Studies on cytochrome c oxidase, I. Purification and characterization of bovine myocardial enzyme and identification of peptide chains in the complex]

As part of the preliminary work for the structural elucidation of cytochrome c oxidase, the enzyme complex was isolated from bovine heart muscle and characterised chemically. The enzyme contains 10-11 nmol haem a, and 12-13 nmol copper per mg protein. The solubilised active enzyme also contains 5% phospholipid, comprising about 2 mol each of cardiolipin and phosphatidylethanolamine per mol haem a. In addition, the preparation contains a small number of detergent molecules (Tween-80). Eight polypeptide components were isolated by preparative dodecylsulphate gel electrophoresis, gel filtration on Biogel P-60, and counter current distribution. The apparent molecular weights of these components were I - 36 000, II - 28 000 (21 000), III - 19 000, IV - 14 000, V - 12 500, VI - 11 000, VII - 10 000 and VIII - 6000. At least seven intact polypeptide chains contribute to the structure of the enzyme complex of the terminal oxidase. On the basis of amino acid analysis and end group determination, they can be divided into two groups. The high molecular weight peptides I -III are hydrophobic and their amino acid compositions differ markedly from those of known enzyme proteins, especially with respect to their contents of leucine and methionine. Components I and II have formyl methionine at their N-termini. They are therefore possibly mitochondrial membrane components from complex 4 of the respiratory chain. Polypeptides IV - VII resemble functional enzyme subunits in their amino acid composition. Some of them possess free N-termini (alanine). The low molecular weight component VIII is heterogeneous and contains the N-terminal amino acids isoleucine, serine and phenylelanine in non-stoichiometric amounts. Analysis gives a minimal protein molecular weight of 130 000 (65 000 per haem a) for the two haem and two copper-containing "monomers". The molecular weight of the moiety preliminarily defined as enzymatic is about 48 000. The chemical characterisation provides data for the strategy of the subsequent sequence analysis of the polypeptides.     

Glycolipid-binding proteins

Proteins which bind glycolipids with high specificity are tentatively divided into two groups. One group consists of activator proteins involved in the catabolism of glycolipids by acid lysosomal hydrolases. Two activator proteins, GM2-activator and sphingolipid activator protein-1, are critically appraised on their glycolipid-binding properties and on their activity to facilitate the transfer of glycolipids. These proteins are glycoproteins localized in the lysosomes. Their molecular weights are in a range of 21 000-27 000, and isoelectric points are 4-5. Glycolipid transfer protein (GLTP) is included in the other group. GLTP purified from pig brain has a molecular weight of about 20 000 and an isoelectric point of 8.3. GLTP facilitates the transfer of various glycosphingolipids and glyceroglycolipids between membranes. The protein does not facilitate the transfer of phospholipids or cholesterol. GLTP binds galactosylceramide. The galactosylceramide-GLTP complex participates in the transfer reaction as the intermediate. Each protein in both groups binds glycolipids with a characteristic specificity to the sugar moiety. A stoichiometry of 1 mol of lipid per mol of protein has been found in all three proteins. Proteins in both groups seem to have a hydrophobic region on their surface, since all three proteins have been efficiently purified by hydrophobic chromatography.     

Quantitation, chemical characteristics, and ultrastructure of the three outer cell wall layers of a gram-negative bacterium

The cell wall of the gram-negative marine pseudomonad (American Type Culture Collection 19855) consists of three layers: the loosely bound outer layer, the outer double-track layer, and the underlying layer. These three layers constitute 4.7, 7.9, and 6.1%, respectively, of the dry weight of the whole cells. All three layers contained protein, lipid, and carbohydrate. The loosely bound outer layer and underlying layer were lower in protein and lipid and higher in amino and nonamino carbohydrate than the outer double-track layer. All three layers contained proteins with similar amino acid compositions. Minicell-like forms attached to the ends of cells were separated with and fractionated from the units of loosely bound outer layer. Examination of negatively stained preparations by electron microscopy revealed the loosely bound outer layer to be composed largely of units ranging from 400 to 1000 nm in diameter. The outer double-track layer, by the same technique, appeared as large, usually rounded sheets, each with a distinct rim. Washing this layer changed the gross chemical composition but did not affect the bimolecular leaflet appearance in thin sections. The underlying layer, when negatively stained, appeared to be composed of a heterogeneous mixture of particles differing in size and shape. It was separated by gel filtration into a large fraction with a molecular weight range in excess of 20 × 10⁶ to 40 × 10⁶ and a small fraction with a lower range of molecular weight. The larger fraction contained both protein and hexosamine, whereas the smaller one contained protein and only traces of hexosamine. A cytochrome-like pigment separated with this latter fraction.     

