Hydrophobic interactions of the apo-Gln-I polypeptide component of human high density serum lipoprotein.

Apo-Gln-I, the major polypeptide component of human serum high density lipoprotein, has four noninteracting hydrophobic sites which associate with alkanes, anionic detergents, and cationic detergents. Hexane and octane bind to these sites with association constants of 6.8 times 10-2 and 1.8 times 10-4 liters/mol, respectively, and compete with the anionic detergent, sodium dodecyl sulfate (C12OSO3-minus), at low detergent ligand binding ratios (i.e. smaller than or equal to 1.0 mol of C12OSO3-minus per mol of protein). At higher detergent binding ratios (larger than 2 mol of C12OSO3-minus per mol of protein) the polypeptide cooperatively binds alkanes and a conformational change is induced.     

Molecular properties, partial purification, and assay by incubation period measurements of the hamster scrapie agent

The scrapie agent causes a progressive degeneration of the central nervous system of animals after a prolonged incubation period. Measurements of incubation period length, defined as the time from inoculation to the onset of clinical signs of neurological dysfunction, were related to the titer of the agent and the dilution of the inoculated sample. Equations defining the relationship provide a new assay for the agent requiring fewer animals than end point titrations. By use of this incubation period assay, the scrapie agent from hamster brain was found to have an s20,w of < 300 S but > 30 S assuming rho p = 1.2 g/cm3. A partially purified fraction P3 was obtained by differential centrifugation and sodium deoxycholate extraction. When P3 was extracted with phenol, virtually no infectivity was found in the aqueous phase even after examining such variables as pH, salt concentration, and predigestion of samples with proteinase K. Nonionic and nondenaturing, anionic detergents did not inactivate the scrapie agent; in contrast, denaturing detergents inactivated the agent. Sodium dodecyl sulfate (NaDodSO4) inactivated greater than 90% of the agent at a NaDodSO4 to protein ratio of 1.8 g/g. Inactivation by NaDodSO4 appears to be a cooperative process. Addition of a nonionic detergent to form mixed micelles with NaDodSO4 prevented inactivation of the agent by NaDodSO4. Weak chaotropic ions do not inactivate the scrapie agent while strong chaotropic ions like SCN- and Cl3CCOO- destroy infectivity at concentrations of 0.2 M. These data provide evidence in support of a protein component within the scrapie agent which is essential for maintenance of infectivity. Thus, it is unlikely that the scrapie agent is composed only of a "naked" nucleic acid as is the case for the plant viroids.     

Interaction of the mouse and bovine myelin basic proteins and two cleavage fragments with anionic detergents

The binding of deoxycholate and dodecyl sulfate to the mouse and bovine myelin basic proteins and two peptide fragments, obtained by cleavage of the bovine basic protein at its single tryptophan residue, was examined. Complete equilibrium binding isotherms for both detergents were obtained by examining their binding to each of the polypeptides immobilized on agarose. The bulk of the binding of dodecyl sulfate was found to be highly cooperative, and at saturation all four polypeptides bound far more detergent than globular, water-soluble proteins. The sum of the dodecyl sulfate bound by each of the two bovine basic protein cleavage fragments was almost twice that bound by the intact protein at saturation, suggesting that cleavage of the bovine basic protein exposes sites for additional binding of dodecyl sulfate. At pH values below pH 8.0, an additional cooperative transition was observed below the critical micelle concentration of sodium dodecyl sulfate in the binding isotherms of all four polypeptides. The midpoint of this transition corresponded to an apparent pK of approximately 5.5; however, the destruction of 90% of the histidine residues in the bovine basic protein had no effect on this transition. At pH 9.2 and moderate ionic strength (I = 0.1), the bulk of the binding of deoxycholate to the mouse and bovine basic proteins occurred at and above the critical micelle concentration of the detergent; and saturation values of deoxycholate binding to these two proteins were considerably higher than that reported for globular, water-soluble proteins. In marked contrast to the results with dodecyl sulfate, neither cleavage fragment was observed to bind deoxycholate. The results suggest that the higher ordered structure of the bovine basic protein may play an important role in the binding of anionic amphiphiles to the protein.     

Interactions of melittin, a preprotein model, with detergents.

