| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
REPORT
RECEPTORS AND SIGNAL TRANSDUCTION
promoter in response to exercise by in vivo imagingDepartment of Medicine, Duke University Medical Center, Durham, North Carolina
Submitted 19 February 2008 ; accepted in final form 17 April 2008
ABSTRACT
Real-time optical bioluminescence imaging is a powerful tool for studies of gene regulation in living animals. To elucidate exercise-induced signaling/transcriptional control of the peroxisome proliferator-activated receptor-
coactivator-1
(Pgc-1) gene in skeletal muscle, we combined this technology with electric pulse-mediated gene transfer to cotransfect the Pgc-1 reporter gene with plasmid DNA encoding mutant/deletion forms of putative regulatory factors and, thereby, assess the responsiveness of the promoter to skeletal muscle contraction. We show that each of the myocyte enhancer factor 2 sites on the Pgc-1 promoter is required for contractile activity-induced Pgc-1 transcription. The responsiveness of the Pgc-1 promoter to contractile activity could be completely blocked by overexpression of the dominant-negative form of activating transcription factor 2 (ATF2), the signaling-resistant form of histone deacetylase (HDAC) 5 (HDAC5), or protein kinase D (PKD), but not by HDAC4. These findings provide in vivo evidence for functional interactions between PKD/HDAC5 and ATF2 regulatory factors and the Pgc-1 gene in adult skeletal muscle.
signal transduction; transcriptional control; reporter gene; optical biolunminescence imaging; electric pulse-mediated gene transfer
coactivator-1 (Pgc-1), a versatile transcriptional coactivator (15), plays a pivotal role in exercise-induced genetic reprogramming in skeletal muscle (1, 3, 10, 17, 27). Although Pgc-1 activity could be controlled by posttranslational modification (8, 16), there is clear evidence that the Pgc-1 gene is transcriptionally activated in response to exercise, which could play an important role in skeletal muscle adaptation. Elucidating the signal transduction that leads to transcriptional regulation of the Pgc-1 gene will, therefore, likely provide valuable insights into the fundamental mechanisms of skeletal muscle plasticity and help in development of effective therapeutics for chronic diseases that are related to skeletal muscle contractile and metabolic functions. A great challenge to exercise scientists is that exercise training cannot be faithfully recapitulated in experimental models in vitro. An imaging system with real-time imaging of gene regulation in living animals will significantly facilitate this important research area.
The mouse Pgc-1 gene, similar to its mammalian homologs, contains conserved myocyte enhancer factor 2 (MEF2; at –2901 and –1539) and cAMP response element (CRE; at –222) sequences in the promoter that converge biological signals for the transcriptional control of the gene (6, 12). We previously established a novel optical bioluminescence imaging system in living mice and showed that double mutation of the two MEF2 sites or single mutation of the CRE site resulted in loss of Pgc-1 promoter responsiveness to motor nerve stimulation in skeletal muscle (2). These findings support the notion that exercise-induced Pgc-1 transcription is mediated by regulatory factors that interact with these cis elements on the Pgc-1 promoter. The functional interaction between regulatory factors and Pgc-1 promoter in response to increased neuromuscular activities remains to be elucidated in vivo.
MATERIALS AND METHODS
Animals. Male C57BL/6J mice (7–8 wk old) were obtained commercially (Jackson Laboratory) and housed in temperature-controlled (21°C) quarters with a 12:12-h light-dark cycle and water and chow (Purina) provided ad libitum. All experimental protocols were approved by the Duke University Institutional Animal Care and Use Committee.
Plasmid DNA constructs.
