Calcium uptake, calcium release and adenosinetriphosphatase activity in sarcoplasmic reticulum fragments deposited on millipore filters

Ligand binding to macromolecules or micelles: use of centrifugal ultrafiltration to measure low-affinity binding

We describe a method for estimating ligand binding to a macromolecular sample under conditions where this binding is of low affinity and must be measured under equilibrium conditions, without removal of the unbound ligand. The method is based on centrifugal ultrafiltration through a membrane with a molecular mass cut-off intermediate between that of the ligand and that of the target, and the amount of bound ligand is calculated from the difference between the (total) ligand in the concentrated sample and the (free) ligand in the ultrafiltrate. Centrifugal ultrafiltration makes it possible to separate free ligand from bound ligand (without changing its concentration) and to simultaneously concentrate the target (such that the proportion of bound ligand becomes significant, even under low-affinity binding conditions). We applied this technique, using Centricon 10 (Amicon) devices, to several cases (soluble proteins, intact membranes, detergent-solubilized proteins, and pure detergent micelles) and assessed its value with respect to the common artifacts that occur in other protocols involving protein retention on nitrocellulose filters (nonspecific ligand adsorption and protein denaturation).

Calcium additional to that bound to the transport sites is required for full activation of the sarcoplasmic reticulum Ca-ATPase from skeletal muscle

The sarcoplasmic reticulum Ca-ATPase is fully activated when approximately 1 microM [Ca2+] saturates the two transport sites; higher [Ca] inhibits the ATPase by competition of Ca-ATP with Mg-ATP as substrates. Here we describe a novel effect of EGTA and other chelators, raising the possibility of an additional activating effect of Ca in the sub- or low microM range. Sarcoplasmic reticulum membranes were isolated from rabbit skeletal muscles. The ATPase activity was measured after incubation at 37 degreesC in 3 mM ATP, 3 mM MgCl2, 50 mM MOPS-Tris (pH 7.2), 100 mM KCl, and variable CaCl2, EGTA and calcimycin. In the absence of added EGTA and Ca the ATPase activity is high due to contaminant Ca. The determination of the ATPase activity in the presence of increasing amounts of EGTA, without added Ca, yields a decreasing sigmoidal function. Ki ranged between 20 and 100 microM, depending on the enzyme concentration. Pi production is linear with time for several [EGTA] yielding suboptimal ATPase activities, which are inhibited by thapsigargin. These suboptimal Ca-ATPase activities are inhibited by preincubation of the enzyme in EGTA, at pH 7.2. This effect increases upon increasing EGTA concentration and preincubation time. The inhibitory effect of the previous exposure of the enzyme to EGTA is partially but significantly reverted by increasing [Ca2+] during incubations. Calcimycin and EDTA have similar effects as EGTA when added in preincubations. The effect of calcimycin is fully reverted by optimal [Ca2+] in incubations. The effects of EGTA, EDTA and calcimycin in preincubation are not additive. The results suggest that an additional calcium, lost during preincubations from a site with affinity near 1 microM, is necessary for full activation of the ATPase.

Direct demonstration of an acid-labile phosphoenzyme in the cycle of the sarcoplasmic reticulum Ca2(+)-dependent adenosinetriphosphatase

The Ca2(+)-dependent adenosinetriphosphatase (Ca2(+)-ATPase) from the sarcoplasmic reticulum (SR) of rat skeletal muscles is phosphorylated by inorganic phosphate (Pi) in the absence of Ca2+. The reaction can be described by the following simplified scheme: [formula: see text] where E-P is a covalent, acid-stable and ADP-insensitive phosphoenzyme, and E.Pi is a noncovalent and acid-labile complex. The reaction is Mg2(+)-dependent. Membrane fragments deposited on Millipore filters were successively perfused with two solutions, at constant flow. The effluent samples were analyzed. The perfused solutions were Ca2+ free and always contained 40% dimethylsulfoxide (DMSO), plus other reactants. Following the successive perfusion of solutions without and with [32P]Pi, 32P binding is only detected in the presence of Mg2+, indicating the formation of the phosphoenzymes (E.Pi and E-P). Following perfusions of the phosphoenzymes with 5% trichloroacetic acid, 32P release indicates the amount of the acid-labile moiety (E.Pi). After phosphorylations, the filters were washed with acid and unlabeled Pi, and the remaining radioactivity was measured to evaluate the acid-stable phosphoenzyme (E-P). The acid-labile and acid-stable phosphoenzymes amounted, respectively, 0.72 +/- 0.12, and 1.48 +/- 0.10 nmol of Pi/mg of protein ( +/- S.E., n = 5), after phosphorylations with 20 microM Pi. The results indicate: (1) The method allowed the evaluation of the acid-labile intermediate of the SR Ca2(+)-ATPase cycle. Keq = k2/k-2), in the above scheme, approaches 2.0. (2) The substrate of the phosphorylation reaction, in the presence of DMSO, is likely to be the Mg.Pi complex, since Mg2+ is necessary for step 1 in the above scheme.

Demonstration of the simultaneous activation of Ca2+-independent and Ca2+-dependent ATPases from rat skeletal muscle microsomes

The activation of the Ca2+-independent (basal) ATPase from rat skeletal muscle microsomes is demonstrated in the presence of enough Ca2+ to provide the simultaneous activation of the (Ca2+ + Mg2+)-ATPase. It was achieved taking advantage of the delayed inorganic phosphate (Pi) release due to the formation of a phosphoenzyme complex during the Ca2+-dependent enzymatic cycle, which is evidenced in fast experiments. The microsomes were immobilized on a filter and perfused at constant flow with an incubation medium which was briefly interrupted with a pulse of appropriate reactants to activate the ATPases, at 2 degrees C. Successive samples were collected after passing through the filter, at approx. 0.1 s intervals. The Pi effluent profile coincides with the pattern of the pulse when it activates only the Ca2+-independent ATPase, it appears delayed when the pulse activates only extra Pi production by the (Ca2+ + Mg2+)-ATPase, and it includes a rapid and a delayed component when both Ca2+-independent and Ca2+-dependent ATPases are activated simultaneously by the pulse.

