Phospholamban deficiency does not compromise exercise capacity

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Phospholamban deficiency does not compromise exercise capacity

Kavin H. Desai¹, Eric Schauble¹, Wusheng Luo², Evangelia Kranias², and Daniel Bernstein¹

¹ Department of Pediatrics, Stanford University, Stanford, California 94305; and ² Department of Pharmacology and Cell Biophysics, University of Cincinnati, Cincinnati, Ohio 45267-0575

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Deficiency of phospholamban (PLB) results in enhancement of basal murine cardiac function and an attenuated response to $beta$ -adrenergicstimulation. To determine whether the absence of PLB also reducesthe reserve capacity of the murine cardiovascular system to respondto stress, we evaluated the heart rate (HR), blood pressure, andmetabolic responses of PLB-deficient (PLB $-$ / $-$ ) mice to graded treadmillexercise (GTE). PLB $-$ / $-$ mice were hypertensive at rest (125 ± 19vs. 109 ± 16 mmHg, P < 0.05) but had normal tachycardic and hypotensiveresponses to isoproterenol. The HR response to GTE was normal;however, the hypertension in PLB $-$ / $-$ mice normalized at peak exercise.Their exercise capacities, as measured by duration of exerciseand peak oxygen consumption ( $V$ O₂), were normal. The oxygen pulse( $V$ O₂/HR) curve was also normal in PLB $-$ / $-$ mice, suggesting anability to appropriately increase stroke volume and oxygen extractionduring GTE, despite an inability to increase $beta$ -adrenergicallystimulated cardiac contractility. Thus deficiency of PLB, althoughresulting in diminished $beta$ -adrenergic inotropic reserve, does notcompromise cardiac performance duringexercise.

treadmill; oxygen pulse; oxygen consumption; contractility; adrenergic

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

THE APPLICATION OF technology previously used in larger mammals has allowed a growing inventory of tools to become availablefor the phenotypic assessment of murine models of cardiovasculardisease. The ability presently exists to evaluate murine myocytecontractility (23), ex vivo whole heart work performance (3),and in vivo ventricular function using two-dimensional and Dopplerechocardiography (4, 21), angiocardiography (14), and,more recently, calcium transients in beating mouse hearts (5).Although these methods are useful for evaluating the heart underresting conditions, cardiovascular stress assessment is limitedto pharmacological manipulations with these systems, which maynot fully reproduce the maximal stress achieved with exercisein the intact, awake animal. In larger mammals with cardiac disease,the gold standard for functional assessment of the intact cardiovascularsystem is graded treadmill exercise (GTE) (6, 24). Recently,we have demonstrated the ability to perform cardiovascular andmetabolic evaluations in awake, unrestrained mice during the physiologicalstress of GTE (2). In the present study, we used these techniquesto evaluate cardiovascular performance in a genetically alteredmodel, the phospholamban (PLB)-deficient mouse, with previouslydemonstrated elevation of basal cardiac function and attenuatedinotropic and lusitropic responses to $beta$ -adrenergicstimulation.

PLB regulates calcium reuptake into the cardiac sarcoplasmic reticulum and has been implicated in the contractile responseto $beta$ -adrenergic receptor ( $beta$ -AR) stimulation (9). Protein kinases,activated by $beta$ -AR stimulation, phosphorylate PLB, removing tonicinhibition of the sarcoplasmic reticulum calcium ATPase, enhancingcalcium reuptake into the sarcoplasmic reticulum, and resultingin enhanced myocardial contractility and relaxation. Studies usingwhole hearts (8, 12) or isolated myocytes (23) have shownthat targeted disruption of the PLB gene (PLB $-$ / $-$ ) enhances cardiaccontractility and relaxation and attenuates the stimulatory effectsof $beta$ -AR agonists compared with wild types (PLB+/+). Similar findingswere observed in vivo when ventricular function was assessed usingechocardiography under anesthesia (7). These experimental systemssuggest not only enhanced resting cardiovascular function butalso an inability to improve cardiac performance during stress.Extrapolation of these findings to the awake animal, however,may be difficult due to the influence of anesthetic agents andto the inability to accurately simulate cardiovascular stressin such systems. To evaluate the effects of disrupting the PLBgene in the awake, active state, we first studied cardiovascularparameters in nonanesthetized, nonrestrained mice at rest andin response to $beta$ -AR agonist stimulation. To determine whetherloss of PLB results in decreased exercise performance due to lossof adrenergically mediated cardiac reserve, we evaluated cardiovascularperformance in PLB-deficient mice duringGTE.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animal subjects. PLB-deficient mice were derived from 129sv/J and CF-1 background strains using homologous recombination in murine embryonicstem cells. Disruption of the PLB gene was produced by replacinga 1.8-kb region of exon 2, which includes the entire protein codingsequence, with a neomycin resistance gene cassette. The deletionof PLB in these mice has been previously demonstrated by lossof the gene using Southern analysis and loss of the protein usingWestern analysis (12). Thirteen adult PLB $-$ / $-$ mice and elevenPLB+/+ age-matched littermates between the ages of 10 and 12 wkwere used for this study. There were no significant differencesin sex distribution or weight between the groups (Table 1). Allmice were kept in standard rodent cages with food and water adlibitum in a 12:12-h light-dark cycle.

