Outer Membrane Proteins of Escherichia coli IV. Differences in Outer Membrane Proteins Due To Strain and Cultural Differences

When the 42,000-dalton major outer membrane protein of Escherichia coli O111 is examined on alkaline polyacrylamide gels containing sodium dodecyl sulfate, it is resolved into three distinct bands designated as proteins 1, 2, and 3. Band 3 consists of two distinct polypeptides, proteins 3a and 3b. E. coli K-12 does not make any protein 2, but makes proteins similar to 1, 3a, and 3b as indicated by comparison of cyanogen bromide peptide patterns. Several Shigella species and most other strains of E. coli resemble E. coli K-12 in that they lack protein 2, whereas Salmonella typhimurium is more similar to E. coli O111. In addition to these species and strain differences, cultural differences resulted in differences in the outer membrane protein profiles. Under conditions of catabolite repression, the level of protein 2 in E. coli O111 decreased while the level of protein 1 increased. An enterotoxin-producing strain similar to E. coli O111 produced no protein 1 and an elevated level of protein 2 under conditions of low catabolite repression. The levels of proteins 1 and 3 are also different in different phases of the growth curve, with protein 1 being the major species in the exponential-phase cells and protein 3 being the major species in stationary-phase cells. A multiply phage-resistant mutant of E. coli K-12 with no obvious cell wall defects produced no protein 1 or 2, but made increased amounts of protein 3. Thus, the major outer membrane proteins of E. coli and related species may vary considerably without affecting outer membrane integrity.     

Outer membrane proteins of Escherichia coli. I. Effect of preparative conditions on the migration of protein in polyacrylamide gels

Outer membrane protein of Escherichia coli prepared for polyacrylamide gel electrophoresis by solubilization of the membrane in an organic solvent followed by dialysis into sodium dodecyl sulfate (SDS) solution or by solublization of the membrane directly in SDS solution followed by dialysis into a SDS-urea solution and brief heating at 100 °C resulted in a simple polypeptide profile on SDS-containing gels. This polypeptide pattern was characterized by a single major protein band migrating with an apparent molecular weight of about 42,000 daltons which accounted for about 70% of the total protein on the gel. However, if the outer membrane protein is dissolved in SDS solution without urea and heated at 70 °C, major bands are observed in three regions of the gel: A broad band or group of bands near the top of the gel with an apparent molecular weight of much greater than 42,000 daltona (peak A), a second band with the same mobility as the 42,000-dalton band in boiled samples (peak B), and a third, faster-migrating band with an apparent molecular weight of less than 42,000 daltons (peak C).Elution of protein from A or C followed by heating at 100 °C converts this protein to a form migrating with peak B. If the outer-membrane protein is dissolved in SDS solution at 37 °C with no further heating and applied to gels, peak B dissappears completely and A and C increase. These can be partially converted to peak B by urea treatment. Protein from peaks A and C was isolated by chromatography on Sephadex in the presence of SDS, and the intrinsic viscosity of this protein was measured before and after boiling. The intrinsic viscosity of protein from peak A was 35 cc/g both before and after boiling, while the intrinsic viscosity of protein from peak C was 28 cc/g before boiling and 35 cc/g after boiling. These results are best explained by assuming that the protein in peak A represents aggregates of a 42,000-dalton species which are dissociated by boiling or solvent treatment and that the protein in peak C represents a monomeric form of the 42,000-dalton protein which is not fully reacted with SDS and which is converted to the “rigid rod” conformation characteristic of protein-SDS complexes only upon boiling or solvent treatment.     

Outer membrane proteins of Escherichia coli. II. Heterogeneity of major outer membrane polypeptides

When E. coli outer membrane protein is dissolved in sodium dodecyl sulfate (SDS) solution and boiled briefly, a single major peak (peak B) with a molecular weight of 42,000 daltons is observed on SDS-containing polyacrylamide gels. If the protein is dissolved in SDS solution at 37 °C and applied to gels without further treatment, peak B disappears and two other major peaks appear: Peak A, which is composed of aggregates and migrates more slowly than peak B, and peak C which is composed of monomeric protein not fully reacted with SDS and which migrates faster than peak B. When cyanogen bromide peptides of protein from peak A and peak C were compared, it was evident that peak A and peak C contained entirely different polypeptides. This was further confirmed by differential labeling studies with methionine and leucine. The cyanogen bromide peptide profiles of protein from peak A suggested that this peak was composed of two polypeptides, and this was confirmed by electrophoresis in an alkaline gel system which resolves peak B into three subcomponents. Two of these were derived from peak A and the third was derived from peak C. These results indicate that the outer membrane of E. coli contains at least three nonidentical major polypeptides, each of which has a nearly identical molecular weight of about 42,000 daltons. These polypeptides are present in identical proportions in the soluble and insoluble fractions obtained when the outer membrane is treated with Triton X-100 plus EDTA.     

