Microtubules modulate cardiomyocyte beta -adrenergic response in cardiac hypertrophy

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Microtubules modulate cardiomyocyte $beta$ -adrenergic response in cardiac hypertrophy

Bradley M. Palmer¹, Scott Valent², Emma L. Holder², Howard D. Weinberger², and Roger D. Bies²

¹ Department of Kinesiology and Applied Physiology, University of Colorado at Boulder, Boulder 80309; and ² Cardiology Division, Health Sciences Center, University of Colorado at Denver, Denver, Colorado 80262

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
Appendix
References

The role of microtubules in modulating cardiomyocyte $beta$ -adrenergic response was investigated in rats with cardiac hypertrophy.Male Sprague-Dawley rats underwent stenosis of the abdominal aorta(hypertensive, HT) or sham operation (normotensive, NT). Echocardiographyand isolated left ventricular cardiomyocyte dimensions demonstratedcardiac hypertrophy in the HT rats after 30 wk. Cardiomyocytemicrotubule fraction was assayed by high-speed centrifugationand Western blot. In contrast to previous reports of increasedmicrotubules after acute pressure overload, microtubule fractionfor HT was significantly lower than that for NT. Cardiomyocyteswere exposed to either 1 µM colchicine, 10 µM taxol, or equivalentvolume of vehicle. Colchicine decreased microtubules, and taxolincreased microtubules in both groups. Cardiomyocyte cytosoliccalcium ([Ca²⁺]_c) and shortening/relaxation dynamics were assessed during exposureto increasing isoproterenol concentrations. The $beta$ -adrenergic responsefor these variables in the HT group was blunted compared withNT. However, increased microtubule assembly by taxol partiallyrecovered the normal $beta$ -adrenergic response for time to peak [Ca²⁺]_c, time to peak shortening, and mechanical relaxation variables.Microtubule assembly may play a significant role in determiningcardiomyocyte $beta$ -adrenergic response in chronic cardiachypertrophy.

signal transduction; cytoskeleton; taxol; colchicine; fura 2

	INTRODUCTION

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CHRONIC PRESSURE OVERLOAD leads to cardiac hypertrophy and dysfunction, which is characterized in part by impaired contractility(8, 10, 11, 18), relaxation (8, 10, 11, 18),cytosolic calcium concentration ([Ca²⁺]_c) handling (9, 18, 25, 28), and $beta$ -adrenergic responsiveness(2, 3, 7, 51). In the failing heart, the $beta$ -adrenergicreceptors, stimulatory G proteins, and adenylate cyclase are reducedin number and activity (7, 15, 33). The progression toheart failure due to chronic hypertension is also accompaniedby the decreased number and function of several other cellularregulatory elements such as sarcoplasmic reticulum (SR), SR Ca²⁺-ATPase and its mRNA, mitochondria, myosin isoforms, and cytoskeletalmicrotubules (15, 25, 29, 35, 39).

Increased cardiac microtubule assembly has been described in acute pressure overload and can result in a functional defectdue to increased intracellular mechanical load (21, 26, 45).However, animal models of chronic pressure overload and humanstudies on failing heart muscle have suggested that microtubuledisruption may be a feature of prolonged cardiac stress (5,10, 35, 39, 47). A loss of microtubules may have deleteriouseffects on cellular function in general (1), but more specificto $beta$ -adrenergic responsiveness are studies suggesting that microtubulesmay be important in stabilizing the stimulatory G protein andthereby augmenting $beta$ -adrenergic signal transduction in nonmusclecells (12, 20, 34, 37, 38, 48, 49). Therefore, alteredcytoskeletal microtubule assembly may play a role in modulatingcardiomyocyte $beta$ -adrenergic responsiveness and [Ca²⁺]_c dynamics, in addition to their influence on mechanicalproperties.

This paper describes the influence of microtubule assembly on the $beta$ -adrenergic responsiveness of [Ca²⁺]_c and shortening/relaxation dynamics of cardiomyocytes isolatedfrom abdominal aortic-constricted rats that had cardiac hypertrophy30 wk after surgery. We tested the hypotheses that cardiomyocytemicrotubule assembly and $beta$ -adrenergic responsiveness were reducedin this model and that the defect in $beta$ -adrenergic-mediated systolicand diastolic functions could be reversed with an increase inmicrotubule assembly. The results of these studies demonstratethat microtubule assembly and $beta$ -adrenergic responsiveness of isolatedcardiomyocytes are reduced in this abdominal aortic constrictedrat model and that $beta$ -adrenergic responsiveness of cardiomyocytecontractile function and [Ca²⁺]_c handling could be partially restored with treatment by taxol,a microtubule-enhancingagent.

	METHODS

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Animal preparation. Male Sprague-Dawley rats were housed in a 12-h light/12-h dark cycle, given standard rat chow and waterad libidum, and randomly assigned to two blood pressure (BP) groups:normotensive (NT, n = 10) and hypertensive (HT, n = 13). Animalsin the HT group received a ligature of 0.8-mm diameter aroundthe abdominal aorta between the renal arteries, and the NT animalsunderwent a sham operation. After 30 wk of recovery, animals werekilled for left ventricular (LV) cardiomyocyte isolation. Bodyweights and kidney weights were recorded for all rats at the timethey were killed. Animal care and use were conducted under theguidelines accepted by the American Physiological Society andreceived prior approval from the Institutional Animal Care andUse Committee at the University of Colorado, BoulderCampus.

