Characterization and partial purification of squalene-2,3-oxide cyclase from Saccharomyces cerevisiae.

The membrane nature of squalene oxide cyclase from Saccharomyces cerevisiae was investigated by comparing properties of the enzyme recovered from both microsomes and the soluble fraction of the yeast homogenate. The "apparent soluble" form and microsomal form of the enzyme were both stimulated by the presence of mammalian soluble cytoplasm and corresponded to one another in response to detergents Triton X-100 and Triton X-114. The observed strong dependence of the enzyme activity on the presence of detergents and the behavior of the enzyme after Triton X-114 phase separation were peculiar to a lipophilic membrane-bound enzyme. A study of the conditions required to extract the enzyme from microsomes confirmed the lipophilic character of the enzyme. Microsomes, exposed to ipotonic conditions to remove peripheral membrane proteins, retained most of the enzyme activity within the integral protein fraction. Quantitative dissociation of the enzyme from membranes occurred only if microsomes were treated with detergents (Triton X-100 or octylglucoside) at concentrations which alter membrane integrity. The squalene oxide cyclase was purified 140 times from yeast microsomes by (a) removal of peripheral proteins, (b) extraction of the enzyme from the integral protein fraction with octylglucoside, and (c) separation of the solubilized proteins by DEAE Bio-Gel A chromatography. Removal of the peripheral proteins seemed to be a key step necessary for obtaining high yields.     

Solubilization of the Cytoplasmic Membrane of Escherichia coli by Triton X-100

Treatment of a partially purified preparation of cell walls of Escherichia coli with Triton X-100 at 23 C resulted in a solubilization of 15 to 25% of the protein. Examination of the Triton-insoluble material by electron microscopy indicated that the characteristic morphology of the cell wall was not affected by the Triton extraction. Contaminating fragments of the cytoplasmic membrane were removed by Triton X-100, including the fragments of the cytoplasmic membrane which were normally observed attached to the cell wall. Treatment of a partially purified cytoplasmic membrane fraction with Triton X-100 resulted in the solubilization of 60 to 80% of the protein of this fraction. Comparison of the Triton-soluble and Triton-insoluble proteins from the cell wall and cytoplasmic membrane fractions by polyacrylamide gel electrophoresis after removal of the Triton by gel filtration in acidified dimethyl formamide indicated that the detergent specifically solubilized proteins of the cytoplasmic membrane. The proteins solubilized from the cell wall fraction were qualitatively identical to those solubilized from the cytoplasmic membrane fraction, but were present in different proportions, suggesting that the fragments of cytoplasmic membrane which are attached to the cell wall are different in composition from the remainder of the cytoplasmic membrane of the cell. Treatment of unfractionated envelope preparations with Triton X-100 resulted in the solubilization of 40% of the protein, and only proteins of the cytoplasmic membrane were solubilized. Extraction with Triton thus provides a rapid and specific means of separating the proteins of the cell wall and cytoplasmic membrane of E. coli.     

A novel two-step extraction method with detergent/polymer systems for primary recovery of the fusion protein endoglucanase I-hydrophobin I

Extraction systems for hydrophobically tagged proteins have been developed based on phase separation in aqueous solutions of non-ionic detergents and polymers. The systems have earlier only been applied for separation of membrane proteins. Here, we examine the partitioning and purification of the amphiphilic fusion protein endoglucanase I(core)-hydrophobin I (EGI(core)-HFBI) from culture filtrate originating from a Trichoderma reesei fermentation. The micelle extraction system was formed by mixing the non-ionic detergent Triton X-114 or Triton X-100 with the hydroxypropyl starch polymer, Reppal PES100. The detergent/polymer aqueous two-phase systems resulted in both better separation characteristics and increased robustness compared to cloud point extraction in a Triton X-114/water system. Separation and robustness were characterized for the parameters: temperature, protein and salt additions. In the Triton X-114/Reppal PES100 detergent/polymer system EGI(core)-HFBI strongly partitioned into the micelle-rich phase with a partition coefficient (K) of 15 and was separated from hydrophilic proteins, which preferably partitioned to the polymer phase. After the primary recovery step, EGI(core)-HFBI was quantitatively back-extracted (K(EGIcore-HFBI)=150, yield=99%) into a water phase. In this second step, ethylene oxide-propylene oxide (EOPO) copolymers were added to the micelle-rich phase and temperature-induced phase separation at 55 degrees C was performed. Total recovery of EGI(core)-HFBI after the two separation steps was 90% with a volume reduction of six times. For thermolabile proteins, the back-extraction temperature could be decreased to room temperature by using a hydrophobically modified EOPO copolymer, with slightly lower yield. The addition of thermoseparating co-polymer is a novel approach to remove detergent and effectively releases the fusion protein EGI(core)-HFBI into a water phase.     

