Metabolic and contractile influence of carbonic anhydrase III in skeletal muscle is age dependent

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Metabolic and contractile influence of carbonic anhydrase III in skeletal muscle is age dependent

Claude H. Côté, Fabrisia Ambrosio, and Guylaine Perreault

Lipid Research Unit, Centre Hospitalier de l'Université Laval Research Center, Ste-Foy, Quebec, Canada G1V 4G2

ABSTRACT

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Carbonic anhydrase (CA) III is very abundant in type I skeletal muscle, but its function is still debated. Our aims were toexamine CA III expression during growth and determine whetherthe effects of CA inhibition previously observed in adult musclescould be seen in younger rats in which CA III levels are lower.CA III content and activity were measured in soleus muscles from10- to 100-day-old rats, and the influence of CA inhibitor onfatigue and hexosemonophosphate content was quantified in vitro.CA III activity and content increased fivefold between 10 and100 days of age. Data analysis revealed that the influence ofCA inhibitor on fatigue was to some extent positively and linearlyrelated to the level of CA III activity. Hexosemonophosphate accumulationwith CA inhibition also became more significant with age. In conclusion,CA III level in soleus muscle does not stabilize before 3 mo afterbirth; data also confirm that the effects of CA inhibitors aredue to inhibition of the CA IIIisoform.

fatigue; carbohydrate; metabolism; sulfonamides

	INTRODUCTION

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CARBONIC ANHYDRASE (CA) III (EC 4.2.1.1), the predominant CA isoform in mammalian skeletal muscle, is found primarily inthe cytosol of type I and IIa muscle fibers (10), liver cells(14), and adipocytes (18). Skeletal muscle also contains thesulfonamide-sensitive CA IV isoform associated with sarcoplasmicreticulum (SR) and sarcolemmal membrane (1, 9, 22). However,this CA isoform is clearly distinct from CA III on the basis ofits localization, specific activity, and sensitivity to sulfonamides,a family of specificinhibitors.

Since its discovery, it has been assumed that the physiological function of CA III was to facilitate CO₂ diffusion acrossthe sarcolemmal membrane, and experimental data supporting thisclaim can be found (12). However, a detailed analysis of thedistribution of CA III in the three main types of skeletal musclefibers reveals no clear relationship between the capacity of amuscle to produce CO₂ and its CA III activity. On the other hand,a very significant negative correlation has been reported betweenCA III activity and activity of key glycolytic enzyme markers(10, 11). This observation, among other factors, led us toinvestigate the influence of CA inhibition on type I skeletalmuscle contractility and energymetabolism.

We reported that CA III inhibition in rat soleus (Sol) muscles incubated in vitro led to an increased resistance to fatiguecompared with control muscles during standardized fatigue protocols(6, 11). We went on to demonstrate that, during sustainedcontractile activity, CA III inhibition could increase the rateof glycogen utilization in rat Sol muscles (5); with testingunder resting conditions, we found an increase in hexosemonophosphate(HMP) concentration when CA III was inhibited (8). Globally,these results suggested that CA III can influence the rate ofutilization of carbohydrates in type I muscles and is possiblyan element of the so-called Randle or glucose-free fatty acid(FFA) cycle. During the course of these experiments, it was foundthat the effects of the CA inhibitor methazolamide (Meth) wereoften quite variable and that this lack of consistency seemedto be related to the age of the animals. Riley et al. (19) brieflylooked at the level of expression of CA III in rats during developmentand found that it increased progressively and quite drasticallywith age in the Sol muscle to reach a plateau at ~75-100 days.Therefore, the aims of the present experiments were 1) to providefurther details with regard to the level of CA III expressionin type I muscle during development and 2) to determine whetherthe influence of CA III inhibition on fatigability and HMP accumulation,previously observed with mature adult rats, could be reproducedin younger animals if they possess much lower levels of CA IIIactivity and content. Our working hypothesis is that the influenceof CA III inhibition on fatigue and HMP accumulation should bequantitatively related to the level of expression of CA III inthe muscletested.

