Electron spin resonance study of the role of nitrosyl-heme in the activation of guanylate cyclase by nitrosoguanidine and related agonists.

One major component of lens plasma membrane is a glycoprotein that SDS-polyacrylamide gel electrophoresis shows to possess an apparent molecular weight of 26,000. When this protein is solubilized in low ionic strength buffers containing SDS, and heated to 100° for 1 to 3 min prior to electrophoresis, conversion into high molecular weight aggregate results. The heat lability of this protein is greatly enhanced if it solubilized and heated in buffers containing 0.1 M NaCl. At this ionic strength, incubation for 3 h at 38° results in conversion of 20% of the protein into high melecular weight aggregates. Most other membrane proteins isolated from lens membrane are insensitive to heat treatment. It is concluded that temperature and ionic strength must be recorded and controlled carefully when using SDS-polyacrylamide gel electrophoresis to study this membrane protein.     

Solubilization of bacterial membrane proteins using alkyl glucosides and dioctanoyl phosphatidylcholine.

The non-ionic detergent octyl glucoside solubilizes a substantial amount of Streptococcus faecalis membrane protein without loss of the monitored enzyme activities. A secondary detergent, dioctanoyl phophatidycholine, appears to increase the yield of solubilized material. In addition, the effect of ionic strength indicates that it may be possible to selectively extract groups of membrane proteins by their characteristic solubility at different ionic strengths. The solubilized membrane-associated enzymes, ATPase and NADH dehydrogenase, enter polyacrylamide gels as distict species. Electrophoretic studies suggest that there are two membrane-associated ATPase in the Streptococcus faecalis, one which dissociates from the membrane in the absence of Mg-2+ ions and the other which remains particulate until solubilized by detergents. Octyl glucoside can be easily removed from a solution containing solubilized proteins and lipid by dialysis.     

Solubilization of bacterial membrane proteins using alkyl glucosides and dioctanoyl phosphatidylcholine

The non-ionic detergent octyl glucoside solubilizes a substantial amount of Streptococcus faecalis membrane protein without loss of the monitored enzyme activities. A secondary detergent, dioctanoyl phosphatidylcholine, appears to increase the yield of solubilized material. In addition, the effect of ionic strength indicates that it may be possible to selectively extract groups of membrane proteins by their characteristic solubility at different ionic strengths.The solubilized membrane-associated enzymes, ATPase and NADH dehydrogenase enter polyacrylamide gels as distinct species. Electrophoretic studies suggest that there are two membrane-associated ATPases in the Streptococcus faecalis, one which dissociates from the membrane in the absence of Mg²⁺ ions and the other which remains particulate until solubilized by detergents.Octyl glucoside can be easily removed from a solution containing solubilized proteins and lipid by dialysis.     

Study of human erythrocyte membrane protein interactions by selective solubilization of Triton-skeletons

Summary— The membrane skeleton, responsible for shape and mechanical properties of the red cell, was purified by the Triton extraction procedure in presence of 5 mM, 150 mM or 600 mM NaCl. The proportion of spectrin, protein 4.1 and actin present in erythrocyte skeletons does not depend on the molarity of NaCl used. In contrast ankyrin, protein band 3 and protein 4.2 are removed from skeletons as the ionic strength increased. Solubilization assays of membrane skeletons were used to study protein interactions inside the skeleton. Solubilization was performed by Tris, a non-selective disruptive reagent, or by p-mercuribenzene sulfonic acid (PMBS), which principally release spectrin and actin. Tris action was assessed by calculation of the percentage of solubilized proteins, which increased proportionally with Tris molarity. PMBS action was kinetically determined as the decrease in skeleton turbidity. With these two reagents, we observed a lower dissociation of skeletons prepared with high ionic strength buffer. Erythrocyte pretreatment with okadaic acid, an inhibitor of serine-threonine phosphatases, revealed a phosphorylation-induced skeleton gelation and a better resistance to Tris-solubilization.     

Interaction of talin with actin: sensitive modulation of filament crosslinking activity.