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Table 1. Cardiovascular and metabolic parameters at baseline and peak exercise

Vessel cannulation. Mice were anesthetized with 1.5% inhaled isoflurane. Induction was performed in a closed chamber and was maintained via anose cone throughout surgery. Carotid arterial cannulation withpolyethylene (PE-10) tubing was performed as previously described(2). Intravenous ampicillin (100 mg/kg) was administered immediatelyafter skin closure, and recovery was allowed for 24 h. All experimentalprotocols were approved by the Administrative Panel on LaboratoryAnimal Care at Stanford University and are in conformity withthe "Guiding Principles for Research Involving Animals and HumanBeings."

Data acquisition. After the arterial catheter was removed from a subcutaneous pocket, the catheter was connected to a Spectramed DTX Plus pressuretransducer (Oxnard, CA) and analog inputs were amplified usinga Gould preamplifier (model 11-1202-25; Cleveland, OH) and amplifier(model 13-4615-52). Analog signals were digitized using a DataTranslation Series analog-to-digital converter (DT2801; Marlboro,MA) and were analyzed and stored using Dataflow data-acquisitionsoftware (Crystal Biotech, Hopkinton, MA). Because of the low-frequencyresponse demonstrated previously with this fluid-filled cathetersystem (2), we elected to utilize only mean, rather than phasic,blood pressure (BP) recordings, although all pressure tracingsclearly demonstrated a phasicwaveform.

For simultaneous metabolic measurements, mice were placed into a Simplex II metabolic rodent treadmill chamber (Columbus Instruments,Columbus, OH), which allows measurement of oxygen consumption( $V$ O₂) and carbon dioxide production ( $V$ CO₂) using an open-circuitvolumetric method of gas analysis (2). Respiratory equivalentratio (RER) was calculated as $V$ CO₂/ $V$ O₂.

Response to exercise. After acclimation for 1 h and after stable baseline HR, BP, $V$ O₂, and $V$ CO₂ measurements were recorded, 2.5 m/min incrementalincreases in treadmill belt speed and 2° increments in angle ofinclination were made every 3 min until the mouse exhibited signsof exhaustion. Exhaustion was defined as the mouse spending >50%of the time or >15 consecutive seconds on the shock grid. Exercisecapacity was defined as time to exhaustion during GTE. To assessexercise differences between the genotypes, mean values for eachparameter were calculated at baseline, at each exercise workload,and at peak exercise. The percent changes between resting andpeak exercise values were also calculated. To indirectly assessventricular stroke volumes during exercise, we calculated meanoxygen pulse values ( $V$ O₂/HR) at each workload and performed linearregression analysis of oxygen pulse versusworkload.

Response to $beta$ -adrenergic agonists. After stable baseline HR and BP measurements were recorded, 1 µg/kg intra-arterial boluses of isoproterenol were administeredin volumes of 0.03 ml of normal saline. This dose has been previouslyshown to produce maximal HR and BP responses in mice (2). Continuousrecordings were performed for 30 min after the bolus or untilbaseline values werereestablished.

