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Review |
Normal mammalian skeletal muscle and its phenotypic plasticity
Department of Anatomy, University of Bern, Bühlstrasse 26, CH-3000 Bern 9, Switzerland
* e-mail: hoppeler{at}ana.unibe.ch
Accepted 13 May 2002
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Summary |
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 TOP Summary IntroductionAnimal size and the...Basis of molecular plasticity...References |
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O2max (0.92) and
were tracked by the scaling of total capillary length (0.95). In this set of
species, we therefore found that maximal metabolic rate and supporting
structures did not scale to the 0.75 power of body mass as generally
suggested. Muscle phenotypic plasticity is reasonably well characterized on a
structural and functional basis, but we still know little about the signals
that cause the changes in gene expression necessary for phenotypic changes in
muscle. The molecular responses of human m. vastus lateralis to endurance
exercise indicate that a single bout of exercise causes specific transient
transcriptional adaptations that may gradually accumulate after their
translation into the (structural) modifications seen with phenotypic
plasticity. Metabolic and mechanical factors are recognized candidate factors
for the control of exercise-induced gene transcription in muscle. Distinct
protein kinases and transcription factors emerge as possible interfaces that
integrate the mechanical (MAPKs and jun/fos) and metabolic (AMPK, HIF-1
and PPAR) stimuli into enhanced gene transcription in skeletal
muscle.
Key words: scaling, morphometry, mRNA, O2max, muscle, phenotype, plasticity
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Introduction |
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TOPSummaryIntroductionAnimal size and the...Basis of molecular plasticity...References |
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). The specific
condition under which skeletal muscle tissue functions in a species impacts on
the structural design of muscle tissue. A dominant mechanical constraint for
the function of muscle tissue is animal size. Thompson
(1942) noted that, as animals
increase in length, muscle force should increase with the square of the length
change while animal mass should increase with the cube of the length change.
Hill (1950) refined Thompson's
arguments and made specific predictions as to how animal size could constrain
muscle design and impact on animal performance. An important consideration in
all modelling efforts is the assumption that force per unit muscle
cross-sectional area is the same for animals of all sizes
(Close, 1972). Hill
(1950) predicted that maximum
power output would increase not as body mass (Mb) but as
some lower power of body mass (he proposed
Mb0.73). He further predicted that animals,
irrespective of body size, should be able to move at the same maximum speeds,
the advantage for larger animals being that they should be able to cover
proportionately longer distances. He further noted that the rates of enzyme
reactions would also have to be adjusted to body size, with smaller species
requiring the metabolic machinery of their muscle cells to run faster.
As several of Hill's (1950)
predictions appeared to be violated by experimental observations, McMahon
(1975) refined the modelling
approach and showed that animals appeared to be built such that their
structures are similarly threatened by elastic failure under their own mass
(elastic similarity). He found that elastic similarity predicted observed
animal locomotor performance characteristics (such as stride length, stride
frequency and the metabolic power required for running) better than the
geometrical similarity models explored by Thompson
(1942) and Hill
(1950). However, the model of
elastic similarity has not remained uncontested
(Heusner, 1982;
Christiansen, 1999; see also
Feldman and McMahon,
1983).
There has been much recent interest in deriving scaling laws from intrinsic
properties of fractal networks of connectivity (blood vessels, bronchial tree;
West et al., 1997). Using this
approach, the 0.75 scaling power of metabolic rate observed by Kleiber
(1932) is seen as a
consequence of minimizing transport times and distances of internally
branching hierarchical networks in systems maximized for metabolic capacity
(West et al., 1999). In a more
general sense, the observed scaling properties of metabolic rate in animals
are seen to be general properties of efficient transportation networks
relating size and flow rates in networks with local connectivity in animals
and plants and even in inanimate systems such as the drainage system of river
basins (Banavar et al., 1999).
As steady-state locomotor performance of animals could be constrained by the
availability of oxygen to skeletal muscle mitochondria
(Vock et al., 1996b), these
recent scaling considerations would lead us to expect that both maximal
aerobic metabolic rate and muscle oxidative capacity would scale close to the
0.75 power of body mass.
In addition to animal size, we expect muscle structure to reflect typical
functional needs related to the `lifestyle' of an animal. Lifestyle is
variable throughout the life of an individual, so we would expect muscle to be
malleable. The design of the muscle machinery should be `optimized' such that
a cheetah should be able to produce enormous power over a very short period
while a gazelle should be able to cruise efficiently at high speed but with
less capacity to accelerate (Hill,
1950). To characterize economic design, Taylor and Weibel
(1981) coined the term
`symmorphosis'. They postulated that, by a process of regulated morphogenesis,
structural elements should be designed to satisfy but not to exceed functional
requirements. In this sense, the structural design of the muscular system of a
species is seen as the consequence of selective pressure during evolution.
Symmorphosis also encompasses the need for phenotypic plasticity of skeletal
muscle tissue. The environmental conditions to which animals are exposed are
not constant, so the demands that muscle tissue has to satisfy can vary over
the lifetime of an animal. To respond to changing demands, skeletal muscle
tissue must be able to adapt. Over the last 10 years, we have learned that, in
response to environmental (or internal) cues, normal skeletal muscle tissue
can alter its gene expression and thus modify its structural composition or
the functional properties of its structural components. We consider this
epigenetic malleability to be an important feature of the `economic design' of
skeletal muscle tissue. Under given constraints, only what is needed must be
provided because structures can be modified when constraints change.
