The organization of hydrogenase in the cytoplasmic membrane of Escherichia coli.

The organization of the membrane-bound hydrogenase from Escherichia coli was studied by using two membrane-impermeant probes, diazotized [125I]di-iodosulphanilic acid and lactoperoxidase-catalysed radioiodination. The labelling pattern of the enzyme obtained from labelled spheroplasts was compared with that from predominantly inside-out membrane vesicles, after recovery of hydrogenase by immunoprecipitation. The labelling pattern of F1-ATPase was used as a control for labelling at the cytoplasmic surface throughout these experiments. Hydrogenase (mol.wt. approx. 63 000) is transmembranous. Crossed immunoelectrophoresis with anti-(membrane vesicle) immunoglobulins, coupled with successive immunoadsorption of the antiserum with spheroplasts, confirmed the location of hydrogenase at the periplasmic surface. Immunoadsorption with sonicated spheroplasts suggests that the enzyme is also exposed at the cytoplasmic surface. Inside-out vesicles were prepared by agglutination of sonicated spheroplasts, and the results of immunoadsorption using these vesicles confirms the location of hydrogenase at the cytoplasmic surface.     

Proteins of the kidney microvillar membrane. Immunoelectrophoretic analysis of the membrane hydrolases: identification and resolution of the detergent- and proteinase-solubilized forms.

Antibodies raised in rabbits to detergent-solubilized pig kidney microvillar proteins have been used to investigate the membrane hydrolases by crossed immunoelectrophoresis. Eight enzymes were detected by specific staining methods: aminopeptidase M, dipeptidylpeptidase IV, neutral endopeptidase, aminopeptidase A, carboxypeptidase P, gamma-glutamyltransferase, trehalase and phosphodiesterase I. The mobility of all these enzymes, with the exception of trehalase and neutral endopeptidase, was increased by treatment of the detergent-solubilized preparation with papain. The difference between the detergent and proteinase forms of these enzymes is attributed to the removal of a small, non-antigenic peptide to which detergent is bound in significant quantities. This interpretation was further supported by experiments in which the microvillus fraction was labelled with an intramembrane photolabelling reagent, 1-azido-4-[125I]iodobenzene. After photolysis, the radioactivity in the membrane could be solubilized by detergent treatment but not by papain treatment. Radioautography after crossed charge-shift immunoelectrophoresis showed a good correlation between charge-shift (signifying the presence of detergent bound to a hydrophobic domain) and the presence of the label.     

Lactoperoxidase-catalyzed iodination of the receptor for immunoglobulin E at the cytoplasmic side of the plasma membrane

The structural organization of the high affinity receptor for immunoglobulin E has been investigated in plasma membrane vesicles from rat basophilic leukemia cells using lactoperoxidase-catalyzed 125I-iodination to label exposed polypeptide regions. Intact vesicles are predominantly right-side-out in orientation, and lactoperoxidase iodination of these vesicles results in labeling of the alpha subunit of receptor but not the beta and gamma subunits. Lysis of these vesicles to expose the cytoplasmic face of the membrane by two different methods permits labeling of the beta and gamma subunits with no increase in labeling of alpha. The results indicate that both the beta and gamma subunits of the receptor have segments exposed at the cytoplasmic side of the plasma membrane. These studies have also revealed a previously unidentified IgE binding component in the membrane vesicles; its 125I-labeling characteristics and some other properties are described.     

Immunogold labelling is a quantitative method as demonstrated by studies on aminopeptidase N in microvillar membrane vesicles

Summary Microvillar membrane vesicle preparations with varying content of aminopeptidase N were prepared from enterocytes of the pig small intestine. Postembedding immunogold labelling of aminopeptidase N was performed on these glutaraldehyde/paraformaldehyde-fixed, osmium tetroxide-treated and Epon-embedded microvillar membrane vesicles. The number of gold particles per micrometre microvillar membrane (labelling intensity) was calculated and compared to the corresponding enzymatic activity. A very close relationship was found between labelling intensity and aminopeptidase N activity, demonstrating that postembedding immunogold labelling can be used quantitatively.     

Phosphorylation and dephosphorylation of membrane proteins as a possible mechanism for structural rearrangement of membrane components.

A correlation was found between dephosphorylation of chicken erythrocyte membrane proteins, aggregation of intramembrane particles, increase in the lipid bilayer phase of the membrane and exposure of membrane phospholipids toward phospholipase A and trinitrobenzene sulfonic acid. Most of the covalently bound phosphate of the membrane proteins turns over and is associated with 5 major bands. It is suggested that phosphorylation and dephosphorylation of these proteins causes changes in their charge and conformation. Such changes might affect the interaction of these proteins with the neighbouring lipids or lipoprotein complexes and results in the aggregation of intramembrane particles and relative increase in the exposed free lipid bilayer phase of the membrane.     