Statistical analyses. Resting and maximal exercise parameters were compared between the two genotypes by using Student's t-test. The percent changein a given parameter from rest to maximal exercise was also comparedbetween genotypes by using a Student's t-test. Values of a parameterduring GTE were compared between genotypes by using both Student'st-test at each workload and a two-way ANOVA for repeated measuresfor the entire GTE protocol. To determine whether significantchanges occurred during exercise for a specified parameter, valuesfor that parameter at each workload were compared with the restingvalue by using a one-way ANOVA with a post hoc Dunnett's test.To compare the oxygen pulse curves during exercise, average slopesand intercepts derived from the linear regression analyses werecompared between genotypes using a Student's t-test. Data from $beta$ -AR agonist studies were analyzed to establish maximal HR elevationand maximal decrease in BP. Percent changes from resting valueswere compared between groups using Student's t-test. All valuesare reported as means ± SD. Statistical significance was definedas a P value < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Surgical results. Overall survival through surgery and the 24-h recovery period was 92%. There was a 100% catheter patency rate among survivinganimals after recovery, leaving 9 PLB+/+ mice and 13 PLB $-$ / $-$ micefor resting studies. Two knockout animals had late catheter failuresand were unable to be evaluated during GTE, leaving 9 PLB+/+ miceand 11 PLB $-$ / $-$ mice for the exercise and $beta$ -AR agonist studies.The overall success rate for completion of the study was 83%.

Resting parameters. Resting, nonanesthetized, nonrestrained cardiovascular and metabolic parameters for both groups are shown in Table 1. PLB $-$ / $-$ mice were hypertensive compared with wild-type littermates (125± 19 vs. 109 ± 16 mmHg, P < 0.05). No differences were found inresting HR, $V$ O₂, $V$ CO_2, or RER between thegroups.

Graded treadmill exercise. At maximal exercise, values for all parameters were nearly identical between PLB-deficient and wild-type mice (Table 1).Exercise capacity was also similar between the two groups, asmeasured by $V$ O₂ at peak exercise and the duration of exerciseprotocol performed (Fig. 1). With the exception of BP, both groupsexhibited typical murine cardiovascular and metabolic responsesto incremental treadmill exercise (2), demonstrating linearincreases in HR, $V$ O₂, $V$ CO₂, and RER with increasing workload(Fig. 1). PLB+/+ mice maintained a steady mean BP during exercise,whereas PLB $-$ / $-$ mice were hypertensive at the onset of exercise,with a subsequent fall in mean BP at maximal exercise (P < 0.05by Dunnett's test between resting value and value at 27.5 m/min).Thus PLB $-$ / $-$ mice had a significantly different percent changein mean BP with exercise between genotypes (P < 0.05 by Student'st-test) (Table 1). All measured parameters returned to baselinevalues within 15 min of cessation of exercise.

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Fig. 1. Cardiovascular (A and B) and metabolic (D-F) responses to graded treadmill exercise (GTE) from baseline to 27.5 m/min belt speed and 22° slope. Note linear increases in heart rate (HR), oxygen consumption ( $V$ O₂), and carbon dioxide production ( $V$ CO₂) with exercise for PLB+/+ (

) and PLB $-$ / $-$ ( $black-diamond$ ) mice and a drop in mean blood pressure (BP) with exercise in PLB $-$ / $-$ mice. Duration of exercise (C) is not different between groups. Values represent means ± SD. RER, respiratory equivalent ratio.

When mean values for each parameter at each exercise workload were compared, no differences were found between the two genotypesat any level of exercise. Exercise workloads $<=$ 27.5 m/min at 22°slope are shown in Fig. 1, because this was the workload achievedby the majority of mice. A two-way ANOVA for repeated measuresduring GTE showed no combined effect of genotype and workloadfor any parameter. The average oxygen pulse values during exerciseare shown in Fig. 2. There are no differences at any workloadand no differences in the percent change from baseline to peakvalues between genotypes. Although there was a trend toward asteeper slope for the PLB $-$ / $-$ mice compared with wild-type mice(0.00181 ± 0.00057 vs. 0.00171 ± 0.00057 ml · kg¹ · min¹ · beat¹ per workload unit; NS = not significant), these slopes were notsignificantly different.

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Fig. 2. Oxygen pulse curves during GTE. Although there is a trend toward a steeper slope in PLB $-$ / $-$ mice ( $black-diamond$ ), there is no significant difference compared with PLB+/+ mice (

). Values represent means ± SD.

