Activation of the sarcoplasmic reticulum Ca2+-ATPase induced by exercise.

Prolonged exercise has been shown to cause disruption of intracellular calcium homeostasis in skeletal muscle, which is normally maintained by the sarcoplasmic reticulum (SR) Ca2+-ATPase. We have investigated the response of this enzyme to increased intracellular calcium levels by investigating the functional and physical characteristics of the SR Ca2+-ATPase and membrane lipids following 2 h of treadmill running and throughout a period of post-exercise recovery. The Ca2+-ATPase of SR membranes purified from exercised rats shows increases in enzymatic activity correlating with post-exercise recovery time. Corresponding increases in active Ca2+-ATPase pump units are observed, as measured by the concentration of phosphorylated enzyme intermediate formed from ATP. However, catalytic turnover rates of the Ca2+-ATPase are unchanged. Using spin-label electron paramagnetic resonance to assess both membrane fluidity and associations between individual Ca2+-ATPase polypeptide chains, we find no exercise-induced alterations in membrane dynamics which could explain the observed increases in Ca2+-ATPase activity. Nor do we find evidence for altered membrane purification as a result of exercise. We suggest that the cell responds to the challenge of increased cytosolic calcium levels by increasing the proportion of functional SR Ca2+-ATPase proteins in the membrane for the rapid restoration of calcium homeostasis.

Adaptive changes in lipid composition of skeletal sarcoplasmic reticulum membranes associated with aging.

We have undertaken a detailed examination of changes associated with aging in lipid composition and corresponding physical properties of hindlimb skeletal sarcoplasmic reticulum (SR) membranes isolated from young (5 months), middle-aged (16 months), and old (28 months) Fischer strain 344 rats. Silica gel HPLC chromatography was used to separate phospholipid headgroup species. Subsequent reversed-phase HPLC was used to resolve fatty acid chain compositions of phosphatidylcholine, phosphatidylethanolamine, and phosphatidylinositol species. For all three phospholipid pools, significant age-related variations are observed in the abundance of multiple molecular species, particularly those having polyunsaturated fatty acid chains. Using mass spectrometry (fast atom bombardment and tandem techniques) to distinguish ester- from ether-linked phosphatidylethanolamine species, we demonstrate that overall plasmenylethanolamine content is substantially increased with age, from 48 mol% to 62 mol%. A substantial increase is also observed in the single molecular species 18:0-20:4 phosphatidylinositol suggesting implications for signalling pathways. In addition, associated with senescence we find a significant increase in the rigidifying lipid, cholesterol. Despite these changes in lipid composition of different aged animals, the average bilayer fluidity examined at several bilayer depths with stearic acid spin labels, is not altered. Neither do we find differences in the rotational mobility of maleimide spin-labeled Ca(2+)-ATPase, as determined from saturation-transfer electron paramagnetic resonance, which is sensitive to both the fluidity of lipids directly associated with the Ca(2+)-ATPase and to its association with proteins.

In vivo aging of rat skeletal muscle sarcoplasmic reticulum Ca-ATPase. Chemical analysis and quantitative simulation by exposure to low levels of peroxyl radicals.

