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First published online February 27, 2009
Journal of Experimental Biology 212, 790-796 (2009)
Published by The Company of Biologists 2009
doi: 10.1242/jeb.025387
Diving into old age: muscular senescence in a large-bodied, long-lived mammal, the Weddell seal (Leptonychotes weddellii)
1 Department of Marine Biology, Texas A&M University at Galveston, 5007
Avenue U, Galveston, TX 77551, USA
2 Marine Mammal Research Unit, University of British Columbia, Room 247, 2202
Main Mall, Vancouver, BC, Canada V6T 1Z4
3 Department of Fisheries and Wildlife, Marine Mammal Institute, Oregon State
University, 2030 SE Marine Science Drive, Newport, OR 97365, USA
4 School of Fisheries and Ocean Sciences, University of Alaska Fairbanks, Alaska
SeaLife Center, 301 Railway Avenue, Seward, AK 99664, USA
5 Department of Health and Kinesiology, Intercollegiate Faculty of Nutrition,
Texas A&M University, College Station TX 77843, USA
* Author for correspondence (e-mail: a.hindle{at}fisheries.ubc.ca)
Accepted 6 January 2009
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Key words: muscle morphology, collagen, diving, aging
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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; Parsons,
2002), and aging theories suggest absence of selection for
adaptations to aging (i.e. different phenotypes between old and young groups)
as this would probably occur at the cost of the individual's inclusive fitness
(Troen, 2003). However,
large-bodied, long-lived mammals are an acknowledged exception
(Gaillard et al., 1994;
Hulbert et al., 2007), and
oxidative stress theories of aging (Sohal
and Weindruch, 1996; Hulbert
et al., 2007) support the suggestion that breath-hold foragers
such as diving, air breathing vertebrates may be particularly susceptible to
oxidative stress and resultant cellular dysfunction and senescence. The life
histories and physiological ecology of many diving mammals, particularly
pinnipeds, are well described. Although ontogeny and early adulthood have
received ample attention (Horning and
Trillmich, 1997a; Horning and
Trillmich, 1997b; Burns
1999; Burns et al.,
1999; Noren et al.,
2001; Kanatous et al.,
2008), few studies have investigated processes, constraints and
adaptations related to aging in older adult pinnipeds. There is limited, mixed
evidence for reproductive senescence in pinnipeds (Boyd et al., 1985;
Pistorius and Bester, 2002;
Beauplet et al., 2006;
Proffitt et al., 2007), and
none for organismal senescence. The difficulty of conducting long-term
ecological studies on land- or ice-breeding aquatic foragers contributes to
the paucity of this information. Aging in wild populations is of ecological
significance since recent life tables generated for several threatened or
declining marine mammal species suggest `aging' populations
(Knowlton et al., 1994;
Hanni et al., 1997;
Holmes and York, 2003), with
older animals constituting a greater proportion of adults, and increasing the
significance of their reproductive output. It is unknown whether aging processes, which are well-documented in humans and domesticated or laboratory-raised mammals, are detectable in long-lived, wild marine mammals. Because of the complex physiological adaptations and adjustments necessary for the daily activities of these breath-hold hunters, such aging processes are likely to impact overall performance (A. G. Hindle and M. Horning, in preparation). Many life history traits including foraging, migration, territory defense and predator avoidance are all critically dependent on skeletal muscle function. Proximate changes in skeletal muscle can be expected to play out at the whole animal level, thereby bridging the conceptual gap between cellular aging and population level senescence.
Skeletal muscle aging is typically characterized by the loss of both
force-generating capacity and muscle endurance
(Evans, 1995). In addition to
the age-related loss of performance caused by declines in muscle mass and
cross-sectional area, a loss of force generation per unit cross-sectional area
(i.e. quality) has also been documented in rodents, primates, domestic animals
and humans (Brooks and Faulkner,
1994; Thompson,
1999). This multi-faceted decline of muscle mass, strength and
quality with advancing age is termed `sarcopenia'.
In humans and laboratory-raised animals, aging is equally detectable in the
contractile and connective tissue components of skeletal muscle. Collagenous
connective tissue makes up the extracellular matrix (ECM), which provides
support and defines muscle framework. The mechanical properties of this ECM
affect those of muscle as well, because the force generated by contractile
tissue must overcome internal work created by connective tissue components in
order to generate movement (Kjaer,
2004). Importantly, collagen content and collagen cross-linking
increase with advancing age in rodents and humans
(Mays et al., 1988;
Kovanen and Suominen, 1989;
Gosselin et al., 1998).
