Update on physical state of bile

Because of recent assertions by a group of investigators that structures called "lamellae" instead of mixed micelles are present in human bile, the nature of biliary cholesterol solubilization and transport ("carriage") has again become a matter of dispute. "Lamellae" are rod- or tubular- shaped banded images observed when biles are negatively stained and dehydrated during electron microscopy; they are believed to be composed principally of biliary phospholipid (which is mostly lecithin) and cholesterol. It is well known that when mixed together in aqueous systems, lecithin and cholesterol, which are otherwise insoluble amphiphilic lipids, swell to form stacked or multilamellar liquid crystals that have regular periodicity because of the bilayer arrangement of the molecules. Provided super-micellar concentrations of cholesterol are present, multilamellar vesicles occur spontaneously in concentrated model biles, and are a frequent occurrence in human gallbladder biles that are beginning to nucleate cholesterol crystals. When multilamellar vesicles are negatively stained and dehydrated, they produce "lamellae" images by electron microscopy. Coincidentally, images of "lamellae" are also produced when purely micellar bile, either model or native is treated similarly. In this review we show that these images are an artifact. This artifact is produced by the dehydration process itself and is due to a phase change i.e. a change in molecular packing which is predicted by the appropriate phase diagram. As a consequence, a dehydrated "lamellae" phase results and the overall effect is an electron microscopic image that is identical to those produced by multilamellar vesicles in supersaturated or lithogenic biles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Two-dimensional crystallization of Ca-ATPase by detergent removal

By using Bio-Beads as a detergent-removing agent, it has been possible to produce detergent-depleted two-dimensional crystals of purified Ca-ATPase. The crystallinity and morphology of these different crystals were analyzed by electron microscopy under different experimental conditions. A lipid-to-protein ratio below 0.4 w/w was required for crystal formation. The rate of detergent removal critically affected crystal morphology, and large multilamellar crystalline sheets or wide unilamellar tubes were generated upon slow or fast detergent removal, respectively. Electron crystallographic analysis indicated unit cell parameters of a = 159 A, b = 54 A, and gamma = 90 degrees for both types of crystals, and projection maps at 15-A resolution were consistent with Ca-ATPase molecules alternately facing the two sides of the membrane. Crystal formation was also affected by the protein conformation. Indeed, tubular and multilamellar crystals both required the presence of Ca2+; the presence of ADP gave rise to another type of packing within the unit cell (a = 86 A, b = 77 A, and gamma = 90 degrees), while maintaining a bipolar orientation of the molecules within the bilayer. All of the results are discussed in terms of nucleation and crystal growth, and a model of crystallogenesis is proposed that may be generally true for asymmetrical proteins with a large hydrophilic cytoplasmic domain.     

The structure and interactions of Ca(2+)-ATPase

Electron crystallographic studies on membrane crystals of Ca(2+)-ATPase reveal different patterns of ATPase-ATPase interactions depending on enzyme conformation. Physiologically relevant changes in Ca2+ concentration and membrane potential affect these interactions. Ca2+ induced difference FTIR spectra of Ca(2+)-ATPase triggered by photolysis of caged Ca2+ are consistent with changes in secondary structure and carboxylate groups upon Ca2+ binding; the changes are reversed during ATP hydrolysis suggesting that a phosphorylated enzyme form of low Ca2+ affinity is the dominant intermediate during Ca2+ transport. A two-channel model of Ca2+ translocation is proposed involving the membrane-spanning helices M2-M5 and M4, M5, M6 and M8 respectively, with separate but interacting Ca2+ binding sites.     

Three-dimensional map of the plasma membrane H+-ATPase in the open conformation

The H+-ATPase from the plasma membrane of Neurospora crassa is an integral membrane protein of relative molecular mass 100K, which belongs to the P-type ATPase family that includes the plasma membrane Na+/K+-ATPase and the sarcoplasmic reticulum Ca2+-ATPase. The H+-ATPase pumps protons across the cell's plasma membrane using ATP as an energy source, generating a membrane potential in excess of 200mV. Despite the importance of P-type ATPases in controlling membrane potential and intracellular ion concentrations, little is known about the molecular mechanism they use for ion transport. This is largely due to the difficulty in growing well ordered crystals and the resulting lack of detail in the three-dimensional structure of these large membrane proteins. We have now obtained a three-dimensional map of the H+-ATPase by electron crystallography of two-dimensional crystals grown directly on electron microscope grids. At an in-plane resolution of 8 A, this map reveals ten membrane-spanning alpha-helices in the membrane domain, and four major cytoplasmic domains in the open conformation of the enzyme without bound ligands.     