Talin is an adhesion plaque protein believed important in linking actin filaments to the plasma membrane. The nature of a direct talin-actin interaction, however, is complex and has remained unclear. We have systematically characterized the effects of pH, ionic strength, temperature, and protein molar ratio on the interaction between highly purified talin and actin. The ability of talin to increase viscosity of F-actin at 25 degrees C and low ionic strength increased with decreasing pH from 7.3 to 6.4 and increasing molar ratio of talin to actin. At pH 6.4 and low ionic strength, talin could extensively crosslink actin filaments into ordered bundles as shown by negative staining and could cosediment with F-actin at molar ratios as high as one talin to two actin monomers. Talin crosslinked prepolymerized actin filaments to a similar extent as actin filaments polymerized in its presence. The 190-kDa calpain-generated proteolytic fragment of talin bound poorly to actin under conditions favorable for intact talin, but was able to crosslink actin filaments at a lower pH. Increasing the ionic strength within a relatively narrow range significantly decreased ability of talin to bind to actin, regardless of pH. The effects of pH and ionic strength on the talin-actin interaction were rapid and reversible. Low-shear-viscosity studies revealed a strong temperature dependence in the talin-actin interaction with significant crosslinking activity at physiological-like ionic conditions and temperature (37 degrees C). Our results consistently demonstrated that talin crosslinks actin filaments and that this direct interaction is highly sensitive to, and dependent upon, ionic conditions and temperature.     

Characterization of an integral membrane glycoprotein associated with the microfilaments of pig intestinal microvilli

An integral membrane glycoprotein of pig intestinal microvilli which exists in two polypeptide forms [mol. wt. 140 K and 200 K as measured by SDS-polyacrylamide gel electrophoresis (SDS-PAGE)] was purified to homogeneity and characterized. The 200-K form is probably a precursor of the 140-K species. We have localized the glycoprotein by electron microscope immunochemistry using specific antibodies and determined its topological organization with respect to the membrane bilayer. Triton X-100 treatments which solubilize most other microvillar membrane glycoproteins from purified, closed, right-side out vesicles do not efficiently extract this protein. The protein can be partially solubilized from the detergent-insoluble residue, either by treatment with proteases (trypsin or papain) or by exposure to low ionic strength buffer in the presence of chelating agents and detergents. Once solubilized by papain or trypsin, the protein co-migrates on SDS-PAGE with the protein obtained by low ionic strength extraction. However, the form of the protein released by papain does not bind detergents and exhibits hydrophilic properties. Our observations are consistent with the 140-K protein having a small hydrophobic domain that anchors it to the microvillar membrane. The 140-K glycoprotein binds in vitro to a 110-K protein of the core cytoskeleton residue. These observations suggest that the 140-K glycoprotein may be a transmembrane protein which may in vivo provide attachment sites for direct or indirect association with polypeptides of the microvillus cytoskeleton.     

Amphilphilic nature of spiralin, the major protein of the Spiroplasma citri cell membrane.

Spiralin could not be solubilized in the absence of detergents, and it was shown by charge-shift crossed immunoelectrophoresis that this protein was capable of binding detergents under nondenaturing conditions. These properties indicate the amphiphilic nature of spiralin, which therefore should be regarded as an intrinsic membrane protein. The efficiency of mild (ionic and neutral) detergents to solubilize spiralin was as follows: deoxycholate greater than lauroyl sarcosinate, cholate, taurocholate, taurodeoxycholate greater than Triton X-100 greater than Brij 58 greater than Tween 20, indicating that mild ionic detergents were more effective than neutral ones. Solubilization of spiralin was quantitative with sodium deoxycholate. It was also shown that although a membrane protein is not extractable by a given detergent from the membrane, this does not necessarily mean that the protein is not soluble in this detergent.     

Cytoplasmic localization of the transforming protein of Fujinami sarcoma virus: salt-sensitive association with subcellular components

Fujinami sarcoma virus (FSV) encodes a transforming protein of 130,000 daltons (P130) which is associated with a tyrosine-specific protein kinase activity. To elucidate mechanisms involved in cell transformation by FSV, we have studied the intracellular location of P130 in rat cells nonproductively infected with FSV. Immunofluorescent staining of several FSV-transformed rat cell lines with a tumor regressor antiserum specific against the fps sequences of P130 showed that the major staining was localized in the cytoplasm. Staining was also seen in cell ruffles and in some cases at areas of cell contact. The cytoplasmic location of P130 staining in cells infected with temperature-sensitive mutants of FSV was unchanged when they were grown at permissive or nonpermissive temperature. Cell fractionation of FSV-transformed cells under various conditions showed that the ionic strength used during cell fractionation had a striking effect on the distribution of P130. At 10 mM NaCl, 70% of P130 sedimented in the large granule fraction, whereas at 500 mM NaCl 70 to 90% of P130 was recovered in the cytosol fraction. Furthermore, a combination of ionic and nonionic detergents that effectively solubilized subcellular membranes was insufficient to solubilize P130 unless the salt concentration was raised. We conclude that the majority of P130 and its associated protein kinase activity are localized in the cytoplasm and that P130 is not an integral membrane protein.     