Sarcoplasmic reticulum (SR) Ca-ATPase of young adult (5 months) and aged (28 months) Fischer 344 male rat skeletal muscle was analyzed for posttranslational modifications as a result of biological aging and their potential functional consequences. The significant differences in the amino acid composition were a 6.8% lower content of sulfhydryl groups and a ca. 4% lower content of Arg residues of the Ca-ATPase from old as compared to young rats. Based on a total of 24 Cys residues the difference in protein thiols corresponds to a loss of 1.5 mol Cys/mol Ca-ATPase as a result of in vivo aging. The loss of Cys residues was not accompanied by a loss of enzyme activity though the 'aged' Ca-ATPase was more sensitive to heat inactivation, aggregation, and tryptic digestion. A comparison of the total sulfhydryl content of all SR proteins present revealed a 13% lower amount for SR vesicles isolated from aged rats. Compared to the alterations of Cys and Arg, there was only a slight and probably physiologically insignificant increase of protein carbonyls with aging, i.e. from 0.32 to 0.46 mol carbonyl groups per mol of Ca-ATPase. When SR vesicles from young rats were exposed to AAPH-derived peroxyl radicals, there was a loss of ca. 1.38 x 10(-4) M total SR sulfhydryl groups per 4 mg SR protein/ml (corresponding to ca. 25%) and a loss of 9.6 x 10(-5) M Ca-ATPase sulfhydryl groups (corresponding to ca. 31%) per 1.6 x 10(-5) M initiating peroxyl radicals, indicating that the stoichiometry of sulfhydryl oxidation was > or = 6 oxidized thiols per initiating AAPH-derived peroxyl radical. Besides Cys, the exposure to AAPH-derived radicals caused a slight loss of Ca-ATPase Arg, Met, and Ser residues. Most importantly, the SR Ca-ATPase exposed to this low concentration of peroxyl radicals displayed physical and functional properties quantitatively comparable to those of SR Ca-ATPase isolated from aged rats, i.e. no immediate loss of activity, increased susceptibility to heat inactivation, aggregation, and tryptic digestion. Moreover, a comparison of kinetically early tryptic fragments by HPLC-electrospray MS and N-terminal sequencing revealed that similar peptide fragments were produced from 'aged' and AAPH-oxidized Ca-ATPase which were not (or kinetically significantly later) generated from the 'young' Ca-ATPase, suggesting some conformational changes of the Ca-ATPase as a result of aging and AAPH-exposure. All except one of these peptides originated from locations remote from the nucleotide-binding and calcium-binding sites. The latter results suggest that aging and AAPH-exposure may target similar Cys residues, mainly at locations remote from the nucleotide-binding and calcium-binding sites, rationalizing the fact that Cys oxidation did not immediately cause inactivation of the Ca-ATPase. Our results provide a quantitative estimate of a net concentration of reactive oxygen species, here peroxyl radicals, which induces physical and chemical alterations of the SR Ca-ATPase quantitatively comparable to those induced by in vivo aging.

Decreased conformational stability of the sarcoplasmic reticulum Ca-ATPase in aged skeletal muscle.

Sarcoplasmic reticulum (SR) membranes purified from young adult (4-6 months) and aged (26-28 months) Fischer 344 male rat skeletal muscle were compared with respect to the functional and structural properties of the Ca-ATPase and its associated lipids. While we find no age-related alterations in (1) expression levels of Ca-ATPase protein, and (2) calcium transport and ATPase activities, the Ca-ATPase isolated from aged muscle exhibits more rapid inactivation during mild (37 degrees C) heat treatment relative to that from young muscle. Saturation-transfer EPR measurements of maleimide spin-labeled Ca-ATPase and parallel measurements of fatty acyl chain dynamics demonstrate that, accompanying heat inactivation, the Ca-ATPase from aged skeletal muscle more readily undergoes self-association to form inactive oligomeric species without initial age-related differences in association state of the protein. Neither age nor heat inactivation results in differences in acyl chain dynamics of the bilayer including those lipids at the lipid-protein interface. Initial rates of tryptic digestion associated with the Ca-ATPase in SR isolated from aged muscle are 16(+/- 2)% higher relative to that from young muscle. indicating more solvent exposure of a portion of the cytoplasmic domain. During heat inactivation these structural differences are amplified as a result of immediate and rapid further unfolding of the Ca-ATPase isolated from aged muscle relative to the delayed unfolding of the Ca-ATPase isolated from young muscle. Thus age-related alterations in the solvent exposure of cytoplasmic peptides of the Ca-ATPase are likely to be critical to the loss of conformational and functional stability.

Benzophenone-sensitized photooxidation of sarcoplasmic reticulum membranes: site-specific modification of the Ca(2+)-ATPase.