Skin electroporation: rapid measurements of the transdermal voltage and flux of four fluorescent molecules show a transition to large fluxes near 50 V

Large molecular fluxes and tight control are highly desired for transdermal drug delivery, which motivated this study of molecular transport due to high voltage pulsing. We used a flow-through sampling system (time resolution of approximately 14 s) to measure the response of human skin in vitro to a series of exponential pulses (time constant of 1 ms; peak transdermal voltages [Uskin,0] of 0 V to approximately 300 V, one pulse every 5.6 s). Four negatively charged, hydrophilic fluorescent tracer molecules were employed: sulforhodamine, lucifer yellow, cascade blue, and calcein (molecular weights of 450 to 625 Da). Although differences in their molecular transport profiles were observed, all four molecules exhibited a transition from small to large fluxes at Uskin,0 approximately 50 V. This behavior may reflect a transition from electroporation of the skin's appendages to electroporation of the multilamellar bilayer membranes within the stratum corneum.     

Kinetic uniformity of the ATP hydrolysis reaction catalyzed by Mg2+-ATPase in smooth muscle cell membrane

The kinetic properties of Mg(2+)-ATPase (EC 3.6.1.3) from myometrium cell plasma membranes have been studied. Under conditions of enzyme saturation with ATP (0.5-1.0 mM) or Mg2+ (1.0-5.0 mM) the initial maximal rates of the Mg(2+)-dependent enzymatic ATP hydrolysis, V0 ATP and V0 Mg, are 27.4 +/- 3.3 and 25.2 +/- 4.1 mumol Pi/hour/mg of protein, respectively. The apparent Michaelis constant, Km, for ATP and of the apparent activation constant, K alpha, for Mg2+ are equal to 28.1 +/- 2.6 and 107.0 +/- 26.0 microM, respectively. The bivalent metal ions used at 1.0 mM suppress the Mg(2+)-dependent hydrolysis of ATP whose efficiency decreases in the following order: Cu2+ > Zn2+ = Ni2+ > Mn2+ > Ca2+ > Co2+. Alkalinization of the incubation medium from pH 6.0 to pH 8.0 stimulates the Mg(2+)-dependent hydrolysis of ATP. It has been found that Mg(2+)-ATPase has the properties of an H(+)-sensitive enzymatic sensor which is characterized by a linear dependence between the initial maximal rate of the reaction, V0, and the pH value. The feasible role of plasma membrane Mg(2+)-ATPase in some reactions responsible for the control of proton and Ca2+ homeostasis in myometrium cells has been investigated.     

Dynamic chain conformations in dimyristoyl glycerol-dimyristoyl phosphatidylcholine mixtures. 2H-NMR studies

The dynamic molecular lipid chain conformations in fully hydrated dimyristoyl phosphatidylcholine (DMPC)-dimyristoyl glycerol (DMG) mixtures have been investigated by 2H-NMR spectroscopy of the individual lipid components, the sn-2 chains of which were perdeuterated or, in the case of DMG, specifically deuterated at the C-2 position. Mixtures of compositions corresponding to the three different regions of the binary phase diagram in which the fluid phase is lamellar (DMPC:DMG 70:30 mol/mol), inverted hexagonal (DMPC:DMG 45:55 and 40:60 mol/mol), or isotropic (DMPC:DMG 20:80 mol/mol) were investigated. The gel phase in all three regions of the phase diagram has a lamellar structure, with the lipid chains rotating about the molecular long axis but executing only limited angular excursions. In the fluid lamellar phase of the 70:30 mol/mol DMPC-DMG mixture the profile of segmental chain flexibility is similar to that in single-component phospholipid bilayers and is characterized by an order parameter plateau for both lipid components. The chain order of the DMPC component is greater than in bilayers of DMPC alone and is also greater than that of the DMG component. In the inverted hexagonal phase of the 45:55 mol/mol DMPC-DMG mixture the chain flexibility profile is characterized by more widely spaced segmental order parameters off the plateau region. The intrinsic degree of chain order in the inverted hexagonal phase is less than in the lamellar phase of the 70:30 mol/mol mixture, and the difference in chain order between the DMPC and DMG components is reduced relative to that in the lamellar phase. The unique conformational features at the C-2 position of the sn-2 chain that characterize bilayers of diacyl phospholipids are found also for the diacylglycerol molecules in the fluid lamellar phase and most probably also in the inverted hexagonal phase. The DMG molecules are therefore integrated in the membrane (or nonlamellar lipid phase) in a configuration that is similar to that of the phospholipids and different from the crystal structure of diacylglycerols.     

