Circular dichroism studies on lipid-protein complexes of a hydrophobic myelin protein

The MAL Family of Proteins: Normal Function, Expression in Cancer, and Potential Use as Cancer Biomarkers

The MAL family of integral membrane proteins consists of MAL, MAL2, MALL, PLLP, CMTM8, MYADM, and MYADML2. The best characterized members are elements of the machinery that controls specialized pathways of membrane traffic and cell signaling. This review aims to help answer the following questions about the MAL-family genes: (i) is their expression regulated in cancer and, if so, how? (ii) What role do they play in cancer? (iii) Might they have biomedical applications? Analysis of large-scale gene expression datasets indicated altered levels of MAL-family transcripts in specific cancer types. A comprehensive literature search provides evidence of MAL-family gene dysregulation and protein function repurposing in cancer. For MAL, and probably for other genes of the family, dysregulation is primarily a consequence of gene methylation, although copy number alterations also contribute to varying degrees. The scrutiny of the two sources of information, datasets and published studies, reveals potential prognostic applications of MAL-family members as cancer biomarkers-for instance, MAL2 in breast cancer, MAL2 and MALL in pancreatic cancer, and MAL and MYADM in lung cancer-and other biomedical uses. The availability of validated antibodies to some MAL-family proteins sanctions their use as cancer biomarkers in routine clinical practice.

MALL, a membrane-tetra-spanning proteolipid overexpressed in cancer, is present in membraneless nuclear biomolecular condensates

Proteolipids are proteins with unusual lipid-like properties. It has long been established that PLP and plasmolipin, which are two unrelated membrane-tetra-spanning myelin proteolipids, can be converted in vitro into a water-soluble form with a distinct conformation, raising the question of whether these, or other similar proteolipids, can adopt two different conformations in the cell to adapt their structure to distinct environments. Here, we show that MALL, another proteolipid with a membrane-tetra-spanning structure, distributes in membranes outside the nucleus and, within the nucleus, in membrane-less, liquid-like PML body biomolecular condensates. Detection of MALL in one or other environment was strictly dependent on the method of cell fixation used, suggesting that MALL adopts different conformations depending on its physical environment —lipidic or aqueous— in the cell. The acquisition of the condensate-compatible conformation requires PML expression. Excess MALL perturbed the distribution of the inner nuclear membrane proteins emerin and LAP2β, and that of the DNA-binding protein BAF, leading to the formation of aberrant nuclei. This effect, which is consistent with studies identifying overexpressed MALL as an unfavorable prognostic factor in cancer, could contribute to cell malignancy. Our study establishes a link between proteolipids, membranes and biomolecular condensates, with potential biomedical implications.

The initial events in myelin synthesis: orientation of proteolipid protein in the plasma membrane of cultured oligodendrocytes

Proteolipid protein (PLP) is the most abundant transmembrane protein in myelin of the central nervous system. Conflicting models of PLP topology have been generated by computer predictions based on its primary sequence and experiments with purified myelin. We have examined the initial events in myelin synthesis, including the insertion and orientation of PLP in the plasma membrane, in rat oligodendrocytes which express PLP and the other myelin-specific proteins when cultured without neurons (Dubois-Dalcq, M., T. Behar, L. Hudson, and R. A. Lazzarini. 1986. J. Cell Biol. 102:384-392). These cells, identified by the presence of surface galactocerebroside, the major myelin glycolipid, were stained with six anti-peptide antibodies directed against hydrophilic or short hydrophobic sequences of PLP. Five of these anti-peptide antibodies specifically stained living oligodendrocytes. Staining was only seen approximately 10 d after PLP was first detected in the cytoplasm of fixed and permeabilized cells, suggesting that PLP is slowly transported from the RER to the cell surface. The presence of PLP domains on the extracellular surface was also confirmed by cleavage of such domains with proteases and by antibody-dependent complement-mediated lysis of living oligodendrocytes. Our results indicate that PLP has only two transmembrane domains and that the great majority of the protein, including its amino and carboxy termini, is located on the extracellular face of the oligodendrocyte plasma membrane. This disposition of the PLP molecule suggests that homophilic interactions between PLP molecules of apposed extracellular faces may mediate compaction of adjacent bilayers in the myelin sheath.