Echocardiography. Echocardiography was used to noninvasively evaluate LV size and function in the rat. LV dimensions weremeasured for NT and HT rat hearts. In preparation for echocardiography,rats were sedated with tribromoethanol (Avertin 160-220 mg/kgip) and ketamine (45-90 mg/kg ip), each rat's chest was shaved,and the rat was positioned prone on an acoustic gel "standoff"pad with electrocardiogram leads attached to the extremities andtail in a standard fashion. Echocardiography was performed usinga Vingmed CFM800 echocardiography machine (Vingmed, Horton, Norway)with a pediatric 7.5-MHz wide-band annular array transducer operatingat frequencies between 9 and 11 MHz. Two-dimensional and M-modeimages were obtained in the parasternal long- and short-axis orientations.Spectral Doppler flow patterns were obtained across all four intracardiacvalves. Two-dimensional and Doppler images were obtained at 48frames/s with a sampling rate of 200 per second for M-mode andDoppler. The digital data for all images and Doppler were immediatelytransferred and stored on a Macintosh computer connected to theVingmed System. Echocardiographic measurements of chamber sizeand wall thickness in systole and diastole were made off-linefrom the stored data utilizing EchoPac(Vingmed).

LV cardiomyocyte isolation. LV cardiomyocytes were obtained from the LV septal and free wall using methods previously describedin detail (28). All chemicals and reagents were obtained fromSigma (St. Louis, MO) except where noted. In brief, animals wereheparinized (250 U ip) and then anesthetized with pentobarbitalsodium (35 mg/kg ip) (Abbott, North Chicago, IL). Hearts wererapidly excised and placed in ice-cold saline. The aorta was thencannulated, and the heart was retrogradely perfused using a modifiedLangendorff perfusion apparatus that delivered three differentsolutions. The first solution was a bicarbonate-based modifiedKrebs-Henseleit buffer, the second solution was a nominal Ca²⁺-containing solution, and the third solution contained collagenase(Worthington, Freehold, NJ) and hyaluronidase. All solutions weremaintained at pH 7.4 and 37°C and were bubbled with 95% O₂-5%CO₂ gas. The atria and right ventricular free wall were removed,leaving the LV free wall and septum, which were minced and placedin a collagenase and hyaluronidase solution. Cardiomyocyte isolationcontinued with mechanical agitation. Isolated cardiomyocytes weresuspended in bicarbonate-based medium 199, seeded onto laminin-coated2-cm diameter glass coverslips, as well as three laminin-coated4-cm diameter plates, and placed in an incubator at 37°C and 5%CO₂.

One coverslip was placed under a microscope, and images of all individual cardiomyocytes were recorded onto videotape. Thesevideo images were examined for visual length, width, and areausing NIH Image 1.41 video frame-grabbing software. The remainingcoverslips and plates were equally divided into three tubulinsubgroups. Exposure to 1 µM colchicine produced a microtubuledepolymerization subgroup (Col), exposure to 10 µM taxol produceda microtubule hyperpolymerization subgroup (Tax), and an equivalentvolume of vehicle was used to produce a control subgroup (Ctrl).The Col and Ctrl subgroups were allowed to incubate for an additional2 h, and the Tax subgroup incubated for an additional 4 h. Cardiomyocytesseeded onto the large plates were then used for assay of cardiaccardiomyocyte tubulin polymerization by Western blot, and thoseseeded on coverslips were used for experiments designed to characterizethe [Ca²⁺]_c and shortening dynamics of thecardiomyocytes.

Western blot analysis of microtubule fraction. After incubation, medium was removed from the plates, and cardiomyocytes wereharvested by brushing them off plates with a rubber policemanand placing them into 1 ml of microtubule stabilization buffer.Stabilizing buffer (32) contained (in mM) 10 sodium phosphate,0.5 MgCl₂, 0.5 GTP, 0.5 ethylenebis(oxyethylenenitrilo)tetraaceticacid, and 100 U/ml aprotinin (Trasylol), which were added to 50ml of glycerol and 5 ml dimethyl sulfoxide and then brought toa 100-ml volume with water and pH of 6.95. Protease inhibitors(10 µM benzamidine, 1 mM phenylmethylsulfonyl fluoride, 1 mM o-phenanthroline,10 mM aprotinin, 10 mM leupeptin, and 10 mM pepstatin A) wereadded to the stabilization buffer just before homogenization tofurther prevent artificial depolymerization of microtubules (13).Tissue was then homogenized at room temperature, and the homogenatewas centrifuged at 100,000 g for 15 min at 25°C. The supernatantwas removed and was considered to hold the free tubulin fractionof thecardiomyocytes.

The remaining pellet containing microtubules was resuspended in 1 ml of depolymerizing buffer (32) and contained 250 mMsucrose, 0.5 mM GTP, 0.5 mM MgCl₂, 100 U/ml Trasylol, and 10 mMsodium phosphate, pH of 6.95, and homogenized at room temperature.The homogenate was then kept on ice for 1 h to depolymerize microtubulesand then centrifuged at 100,000 g for 15 min at 4°C. The supernatantcontained the fraction of tubulin existing as microtubules. Thefinal pellet was extracted with 10% SDS, 100 mM $beta$ -mercaptoethanol,in Tris buffer and analyzed by Western blot with anti-tubulinantibodies to ensure all the tubulin had been extracted from thetissue pellet. The protein concentration of each fraction wasanalyzed by DC protein assay (Bio-Rad, Hercules, CA) to normalizesampleloading.