Interior and surface of monomeric proteins

The solvent-accessible surface area (As) of 46 monomeric proteins is calculated using atomic co-ordinates from high-resolution and well-refined crystal structures. The As of these proteins can be determined to within 1 to 2% and that of their individual residues to within 10 to 20%. The As values of proteins are correlated with their molecular weight (Mr) in the range 4000 to 35,000: the power law As = 6.3 M0.73 predicts protein As values to within 4% on average. The average water-accessible surface is found to be 57% non-polar, 24% polar and 19% charged, with 5% root-mean-square variations. The molecular surface buried inside the protein is 58% non-polar, 39% polar and 4% charged. The buried surface contains more uncharged polar groups (mostly peptides) than the surface that remains accessible, but many fewer charged groups. On average, 15% of residues in small proteins and 32% in larger ones may be classed as "buried residues", having less than 5% of their surface accessible to the solvent. The accessibilities of most other residues are evenly distributed in the range 5 to 50%. Although the fraction of buried residues increases with molecular weight, the amino acid compositions of the protein interior and surface show no systematic variation with molecular weight, except for small proteins that are often very rich in buried cysteines. From amino acid compositions of protein surfaces and interiors we calculate an effective coefficient of partition for each type of residue, and derive an implied set of transfer free energy values. This is compared with other sets of partition coefficients derived directly from experimental data. The extent to which groups of residues (charged, polar and non-polar) are buried within proteins correlates well with their hydrophobicity derived from amino acid transfer experiments. Within these three groups, the correlation is low.     

Structural studies on a glycoprotein isolated from alveoli of patients with alveolar proteinosis.

A major glycoprotein 36 000 molecular weight) has been isolated from lung lavage of patients with alveolar proteinosis and found to contain five residues of hydroxyproline, fifty residues of glycine, three residues of methionine, 3 mol of sialic acid, 4.4 mol of mannose, 4.0 mol of galactose, 6.0 mol of glucosamine, and 1 mol of fucose. Cyanogen bromide (CNBr) treatment of the glycoprotein resulted, as expected, in four peptides of apparent molecular weights of 18 000, 12 000, 5000 and 1000, respectively. The chemical compositions of the CNBr peptides indicate the presence of hydroxyproline and high amounts of glycine in all but one of the peptides; two of the four CNBr peptides contain carbohydrate. Gel filtration, acrylamide gel electrophoresis and end-group analyses of the native glycoprotein and its CNBr peptides indicate that the peptides are homogeneous. End-group analyses of the CNBr cleavage products assign the 18 000 molecular weight peptide to the NH2-terminal portion and the 1000 molecular weight peptide to the COOH-terminal portion of the native glycoprotein molecule. Pronase digestion of the 36 000 molecular weight glycoprotein, followed by gel filtration and cation exchange chromatography, resulted in two fractions. One fraction was acidic and contained all the carbohydrate, a high content of aspartic acid and no hydroxyproline. The other fraction was basic and contained 8.4% hydroxyproline, 14% proline, 28% glycine and no carbohydrate, suggesting the presence of collagen-like sequence in the peptide chain. Paper electrophoresis of the basic fraction demonstrated two components, the amino acid compositions of which are identical to those of collagen. Partial amino-terminal sequence analysis of one of the CNBr peptides (18 000 molecular weight) indicated the presence of -Fly-Pro-HyP-Gly-sequence in the peptide chain, which confirms our suggestion that collagen-like regions are present in the native glycoprotein molecule. Limited acid hydrolysis of the acidic fraction and subsequent fractionation of the acid hydrolysate using Dowex column yielded a fraction which produced brown colour with ninhydrin reagent. Paper chromatography of this fraction demonstrated a large component which also stained brown with ninhydrin reagent. After acid hydrolysis, this component was found to consist of equal amounts of asparitic acid and glucosamine, indicating that the N-acetylglucosamine of the oligosaccharides is linked to the asparagine residue of the peptide. No serine or threonine linkages are present.     

The self-association of L-alpha hydroxyacid oxidase.

