Preparation of reconstituted acetylcholine receptor membranes suitable for AFM imaging of lipid–protein interactions

The nicotinic acetylcholine receptor (nAChR) has been reconstituted in POPC vesicles at high lipid–protein (L/P) ratios for the preparation of supported lipid bilayers with a low protein density for studies of protein–lipid interactions using atomic force microscopy (AFM). Initial reconstitutions using a standard dialysis method with bulk L/P ratios ranging from 20:1 to 100:1 (w/w) gave heterogeneous samples that contained both empty vesicles and proteoliposomes with a range of L/P ratios. This is problematic because empty vesicles adsorb and rupture to form bilayer patches more rapidly than do protein-rich vesicles, resulting in the loss of protein during sample washing. Although it was not possible to find reconstitution conditions that gave homogeneous populations of vesicles with high L/P ratios, an additional freeze–thaw cycle immediately after dialysis did reproducibly yield a fraction of proteoliposomes with L/P ratios above 100:1. These proteoliposomes were separated by sucrose gradient centrifugation and used to prepare supported bilayers with well-separated individual receptors and minimal adsorbed proteoliposomes. AFM images of such samples showed many small features protruding from the bilayer surface. These features range in height from 1 to 5 nm, consistent with the smaller intracellular domain of the protein exposed, and have lateral dimensions consistent with an individual receptor. Some bilayers with reconstituted protein also had a small fraction of higher features that are assigned to nAChR with the larger extracellular domain exposed and showed evidence for aggregation to give dimers or small oligomers. This work demonstrates the importance of using highly purified reconstituted membranes with uniform lipid–protein ratios for AFM studies of integral membrane protein–lipid interactions.     

Lipid bilayers and liposomes in reconstitution experiments with cholinergic proteolipid from torpedo electroplax

The cholinergic proteolipid from $\text{Torpedo}$ electroplax was used in reconstitution experiments in artificial membranes being incorporated directly into the membrane-forming solution or into liposomes (proteoliposomes) which interacted with lecithin bilayers. In both cases the membrane became reactive to acetylcholine by a decrease in resistance and an increase in the frequency and amplitude of minute current fluctuations of 3·10^?11 to 4·10^?10mho. The injection of d-tubocurarine prod$\text{u}$ ced an increase in membrane resistance and a decrease in the amplitude of the current fluctuations. These results suggest that the cholinergic proteolipid is reconstituted in an active form in the bilayer.     

Calcium Movements Mediated by Proteolipid Protein and Nucleotides in Liposomes Prepared with the Endogenous Lipids from Brain White Matter

A lipid extract with a composition similar to that of myelin was used to prepare liposomes and proteoliposomes containing the Folch-Lees proteolipid apoprotein. Freeze-fracture replicas of the proteoliposomes were prepared to demonstrate the presence of intramembrane protein particles in the fracture faces of the lipid bilayer. Experiments with 45CaCl2 showed that a steady calcium movement occurs across liposomal membranes, approaching equilibrium between intra- and extravesicular spaces. The most significant finding was that Mg-ATP, ATP analogues, and other nucleotides depressed significantly the calcium fluxes in proteoliposomes, having no effect on liposomes that lacked the proteolipid protein. It is suggested that this intrinsic protein, interacting with nucleotides and endogenous lipids, could be involved in the regulation of calcium levels in myelin by means of a conformational change mechanism. These observations could lead to implications concerning the pathophysiology of myelin.     

Effect of N,N-Dicyclohexylcarbodiimide on Acetylcholine Release from Torpedo Synaptosomes and Proteoliposomes Reconstituted with the Proteolipid Mediatophore

The mediatophore is a presynaptic membrane protein that has been shown to translocate acetylcholine (ACh) under calcium stimulation when reconstituted into artificial membranes. The mediatophore subunit, a 15-kDa proteolipid, presents a very high sequence homology with the N,N'-dicyclohexylcarbodiimide (DCCD)-binding proteolipid subunit of the vacuolar-type H(+)-ATPase. This prompted us to study the effect of DCCD, a potent blocker of proton translocation, on calcium-dependent ACh release. The present work shows that DCCD has no effect on ACh translocation either from Torpedo synaptosomes or from proteoliposomes reconstituted with purified mediatophore. However, using [14C]DCCD, we were able to demonstrate that the drug does bind to the 15-kDa proteolipid subunit of the mediatophore. These results suggest that although the 15-kDa proteolipid subunits of the mediatophore and the vacuolar H(+)-ATPase may be identical, different domains of these proteins are involved in proton translocation and calcium-dependent ACh release and that the two proteins have a different membrane organization.     