Isolation and chemical composition of the cytoplasmic membrane of the archaebacterium Methanospirillum hungatei

The cytoplasmic membrane of Methanospirillum hungatei was isolated from osmotic lysates of spheroplasts, with yields of 7-8% of the cell dry weight. Cytoplasmic contamination was negligible, as judged by the removal of soluble enzymes. The cytoplasmic membrane consists of lipid (35-37%), primarily as a biphytanyldiglycerol tetraether glycolipid; protein (45-50%); and carbohydrate (10-12%). Ultra-thin sections showed that the trilaminar membrane formed vesicles with a maximum diameter of 0.4 microns. Protrusions of membrane projecting from the vesicles were seen often in negatively stained preparations. Fractionation of M. hungatei cells grown in the presence of [14C]mevalonic acid revealed that 90% of the phytanyl lipids were present in the cytoplasmic membrane band, with two minor bands accounting for the remainder of the label. Approximately 50% of the galactose, glucose, and mannose present in the cytoplasmic membrane was found in lipid extracts, while the remainder of these sugars and 98% of the rhamnose were present as nonlipid sugars. The cell sheath, isolated with a yield of 13% of the cell dry weight, contained the same sugars as the cytoplasmic membrane, but in very different proportions. Amino acid analysis of the membrane proteins showed that hydrophobic amino acid residues made up 37% of the total, neutral amino acids, 39%, basic, 8%, acidic, 16%, and that half-cysteine was present. Sodium dodecyl sulfate-polyacrylamide gel patterns of solubilized cytoplasmic membrane proteins revealed major bands at 195, 74.5, 44, 32, and 30 KDa. Significant amounts of nickel co-isolated with the cytoplasmic membrane, accounting for 0.16% of the membrane dry weight.     

The organization of formate dehydrogenase in the cytoplasmic membrane of Escherichia coli.

The arrangement of the proton-translocating formate dehydrogenase of the anaerobic respiratory chain of Escherichia coli within the cytoplasmic membrane was examined by direct covalent modification with non-membrane-permeant reagents. Three methods were employed, lactoperoxidase-catalysed radioiodination, labelling with diazotized [125I] di-iodosulphanilic acid and labelling with diazobenzene [35S] sulphonate. All three procedures yield consistent with the view that the two larger subunits of the enzyme, Mr 110000 and 32000, both occupy transmembranous locations within the membrane. In each case the modification of the Ca2+ or Mg2+-activated F1-ATPase was monitored, and all reagents employed correctly located this enzyme at the cytoplasmic face of the membrane. A procedure involving agglutination with specific antibodies is described which appears to fractionate membrane vesicles of mixed orientation into two populations, one with the same membrane orientation as that of spheroplasts and the other opposite orientation.     

Immunomicroscopic localization of aminopeptidase N in the pig enterocyte. Implications for the route of intracellular transport

The subcellular localization of aminopeptidase N (EC 3.4.11.2) in the pig enterocyte was investigated by immunofluorescence and immunoelectron microscopy (immunogold staining). By indirect immunofluorescence on either frozen or paraffin-embedded sections, a very intense staining in the microvillar membrane and a weak intracellular staining was demonstrated. No staining was detected in the basolateral membrane. Likewise, the immunogold labelling on Epon-embedded sections was concentrated in the microvillar membrane, whereas the basolateral membrane did not contain significant amounts of labelling. Labelling was demonstrated in the Golgi apparatus and in a minor fraction of the intracellular smooth vesicles positioned between the Golgi apparatus and the microvillar membrane. These observations are compatible with the view that newly synthesized aminopeptidase N is delivered directly to the microvillar membrane by smooth vesicles having a diameter about 70 to 100 nm and does not pass the basolateral membrane on its way to the brush border membrane.     