Bee venom melittin is a water-soluble tetramer of identical polypeptide chains. Each chain has 26 residues. The 20 N-terminal residues are hydrophobic and the 6 C-terminal residues are basic. Melittin has been shown to integrate into natural and synthetic membranes and to lyse a wide variety of cells. To understand how a water-soluble protein can spontaneously partition into a membrane, we have studied the interaction of melittin with micelles of deoxycholate (DOC), Brij 58, and sodium dodecyl sulfate (NaDodSO4). Circular dichroism spectra showed that NaDodSO4, an ionic detergent, and Brij 58, a nonionic detergent, caused similar major changes in the protein's conformation. Gel filtration studies revealed that melittin forms mixed micelles with either Brij or DOC. The melittin-DOC mixed micelles have 2 mol of DOC per mol of melittin. Cross-linking studies with dimethyl suberimidate confirmed that the protein is a tetramer and showed that it becomes monomeric either in mixed micelles with Brij or DOC or in butanol. Despite this major structural change of melittin in the presence of an amphiphile, the covalently cross-linked form is as active in human erythrocyte lysis as the native protein.     

A detergent-activated tyrosinase from Xenopus laevis. II. Detergent activation and binding

Tyrosinase purified from Xenopus is enzymatically inactive in aqueous buffers but is activated for both of its substrates by exposure to a variety of anionic detergents. Cationic and nonionic detergents, as well as a variety of other agents are ineffective. This stimulation by detergents is observed at all stages of the purification (Wittenberg, C., and Triplett, E. L. (1985) J. Biol. Chem. 260, 12535-12541). Sodium dodecyl sulfate (NaDodSO4) is the most effective activator, and it was chosen for further characterization. Activation of both activities by NaDodSO4 is rapid and concentration dependent, resulting in maximal activity after 4 min at 1 mM NaDodSO4. NaDodSO4 treatment also results in both long and short term stabilization of the enzyme. The activation and stabilization are separable but stoichiometrically related. Both effects occur well below the critical micelle concentration suggesting that the interaction of NaDodSO4 monomers with the enzyme is involved in these processes. In support of this suggestion, the enzyme is shown to bind NaDodSO4 with high affinity, as determined by equilibrium dialysis. The isotherm for this binding correlates well with the requirement of NaDodSO4 for both activation and stabilization. All three effects are observable at 3 X 10(-5) M NaDodSO4 in the presence of 0.1 M sodium chloride. Activation and stabilization are maximal at 6 X 10(-4) M NaDodSO4, the critical micelle concentration of NaDodSO4 under these conditions.     

A new competition assay for the solubilized hepatic galactosyl receptor

The present method of quantitating soluble asialoglycoprotein (galactosyl) receptor activity relies on the selective precipitation of receptor-ligand complexes to allow separation from free ligand. To provide an alternative to selective precipitation procedures, a simple and rapid method to assay for detergent-solubilized galactosyl receptor activity has been developed which uses permeabilized, fixed cells as a source of immobilized solid-phase receptors. Isolated rat hepatocytes were treated with digitonin to make available the internal as well as the external receptors. The permeable cells were also treated with glutaraldehyde to prevent further protein loss during subsequent exposure to detergents such as Triton X-100. The permeable/fixed cells, which retained about 70% of their total 125I-asialo-orosomucoid (125I-ASOR)-binding activity, with 89% specific binding, were insoluble even in 0.5% Triton X-100 and were easily pelleted. The permeable/fixed cells can be prepared in advance and stored frozen for months. A detergent extract of receptor is mixed with a constant amount of both 125I-ASOR and permeable/fixed cells. Soluble active receptors compete with immobilized receptors on the treated cell for binding of the 125I-ASOR. The assay is reproducible, linear over a broad range of soluble receptor concentration, and can quantitate receptor activity from as few as 10(5) hepatocytes. A modified purification procedure for the rat hepatic galactosyl receptor using this competition assay is also described.     

