The following is the abstract of the article discussed in the subsequent letter:
![]() |
ABSTRACT |
---|
Jones, Terry E., Keith Baar, Edward Ojuka, May Chen, and John O. Holloszy. Exercise induces an increase in muscle UCP3 as a component of the
increase in mitochondrial biogenesis. Am J Physiol
Endocrinol Metab 284: E96-E101, 2003. First published September 17, 2002; 10.1152/ajpendo.00316.2002.Previous studies have
indicated that exercise acutely induces large increases in uncoupling
protein-3 (UCP3) in skeletal muscle, whereas endurance training results
in marked decreases in muscle UCP3. Because UCP3 expression appears to
be regulated by the same mechanism as other mitochondrial constituents,
it seemed unlikely that exercise would result in such large and
divergent changes in mitochondrial composition. The purpose of this
study was to test the hypothesis that major changes in UCP3 protein
concentration do not occur independently of mitochondrial biogenesis
and that UCP3 increases as a component of the exercise-induced increase
in mitochondria. We found a large increase in UCP3 mRNA immediately and
3 h after a bout of swimming. UCP3 protein concentration was
increased ~35% 18 h after a single exercise bout, ~63% after
3 days, and ~84% after 10 days of exercise. These increases in UCP3
roughly paralleled those of other mitochondrial marker proteins. Our
results are consistent with the interpretation that endurance exercise
induces an adaptive increase in mitochondria that have a normal content
of UCP3.
![]() |
LETTER |
---|
To the Editor: The primary physiological function of mitochondrial uncoupling protein-3 (UCP3) is not yet known. Because of its homology with UCP1, it has been hypothesized that UCP3 is involved in the regulation of energy expenditure in skeletal muscle. Therefore, the effect of exercise and endurance training on UCP3 expression has been extensively studied. These studies unequivocally show that UCP3 mRNA expression is transiently upregulated after an acute bout of exercise (4-6, 14), an effect largely accounted for by increased free fatty acid levels (10). Recently, Jones et al. (3) confirmed this finding, showing that, in rats, UCP3 mRNA was increased acutely and 3 h after a single exercise bout. Jones et al. also reported a marked ~63 and ~84% increase in UCP3 protein after 3 and 10 days of endurance training, respectively. These findings have led the authors to conclude that "endurance exercise results in an increase in UCP3 protein in skeletal muscle as a component of the exercise-induced increase in mitochondrial biogenesis" (3). In this case, however, their conclusion is in contrast with the generally observed finding of decreased UCP3 mRNA and protein levels following endurance training (1, 7, 8, 11-14). For example, Boss et al. (1) showed downregulation of UCP3 mRNA after 8 wk of endurance training in rats (1). In humans, these findings are extended to the protein level, showing decreased UCP3 protein content in trained athletes (7) and after training (11). What can be the reason for the discrepancy between these studies and the conclusion of Jones et al.? Jones et al. show that UCP3 is increased by ~35, ~64, and ~84% with a concerted upregulation of cytochrome c and citrate synthase (marker proteins for mitochondrial density). Thus, if the upregulation of UCP3 related to the actual mitochondrial density, the more obvious conclusion would have been that the 10-day training program did not affect mitochondrial UCP3 content. Papers showing declined UCP3 protein levels following training have a cross-sectional (7) rather than a longitudinal design. In longitudinal designs, declined UCP3 levels have been reported after a 14-day training period (9) or longer (11). At present, there is paucity of data about the precise triggers, conditions, and time frame related to training-induced downregulation of UCP3. It therefore cannot be ruled out that the training intervention applied by Jones et al. is of insufficient duration to detect a training-induced decline in UCP3. Moreover, the divergent effect of acute exercise and training on UCP3 mRNA expression perfectly illustrates the importance of the time frame of sampling. Tsuboyama-Kasaoka et al. (14) showed profound upregulation of UCP3 mRNA 3 h postexercise and a return to pretraining levels within 22 h, and reduced levels were recorded 44 h postexercise. In the study by Jones et al., increased UCP3 protein with undetectably low mRNA levels (i.e., very low transcriptional activity) was reported 18 h after a single exercise session. It is therefore conceivable that the protein levels will decrease after the 18-h period. Because Jones et al. sampled muscles 18-20 h postexercise, it is likely that the mRNA data, and possibly protein levels reported, are biased by the remnant effect of the final exercise bout.
