SERCA1a can functionally substitute for SERCA2a in the heart

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SERCA1a can functionally substitute for SERCA2a in the heart

Yong Ji¹, Evgeny Loukianov¹, Tanya Loukianova¹, Larry R. Jones², and Muthu Periasamy¹

¹ Division of Cardiology, Department of Internal Medicine, University of Cincinnati College of Medicine, Cincinnati, Ohio 45267; and ² Department of Medicine and Krannert Institute of Cardiology, Indiana University School of Medicine, Indianapolis, Indiana 46202

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

We recently generated a transgenic (TG) mouse model in which the fast-twitch skeletal muscle sarcoplasmic reticulum (SR) Ca²⁺-ATPase (SERCA1a) is overexpressed in the heart. Ectopic overexpressionof SERCA1a results in remodeling of the cardiac SR containing80% SERCA1a and 20% endogenous SERCA2a with an ~2.5-fold increasein the total amount of SERCA protein (E. Loukianov et al. Circ.Res. 83: 889-897, 1998). We have analyzed the Ca²⁺ transport properties of membranes from SERCA1a TG hearts in comparisonto control hearts. Our data show that the maximal velocity ofSR Ca²⁺ transport was significantly increased (~1.9-fold) in TG hearts,whereas the apparent affinity of the SERCA pump for Ca²⁺ was not changed. Addition of phospholamban antibody in the Ca²⁺ uptake assays increased the apparent affinity for Ca²⁺ to the same extent in TG and non-TG (NTG) hearts, suggestingthat phospholamban regulates the SERCA1a pump in TG hearts. Analysisof SERCA enzymatic properties in TG hearts revealed that the SERCApump affinity for ATP, the Hill coefficient, the pH dependenceof Ca²⁺ uptake, and the effect of acidic pH on Ca²⁺ transport were similar to those of NTG hearts. Interestingly,the rate constant of phosphoenzyme decay (turnover rate of SERCAenzyme) was also very similar between TG and NTG hearts. Togetherthese findings suggest that 1) the SERCA1a pump can functionallysubstitute for SERCA2a and is regulated by endogenous phospholambanin the heart and 2) SERCA1a exhibits several enzymatic propertiessimilar to those of SERCA2a when expressed in a cardiacsetting.

sarco(endo)plasmic reticulum calcium-adenosinetriphosphatase; isoform; calcium transport; phospholamban

	INTRODUCTION

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THE SARCOPLASMIC RETICULUM (SR) Ca²⁺-ATPase (SERCA) plays a central role in muscle contraction and relaxation by regulatingintracellular Ca²⁺ concentration (9). Muscle contraction is activated by therelease of Ca²⁺ via the SR Ca²⁺ release channel, whereas muscle relaxation is produced by Ca²⁺ reuptake into the SR by SERCA. The SERCA pump is an ~110-kDatransmembrane protein (34) and belongs to the P-type superfamilyof ion transport ATPases, which couple vectorial ion transportprocesses with the formation and decomposition of a phosphorylatedenzyme intermediate (E-P) (12).

Molecular cloning analyses identified three distinct SERCA genes, SERCA1, SERCA2, and SERCA3, which encode at least five Ca²⁺ pump isoforms (4, 7, 33, 47, 48). All these isoformsare produced by alternate mRNA splicing and are expressed in adevelopmental and tissue-specific manner. The SERCA1 gene encodestwo alternatively spliced transcripts, SERCA1a and SERCA1b, whichare exclusively expressed in the fast-twitch fibers of skeletalmuscle. SERCA1a is predominantly expressed in the adult stages;SERCA1b is mainly expressed in the fetal/neonatal stages (4).The SERCA2 gene encodes SERCA2a and SERCA2b isoforms. SERCA2ais the primary isoform expressed in the heart and in slow-twitchfibers of skeletal muscle (47, 48) and is also expressed infast-twitch skeletal muscle during fetal/neonatal stages, butit is replaced by the SERCA1a isoform in the adult stage (48).However, SERCA1a is never expressed in the heart. The SERCA2bisoform is ubiquitously expressed but found at high levels insmooth muscle tissues (33), and the SERCA3 isoform is restrictedto specialized cell types, such as epithelial and endothelialcells (7).