Nearest-Neighbor Analysis of Escherichia coli Outer Membrane Proteins, Using Cleavable Cross-Links

A specific dimer of the 37,000-dalton, major outer membrane protein was demonstrated by chemical cross-linking with cleavable reagents.     

Outer Membrane Proteins of Escherichia coli VII. Evidence That Bacteriophage-Directed Protein 2 Functions as a Pore

Protein 1, a major protein of the outer membrane of Escherichia coli, has been shown to be the pore allowing the passage of small hydrophilic solutes across the outer membrane. In E. coli K-12 protein 1 consists of two subspecies, 1a and 1b, whereas in E. coli B it consists of a single species which has an electrophoretic mobility similar to that of 1a. K-12 strains mutant at the ompB locus lack both proteins 1a and 1b and exhibit multiple transport defects, resistance to toxic metal ions, and tolerance to a number of colicins. Mutation at the tolF locus results in the loss of 1a, in less severe transport defects, and more limited colicin tolerance. Mutation at the par locus causes the loss of protein 1b, but no transport defects or colicin tolerance. Lysogeny of E. coli by phage PA-2 results in the production of a new major protein, protein 2. Lysogeny of K-12 ompB mutants resulted in dramatic reversal of the transport defects and restoration of the sensitivity to colicins E2 and E3 but not to other colicins. This was shown to be due to the production of protein 2, since lysogeny by phage mutants lacking the ability to elicit protein 2 production did not show this effect. Thus, protein 2 can function as an effective pore. ompB mutations in E. coli B also resulted in loss of protein 1 and similar multiple transport defects, but these were only partially reversed by phage lysogeny and the resulting production of protein 2. When the ompB region from E. coli B was moved by transduction into an E. coli K-12 background, only small amounts of proteins 1a and 1b were found in the outer membrane. These results indicate that genes governing the synthesis of outer membrane proteins may not function interchangeably between K-12 and B strains, indicating differences in regulation or biosynthesis of these proteins between these strains.     

Alterations in the Outer Membrane of the Cell Envelope of Heptose-Deficient Mutants of Escherichia coli

The composition of the cell envelope of a heptose-deficient lipopolysaccharide mutant of Escherichia coli, GR467, was studied after fractionation into its outer and cytoplasmic membrane components by means of sucrose density gradient centrifugation. The outer membrane of GR467 had a lower density than that of its parent strain, CR34. Analysis of the fractionated membranes of GR467 indicated that the phospholipid-to-protein ratio had increased 2.4-fold in the outer membrane. The ratio in the mutant cytoplasmic membrane was also increased, although to a lesser extent. By employing a third parameter, the lipid A content of the outer membrane, it was found that the observed phospholipid-to-protein change in the outer membrane was due predominantly to a decrease in the relative amount of protein. This decrease in protein was particularly significant, since it was concomitant with a 68% decrease in the lipid A recovered in the outer membrane of GR467 relative to the lipid A recovered in the outer membrane of CR34. Similar findings were observed in a second heptose-deficient mutant of E. coli, RC-59. The apparent protein deficiency in GR467 was further studied by subjecting solubilized envelope proteins to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It was found that major envelope proteins which were localized in the outer membrane were greatly diminished in GR467. Two revertants of GR467 with the wild-type amounts of heptose had wild-type relative levels of protein in their outer membranes. A partial heptose revertant had a relative level of protein in its outer membrane between those of the mutant and wild type.     