Characterization of thermotropic structural transitions of the erythrocyte membrane: a biochemical and electron-paramagnetic resonance approach

The relationship between membrane structural properties and functions has been generally inferred from observed thermotropic phenomena. By the use of 16-dinyloxyl stearic acid spin probe we investigated the red blood cell membrane components involved in three characteristic thermotropic structural transitions occurring at 8, 20, and 40 degrees C. The transition at 8 degrees C is removed by chymotrypsin treatment at the cytoplasmic membrane layer. The 20 degrees C phase transition is unmodified after chymotrypsin treatment and occurs at 15 degrees C after complete proteolysis of intramembrane chymotrypsin-insensitive peptides. Liposomes from the total lipid extract of RBC show only one thermotropic transition at 15 degrees C. The 40 degrees C phase transition is absent in vesicles free of skeletal proteins, in vesicles obtained after RBC storage, and in low-ionic-strength resealed ghosts. Transitions at 8 degrees C and 40 degrees C appear to be due to the interactions of cytoplasmic exposed proteins with membrane, whereas the 20 degrees C transition is intrinsic to the lipid component.     

The surface properties of Neisseria gonorrhoeae: topographical distribution of the outer membrane protein antigens.

Gonococci were labelled with 125I using the lactoperoxidase system. The amount of label incorporated was similar with all strains including those which appeared capsulated. Electrophoresis on sodium dodecyl sulphate-polyacrylamide gels revealed that the major proteins labelled were those found in outer membrane preparations. Comparison of variants of one strain showed that the major outer membrane protein (protein I) was always present and heavily labelled. The second major protein (protein II) was present in variable amounts but labelling was proportional to the amount present. A third protein (III) was only present in outer membranes from a freshly isolated variant but was present in whole cells of each strain. Protein III was not labelled in whole cells but was labelled in outer membrane preparations suggesting that many membranes have their inner surface exposed. The labelling of a strain adapted to growth in guinea-pig chambers failed to reveal any new major surface proteins. The results demonstrate the variation in surface topography possible with variants of one strain of gonococcus but show that one major protein antigen is always expressed on the surface.     

Lactoperoxidase-catalyzed iodination of surface membrane lipids

Lactoperoxidase-catalyzed iodination of intact cells, is known to label predominantly, if not exclusively, the exposed tyrosine residues of cell surface proteins. The present study demonstrates that during this iodination process surface membrane lipids are also iodinated through an enzyme-dependent step. Phosphatidylcholine, cholesterol-phosphatidylcholine liposomes and confluent secondary cultures of chick embryo cells were iodinated by the lactoperoxidase-glucose oxidase-glucose [¹²⁵I] procedure. Liposomes were efficiently labeled. In the cells, 20–30% of the radioactivity was found in proteins and 20–30% in the lipids. Both neutral and polar lipids were found to bind [¹²⁵I] covalently. Controls in which lactoperoxidase was omitted showed < 6% of the radioactivity found in liposomes or cells labeled with the enzyme.     

Biogenesis of endoplasmic reticulum membrane in rat liver cells. II. Discharge of the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 on the cytoplasmic side of the endoplasmic reticulum membrane.

The direction of discharge of the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 from bound polyribosomes of rough microsomes was investigated in order to elucidate the mechanism of separation of these membrane proteins from secretory proteins, which are also synthesized by the same class of ribosomes of rough endoplasmic reticulum. The nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 in intact rough microsomes were accessible to externally added 125I-Fab's against these proteins, and were susceptible to trypsin digestion, whereas the nascent peptides of serum albumin were not. The nascent peptides of these two microsomal proteins were released into the cytoplasm by puromycin treatment of intact rough microsomes, while the nascent peptides of serum albumin were retained in the microsomal lumen. These observations suggest that the nascent peptides of microsomal proteins, which are present on the cytoplasmic surface of the endoplasmic reticulum membrane, are exposed on the surface of microsomal vesicles, while those of secretory proteins are enclosed inside the vesicles. Therefore, the topographical separation of microsomal membrane proteins from secretory proteins is accomplished at the step of their synthesis by the bound polyribosomes of rough endoplasmic reticulum.     

Intramembrane particle aggregation in erythrocyte ghosts. II. The influence of spectrin aggregation.

Physicochemical properties of mixtures of spectrin and actin extracted from human erythrocyte ghosts have been correlated with ultrastructural changes observed in freeze-fractured erythrocyte membranes. (1) Extracted mixtures of spectrin and actin have a very low solubility (less than 30 mug/ml) near their isoelectric point, pH 4.8. These mixtures are also precipitated by low concentrations of Ca2+, Mg2+, polylysine or basic proteins. (2) All conditions which precipitate extracts of spectrin and actin also induce aggregation of the intramembrane particles in spectrin-depleted erythrocyte ghosts. Precipitation of the residual spectrin molecules into small patches on the cytoplasmic surface of the ghost membrane is thought to be the cause of particle aggregations, implying an association between the spectrin molecules and the intramembrane particles. (3) When fresh ghosts are exposed to conditions which precipitate extracts of spectrin and actin, only limited particle aggregation occurs. Instead, the contraction of the intact spectrin meshwork induced by the precipitation conditions compresses the lipid bilayer of the membrane, causing it to bleb off particle-free, protein-free vesicles. (4) The absence of protein in these lipid vesicles implies that all the proteins of the erythrocyte membrane are immobilized by association with either the spectrin meshwork or the intramembrane particles.     

