A major outer membrane protein (O-8) of Escherichia coli K-12 exists as a trimer in sodium dodecyl sulfate solution

Polar flagella rotation in Vibrio parahaemolyticus confers resistance to bacteriophage infection

Bacteriophage has been recognized as a novel approach to treat bacterial infectious diseases. However, phage resistance may reduce the efficacy of phage therapy. Here, we described a mechanism of bacterial resistance to phage infections. In Gram-negative enteric pathogen Vibrio parahaemolyticus, we found that polar flagella can reduce the phage infectivity. Deletion of polar flagella, but not the lateral flagella, can dramatically promote the adsorption of phage to the bacteria and enhances the phage infectivity to V. parahaemolyticus, indicating that polar flagella play an inhibitory role in the phage infection. Notably, it is the rotation, not the physical presence, of polar flagella that inhibits the phage infection of V. parahaemolyticus. Strikingly, phage dramatically reduces the virulence of V. parahaemolyticus only when polar flagella were absent both in vitro and in vivo. These results indicated that polar flagella rotation is a previously unidentified mechanism that confers bacteriophage resistance.

Characterization of the refolding and reassembly of an integral membrane protein OmpF porin by low-angle laser light scattering photometry coupled with high-performance gel chromatography

The refolding and reassembly of an integral membrane protein OmpF porin denatured in sodium dodecylsulfate (SDS) into its stable species by the addition of n-octyl-beta-D-glucopyranoside (OG) have been studied by means of circular dichroism (CD) spectroscopy and low-angle laser light scattering photometry coupled with high-performance gel chromatography. The minimal concentration where change in the secondary structure was induced by the addition of OG was found to be 6.0 mg/ml in CD experiments. A species unfolded further than the SDS-denatured form of this protein was observed at an early stage (5-15 min) of refolding just above the minimal OG concentration. In addition, the CD spectrum of protein species obtained above the minimal OG concentration showed that the protein is composed of a beta-structure which is different from the native structure of this protein. In light scattering experiments, no changes in molecular assemblies were observed when the OG concentration was below its minimal refolding concentration determined by CD measurements. Above the minimal concentration, a compact monomeric species was observed when denatured OmpF porin was incubated for 5 min at 25 degrees C in a refolding medium containing 1 mg/ml SDS and 7 mg/ml OG, and then injected into columns equilibrated with the refolding medium. After an incubation of 24 h before injection into the columns, predominant dimerization of this protein was observed in addition to incorrect aggregation.

Characterization of ompF domains involved in Escherichia coli K-12 sensitivity to colicins A and N

Various ompF-ompC, ompC-ompF, and ompF-ompC-ompF chimeric genes were used to locate the domains of the OmpF protein involved in cellular sensitivity to colicins. Various parts of the porin participate in the entry of colicins. Colicin N receptor activity was found to require three regions: RN1, located between residues 1 and 63; RN2, located between residues 115 and 262; and RN3, located between residues 279 and 297. The central domain from residues 143 to 262 is involved during the translocation step after the binding step. A large region, including residues 1 to 262, is necessary during colicin A entry. The locations and interactions between these domains specifically required for the uptake of colicins to occur are described and discussed with regard to the homology and topology of the OmpC, OmpF, and PhoE porins.

Immunological approach of assembly and topology of OmpF, an outer membrane protein of Escherichia coli

Various monoclonal antibodies (MoF) directed against cell-surface-exposed epitopes of OmpF, one major outer membrane pore protein of Escherichia coli B and K-12, have been used to study the assembly and the topology of the protein. This paper firstly describes the characterization of the OmpF epitopes recognized by the various monoclonal antibodies. A comparison between OmpC, OmpF and PhoE porins with respect to their primary amino acid sequence and their cell-surface exposed regions allows us to propose a rough model including 2 antigenic sites. The second part is focused on the assembly of the OmpF protein in the outer membrane. Various forms, precursor, unassembled monomer, metastable oligomer (pre-trimer) and trimer are detected with immunological probes directed against OmpF during a kinetic analysis of the process. The requirement for a concomitant lipid synthesis during the trimerization has been demonstrated by investigating the presence of a specific native epitope. The role of lipopolysaccharide during the stabilization of the conformation is discussed with regard to the various steps of assembly.