A simple, rapid and non-destructive procedure to extract cell wall-associated proteins from Frankia

A simple cell fractionation procedure was developed to extract cell wall-associated proteins from the nitrogen-fixing actinomycete Frankia. The method was based on washing Frankia mycelia in 62.5 mM Tris-HCl (pH 6.8) buffer supplemented with 0.1% Triton X-100 as solubilizing agent. Cell wall-associated proteins were efficiently extracted in less than 10 min, recovering approximately 94.5+/-7.44 microg protein per extraction procedure from exponentially growing cells corresponding to 50 ml of culture. The amount of cell lysis occurring during the cell wall extraction was estimated to be 1.50+/-0.51%. Three peptidoglycan hydrolases with apparent molecular masses of 4.7, 12.1, and 17.8 kDa were detected by zymography in the cell wall-associated protein fraction. On the contrary, no cell wall lytic enzyme was detected in the cytoplasmic protein fraction. These results indicate that the present method enables a specific extraction of cell wall-associated proteins. Moreover, fluorescein isothiocyanate (FITC) labelling of the cell surface proteins showed an efficient removal of cell wall-associated proteins. Growth of the treated Frankia cells (i.e. cells from which the cell wall-associated proteins were removed) in semi-solid media suggested that these cells were still viable. This technique is of importance for functionality studies of cell wall-associated proteins, particularly for bacteria where traditional cell fractionation methods are difficult to be applied.     

Choline acetyltransferase in mammalian synaptosomes: Evidence for an integral membrane-bound form

Choline acetyltransferase activity was detected in extensively washed membranes prepared from rat and guinea pig synaptosomes. When these preparations were treated with the non-ionic detergent Triton X-114 and heated to 37°C to cause phase separation, a significant percentage was found to associate with the detergent-rich phase, indicating that the enzyme might be an integral membrane-bound protein. In guinea pigs receiving septal lesions, a large reduction in both total and in Triton X-114-extractable choline acetyltransferase in hippocampal synaptosomes was observed indicating that the detergent-extracted form is associated with cholinergic nerve terminals. When membrane-bound choline acetyltransferase from lysed, washed synaptosomes was incubated in Triton X-114, 30% of the membrane-associated enzyme could be extracted into the detergent-rich phase. This extraction could be improved by reducing the chloride content of the extraction medium. When the chloride content of synaptosomes, prepared from rat cerebral cortex, was manipulated, by either exposure to γ-aminobutyric acid, muscimol or to a medium containing reduced levels of chloride, the ability of antibodies against choline acetyltransferase to specifically immunolyse (in the presence of complement) the cholinergic synaptosome population was enhanced. These results suggest that the choline acetyltransferase found in the nerve terminal region exists in at least two forms (a soluble and a lipophilic form) which are partially interconvertible. The conversion between the two forms can be influenced by chloride ions.     

Protein organization in mouse liver peroxisomes.