Free tubulin and microtubule fractions were analyzed by electrophoretic separation on 10% SDS-PAGE gel and transferred ontonitrocellulose membranes. Membranes were probed with a mouse-tubulinmonoclonal antibody (Amersham, Arlington Heights, IL) and visualizedwith horseradish peroxidase-conjugated anti-mouse secondary antibody(Sigma) using enhanced chemiluminescence (Amersham). Densitometrywas performed to semiquantify protein content in each lane fromthe integrated absorption of each band. The microtubule fractionwas calculated as density of the polymerized lane divided by thesum of densities of the free and polymerized lanes. Figure 1 illustratestypical results of the Western blot analysis of microtubule fractionsfor the two BP groups and for each of the three tubulin subgroups.

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Fig. 1. Cardiomyocyte microtubule content. Western blots demonstrated that microtubule fraction (MT) was reduced and free tubulin fraction (F) increased in hypertensive (HT) group compared with normotensive (NT) group. Agents colchicine (Col) and taxol (Tax), respectively, decreased and increased microtubule assembly in both groups compared with controls (Ctrl).

Experimental protocols. Fura 2-AM (Molecular Probes, Eugene, OR) was introduced into the incubation media bathing the glasscoverslips at a concentration of 2 µM. After an additional 5 minin the incubator, each coverslip was removed from the media andused to form the bottom plate of a custom flow-through chamber.The chamber was placed on the stage of an inverted microscope(Nikon Diaphot) fitted with a ×40 oil immersion objective. Superfusionof a Tyrode solution (in mM: 140 NaCl, 6 KCl, 1 MgCl₂, 2 CaCl₂,10 glucose, 2 pyruvate, and 5 HEPES, pH = 7.4) was maintainedat 29°C. Cardiomyocytes were electrically paced via field stimulationusing platinum electrodes with a stimulus duration of 0.5 ms,a voltage of 1.5 times their threshold of stimulation, and a pacingfrequency of 0.5 Hz (Grass Instruments, Boston,MA).

After a cardiomyocyte was identified for study, pacing was ceased for 2 min to reduce any possible discrepancies due to differentialtimes to identification. Continuous electrical pacing began again,and cardiomyocyte [Ca²⁺]_c and shortening dynamics were recorded at exactly 1 min afterthe exposure to each of the seven successively increasing concentrationsof isoproterenol (Iso): namely, baseline (0 nM), 10 nM, 30 nM,100 nM, 300 nM, 1 µM, and 10 µM Iso, which were prepared in theTyrode solution. Maximal $beta$ -adrenergic response was achieved at300 nM Iso, and higher doses did not result in further increasesin cellfunction.

Figure 2 illustrates representative fluorescence ratio (R) and cardiomyocyte length transients for the two BP groups at baseline(0 nM Iso). Superimposed on these transients are depictions ofthe measures used to characterize the [Ca²⁺]_c and shortening/relaxation dynamics.

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Fig. 2. Representative examples of cytosolic Ca²⁺ concentration ([Ca²⁺]_c) and shortening/relaxation transients at baseline. A: [Ca²⁺]_c transients were fit with a double-exponential function (see APPENDIX) that is superimposed here on the original data. Variables describing double-exponential function are depicted. TTPR, time to peak ratio (R); R_peak, peak R; R_rest, resting R; R_diff, peak minus resting R; k_fall, rate of ratio fall; k_rise, rate of ratio rise. B: shortening transients were analyzed for resting length, maximal shortening, maximal velocities of shortening and relaxation, and time to peak shortening (TTPS). Other characteristics used for comparisons were maximal shortening as a percentage of resting length, maximal shortening rate (MSR = maximal shortening velocity/maximal shortening), maximal relaxation rate (MRR = maximal relaxation velocity/maximal shortening), and times to 25, 50, 75, and 90% recovery.

Measurements of [Ca²⁺]_c dynamics. Fluorescence of fura 2 was induced with a fluorescence system (IonOptix, Milton, MA) fitted with optical filters of wavelength1 = 400 nm and wavelength 2 = 360 nm (the isosbestic wavelength).This choice of filters takes advantage of a linear relationshipbetween [Ca²⁺]_c and R when an excitation wavelength over 390 nm is used (42).Fluorescence intensities were recorded as photon counting ratesusing a personal computer. The value for cardiomyocyte fluorescencebackground was determined for each cell by superfusion of calcium-freeTyrode + 1 µM digitonin for 4 min, which released cytosolic fura2, and the subsequent measure of fluorescence with calcium-freeTyrode as superfusate. Background and compartmentalization offura 2 into organelles or into areas inaccessible to [Ca²⁺]_c were therefore incorporated into the calculation of R betweenwavelength 1 and wavelength 2 (17). The recorded cardiomyocyteR transients were analyzed to determine the following characteristics:resting R (R_rest), peak R (R_peak), peak minus resting R (R_diff),two exponential rate constants (k_rise and k_fall) determined bynonlinear least-squares fitting of a double-exponential functionto the recorded transient, and the time to peak R (TTPR) determinedfrom the exponential rate constants as (ln k_rise $-$ ln k_fall)/(k_rise $-$ k_fall) (see APPENDIX).