	MATERIALS AND METHODS

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Animal care. Sol muscles from 10- to 100-day-old female Wistar rats were used. For most experiments, four age groups were selected: 20-23,30, 45, and 55 days. For some of the noncontractile measurements,10-, 70-, and 100-day-old animals were also used. Sample sizein all cases ranged from five to seven. Rats were anesthetizedwith pentobarbital sodium (50 mg/kg ip), and the Sol muscle wascarefully dissected. The use and care of the animals in thesestudies were approved by and followed the guidelines of the UniversityHospital Research Center Animal Care and Use Committee. Rats weregiven food and water ad libitum. At the end of the experiment,animals were killed with an overdose of theanesthetic.

Measurement of contractile properties and fatigability. Contractile and fatigue data were obtained from all groups of animals except the 10-day-old rats. Contractile properties weremeasured in vitro in Krebs-Ringer bicarbonate buffer maintainedat 25°C and supplemented with curare (20 mg/ml) and glucose (11mM) unless otherwise specified. The pH of the bathing solutionwas stabilized at 7.4 by equilibration with a gas mixture of 95%O₂-5% CO₂. Muscles were placed in a vertical bath and securedat each end with silk sutures. One tendon was attached to a rigidsupport at the bottom of the bath; the other end was connectedto an isometric force transducer (model FT-03C, Grass) througha stainless steel hook. Muscles were stimulated with 25-V squarepulses of 0.2-ms duration delivered through platinum field electrodes.Current was supramaximal. This procedure has been described indetail elsewhere (8, 11).

Muscles were first adjusted to their optimum length, defined as the length at which maximum isometric twitch tension was produced.Muscles were then allowed to equilibrate with the incubation mediumfor 30 min with or without 1 mM Meth. This concentration inhibits100% of the Sol muscle CA III activity. We have data showing thatincubation times of ~10 min are sufficient for Meth to reach equilibriumwithin the muscle cytosol, which also corresponds to the timenecessary for Meth to have an influence on muscle fatigue. Maximumtwitch tension, time to peak twitch tension (TPT), and half relaxationtime (RT_1/2) were first obtained from a twitch contraction.Maximum tetanic tension (P_o) and the maximum rate of tetanic tensiondevelopment were measured, and the muscles were allowed to restfor 10 min before initiation of the fatigue protocol. The fatiguetest consisted of one tetanic contraction at 10 Hz every 5 s for30 min, with each single train of pulses lasting 0.5 s. This frequencyof stimulation produces a partly fused tetanic contraction generating~45% of P_o at the beginning of the fatigue test. This is the sametest used in previous experiments (5-8, 11); it was designedto induce a significant amount of tension loss over a relativelylong period to allow recruitment of the aerobic metabolism and,therefore, an increased CO₂ production. After the fatigue protocol,muscles were removed from the chamber, blotted, and weighed. Themean cross-sectional area of each muscle was estimated by dividingmuscle mass by fiber length and the density of mammalian skeletalmuscle (1.062 g/cc). Under the experimental conditions used forthese experiments, P_o was stable for $>=$ 4h.

Measurement of CA activity. CA activity was measured in the cytosolic fraction by the phenol red technique exactly as described previously (9). Eachindividual reaction contained the muscle extract diluted to afinal volume of 50 µl (in homogenization buffer), 50 µl of reactionbuffer (75 mM Na₂CO₃ and 50 mM NaHCO₃), and 100 µl of the pH indicatorsolution (2.5 mg phenol red/100 ml 5 mM NaHCO₃). The reactionwas initiated by the addition of 200 µl of CO₂-saturated H₂O.To differentiate between the sensitive and resistant CA activities,measurements were performed 1) without Meth, which gives a measureof the total CA activity in the extract, and 2) with 5 µM Meth,a concentration known to inhibit all forms of sensitive CA isoformswithout influencing the resistant CA IIIisoform.

Electrophoresis and immunoblotting. The soluble cytosolic fraction of Sol muscle was prepared by homogenization in 20 vol (wt/vol) of low-ionic-strength buffer(2.5 mM HEPES, 1 mM MgCl₂, 1 mM EDTA, 1 mM dithiothreitol, pH7.4) and centrifugation for 10 min at 10,000 g, as described byLebherz et al. (15). Cytosolic extracts were resolved on 12%polyacrylamide gels and stained with Coomassie blue or transferredto nitrocellulose sheets that were incubated with a rabbit polyclonalantiserum (1:30,000) raised against rat CA III. Details regardingdetection of the antigen-antibody complexes and the antibody preparationand characterization have been reported previously (19).

