Effects of temperature, lipid modification and pH on the mobility of the major proteins of the receptor-rich membranes from Torpedo marmarata

The factors influencing the overall mobility of the major proteins of the acetylcholine receptor-rich membranes from Torpedo marmorata have been investigated by saturation transfer ESR spectroscopy and the lateral distribution of these proteins has been studied by electron microscopy. A spin-labelled derivative of maleimide, 3-maleimido-2,2,5,5-tetramethyl-1-pyrrolidinyloxyl (MSL), was used under various conditions of incubation, enabling us to attach it mainly to either an extrinsic protein of 43 kdaltons, or an intrinsic protein (40 kdaltons) bearing the alpha-toxin-binding site. (1) The direct reaction of MSL with the membrane fragments resulted in almost exclusive labelling of the 43 kdalton protein, an extrinsic protein located on the inner face of the receptor-rich membranes. (2) After the free SH groups were blocked with N-ethylmaleimide and the disulfide bridges opened with the reducing agent dithiothreitol, MSL reacted with both the 40 and 43 kdalton proteins (6.0 +/- 0.6 MSL molecules per alpha-toxin-binding site). (3) After the latter labelling procedure membranes were exposed to pH 11, resulting in extraction of the 43 kdalton protein and leaving 2.2 +/- 0.4 MSL molecules per alpha-toxin-binding site; sodium dodecyl sulfate polyacrylamide gel electrophoresis performed with N-[14C] ethylmaleimide suggested that MSL was bound mainly to the 40 kdalton polypeptide chain of the acetylcholine receptor. The following conclusions were made with the native and alkaline-treated membranes: In the native membranes, saturation transfer ESR does not reveal any significant protein rotational diffusion (rotational correlation time tau C greater than 1 ms). Temperature variations and/or lipid modifications obtained by fusion of exogenous lipids and/or cholesterol exchange have little influence on the saturation transfer ESR spectra. Electron microscopy reveals that upon lipid addition, proteins remain in the form of clusters while areas depleted of proteins appear. On the other hand, alkaline treatment strikingly enhances the motion of the MSL-labelled proteins in the membrane (100 less than or equal to tau c less than or equal to 120 microseconds). Furthermore, the rotational diffusion of the MSL-labelled proteins (mainly the 40 kdalton protein) becomes sensitive to temperature, lipid composition and the lipid-to-proteins ratio. Electron microscopy shows that alkaline extraction does not cause large reorganization of the acetylcholine receptor in the plane of the membrane. However, when phospholipids are added to pH 11 treated membranes, a dispersion of the receptor and rosettes is observed. In contrast, cholesterol enrichment of the latter membranes induces clustering of the receptor immobilization as judged by saturation transfer ESR. Upon reassociation of the pH 11 soluble proteins with the alkaline-treated membranes, the restriction of the acetylcholine receptor rotational mobility is also restored (tau c greater than or equal to 1 ms).     

Purification of Torpedo californica post-synaptic membranes and fractionation of their constituent proteins.

A rapid methof for preparation of membrane fractions highly enriched in nicotinic acetylcholine receptor from Torpedo californica electroplax is described. The major step in this purification involves sucrose-density-gradient centrifugation in a reorienting rotor. Further purification of these membranes can be achieved by selective extraction of proteins by use of alkaline pH or by treatment with solutions of lithium di-idosalicylate. The alkali-treated membranes retain functional characteristics of the untreated membranes and in addition contain essentially only the four polypeptides (mol.wts. 40000, 50000, 60000 and 65000) characteristic of the receptor purified by affinity chromatography. Dissolution of the purified membranes or of the alkali-treated purified membranes in sodium cholate solution followed by sucrose-density-gradient centrifugation in the same detergent solution yields solubilized receptor preparations comparable with the most highly purified protein obtained by affinity-chromatographic procedures.     