Comparative study of myelin proteolipid apoprotein solvation by multilayer membranes of synthetic DPPC and biological lipid extract from bovine brain. An FT-IR investigation

The interaction between the aqueous form of the myelin proteolipid apoprotein (PLA) and model membranes prepared with either synthetic dipalmitoylphosphatidyl choline (DPPC) or biological lipids extracted from bovine brain (BE) has been investigated by Fourier-Transform IR spectroscopy. IR spectra obtained with lyophilized samples of PLA demonstrated 2 main peaks (amide I and amide II) culminating at 1656 cm-1 and 1545 cm-1, which we assigned to helical conformation. When PLA was solvated in DPPC or BE membranes, both the amide I and amide II features remained located at 1655 cm-1 and 1545 cm-1, although their half-width significantly decreased, demonstrating that the lipid environment favoured alpha helix structures. However differences between both mixtures were detected by measuring the amide I and amide II half-widths as a function of the L:P molar ratio. Moreover, analysis of the 1545/1515 peak intensity ratio brought evidence of different localization and/or molecular arrangement of the protein segments containing tyrosine residues, depending on the lipid composition of the membrane. According to previously published models, these data suggest that recombinants prepared with PLA and BE multilayers better mimic the biological membrane than do DPPC-PLA mixtures.

Acylation in vitro of the myelin proteolipid protein and comparison with acylation in vivo: acylation of a cysteine occurs nonenzymatically

Characteristics of fatty acylation of myelin proteolipid protein (PLP) in vitro were compared with the corresponding process in vivo. Rapid and efficient separation of labelled PLP from other proteins and lipids was effected by extraction into chloroform/methanol/0.1 N HCl (10/10/1) and chromatography on Sephadex LH-60 in the same solvent. Covalent linkage of [3H]-palmitate to PLP was demonstrated by repetitive chromatography on LH-60, thin layer chromatography, and polyacrylamide gel electrophoresis. Reductive cleavage with sodium borohydride of PLP acylated in vitro or in vivo yielded [3H]-hexadecanol, identifying at least one of the acyl linkages as a thiolester bond. When PLP was acylated with acyl-CoA as the fatty acid donor, the reaction occurred non-enzymatically as supported by the following observations: 1) acylation activity increased with increasing pH above pH 7.5, 2) acylation activity was heat stable, 3) acylation activity was not removed from PLP during purification in organic solvents or in Triton X-100-containing buffers, and 4) acylation of tryptic fragments occurred in the absence of an exogenously added enzyme source. The relevance of in vitro fatty acylation of PLP to that in vivo was confirmed by comparison of proteolytically derived peptide maps that showed that likely the same domain of PLP was acylated in vitro and in vivo.

The secondary structure of a membrane-embedded peptide from the carboxy terminus of lipophilin as revealed by circular dichroism

Several intramembranous peptides have been isolated from the major myelin proteolipid protein (lipophilin) isolated from normal human myelin membrane after labelling the protein with a membrane-permeable photolabel, 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine. Peptide T-3, comprising residues 205-268, represents the C-terminal portion of the protein. Reconstitution of peptide T-3 into lipid vesicles prepared from egg phosphatidylcholine (PC) or into lysoPC micelles yielded visually transparent preparations, free of scattering artifacts, which were used for circular dichroism studies to assess the extent of secondary structure in the peptide. Peptide T-3 had a high degree of alpha-helix in various environments. In aqueous environment, the secondary structure was 45% alpha-helix, 33% beta-structure and 9% beta-turns. Transfer of the peptide to PC vesicles or lysoPC micelles increased the proportion of alpha-helix and decreased that of beta-structure. In PC vesicles, the alpha-helical content was 80% with little or no beta-structure. Small amounts of other structures such as beta-turns and unordered structures were also present. The partitioning of this C-terminal section of lipophilin into membranes may have an important role initiating and/or stabilizing the native conformation of lipophilin in the myelin membrane.

