HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) All Versions of this Article: 295/2/R642    most recent 00852.2007v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Stary, C. M. Articles by Hogan, M. C. Search for Related Content PubMed PubMed Citation Articles by Stary, C. M. Articles by Hogan, M. C.

EXERCISE AND RESPIRATORY PHYSIOLOGY

Elevation in heat shock protein 72 mRNA following contractions in isolated single skeletal muscle fibers

Division of Physiology, Department of Medicine, University of California San Diego, La Jolla, California

Submitted 28 November 2007 ; accepted in final form 2 June 2008

	ABSTRACT

TOP ABSTRACT RESULTS GRANTS REFERENCES

 
The purpose of the present study was 1) to develop a stable model for measuring contraction-induced elevations in mRNA in single skeletal muscle fibers and 2) to utilize this model to investigate the response of heat shock protein 72 (HSP72) mRNA following an acute bout of fatiguing contractions. Living, intact skeletal muscle fibers were microdissected from lumbrical muscle of Xenopus laevis and either electrically stimulated for 15 min of tetanic contractions (EX; n = 26) or not stimulated to contract (REST; n = 14). The relative mean developed tension of EX fibers decreased to 29 ± 7% of initial peak tension at the stimulation end point. Following treatment, individual fibers were allowed to recover for 1 (n = 9), 2 (n = 8), or 4 h (n = 9) prior to isolation of total cellular mRNA. HSP72, HSP60, and cardiac -actin mRNA content were then assessed in individual fibers using quantitative PCR detection. Relative HSP72 mRNA content was significantly (P < 0.05) elevated at the 2-h postcontraction time point relative to REST fibers when normalized to either HSP60 (18.5 ± 7.5-fold) or cardiac -actin (14.7 ± 4.3-fold), although not at the 1- or 4-h time points. These data indicate that 1) extraction of RNA followed by relative quantification of mRNA of select genes in isolated single skeletal muscle fibers can be reliably performed, 2) HSP60 and cardiac -actin are suitable endogenous normalizing genes in skeletal muscle following contractions, and 3) a significantly elevated content of HSP72 mRNA is detectable in skeletal muscle 2 h after a single bout of fatiguing contractions, despite minimal temperature changes and without influence from extracellular sources.

exercise; heat shock; stress

Exercise is a nonspecific stress that particularly affects skeletal muscle, and it has been established in whole animal (57, 60) and human models (13, 47, 53, 69, 71) that a single bout of high-intensity exercise can induce an acute elevation in skeletal muscle HSP72. However, due to the multiplicity of potential signaling mechanisms that occur simultaneously within intensely contracting skeletal muscle, including alterations of the phosphorylation potential (12, 23, 50), impaired cytosolic Ca²⁺ cycling (76, 78), decreases in intracellular PO₂ (21, 56), accumulation of metabolic byproducts in the extracellular medium, and the generation of heat, which may reach 45°C in contracting whole muscle (57), it remains uncertain which, if any, intracellular disruptions may be responsible for the observed increased production of HSP72. Furthermore, the utilization of whole animal and isolated muscle preparations make it difficult to isolate and determine the precise signaling mechanisms for induction of HSP72 at the cellular level.

Unlike whole animal and whole muscle models, in the isolated intact single skeletal muscle fiber preparation the extracellular environment is homogeneous and can be easily adjusted and determined, therefore eliminating complications associated with extracellular stimuli, intracellular substrate availability, extracellular pH, and/or metabolic waste product removal. In addition, through conduction and convection in a well-stirred medium, the minimal amount of internal labile heat produced from contractions (31) is rapidly dissipated, and temperature is therefore predominantly determined by the extracellular environment, which can be easily set and maintained. Therefore, to determine whether an exercise-induced intracellular signal other than heat production can stimulate an immediate elevation of HSP72 mRNA in skeletal muscle, we developed a stable model for measuring contraction-induced elevations in mRNA in single skeletal muscle fibers via quantitative PCR (qPCR) utilizing TaqMan minor-groove binder (MGB) probes. We then employed this model to test the hypothesis that a single bout of fatiguing, tetanic contractions would induce an acute elevation of HSP72 mRNA in isolated single skeletal muscle fibers at 1, 2, and 4 h.

Methods

Female adult Xenopus laevis were used in this investigation. All procedures were approved by the University of California San Diego Animal Use and Care Committee and conform to National Institutes of Health standards.

Experimental protocol. Single muscle fibers were isolated and prepared as described previously (22). Briefly, frogs were doubly pithed, and the lumbrical muscles (II-IV) were removed. To reduce possible fiber-type variability of HSP72 expression, primarily fast-twitch, glycolytic skeletal muscle fibers were selected for use in the present study, as previously described (32, 64). Individual, single skeletal muscle fibers (n = 54) were microdissected with tendons intact in a chamber of physiological Ringers solution at a pH = 7.0. Platinum clips were attached to the tendons of each muscle fiber to facilitate positioning within the Ringers solution-filled chamber. One tendon was fixed, whereas the other tendon was attached to an adjustable force transducer (model 400A; Aurora Scientific, Aurora, Ontario, Canada), allowing the muscle to be set at optimum muscle length. The analog signal from the force transducer was recorded via a data acquisition system (AcqKnowledge; Biopac Systems, Santa Barbara, CA) for subsequent analysis. Individual fibers were perfused throughout the experiment with air-equilibrated Ringers solution to maintain a stable temperature (22°C) and to reduce the occurrence of an appreciable unstirred layer surrounding the cell.