Though many collagen isoforms occur in skeletal muscle, the stiffer type I
and more compliant type III are key in defining ECM mechanical properties
(Kovanen, 2002;
Kjaer, 2004). Despite
functional differences amongst collagen isoforms, higher relative and overall
collagen levels correlate with increased muscle stiffness, or
length–passive tension (Alnaqeeb et
al., 1984; Gosselin et al.,
1994), which is expected to impair muscle contraction or
relaxation events (Alnaqeeb et al.,
1984). As with total collagen content, an adjustment in the ratio
of the two key isoforms can influence contractile properties. Exercise
training, injury, disease and aging are all associated with some degree of ECM
remodeling (Mohan and Radha,
1980; Marshall et al.,
1989; Williams et al.,
1999; Miller et al.,
2001; Mackey et al.,
2004). Detectable signs of normal aging in skeletal muscle include
increased deposition of total collagen
(Mays et al., 1988;
Kovanen and Suominen, 1989;
Gosselin et al., 1998)
resulting from increased resistance to collagen degradation and turnover
(Mohan and Radha, 1980), as
well as a relatively greater contribution of type I, at the expense of type
III, to the collagen pool (Mays et al.,
1988; Kovanen and Suominen,
1989). Both developments are expected to compromise the internal
work capability of skeletal muscle with age.
Based on aging theory, we tested the null hypothesis that free-ranging Weddell seals do not survive to a time at which age-associated remodeling of myofibers and the ECM becomes detectable. Specifically, the histology of emerging senescence was quantified in contractile and connective tissue components of propulsive (longissimus dorsi) and maneuvering (pectoralis) muscles in individual, known-age seals.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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).
Seals were restrained initially with a head-bag (Stirling, 1966) and then were
chemically sedated with an intramuscular injection of ketamine hydrochloride
combined with diazepam (2 mg kg–1 ketamine: 0.01 mg
kg–1 diazepam) or midazolam hydrochloride [2 mg
kg–1 ketamine: 0.1 mg kg–1 (J. E. Mellish et
al., in preparation)]. Animals were weighed from a suspended force
transduction scale (San Diego Scale Company, San Diego, CA, USA; accurate to
0.5 kg). Only males and non-pregnant, non-lactating females were sampled.
Absence of late stage fetus and amniotic sac was confirmed by trans-abdominal
ultrasonographic imaging (Sonosite 180 Vet; Bothwell, WA, USA) prior to
sampling, and lactation status was derived from an available database of
females noted to have produced a pup earlier in the season. Animal selection
for the study was random, and independent from apparent health at time of
capture, although one additional female was not sampled because of ethical
considerations based on health complications that became apparent during
initial sedation. Muscle biopsies were collected upon initial capture, or in
the case of 19 females, only during the last of multiple sequential captures
(10±1.0 days, 2–16 days after initial capture), to avoid muscle
biopsies potentially affecting simultaneously recorded behavioral telemetry
data. All work was conducted under permits through the Antarctic Conservation
Act (#2007–007) and Marine Mammal Protection Act (#1034–1854), as
well as local animal use committees (Texas A&M University Animal Use
Protocol #2006–160; Alaska SeaLife Center Animal Use Protocol
#05–004; and Oregon State University Animal Use Protocol #3454). Biopsies were collected under sedation and application of a local anesthetic from longissimus dorsi and pectoralis muscles. Biopsy sites (5 cm'5 cm) were clipped and shaved, cleaned with povidone iodine scrub and 70% isopropyl alcohol, and blocked with 1 ml lidocaine (2%). After 10 min, an incision was made with a #10 scalpel, and the sterile biopsy needle [0.635 cm (1/4'') o.d. x 20.32 cm (8'') UCH Needle, Popper and Sons, NY, USA] was inserted. A maximum of six muscle biopsies were collected per site. Following sample collection the wound was flushed with cephazolin sodium (Webster Veterinary, Sterling, MA, USA; 0.5 g in 5 ml distilled water).
