James G. Stout

Molecular Cloning of Human Plasma Membrane Phospholipid Scramblase A PROTEIN MEDIATING TRANSBILAYER MOVEMENT OF PLASMA MEMBRANE PHOSPHOLIPIDS

The rapid movement of phospholipids (PL) between plasma membrane leaflets in response to increased intracellular Ca2+ is thought to play a key role in expression of platelet procoagulant activity and in clearance of injured or apoptotic cells. We recently reported isolation of a ∼37-kDa protein in erythrocyte membrane that mediates Ca2+-dependent movement of PL between membrane leaflets, similar to that observed upon elevation of Ca2+ in the cytosol (Bassé, F., Stout, J. G., Sims, P. J., and Wiedmer, T. (1996) J. Biol. Chem.271, 17205–17210). Based on internal peptide sequence obtained from this protein, a 1,445-base pair cDNA was cloned from a K-562 cDNA library. The deduced “PL scramblase” protein is a proline-rich, type II plasma membrane protein with a single transmembrane segment near the C terminus. Antibody against the deduced C-terminal peptide was found to precipitate the ∼37-kDa red blood cell protein and absorb PL scramblase activity, confirming the identity of the cloned cDNA to erythrocyte PL scramblase. Ca2+-dependent PL scramblase activity was also demonstrated in recombinant protein expressed from plasmid containing the cDNA. Quantitative immunoblotting revealed an approximately 10-fold higher abundance of PL scramblase in platelet (∼104 molecules/cell) than in erythrocyte (∼103 molecules/cell), consistent with apparent increased PL scramblase activity of the platelet plasma membrane. PL scramblase mRNA was found in a variety of hematologic and nonhematologic cells and tissues, suggesting that this protein functions in all cells.

Isolation of an Erythrocyte Membrane Protein that Mediates Ca2+-dependent Transbilayer Movement of Phospholipid

Elevation of intracellular Ca2+ in erythrocytes, platelets, and other cells initiates rapid redistribution of plasma membrane phospholipids (PL) between inner and outer leaflets, collapsing the normal asymmetric distribution. Consequently, phosphatidylserine and other lipids normally sequestered to the inner leaflet become exposed at the cell surface. This Ca2+-induced mobilization of phosphatidylserine to the surface of activated, injured, or apoptotic cells confers a procoagulant property to the plasma membrane, which promotes fibrin clotting and provides a signal for cell removal by the reticuloendothelial system. To identify the constituent of the membrane that mediates this Ca2+-dependent “PL scramblase” activity, we undertook purification and reconstitution of membrane component(s) with this activity from detergent extracts of erythrocyte ghosts depleted of cytoskeleton. Active fractions were identified by their capacity to mediate the Ca2+-dependent redistribution of 7-nitrobenz-2-oxa-1,3-diazol-4-yl-labeled PL between leaflets of reconstituted proteoliposomes. This PL scramblase activity co-eluted through multiple chromatographic steps with a single polypeptide of ∼37 kDa, which was purified to apparent homogeneity as resolved by silver staining. The activity associated with this protein band was inactivated by trypsin. The isolated protein reconstituted in proteoliposomes mediated nonselective, bidirectional transport of 7-nitrobenz-2-oxa-1,3-diazol-4-yl-PL between membrane leaflets, with half-maximal activation between 20 and 60 μM Ca2+ (saturation >100 μM), mimicking the Ca2+-dependent transbilayer lipid movement intrinsic to the erythrocyte membrane.

Scott syndrome erythrocytes contain a membrane protein capable of mediating Ca2+-dependent transbilayer migration of membrane phospholipids.

Phospholipid (PL) scramblase is a plasma membrane protein that mediates accelerated transbilayer migration of PLs upon binding Ca2+, facilitating rapid mobilization of phosphatidylserine to the cell surface upon elevation of internal Ca2+. In patients with Scott syndrome, a congenital bleeding disorder related to defective expression of membrane coagulant activity, circulating blood cells show decreased cell surface exposure of phosphatidylserine at elevated cytosolic [Ca2+], implying an underlying defect or deficiency of PL scramblase. To gain insight into the molecular basis of this disorder, we compared PL scramblase in Scott erythrocyte membranes to those of normal controls. Whereas membranes of Scott cells were unresponsive to Ca2+-induced activation of PL scramblase at neutral pH, apparently normal PL scramblase activity was induced at pH < 6.0. After extraction with octylglucoside, a membrane protein was isolated from the Scott cells which exhibited normal PL scramblase activity when reconstituted in vesicles with exogenous PLs. Like PL scramblase from normal erythrocytes, PL scramblase from Scott erythrocytes was maximally activated either by addition of Ca2+ (at pH 7.4) or by acidification to pH < 6.0, and similar apparent affinities for Ca2+ and rates of transbilayer transfer of PLs were observed. This suggests that the defect in Scott syndrome is related to an altered interaction of Ca2+ with PL scramblase on the endofacial surface of the cell membrane, due either to an intrinsic constraint upon the protein preventing interaction with Ca2+ in situ, or due to an unidentified inhibitor or cofactor in the Scott cell that is dissociated by detergent.