Temperate Bacteriophage Which Causes the Production of a New Major Outer Membrane Protein by Escherichia coli

Under most conditions of growth, the most abundant protein in the outer membrane of most strains of Escherichia coli is a protein designated as “protein 1” or “matrix protein”. In E. coli B, this protein has been shown to be a single polypeptide with a molecular mass of 36,500 and it may account for more than 50% of the total outer membrane protein. E. coli K-12 contains a very similar, although probably not identical, species of protein 1. Some pathogenic E. coli strains contain very little protein 1 and, in its place, make a protein designated as protein 2 which migrates faster on alkaline polyacrylamide gels containing sodium dodecyl sulfate and which gives a different spectrum of CNBr peptides. An E. coli K-12 strain which had been mated with a pathogenic strain was found to produce protein 2, and a temperate bacteriophage was isolated from this K-12 strain after induction with UV light. This phage, designated as PA-2, is similar in morphology and several other properties to phage lambda. When strains of E. coli K-12 are lysogenized by phage PA-2, they produce protein 2 and very little protein 1. Adsorption to lysogenic strains grown under conditions where they produce little protein 1 and primarily protein 2 is greatly reduced as compared to non-lysogenic strains which produce only protein 1. However, when cultures are grown under conditions of catabolite repression, protein 2 is reduced and protein 1 is increased, and lysogenic and non-lysogenic cultures grown under these conditions exhibit the same rate of adsorption. Phage PA-2 does not adsorb to E. coli B, which appears to have a slightly different protein 1 from K-12. These results suggest that protein 1 is the receptor for PA-2, and that protein 2 is made to reduce the superinfection of lysogens.     

Strain-specific variation in the protein and lipopolysaccharide composition of the group B meningococcal outer membrane.

Variation in the protein and lipopolysaccharide composition of the meningococcal outer membrane may be due to either serotype differences or to changes in cultural conditions. There are 12 antigenically distinct serotypes of group B meningococci, and these are associated with distinct major outer membrane protein patterns on sodium dodecyl sulfate-polyacrylamide gels. In most strains the predominant outer membrane protein carries the serotype-specific determinant. Certain strains, when grown under similar conditions in different media showed an altered membrane composition. The type 2 strain, M986, grown in modified Frantz medium-A, had a reduced amount of the major 41,000-dalton protein while a 28,000-dalton protein predominated. The altered protein composition may be related to changes in cell metabolism as reflected by the pH of the medium after growth. Growth of the organism in Frantz medium-B caused a negligible drop in pH and the 41,000-dalton protein remained predominant. There was also variation associated with changes in the growth rate. Increasing the aeration caused a concomitant increase in growth rate and cell yield. We observed two quantitative changes in outer membrane proteins in four of seven strains examined: (i) where only a single major protein changed (three strains), and (ii) where an increase in one protein component was associated with a decrease in another protein (one strain). When the strains were grown in tryptic soy broth (Difco Laboratories, Detroit, Mich.) with either high or low aeration, the total protein in the outer membrane remained constant. In contrast, with high aeration there was a significant increase in lipopolysaccharide. These studies suggest that the cell surface proteins may be altered by the organism to meet a variety of environmental conditions.     

A new form of structural lipoprotein of outer membrane of Escherichia coli.

Among the membrane proteins synthesized in toluene-treated cells of Escherichia coli were two distinct membrane proteins of different molecular weights, which were cross-reactive with antiserum against a structural lipoprotein of the outer membrane. One was thought to be the known membrane lipoprotein since it migrated to the same position as that of the lipoprotein (Mr = 7,200) in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. However, the other protein migrated slower than the lipoprotein. No protein corresponding to the slower-migrating species was detected in the membrane proteins synthesized in vivo. The apparent molecular weight of the protein at the new peak was estimated to be between 10,000 and 15,000. Both the new protein and the lipoprotein were found to be synthesized from stable mRNA(s) in the toluene-treated cells. The synthesis of the new protein as well as the lipoprotein was sensitive to chloramphenicol, indicating that both proteins were synthesized on ribosomes. Peptides mapping of the new protein revealed the same COOH-terminal sequence as in the lipoprotein. This indicates that the new protein has an extra sequence at the NH2-terminal end. This hypothesis is supported by the finding that the NH2 terminus of the new lipoprotein is methionine, while that of the lipoprotein is a substituted cysteine. From double label experiments with each of 17 different amino acids and arginine, the amino acid composition of the extra region was deduced. The new protein was found to contain at least 18 to 19 extra amino acid residues over the lipoprotein, if it is assumed that the new protein has no extra arginine residues. It was found that 4 out of the 5 amino acids which were deficient in the lipoprotein (phenylalanine, tryptophan, proline, and histidine) were also deficient in the new protein, but the fifth one, glycine, was present in the new protein. From these results, it seems possible that this new form of the lipoprotine is a precursor of the lipoprotein (prolipoprotein) in the process of biosynthesis and assembly of the lipoprotein in the outer membrane.     