Measurement of HMPs. In a separate series of experiments, muscles were frozen at time 0 of the fatigue protocol, as per previously published experimentswhere HMP accumulation was observed (8). This means that muscleswere freeze-clamped exactly 10 min after the value for P_o wasobtained. Samples were homogenized at 0°C in 5 vol (wt/vol) of0.6 M perchloric acid and centrifuged at 5,000 g for 10 min. Thesupernatant was recovered and neutralized with 2 M KHCO₃. Measurementsof glucose 6-phosphate (G-6-P) were obtained fluorometrically,as described by Lowry and Passonneau (16).

Data analysis. All results for metabolite concentrations are expressed in nanomoles per gram wet muscle, unless specified otherwise, andare presented as means ± SE. Data for fatigue measurements wereanalyzed by a two-way ANOVA for repeated measures followed byFisher's protected least significant difference test when a significantF ratio was obtained. Data for metabolites and contractile propertieswere analyzed by a regular two-way ANOVA. Curve fitting was performedto evaluate the relationship between CA III activity and its influenceon fatigue and HMP accumulation by using a best-fit approach.Linear and polynomial regressions were used. In all cases thelevel of significance was set at P < 0.05.

	RESULTS

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Table 1 presents data for muscle mass and contractile properties of Sol muscles dissected from rats of four different agegroups. As expected, muscle mass increased with age. Age alsohad a significant effect on contractile properties. Twitch contractilespeed became slower, as shown by increases in TPT and RT_1/2values. Values of TPT for the 23-day-old animals were significantlylower than those for the 45- and 55-day-old animals, whereas valuesfor the 30-day-old animals were statistically different from thosefor the oldest group only. The same general trend could be observedfor RT_1/2 values as stabilization occurred by 45 days. However,this was the only contractile variable for which a significanteffect of Meth could be observed; indeed, a significant increasewas noted at 30 days, whereas only tendencies could be seen withthe two older groups. Absolute twitch and tetanic force productionincreased constantly over the time span covered in our experiment,whereas normalized P_o stabilized at 30 days. All values for forceproduction were not influenced by the presence of Meth in thebathing medium.

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Table 1. Contractile properties of soleus muscles

Values for Sol muscle CA III specific activity are shown in Fig. 1. CA III activity increases almost constantly from birthto adulthood, with values increasing roughly fivefold between10 and 100 days of age. The slope of the increase in CA III activityis very high between 10 and 25 days; the increase is slower between25 and 100 days. A parallel increase in CA III content is alsoclearly visible on the immunoblot shown in Fig. 2. In contrastto CA III, the level of sensitive CA activity, which representsCA isoforms in cytosolic skeletal muscle extract other than CAIII, stabilized quite rapidly after a significant increase between20 and 40 days of age to remain quite constant until $>=$ 100 daysof age (data not shown).

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Fig. 1. Changes in soleus muscle carbonic anhydrase (CA) III specific activity as a function of age. CA III specific activity was measured with cytosolic extracts prepared from soleus muscles dissected from rats of different ages. CA III specific activity was calculated by subtracting value obtained for sensitive CA activity [with 5 µM methazolamide (Meth)] from value for total CA activity (no Meth). Values are means ± SE; n = 5-7 determinations for each point.

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Fig. 2. Changes in CA III content of soleus muscle as a function of age. CA III content was quantified by Western blotting. Soleus muscle cytosolic extracts were electrophoretically separated and transferred on nitrocellulose membranes for immunodetection with a CA III-specific antibody. CA III content increased steadily over time during growth. Bottom: typical blots, with molecular weight markers on left. Values are means ± SE. Optical density values represent mean of 4 different experiments performed in duplicate.