Muscle biopsies for histological analyses were placed immediately in ice-cold cryoprotectant (7% glycerol, 4% sucrose in PBS) for approximately 1 h. Samples were then removed, blotted dry, mounted in tissue freezing medium (TissueTek OCT, Sakura, Torrence, CA, USA) and frozen in liquid nitrogen-cooled isopentane. Muscle samples were stored at –80°C for up to 3 weeks prior to analyses.
Muscle morphology
Cryopreserved muscle biopsies were sectioned for all subsequent analyses at
–20°C on a cryostat (TissueTek). Serial 7–9 µm sections
were examined with a light microscope to confirm transverse orientation.
Slides were air dried for up to 30 min, then stored at –80°C in
airtight slide boxes for up to 3 weeks prior to processing. To visualize
muscle morphological features such as fiber cross-sectional area and myocyte
density, frozen slides were warmed at room temperature (RT), rinsed in PBS and
stained with Hematoxylin (1 min). Extracellular space (ECS) was calculated for
each slide from the measured fiber cross-sectional area and density (myocyte
density x average cross-sectional area), and expressed as a volume
percentage.
Collagen
Total collagen was visualized with Picrosirius Red histochemical staining
(Sweat et al., 1964). The
original method was modified by the addition of phosphomolybdic acid
treatment, which has been reported to prevent uptake of the Picrosirius Red
stain into the cytoplasm (Dolber and
Spach, 1987). Sections were fixed in Bouin's solution for 30 min
at room temperature. Slides were rinsed (1 min) in distilled water and placed
in 0.2% phosphomolybdic acid for 5 min, prior to a 90-min immersion in
Picrosirius Red solution (0.1% F3B Sirius Red in saturated aqueous picric
acid). Slides were rinsed for 10 s each in acidified H2O (0.5%
glacial acetic acid) and picric alcohol (20% ethanol, 70% dH2O, 10%
picric acid), then dehydrated (70%, 95%, 2x100% ethanol), cleared in
xylene, and mounted.
Collagen types I and III were analyzed in muscle cross sections following
the method described by Mackey et al.
(Mackey et al., 2004).
Briefly, frozen sections were fixed in acetone at –20°C, then
blocked with 5% goat serum in TBS (50 mmol l–1 Tris, 150 mmol
l–1 NaCl, pH 7.5) for 60 min at room temperature. Sections
were washed (0.5% Tween 20 in TBS) and then incubated with rabbit primary
antibody (Rockland Immunochemicals, Gilbertsville, PA, USA) for 40 min at room
temperature. Primary antibodies were diluted in 1% BSA-TBS in the ratios of
1:75 for type I collagen, and 1:100 for type III collagen. Sections were
washed again and incubated for 30 min at room temperature in
peroxidase-labeled goat anti-rabbit secondary antibody (Rockland
Immunochemicals, 1:1000 diluted in 1% BSA-TBS). After a final wash, sections
were stained with diaminobenzidine substrate-chromogen (5-min exposure; Dako,
Carpinteria, CA, USA) and the amounts of the collagen isoforms determined.
Slides were rinsed in dH2O and then dehydrated in 95% and 100%
ethanol, cleared with xylene and mounted.
Image analysis
All images were viewed with a Nikon E400 microscope, and collected using a
Spot Pursuit Slider CCD camera. Images were calibrated (to the nearest 1
µm) using a stage micrometer. Muscle morphology, such as myocyte densities
and cross-sectional areas, as well as areas occupied by type I, type III, and
total collagen were quantified using ImageJ image analysis software (version
1.37s, National Institutes of Health, Bethesda, MD, USA). A minimum of 50
myocytes were included in the analyses for each animal. Cells directly
adjacent to the edge of the section were excluded. Total collagen was
identified by positive extracellular staining with Picrosirius Red. The ImageJ
thresholding feature was used to isolate and quantify these stained
intercellular regions. Regions identified as type I or type III collagen based
on immunohistochemistry were similarly isolated and quantified.
Statistics
Adult seals were classified as either `young' (ages 9–16 years) or
`old' (17+ years), per the reproductive population data available for this
species (Proffitt et al.,
2007). Histological variables were considered with respect to seal
age (i.e. `young' or `old' cohort), sex and biopsy location (longissimus or
pectoralis muscles) using three-way ANOVA procedures. LSD post-hoc
tests for significant differences in sample means were performed when global
F-tests were significant. When F-tests did not reveal any
significant differences between males and females, data from both sexes were
pooled for post-hoc comparisons. Data were tested for normality using
the Shapiro–Wilkes statistic and homogeneity of variance was confirmed
using a modified Levene test. Natural log transformations were employed when
necessary to meet assumptions for parametric tests. Significance was set at
the 5% level and means are presented ± 1 s.e.m. Statistical analyses
were performed using SPSS software (version 11.5.1; Chicago, IL, USA).