Measurement of shortening/relaxation dynamics. The positions of cardiomyocyte edges were determined using a video-edge detectiondevice (Crescent Electronics, Provo, UT) and recorded using ananalog-to-digital converter of the same personal computer thatrecorded fluorescence. The recorded cardiomyocyte shortening transientswere analyzed to determine the following characteristics: maximalshortening as a percentage of resting length, time to peak shortening(TTPS), maximal shortening rate (MSR) defined as maximal shorteningvelocity/maximal shortening, maximal relaxation rate (MRR) definedas maximal relaxation velocity/maximal shortening, and times to25, 50, 75, and 90% recovery (T₂₅, T₅₀, T₇₅, and T₉₀,respectively).

Analysis. All values are reported or depicted as means ± SE. To test for expected morphological and structural differencesbetween the NT and HT groups, unpaired two-tailed t-tests wereperformed on all variables describing animal organ morphology,cardiomyocyte dimension, and microtubule fraction. To test fordifferences in the relative responsiveness of the BP groups toIso, all variables describing the [Ca²⁺]_c and shortening/relaxation transients of the Ctrl subgroupswere subjected to a 2(BP) × 5(Iso) repeated measures ANOVA. Totest for the possible tubulin modulation of responsiveness toIso, all variables describing the [Ca²⁺]_c and shortening transients at 300 nM Iso were subjected to a2(BP) × 3(tubulin) ANOVA. In addition, to determine which, ifany, tubulin subgroup of the HT group may have tended to recovera normal $beta$ -adrenergic response, a Duncan's multiple range testwas performed to make pairwise comparisons between the mean valuesfor the following subgroups: HT + Col, HT + Ctrl, HT + Tax, andNT + Ctrl. Significance of all statistical results was assignedwhen P < 0.05.

	RESULTS

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Animal model. The animal morphology data collectively suggest that stenosis of the abdominal aorta between the renal arteriessuccessfully produced a model of renovascular hypertension, whichresulted in cardiac hypertrophy like that described by others(6, 22). Table 1 presents the results of animal organ morphologiesand cardiomyocyte dimensions. There was no statistically significantdifference for the body mass of the NT and HT groups. Right kidneymass was also not different, but left kidney mass was significantlysmaller in the HT group without any visual signs of necrosis,thereby providing one noncardiac-related indicator of a successfulabdominal aorta stenosis.

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Table 1. Animal morphology, LV and cardiomyocyte dimension, and microtubule fraction

Although LV mass was not measured to demonstrate hypertrophy, there was an ~20% increase in anterior and posterior LV wallthicknesses at diastole in the HT group, and the LV lumen diameterwas smaller in the HT group (Table 1). In addition, isolatedcardiomyocyte width and area were also greater in the HT groupby ~7 and ~11%, respectively, whereas cardiomyocyte length wasnot found to be different between thegroups.

Western blot analysis of microtubule fraction. Western blot analysis of free and microtubule fractions showed that the microtubulefraction was found to be consistently decreased in the HT groupcompared with the NT group (Fig. 1). Chemical treatment with colchicineor taxol caused either a decrease or increase of microtubules,respectively. Table 1 provides the tabular results of the spotdensitometry for the NT and HT groups. The present results ina rat model 30-wk postabdominal aortic constriction suggest thatthe microtubule assembly after chronic left heart pressure overloadin the rat with renovascular hypertension is decreased, whichwould be consistent with findings from others (35, 36, 39).

[Ca²⁺]_c dynamics. In general, [Ca²⁺]_c dynamics of the HT group were subtly different from the NT group. TTPR was significantly higher and R_restlower in the HT + Ctrl subgroup relative to the NT + Ctrl subgroup(Fig. 3). More pertinent to this study, however, was the significantlyimpaired $beta$ -adrenergic responsiveness of the HT group. The significantBP × Iso interaction for R_rest indicates that the HT + Ctrl subgroupdid not appreciably raise resting [Ca²⁺]_c in response to Iso compared with the NT + Ctrl subgroup (Table2). At 300 nM Iso, all [Ca²⁺]_c transient characteristics (except k_rise) of the HT group tendedto be different from those of the NT group, therefore indicatinga decreased response of the HT group to Iso. These later differencesin R_diff, TTPR, and k_fall are consistent with previous reportsof lower peak [Ca²⁺]_c, lower rate of [Ca²⁺]_c rise, and lower rate of SR Ca²⁺ reuptake found with cardiac hypertrophy due to hypertension ingeneral (9, 18, 25, 28) and in response to $beta$ -adrenergicstimulation (3, 51).

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Fig. 3. Response of [Ca²⁺]_c variables to isoproterenol (Iso). A: $beta$ -adrenergic stimulation increased resting [Ca²⁺]_c in NT group more than in HT group. An increase in microtubule assembly in HT + taxol (Tax) subgroup tended to restore normal $beta$ -adrenergic response. B: TTPR increased slightly with $beta$ -adrenergic stimulation in HT group but not in NT group. HT + Tax subgroup showed a response indistinguishable from NT group. C: k_fall increased with $beta$ -adrenergic stimulation but more so in the NT group than in HT group (see Table 2). Microtubule assembly appeared to partially restore k_fall of HT + Tax group at high Iso concentrations. * Significantly different from NT + Ctrl (P < 0.05).

