Differential Effects of 4-Chloro-m-cresol and Caffeine on Skinned Fibers from Rat Fast and Slow Skeletal Muscles

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Vol. 294, Issue 3, 884-893, September 2000

Differential Effects of 4-Chloro-m-cresol and Caffeine on Skinned Fibers from Rat Fast and Slow Skeletal Muscles¹

Stéphanie Choisy, Corinne Huchet-Cadiou and Claude Léoty

Laboratoire de Physiologie Générale, Centre National de la Recherche Scientifique Equipe Postulante 1593, Faculté des Sciences et des Techniques de Nantes, Nantes, France

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Contractile responses to 4-chloro-m-cresol (4-CmC) were tested in saponin- and Triton X-100-skinned fibers from soleus andedl (extensor digitorum longus) muscles of adult rats and comparedwith those to caffeine. The testing of different concentrationsof 4-CmC on saponin-skinned fibers showed that 4-CmC induced adose-dependent caffeine-like transient contractile response inedl and soleus due to an activation of the ryanodine receptor.Both types of skeletal muscles showed a 10 to 20 times lower 4-CmCthreshold concentration and EC₅₀ value (concentration providing50% of the maximal 4-CmC contracture) than for caffeine. The resultsindicate that edl is more sensitive than soleus to 4-CmC and thatthis difference in sensitivity is more marked than with caffeine.Furthermore, an increase in cytosolic Ca²⁺ activity induced a more marked shift of dose-response curvestoward lower concentrations for 4-CmC than caffeine. Experimentsconducted on Triton X-100-skinned fibers showed that in both muscles,4-CmC decreased in a dose-dependent manner the Ca²⁺-activated force of contractile apparatus, particularly in edl.Furthermore, the tension pCa curves indicated that 4-CmC induceda dose-dependent sensitizing (soleus) or desensitizing (edl) effecton the Ca²⁺ sensitivity of myofibrils. These results indicate that edl andsoleus contractile responses can be discriminated with 4-CmC insteadof caffeine and that care must be taken in interpreting resultsbecause muscular pathology could be due in part to an increasein intracellular Ca²⁺.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

Molecular and functional differences between fast-twitch [extensor digitorum longus (edl)] and slow-twitch (soleus) skeletalmuscles have been well documented in recent years in relationto contractile proteins (Danielli-Betto et al., 1990), pumpingmechanisms of the sarcoplasmic reticulum (Brandl et al., 1986),intracellular proteins, or calcium-release mechanisms from thesarcoplasmic reticulum (Jorgensen and Jones, 1986; Damiani andMargreth, 1994; Delbono and Meissner, 1996). In mammalian skeletalmuscle, the main source of Ca²⁺ is the sarcoplasmic reticulum, from which Ca²⁺ is released mainly through the ryanodine receptor RyR1 (Takeshimaet al., 1989; Ogawa, 1994; Franzini-Armstrong and Protasi, 1997).The mechanisms of Ca²⁺ release in fast- and slow-twitch fibers have been analyzed insarcoplasmic reticulum vesicles (Lee et al., 1991) and in intact(Delbono and Meissner, 1996) and skinned (Salviati and Volpe,1988) fibers through the use of different drugs and calcium-releasemodulators of ryanodine receptor (caffeine, Mg²⁺, Ca²⁺, ryanodine, doxorubicin). Although caffeine has been widely usedas a Ca²⁺-releasing agent in intact and skinned fibers (Rousseau et al.,1988; Salviati and Volpe, 1988; Fryer and Neering, 1989; Su andChang, 1995; Pagala and Taylor, 1998), it is known to exert variousside effects, particularly inhibition of phosphodiesterases andincrease in Ca²⁺ sensitivity of cardiac and skeletal contractile proteins (Butcherand Sutherland, 1962; Wendt and Stephenson, 1983).

Chlorocresols, especially 4-chloro-m-cresol (4-CmC), have recently been reported to be strong stimulators of ryanodine receptorsin cerebellum, intact skeletal muscle, and cardiac skinned fibers(Zorzato et al., 1993; Herrmann-Frank et al., 1996a,b; Westerbladet al., 1998; Choisy et al., 1999). In particular, 4-CmC stimulatedCa²⁺-activated [³H]ryanodine binding on heavy sarcoplasmic reticulum vesicles fromrabbit back muscles, producing a half-maximal activation at about100 µM (Herrmann-Frank et al., 1996a,b). Moreover, 4-CmC increasedthe affinity of [³H]ryanodine binding on sarcoplasmic reticulum vesicles from malignanthyperthermia-susceptible muscle compared with normal muscle. Consequently,it has been proposed that 4-CmC could replace caffeine in thetest for muscle susceptibility to malignant hyperthermia (Herrmann-Franket al., 1996a,b). Furthermore, 4-CmC induced a caffeine-like transientcontracture in intact fibers at concentrations 10 times less thanthat with caffeine (Herrmann-Frank et al., 1996a,b). Thus, theresults in the literature indicate that slow- and fast-twitchmuscles have different sensitivities to caffeine (Salviati andVolpe, 1988) and that 4-CmC is a more sensitive tool than caffeine(Herrmann-Frank et al., 1996a,b). In this context, the aim ofthis work was to compare the effect of 4-CmC on edl and soleusmuscles and to investigate whether 4-CmC induces a more specificcontractile response than caffeine. The experiments were conductedon saponin-skinned fibers (in which the sarcoplasmic reticulumand contractile apparatus were functional and the sarcolemma disrupted)of edl and soleus rat muscles. The effect of 4-CmC on the Ca²⁺ content of sarcoplasmic reticulum was estimated by analysis ofcaffeine contracture after the application of different concentrationsof chlorocresol. The cytosolic Ca²⁺ concentration dependence of the 4-CmC response was also investigated.Moreover, the effects of 4-CmC on the contractile apparatus ofedl and soleus Triton X-100-skinned fibers weretested.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