Cyst(e)ine residues of bovine white-matter proteolipid proteins. Role of disulphides in proteolipid conformation

Cyst(e)ine residues of bovine white-matter proteolipid proteins were characterized in a highly purified preparation. From a total of 10.6 cyst(e)ine residues/molecule of protein, as determined by performic acid oxidation, 2.5-3 thiol groups were freely accessible to iodoacetamide, iodoacetic acid and 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB), when the proteins were solubilized in chloroform/methanol (C/M) (2:1, v/v). The presence of lipids had no effect on thiol-group exposure. One thiol group available to DTNB in C/M could not be detected when proteolipids were solubilized in the more polar solvent n-butanol. In a C/M solution of purified proteolipid proteins, SDS did not increase the number of reactive thiol groups, but the cleavage of one disulphide bridge made it possible to alkylate six more groups. C.d. and fluorescence studies showed that rupture of this disulphide bond changed the protein conformation, which was reflected in partial loss of helical structure and in a greater exposure to the solvent of at least one tryptophan residue. Cyst(e)ine residues were also characterized in the different components [PLP (principal proteolipid protein), DM20 and LMW (low-Mr proteins)] of the proteolipid preparation. Although the numbers of cyst(e)ine residues in PLP and DM20 were similar, in LMW fewer residues were alkylated under four different experimental conditions. The differences, however, are not simply related to differences in Mr.

Expression of a plasma membrane proteolipid during differentiation of neuronal and glial cells in primary culture

Plasma membrane proteolipid protein (PM-PLP) synthesis was examined in embryonic rat neurons and neonatal rat glial cells during differentiation in culture. Glial cultures were treated with 1 mM N6, O2, dibutyryl cyclic adenosine monophosphate (dbcAMP) following confluency to induce differentiation, which resulted in the elaboration of long cellular processes. However, no changes in the biosynthetic level of PM-PLP was observed during the differentiation of these cells. Neurons differentiated spontaneously in culture, forming cellular aggregates immediately following plating and elaborating a network of neurites over 7 days. The differentiation of neurons was accompanied by a seven-fold increase in PM-PLP synthesis with increases in biosynthetic increase in PM-PLP synthesis with increases in biosynthetic rate observed between days 1 and 3 and between days 3 and 7 in culture. Ultrastructural examination of neurons indicated that the Golgi apparatus was also developing during this period of time, with an increase in both the number of lamellae and generation of vesicles. The transport of PM-PLP to the plasma membrane was therefore examined in neurons at day 7 in culture by pulse labeling experiments with monensin and colchicine. Monensin (1 microM) was found to inhibit the appearance of radiolabeled PM-PLP in the plasma membrane by 63%, indicating that a functional Golgi apparatus is required for transport of PM-PLP to its target membrane. Colchicine (125 microM) also inhibited the appearance of newly synthesized PM-PLP in the plasma membrane by greater than 40%, suggesting that microtubules may also be required for PM-PLP transport to the plasma membrane.

Freeze-fracture characterization of proteolipid protein and basic protein of central nervous system myelin incorporated in liposomes

Proteolipid protein (PLP) and basic protein (BP) of central nervous system myelin were purified from calf brain white matter and incorporated in liposomes of L-dimyristoyl-alpha-phosphatidylcholine (DML) or in liposomes formed with an extract of natural lipids from myelin. Freeze-fracture replicas of the liposomes were prepared to study the number and size of intramembrane protein particles (IMP) in the fracture faces of the lipid bilayer. Globular and elongated IMP were observed in the freeze-fracture liposome membranes after incorporation of proteolipid protein. Globular IMP were the most frequently found (91-96% of the total IMP), and some of them showed a tiny black spot or pit on the top, suggesting the presence of hydrophilic channels in these particles. Globular and elongated IMP were also observed in the fractured membranes when basic protein was incorporated in liposomes. Again, globular IMP were the most frequent (92-95%) but no spots were present on the top. In addition, both globular and elongated IMP generated by basic protein were significantly larger than IMP generated by PLP. The proportion, size and form of globular and elongated particles generated by PLP and BP were unaffected by the amount of protein incorporated in liposomes (0.13-0.75 protein/lipid, w/w) nor by the type of lipid matrix used (DML or myelin natural lipid mixture). Intramembrane particles were absent from membranes of liposomes of pure lipid.