Isoproterenol response. Administration of the $beta$ -AR agonist isoproterenol resulted in expected tachycardic and hypotensive responses within 1 min ofinjection in both PLB $-$ / $-$ and wild-type mice (Fig. 3). No differenceswere found in maximally stimulated HR (691 ± 15 vs. 684 ± 17 beats/min,respectively) or mean BP (90.7 ± 8.1 vs. 83.1 ± 4.5 mmHg, respectively)between the two groups. Percent changes from basal values in responseto isoproterenol were also not different between PLB $-$ / $-$ and PLB+/+mice (21.4 ± 2.0 and 26.2 ± 2.4% for HR and $-$ 21.7 ± 3.1 and $-$ 22.1± 1.5 for BP, respectively) (Fig. 4).

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Fig. 3. Representative HR (diamonds) and mean BP (squares) responses to a single intra-arterial bolus of 1 µg/kg isoproterenol for PLB $-$ / $-$ (A) and PLB+/+ (B) mice. Note rapid responses of both parameters within 1 min after administration and return to baseline before 10 min.

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Fig. 4. Isoproterenol-stimulated changes in HR and mean BP for PLB+/+ and PLB $-$ / $-$ mice. Columns and error bars represent means ± SD.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

This study provides the first evaluation of the role of PLB in the cardiovascular and metabolic responses of the intact, awakeanimal at rest and during exercise. Ablation of PLB has been shownto improve cardiac contractility and relaxation in vitro (8,12, 23) and in vivo (7). Although basal cardiac functionis enhanced, cardiac reserve appears to be diminished as evidencedby an attenuated response to $beta$ -adrenergic stimulation. These studies,however, utilize techniques that do not necessarily reproducethe physiological responses of the intact, nonanesthetized organismand cannot assess the cardiovascular response to severe physiologicalstress such as that provided by exercise. Our primary aim, therefore,was to determine whether the in vitro enhancements of basal cardiacfunction demonstrated in PLB-deficient mice would confer a cardiovascularadvantage in vivo or whether decreased adrenergic reserve wouldlead to impaired function during cardiovascularstress.

GTE provides one of the most severe physiological stresses to the cardiovascular system and has been extensively used to quantitativelyevaluate cardiovascular fitness and disease (13, 19, 20,22). We have previously shown that treadmill exercise in miceproduces quantifiable and reproducible changes in cardiovascularand metabolic indexes similar to those in humans and other species(2). With the use of our established exercise protocol, PLB-deficientmice achieve normal peak and submaximal exercise values for allmeasured parameters, indicating that, during severe exercise stress,their overall cardiovascular and metabolic physiology is not significantlydifferent from that of controls. The fact that they reach thesame peak exercise workload and peak $V$ O₂ indicates that theirexercise capacities are also normal. These results are somewhatsurprising, because PLB-deficient mice show attenuated cardiaccontractile responses to $beta$ -AR stimulation. Thus one might expectthat this reduction in adrenergic reserve would lead to a limitedcardiovascular response to physiological stress such as exercise,during which adrenergic stimulation plays a major role. However,as we have recently demonstrated in $beta$ ₁-adrenergic receptor knockoutmice, a significant attenuation of the chronotropic response toexercise does not reduce total exercise capacity (15). Our findingssuggest, similarly, that the majority of the PLB deficiency-inducedalterations in myocardial contractility and reserve are adequatelycounterbalanced by other regulatory pathways, most likely thoseinvolving regulation of ventricular preload and afterload andoxygenextraction.

In our discussion of peak $V$ O₂, it is important to emphasize its distinction from maximum $V$ O₂ ( $V$ O_{2 max}). In a review ofthe literature, we found that $V$ O_{2 max} is very difficult to establishreproducibly in mice using treadmill exercise (1). Thus wemake no assertion of establishing $V$ O_{2 max} in this study, andwe cannot deny the possibility that differences in $V$ O_{2 max} valuesmay exist for PLB-deficient mice that our study would not havebeen able to detect. We have demonstrated, however, that the exerciseworkloads used in our protocol induce a quantifiable and reproduciblelevel of cardiovascular stress (2) and that peak $V$ O₂ and peakexercise values established using our protocol are useful forevaluating cardiac reserve in genetically altered mice (15).