The influence of age alone on Sol muscle resistance to fatigue can be observed in Fig. 3. The stimulation parameters werekept the same for the three groups of muscles tested, even thoughcontractile speed was changing over this age period. Muscles fromthe 23-day-old animals developed significantly higher relativetension than the two other groups starting from 1 min until theend of the protocol. The 30- and 45-day-old animals were moreclosely matched, inasmuch as significant differences could beobserved only between 10 and 25 min. Muscles from 55-day-old animalswere also tested, despite their large size, but are not shownin Fig. 3, whereas muscles from 10-day-old animals were too smallfor manipulation in our set-up. In Fig. 4 the impact of Meth onmuscle fatigue is presented for 23-, 30-, and 45-day-old rats.As previously observed with 45-day-old animals, tension productionwas clearly different between Meth-treated and control muscles,the muscles incubated with Meth showing significantly higher valuesfor tension production than the control muscles between 1 minand the end of the fatigue test. The influence of Meth was verysimilar in muscles from 55- and 45-day-old animals (data not shown).No statistically significant difference could be observed in the23-day-old animals, even though there was an obvious tendencyfor the Meth-treated muscles to perform better than the controlmuscles, especially in the middle of the protocol. At 30 daysof age the Meth-treated muscles showed an increased resistanceto fatigue compared with control muscles very similar to thatdocumented for Sol muscles from 45- to 55-day-old animals, butsome time points did not reach statistical significance.

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Fig. 3. Resistance to fatigue of control (Ctr) soleus muscle from rats at different ages. Fatigue curves were obtained with control soleus muscles from 23- to 45-day-old rats. Muscles were stimulated as described in MATERIALS AND METHODS. Significantly more tension was produced by muscles from 23-day-old animals than by muscles from 2 other groups, except at 1st time point. At 30 days a significantly higher resistance to fatigue between 10 and 30 min was observed in 30- than in 45-day-old animals. Values are means ± SE; n = 5-7 muscles for each group.

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Fig. 4. Influence of CA inhibition on fatigue resistance of soleus muscles from rats of different ages. Soleus muscles were dissected from 23- to 45-day-old rats. For each age group, muscles were submitted to same fatigue test used in Fig. 3 in presence or absence (Ctr) of 1 mM Meth. Only at 45 days was a significant difference between groups found over entire duration of protocol. At 23 days, no significant influence of methazolamide could be observed over 30-min period. Values are means ± SE; n = 5-7 muscles in each group. See RESULTS for statistical comparison.

To better analyze the influence of CA III content and activity on resistance to fatigue, the average difference in tensionproduction between control and Meth-treated muscles over the 30-minduration of the fatigue test (tension-time integral) was calculatedand plotted against the muscle CA III specific activity (Fig.5). The data analysis revealed a significant relationship betweenSol muscle CA III activity and the difference in the integratedvalue for tension production between control and Meth-treatedmuscles. The relationship was especially solid for activity levelsbetween 25 and 35 U/mg, whereas a plateau was observed thereafterwith increasing levels of activity. Not surprisingly, this plateauwould suggest that, in adult animals, a factor(s) other than CAIII activity obviously modulates resistance to fatigue. Overall,the relationship was best described by a second-order polynomialequation that yielded a value for r² of 0.996.

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Fig. 5. Relationship between influence of CA inhibition on soleus muscle resistance to fatigue and CA III activity level in 23-, 30- to 32-, 40- to 42-, 55- to 60-, and 70-day-old animals. Difference in tension-time integral between control and Meth-treated muscles over 30-min fatigue test (expressed as percent initial tension) for each group of muscles was calculated and plotted as a function of their respective specific CA III activity values. Curve is best fit obtained with a 2nd-order polynomial curve. Values are means ± SE; n = 5-7 muscles for each point.

A second documented influence of CA III inhibition by Meth in Sol muscle is its effect on HMP accumulation compared with controlmuscles. Figure 6 shows that the influence of Meth on muscle G-6-Pcontent drastically increases for CA III activity levels between27 and 37 U/mg, with again a plateau thereafter. Meth has no significanteffect on G-6-P content of Sol muscle in <45-day-old rats.