Immediately following microdissection, individual fibers were randomly assigned to either the contraction treatment group (EX; n = 26), consisting of 15 min of tetanic contractions at a 0.33-Hz stimulation frequency, or to the no-contraction treatment group (REST; n = 14). REST fibers were kept in solution following microdissection for either 0 (n = 4), 1 (n = 3), 2 (n = 4), or 4 h (n = 3). Tetanic contractions were elicited using direct (8–10 V) stimulation of the muscle (model S48; Grass Instruments, Warwick, RI). The stimulation protocol consisted of 250-ms trains of 70-Hz impulses of 1 ms duration. Following contractions, fibers were processed for isolation of total cellular RNA at either 1 h (n = 9), 2 h (n = 8), or 4 h (n = 9) posttreatment. Prior to processing for RNA isolation, individual fibers were electrically stimulated to test for fiber viability.

RNA extraction and cDNA synthesis. Isolation of total cellular RNA from individual fibers was performed using a protocol incorporating Trizol reagent (Invitrogen, Carlsbad, CA) and the Micro RNeasy Total RNA isolation kit (Qiagen, Valencia, CA). Individual fibers were manually cleaned of residual cellular debris and removed from the tendon. Fibers were then introduced into 0.5 ml of Trizol reagent, and RNA was isolated according to the manufacturer's protocol. RNA was then eluted using the Micro RNeasy Total RNA isolation kit (Qiagen). Quantification of RNA content of 14 separate fibers was performed in triplicate using a NanoDrop fluorospectrometer (model ND-3300) with Ribogreen RNA fluorescent indicator dye (NanoDrop, Wilmington, DE). The amount of total mRNA recovered from these single fibers was 14 ± 2 pg·µl^–1·fiber^–1. First-strand cDNA synthesis was performed on the DNase-treated total RNA using a Thermoscript Taq-free kit (Invitrogen) per manufacturer's protocol. All resulting cDNA was subjected to qPCR amplification using TaqMan MGB probes with 6-FAM fluorescence detection.

TaqMan-MGB primers and fluorogenic probe design. TaqMan-MGB probes (Applied Biosystems, Foster City, CA) are a new class of reporter probes that incorporate a 5' reporter dye (6-FAM) and a 3' nonfluorescent quencher (30), offering the advantage of lower background signal and increased melting temperature, thereby increasing sequence specificity. Sequence-specific TaqMan primers and probes were designed to definitive Xenopus laevis gene sequences recorded in GenBank for HSP72 (GenBank ascension no. BC078115), HSP60 (GenBank ascension no. BC041192), and cardiac -actin (GenBank ascension no. X03469) with Primer Express version 2.0 (Applied Biosystems). Optimal primers and probes were 20–80% GC rich, between 9–40 bases in length, had primer melting temperature values of 58–60°C, with probe melting temperatures 10°C higher than the primer melting temperatures. The probe selected was close to the 3' end of the forward primer, had more bases of Cs than Gs, and < 4 contiguous Gs in the strand, as recommended by the manufacturer and described by Livak et al. (37). Amplicons were then homology-searched to ensure that they were specific for the target mRNA transcript using an NCBI BLAST search. Primers and probe sequences are presented in Table 1.

Amplification was performed in 0.6 ml 96-well polypropylene real-time PCR plates (Stratagene). qPCR parameters were as follows: 95°C for 10 min followed by 40 cycles at 95°C for 15 s and 60°C for 1 min. As the comparative quantification calculation is based on the assumption that amplification of individual genes occurs with similar reaction efficiencies, qPCR assays of three-step 10x serial dilutions of RT product from heat-shocked (37°C for 1 h; n = 6) Xenopus muscle bundles were performed with each gene primer set used, and the reaction efficiencies calculated and compared. Heat shock was sufficient to generate sufficient HSP72 mRNA content for an accurate serial dilution. Following amplification, select amplicons were electrophoresed on a 1.5% agarose gel adjacent to a 100-bp ladder, and visualized with ethidium-bromide for fragment size. Band location of amplicon for HSP72, HSP60, and cardiac -actin corresponded to sequence size (60 bp), indicating specific amplification of the desired sequence. No bands were detected in the negative control no-template control or no-reverse transcription control lanes, indicating that these samples were free from both genomic DNA contamination and amplified primer-dimer.

Calculations. The suitability of cardiac -actin and HSP60 as internal, endogenous normalizers, i.e., housekeeping genes (HKGs), and the fold change of HSP72 mRNA between treatment groups were determined by the relative quantification method (C_t), as originally reported by Livak and Schmittgen (38), according to the equation, where C_t = (C_{t target} – C_{t reference})_{treatment 1} – (C_{t target} – C_{t reference})_{treatment 2}, where C_t is the threshold cycle, and the target gene in each treatment group is normalized to the reference gene. To compare the suitability of HSP60 and cardiac -actin as HKGs, the fold change in single fibers from the contraction treatment group (treatment 2) of HSP60 mRNA (target) was calculated with cardiac -actin as the reference (HKG) gene and relative to the expression of HSP60 in single fibers from the rest (no contractions) treatment group (treatment 1). Using this analysis, if the level of the two HKGs was not affected by experimental conditions, the values of the mean fold change at each time point should be very close to 1 (i.e., since 2⁰ = 1) (38). In a similar manner, the fold change of HSP72 of single fibers in the contraction treatment group was analyzed with either HSP60 or cardiac -actin as the reference gene and relative to the expression of HSP72 in single fibers from the rest treatment group. An increase in HSP72 mRNA resulting from the treatment effect will be reflected by values of fold change > 1.