Benzophenone (BP) was used as a photosensitizer to initiate lipid peroxidation in model and native biological membranes at concentrations of BP that do not perturb bilayer structure, as assessed by stearic acid spin label dynamics. Illumination of BP partitioned into sarcoplasmic reticulum membranes (SR) results in an exponential decay of BP and a linear accumulation of conjugated dienes and other products of lipid peroxidation as observed previously for micelles of linoleic acid [Marcovic and Patterson. Photochem. Photobiol. 58:329-334, 1993]. Lipid peroxidation was substantially inhibited in the presence of membrane-spanning proteins in SR compared to protein-free lipid vesicles, suggesting the competitive reaction of the initiator (triplet BP) and BP-derived radical species with protein groups. Modification of the predominant integral membrane protein, the Ca(2+)-ATPase, was demonstrated by changes in Ca(2+)-ATPase amino acid composition as well as by its functional inhibition. The rate of calcium transport showed an immediate exponential decay to completion, while calcium-dependent ATPase activity exhibited an initial lag before modest inactivation. These results are consistent with the respective localization of calcium transport sites within membrane-spanning peptides and the ATP-binding site within the cytosolic domain of the Ca(2+)-ATPase, further suggesting that photosensitization of BP models oxidative stress inside the hydrophobic interior of the SR membrane.

Accumulation of nitrotyrosine on the SERCA2a isoform of SR Ca-ATPase of rat skeletal muscle during aging: a peroxynitrite-mediated process?

The SR Ca-ATPase in skeletal muscle SR vesicles isolated from young adult (5 months) and aged (28 months) rats was analyzed for nitrotyrosine. Only the SERCA2a isoform contained significant amounts with approximately one and four nitrotyrosine residues per young and old Ca-ATPase, respectively. The in vitro exposure of SR vesicles of young rats to peroxynitrite yielded selective nitration of the SERCA2a Ca-ATPase even in the presence of excess SERCA1a. No nitration was observed during the exposure of SR vesicles to nitric oxide in the presence of O2. These data suggest the vivo presence of peroxynitrite in skeletal muscle. The greater nitrotyrosine content of SERCA2a from aged tissue implies an age-associated increase in susceptibility to oxidation by this species.

Age-related chemical modification of the skeletal muscle sarcoplasmic reticulum Ca-ATPase of the rat.

Much emphasis has been placed on the description of age-related changes in skeletal muscle physiology. The present paper summarizes the chemical characterization of age-related post-translational modifications of the rat skeletal muscle sarcoplasmic reticulum (SR) Ca-ATPase isoforms SERCA1 and SERCA2a obtained from 5- and 28-month-old male Fischer 344 rats. Whereas the SERCA1 isoform shows an age-dependent loss of Cys and Arg, the SERCA2a isoform displays a loss of Cys but also a significant accumulation of 3-nitrotyrosine. The in vitro exposure of SR vesicles particularly rich in SERCA1 (>90%) from 5-month-old rats to low levels of peroxyl radicals yielded SR vesicles with physical properties of the SR Ca-ATPase identical to those observed for the SR Ca-ATPase obtained from 28-month-old rats. The peroxyl radical-modified SR Ca-ATPase showed a loss of Cys and Arg but also of Ser and Met, indicating that peroxyl radicals, though a good model oxidant to generate 'aged' SR vesicles, may not be the only oxidant responsible for the chemical modification of the SR Ca-ATPase in vivo. In fact, efficient thiol modification of the SERCA1 was also observed after the exposure to peroxynitrite. Peroxynitrite selectively nitrated the tyrosine residues of the SERCA2a isoform even in the presence of an excess of SERCA1. Thus, peroxynitrite may be responsible for the age-dependent modification of the SR Ca-ATPase in vivo.

Decrease in Ca-ATPase activity in aged synaptosomal membranes is not associated with changes in fatty acyl chain dynamics.