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Table 2. Significance values for main effects and interactions from analyses of variance

Iso differentially affected the tubulin subgroups as indicated by the post hoc pairwise comparisons between the HT tubulinsubgroups and the NT + Ctrl subgroup. We found that the HT + Coland HT + Ctrl subgroups, but not the HT + Tax subgroup, were significantlydifferent from the NT + Ctrl for R_rest and TTPR at high Iso conditions(Fig. 3). Therefore, increased microtubule assembly in the HT+ Tax group partially restored the normal response of R_rest andTTPR at high Isoconditions.

Shortening/relaxation dynamics. In general, cardiomyocyte shortening/relaxation dynamics of the HT group were significantlydifferent compared with the NT group. The variables TTPS, MRR,T₂₅, T₅₀, T₇₅, and T₉₀ indicated impaired function in the HT +Ctrl subgroup, i.e., the HT + Ctrl subgroup reached peak shorteninglater and relaxed later than did the NT + Ctrl subgroup (Table2 and Fig. 4). In addition, the HT + Ctrl subgroup respondedless to the Iso intervention than did the NT + Ctrl subgroup,as indicated by the BP × Iso interaction found for MSR and MRR(Table 2). These last observations confirm that the HT grouppossessed a decreased $beta$ -adrenergic responsiveness. All shortening/relaxationdynamics (except maximal shortening) of the HT group at maximal $beta$ -adrenergic stimulation were impaired relative to the NT group(Table 2 and Fig. 4). The present observations therefore indicatedepressed cardiomyocyte shortening/relaxation dynamics and $beta$ -adrenergicresponsiveness of the HT group consistent with previous reports(3, 8, 10, 18, 21, 26, 45, 50, 51).

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Fig. 4. Response of shortening/relaxation variables to Iso. A: maximal shortening increased with $beta$ -adrenergic stimulation but was not found to have a different $beta$ -adrenergic responsiveness between blood pressure groups. B: TTPS tended to decrease with $beta$ -adrenergic stimulation but more so in NT group than in HT group. Microtubule assembly in HT + Tax subgroup tended to recover $beta$ -adrenergic responsiveness of this variable. C: $beta$ -adrenergic stimulation increased MRR but more so in NT group than in HT group. State of microtubule assembly was found to be directly proportional to $beta$ -adrenergic responsiveness of this variable. * Significantly different from NT + Ctrl (P < 0.05).

The two-way ANOVA at 300 nM Iso revealed a tubulin main effect for the MRR, which provides strong evidence for the suggestionthat increased microtubule assembly improved $beta$ -adrenergic-mediatedrelaxation for both BP groups. Post hoc pairwise comparisons athigh Iso conditions substantiate that microtubule assembly inthe HT + Tax subgroup partially restored the normal response ofshortening/relaxation characteristics to Iso. Specifically, TTPS,MRR, T₂₅, T₅₀, T₇₅, and T₉₀ for the HT + Tax subgroup were notsignificantly different from NT + Ctrl, whereas HT + Col and HT+ Ctrl were significantly different (Fig. 4 and Table 2).

Relationships between [Ca²⁺]_c and shortening/relaxation dynamics. Our main observation, that depressed cardiomyocyte $beta$ -adrenergic responsiveness in the HT group was improved by a taxol-inducedincrease in microtubule assembly, may be best explained throughvisualizing the effects of $beta$ -adrenergic stimulation on the relationshipsbetween [Ca²⁺]_c and shortening/relaxation dynamics, as illustrated in Fig.5. Figure 5A graphically depicts the relationship between systolicvariables for [Ca²⁺]_c and shortening/relaxation, namely TTPR and TTPS, for the NTgroup at baseline and 300 nM Iso conditions. All subgroups ofthe NT groups were found to follow a similar pattern with $beta$ -adrenergicstimulation, i.e., TTPS decreased without a significant changein TTPR. Figure 5B depicts the same relationship for the HT group,which followed a different pattern, i.e., TTPS decreased and TTPRincreased with $beta$ -adrenergic stimulation. However, the HT + Taxsubgroup partially recovered the normal $beta$ -adrenergic responseof no change in TTPR with $beta$ -adrenergic stimulation. Diastolicvariables for [Ca²⁺]_c and shortening/relaxation, namely k_fall and MRR, for the NTgroup are compared in Fig. 5C. Note that the slopes of the relationshipsbetween baseline and 300 nM Iso were similar for all groups andsubgroups. However, the NT group and the HT + Tax subgroup movedfurther along this common relationship in response to Iso comparedwith the HT + Col and HT + Ctrl subgroups.

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Fig. 5. Effect of Iso on relationships between [Ca²⁺]_c and shortening/relaxation characteristics. A: relationships between systolic variables TTPR and TTPS for NT tubulin subgroups respond similarly to Iso. B: relationships between TTPR and TTPS for HT + Col and HT + Ctrl subgroups respond differently to Iso compared with NT, but HT + Tax tended to recover normal Iso response. C: relationships between diastolic variables k_fall and MRR for NT tubulin subgroups respond similarly to Iso. D: relationships between k_fall and MRR for HT + Col and HT + Ctrl subgroups respond to Iso similar to NT, but maximal response is blunted. HT + Tax subgroup partially recovered normal $beta$ -adrenergic response.