The functional significance of having various SERCA isoforms is not completely understood. Given the selective expressionpattern of SERCA isoforms in a tissue-specific and developmentalmanner, it seems likely that SERCA1a and SERCA2a pumps have distinctCa²⁺ transport properties and contribute differently to the contractilefunction unique to each muscle type. It has been reported thatthe Ca²⁺ transport capacity is much lower in cardiac than in fast-twitchskeletal muscle SR (8, 43, 46). This is partly due to thedifference in SERCA pump density (8, 43). The apparent affinityof cardiac SERCA enzyme for Ca²⁺ is also two to three times lower than that of fast-twitch skeletalmuscle SERCA (8, 43, 46). This has been mainly attributedto specific interaction of SERCA2a with phospholamban (PLB), whichis a transmembrane phosphoprotein specifically expressed in cardiac,slow-twitch skeletal, and smooth muscles and regulates the apparentCa²⁺ affinity of SERCA2a by reversible phosphorylation (28).

On the other hand, the primary structure of SERCA1a and SERCA2a protein is ~84% identical (5). As a consequence, the twoSERCA isoforms are predicted to have essentially identical topologiesand tertiary structure. Recently, the biochemical properties ofSERCA isoforms were studied by expressing different SERCA proteinsin nonmuscle COS-1 and HEK-293 cells (31, 32). These studiesrevealed that SERCA1a and SERCA2a isoforms are similar in termsof Ca²⁺ transport capacity, apparent affinity for Ca²⁺ and ATP, and enzyme turnover during ATP hydrolysis (31). However,these in vitro studies may have potential limitations becauseof the absence of native regulators such as PLB and the nativephospholipid environment in the muscle cells, which has been shownto greatly influence the Ca²⁺ transport function (15, 26). Therefore, it remains to bedetermined whether the observed difference in Ca²⁺ transport capacity between fast-twitch skeletal and cardiac SRis due to the difference in SERCA pump density (level) (43)or the difference in enzymatic properties of SERCA isoforms andtheir interaction with tissue-specific regulators (e.g., PLB).To determine whether the SERCA1a isoform differs from the SERCA2aisoform in terms of Ca²⁺ transport properties, we utilized a transgenic (TG) mouse modelin which the fast-twitch SERCA1a pump is ectopically overexpressedin the heart. Ectopic overexpression of SERCA1a results in remodelingof the cardiac SR containing 80% SERCA1a and 20% endogenous SERCA2awith an ~2.5-fold increase in total SERCA pump level (29a). TheTG model provides us with an in vivo system to compare the Ca²⁺ transport properties of SERCA1a with SERCA2a under the same muscleenvironment.

	MATERIAL AND METHODS

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SERCA1a TG mice. Construction of the SERCA1a transgene and generation of TG mice are described elsewhere (29a). SERCA1a TG mice were generatedusing the cardiac $alpha$ -myosin heavy chain promoter (17) linkedto rat SERCA1a cDNA. Five independent lines (transgene copies2-9) were identified to express SERCA1a mRNA and protein in thehearts. TG line 38, which showed the highest level of SERCA1amRNA and protein, was chosen to study SERCA functionalproperties.

Preparation of cardiac homogenates and microsomes enriched in SR membranes. Excised hearts from 12- to 13-wk-old mice were rinsed with ice-cold saline, immediately frozen in liquid nitrogen, and storedat $-$ 80°C. The frozen hearts were powdered and homogenized at 4°Cin a solution containing 10 mM imidazole (pH 7.0), 0.3 M sucrose,10 mM NaF, 1 mM EDTA, 0.3 mM phenylmethylsulfonyl fluoride, 0.5mM dithiothreitol, and the other protease inhibitors: 10 µg/mlaprotinin, 10 µg/ml leupeptin, and 2 µg/ml pepstatin A. For assayof SERCA activity, microsomal fractions enriched in SR membraneswere obtained using differential centrifugation of the cardiachomogenates, as described previously (25). Protein concentrationswere determined by the Bio-Rad method, with BSA asstandard.

Measurement of SERCA activity. Ca²⁺-ATPase activity was measured in isolated microsomes enriched in cardiac SR, as described elsewhere (24). The reactionmixture contained 50 mM histidine, pH 7.0, 100 mM KCl, 5 mM MgCl₂,5 mM azide, 20 µg/ml microsomal protein, 1 mM EGTA, and variousCaCl₂ concentrations to yield the desired free Ca²⁺ concentration from 0.1 to 10 µM (40). The Ca²⁺ ionophore A-23187 (2 µM) was added to the assay system to ensurethat Ca²⁺ accumulated by SR vesicles during the assay does not inhibitthe Ca²⁺ pumps from inner surfaces of the vesicles (23). In addition,3.33 mM phosphoenolpyruvate and 3 U/ml pyruvate kinase were includedto regenerate ATP from ADP during the reaction (24). The reactionwas started by addition of 3 mM ATP at 37°C and was stopped after20 min by addition of colorimetric reagent. Absorbance was readat 660 nm to monitor the liberated P_i, and the rate of ATP hydrolysiswas determined by measuring the amount of P_i liberated during20 min of incubation of microsomes. Ca²⁺-dependent ATPase activity was calculated by subtracting Ca²⁺-independent (basal) ATPase activity (measured in the presenceof 2 mM EGTA and the absence of Ca²⁺) from total ATPase (in the presence of Ca²⁺). The SERCA origin of Ca²⁺-ATPase activity in the isolated microsomes was evaluated by thapsigargininhibition, as described previously (41). It has been establishedthat thapsigargin is the most potent and specific inhibitor ofSERCAs, and it inhibits SERCA Ca²⁺ transport and Ca²⁺-ATPase activity (21). Preincubation (2 min at 37°C) of reactionmixture containing microsomal protein with 1 µM thapsigargin resultedin 92-96% inhibition of Ca²⁺-dependent ATP hydrolysis in the microsomes, indicating that theCa²⁺-dependent ATP hydrolysis is mostly due toSERCAs.