All procedures in this study were performed according to a university committee and to the stipulations of the Helsinki Declarationsfor the care and use of laboratoryanimals.

Adult male rats were heavily anesthetized by an ether vapor flow. After respiratory arrest, the heart was quickly excised,and fast- and slow-twitch skeletal muscles (edl and soleus) wereremoved and placed at room temperature in a physiological solutionthat contained 140 mM NaCl, 6 mM KCl, 3 mM CaCl₂, 5 mM glucose,and 5 mM HEPES. The pH was adjusted to 7.4 with Tris-base. Allexperiments were conducted on chemically skinned preparationsof hindlimbmuscles.

Chemically Skinned Skeletal Fibers. Small bundles (100- to 250-µm diameter and 1.5-2.5 mm in length) of soleus and edl muscles were dissected and placed in arelaxing solution of pCa 9.0 (pCa = $-$ log₁₀[Ca²⁺]), of a composition that is reported in Table 1, for subsequentchemical skinned treatments (saponin or Triton X-100). Saponin50 µg/ml (Endo and Iino, 1980) was prepared in a pCa 9.0 solutionin which the preparations were immersed for 30 min under constantstirring. This treatment disrupts the sarcolemma but does notaffect the ability of the sarcoplasmic reticulum to accumulateand release Ca²⁺. The preservation of the sarcoplasmic reticulum function is indicatedby the capacity of caffeine to induce contractures (Endo and Kitazawa,1978).

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TABLE 1
Composition of solutions used for saponin and Triton X-100 experiments
For saponin experiments, solution 1 contained 25 mM caffeine and solution 5 contained 0.1 to 25 mM caffeine or 2.5 µM to 2 mM 4-CmC.

For Triton-skinned fibers, preparations were placed for 1 h in a relaxing solution (pCa 9.0) containing Triton X-100 1% (v/v)under constant stirring and then transferred into pCa 9.0 notcontaining Triton X-100. This treatment permeabilizes the sarcolemmawithout affecting the biochemical and structural properties ofmyofibrils (Stephenson et al., 1981

), so that measurement of theCa²⁺ sensitivity of contractile proteins and maximal Ca²⁺-activated tension (T_max) can beperformed.

Saponin- or Triton-skinned fibers were transferred and mounted in an experimental system, as described by Huchet and Léoty(1993)

. This system allowed measurements of the tension developedby the preparation immersed in 2.5-ml tubes (Nalge Nunc International,Roskilde, Denmark). The tubes were placed on a rotative platefixed on a disk positioned on a magnetic stirrer (Rotamag 10,Prolabo, Paris, France), which allowed the solutions to be continuouslymixed. The measurement system was composed of two stainless steeltubes fixed to an assembly. One end of the fiber bundle was snaredin a loop of fine hair pulled into a tube glued to a fixed rod.The second end of the preparation was snared in identical mannerto a tube glued to a flexible rod that formed the arm of the transducer[Kaman KD 2300, 0.5 S.U. (unshielded), Colorado Springs, CO].The diameter and length of the skinned muscle fibers were measuredunder a binocular microscope. The muscle fiber was adjusted toslack length and then stretched step by step until tension wasmaximal at pCa 4.5 (T_max), i.e., when the fiber reached 120% ofits resting length (Laszewski-Williams et al., 1989

; Lamb andStephenson, 1990

; Trachez et al., 1990

). All experiments wereconducted at 22°C.