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Myocyte morphology
In only one instance (myocyte density, see below) were differences detected
between male and female (non-lactating, non-pregnant) seals in any of the
histological variables measured. For all other variables in which no
significant difference was seen between males and females, data from both
sexes were pooled for post-hoc comparisons. Myocyte cross-sectional
area (CSA) was significantly lower in pectoralis
(4046±156µm2) compared with longissimus dorsi
(5057±185 µm2; F1,64=22.593,
P<0.001; Fig. 1;
Table 1) muscle. CSA increased
by 22% with age in the longissimus dorsi (P=0.003), but a similar
increase did not occur in the pectoralis (P=0.565).
As CSA increased in the longissimus dorsi of older seals, myocyte density
decreased (P=0.012; Table
1). A parallel decrease in myocyte density (16%) also occurred in
the pectoralis (P=0.030; Table
1). Despite the similar degree of myocyte density decline in both
muscle groups, a significant site effect was observed, with density 18.5%
higher overall in the pectoralis (F1,54=10.920,
P=0.002; Table 1).
Aging was associated with a 35–40% increase of ECS in both the
longissimus and pectoralis (F1,54=7.571,
P=0.008), and was 
30% higher in the pectoralis overall
(F1,54=4.628; P=0.036;
Table 1).
Myocyte density was the only histological variable measured for which a significant sex difference was noted (F1,54=4.098; P=0.048), with females showing 12% higher densities than males overall. This difference occurred alongside significant interactions between age and sex (F1,54=10.920; P=0.002), as well as age, sex and muscle type (F1,54=5.997; P=0.018).
Collagen
Total collagen content (%) was significantly elevated with age in both
muscles (ln-transformed; F1,72=44.674,
P<0.001; Table 2)
and was not significantly different between muscles
(F1,72=1.581, P=0.213). Total collagen increased
115% in the longissimus (from 5.9% in `young'; P<0.001), and 65%
in the pectoralis (from 7.6% in `young'; P<0.001).
The combined result of age-related changes in myocyte morphology and
collagen content is the ratio of muscle to collagen (volume ratio within
analyzed biopsy area). This ratio is depressed in old adults (ln-transformed;
F1,53=41.897, P<0.001;
Table 2) in the longissimus
dorsi (63%; P<0.001) and in the pectoralis (49%;
P<0.001; Table 2).
The unique degrees of decline with age in the two muscles results in a
significant location difference (F1,53=5.821,
P=0.019; Table 2).
When compared for the `young' cohort, muscle: collagen is 30% lower in
the pectoralis (P=0.029) and this ratio declines with age to levels
that are not significantly different from each other (P=0.310;
Table 2).
Collagen types were documented for only the 2006 data set because of a labeling failure with the 2007 antibody batch. Despite the limited data set, an age effect was seen in the ratio of collagen type I to III (ln-transformed; F1,26=15.049, P=0.001; Fig. 2, Table 2). This ratio increased with age in both muscles (79% in the pectoralis, P=0.009; 49% in the longissimus dorsi, P=0.035), resulting in no significant effect of biopsy location (P=0.917; Table 2).
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Muscle morphology
In free-ranging Weddell seals (aged 9–26 years) average myocyte CSA
was higher in longissimus dorsi (5057 µm2) than in pectoralis
(4046 µm2) muscle. The elevated CSA for the longissimus dorsi
can in part be explained by a significant (22%) increase in this variable with
age, compared with a mere 4% non-significant increase in the pectoralis. Even
in young adults, myocyte CSA of the longissimus exceeds that of the pectoralis
by 17% (Table 1). This
difference could reflect muscle power output, in that the longissimus muscle
serves primarily a propulsive function in phocid seals, whereas pectoralis is
used for maneuvering, and controls pitch and directionality.