Membrane proteins of Escherichia coli K-12: two-dimensional polyacrylamide gel electrophoresis of inner and outer membranes.

Protein compositions of the inner and outer membranes of Escherichia coli K-12 have been analyzed by two-dimensional gel electrophoresis in which proteins are separated according to apparent isoelectric point (first dimension) and to apparent molecular weight (second dimension). Membrane proteins except for a pair of major outer membrane proteins (proteins Ia and Ib) were found to be solubilized effectively by lysis buffer containing urea, Triton X-100, ampholines and 2-mercaptoethanol. The latter two proteins could be solubilized after precipitation of membrane fraction with trichloroacetic acid; they formed a pair of spots at an acidic region on the electropherogram. Another major protein of the outer membrane, protein II, was also identified. Most of the inner and outer membrane proteins were shown to be focused at a pH range between 4 and 6.5. Specific protein patterns characteristic for both the inner and outer membranes could thous be visualized by the present system. At least 120 and 50 protein species were detected for the inner and outer membranes, respectively.     

Architecture of the Outer Membrane of Escherichia coli III. Protein-Lipopolysaccharide Complexes in Intramembraneous Particles

In a previous paper (A. Verkleij, L. van Alphen, J. Bijvelt, and B. Lugtenberg, Biochim. Biophys. Acta 466:269-282, 1977) we have hypothesized that particles on the outer fracture face of the outer membrane ([Formula: see text]), with corresponding pits on the inner fracture face of the outer membrane ([Formula: see text]), consist of lipopolysaccharide (LPS) aggregates stabilized by divalent cations and that they might contain protein and/or phospholipid. In the present paper the roles of LPS, cations, and proteins in these [Formula: see text] particles are described more extensively, using a strain that lacks the major outer membrane proteins, b, c, and d (b(-) c(-) d(-)), and has a reduction in the number of [Formula: see text] particles of 75%. To study the role of divalent cations in the formation of [Formula: see text] particles, these b(-) c(-) d(-) cells were grown or incubated with Ca(2+), Mg(2+), or putrescine. The presence of Ca(2+) resulted in the appearance of many [Formula: see text] particles and [Formula: see text] pits. Mg(2+) and putrescine were less effective than Ca(2+). Introduction of these particles was not accompanied by alterations in the relative amounts of LPS and cell envelope proteins. Ca(2+) treatment of a heptoseless derivative of a b(-) c(-) d(-) strain did not result in morphological changes. Incubation of Ca(2+)-treated cells with ethylenediaminetetraacetate caused the disappearance of the introduced particles as well as the release of more than 60% of the cellular LPS. These results strongly support the hypothesis that LPS is involved in the formation of [Formula: see text] particles and [Formula: see text] pits. The roles of various outer membrane proteins in the formation of [Formula: see text] particles were studied by comparing the freeze-fracture morphology of b(-) c(-) d(-) cells with that of cells which contain one of the outer membrane proteins b, c, d, and e or the receptor protein for bacteriophage lambda. The results showed that the presence of any of these five proteins in a b(-) c(-) d(-) background resulted in a large increase in the number of [Formula: see text] particles and [Formula: see text] pits, indicating that these proteins are, independent of each other, involved in the formation of [Formula: see text] particles and [Formula: see text] pits. The simplest explanation for the results is that in wild-type cells each particle consists of LPS complexed with some molecules of a single protein species, stabilized by either divalent cations or polyamines. It is hypothesized that the outer membrane of the wild-type cell contains a heterogeneous population of particles, of which 75% consists of protein b-LPS, protein c-LPS, and protein d-LPS particles. A function of these particles as aqueous pores is proposed.     

Organization of K88ac-encoded polypeptides in the Escherichia coli cell envelope: use of minicells and outer membrane protein mutants for studying assembly of pili

Escherichia coli K-12 minicells, harboring recombinant plasmids encoding polypeptides involved in the expression of K88ac adhesion pili on the bacterial cell surface, were labeled with [35S]methionine and fractionated by a variety of techniques. A 70,000-dalton polypeptide, the product of the K88ac adhesion cistron adhA, was primarily located in the outer membrane of minicells, although it was less clearly associated with this membrane than the classical outer membrane proteins OmpA and matrix protein. Two polypeptides of molecular weights 26,000 and 17,000 (the products of adhB and adhC, respectively) were located in significant amounts in the periplasmic space. The 29,000-dalton polypeptide was shown to be processed in E. coli minicells. The 23.500-dalton K88ac pilus subunit (the product of adhD) was detected in both inner and outer membrane fractions. E. coli mutants defective in the synthesis of murein lipoprotein or the major outer membrane polypeptide OmpA were found to express normal amounts of K88ac antigen on the cell surface, whereas expression of the K88ac antigen was greatly reduced in perA mutants. The possible functions of the adh cistron products are discussed.     