Data and statistical analysis. Changes in force over time were tested via a repeated-measures two-way ANOVA. Relative fold change in qPCR amplicon content between treatment groups was tested via a two-way ANOVA. When significant F values were present, the Bonferroni post hoc test was employed for determination of between-group differences. Relative fold changes from mean rest values in qPCR amplicon content were tested via a one-sample t-test, with 1 as the test variable, since 2⁰ = 1. Statistical significance was accepted at P < 0.05.

	RESULTS

TOP ABSTRACT RESULTS GRANTS REFERENCES

 
Examples of fluorescence emission during PCR amplification for 10x serial dilutions of RT product from a heat-shocked Xenopus skeletal muscle bundle are illustrated in Fig. 1 for HSP60 (Fig. 1A), cardiac -actin (Fig. 1B), and HSP72 (Fig. 1C). When the C_t of individual TaqMan primer/probe sets are plotted against the base 10 log of the dilution, (Fig. 1D), individual amplification efficiencies of RT product from this bundle for each primer/probe set can be calculated. The mean amplification efficiencies for all serial dilutions (n = 3) of individual TaqMan primer/probe sets yielded a mean efficiency of 101.7 ± 2.3% (HSP60 = 99%; cardiac -actin = 101%; HSP72 = 106%), indicating that these primer/probe sets are suitable for comparative C_t analysis of their respective genes.

View larger version (10K): [in this window] [in a new window]   Fig. 1. Individual quantitative PCR (qPCR) plots of heat shock protein 60 (HSP60; A), cardiac a-actin (B), and HSP72 (C) amplified from serial 10x dilutions of RT product isolated from a heat-shocked Xenopus muscle bundle. When plotted against the log of template concentration, the threshold cycle (Ct) can be used to estimate efficiency of amplification (D) by comparing the slope to –3.32 (100% efficiency).

View larger version (20K): [in this window] [in a new window]   Fig. 2. Representative stress (developed tension/cross-sectional area) recording of an individual fiber (A) and relative mean peak developed tension of all fibers subjected to 15 min of 0.33-Hz tetanic contractions (B; means ± SE; n = 26). Significant development of fatigue was demonstrated at the stimulation end point in all fibers; however, no difference in relative developed tension was observed at the stimulation end point between fibers allowed to recover 1, 2, or 4 h.

View larger version (8K): [in this window] [in a new window]   Fig. 3. Relative mean fold change from rest of HSP60 mRNA normalized to cardiac -actin mRNA remained stable at 1 h (mean ± SE; n = 9) and 2 h postexercise (means ± SE; n = 8), yet had an upward (yet not statistically significant) trend 4 h (mean ± SE; n = 9) following exercise (A). When normalized to HSP60 or cardiac -actin, HSP72 mRNA was significantly (P < 0.05) elevated at the 2-h time point, relative to rest fibers (B). *Significant increase above rest (>1-fold, since 20 = 1).

The results of the present study, in which isolated single skeletal muscle fibers were subjected to an acute bout of fatiguing contractions followed by comparative analysis of HSP72, HSP60, and cardiac -actin mRNA demonstrate that 1) isolation of mRNA followed by qPCR can be reliably performed in isolated single skeletal muscle fibers, 2) HSP60 and cardiac -actin are suitable HKGs for comparative analysis of transcription in skeletal muscle in response to contractions, 3) HSP72 mRNA content significantly increases in these single skeletal muscle fibers 2 h following a single bout of fatiguing contractions, and 4) the contraction-related stimulus for increased HSP72 mRNA in these skeletal muscle fibers is intracellular in nature, and occurs independently of any significant alteration in temperature.

Single skeletal muscle fiber model of transcriptional activation following contractions. The upregulation of HSP72 occurs following activation and trimerization of heat-shock transcription factor, permitting binding to the heat-shock response promoter element with subsequent initiation of transcription (2). Although HSP72 mRNA expression is regulated following activation of heat-shock transcription factor (7), protein expression appears to be controlled at the level of transcription (51, 58, 73). Increased transcription of HSP72 mRNA in skeletal muscle following a single, acute bout of exercise has been previously described in both exercising animals (20, 39, 43, 44, 57, 60) and humans (15, 26, 27, 47, 52, 55, 67–69, 72). However, an accurate assessment of the cellular transcriptional response of skeletal muscle to contractions in these models is precluded by heterogeneity of tissue, motor unit recruitment, and muscle fiber type. Furthermore, due to the heterogeneous mix of tissue contained in whole muscle or biopsy homogenates which have been shown to produce HSP72 in response to stress, including nervous tissue (59), endothelium (25), and phagocytic cells (27), the increase in HSP72 mRNA arising from the skeletal muscle myocyte alone cannot be established from these previous studies.

The isolated single skeletal muscle fiber preparation used in the present study is free from these above-mentioned constraints and was therefore utilized to establish a model of gene analysis following contractions in skeletal muscle. Isolated single skeletal muscle fibers from Xenopus laevis have been commonly employed in delineating mechanisms of fatigue (74, 75, 77) and muscle bioenergetics during contractions (21, 50, 62, 63). Furthermore, the Xenopus HSP72 gene has been cloned (5, 29), and it has been demonstrated that Xenopus skeletal muscle responds to heat stress with increased transcription of HSP72 (1). However, prior to the present study, it was unknown whether Xenopus skeletal muscle increases transcription of HSP72 mRNA in response to contractions, as has been documented in other species.