We have examined lipid peroxidation (LPO) and fatty acid acyl chain dynamics in synaptosomal membranes isolated from aged rat (Fischer 344 x Brown Norway F1 hybrids) brains, correlating these results with measurements of enzymatic activity of the synaptic plasma membrane Ca2(+)-ATPase (PMCA). Calcium-dependent ATPase activity in these membranes exhibits progressive decreases with a maximal loss of activity with age of approximately 35%. The sensitivity of this membrane-bound ion transporter to the lipid composition of the surrounding membrane, as well as the high abundance of oxidatively sensitive polyunsaturated fatty acyl chains in synaptosomal membranes, suggests that this age-related loss in catalytic turnover may result from LPO-mediated protein modification and/or changes in the physical structure of the bilayer. However, high-performance liquid chromatography analysis of 2,4-dinitrophenylhydrazone derivatives reveals no significant age-related increases in the content of reactive aldehydes (malondialdehyde, formaldehyde, acetaldehyde or acetone) which comprise breakdown products of lipid peroxidation. Electron paramagnetic resonance measurements employing 5- and 12-stearic acid spin labels with the nitroxide reporter groups at two depths in the bilayer were used to assess the fatty acyl chain dynamics (fluidity) of synaptosomal membranes. The resulting spectra demonstrate anisotropic lipid dynamics of two populations of lipids, i.e. lipids in direct association with membrane proteins (boundary lipids) and bulk lipids that do not directly associate with proteins. The nanosecond dynamics of both lipid populations is unaltered with age indicating that any compositional changes occurring with age are insufficient to result in alterations in bilayer fluidity relevant to PMCA activity. Thus, the observed age-related decline in PMCA activity may be explained by direct modification of membrane protein.

Protein oxidation and age-dependent alterations in calcium homeostasis.

Alterations in the capacity to maintain normal calcium homeostasis have been suggested to underlie the reduced cellular function characteristic of the aging process, and to predispose the senescent organism to a host of diverse pathologies including cancer, heart disease, and a range of muscle and neurodegenerative diseases. Therefore, critical to the eventual treatment of many age-related diseases has been the identification of both post-translational modifications and the underlying structural changes that result in an age-related decline in the function of critical calcium regulatory proteins. In brain, multiple methionines within the calcium signaling protein calmodulin (CaM) are oxidized to their corresponding methionine sulfoxides during aging, resulting in an inability to activate a range of target proteins, including the plasma membrane (PM) Ca-ATPase involved in the maintenance of the low intracellular calcium levels necessary for intracellular signaling. Likewise, changes in the transport activity of the PM-Ca-ATPase occur during aging. In muscle, the function of the SERCA2a isoform of the Ca-ATPase within the sarcoplasmic reticulum (SR) declines during aging as a result of the nitration of selected tyrosines. The age-related loss-of-function of these critical calcium regulatory proteins are consistent with observed increases in intracellular calcium levels within senescent cells. A possible regulatory role for these post-translational modifications is discussed, since they have the potential to be reversed following the restoration of normal cellular redox conditions by intracellular repair enzymes that are specific for these post-translational modifications. It is suggested that the reversible oxidation of critical calcium regulatory proteins within excitable cells by reactive oxygen species functions to enhance cellular survival under conditions of oxidative stress by reducing the energy expenditure within excitable cells. Thus, a diminished ability to efficiently generate cellular ATP may ultimately underlie the loss of calcium homeostasis and cellular function during aging.

The oxidative inactivation of sarcoplasmic reticulum Ca(2+)-ATPase by peroxynitrite.