We will first review the impact of the fundamental variable body mass on the structure of skeletal muscle tissue (essentially of mammals) and then discuss the mechanisms by which an extant muscle structure is modified to accommodate differences in load characteristics experienced by an individual during its lifetime. The second part of this review reports the state of knowledge on the molecular mechanisms that are at the basis of the phenotypic malleability of muscle tissue.
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Animal size and the composition of skeletal muscle tissue |
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O2max)
and skeletal muscle morphology have been studied systematically (for reviews,
see Weibel et al., 1992;
Hoppeler and Weibel, 1998). In
both these reviews, data relevant to oxygen transfer from the lungs to
skeletal muscle mitochondria for a broad size range of mammalian species were
presented. All data were obtained according to a standard experimental
protocol. From all species, VO2max while running was
obtained together with estimates of muscle structural variables representative
of the entire skeletal musculature. The technique of whole-body sampling of
the musculature according to statistical principles
(Hoppeler et al., 1984) was
developed to estimate typical muscle `organ' structural variables. In all
studies, we sampled 15 randomly selected locations from the whole musculature
of each animal. The data thus obtained can therefore be considered to be
largely insensitive to species-specific or circumstantial use of individual
muscles. In this review, we present and discuss the entire set of muscle
morphometric data, not only those related to oxygen transfer and reported
previously (Table 1). This set
of data is similar, but not identical, to data published previously
(Hoppeler and Weibel, 1998).
For some species (goat, guinea pig and dog), we increased the number of
observations by including all data for which a complete set of functional and
morphometric measurements was available. This does not impact on the validity
of interpretations of results published previously with the more limited data
sets.
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To remain consistent with previous data sets (see
Hoppeler and Weibel, 1998), we
have opted to disregard the phylogenetic relationship of the species
evaluated. As the species analysed share a variable part of their evolutionary
history, they cannot be considered independent sensu stricto from a
statistical point of view. The possibility that taking phylogeny into
consideration might have had some impact on the scaling of the functional and
structural variables under scrutiny cannot therefore be excluded
(Garland, 1999;
Garland and Ives, 2000).
Muscle mass and fibre size
As noted previously (e.g. Hoppeler,
1990), relative muscle mass measured by complete dissection of the
carcass of an animal is size-invariant (muscle mass scales to
Mb0.99; Fig.
1A). A similar scaling exponent of close to unity (1.05) was found
to relate white muscle mass to body mass in an intraspecific comparison in
rainbow trout Oncorhynchus mykiss
(Goolish, 1989). In general,
we find that active species in any size class tend to have a larger relative
muscle mass than sedentary species (Kayar
et al., 1989; Weibel et al.,
1992). More surprisingly, we find that fibre cross-sectional area
(measured as mean fibre cross-sectional area, obtained from low-power electron
micrographs) is found to be body-mass-independent at least for animals down to
the size of a 16g woodmouse (Fig.
1B). There is no indication that active animals have larger fibre
sizes than inactive ones.
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Myofibrils constitute the major compartment in muscle cells, comprising 73.2% of muscle fibre volume in horses to 83.3% of muscle fibre volume in goats. Total myofibrillar volume is directly proportional to muscle mass (scaling factor 0.98). Skeletal muscle sarcomeres are built very similarly in all mammalian species, so the total number of cross-bridges that the myosin heads can form with actin is directly proportional to muscle mass. Deviations of the ATP demand for muscle contraction from direct proportionality to body mass must therefore depend mainly on size-dependent differences in cross-bridge cycling rates.
Structural and functional variables related to oxidative
metabolism
We have reported the scaling of structures determining muscle oxygen demand
(mitochondria) and muscle oxygen supply (capillaries) with body mass and on
the relationship between these structures and
O2max
(Hoppeler et al., 1981). With
the current set of data and considering all species, we observe that
O2max scales to
Mb0.92, as previously reported for a similar
set of animals (Fig. 2;
Hoppeler and Weibel, 1998).
This is greater than the scaling exponent of 0.809 reported for 22 wild and
domestic mammalian species reported by Taylor and Weibel
(1981). This difference in
scaling is probably due to the inclusion of `athletic' species (foxes, dogs
and horses) in the larger size classes. If the regression for the current data
set is calculated without these species,
O2max scales to
Mb0.86.
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Overall, the present data confirm the observation that
O2max closely
tracks total mitochondrial volume, V(mt). For V(mt), we find
a scaling factor of 0.91 for all species (0.86 for the `sedentary' subset). If
we subdivide the mitochondrial population into central and subsarcolemmal
mitochondria, we find that subsarcolemmal mitochondria represent between 16
and 35% of the total mitochondrial population, with no apparent systematic
relationship to the activity level of the species. The volumes of both
subsarcolemmal and central mitochondria and total mitochondrial volume scale
similarly to body mass. Capillary length J(c) can be calculated from
capillary density [(Na(c,f); Table
1)] using the formula published previously with a tortuosity
factor of 1.24 (Conley et al.,
1987). J(c) scales as
Mb0.95 for all species and as
Mb0.92 for the sedentary subset. These scaling
factors are very close to values reported previously for individual muscles
(diaphragm, semitendinosus, longissimus dorsi and vastus medialis) in 21 wild
and domestic species (Hoppeler et al.,
1981). The difference in capillary length between athletic and
sedentary species is smaller than that observed for the volume of mitochondria
because oxygen supply is helped in athletic species by the greater haemoglobin
concentration in their circulation (Conley
et al., 1987). The current data set supports the hypothesis of an
extremely close match between oxidative capacity and capillary supply from a
scaling perspective (Hoppeler and Kayar,
1988).