Effect of lipopolysaccharide structure on reactivity of antiporin monoclonal antibodies with the bacterial cell surface

We studied the reactivity of 66 anti-Escherichia coli B/r porin monoclonal antibodies (MAbs) with several E. coli and Salmonella typhimurium strains. Western immunoblots showed complete immunological cross-reactivity between E. coli B/r and K-12; among 34 MAbs which recognized porin in immunoblots of denatured outer membranes of E. coli B/r, all reacted with OmpF in denatured outer membranes of E. coli K-12. Extensive reactivity, although less than that for strain B/r (31 of 34 MAbs), occurred for porin from a wild-type isolate, E. coli O8:K27. Only one of the MAbs reacted with porin in denatured outer membranes of S. typhimurium. Even with immunochemical amplification of the Western immunoblot technique, only six MAbs recognized S. typhimurium porin (OmpD), demonstrating that there is significant immunological divergence between the porins of these species. Antibody binding to the bacterial surface, which was analyzed by cytofluorimetry, was strongly influenced by lipopolysaccharide (LPS) structure. An intact O antigen, as in E. coli O8:K27, blocked adsorption of all 20 MAbs in the test panel. rfa+ E. coli K-12, without an O antigen but with an intact LPS core, bound seven MAbs. When assayed against a series of rfa E. coli K-12 mutants, the number of MAbs that recognized porin surface epitopes increased sequentially as the LPS core became shorter. A total of 17 MAbs bound porin in a deep rough rfaD strain. Similar results were obtained with S. typhimurium. None of the anti-E. coli B/r porin MAbs adsorbed to a smooth strain, but three antibodies recognized porin on deep rough (rfaF, rfaE) mutants. These data define six distinct porin surface epitopes that are shielded by LPS from reaction with antibodies.

Lipopolysaccharide tightly bound to porin monomers and trimers from Escherichia coli K-12

Lipopolysaccharide (LPS) bound to isolated porin was detected on polyacrylamide gels by using a carbohydrate-specific silver stain and on Western blots by using anti-lipid A monoclonal antibodies. Porin was isolated from Escherichia coli JF733 (Ra chemotype) and D21f2 (Re chemotype). Isolated porin was separated from loosely associated LPS by polyacrylamide gel electrophoresis (PAGE) in sodium dodecyl sulfate (SDS). Unheated porin traveled on gels as aggregates, presumably trimers, with an apparent molecular weight of 78,000 to 83,000. After heating to 100 degrees C for 2 min in SDS, the porin traveled as a monomer with a molecular weight of 36,000. The unheated, high-molecular-weight trimer band reacted in the gel with the carbohydrate-specific silver stain, while the heated monomer band showed no staining. In contrast, lipid A-specific monoclonal antibodies showed reactivity on Western blots to the 36,000-molecular-weight band but not to the trimer. Finally, both monomer and trimer bands were isolated from gels and rerun by SDS-PAGE. LPS was released from the trimer preparation when the sample was heated, but the monomer band that was formed by heating the trimer isolate still reacted with anti-lipid A antibodies. Quantitative Limulus amebocyte lysate analysis revealed an approximately equal molar ratio of LPS to protein in the electroeluted porin monomer. Thus, some but not all of the LPS could be released from trimer complexes by boiling in SDS. The isolated monomer did not release more LPS on boiling in SDS a second time but still had LPS tightly bound, as detected by lipid A-specific monoclonal antibodies.

Construction of a series of ompC-ompF chimeric genes by in vivo homologous recombination in Escherichia coli and characterization of their translational products

OmpC and OmpF are major outer membrane proteins and although they are homologous proteins, they function differently in several respects. As an approach to elucidate the submolecular structures that determine their differences, we have constructed a series of ompC-ompF chimeric genes by in vivo homologous recombination between these two genes, which are adjacent on a plasmid. The recombination sites in the chimeric genes were localized by means of restriction endonuclease analysis and nucleotide sequence determination. Most of the chimeric gene products were accumulated in the outer membrane. One of the chimeric gene products, with a fusion site in a central region between the OmpC and OmpF proteins, was normally expressed but not accumulated in the outer membrane. The trimeric structures of some of the chimeric gene products appeared to be extremely unstable in a SDS solution. From these results, domains contributing to the formation of specific structures in which the OmpC and OmpF proteins differ were identified. Bacterial cells possessing the chimeric gene products were also investigated as to their sensitivity to phages that require either OmpC or OmpF as a receptor component. With the aid of the chimeric gene products, the immunogenic determinants for three anti-OmpC monoclonal antibodies were found to be localized at different portions of the OmpC polypeptide: the N-terminal, central and C-terminal portions, respectively.

