Action of lecithin:cholesterol acyltransferase on model lipoproteins. Preparation and characterization of model nascent high density lipoprotein

Apolipoprotein A-I, the major protein of human plasma high density lipoprotein, is the primary activator of plasma lecithin:cholesterol acyltransferase. In vitro, the association of apolipoprotein A-I with physiological phosphatidylcholines can be catalyzed by mixing the protein and lipid with sodium cholate, which is removed by chromatography. The apolipoprotein A-I/phospholipid complex has the physical properties of an HDL, and when cholesterol is present the complex is a highly reactive substrate in the lecithin:cholesterol acyltransferase-catalyzed reaction. The relative reactivity of this complex compared with a number of other lipid-protein complexes is presented and discussed.

Evidence for membrane microheterogeneity in the sarcoplasmic reticulum of fast twitch skeletal muscle

Sarcoplasmic reticulum (SR) from rabbit back muscles can be readily subfractionated into two morphologically and compositionally different vesicular populations, SRH (heavy) and SRL (light) derived from terminal cisternae and longitudinal SR, respectively. Polyacrylamide gels indicate that SRH contains most of the calsequestrin. Quantitation of freeze-fractured isolated preparations reveals that, while differences in vesicular dimensions are seen in SRH and SRL, the intramembrane particle (Ca2+ ATPase) density is identical. Phospholipid headgroup composition is the same in SRH and SRL, but fatty acyl moieties show significant differences in the ratio of saturated to unsaturated phospholipids in the two fractions. The vesicular dimensions of the purified Ca2+-ATPases, SRHP and SRLP, from the two fractions are identical, but the freeze-fracture particle density is higher in the SRLP fraction. The phospholipid composition remains similar after purification, but the differences in phospholipid fatty acyl composition of the preparations are maintained. SRH and SRHP contain almost twice as much of the unsaturated species as compared to SRL and SRLP. Differences in intramembrane particle density in purified fractions, thermotropic segregation of particles in freeze-fractured purified fractions, as well as differences in turnover of the acyl phosphate, appear to reflect the differences in fatty acyl chain composition of the two SR fractions and provide evidence of microheterogeneity in lipid-protein environment of the SR.

Cholesteryl ester-rich microemulsions: stable protein-free analogs of low density lipoproteins

A method has been devised for the preparation of stable lipid microemulsions containing cholesterol, cholesteryl ester, phosphatidylcholine, and trioleoylglycerol in the relative molar ratios found in low density lipoproteins. Gel permeation chromatography showed these microemulsions to be essentially homogeneous with respect to chemical composition. Omission of triolein or substitution of a diunsaturated phosphatidylcholine for either a disaturated or monosaturated-monounsaturated phosphatidylcholine destroyed the observed homogeneity of the microemulsions. The particle diameter of the negatively-strained relative elution volumes of the cholesteryl ester-rich microemulsion, VLDL2, VLDL3, and LDL indicated a mean diameter of about 35 nm. The cholesteryl ester-rich microemulsion can be used as a cholesteryl ester donor for plasma protein-mediated transfer of cholesteryl ester to plasma lipoproteins and for studying apoprotein-lipid interactions.

Evidence for a calcium-sensitive factor which alters the alkaline pH sensitivity of sarcoplasmic reticulum calcium transport