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Fig. 6. Relationship between level of CA III activity and effect of CA inhibition on glucose 6-phosphate concentration ([G-6-P]) in soleus muscle was investigated in a separate series of experiments in 25- to 30-, 40-, 55-, and 70-day-old rats. [G-6-P] is expressed as increase induced by incubation with Meth compared with respective control muscle. Curve is simply an interpolation between points. Values are means ± SE; n = 4-6 muscles for each point.

	DISCUSSION

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Contractile properties. Data obtained for isometric contractile measurements are in good agreement with published values for rat Sol muscles (4).Few studies have examined the influence of age on Sol muscle contractility;however, the general trend from a few weeks after birth to adulthoodis a slowing of isometric and isotonic contractile speed and anincrease in capacity for tension production (3, 15). Althoughthe increased tension production is basically the result of anaugmented cross-sectional area with age, the diminished speedof contraction is mainly associated with the maturation of themyosin heavy chain population of the Sol muscle. As documentedpreviously, the proportion of type I fiber in the Sol muscle seemsto be constantly but slowly increasing with age. At 1 wk afterbirth, rat Sol muscles are composed of 55% type I and 45% typeIIc fibers; at 9 wk, type I fibers account for 66%, IIa for 30%,and IIb for 4% (21). Thereafter, the proportion of type I fiberscontinues to increase to reach values as high as 95% in 24-mo-oldanimals (15). This evolution of the type I fiber populationwith age may be related to the fact that the Sol muscle is involvedin postural functions, where load is a major determinant. Becausetype I fibers are ideally suited for postural work, their increasingpresence with animal growth appearslogical.

In parallel with the decrease in contractile speed, the rate of relaxation also slows significantly with age. This changeis mainly related to qualitative and quantitative modificationsat the level of the SR. The SR Ca²⁺-ATPase activity will indeed determine the rate of Ca²⁺ reuptake and, therefore, the duration of the active state andthe rate of relaxation. We and others have demonstrated previouslythat 1 mM Meth can have a significant effect on twitch relaxationtime (6, 23). This effect was subsequently attributed to thepresence in the SR fraction of the membrane-bound CA IV isoform(22). Unlike CA III, this isoform is present in all types ofmuscle fibers (9). It is postulated that it could be involvedin the exchange of ions within the SR during contraction, inasmuchas its inhibition is known to influence the Ca²⁺ transient (23). Our observation of a prolongation of twitch relaxationtime in the presence of Meth in 30-day-old rats suggests thatCA IV activity in the SR fraction of the Sol muscle does not reacha functional level before that age. However, to the best of ourknowledge, no study of the evolution of CA IV activity over timein the SR fraction of skeletal muscle isavailable.

Influence of age on fatigability. The stimulation parameters used for the fatigue protocol have been selected on the assumption that the level of muscle contractionwould be of moderate intensity, allowing us to conduct a long-durationtest where oxidative metabolism would be recruited and CO₂ wouldbe produced. This is the same test we have used in previous experiments,and it allows a clear distinction between Sol muscles incubatedwith and without CA inhibitor (5, 6, 8). The first strikingobservation with regard to the fatigue tests is that young andsmall Sol muscles tolerate this protocol much better than olderand larger muscles. Several factors can possibly explain the differencein the fatigue curves of control Sol muscles from 23-, 30-, and45-day-old animals. First and most importantly, the stimulationfrequency (10 Hz) was kept constant for all age groups; however,the force-frequency curves for these groups are slightly differentbecause of the difference in speed of contraction, which leadsto a leftward shift of the curve for old muscles compared withyoung muscles. A consequence of such a choice is that the levelof tension the muscles were asked to develop at the onset of thefatigue test was higher in the older and slower muscles, expressedin relative (percent maximum tetanic tension) or absolute values.Muscles from 23-day-old animals were producing 36.5 ± 3.3% ofP_o at 10 Hz, whereas Sol muscles from 30- and 45-day-old ratsreached values of 45.4 ± 2.0 and 47 ± 2.1%, respectively. In otherwords, the workload was lower for the young than for the oldermuscles. Second, the metabolic machinery of the Sol muscle isundergoing significant changes over this period as the animalreaches sexual maturity. Along with changes in fiber types, theoxidative and glycolytic capacities of each fiber type undergochanges over this period, as does capillary density (21). Althoughall these age-related changes will not be specifically discussed,it should be understood that changes at these levels can impactfatigue resistance. Finally, one could also isolate muscle sizeas one factor governing the muscle's capacity to maintain tensionover time, inasmuch as O₂ diffusion in vitro is basically a functionof muscle thickness. Although the evidence is clear that the Solmuscles from 45-day-old animals can maintain their functionalintegrity for up to 4 h in such an in vitro set-up at 25°C, diffusionof O₂, nutrients, and metabolic by-products may be easier andmore efficient in the smaller muscles, allowing them to performbetter.