Extraction of peripheral proteins from nicotinic acetylcholine receptor-enriched membranes

The solubilisation of membrane proteins from nicotinic acetylcholine receptor-enriched membranes from the electric organ of Torpedo marmorata was studied. Chaotropic ions were shown to be ineffective in extracting peripheral proteins from these membranes. Two different anhydrides, 2,3-dimethylmaleic and 3,4,5,6-tetrahydrophthalic anhydride, released certain peripheral membrane proteins but not the integral receptor protein. Treatment of membranes containing $\text{> 3}\text{nmol}$ α-bungarotoxin binding sites per mg protein with anhydride resulted in a 43 kDa polypeptide as the major constituent of the solubilised material. The nature of the 43 kDa polypeptide is discussed. Gentle anhydride treatment did not change the α-bungarotoxin and carbamoylcholine binding properties of the receptor.     

Extraction of peripheral proteins is accompanied by selective depletion of certain glycerophospholipid classes and changes in the phosphorylation pattern of acetylcholine-receptor-rich-membrane proteins.

The widely used alkaline treatment of acetylcholine-receptor (AChR)-rich membranes from Torpedo marmorata (electric fish) and Discopyge tschudii (a marine ray) results not only in the extraction of non-receptor peripheral proteins but also in that of glycerophospholipids (approximately 13%). Minor acidic phospholipids, notably phosphatidic acid and polyphosphoinositides, are particularly enriched in the NaOH extracts. When electrocytes or receptor-rich membranes are incubated with [32P]Pi or [gamma-32P]ATP, polyphosphoinositides accumulate most of the label (approximately 45% in D. tschudii; 96% in T. marmorata) and exhibit the highest specific radioactivity. Furthermore, more than 50% of these phosphorylated lipids are extracted by NaOH together with the peripheral membrane proteins. NaOH treatment also results in modification of the phosphorylation pattern of AChR membrane proteins. Phosphorylation decreases in the Mr-43,000 group of peripheral proteins and in the gamma-subunit of the receptor. The results indicate that polyphosphoinositides constitute a metabolically very active lipid pool in the postsynaptic membrane, and that a substantial proportion of these phospholipids are preferentially released from the membrane together with other acidic phospholipids upon peripheral-protein extraction. The conclusion is drawn that membranes submitted to the above treatments can no longer be considered equivalent to native ones in terms of their phospholipid composition and phosphorylation characteristics.     

Enrichment of Na+-Ca2+ exchange in cardiac sarcolemmal vesicles by alkaline extraction

Exposure of canine cardiac sarcolemmal vesicles to alkaline media (greater than or equal to pH 12) results in the extraction of 33% of the protein. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows that specific proteins are being solubilized. Most of the phospholipid and sialic acid remains with the pellet after centrifugation. Electron microscopy reveals that alkaline treatment does not cause gross morphological damage to the vesicles, although freeze-fracture demonstrates some aggregation of intramembrane particles. The data indicate that high pH probably removes peripheral proteins and leaves the integral proteins in place. We find complete recovery of Na+-Ca2+ exchange activity in alkaline-extracted membranes after solubilization and reconstitution. These vesicles contain only 50% of the protein of vesicles reconstituted from control sarcolemma. Thus, the specific activity of Na+-Ca2+ exchange is doubled. Alkaline extraction is a useful and reproducible procedure for enrichment of the Na+-Ca2+ exchange protein. (Na+ + K+)-ATPase is completely inactivated by exposure to pH 12 medium though immunodetection shows that the (Na+ + K+)-ATPase proteins are not extracted. We detect both alpha and alpha + forms of (Na+ + K+)-ATPase and deduce that the Na+ pump proteins do not comprise a major fraction of sarcolemmal protein.     

Identification of exposed and buried determinants of the membrane-bound acetylcholine receptor from Torpedo californica