Characterization of structural unit of phospholamban by amino acid sequencing and electrophoretic analysis

The partial amino acid sequence of phospholamban from canine cardiac sarcoplasmic reticulum was determined by sequence analysis of the peptides obtained from the protein cleaved by cyanogen bromide and with TPCK-trypsin. The sequence determined initiated with N alpha-acetylated methionine followed by 44 amino acid residues intervening two unidentified residues. This polypeptide would represent a structural unit (protomer) of phospholamban. Analysis of temperature-dependent conversion of phospholamban from 26 kDa to lower molecular weight form (6 kDa) suggested that phospholamban holoprotein is composed of five identical protomers.

Outer-membrane permeability of bacteria

Gram-negative bacteria evolved to survive under the conditions in which a number of hazardous compounds are abundant. The outer membrane which protects the cell interior acts as a barrier against such hazardous agents, yet the cells must incorporate the chemicals that are essential for the cellular activity. The devices that Gram-negative bacteria developed to incorporate such essence are the transmembrane pores. These pores could be subdivided into three categories: (1) pore made of porins has a weak solute selectivity; (2) pore made of lamB protein and tsx proteins hold intermediate solute specificity. and (3) pores for the diffusion of vitamin B12 and ferric ion-chelator complexes have a tight solute specificity. Porins are identified from a number of Gram-negatives and from the outer membrane of mitochondria of various sources. Studies on the diffusion properties of these outer-membrane proteins provided essential information to understand membrane transports.

Domains involved in osmoregulation of the ompF gene in Escherichia coli

Expression of the ompF gene, which is under the control of the OmpR protein, is regulated by the osmolarity of the medium. To study the mechanism of osmoregulation, plasmids carrying two different types of chimeric genes were constructed. In one type, the coding region of the ompF gene was linked to the trp promoter (trpPO) preceding ompF, and in the other type the ompF upstream region, mostly composed of the region for regulation by OmpR and the promoter region, was linked to the lacZ gene by protein fusion. Expression of beta-galactosidase by the lacZ chimeric gene was OmpR dependent and osmoregulated as sensitively as that of the intact ompF gene. In the ompR20 background the direction of osmoregulation was opposite that of normal osmoregulation, as was the direction of osmoregulation of the intact ompF gene. Osmoregulation was also observed with trpPO-ompF chimeric genes. However, the regulation was not as sensitive to the osmolarity of the medium as was regulation of the intact ompF gene and was independent of OmpR. These results suggest that OmpR-dependent osmoregulation played a primary role in the osmoregulation of ompF expression and that ompR-independent osmoregulation most likely did not play a crucial role. Studies with a series of trpPO-ompF chimeric genes also suggest that the untranslated leader region, about 100 base pairs in length, between the transcription initiation site and the initiation codon was not required for osmoregulation.

Construction of a series of ompF-ompC chimeric genes by in vivo homologous recombination in Escherichia coli and characterization of the translational products

OmpF and OmpC are major outer membrane proteins. Although they are homologous proteins, they function differently in several respects. As an approach to elucidate the submolecular structures that determine the difference, a method was developed to construct a series of ompF-ompC chimeric genes by in vivo homologous recombination between these two genes, which are adjacent on a plasmid. The genomic structures of these chimeric genes were determined by restriction endonuclease analysis and nucleotide sequence determination. In almost all cases, recombination took place between the corresponding homologous regions of the ompF and ompC genes. Many of the chimeric genes produced proteins that migrated to various positions between the OmpF and OmpC proteins on polyacrylamide gel. On the basis of the results, a domain contributing to the mobility difference the OmpF and OmpC proteins was identified. Some chimeric genes did not accumulate outer membrane proteins, despite the fact that the fusion of the ompF and ompC genes was in frame. Bacterial cells possessing the chimeric proteins were also tested as to their sensitivity to phages which require either OmpF or OmpC as a receptor component. The chimeric proteins were either of the OmpF or OmpC type with respect to receptor activity. Based on the observations, the roles of submolecular domains in the structure, function, and biogenesis of the OmpF and OmpC proteins are discussed.

Mutation causing reverse osmoregulation of synthesis of OmpF, a major outer membrane protein of Escherichia coli

Supplementation of growth media with high concentrations of substances like sucrose results in the induction of OmpC synthesis and the suppression of OmpF synthesis. We isolated a novel mutant in which OmpF synthesis is in the opposite direction from normal osmoregulation. By transductional mapping, the mutation was localized at 75 min between malA and aroB on the Escherichia coli chromosome map where the ompR-envZ region is. The mutation was suppressed by a plasmid carrying the ompR gene but not by a plasmid carrying the envZ gene alone. The mutation also resulted in the almost complete suppression of OmpC synthesis. However, the remaining OmpC synthesis was osmoregulated normally. Based on these observations, the mechanism of osmoregulation of OmpF-OmpC synthesis is discussed.