Oxalase-supported, ATP-dependent Ca2+ uptake by cardiac and skeletal muscle sarcoplasmic reticulum (SR) exhibits a pH profile with the maximal rate of Ca2+ uptake at pH 6.6-6.8 and marked inhibition (90-95%) at pH 7.4-7.6, a point at which Ca2+-dependent ATPase activity is optimal. These observations are noted when the SR is first preincubated in media containing no added Ca2+. This alkaline pH inhibition is not caused by an irreversible perturbation since the Ca2+ uptake rate is fully restored by changing the alkaline pH preincubation medium to pH 6.8. When SR is preincubated with added Ca2+, Ca2+ uptake at alkaline pH (7.4-7.6) is only inhibited by 10-30%. Ca2+ uptake at pH 6.8 is the same regardless of preincubation conditions. A depressed oxalate permeability is not a factor in the observed alkaline pH inhibition of Ca2+ uptake. At alkaline pH, the relationship between the preincubation Ca2+ concentration and the rate of Ca2+ uptake is hyperbolic; the half-maximal free Ca2+ concentration for stabilization of Ca2+ uptake is 8-15 microM with a Vmax equal to the velocity at the optimal pH. The Hill coefficient is 1.0, implying a single class of Ca2+-requiring sites for stabilization at alkaline pH. In contrast to its effect on Ca2+ uptake, the presence of Ca2+ during preincubation does not alter the pH sensitivity of Ca2+-dependent ATPase activity. Thus, the presence of Ca2+ during preincubation may stabilize a state of the CaATPase, conducive to the coupling of net Ca2+ translocation to Ca2+-dependent ATPase activity, which is ordinarily opposed by alkaline pH. The data suggest a single class of Ca2+-requiring sites which favors this coupled state.

Physical properties of lipid-protein complexes formed by the interaction of dimyristoylphosphatidylcholine and human high-density apolipoprotein A-II

Apolipoprotein A-II (apoA-II) from human plasma high-density lipoproteins associates with dimyristoylphosphatidylcholine (DMPC) to give complexes whose structure is determined by the temperature at which the reaction is conducted. The temperature dependence is related to the gel leads to liquid crystalline transition temperature, Tc, of DMPC which occurs at 23.9 degrees C. At T less than Tc (20 degrees C), T = Tc, and T greater than Tc (30 degrees C), three different complexes can be isolated. At 20 degrees C, at 75:1 (molar ratio of lipid to protein) complex is formed. This complex has a molecular weight (Mt) of 343 000, a Stokes radius, Rs, of 65 A, and a partial specific volume (v) of 0.914 mL/g. At 24 degrees C, two different complexes may be formed. One is similar to the one formed at 20 degrees C and the other is a complex with a DMPC:apoA-II ratio of 241:1; the corresponding physical constants for the latter complex are Mr = 1580 000, Rs = 120 A, and v = 0.948 mL/g. This complex is asymmetric, having a frictional coefficient f/f0 = 1.20. AT 30 degrees C, a 45:1 complex was formed; for this complex, Mr = 229 000, Rs = 57 A, and v = 0.892 mL/g. Electron microscopy reveals that the negatively stained complexes are arranged in rouleaux having subunits with average dimensions of 175 x 60, 250 x 62, and 50 x 55 A for the 45:1, 75:1, and 240:1 complexes, respectively. The multiple lipid-protein species formed by apoA-II and DMPC suggest the possible existence of more than one macromolecular spices of lipid and apoA-II in the plasma.

The sarcoplasmic reticulum-glycogenolytic complex in mammalian fast twitch skeletal muscle. Proposed in vitro counterpart of the contraction-activated glycogenolytic pool

Evidence is presented that the sarcoplasmic reticulum (SR)-glycogenolytic complex isolated from fast twitch skeletal muscle is a highly specific, functionally defined compartment for phosphorylase regulation. The addition of ATP alone results in prompt phosphorylase activation which demonstrates calcium dependence similar to the calcium-magnesium ATPase that catalyzes SR calcium transport suggesting that these two calcium-requiring -ystems might interact within the complex. Lowering extravesicular calcium concentration by transport of calcium into the SR lumen resulted in inactivation of phosphorylase a. This effect could be prevented by the addition of the calcium ionophore X537A which inhibits SR calcium sequestration or a calcium EGTA buffer which maintains free calcium. It was mimicked by EGTA addition. Since exogenous phosphorylase b and phosphorylase a were not activated or inactivated, respectively, by the endogenous activating enzymes or phosphatase in the SR-glycogenolytic complex, these regulatory enzymes may be compartmented. In addition, endogenous phosphorylase could be uncoupled from its activating enzymes by amylase treatment. These results suggest that the SR-glycogenolytic complex in fast twitch skeletal muscle is a compartmented system for phosphorylase activation controlled by SR calcium flux, a feature in contrast to the cardiac complex (Entman, M.L., Kaniike, K., Goldstein, M.A., Nelson, T.E., Bornet, E.P., Futch, T.W., and Schwartz, A. (1976) J. Biol. Chem. 251, 3140-3146). We suggest that the complex is the in vitro counterpart of the well documented rapid burst of glycogenolysis which ensures with the onset of contraction.