Characterization and biosynthesis of the plasma membrane proteolipid protein in neural tissue

In this study we have characterized, in brain, the expression of a plasma membrane proteolipid protein (PM-PLP) complex that can form cation-selective channels in lipid bilayers. We isolated PLP fractions from synaptic plasma membrane and glial microsomes and found a high degree of similarity in both size and amino acid composition to the complex we had previously isolated from kidney. Antibodies specific to the kidney PM-PLP were prepared, and, on the basis of immunoblot and immunoprecipitation studies, the PM-PLP complex isolated from neural membranes was shown to be immunologically related to the kidney PM-PLP. These proteolipid proteins exhibited a molecular weight of approximately 14K and contained a high percentage of hydrophobic amino acids with an apparent absence of cysteine. The biogenesis of PM-PLP in brain was studied by in vitro translation of free and bound polysomes and total RNA in a rabbit reticulocyte lysate followed by immunoprecipitation of the translation products. From these studies it is concluded that the PM-PLP complex is synthesized on the rough endoplasmic reticulum. On the basis of the identical electrophoretic mobility of material isolated from plasma membranes and material immunoprecipitated after translation of bound polysomes and isolated RNA, it appears that the PM-PLP does not undergo detectable posttranslational processing between its site of synthesis and its incorporation into the plasma membrane.

The presence of aldehyde-reacted proteins in normal and multiple sclerosis white matter

The incorporation of tritium from NaB3H4 into the major protein components of myelin and the presence of weak fluorescence emission bands at wavelengths of approximately 440 and 500 nm from sodium dodecyl sulfate-solubilized, delipidated white matter are indicative of the presence of the products of aldehyde reactions with proteins. The incorporation of tritium from NaB3H4 into myelin proteins was confirmed by reaction with purified components of myelin basic protein or with lipophilin, a purified fraction of proteolipid protein. From the extent of tritium incorporation into the purified proteins, it is estimated that approximately 0.2 mol of tritium is incorporated/mol of myelin basic protein and approximately 0.4 mol of tritium/mol of proteolipid protein. There is approximately 50% greater incorporation of tritium into a more degraded, less positively charged form of the basic protein. The incorporation of tritium into normal and multiple sclerosis white matter was compared. There is a small but statistically significant difference in the percentage of the total counts incorporated into the major protein fractions for the two groups, with the multiple sclerosis samples showing a higher percentage of the counts in the Wolfgram protein and a lower percentage in the myelin basic protein compared with the normal samples.

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.

Structure of the proteolipid protein extracted from bovine central nervous system myelin with nondenaturing detergents

As a basis for attempts to define the structures of the proteins within myelin, methods have been developed for their extraction and isolation in solutions of non-denaturing detergents. With use of solutions of deoxycholate or Triton X-100, up to 90% of the protein has been extracted from bovine CNS myelin, along with most of the phospholipid. The proteolipid protein has been purified in deoxycholate solutions by chromatography on a blue dye-ligand column, which retained all of the basic protein and 2',3'-cyclic nucleotide-3'-phosphodiesterase, and then on Sephacryl S300, which separated proteolipid protein from phospholipid and high-molecular-weight proteins. The proteolipid protein was isolated from Triton X-100 extracts of myelin by adsorption onto phosphocellulose resin, with subsequent elution by 0.5 M sodium chloride. Gel permeation chromatography was used as the final purification step. Sedimentation equilibrium experiments gave a monomer molecular weight of 134,000 +/- 8000 in deoxycholate and 145,000 +/- 17,000 in Triton X-100 solutions. On the basis of an apparent subunit molecular weight of 23,500 it was deduced that the native protein is probably hexameric. Above 0.2 gL-1 in Triton X-100 solutions and 0.5 gL-1 in deoxycholate solutions the protein aggregated. In deoxycholate solutions the protein adopts the highly helical conformation expected for an intrinsic membrane protein.

Volume properties of mixtures of lipophilin and dimyristoylphosphatidylcholine

The hydrophobic myelin protein, lipophilin, has been incorporated into bilayers of dimyristoylphosphatidylcholine by dialysis from 2-chloroethanol. The protein was shown to be incorporated into a protein-lipid complex of uniform density by density gradient sedimentation equilibrium. The volume properties of the resulting complexes were studied by densitometry. It was found that a molecule of the protein could prevent an increase in volume at the phase transition temperature of 19 lipid molecules. The remaining lipid underwent its phase transition over a broader temperature range, resulting in a decrease in the volume coefficient of expansion in the region of the phase transition. The protein has little effect on this parameter at higher or lower temperatures. The partial specific volume of the lipid alone was similar to what has been previously determined using freshly prepared suspensions. The partial specific volume of the protein alone was similar to the value calculated based on the amino acid composition. The partial specific volume of the lipid-protein complex, however, was less than the weighted average of the components, indicating that lipophilin could induce an increase in the density of the lipid. This condensing effect of lipophilin was observed both above and below the phase transition and may be a general property of proteins incorporated into lipid bilayers.