We observe that maximal aerobic capacity and the quantities of muscle
structural elements determining this function (mitochondria and capillaries)
scale with scaling factors larger than 0.75, as predicted by recent
theoretical considerations (West et al.,
1997). In view of the proposed generality of scaling laws, this
seems surprising. The number and selection of species considered in this
review and the size range may be too limited and might skew the relationship
between body mass and the investigated variables. However, alternative
explanations for scaling factors differing from 0.75 have been proposed and
may have to be considered in this context. On the basis of metabolic control
theory, one would expect scaling of metabolic rate to depend on multiple-site
control and to show different exponents depending on whether basal or maximal
metabolic rate is considered (Darveau et
al., 2002). Bejan
(2000) showed that a scaling
factor of close to 0.875 would be expected for a bioengineering approach to
scaling of metabolic rate encompassing both the fractal transportation network
concept (West et al., 1997)
and heat transfer considerations.
Intramyocellular lipid stores
Morphometry lends itself well to determining intramyocellular lipid
concentrations in the form of lipid droplets (IMCLs) found in contact with
mitochondria (Vock et al.,
1996a; Howald et al.,
2002). We find the scaling of IMCLs
(Fig. 3) to be very similar to
the scaling of
O2max and of
mitochondrial volume. There seems to be a strong tendency for athletic species
to have larger intramyocellular (lipid) substrate reserves, as was previously
noted by Vock et al.
(1996a).
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Allometric scaling of RNA and DNA concentrations
We have so far discussed the size-dependent structural design of mammalian
skeletal muscle tissue and have expanded this discussion to the compartments
that can efficiently be quantified by electron microscopic morphometry. For
oxidative enzymes such as citrate synthase, it has been shown that activity
decreases per gram muscle tissue in accordance with the morphometric data on
mitochondria (Emmett and Hochachka,
1981; Hochachka et al.,
1988). In contrast, the activities of enzymes associated with
anaerobic metabolism, such as lactate dehydrogenase and pyruvate kinase,
increase with increasing body mass (Somero
and Childress, 1980; Emmett
and Hochachka, 1981). For these enzymes, there is no established
structural correlate. The opposite scaling of aerobic and anaerobic enzyme
concentrations cannot be explained by overall regulation of protein synthesis
or degradation (Yang and Somero,
1996). Explanations must therefore be sought at the
transcriptional or translational level.
Little is known as to the allometric scaling of RNA and DNA concentrations
and, hence, whether and how the observed size-dependencies of protein
concentrations (ultimately estimated morphometrically as structural
quantities) are achieved at the molecular level. This problem has been
addressed by using fish as a model organism
(Yang and Somero, 1996;
Burness et al., 1999), an
approach that allows large intraspecific size differences to be included. The
scarce data on fish show a complex pattern in which not only size but also age
and growth rate seem to influence DNA and mRNA concentrations
(Burness et al., 1999), with
translational regulation being implicated in the regulation of the
concentration of glycolytic enzymes (Yang
and Somero, 1996). The molecular mechanisms by which basic levels
of protein concentrations are established and controlled in muscle thus remain
largely unexplained.
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Basis of molecular plasticity of skeletal muscle tissue |
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TOPSummaryIntroductionAnimal size and the...Basis of molecular plasticity...References |
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Different forms of exercise such as `high repetitive, low load' (endurance)
exercise and `low repetitive, high load' (strength or resistance) exercise
induce specific and distinct structural and functional modifications in muscle
fibres. Classical endurance training interventions of 6-8 weeks duration in
previously untrained human subjects can lead to an elevation of mitochondrial
volume density of up to 40 %, while capillary density may be increased by
close to 30 % (Hoppeler et al.,
1985). In response to strength training of similar duration,
myofibrillar volume selectively increases by as much as 20 %
(Luethi et al., 1986). These
training responses involve changes in gene expression. The set of mRNAs
expressed provides a basic instruction for the palette of translated proteins
that is finally manifest as a characteristic structural adaptation to exercise
training. Endurance training influences gene expression in skeletal muscle
within a matter of 30 min to some hours (regulatory genes) or as a consequence
of weeks of systematic training (structural genes). In contrast, little is
known about transcriptional adaptations in response to resistance exercise
(Kadi and Thornell, 2000;
Booth et al., 1998).
This second part of this article will briefly review the most striking transcriptional adaptations seen in exercised skeletal muscle and provide a model aimed at linking these events to physiological signals induced by exercise. A particular focus will be on transcriptional adaptations to endurance-type exercise in human skeletal muscle since these have been best characterized.
The transcriptional response of a variety of genes to a single bout of
exercise is transient (Seip et al.,
1997; Pilegaard et al.,
2000). Depending on the time course of appearance of the maximal
response to a single bout of exercise, these transcriptional events can be
grouped into early and late responses, i.e. occurring within 0.1-1 h and
within 1-4 h, respectively (see Table
2). Many of the genes induced early correspond to the classically
defined immediate early genes involved in transcriptional and hormonal cell
regulation. The later-responding genes mostly have particular functions in
cellular metabolism. For example, 30 min of treadmill running and ergometer
training above the aerobic threshold induces expression of the jun/fos family
of transcription factors in human m. vastus lateralis
(Puntschart et al., 1998;
Aronson et al., 1998).
Furthermore, 45 min of knee-extensor ergometer exercise increases the mRNA
level of the angiogenic factor VEGF
(Richardson et al., 1999;
Gustafsson et al., 1999).
Ergometer training of more than 60 min near the aerobic threshold induces
expression of the metabolic genes LPL, CPTI, PDK4, GYS and UCP-3 in human m.
vastus lateralis (Pilegaard et al.,
2000; see Table
2).
