Charlotte A. Tate

Palmitylcarnitine inhibition of the calcium pump in cardiac sarcoplasmic reticulum: A possible role in myocardial ischemia

Abstract Palmitylcarnitine is a time-dependent inhibitor of the Ca 2 + -ATPase activity of cardiac sarcoplasmic reticulum isolated from adult dogs. Half-maximal inhibition was obtained at approximately 20 μM (2 μmoles/mg). The extent of inhibition depended on the ratio of palmitylcarnitine to sarcoplasmic reticulum protein. Calcium uptake by cardiac sarcoplasmic reticulum (measured in the presence of sodium oxalate) was found to be even more sensitive to inhibition by palmitylcarnitine and complete inhibition was obtained at concentrations as low as 2.5 μM (0.25 μmole/mg) following preincubation. Calcium binding (measured in the absence of oxalate) was inhibited by palmitylcarnitine and calcium release was stimulated at similar ratios. The level of palmitylcarnitine has been reported to increase several fold in myocardial ischemia and inhibition of the sarcoplasmic reticulum calcium pump could conceivably contribute either to the initial loss of contractility or the subsequent inability to restore full contractile function after prolonged ischemia.

Calcium uptake by two preparations of mitochondria from heart

Ca/+ transport and respiratory characteristics of two preparations of cardiac mitochondria (Palmer, J.W., Tandler, B. and Hoppel, C.L. (1977) J. Biol. Chem. 252, 8731-8739) isolated using polytron homogenization (subsarcolemmal mitochondria) and limited Nagarse exposure (intermyofibrillar mitochondria) are described. The Nagarse procedure yields mitochondria with 50% higher rates of oxidative phosphorylation than the polytron-prepared mitochondria in both rat and dog. Rat hear intermyofibrillar mitochondria contain 50% more cytochrome aa3 than the polytron preparation, whereas in the dog, cytochrome aa3 content is not significantly different. Cytochrome oxidase activities and cytochrome c, c1 and b contents were comparable in both populations of rat and dog heart mitochondria. The V of succinate-supported Ca2+ accumulation for Nagarse-prepared mitochondria from rat heart was 1.8-fold higher than the polytron-prepared mitochondria. In dog heart, the Nagarse preparation showed a 3.0-fold higher V for Ca2+ uptake compared to the polytron preparation. A lower apparent affinity for Ca2+ was demonstrated in the intermyofibrillar mitochondria for both species (Km is 2-2.5-fold higher). The Hill coefficient was 1 both mitochondrial types. Subsarcolemmal mitochondria from both species were treated with Nagarse to determine the role of this treatment on the observed differences. Nagarse did not alter any kinetic parameter of Ca2+ uptake. The properties of these mitochondria with reference to their presumed intracellular location may pertain to the role of mitochondria as an intracellular Ca2+ buffering mechanism in contractile tissue.

Developmental regulation of the sarcoplasmic reticulum calcium pump in the rabbit heart.

ABSTRACT: Previous studies have demonstrated that myocardial function changes during mammalian perinatal development. The purpose of this study was to evaluate the subcellular basis underlying the slower relaxation in the developing heart by examining perinatal changes in sarcoplasmic reticulum (SR) function, and in SR Ca2+ pump protein and mRNA abundance. We measured Ca2+ uptake and ATPase rates in isolated fetal, newborn, and adult rabbit cardiac SR membranes. In fetal and adult SR membranes, we estimated the active Ca2+ pump protein content by measuring the steady state Ca2+-dependent phosphoenzyme content; the total Ca2+ pump protein content was estimated by Western analysis of the immuno-reactive Ca2+ pumps. We isolated RNA from fetal and adult hearts and estimated the SR Ca2+ pump mRNA content by Northern analysis. Ca2+ uptake and ATPase rates were significantly lower in the fetal and newborn SR membranes compared with the adult. The contents of active and total Ca2+ pump protein and of Ca2+ pump mRNA were 52–63% lower in the fetus than in the adult. These results indicate that a great deal of the slower sarcoplasmic reticulum Ca1+ uptake and ATPase rates in the fetal rabbit heart can be related to lower Ca2+ pump mRNA and protein contents. It is evident that transcriptional and/or posttran-scriptional regulation of the SR Ca2+ pump may form an important part of the subcellnlar basis of the perinatal change in mammalian cardiac relaxation.