Promoter exchange between ompF and ompC, genes for osmoregulated major outer membrane proteins of Escherichia coli K-12

Expression of the ompF and ompC genes coding for major outer membrane proteins OmpF and OmpC is regulated in opposite directions by medium osmolarity. Chimera genes were constructed by a reciprocal exchange of the promoter-signal sequence region between the two genes. The chimera gene construction was designed so that the proteins synthesized by these genes were essentially the same as the OmpC and OmpF proteins. Studies with the chimera genes demonstrated that the osmoregulation of the OmpF-OmpC synthesis was promoter dependent. They also showed that cells grew normally even when the osmoregulation took place in opposite directions. The effects of the ompR2 and envZ mutations, which suppress ompC and ompF expression, respectively, also became reversed. The reduced expression was still subject to the promoter-controlled osmoregulation. Based on these observations, the mechanism of regulation of the ompF-ompC gene expression and its physiological importance are discussed.

Porins of Brucella species

The outer membrane of Brucella species contains two major proteins, denoted as group 2 and group 3 proteins (Verstreate et al., Infect. Immun. 35:979-989, 1982). We reconstituted proteoliposomes from the purified proteins and egg phosphatidylcholine and showed that group 2 proteins, but not a group 3 protein, had the porin activity. The influx rates of sugars of various sizes into the proteoliposomes indicated that the porin channels had apparent diameters in a range comparable to that of Escherichia coli OmpF porin and that the channels were predominantly open. Among different Brucella species, there were small but detectable differences in the channel diameter, and it was possible to explain the differential sensitivity of several Brucella species to diagnostic dyes on the basis of these observed differences.

Heat modifiability and detergent solubility of outer membrane proteins of Rhodopseudomonas sphaeroides

The outer membrane fraction from Rhodopseudomonas sphaeroides was isolated by isopycnic density centrifugation. The purity of this fraction was assayed by several methods. When the outer membrane fraction obtained after French press lysis of cells was compared with the outer membrane fragments released during spheroplast formation, the polypeptide profiles were identical. Detergent solubilization of membrane fractions showed that Triton X-100 nonselectively solubilizes both the cytoplasmic membrane and the outer membrane, whereas Deriphat 160 selectively solubilizes the cytoplasmic membrane. Several outer membrane polypeptides, including the major outer membrane protein, exhibited changes in electrophoretic mobility that depended upon the temperature of solubilization in sodium dodecyl sulfate. Solubilization at room temperature in the presence of ions reproduced the effect of thermal denaturation on the major outer membrane polypeptide.

Outer membrane porins are important in maintenance of the surface structure of Escherichia coli cells

Escherichia coli cells lacking the OmpF and OmpC proteins, porin proteins of the outer membrane, are often unstable and easily revert to strains which either have regained one or both of these proteins or contain a new outer membrane protein. The structural importance of porin proteins in the cell surface was studied in the present work. Tris-hydrochloride buffer at a concentration of 120 mM caused deformation of the cell surface of a strain lacking these porins; the undulated appearance of the negatively stained cell surface changed to a smooth and expanded form. The Tris-induced deformation was seldom observed with either the wild-type strain or a pseudorevertant that possessed the OmpF protein. The role of the OmpF protein in stabilizing the cell surface against Tris treatment could be slightly taken over by the LamB protein, which shares a number of unique properties with the former proteins. The deformation of the cell surface by Tris-hydrochloride buffer was accompanied by a loss of viability, the lethal damage being especially significant when the cells lacked porins. Upon induction with maltose, cells with the undulated appearance could absorb lambda phages, whereas the deformed cells could not. These results suggest that the instability of cells lacking porins is primarily due to a structural defect of the outer membrane.

Outer membrane porin proteins F, P, and D1 of Pseudomonas aeruginosa and PhoE of Escherichia coli: chemical cross-linking to reveal native oligomers

Native oligomers of three Pseudomonas aeruginosa outer membrane porin proteins and one Escherichia coli porin were demonstrated by using a chemical cross-linking technique. P. aeruginosa protein F, the major constitutive outer membrane porin, was cross-linked to dimers in outer membrane and whole-cell cross-linking experiments. Purified preparations of P. aeruginosa proteins F, D1 (glucose induced), and P (phosphate starvation induced) and E. coli protein PhoE (Ic) were also cross-linked to reveal dimers and trimers upon two-dimensional sodium dodecyl sulfate-polyacrylamide electrophoretic analysis. Cross-linking of protein F was abolished by pretreatment of the protein with sodium dodecyl sulfate, indicating that the cross-linked products were due to native associations in the outer membrane.