Peroxisomes from mouse liver were fractionated with Triton X-114, a procedure which yields a detergent phase consisting of proteins containing hydrophobic binding sites, and a nondetergent, or aqueous, phase containing hydrophilic proteins. When this method was applied to peroxisomes from control mice, catalase and fatty acyl-CoA oxidase distributed to the aqueous phase, whereas the integral membrane protein, PMP68, and the bifunctional protein were recovered exclusively in the detergent phase. Urate oxidase distributed intermediate between these two phases. With peroxisomes from mice treated with the peroxisome proliferator clofibrate, the bifunctional protein was recovered in both the detergent and the aqueous phases, and urate oxidase was shifted toward the aqueous phase. Other analyses of the subperoxisomal distribution of the bifunctional protein were consistent with a proportion of this protein being tightly associated with the peroxisomal membrane, or with some other uncharacterized, poorly soluble, component. Sucrose gradient centrifugation of the aqueous phase resulting from Triton X-114 fractionation of peroxisomes revealed that a major proportion of catalase, fatty acyl-CoA oxidase, the bifunctional protein, and other unidentified proteins behaved as if associated under these conditions. In this respect, use of a higher concentration of Triton X-114 for peroxisome fractionation led to the partitioning of some catalase and fatty acyl-CoA oxidase to the detergent phase, indicating the presence of some detergent-accessible hydrophobic binding sites even on these proteins. These data have been interpreted as indicating matrix protein associations in vivo, associations which may be responsive to proliferator treatment.     

A novel two-step extraction method with detergent/polymer systems for primary recovery of the fusion protein endoglucanase I–hydrophobin I

Extraction systems for hydrophobically tagged proteins have been developed based on phase separation in aqueous solutions of non-ionic detergents and polymers. The systems have earlier only been applied for separation of membrane proteins. Here, we examine the partitioning and purification of the amphiphilic fusion protein endoglucanase I_core–hydrophobin I (EGI_core–HFBI) from culture filtrate originating from a Trichoderma reesei fermentation. The micelle extraction system was formed by mixing the non-ionic detergent Triton X-114 or Triton X-100 with the hydroxypropyl starch polymer, Reppal PES100. The detergent/polymer aqueous two-phase systems resulted in both better separation characteristics and increased robustness compared to cloud point extraction in a Triton X-114/water system. Separation and robustness were characterized for the parameters: temperature, protein and salt additions. In the Triton X-114/Reppal PES100 detergent/polymer system EGI_core–HFBI strongly partitioned into the micelle-rich phase with a partition coefficient (K) of 15 and was separated from hydrophilic proteins, which preferably partitioned to the polymer phase. After the primary recovery step, EGI_core–HFBI was quantitatively back-extracted (K_{EGIcore–HFBI}=150, yield=99%) into a water phase. In this second step, ethylene oxide–propylene oxide (EOPO) copolymers were added to the micelle-rich phase and temperature-induced phase separation at 55°C was performed. Total recovery of EGI_core–HFBI after the two separation steps was 90% with a volume reduction of six times. For thermolabile proteins, the back-extraction temperature could be decreased to room temperature by using a hydrophobically modified EOPO copolymer, with slightly lower yield. The addition of thermoseparating co-polymer is a novel approach to remove detergent and effectively releases the fusion protein EGI_core–HFBI into a water phase.     

Phase separation of integral membrane proteins in Triton X-114 solution

A solution of the nonionic detergent Triton X-114 is homogeneous at 0 degrees C but separates in an aqueous phase and a detergent phase above 20 degrees C. The extent of this detergent phase separation increases with the temperature and is sensitive to the presence of other surfactants. The partition of proteins during phase separation in solutions of Triton X-114 is investigated. Hydrophilic proteins are found exclusively in the aqueous phase, and integral membrane proteins with an amphiphilic nature are recovered in the detergent phase. Triton X-114 is used to solubilize membranes and whole cells, and the soluble material is submitted to phase separation. Integral membrane proteins can thus be separated from hydrophilic proteins and identified as such in crude membrane or cellular detergent extracts.     

Fractionation of renal brush border membrane proteins with Triton X-114 phase partitioning.