Pgc-1L is a construct containing a 3.1-kb 5'-flanking region of the mouse Pgc-1 gene upstream of the firefly luciferase coding sequence (6), and mutations of each of the MEF2 binding sites, 
MEF2(–2901) and MEF2(–1539), were generated by site-directed mutagenesis based on the sequence information described previously (6). Pgc-1L with CRE site mutation, CRE(–222), has been used previously (2). Plasmid HDAC5(S2A) encodes FLAG-tagged histone deacetylase 5 (HDAC5) with mutations of serine sites at 259 and 498 to nonphosphorylatable alanine sites (31). Similarly, HDAC4(S3A) encodes FLAG-tagged HDAC4 with serine-to-alanine mutations at residues 246, 467, and 632 (38). These mutations render the mutant HDAC proteins resistant to upstream signals (31, 38). Plasmid PKD(K/W) encodes a catalytically inactive mutant of protein kinase D (PKD) with a hemagglutinin (HA) tag (31). The dominant-negative ATF2N encodes a FLAG-tagged, truncated activating transcription factor 2 (ATF2) with NH2-terminal deletion from amino acid 1 to 137 (30). pCI-neo is a mammalian expression vector without coding region (Promega) used as a negative control for the mutant/deletion expression vectors described above. pEGFP-N1 was purchased from Invitrogen. All plasmid DNAs were purified using the Endo-Free Plasmid Mega kit (Qiagene) and dissolved at a concentration of 2.5 mg/ml in 0.9% NaCl solution.
Electric pulse-mediated gene transfer.
Electric pulse-mediated gene transfer was modified from previous studies (2, 9, 25). Briefly, under pentobarbital sodium anesthesia (50 mg/kg ip), both tibialis anterior (TA) muscles were injected with a mixture of DNA (15 µg of Pgc-1L and 50 µg of plasmid DNA encoding a mutant/deletion form of regulatory factor) by use of a 0.5-ml syringe with a 28-gauge needle at a rate of <0.015 ml/min. Eight electric pulses (100 ms, 1 Hz, 100 V) were delivered immediately to the injected TA muscle using a square-pulse stimulator (model S88K, Grass Telefactor) through a two-needle array (model 533, BTX) placed on the medial and lateral sides of the TA muscle, so that the electrical field was perpendicular to the long axis of the myofibers. Mice were allowed to recover for 10 days before electrode implantation, nerve stimulation, and imaging analysis.
Motor nerve stimulation and optical bioluminescence imaging. Under anesthesia, electrodes were implanted, and motor nerve stimulation was initiated within 30 min and continued for 2 h. In vivo bioluminescence images were acquired and analyzed as described previously (2). The total flux (in photons·s–1·cm–2·steradian) within the region of interest was measured. The ratio of the total flux from the stimulated muscle to that from the contralateral control muscle was determined before and after motor nerve stimulation.
Western immunoblot analysis.
TA muscles were homogenized and analyzed by immunoblot as described elsewhere (32). Antibodies used were ANTI-FLAG polyclonal antibody (F-7425, Sigma), anti-HA antibody (Roche), and anti--tubulin antibody (Sigma).
Statistics. Luciferase activity in the stimulated TA muscle was divided by that in the contralateral control muscle. Values before and after motor nerve stimulation were compared by paired Student's t-test, with P < 0.05 considered statistically significant. Values are means ± SE.
RESULTS AND DISCUSSION
To further define the functional role of the cis elements on the Pgc-1 promoter, we performed site-directed mutagenesis for each of the MEF2 sites individually and confirmed that they are equally important for the transcriptional activation of the Pgc-1 gene in skeletal muscle in vivo (Fig. 1). These findings raised the possibility that exercise-induced Pgc-1 transcriptional activation is fully dependent on functional interactions of regulatory factors with the MEF2 and the CRE cis elements on the Pgc-1 promoter.
|
L reporter gene. This approach, analogous to cotransfection approaches used extensively in cultured cells, had not been possible in a living animal until recent improvement of the gene transfer technique in adult skeletal muscle (9, 25). We first checked the efficiency of in vivo cotransfection to ensure possible dominant-negative effect of the transgenes. Gene transfer of a plasmid DNA containing the enhanced green fluorescent protein transfected 
60% of the myofibers in mouse TA muscles (Fig. 2A), which maintained normal morphology following the recovery (10 days). We then cotransfected TA muscles with plasmid DNAs containing Pgc-1L reporter gene (3.1-kb mouse Pgc-1 promoter driving firefly luciferase) and an empty control vector (pCI-neo) or plasmid DNA encoding epitope-tagged mutant/deletion forms of putative regulatory proteins. Consistent with efficient gene transfer, transgene products, but not the empty control vector, could be readily detected by immunoblot analysis (Fig. 2B). These results demonstrated high feasibility for the in vivo approach and prompted us to proceed with the investigation of functional interactions of the putative regulatory factors with the MEF2 and CRE cis elements on the Pgc-1 promoter.