In the present study, the limited amount of total mRNA recovered from these single fibers prevents utilization of the standard dilution technique of qPCR analyses of mRNA content. For example, while the standard dilution technique, in which the absolute quantification of starting material is determined through calculations of reaction efficiency (determined from serial dilutions of known concentrations of genetic material), provides an estimate of absolute copy count of starting genetic material, comparisons between samples is improved with a standardized amount of genetic material (9). However, relative increases in transcription of select genes from human skeletal muscle fiber segments has recently been measured using relative quantification analyses of real-time PCR amplicons (24, 38). This technique utilizes an endogenous normalizing gene to standardize the number of duplicative cycles necessary to achieve a given level of fluorescence (C_t), and thereby the relative quantity of starting material, between samples.

Endongenous normalizers (HKGs). A commonly used endogenous control gene in skeletal muscle is the glycolytic enzyme GAPDH. However, it has been demonstrated that the expression of GAPDH mRNA may become unstable following exercise paradigms (41, 49), suggesting that its use as a HKG may be inappropriate in studies investigating the transcriptional response to exercise. A similar debate exists over the common use of the skeletal muscle structural protein β-actin as a suitable HKG in skeletal muscle following exercise (24, 41), suggesting that the frequent use of these genes as endogenous internal controls may be inappropriate in studies incorporating skeletal muscle contraction. In the present study, cardiac -actin and HSP60 were employed as novel internal HKGs in skeletal muscle following contractions.

Cardiac -actin and skeletal muscle -actin are thin filament variants of the contractile apparatus that are coexpressed in both heart and skeletal muscle (18, 70), yet are likely differentially regulated (18, 19). Although stable expression of cardiac -actin following exercise has been demonstrated in cardiac muscle (66), the results of the present study are the first to employ cardiac -actin as an endogenous control in single skeletal myocyte gene expression assays. HSP60 is a component of mitochondrial chaperonin, the major site of mitochondrial protein folding for import and increased expression has been demonstrated to preserve mitochondrial function and to diminish apoptosis in cardiac myocytes following ischemia-reperfusion (35). While HSP60 protein has been shown to increase in muscle many hours to days following exhaustive exercise (26, 47), skeletal muscle HSP60 mRNA has been shown to be stable 2 h postexercise (14). In the present study, the relative ratio of HSP60 mRNA to cardiac -actin mRNA in isolated single skeletal muscle fibers remained unchanged at all time points following 15-min tetanic fatiguing contractions (relative to REST fibers, Fig. 3A), demonstrating the potential suitability of either gene as a general internal control for studies investigating the acute transcriptional response of skeletal muscle to contractions.

HSP72 mRNA in response to contractions. Similar to the stable expression of HSP60, the expression of HSP72 mRNA remained stable in all REST fibers, independent of postdissection recovery time, indicating that any possible transcriptional activation induced by stretch (6, 79) or cytoskeletal mechanical stress (3) during the microdissection process was negligible. In contrast, the relative HSP72 mRNA content of EX single fibers significantly increased 2 h following 15 min of fatiguing tetanic contractions when normalized to either HSP60 or cardiac -actin mRNA content (Fig. 3B).

Previous studies have demonstrated increased HSP72 mRNA production in individual cultured myotubes in response to hypoxia (4) and heat shock (40, 65). However, the findings of the present study are the first to demonstrate an elevation of HSP72 mRNA content in individual adult isolated skeletal muscle cells in response to contractions. The findings of the present study are in temporal agreement with Walsh et al. (72) who demonstrated a significant acute elevation of HSP72 mRNA (7.5-fold) only at the 2-h time point following the completion of a single bout of high-intensity exercise in humans. Although the relative linear fold change from rest of HSP72 mRNA (18.5 ± 7.5-fold when normalized to HSP60) in the present study is substantially higher than the acute response previously reported by Walsh et al. (72). Neufer et al.(50a) have reported larger (50-fold) changes in HSP72 mRNA after 24 h following the cessation of exercise. However, the large acute increase in HSP72 mRNA in the present study may be partly a result of large intercell variations in the HSP72 mRNA response, which are amplified in single cell studies. For example, if the relative linear fold change of HSP72 mRNA content from rest of individual fibers in the 2-h group is converted to base 2-log fold change (which minimizes the influence of individual outliers) the result is 2.39 ± 0.8 (normalized to HSP60). When this mean base 2-log fold change value is transformed directly back to linear fold change, the result is a relative linear fold change of 5.2 ± 1.7, a value close to that described by Walsh et al. (72).

Immediate, acute elevations of HSP72 mRNA in response to exercise has also been demonstrated in excised whole muscle (57) and in skeletal muscle biopsied from exercising humans (15, 47, 52, 55, 71) and horses (53). However, debate regarding heat as a mitigating influence in transcriptional activation in these studies has remained (47, 71). The findings of the present study, in which labile heat production was negligible (31), appear to confirm recent findings (48) that factors other than heat exposure, such as alterations in cytosolic [Ca²⁺] (28), decreases in phosphorylation potential (10, 15), or reactive oxygen species production (16), contribute to exercise-induced transcription of HSP72.

Perspectives and Significance

The present study describes the development of a novel technique to isolate and quantify mRNA in isolated single skeletal muscle fibers using HSP60 and cardiac -actin as endogenous normalizing genes, and demonstrated that a single bout of fatiguing contractions is sufficient to elevate HSP72 mRNA, independently of alterations in temperature or signal transduction originating from extracellular sources (e.g., cytokine, catecholamine, hormone, etc.). These findings in isolated amphibian myocytes confirm previous findings in mammalian whole muscle, and establish a stable model of HSP72 induction in single cells.

