Factors affecting the electrophoretic mobility of the major outer membrane proteins of Escherichia coli in polyacrylamide gels.

The outer membrane proteins of Escherichia coli can be resolved by polyacrylamide gel electrophoresis in the presence of anionic detergents. Factors such as the choice of detergent and buffer system and the presence of urea in the separation gel are all shown to affect the charge and/or the configuration of the detergent-protein complexes and will affect the relative migration of these complexes to different extents. The procedures described in this paper may be of use in the determination of the relatedness of the proteins from the same or different strains. In addition, detailed examinations of the effects of these different parameters and the effect of changes in acrylamide concentrations may be useful in the detection of unusual characteristics which may indicate the presence of posttranslational modification.

In vivo effects of local anesthetics on the production of major outer membrane proteins by Escherichia coli.

Synthesis of a major outer membrane pore protein (the OmpF protein) by Escherichia coli K-12 was specifically and reversibly inhibited by low doses of procaine and other local anesthetics. The treated cells maintained the same total number of pores in their outer membrane by increased synthesis of the OmpC pore protein. Procaine also inhibited synthesis of the OmpF protein by Salmonella typhimurium and by E. coli B, although in the latter case, some OmpF protein was still detected in the outer membrane of treated cells. Experiments in which transcription was blocked by pretreatment with rifampicin indicated that procaine did not inhibit translation of the stable OmpF mRNA and that there was no pool of preformed OmpF and mRNA in cells grown in the presence of procaine. Procaine did not affect biosynthesis of the lipopolysaccharide core and did not inhibit the association of OmpF protein with the peptidoglycan. These results are discussed in terms of the known effects of procaine on membrane molecular packaging.

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.

Comparison of rat liver mitochondrial and microsomal membrane proteins.

An improved method is described for dissolving membrane proteins and for resolving them by polyacrylamide gel electrophoresis. With this procedure, the inner mitochondrial membrane has been found to contain 23 different protein species and the outer membrane 12. Only one protein species appears to be common to the two membranes. Smooth and rough microsomal membranes contain 15 different proteins. The approximate molecular weight and relative amount of each protein species have been extrapolated from the gel patterns. The outer mitochondrial membrane and the smooth microsomal membrane contain at least three protein species that appear to be identical, suggesting that they possess a common origin.

Protein composition of the cell wall and cytoplasmic membrane of Escherichia coli.

Envelope preparations obtained by passing Escherichia coli cells through a French pressure cell were separated by sucrose density gradient centrifugation into two distinct particulate fractions. The fraction with the higher density was enriched in fragments derived from the cell wall, as indicated by the high content of lipopolysaccharide, the low content of cytochromes, and the similar morphology of the fragments and intact cell walls. The less-dense fraction was enriched in vesicles derived from the cytoplasmic membrane, as indicated by the enrichment of cytochromes, the enzymes lactic and succinic dehydrogenase and nitrate reductase, and the morphological similarity of the vesicles to intact cytoplasmic membrane. Both fractions were rich in phospholipid. The protein composition was compared by mixing the cytoplasmic membrane-enriched fraction from a (3)H-labeled culture with the cell wall-enriched fraction from a (14)C-labeled culture and examining the resulting mixture by gel electrophoresis. Thirty-four bands of radioactive protein were resolved; of these, 27 were increased two- to fourfold in the cytoplasmic membrane-enriched fraction, whereas 6 were similarly increased in the cell wall-enriched fraction. One of the proteins which is clearly localized in the cell wall is the protein with a molecular weight of 44,000, which is the major component of the envelope. This protein accounted for 70% of the total protein of the cell wall, and its occurrence in the envelope from spheroplasts suggests that it is a structural protein of the outer membranous component of the cell wall.

Solubilization of the cytoplasmic membrane of Escherichia coli by Triton X-100.