The ability of five rabbit anti-acetylcholine receptor antisera to recognize the membrane-bound receptor from Torpedo californica has been investigated. Two antisera, raised against affinity-purified native receptor, react extensively with purified receptor-rich membrane vesicles. Since the membrane vesicles are impermeable to macromolecules and are oriented right side out, these two antisera recognize predominantly extracellular determinants. Two antisera against sodium dodecyl sulfate denatured receptor and one against purified delta subunit react poorly with the membrane-bound receptor. Only 10-20% of the determinants recognized by these antisera are accessible to antibodies when the receptor is membrane bound. Many of the latent sites can be exposed by permeabilizing the vesicles with saponin, by alkaline extraction of the membranes to remove peripheral proteins, or by a combination of these two treatments. These treatments neither solubilize the receptors nor interfere with their ability to undergo agonist-induced affinity changes. Subunit analysis of the sites on the membrane-bound receptor that are accessible to antibodies indicates that the alpha, beta, and delta chains possess extracellular determinants. Buried sites are present on all four of the subunits. Saponin permeabilization makes latent sites accessible on alpha and delta while alkaline extraction uncovers determinants on alpha, gamma, and delta. Treatment of membranes by both procedures reveals sites on beta, gamma, and delta that are not uncovered by either treatment alone. This study, in conjunction with results from other laboratories demonstrating that the gamma chain is extracellularly exposed, suggests that all four subunits are transmembrane proteins.     

The sidedness of the COOH terminus of the acetylcholine receptor delta subunit

The nicotinic acetylcholine receptor from Torpedo sp. occurs as a dimer, disulfide-cross-linked between delta subunits. We determined the sidedness of the COOH terminus of the acetylcholine receptor delta subunit by locating the delta-delta disulfide relative to the membrane and by identifying the Cys residue forming the disulfide. We used receptor-rich native membrane vesicles isolated from Torpedo californica electric tissue and characterized as to orientation and intactness. These vesicles had not been extracted and retained v ("43-kDa protein") as a marker of the cytoplasmic surface. Using the reduction of v as an assay of permeability, we showed that two reductants, 2-mercaptoethanesulfonate and reduced glutathione, were relatively impermeant. Both of these reductants reduced the delta-delta disulfide in sealed right-side-out vesicles equally in the presence and absence of saponin, and 2-mercaptoethanesulfonate reduced this disulfide equally in the presence and absence of Triton X-100. By contrast, surfactants enhanced the reduction of dimer in inside-out and sequestered vesicles. We conclude that the disulfide is extracellular. To identify the Cys residue forming the disulfide, we labeled the sulfhydryls both in receptor dimer and in monomer generated by mild reduction of dimer. By high performance liquid chromatography and NH2-terminal sequencing of cyanogen bromide fragments of labeled delta-delta dimer and delta monomer, we found that the penultimate residue, delta-Cys-500, uniquely formed an intersubunit disulfide and that this disulfide was uniquely reduced when receptor dimer was reduced to monomer. Therefore, the delta COOH terminus is extracellular.     

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.     

Effects of temperature,lipid modification and pH on the mobility of the major proteins of the receptor-rich membranes from Torpedo marmorata

The factors influencing the overall mobility of the major proteins of the acetylcholine receptor-rich membranes from Torpedo marmorata have been investigated by saturation transfer ESR spectroscopy and the lateral distribution of these proteins has been studied by electron microscopy. A spin-labelled derivative of maleimide, 3-maleimido-2,2,5,5-tetramethyl-1-pyrrolidinyloxyl (MSL), was used under various conditions of incubation, enabling us to attach it mainly to either an extrinsic protein of 43 kdaltons, or an intrinsic protein (40 kdaltons) bearing the α-toxin-binding site. (1) The direct reaction of MSL with the membrane fragments resulted in almost exclusive labelling of the 43 kdalton protein, an extrinsic protein located on the inner face of the receptor-rich membranes. (2) After the free SH groups were blocked with $\text{N-}\text{ethylmaleimide}$ and the disulfide bridges opened with the reducing agent dithiothreitol, MSL reacted with both the 40 and 43 kdalton proteins ($\text{6.0±0.6}\text{MSL}$ molecules per α-toxin-binding site). (3) After the latter labelling procedure membranes were exposed to pH 11, resulting in extraction of the 43 kdalton protein and leaving $\text{2.2 ± 0.4}\text{MSL}$ molecules per α-toxin-binding site; sodium dodecyl sulfate polyacrylamide gel electrophoresis performed with $\text{N-[}{}^{14}\text{C}\text{]}\text{ethylmaleimide}$ suggested that MSL was bound mainly to the 40 kdalton polypeptide chain of the acetylcholine receptor. The following conclusions were made with the native and alkaline-treated membranes: In the native membranes, saturation transfer ESR does not reveal any significant protein rotational diffusion (itrotational correlation time $\text{τ}{}_{\mathrm{c}}\text{> 1}\text{ms}$). Temperature variations and/or lipid modifications obtained by fusion of exogenous lipids and/or cholesterol exchange have little influence on the saturation transfer ESR spectra. Electron microscopy reveals that upon lipid addition, proteins remain in the form of clusters while areas depleted of proteins appear. On the other hand, alkaline treatment strikingly enhances the motion of the MSL-labelled proteins in the membrane ($\text{100 ? τ}{}_{\mathrm{c}}\text{? 120 μ}\text{s}$). Furthermore, the rotational diffusion of the MSL-labelled proteins (mainly the 40 kdalton protein) becomes sensitive to temperature, lipid composition and the lipid-to-protein ratio. Electron microscopy shows that alkaline extraction does not cause large reorganization of the acetylcholine receptor in the plane of the membrane. However, when phospholipids are added to pH 11 treated membranes, a dispersion of the receptor rosettes is observed. In contrast, cholesterol enrichment of the latter membranes induces clustering of the receptor and immobilization as judged by saturation transfer ESR. Upon reassociation of the pH 11 soluble proteins with the alkaline-treated membranes, the restriction of the acetylcholine receptor rotational mobility is also restored ($\text{τ}{}_{\mathrm{c}}\text{? 1}\text{ms}$).     