Isolation, purification, and partial characterization of Brucella abortus matrix protein

Peptidoglycan sacculi with peptidoglycan-associated proteins were prepared from cell envelopes of Brucella abortus by extraction with sodium dodecyl sulfate (SDS) at 50 degrees C. On extraction of these preparations with SDS at 100 degrees C, a protein was obtained whose removal from peptidoglycan was confirmed by electron microscopy. Incubation of the 50 degrees C SDS-extracted cell envelopes with 50 mM MgCl2 in SDS-2-beta-mercaptoethanol at 37 degrees C also extracted the protein, along with lipopolysaccharide. At temperatures below 60 degrees C, the protein did not bind SDS strongly and had an apparent molecular weight greater than 92,000 in SDS-polyacrylamide gel electrophoresis. At higher temperatures, SDS bound strongly, and the apparent molecular weight was 38,000. Urea at 5 M did not alter the electrophoretic mobility of this 38,000-molecular-weight form. Immunoelectrophoresis in detergents with antisera to cell envelopes, carbohydrate staining of SDS-polyacrylamide gels, and production of anti-lipopolysaccharide antibodies by mice immunized with the purified protein indicated that lipopolysaccharide was present in free and protein-bound forms. Sequential gel filtration in SDS-EDTA and SDS-NaCl removed most lipopolysaccharide. After further purification by preparative SDS-polyacrylamide gel electrophoresis, a gas-liquid chromatographic analysis showed residual lipid tightly associated with the protein. The results suggested that the interactions between matrix proteins and other outer membrane components are stronger in B. abortus than in Escherichia coli, which was used as a control throughout.

Assembly in vivo of enterotoxin from Escherichia coli: formation of the B subunit oligomer

An oligomer of the B subunit of heat-labile enterotoxin of Escherichia coli has been observed in minicells and in whole cells. There is a delay after synthesis of the B subunit before it appears in the oligomer. The delay is not due to slow processing of the precursor. A similar delay in oligomerization of the major outer membrane protein OmpF is also described.

Estimation of molecular weights of membrane proteins in the presence of SDS by low-angle laser light scattering combined with high-performance porous silica gel chromatography. Confirmation of the trimer structure of porin of the E. coli outer membrane

An assessment study was carried out to evaluate the performance of the low-angle laser light-scattering technique combined with high-performance porous silica gel chromatography in the presence of sodium dodecyl sulfate and precision differential refractometry. It was found that the combined technique is highly promising as a reliable method for determining the molecular weight of a membrane protein solubilized by the surfactant. As a test, molecular weights of porin forming the permeability channel of the outer membrane of E. coli B in an oligomeric form were measured before and after heat treatment, which is known to cause dissociation. The results obtained indicate that the porin oligomer is a trimer with stoichiometric composition.

Roles of lipopolysaccharide and outer membrane protein OmpC of Escherichia coli K-12 in the receptor function for bacteriophage T4

The roles of lipopolysaccharide and OmpC, a major outer membrane protein, in the receptor function for bacteriophage T4 were studied by using Escherichia coli K-12 strains having mutations in the ompC gene or in genes controlling different stages of lipopolysaccharide synthesis. The receptor activity for T4 was monitored by (i) T4 sensitivity of intact cells, (ii) phage inactivation activity of cell envelopes, and (iii) phage inactivation activity of specimens reconstituted from purified OmpC and lipopolysaccharide. It was found that (i) in the presence of the OmpC protein, the essential region of the lipopolysaccharide for the receptor activity was the core-lipid A region that includes the heptose region, whereas the glucose region was not necessarily required for the receptor function; (ii) the OmpC protein was not required at all when the distal end of the lipopolysaccharide was removed to expose a glucose residue at the distal end; and (iii) when cells lacked both the OmpC protein and the glucose region, they became extremely resistant to T4. Based on these findings, the roles of the OmpC protein and lipopolysaccharide in T4 infection are discussed.

Primary structure of major outer-membrane protein I (ompF protein, porin) of Escherichia coli B/r

In the outer membrane of Gram-negative bacteria hydrophilic pores exist, allowing the diffusion of various low-molecular-weight solutes. These pores are formed by proteins, the porins. In a preliminary communication [Chen, Krämer, Schmidmayr & Henning (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 5014-5017] we presented the primary structure of one of these porins, the 340-amino-acid-residue protein I (ompF protein) from Escherichia coli B/r. In the present paper we give the experimental evidence for this sequence. Two tryptophan positions, one valine position, two aspartic acid positions and nine out of 82 amide determinations have been corrected. To aid further studies on this class of transmembrane proteins, the isolation of most of the constituent peptides is documented.