Interaction of proteins with detergents: Binding of cationic detergents with lysozyme

Binding studies of cationic detergents such as cetyl trimethylammonium bromide, Cetylpyridinium bromide and dodecyl trimethylammonium bromide with lysozyme were carried out by equilibrium dialysis, ultraviolet difference and circular dichroism techniques at 25 C. Binding isotherms at pH 5·0, 7·0 and 9·0 show cooperative binding at all concentrations of detergents and the number of available binding sites in lysozyme increases with pH. Gibbs free energy of binding calculated on the basis of Wymans’ binding potential concept increases with pH indicating increased binding strength at higher pH. The ultraviolet difference spectra of the detergent complexes with lysozyme at pH 7·0 and 9·0 in the region of 250–300 nm indicate the involvement of aromatic amino acid residues as probable binding sites and also the carboxylate groups since the binding is cooperative. The circular dichroism spectra also indicate the involvement of aromatic amino acid residues in the binding of these detergents. This is substantiated by the decrease in the intensity of the aromatic positive bands in the near ultraviolet region. The increase in the magnitude of [θ]_{222 nm} values in the far ultraviolet region with the increase in the concentration of the detergent in the complex indicates conformational changes resulting in an increase of α-helical content producing a more ordered structure of lysozyme.These binding studies show that at pH 7·0 and 9·0, hydrophobic interactions play a major role, while at pH 5·0 only electrostatic interactions play prominent role in the binding of these detergents. Paper presented at the International Symposium on Biomolecular Structure and Interactions held at the Molecular Biophysics Unit, Indian Institute of Science, Bangalore, during 17–22, December 1984.     

A detergent-activated tyrosinase from Xenopus laevis. I. Purification and partial characterization

A tyrosinase has been purified from the skin of the frog Xenopus laevis. Dihydroxyphenylalanine oxidase and tyrosine hydroxylase activities co-purify throughout the procedure. The enzyme is isolated in an inactive form, but both enzymatic activities are activated by a variety of anionic detergents. Of these, sodium dodecyl sulfate (NaDodSO4) is the most effective. The enzyme activation occurs at NaDodSO4 concentrations well below the critical micelle concentration and it remains active at concentrations as high as 30 mM (1%). Neither activity is stimulated by cationic or nonionic detergents, or a variety of other agents, including trypsin. The purified tyrosinase is a glycoprotein having a polypeptide Mr = 175,000 by NaDodSO4-polyacrylamide gel electrophoresis. This monomeric species is enzymatically active in the presence of NaDodSO4. Detergent-activated tyrosinase has a KM for dihydroxyphenylalanine of 6 X 10(-4) M and a KM for tyrosine of 4 X 10(-4) M. Both activities are inhibited by copper chelators but not by an iron chelator. Further characterization of the detergent activation of this enzyme is presented in a companion paper (Wittenberg, C., and Triplett, E. L. (1985) J. Biol. Chem. 260, 12542-12546).     

Improved catalytic properties of immobilized lipases by the presence of very low concentrations of detergents in the reaction medium

The addition of a very small concentration of a detergent (in many instances under the critical micellar concentration (cmc)) has been found to greatly increase the activity of immobilized lipases, using those from Pseudomonas fluorescens (PFL) and Candida antarctica (isoform B) as model enzymes. However, the detergents may also have a negative effect on enzyme activity; in fact, for all enzyme preparations and substrates the activity/detergent concentration curve reached a maximum value and started to decrease, in many instances even under the initial value. The concentration and nature of the detergent (SDS, CTAB, Triton X-100, or X-45) that permitted the maximum hyperactivation was different depending on the substrate. The best hyperactivation values promoted by the presence of detergent were over a 20-fold factor. The presence of detergents permitted the inhibition of lipases by irreversible covalent inhibitors (e.g., 4-(2-aminoethyl)benzenesulfonyl fluoride hydrochloride) (AEBSF) while the enzyme, in the absence of detergent, is not inhibited by these irreversible inhibitors. This suggested that the main effect of the detergents is to shift the conformational equilibrium of lipases toward the open form. Moreover, the presence of detergents also permitted to improve the enantioselectivity exhibited by the immobilized lipases in some cases. For example, the enantioselectivity of PFL-glyoxyl agarose increased from 40 to more than 100 in the hydrolysis of (+/-)-2-hydroxy-4-phenylbutyric acid ethyl ester by using 0.1% CTAB.     

Binding isotherms of sodium dodecyl sulfate to protein polypeptides with special reference to SDS-polyacylamide gel electrophoresis.