|
, directing phenotypic adaptation in skeletal muscle. The interaction between class II HDACs and MEF2 serves as an ideal "on-and-off" control for skeletal muscle adaptation. A recent study in which skeletal muscle-specific overexpression of a constitutively active form of MEF2C enhanced expression of proteins in the oxidative metabolism pathway and resulted in formation of more oxidative fibers in otherwise glycolytic muscles provides direct proof of this concept (28). Indeed, HDAC-mediated control of metabolic function has also been shown in Pgc-1 gene expression in oxidative cardiac myocytes; loss of such control leads to the detrimental consequence of heart failure due to reduced mitochondrial biogenesis and function (6). However, it has yet to be demonstrated in a loss-of-function manner that MEF2 controls the Pgc-1 gene transcription in adult skeletal muscle in vivo.
We chose to focus on two class II HDACs, HDAC4 and HDAC5, because they bind to and repress MEF2 activities (19, 22) and their activities are highly regulated by neuromuscular activity (18, 20, 28). Cotransfection of Pgc-1 reporter gene with an empty control vector (pCI-neo) in TA muscle followed by motor nerve stimulation resulted in a twofold increase in luciferase activity (Fig. 3), and cotransfection of a nonphosphorylatable, signal-resistant mutant of HDAC4 [HDAC4(S3A)] or HDAC5 [HDAC(S2A)] did not affect the basal activity of the Pgc-1 reporter gene (not shown). However, motor nerve stimulation-induced Pgc-1 transcription was completely blocked by overexpression of HDAC5(S2A), but not HDAC4(S3A) (P < 0.05 vs. contralateral control TA muscle; P = 0.43 vs. pCI-neo empty vector control). These findings suggest that the Pgc-1 gene is preferentially controlled by the HDAC5-MEF2 interaction.
|
gene by phosphorylating HDAC5 and releasing MEF2 from inhibition. Consistent with this hypothesis, cotransfection of a signal-resistant PKD [PKD(K/W)] completely blocked motor nerve stimulation-induced transcriptional activation of the Pgc-1 gene in skeletal muscle. More recently, it has been shown that HDAC5 can be phosphorylated by AMP-activated protein kinase, leading to reduced association of HDAC5 with the promoter of glucose transporter 4 and enhanced the gene expression (21). Taken together, these findings indicate the importance of HDAC5 in the control of the skeletal muscle metabolic phenotype through the Pgc-1 gene.
The p38 mitogen-activated protein kinase (MAPK) pathway in skeletal muscle has been a focus of research (26, 29, 37), inasmuch as various forms of contractile activity activate the p38 MAPK pathway in skeletal muscle (4, 5, 14, 33), suggesting its importance in muscle adaptation. We and others recently obtained evidence that activation of the p38 MAPK and its downstream effector ATF2 participates in Pgc-1 gene expression in skeletal muscle (1, 34). ATF2, as a member of the leucine zipper family of transcription factors, binds to the CRE for its transactivation function. Pharmacological inhibition of the p38 MAPK pathway or overexpression of a dominant-negative form of ATF2 blocks the transcriptional activation of the Pgc-1 gene in skeletal muscles in culture (1, 34). However, the functional role of ATF2 in transcriptional control of the Pgc-1 gene in vivo has not been confirmed in skeletal muscle in a physiological model of exercise. Here, we showed that overexpression of a truncated, dominant-negative form of ATF2 (30) completely blocked contractile activity-induced Pgc-1 reporter gene activity, providing direct evidence that ATF2 plays an essential role in the transcriptional control of the Pgc-1 gene in skeletal muscle (Fig. 3).
Interestingly, the PKD/HDAC5/MEF2 and p38/ATF2 signal transductions have been linked to the stress and the calcium signals in striated muscles (7, 23, 31, 34). The functional interactions of these two regulatory modules with the Pgc-1 promoter observed in the present study are consistent with the notion that multiple cellular signals converge to control a powerful regulatory factor, such as Pgc-1, in defining skeletal muscle phenotype (Fig. 4). The multiple signal/transcription control system would not only allow for more sophisticated fine tuning of the adaptive functions, but it would also ensure the validity of the signals to avoid unnecessary dysregulation of the system. Future research should focus on dissection of each one of the physiological signals in skeletal muscle adaptation. The analytic system employed in the present study by combining efficient gene transfer of regulatory factors with biochemiluminescence imaging of reporter gene is an exciting step toward a complete elucidation of all the signaling and transcription mechanisms of skeletal muscle adaptation and could be applicable to other organ systems and disease models.
|
This study was supported by National Institute of Arthritis and Musculoskeletal and Skin Diseases Grant AR-050429 to Z. Yan.