Outer membrane proteins of Brucella abortus: isolation and characterization

Outer membrane proteins were derived from one rough and four smooth strains of Brucella abortus by sequential extraction of physically disrupted cells with N-lauroylsarcosinate and dipolar ionic detergent. Extraction of outer membrane proteins was ineffective, however, without predigestion with lysozyme. Three groups of proteins were present and could be separated in their native state by sequential anion-exchange chromatography and gel filtration. Membrane proteins contained substantial quantities of tightly adherent lipopolysaccharide which could be reduced but not eliminated by extraction of cells with trichloroacetic acid before disruption. Group 2 proteins, apparently trimers in their native state, gave rise to 43,000- and 41,000-molecular-weight bands after complete denaturation in sodium dodecyl sulfate. They were antigenically identical among all the strains, showed close resemblance in amino acid composition to each other and a general similarity to OmpF of Escherichia coli, and are proposed to be the porins of B. abortus. Group 3 proteins occurred as 30,000-molecular-weight bands on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, although additional bands were frequently observed in this region. In none of the strains did group 3 proteins manifest heat-modifiable characteristics. Proteins of different strains bore a high degree of similarity to each other in amino acid composition, except in methionine, isoleucine, tyrosine, and histidine. Differences occurred consistently in amino acid composition between group 2 and 3 proteins, and some of these correspond to differences between OmpF and OmpA. Group 2 and 3 proteins were antigenically distinct from each other, but the principal group 3 antigens were shared among all the strains. Despite the lack of heat modifiability, perhaps influenced by adherent lipopolysaccharide, group 3 proteins are proposed as counterparts to OmpA. Most of the group 1 proteins, minor components, were physically associated with those of group 3 unless in sodium dodecyl sulfate. Group 1 proteins produced a major band at 94,000 and exhibited heat modifiability. No evidence was found of a low-molecular-weight lipoprotein in the outer membrane of B. abortus, but this is not taken to exclude its occurrence.

Stability and inhibition of Aspergillus and Rhizopus lipases

A lipase (triacylglyceral aclhydrolase, EC 3.1.1.3) secreted by Aspergillus contains two chains each of molecular weight 25000, with 12 mannose, two galactose and two N-acetylglucosamine residues per chain. The average hydrophobicity is close to the mean fov globular proteins. Thermal denaturation was biphasic when followed by circular dichroism but the stability is not unusual for globular proteins, nor does partial removal of the carbohydrate affect it. (delta G=46kJ). Refolding did not occur. The inhibitory effect of 2H2O on the rate of reaction implicates a histidine in the active centre. The inhibitory effect of concanavalin A was complex but the active centre was blocked. A lipase from Rhizopus arrhizus showed immunological identity with Aspergillus lipase, but unlike that one, was not inhibited by the antiserum. Similarly it was not inhibited by concanavalin -A although Con A-Sepharose was used in its isolation. It was 4-fold as active as the Aspergillus enzyme but had low thermal stability (delta K= 16kJ). The interfacial location of lipases does not impose any special requirement on the overall structure of the enzyme.

Immunization with major outer membrane protein (porin) preparations in experimental murine salmonellosis: effect of lipopolysaccharide

A crude major outer membrane (porin) preparation, obtained from a rough strain of Salmonella typhimurium earlier shown to be protective both in active and passive immunization of mice against challenge with smooth S. typhimurium, was further purified. Removal of the main impurities, lipopolysaccharide (LPS) and lipoprotein, was accompanied by loss of protective capacity in passive immunization experiments. Reconstitution with rough LPS restored the protective capacity. Protection was, however, concluded not to be due to anti-LPS, because a large fraction of the anti-LPS antibodies could be removed from the protective rabbit antiserum with an LPS immunosorbent without loss of protection.

Role of lipopolysaccharide in the receptor function for bacteriophage TuIb in Escherichia coli

Bacteriophage TuIb required lipopolysaccharide in addition to the OmpC trimer as a receptor component. Both the fatty acid and polysaccharide regions of lipopolysaccharide were shown to participate in the receptor function. The roles of lipopolysaccharide and outer membrane proteins in the receptor function for T-even type bacteriophages are discussed.