As the published values for the molecular weight of L-alpha-hydroxyacid oxidase vary from 89 000 to 430 000, it is possible that such variations could be due to a concentration dependence of the molecular weight. The molecular weight of rat L-alpha-hydroxyacid oxidase was studied over a wide range of concentrations, using equilibrium sedimentation and gel exclusion chromatography. The partial specific volumes (0.726 and 0.730 for hydroxyacid oxidase A and hydroxyacid oxidase B, respectively) were calculated from the amino acid compositions, and were used to calculat molecular weights from the equilibrium sedimentation data. The molecular weight at infinite dilution was found to be 150 000 for both the A and B isozymes. Both isozymes exhibit association-dissociation behaviour at low concentrations. The self-association of the hydroxyacid oxidase B isozyme can be described by the relation (see article) where K1,2 = 5.4-10(5) M-1 and K2,4 = 1.7-10(5) M-1. Previously published values of the molecular weight of these isozymes are in accord with the observed concentration dependence.     

Compositional characteristics of a chloroform/methanol soluble protein fraction from spinach chloroplast membranes.

Extraction of an aqueous suspension of spinach chloroplast lamellae with a chloroform/methanol mixture leads to solubilization of about 1/3 of the total membrane protein. Amino acid analysis of the chloroform/methanol-soluble protein shows that this fraction is largely enriched in the hydrophobic residues proline, leucine, alanine and phenylalanine and considerably depleted in polar amino acids, namely lysine and arginine. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the solubilized material reveals the presence of a variety of low molecular weight polypeptides (molecular weight less than or equal to 25 000), with more than 50% of the total fraction being contributed by a 25 000 dalton band. This band, which accounts for about 25% of the total chloroplast lamellar protein, has recently been identified as the main component of the light-harvesting chlorophyll-protein complex. The physiological role of most of the chloroform/methanol-soluble protein fraction is not known at present. From its chemical properties and apparent biological inertness, we propose that it plays mainly a structural role in situ, interacting with the lipid moiety of the chloroplast membrane. The material insoluble in the aqueous chloroform/methanol mixture is largely enriched in manganese, iron, cytochrome and water-soluble proteins, such as chloroplast coupling factor and ribulose diphosphate carboxylase.     

Production of autostimulatory growth factors by the human carcinoma line,RPMI 2650

Summary The human carcinoma line RPMI 2650 produces autocrine factors; they are detected by the ability of RPMI 2650 conditioned medium (CM) to stimulate growth in soft agar of RPMI 2650 cells plated at low density. The autocrine activity in crude CM can be fractionated by ultrafiltration into a lower molecular weight (MW) fraction (R1–30), which concentrates molecules in the 1000–30 000 Da range; and a higher MW fraction (R30) with molecules greater than 30 000 Da in a more concentrated form. R1–30 is labile to acid, base, and heat treatment, whereas R30 is stable to (and sometimes activated by) these treatments. Boiling of R30, however, renders it labile to acid, base, and trypsin treatments. CM can be separated into a weakly heparin-binding fraction (with stability properties similar, but not identical, to R1–30), and a non-heparin binding fraction (with stability properties similar to R30). RPMI 2650 cells secrete transforming growth factor (TGF)α- and TGFβ-like molecules, but the R1–30 fraction can be distinguished from these TGFs, and from most other known growth factors, by its unusual combination of acid lability and weak affinity for heparin. Since the R30/non-heparin binding fraction is rendered labile by boiling or acid treatment, it may represent a bound or conformationally stable form of a growth factor.     

The procuticle of Drosophila: heterogeneity of urea-soluble proteins.

Proteins, soluble in 7 M urea, 4 M guanidine hydrochloride, or 2% sodium dodecyl sulfate, have been extracted from untanned larval cuticles of Drosophila melanogaster. A major protein fraction, apparent molecular weight 8000 - 10 000, is resolved into eight different components (five major, three minor) by gradient gel electrophoresis under nondenaturing conditions. Proteins extracted in 7 M urea have been resolved by diethylaminoethylcellulose chromatography into five fractions, three of which are greatly enriched for electrophoretically homogeneous proteins. The five fractions have different amino acid compositions. Electrophoretic variants involving four of the five major proteins have been obtained. Preliminary genetic analysis indicates that at least three of the five proteins are specified by separate structural genes.     

Isolation and characterization of major intrinsic microsomal membrane proteins.