Treatment of a partially purified preparation of cell walls of Escherichia coli with Triton X-100 at 23 C resulted in a solubilization of 15 to 25% of the protein. Examination of the Triton-insoluble material by electron microscopy indicated that the characteristic morphology of the cell wall was not affected by the Triton extraction. Contaminating fragments of the cytoplasmic membrane were removed by Triton X-100, including the fragments of the cytoplasmic membrane which were normally observed attached to the cell wall. Treatment of a partially purified cytoplasmic membrane fraction with Triton X-100 resulted in the solubilization of 60 to 80% of the protein of this fraction. Comparison of the Triton-soluble and Triton-insoluble proteins from the cell wall and cytoplasmic membrane fractions by polyacrylamide gel electrophoresis after removal of the Triton by gel filtration in acidified dimethyl formamide indicated that the detergent specifically solubilized proteins of the cytoplasmic membrane. The proteins solubilized from the cell wall fraction were qualitatively identical to those solubilized from the cytoplasmic membrane fraction, but were present in different proportions, suggesting that the fragments of cytoplasmic membrane which are attached to the cell wall are different in composition from the remainder of the cytoplasmic membrane of the cell. Treatment of unfractionated envelope preparations with Triton X-100 resulted in the solubilization of 40% of the protein, and only proteins of the cytoplasmic membrane were solubilized. Extraction with Triton thus provides a rapid and specific means of separating the proteins of the cell wall and cytoplasmic membrane of E. coli.

Effect of ethylenediaminetetraacetic acid, Triton X-100, and lysozyme on the morphology and chemical composition of isolate cell walls of Escherichia coli.

Extraction of a partially purified preparation of cell walls from Escherichia coli with the nonionic detergent Triton X-100 removed all cytoplasmic membrane contamination but did not affect the normal morphology of the cell wall. This Triton-treated preparation, termed the "Triton-insoluble cell wall," contained all of the protein of the cell wall but only about half of the lipopolysaccharide and one-third of the phospholipid of the cell wall. This Triton-insoluble cell wall preparation was used as a starting material in an investigation of several further treatments. Reextraction of the Triton-insoluble cell wall with either Triton X-100 or ethylenediaminetetraacetic acid (EDTA) caused no further solubilization of protein. However, when the Triton-insoluble cell wall was extracted with a combination of Triton X-100 and EDTA, about half of the protein and all of the remaining lipopolysaccharide and phospholipid were solubilized. The material which remained insoluble after this combined Triton and EDTA extraction still retained some of the morphological features of the intact cell wall. Treatment of the Triton-insoluble cell wall with lysozyme resulted in a destruction of the peptidoglycan layer as seen in the electron microscope and in a release of diaminopimelic acid from the cell wall but did not solubilize any cell wall protein. Extraction of this lysozyme-treated preparation with a combination of Triton X-100 and EDTA again solubilized about half of the cell wall protein but resulted in a drastic change in the morphology of the Triton-EDTA-insoluble material. After this treatment, the insoluble material formed lamellar structures. These results are interpreted in terms of the types of noncovalent bonds involved in maintaining the organized structure of the cell wall and suggest that the main forces involved are hydrophobic protein-protein interactions between the cell wall proteins and to a lesser degree a stabilization of protein-protein and protein-lipopolysaccharide interactions by divalent cations. A model for the structure of the E. coli cell wall is presented.

Examination of the protein composition of the cell envelope of Escherichia coli by polyacrylamide gel electrophoresis.

An envelope preparation containing the cell wall and cytoplasmic membrane of Escherichia coli was obtained by breaking the cells with a French pressure cell and sedimentating the envelope fraction by ultracentrifugation. This fraction was prepared for polyacrylamide gel electrophoresis by dissolving the protein in an acidified N,N'-dimethylformamide, removing lipids by gel filtration in the same organic solvent and removing the solvent by dialysis against aqueous urea solutions. More than 80% of the total protein of the envelope fraction was recovered in soluble form. Electrophoresis on sodium dodecyl sulfate-containing gels yielded from 20 to 30 well-resolved bands of protein. One major protein band was observed on the gels. This protein had a molecular weight of 44,000 and accounted for as much as 40% of the total protein of the envelope fraction. A double-labeling technique was used to examine the protein composition of the envelope fraction from cells grown under different sets of conditions which result in large changes in the levels of membrane-bound oxidative enzymes. These changes in growth conditions resulted in only minor alterations in the protein profiles observed on the gels, suggesting that this organism is able to adapt to changes in growth environment with only minor modifications of the major proteins of the cell envelope.

Comparison of the envelope protein compositions of several gram-negative bacteria.

Five gram-negative species contained one or two major protein species with electrophoretic mobilities similar to the major protein of the Escherichia coli cell wall.