Manganese proteins isolated from spinach thylakoid membranes and their role in O2 evolution. I. A 56 kilodalton managnese-containing protein, a probable component of the coupling factor enzyme

The binding of endogenous manganese (Mn) to proteins released from spinach grana-thylakoid membranes by 2% cholate detergent or by osmotic shock is investigated. A mixture of 15-20 proteins is released by cholate and has been separated by isoelectric focusing in a sucrose gradient or by chromatofocusing. Mn coelutes with several proteins, but is lost upon dialysis. A dramatic redistribution of this Mn occurs in proteins released by osmotic shock in the presence of hydrophobic and hydrophilic oxidants. Maintaining an oxidizing solution potential during extraction apparently precludes reduction of the higher oxidation states of Mn to the labile Mn(II) state by reducing agents released from the membranes during lysing. This allows proteins to be separated which bind non-labile Mn ions. Under these extraction conditions, a protein is isolated which has an apparent molecular weight (Mr) of 65000 or 56000 on SDS-polyacrylamide gel electrophoresis depending on the sample buffer system used. The nondissociated protein occurs as a monomer of 58 kDa (90%) and an apparent dimer of 112 kDa (10%) by gel filtration. This protein binds little Mn if extracted by cholate and separated by isoelectric focusing. However, extraction by osmotic shock in the presence of oxidants and separation by chromatofocusing results in the retention of 1.9 +/- 0.3 Mn ions per monomer. This protein is identical to that reported by Spector and Winget (Spector, M., and Winget, G.D. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 957-959). Contrary to their result, this protein does not reconstitute O2 evolution when added to depleted membranes. Rabbit antibody to this purified protein inhibits O2 evolution by 20% when incubated with intact grana-thylakoid membranes or 10-20% with partially inverted, French-pressed thylakoids. This inhibition is completely removed by 10(-3)M NH3Cl as an uncoupler of photophosphorylation. These results support a role in Phosphorylation and a location on the outer surface of the thylakoids. This antibody also selectively binds purified coupling factor, CF1, the multisubunit phosphorylation enzyme which is located on the outer thylakoid surface and which is known to bind two Mn ions tightly (Hochman, Y. and Carmeli, C. (1981) Biochemistry 20, 6293-6297). Thus the beta-subunit of CF1, which has a molecular weight of 56 kDa, can be identified as the locus of Mn binding in CF1 and as the Mn protein isolated by Spector and Winget. This protein plays no role on O2 evolution.     