Phospholipid asymmetry in the isolated sarcoplasmic reticulum membrane

The total phospholipid content and distribution of phospholipid species between the outer and inner monolayers of the isolated sarcoplasmic reticulum membrane was measured by phospholipase A2 activities and neutron diffraction. Phospholipase measurements showed that specific phospholipid species were asymmetric in their distribution between the outer and inner monolayers of the sarcoplasmic reticulum lipid bilayer; phosphatidylcholine (PC) was distributed 48/52 +/- 2% between the outer and inner monolayer of the sarcoplasmic reticulum bilayer, 69% of the phosphatidyl-ethanolamine (PE) resided mainly in the outer monolayer of the bilayer, 85% of the phosphatidylserine (PS) and 88% of the phosphatidylinositol (PI) were localized predominantly in the inner monolayer. The total phospholipid distribution determined by these measurements was 48/52 +/- 2% for the outer/inner monolayer of the sarcoplasmic reticulum lipid bilayer. Sarcoplasmic reticulum phospholipids were biosynthetically deuterated and exchanged into isolated vesicles with both a specific lecithin and a general exchange protein. Neutron diffraction measurements directly provided lipid distribution profiles for both PC and the total lipid content in the intact sarcoplasmic reticulum membrane. The outer/inner monolayer distribution for PC was 47/53 +/- 1%, in agreement with phospholipase measurements, while that for the total lipid was 46/54 +/- 1%, similar to the phospholipase measurements. These neutron diffraction results regarding the sarcoplasmic reticulum membrane bilayer were used in model calculations for decomposing the electron-density profile structure (10 A resolution) of isolated sarcoplasmic reticulum previously determined by X-ray diffraction into structures for the separate membrane components. These structure studies showed that the protein profile structure within the membrane lipid bilayer was asymmetric, complementary to the asymmetric lipid structure. Thus, the total phospholipid asymmetry obtained by two independent methods was small but consistent with a complementary asymmetric protein structure, and may be related to the highly vectorial functional properties of the calcium pump ATPase protein in the sarcoplasmic reticulum membrane.

Age-Related Levels of GABA/Benzodiazepine Binding Sites in Cerebrum of F-344 Rats: Effects of Exercise

We examined gamma-aminobutyric acid (GABA), benzodiazepine and convulsant sites of postsynaptic GABA/benzodiazepine receptors (GBZR) in cerebral membranes of inbred Fischer 344 male rats as a function of age. In aged rats (23 to 24 months), the benzodiazepine binding site as determined by [3H]flunitrazepam was 47% and 43% lower than corresponding values in young adult (3 to 4 months) and mature (10 to 12 months) rats, respectively. The decrease was due to the loss of binding density rather than a change in affinity. No statistically significant age-related changes in [3H]muscimol binding were observed when 5 nM or 40 nM labeled muscimol were used. GABA produced a dose-dependent stimulation of flunitrazepam binding in all age groups, but the maximum stimulation in aged animals was significantly higher (24%) than in young and mature animals. The [35S]TBPS binding site, the convulsant site of GABA/benzodiazepine receptors, was unaffected with age. We also studied the effects of exercise on GBZR binding sites of aged rats. The decline of flunitrazepam binding sites and the high sensitivity of flunitrazepam binding to regulation by GABA in aged animals were reversed by 8 to 10 weeks of endurance exercise. Endurance exercise did not have any significant effect on muscimol or TBPS binding sites. Results suggest that there are aged-related alterations of GBZR binding sites and that these modifications can be reversed by exercise.

Time-dependent resistance to alkaline pH of oxalate-supported calcium uptake by sarcoplasmic reticulum

Abstract Both oxalate-supported Ca 2+ uptake and Ca 2+ -stimulated ATPase activity of the sarcoplasmic reticulum are sensitive to the pH of the assay medium. Ca 2+ uptake is optimal at relatively acidic pH (6.2–6.6); whereas, Ca 2+ -stimulated ATPase activity is optimal at a more alkaline pH (7.4–8.0). Following the addition of ATP, Ca 2+ uptake demonstrates a time-dependent resistance to the inhibition by an alkaline pH. Once the linear phase of Ca 2+ uptake is reached, alkalinization thereafter does not alter the rate established at the acidic pH. A similar time-dependent resistance is observed to the inhibition of Ca 2+ uptake by the cation ionophore, X537A. In contrast, acidification of the alkaline medium after Ca 2+ uptake is initiated by ATP has no such resistance to change. Acidification results in a prompt acceleration of the rate of Ca 2+ uptake identical to that observed under control conditions at the acidic pH. Ca 2+ -stimulated ATPase activity, however, increases with alkalinization and decreased with acidification, regardless of time, in a manner expected from the rates observed under conditions when the pH is constant from the time of ATP addition. The results suggest that there is a time-dependent, pH-sensitive factor of oxalate-supported Ca 2+ uptake. This factor can be activated by acidification at any time after ATP addition and, thus, does not represent a destruction of membrane function. In contrast, Ca 2+ -stimulated ATPase activity demonstrates no time-dependent resistance to pH change.

The regulatory role of calcium in striated muscle.