CA III and its influence on fatigue. CA III activity and content increased with age. The rate of increase was particularly important between 10 and 25 days ofage. After 25 days of age, CA III activity continued to increaselinearly until 100 days, but at a slower rate. These observationsare in good agreement with the data of Riley et al. (19), whoobserved a 3.5-fold increase in the Sol muscle CA III activitybetween 30 and 100 days of age. They also show that the activitylevel measured at 100 days remains constant for the rest of theanimal's life. The faster rate of increase observed in the first4 wk may be related to the drastic changes in fiber type compositionas the proportion of oxidative and CA III-rich fibers (type Iand IIa) increased from 55 to ~93% (21). However, changes infiber types cannot explain the increase in CA III activity after4-6 wk of age. After this period, it could be hypothesized thatthe metabolic machinery is undergoing changes that require a higherlevel of CAIII.

We previously showed and characterized the influence of Meth on Sol muscle fatigue and subsequently proposed that it may belinked to an effect on carbohydrate metabolism (5, 8). Methat a dose sufficient to totally abolish CA III activity leadsto an improved resistance to fatigue when muscles are submittedto the same fatigue test used in the present study. Such an effectwas not seen with 5 µM Meth, a concentration that inhibits onlythe sensitive CA IV isozyme present in the SR and within the sarcolemma.Also, no effect on fatigue was seen with acetazolamide, anotherCA inhibitor with the same affinity for CA III as Meth but witha very low rate of penetration through the cell membrane (6).Collectively, these data strongly indicate that this effect onfatigue is due to inhibition of an intracellular CA isoform witha low affinity for Meth, CA III being the solecandidate.

Although the last observations may appear quite convincing, there remains the unlikely possibility that inhibition of CA IIIis not responsible for the effect on fatigue. Because a specificinhibitor of CA III is still not available, the demonstrationthat the influence of Meth on fatigue and metabolism is, to someextent, proportional and linearly related to the level of CA IIIactivity could be an incisive argument supporting the conclusionpreviously proposed. Indeed, the fact that Meth at a constantdose has a growing influence on fatigue resistance, as CA IIIactivity and content steadily increase, argues strongly againstthis influence being related to nonspecific effects of the CAinhibitor. However, the relationship between the level of CA IIIactivity and fatigue resistance and HMP accumulation is no moreapparent at >35 U/mg, which, not surprisingly, suggests that otherfactors also have an impact. As mentioned previously, the metabolicand contractile machineries are undergoing numerous changes inrats of this age, along with maturation of some morphometric variablessuch as fiber size and capillary density. It is therefore plausiblethat the influence of increasing CA III activity may be counteractedby the global impact of several other determiningparameters.

The fact that no relationship could be identified between the level of sensitive CA activity and the effect on fatigue supportsthe relationship between CA III inhibition and fatigue resistance.Sensitive CA activity in the Sol muscle could possibly resultfrom the presence of the CA IV isoform found in the SR and sarcolemmalfractions. However, because we used cytosolic extracts in ourstudies, we do not expect to see high levels of these CA activities,which should remain in the pellet. Another source of sensitiveCA activity can be red blood cells trapped in muscle capillaries.Red blood cells are very rich in CA I and CA II, two isoformswith very high specific activities. There also remains the possibilitythat a CA II-like activity may also be present in the cytosolof some skeletal muscle fibers, even though the evidence againstsuch a conclusion appears quite strong (10, 13). In any case,in our protocols the level of sensitive CA activity was constantfrom 40 to 70 days, which clearly suggests that regardless ofthe nature of this activity, it is not closely related to theobserved effect ofMeth.