These findings may be pertinent in the design of future therapeutics for skeletal muscle injury and aging. Increased levels of skeletal muscle HSP72 have been shown to be protective and to improve recovery following damage (42, 45), and decreases in HSP72 may be associated with the age-related decline in skeletal muscle function (42). The single skeletal muscle fiber model of contraction-induced transcription developed in the present study permits greater control, specificity, and fidelity of the intracellular factors that regulate the induction of specific genes in skeletal muscle following exercise. This model is unique in that discreet intra- and extracellular factors including cytoslic calcium, extracellular PO₂, reactive oxygen species, and muscle fiber types can be individually investigated as potential mechanisms of exercise-induced HSP72 induction.

	GRANTS

TOP ABSTRACT RESULTS GRANTS REFERENCES

 
This work was supported by National Institute of Arthritis and Musculoskeletal and Skin Diseases Grant AR-40155 and by the University of California San Diego Medical Scientist Training Program Award, National Institute of General Medical Sciences T32-GM007198.

	FOOTNOTES

 

Address for reprint requests and other correspondence: M. C. Hogan, 9500 Gilman Dr., La Jolla, CA 92093-0623 (e-mail: mchogan{at}ucsd.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

TOP ABSTRACT RESULTS GRANTS REFERENCES

 

1. Ali A, Fernando P, Smith WL, Ovsenek N, Lepock JR, Heikkila JJ. Preferential activation of HSF-binding activity and hsp70 gene expression in Xenopus heart after mild hyperthermia. Cell Stress Chaperones 2: 229–237, 1997.[CrossRef][Web of Science][Medline]
2. Amin J, Ananthan J, Voellmy R. Key features of heat shock regulatory elements. Mol Cell Biol 8: 3761–3769, 1988.[Abstract/Free Full Text]
3. Barash IA, Mathew L, Ryan AF, Chen J, Lieber RL. Rapid muscle-specific gene expression changes after a single bout of eccentric contractions in the mouse. Am J Physiol Cell Physiol 286: C355–C364, 2004.[Abstract/Free Full Text]
4. Benjamin IJ, Kroger B, Williams RS. Activation of the heat shock transcription factor by hypoxia in mammalian cells. Proc Natl Acad Sci USA 87: 6263–6267, 1990.[Abstract/Free Full Text]
5. Bienz M. Developmental control of the heat shock response in Xenopus. Proc Natl Acad Sci USA 81: 3138–3142, 1984.[Abstract/Free Full Text]
6. 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.[Abstract/Free Full Text]
7. Chen HW, Chou FP, Lue SI, Hsu HK, Yang RC. Evidence of multi-step regulation of HSP72 expression in experimental sepsis. Shock 12: 63–68, 1999.[Web of Science][Medline]
8. Christians ES, Yan LJ, Benjamin IJ. Heat shock factor 1 and heat shock proteins: critical partners in protection against acute cell injury. Crit Care Med 30: S43–S50, 2002.[CrossRef][Web of Science][Medline]
9. da Costa N, Blackley R, Alzuherri H, Chang KC. Quantifying the temporospatial expression of postnatal porcine skeletal myosin heavy chain genes. J Histochem Cytochem 50: 353–364, 2002.[Abstract/Free Full Text]
10. Ecochard L, Roussel D, Sempore B, Favier R. Stimulation of HSP72 expression following ATP depletion and short-term exercise training in fast-twitch muscle. Acta Physiol Scand 180: 71–78, 2004.[CrossRef][Web of Science][Medline]
11. Essig DA, Nosek TM. Muscle fatigue and induction of stress protein genes: a dual function of reactive oxygen species? Can J Appl Physiol 22: 409–428, 1997.[Web of Science][Medline]
12. Febbraio MA, Dancey J. Skeletal muscle energy metabolism during prolonged, fatiguing exercise. J Appl Physiol 87: 2341–2347, 1999.[Abstract/Free Full Text]
13. Febbraio MA, Koukoulas I. HSP72 gene expression progressively increases in human skeletal muscle during prolonged, exhaustive exercise. J Appl Physiol 89: 1055–1060, 2000.[Abstract/Free Full Text]
14. Febbraio MA, Mesa JL, Chung J, Steensberg A, Keller C, Nielsen HB, Krustrup P, Ott P, Secher NH, Pedersen BK. Glucose ingestion attenuates the exercise-induced increase in circulating heat shock protein 72 and heat shock protein 60 in humans. Cell Stress Chaperones 9: 390–396, 2004.[CrossRef][Web of Science][Medline]
15. Febbraio MA, Steensberg A, Walsh R, Koukoulas I, van Hall G, Saltin B, Pedersen BK. Reduced glycogen availability is associated with an elevation in HSP72 in contracting human skeletal muscle. J Physiol 538: 911–917, 2002.[Abstract/Free Full Text]
16. Fischer CP, Hiscock NJ, Basu S, Vessby B, Kallner A, Sjoberg LB, Febbraio MA, Pedersen BK. Vitamin E isoform-specific inhibition of the exercise-induced heat shock protein 72 expression in humans. J Appl Physiol 100: 1679–1687, 2006.[Abstract/Free Full Text]