ACKNOWLEDGMENTS
We thank E. N. Olson and R. Bassel-Duby for kind gifts of Pgc-1L and HDAC5(S2A) and PKD(K/W) DNA constructs, T. P. Yao for providing HDAC4(S3A) construct, and G. Thiel for providing ATF2N construct. We thank Mei Zhang for excellent technical assistance.
Present address of T. Akimoto: Division of Biomedical Materials and Systems, Center for Disease Biology and Integrative Medicine, Graduate School of Medicine, The University of Tokyo, 7-3-1 Hongo, Bunkyo, Tokyo 113-0033, Japan.
FOOTNOTES
Address for reprint requests and other correspondence: Z. Yan, 4321 Medical Park Dr., Suite 200, Duke Univ. Independence Park Facility, Durham, NC 27704 (e-mail: zhen.yan{at}duke.edu)
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
REFERENCES
1. Akimoto T, Pohnert SC, Li P, Zhang M, Gumbs C, Rosenberg PB, Williams RS, Yan Z. Exercise stimulates Pgc-1 transcription in skeletal muscle through activation of the p38 MAPK pathway. J Biol Chem 280: 19587–19593, 2005.
2. Akimoto T, Sorg BS, Yan Z. Real-time imaging of peroxisome proliferator-activated receptor- coactivator-1 promoter activity in skeletal muscles of living mice. Am J Physiol Cell Physiol 287: C790–C796, 2004.
3. Baar K, Wende AR, Jones TE, Marison M, Nolte LA, Chen M, Kelly DP, Holloszy JO. Adaptations of skeletal muscle to exercise: rapid increase in the transcriptional coactivator PGC-1. FASEB J 16: 1879–1886, 2002.
4. Boppart MD, Asp S, Wojtaszewski JF, Fielding RA, Mohr T, Goodyear LJ. Marathon running transiently increases c-Jun NH2-terminal kinase and p38 activities in human skeletal muscle. J Physiol 526: 663–669, 2000.
5. Boppart MD, Hirshman MF, Sakamoto K, Fielding RA, Goodyear LJ. Static stretch increases c-Jun NH2-terminal kinase activity and p38 phosphorylation in rat skeletal muscle. Am J Physiol Cell Physiol 280: C352–C358, 2001.
6. Czubryt MP, McAnally J, Fishman GI, Olson EN. Regulation of peroxisome proliferator-activated receptor coactivator 1 (PGC-1) and mitochondrial function by MEF2 and HDAC5. Proc Natl Acad Sci USA 100: 1711–1716, 2003.
7. Enslen H, Raingeaud J, Davis RJ. Selective activation of p38 mitogen-activated protein (MAP) kinase isoforms by the MAP kinase kinases MKK3 and MKK6. J Biol Chem 273: 1741–1748, 1998.
8. Fan M, Rhee J, St-Pierre J, Handschin C, Puigserver P, Lin J, Jaeger S, Erdjument-Bromage H, Tempst P, Spiegelman BM. Suppression of mitochondrial respiration through recruitment of p160 myb binding protein to PGC-1: modulation by p38 MAPK. Genes Dev 18: 278–289, 2004.
9. Fujii N, Boppart MD, Dufresne SD, Crowley PF, Jozsi AC, Sakamoto K, Yu H, Aschenbach WG, Kim S, Miyazaki H, Rui L, White MF, Hirshman MF, Goodyear LJ. Overexpression or ablation of JNK in skeletal muscle has no effect on glycogen synthase activity. Am J Physiol Cell Physiol 287: C200–C208, 2004.