The age-related elevation of CSA in Weddell seal myocytes is at odds with
expectations for mammalian muscle aging, which is generally associated with
declining myocyte size (Evans,
1995). Although increasing mass with age is expected for Weddell
seals (Fujise et al., 1985),
this trend diminishes beyond prime reproductive age (J. E. Mellish et al., in
preparation). The observed age-related elevation in myocyte CSA, therefore,
cannot be explained by increased body mass. Our finding is also contrary to
the classic expectations for muscle structure adjustments based on constraints
associated with apneustic or hypoxic exercise. Hypoxic tissue environments,
similar to the chronic hypoxia of mountaineering, are generally associated
with CSA declines to improve tissue oxygen handling
(Hoppeler et al., 1990). The
regular apneustic exercise in diving, air breathing vertebrates should result
in chronic submergence hypoxia (Guyton et
al., 1985; Qvist et al.,
1986; Davis and Kanatous,
1999; Ponganis et al.,
2007). However, adaptations for apneustic exercise and tolerance
to tissue hypoxia might reduce selective forces leading to CSA declines with
age.
The observed age-related elevation in myocyte CSA could be explained by increased loading or use. Because body mass did not significantly increase along with myocyte CSA, it is unlikely that these increases are in response to loading outside the muscle. Instead this suggests that CSA increases are an adaptive response to increased internal work demands related to fibrosis and elevated muscle stiffness.
The large myocyte CSAs of Weddell seals correspond to elevated diffusion
distance, and indeed low indices of capillarity are documented for this
species (Kanatous et al.,
2002). In compensation, Weddell seal muscles are characterized by
a predominantly interfibrillar mitochondrial distribution, elevated volume
density of interfiber lipid droplets, and high skeletal muscle myoglobin
content (Kanatous et al.,
2002). There is a correlation between the elevated myocyte CSA in
the longissimus dorsi compared with the pectoralis, and the myoglobin contents
of these muscles (45.9±3.3 mg g–1 wet weight
versus 31.5±4.6 mg g–1 wet weight)
(Kanatous et al., 2002). The
age-related elevation of CSA in the longissimus dorsi in this study is not,
however, accompanied by a significant myoglobin increase (A. G. Hindle et al.,
in preparation). If elevated myoglobin content is not driving the increased
myocyte CSA either, again we speculate that this occurs as a result of
elevated internal resistance related to increases in the ECM and in relative
collagen content. In any case, the lack of a concomitant myoglobin elevation
alongside myocyte CSA could imply that aged longissimus dorsi muscles are more
susceptible to the development of a hypoxic core during underwater or
terrestrial activity, potentially affecting aerobic dive limit, or leading to
fatigue and injury.
Myocyte density decreased with advancing age in both muscle groups examined
(Table 1). This could be the
result of the observed increase in myocyte CSA with age, or rather, the change
in CSA may be a compensatory, exercise-induced hypertrophy of remaining
fibers. The higher myocyte densities found in the pectoralis, over the
longissimus, in both age groups is a function of its consistently lower fiber
CSA (Table 1). Amongst
significant interaction effects, myocyte density was the only variable for
which a significant sex difference was noted. As muscle stress and injury
contribute to apoptosis-driven myofiber loss (Yashuhara et al., 2000;
Phaneuf and Leeuwenburgh,
2001; Pollack et al.,
2002), perhaps the generally reduced fiber densities observed for
males compared to females is the result of elevated muscle stress related to
territory defense during the breeding season, when our sampling occurred.
Extracellular space
A significant increase of 35–40% in ECS occurred with age in
free-ranging Weddell seals (Table
1). The elevation of ECS may diminish specific force of muscle
(force per muscle CSA, and per muscle mass), given that a smaller proportion
of total muscle volume is contractile tissue. Age-related motor unit loss via
apoptosis or denervation (Dirks and
Leeuwenburgh, 2002; Brooks and
Faulkner, 1994) provides a mechanism for expanding ECS, as
remodeling subsequent to motor unit removal generally compensates incompletely
for fiber loss (Edström and Larsson,
1987; Brooks and Faulkner,
1994). Adjustments in collagen turnover with age (see below)
probably contribute to ECS increases. Such contractile power loss may have
important fitness considerations (A. G. Hindle and M. Horning, in
preparation). Furthermore, declines in muscle performance may be of particular
significance for males during the breeding season, in which aggressive
territoriality by underwater defense of breathing holes is paramount to
reproductive success.
Collagen
A striking increase in extracellular collagen within the endomysium was
noted in mature seals in both muscle types (115% in the longissimus, 65% in
the pectoralis; Table 2).