Outer membrane proteins of Escherichia coli. 3. Evidence that the major protein of Escherichia coli O111 outer membrane consists of four distinct polypeptide species.

Previous studies have shown that the outer membrane of Escherichia coli O111 gives a single, major, 42,000-dalton protein peak when analyzed by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis at neutral pH. Further studies have shown that this peak consists of more than a single polypeptide species, and on alkaline SDS-gel electrophoresis this single peak is resolved into three subcomponents designated as proteins 1, 2, and 3. By chromatography of solubilized, outer membrane protein on diethylaminoethyl-cellulose followed by chromatography on Sephadex G-200 in the presence of SDS, it was possible to separate the 42,000-dalton major protein into four distinct protein fractions. Comparison of cyanogen bromide peptides derived from these fractions indicated that they represented at least four distinct polypeptide species. Two of these proteins migrated as proteins 1 and 2 on alkaline gels. The other two proteins migrated as protein 3 on alkaline gels and cannot be separated by SDS-polyacrylamide gel electrophoresis. In purified form, these major proteins do not contain bound lipopolysaccharide, phospholipid, or phosphate. These proteins may contain a small amount of carbohydrate, as evidenced by the labeling of these proteins by glucosamine, and to a lesser extent by glucose, under conditions where the metabolism of these sugars to amino acids and lipids is blocked. All of the proteins were labeled to the same extent by these sugars. Thus, it was concluded that there are at least four distinct polypeptide species with apparent molecular masses of about 42,000 daltons in the outer membrane of E. coli O111.

Function of the rfb gene cluster and the rfe gene in the synthesis of O antigen by Shigella dysenteriae 1.

A plasmid that included both an 8.9 kb chromosomal DNA insert containing genes from the rfb cluster of Shigella dysenteriae 1 and a smaller insert containing the rfp gene from a S. dysenteriae 1 multicopy plasmid resulted in efficient expression of O antigen in an rfb-deleted strain of Escherichia coli K-12. Eight genes were identified in the rfb fragment: the rfbB-CAD cluster which encodes dTDP-rhamnose synthesis, rfbX which encodes a hydrophobic protein involved in assembly of the O antigen, rfc which encodes the O antigen polymerase, and two sugar transferase genes. The production of an O antigen also required the E. coli K-12 rfe gene, which is known to encode a transferase which adds N-acetylglucosamine phosphate to the carrier lipid undecaprenol phosphate. Thus Rfe protein appears to function as an analogue of the Salmonella RfbP protein to provide the first sugar of the O unit. Functional analysis of the other genes was facilitated by the fact that partial O units of one, two or three sugars were efficiently transferred to the lipopolysaccharide core. This analysis indicated that the plasmid-encoded Rfp protein is the transferase that adds the second sugar of the O unit while the two rfb transferases add the distal sugars to make an O antigen whose structure is (Rha-Rha-Gal-GlcNAc)n. The use of the rfe gene product as the transferase that adds the first sugar of an O unit is a novel mechanism which may be used for the synthesis of other enteric O antigens.

Export of protein in Escherichia coli: a novel mutation in ompC affects expression of other major outer membrane proteins.

A mutation within the ompC structural gene of Escherichia coli K-12 which affects expression of outer membrane proteins was characterized. The mutation consisted of a 6-base-pair deletion near the 3' end of the gene which removed the amino acids Val-300 and Gly-301 of the mature coding sequence but otherwise left the reading frame intact. The deletion occurred within a region highly conserved among the porins. No protein product was detected from a single copy of the mutant gene. The mutation caused a trans-dominant decrease in the expression of a wild-type ompC allele. The mutation caused a similar decrease in the amounts of OmpA, OmpF, LamB, and Lc proteins, yet it did not appear to affect the minor outer membrane proteins. It had no significant effect on transcription from either ompF or ompC promoters as measured with lacZ operon fusions. The effects of the mutation on other proteins were completely eliminated when the signal sequence was disrupted so that the mutant protein no longer interacted with the secretion machinery of the cell but instead accumulated as precursor in the cytoplasm. A model is proposed involving the translocation of proteins to the outer membrane and the importance of protein conformation in this process.

Genetics of lipopolysaccharide biosynthesis in enteric bacteria.