Surface plasmon resonance studies of complex formation between cytochrome c and bovine cytochrome c oxidase incorporated into a supported planar lipid bilayer. II. Binding of cytochrome c to oxidase-containing cardiolipin/phosphatidylcholine membranes.

Complex formation between horse heart cytochrome c (cyt c) and bovine cytochrome c oxidase (cco) incorporated into a supported planar egg phosphatidylcholine membrane containing varying amounts of cardiolipin (CL) (0-20 mol%) has been studied under low (10 mM) and medium (160 mM) ionic strength conditions by surface plasmon resonance (SPR) spectroscopy. Both specific and nonspecific modes of cyt c binding are observed. The dissociation constant of the specific interaction between cyt c and cco increases from approximately 6.5 microM at low ionic strength to 18 microM at medium ionic strength, whereas the final saturation level of bound protein is independent of salt concentration and corresponds to approximately 53% of the total cco molecules present in the membrane. This suggests a 1:1 binding stoichiometry between the two proteins. The nonspecific binding component is governed by electrostatic interactions between cyt c and the membrane lipids and results in a partially ionic strength-reversible protein-membrane association. Thus, hydrophobic interactions between cyt c and the membrane, which are the predominant mode of binding in the absence of cco, are greatly suppressed. Both the amount of nonspecifically bound protein and the binding affinity can be varied over a broad range by changing the ionic strength and the extent of CL incorporation into the membrane. Under conditions approximating the physiological state in the mitochondrion (i.e., 20 mol% CL and medium ionic strength), 1-1.5 cyt c molecules are bound to the lipid phase per molecule of cco, with a dissociation constant of 0.1 microM. The possible physiological significance of these observations is discussed.     

Localization in the Cell and Extraction of Alkaline Phosphatase from Bacillus subtilis

Study of protoplasts, lysed protoplasts, and cells treated with lysozyme in the absence of osmotic stabilizer suggested that the alkaline phosphatase (EC 3.1.3.1.) of Bacillus subtilis is located in the protoplasmic membrane. Cytochemical evidence in support of this view is presented. The enzyme protein was strongly bound to the membrane structure and could not be solubilized by a number of treatments known to release enzymes from membranes and other lipoprotein structures. Alkaline phosphatase was, however, solubilized by treatment of intact B. subtilis cells or isolated protoplasmic membranes with strong salt solutions at pH 7.2, suggesting that electrostatic forces are responsible for the association between membrane and enzyme protein. Dialysis of alkaline phosphatase solutions against buffer of low ionic strength resulted in precipitation of the enzyme.     

Effect of ion binding on protein transport through ultrafiltration membranes

Electrostatic interactions can have a significant impact on protein transmission through semipermeable membranes. Experimental data for the transport of bovine serum albumin (BSA) through a polyethersulfone ultrafiltration membrane were obtained in different salt solutions over a range of pH and salt concentrations. Net BSA charge under the same conditions was evaluated from mobility data measured by capillary electrophoresis. The results show that specific ionic composition, in addition to solution pH and ionic strength, can strongly affect the rate of protein transport through semipermeable ultrafiltration membranes. The effects of different ions on BSA sieving are due primarily to differences in ion binding to the protein, which leads to significant differences in the net protein charge at a given pH and ionic strength. This effect could be described in terms of an effective protein radius, which accounts for the electrostatic exclusion of the charged protein from the membrane pores. These results provide important insights into the nature of the electrostatic interactions in membrane systems.     

Triton solubilization of proteins from pig liver mitochondrial membranes

Various aspects of membrane solubilization by the Triton X-series of nonionic detergents were examined in pig liver mitochondrial membranes. Binding of Triton X-100 to nonsolubilized membranes was saturable with increased concentrations of the detergent. Maximum binding occurred at concentrations exceeding 0.5% Triton X-100 (w/v). Solubilization of both protein and phospholipid increased with increasing Triton X-100 to a plateau which was dependent on the initial membrane protein concentration used. At low detergent concentrations (less than 0.087% Triton X-100, w/v), proteins were preferentially solubilized over phospholipids. At higher Triton X-100 concentrations the opposite was true. Using the well-defined Triton X-series of detergents, the optimal hydrophile-lipophile balance number (HLB) for solubilization of phosphatidylglycerophosphate synthase (EC 2.7.8.5) was 13.5, corresponding to Triton X-100. Activity was solubilized optimally at detergent concentrations between 0.1 and 0.2% (w/v). The optimal protein-to-detergent ratio for solubilization was 3 mg protein/mg Triton X-100. Solubilization of phosphatidylglycerophosphate synthase was generally better at low ionic strength, though total protein solubilization increased at high ionic strength. Solubilization was also dependent on pH. Significantly higher protein solubilization was observed at high pH (i.e., 8.5), as was phosphatidylglycerophosphate synthase solubilization. The manipulation of these variables in improving the recovery and specificity of membrane protein solubilization by detergents was examined.     