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An increase in muscle activity causes acute perturbations of the physical
environment and the chemical constitution of skeletal muscle fibres,
suggesting that metabolic (lactate, oxygen, disturbances in ATP turnover) and
mechanical factors are the signals sensed and integrated into the
transcriptional adaptations seen in exercised skeletal muscle. This concept is
supported by the observation that increasing the contribution of metabolic and
of mechanical factors to the physiological stimuli modulates the
transcriptional response. For example, VEGF mRNA is induced concomitant with
(but is not correlated to) reduced oxygen tension
(Richardson et al., 1999). In
addition, the VEGF response is reported to be proportional to the increase in
plasma lactate level incurred during exercise
(Gustafsson et al., 1999). The
role of mechanical factors is best supported by animal model studies
demonstrating that mechanical factors (stretch) modulate transcriptional
induction of the c-jun and c-fos genes within 1 h
(Dawes et al., 1996). In
situ hybridization experiments with human m. vastus lateralis show an
increase in levels of c-fos and c-jun mRNA after running exercise in a patchy
expression pattern, indicating that factors other than metabolic products
related to fibre recruitment contribute to increased c-fos gene transcription
(Puntschart et al., 1998).
Overall, these observations emphasize that metabolic and mechanical factors
together influence the steady-state level of mRNA, possibly by modulating the
rate of gene transcription as well as through pathways of RNA degradation.
The proposal that mechanical factors are involved in the regulation of the
mRNA concentration in response to exercise training is supported by
observations in mechanically stressed skeletal muscle. These observations
indicate that mechanisms known to contribute to pre-transcriptional control
are affected concomitantly with transcription of downstream target genes. In
particular, exercise can induce all three limbs of the MAP-kinase pathways
(ERK1/2, JNK and p38) in human m. vastus lateralis (Aronson et al.,
1997,
1998;
Yu et al., 2001;
Boppart et al., 1999;
Widegren et al., 2001).
Activation of these kinases is known to affect transcription factors of the
jun/fos and ATF/CREB family (Hunter and
Karin, 1992), which bind to the promoter of many genes, e.g.
c-jun, c-fos and the gene for cytochrome c, that are affected
synchronously by exercise (Hood,
2001). In situ studies have demonstrated that mechanical
factors, i.e. the degree of tension in rat muscle fibres, control JNK and
ERK1/2 differently and directly (Martineau
and Gardiner, 2001). In contrast, the p38 pathway in skeletal
muscle is responsive only when mechanical stress (stretch, exercise) is
applied in vivo (Boppart et al.,
2001), indicating that p38 is presumably indirectly (possibly
endocrinally) controlled by mechanical factors. Furthermore, activation of
p70S6 kinase may relate to the indirect effects of mechanical or metabolic
stimuli that are responsible for muscle hypertrophy by influencing translation
factors (Nader and Esser,
2001). Mechanically induced release of growth factors (MGF, IL-6)
has been recognized as another signalling route in exercised skeletal muscle
and may represent an important link between contracting skeletal muscles and
exercise-related metabolic changes
(Goldspink, 1999;
Pedersen et al., 2001).
Activation of all these mechano-transduction events is potentially linked to
mechano-sensation via integrins and associated kinases
(Gordon et al., 2001;
Carson and Wei, 2000;
Chiquet and Flück,
2001).
It is not clear which factors sense and integrate the metabolic signals to
skeletal muscle. Candidate factors that are potentially activated by metabolic
factors such as reduced AMP, oxygen or fatty acids include
5'-AMP-activated protein kinase (AMPK), transcription factors such as
hypoxia-inducible factor 1 alpha (HIF-1) and
peroxisome-proliferator-activated receptor-alpha (PPAR). Ergometer
exercise has been demonstrated to activate 2-AMPK, but not the 1
form, in human m. vastus lateralis in an intensity-dependent manner
(Wojtaszewski et al., 2000).
The AMPK complex is involved in the regulation of skeletal muscle metabolism
during exercise and was recently implicated in the control of transcription of
the glucose transporter glut-4 in mouse skeletal muscle
(Zheng et al., 2001).
HIF-1 and PPAR are known to promote transcription of genes
involved in carbohydrate metabolism, oxygen delivery and fatty acid oxidation
through binding to specific promoter regions
(Escher and Wahli, 2000;
Semenza, 2001). Both these
transcription factors are largely controlled by post-translational events.
In many tissues, reduced oxygen tension (tissue hypoxia) instantaneously
stabilizes the normally degraded HIF-1
(Jewell et al., 2001) by a
process involving reduced hydroxylation of particular residues
(Wenger and Bauer, 2001). The
resulting increase in HIF-1 levels promotes the transcription of VEGF
and glycolytic genes (Semenza,
2001). The reduced oxygen tension in response to a single bout of
exercise (Richardson et al.,
1999) suggests that the concomitant increase in levels of mRNA for
HIF-1-dependent VEGF and glycolytic genes in exercised m. vastus
lateralis (Pilegaard et al.,
2000; Richardson et al.,
1999) may be brought about by a hypoxic stabilization of
HIF-1. Support for a sensitivity to exercise of HIF-1 in
skeletal muscle is provided by the increase in HIF-1 mRNA levels in m.
vastus lateralis in response to repeated bouts of exercise in hypoxia
(Vogt et al., 2001).
Similarly, the abundance of PPAR and the transcript levels of genes
whose transcription is known to be regulated by PPAR were concomitantly
increased in trained human m. vastus lateralis
(Horowitz et al., 2000).