Treatment of the membrane matrix derived from hepatic microsomes with buffered 1 M urea resulted in the selective extraction of a group of proteins together with a portion of the membrane lipid. Thorough chemical characterization of this fraction has been performed, and the proteins have been fractionated by two different procedures. The first of these, preparative polyacrylamide gel electrophoresis, has produced five highly homogeneous membrane proteins which have been characterized with regard to molecular weight, electrophoretic behavior in five different polyacrylamide systems, NH2 terminus, relative carbohydrate content, isoelectric point, and amino acid composition. The five proteins of this group fell in the molecular weight range of 54,000 to 96,000 and had isoelectric points ranging from pH 4.9 to pH 6.7. Further fractionation of the urea-soluble proteins by gel filtration in a sodium dodecyl sulfate-containing medium resulted in the isolation of four homogeneous molecular weight classes of proteins which have been characterized with respect to various physicochemical parameters. The major membrane glycoprotein (apparent molecular weight, 171,000) was isolated by this procedure and found to contain approximately equal amounts of NH2-terminal glycine and serine. suggesting the presence of at least two polypeptide chains in this molecular weight region. From the urea-insoluble fraction of the membrane comprising approximately 80% of the total protein, five intrinsic polypeptides designated S-5 through S-9 were isolated. S-5 (54,000) and S-6 (49,000) represent the most prominent components in the microsomal membrane, accounting for close to 30% of the total protein. Also isolated and characterized is the smallest membrane protein (S-9), a hydrophobic polypeptide of molecular weight 16,000. All of the urea-insoluble proteins are glycoproteins, and S-7 (35,000) gives the second most intense stain for carbohydrate of all proteins in the microsomal membrane.     

Compositional characteristics of a chloroform/methanol soluble protein fraction from spinach chloroplast membranes

Extraction of an aqueous suspension of spinach chloroplast lamellae with a chloroform/methanol mixture leads to solubilization of about $\text{1}\text{3}$ of the total membrane protein. Amino acid analysis of the chloroform/methanol-soluble protein shows that this fraction is largely enriched in the hydrophobic residues proline, leucine, alanine and phenylalanine and considerably depleted in polar amino acids, namely lysine and arginine. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the solubilized material reveals the presence of a variety of low molecular weight polypeptides (molecular weight ? 25 000), with more than 50% of the total fraction being contributed by a 25 000 dalton band. This band, which accounts for about 25% of the total chloroplast lamellar protein, has recently been identified as the main component of the light-harvesting chlorophyll-protein complex. The physiological role of most of the chloroform/methanol-soluble protein fraction is not known at present. From its chemical properties and apparent biological inertness, we propose that it plays mainly a structural role in situ, interacting with the lipid moiety of the chloroplast membrane. The material insoluble in the aqueous chloroform/methanol mixture is largely enriched in manganese, iron, cytochrome and water-soluble proteins, such as chloroplast coupling factor and ribulose diphosphate carboxylase.     

Low molecular weight plasma proteins isolated from preparations of human immunoglobulin

Low molecular weight proteins co-purified with IgG constitute 0.22% of the total protein purified from human plasma by ion-exchange chromatography on DEAE-cellulose. We have found that these low molecular weight proteins were obtained free of immunoglobulin by ultrafiltration in 5 M guanidinium chloride. Electrophoresis and isoelectric focusing in polyacrylamide gels demonstrated that this fraction of low molecular weight proteins is remarkably heterogeneous. Chromatography of an Mr 6000 to 12 000 fraction on hydroxyapatite resolved fourteen discrete protein peaks. Three of the peaks contained proteins which appeared to be homogeneous on acid-urea polyacrylamide gels. Two of these proteins were similar in composition to B2 globulin and may represent degradation products of some larger protein. The third protein was found to have an amino-terminal sequence identical to C3a. This population of low molecular weight plasma proteins has previously been shown to contain the cystic fibrosis mucociliary inhibitor and is here shown to contain two proteins similar to B2 globulin, C3a and many proteins remaining to be characterized. The presence of these low molecular weight proteins in measurable concentrations may be insufficiently appreciated in studies using 'purified' immunoglobulins as biological or chemical probes.     

Strain-specific differences in the proline-rich proteins and glycoproteins induced in rat salivary glands by chronic isoprenaline treatment.