Intracellular vesicles involved in the transport of Semliki Forest virus membrane proteins to the cell surface.

The route of transport of Semliki Forest virus (SFV) membrane glycoproteins to the plasma membrane was studied using immunoperoxidase electron microscopy. SFV glycoproteins were localized in cultured BHK-21 fibroblasts infected with a temperature-sensitive mutant ts-1 of SFV, which shows a temperature-dependent, reversible defect in the transport of membrane glycoproteins to the cell surface. At 39 degrees C (restrictive temperature) the viral proteins were retained in the endoplasmic reticulum and the nuclear membrane. After shift of the infected cultures to 28 degrees C (permissive temperature) the proteins were synchronously transported to the Golgi complex. In the Golgi complex the labeled proteins were first (at 2.5 min) detected in large Golgi-associated vacuoles (GAV). Subsequently, i.e., at 5-30 min, the viral glycoproteins appeared in the cisternal stack: at 5 min the label was found in one or two of the proximal cisternae whereas at 15 or 30 min also the more distal cisternae were partially or uniformly labeled. At all time points examined after the temperature-shift, peroxidase label was found in 50 nm vesicles which were frequently coated. At 30 min, in addition to the 50 nm vesicles, larger 80 nm vesicles, which often had a cytoplasmic coat were labeled in the Golgi region. These results identify two major size classes of both coated and smooth vesicles which appear to function in the transport of the viral membrane proteins from the endoplasmic reticulum via distinct GAV and the stacked Golgi cisternae to the plasma membrane.     

Regulation of the glucose phosphotransferase system in Brochothrix thermosphacta by membrane energization.

Uptake of 2-deoxyglucose, alpha-methylglucopyranoside, and glucose into intact cells of Brochothrix thermosphacta (formerly Microbacterium thermosphactum, ATCC 11509) was stimulated by KCN or CCCP. The glucose analogs were recovered almost totally as the sugar phosphates. Membrane vesicles were isolated from protoplasts and shown to be right side out by freeze fracturing and by using ATPase as a marker for the cytoplasmic membrane surface. Uptake of glucose into vesicles was dependent on the presence of phosphoenolpyruvate. NADH oxidation, K+ -diffusion gradients, and externally directed lactate gradients (pH greater than 7 initially) were used to generate transmembrane potentials across membrane vesicles. Above a threshold value of about -50 mV, uptake of glucose into membrane vesicles was reduced. Likewise, the maximum uptake of glucose and its two analogs into cells occurred when the protonmotive force was less than about -50 mV.     

Evidence that the hydrophobic domain of rat renal γ-glutamyltransferase spans the brush border membrane

Lactoperoxidase and glucose oxidase catalyzed ¹²⁵I-iodination was used to specifically label isolated rat renal brush border membrane vesicles from either side of the membrane. Autoradiography of total membrane proteins demonstrated that asymmetric labeling was achieved. Specific immunoprecipitates of aminopeptidase M, an established transmembrane protein, and of γ-glutamyltransferase were isolated from vesicles solubilized with Triton X-100 or with papain. Following electrophoresis and autoradiography, the immunoprecipitates of the two solubilized forms of each enzyme derived from externally labeled vesicles exhibited the same intensity of labeling. In these experiments, the small subunit of the γ-glutamyltransferase was preferentially labeled suggesting that, compared to the large subunit, it is more exposed on the external surface of the membrane. With the samples derived from internally labeled vesicles, the Triton-solubilized form of each enzyme was intensely labeled, whereas the papain-solubilized forms contained insignificant amounts of radioactivity. Thus, the extent of contramembrane labeling was minimal. In these experiments, the large subunit of the γ-glutamyltransferase was preferentially labeled. The similarity of the labeling patterns obtained for aminopeptidase M and γ-glutamyltransferase suggests that the hydrophobic domain of the two amphipathic enzymes are selectively labeled from the internal surface and that the γ-glutamyltransferase may also be a transmembrane protein.     

Asymmetric distribution of nitrate reductase subunits in the cytoplasmic membrane of Escherichia coli: evidence derived from surface labeling studies with transglutaminase.