Unsaturated long-chain fatty acids which are released from adipose tissue
during exercise serve as ligands for PPAR and stimulate
PPAR-activated gene transcription
(Kliewer et al., 1997).
Recently, we observed an increase in PPAR mRNA levels in response to
training in human m. tibialis anterior, indicating that this factor is also
controlled by transcriptional events (B. Schmitt, J. Décombaz, M.
Flück and H. Hoppeler, unpublished observations). There is evidence that
contractile-exercise-induced transcription of mitochondrial transcription
factor A (Tfam) and nuclear respiratory factor-1 (NRF-1) is involved in the
coordinated expression of the nuclear and mitochondrial genomes and may be a
link to mitochondrial biogenesis as a result of enhanced metabolic flux
(Hood, 2001;
Bengtsson et al., 2001). Thus,
distinct protein kinases and transcription factors appear to be the interface
that integrates mechanical (MAPKs and jun/fos) and metabolic (AMPK,
HIF-1 and PPAR) stimuli into enhanced gene transcription.
The steady-state level of RNA is determined by the balance of gene
transcription and RNA degradation (Booth
and Thomason, 1991). Contractile activity modulates the level of
factors interacting with the cytochrome c mRNA
(Yan et al., 1996) in a region
of the 3' untranslated region (3'UTR) known to determine the
degradation of mRNA (Sachs,
1993). These observations indicate that mRNA degradation is a
mechanism effective in the control of transcript level in (human) skeletal
muscle. The involvement of RNA degradation and chromatin structure
(Felsenfeld et al., 1996),
controlling the recruitment and assembly of transcription factors and
polymerase complexes for individual gene promoter regions, in determining
exercise-modulated mRNA levels in human skeletal muscle is not understood.
Changes in gene expression result in an incremental adaptation in protein
level and activity determined by the spatial organization of the corresponding
protein and its biological half-life. The transient nature of transcriptional
adaptation following a single bout of exercise indicates that detectable
distinct structural (and functional) adaptations may reflect the gradual
accumulation of discrete post-transcriptional micro-adaptations of the
corresponding protein (Vogt et al.,
2001). Evidence for such a scenario comes from the increase in
angiogenic VEGF mRNA level concomitant with an increased capillary-to-fibre
ratio and the concomitant modulation of RNAs coding for proteins involved in
oxidative phosphorylation (Puntschart et
al., 1995). The increased steady-state levels of VEGF, CPTI and
mitochondrially encoded RNAs (COX 1, NADH reductase subunit 6, 16S rRNA) and
in nuclear-encoded RNAs (COX 4, SDH, fumarase) in trained human m. vastus
lateralis (Vogt et al., 2001;
Pilegaard et al., 2000;
Puntschart et al., 1995)
indicate that transcriptional changes are responsible for the typical
structural changes observed in response to endurance-type exercise.
The distinct pattern of changes in the steady-state mRNA level of genes
involved in carbohydrate and fatty acid metabolism in response to exercise
training demonstrates that expressional changes are specific for the pattern
of physiological stimuli applied. For example, increases in mRNA levels for
medium-chain acyl-CoA dehydrogenase, which is involved in oxidative
metabolism, in m. vastus lateralis are seen only in response to exercise at
low intensity (Vogt et al.,
2001), when oxidation of fatty acids predominates over that of
carbohydrates (Brooks and Mercier,
1994). In contrast, phosphofructokinase mRNA levels were found to
increase only in response to high-intensity training, while HIF-1 mRNA
levels were found to increase under conditions of hypoxia
(Vogt et al., 2001).
Furthermore, the differences in the response of VEGF and CPTI mRNA levels in
m. vastus lateralis to a single bout of training indicate that endurance
training modulates the sensitivity of expressional responses to exercise
stimuli (Richardson et al.,
1999; Pilegaard et al.,
2000). A main issue for future research is to elucidate the extent
to which the specific structural and functional adaptations of skeletal muscle
in response to defined external stimuli, i.e. the combination of mechanical
and metabolic stimuli, is due to specific modifications in the gene
profile.
In conclusion, the present data support and complement previous reports on the scaling of the structural variables of skeletal muscle tissue with body mass. Muscle mass and myofibrillar volume are found to represent constant fractions of body mass, while structures related to the oxidative metabolic capacity of muscle tissue have scaling factors smaller than unity (ranging from 0.86 to 0.95). These values, however, seem to be consistently larger than the scaling factor of 0.75 proposed from general considerations related to the design of fractal networks of connectivity such as circulatory systems. In the context of the basic design properties of skeletal muscle, malleability is considered to be an important feature of the `economic design' of muscle tissue. Future research will therefore concentrate on the molecular basis of the phenotypic plasticity of skeletal muscle tissue. There is evidence that transient transcriptional regulations after exercise perturbations occur in response to repetitive stimuli and eventually lead to specific modifications of the transcriptome and eventually of the proteome. We propose that muscle tissue can sense and respond to both mechanical and metabolic disturbances, with the two stimuli acting through distinct signalling pathways.
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Acknowledgments |
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References |
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TOPSummaryIntroductionAnimal size and the...Basis of molecular plasticity...References |
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Aronson, D., Boppart, M. D., Dufresne, S. D., Fielding, R. A. and Goodyear, L. J. (1998). Exercise stimulates c-Jun NH2 kinase activity and c-Jun transcriptional activity in human skeletal muscle. Biochem. Biophys. Res. Commun. 251,106 -110.[Medline]
Aronson, D., Violan, M. A., Dufresne, S. D., Zangen, D., Fielding, R. A. and Goodyear, L. J. (1997). Exercise stimulates the mitogen-activated protein kinase pathway in human skeletal muscle. J. Clin. Invest. 99,1251 -1257.[Medline]
Banavar, J. R., Maritan, A. and Rinaldo, A. (1999). Size and form in efficient transportation networks. Nature 399,130 -132.[Medline]
Bejan, A. (2000). Shape and Structure from Engineering to Nature. Cambridge: Cambridge University Press. pp. 260-266.