The effect of a proteolipid from sarcoplasmic reticulum on the physical properties of artificial phospholipid membranes

Sarcoplasmic reticulum membranes from skeletal muscle contain a proteolipid ($\text{M}{}_{\mathrm{<mtext>r</mtext>}}\text{≈ 12 000}$) which reduces both the nonspecific ion and water permeabilities of artificial planar phospholipid bilayers. The proteolipid does not show any ionophoric effect or specific pore formation for Ca²⁺. The a.c. capacitance of the bilayers is unaffected whereas the refractive index is increased by the presence of proteolipid. The results support the view that the proteolipid interacts with the phospholipids in the bilayer interior and causes a condensation in the packing of the alkyl chains.     

Interaction of phosphatidylserine synthase from E. coli with lipid bilayers: coupled plasmon-waveguide resonance spectroscopy studies

The interaction of phosphatidylserine (PS) synthase from Escherichia coli with lipid membranes was studied with a recently developed variant of the surface plasmon resonance technique, referred to as coupled plasmon-waveguide resonance spectroscopy. The features of the new technique are increased sensitivity and spectral resolution, and a unique ability to directly measure the structural anisotropy of lipid and proteolipid films. Solid-supported lipid bilayers with the following compositions were used: 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC); POPC-1-palmitoyl-2-oleoyl-sn-glycero-3-phosphate (POPA) (80:20, mol/mol); POPC-POPA (60:40, mol/mol); and POPC-1-palmitoyl-2-oleoyl-sn-glycero-3-[phospho-rac-(1-glycerol)] (POPG) (75:25, mol/mol). Addition of either POPA or POPG to a POPC bilayer causes a considerable increase of both the bilayer thickness and its optical anisotropy. PS synthase exhibits a biphasic interaction with the bilayers. The first phase, occurring at low protein concentrations, involves both electrostatic and hydrophobic interactions, although it is dominated by the latter, and the enzyme causes a local decrease of the ordering of the lipid molecules. The second phase, occurring at high protein concentrations, is predominantly controlled by electrostatic interactions, and results in a cooperative binding of the enzyme to the membrane surface. Addition of the anionic lipids to a POPC bilayer causes a 5- to 15-fold decrease in the protein concentration at which the first binding phase occurs. The results reported herein lend experimental support to a previously suggested mechanism for the regulation of the polar head group composition in E. coli membranes.     

The integrity of proteoliposomes adsorbed on a biosurface

Proteoliposomes encapsulating [¹⁴C]glucose have been prepared from a mixture of dipalmitoylphosphatidylcholine and phosphatidylinositol by sonication (SUV) and reverse phase evaporation (REV) and conjugated with wheat germ agglutinin (WGA). The proteoliposomes were characterised in terms of size and composition and covered a range of size (weight-average diameter) from approximately 60–330 nm and surface-bound WGA (weight-average number of protein molecules per liposome) from approximately 70 to 3000. Methods have been developed for assessing the extent of adsorption and integrity of the proteoliposomes when targeted to glycophorin A-coated microtitre wells. From the amount of [¹⁴C]glucose released by detergent disruption from the adsorbed proteoliposomes it is found that the extent of adsorption increases with proteoliposome size and WGA conjugation and that the integrity of the proteoliposomes remains intact on adsorption. The results can be explained in terms of monolayer coverage of the surface with preferential adsorption of larger proteoliposomes from the size distribution.     

Intrinsic fluorescence of a non-myelin apoproteolipid and evidence for the existence of conformational flexibility

An extremely hydrophobic protein (Mr = 16000), which in its native form is only soluble in organic solvents and which differs from the myelin proteolipid (Mr = 24000), was purified to homogeneity. Intrinsic fluorescence studies on this apoproteolipid have revealed a large conformational flexibility. In the water-soluble form the emitting residues appear to be buried in a hydrophobic core while in organic solvents they are exposed to the external medium. Structural changes depending on the organic solvent are also observed. The emission characteristics of reconstituted proteoliposomes may be due to the formation of a membrane-linked complex between several proteolipid monomers.     