Ca²⁺ transport assays. Oxalate-facilitated Ca²⁺ uptake into SR vesicles in cardiac homogenates was determined by the Millipore filtration techniquefollowing an established method (18). Cardiac homogenates (100µg/ml) were incubated (37°C) in a medium containing 40 mM imidazole(pH 7.0), 100 mM KCl, 5 mM MgCl₂, 5 mM NaN₃, 5 mM potassium oxalate,0.5 mM EGTA, and various concentrations of CaCl₂ to yield 0.03-3µM free Ca²⁺ (containing 1 µCi/µmol ⁴⁵Ca²⁺), as determined by the computer program (40). Ruthenium red(1 µM) was added to obtain the maximal stimulation of SR Ca²⁺ uptake by inhibiting the Ca²⁺ release channel (18). The reaction was initiated by the additionof 5 mM ATP. The rate of Ca²⁺ uptake was calculated by least-squares linear regression analysisof uptake at 30, 60, and 90 s. SR specificity of Ca²⁺ uptake in cardiac homogenates was confirmed by thapsigargin inhibition.We observed that preincubation of homogenates with 1 µM thapsigarginresulted in 95 and 94% inhibition of Ca²⁺ uptake activity at saturated Ca²⁺ concentration in hearts from TG and non-TG (NTG) mice, respectively,suggesting that the Ca²⁺ uptake measured with cardiac homogenates is mostly supportedby SR Ca²⁺ uptake, as defined previously (29).

For the assay of pH dependence of Ca²⁺ uptake, 40 mM MOPS was substituted for 40 mM imidazole, and the pH was set at each pointfrom 6.0 to 8.0. The effect of acidic pH (pH 6.0 and 6.3) on Ca²⁺ transport was assayed at various Ca²⁺ concentrations (0.1-100 µM) determined by the computer program(40).

The effect of PLB monoclonal antibody (2D12) on SR Ca²⁺ uptake was determined as described previously (8). Briefly, a controlsample and the sample with antibody 2D12 were preincubated for15 min at 4°C. The ratio of antibody protein to cardiac homogenateprotein was 1:2 (wt/wt) (8). Then the Ca²⁺ uptake reaction was started by addition of 5 mM ATP and performedas describedabove.

Formation and decay of E-P in the presence of ATP and Ca²⁺. The steady-state levels of Ca²⁺-dependent E-P were measured as described by Anderson et al. (2). Cardiac homogenate protein(20 µg) was added to 0.1 ml of reaction mixture containing 40mM imidazole, pH 7.0, 100 mM KCl, 5 mM MgCl₂, 5 mM NaN₃, and variousconcentrations of free Ca²⁺ (0.1-100 µM) or 1 mM EGTA. The components of the reaction mixturewere preincubated in ice with vortex mixing. The reaction wasinitiated by addition of 2 µM [ $gamma$ -³²P]ATP (sp. act. 10 µCi/nmol) at 0°C and acid quenched after 15s by addition of 1 ml of ice-cold stop solution (6% TCA, 0.3 mMATP, and 5 mM P_i). The samples were placed in ice for 5 min andthen vacuum filtered through 0.45-µm Millipore filters. Proteinsremaining on the filters were washed three times with 15 ml ofstop solution, then the filters were processed for scintillationcounting. Ca²⁺-dependent E-P formation was calculated as the difference betweenthe amount of ³²P incorporation into protein in the presence of Ca²⁺ and in the presence ofEGTA.

To test whether the phosphoenzyme formation was mainly restricted to SERCA protein, acid SDS-PAGE (pH 6.3) and autoradiographyof E-P protein were carried out as described by Sarkadi et al.(42). Additionally, 500 nM thapsigargin was preincubated withcardiac homogenates for 5 min on ice to determine the specificinhibition by thapsigargin on Ca²⁺-dependent E-P formation of the SERCApump.

