboe and Prestus (Lindboe and Prestus,
1985) found that immobilization and food deprivation had different
effects on the size of different histochemical fiber types in the tibial
muscles of rats. Food deprivation resulted in atrophy of all fiber types, but,
immobilization resulted in a differential size change of different
histochemical fiber types.
The dogs in Qeqertarsuaq experienced the combined effects of inactivity and undernourishment during summer, whereas the dogs in Qaanaaq experienced only inactivity but were well fed. Thus, by comparing these two groups, we can partition change of muscle size and structure for effects of undernourishment and inactivity.
The average diameter of muscle fibers of dogs during winter at both
locations, and of dogs in Qaanaaq during summer is within the range of
50–64 µm reported for domestic dogs
(Z'Berg and Augsburger, 2002).
The diameter of muscle fibers of dogs during summer in Qeqertarsuaq is much
smaller, indicating atrophy of muscle fibers. Based on a qualitative or
semi-quantitative analysis, Lindboe et al.
(Lindboe et al., 1982)
reported that anorectic human patients also have muscle fiber diameters that
are significantly below average. McLoughlin at al.
(McLoughlin at al., 1998)
found that the muscle fibers of anorectic patients showed separation and
segmental loss of myofibrils in the m. vastus lateralis, thus indicating
severe atrophy. All these patients were physically active, some even
over-exercising, walking or jogging up to 6 h daily, so the skeletal muscle
atrophy with underlying ultrastructural changes was clearly a result of
undernutrition and not of inactivity. These findings are identical to what we
see in dogs from Qeqertarsuaq, where dogs were undernourished and inactive. In
Qaanaaq, where dogs were well nourished and inactive, we did not find any of
these changes. Based on the similarity of ultrastructural findings, we can
safely conclude that depletion of myofilaments and segmental ramification of
sarcomeres is a result of undernourishment. Comparing a large number of TEM
images, the effects of undernourishment appear to be unevenly distributed
within a myofiber, i.e. some myofibrils are more affected than others,
resulting in differential depletion of sarcomeres.
We introduced the M/Z ratio as a semi-quantitative measure to support the observed sarcomere changes. The key to interpreting changes of the M/Z ratio is that the Z-line remains constant while the M-line changes with an increasing or decreasing size of the contractile filament compartment in a sarcomere. Thus, an M/Z ratio smaller than 1 indicates a reduction/depletion of myofilaments from a sarcomere whereas an M/Z ratio of 1 or higher suggests normal sarcomere structure. The M/Z ratio of Qeqertarsuaq dogs during summer suggests a serious depletion of sarcomeres, whereas Qeqertarsuaq dogs during winter and all dogs from Qaanaaq had normal sarcomeres. However, many of our TEM images showed that for example in dogs from Qeqertarsuaq in summer even within one myofibril the sarcomere structure varies between full and depleted. We suggest that this sketchy pattern is caused by differential depletion of myofibrils. Because we applied random sampling for M/Z-ratio measurements we are confident that we have identified average differences between muscle samples from different locations and different seasons. Because we have taken that measurement only on clearly defined longitudinal sections of muscles we excluded stereological artifacts. Differential depletion of myofibers explains the patchy pattern of concave sarcomeres and the rather proportional changes of depleted sarcomeres observed between the different groups.
The capillary network supposedly is an important determinant for oxygen
transport to the muscles (Hoppeler and
Kayar, 1988). The dogs in all four groups of our study maintained
a stable capillary network throughout the year, as shown by the constant
capillary-to-fiber ratio and the constant number of capillaries adjacent to
one myofiber. However, dogs from Qaanaaq that were used more intensively for
hunting always had a higher capillary-to-fiber ratio than dogs from
Qeqertarsuaq. We also found significant differences in capillary density and
the distance between neighboring capillaries between the seasons. Because in
each of these groups the capillary density is higher in summer than in winter,
we conclude that these changes are not affected by training but are related to
the decreased fiber size in summer. When the fiber diameter decreases but the
capillary network remains unchanged the capillary density per area will
automatically increase. The same type of correlated changes was described by
Deveci and Eggington (Deveci and Eggington,
2002) in a morphometric study of Syrian hamsters.