Use of a fluorescence spectroscopy technique to study the adsorption of sodium dodecylsulfonate on liposomes

The fluorescent probe 2-(p-toluidinyl)-naphthalene-6-sodium sulfonate (TNS) was used to study the surface adsorption of sublytic concentrations of the anionic surfactant sodium dodecylsulfonate (C(12)-SO(3)) on phosphatidylcholine (PC) bilayers. The number of adsorbed molecules was quantified by determination of the electrostatic potential (psi(o)) of the bilayers. The abrupt decrease in the fluorescence intensity detected even 10 s after the surfactant addition and the slight fluorescence variations with time indicated that the surfactant adsorption was very fast and almost complete. For a given number of monomers adsorbed a linear dependence between the lipid and C12-SO3 concentrations was obtained, indicating similar adsorption mechanism regardless of the surfactant concentration. Hence, a monomeric adsorption is assumed even in systems with a C12-SO3 concentration above its CMC. In addition, this linear correlation allowed us to determine the surfactant/lipid molar ratios (Re) (inversely related to the C12-SO3 ability to be adsorbed on liposomes) and the bilayer/aqueous phase coefficients (K). The fact that the lowest values for Re were always reached after 10 s of incubation corroborates the rapid kinetics of the process. The decrease in the C12-SO3 partitioning (K) when the number of surfactant molecules exceeded 15000 was possibly due to the electrostatic repulsion between the free and the adsorbed monomers, which could hinder the incorporation of new monomers on the charged surface of liposomes.     

PROTEOLYTIC DIGESTION OF BOVINE BRAIN WHITE MATTER PROTEOLIPID

—Proteolipids were previously considered to be resistant to proteolytic digestion. In the present study, crude bovine white matter proteolipid, proteolipid apoprotein, and chemically modified proteolipids were subjected to the action of the following proteolytic enzymes in the absence and presence of detergents: trypsin, α-chymotrypsin, elastase, thermolysin and collagenase. The course of digestion was followed by the release of Fluorescamine-reactive groups. Tryptic digestion of the crude proteolipid and the apoprotein in the absence of detergent amounted to 10 and 40% respectively of the digestion in the presence of detergent. Peptide mapping and protein analyses of both the soluble digests and the insoluble residues confirmed digestion. In the presence of either sodium deoxycholate or Triton X-100, essentially all of the crude proteolipid and 60% of the proteolipid apoprotein were solubilized by trypsin. Digestion of the apoprotein was observed only in preparations which had not been dried. In the absence of detergent, (1) the oxidized crude proteolipid was more susceptible to tryptic digestion than were either the unoxidized or carboxymethylated preparations, (2) both the apoprotein and the oxidized proteolipid were digested by thermolysin or α-chymotrypsin, and (3) all preparations were attacked by elastase.     

Blockade of a mitochondrial cationic channel by an addressing peptide: An electrophysiological study

Summary A voltage-dependent cationic channel of large conductance is observed in phospholipid bilayers formed at the tip of microelectrodes from proteoliposomes derived from mitochondrial membranes. This channel was blocked by a 13-residue peptide with the sequence of the amino terminal extremity of the nuclear-coded subunit IV of cytochromec oxidase. The blockade was reversible, voltage- and dose-dependent. The peptide did not affect the activity of aTorpedo chloride channel observed under the same conditions. From experiments with phospholipid monolayers, it is unlikely that the peptide inserts into bilayers under the experimental conditions used. The blockade was observed from both sides of the membrane, being characterized by more frequent transitions to the lower conductance states, and a maximum effect was observed around 0 mV. Channels, the gating mechanism of which had been eliminated by exposure to trypsin, were also blocked by the peptide. For trypsinized channels, the duration of the closure decreased and the blockade saturated at potentials below –30 mV. These observations are consistent with a translocation of the peptide through the channel. Dynorphin B, which has the same length and charge as the peptide, had some blocking activity. Introduction of negative charges in the peptide by succinylation suppressed the activity.     

Lipid vesicle adsorption versus formation of planar bilayers on solid surfaces.