The rate of SERCA phosphoenzyme decay was determined by first obtaining the steady-state levels of phosphoenzyme, as describedabove. At 15 s after the addition of radioactive ATP, 0.1 ml of1.0 mM nonradioactive ATP was added with rapid mixing, and thesamples were acid quenched with 6% TCA at different time intervals(16). A time-0 baseline was obtained by acid quenching beforethe chase. The entire procedure was carried out at 0°C. Filtrationwas performed as describedabove.

Statistical analysis. Values are means ± SE. Data concerning the dependence of ATP hydrolysis and Ca²⁺ uptake rates on free Ca²⁺ and ATP concentrations were fit to the equation for a generalcooperative model for substrate as follows

<IT>v</IT> = <IT>V</IT>max [S]<IT>n</IT>/(<IT>K</IT>0.5 + [S]<IT>n</IT>)

where V_max (maximum velocity), K_0.5 (concentration required for half-maximal activation), and n (equivalent of the Hill coefficient)were calculated by using nonlinear regression analysis with Origin3.5 (MicroCal Software) and where [S] is substrateconcentration.

The E-P decomposition data were analyzed using the first-order exponential equation

<IT>y</IT> = <IT>A</IT><SUB>1</SUB> <IT>e</IT><SUP>−<IT>kt</IT></SUP>

Statistical analysis was performed by unpaired two-tailed Student's t-test. P < 0.05 was considered to besignificant.

	RESULTS

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Generation and characterization of SERCA1a TG mice have been described elsewhere (29a). We have shown that ectopic overexpressionof SERCA1a in the hearts results in remodeling of the cardiacSR containing ~80% SERCA1a and ~20% endogenous SERCA2a with an~2.5-fold increase in total SERCA protein levels. SERCA1a overexpressiondid not alter the expression levels of other proteins, includingPLB. The SERCA1a TG mice are healthy and do not display cardiacpathology. Functional analysis of SERCA1a TG hearts demonstratesa significant enhancement (40-42%) in the cardiac contractileperformance(29a).

SERCA1a overexpression increases the rate of ATP hydrolysis without altering the apparent pump affinity for Ca²⁺. To determine the effect of SERCA1a overexpression in SERCA activity in hearts from TG mice, we used isolated microsomes enrichedin cardiac SR to measure the Ca²⁺-dependent ATP hydrolysis. The rate of ATP hydrolysis was significantlyhigher in TG than in control microsomes over a wide range of Ca²⁺ concentrations (0.03-10 µM; Fig. 1A). The maximum rate of ATPhydrolysis was increased ~2.5-fold in TG compared with NTG hearts(Fig. 1A, Table 1). These data indicate that SERCA1a overexpressionresults in a significant increase in cardiac SERCA activity. However,K_0.5 of Ca²⁺ for ATPase activity was similar in TG and NTG hearts (Fig. 1B).Ca²⁺ activation of Ca²⁺-ATPase activity was best fit by a model requiring two cooperativeCa²⁺-binding sites in TG and NTG hearts (Table 1).

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Fig. 1. Ca²⁺ dependence of Ca²⁺-ATPase activity. Ca²⁺ activation of ATPase activity was measured in microsomes isolated from transgenic (TG) and non-TG (NTG) hearts. Microsomes (20 µg/ml) enriched in sarcoplasmic reticulum membranes were incubated with reaction mixture containing 2 mM EGTA or various concentrations of Ca²⁺. Ca²⁺-dependent ATP hydrolysis was determined by subtracting basal ATPase (in presence of EGTA) from total ATPase activity (in presence of added Ca²⁺). Average of 4 separate determinations is shown, each performed in duplicate. Curve represents best fit of data to a general cooperative model.

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Table 1. Kinetic parameters for Ca²⁺ uptake in the absence and presence of PLB antibody and Ca²⁺-ATPase activity in TG and NTG mouse hearts

Apparent pump affinity for Ca²⁺ is not altered in SERCA1a TG hearts, but the V_max of SR Ca²⁺ uptake is increased. To investigate the Ca²⁺ transport properties of SERCA1a hearts, we used cardiac homogenates to perform the ATP-dependent oxalate-facilitatedSR Ca²⁺ uptake. Our results showed that the velocity of SR Ca²⁺ uptake was significantly higher in TG than in NTG hearts overa wide range of Ca²⁺ concentrations (0.03-3 µM; Fig. 2A). The V_max of SR Ca²⁺ uptake was ~1.9-fold higher in TG than in NTG hearts (Table 1).