At a first glimpse, our results appear to be in partial contrast to those
of Capric and James (Capric and James, 1983) who reported that the
capillary-to-fiber ratio of untrained dogs increased after training on a
treadmill for 6 weeks. However, in our study, the capillary-to-fiber ratio of
the dogs from Qeqertarsuaq always was in the range of the values found in
untrained dogs, whereas the dogs from Qaanaaq had a capillary-to-fiber ratio
comparable to that of trained dogs, but we found no change in the
capillary-to-fiber ratio in response to season. We suggest that training has a
long-term effect on the capillary network and is not easily downregulated
during periods of low activity. This would explain why the dogs from Qaanaaq
that were more frequently used for sledding have a higher capillary-to-fiber
ratio than dogs from Qeqertarsuaq that were used only on shorter and
occasional trips. However, the capillary network may be affected by many more
factors than just training, e.g. Hepple and Vogell
(Hepple and Vogell, 2004) and
Mathieu-Costello et al. (Mathieu-Costello
et al., 2005) showed that the capillary network does not change
with age. This suggests that once the capillary network has been established
there is no flexibility for downregulation, ultimately supporting our
interpretation of long-term effects on the capillary network and the lack of
flexibility for downregulation.
Other mammalian model systems show similarly contrasting results. For
example, capillary densities of heart and skeletal muscles of European
woodmice (Apodemus sylvaticus) that were trained on a treadmill did
not differ from activity-restrained woodmice
(Hoppeler et al., 1984). But,
in rats (Poole and Mathieu-Costello,
1989) and humans (Ingjer,
1979; Zumstein et al.,
1983) endurance training resulted in an increased capillary
network.
Blood plasma parameters
Blood plasma parameters must be discussed with caution. Blood sampling and
in particular storage cannot always match standard conditions as requested by
laboratory protocols. In our study, samples could not be kept at
–25°C during transport back to the home laboratory thus potentially
increasing error variance in the final analysis. Blood samples in general
suggested a satisfying health status of the dogs, except for one dog in
Qeqertarsuaq, which obviously suffered from some liver dysfunction. However,
this dog in particular was very active and second in the hierarchy of the
team, and did not show any signs of impaired health.
An elevated level of AP is difficult to interpret if it is not clearly
associated with other blood plasma parameters. Elevation of AP can be
associated with extreme exercise or over-exercising. For example, Hinchcliff
(Hinchcliff, 1996) and Burr et
al. (Burr et al., 1997)
compared sled dogs finishing a long distance race with dogs that did not
finish the race, and always found significantly higher levels of AP in the
non-finishing group than in the finishing group.
Conclusion
The reported seasonal changes in skeletal muscle morphology of Inuit sled
dogs are a result of the Greenlandic sled dog husbandry, that varies depending
on the importance of the dogs in the daily life of the Inuit. The summer
season is marked with movement restriction and severe undernutrition in parts
of Greenland, where the dogs are no longer important in peoples' daily lives.
During the working winter season the dogs receive sufficient food; especially
where they are still used frequently for hunting and transportation, in the
northernmost parts of Greenland. While other arctic mammals gain weight
rapidly during summer and build up fat deposits for the upcoming winter
season, the sled dogs keep or even lose weight in summer as a result of
undernourishment and inactivity. In summer, skeletal muscle morphology of dogs
kept in western Greenland is characterized by atrophied fibers with depleted
and deranged myofilaments in the concave sarcomeres. The sarcoplasmatic
compartment is dilated. These changes in muscle structure are reversible and
the dogs quickly recover, their muscles gain full functionality and normal
structural appearance when fed more and regularly during the working season.
Muscle fibers of dogs kept in Northern Greenland are atrophied too, but packed
densely during summer and the structure of the sarcomeres appears normal. By
contrast, the capillary network remains unchanged throughout the year at both
locations.
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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  K. Knight INUIT SLED DOGS' AMAZINGLY PLASTIC MUSCLES J. Exp. Biol., April 15, 2009; 212(8): ii - ii. [Full Text] [PDF]
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