G-6-P accumulation. As we and others have shown previously, CA inhibitor can also influence muscle, even under resting conditions (8). Indeed,the presence of 1 mM Meth (0.1 mM ethoxzolamide has the same effect)during the 45-min equilibration period preceding the fatigue protocolleads to an accumulation of HMPs, i.e., G-6-P and fructose 6-phosphate,along with a slight drop in intracellular pH. Although a mechanisticexplanation exists for the effect on pH, explanations for theeffect on G-6-P have been proposed only recently (8) but arestill speculative at this point and will not be the focus of thisdiscussion. As was the case for the effect of Meth on fatigue,the extent of G-6-P accumulation induced by Meth compared withage-matched control muscles is partially dictated by the levelof CA III activity. This again suggests that this effect on carbohydratemetabolism is likely related to the inhibition of CA III activity.However, the relationship is not as linear and extended as theone for fatigue, which may suggest that other metabolic characteristicsof skeletal muscle, also changing during development, could alsobe relevant to this effect. Interestingly, basal and insulin-stimulatedglucose uptake undergo marked changes in the rat Sol muscle between21 and 35 days of age (2), and this effect is not due to variationsin the concentration of the GLUT-4 glucose transporter. One questionthat arises is whether the increased resistance to fatigue withCA inhibitor is partially or totally related to the buildup ofHMPs in these muscles at the onset of the fatigue test. Indeed,such an important pool of glycolytic substrates could facilitateand possibly accelerate the use of glycolysis as an ATP synthesispathway, especially in the first minutes of the test. Testingof muscles incubated with Meth for shorter periods of time beforethe fatigue test should enable us to answer that question, sinceHMP accumulation should be decreased, inasmuch as the time ofcontact with CA inhibitor isshorter.

In summary, the content and level of activity of CA III in the type I Sol muscle are constantly increasing during developmentin the rat until stabilization occurs at ~100 days of age. Thepreviously documented influence of CA inhibitors on fatigue resistanceand HMP accumulation was very tightly correlated with the levelof CA III activity, further supporting the conclusion that thesetwo effects are indeed the direct result of CA IIIinhibition.

Perspectives

General-purpose CA inhibitors, such as Meth, have been used to study CA III function, and it is not always perfectly clearthat the observed effects are the consequence of CA inhibitiononly. By confirming that the effects of Meth are quite specific,the present experiments further support the hypothesis that anactive CA III in a type I muscle can modulate carbohydrate metabolismand could therefore be linked to the still debated glucose-FFAcycle. Glycogen sparing is very highly efficient in type I fibers,where the highest CA III activities are found. Whether CA IIIhas a direct effect on carbohydrate utilization or an indirectaction linked to the preferential use of FFA as oxidative substrateremains to be investigated. CA III is unique among CA isoforms,in that it can also act as a protein phosphatase, which couldinteract with numerous enzymatic cascades of lipid and carbohydratemetabolism. Type I fibers preferentially use triglycerides, andbecause the hormone-sensitive lipase is sensitive to pH fluctuationsand activated through a cascade of phosphatase reactions, CA IIIcould potentially modulate FFA metabolism. CA III is found invery high concentrations, specifically in the three tissues controllingenergy metabolism, i.e., fat cells, skeletal muscle, and liver,suggesting that it could possibly be a metabolic modulator. Specificinhibitors and/or mutant animals for CA III would greatly helpin investigating thesepossibilities.

	ACKNOWLEDGEMENTS

F. Ambrosio was the recipient of a scholarship from la Faculté des Etudes Supérieures de l'Université Laval. Methazolamidewas generously provided by CyanamidCanada.

	FOOTNOTES

This work was supported by grants from the Natural Sciences and Engineering Research Council ofCanada.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests: C. H. Côté, Laval University Hospital Center, Research Center, Rm. 9500, 2705 Blvd. Laurier, Ste-Foy, QC, Canada, G1V 4G2.

Received 3 June 1998; accepted in final form 13 October 1998.

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