Protease effects on the structure of acetylcholine receptor membranes from Torpedo californica

Protease digestion of acetylcholine receptor-rich membranes derived from Torpedo californica electroplaques by homogenization and isopycnic centrifugation results in degradation of all receptor subunits without any significant effect on the appearance in electron micrographs, the toxin binding ability, or the sedimentation value of the receptor molecule. Such treatment does produce dramatic changes in the morphology of the normally 0.5- to 2-microns-diameter spherical vesicles when observed by either negative-stain or freeze-fracture electron microscopy. Removal of peripheral, apparently nonreceptor polypeptides by alkali stripping (Neubig et al. 1979, Proc. Natl. Acad. Sci. U. S. A. 76:690-694) results in increased sensitivity of the acetylcholine receptor membranes to the protease trypsin as indicated by SDS gel electrophoretic patterns and by the extent of morphologic change observed in vesicle structure. Trypsin digestion of alkali- stripped receptor membranes results in a limit degradation pattern of all four receptor subunits, whereupon all the vesicles undergo the morphological transformation to minivesicles. The protein-induced morphological transformation and the limit digestion pattern of receptor membranes are unaffected by whether the membranes are prepared so as to preserve the receptor as a disulfide bridged dimer, or prepared so as to generate monomeric receptor.     

Interaction of the 43K protein with components of Torpedo postsynaptic membranes

Interactions of the major Mr 43 000 peripheral membrane protein (43K protein) with components of Torpedo postsynaptic membranes have been examined. Treatment of membranes with copper o-phenanthroline promotes the polymerization of 43K protein to dimers and higher oligomers. These high molecular weight forms of 43K protein can be converted to monomers by reduction with dithiothreitol and do not contain any of the other major proteins found in these membranes, including the subunits of the acetylcholine receptor, as shown by immunoblotting with monoclonal antibodies. To study directly its interactions with the membrane, the 43K protein was radioiodinated and purified by immunoaffinity chromatography. Purified 43K protein binds tightly to pure liposomes of various compositions in a manner that is not inhibited by KCl concentrations up to 0.75 M. The binding can be reversed by adjusting the pH of the reaction to 11, the same treatment that removes 43K protein from postsynaptic membranes. Unlabeled 43K protein solubilized from Torpedo membranes with cholate can be reconstituted with exogenously added lipids in the absence of the receptor. The results suggest that 43K protein molecules are amphipathic and that they may interact with each other and with the lipid bilayer. These interactions cannot explain the coextensive distribution of 43K proteins with acetylcholine receptors in situ. However, they could account for the association of the 43K protein with the postsynaptic membrane and may contribute to the maintenance of the structure of the cytoplasmic specialization of which this protein is a major component.     

Receptor for bacteriophage lambda of Escherichia coli forms larger pores in black lipid membranes than the matrix protein (porin).

The receptor for phage lambda in Escherichia coli was isolated by cholate extraction and purified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Protein bands corresponding to the monomer and the dimer were eluted from the gel and tested for their activity to inactivate phage lambda and to form pores in black lipid membranes. It was found that only the dimer inactivated phage lambda, whereas both the monomer and the dimer were active in forming pores. The pore characteristics were similar to those exhibited by the matrix protein (porin) (R. Benz, K. Janko, W. Boos, and P. L?uger, Biochim. Biophys. Acta 511:305--319, 1978). In comparison, the lambda receptor showed a somewhat higher degree of cation specificity, and its pore size was larger. Assuming that the thickness of the outer membrane is 7.5 nm and that the pore is an ideal hydrophilic channel, the pore diameter in vivo was estimated to be 1.6 nm for the lambda receptor and 1.2 nm for the matrix protein.     

Visualization of the cytoplasmic surface of Torpedo postsynaptic membranes by freeze-etch and immunoelectron microscopy