Purification and characterization of the ecto-Mg-ATPase of chicken gizzard smooth muscle

The ecto-Mg-ATPase isolated from chicken gizzard smooth muscle was solubilized, purified and characterized. The purification did not require the use of expensive or specialized apparatus. The chromatographic and electrophoretic characteristics of the ecto-Mg-ATPase from chicken are similar to those reported earlier for the ecto-Mg-ATPase isolated from rabbit skeletal muscle transverse tubule membranes [1992, J. Biol. Chem. 267, 11777-11782]. One obvious difference found was that the solubilized chicken ecto-Mg-ATPase can be stimulated approximately 1900% by the lectin Concanavalin A (Con A) under the same conditions that the rabbit enzyme is inhibited by approximately 50%. This stimulatory effect of Con A is useful for following the purification, and also increases the specific activity of the chicken enzyme to a very high level similar to that observed for the rabbit enzyme. After purification of the solubilized chicken ecto-Mg-ATPase by three steps of anion exchange chromatography, as well as Con A and erythroagglutinating Phaseolus vulgaris (PHA-E) lectin affinity chromatographies, a single diffuse glycoprotein band at approximately 66 kDa is observed after SDS-PAGE. This protein could be deglycosylated to a core protein of 53 kDa. Thus, the chicken gizzard protein is very similar in molecular size to the rabbit skeletal muscle ecto-Mg-ATPase both before and after deglycosylation [1992, J. Biol. Chem. 267, 11777-11782]. The N-terminal sequence of the 66 kDa chicken gizzard protein was found to be: Ala-Arg-Arg-Ala-Ala-Ala-Val-Leu-Leu-Leu-Leu-Ala. This is a unique sequence which, while very different from the rabbit ecto-Mg-ATPase N-terminus, exhibits some of the same characteristics, since it contains basic residues as the second and third amino acids, with the remainder of the N-terminus being very hydrophobic in nature. Furthermore, the chicken gizzard ecto-Mg-ATPase can be separated from the adhesion molecule, truncated cadherin (T-cadherin) by anion exchange chromatography, and is therefore not identical to that protein, as had been recently proposed [1993, Arch. Biochem. Biophys. 303, 32-43].

Ethanol disordering of GM1-enriched Short-Sleep synaptosomal plasma membranes

The Long-Sleep (LS) and Short-Sleep (SS) mouse synaptosomal plasma membranes differ in ethanol sensitivity at superficial membrane regions, which corresponds with the behavioral response of the mice to ethanol hypnosis. The only significant difference between these synaptosomal plasma membranes is the synaptosomal monosialoganglioside (GM1) content, LS > SS. Here, GM1 was examined as a parameter for increasing membrane sensitivity to ethanol effects in the ethanol-resistant SS membranes. Synaptosomal plasma membranes from SS mice were allowed to incorporate exogenous GM1. Membrane order was then studied at the surface, intermediate, and interior regions of the membranes by delayed Fourier transform proton NMR in the presence and absence of perdeuterated ethanol. Differences in membrane order were observed in all three membrane regions with increasing perdeuterated ethanol concentrations depending on the synaptosomal GM1 content.

Purification, Characterization, and Molecular Cloning of the Chicken Gizzard Smooth Muscle Ecto-ATPase

The ecto-ATPase from chicken smooth muscle was solubilized, purified, and characterized. Mono- and polyclonal antibodies were raised and the tissue distribution based on Western analysis was determined. N-terminal and internal protein sequences were determined and used to design degenerate oligonucleotide probes to screen a chicken muscle cDNA library. Two overlapping partial clones encoding most of the ecto-ATPase were isolated and sequenced. A unified theory as to the mechanism by which many varied types of molecules modulate ecto-ATPase activity was developed, and the theory was supported by cross-linking data.

Characterization of a GM1-dependent surface interaction for alcohol with DPPC membranes

A unique surface interaction for perdeuterated ethanol and 1-butanol with dipalmitoylphosphatidylcholine (DPPC)/monosialoganglioside (GM1) multilamellar vesicles can be detected from the fast exchange averaging of the nuclear quadrupole coupling constant of the alcohol in the free and bound states using deuterium NMR. At 1.0% perdeuterated ethanol or 0.5% perdeuterated 1-butanol, a small splitting of the alcohol resonance(s) was detected in the liquid-crystalline phase, but not in the gel phase of the bilayer. The observed splitting is proportional to the fraction of alcohol bound and is dependent on temperature, alcohol, and GM1 concentrations. The splitting was only observed in the presence of negatively charged GM1 but not neutral asialoganglioside (asialo-GM1) in DPPC multilamellar vesicles. The observed splitting decreased with the addition of Ca2+ or Mg2+ ions. This effect was reversed upon the addition of chelating agents. It is proposed that the unique surface interaction for alcohol may result from small surface perturbations of the phosphatidylcholine head groups by the negatively charged sialic moieties of neighboring GM1 molecules in the bilayer.