Parotid and submandibular glands were isolated from five strains of rat after chronic injection of the beta-adrenergic receptor agonist isoprenaline (isoproterenol). The glands were observed to have undergone a marked increase in wet weight, owing to hypertrophy and hyperplasia. The 100 000 g soluble fraction of gland cell lysates were extracted with 10% (w/v) trichloroacetic acid, and the soluble material subsequently analysed by SDS (sodium dodecyl sulphate)/polyacrylamide-gel electrophoresis. By this procedure, evidence was obtained for the induction, in isoprenaline-treated parotid and submandibular glands, of proline-rich proteins with apparent Mr values ranging from 20 000 to 40 000. Heterogeneity was evident in the proteins produced for a specific gland between the rat strains, although the amino acid compositions were the same. Products from induced mRNAs translated in vitro had similar mobilities in SDS/polyacrylamide gels, despite the apparent difference in mobility of trichloracetic acid-extracted proline-rich proteins from the various strains. Strain-specific differences were noted for the proline-rich glycoproteins from control salivary glands as well as those induced as a consequence of isoprenaline treatment. Although the glycoproteins had similar amino acid compositions, there was considerable heterogeneity in the carbohydrate compositions for these proteins, suggesting that the differences were the result of post-translational modifications during glycosylation. Induction of the increased activity of the Golgi membrane marker enzyme UDP-galactose:2-acetamido-2-deoxy-D-glucosamine 4 beta-galactosyltransferase (EC 2.4.1.22) occurred to the same extent in the parotid glands of all strains examined. There was no change in the specific activity of a second enzyme, UDP-galactose:N-acetylgalactosaminyl-protein 3 beta-galactosyltransferase (no EC designation).     

Structure-Based Analysis of the Ligand-Binding Mechanism for DhelOBP21, a C-minus Odorant Binding Protein,from Dastarcus helophoroides (Fairmaire; Coleoptera: Bothrideridae)

Odorant binding proteins (OBPs) transport hydrophobic odor molecules across the sensillar lymph to trigger a neuronal response. Herein, the Minus-C OBP (DhelOBP21) was characterized from Dastarcus helophoroides, the most important natural parasitic enemy insect that targets Monochamus alternatus. Homology modeling and molecular docking were conducted on the interaction between DhelOBP21 and 17 volatile molecules (including volatiles from pine bark, the larva of M. alternatus, and the faeces of the larva). The predicted three-dimensional structure showed only two disulfide bridges and a hydrophobic binding cavity with a short C-terminus. Ligand-binding experiments using N-phenylnaphthylamine (1-NPN) as a fluorescent probe showed that DhelOBP21 exhibited better binding affinities against those ligands with a molecular volume between 100 and 125 ų compared with ligands with a molecular volume between 160 and 185 ų. Molecules that are too big or too small are not conducive for binding. We mutated the amino acid residues of the binding cavity to increase either hydrophobicity or hydrophilia. Ligand-binding experiments and cyber molecular docking assays indicated that hydrophobic interactions are more significant than hydrogen-bonding interactions. Although hydrogen-bond interactions could be predicted for some binding complexes, the hydrophobic interactions had more influence on binding following hydrophobic changes that affected the cavity. The orientation of ligands affects binding by influencing hydrophobic interactions. The binding process is controlled by multiple factors. This study provides a basis to explore the ligand-binding mechanisms of Minus-C OBP.     

Acidic ribosomal proteins of Neurospora crassa

Neurospora crassa acidic ribosomal proteins from the high salt-ethanol extract of 80 S ribosomes have been fractionated by DEAE-cellulose chromatography. Six acidic ribosomal proteins were purified. All resemble Escherichia coli L7 and L12 in amino acid composition and molecular weight but each has a slightly different net charge at pH 3.2. Four have an apparent molecular weight of approx. 14 000, and two have a molecular weight of approx. 14 800. The amino acid compositions and circular dichroism (CD) spectra of the purified Neuropsora proteins are identical for the four 14 kDa proteins, but clearly distinguishable from the two 14.8 kDa proteins. The latter are also identical in amino acid composition and CD spectra. This suggests that there are two Neurospora acidic, or 'A', proteins, one of which exists in four microheterogeneous forms and the other exists in two forms.     