	DISCUSSION

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This study demonstrated that microtubule assembly and $beta$ -adrenergic responsiveness of isolated cardiomyocytes were depressedin a rat model of cardiac hypertrophy 30 wk after abdominal aorticconstriction. The unique finding of this study was the partialreversal of the depressed cardiomyocyte $beta$ -adrenergic responsivenessof [Ca²⁺]_c and shortening/relaxation dynamics by a taxol-induced increasein microtubule assembly in thismodel.

The abdominal aortic constriction rat model produced here developed morphological characteristics consistent with cardiachypertrophy due to hypertension. A reduced mass of the left kidney,which was distal to aortic stenosis, serves as an important noncardiacindication of surgical success. Although not tested, this findingsuggests that the renin-angiotensin system probably played a rolein the development of cardiac hypertrophy (6, 22). For thisreason, this model may differ from other models of pressure overloadusing thoracic or pulmonary aortic constrictions (3, 21,26, 45). We found significant increases in anterior and posteriorLV wall thicknesses and a decrease in the LV lumen diameter, whichare consistent with cardiac remodeling that would recover normalwall stress in response to increased afterload (8). Cardiachypertrophy was also reflected in the width and area of the isolatedLV cardiomyocytes, thereby indicating that morphological remodelingwas pervasive to the cellular level (41, 50). These data collectivelyindicate that the hearts of these male Sprague-Dawley rats at30 wk postabdominal aortic constriction were in a state of cardiachypertrophy due to hypertension. This is in contrast to the Fischer344 strain that may reach heart failure by 20 wk of comparablecardiac stress (8, 15).

Cardiomyocyte microtubule fraction was reduced in this 30-wk abdominal aortic-constricted rat model. This result is in starkcontrast to the increase in microtubules observed with an 8-wkpressure overload left ventricle rat model (21) and with a 2-wkmodel of feline right heart pressure overload (45). However,the data are consistent with the possibility that microtubuleassembly after pressure overload may follow a pattern of acuteincrease followed by chronic decrease. This specific pattern ofmicrotubule assembly has been reported in the hypertensive ratmodel by others (35, 36, 39) and is a pattern similar tothat seen for other intracellular proteins and mRNA during theprogression of chronic hypertension to heart failure (15, 25,29). The activation of angiotensin II may have further affectedmicrotubule assembly due to activation of mitogen-activated proteinkinase (27) and the subsequent destabilizing effect of mitogen-activatedprotein kinase phosphorylation on microtubules (16). We thereforeconclude that our finding of decreased cardiomyocyte microtubulefraction in this 30-wk abdominal aortic-constricted rat modelis characteristic of a later stage of cardiac hypertrophy dueto renovascularhypertension.

The resting [Ca²⁺]_c of the NT group increased with Iso (Fig. 3A), thereby indicating that the net rate of calcium influx intoNT cardiomyocytes became greater than the net rate of calciumefflux after $beta$ -adrenergic stimulation. $beta$ -Adrenergic stimulationnormally leads to an increase in calcium current by modulationof the L-type channel, either by cAMP-mediated phosphorylationor by direct action of the stimulatory G protein (4, 44),but it is not known to affect efflux mechanisms, namely the Na⁺/Ca²⁺ exchanger and the sarcolemmal Ca²⁺-ATPase. Therefore, calcium efflux by Na⁺/Ca²⁺ exchanger and sarcolemmal Ca²⁺-ATPase did not match the $beta$ -adrenergic-induced increase in calciumcurrent and constitutes the normal response of cardiomyocytesin our experimental setting. In contrast, the resting [Ca²⁺]_c of the HT group did not increase with Iso as much (Fig. 3A).Because $beta$ -adrenergic stimulation elicits a blunted increase incalcium current of HT cardiomyocytes (40, 51), and calciumefflux mechanisms have been shown to be upregulated in cardiachypertrophy (14, 24, 31), we conclude that calcium effluxby Na⁺/Ca²⁺ exchanger and sarcolemmal Ca²⁺-ATPase was better able to maintain intracellular calcium homeostasisin response to the impaired Iso-induced increases in calcium currentin the HTgroup.

There was a slight recovery of a normal $beta$ -adrenergic response of R_rest in the HT + Tax subgroup at high Iso concentration,therefore suggesting that microtubule assembly partially recoveredthe normal $beta$ -adrenergic responsiveness of the L-type calcium currentin the HT group. Interestingly, the HT + Col subgroup demonstrateda slight recovery of a normal $beta$ -adrenergic response of R_rest atlow Iso concentrations (Fig. 3A). This and similar observationsfor the HT + Col subgroup with TTPR and MRR at low Iso concentrationsraise the possibility that Col and Tax may differentially influencecardiomyocyte function, including $beta$ -adrenergic responsiveness,through means independent of their influence on microtubuleassembly.