Bengtsson, J., Gustafsson, T., Widegren, U., Jansson, E. and Sundberg, C. J. (2001). Mitochondrial transcription factor A and respiratory complex IV increase in response to exercise training in humans. Pflügers Arch. 443, 61-66.[Medline]
Booth, F. W. and Thomason, D. B. (1991).
Molecular and cellular adaptation of muscle in response to exercise:
Perspective of various models. Physiol. Rev.
71,541
-585.
Booth, F. W., Tseng, B. S., Flück, M. and Carson, J. A. (1998). Molecular and cellular adaptation of muscle in response to physical training. Acta Physiol. Scand. 162,343 -350.[Medline]
Boppart, M. D., Aronson, D., Gibson, L., Roubenoff, R., Abad, L.
W., Bean, J., Goodyear, L. J. and Fielding, R. A. (1999).
Eccentric exercise markedly increases c-Jun NH(2)-terminal kinase activity in
human skeletal muscle. J. Appl. Physiol.
87,1668
-1673.
Boppart, M. D., Hirshman, M. F., Sakamoto, K., Fielding, R. A. and Goodyear, L. J. (2001). Static stretch increases c-Jun NH2-terminal kinase activity and p38 phosphorylation in rat skeletal muscle. Am. J. Physiol. 280,C352 -C358.
Brooks, G. A. and Mercier, J. (1994). Balance
of carbohydrate and lipid utilization during exercise: The crossover concept.
J. Appl. Physiol. 76,2253
-2261.
Burness, G. P., Leary, S. C., Hochachka, P. W. and Moyes, C.
D. (1999). Allometric scaling of RNA, DNA and enzyme levels:
an intraspecific study. Am. J. Physiol.
277,R1164
-R1170.
Carson, J. A. and Wei, L. (2000). Integrin
signaling's potential for mediating gene expression in hypertrophying skeletal
muscle. J. Appl. Physiol.
88,337
-343.
Chiquet, M. and Flück, M. (2001). Early responses to mechanical stress: from signals at the cell surface to altered gene expression, cell and molecular responses to stress. In Protein Adaptations and Signal Transduction (ed. K. B. Storey and J. M. Storey), pp. 97-110. Amsterdam: Elsevier Science B. V.
Christiansen, P. (1999). Scaling of the limb long bones to body mass in terrestrial mammals. J. Morphol. 239,167 -190.[Medline]
Close, R. I. (1972). Dynamic properties of
mammalian skeletal muscle. Physiol. Rev.
52,129
-197.
Conley, K. E., Kayar, S. R., Roesler, K., Hoppeler, H., Weibel, E. R. and Taylor, C. R. (1987). Adaptive variation in the mammalian respiratory system in relation to energetic demand. IV. Capillaries and their relationship to oxidative capacity. Respir. Physiol. 69,47 -64.
Darveau, C.-A., Suarez, R. K., Andrews, R. D. and Hochachka, P. W. (2002). Allometric cascade: A unifying principle of body mass effects on metabolism. Nature 417,166 -170.[Medline]
Dawes, N. J., Cox, V. M., Park, K. S., Nga, H. and Goldspink, D. F. (1996). The induction of c-fos and c-jun in the stretched latissimus dorsi muscle of the rabbit: responses to duration, degree and re-application of the stretch stimulus. Exp. Physiol. 81,329 -339.[Abstract]
Emmett, B. and Hochachka, P. W. (1981). Scaling of oxidative and glycolytic enzymes in mammals. Respir. Physiol. 45,261 -272.[Medline]
Escher, P. and Wahli, W. (2000). Peroxisome proliferator-activated receptors: insight into multiple cellular functions. Mutat. Res. 448,121 -138.[Medline]
Feldman, H. A. and McMahon, T. A. (1983). The 3/4 mass exponent for energy metabolism is not a statistical artifact. Respir. Physiol. 52,149 -163.[Medline]
Felsenfeld, G., Boyes, J., Chung, J., Clark, D. and Studitsky,
V. (1996). Chromatin structure and gene expression.
Proc. Natl. Acad. Sci. USA
93,9384
-9388.
Garland, T. (1999). An introduction to phylogenetically based statistical methods, with a new method for confidence intervals on ancestral values. Am. Zool. 39,374 -388.
Garland, T. and Ives, A. R. (2000). Using the past to predict the present: Confidence intervals for regression equations in phylogenetic comparative methods. Am. Nat. 155,346 -364.[Medline]
Goldspink, G. (1999). Changes in muscle mass and phenotype and the expression of autocrine and systemic growth factors by muscle in response to stretch and overload. J. Anat. 194,323 -334.
Goolish, E. M. (1989). The scaling of aerobic
and anaerobic muscle power in rainbow trout (Salmo gairdneri).
J. Exp. Biol. 147,493
-505.
Gordon, S. E., Flück, M. and Booth, F. W.
(2001). Selected contribution: Skeletal muscle focal adhesion
kinase, paxillin and serum response factor are loading dependent.
J. Appl. Physiol. 90,1174
-1183.
Gunn, H. M. (1989). Heart weight and running ability. J. Anat. 167,225 -233.[Medline]
Gustafsson, T., Puntschart, A., Kaijser, L., Jansson, E. and
Sundberg, C. J. (1999). Exercise-induced expression of
angiogenesis-related transcription and growth factors in human skeletal
muscle. Am. J. Physiol.