Isolation and characterization of band 3, the predominant polypeptide of the human erythrocyte membrane.

Band 3 is the predominant approximately 90,000-dalton polypeptide component of the human erythrocyte membrane. It was solubilized selectively, along with the other major glycoproteins, by extracting membrane ghosts with Triton X-100 under nondenaturing conditions. Two major polypeptides remained associated with Band 3 under these conditions; however one (Band 6) could be dissociated at an ionic strength of 0.15 and the other (Band 4.2) by treatment with p-chloromercuribenzoate. Band 3 was then purified (greater than or equal to 97%) by aminoethyl cellulose ion exchange chromatography. The isolated protein was free of phospholipid and was moderately enriched in apolar amino acid residues; it contained galactose and glucosamine but very little sialic acid and galactosamine. When Band 3 was labeled by treatment of ghosts with galactose oxidase plus KB3H4 and then purified, the electrophoretic mobility of its radioactivity lagged slightly behing that of its Coomassie blue staining profile. Variation in glycosylation could therefore cause the diffuse trailing zone characteristically observed for Band 3 on polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The ultraviolet circular dichroism of Band 3 was stable in nonionic detergent and suggested an alpha helix content of 43%, a value close to that estimated for this polypeptide in the membrane.     

Role of anionic lipid in bacterial membranes

The major phospholipids of Bacillus stearothermophilus are phosphatidylethanolamine (PE), phosphatidylglycerol (PG), and cardiolipin (CL). Under the growth conditions used in this study the concentration of anionic lipid (PG + CL) was determined by the pH of the culture medium. Cells grown in a complex medium at pH 5.8, 7.0, and 8.0 contained 17, 29 and 36 nmol of anionic (PG + CL) lipid/mg cell (dry weight). The concentration of the zwitterionic lipid phosphatidylethanolamine (PE) was 17-20 nmol/mg cell (dry weight) under all conditions. Analysis of isolated membrane preparations suggested that the amount of anionic lipid per unit area of membrane increased as the pH of the growth medium was increased. Membranes from cells grown at pH 5.8 and 8.0 contained 130 and 320 nmol anionic lipid/mg membrane protein, respectively. Phosphatidylethanolamine appeared to be localized on the inner membrane surface in cells grown under all conditions. Increasing the ionic strength of the culture medium by the addition of NaCl or KCl had little effect on growth at pH 5.8 but inhibited growth at pH 7 and 8. It was concluded that anionic phospholipid plays an important physiological role in maintaining an acidic pH at the outer membrane surface.     

Properties of talin from chicken gizzard smooth muscle

This paper describes the structural and biochemical characterization of talin, a protein localized to various cellular sites where bundles of actin filaments attach to the plasma membrane. By sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the protein has a molecular mass of 225,000 +/- 5,000 daltons. Hydrodynamic measurements at protein concentrations less than 0.72 mg/ml indicate a monomeric protein with a native molecular mass of 213,000 +/- 15,000 daltons. Sedimentation equilibrium experiments indicate self-association at protein concentrations of 0.72 mg/ml and higher. The data suggest that this self-association is a simple monomer:dimer equilibrium over the range of concentrations observed. At low protein concentrations where talin is a monomer, the Stokes radius and sedimentation coefficient vary with ionic strength. Under low ionic strength conditions (5-20 mM NaCl), talin has a Stokes radius of 6.5 nm and a sedimentation value of 9.4, suggesting an asymmetric globular molecule; whereas under high ionic strength conditions (200 mM NaCl), the Stokes radius increases to 7.7 nm and the sedimentation coefficient decreases to 8.8, suggesting a more elongated protein. This conformation change is confirmed by electron microscopy which reveals a more globular protein at low ionic strength which unfolds to become an elongated flexible molecule as the ionic strength is increased to physiological and higher levels. The amino acid composition of talin indicates a low level of aromatic residues, consistent with its relatively low extinction coefficient, talin has an isoelectric point between pH 6.7 and 6.8 based on isoelectric focusing. The detailed purification of talin is described.     

Ionic-strength-dependent changes in the structure of the major protein of the human erythrocyte membrane.