Whereas R_rest is indicative of intracellular calcium homeostasis maintained by the sarcolemma, TTPR is more indicative of[Ca²⁺]_c dynamics during a contraction and is principally influencedby the SR. The TTPR of a [Ca²⁺]_c transient represents the relative balance between the ratesof [Ca²⁺]_c influx and removal, i.e., an increase in the TTPR would occurif either rates of [Ca²⁺]_c influx or [Ca²⁺]_c removal were decreased (see APPENDIX). Because TTPR for the NTgroup was not substantially changed by Iso (Figs. 3B and 5A),we conclude that the normal response of calcium regulation toIso is to preserve the time to peak of the [Ca²⁺]_c dynamics. Yet k_fall increased and k_rise tended to decreasewith Iso. Because k_fall and k_rise are analogous to the respectivevelocities of [Ca²⁺]_c movement divided by the total [Ca²⁺]_c transferred, $beta$ -adrenergic stimulation must have increased SRcalcium reuptake velocity relative to SR calcium content and increasedSR calcium content relative to SR calcium release velocity insuch a way as to preserve the time to peak [Ca²⁺]_c in the NTgroup.

TTPR was generally longer in the HT group compared with the NT group (Figs. 3B and 5B), indicating a relative mismatch betweenthe rates of [Ca²⁺]_c influx and removal typical of diastolic dysfunction. L-typecalcium current has not been found to be lower in HT (19, 23,40); however, other factors influencing [Ca²⁺]_c influx during calcium-induced calcium release, such as densityand calcium sensitivity of the SR Ca²⁺ release channels, SR calcium content, and conductance of SR calciumto the cytosol have been implicated as being reduced in the HTstate (41, 46). In addition, the rate of [Ca²⁺]_c removal by the SR has been reported to be reduced in the HTstate (18, 28, 51). Therefore, the relative mismatch inthe rates of [Ca²⁺]_c influx and removal in the HT group, as indicated by the generallylonger TTPR, may be due to multiple impaired calcium regulatorymechanisms. Taxol treatment of the HT group partially recovereda normal TTPR, particularly at high Iso concentrations (Figs.3B and 5B), therefore indicating that either a direct effect ofTax or its influence on microtubule assembly in the HT group enhancedthe $beta$ -adrenergic-mediated changes in calcium regulation, suchas increased calcium current and/or increased rate of [Ca²⁺]_c removal by the SR (Fig. 3C).

The rate of [Ca²⁺]_c removal, k_fall, increased with Iso in both groups as would be expected via cAMP-mediated phosphorylationof phospholamban and its subsequent decreased inhibition of theSR Ca²⁺-ATPase (4). However, the effect of maximal Iso on k_fall ofthe HT group was less than that on the NT group (Table 2), whichis consistent with previous findings of decreased $beta$ -adrenergicresponsiveness in HT cardiomyocytes (51). Iso also induced adecrease in k_rise of the HT group similar to that of the NT group.Therefore, our data support the idea that the principal defectin the $beta$ -adrenergic response in the HT group is a blunted $beta$ -adrenergicincrease in the velocity of SR calciumreuptake.

Cardiomyocyte shortening/relaxation dynamics of the two BP groups were generally differentially affected by $beta$ -adrenergic stimulation.One obvious exception, however, was the variable of maximal shortening,which increased similarly in both groups with $beta$ -adrenergic stimulation(Fig. 4A). Although we would have expected group differences inmaximal shortening (21, 26, 45, 50) and its $beta$ -adrenergicresponsiveness (51), they were not observed in this 30-wk cardiachypertrophy model compared with normal. Nevertheless, $beta$ -adrenergicstimulation did differentially affect the MSR and MRR of the twoBP groups, and all other variables were indeed found to be differentbetween the two groups at maximal $beta$ -adrenergic stimulation (Table2). Therefore, there were many indicators of differential $beta$ -adrenergicresponsiveness of the shortening/relaxationdynamics.

The variable TTPS represents the relative balance between the rates of mechanical shortening and relaxation, i.e., an increasein the TTPS would occur if either of the rates of shortening orrelaxation were decreased. TTPS was significantly decreased inboth groups with $beta$ -adrenergic stimulation (Figs. 4B and 5, A andB), therefore, either or both rates of mechanical shortening andrelaxation must have increased, as would be expected. Microtubuleassembly in the HT group by Tax partially recovered the TTPS athigh Iso concentrations (Figs. 4B and 5B) and, therefore, musthave enhanced the $beta$ -adrenergic-mediated increase in the ratesof mechanical shortening and/orrelaxation.

We observed that MRR was increased with $beta$ -adrenergic stimulation, as observed by others (30), but the response was bluntedin the HT group (Fig. 4C). This measure of mechanical relaxationwas also reflected in other measures of cardiomyocyte relaxation,such as T₂₅, T₅₀, T₇₅, and T₉₀. The tubulin main effect for theMRR at the 300 nM Iso condition suggests that $beta$ -adrenergic responsivenessof MRR was directly proportional to the state of microtubule assembly,i.e., the response was increased by Tax and decreased by Col.This result may be due to one or both of the following possibilities:1) microtubule assembly is directly related to $beta$ -adrenergic responsivenessof this variable in both BP groups, and 2) microtubule assemblydirectly correlates with relaxation function through mechanicalinfluences. However, microtubules have been implicated to reducecontractile and relaxation function by increasing intracellularstiffness and/or viscosity (26, 43, 45). Because $beta$ -adrenergic-mediatedrelaxation improved with increased microtubules in the presentstudy, we conclude that microtubules augmented relaxation by improving $beta$ -adrenergic responsiveness more so than opposed relaxation throughtheir mechanical properties. This microtubule-induced improvementin $beta$ -adrenergic-mediated function was observed for all measuresof relaxation, including T₂₅, T₅₀, T₇₅, and T₉₀, as well as forthe shortening variableTTPS.