The enzyme transglutaminase has been used to label surface proteins of Escherichia coli cytoplasmic membranes by covalently attaching to them a small fluorescent primary amine, dansyl cadaverine. Spheroplasts lacking outer membrane, osmotically lysed vesicles from the spheroplasts, and vesicles made by breaking cells in a French pressure cell were each labeled with transglutaminase and dansyl cadaverine. When the total cytoplasmic membrane proteins of each were examined on sodium dodecyl sulfate gels, three rather different labeling patterns were obtained. Labeling of the respiratory enzyme, nitrate reductase, in the membranes of each of these preparations was also examined. Membrane-bound nitrate reductase contains three subunits: A, B, and C. Dansyl cadaverine labeling of nitrate reductase in the presence of Triton X-100 indicated that subunits A and C could be labeled. When nitrate reductase was isolated from dansyl cadaverine-labeled spheroplasts, none of the subunits was labeled. When nitrate reductase was isolated from French press vesicles, subunit A was labeled and labeling was enhanced by the presence of nitrate during labeling. When nitrate reductase from osmotic vesicles was examined, subunit A was labeled in the presence of nitrate but no labeled subunits appeared when the vesicles were labeled in the absence of nitrate. It was concluded that (i) nitrate reductase is buried in the membrane with subunit A exposed only on the inner surface of the membrane, (ii) subunit C is sufficiently buried within the membrane so that it is inaccessible to transglutaminase, (iii) subunit B is not labeled under any condition, so its location is not known, and (iv) large osmotic vesicles are probably mosaics in which some protein components have been reoriented.     

Ultrastructural organization of cytoplasmatic membrane of Anaerobacter polyendosporus studied by electron microscopic cryofractography]

Anaerobacter polyendosporus cells do not have typical mesosomes. However, the analysis of this anaerobic multispore bacterium by electron microscopic cryofractography showed that its cytoplasmic membrane contains specific intramembrane structures in the form of flat lamellar inverted lipid membranes tenths of nanometers to several microns in size. It was found that these structures are located in the hydrophobic interior between the outer and inner leaflets of the cytoplasmic membrane and do not contain intramembrane particles that are commonly present on freeze-fracture replicas. The flat inverted lipid membranes were revealed in bacterial cells cultivated under normal growth conditions, indicating the existence of a complex-type compartmentalization in biological membranes, which manifests itself in the formation of intramembrane compartments having the appearance of vesicles and inverted lipid membranes.     

The organization of NADH dehydrogenase polypeptides in the inner mitochondrial membrane.

The organization of the constituent polypeptides of mitochondrial NADH dehydrogenase was studied by using two membrane-impermeable probes, diazobenzene[35S]sulphonate and lactoperoxidase-catalysed radioiodination. The incorporation of label into the subunits of the isolated enzyme was compared with that obtained with enzyme immunoprecipitated from labelled mitochondria or inverted submitochondrial particles. On the basis of accessibility to these two labels, we divide the polypeptides of Complex I into five groups: those that are apparently buried in the enzyme, those that are accessible to labelling in the isolated enzyme but not in the membrane, those that are exposed on the cytoplasmic face of the membrane, those that are exposed on the matrix face and finally those that are exposed on both faces and are therefore transmembranous. We conclude that NADH dehydrogenase is asymmetrically organized across the inner mitochondrial membrane.     

Appearance and distribution of surface proteins of the human erythrocyte membrane. An electron microscope and immunochemical labeling study

We have used freeze-etching, before and after immunoferritin labeling, to visualize spectrin molecules and other surface proteins of the human erythrocyte membrane. After intramembrane particle aggregation was induced, spectrin molecules, identified by labeling with ferritin-conjugated antispectrin, were clustered on the cytoplasmic surface of the membrane in patches directly underlying the particle clusters. This labeling pattern confirms the involvement of spectrin in such particle aggregates, as previously inferred from indirect evidence. Ferritin-conjugated antihapten molecules, directed against external and cytoplasmic surface proteins of the erythrocyte membrane which had been covalently labeled nonspecifically with the hapten p-diazoniumphenyl-beta-D-lactoside, were similarly found in direct association with such intramembrane particle aggregates. This indicates that when spectrin and the intramembrane particles are aggregated, all the major proteins of the erythrocyte membrane are constrained to coaggregate with them. Although giving no direct information concerning the freedom of translational movement of proteins in the unperturbed erythrocyte membrane, these experiments suggest that a close dynamic association may exist between the integral and peripheral protein components of the membrane, such that immobilization of one component can restrict the lateral mobility of others.