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Fig. 2. Effect of phospholamban (PLB) monoclonal antibody (Ab) on sarcoplasmic reticulum Ca²⁺-ATPase (SERCA) uptake. Initial rates of Ca²⁺ uptake were determined in cardiac homogenates. Cardiac homogenates were incubated at 0°C for 15 min in absence ( $-$ Ab) or presence (+Ab) of PLB antibody, then Ca²⁺ dependence of Ca²⁺ uptake was assayed. PLB monoclonal antibody shifts Ca²⁺ activation curve to left in TG and NTG hearts. Data are expressed as nmol Ca²⁺ · mg¹ · min¹ (A) and as percentage of Ca²⁺ uptake rate at pCa 6.0 in A (B). Average of 4 separate determinations is shown.

An increase in SR Ca²⁺ transport function could result from an increased pump level or from a higher affinity of expressed pumpsfor Ca²⁺. Therefore, we determined the SERCA pump affinity for Ca²⁺. Analysis of the K_0.5 values from Ca²⁺ uptake assay revealed no significant difference between TG andNTG hearts (Table 1). This result indicates that the apparentSERCA affinity for Ca²⁺ is not altered in SERCA1a TG hearts. This is quite consistentwith the results independently obtained from ATP hydrolysis assay,as described above. The K_0.5 values we measured in TG and NTGhearts are similar to those preciously obtained from wild-typemice (18, 30). The apparent Ca²⁺ cooperativity of Ca²⁺ uptake (Hill coefficient) was also similar in TG and NTG hearts(Table 1).

Anti-PLB antibody increases the apparent SERCA affinity for Ca²⁺ in TG hearts. Despite SERCA1a overexpression, we did not observe an increase in the apparent SERCA affinity for Ca²⁺ in TG hearts compared with the affinity for Ca²⁺ determined in NTG hearts. This result suggests that PLB may interactwith SERCA1a in TG hearts. To further determine whether PLB interactswith SERCA1a, we tested the effect of anti-PLB antibody 2D12 onthe SR Ca²⁺ uptake function in TG and NTG hearts. This antibody was previouslyshown to remove the inhibitory effect of PLB on the Ca²⁺ pump (6, 8). Addition of PLB antibody increased the rateof SR Ca²⁺ uptake 1.5- to 2.5-fold at lower Ca²⁺ concentrations (<1 µM) in TG and NTG hearts (Fig. 2A). PLB antibodytreatment increased the pump affinity for Ca²⁺ to a similar extent (2.4-fold decrease in K_0.5) in TG and NTGhearts (Table 1, Fig. 2B). These data are comparable to the previouslyreported data showing the effect of anti-PLB antibody on cardiacSERCA (8, 39). At the same time, PLB antibody treatment didnot stimulate the Ca²⁺ uptake rates at saturating Ca²⁺ concentrations (>1 µM) in TG and NTG hearts (Table 1), indicatingthat the V_max of Ca²⁺ uptake was not affected by PLB antibody, which is quite consistentwith the results reported earlier (8, 30, 39).

pH dependence of SR Ca²⁺ uptake is similar in TG and NTG hearts. It has been proposed that SERCA is also an H⁺ pump that generates an H⁺ gradient to sustain Ca²⁺ transport and exchanges H⁺ for Ca²⁺ (10, 35). It is known that the SERCA Ca²⁺ transport function is pH dependent. TG and NTG hearts showedsimilar pH dependence for Ca²⁺ uptake rate when pH was varied from 6.0 to 8.0 (Fig. 3A). Theoptimal pH for Ca²⁺ uptake was ~7.0 for TG and NTG cardiac tissues. Because Ca²⁺ binding to the Ca²⁺-ATPase is pH dependent (10), we measured the effect of acidicpH on the apparent affinity of SERCA for Ca²⁺. In TG and NTG hearts the apparent affinity of the enzyme forCa²⁺ decreased ~10 times when the pH was lowered from 7.0 to 6.3 anddecreased ~40 times when the pH was lowered from 7.0 to 6.0 (Fig.3B). TG and NTG hearts showed similar apparent affinity for Ca²⁺ at pH 6.3 (2.32 ± 0.18 vs. 2.06 ± 0.20 µM, n = 3, P > 0.05) andpH 6.0 (9.87 ± 0.42 vs. 10.35 ± 1.35 µM, n = 3, P > 0.05; Fig.3B). In addition to its effect on Ca²⁺ affinity, lowering the pH also caused a decrease in the V_maxof Ca²⁺ uptake. However, at pH 6.3, TG hearts still showed an ~1.9-foldincrease in the V_max for Ca²⁺ uptake compared with NTG hearts, similar to the increase observedat neutral pH (data not shown). At pH 6.0 the V_max of Ca²⁺ uptake could not be reached, even in the presence of 100 µM Ca²⁺ in TG and NTG hearts. Acidic pH decreased the apparent cooperativityof Ca²⁺ uptake (Hill coefficient) in TG and NTG hearts, which is consistentwith the results reported previously (13). There is no differencein the magnitude of decrease between TG and NTG cardiac tissues(Fig. 2B).