The oxidative inactivation of rabbit skeletal muscle Ca(2+)-ATPase in sarcoplasmic reticulum (SR) vesicles by peroxynitrite (ONOO-) was investigated. The exposure of SR vesicles (10 mg/ml protein) to low peroxynitrite concentrations ( < or = 0.2 mM) resulted in a decrease of Ca(2+)-ATPase activity primarily through oxidation of sulfhydryl groups. Most of this deactivation (ca.70%) could be chemically reversed by subsequent reduction of the enzyme with either dithiothreitol (DTT) or sodium borohydride (NaBH4), indicating that free cysteine groups were oxidized to disulfides. The initial presence of 5 mM glutathione failed to protect the SR Ca(2+)-ATPase activity. However, as long as peroxynitrite concentrations were kept < or = 0.45 mM, the efficacy of DTT to reverse Ca(2+)-ATPase inactivation was enhanced for reaction mixtures which initially contained 5 mM glutathione. At least part of the disulfides were formed intermolecularly since gel electrophoresis revealed protein aggregation which could be reduced under reducing conditions. The application of higher peroxynitrite concentrations ( > or = 0.45 mM) resulted in Ca(2+)-ATPase inactivation which could not be restored by exposure of the modified protein to reducing agents. On the other hand, treatment of modified protein with NaBH4 recovered all SR protein thiols. This result indicates that possibly the oxidation of other amino acids contributes to enzyme inactivation, corroborated by amino acid analysis which revealed some additional targets for peroxynitrite or peroxynitrite-induced processes such as Met, Lys, Phe, Thr, Ser, Leu and Tyr. Tyr oxidation was confirmed by a significant lower sensitivity of oxidized SR proteins to the Lowry assay. However, neither bityrosine nor nitrotyrosine were formed in significant yields, as monitored by fluorescence spectroscopy and immunodetection, respectively. The Ca(2+)-ATPase of SR is involved in cellular Ca(2+)-homeostasis. Thus, peroxynitrite mediated oxidation of the Ca(2+)-ATPase might significantly contribute to the loss of Ca(2+)-homeostasis observed under biological conditions of oxidative stress.

Decreased plasma membrane calcium transport activity in aging brain.

We have assessed the functional properties of both calmodulin (CaM) and the plasma membrane Ca(2+)-ATPase in brains of young, middle aged, and old Fisher 344 rats. Under optimal conditions of saturating Ca2+ and ATP, the CaM-activated Ca(2+)-ATPase activity was decreased with increasing age, particularly when CaM isolated from the brains of aged rats was used to stimulate the enzyme. In the case of CaM, structural modifications within the primary sequence of the protein from aged brains were identified. We found that during normal biological aging approximately 6 methionine residues were modified to their corresonding sulfoxide per CaM, and no other amino acids were modified. Some aspects of the age-related decline in the effectiveness of CaM as an activator of Ca(2+)-ATPase could be simulated using a range of reactive oxygen species (including hydrogen peroxide and oxoperoxynitrite) and, in the latter case, the extent of oxidative modification of specific methionine residues was directly related to their surface accessibility. The pattern of oxidative modification of the methionines in the aged CaM was less straightforward, though both in vitro oxidation of CaM and aging within the brain markedly decreased the functional properties of this important Ca(2+)-regulating protein.

Rotational dynamics of lipid and the Ca-ATPase in sarcoplasmic reticulum. The molecular basis of activation by diethyl ether.

We have investigated the role of lipid and protein dynamics in the activation of the Ca2+-dependent ATPase in sarcoplasmic reticulum (SR) by diethyl ether. Conventional and saturation-transfer electron paramagnetic resonance (EPR) were used to probe rotational motions of spin labels attached either to fatty acid hydrocarbon chains or to the Ca-ATPase in SR. We confirm previous studies (Salama, G., and Scarpa, A. (1980) J. Biol. Chem. 255, 6525-6528; Salama, G., and Scarpa, A. (1983) Biochem. Pharmacol. 32, 3465-3477; Kidd, A., Scales, D., and Inesi, G. (1981) Biochem. Biophys. Acta 65, 124-131) reporting that addition of diethyl ether to SR results in an approximately 2-fold enzymatic activation, without loss of coupling. Diethyl ether progressively fluidizes the SR membrane with respect to lipid hydrocarbon chain dynamics probed at several depths in the bilayer. Digital substractions, used to analyze two-component lipid spin label spectra, reveal that a 2-fold mobilization occurs in the population of lipid probes motionally restricted by the protein, while the remaining more mobile population is less affected. The microwave saturation properties of lipid probes also indicate that restricted motions of these probes are mobilized in maximally activated SR membranes. Saturation-transfer EPR, applied to maleimide spin-labeled Ca-ATPase, demonstrates that a 2-fold increase in microsecond rotational motion of the Ca-ATPase correlates with the maximal enzymatic activation. Effects of diethyl ether on both the enzymatic activity and molecular dynamics are completely reversible by dilution with buffer. We propose that ether activates by selectively mobilizing lipid chains adjacent to the enzyme, thus facilitating protein motions that are essential for calcium transport.