In summary, we think that the paper by Jones et al. (3) is compatible with previous studies. The lack of increase in UCP3 when expressed per mitochondria and the undetectably low mRNA levels 18 h postexercise make it feasible that, in the long term (depending on the UCP3 half-life time), decreased UCP3 protein levels will be detected after endurance training. Furthermore, this study again stresses the importance of considering the remnant effect of the final exercise bout when studying the effects of endurance training. Indeed, in previous papers from the same laboratory in which the same protocol was used, it was shown that the training-induced increase in GLUT4 was almost completely abolished within 40 h postexercise (2).
![]() |
REFERENCES |
---|
1.
Boss, O,
Samec S,
Desplanches D,
Mayet MH,
Seydoux J,
Muzzin P,
and
Giacobino JP.
Effect of endurance training on mRNA expression of uncoupling proteins 1, 2, and 3 in the rat.
FASEB J
12:
335-339,
1998
2.
Host, HH,
Hansen PA,
Nolte LA,
Chen MM,
and
Holloszy JO.
Rapid reversal of adaptive increases in muscle GLUT-4 and glucose transport capacity after training cessation.
J Appl Physiol
84:
798-802,
1998
3.
Jones, TE,
Baar K,
Ojuka E,
Chen M,
and
Holloszy JO.
Exercise induces an increase in muscle UCP3 as a component of the increase in mitochondrial biogenesis.
Am J Physiol Endocrinol Metab
284:
E96-E101,
2002.
4.
Pedersen, SB,
Lund S,
Buhl ES,
and
Richelsen B.
Insulin and contraction directly stimulate UCP2 and UCP3 mRNA expression in rat skeletal muscle in vitro.
Biochem Biophys Res Commun
283:
19-25,
2001[ISI][Medline].
5.
Pilegaard, H,
Keller C,
Steensberg A,
Helge JW,
Pedersen BK,
Saltin B,
and
Neufer PD.
Influence of pre-exercise muscle glycogen content on exercise-induced transcriptional regulation of metabolic genes.
J Physiol
541:
261-271,
2002
6.
Pilegaard, H,
Ordway GA,
Saltin B,
and
Neufer PD.
Transcriptional regulation of gene expression in human skeletal muscle during recovery from exercise.
Am J Physiol Endocrinol Metab
279:
E806-E814,
2000
7.
Russell A, Wadley G, Hesselink MKC, Schaart G, Lo SK, Leger B,
Garnham A, Kornips E, Cameron-Smith D, Giacobino JP, Muzzin P, Snow R,
and Schrauwen P. UCP3 protein expression is lower in type 1, IIa
and IIx muscle fiber types of endurance trained compared to untrained
subjects. Pflügers Arch [Online],
http://link.springer-ny.com/link/service/journals/00424/contents/02/00943/paper/500424-002-0943-5ch110.html
8.
Russell, A,
Wadley G,
Snow R,
Giacobino JP,
Muzzin P,
Garnham A,
and
Cameron-Smith D.
Slow component of O2 kinetics: the effect of training status, fibre type, UCP3 mRNA and citrate synthase activity.
Int J Obes Relat Metab Disord
26:
157-164,
2002[Medline].
9.
Schrauwen P and Hesselink MK. Uncoupling protein 3 and physical
activity; the role of UCP3 revisited. In press.
10.
Schrauwen, P,
Hesselink MK,
Vaartjes I,
Kornips E,
Saris WH,
Giacobino JP,
and
Russell A.
Effect of acute exercise on uncoupling protein 3 is a fat metabolism-mediated effect.
Am J Physiol Endocrinol Metab
282:
E11-E17,
2002
11.
Schrauwen, P,
Saris WH,
and
Hesselink MK.
An alternative function for human uncoupling protein 3: protection of mitochondria against accumulation of nonesterified fatty acids inside the mitochondrial matrix.
FASEB J
15:
2497-2502,
2001
12.
Schrauwen, P,
Troost FJ,
Xia J,
Ravussin E,
and
Saris WH.
Skeletal muscle UCP2 and UCP3 expression in trained and untrained male subjects.
Int J Obes Relat Metab Disord
23:
966-972,
1999[Medline].
13.
Tonkonogi, M,
Krook A,
Walsh B,
and
Sahlin K.
Endurance training increases stimulation of uncoupling of skeletal muscle mitochondria in humans by non-esterified fatty acids: an uncoupling-protein-mediated effect?
Biochem J
351:
805-810,
2000[ISI][Medline].
14.