Pal Lipoprotein of Escherichia coli Plays a Major Role in Outer Membrane Integrity

The Tol-Pal system of gram-negative bacteria is composed of five proteins. TolA, TolQ, and TolR are inner membrane proteins, TolB is a periplasmic protein, and Pal, the peptidoglycan-associated lipoprotein, is anchored to the outer membrane. In this study, the roles of Pal and major lipoprotein Lpp were compared in Escherichia coli. lpp and tol-pal mutations have previously been found to perturb the outer membrane permeability barrier and to cause the release of periplasmic proteins and the formation of outer membrane vesicles. In this study, we showed that the overproduction of Pal is able to restore the outer membrane integrity of an lpp strain but that overproduced Lpp has no effect in a pal strain. Together with the previously reported observation that overproduced TolA complements an lpp but not a pal strain, these results indicate that the cell envelope integrity is efficiently stabilized by an epistatic Tol-Pal system linking inner and outer membranes. The density of Pal was measured and found to be lower than that of Lpp. However, Pal was present in larger amounts compared to TolA and TolR proteins. The oligomeric state of Pal was determined and a new interaction between Pal and Lpp was demonstrated.     

Transport of hemolysin by Escherichia coli

The hemolytic phenotype in Escherichia coli is determined by four genes. Two (hlyC and hlyA) determine the synthesis of a hemolytically active protein which is transported across the cytoplasmic membrane. The other two genes (hlyBa and hlyBb) encode two proteins which are located in the outer membrane and seem to form a specific transport system for hemolysin across the outer membrane. The primary product of gene hlyA is a protein (protein A) of 106,000 daltons which is nonhemolytic and which is not transported. No signal peptide can be recognized at its N-terminus. In the presence of the hlyC gene product (protein C), the 106,000-dalton protein is processed to the major proteolytic product of 58,000 daltons, which is hemolytically active and is transported across the cytoplasmic membrane. Several other proteolytic fragments of the 106,000-dalton protein are also generated. During the transport of the 58,000-dalton fragment (and possible other proteolytic fragments of hlyA gene product), the C protein remains in the cytoplasm. In the absence of hlyBa and hlyBb the entire hemolytic activity (mainly associated with the 58,000-dalton protein) is located in the periplasm: Studies on the location of hemolysin in hlyBa and hlyBb mutants suggest that the gene product of hlyBa (protein Ba) binds hemolysin and leads it through the outer membrane whereas the gene product of hlyBb (protein Bb) releases hemolysin from the outer membrane. This transport system is specific for E coli hemolysin. Other periplasmic enzymes of E coli and heterologous hemolysin (cereolysin) are not transported.     

Outer membrane of Escherichia coli: properties of the F sex factor traT protein which is involved in surface exclusion.

The traT protein (TraTp) of the F sex factor is the product of one of the two genes involved in surface exclusion. Several detergents were examined under different conditions in order to determine their ability to solubilize TraTp from membrane vesicles. These experiments showed that TraTp behaved similar to a number of peptidoglycan-associated outer membrane proteins and that it existed in multimeric aggregates within the membrane. However, unlike other major outer membrane proteins, the amount of TraTp incorporated into the membrane was not affected by lipopolysaccharide-deficient mutants, even when mutants totally lacking the neutral sugars in their lipopolysaccharide backbone were used. TraTp wqs also examined by two-dimensional gel electrophoresis, where it ran as a discrete spot with a very basic isoelectric point. By coupling cyanogen bromide-activated dextran onto whole cells and by labeling whole cells with 125I (via lactoperoxidase), it was shown that TraTp was exposed on the cell surface. TraTp in a membrane environment was also insensitive to proteolytic attack by trypsin.     