The absorption and spreading behavior of lipid vesicles composed of either palmitoyloleoylphosphatidylcholine (POPC) or Escherichia coli lipid upon contact with a glass surface was examined by fluorescence measurements. Fluorescently labeled lipids were used to determine 1) the amount of lipid adsorbed at the surface, 2) the extent of fusion of the vesicles upon contact with the surface, 3) the ability of the adsorbed lipids to undergo lateral diffusion, and 4) the accessibility of the adsorbed lipids by external water soluble molecules. The results of these measurements indicate that POPC vesicles spread on the surface and form a supported planar bilayer, whereas E. coli lipid vesicles adsorb to the surface and form a supported vesicle layer. Supported planar bilayers were found to be permeable for small molecules, whereas supported vesicles were impermeable and thus represented immobilized, topologically separate compartments.     

Formation of model lipid bilayers at the silica-water interface by co-adsorption with non-ionic dodecyl maltoside surfactant

This present article describes a new and simple method for preparing model lipid bilayers. Stable and reproducible surface layers were produced at silica surfaces by co- adsorbing lipid with surfactant at the silica surface from mixed micellar solutions. The adsorption was followed in situ by use of ellipsometry. The mixed micellar solution consisted of a lipid (L-alpha-dioleoyllecithin) and a non-ionic sugar-based surfactant (n-dodecyl-beta-maltoside). The latter showed, by itself, no affinity for the surface and could, therefore, easily be rinsed off the surface after the adsorption step. By first adsorbing from solutions with high lipid and surfactant concentrations and then, in succession, rinsing and re-adsorbing from solutions with lower lipid-surfactant concentrations, a dense-packed lipid bilayer was produced at the silica surface. The same result can be achieved in a one-step process where the rinsing, after adsorption from the concentrated solution, is performed very slowly. The thickness of the adsorbed lecithin bilayer after this treatment found was to be about 44 +/- 3 A, having a mean refractive index of 1.480 +/- 0.004. The calculated surface excess of lipids on silica was about 4.2 mg m(-2), giving an average area per lipid molecule in the two layers of 62 +/- 3 A2. The physical characteristic of the adsorbed bilayer is in good agreement with previously reported data on bulk and surface supported lipid bilayers. However, in contrast to previous investigations, we found no support for the presence of a thicker multi-molecular water layer located between the lipid layer and the solid substrate.     

Conversion between two cytochalasin B-binding states of the human GLUT1 glucose transporter.

Two cytochalasin B-binding states of the human red blood cell facilitative glucose transporter GLUT1 were studied, one exhibiting one cytochalasin B-binding site on every second GLUT1 monomer (state 1) and the other showing one site per monomer (state 2). Quantitative affinity chromatography of cytochalasin B was performed on (a) biotinylated red blood cells, (b) cytoskeleton-depleted red blood cell membrane vesicles, and (c) GLUT1 proteoliposomes. The cells were adsorbed on streptavidin-derivatized gel beads, and the vesicles and proteoliposomes entrapped in dextran-grafted agarose gel beads. Cytochalasin B binding to free vesicles and proteoliposomes was analyzed by Hummel and Dreyer size-exclusion chromatography and ultracentrifugation. Analysis of the biotinylated cells indicated an equilibrium between the two GLUT1 states. GLUT1 in free membrane vesicles attained state 2, but was converted into state 1 on entrapment of the vesicles. Purification of GLUT1 in the presence of non-ionic detergent followed by reconstitution produced GLUT1 in state 1. This state was maintained after entrapment of the proteoliposomes. Finally, GLUT1 showed slightly higher affinity for cytochalasin B in state 1 than in state 2. In summary, the cytochalasin B-binding state of GLUT1 seemed to be affected by (a) biotinylation of the cell surface, (b) removal of the cytoskeleton at high pH and low ionic strength, (c) interaction between the dextran-grafted agarose gel matrix and the membrane vesicles, and (d) reconstitution to form proteoliposomes.     