To clarify the mode of interaction between sodium dodecyl sulfate (SDS) and protein polypeptides with special reference to SDS-polyacrylamide gel electrophoresis, the binding of SDS to several protein polypeptides was investigated by the equilibrium dialysis technique. Each of the binding isotherms was characterized by the presence of two phases: an initial gradual increase in the amount of binding to 0.3-0.6 g/g (first phase) and a subsequent steep increase to 1.2-1.5 g/g (second phase). The binding was completed at a concentration of SDS below the critical micelle concentration. Throughout the first and second phases, the isotherms obtained were different for each kind of protein. On the basis of experiments with bovine serum albumin and ribonuclease (EC 3.1.4.22], the isotherms were profoundly affected by the method used for modification of the sulfhydryl groups. The claim of Reynolds and Tanford (Proc. Natl, Acad. Sci. U.S., 66, 1002 (1970)) that the isotherms are virtually identical for many kinds of proteins was not supported by the present data. Changes in the gross and local conformations were examined with reference to the isotherms by measurements of CD spectrum, free boundary electrophoresis, and gel filtration. The results obtained were collectively interpreted based on the model of SDS-protein polypeptide complexes proposed by the present authors (J. Biochem., 75, 309 (1974)).     

Interaction of bacterial F1-ATPase with octyl glucoside and deoxycholate

Purified F₁-ATPase from Micrococcus lysodeikticus (Micrococcus luteus) contains extensive and easily accessible areas capable of hydrophobic interaction. These hydrophobic areas were demonstrated by the binding of a non-ionic and a mild anionic detergent to this protein, evidenced by charge shift electrophoresis and measured by equilibrium gel chromatography with labelled detergents. F₁-ATPase bound 0.06 ± 0.01 g octyl glucoside per g protein and 0.12 ± 0.01 g deoxycholate per g protein, which amount to 81 and 119 amphiphile molecules per protein molecule, respectively. Deoxycholate and octyl glucoside inhibited the Ca²⁺- and Mg²⁺-dependent ATP hydrolytic activity of the enzyme. The inhibition by octyl glucoside was moderately cooperative. Binding of these detergents to the enzyme did not seem to induce any disruption of its quaternary structure, although the spontaneous dissociation of the δ subunit, which is not essential for the enzyme activity, increased during deoxycholate treatment. These results suggest that hydrophobic domains play a role in the enzymatic activity of this coupling factor and / or in its interaction with the membrane.     

Quantitative analysis of glomerular basement membrane glycosaminoglycans and evidence for their binding to adjacent cell membrane lipids

Glycosaminoglycans (GAG) were isolated from rat renal glomerular basement membranes subjected to extraction with detergents, and were quantitatively analyzed using a recently described competitive binding assay that is specific for and sensitive to microgram amounts of chondroitin and heparan sulfate. Whereas crude membranes prepared by osmotic lysis contained only 6 micrograms/mg dry wt, subsequent treatment with Triton X-100 or deoxycholate (DOC) increased measureable GAG to about 17 and 34 micrograms/mg, respectively. Repeated freezing and thawing of isolated glomeruli also augmented measurable GAG content in subsequently osmotically lysed membranes to levels observed in Triton-treated membranes. DOC solubilized approximately equal to 15-20% of membrane-associated GAG. Chondroitin sulfate comprised approximately equal to 30% of total GAG, and all of the chondroitin sulfate but only 10% of the heparan sulfate was extracted from the insoluble matrix by DOC. The findings indicate that GAG content of glomerular basement membrane is several-fold higher than previously estimated, and that a substantial portion is bound to cell membrane lipids. The results further suggest two populations of GAG in basement membrane; one that is intercalated with adjacent cell membranes, and another that remains as an integral component of the insoluble matrix after detergent extraction.     

Role of terminal nonhomologous domains in initiation of human red cell spectrin dimerization