From a historical perspective, the study of both the biochemistry and the genetics of lipopolysaccharide (LPS) synthesis began with the enteric bacteria. These organisms have again come to the forefront as the blocks of genes involved in LPS synthesis have been sequenced and analyzed. A number of new and unanticipated genes were found in these clusters, indicating a complexity of the biochemical pathways which was not predicted from the older studies. One of the most dramatic areas of LPS research has been the elucidation of the lipid A biosynthetic pathway. Four of the genes in this pathway have now been identified and sequenced, and three of them are located in a complex operon which also contains genes involved in DNA and phospholipid synthesis. The rfa gene cluster, which contains many of the genes for LPS core synthesis, includes at least 17 genes. One of the remarkable findings in this cluster is a group of several genes which appear to be involved in the synthesis of alternate rough core species which are modified so that they cannot be acceptors for O-specific polysaccharides. The rfb gene clusters which encode O-antigen synthesis have been sequenced from a number of serotypes and exhibit the genetic polymorphism anticipated on the basis of the chemical complexity of the O antigens. These clusters appear to have originated by the exchange of blocks of genes among ancestral organisms. Among the large number of LPS genes which have now been sequenced from these rfa and rfb clusters, there are none which encode proteins that appear to be secreted across the cytoplasmic membrane and surprisingly few which encode integral membrane proteins or proteins with extensive hydrophobic domains. These data, together with sequence comparison and complementation experiments across strain and species lines, suggest that the LPS biosynthetic enzymes may be organized into clusters on the inner surface of the cytoplasmic membrane which are organized around a few key membrane proteins.

Regulation in Escherichia coli of the porin protein gene encoded by lambdoid bacteriophages.

Specialized lambda transducing phages carrying the cloned lc porin gene from the lambdoid bacteriophage PA-2, including various amounts of a sequence 5' to the start of transcription, were used to study the regulation of the porin gene. It was found that a cyclic AMP receptor protein consensus binding site 65 base pairs 5' to the start of transcription was required for catabolite repression of lc but was not sufficient for maximum expression under derepressing conditions. A sequence located more than 209 base pairs 5' to the start of transcription was necessary for maximum expression. By manipulating the copy number of the lc gene and the temperature and by measuring both the rate of synthesis of mRNA and the amount of Lc protein in the outer membrane, it was determined that the expression of lc is regulated primarily at the level of transcription and that expression is not autoregulated. Evidence is also presented that the silent phage porin gene nmpC of Escherichia coli K-12 is transcribed to the same extent as lc even though it does not give rise to a stable pool of mRNA. The structure of the 5' end of lc and nmpC is similar to that of ompF, and a model for transcriptional regulation is presented which may apply to all of these porin genes.

Export-defective lamB protein is a target for translational control caused by ompC porin overexpression.

Overexpression of OmpC protein from an inducible plasmid vector reduced the amount of the precursor form of LamB protein in LamB signal sequence mutants. The stability of the precursor form of LamB protein was not affected, indicating that the effect of OmpC overexpression was on the synthesis of the precursor rather than on degradation. These results indicate that a functional signal sequence is not required on an outer membrane protein for it to be a target for translational control.

Regulation of outer membrane protein synthesis in Escherichia coli K-12: deletion of ompC affects expression of the OmpF protein.

A chromosomal deletion beginning at a Tn10 located ca. 8 kilobases upstream from the ompC structural gene and extending through the 2.6-kilobase HindIII fragment carrying the ompC was isolated. The 2.6-kilobase ompC fragment was cloned into lambda 540 to obtain phage lambda 540C1. When the deletion mutant was lysogenized with lambda 540C1, the resulting strain produced normal levels of OmpC protein, and expression of this protein was regulated by osmolarity, carbon source, and the lc gene of phage PA-2, indicating that the cloned fragment contained all of the information required for regulated expression of ompC. The strain carrying the deletion was partially constitutive for expression of OmpF protein, whereas the lambda 540C1 lysogen of this strain and other strains with mutations in ompC repressed OmpF synthesis under conditions which lead to high-level expression of OmpC protein. Strains which are diploid or triploid for ompC show strong inhibition of synthesis of OmpF protein. We conclude that a regulatory element located upstream from the ompC coding sequence inhibits translation of OmpF protein under conditions which favor OmpC expression. Since ompF is known to repress transcription of ompC, we propose that these two genes constitute a closed regulatory loop which acts to amplify regulatory signals which control expression of these proteins.