Inhibition of plasma membrane Ca(2+)-ATPase activity by volatile anesthetics

BACKGROUND: The precise sites and mechanisms of action of volatile anesthetics remain unknown. Recently, several integral membrane proteins have been suggested as potential targets to which anesthetics can bind at hydrophobic regions. Impairment of cell Ca2+ homeostasis has been postulated as one of the possible mechanisms of anesthetic action. To test these hypotheses, the authors selected the human erythrocyte Ca(2+)-ATPase as a model membrane protein. This enzyme is an integral membrane protein that is instrumental in maintaining Ca2+ homeostasis in the cell in which it is the sole Ca(2+)-transporting system. Thus, any functional alteration of the Ca(2+)-ATPase by anesthetics may lead to serious perturbations in Ca(2+)-regulated processes in the cell. METHODS: The Ca(2+)-ATPase activity was measured as a function of increased concentration of four volatile anesthetics: halothane, isoflurane, enflurane, and desflurane. RESULTS: All four anesthetics significantly inhibited the Ca(2+)-ATPase activity in a dose-dependent manner. The half-maximal inhibition occurred at anesthetic concentrations from 0.3 to 0.7 vol% at 37 degrees C, which, except for desflurane, is a clinically relevant concentration range. The greater the clinical potency of the volatile anesthetics studied, the less was the concentration required to inhibit the Ca(2+)-ATPase activity. The inhibition was less at 25 degrees C than at 37 degrees C, which is consistent with direct interactions of the nonpolar interfaces of the enzyme with the nonpolar of the portions of the anesthetics. CONCLUSIONS: The authors' findings indicate that the Ca(2+)-ATPase is a suitable model for investigating the mechanism of action of volatile anesthetics on the integral membrane protein, and that this inhibition may be specific.     

Ultrastructural studies of bones from patients with osteogenesis imperfecta

Bone samples from patients suffering from osteogenesis imperfecta (OI) types I, II, III and IV, as well as normal controls, were studied by scanning (SEM) and transmission electron microscopy (TEM). SEM views of normal bone at low magnification show coherent structure, with regular striations due to a lamellar plywood-like arrangement of the mineralized collagen fibrils. Compact lamellar bone was also found in various OI specimens, but in limited disconnected regions separated by open spaces. Furthermore, some OI, but not normal, bones have regions of loose unconnected fibers and others of apparently abnormally dense mineral deposition. High resolution TEM studies of OI bone fragments have served to elucidate the structures of these different textures. There appears to be a substantial, though reduced, proportion of normal lamellar bone even in quite severe OI. However, the regions of loose fibers are largely unmineralized and probably contain abnormal collagen. Other regions are overmineralized, with generally small unorganized apatite crystals deposited onto fibril surfaces or in separate clusters. These structural abnormalities, together with the paucity of normal bone, may explain the fragility of OI bones.     

How to make tubular crystals by reconstitution of detergent-solubilized Ca2(+)-ATPase

In an attempt to better define the parameters governing reconstitution and two-dimensional crystallization of membrane proteins, we have studied Ca2(+)-ATPase from rabbit sarcoplasmic reticulum. This ion pump forms vanadate-induced crystals in its native membrane and has previously been reconstituted at high lipid-to-protein ratios for functional studies. We have characterized the reconstitution of purified Ca2(+)-ATPase at low lipid-to-protein ratios and discovered procedures that produce long, tubular crystals suitable for helical reconstruction. C12E8 (n-dodecyl-octaethylene-glycol monoether) was used to fully solubilize various mixtures of lipid and purified Ca2(+)-ATPase, and BioBeads were then used to remove the C12E8. Slow removal resulted in two populations of vesicles, and the proteoliposome population was separated from the liposome population on a sucrose density gradient. These proteoliposomes had a lipid-to-protein ratio of 1:2, and virtually 100% of molecules faced the outside of vesicles, as determined by fluorescein isothiocyanate labeling. Cycles of freeze-thaw caused considerable aggregation of these proteoliposomes, and, if phosphatidyl ethanolamine and phosphatidic acid were included, or if the bilayers were doped with small amounts of C12E8, vanadate-induced tubular crystals grew from the aggregates. Thus our procedure comprised two steps-reconstitution followed by crystallization-allowing us to consider mechanisms of bilayer formation separately from those of crystallization and tube formation.     