Fast, efficient reconstitution of the cyclooxygenases into proteoliposomes

To study the physical and catalytic properties of purified membrane proteins, it is often necessary to reconstitute them into lipid bilayers. Here, we describe a fast efficient method for the direct incorporation of cyclooxygenase-1 and -2 (COX-1 and -2) isozymes into liposomes without loss of activity. Purified COX-1 and -2 spontaneously incorporate into large unilamellar vesicles produced from a mixture of DOPC:DOPS (7:3) that has been doped with oleic acid. When incorporation was measured by comparing cyclooxygenase activity to total phospholipid in the proteoliposomes, molar reconstitution ratios of 1000:1 (phospholipid:COX) were obtained. Electron paramagnetic resonance spectroscopic spin counting analysis of proteoliposomes formed with nitroxide spin-labeled COX-2 gave a nearly identical phospholipid:COX ratio, confirming that incorporation had no effect on enzyme activity, and demonstrating that the efficiency of protein incorporation is sufficient for EPR spectroscopic analysis. The spontaneous incorporation of cyclooxygenase into intact liposomes allows only insertion into the outer leaflet for this monotopic enzyme, an orientation confirmed by immunogold staining of the proteoliposomes. This method of reconstitution into liposomes may be generally applicable to the class of monotopic integral membrane proteins typified by the cyclooxygenase isozymes.     

Patch-clamp study of liver nuclear ionic channels reconstituted into giant proteoliposomes

Nuclear ionic channels (NICs) represent ubiquitous structures of living cells, although little is known about their functional properties and encoding genes. To characterize NICs, liver nuclear membrane vesicles were reconstituted into either planar lipid bilayers or proteoliposomes. Reconstitution of nuclear envelope (NE) vesicles into planar lipid bilayer proceeded with low efficiency. NE vesicle reconstitution into proteoliposomes led to NIC observations by the patch-clamp technique. Large conductance, voltage-gated, K(+)-permeant and Cl(-)-permeant NICs were characterized. An 80-105-pS K(+)-permeant NIC with conducting sub-state was also recorded. Our data establish that NICs can be characterized upon reconstitution into giant proteoliposomes and retain biophysical properties consistent with those described for native NICs.     

Kinetics of adsorption of beta-amyloid peptide Abeta(1-40) to lipid bilayers

The Alzheimer's disease-related peptide beta-amyloid (Abeta) is toxic to neurons. The toxicity of the peptide appears to require conversion of the monomeric form to an aggregated fibrillar species. The interaction of Abeta with cell membranes has attracted interest as one plausible mechanism by which the peptide exerts its toxic activity. We developed two methods to measure the adsorption of fresh (monomeric) and aged (aggregated) Abeta to lipid bilayers. In one method, the kinetics of Abeta adsorption and desorption to liposomes deposited onto a dextran-coated surface was measured using surface plasmon resonance. In the other method, Abeta was contacted with liposome-coated magnetic beads; adsorbed Abeta was separated from solution-phase peptide by use of a magnetic field. Monomeric Abeta adsorbed quickly but reversibly to lipid bilayers with low affinity, while aggregated Abeta adsorbed slowly but irreversibly. These two methods provide complementary means of quantifying the adsorption of aggregating proteins to membranes. The results correlate strongly with previous observations that fibrillar, but not monomeric, Abeta restricts the motion of acyl tails in phospholipid bilayers. The methods should be useful for further elucidation of the role of membrane adsorption in mediating Abeta toxicity, and in the search for inhibitors of toxicity.     

Reconstitution of membrane proteins: sequential incorporation of integral membrane proteins into preformed lipid bilayers

Several integral membrane proteins can be inserted sequentially into preformed unilamellar vesicles (ULV's) composed of dimyristoylphosphatidylcholine (DMPC) and cholesterol in a gel phase. Thus, proteoliposomes of DMPC, cholesterol, and bacteriorhodopsin from Halobacterium halobium rapidly incorporate UDPglucuronosyltransferase (EC 2.4.1.17) from pig liver microsomes, cytochrome oxidase from beef heart mitochondria, and additional bacteriorhodopsin, added sequentially. This process of spontaneous incorporation can be regulated to produce complex artificial membranes that contain phospholipids and proteins at ratios (mol/mol) equivalent to what is found in biological membranes. The ability of the lipid-protein bilayers to incorporate additional integral membrane proteins is not affected by annealing of the proteoliposomes at 37 degrees C nor by the order of addition of the proteins. Bacteriorhodopsin-containing vesicles formed by the sequential addition of integral membrane proteins demonstrate light-driven proton pumping. Therefore, they have retained a vesicular structure. Vesicles containing one or two different proteins will fuse with each other at 21 degrees C or with ULV's devoid of proteins. Incorporation of bacteriorhodopsin or UDPglucuronosyltransferase into proteoliposomes containing DMPC, with or without cholesterol as impurity, also occurs above the phase transition for DMPC. The presence of a protein in a liquid-crystalline bilayer provides the necessary condition for promoting the spontaneous incorporation of other membrane proteins into preformed bilayers.     