Human erythrocyte spectrin is an antiparallel heterodimer comprised of a 280 kDa alpha subunit and a 246 kDa beta subunit which further associates into tetramers in the red cell membrane cytoskeleton. Lateral association of the flexible rodlike monomers involves a multiple-step process that is initiated by a high affinity association near the actin-binding end of the molecule (dimer nucleation site). In this study, recombinant alpha and beta proteins comprising two or four "spectrin type" motifs with and without adjacent, terminal nonhomologous domains were evaluated for their relative contributions to dimer initiation, and the thermodynamic properties of these heterodimer complexes were measured. Sedimentation equilibrium studies showed that in the absence of the heterologous subunit, individual recombinant proteins formed weak homodimers (K(d) > 0.3 mM). When 2-motif (alpha20-21 and beta1-2) and 4-motif (alpha18-21 and beta1-4) recombinants lacking the terminal nonhomologous domains were paired with the complementary protein, high affinity heterodimers were formed in sedimentation equilibrium analysis. Both the alpha20-21/beta1-2 complex and the alpha20-21EF/betaABD1-2 complex showed stoichiometric binding with similar binding affinities (K(d) approximately 10 nM) using isothermal titration calorimetry. The alpha20-21/beta1-2 complex showed an enthalpy of -10 kcal/mol, while the alpha20-21EF/betaABD1-2 complex showed an enthalpy of -13 kcal/mol. Pull-down assays using alpha spectrin GST fusion proteins showed strong associations between all heterodimer complexes in physiological buffer, but all heterodimer complexes were destabilized by the presence of Triton X-100 and other detergents. Complexes lacking the nonhomologous domains were destabilized to a greater extent than complexes that included the nonhomologous domains. The detergent effect appears to be responsible for the apparent essential role of the nonhomologous domains in prior reports. Taken together, our results indicate that the terminal nonhomologous domains do not contribute to dimer initiation nor are they required for formation of high affinity spectrin heterodimers in physiological buffers.     

Immobilized cytochrome P-450LM2. Dissociation and reassociation of oligomers.

Subunit interactions in the purified hexameric cytochrome P-450_LM2 have been studied using covalent binding of one of the 6 protomers to an insoluble matrix. High ionic strength, large-scale pH changes, guanidine chloride and sodium cholate taken at membrane-solubilizing concentrations, had no effect on the aggregation state of the immobilized hemoprotein. SDS caused a 6-fold decrease in the amount of the bound cytochrome. Non-ionic detergents (Emulgen 913, octylglucoside, Tritons) induced hexamer dissociation. In the presence of Emulgen 913 (> 0.2%), monomers and immobilized dimers were obtained as cytochrome P-450 was studied in an aqueous medium and in the immobilized state, respectively. Immobilized dimers could be reconstituted to hexamers by treatment with an excess of solubilized monomers after removal of the detergent. In the presence of various phospholipids, which increased the immobilized cytochrome P-450_LM2 demethylase activity and induced characteristic spectral changes, no hexamer dissociation was shown. The data obtained are thus in agreement with the suggestion that hexameric arrangement is inherent in the cytochrome P-450 when it is bound to the native membranes.     

Characterization of dodecylphosphocholine/myelin basic protein complexes

The stoichiometry of myelin basic protein (MBP)/dodecylphosphocholine (DPC) complexes and the location of protein segments in the micelle have been investigated by electron paramagnetic resonance (EPR), ultracentrifugation, photon correlation light scattering, 31P, 13C, and 1H nuclear magnetic resonance (NMR), and electron microscopy. Ultracentrifugation measurements indicate that MBP forms stoichiometrically well-defined complexes consisting of 1 protein molecule and approximately 140 detergent molecules. The spin-labels 5-, 12-, and 16-doxylstearate have been incorporated into DPC/MBP aggregates. EPR spectral parameters and 13C and 1H NMR relaxation times indicate that the addition of MBP does not affect the environment and location of the labels or the organization of the micelles except for a slight increase in size. Previous results indicating that the protein lies primarily near the surface of the micelle have been confirmed by comparing 13C NMR spectra of the detergent with and without protein with spectra of protein/detergent aggregates containing spin-labels. Electron micrographs of the complexes taken by using the freeze-fracture technique confirm the estimated size obtained by light-scattering measurements. Overall, these results indicate that mixtures of MBP and DPC can form highly porous particles with well-defined protein and lipid stoichiometry. The structural integrity of these particles appears to be based on protein-lipid interactions. In addition, electron micrographs of aqueous DPC/MBP suspensions show the formation of a small amount of material consisting of large arrays of detergent micelles, suggesting that MBP is capable of inducing large changes in the overall organization of the detergent.     