17. Giffard RG, Yenari MA. Many mechanisms for hsp70 protection from cerebral ischemia. J Neurosurg Anesthesiol 16: 53–61, 2004.[CrossRef][Web of Science][Medline]
18. Gunning P, Ponte P, Blau H, Kedes L. -Skeletal and -cardiac actin genes are coexpressed in adult human skeletal muscle and heart. Mol Cell Biol 3: 1985–1995, 1983.[Abstract/Free Full Text]
19. Gunning P, Ponte P, Kedes L, Eddy R, Shows T. Chromosomal location of the co-expressed human skeletal and cardiac actin genes. Proc Natl Acad Sci USA 81: 1813–1817, 1984.[Abstract/Free Full Text]
20. Hernando R, Manso R. Muscle fibre stress in response to exercise: synthesis, accumulation and isoform transitions of 70-kDa heat-shock proteins. Eur J Biochem 243: 460–467, 1997.[Web of Science][Medline]
21. Hogan MC. Fall in intracellular PO₂ at the onset of contractions in Xenopus single skeletal muscle fibers. J Appl Physiol 90: 1871–1876, 2001.[Abstract/Free Full Text]
22. Hogan MC. Phosphorescence quenching method for measurement of intracellular PO₂ in isolated skeletal muscle fibers. J Appl Physiol 86: 720–724, 1999.[Abstract/Free Full Text]
23. Hultman E, Greenhaff PL. Skeletal muscle energy metabolism and fatigue during intense exercise in man. Sci Prog 75: 361–370, 1991.[Medline]
24. Jemiolo B, Trappe S. Single muscle fiber gene expression in human skeletal muscle: validation of internal control with exercise. Biochem Biophys Res Commun 320: 1043–1050, 2004.[CrossRef][Web of Science][Medline]
25. Jornot L, Mirault ME, Junod AF. Differential expression of hsp70 stress proteins in human endothelial cells exposed to heat shock and hydrogen peroxide. Am J Respir Cell Mol Biol 5: 265–275, 1991.[Web of Science][Medline]
26. Khassaf M, Child RB, McArdle A, Brodie DA, Esanu C, Jackson MJ. Time course of responses of human skeletal muscle to oxidative stress induced by nondamaging exercise. J Appl Physiol 90: 1031–1035, 2001.[Abstract/Free Full Text]
27. Khassaf M, McArdle A, Esanu C, Vasilaki A, McArdle F, Griffiths RD, Brodie DA, Jackson MJ. Effect of vitamin C supplements on antioxidant defence and stress proteins in human lymphocytes and skeletal muscle. J Physiol 549: 645–652, 2003.[Abstract/Free Full Text]
28. Kiang JG, Tsokos GC. Heat shock protein 70 kDa: molecular biology, biochemistry, and physiology. Pharmacol Ther 80: 183–201, 1998.[CrossRef][Web of Science][Medline]
29. Klein SL, Strausberg RL, Wagner L, Pontius J, Clifton SW, Richardson P. Genetic and genomic tools for Xenopus research: The NIH Xenopus initiative. Dev Dyn 225: 384–391, 2002.[CrossRef][Web of Science][Medline]
30. Kutyavin IV, Afonina IA, Mills A, Gorn VV, Lukhtanov EA, Belousov ES, Singer MJ, Walburger DK, Lokhov SG, Gall AA, Dempcy R, Reed MW, Meyer RB, Hedgpeth J. 3'-Minor groove binder-DNA probes increase sequence specificity at PCR extension temperatures. Nucleic Acids Res 28: 655–661, 2000.[Abstract/Free Full Text]
31. Lannergren J, Elzinga G, Stienen GJ. Force relaxation, labile heat and parvalbumin content of skeletal muscle fibres of Xenopus laevis. J Physiol 463: 123–140, 1993.[Abstract/Free Full Text]
32. Lannergren J, Smith RS. Types of muscle fibers in toad skeletal muscle. Acta Physiol Scand 68: 263–274, 1968.
33. Latchman DS. Heat shock proteins and cardiac protection. Cardiovasc Res 51: 637–646, 2001.[Abstract/Free Full Text]
34. Lepore DA, Knight KR, Anderson RL, Morrison WA. Role of priming stresses and Hsp70 in protection from ischemia-reperfusion injury in cardiac and skeletal muscle. Cell Stress Chaperones 6: 93–96, 2001.[CrossRef][Web of Science][Medline]
35. Lin KM, Lin B, Lian IY, Mestril R, Scheffler IE, Dillmann WH. Combined and individual mitochondrial HSP60 and HSP10 expression in cardiac myocytes protects mitochondrial function and prevents apoptotic cell deaths induced by simulated ischemia-reoxygenation. Circulation 103: 1787–1792, 2001.[Abstract/Free Full Text]
36. Liu Y, Gampert L, Nething K, Steinacker JM. Response and function of skeletal muscle heat shock protein 70. Front Biosci 11: 2802–2827, 2006.[CrossRef][Web of Science][Medline]
37. Livak KJ, Flood SJ, Marmaro J, Giusti W, Deetz K. Oligonucleotides with fluorescent dyes at opposite ends provide a quenched probe system useful for detecting PCR product and nucleic acid hybridization. PCR Methods Appl 4: 357–362, 1995.[Web of Science][Medline]
38. Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(^–C_t) Method. Methods 25: 402–408, 2001.[CrossRef][Web of Science][Medline]
39. Locke M, Noble EG, Atkinson BG. Exercising mammals synthesize stress proteins. Am J Physiol Cell Physiol 258: C723–C729, 1990.[Abstract/Free Full Text]