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Fig. 3. pH dependence of sarcoplasmic reticulum Ca²⁺ uptake. A: initial rate of sarcoplasmic reticulum Ca²⁺ uptake determined in cardiac homogenates at different pH values from pH 6.0 to 8.0. Free Ca²⁺ concentration was 1 µM. B: effect of acidic pH on Ca²⁺ dependence of Ca²⁺ uptake. Rate of Ca²⁺ uptake was measured in reaction media containing 0.1-10 µM free Ca²⁺ at pH 7.0, 6.3, and 6.0, as determined by computer program. Values are representative of 3 separate determinations.

Increased V_max of Ca²⁺ transport in TG hearts is due to the increased active pump (E-P) level. Ca²⁺ translocation is tightly coupled with the formation of SERCA E-P, in which the terminal phosphate of ATP is incorporatedinto the aspartyl residue of the ATPase enzyme, so that the steady-statelevel of E-P can be used to quantitate the amount of active enzyme(36). To address whether the increase in SR Ca²⁺ transport and Ca²⁺-ATPase activity in TG hearts is due to an increase in activepump fraction, we measured the amount of E-P formed during enzymeturnover. Autoradiography demonstrated that the Ca²⁺-dependent incorporation of ³²P from ATP into a single ~110-kDa band corresponds to SERCA. Radiationincorporation was totally Ca²⁺ dependent and completely blocked by 500 nM thapsigargin (Fig.4A). This specificity allows us to quantitate the amount of E-P.TG cardiac homogenates displayed a 2.5-fold increase in the steady-statelevel of E-P compared with NTG homogenates (141.11 ± 4.43 vs.55.11 ± 2.02 pmol/mg, n = 6, P < 0.01; Fig. 4B). This is quiteconsistent with the magnitude of the increase in ATP hydrolysisand SERCA protein level. The E-P data indicate that the ectopicallyexpressed SERCA1a pump in the hearts is functional and the increasein the V_max of SR Ca²⁺ uptake and ATP hydrolysis is due to increase in the total amountof SERCA pumps.

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Fig. 4. Formation of SERCA phosphorylated intermediate (E-P) in presence of ATP and Ca²⁺. A: autoradiograph showing Ca²⁺ dependence and thapsigargin (Thg) sensitivity of phosphoenzyme formation. E-P protein (10 µg/well) was run in 7% acidic SDS-PAGE (pH 6.3), and autoradiography was carried out as described in MATERIALS AND METHODS. B: Ca²⁺ dependence of E-P formation determined by filtration technique. Cardiac homogenates (0.2 mg/ml) were phosphorylated on ice in presence of 2 µM [ $gamma$ -³²P]ATP and various concentrations of Ca²⁺. Reaction was stopped at 15 s with 1 ml of TCA-ATP-P_i solution, then subjected to vacuum filtration. C: ATP dependence of E-P formation. Reaction medium contained 0.1-2 µM [ $gamma$ -³²P]ATP. Data are expressed as percentage of E-P formation obtained at 2 µM [ $gamma$ -³²P]ATP. Average of 6 separate determinations is shown.

It was shown that SERCA1a and SERCA2a isoforms differ in their nucleotide-binding domains (5). To determine whether thereis a difference in ATP dependence or ATP-binding properties betweenSERCA1a and SERCA2a isoforms, we measured the ATP dependence ofE-P formation at 0-2 µM Mg₂ATP, which reflects nucleotide bindingto the high-affinity catalytic site (1). We observed that theATP dependence was similar in TG and NTG hearts, with apparentK_0.5 for ATP of 0.43 ± 0.13 and 0.35 ± 0.12 µM, respectively (n= 6, P > 0.05; Fig. 4C), and did not show any sign of cooperativity(Hill coefficient = 1). These values are in the same range asthose previously obtained from mammalian hearts (37).