Calcium plays numerous roles in striated muscle, including excitation-contraction coupling and the stimulation of substrate oxidation by the mitochondria. These two topics are considered in this symposium. The purpose of this introductory paper is to present a conceptual framework about the control of calcium movements in striated muscle. Additionally, we provide a brief historical perspective regarding the key research observations leading to our current understanding of the various cellular systems controlling calcium flux in the muscle cell.

The effect of glucagon on the kinetics of hepatic mitochondrial calcium uptake

SummaryPrevious work by this and other laboratories has shown that glucagon administration stimulates calcium uptake by subsequently isolated hepatic mitochondria. This stimulation of hepatic mitochondrial Ca2+ uptake byin vivo administration of glucagon was further characterized in the present report. Maximal stimulation of mitochondrial Ca2+ accumulation was achieved between 6–10 min after the intravenous injection of glucagon into intact rats. Under control conditions, Ca2+ uptake was inhibited by the presence of Mg2+ in the incubation medium. Glucagon treatment, however, appeared to obliterate the observed inhibition by Mg2+ of mitochondrial Ca2+ uptake. Kinetic experiments revealed the usual sigmoidicity associated with initial velocity curves for mitochondrial calcium uptake. Glucagon treatment did not alter this sigmoidal relationship. Glucagon treatment significantly increased the Vmax for Ca2+ uptake from 292±22 to 377±34 nmoles Ca2+ /min per mg protein (n=8) but did not affect the K0.5, (6.5–8.6 μM). Since the major kinetic change in mitochondrial Ca2+ uptake evoked by glucagon is an increase in Vmax, the enhancement mechanism is likely to be an increase either in the number of active transport sites available to Ca2+ or in the rate of Ca2+ carrier movement across the mitochondrial membranes.

The role of dicarboxylic anion transport in the slower Ca2+ uptake in fetal cardiac sarcoplasmic reticulum

ABSTRACT: Sarcoplasmic reticulum- (SR-)mediated Ca2+ transport is slower in the fetal heart compared with the adult. Virtually all previous studies of cardiac SR Ca2+ transport were performed in the presence of oxalate, a dicarboxylic anion that is cotransported with Ca2+ in skeletal muscle SR. If anion transport is developmentally regulated in cardiac SR, this could explain, in part, the previously reported results. The purposes of this study were to establish the presence of an SR dicarboxylic anion transport process in the rabbit heart and to determine if the perinatal changes in SR Ca2+ transport occur in a dicarboxylic anion-dependent and/or independent manner. In isolated fetal and adult rabbit cardiac SR membranes, we measured Ca2+ ATPase rates and 45Ca2+ uptake in the presence of the dicarboxylic anions maleate and succinate compared with the zwitterionic buffer PIPES, to which cardiac SR is essentially impermeable. We also measured 14C-succinate uptake by fetal and adult SR membranes. Anion-independent Ca2+ ATPase activity and net 45Ca2+ uptake were significantly lower in the fetal SR membranes than in the adult. Maleate and succinate increased the Ca2+ ATPase rates in the fetal and adult SR, but the effect was significantly greater in the adult. Maleate and succinate stimulated earlier attainment of maximal net Ca2+ uptake in the fetal and adult SR, suggesting that these dicarboxylic anions stimulated the rate of Ca2+ accumulation. Maleate and succinate significantly increased the maximal net Ca2+ uptake in the adult SR, but not in the fetus. The percentage of stimulation of Ca2+ uptake by maleate and succinate was similar in the fetal and adult SR. Dicarboxylic anion transport, as estimated by 14C-succinate uptake, was significantly lower in the fetus. The previously reported slower Ca2+ uptake rate in the fetus is related to dicarboxylic anion-dependent as well as independent mechanisms. The results provide firm support for the presence of a cardiac SR dicarboxylic anion transport process in rabbits that is developmentally regulated. These results also support the previously reported developmental regulation of the SR Ca2+ pump.

Spontaneous calcium release from sarcoplasmic reticulum. A re-examination.

A recent study by Blayney and co-workers (Blayney, L., Thomas, H., Muir, J. and Henderson, A. (1977) Biochim. Biophys. Acta 470, 128--133) purported to demonstrate that apparent spontaneous calcium release in sarcoplasmic reticulum is an artifact of the uptake of murexide dye. This report demonstrates that spontaneous calcium release (1) takes place despite equilibration of murexide sarcoplasmic reticulum to a stable baseline; (2) may be reversed by addition of ATP or oxalate after release has begun. The identical phenomenon can be demonstrated utilizing the indicator arsenazo III or Millipore filtration methods. The results suggest that equilibration of the murexide with sarcoplasmic reticulum vesicles must occur prior to ATP addition in order to achieve a stable baseline but that spontaneous calcium release is not an artifact.