40. Maglara AA, Vasilaki A, Jackson MJ, McArdle A. Damage to developing mouse skeletal muscle myotubes in culture: protective effect of heat shock proteins. J Physiol 548: 837–846, 2003.[Abstract/Free Full Text]
41. Mahoney DJ, Carey K, Fu MH, Snow R, Cameron-Smith D, Parise G, Tarnopolsky MA. Real-time RT-PCR analysis of housekeeping genes in human skeletal muscle following acute exercise. Physiol Genomics 18: 226–231, 2004.[Abstract/Free Full Text]
42. McArdle A, Dillmann WH, Mestril R, Faulkner JA, Jackson MJ. Overexpression of HSP70 in mouse skeletal muscle protects against muscle damage and age-related muscle dysfunction. FASEB J 18: 355–357, 2004.[Abstract/Free Full Text]
43. McArdle A, Pattwell D, Vasilaki A, Griffiths RD, Jackson MJ. Contractile activity-induced oxidative stress: cellular origin and adaptive responses. Am J Physiol Cell Physiol 280: C621–C627, 2001.[Abstract/Free Full Text]
44. Milne KJ, Noble EG. Exercise-induced elevation of HSP70 is intensity dependent. J Appl Physiol 93: 561–568, 2002.[Abstract/Free Full Text]
45. Miyabara EH, Martin JL, Griffin TM, Moriscot AS, Mestril R. Overexpression of inducible 70-kDa heat shock protein in mouse attenuates skeletal muscle damage induced by cryolesioning. Am J Physiol Cell Physiol 290: C1128–C1138, 2006.[Abstract/Free Full Text]
46. Morimoto RI. Cells in stress: transcriptional activation of heat shock genes. Science 259: 1409–1410, 1993.[Free Full Text]
47. Morton JP, Maclaren DP, Cable NT, Bongers T, Griffiths RD, Campbell IT, Evans L, Kayani A, McArdle A, Drust B. Time course and differential responses of the major heat shock protein families in human skeletal muscle following acute non-damaging treadmill exercise. J Appl Physiol 101: 176–182, 2006.[Abstract/Free Full Text]
48. Morton JP, Maclaren DP, Cable NT, Campbell IT, Evans L, Bongers T, Griffiths RD, Kayani AC, McArdle A, Drust B. Elevated core and muscle temperature to levels comparable to exercise do not increase heat shock protein content of skeletal muscle of physically active men. Acta Physiol (Oxf) 190: 319–327 2007.[CrossRef][Medline]
49. Murphy RM, Watt KK, Cameron-Smith D, Gibbons CJ, Snow RJ. Effects of creatine supplementation on housekeeping genes in human skeletal muscle using real-time RT-PCR. Physiol Genomics 12: 163–174, 2003.[Abstract/Free Full Text]
50. Nagesser AS, van der Laarse WJ, Elzinga G. Metabolic changes with fatigue in different types of single muscle fibres of Xenopus laevis. J Physiol 448: 511–523, 1992.[Abstract/Free Full Text]
50. Neufer PD, Ordway GA, Hand GA, Shelton JM, Richardson JA, Benjamin IJ, Williams RS. Continuous contractile activity induces fiber type specific expression of HSP70 in skeletal muscle. Am J Physiol Cell Physiol 271: C1828–C1837, 1996.[Abstract/Free Full Text]
51. Ohnishi K, Wang X, Takahashi A, Matsumoto H, Ohnishi T. The protein kinase inhibitor, H-7, suppresses heat induced activation of heat shock transcription factor 1. Mol Cell Biochem 197: 129–135, 1999.[CrossRef][Web of Science][Medline]
52. Paulsen G, Vissing K, Kalhovde JM, Ugelstad I, Bayer ML, Kadi F, Schjerling P, Hallen J, Raastad T. Maximal eccentric exercise induces a rapid accumulation of small heat shock proteins on myofibrils and a delayed HSP70 response in humans. Am J Physiol Regul Integr Comp Physiol 293: R844–R853, 2007.[Abstract/Free Full Text]
53. Poso AR, Eklund-Uusitalo S, Hyyppa S, Pirila E. Induction of heat shock protein 72 mRNA in skeletal muscle by exercise and training. Equine Vet J Suppl 34: 214–218, 2002.[Medline]
54. Powers SK, Locke, Demirel HA. Exercise, heat shock proteins, and myocardial protection from I-R injury. Med Sci Sports Exerc 33: 386–392, 2001.[CrossRef][Web of Science][Medline]
55. Puntschart A, Vogt M, Widmer HR, Hoppeler H, Billeter R. Hsp70 expression in human skeletal muscle after exercise. Acta Physiol Scand 157: 411–417, 1996.[CrossRef][Web of Science][Medline]
56. Richardson RS, Noyszewski EA, Kendrick KF, Leigh JS, Wagner PD. Myoglobin O₂ desaturation during exercise. Evidence of limited O₂ transport. J Clin Invest 96: 1916–1926, 1995.[Web of Science][Medline]
57. Salo DC, Donovan CM, Davies KJ. HSP70 and other possible heat shock or oxidative stress proteins are induced in skeletal muscle, heart, and liver during exercise. Free Radic Biol Med 11: 239–246, 1991.[CrossRef][Web of Science][Medline]
58. Schett G, Steiner CW, Groger M, Winkler S, Graninger W, Smolen J, Xu Q, Steiner G. Activation of Fas inhibits heat-induced activation of HSF1 and up-regulation of hsp70. FASEB J 13: 833–842, 1999.[Abstract/Free Full Text]