Turnover rate of SERCA enzyme (E-P decay) is similar in TG and NTG hearts. An increase in the velocity of SR Ca²⁺ transport can occur as a result of an increase in total pump number and/or faster turnoverrate of the SERCA pump. To determine the turnover rate of SERCAenzyme in TG hearts, we measured the rate of E-P decay by performingisotopic chase experiments, as described below. These experimentswere carried out at low ATP concentrations (2 µM) and at 0°C toslow the phosphoenzyme decomposition. The E-P turnover rate wasdetermined by first obtaining steady-state levels of radioactivephosphoenzyme in the presence of 100 µM Ca²⁺ and 2 µM [ $gamma$ -³²P]ATP and then adding an excess of nonradioactive ATP. After additionof cold ATP, nearly all the newly formed phosphoenzyme is nonradioactive,so the rate of the disappearance of radioactive phosphoenzymerepresents phosphoenzyme turnover rate (16). We found that the[³²P]phosphoenzyme decayed in a few seconds and exhibited a first-orderexponential curve (Fig. 5), which is in agreement with previousreports (8, 45). As a function of time, the rate of E-P decompositionwas similar in TG and NTG hearts, with rate constants of 0.39± 0.01 and 0.37 ± 0.02 s¹, respectively (n = 10, P > 0.05). Because the turnover rate ofphosphoenzyme (rate constant) measured under this condition isindependent of the amount of E-P, our results demonstrate thatthe turnover rates of SERCA1a and SERCA2a enzymes in the cardiacenvironment are similar.

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Fig. 5. Decomposition of E-P in presence of ATP and Ca²⁺. Cardiac homogenates were phosphorylated for 15 s on ice in presence of 100 µM Ca²⁺ and 2 µM [ $gamma$ -³²P]ATP to obtain steady-state level of E-P. Isotopic chase experiments were conducted by adding 1 mM nonradioactive ATP to measure decay of E-P, and reaction was stopped at different times, then subjected to vacuum filtration. Data are expressed as percentage of E-P value at time-0 baseline from 10 separate preparations.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

We have utilized a TG mouse model that ectopically overexpresses SERCA1a in the hearts to investigate the Ca²⁺ transport properties of the SERCA1a pump. Our findings indicatethat 1) SERCA1a overexpression results in a significant increasein the SR Ca²⁺ transport function because of the increase in SERCA pump level,2) PLB interacts with the SERCA1a pump in the heart, and 3) theSERCA1a pump is similar to SERCA2a in terms of kinetic properties.These findings suggest that SERCA1a can functionally substitutefor SERCA2a in the heart. Recently, using adenoviral gene transfer,Inesi et al. (20) showed that overexpression of SERCA1a in chickneonatal cardiac myocytes enhanced SR Ca²⁺ transport function and myocyte shortening. These results alsosuggest that SERCA1a can functionally substitute for SERCA2a incardiacmyocytes.

In the present study we found that, despite SERCA1a overexpression, the apparent SERCA affinity for Ca²⁺ was similar in TG and NTG hearts, suggesting that PLB regulatesSERCA1a in TG hearts. Previous in vitro studies showed that PLBcan regulate SERCA1a when reconstituted together in lipid bilayers(15, 26) or when coexpressed with SERCA1a in COS-1 cells (19).Similarly, studies in TG mice showed that ectopic expression ofPLB in mouse fast-twitch skeletal muscle decreased the affinityof SERCA1a for Ca²⁺ (44). To further understand whether SERCA1a is regulated bynative PLB in TG hearts, we tested the effect of anti-PLB antibody2D12 on SR Ca²⁺ uptake, which has been proven to relieve PLB inhibition on cardiacSERCA (6, 8). We found that addition of PLB antibody increasedthe apparent Ca²⁺ affinity 2.4-fold in TG hearts, suggesting that PLB can interactwith SERCA1a in the hearts. In TG hearts, 80% of total SERCA pumpsare represented by SERCA1a and only 20% by SERCA2a (29a). Therefore,the shift in the apparent affinity for Ca²⁺ by PLB antibody is largely determined by SERCA1a in TG hearts.Furthermore, we observed that the magnitude of the shift in SERCAaffinity for Ca²⁺ by PLB antibody was very similar in TG and NTG hearts. Thus PLBappears to interact with SERCA1a in a manner similar to SERCA2a.Consistent with this, a major binding site for PLB has been identifiedbetween Asp³⁷⁰ and Lys⁴⁰⁰ in SERCA2a, a region that is highly conserved between SERCA1and SERCA2 isoforms (22). Taken together, these results suggestthat the difference in apparent Ca²⁺ affinity observed in skeletal and cardiac SR is not due to differencesin Ca²⁺-binding properties of SERCA isoforms but mainly to selectiveregulation by PLB. This is also supported by the finding thatCa²⁺ binding to the ATPase under equilibrium conditions in the absenceof ATP was identical in cardiac and skeletal SR (8). In addition,we found that the V_max of Ca²⁺ uptake remained unchanged after PLB antibody treatment, providingadditional evidence that the main regulatory effect of PLB ison the apparent affinity for Ca²⁺, but not on the V_max of the Ca²⁺ transport, which is in agreement with reports from other investigators(8, 30, 39).