Frequency-domain fluorescence spectroscopy resolves the location of maleimide-directed spectroscopic probes within the tertiary structure of the Ca-ATPase of sarcoplasmic reticulum.

We have used fluorescence spectroscopy to characterize three covalently bound spectroscopic maleimide derivatives with respect to their location within the tertiary structure of the Ca-ATPase of sarcoplasmic reticulum (SR). These derivatives include (1) 2-(4'-maleimidoanilino)naphthalene-6-sulfonic acid, (2) 4-(dimethylamino)azobenzene-4'-maleimide, and (3) fluorescein 5'-maleimide. Biochemical assays demonstrate that modification with any of these three derivatives results in the same functional effects, observed following derivatization of cysteines 344 and 364 by N-ethylmaleimide [Saito-Nakatsuka et al. (1987) J. Biochem. (Tokyo) 101, 365-376]. These residues bracket the ATPase's phosphorylation site (Asp 351) and thus may provide spectroscopic probes of the protein's conformation in this essential region. In agreement with sequencing results, SDS-polyacrylamide gels show that maleimide-modified SR exhibits fluorescence exclusively on the A1 tryptic fragment of the Ca-ATPase. Extensive tryptic digestion followed by centrifugation demonstrates essentially all of the fluorescence was associated with the soluble rather than insoluble (membrane-associated) peptides, confirming the predicted extramembranous location of these residues. Utilizing frequency-domain fluorescence spectroscopy, we were able to recover the transient effects associated with a distribution of donor-acceptor distances. We find from these fluorescence resonance energy transfer measurements that covalently bound maleimide probes are 36 A apart, independent of whether a discrete distance is assumed or a distance distribution model is utilized, in which the conformational variability of the protein is taken into account. While a unimodal distance distribution is adequate to describe the intensity decay associated with maleimide-directed donor-acceptor pairs, a bimodal distribution of distances is necessary to describe the frequency response associated with the energy transfer between maleimide-directed chromophores and other covalently bound probes on the Ca-ATPase, consistent with the large spatial separation observed between maleimides. We recover mean distances of 42 and 77 A between maleimide sites and bound FITC (Lys 515) and mean distances of 28 and 37 A between the maleimide- and the iodoacetamide-directed probes (Cys 670 and 674, whose close proximity approximates a single locus). The measured distances are presented in a model and have permitted us to describe a unique arrangement of these covalently bound probes within both the secondary and tertiary structure of the Ca-ATPase. The resolution inherent in the frequency-domain fluorescence technique to multiple donor-acceptor distances should be generally applicable to a wide range of biological systems in which specific labeling of single unique donor-acceptor sites is not feasible.

Temperature dependence of rotational dynamics of protein and lipid in sarcoplasmic reticulum membranes.

We have investigated the relationship between function and molecular dynamics of both the lipid and the Ca-ATPase protein in sarcoplasmic reticulum (SR), using temperature as a means of altering both activity and rotational dynamics. Conventional and saturation-transfer electron paramagnetic resonance (EPR) was used to probe rotational motions of spin-labels attached either to fatty acid hydrocarbon chains or to the Ca-ATPase sulfhydryl groups in SR. EPR studies were also performed on aqueous dispersions of extracted SR lipids, in order to study intrinsic lipid properties independent of the protein. While an Arrhenius plot of the Ca-ATPase activity exhibits a clear change in slope at 20 degrees C, Arrhenius plots of lipid hydrocarbon chain mobility are linear, indicating that an abrupt thermotropic change in the lipid hydrocarbon phase is not responsible for the Arrhenius break in enzymatic activity. The presence of protein was found to decrease the average hydrocarbon chain mobility, but linear Arrhenius plots were observed both in the intact SR and in extracted lipids. Lipid EPR spectra were analyzed by procedures that prevent the production of artifactual breaks in the Arrhenius plots. Similarly, using sample preparations and spectral analysis methods that minimize the temperature-dependent contribution of local probe mobility to the spectra of spin-labeled Ca-ATPase, we find that Arrhenius plots of overall protein rotational mobility also exhibit no change in slope. The activation energy for protein mobility is the same as that of ATPase activity above 20 degrees C; we discuss the possibility that overall protein mobility may be essential to the rate-limiting step above 20 degrees C.