Reversible binding of substance P to artificial lipid membranes studied by capacitance minimization techniques

Interaction of substance P with electrically neutral, planar lipid bilayers prepared from 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine and with anionic bilayers prepared from mixtures of 1,2-dioleoyl-sn-glycero-3-phosphocholine and brain phosphatidylserine was measured using the capacitance minimization method for monitoring the membrane surface potential caused by the positive charges and electric dipole moment of adsorbed peptide. Substance P bound to the electrically neutral bilayers from 9 mM KCl (buffered to pH 5.5 with 2.0 mM 2-(N-morpholino)ethanesulfonate) with a maximal binding density of about 1 x 10(-2) molecules per nm2 and a dissociation constant of about 2 x 10(-4) M. Measurement of the surface potential at different ionic strengths (shielding of surface charges) allowed distinction between the fixed-charge surface potential and a dipole potential. Ascribing this dipole potential to membrane-bound substance P would imply an effective dipole moment normal to the bilayer surface of about 20 Debye per molecule. Magnitude and polarity are consistent with an alpha-helical domain at the C-terminal end of substance P which is oriented normal to the surface of the membrane, and inserted so as to be inaccessible to the aqueous phase. Consistent measurements were obtained with anionic membranes at low substance P concentrations (10(-7)-10(-6) M; pH 7.2). They indicated electrostatic accumulation of the triply charged peptide on the surface of the membrane followed by hydrophobic interaction with the same parameters as for neutral membranes. The results agree with the membrane structure of substance P determined with infrared attenuated total reflection spectroscopy, circular dichroism measurements, and thermodynamic estimations.     

Glutamate transport in pig heart mitochondria. Binding and structural properties of high-glutamate affinity proteolipid: Reconstitution studies

Previously, a proteolipid that can bind glutamate with high affinity has been isolated from pig heart mitochondrial membranes. A final affinity chromatography on γ-methylglutamate-albumin coreticulated on glass fiber was necessary. This procedure includes long dialysis steps which tend to denature the high-glutamate affinity proteolipid.Here is described a new method of isolation which avoids long dialysis steps and yields greater amounts of the high-glutamate affinity proteolipid.The binding of glutamate or aspartate on high-glutamate affinity proteolipid has been studied by gel filtration, by equilibrium dialysis or by a new procedure of rapid centrifugation based on the insolubility of high-glutamate affinity proteolipid in water. The latter method permits the detection of low and high affinity sites for glutamate with a $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ 60 mM and 55 μM, respectively. Among a series of analogues, aspartate appeared to be the best competitor: $\text{K}{}_{\mathrm{<mtext>d</mtext>}}\text{= 30 μ}\text{M}$ and two $\text{K}{}_{\mathrm{<mtext>i</mtext>}}$ values, 0.37 mM (at high glutamate concentration) and 3.8 μM (at low glutamate concentration). High-glutamate affinity proteolipid binds 0.4 nmol of glutamate but only 0.1 nmol of aspartate per mg protein. The sites for glutamate and aspartate appear to be different but interdependent.In the presence of high-glutamate affinity proteolipid, externally added glutamate stimulated the efflux of aspartate from preloaded liposomes.High-glutamate affinity proteolipid contains cardiolipin, phosphatidyl choline and phosphatidyl ethanolamine the distribution of which is different from that of the inner membrane.The effects of various phospholipases, trypsin, and thiol reagents were studied on the binding of glutamate. High-glutamate affinity proteolipid binds 9 nmol $\text{N-}\text{ethylmaleimide}$ per mg protein but only 6.1 nmol in the presence of glutamate. The dissociation of high-glutamate affinity proteolipid caused by thiol reagents yielded a soluble protein fraction with higher affinity for glutamate.Electrophoresis and an immunological approach allowed the detection and titration of the glutamate dehydrogenase and aspartate aminotransferase present in high-glutamate affinity proteolipid in inhibited forms, the latter being 26-fold more concentrated than the former.