The synapse-specific Mr 43,000 protein (43K protein) and the acetylcholine receptor were visualized by freeze-etch immunoelectron microscopy in preparations of purified Torpedo postsynaptic membranes. Vesicles were immobilized on glass and then sheared open by sonication to expose the cytoplasmic surface. Membranes were labeled with monoclonal antibodies to the 43K protein or the acetylcholine receptor. The cytoplasmic surface was devoid of filamentous structure, and the 43K protein and the cytoplasmic projection of the acetylcholine receptor were associated with prominent surface particles. Acetylcholine receptor and 43K protein, in membrane surfaces in direct contact with glass coated with polyornithine, segregated into dense particle aggregates separated by smooth membrane patches, whereas those in contact with glass coated with Alcian Blue underwent little or no detectable rearrangement. After treatment of vesicles at alkaline pH to remove the 43K protein, the cytoplasmic surfaces were still covered by a dense array of particles that were more uniform in shape and appeared slightly shorter than those seen on unextracted membranes, but similar in height to the extracellular projection. Monoclonal antibodies to the acetylcholine receptor labeled these particles, while antibodies to 43K protein did not. We conclude that the 43K protein is in direct association with the receptor and that complexes of the receptor and 43K protein can undergo surface-induced lateral redistribution. In addition, the cytoplasmic projection of the acetylcholine receptor is sufficiently large to be readily detected by freeze-etch electron microscopy and is similar in height to the extracellular projection.     

A differential scanning calorimetry study of acetylcholine receptor-rich membranes from Torpedo californica

Various acetylcholine receptor-rich membrane preparations from Torpedo californica electroplax tissue were examined using the techniques of differential scanning calorimetry coupled with gel electrophoretic analysis of heat-denaturing material and functional assays following passage through discrete transitions. In unfractionated membranes, four irreversible calorimetric transitions were observed, one of which (Td = 59 degrees C) could be assigned to a complete loss of acetylcholine receptor function. A second lower temperature transition apparently corresponds to loss of certain peripheral membrane proteins including the Mr = 43,000 polypeptide and the acetylcholinesterase activity. Membrane preparations highly enriched in acetylcholine receptor polypeptides contained a major transition at 59 degrees C which could be shown to be sensitive to the presence of added ligands of the acetylcholine receptor, supporting its assignment to structural alterations of the receptor protein or its arrangement in the membrane.     

Effects of ZnCl2 on membrane interactions in myelin of normal and shiverer mice

X-ray diffraction was used to record the effects of metal cations on the structure of peripheral nerve myelin. Acidic saline (pH 5.0) either with or without added metal cations caused myelin to swell by 10-20 A from its native period of 178 A. The X-ray patterns usually showed broad reflections, and higher orders were either weak or unobserved. With added ZnCl2, however, the swollen myelin gave diffraction patterns that retained sharp reflections to approx. 15 A spacing. Alkaline saline (pH 9.7) containing ZnCl2 produced a reduction of the myelin period by approx. 5 A which was at least twice as much as that produced by other metals. To examine the underlying chemical basis for these unique interactions of Zn2+ with myelin, we carried out parallel X-ray experiments on sciatic nerve from the shiverer mutant mouse, which lacks the major myelin basic proteins. Shiverer myelin responded like normal myelin to ZnCl2 in acidic saline; however, in alkaline saline shiverer myelin showed broadened X-ray reflections which indicated disordering of the regularity of the membrane arrays, and additional reflections were recorded which indicated lipid phase separation. This breakdown may come about by the binding of Zn2+ to negatively-charged lipids which could be more exposed due to the absence of myelin basic proteins. Electron density profiles were calculated on the assumption that, except for changes in their packing, the myelin membranes were minimally altered in structure. For both normal and shiverer myelins, treatments under acidic conditions resulted in swelling at the extracellular apposition and a slight narrowing of the cytoplasmic space. This swelling is likely due to adsorption of protons and divalent cations. Interaction between Zn2+ and myelin P0 glycoprotein could preserve an ordered arrangement of the apposed membrane surfaces. Alkaline saline containing ZnCl2 produced compaction at the cytoplasmic apposition in both normal and shiverer myelins possibly through interactions with a portion of P0 glycoprotein which extends into the cytoplasmic space between membranes.     