Previous studies have shown that alterations in PLB protein level by means of PLB gene ablation or overexpression result inaltered apparent pump affinity for Ca²⁺ (30, 25). Because the levels of the cardiac SERCA were notchanged in these previous studies, the data suggested that alterationsin the relative stoichiometry of PLB to SERCA can alter the apparentSERCA affinity for Ca²⁺ (28). In contrast, in SERCA1a TG hearts the SERCA pump levelwas increased ~2.5-fold without a change in the PLB protein level.Therefore, because of the preferential increase in the SERCA-to-PLBprotein ratio, one would expect a significant increase in theSERCA apparent affinity for Ca²⁺. Surprisingly, we did not find such an effect in TG hearts. Moreover,we obtained similar results when SERCA2a was overexpressed inthe heart. In SERCA2a TG hearts the total SERCA2a protein wasincreased by ~50%, resulting in a 37% increase in the V_max ofSR Ca²⁺ uptake, but the PLB level was unchanged, and the apparent affinityfor Ca²⁺ was not altered (3a). The molecular mechanisms of SERCA regulationby PLB are not completely understood, and the functional stoichiometryof PLB to SERCA2a is not known. This is complicated by the factthat PLB exists as a pentamer (inactive form) and a monomer (activeform), as evaluated using an electron paramagnetic resonance technique(11). The equilibrium between these two states may be regulatedby phosphorylation of PLB (11) and SERCA pump level (D. Thomas,personal communication). Therefore, an increase in SERCA pumplevel may shift the dynamic equilibrium of PLB toward a monomer,which has been reported to be a more effective inhibitor thana PLB pentamer (3, 11, 27). At any rate, our results suggestthat there is enough "space" for PLB molecules in the heart toeffectively inhibit a 2.5-fold overexpression of Ca²⁺pumps.

Our studies showed that, regardless of the total SERCA pump level, the enzymatic properties of SERCA pumps from TG and NTGhearts are similar. The TG and NTG hearts revealed similar apparentaffinity for Ca²⁺ and ATP and similar Hill coefficients. In addition, the phosphoenzymeturnover was also similar between TG and NTG hearts, suggestingthat SERCA1a and SERCA2a have similar kinetic properties in cardiacSR. This is consistent with the previous results showing similarenzymatic properties of SERCA1a and SERCA2a in nonmuscle cell(COS-1 and HEK-293) microsomes (31, 32). On the other hand,it has been found that the effect of acidic pH on K_0.5 and V_maxof Ca²⁺ uptake was less pronounced in fast-twitch skeletal muscle SRvesicles than in cardiac SR vesicles, suggesting that SERCA1ais more resistant than SERCA2a to acidic pH (46). In our studies,however, we observed that acidic pH exerted a similar inhibitoryeffect on SERCA in TG and NTG hearts. Acidic pH lowered apparentCa²⁺ affinity and Ca²⁺ binding cooperativity. Although there are reports which indicatethat acidic pH enhances the Ca²⁺-binding cooperativity (when the free Ca²⁺ concentrations are controlled with buffers other than EGTA) (14),in this study we found that the Ca²⁺-binding isotherms at various pH levels remain the same in TGand NTG cardiac tissues. These data suggest that SERCA1a and SERCA2ahave similar pH dependence under a similar cardiac SR environment.The difference in pH dependence of Ca²⁺ uptake observed between fast-twitch skeletal SR and cardiac SRmay be due to differences in the SR membrane environments, includingphospholipid composition and tissue-specific modulators (suchas PLB). Recently, a low-molecular-weight proteolipid, sarcolipin,has been found to be mainly expressed in fast-twitch skeletalmuscle to regulate SERCA1 and has structural homology with PLB(38). Therefore, we should not exclude the possibility thatthe functional properties of SERCA isoforms may be additionallyregulated by the other tissue-specificmodulators.

	ACKNOWLEDGEMENTS

We thank Dr. Evangelia G. Kranias and Dr. Giuseppe Inesi for valuable advice on SR Ca²⁺ uptake and enzyme kinetic studies and Dr. Richard A. Walsh forsupport of thestudy.

	FOOTNOTES

This study was supported by National Heart, Lung, and Blood Institute Specialized Center of Research Grants HL-52318 (project3) (M. Periasamy) and HL-49428 (L. R.Jones)

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: M. Periasamy, Div. of Cardiology, Dept. of Internal Medicine, University of Cincinnati College of Medicine, 231 Bethesda Ave., Cincinnati, OH 45267-0542.

Received 13 May 1998; accepted in final form 10 September 1998.

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