Calcium signaling dysfunction in schizophrenia: a unifying approach

The present paper demonstrates a remarkable pervasiveness of underlying Ca(2+) signaling motifs among the available biochemical findings in schizophrenic patients and among the major molecular hypotheses of this disease. In addition, the paper reviews the findings suggesting that Ca(2+) is capable of inducing structural and cognitive deficits seen in schizophrenia. The evidence of the ability of antipsychotic drugs to affect Ca(2+) signaling is also presented. Based on these data, it is proposed that altered Ca(2+) signaling may constitute the central unifying molecular pathology in schizophrenia. According to this hypothesis schizophrenia can result from alterations in multiple proteins and other molecules as long as these alterations lead to abnormalities in certain key aspects of intracellular Ca(2+) signaling cascades.     

Effect of high pressure on the association of melittin to membranes

To determine the underlying basis for the sensitivity of peripheral peptides to lipid packing, we monitored the change in association of melittin to different membranes under hydrostatic pressure by fluorescence polarization and by fluorescence intensity in the presence of aqueous quenchers. Association to lysophosphatidylcholine micelles or to membranes composed of dimyristoylphosphatidylcholine, dipalmitoylphosphatidylcholine, palmitoyloleoylphosphatidylcholine, or dioleoylphosphatidylcholine was found to be stable from 1 to 2000 atm. Similar results were obtained using multilamellar vesicles, small unilamellar vesicles, or large unilamellar vesicles. Thus, the increase in lipid chain packing induced by pressure does not alter the association of bound complexes. This result indicates similar compressibilities of the peptide and the head group binding region. Increasing the ionic strength to increase the charge of the free peptide also resulted in a pressure-insensitive complex showing that the hydration does not change upon binding. This conclusion is substantiated by a lack of van't Hoff delta H to dioleoylphosphatidylcholine large unilamellar vesicles. To gain a more molecular picture of these associations, the rotational properties of the tryptophan side chain of bound melittin as a function of lipid packing was also studied. These data indicate subtle differences in peptide orientation in different lipids.     

Rho guanosine triphosphatase mediates the selective stabilization of microtubules induced by lysophosphatidic acid

We have examined the ryanodine receptor, Ca(2+)-ATPase, calsequestrin and phospholamban mRNA levels in the left ventricles of pacing-induced heart failure and norepinephrine infusion dogs. The heart failure dogs showed a decrease in the levels of ryanodine receptor and Ca(2+)-ATPase mRNAs. Norepinephrine infusion caused a reduction of Ca(2+)-ATPase mRNA but no change in ryanodine receptor mRNA. There was a corresponding reduction of the immunoreactive Ca(2+)-ATPase protein levels in both heart failure and norepinephrine infusion animals compared to controls. In contrast, the mRNAs of calsequestrin and phospholamban were unchanged in dogs with either congestive heart failure or norepinephrine infusion. Thus, since norepinephrine infusion and congestive heart failure produced similar reductions of Ca(2+)-ATPase mRNA and protein, we postulate that the down-regulation of Ca(2+)-ATPase in congestive heart failure may be caused, at least in part, by sympathetic stimulation that occurs in heart failure.     

Crystal structure of beta-D-cellotetraose hemihydrate with implications for the structure of cellulose II

The crystal structure of beta-D-cellotetraose shows the same molecule packing as cellulose II, with two antiparallel molecules in the unit cell: For cellulose II, the orientation of the C6-O6 bonds has been described as gauche-trans and trans-gauche, respectively, for the two antiparallel molecules, which otherwise have identical conformations. In contrast, in beta-D-cellotetraose all C6-O6 bonds are gauche-trans, but the conformations of the two antiparallel molecules are different. Energy minimization and molecular dynamics studies suggest that the structure of cellulose II should be reinvestigated in light of these findings.     