Manganese proteins isolated from spinach thylakoid membranes and their role in O2 evolution: I. A 56 kilodalton manganese-containing protein,a probable component of the coupling factor enzyme

The binding of endogenous manganese (Mn) to proteins released from spinach grana-thylakoid membranes by 2% cholate detergent or by osmotic shock is investigated. A mixture of 15–20 proteins is released by cholate and has been separated by isoelectric focusing in a sucrose gradient or by chromatofocusing. Mn coelutes with several proteins, but is lost upon dialysis. A dramatic redistribution of this Mn occurs in proteins released by osmotic shock in the presence of hydrophobic and hydrophilic oxidants. Maintaining an oxidizing solution potential during extraction apparently precludes reduction of the higher oxidation states of Mn to the labile Mn(II) state by reducing agents released from the membranes during lysing. This allows proteins to be separated which bind non-labile Mn ions. Under these extraction conditions, a protein is isolated which has an apparent molecular weight (M_r) of 65 000 or 56 000 on SDS-polyacrylamide gel electrophoresis depending on the sample buffer system used. The nondissociated protein occurs as a monomer of 58 kDa (90%) and an apparent dimer of 112 kDa (10%) by gel filtration. This protein binds little Mn if extracted by cholate and separated by isoelectric focusing. However, extraction by osmotic shock in the presence of oxidants and separation by chromatofocusing results in the retention of 1.9 ± 0.3 Mn ions per monomer. This protein is identical to that reported by Spector and Winget (Spector, M., and Winget, G.D. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 957–959). Contrary to their result, this protein does not reconstitute O₂ evolution when added to depleted membranes. Rabbit antibody to this purified protein inhibits O₂ evolution by 20% when incubated with intact grana-thylakoid membranes or 10–20% with partially inverted, French-pressed thylakoids. This inhibition is completely removed by 10^?3 M NH₃Cl as an uncoupler of photophosphorylation. These results support a role in Phosphorylation and a location on the outer surface of the thylakoids. This antibody also selectively binds purified coupling factor, CF₁, the multisubunit phosphorylation enzyme which is located on the outer thylakoid surface and which is known to bind two Mn ions tightly (Hochman, Y. and Carmeli, C. (1981) Biochemistry 20, 6293–6297). Thus the β-subunit of CF₁, which has a molecular weight of 56 kDa, can be identified as the locus of Mn binding in CF₁ and as the Mn protein isolated by Spector and Winget. This protein plays no role on O₂ evolution.     

Dystrophin in electric organ of Torpedo californica homologous to that in human muscle

We have found that dystrophin is highly concentrated at neuromuscular junctions and innervated membranes of the electric organ of Torpedo californica. In acetylcholine receptor-rich Torpedo membrane preparations dystrophin represents approximately 0.4% of total protein and can be extracted from these membranes by alkaline treatment in the absence of detergent, indicating that it is a peripheral membrane protein. Polyclonal antibodies raised against electrophoretically isolated Torpedo dystrophin cross-react with dystrophin in human muscle and unequivocally discriminate between normal and Duchenne muscular dystrophy patient's muscle. These results indicate that dystrophin is phylogenetically a highly conserved protein and that the relatively abundant dystrophin in electric organ would facilitate further investigations of its structure and function.     

Isolation and partial characterization of heparan sulphate proteoglycan from the human glomerular basement membrane.

Heparan sulphate proteoglycan was solubilized from human glomerular basement membranes by guanidine extraction and purified by ion-exchange chromatography and gel filtration. The yield of proteoglycan was approx. 2 mg/g of basement membrane. The glycoconjugate had an apparent molecular mass of 200-400 kDa and consisted of about 75% protein and 25% heparan sulphate. The amino acid composition was characterized by a high content of glycine, proline, alanine and glutamic acid. Hydrolysis with trifluoromethanesulphonic acid yielded core proteins of 160 and 110 kDa (and minor bands of 90 and 60 kDa). Alkaline NaBH4 treatment of the proteoglycan released heparan sulphate chains with an average molecular mass of 18 kDa. HNO2 oxidation of these chains yielded oligosaccharides of about 5 kDa, whereas heparitinase digestion resulted in a more complete degradation. The data suggest a clustering of N-sulphate groups in the peripheral regions of the glycosaminoglycan chains. A polyclonal antiserum raised against the intact proteoglycan showed reactivity against the core protein. It stained all basement membranes in an intense linear fashion in immunohistochemical studies on frozen kidney sections from man and various mammalian species.