Ca²⁺ Load-Release Cycle in Sarcoplasmic Reticulum of Saponin-Skinned Skeletal Muscle Fibers. A single fiber was successively immersed in five different solutions (Table 1). This protocol makes it possible to load thesarcoplasmic reticulum with Ca²⁺ and then release it by applying caffeine (Su and Hasselbach,1984). EGTA, Mg²⁺, Ca²⁺, and caffeine concentrations varied with the solutions. Solution1 (pCa 9.0), consisting of 10 mM EGTA, 1 mM Mg²⁺, and 25 mM caffeine, was used to deplete the sarcoplasmic reticulumof Ca²⁺. Solution 2 was a caffeine-free washing solution and was similarto solution 1. Solution 3 (pCa 7.0), consisting of 10 mM EGTAand 1 mM Mg²⁺, allowed Ca²⁺ loading of the sarcoplasmic reticulum and was obtained by mixingpCa 9.0 and pCa 4.5, (10 mM EGTA, 1 mM Mg²⁺), in appropriate proportions. Solution 4 (pCa 7.0 or 7.5), consistingof 0.4 mM EGTA and 0.1 mM Mg²⁺, was used to wash out solution 3 and to prepare the fiber forthe next solution. Solution 5 was similar to solution 4 but containeddifferent concentrations of caffeine (0.1-25 mM) or 4-CmC (2.5µM to 2 mM) added to induce transient contracture. At the beginningof the experiments, two or three challenges were performed withcaffeine (10 mM). The experimental protocol consisted of a testcycle of 4-CmC contracture using different 4-CmC concentrations(2.5 µM to 2 mM) added to solution 5 in the place of caffeine.Immediately after the application of 4-CmC, the fiber was immersedin a 10 mM (or 2.5 mM) caffeine solution to estimate the decreaseof sarcoplasmic reticulum Ca²⁺ content. Skinned fibers were incubated for 2 min in all solutionsexcept solution 5, in which fiber was immersed until the end ofcontracture. The experiments were conducted in slow- and fast-twitchskeletal muscles. For caffeine or 4-CmC response, contractureamplitude (mN/mm²), time to peak (s), and time of half-relaxation (s) were measured.Contracture amplitudes were related to the maximal tension developedin the presence of 4-CmC (or caffeine), and the dose-responsecurves were fitted for eachfiber.

The reversibility of 4-CmC effects was tested by performing a subsequent control (10 mM caffeine) every other test cycle.Isometric tension was recorded on chart paper (Linear Bioblock),and baseline tension was established at the steady state measuredin relaxing solution (pCa 9.0).

Triton X-100-Skinned Skeletal Muscles Fibers. Tension-pCa relationships were obtained by exposing Triton-skinned fibers of slow- and fast-twitch skeletal muscles sequentiallyto solutions of decreasing pCa. The intermediate solutions wereobtained by mixing pCa 9.0 and pCa 4.5 (10 mM EGTA, 1 mM Mg²⁺) solutions (Table 1) in appropriate quantities. Solutions containingdifferent concentrations of Ca²⁺ were prepared. For each concentration, one solution served asa control and the other contained 4-CmC (0.01, 0.5, 1, or 2 mM).Isometric tension was recorded, as for saponin-skinned fibers.Baseline tension was established at the steady state measuredin the relaxing solution pCa 9.0.

For each tested fiber, data for relative tension above 10% and below 90% were fitted using a modified Hill equation (Huchetand Léoty, 1993

). Relative tension:

T/T<SUB><UP>max</UP></SUB>=[<UP>Ca</UP><SUP>2+</SUP>]<SUP>n<SUB><UP>H</UP></SUB></SUP>/[K]<SUP>n<SUB><UP>H</UP></SUB></SUP>+[<UP>Ca</UP><SUP>2+</SUP>]<SUP>n<SUB><UP>H</UP></SUB></SUP>

where, tension was expressed in millinewtons per squaremillimeter.

The Hill coefficient, n_H, and the pCa for the half-maximal activation, pCa₅₀ = $-$ log₁₀ (K/n_H), were calculated for each experimentusing linear regression analysis. K corresponds to the calciumconcentration (M) that induced half-maximal activation:

K=10<SUP><UP>−pCa<SUB>50</SUB></UP></SUP>

The Hill coefficient for each type of fiber was calculated as the slope of the fitted straight lines. Baseline tension wasthe same as that for pCa 9.0, and T_max was obtained for pCa 4.5.pCa₅₀ expressed the apparent Ca²⁺ sensitivity of contractile proteins, and n_H indicated the cooperativity(Ashley et al., 1991

Skinned Fiber Solutions. The composition of the solutions (i.e., the Ca²⁺ concentrations used for saponin or Triton X-100 protocols) was calculated usingthe computer program of Godt and Nosek (1986). The compositionof basic solutions (pCa 9.0, 4.5) was reported in Table 1. Foreach solution, ionic strength was adjusted to 160 mM with KCland pH was adjusted to 7.1 with HCl or KOH. In saponin-skinnedfiber experiments, solutions also contained phosphocreatine kinase(17.5 I.U./ml) and sodium azide (1mM).

Chemical products were obtained from Sigma Chemical Co. (St. Louis, MO). 4-CmC was purchased from Fluka (New Ulm, Germany),prepared as a stock solution of 0.25 M in dimethyl sulfoxide (dimethylsulfoxide had a maximal final concentration of 0.8%), and dilutedfor further use to obtain a final concentration of 1 µM to 2mM.