Intracellular calcium concentration impairment in hepatocytes from thioacetamide-treated rats. Implications for the activity of Ca(2+)-dependent enzymes

METHODS/RESULTS: Thioacetamide induced a severe perivenous necrosis followed by a hepatocellular regenerative response, when administered in a single dose of 6.6 mmol/kg to rats. As (Ca2+)i plays an important role in both toxic cell killing and cell proliferation, the disturbances in the basal cytosolic calcium as well as the levels of Ca2+ sequestered in the endoplasmic reticulum were determined in hepatocytes isolated at 0, 12, 24, 48 and 72 h after thioacetamide administration. The basal Ca2+ increased progressively, reaching a maximum at 24 h of the intoxication (205%, p < 0.001), while the microsomal sequestered Ca2+ decreased at 24 h to 16% (p < 0.001) when compared with untreated controls. Changes in the activity of glycogen phosphorylase alpha paralleled those of basal free calcium and showed the maximum value also at 24 h (291%; p < 0.001). Moreover, there was a close association in time between the basal concentration of Ca2+ and the inhibition of microsomal Ca(2+)-dependent ATPase activity. CONCLUSIONS: The significant decrease in the levels of GSH and protein thiols indicates that oxidative stress is involved in thioacetamide-induced cell injury, but these decreases did not precede changes in cytosolic Ca2+ level. In the sequence of events leading to hepatic cell injury and regeneration, thioacetamide mobilized hepatic (Ca2+)i via inhibition of microsomal Ca(2+)-ATPase which may have activated Ca(2+)-dependent mechanisms involved both in cell death and in acute mitogen response.     

Constructing aligned sequence blocks

Optical and electron microscopy were employed to characterize microstructures formed by thermal mechanical treatment of glycol suspensions of various pure and binary mixtures of the brain-derived galactosphingolipids hydroxy fatty acid cerebroside (HFA-Cer), non-hydroxy fatty acid cerebroside (NFA-Cer) and sulfatide (S-Cer). Negative staining indicated some new features of the neutral cerebroside suspensions in glycol. HFA-Cer formed a small fraction of both unilamellar cylinders (ULCs) (lumina ca. 27 nm) and giant multilamellar cochleates in addition to the typical nonhelical multilamellar cylinders (MLCs) (lumina ca. 10-30 nm). NFA-Cer formed a gel composed of a significant fraction of very long ULCs (lumina ca. 17 nm) without helical substructure, in addition to multilamellar helical structures such as ribbons and cylinders (lumina ca. 70 nm). Anisotropic lamellar micelle-shards of NFA-Cer were also detected by negative staining. S-Cer formed short ULCs (lumina ca. 44 nm) with no obvious helical substructure. Complex mixture data are thought to result from thermodynamic and kinetic factors. HFA-Cer is highly insoluble and promotes a network of rigid intralamellar hydrogen bonding that tends to exclude other lipids. NFA-Cer stabilizes helical defects in the lamellae, and S-Cer enhances disorder or micellization. The processes of microstructure nucleation and lipid phase separation were affected by mixtures such that metastable microstructures were trapped or the length of lamellar cylinders was altered.     

Specificity in the recognition of crystals by antibodies

We show that IgG molecules isolated from the serum of rabbits injected with crystals of monosodium urate monohydrate, magnesium urate octahydrate and allopurinol, can each catalyze the nucleation of the same type of crystal to which they were exposed. These results generalize previous findings related to monosodium urate monohydrate and assess the idea that the invasion of a foreign crystal into an organism may amplify a population of antibodies which bear in their binding sites an imprint of the crystal surface structure. Such antibodies can further act as nucleating templates which accelerate crystal formation in vitro. Antibodies isolated from rabbits injected with sodium urate crystals do not cross-react or cross-react only to a low extent with antibodies isolated from rabbits injected with crystals of either magnesium urate or allopurinol. These results indicate a high specificity of the elicited antibodies, as these can distinguish between nuclei of crystals having similar molecular and structural characteristics.     