Analysis of brush border membrane proteins by gel electrophoresis has revealed a complex polypeptide composition. We have investigated the use of Triton X-114 phase partitioning to fractionate such proteins on the basis of their degree of hydrophobicity. Each of the fractions was composed of a complex but distinct set of proteins. Most proteins were solubilized by Triton X-114 and partitioned into the detergent-poor fraction. Trehalase, gamma-glutamyl transpeptidase, and leucine aminopeptidase were well solubilized (greater than 80%) and enriched 5.1-, 3.9-, and 2.5-fold in the detergent-rich fraction. In contrast, alkaline phosphatase and 5'-nucleotidase were poorly solubilized. The specific activities of these enzymes were increased 2.7- and 2.3-fold in the insoluble protein fraction. Maltase was almost completely solubilized and partitioned into the detergent-poor fraction with a small enrichment factor (1.3). These results suggest that Triton X-114 phase partitioning could be useful as a first step in the purification of many brush border membrane proteins.     

Triton X-114 phase fractionation of membrane proteins of the cyanobacterium Anacystis nidulans R2

The thylakoid polypeptides of the cyanobacterium Anacystis nidulans R2 were analyzed by Triton X-114 phase fractionation [C. Bordier (1981) J. Biol. Chem.256, 1604–1607, as adapted for photosynthetic membranes by T. M. Bricker and L. A. Sherman (1982) FEBS Lett.149, 197–202]. In this procedure, polypeptides with extensive hydrophobic regions (i.e., intrinsic proteins) form mixed micelles with Triton X-114, and are separated from extrinsic proteins by temperature-mediated precipitation of the mixed Triton X-114-intrinsic protein micelles. The polypeptide pattern after phase fractionation was highly complementary, with 62 of the observed 110 polypeptide components partitioning into the Triton X-114-enriched fraction. Identified polypeptides fractionating into the Triton X-114 phase included the apoproteins for Photosystems I and II, cytochromes f and b₆, and the herbicide-binding protein. Identified polypeptides fractioning into the Triton X-114-depleted (aqueous) phase included the large and small subunits of RuBp carboxylase, cytochromes c₅₅₀ and c₅₅₄, and ferredoxin. Enzymatic radioiodination of the photosynthetic membranes followed by Triton X-114 phase fractionation allowed direct identification of intrinsic polypeptide components which possess surface-exposed regions susceptible to radioiodination. The most prominent of these polypeptides was a 34-kDa component which was associated with photosystem II. This phase partitioning procedure has been particularly helpful in the clarification of the identity of the membrane-associated cytochromes, and of photosystem II components. When coupled with surface-probing techniques, this procedure is very useful in identifying intrinsic proteins which possess surface-exposed domains. Phase fractionation, in conjunction with the isolation of specific membrane components and complexes, has allowed the identification of many of the important intrinsic thylakoid membrane proteins of A. nidulans R2.     

Fractionation of Tetrahymena ciliary membranes with triton X-114 and the identification of a ciliary membrane ATPase

Cilia were isolated from Tetrahymena thermophila, extracted with Triton X-114, and the detergent-soluble membrane + matrix proteins separated into Triton X-114 aqueous and detergent phases. The aqueous phase polypeptides include a high molecular mass polypeptide previously identified as a membrane dynein, detergent-soluble alpha and beta tubulins, and numerous polypeptides distinct from those found in axonemes. Integral membrane proteins partition into the detergent phase and include two major polypeptides of 58 and 50 kD, a 49-kD polypeptide, and 5 polypeptides in relatively minor amounts. The major detergent phase polypeptides are PAS-positive and are phosphorylated in vivo. A membrane-associated ATPase, distinct from the dynein-like protein, partitions into the Triton X-114 detergent phase and contains nearly 20% of the total ciliary ATPase activity. The ATPase requires Mg++ or Ca++ and is not inhibited by ouabain or vanadate. This procedure provides a gentle and rapid technique to separate integral membrane proteins from those that may be peripherally associated with the matrix or membrane.     