Analysis of Fitted Curves for Saponin-Skinned Fibers. For each experimented fiber, 4-CmC (or caffeine) contracture amplitudes were related to the maximal tension developed in thepresence of 4-CmC (or caffeine), and results were fitted usinga modified Hill equation (Huchet and Léoty, 1993), which gavean EC₅₀ and a Hill coefficient. Mean values calculated for thesetwo parameters were used to plot the dose-response curves on whichmean values of each concentration of 4-CmC (or caffeine) werereported.

For each experimented fiber, the amplitude of the caffeine response obtained after 4-CmC pretreatment was compared with thecontrol response (without 4-CmC pretreatment), and the percentageof decrease of the caffeine response was related to the various4-CmC concentrations tested. As the points fitted a sigmoid curve,the modified Hill equation was used to estimate the IC₅₀ (i.e.,the 4-CmC concentration that induced half-maximal inhibition ofcaffeinecontracture).

Statistical Analysis. All values are expressed as mean ± S.E.M. Student's unpaired t test was used to compare the different parameters between edland soleus. Statistical significance was reached when P < .05.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

4-CmC Effects on Sarcoplasmic Reticulum Ca²⁺-Release Mechanisms and Comparison with Caffeine. Different 4-CmC concentrations (2.5 µM to 2 mM) were added to the Ca²⁺-release solution (pCa 7.5). After an identical loading procedurein saponin-skinned fibers of edl and soleus muscles, the applicationof 4-CmC produced a caffeine-like transient contracture in a dose-dependentmanner (Fig. 1, A and B). In edl fibers, a contracture thresholdwas found at 10 µM 4-CmC, and in soleus fibers, a threshold wasfound at larger concentrations of 25 to 50 µM (Fig. 2A). The maximalamplitude of 4-CmC response (Table 2) was also obtained at lowerconcentrations in edl (0.5 mM) than in soleus (2 mM). The 4-CmC-EC₅₀(i.e., the 4-CmC concentration providing 50% of the maximal 4-CmCcontracture) was significantly lower in edl (70 ± 10 µM, n = 9)than in soleus (180 ± 40 µM, n = 8; P < .05). The results fordifferent concentrations of 4-CmC (0.5, 1 and 2 mM) showed thatthe time to peak (s) of the edl contracture was significantlyshorter than for soleus (Table 3). At 1 mM 4-CmC, the time topeak of edl was 38% shorter than that observed for soleus. Thetime of half-relaxation of 4-CmC contracture was different foredl and soleus. Indeed, an increase in the 4-CmC concentrationinduced a decrease of the time of half-relaxation for soleus butincreased it for edl (Table 3).

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Fig. 1. 4-CmC contractures in soleus (A) and edl (B) saponin-skinned fibers at pCa 7.5. The first trace corresponds to the application of 10 mM caffeine, and the last four traces represent responses obtained for 0.05, 0.1, 0.5, and 1 mM 4-CmC. The "squared" variation in tension occurring before the contracture is due to the change of solutions. Experiments were performed at 22°C.

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Fig. 2. 4-CmC dose-response curves for saponin-skinned fibers at pCa 7.5 (A) and pCa 7.0 (B). Amplitudes of the contractures obtained for soleus (n = 8, A; n = 6, B) and edl (n = 9, A; n = 8, B) are expressed as a percentage of maximal response. Curves were fitted using the modified Hill equation.

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TABLE 2
Amplitude (mN/mm²) of 4-CmC contractures at pCa 7.5 and pCa 7.0 in saponin-skinned fibers of soleus and edl muscles; n represents the number of fibers

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TABLE 3
Time to peak (s) and time of half-relaxation (s) of 4-CmC contractures in soleus and edl saponin-skinned fibers at pCa 7.5; n represents the number of fibers

The effects of caffeine (0.1 to 25 mM) were also tested in saponin-skinned fibers. Slow-twitch fibers exhibited a thresholdcontractile response at a lower caffeine concentration (0.75 mM,n = 5) than fast-twitch fibers (1 mM, n = 6) at pCa 7.5 (Fig.3A). However, as for 4-CmC, the caffeine EC₅₀ found in edl (1.72± 0.17 mM, n = 6) was lower than in soleus (2.18 ± 0.25 mM, n= 5) but not significantly different (P $>=$ .05). Contrary to 4-CmC,no significant differences in contracture kinetics were foundbetween the two types of skeletal muscle at all caffeine concentrationstested.

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Fig. 3. Caffeine dose-response curves for saponin-skinned fibers at pCa 7.5 (A) and pCa 7.0 (B). Amplitudes of the contractures obtained for soleus (n = 5, A; n = 3, B) and edl (n = 6, A; n = 7, B) are expressed as a percentage of maximal response. Curves were fitted using the modified Hill equation.

Both types of skeletal muscle showed a 4-CmC transient contracture, with an EC₅₀ value and a threshold concentration 10 to20 times lower than for caffeine. The amplitude obtained for themaximal response developed in the presence of caffeine or 4-CmCwas similar for edl and soleus muscle. For example, contractureamplitude for edl was 80.8 ± 7.0 mN/mm² (n = 15) in the presence of 0.5 mM 4-CmC (Table 2) and 80.3± 8.4 mN/mm² (n = 6) with 10 mMcaffeine.