Isolation and partial characterization of chromoprotein from the larval hemolymph of the Japanese oak silkworm (Antheraea yamamai)

A total of two different hemolymph proteins (designated P-I and P-II) of the Japanese oak silkworm, Antheraea yamamai, were purified from the hemolymph of the fifth instar larvae using four chromatographic steps: (a) hydrophobic interaction chromatography; (b) ion exchange chromatography; (c) gel-filtration; and (d) reverse-phase high performance liquid chromatography (HPLC). These two proteins were separated by TSKgel Phenyl-5PW RP column chromatography. P-I has an apparent molecular weight of 31 000 or 35 000, as determined by gel-filtration and SDS-PAGE, respectively. P-II shows a molecular weight of 22 000 or 25 000, by gel-filtration and SDS-PAGE, respectively. The molecular weight of P-I and P-II were determined to be 31 076 and 21 500 by MALDI-TOF MS, respectively. These results suggest that both P-I and P-II are monomers. The N-terminal sequence analysis suggests that P-I is closely related to the ommochrome-binding protein (OBP) from the hemolymph of Manduca sexta, with 40% identity in the first 30 residues, while P-II is similar to the biliproteins (BPs) from other lepidopteran insects (50% identity). Spectroscopic analysis shows that the blue chromophore of A. yamamai BP is not biliverdin IX, which is present in the biliproteins of most insects.     

Binding of nonsuppressible insulinlike activity to human serum. Evidence for a carrier protein.

When ¹²⁵I-labeled nonsuppressible insulinlike activity—soluble in acid/ethanol (NSILA-S) is incubated with human serum between 10 and 20% of the radioactivity are bound to serum proteins and can be displaced specifically by cold NSILA-S. Chromatography of the incubation mixture on Sephadex G-200 at pH 7.5 reveals three peaks of radioactivity in the large molecular weight region and a fourth one corresponding to low molecular unbound labeled NSILA-S. An excess of cold NSILA-S during preincubation leads to the disappearance of the two major large molecular weight peaks and to a concomitant increase of the peak eluting in the low molecular weight range. Binding of ¹²⁵I-labeled NSILA-S is highly sensitive to small concentrations of cold NSILA-S, whereas insulin, ACTH and human growth hormone are completely ineffective in displacing bound ¹²⁵I-labeled NSILA-S. NSILA-S preparations of different purity show displacement according to their specific biological activities. Furthermore, binding of ¹²⁵I-labeled NSILA-S to serum pH- and time-dependent and displays saturation characteristics. Chromatography of serum on Sephadex G-200 with 0.15 m acetic acid/0.15 m NaCl localizes the binding fraction in the 50,000–70,000 molecular weight range. Boiling of serum for 5 min abolishes binding completely.These studies help explain why the molecular weight of NSILA varied considerably from one group of investigators to the other.     

The characterization of the proteins which are secreted by the mucocysts of Tetrahymena thermophila

The ‘mucus’ which is discharged by the ciliated protozoan Tetrahymena thermophila has been isolated. All preparations have been shown to consist of a highly consistent mixture of at least 30 proteins varying in molecular weight between 200 000 and 10 000. In marked contrast to mammalian mucins these preparations have a very low (3% w/v) carbohydrate content with glucosamine being the major sugar. The amino acid analyses show that aspartic and glutamic acids and their amides together with serine and glycine account for 45% of the amino acids.     

Ribosomal proteins

Summary The proteins of E. coli ribosomes were separated by a specially developed type of preparative polyacrylamide gel electrophoresis and proteins corresponding to 16 of the separated bands have so far been isolated. The amino acid compositions and the tryptic peptide maps of these proteins show certain degree of similarity as well as distinct differences. Determination of molecular weights revealed a wide range: The lowest molecular weight was 9,000 and the highest 41,000 for the proteins so far studied.The similarities between various ribosomal proteins in their amino acid compositions and their peptide maps on one hand and the wide range in their molecular weights on the other hand can be explained by a hypothesis involving gene duplications.     

Solubilization and reconstruction of microsomal AMP-deaminase from skeletal muscles]

Microsomal AMP-deaminase was solubilized by 0.5 M KCl after treatment of microsomal membranes with 0.12 M KCl. Using disc-electrophoresis in polyacrylamide gel in the presence of sodium dodecyl sulfate one major protein component (mol. weight about 90 000) and three minor ones with molecular weights of 110 000, 80 000, and 60 000 were found in the soluble fraction. In addition to proteins, the fraction was found in the soluble fraction. In addition to proteins, the fraction was found to contain a small amount of phospholipids. The deaminase found in the solution may be reconstructed into the membranes at a decrease in KCl concentration, part of enzyme being bound in the inactive form under excess of the soluble fraction. Deaminase binding to the membranes is unaffected by the changes within the pH range of 6.2--7.8 and temperature range of 4--10 degrees C. It is assumed that AMP-deaminase is bound to other membrane components by electrostatic bonds.