Fractionation of detergent lysates of cells by ammonium sulphate-induced phase separation

A procedure is described for fractionating detergent lysates of cells based on the ability of (NH4)2SO4 to induce phase separation of detergents such as Triton X-100, sodium deoxycholate, and sodium cholate, into detergent-rich and detergent-depleted phases. An analysis of six murine lymphocyte cell surface molecules revealed that the partitioning in Triton X-100 of each molecule was highly dependent upon the (NH4)2SO4 concentration, each antigen partitioning into the detergent-rich phase at a defined salt concentration. In contrast, none of the six molecules appeared in the detergent-rich phase of a Triton X-114 phase separation, even though two of the molecules, namely Ly-2/3 and L3T4, are well-characterized integral membrane proteins. It was also observed that (NH4)2SO4 resulted in the partitioning of many nonmembrane proteins into the detergent-rich phase, indicating that the procedure can be used to fractionate all cellular proteins. By judicious choice of (NH4)2SO4 concentrations, precipitation of cellular proteins at two different (NH4)2SO4 concentrations, and combining the method with subcellular fractionation prior to detergent solubilization, substantial enrichment and concentration of particular cellular proteins could be achieved.     

Characterization of the cell wall and cell wall proteins of Chromatium vinosum.

Highly purified cell walls of Chromatium vinosum were isolated by differential centrifugation, with or without Triton X-100 extraction. The isolated material had a protein composition similar to that of cell walls obtained by sucrose density gradient centrifugation. Twenty-two proteins were reproducibly detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A 42-kilodalton protein was shown to account for 65% of the total cell wall protein. The majority of cell wall proteins were solubilized in sodium dodecyl sulfate at room temperature; however, they existed as high-molecular-weight complexes unless heated to 45 degrees C or above. The cell wall contained one heat-modifiable protein which migrated with an apparent molecular weight of 37,400 when solubilized at 70 degrees C or below, but which migrated with an apparent molecular weight of 52,500 if solubilized at 100 degrees C. The electrophoretic mobility of three proteins was modified by 2-mercaptoethanol. The majority of C. vinosum cell wall proteins had isoelectric points between pH 4.5 and 5.5, and the 42-kilodalton protein focused at pH 4.9. No proteins were detected which were analogous to the lipoprotein or peptidoglycan-associated proteins of the Enterobacteriaceae. Nearest-neighbor analysis with a reducible, cross-linking reagent indicated that three proteins, including the 42-kilodalton protein, associated with themselves. Most of the cell wall proteins were partially accessible to proteases in both intact cells and isolated cell walls. Protease treatment of the whole cell or isolated cell wall digested approximately an 11,000-molecular-weight portion of the 42-kilodalton protein.     

Treatment of C6 Glioma Cells and Rats with Antidepressant Drugs Increases the Detergent Extraction of Gsα from Plasma Membrane

Results from previous studies suggested that chronic treatment of rats or C6 glioma cells with antidepressants augments the coupling between Gs and adenylyl cyclase. As these effects on C6 glioma cells are seen in the absence of presynaptic input, several antidepressant drugs may have a direct "postsynaptic" effect on their target cells. It was hypothesized that the target of antidepressant action was some membrane protein that may regulate coupling between G proteins and adenylyl cyclase. To test this, C6 glioma cells were treated with amitriptyline, desipramine, iprindole, or fluoxetine for 3 days. Chlorpromazine served as a control for these treatments. Membrane proteins were extracted sequentially with Triton X-100 and Triton X-114 from C6 glioma cells. Triton X-100 extracted more G(s alpha) in membranes prepared from antidepressant-treated C6 glioma cells than from control groups. In addition, cell fractionation studies revealed that the amount of G(s alpha) in caveolin-enriched domains was reduced after antidepressant treatment and that adenylyl cyclase comigrated with G(s alpha) in the gradients. These data suggest that some postsynaptic component that increases availability of Gs to activate effector molecules, such as adenylyl cyclase, might be a target of antidepressant treatment.     