These results indicate that edl is more sensitive than soleus to 4-CmC and that this difference in sensitivity is more markedthan with caffeine. The similarity between 4-CmC and caffeinecontractile responses suggested that 4-CmC produces Ca²⁺ release from the sarcoplasmic reticulum by activating the ryanodinereceptor. This possibility was investigated further on the twotypes of skeletalmuscle.

Effect of 4-CmC on Sarcoplasmic Reticulum Ca²⁺ Content. Caffeine contracture is commonly used to study sarcoplasmic reticulum Ca²⁺ content. In an attempt to determine whether 4-CmC affected sarcoplasmicreticulum Ca²⁺ content, caffeine contractures were elicited after applicationof different concentrations of 4-CmC to saponin-skinned slow-and fast-twitch muscles. Experiments conducted at pCa 7.5 consistedin applying different concentrations of 4-CmC (0.01-2 mM) for1 min followed by the application of caffeine. To assess the effectsof 4-CmC, 2.5 mM caffeine was selected as the concentration producingapproximately 50% of maximal contracture and 10 mM as that producingmaximalresponse.

4-CmC induced a dose-dependent decrease of caffeine contracture in edl and soleus fibers. As illustrated in Fig. 4, A andB, the decrease in 10 mM caffeine contracture was greater forlow concentrations of 4-CmC in edl than soleus muscle. The concentrationsof 4-CmC that gave 50% inhibition of 10 and 2.5 mM caffeine contractures(IC₅₀) did not differ significantly (P $>=$ .05) in edl, 100 ± 20µM (n = 10) and 90 ± 20 µM (n = 6), respectively; whereas forsoleus, the 4-CmC concentrations were significantly different(P < .05), 270 ± 10 µM (n = 5) and 160 ± 30 µM (n = 5), respectively.These results showed that like caffeine, 4-CmC induced Ca²⁺ release from the sarcoplasmic reticulum in edl and soleus muscles.

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Fig. 4. Inhibition curves of caffeine contracture for different concentrations of 4-CmC in soleus (A) and edl (B) saponin-skinned fibers at pCa 7.5. Data are the percentages of inhibition of 2.5 (n = 5, A; n = 6, B) and 10 (n = 5, A; n = 10, B) mM caffeine contractures for each concentration of 4-CmC compared with the control. Points were fitted using a sigmoid equation, which yielded the slope of the curve (n) and the IC₅₀. Vertical bars represent ±S.E.M.

Action of 4-CmC and Caffeine on Ryanodine Receptor. It is well known that the sarcoplasmic reticulum Ca²⁺-release channel is inhibited by concentrations of ryanodine $>=$ 10 µM onlyif this receptor is activated (Alderson and Feher, 1987). Caffeineis an activator of the ryanodine receptors. Caffeine (10 mM) wasassociated with ryanodine (100 µM), and after three challenges,the caffeine contracture disappeared (Fig. 5, traces 1 and 2).In these conditions, to see whether 4-CmC was acting as caffeine,we applied 4-CmC (1 mM) with ryanodine (100 µM): after three challenges,4-CmC contracture was totally suppressed (Fig. 5, traces 3 and4). Then, because 4-CmC and caffeine associated with ryanodinehad the same effect, it suggested that 4-CmC was acting on thesame Ca²⁺-release mechanism as caffeine (i.e., the ryanodine receptor).

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Fig. 5. 4-CmC (1 mM) and caffeine contracture (10 mM) after ryanodine treatment (100 µM) in slow-twitch skeletal saponin-skinned fibers at pCa 7.5. Caffeine experiments (1 and 2) were conducted on one fiber, and 4-CmC experiments (3 and 4) were conducted on another fiber. Traces 1 and 3 correspond to the contractures obtained respectively with 10 mM caffeine (1) and 1 mM 4-CmC (3), in control conditions, i.e., before ryanodine treatment. Traces 2 and 4 represent respectively the tension developed in the presence of 10 mM caffeine associated with 100 µM ryanodine and in the presence of 1 mM 4-CmC associated with 100 µM ryanodine, after three running challenges. Tension remaining for trace 2 is due to an effect on contractile apparatus.