The effect of ionic strength on the proteolysis by trypsin of the major membrane-penetrating protein (polypeptide 3) in the erythrocyte membrane was studied. Both the intracellular and extracellular regions of the protein are susceptible to trypsin proteolysis under hypo-osmotic conditions, whereas under iso-osmotic conditions the extracellular region of the protein is resistant to trypsin, and the intracellular region yields only two cleavage products with trypsin. Studies of the fragments obtained from polypeptide 3 by trypsin digestion under iso-osmotic conditions of 'ghosts' radioiodinated with lactoperoxidase confirmed our earlier conclusions that the polypeptide chain of polypeptide 3 traverses the membrane twice. Ionic-strength-dependent changes were also observed in the incorporation of iodine by lactoperoxidase into the individual extracellular tyrosine sites of the protein. These results show that polypeptide 3 undergoes ionic-strength-dependent changes in structure.     

Examination of actin polymerization and viscosity induced by cations and ionic strength when cross-linked by alpha-actinin

Increasing potassium chloride concentration from 0 to 100 mM and magnesium chloride from 0 to 2 mM show a parallel rate increase in polymerizing actin, whereas increasing calcium chloride concentration from 0 to 0.2 mM decreases the rate of polymerizing actin. The presence of alpha-actinin has little influence on the polymerization kinetics of actin under these conditions. Viscometric measurements indicate that the presence of various mono- and divalent cations, ionic strength, and alpha-actinin in combination are responsible for changes in the mechanical properties of solutions containing actin. The actin filament dynamic behavior is drastically reduced under these conditions as confirmed by quasi-elastic light scattering.     

Adenosine-3':5'-monophosphate-dependent and plasma-membrane-associated protein kinase from bovine corpus luteum. Solubilization and properties of solubilized enzyme.

The solubilization of plasma membrane fractions FI and FII associated protein kinases has been attempted using monovalent salts of high ionic strength and various detergent treatments. Extraction of FI and FII plasma membranes with high ionic strength salt solutions did not release more than 20% of the protein kinase activity. Similarly, monovalent salts released little adenosine 3':5'-monophosphate (cyclic AMP) binding activity, but after extraction binding capacity of cyclic [3H]AMP to plasma membranes was increased about 150-200%. Triton X-100 was a better solubilizing agent that Lubrol WX or deoxycholate. In addition to solubilization, 0.1% Triton X-100 also stimulated the protein kinase activity 150-200%. The properties of Triton X-100 solubilized FI and FII and purified cytosol KII were characterized with respect to protein substrate specificity, effect of cyclic AMP, cyclic nucleotide specificity, effects of divalent metal ion and gonadotropins. Upon sucrose density gradient centrifugation, FI solubilized protein kinase and cyclic AMP binding activities co-sedimented with a sedimentation coefficient of 6.3 S. The FII solubilized protein kinase sedimented as two components with sedimentation coefficients of 7.7 S and 5.5 S. The cyclic AMP binding activity also sedimented as two components with sedimentation coefficient 6.7 S and 5.5 S. Cyclic AMP caused dissociation of solubilized protein kinase from FI into a single catalytic (4.8 S) and two cyclic AMP binding subunits (8.1 S and 6.7 S). FII solubilized enzyme was dissociated into one catalytic (4.8 S) and one cyclic AMP binding subunit (6.3 S). Fractionation of FI and FII solubilized enzymes on DEAE-cellulose column chromatography resolved them each into two peaks Ia, Ib and IIa, IIb, respectively. Peaks Ib and IIb were more sensitive to cyclic AMP STIMULATION THAN Ia and IIa peaks. From these studies it is concluded that the plasma-membrane associated and cytosol protein kinases have similar catalytic properties but differ in some of their physical properties.     

Increased degradation rates of protein in aging human fibroblasts and in cells treated with an amino acid analog.

Isolated polytene nuclei from Drosophila hydei salivary glands were subjected to various in vitro conditions, and structural and functional alterations were observed. The conditions required to best maintain the structure were different from those needed for maximal RNA synthesis. However, both the structure and function were adequately maintained at a moderate ionic strength. Functionally the RNA synthetic activity of giant chromosomes under these conditions shows a close resemblance to the in vivo situation according to several criteria. Morphologically chromosomes from isolated nuclei show an intact and distinctive banding pattern in squash preparations, but they are much more condensed than chromosomes derived directly from cells. Decreasing the ionic strength reduces the degree of condensation but also diminishes the RNA synthetic activity of the isolated nuclei. Increasing the ionic strength results in maximal endogenous RNA polymerase activity, but considerably alters the chromosomal morphology. The chromosomes from isolated nuclei did not exhibit any template activity with exogenously added RNA polymerase B from Drosophila hydei. The possible implications of these findings are discussed.