The ratio of $V$ O₂ to HR, or oxygen pulse, can be used as a measure of HR-independent cardiovascular performance during exercise(22). The normal oxygen pulse values of PLB-deficient mice indicatea normal increase in $V$ O₂ for a given increase in HR during exercise.Because PLB-deficient mice are unable to increase cardiac contractilityboth in vitro and in vivo, there must be alternative compensatorymechanisms to allow normal cardiac performance.

Oxygen pulse = <A><AC>V</AC><AC>˙</AC></A><SC>o</SC>2/HR = SV × (CaO2 − CvO2)

A rearrangement of the Fick equation directly relates the oxygen pulse to left ventricular stroke volume (SV) and oxygenextraction (Ca_O₂ $-$ Cv_O₂), suggesting two possible mechanisms formaintaining cardiac performance during exercise: increasing strokevolume and/or increasing oxygen extraction. We have previouslydemonstrated that oxygen extraction plays a role in augmentingmurine cardiac output by measuring an ~30% increase in oxygenextraction during exercise in wild-type mice (15). This is unlikelyto be the sole mechanism, however, because in these same micethe oxygen pulse increased by ~55%. Thus increases in stroke volumemust also occur during exercise. Therefore, it is possible thatPLB-deficient mice compensate for an inability to increase contractilityby enhancing oxygen extraction and/or by increasing strokevolume.

By what mechanism is the latter achieved? In mammalian hearts, stroke volume can be enhanced by 1) improving ventricular contractility,2) reducing afterload, such as by lowering systemic vascular resistance,or 3) enhancing preload, such as by improving ventricular fillingand end-diastolic pressure (19). It is unlikely that PLB-deficientmice significantly increase intrinsic ventricular contractilityduring exercise, as suggested by previous in vitro and in vivostudies (7, 12). A reduction in ventricular afterload, however,is suggested by the drop in mean BP that PLB-deficient mice demonstrateduring exercise. Furthermore, echocardiographic studies have shownenhanced ventricular filling velocities in PLB-deficient mice,suggesting improved ventricular preload (7). Both of the lattermechanisms may allow PLB-deficient mice to increase their strokevolumes during exercise and compensate for their inability toenhance myocardial contractility. Thus we have evidence suggestingthat compensatory changes in stroke volume do occur in PLB-deficientmice during exercise; however, we cannot rule out the possibilitythat increases in both stroke volume and oxygen extraction areinvolved in maintaining normal exercisecapacities.

PLB-deficient mice have higher resting BPs than their wild-type littermate controls. Although basal hypertension has not beenpreviously reported in awake mice, it has been observed in anesthetizedanimals (11). An elevation of resting mean BP may be the resultof enhanced basal myocardial contractility, previously demonstratedin PLB-deficient hearts, or of alterations in basal peripheralvasculartone.

The significant drop in BP seen in PLB-deficient mice in response to exercise may simply reflect their elevated resting BPs.Other factors, however, may also play a role. Exercise in largermammals results in a redistribution of blood flow away from vasoconstrictingsplanchnic beds and toward vasodilated skin and active musclebeds (16-18). Lack of PLB may preferentially attenuate the responseto sympathetically mediated vasoconstriction during exercise whilethe locally mediated vasodilatory responses to acidosis, hypoxia,and hyperkalemia in working muscle and epidermal beds remain intact,resulting in a reduction in total vascular resistance and a dropin mean BP during prolonged exercise. Indeed, PLB-deficient aorticrings show a rightward shift in the force-concentration curvesfor the $alpha$ -adrenergic agonist phenylephrine, confirming a decreasedsensitivity to vasoconstrictive stimuli (10).

A normal chronotropic response to $beta$ -AR agonists has been previously demonstrated in PLB-deficient mice in vitro and in vivounder anesthesia (7, 12). We confirm the normal HR responsein the absence of anesthesia and show a normal BP response aswell. This suggests that the effects of pharmacological $beta$ -adrenergicstimulation on cardiac chronotropy and mean systemic arterialpressure remain intact in PLB-deficient mice and must involveeffector systems other than those mediated by PLB. This does notcontradict our findings of altered resting and exercising BPsin PLB-deficient mice, however, because BP homeostasis involvesmechanisms more complex than purely $beta$ -adrenergicstimulation.