Cytosolic Ca²⁺ Modulation of Ca²⁺ Release Induced by 4-CmC. It has been shown that the effectiveness of caffeine in increasing the rate of Ca²⁺ release is dependent on the free Ca²⁺ concentration in the release medium (Rousseau et al., 1988);to further compare the two substances, the effect of an increasein free Ca²⁺ concentration on the Ca²⁺-release rate by caffeine and 4-CmC was tested. In saponin-skinnedfibers, the influence of cytosolic (cis) Ca²⁺ concentrations (31 and 100 nM) on 4-CmC contractile responseswas tested in both types of fibers. 4-CmC (2.5 µM to 2 mM) wasapplied to the Ca²⁺-release solution at pCa 7.0 (100 nM Ca²⁺), and contractile responses were compared with those obtainedat pCa 7.5 (31 nM Ca²⁺). 4-CmC dose-responses curves plotted for pCa 7.0 showed thatthe threshold concentrations in both muscles (2.5-5 µM, n = 8for edl; 10-50 µM, n = 6 for soleus) and the EC₅₀ values wereshifted to lower values than those observed at pCa 7.5 (Fig. 2,A and B). Thus, edl saponin-skinned fibers showed a 7- to 10-foldlower 4-CmC-EC₅₀ when sarcoplasmic reticulum Ca²⁺-release channels were activated by 4-CmC in the presence of 100nM Ca²⁺. For example, in edl, the EC₅₀ values were significantly different(P < .05) at pCa 7.5 and pCa 7.0: 70 ± 10 µM (n = 6) and 10 ±2 µM (n = 8) of 4-CmC, respectively. Moreover, 4-CmC-EC₅₀ foundat pCa 7.0 was significantly different between edl and soleus.An increase in intracellular Ca²⁺ induced a more reduced shift in the 4-CmC dose-response curvesof soleus than edl. The EC₅₀ value was significantly potentiated(P < .05) more than twice as much when cis Ca²⁺ was increased by 69 nM in soleus muscle [i.e., 70 ± 10 µM (n= 6) compared with 180 ± 40 µM, n = 8, at pCa 7.5].

Similar experiments were conducted with caffeine at pCa 7.0 in edl and soleus muscles. As illustrated by the dose-responsecurves plotted for caffeine (Fig. 3, A and B), there was a shiftin the concentration threshold (to 0.1 mM) and in EC₅₀ valuestoward lower values in soleus and edl. The EC₅₀ value was significantlyreduced (P < .05) to 0.72 ± 0.24 mM (n = 7) (i.e., by a ratioof 2.5 in edl) and to 0.41 ± 0.05 mM (n = 3) (i.e., by a ratioof 5.0 in soleus) compared with values obtained at pCa 7.5. Nevertheless,at pCa 7.0, caffeine EC₅₀ was not significantly different betweenedl and soleus. 4-CmC exhibited a greater sensitivity than caffeineto an increase in cytosolic Ca²⁺activity.

Because caffeine exerts side effects on the contractile apparatus, we conducted tests on Triton X-100-skinned fibers to determinewhether similar effects were produced with 4-CmC.

Effects of 4-CmC on Properties of Contractile Proteins. Maximal Ca²⁺-activated tension (T_max) and apparent Ca²⁺ sensitivity of contractile proteins (pCa₅₀) were analyzed in the absenceand presence of different concentrations of 4-CmC (0.01, 0.5,1, or 2 mM) in skeletal Triton X-100-skinned fibers. Tension insoleus and edl muscle fibers was measured in control conditionsand in the presence of 4-CmC (Fig. 6). The relationships betweensteady-state Ca²⁺-activated tension and free Ca²⁺ concentrations in the presence and absence of 1 and 2 mM 4-CmCare illustrated in Fig. 7. In both edl and soleus fibers, thecapacity of contractile proteins to develop force when maximallyactivated by Ca²⁺ (pCa 4.5) was reduced in the presence of increasing concentrationsof 4-CmC (Table 4). The decrease in maximal tension was morepronounced in edl than in soleus (Table 4). With 2 mM 4-CmC,T_max was decreased by 59.4% in edl fibers (n = 9) compared withonly 28.4% in soleus fibers (n = 12). The effect of large concentrationsof 4-CmC (1 and 2 mM) on maximal Ca²⁺-activated tension was not reversible.

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Fig. 6. Effect of 2 mM 4-CmC on Ca²⁺-activated tension and maximal Ca²⁺-activated tension (pCa 4.5) of soleus (A) and edl (B). Tension was induced by soaking fibers in a solution of decreasing pCa not containing (a-g, soleus; a-h, edl) or containing (a'-g', soleus; a'-h', edl) 2 mM 4-CmC. Values for pCa were a = 7, b = 6.5, c = 6.25, d = 6, e = 5.875, f = 4.5, g = 9 in soleus and a = 7, b = 6.5, c = 6.25, d = 6.125, e = 6.0, f = 5.875, g = 4.5, h = 9 in edl.

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Fig. 7. Effects of various concentrations of 4-CmC on myofibrils Ca²⁺ sensitivity of slow- and fast-twitch Triton-skinned fibers from skeletal muscle. Tension-pCa curves were obtained with soleus (A) and edl (B) fibers. Isometric tension-pCa ( $-$ log₁₀[Ca²⁺]) relationships were determined in twitch fibers in the absence (n = 12, A; n = 10, B) or presence of 1 (n = 8, A; n = 10, B) or 2 (n = 12, A; n = 9, B) mM 4-CmC. Force is expressed as the percentage of maximal tension at pCa 4.5 for each concentration of 4-CmC tested. Curves were fitted using the modified Hill equation. Temperature was 22°C.