Direct and indirect effects of insulin in suppressing glucose production in depancreatized dogs: role of glucagon

The subcellular locations of Ca(2+)-ATPases in the membranes of cauliflower (Brassica oleracea L.) inflorescences were investigated. After continuous sucrose gradient centrifugation a 111-kD calmodulin (CaM)-stimulated and caM-binding Ca(2+)-ATPase (BCA1; P. Askerlund [1996] Plant Physiol 110: 913-922; S. Malmstr?m, P. Askerlund, M.G. Plamgren [1997] FEBS Lett 400: 324-328) comigrated with vacuolar membrane markers, whereas a 116-kD caM-binding Ca(2+)-ATPase co-migrated with a marker for the plasma membrane. The 116 kD Ca(2+)-ATPase was enriched in plasma membranes obtained by aqueous two-phase partitioning, which is in agreement with a plasma membrane location of this Ca(2+)-ATPase. Countercurrent distribution of a low-density intracellular membrane fraction in an aqueous two-phase system resulted in the separation of the endoplasmic reticulum and vacuolar membranes. The 111-kD Ca(2+)-ATPase co-migrated with a vacuolar membrane marker after countercurrent distribution but not with markers for the endoplasmic reticulum. A vacuolar membrane location of the 111-kD Ca(2+)-AtPase was further supported by experiments with isolated vacuoles from cauliflower: (a) Immunoblotting with an antibody against the 111-kD Ca(2+)-ATPase showed that it was associated with the vacuoles, and (b) ATP-dependent Ca2+ uptake by the intact vacuoles was found to be CaM stimulated and partly protonophore insensitive.     

The epidermal growth factor/cAMP-inducible ectoCa(2+)-ATPase of human hepatoma Li-7A cells is similar to rat liver ectoATPase/hepatocyte cell adhesion molecule (cell-CAM 105)

Human hepatoma Li-7A cells exhibit two cell surface ATPase (ectoATPase) activities distinguishable by their different biochemical properties. The activity of the minor ectoATPase, ectoCa(2+)-ATPase, is enhanced severalfold when Li-7A cells are treated simultaneously by epidermal growth factor (EGF) and cAMP elevating agents (Knowles, A. F., 1990, Arch. Biochem. Biophys. 283, 114-119). Here we report that the human ectoCa(2+)-ATPase is biochemically similar to the major rat hepatocyte ectoATPase/cell adhesion molecule (cell-CAM 105) with respect to response to divalent ions and sulfhydryl reagents. Furthermore, the binding of rat liver ectoATPase antibody increased markedly in EGF/cholera toxin/hydrocortisone-treated Li-7A cells compared to untreated cells. Western blot analysis revealed cross-reactivity of the antibody with a 125-kDa protein. Partial purification of ectoCa(2+)-ATPase from EGF/cholera toxin/hydrocortisone-treated Li-7A cells confirmed that enrichment of the 125-kDa protein correlated with an increase in ATPase activity. We conclude that EGF and increased levels of cAMP lead to increased synthesis of the ectoCa(2+)-ATPase in Li-7A cells. The present demonstration of similarity between the ectoCa(2+)-ATPase and a rat liver cell adhesion molecule, cell-CAM 105, contributes significantly to an understanding of the implication of down-regulation of ectoCa(2+)-ATPase during hepatocyte-hepatoma transformation.     

Ca(2+)-ATPases in the cochlear duct

Differing levels of the Ca(2+)-ATPase enzymes that reside on the plasma membrane (PM) and on the endoplasmic reticulum (ER) were identified in individual rat cochlear tissues by the use of a semi-quantitative enzyme-linked immunosorbent assay (ELISA). Unlike other studies, a specific antibody to PM Ca(2+)-ATPase was used to detect significantly greater levels (about 2x) of PM Ca(2+)-ATPase in the stria vascularis (SV) than that in the spiral ligament (SL) and organ of Corti (OC) tissues. Similarly, levels of ER Ca(2+)-ATPase were also significantly higher in the SV than in the SL and OC tissues. The presence of ER Ca(2+)-ATPase in the tissues of the SV has not been demonstrated previously. Given the importance of Ca2+ homeostasis in the inner ear, the statistically significantly higher densities of both PM and ER Ca(2+)-ATPase measured in the SV relative to the SL and OC regions would indicate tissue-specific responses to fluctuations in systemic and local Ca2+ concentrations.