Double Triton X-114 Phase Partitioning for the Purification of Plant Cytochromes P450 and Removal of Green Pigments

A double Triton X-114 phase partitioning procedure that separates plant cytochromes P450 from green pigments and provides an extract highly enriched in total cytochromes P450 has been developed. Upon phase partitioning in Triton X-114, plant cytochromes P450 have previously been found to partition to the pigmented detergent rich phase. These partitionings were carried out using phosphate buffer. We found that the partitioning of the cytochromes P450 could be shifted to a pigment-free Triton X-114 poor phase by changing the buffer component to borate. The protein extract containing the cytochromes P450 but devoid of green pigment was subjected to a second phase partitioning step before which the buffer was changed from borate to phosphate. This second phase partitioning step produced a Triton X-114-rich phase highly enriched in cytochromes P450 proteins compared to the microsomal starting material as monitored by sodium dodecyl sulfate–polyacrylamide gel electrophoresis, cytochrome P450 reconstitution assays, and Western blotting. The yield of the double phase partitioning purification procedure is about 26% which is high compared to the yields obtained at similar stages of purification using column chromatography. The double phase partitioning procedure takes 3–4 h to complete. This is very fast compared to traditional purification schemes for cytochromes P450 which involve multiple of column chromatographic steps. Plant cytochromes P450 are labile, low abundant proteins that are difficult to isolate. The double Triton X-114 phase partitioning here reported thus constitutes a versatile, efficient purification procedure circumventing many of the problems previously encountered.     

Phase separation temperatures of mixtures of Triton X-114 and Triton X-45: application to protein separation.

Triton X-114 solutions separate above 22 degrees C into two immiscible aqueous phases. The more dense phase is enriched in detergent, and the less dense phase is depleted of detergent, relative to the original single phase. This phenomenon has been used to partition proteins according to hydrophobicity. The phase separation temperature is sensitive to the length of the polyoxyethylene headgroup. When Triton X-45, with a shorter headgroup, is mixed with Triton X-114 in various proportions, the phase transition temperature can be adjusted anywhere between 0 and 22 degrees C. Partitioning properties of the resulting mixtures are similar to those of Triton X-114 alone.     

The characterization of plasma membrane-bound tubulin of cauliflower using Triton X-114 fractionation.

The cortical microtubules determine how cellulose microfibrils are deposited in the plant cell wall and are thus important for the control of cell expansion. To understand how microtubules can control microfibril deposition, the components that link the microtubules to the plasma membrane (PM) of plant cells must be isolated. To obtain information on the properties of the tubulin-membrane associations, cauliflower (Brassica oleracea) PM was subjected to Triton X-114 fractionation, and the distribution of alpha- and beta-tubulin was analyzed using immunoblotting. Approximately one-half of the PM-associated tubulin was solubilized by Triton X-114 and 10 to 15% of both alpha- and beta-tubulin was recovered in the detergent phase (indicative of hydrophobic properties) and 30 to 40% was recovered in the aqueous phase. The hydrophobic tubulin could be released from the membrane by high pH extraction with preserved hydrophobicity. A large part of the PM-associated tubulin was found in the Triton-insoluble fraction. When this insoluble material was extracted a second time, a substantial amount of hydrophobic tubulin was released if the salt concentration was increased, suggesting that the hydrophobic tubulin was linked to a high-salt-sensitive protein aggregate that probably includes other components of the cytoskeleton. The hydrophobicity of a fraction of PM-associated tubulin could reflect a direct or indirect interaction of this tubulin with the lipid bilayer or with an integral membrane protein and may represent the anchoring of the cortical microtubules to the PM, a key element in the regulation of cell expansion.     