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TABLE 4
Effect of 4-CmC on maximal Ca²⁺-activated tension (pCa 4.5), pCa₅₀, and the Hill coefficient in Triton X-100-skinned soleus and edl fibers
The mean ± S.E.M. for pCa₅₀ were obtained by fitting the curves to the Hill equation. The mean ± S.E.M. of the Hill coefficient (n_H) were obtained from the Hill plot curves; n represents the number of fibers.

Under control conditions, the values for pCa₅₀ (the Ca²⁺ concentration producing 50% maximal tension) and the Hill coefficient(n_H, representing cooperativity) were significantly differentbetween edl and soleus and similar to those usually found forthese two typical fast- and slow-twitch muscles (Stephenson andWilliams, 1981

). As shown in Table 4, slow-twitch muscle wasmore sensitive to Ca²⁺, and cooperativity was lower than that for fast-twitch fibers.The addition of 4-CmC to the Ca²⁺-buffered solutions (10 mM EGTA) in which isometric tension wasmeasured led to changes in apparent Ca²⁺ sensitivity in both types of skeletal fibers. The n_H coefficientswere changed to a lesser degree in soleus than edl (Table 4).The application of 4-CmC induced a different shift in force-pCarelationships for edl and soleus (Fig. 7). The increase in 4-CmCconcentrations produced a progressive shift of the pCa-tensioncurve for edl to the right, indicative of a significant decreaseof the Ca²⁺ sensitivity of contractile proteins beginning at 0.01 mM 4-CmC.For example, application of 2 mM 4-CmC decreased the pCa₅₀ control(Table 4) by $Delta$ pCa₅₀ = 0.167 (n = 9). Soleus muscle showed a reducedand nonsignificant decrease in Ca²⁺ sensitivity for low concentrations of 4-CmC and a significantshift (P < .05) of control pCa₅₀ to higher pCa for concentrationsof $>=$ 0.5 mM (Table 4). Contrary to edl, a significant increaseof Ca²⁺ sensitivity occurred in soleus at high 4-CmC concentrations (0.5-2mM).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

This study shows that 4-CmC induces caffeine-like transient contractures in a dose-dependent manner in saponin-skinned fibersisolated from fast- and slow-twitch skeletal muscles of the ratand that the muscles show differences in sensitivity (Fig. 1,A and B). Previous studies have reported that 4-CmC is a potentactivator of skeletal (Herrmann-Frank et al., 1996a,b; Westerbladet al., 1998) and cardiac (Choisy et al., 1999) ryanodine receptors.Unlike caffeine, which induces contractures with millimolar concentrations(Salviati and Volpe, 1988; Herrmann-Frank et al., 1996a,b), 4-CmCproved efficient with micromolar concentrations. This result isconsistent with that of Herrmann-Frank et al. (1996b), who founda threshold activity for 75 µM 4-CmC on intact human skeletalfibers isolated from malignant hyperthermia nonsusceptible muscle.Moreover, other authors have shown that 4-CmC was efficient atmicromolar concentrations on PC12 cells (Zorzato et al., 1993),intact mouse skeletal muscle (Westerblad et al., 1998), and frogskeletal fibers (Struk and Melzer, 1999). The difference in sensitivityto 4-CmC and caffeine of skeletal muscles could be explained bythe presence of distinct site or sites of action of these twosubstances on the ryanodine receptor. Indeed, it has been reportedthat caffeine acts preferentially on the cytosolic side of theryanodine receptor, whereas 4-CmC is more potent in activatingthe ryanodine receptor when applied on the luminal side (Herrmann-Franket al., 1996a).

The decrease in caffeine contractures (2.5 and 10 mM) induced by 4-CmC suggests that 4-CmC releases Ca²⁺ from the sarcoplasmic reticulum. Furthermore, caffeine and 4-CmCcontractures were totally abolished when ryanodine (100 µM) wasassociated with each of these substances, which would indicatethat 4-CmC and caffeine activate the same Ca²⁺-release mechanism (i.e., the ryanodinereceptor).

In saponin-skinned fibers, edl showed greater sensitivity (a lower threshold and EC₅₀) than soleus for 4-CmC, which was probablynot due to an inhibitory action on the sarcoplasmic reticulumCa²⁺ pump. Indeed, Zorzato et al. (1993) concluded that at 1 mM, chlorocresoldid not involve inhibition of sarcoplasmic reticulum Ca²⁺ pump on longitudinal sarcoplasmic reticulum vesicles. Moreover,Westerblad et al. (1998) showed that on intact structure, 0.1mM 4-CmC had no inhibitory effect on the Ca²⁺ ATPase of sarcoplasmic reticulum. Under our conditions of experimentsused for saponin-skinned fibers, it is difficult to answer tothisquestion.