In summary, we find that despite subtle alterations in cardiovascular performance during exercise, the exercise capacitiesof PLB-deficient mice are not different from wild-type mice, suggestingthat attenuated adrenergic reserve does not compromise overallcardiovascular performance. Alternative regulatory pathways appearto adequately compensate for any deficiency that a lack of PLBimposes on the normal cardiovascular system during exercise. Thisdoes not imply that PLB inhibition could not be advantageous inthe presence of cardiac pathology. PLB inhibition, much like $beta$ -adrenergicstimulation, may have a profound beneficial effect on exercisecapacity in animals with failing hearts and diminished cardiovascularreserve that would not be apparent in animals with normalhearts.

This study also demonstrates the importance of examining cardiovascular regulation in an intact animal both at rest and duringphysiological stress such as that provided by treadmill exercise.Such methodology is critical for evaluating cardiovascular phenotypesresulting from manipulations of the murine genome and, more importantly,for determining their relevance to whole bodyfunction.

	ACKNOWLEDGEMENTS

This study was supported in part by an American Heart Association Clinician Scientist Award (K. H. Desai) and by NationalHeart, Lung, and Blood Institute Grants HL-26057, HL-52318, andHL-22619 (E. G.Kranias).

	FOOTNOTES

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 and other correspondence: D. Bernstein, 750 Welch Rd., Ste. 305, Palo Alto, CA 94304 (E-mail: danb{at}leland.stanford.edu).

Received 8 October 1998; accepted in final form 4 January 1999.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1. Desai, K. H., and D. Bernstein. Exercise and oxygen consumption in the mouse. In: Cardiovascular Physiology in the Genetically Engineered Mouse, edited by B. D. Hoit, and R. A. Walsh. Norwell, MA: Kluwer, 1998.

2. Desai, K. H., R. Sato, E. Schauble, G. S. Barsh, B. K. Kobilka, and D. Bernstein. Cardiovascular indexes in the mouse at rest and with exercise: new tools to study models of cardiac disease. Am. J. Physiol. 272 (Heart Circ. Physiol. 41): H1053-H1061, 1997[Abstract/Free Full Text].

3. Grupp, I. L., A. Subramaniam, T. E. Hewett, J. Robbins, and G. Grupp. Comparison of normal, hypodynamic, and hyperdynamic mouse hearts using isolated work-performing heart preparations. Am. J. Physiol. 265 (Heart Circ. Physiol. 34): H1401-H1410, 1993[Abstract/Free Full Text].

4. Gui, Y. H., K. K. Linask, P. Khowsathit, and J. C. Huhta. Doppler echocardiography of normal and abnormal embryonic mouse heart. Pediatr. Res. 40: 633-642, 1996[Medline].

5. Hampton, T. G., E. G. Kranias, and J. P. Morgan. Simultaneous measurement of intracellular calcium and ventricular function in the phospholamban-deficient mouse heart. Biochem. Biophys. Res. Commun. 226: 836-841, 1996[Medline].

6. Hittinger, L., T. Patrick, T. Ihara, N. Hasebe, Y. T. Shen, B. Kalthof, R. P. Shannon, and S. F. Vatner. Exercise induces cardiac dysfunction in both moderate, compensated and severe hypertrophy. Circulation 89: 2219-2231, 1994[Abstract/Free Full Text].

7. Hoit, B. D., S. F. Khoury, E. G. Kranias, N. Ball, and R. A. Walsh. In vivo echocardiographic detection of enhanced left ventricular function in gene-targeted mice with phospholamban deficiency. Circ. Res. 77: 632-637, 1995[Abstract/Free Full Text].

8. Kiss, E., I. Edes, Y. Sato, W. Luo, S. B. Liggett, and E. G. Kranias. $beta$ -Adrenergic regulation of cAMP and protein phosphorylation in phospholamban-knockout mouse hearts. Am. J. Physiol. 272 (Heart Circ. Physiol. 41): H785-H790, 1997[Abstract/Free Full Text].

9. Koss, K. L., and E. G. Kranias. Phospholamban: a prominent regulator of myocardial contractility. Circ. Res. 79: 1059-1063, 1996[Free Full Text].

10. Lalli, J., J. M. Harrer, W. Luo, E. G. Kranias, and R. J. Paul. Targeted ablation of the phospholamban gene is associated with a marked decrease in sensitivity in aortic smooth muscle. Circ. Res. 80: 506-513, 1997[Abstract/Free Full Text].