Effect of the state of association of melittin and phospholipids on their reciprocal binding

In solutions of increasing ionic strength, the molecular weight of melittin varies from 2840 (monomeric melittin) to 11200. This polymerization, concomitant with an important change in conformation (Talbot, J.C., Dufourcq, J., De Bony, J., Faucon, J.F. and Lussan, C. (1979) FEBS Lett. 102, 191-193), is accompanied by a significant alteration in the partial specific volume of the molecule. The binding of melittin to phospholipids (phosphatidylserine, lysolecithin, dihexanoyl-, dioctanoyl- and lysolauroylphosphatidylcholine) depends on the state of association of the toxin and on the critical micelle concentration of lipids. No interaction is observed between monomeric melittin and free lipids, whereas tetrameric melittin can bind free lipids to form mixed micelles. At phospholipid concentrations above the critical micelle concentration, melittin in any state of self-association can bind lipids. The mixed micelles formed at saturation appear to be independent of the initial state of association of melittin.

Myelin lipophilin-induced demyelinating disease of the central nervous system

Purified lipophilin, a hydrophobic lipoprotein of myelin, induces a cell-mediated demyelinating disease of the central nervous system similar to experimental allergic encephalomyelitis (EAE) induced by the myelin basic protein (MBP). Guinea pigs challenged with lipophilin (emulsified with CFA) developed clinical and histological signs of disease indistinguishable from those developed by animals similarly challenged with MBP. Both lipophilin and MBP induced and elicited delayed-type hypersensitivity in animals challenged with respective antigens. Tryptophan, an essential component of the MBP-determinant for disease in guinea pigs, is required for the encephalitogenicity of lipophilin.

Circular dichroic, infrared and other studies on the protein component of pig brain thromboplastin

1. A four-step procedure used to isolate the protein component (apoprotein III) of pig brain thromboplastin yielded approximately 25 mg from 500g of brain. 2. In the absence of detergent, apoprotein III had an apparent mol.wt. of 360 000 by gel-filtration, and, after electrophoresis on polyacrylamide gels in the presence of sodium docecyl sulphate, it appeared as a major protein band of mol.wt.59 000, suggesting the existence of polymeric and monomeric forms. 3. Chemical analyses of apoprotein III revealed that hydrophilic and hydrophobic amino acids were present in a ratio of 3:2, together with approx, 9% (w/w) of carbohydrate. 4. The far-u.v.c.d. and i.r. spectral data indicated that, like other membrane proteins, apoprotein III has a high percentage of unordered structure with lesser amounts of alpha and beta-forms. 5. Relipidation of apoprotein III to restore clotting activity caused no extensive alteration in the c.d. and i.r. spectra, indicating that the phospholipid associates with a comparatively small hydrophobic segment. The constrained unordered conformation, which makes the major contribution to the c.d. spectrum, probably forms a separate domain in the aqueous phase. The absence of any increase in the amplitude of both negative c.d. extrema, following relipidation, contrasted with the substantial increase observed in a helix-forming solvent and raises the possibility that the more stable polymeric form of apoprotein III is retained as the active form in the lipid phase. 6. We suggest that as a consequence of cell membrane damage, the recognition and activation of factor VII may involve minor changes of conformation that are dependent upon the flexibility inherent in an unordered secondary structure.

Interactions of Folch-Lees proteolipid apoprotein with planar lipid bilayers

Water-soluble Folch-Lees proteolipid apoprotein from bovine CNS white matter induces a voltage-dependent conductance in black lipid membranes. Na+ is required for the induced conductance change but the established conductance has very low ionic selectivity. The induced conductance fluctuates with a minimum amplitude of 10(-11)--10(-10) mho. The magnitude of the conductivity change is dependent on protein concentration and on the composition of lipid bilayers. At a fixed voltage the induced conductance of a phosphatidylcholine-cholesterol membrane is proportional to the sixth power of the protein concentration and the first power of Na+ concentration. The interactions between the apoprotein and the lipids are both electrostatic and hydrophobic, but the interaction leading to the conductance increase appears to be mainly hydrophobic. Both the increase in conductance and the current fluctuations remain after extensive washing of the chambers to remove the protein. Furthermore, pronase or glutaraldehyde added to either the cis or trans side of the membrane does not affect the apoprotein-established conductance. However, if the bilayer is formed in the presence of both the apoprotein and pronase or if the apoprotein is treated with pronase prior to its addition to the chamber, no conductance change is observed. The association of the apoprotein with the membrane thus appears to render the protein inaccessible to proteolytic digestion, suggesting that the apoprotein is at least partially imbedded in the membrane interior.