Lipid fluidity directly modulates the overall protein rotational mobility of the Ca-ATPase in sarcoplasmic reticulum.

We have developed a quantitative and relatively model-independent measure of lipid fluidity using EPR and have applied this method to compare the temperature dependence of lipid hydrocarbon chain fluidity, overall protein rotational mobility, and the calcium-dependent enzymatic activity of the Ca-ATPase in sarcoplasmic reticulum. We define membrane lipid fluidity to be T/eta, where eta is the viscosity of a long chain hydrocarbon reference solvent in which a fatty acid spin label gives the same EPR spectrum (quantitated by the order parameter S) as observed for the same probe in the membrane. This measure is independent of the reference solvent used as long as the spectral line shapes in the membrane and the solvent match precisely, indicating that the same type of anisotropic probe motion occurs in the two systems. We argue that this empirical measurement of fluidity, defined in analogy to the macroscopic fluidity (T/eta) of a bulk solvent, should be more directly related to protein rotational mobility (and thus to protein function) than are more conventional measures of fluidity, such as the rate or amplitude of rotational motion of the lipid hydrocarbon chains themselves. This new definition thus offers a fluidity measure that is more directly relevant to the protein's behavior. The direct relationship between this measure of membrane fluidity and protein rotational mobility is supported by measurements in sarcoplasmic reticulum. The overall rotational motion of the spin-labeled Ca-ATPase protein was measured by saturation-transfer EPR. The Arrhenius activation energy for protein rotational mobility (11-12 kcal/mol/degree) agrees well with the activation energy for lipid fluidity, if defined as in this study, but not if more conventional definitions of lipid fluidity are used. This agreement, which extends over the entire temperature range from 0 to 40 degrees C, suggests that protein mobility depends directly on lipid fluidity in this system, as predicted from hydrodynamic theory. The same activation energy is observed for the calcium-dependent ATPase activity under physiological conditions, suggesting that protein rotational mobility (dependent on lipid fluidity) is involved in the rate-limiting step of active calcium transport.

Phosphorylation-dependent changes in the spatial relationship between Ca-ATPase polypeptide chains in sarcoplasmic reticulum membranes.

In order to investigate possible structural changes associated with the coupling mechanisms of the Ca-ATPase in sarcoplasmic reticulum membranes, we have utilized fluorescence resonance energy transfer between spectroscopic probes covalently bound to different domains of the ATPase. Using time-correlated single photon counting, we have directly measured the energy transfer efficiency between 5-[2-[(iodoacetyl)amino]ethyl]aminonaphthalene-1-sulfonic acid (IAEDANS), that is specifically bound to the B trypic fragment at cysteines 670 and 674 and acceptors covalently bound either near the nucleotide binding site, i.e. fluorescein 5-isothiocyanate at lysine 515, also on the B fragment, or maleimide-directed probes specifically located on the A1, tryptic fragment, i.e. 4-dimethylaminoazobenzene-4'-maleimide (DABmal) or fluorescein-5-maleimide (Fmal), probably at cysteines 344 and 364. All of these donor-acceptor pairs exhibit energy transfer both within and between Ca-ATPase molecules allowing us to investigate spatial relationships between the A1 and B domains and between different ATPase polypeptide chains. Differentiation between the intra- and intermolecular components of energy transfer was accomplished in two ways: 1) by comparing the transfer efficiencies in native membranes before and after detergent solubilization and 2) by reconstituting ATPase chains that have already been labeled with either the donor or acceptor chromophores. Using this approach, we find no significant change in the intramolecular transfer efficiency between any of these donor-acceptor pairs either upon binding of calcium to the high affinity sites or upon stabilization of the phosphoenzyme intermediate, indicating that there are no large structural changes within the B tryptic fragment or, alternatively, between the A1 and B fragments. With respect to intermolecular energy transfer, we observe no effect of calcium binding on the unliganded enzyme with either donor-acceptor pair. However, formation of the phosphoenzyme intermediate results in a measurable increase in the transfer efficiency between IAEDANS and DABmal (or Fmal); this increase is reversible upon phosphoenzyme destabilization by subsequent addition of calcium. There is no corresponding change in the intermolecular component of fluorescence resonance energy transfer between IAEDANS and fluorescein 5-isothiocyanate, indicating that the change in fluorescence resonance energy transfer probably occurs as a result of reorientation of associated ATPase polypeptide chains with respect to one another.