Tsuboyama-Kasaoka, N,
Tsunoda N,
Maruyama K,
Takahashi M,
Kim H,
Ikemoto S,
and
Ezaki O.
Up-regulation of uncoupling protein 3 (UCP3) mRNA by exercise training and down-regulation of UCP3 by denervation in skeletal muscles.
Biochem Biophys Res Commun
247:
498-503,
1998[ISI][Medline].
Matthijs K. C. Hesselink Department of Movement Sciences | ||||||||||||
Patrick Schrauwen Department of Human Biology Nutrition and Toxicology Research Institute Maastricht, 6200 MD Maastricht University, The Netherlands |
To the Editor: Drs. Hesselink
and Schrauwen say, in their letter entitled Divergent effects of
acute exercise and endurance training on UCP3 expression, that our
findings show that "... if related to actual mitochondrial
density, the more obvious conclusion would have been that the 10-day
training program did not affect mitochondrial UCP3 content." This is
exactly what we concluded: "These increases in UCP3 roughly
paralleled those of other mitochondrial marker proteins. Our results
are consistent with the interpretation that endurance exercise induces
an adaptive increase in mitochondria that have a normal content of
UCP3." So we do not understand what is meant by "...the more
obvious conclusion would have been... ."
Mitochondrial biogenesis is regulated and coordinated by the
transcriptional coactivator PGC-1 (3, 6). The uncoupling proteins (UCPs) are among the mitochondrial proteins that increase and
are incorporated into mitochondria in response to increases in PGC-1
(3, 6). PGC-1 protein increases in muscle in response to
exercise and, likely, mediates the adaptive increase in mitochondria in
skeletal muscle (1). In addition, the peroxisome
proliferator-activated receptor-
REPLY
(which is coactivated by PGC-1) is
activated by fatty acids and mediates an increase in the mitochondrial
enzymes involved in the oxidation of fatty acids (2, 5).
Apparently, an increase in UCP3 is a component of this response
(4). Each bout of exercise induces increases in PGC-1
expression and in plasma fatty acid concentration that result over time
in an increase in muscle mitochondria. In this context, the suggestion
that mitochondria undergo an enormous change in mitochondrial
composition, with large increases in the enzymes involved in
carbohydrate and fat oxidation but a large decrease in UCP3 protein,
does not seem plausible.
![]() |
FOOTNOTES |
---|
First published September 17, 2002;10.1152/ajpendo.00417.2002
![]() |
REFERENCES |
---|
1.
Baar, K,
Wende AR,
Jones TE,
Marison M,
Nolte LA,
Chen M,
Kelly DP,
and
Holloszy JO.
Adaptations of skeletal muscle to exercise: rapid increase in the transcriptional coactivator PGC-1.
FASEB J
16:
1879-1886,
2002
2.
Gulick, T,
Cresci S,
Caira T,
Moore DD,
and
Kelly DP.
The peroxisome proliferator-activated receptor regulates mitochondrial fatty acid oxidative enzyme gene expression.
Proc Natl Acad Sci USA
91:
11012-11016,
1994
3.
Puigserver, P,
Wu Z,
Park CW,
Graves R,
Wright M,
and
Spiegelman BM.
A cold-inducible coactivator of nuclear receptors linked to adaptive thermogenesis.
Cell
92:
829-839,
1998[ISI][Medline].
4.
Schrauwen, P,
Hoppeler H,
Billeter R,
Bakker AHF,
and
Pendergast DR.
Fiber type dependent upregulation of human skeletal muscle UCP2 and UCP3 mRNA expression by high-fat diet.
Int J Obes Relat Metab Disord
25:
449-456,
2001[Medline].
5.
Vega, R,
Huss JM,
and
Kelly DP.
The coactivator PGC-1 cooperates with peroxisome proliferator-activated receptor in transcriptional control of nuclear genes encoding mitochondrial fatty acid oxidation enzymes.
Mol Cell Biol
20:
1868-1876,
2000
6.
Wu, Z,
Puigserver P,
Andersson U,
Zhang C,
Adelmant G,
Mootha V,
Troy A,
Cinti S,
Lowell B,
Scarpulla RC,
and
Spiegelman BM.
Mechanisms controlling mitochondrial biogenesis and respiration through the thermogenic coactivator PGC-1.
Cell
98:
115-124,
1999[ISI][Medline].
John O. Holloszy, Terry E. Jones Department of Internal Medicine Washington University School of Medicine St. Louis, MO 63110 |
HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
Visit Other APS Journals Online |