Protein Composition of the Outer Membrane of Salmonella typhimurium: Effect of Lipopolysaccharide Mutations

The protein composition of the outer membrane of Salmonella typhimurium has been analyzed by electrophoresis on slabs of sodium dodecyl sulfate-acrylamide gel. This powerful technique allows very high resolution of protein mixtures and has permitted the identification of multiple major protein components of the outer membrane; no evidence for a single major component of molecular weight 44,000 was obtained. These proteins were shown to be decreased in amount in mutants which have defective lipopolysaccharides. Mutants of an apparently new type were also found which contain decreased amounts of the proteins and the parent-like lipopolysaccharide, yet are resistant to a lipopolysaccharide-specific phage, C21. Several outer membrane proteins are insoluble in sodium dodecyl sulfate unless heated at high temperature (above 70 C). A purification procedure based on this property is tentatively suggested.     

Localization of proteolytic activity in the outer membrane of Escherichia coli.

An enzyme in the cytoplasmic membrane, nitrate reductase, can be solubilized by heating membranes to 60 degrees C for 10 min at alkaline pH. A protease in the cell envelope has been shown to be responsible for this solubilization. The localization of this protease in the outer membrane was demonstrated by separating the outer membrane from the cytoplasmic membrane, adding back various forms of outer membrane protein to the cytoplasmic membrane, and following the increase in nitrate reductase solubilization with increasing amounts of outer membrane proteins. This solubilization is accompanied by the cleavage of one of the subunits of nitrate reductase and is inhibited by the protease inhibitor p-aminobenzamidine. Analysis of membrane proteins synthesized by cells grown in the presence of various amounts of p-aminobenzamidine revealed that p-aminobenzamidine affects the synthesis of the major outer membrane proteins but has little effect on the synthesis of cytoplasmic membrane proteins. When outer membrane is reacted with the protease inhibitor [3H]diisopropylfluorophosphate, a single protein in the outer membrane is labeled. Since the interaction with diisopropylfluorophosphate is inhibited by p-aminobenzamidine, it is suggested that this single outer membrane protein is responsible for the in vitro solubilization of nitrate reductase and the in vivo processing of the major outer membrane proteins.     

Characterization of Serologically Dominant Outer Membrane Proteins of Neisseria gonorrhoeae

The proteins of the outer membrane of Neisseria gonorrhoeae play an important role in the serotyping system defined by K. H. Johnston et al. (J. Exp. Med. 143:741–758, 1976). This study attempted to delineate the molecular arrangement of the major proteins of the outer membrane of the gonococcus by using three approaches. First, natural protein-protein relationships were demonstrated by symmetrical, two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Second, proteins exposed on the surface of outer membrane vesicles were cross-linked by using the bifunctional reagents dimethyl-3,3′-dithiobispropionimidate and dithiobis[succinimidyl propionate]. Third, specific antigen-antibody interactions on the surface of membrane vesicles were analyzed by radioautographic techniques. The major proteins of the outer membrane of the gonococcus were defined, and a nomenclature was devised to take into account the effects of heat and reducing agents on the resolution of these proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Results of cross-linking experiments strongly suggest that two of the major proteins of the gonococcal outer membrane (proteins 1 and 3) form a hydrophobically associated trimeric unit in situ which can be stabilized by selective cross-linking reagents. Results substantiated that these proteins are responsible for imparting serotypic specificity.     

Isolation and Characterization of Outer and Cytoplasmic Membranes from Spheroplasts of Acetobacter aceti

The spheroplast membrane of Acetobacter aceti IFO 3284 was separated into outer and cytoplasmic membranes by alkaline sucrose density gradient centrifugation after treatment of the cells with lysozyme in sucrose-EDTA, pH 8.0. The cytoplasmic membrane, which was transparent and red colored, showed a specific gravity of 1.15 g/ml, and a number of protein components. High contents of heme b and heme c, and high enzyme activities of various membrane-bound primary dehydrogenases, which are characteristics of acetic acid bacteria, were found in the cytoplasmic membrane fraction. On the other hand, the outer membrane, which was white and turbid when homogenized, exhibited a high content of 2-keto-3-deoxyoctonate, and only four major polypeptides were observed on SDS-polyacrylamide gel electrophoresis. The outer membrane showed a specific gravity of 1.25 g/ml due to its high lipopolysaccharide content. A predominant species of the outer membrane proteins, tentatively designated as AI, was found to be heat-modifiable in SDS solution. The Al peptide on SDS-polyacrylamide gel showed varied migration, from a position corresponding to 31,000 daltons to one of 37,000 daltons, when heated at over 60°C and then subjected to gel electrophoresis.