276,H679
-H685.
Heider, H., Puntschart, A., Widmer, H.-R., Jostarndt, K., Hoppeler, H. and Billeter, R. (1995). Signal transduction in human muscle after a single bout of exercise (Abstract). Experientia 51,A36 .
Heusner, A. A. (1982). Energy metabolism and body size. I. Is the 075 mass exponent of Kleiber's equation a statistical artefact? Respir. Physiol. 48, 1-12.[Medline]
Hill, A. V. (1950). The dimensions of animals and their muscular dynamics. Sci. Prog. 38,209 -230.
Hochachka, P. W., Emmett, B. and Suarez, R. K. (1988). Limits and constraints in the scaling of oxidative and glycolytic enzymes in homeotherms. Can. J. Zool. 66,1128 -1138.
Hood, D. A. (2001). Invited review: Contractile
activity-induced mitochondrial biogenesis in skeletal muscle. J.
Appl. Physiol. 90,1137
-1157.
Hoppeler, H. (1990). The different relationship
of O2max to
muscle mitochondria in humans and quadrupedal animals. Respir.
Physiol. 80,137
-146.[Medline]
Hoppeler, H., Howald, H., Conley, K., Lindstedt, S. L.,
Claassen, H., Vock, P. and Weibel, E. R. (1985). Endurance
training in humans: Aerobic capacity and structure of skeletal muscle.
J. Appl. Physiol. 59,320
-327.
Hoppeler, H. and Kayar, S. (1988). Capillarity
and oxidative capacity of muscles. News Physiol. Sci.
3, 113-116.
Hoppeler, H., Lindstedt, S. L., Uhlmann, E., Niesel, A. and Cruz Orive, L. W. E. R. (1984). Oxygen consumption and the composition of skeletal muscle tissue after training and inactivation in the European woodmouse (Apodemus sylvaticus). J. Comp. Physiol. B 155,51 -61.
Hoppeler, H., Mathieu, O., Weibel, E. R., Krauer, R., Lindstedt, S. L. and Taylor, C. R. (1981). Design of the mammalian respiratory system. VIII. Capillaries in skeletal muscle. Respir. Physiol. 44,129 -150.[Medline]
Hoppeler, H. and Weibel, E. R. (1998). Limits for oxygen and substrate transport in mammals. J. Exp. Biol. 201,1051 -1064.[Abstract]
Horowitz, J. F., Leone, T. C., Feng, W., Kelly, D. P. and Klein, S. (2000). Effect of endurance training on lipid metabolism in women: a potential role for PPARalpha in the metabolic response to training. Am. J. Physiol. 279,E348 -E355.
Howald, H., Boesch, C., Kreis, R., Matter, S., Billeter, R.,
Essen-Gustavsson, B. and Hoppeler, H. (2002). Content of
intramyocellular lipids derived by electron microscopy, biochemical assays and
1H-MR spectroscopy. J. Appl. Physiol.
92,2264
-2272.
Hunter, T. and Karin, M. (1992). The regulation of transcription by phosphorylation. Cell 70,375 -387.[Medline]
Jewell, U. R., Kvietikova, I., Scheid, A., Bauer, C., Wenger, R.
H. and Gassmann, M. (2001). Induction of HIF-1alpha in
response to hypoxia is instantaneous. FASEB J.
15,1312
-1314.
Kadi, F. and Thornell, L. E. (2000). Concomitant increases in myonuclear and satellite cell content in female trapezius muscle following strength training. Histochem. Cell Biol. 113,99 -103.[Medline]
Kayar, S. R., Hoppeler, H., Lindstedt, S. L., Claassen, H., Jones, J. H. E. G. B. and Taylor, C. R. (1989). Total muscle mitochondrial volume in relation to aerobic capacity of horses and steers. Pflügers Arch. 413,343 -347.[Medline]
Kleiber, M. (1932). Body size and metabolism. Hilgardia 6,315 -353.
Kliewer, S. A., Sundseth, S. S., Jones, S. A., Brown, P. J.,
Wisely, G. B., Koble, C. S., Devchand, P., Wahli, W., Willson, T. M., Lenhard,
J. M. and Lehmann, J. M. (1997). Fatty acids and eicosanoids
regulate gene expression through direct interactions with peroxisome
proliferator-activated receptors alpha and gamma. Proc. Natl. Acad.
Sci. USA 94,4318
-4323.
Luethi, J. M., Howald, H., Claassen, H., Roesler, K., Vock, P. and Hoppeler, H. (1986). Structural changes in skeletal muscle tissue with heavy-resistance exercise. Int. J. Sports Med. 7,123 -127.[Medline]
Martineau, L. C. and Gardiner, P. F. (2001).
Insight into skeletal muscle mechanotransduction: MAPK activation is
quantitatively related to tension. J. Appl. Physiol.
91,693
-702.
McMahon, T. A. (1975). Using body size to
understand the structural design of animals: quadrupedal locomotion.
J. Appl. Physiol. 39,619
-627.
Nader, G. A. and Esser, K. A. (2001).
Intracellular signaling specificity in skeletal muscle in response to
different modes of exercise. J. Appl. Physiol.
90,1936
-1942.
Pedersen, B. K., Steensberg, A., Fischer, C., Keller, C., Ostrowski, K. and Schjerling, P. (2001). Exercise and cytokines with particular focus on muscle-derived IL-6. Exerc. Immunol. Rev. 7,18 -31.[Medline]
Pilegaard, H., Ordway, G. A., Saltin, B. and Neufer, P. D. (2000). Transcriptional regulation of gene expression in human skeletal muscle during recovery from exercise. Am. J. Physiol. 279,E806 -E814.