Protein interaction with immobilized ligands: quantitative analyses of equilibrium partition data and comparison with analytical chromatographic approaches using immobilized metal affinity adsorbents

Quantitative or analytical affinity chromatography has been successful primarily for the analysis of biologically determined macromolecular affinity relationships. Quantitative approaches are also needed to better characterize simpler, chemically defined immobilized ligands with potential for selective interaction with specific, predetermined protein surface groups. Protein interaction with immobilized metal is a rather selective and versatile, high-affinity adsorption technique for which there is little quantitative information. Using model protein interactions with immobilized Cu2+ ions, we have compared analytical frontal affinity chromatographic methods to a simple, nonchromatographic protocol for the rapid determination of quantitative affinity relationships. Values obtained for the equilibrium dissociation constant (Kd) and binding capacity (Lt) characterizing the interaction of lysozyme with immobilized Cu2+ were quite similar by frontal analysis (Kd = 37-42 X 10(-6) M; Lt = 6.8-7.4 X 10(-6) mol protein/ml gel) and by equilibrium binding analyses (Kd = 33 +/- 4.7 X 10(-6) M; Lt = 5.8-6.1 X 10(-6) mol protein/ml gel; 14 determinations). The interaction of ovalbumin with immobilized Cu2+ was characterized by an affinity (Kd = 4.2-4.8 X 10(-6) M) and capacity (Lt = 1.5-2.1 X 10(-6) mol protein/ml gel) which were also the same regardless of the method for affinity analysis. These values indicate that the total protein bound at saturation corresponds to as much as 17% of the total immobilized Cu2+ ions (approximately 40 X 10(-6) mol/ml gel). Thus, depending on the fraction of total immobilized Cu2+ available for interaction with a given protein (e.g., lysozyme), the number of individual immobilized ligands actively participating as well as those rendered unavailable upon individual protein binding events may be greater than 1. Linear Scatchard plots obtained for both lysozyme and ovalbumin (purified) suggest the presence of only a single type of immobilized Cu2+-protein interaction operative under the experimental conditions employed. However, Scatchard analyses of data obtained by the nonchromatographic equilibrium binding method also demonstrated the ability to simultaneously resolve the contribution of two components whose presence was predicted by frontal chromatography. Our results support the validity and utility of equilibrium binding data analyzed according to the equations outlined by Scatchard and others as an alternative to analytical chromatographic methods.     

Molecular structure of the beta-adrenergic receptor

The beta-adrenergic receptor from several tissues has been purified to homogeneity or photoaffinity radiolabeled and its subunit molecular weight determined by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. In this study we have examined the oligomeric structure of nondenatured beta 1- and beta 2-adrenergic receptor proteins, as solubilized with the detergent digitonin. Model systems used were frog and turkey red blood cell as well as rat, rabbit, and bovine lung plasma membrane preparations. To correct for the effects of detergent binding, sedimentation equilibrium analysis in various solvents, as adapted for the air-driven ultracentrifuge, was used. With this approach an estimate of 6 g of digitonin/g of protein binding was determined, corresponding to a ratio of 180 mol of digitonin/mol of protein. Protein molecular weights estimated by this method were 43 500 for the turkey red blood cell beta 1 receptor and 54 000 for the frog red blood cell beta 2 receptor. Molecular weights of 60 000-65 000 were estimated for beta 1 and beta 2 receptors present in mammalian lungs. These values agree with estimates of subunit molecular weight obtained by SDS gel electrophoresis of purified or photoradiolabeled preparations and suggest beta-adrenergic receptors to be digitonin solubilized from the membrane as single polypeptide chains.     

Mechanism of detergent interaction with hemoproteins in aqueous media

The interactions of myoglobin, cytochrome c, and cytochrome P-450 LM-2 isolated from rabbit liver microsomes with detergents of type A (TM 3-12, Tween 20, Triton N-101) and detergent of B type (sodium cholate) in aqueous media were studied. These interactions are accompanied by a decrease in the Soret band intensity for all three hemoproteins. The rate of this process depends on the nature and concentration of the detergent as well as on temperature. The rate of the Soret band decrease is maximal for the zwitter-ionic surfactant TM 3-12. The rate constants of hemoprotein transformation depend on the detergent concentration. The detergent effects on the conformation and structure of the protein were demonstrated, using CD spectra and second derivatives of the absorption spectra of the hemoproteins in the presence of the detergents. The activation energies for myoglobin transformation in the presence of various detergents are equal to 17-23 kcal/mol and possibly reflect the cleavage of the coordinative heme-apoprotein bonds. A model of detergent interaction with hemoproteins is discussed. According to this model, the bimolecular interaction of the proteins with surfactants is observed at the detergent concentrations that are much lower than those for critical micelle formation values.     