Arrangement of bacteriophage lambda receptor protein (LamB) in the cell surface of Escherichia coli: a reconstitution study

The LamB protein purified in a solution of sodium dodecyl sulfate was assembled into an ordered hexagonal lattice structure with a lattice constant of about 7.8 nm in the presence of lipopolysaccharide. The LamB alone formed aggregates with some lattice structure. However, the regularity of the lattice was only maintained within a very small area. An ordered hexagonal lattice was also formed when the wild-type lipopolysaccharide was replaced by heptoseless lipopolysaccharide, lipid A, and even fatty acid. However, the lattice constants were appreciably smaller than that with the wild-type lipopolysaccharide. The results suggest that the heptose-containing polysaccharide region, as well as the fatty acid region, are involved in the interaction with the LamB protein. The LamB-lipopolysaccharide lattice was preferably formed on the peptidoglycan layer when the lipoprotein was covalently bound to this layer. These results indicate that the molecular arrangement of the LamB protein in the outer membrane is similar to that of matrix proteins, OmpC and OmpF, which exist as trimers. The ordered hexagonal lattice was active in the receptor function for lambda, resulting in phage adsorption and deoxyribonucleic acid ejection. Thus, this reconstitution system should provide a useful means of studying the mechanism of lambda infection.

Comparison of outer membrane porin proteins produced by Escherichia coli and Salmonella typhimurium

The OmpC, OmpF, and Lc (NmpC) porin proteins of Escherichia coli K-12 have been shown to be similar to the OmpC (36K), OmpF (35K) and OmpD (34K) porin proteins of Salmnella typhimurium LT2 in terms of function, regulation of expression, and, in the case of OmpC and OmpF proteins, equivalence of the genetic loci determining their production. However, the corresponding pairs of proteins from these two species showed only limited similarity in peptide maps and no similarity in terms of migration on polyacrylamide gels.

Association of protein with the cell wall of Streptococcus mutans

Cell walls from Streptococcus mutans were prepared by conventional technique and subjected to a series of extraction procedures involving classical protein solvents. The extracted walls contained several non-peptidoglycan amino acids and were also amenable to radiolabeling with [125I]sodium iodide and chloramine T. The cell walls could be chemically modified with tetranitromethane and diazo-1H-tetrazole, suggesting the presence of tyrosine or histidine or both. Flourescence spectra of the walls revealed the presence of either tyrosine or tryptophan. Several proteases, including pronase, trypsin, subtilisin, and proteinase K, removed some of the label from the walls. In contrast, treatment of the walls with salts or denaturants did not result in the solubilization of label. When the walls were solubilized with mutanolysin and subjected to chromatography, three peaks of radioactivity with apparent molecular weights of 73,000, 39,000, and 9,600 were observed. Wall digests subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a single band of radioactivity corresponding to an apparent molecular weight of 79,000. Isoelectric focusing of labeled wall digest gave rise to two major bands of radioactivity with isoelectric points of approximately 2.4 and 5.6. The results suggest that the cell wall of S. mutans contains tightly and possibley covalently bound polypeptide molecules. We propose that the cell wall polypeptides of S. mutans serve as factors in the attachment of the bacteria to smooth surfaces.

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.

Protein neighborhoods in the outer membrane of Salmonella typhimurium

The organization of proteins in the outer membrane of Salmonella typhimurium was analyzed by cross-linking with cleavable reagents and symmetrical two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis. The major outer membrane proteins could be cross-linked to form multimeric complexes. The pore-forming 44 000, 36 000 and 34 000 dalton proteins were cross-linked to form dimers and trimers. Lipoprotein was cross-linked to 33 000 and 17 500 dalton proteins. In addition the 33 000, 24 000, 17 500 dalton proteins and the free form of lipoprotein were cross-linked to the peptidoglycan layer of the cell wall. The cross-linked complexes found were similar to those of analogous proteins in the outer membrane of Escherichia coli, thus suggesting a similar organization of outer membrane proteins in these species.

The role of the Escherichia coli lambda receptor in the transport of maltose and maltodextrins

The lambda receptor is a peptidoglycan-associated integral protein that spans the outer membrane. Beside its function in phage lambda adsorption it participates in transport. The latter function can be summarized as follows: 1) Receptor allows the nonspecific permeation of small molecules other than maltose and maltodextrins (in close analogy to a molecular sieve). Here the only criterion for selectivity is size and it has the properties of an unspecific pore. In this respect, it is similar to the outer membrane proteins Ia, Ib, and Ic, the porins. 2) It is a binding protein for maltodextrins. Binding affinity is low but increases by a factor of 500 as the chain length of the maltodextrins increases. In contrast, the affinity of the periplasmic maltose-binding protein for maltose and maltodextrins is similarly high (in the microM range). 3) In the in vitro system of liposomes, the lambda receptor facilitates specifically the diffusion of maltodextrins that exceed the size limit given by its porin function. This clearly demonstrates that the lambda receptor alone is able to specifically overcome the permeability barrier of the outer membrane for maltodextrins. 4) From the genetic and kinetic analysis of maltose and maltodextrin transport, it can be concluded that the lambda receptor interacts with the periplasmic maltose-binding protein. 5) Electron microscopic studies indicate a location for the maltose-binding protein in the outer cell envelope. This location is dependent on the presence of the lambda receptor.