Altered turnover of calcium regulatory proteins of the sarcoplasmic reticulum in aged skeletal muscle.

We have measured the in vivo protein turnover for the major calcium regulatory proteins of the sarcoplasmic reticulum from the skeletal muscle of young adult (7 months) and aged (28 months) Fischer 344 rats. From the time course of the incorporation and decay of protein-associated radioactivity after a pulse injection of [14C]leucine and correcting for leucine reutilization, in young rats, the apparent half-lives for calsequestrin, the 53-kDa glycoprotein, and ryanodine receptor are 5.4 +/- 0.4, 6.3 +/- 1.3, and 8.3 +/- 1.3 days, respectively. A half-life of 14.5 +/- 2.5 days was estimated for the Ca-ATPase isolated from young muscle. Differences in protein turnover associated with aging were determined using sequential injection of two different isotopic labels ([14C]leucine and [3H]leucine) to provide an estimate of protein synthesis and degradation within the same animal. The Ca-ATPase and ryanodine receptor isolated from aged muscle exhibits 27 +/- 5% and 25 +/- 3% slower protein turnover, respectively, relative to that from young muscle. In contrast, the 53-kDa glycoprotein exhibits a 25 +/- 5% more rapid turnover in aged SR, while calsequestrin exhibits no age-dependent alteration in turnover. Statistical analysis comparing the sensitivity of various methods for discriminating different rates of protein turnover validates the approach used in this study and demonstrates that the use of two isotopic labels provides at least a 6-fold more sensitive means to detect age-related differences in protein turnover relative to other methods.

Lysophosphatidylcholine modulates catalytically important motions of the Ca-ATPase phosphorylation domain.

Catalytically important motions of the Ca-ATPase, modulated by the physical properties of surrounding membrane phospholipids, have been suggested to be rate-limiting under physiological conditions. To identify the nature of the structural coupling between the Ca-ATPase and membrane phospholipids, we have investigated the functional and structural effects resulting from the incorporation of the lysophospholipid 1-myristoyl-2-hydroxy-sn-glycerol-3-phosphocholine (LPC) into native sarcoplasmic reticulum (SR) membranes. Nonsolubilizing concentrations of LPC abolish changes in fluorescence signals associated with either intrinsic or extrinsic chromophores that monitor normal conformational transitions accompanying calcium activation of the Ca-ATPase. There are corresponding decreases in the rates of calcium transport coupled to ATP hydrolysis, suggesting that LPC may increase conformational barriers associated with catalytic function. Fluorescence anisotropy measurements of the lipid analogue 1-(4-trimethylammoniumphenyl)-6-phenyl-1,3,5-hexatriene (TMA-DPH) partitioned into SR membranes indicate that LPC does not significantly modify lipid acyl chain rotational dynamics, suggesting differences in headgroup conformation between LPC and diacylglycerol phosphatidylcholines. Complementary measurements using phosphorescence anisotropy of erythrosin isothiocyanate at Lys464 on the Ca-ATPase provide a measure of the dynamic structure of the phosphorylation domain, and indicate that LPC restricts the amplitude of rotational motion. These results suggest a structural linkage between the cytosolic phosphorylation domain and the conformation of membrane phospholipid headgroups. Thus, changes in membrane phospholipid composition can modulate membrane surface properties and affect catalytically important motions of the Ca-ATPase in a manner that suggests a role for LPC generated during signal transduction.