Muscle stiffening due to heightened collagen content or stability has been
widely reported in terrestrial mammals
(Mohan and Radha, 1980;
Kovanen and Suominen, 1989;
Gosselin et al., 1998). Such
collagen remodeling in aged muscle (mediated by transforming growth
factor-beta) has also been documented subsequent to mechanical, cytokine or
oxidative tissue stress (Border and Noble,
1994; Cannon and St Pierre,
1998). As expected, increased total collagen content was
accompanied by a decreased cross-sectional area ratio of muscle to collagen,
generally accompanied by tissue stiffness
(Kovanen et al., 1984;
Gosselin et al., 1994;
Gosselin et al., 1998). These
age-related developments in the swimming muscles of Weddell seals could impede
contractile force production and efficiency, and elevate energy requirements
for locomotion and foraging.
Type I collagen is the `stiffer' isoform, lending structural rigidity and
storing elastic energy to increase fatigue resistance
(Kovanen, 2002). Type III
collagen, by contrast, confers compliance to muscle, more easily permitting
structural changes and faster contractions
(Kovanen, 2002). Type I was
the dominant form of collagen in all samples analyzed
(Fig. 2). The ratio of collagen
type I to type III was similar in both muscles, increasing with age by
1.5x in the longissimus dorsi and 1.8x in the pectoralis
(Table 2). These age-related
changes were comparable to those in laboratory-raised rats (ratio of 2.1 at 1
month; 4.0 at 2 years) (Kovanen and
Suominen, 1989), although on average this ratio did not exceed 3.5
in seals (Table 2).
Increased muscle stiffness with age, as a result of elevated total and
relative collagen content and an increased type I:III collagen ratio, benefits
the stability and fatigue resistance of slow-twitch fibers
(Kovanen et al., 1984), the
dominant muscle type in Weddell seals
(Kanatous et al., 2002). This
stability may, however, compromise sprint capacity and increase the likelihood
of muscle injury and fatigue following burst-force generation
(Kovanen et al., 1984). It may
also compromise contractile efficiency, as a greater force output is necessary
to overcome this heightened elastic component for a contraction of a given
size. For seals exploiting the same prey resources throughout a lifetime,
older individuals would be at an energetic disadvantage. Energetic simulations
for aging Weddell seals reveal that even a small decline in the contractile
ability of swimming muscle can produce a significant negative impact on
energetic efficiency of foraging (A. G. Hindle and M. Horning, in
preparation).
Conclusions
We reject the null-hypothesis that Weddell seals do not survive to an age
where remodeling of myofibers and ECM become detectable. Age-specific
reproductive rates in female Weddell seals remain elevated until the age of
20–22 and above (Cameron,
2001), and females have been recorded to pup to the age of 28
(Proffitt et al., 2007). This
suggests that, contrary to predictions from classic theory of aging, muscular
senescence does occur in these wild mammals well within their reproductive
lifespan.
Our findings also suggest a probable effect of aging on sprint capacity and contractile efficiency. Modeling the effects of a possible reduction in contractile efficiency (A. G. Hindle and M. Horning, in preparation) in turn suggests a probable effect on foraging efficiency with age, as a result of such muscular senescence. Data and model combined suggests two potential outcomes for aging marine mammals in the wild: (1) tissue aging (in this case, skeletal muscle) is the basis for performance declines, leading to individual organismal senescence, altered energy balance, compromised individual condition and health, and ultimately reproductive senescence; (2) behavioral plasticity might compensate for the deleterious effects of aging on performance, allowing individuals to maintain positive energy balance and reproductive output, through adjustments of foraging behavior.
LIST OF ABBREVIATIONS
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Footnotes |
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References |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Alnaqeeb, M. A., Al Zaid, N. S. and Goldspink, G. (1984). Connective tissue changes and physical properties of developing and ageing skeletal muscle. J. Anat. 139,677 -689.[Medline]
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Border, W. A. and Noble, N. A. (1994).
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Boyd, I. L. (1985). Pregnancy and ovulation rates in grey seals (Halichoerus grypus) on the British coast. J. Zool. A 205,265 -272.
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Dolber, P. C. and Spach, M. S. (1987). Picrosirius red staining of cardiac muscle following phosphomolybic acid treatment. Stain Technol. 62, 23-26.[Medline]
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