Phospholipids as the molecular instruments of ion and solute transport in biological membranes

Partition studies have established that phospholipids generally have the capabilities to mediate the transmembrane transport of the full range of ions and solutes that physiologically cross biological membranes. The list of transportable species includes cations, anions, amino acids, citric acid cycle intermediates, nucleotides, and sugars. Phospholipid-mediated transport can be readily modulated by altering the phospholipid mixture or by addition of detergents, nucleotides, divalent metals, proteins, peptides, or ring compounds. Containment of phospholipid within channels in protein appears to be the precondition for the formation of the micellar structure requisite for solute transport. Phospholipid-mediated transport is postulated to be a central feature of energy coupling, membrane-spanning systems, and membrane-bound, phospholipid-requiring enzymes.

Influence of molecular size and osmolarity of sugars and dextrans on the synthesis of outer membrane proteins O-8 and O-9 of Escherichia coli K-12

Supplementation of the growth medium with high concentrations of sugars or low-molecular-weight dextrans results in a drastic change in the ratio of outer membrane proteins O-8 and O-9, due to induction of O-8 synthesis and suppression of O-9 synthesis. Sugars and dextrans of molecular weights greater than 600 to 700 switched the synthesis of O-9 to that of O-8 more effectively than those of lower molecular weight, although the effect was almost the same within each of the two groups irrespective of the differences in molecular weight within the group. Proteins O-8 or O-9, or both, are responsible for the formation of pores that allow the passive diffusion of hydrophilic molecules whose molecular weights are smaller than about 600 (T. Nakae, Biochem. Biophys. Res. Commun. 71:877-884, 1976). The results indicate that substances that cannot pass through the outer membrane switch the synthesis of O-9 to that of O-8 more effectively than those that can penetrate this membrane with the aid of O-8, O-9, or both. It is suggested that the osmotic pressure exerted on the outer membrane plays an important role in the regulation of synthesis of the two proteins.

Interaction of bacteriophage T4 with reconstituted cell envelopes of Escherichia coli K-12

The interaction with bacteriophage T4 of the cell surface of Escherichia coli K-12 reconstituted from outer membrane protein O-8, lipopolysaccharide, and the lipoprotein-bearing peptidoglycan sacculus was studied. The reconstituted cell surface was active as a receptor for the phage, resulting in the contraction of the tail sheath, a morphological change in the base plate which was accompanied by the extension of short tail pins down to the cell surface and the penetration of the needle through the cell surface. However, the ejection of phage deoxyribonucleic acid did not take place. Both O-8 and lipopolysaccharide were essential for the interaction. In the reconstitution, the wild-type lipopolysaccharide could not be replaced by either heptoseless lipopolysaccharide or lipid A. The lipoprotein-bearing peptidoglycan sacculus was also found to be an active component for the phage adsorption. The sacculus most likely functioned as a basal framework on which O-8 and lipopolysaccharide assembled to form a flat sheet which is large enough to interact with individual distal ends of long tail fibers of a single phage particle.

Arrangement of proteins O-8 and O-9 in outer membrane of Escherichia coli K-12. Existence of homotrimers and heterotrimers

1. The molecular arrangement of major outer membrane proteins O-8 and O-9 that exist as trimers has been studied by means of cross-linking with dimethylsuberimidate. 2. The cross-linked samples were examined on a urea/sodium dodecyl sulfate/polyacrylamide gel which was developed to separate cross-linked trimer and dimer of O-8 from those of O-9. 3. Cells simultaneously synthesizing both O-8 and O-9 formed heterotrimers (trimers containing both proteins) as well as homotrimers. 4. Quantitative analyses revealed that there was no discrimination between O-8 and O-9 in the assembly process to form trimers. 5. When cells were grown sequentially under two different sets of conditions so that the cells synthesized either one of the two proteins in the first stage and the other in the second stage of growth, no heterotrimers were formed. This result indicates that subunit exchange did not take place between trimers which had been incorporated into the outer membrane.