10. Goto M, Terada S, Kato M, Katoh M, Yokozeki T, Tabata I, Shimokawa T. cDNA cloning and mRNA analysis of PGC-1 in epitrochlearis muscle in swimming-exercised rats. Biochem Biophys Res Commun 274: 350–354, 2000.[CrossRef][Web of Science][Medline]
11. Han J, Jiang Y, Li Z, Kravchenko VV, Ulevitch RJ. Activation of the transcription factor MEF2C by the MAP kinase p38 in inflammation. Nature 386: 296–299, 1997.[CrossRef][Medline]
12. Handschin C, Rhee J, Lin J, Tarr PT, Spiegelman BM. An autoregulatory loop controls peroxisome proliferator-activated receptor coactivator 1 expression in muscle. Proc Natl Acad Sci USA 100: 7111–7116, 2003.
13. Huynh QK, McKinsey TA. Protein kinase D directly phosphorylates histone deacetylase 5 via a random sequential kinetic mechanism. Arch Biochem Biophys 450: 141–148, 2006.[CrossRef][Web of Science][Medline]
14. Irrcher I, Adhihetty PJ, Sheehan T, Joseph AM, Hood DA. PPAR coactivator-1 expression during thyroid hormone- and contractile activity-induced mitochondrial adaptations. Am J Physiol Cell Physiol 284: C1669–C1677, 2003.
15. Knutti D, Kralli A. PGC-1, a versatile coactivator. Trends Endocrinol Metab 12: 360–365, 2001.[CrossRef][Web of Science][Medline]
16. Lagouge M, Argmann C, Gerhart-Hines Z, Meziane H, Lerin C, Daussin F, Messadeq N, Milne J, Lambert P, Elliott P, Geny B, Laakso M, Puigserver P, Auwerx J. Resveratrol improves mitochondrial function and protects against metabolic disease by activating SIRT1 and PGC-1. Cell 127: 1109–1122, 2006.[CrossRef][Web of Science][Medline]
17. Lin J, Wu H, Tarr PT, Zhang CY, Wu Z, Boss O, Michael LF, Puigserver P, Isotani E, Olson EN, Lowell BB, Bassel-Duby R, Spiegelman BM. Transcriptional co-activator PGC-1L drives the formation of slow-twitch muscle fibres. Nature 418: 797–801, 2002.[CrossRef][Medline]
18. Liu Y, Randall WR, Schneider MF. Activity-dependent and -independent nuclear fluxes of HDAC4 mediated by different kinases in adult skeletal muscle. J Cell Biol 168: 887–897, 2005.
19. Lu J, McKinsey TA, Nicol RL, Olson EN. Signal-dependent activation of the MEF2 transcription factor by dissociation from histone deacetylases. Proc Natl Acad Sci USA 97: 4070–4075, 2000.
20. McGee SL. Exercise and HDAC interactions. Physiol Appl Nutr Metab 32: 852–856, 2007.[CrossRef]
21. McGee SL, van Denderen BJ, Howlett KF, Mollica J, Schertzer JD, Kemp BE, Hargreaves M. AMP-activated protein kinase regulates GLUT4 transcription by phosphorylating histone deacetylase 5. Diabetes 57: 860–867, 2008.
22. McKinsey TA, Zhang CL, Lu J, Olson EN. Signal-dependent nuclear export of a histone deacetylase regulates muscle differentiation. Nature 408: 106–111, 2000.[CrossRef][Medline]
23. McKinsey TA, Zhang CL, Olson EN. Activation of the myocyte enhancer factor-2 transcription factor by calcium/calmodulin-dependent protein kinase-stimulated binding of 14-3-3 to histone deacetylase 5. Proc Natl Acad Sci USA 97: 14400–14405, 2000.
24. Michael LF, Wu Z, Cheatham RB, Puigserver P, Adelmant G, Lehman JJ, Kelly DP, Spiegelman BM. Restoration of insulin-sensitive glucose transporter (GLUT4) gene expression in muscle cells by the transcriptional coactivator PGC-1. Proc Natl Acad Sci USA 98: 3820–3825, 2001.
25. Mir LM, Bureau MF, Gehl J, Rangara R, Rouy D, Caillaud JM, Delaere P, Branellec D, Schwartz B, Scherman D. High-efficiency gene transfer into skeletal muscle mediated by electric pulses. Proc Natl Acad Sci USA 96: 4262–4267, 1999.
26. Niu W, Huang C, Nawaz Z, Levy M, Somwar R, Li D, Bilan PJ, Klip A. Maturation of the regulation of GLUT4 activity by p38 MAPK during L6 cell myogenesis. J Biol Chem 278: 17953–17962, 2003.