Equilibrium and steady state thermodynamics of active transport systems studied on simple models simulating Ca2+ transport through sarcoplasmic reticulum membranes

Equilibrium and steady state conditions of primary active transport systems are analyzed in models simulating well known characteristics of calcium transport through sarcoplasmic reticulum membranes. The model for the equilibrium simulations is a closed system with two compartments and a vectorial chemical reaction coupling Ca transport and ATP breakdown. The chemical potential difference for Ca (delta mu Ca) is calculated as a function of the total amount of Ca (Cat) and nucleotides (Nt) in the system. Results are obtained by successive approximations along the thermodynamic pathway of the reaction, up to minimizing free energy of the system, since the solution of the explicit equations cannot be obtained with computers of current precision for data within physiological ranges. delta mu Ca and [Caout] are extremely dependent on Cat and Nt for certain combinations of the variables, i.e. [Caout] can be raised from 10(-8) to 10(-6) M when Cat varies from 0.998 to 1.002 mM, therefore, the running force of the spontaneous reaction is largely shifted by tiny changes in the parameters of the system. For steady state simulations, ATP supply to the system, ADP and Pi drainage, and Ca diffusion through the barrier, are assumed. Again, conditions within physiological ranges can be found where tiny changes in Cat, the rate of ATP supply, diffusion, the ratio between the volumes of the compartments, or a relative uncoupling between the transport and hydrolytic reactions, largely shifts delta mu Ca and [Caout], thus making the steady state highly unstable and therefore well designed to operate as an amplifier of physiological signals. The equilibrium model describes some physicochemical characteristics of the system; the steady state model is more useful to simulate several physiological situations.

Comparison of Ca2+, Sr2+, and Mn2+ fluxes in mitochondria of the perfused rat heart

The amount of readily exchangeable Ca2+ in mitochondria of an isolated working rat heart is less than 10 ng-ions/g heart. We therefore conclude that either no Ca2+ enters mitochondria or that the Ca+ which does enter is removed continuously. Using Sr2+ and Mn2+, we obtained evidence that the mitochondrial Na+-Ca2+ exchanger was indeed operational in releasing metal from mitochondria of the heart. When Ca2+ in the perfusate was replaced by Sr2+, we found that a significant amount of Sr2+ (approximately 100 ng-ions/g heart) entered mitochondria. When the heart then was returned to a Ca2+-containing perfusate, over 80% of the Sr2+ was washed out of mitochondria within 30 seconds. When low levels of Mn2+ were added to the perfusate, we found that Mn2+ accumulated in mitochondria irreversibly. This is evidence for the operation of the Na+-Ca2+ exchanger because Na+ was found to release Ca2+ and Sr2+ but not Mn2+ from isolated rat heart mitochondria. Our estimates indicate that when the Na+-Ca2+ exchanger is maximally operative, as in the Sr2+-perfused heart, the flux of Sr2+ through mitochondria is at most 10% of the total flux needed for the activation of contraction. The low level of Ca2+ in the mitochondria of Ca2+-perfused hearts suggests a much smaller flux of Ca2+ through the mitochondria in this case. We therefore conclude that mitochondria play little if any role in the beat-to-beat regulation of normal Ca2+ fluxes in the rat heart.

Relationship between calcium ion transport and (Ca2+ + Mg2+)-atpase activity in adipocyte endoplasmic reticulum

Calcium uptake by adipocyte endoplasmic reticulum was studied in a rapidly obtained microsomal fraction. The kinetics and ionic requirements of Ca2+ transport in this preparation were characterized and compared to those of (Ca2+ + Mg2+)-ATPase activity. The time course of Ca2+ uptake in the presence of 5 mM oxalate was nonlinear, approaching a steady-state level of 10.8--11.5 nmol Ca2+/mg protein after 3--4 min of incubation. The rate of Ca2+ transport was iM oxalate. The calculated initial rate of calcium uptake was 18.5 nmol Ca2+/mg protein per min. The double reciprocal plot of ATP concentration against transport rate was nonlinear, with apparent Km values of 100 muM and 7 muM for ATP concentration ranges above and below 50 muM, respectively. The apparent Km values for Mg2+ and Ca2+ were 132 muM and 0.36--0.67 muM, respectively. The energy of activation was 23.4 kcal/mol. These kinetic properties were strikingly similar to those of the microsomal (Ca2+ + Mg2+)-ATPase. The presence of potassium was required for maximum Ca2+ transport activity. The order of effectiveness of monovalent cations in stimulating both Ca2+ transport and (Ca2+ + Mg2+)-ATPase activity was K+ greater than Na+ = NH4+ greater than Li+. Ca2+ transport and (Ca2+ + Mg2+)-ATPase activity were both inhibited 10--20% by 6 mM procaine and less than 10% by 10 mM sodium azide. Both processes were completely inhibited by 3 mM dibucaine or 50 muM p-chloromercuribenzene sulfonate. The results indicate that Ca2+ transport in adipocyte endoplasmic reticulum is mediated by a (Ca2+ + Mg2+)-ATPase and suggest an important role for endoplasmic reticulum in control of intracellular Ca2+ distribution.