Puntschart, A., Claassen, H., Jostarndt, K., Hoppeler, H. and
Billeter, R. (1995). mRNAs of enzymes involved in energy
metabolism and mtDNA are increased in endurance trained athletes.
Am. J. Physiol. 269,C619
-C625.
Puntschart, A., Vogt, M., Widmer, H. R., Hoppeler, H. and Billeter, R. (1996). Hsp70 expression in human skeletal muscle after exercise. Acta Physiol. Scand. 157,411 -417.[Medline]
Puntschart, A., Wey, E., Jostarndt, K., Vogt, M., Wittwer, M., Widmer, H. R., Hoppeler, H. and Billeter, R. (1998). Expression of fos and jun genes in human skeletal muscle after exercise. Am. J. Physiol. 43,C129 -C137.
Richardson, R. S., Wagner, H., Mudaliar, S. R., Henry, R.,
Noyszewski, E. A. and Wagner, P. D. (1999). Human VEGF gene
expression in skeletal muscle: effect of acute normoxic and hypoxic exercise.
Am. J. Physiol. 277,H2247
-H2252.
Sachs, A. B. (1993). Messenger RNA degradation in eukaryotes. Cell 74,413 -421.[Medline]
Seip, R. L., Mair, K., Cole, T. G. and Semenkovich, C. F.
(1997). Induction of human skeletal muscle lipoprotein lipase
gene expression by short-term exercise is transient. Am. J.
Physiol. 272,E255
-E261.
Semenza, G. L. (2001). HIF-1 and mechanisms of hypoxia sensing. Curr. Opin. Cell Biol. 13,167 -171.[Medline]
Somero, G. N. and Childress, J. J. (1980). A violation of the metabolism—size scaling paradigm activities of glycolytic enzymes in muscle increase in larger-size fish. Physiol. Zool. 53,322 -337.
Taylor, C. R. and Weibel, E. R. (1981). Design of the mammalian respiratory system. Respir. Physiol. 44, 1-126.
Thompson, D'A. W. (1942) On Growth and Form. Cambridge: Cambridge University Press.
Vock, R., Hoppeler, H., Claassen, H., Wu, D. X. Y., Billeter, R., Weber, J. M., Taylor, C. R. and Weibel, E. R. (1996a). Design of the oxygen and substrate pathways. VI. Structural basis of intracellular substrate supply to mitochondria in muscle cells. J. Exp. Biol. 199,1689 -1697.[Abstract]
Vock, R., Weibel, E. R., Hoppeler, H., Ordway, G., Weber, J. M. and Taylor, C. R. (1996b). Design of the oxygen and substrate pathways. V. Structural basis of vascular substrate supply to muscle cells. J. Exp. Biol. 199,1675 -1688.[Abstract]
Vogt, M., Puntschart, A., Geiser, J., Zuleger, C., Billeter, R.
and Hoppeler, H. (2001). Molecular adaptations in human
skeletal muscle to endurance training under simulated hypoxic conditions.
J. Appl. Physiol. 91,173
-182.
Weibel, E. R., Taylor, C. R. and Hoppeler, H. (1992). Variations in function and design: Testing symmorphosis in the respiratory system. Respir. Physiol. 87,325 -348.[Medline]
Wenger, R. H. and Bauer, C. (2001). Oxygen
sensing: `hydroxy' translates `oxy'. News Physiol.
Sci. 16,195
-196.
West, G. B., Brown, J. H. and Enquist, B. J.
(1997). A general model for the origin of allometric scaling laws
in biology. Science 276,122
-126.
West, G. B., Brown, J. H. and Enquist, B. J.
(1999). The fourth dimension of life: Fractal geometry and
allometric scaling of oganisms. Science
284,1677
-1679.
Widegren, U., Ryder, J. W. and Zierath, J. R. (2001). Mitogen-activated protein kinase signal transduction in skeletal muscle: effects of exercise and muscle contraction. Acta Physiol. Scand. 172,227 -238.[Medline]
Wojtaszewski, J. F., Nielsen, P., Hansen, B. F., Richter, E. A.
and Kiens, B. (2000). Isoform-specific and exercise
intensity-dependent activation of 5'-AMP-activated protein kinase in
human skeletal muscle. J. Physiol., Lond.
528,221
-226.
Yan, Z., Salmons, S., Dang, Y. I., Hamilton, M. T. and Booth, F.
W. (1996). Increased contractile activity decreases
RNA—protein interaction in the 3'-UTR of cytochrome c mRNA.
Am. J. Physiol. 271,C1157
-C1166.
Yang, T. H. and Somero, G. N. (1996). Activity of lactate dehydrogenase but not its concentration of messenger RNA increases with body size in barred sand bass, Paralabrax nebulifer (Teleostei). Biol. Bull. 191,155 -158.[Abstract]
Yu, M., Blomstrand, E., Chibalin, A. V., Krook, A. and Zierath,
J. R. (2001). Marathon running increases ERK1/2 and p38 MAP
kinase signalling to downstream targets in human skeletal muscle.
J. Physiol., Lond. 536,273
-282.
Zheng, D., MacLean, P. S., Pohnert, S. C., Knight, J. B., Olson,
A. L., Winder, W. W. and Dohm, G. L. (2001). Regulation of
muscle GLUT-4 transcription by AMP-activated protein kinase. J.
Appl. Physiol. 91,1073
-1083.
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