27. Pilegaard H, Saltin B, Neufer PD. Exercise induces transient transcriptional activation of the PGC-1 gene in human skeletal muscle. J Physiol 546: 851–858, 2003.
28. Potthoff MJ, Wu H, Arnold MA, Shelton JM, Backs J, McAnally J, Richardson JA, Bassel-Duby R, Olson EN. Histone deacetylase degradation and MEF2 activation promote the formation of slow-twitch myofibers. J Clin Invest 117: 2459–2467, 2007.[CrossRef][Web of Science][Medline]
29. Puigserver P, Rhee J, Lin J, Wu Z, Yoon JC, Zhang CY, Krauss S, Mootha VK, Lowell BB, Spiegelman BM. Cytokine stimulation of energy expenditure through p38 MAP kinase activation of PPAR coactivator-1. Mol Cell 8: 971–982, 2001.[CrossRef][Web of Science][Medline]
30. Steinmuller L, Thiel G. Regulation of gene transcription by a constitutively active mutant of activating transcription factor 2 (ATF2). Biol Chem 384: 667–672, 2003.[CrossRef][Web of Science][Medline]
31. Vega RB, Harrison BC, Meadows E, Roberts CR, Papst PJ, Olson EN, McKinsey TA. Protein kinases C and D mediate agonist-dependent cardiac hypertrophy through nuclear export of histone deacetylase 5. Mol Cell Biol 24: 8374–8385, 2004.
32. Waters RE, Rotevatn S, Li P, Annex BH, Yan Z. Voluntary running induces fiber type-specific angiogenesis in mouse skeletal muscle. Am J Physiol Cell Physiol 287: C1342–C1348, 2004.
33. Widegren U, Jiang XJ, Krook A, Chibalin AV, Bjornholm M, Tally M, Roth RA, Henriksson J, Wallberg-henriksson H, Zierath JR. Divergent effects of exercise on metabolic and mitogenic signaling pathways in human skeletal muscle. FASEB J 12: 1379–1389, 1998.
34. Wright DC, Geiger PC, Han DH, Jones TE, Holloszy JO. Calcium induces increases in peroxisome proliferator-activated receptor coactivator-1 and mitochondrial biogenesis by a pathway leading to p38 mitogen-activated protein kinase activation. J Biol Chem 282: 18793–18799, 2007.
35. Wu H, Naya FJ, McKinsey TA, Mercer B, Shelton JM, Chin ER, Simard AR, Michel RN, Bassel-Duby R, Olson EN, Williams RS. MEF2 responds to multiple calcium-regulated signals in the control of skeletal muscle fiber type. EMBO J 19: 1963–1973, 2000.[CrossRef][Web of Science][Medline]
36. Wu H, Rothermel B, Kanatous S, Rosenberg P, Naya FJ, Shelton JM, Hutcheson KA, DiMaio JM, Olson EN, Bassel-Duby R, Williams RS. Activation of MEF2 by muscle activity is mediated through a calcineurin-dependent pathway. EMBO J 20: 6414–6423, 2001.[CrossRef][Web of Science][Medline]
37. Zetser A, Gredinger E, Bengal E. p38 mitogen-activated protein kinase pathway promotes skeletal muscle differentiation. Participation of the Mef2c transcription factor. J Biol Chem 274: 5193–5200, 1999.
38. Zhao X, Ito A, Kane CD, Liao TS, Bolger TA, Lemrow SM, Means AR, Yao TP. The modular nature of histone deacetylase HDAC4 confers phosphorylation-dependent intracellular trafficking. J Biol Chem 276: 35042–35048, 2001.
This article has been cited by other articles:
|
|
 |
|
  T. E. Jensen, S. J. Maarbjerg, A. J. Rose, M. Leitges, and E. A. Richter Knockout of the predominant conventional PKC isoform, PKC{alpha}, in mouse skeletal muscle does not affect contraction-stimulated glucose uptake Am J Physiol Endocrinol Metab, August 1, 2009; 297(2): E340 - E348. [Abstract] [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
| Visit Other APS Journals Online |
60% GFP-positive myofibers. Red lines outline boundary of muscle sections. *, Myofibers that are negative for GFP signals. Scale bars, 250 and 50 µm for x4 and x40 images, respectively. B: expression of ATF2