Rapid purification of canine cardiac sarcoplasmic reticulum Ca2+-ATPase

A pure, enzymatically active Ca2+-dependent adenosine triphosphatase (Ca2+-ATPase) has been isolated from canine ventricular sarcoplasmic reticulum. In contrast to that derived from skeletal muscle, the Ca2+-ATPase from cardiac sarcoplasmic reticulum was more active when solubilization and subsequent purification took place in the presence of its substrates, Ca2+ and ATP. Cholate- or deoxycholate-solubilized Ca2+-ATPase is recovered following rapid glycerol dilution and centrifugation. The Ca2+-ATPase is stable and possesses hydrolytic capacities up to 4 mumol/mg/min. Sodium dodecyl sulfate-polyacrylamide gels reveal the presence of one protein in the range of 95,000 to 100,000 daltons. This method also yields purified Ca2+-ATPase from fast skeletal muscle of similar activities to those reported by other laboratories.

Morphological and biochemical correlates of skeletal muscle contractility in the cat. I. Histochemical and electron microscopic studies

Three cat hind limb muscles have been examined, histochemically and ultrastructurally, in a multiparameter correlative study of structure and function in skeletal muscle contractility. The soleus, a histochemically pure, slow-twitch muscle possesses ultrastructural features which are, in many cases, significantly different from those of almost pure fast twitch caudofemoralis muscle. Although stereological analysis of fiber types indicates a correlation between speed of relaxation and volume of sarcoplasmic reticulum, morphological features such as fenestrated collars and triad morphology are identical in all fiber types. The fast twitch-oxidative-glycolytic fiber possesses features common to both slow twitch fibers (high mitochondrial content) as well as fast twitch fibers (high sarcoplasmic reticulum content) in addition to Z band width which falls in between these two fiber types. Sarcoplasmic microtubules have been described in all three fiber types in all muscles examined. They occur in predictable orientation and their possible function(s) is described.

Morphological and biochemical correlates of skeletal muscle contractility in the cat. II. Physiological and biochemical studies

Isometric twitch characteristics and biochemical parameters of isolated myosin and sarcoplasmic reticulum have been compared in three cat hind limb muscles. The fast twitch caudofemoralis and the slow twitch soleus are almost pure muscles as judged from histochemical studies. Isolated myosin from the caudofemoralis is not only 2- to 3-fold higher in its ATPase activities than that of the soleus, but also in non-dissociated forms has greater electrophoretic mobility than the soleus myosin. Purified myosins from fast muscles as well as soleus exhibited three light chains upon electrophoresis. However, the intact non-solubilized myosins differed in electrophoretic mobilities. The sarcoplasmic reticulum fraction isolated from caudfemoralis exhibits faster rates of Ca++ binding and uptake than soleus, and when fit to a two component model, the caudofemoralis SR exhibits a higher amount of a fast binding site than does soleus SR, features reflected in differences in the relaxation time of the two muscles. In contrast, the fast twitch tibialis anterior has been shown to be a gradient of fiber types and its isometric twitch may be separated by selective nerve stimulation, into a fast and a slow twitch component. Our findings that myosin fractions, as well as sarcoplasmic reticulum fractions isolated from these two components differ with respect to their biochemical characteristics add support to the possibility of a dual function in this muscle.