Our results also showed that 4-CmC inhibited the caffeine contractures in edl and soleus muscles with a different sensitivity.The difference in 4-CmC sensitivity between fast- and slow-twitchskeletal muscles may also have resulted from the presence of variousisoforms of ryanodine receptor (RyR1 and/or RyR3) in these twotypes of muscle (Conti et al., 1996) and/or the difference inryanodine receptor gating (Shin et al., 1996). Different reportshave shown that Ca²⁺-release kinetic is faster in intact fibers (Delbono and Meissner,1996), in sarcoplasmic reticulum vesicles (Lee et al., 1991),and in skinned fibers (Salviati and Volpe, 1988) of edl than ofsoleus muscle. Our results indicated that the time to peak of4-CmC contractures was shorter for edl than for soleus (Table3).

The increase in cytosolic Ca²⁺ (31-100 nM, i.e., pCa 7.5-7.0) shifted the dose-response curves to lower 4-CmC concentrationsin saponin-skinned fibers. These results are similar to thosereported by Herrmann-Frank et al. (1996a) for sarcoplasmic reticulumvesicles of skeletal muscle, in which a decrease in cytosolicCa²⁺ (900-100 nM) shifted the dose-response curve to higher 4-CmCconcentrations. Moreover, 4-CmC used to detect pathological muscularstructure (malignant hyperthermia), in which the resting myoplasmicCa²⁺ concentration is increased, is described to make the ryanodinereceptor more sensitive to [³H]ryanodine binding (Herrmann-Frank et al., 1996b). In our study,edl exhibited greater sensitivity than soleus to 4-CmC. This effectwas more marked for higher than lower cytosolic Ca²⁺ activity, whereas under similar conditions the caffeine sensitivityof skeletal muscles was less affected. This difference betweencaffeine and 4-CmC could be explained by a 4-CmC binding site,presumably located on the luminal side of the ryanodine receptorand close to the potential high-affinity Ca²⁺ intrareticular binding site as suggested by Herrmann-Frank etal. (1996a).

Thus, 4-CmC appears to be a more useful pharmacological tool than caffeine in discriminating between the contractile responsesof edl and soleus, especially if the side effects on contractileproteins can bereduced.

Triton X-100-skinned fibers were used to determine the effect of 4-CmC on the myofibrillar responsiveness of mammalian skeletalmuscle. These results show that in both edl and soleus muscles,4-CmC decreased maximal-activated tension in a dose-dependentmanner, particularly in edl at concentrations of $>=$ 0.5 mM. It couldbe proposed that 4-CmC affects the biochemical states of crossbridgesduring the working cycle. The tension-pCa curves were shiftedto lower Ca²⁺ concentrations in soleus and to higher concentrations in edl.As pCa-tension curves are assumed to reflect the Ca²⁺-binding properties of troponin C (TnC), the effect of 4-CmC couldbe due to its direct action on contractile proteins, and moreparticularly on TnC. Indeed, striated muscles contain two isoformsderived from a single copy gene: TnC-fast (TnC-f) expressed infast skeletal muscle and TnC-slow (TnC-s) in slow muscle (Wilkinson,1980). A major difference between the two TnC isoforms concernsthe Ca²⁺ binding loops. Our investigations indicate that the Hill coefficientin edl was significantly decreased by the application of 2 mM4-CmC but only slightly modified in soleus fibers. Accordingly,one possible explanation for changes in the Ca²⁺ sensitivity of contractile proteins is that Ca²⁺ binding loops were affected by 4-CmC. Further research is requiredto determine in which way 4-CmC affects myofilaments. Interestingly,the effect of 4-CmC on myofibrillar responsiveness is reminiscentof that of caffeine in skeletal muscles (Wendt and Stephenson,1983).

In conclusion, these results indicating that micromolar 4-CmC concentrations release Ca²⁺ via activation of the sarcoplasmic reticulum ryanodine receptorin mammalian skeletal muscle strongly support the findings ofHerrmann-Frank et al. (1996a,b). The difference in sensitivityto cytosolic Ca²⁺ activity between caffeine and 4-CmC could be of importance tostudies of muscular pathology resulting in part from increasedintracellular Ca²⁺. Moreover, because edl is more sensitive than soleus to 4-CmC,this substance may be a better tool than caffeine in discriminatingbetween edl and soleus contractileresponses.

	Footnotes

Accepted for publication May 26, 2000.

Received for publication January 29, 2000.

¹ We are grateful to the Foundation Langlois and the Center National d'Etudes Spatiales (CNES) for funding this study. Thiswork was performed as part of the Ph.D. requirements of S.Choisy.

Send reprint requests to: Dr. Stéphanie Choisy, Laboratoire de Physiologie Générale, CNRS EP 1593, Faculté des Sciences et des Techniques de Nantes, 2 rue de la Houssinière, BP 92208, 44322 Nantes Cedex 3, France. E-mail: stchoisy{at}yahoo.com

	Abbreviations

edl, extensor digitorum longus; 4-CmC, 4-chloro-m-cresol; RyR, ryanodine receptor.

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