59. Sharp FR, Sagar SM. Alterations in gene expression as an index of neuronal injury: heat shock and the immediate early gene response. Neurotoxicology 15: 51–59, 1994.[Web of Science][Medline]
60. Skidmore R, Gutierrez JA, Guerriero V Jr, Kregel KC. HSP70 induction during exercise and heat stress in rats: role of internal temperature. Am J Physiol Regul Integr Comp Physiol 268: R92–R97, 1995.[Abstract/Free Full Text]
61. Snoeckx LH, Cornelussen RN, Van Nieuwenhoven FA, Reneman RS, Van Der Vusse GJ. Heat shock proteins and cardiovascular pathophysiology. Physiol Rev 81: 1461–1497, 2001.[Abstract/Free Full Text]
62. Stary CM, Hogan MC. Intracellular pH during sequential, fatiguing contractile periods in isolated single Xenopus skeletal muscle fibers. J Appl Physiol 99: 308–312 2005.[Abstract/Free Full Text]
63. Stary CM, Hogan MC. Phosphorylating pathways and fatigue development in contracting Xenopus single skeletal muscle fibers. Am J Physiol Regul Integr Comp Physiol 278: R587–R591, 2000.[Abstract/Free Full Text]
64. Stary CM, Mathieu-Costello O, Hogan MC. Resistance to fatigue of individual Xenopus single skeletal muscle fibres is correlated with mitochondrial volume density. Exp Physiol 89: 617–621, 2004.[Abstract/Free Full Text]
65. Suzuki K, Smolenski RT, Jayakumar J, Murtuza B, Brand NJ, Yacoub MH. Heat shock treatment enhances graft cell survival in skeletal myoblast transplantation to the heart. Circulation 102: III216–III221, 2000.[Medline]
66. Tate CA, Helgason T, Hyek MF, McBride RP, Chen M, Richardson MA, Taffet GE. SERCA2a and mitochondrial cytochrome oxidase expression are increased in hearts of exercise-trained old rats. Am J Physiol Heart Circ Physiol 271: H68–H72, 1996.[Abstract/Free Full Text]
67. Thompson HS, Clarkson PM, Scordilis SP. The repeated bout effect and heat shock proteins: intramuscular HSP27 and HSP70 expression following two bouts of eccentric exercise in humans. Acta Physiol Scand 174: 47–56, 2002.[CrossRef][Web of Science][Medline]
68. Thompson HS, Maynard EB, Morales ER, Scordilis SP. Exercise-induced HSP27, HSP70 and MAPK responses in human skeletal muscle. Acta Physiol Scand 178: 61–72, 2003.[CrossRef][Web of Science][Medline]
69. Thompson HS, Scordilis SP, Clarkson PM, Lohrer WA. A single bout of eccentric exercise increases HSP27 and HSC/HSP70 in human skeletal muscle. Acta Physiol Scand 171: 187–193, 2001.[CrossRef][Web of Science][Medline]
70. Vandekerckhove J, de Couet HG, Weber K. Actin, Structure and Function in Muscle and Non-Muscle Cells. Sydney, Australia: Academic, 1983.
71. Vissing K, Andersen JL, Schjerling P. Are exercise-induced genes induced by exercise? FASEB J 19: 94–96, 2005.[Abstract/Free Full Text]
72. Walsh RC, Koukoulas I, Garnham A, Moseley PL, Hargreaves M, Febbraio MA. Exercise increases serum Hsp72 in humans. Cell Stress Chaperones 6: 386–393, 2001.[CrossRef][Web of Science][Medline]
73. Wang Y, Theriault JR, He H, Gong J, Calderwood SK. Expression of a dominant negative heat shock factor-1 construct inhibits aneuploidy in prostate carcinoma cells. J Biol Chem 279: 32651–32659, 2004.[Abstract/Free Full Text]
74. Westerblad H, Allen DG. Cellular mechanisms of skeletal muscle fatigue. Adv Exp Med Biol 538: 563–570; discussion 571, 2003.[Web of Science][Medline]
75. Westerblad H, Allen DG. Recent advances in the understanding of skeletal muscle fatigue. Curr Opin Rheumatol 14: 648–652, 2002.[CrossRef][Web of Science][Medline]
76. Westerblad H, Allen DG, Lee JA. Measurements of intracellular calcium during fatiguing stimulation in single Xenopus muscle fibres. Prog Clin Biol Res 315: 231–232, 1989.[Medline]
77. Westerblad H, Lee JA, Lannergren J, Allen DG, Lamb AG, Bolsover SR. Cellular mechanisms of fatigue in skeletal muscle. Am J Physiol Cell Physiol 261: C195–C209, 1991.[Abstract/Free Full Text]
78. Williams JH, Ward CW, Klug GA. Fatigue-induced alterations in Ca²⁺ and caffeine sensitivities of skinned muscle fibers. J Appl Physiol 75: 586–593, 1993.[Abstract/Free Full Text]
79. Wretman C, Lionikas A, Widegren U, Lannergren J, Westerblad H, Henriksson J. Effects of concentric and eccentric contractions on phosphorylation of MAPK(erk1/2) and MAPK(p38) in isolated rat skeletal muscle. J Physiol 535: 155–164, 2001.[Abstract/Free Full Text]

This Article Abstract Full Text (PDF) All Versions of this Article: 295/2/R642    most recent 00852.2007v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Stary, C. M. Articles by Hogan, M. C. Search for Related Content PubMed PubMed Citation Articles by Stary, C. M. Articles by Hogan, M. C.