Cyclic AMP modulation of calcium accumulation by sarcoplasmic reticulum from fast skeletal muscle

The role of cyclic 3',5'-AMP in modulating sarcoplasmic reticulum from fast skeletal muscle was studied. The rate of Ca2+ uptake was stimulated in the presence of protein kinase plus 1 micron cyclic AMP. The stimulation was absent when denatured protein kinase was used. When an adenylate cyclase inhibitor was added, the uptake rates fell to 55% of control. This decrease in rate was partially overcome by 1 micron cyclic AMP. A modulating role for cyclic AMP in fast skeletal muscle is proposed.

The fenestrated collar of mammalian cardiac sarcoplasmic reticulum: a freeze-fracture study

Freeze-fracture studies of papillary muscles from cat, rabbit and dog reveal the presence of a fenestrated collar of the sarcoplasmic reticulum (SR) in the region of the M band. This membrane specialization is structurally similar to that observed previously in skeletal muscle. This report includes mammalian cardiac muscle on the list of those muscles containing this SR membrane structure.

Calcium release from skeletal muscle sarcoplasmic reticulum: site of action of dantrolene sodium

The muscle relaxant dantrolene sodium acts directly and specifically on skeletal muscle, unlike other pharmacological agents which affect the central nervous system or act at the nueromuscular junction. Dantrolene sodium markedly suppresses the release of calcium previously sequestered by skeletal, but not cardiac, muscle sarcoplasmic reticulum. No effect in the total amount of calcium accumulated was found. In situ, the drug may reduce the amount of calcium necessary for muscle contraction.

The rate of calcium uptake into sarcoplasmic reticulum of cardiac muscle and skeletal muscle. Effects of cyclic AMP-dependent protein kinase and phosphorylase b kinase

Calcium transport into sarcoplasmic reticulum fragments isolated from dog cardiac and mixed skeletal muscle (quadriceps) and from mixed fast (tibialis), pure fast (caudofemoralis) and pure slow (soleus) skeletal muscles from the cat was studied. Cyclic AMP-dependent protein kinase and phosphorylase b kinase stimulated the rate of calcium transport although some variability was observed. A specific protein kinase inhibitor prevented the effect of protein kinase but not of phosphorylase b kinase. The addition of cyclic AMP to the sarcoplasmic reticulum preparations in the absence of protein kinase had only a slight stimulatory effect despite the presence of endogenous protein kinase. Cyclic AMP-dependent protein kinase catalyzed the phosphorylation of several components present in the sarcoplasmic reticulum fragments; a 19000 to 21 000 dalton peak was phosphorylated with high specific activity in sarcoplasmic reticulum preparations isolated from heart and from slow skeletal muscle, but not from fast skeletal muscle. Phosphorylase b kinase phosphorylated a peak of molecular weight 95000 in all of the preparations. Cyclic AMP-dependent protein kinase-stimulated phosphorylation was optimum at pH 6.8; phosphorylase b kinase phosphorylation had a biphasic curve in cardiac and slow skeletal muscle with optima at pH 6.8 and 8.0. The addition of exogenous phosphorylase b kinase or protein kinase increased the endogenous level of phosphorylation 25-100%. All sarcoplasmic reticulum preparations contained varying amounts of adenylate cyclase, phosphorylase b and a (b:a = 30.1), "debrancher" enzyme and glycogen (0.3 mg/mg protein), as well as varying amounts of protein kinase and phosphorylase b kinase which were responsible for a significant endogenous phosphorylation. Thus, the two phosphorylating enzymes stimulated calcium uptake in the sarcoplasmic reticulum of a variety of muscles possessing different physiologic characteristics and different responses to drugs. In addition, the phosphorylation catalyzed by these enzymes occurred at two different protein moieties which make physiologic interpretation of the role of phosphorylation difficult. While the role phosphorylation in these mechanisms is complex, the presence of a glycogenolytic enzyme system may be an important link in this phenomenon. The sarcoplasmic reticulum represents a new substrate for phosphorylase b kinase.