We have described above several examples of Tax-induced improvements in $beta$ -adrenergic responses in the HT group that were notclearly accompanied by similar responses in the NT group. Thismay be due to the NT group having an intact $beta$ -adrenergic reserveand microtubule assembly; therefore, any amplification of the $beta$ -adrenergic responsiveness to be gained by Tax treatment mayhave been too small to discern under these experimental conditions.In contrast, Col and Tax treatments of the HT group may independentlyinfluence one or several impaired sites along the $beta$ -adrenergic-signalingpathway: $beta$ -receptor, G protein, adenylate cyclase, cAMP metabolism,protein kinase A, SR Ca²⁺-ATPase, or phospholamban (7, 15, 33). The data of thepresent report suggest that the specific mechanisms most influencedby microtubule assembly remain poorly understood, and that futureinvestigations should focus on identifying those sites at whichmicrotubules contribute to restoring intrinsic cardiomyocyte functionand $beta$ -adrenergicresponsiveness.

In summary and in conclusion, microtubules were reduced in this rat model of chronic cardiac hypertrophy due to renovascularhypertension. The $beta$ -adrenergic responses of cardiomyocyte functionswere generally blunted in this model. More specifically, the $beta$ -adrenergic-stimulatedincrease in resting [Ca²⁺]_c, preservation of time to peak [Ca²⁺]_c, increase in SR calcium reuptake rate, decrease in TTPS subjects,and increase in mechanical relaxation rate were less effectivein this model than in normal subjects. However, increased microtubuleassembly by taxol partially recovered the normal $beta$ -adrenergicresponse for resting [Ca²⁺]_c, time to peak [Ca²⁺]_c, TTPS, and mechanical relaxation rate. Microtubule assemblymay therefore play a significant role in determining the $beta$ -adrenergicresponse of cardiomyocytes in chronic cardiac hypertrophy. Chemicalagents that promote microtubule assembly may be able to partiallyrestore $beta$ -adrenergic responsiveness towardnormal.

	APPENDIX

Top Abstract Introduction Methods Results Discussion Appendix References

The [Ca²⁺]_c transients were represented here by fluorescence R transients. Fluorescence R transients were fit to a double exponentialfunction having the following form

R = Ramp(<IT>e</IT>−<IT>k</IT>fall<IT>t</IT> − <IT>e</IT>−<IT>k</IT>rise<IT>t</IT>) + Rrest (A1)

where R_amp is a theoretical amplitude at time 0, R_rest is resting R, k_fall is rate of ratio fall, k_rise is rate of ratiorise, and t is time. R_peak was calculated from Eq. A1 evaluatedat the time of peak R. TTPR was determined as the time at whichthe time derivative of Eq. A1 equals zero, i.e., dR/dt = 0 when

T T PR = (ln <IT>k</IT>rise − ln <IT>k</IT>fall)/(<IT>k</IT>rise − <IT>k</IT>fall) (A2)

The variable TTPR therefore depends on the relationship between k_rise and k_fall. Because k_rise is analogous to the rate of[Ca²⁺]_c influx, i.e., the velocity of [Ca²⁺]_c influx (in units of nM/s) divided by the total [Ca²⁺]_c transferred (in units of nM), and k_fall is likewise analogousto the rate of [Ca²⁺]_c removal, the changes in TTPR are reflective of changes in calciumregulatory elements that determine [Ca²⁺]_c influx and removal. The change in TTPR due to a change in k_risecan be determined as the derivative to TTPR with respect to k_rise

d T T PR/d<IT>k</IT>rise = (1/<IT>k</IT>rise − T T PR)/(<IT>k</IT>rise − <IT>k</IT>fall) (A3)

Because k_rise > k_fall and TTPR > 1/k_rise, then the value for Eq. A3 is always negative, meaning that an increase in TTPR couldbe due to a decrease in k_rise. The change in TTPR due to a changein k_fall can be determined similarly as

d T T PR/d<IT>k</IT>fall = ( T T PR − 1/<IT>k</IT>fall)/(<IT>k</IT>rise − <IT>k</IT>fall) (A4)

Because k_rise > k_fall and TTPR < 1/k_fall, then the value for Eq. A4 is also always negative, meaning that an increase in TTPRcould be due to a decrease in k_fall. An increase in TTPR may bedue to a decrease in either rate of [Ca²⁺]_c influx orremoval.

	ACKNOWLEDGEMENTS

The authors are grateful for the expert technical assistance of Jinger S. Gottschall, Mark W. Lopez, Joshua M. Lynch, EricA. Mokelke, and M. Charlotte Olsson, and for the valuable commentsof Drs. J. David Port and Russell L. Moore

	FOOTNOTES

This work was supported, in part, by National Heart, Lung, and Blood Institute Grants HL-40306 and HL-44146.

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: B. M. Palmer, CB 354, Dept. of Kinesiology and Applied Physiology, Univ. of Colorado, Boulder, CO 80309.

Received 16 April 1998; accepted in final form 22 July 1998.

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