Thermodynamics of sodium dodecyl sulfate partitioning into lipid membranes

The partition equilibria of sodium dodecyl sulfate (SDS) and lithium dodecyl sulfate between water and bilayer membranes were investigated with isothermal titration calorimetry and spectroscopic methods (light scattering, (31)P-nuclear magnetic resonance) in the temperature range of 28 degrees C to 56 degrees C. The partitioning of the dodecyl sulfate anion (DS(-)) into the bilayer membrane is energetically favored by an exothermic partition enthalpy of Delta H(O)(D) = -6.0 kcal/mol at 28 degrees C. This is in contrast to nonionic detergents where Delta H(O)(D) is usually positive. The partition enthalpy decreases linearly with increasing temperature and the molar heat capacity is Delta C(O)(P) = -50 +/- 3 cal mol(-1) K(-1). The partition isotherm is nonlinear if the bound detergent is plotted versus the free detergent concentration in bulk solution. This is caused by the electrostatic repulsion between the DS(-) ions inserted into the membrane and those free in solution near the membrane surface. The surface concentration of DS(-) immediately above the plane of binding was hence calculated with the Gouy-Chapman theory, and a strictly linear relationship was obtained between the surface concentration and the extent of DS(-) partitioning. The surface partition constant K describes the chemical equilibrium in the absence of electrostatic effects. For the SDS-membrane equilibrium K was found to be 1.2 x 10(4) M(-1) to 6 x 10(4) M(-1) for the various systems and conditions investigated, very similar to data available for nonionic detergents of the same chain length. The membrane-micelle phase diagram was also studied. Complete membrane solubilization requires a ratio of 2.2 mol SDS bound per mole of total lipid at 56 degrees C. The corresponding equilibrium concentration of SDS free in solution is C (sat)(D,F) approximately 1.7 mM and is slightly below the critical micelles concentration (CMC) = 2.1 mM (at 56 degrees C and 0.11 M buffer). Membrane saturation occurs at approximately 0.3 mol SDS per mol lipid and the equilibrium SDS concentration is C (sat)(D,F)approximately equal 2.2 mM +/- 0.6 mM. SDS translocation across the bilayer is slow at ambient temperature but increases at high temperatures.     

Activities of lectins and their immobilized derivatives in detergent solutions. Implications on the use of lectin affinity chromatography for the purification of membrane glycoproteins.

The effects of several commonly used detergents on the saccharide-binding activities of lectins were investigated using lectin-mediated agglutination of formalin-fixed erythrocytes and affinity chromatography of glycoproteins on columns of lectins immobilized on polyacrylic hydrazide-Sepharose. In the hemagglutination assays, Ricinus communis I (RCA1) and II (RCAII), concanavalin A (Con A), and the agglutinins from peanut (PNA), soybean (SBA), wheat germ (WGA), and Limulus polyphemus (LPA) were tested with several concentrations of switterionic, cationic, anionic, and nonionic detergents. It was found that increasing detergent concentrations eventually affected hemagglutination titers in both test and control samples, and the highest detergent concentrations not affecting lectin hemagglutinating activities were determined. The effects of detergents on specific binding of [3H]fetuin and asialo[3H]fetuin to and elution from columns of immobilized lectins were less severe when compared with lectins in solution, suggesting that the lectins are stabilized by covalent attachment to agarose beads. Nonionic detergents did not affect the binding efficiency of the immobilized lectins tested at concentrations used for membrane solubilization while cationic and zwitterionic detergents caused significant inhibition of Con A- and SBA-Sepharose activities. In sodium deoxycholate (greater than 1%) only RCAI-Sepharose retained its activity, whereas the activities of the other lectins were reduced dramatically. Low concentrations of sodium dodecyl sulfate (0.05%) inhibited only the activity of immobilized SBA, but at higher concentration (0.1%) and prolonged periods of incubation (16 h, 23 degrees C) most of the lectins were inactivated. These data are compared with previous reports on the use of detergents in lectin affinity chromatography, and the conditions for the optimal use of detergents are detailed.