The structure of melittin in lipid bilayer membranes

0.15 M inorganic phosphate dramatically increased the alpha-helix content of melittin in aqueous solution. When melittin interacted with egg yolk phosphatidylcholine liposomes in the absence of inorganic phosphate, it was converted to an alpha-helix rich form, as postulated by Dawson et al. (Dawson, C.R., Drake, A.F. Helliwell, J. and Hider, R.C. (1978) Biochim. Biophys. Acta 510, 75--86).

Study of fluorescent tryptophyl residues and extrinsic probes for the characterization of molecular domains of Folch-Pi apoprotein

The highly hydrophobic myelin Folch-Pi apoprotein can be solubilized in organic as well as in aqueous media. In order to understand the molecular organization changes consecutive to changes in the solvent medium, the environment of intrinsic probes and extrinsic labels has been studied by fluorescence and accessibility to some reagents. In acqueous solution, only two tryptophan residues per protein molecule of 23,500 molecular weight have been shown to fluoresce, and their fluorescence characterisitics indicate an hydrophobic and/or constrained environment. Two ANS binding sites have also been observed having a high quenching effect on the intrinsic chromophore fluorescence. A large accessibility has been evidenced for the protein sulfhydryl groups in chloroform-methanol 2:1 (v/v), both by kinetic study of the protein reaction with a specific reagent, N-(1-anilino-naphtyl-4) maleimide, and by the fluorescence characteristics of this probe once linked to the protein. The free sulfhydryl groups were still reactive in acqueous solution, but extrinsic fluorescence of the labelled apoprotein transferred from chloroform-methanol 2:1 (v/v) into water gave evidence of constraints on the probe or on its environment. Such constraints may contribute to the solubilization in acqueous solution of this highly hydrophobic protein.

The molecular size and shape of the Folch-Pi apoprotein in aqueous and organic solvents

In 1% acetic acid, sedimentation velocity measurements and equilibrium ultracentrifuge experiments demonstrate that the Folch-Pi apoprotein is not monodisperse. The weight-average molecular weight calculated from ultracentrifuge experiments and combining sedimentation coefficient and viscosity measurements, ranged from 64000 to 80000. The intrinsic viscosity value suggests an asymetric shape for the apoprotein if a low value of hydration is considered. In dioxan/1% acetic acid (2:3, v/v) a smaller sedimentation coefficient was found, the intrinsic viscosity value remaining identical to that in 4% acetic acid. In pure 2-chloroethanol, light-scattering experiments led to a molecular weight of 165000 indicating that even in this solvent the protein is not monomeric. Intrinsic viscosity and light scattering measurements on the one hand, primary sequence on the other hand (six proline residues per monomer of Mr 23500) suggest that the molecule in 2-chloroethanol may consist of rod-like segments with flexible junctions.

Effect of phospholipase A2 on purified gastric vesicles

The phospholipid and fatty acid composition and role of phospholipids in enzyme and transport function of gastric (H+ + K+)-ATPase vesicles was studied using phospholipase A2 (bee venom). The composition (%) was phosphatidyl-choline (PC) 33%; sphingomyelin (sph) 25%; phosphatidylethanolamine (PE) 22%; phosphatidylserine (PS) 11%; and phosphatidylinositol (PI) 8%. The fatty acid composition showed a high degree of unsaturation. In both fresh and lyophilized preparations, even with prolonged incubation, only 50% of phospholipids were hydrolyzed, but the amount of PE and PS disappearing was increased following lyophilization. There was a marked decrease in K+-ATPase activity (75%) but essentially no loss of the associated K+ p-nitrophenyl phosphatase was found. ATPase activity could be largely restored by various phospholipids (PE greater than PC greater than PS). There was also an increase in Mg2+-ATPase activity, partially reversed in fresh preparations by the addition of phospholipids (PE greater than PS greater than PC). Proton transport activity of the preparation was rapidly inhibited, initially due to a large increase in the HCl permeability of the preparation. Associated with these enzymatic and functional changes, the ATP-induced conformational changes, as indicated by circular dichroism spectra were inhibited.