2-D differential membrane proteome analysis of scarce protein samples

Proteome studies with small sample amounts are difficult to perform, especially when membrane proteins are the focus of interest. In our study a new method for the analysis of scarce membrane protein samples combining large gel 2-D-CTAB/SDS-PAGE with fluorescence dye saturation labelling (satDIGE) was developed, allowing a highly sensitive differential analysis of different cell states. After Triton X-114 phase partitioning, enriched membrane protein samples of T cells were labelled at cysteine residues using fluorescence dyes and separated by large gel 2D-CTAB/SDS-PAGE. For a differential analysis 3 mug protein was found to be sufficient to detect proteins in a widespread well-separated diagonal spot pattern.     

Selective release of the Treponema pallidum outer membrane and associated polypeptides with Triton X-114.

The effects of the nonionic detergent Triton X-114 on the ultrastructure of Treponema pallidum subsp. pallidum are presented in this study. Treatment of Percoll-purified motile T. pallidum with a 1% concentration of Triton X-114 resulted in cell surface blebbing followed by lysis of blebs and a decrease in diameter from 0.25-0.35 micron to 0.1-0.15 micron. Examination of thin sections of untreated Percoll-purified T. pallidum showed integrity of outer and cytoplasmic membranes. In contrast, thin sections of Triton X-114-treated treponemes showed integrity of the cytoplasmic membrane but loss of the outer membrane. The cytoplasmic cylinders generated by detergent treatment retained their periplasmic flagella, as judged by electron microscopy and immunoblotting. Recently identified T. pallidum penicillin-binding proteins also remained associated with the cytoplasmic cylinders. Proteins released by Triton X-114 at 4 degrees C were divided into aqueous and hydrophobic phases after incubation at 37 degrees C. The hydrophobic phase had major polypeptide constituents of 57, 47, 38, 33-35, 23, 16, and 14 kilodaltons (kDa) which were reactive with syphilitic serum. The 47-kDa polypeptide was reactive with a monoclonal antibody which has been previously shown to identify a surface-associated T. pallidum antigen. The aqueous phase contained the 190-kDa ordered ring molecule, 4D, which has been associated with the surface of the organisms. Full release of the 47- and 190-kDa molecules was dependent on the presence of a reducing agent. These results indicate that 1% Triton X-114 selectively solubilizes the T. pallidum outer membrane and associated proteins of likely outer membrane location.     

Effect of Ethylenediaminetetraacetic Acid, Triton X-100, and Lysozyme on the Morphology and Chemical Composition of Isolated Cell Walls of Escherichia coli

Extraction of a partially purified preparation of cell walls from Escherichia coli with the nonionic detergent Triton X-100 removed all cytoplasmic membrane contamination but did not affect the normal morphology of the cell wall. This Triton-treated preparation, termed the “Triton-insoluble cell wall,” contained all of the protein of the cell wall but only about half of the lipopolysaccharide and one-third of the phospholipid of the cell wall. This Triton-insoluble cell wall preparation was used as a starting material in an investigation of several further treatments. Reextraction of the Triton-insoluble cell wall with either Triton X-100 or ethylenediaminetetraacetic acid (EDTA) caused no further solubilization of protein. However, when the Triton-insoluble cell wall was extracted with a combination of Triton X-100 and EDTA, about half of the protein and all of the remaining lipopolysaccharide and phospholipid were solubilized. The material which remained insoluble after this combined Triton and EDTA extraction still retained some of the morphological features of the intact cell wall. Treatment of the Triton-insoluble cell wall with lysozyme resulted in a destruction of the peptidoglycan layer as seen in the electron microscope and in a release of diaminopimelic acid from the cell wall but did not solubilize any cell wall protein. Extraction of this lysozyme-treated preparation with a combination of Triton X-100 and EDTA again solubilized about half of the cell wall protein but resulted in a drastic change in the morphology of the Triton-EDTA-insoluble material. After this treatment, the insoluble material formed lamellar structures. These results are interpreted in terms of the types of noncovalent bonds involved in maintaining the organized structure of the cell wall and suggest that the main forces involved are hydrophobic protein-protein interactions between the cell wall proteins and to a lesser degree a stabilization of protein-protein and protein-lipopolysaccharide interactions by divalent cations. A model for the structure of the E. coli cell wall is presented.