11. Lorenz, J. N., and E. G. Kranias. Regulatory effects of phospholamban on cardiac function in intact mice. Am. J. Physiol. 273 (Heart Circ. Physiol. 42): H2826-H2831, 1997.

12. Luo, W., I. L. Grupp, J. Harrer, S. Ponniah, G. Grupp, J. J. Duffy, T. Doetschman, and E. G. Kranias. Targeted ablation of the phospholamban gene is associated with markedly enhanced myocardial contractility and loss of beta-agonist stimulation. Circ. Res. 75: 401-409, 1994[Abstract/Free Full Text].

13. Overton, J. M. Influence of autonomic blockade on cardiovascular responses to exercise in rats. J. Appl. Physiol. 75: 155-161, 1993[Abstract/Free Full Text].

14. Rockman, H. A., S. Ono, R. S. Ross, L. R. Jones, M. Karimi, V. Bhargava, J. J. Ross, and K. R. Chien. Molecular and physiological alterations in murine ventricular dysfunction. Proc. Natl. Acad. Sci. USA 91: 2694-2698, 1994[Abstract/Free Full Text].

15. Rohrer, D. K., E. H. Schauble, K. H. Desai, B. K. Kobilka, and D. Bernstein. Alterations in dynamic heart rate control in the $beta$ ₁-adrenergic receptor knockout mouse. Am. J. Physiol. 274 (Heart Circ. Physiol. 43): H1184-H1193, 1998[Abstract/Free Full Text].

16. Seto, H., M. Kageyama, K. Nomura, N. Watanabe, S. Inagaki, M. Kakishita, O. Wada, and H. Asanoi. Whole-body 201Tl scintigraphy during one-leg exercise and at rest in normal subjects: estimation of regional blood flow changes. Nucl. Med. Commun. 16: 661-666, 1995[Medline].

17. Shen, W., M. Lundborg, J. Wang, J. M. Stewart, X. Xu, M. Ochoa, and T. H. Hintze. Role of EDRF in the regulation of regional blood flow and vascular resistance at rest and during exercise in conscious dogs. J. Appl. Physiol. 77: 165-172, 1994[Abstract/Free Full Text].

18. Shen, W., X. Zhang, G. Zhao, M. S. Wolin, W. Sessa, and T. H. Hintze. Nitric oxide production and NO synthase gene expression contribute to vascular regulation during exercise. Med. Sci. Sports Exerc. 27: 1125-1134, 1995[Medline].

19. Sheriff, D. D., X. P. Zhou, A. M. Scher, and L. B. Rowell. Dependence of cardiac filling pressure on cardiac output during rest and dynamic exercise in dogs. Am. J. Physiol. 265 (Heart Circ. Physiol. 34): H316-H322, 1993[Abstract/Free Full Text].

20. Stebbins, C. L., and J. D. Symons. Vasopressin contributes to the cardiovascular response to dynamic exercise. Am. J. Physiol. 264 (Heart Circ. Physiol. 33): H1701-H1707, 1993[Abstract/Free Full Text].

21. Tanaka, N., N. Dalton, L. Mao, H. A. Rockman, K. L. Peterson, K. R. Gottshall, J. J. Hunter, K. R. Chien, and J. J. Ross. Transthoracic echocardiography in models of cardiac disease in the mouse. Circulation 94: 1109-1117, 1996[Abstract/Free Full Text].

22. Wasserman, K., J. E. Hansen, D. Y. Sue, B. J. Whipp, and R. Casaburi. Principles of Exercise Testing and Interpretation. Philadelphia, PA: Lea and Febiger, 1994.

23. Wolska, B. M., M. O. Stojanovic, W. Luo, E. G. Kranias, and R. J. Solaro. Effect of ablation of phospholamban on dynamics of cardiac myocyte contraction and intracellular Ca²⁺. Am. J. Physiol. 271 (Cell Physiol. 40): C391-C397, 1996[Abstract/Free Full Text].

24. Yasu, T., T. Katsuki, N. Ohmura, I. Nakada, M. Owa, M. Fujii, A. Sakaguchi, and M. Saito. Delayed improvement in skeletal muscle metabolism and exercise capacity in patients with mitral stenosis following immediate hemodynamic amelioration by percutaneous transvenous mitral commissurotomy. Am. J. Cardiol. 77: 492-497, 1996[Medline].

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