In vitro depolarization of Escherichia coli membrane vesicles by colicin Ia.

Conditions are reported under which membrane vesicles prepared from Escherichia coli K12 are depolarized by colicin Ia. Although incubation of membrane vesicles with active colicin Ia affects neither transport activity nor the ability of such vesicles to generate a deltapH or deltapsi, a single freeze-thaw cycle of such vesicles in the presence of colicin Ia leads to 1) retention of the colicin by the vesicles, 2) inactivation of transport activity, and 3) membrane depolarization, with a concomitant increase in the transmembrane deltapH. These effects are dependent upon the presence of active colicin Ia during the freeze-thaw cycle. These findings are consistent with our previous results showing that Ia-treated whole cells or membrane vesicles prepared from such cells are defective in their ability to generate a deltapsi, yet generate an increased deltapH (Tokuda, H., and Konisky, J. (1978) Proc. Natl. Acad. Sci. U. S. A., 75, 2579--2583). In addition to its effect on vesicles prepared from sensitive cells, we show that vesicles prepared from both colicin Ia-resistant and -tolerant cells are depolarized by colicin treatment with a concomitant increase in deltapH. It is concluded that the final target of colicin Ia is the cytoplasmic membrane. A model for the mechanism of colicin Ia action is presented in which colicin Ia binds to the specific colicin Ia outer membrane receptor and is subsequently translocated to the cytoplasmic membrane where its integration leads to the formation of ion channels.     

Cleavage of colicin Ia by the Escherichia coli K-12 outer membrane is not mediated by the colicin Ia receptor.

Colicin Ia can be cleaved by isolated outer membranes prepared from sensitive and resistant (lacking the colicin Ia receptor) strains of Escherichia coli. Both active and heat-denatured colicin Ia are extensively fragmented. Such proteolysis does not occur when colicin Ia is added to whole sensitive or resistant cells. These results demonstrate that cleavage of colicin Ia is not mediated by its outer membrane receptor.     

Dynamic aspects of colicin N translocation through the Escherichia coli outer membrane.

Colicin N is a bacteriocin that kills sensitive Escherichia coli cells. After binding to the cell surface-exposed receptor, a short period exists when a significant number of the cell-associated colicin N molecules are sensitive to external enzymes. Two colicin N populations are discriminated by proteases: the susceptible pool bound to OmpF porin on the cell surface and another population corresponding to protease-inaccessible colicin N. During translocation, colicin N reaches the periplasmic space and proteolytic cleavage of the colicin occurs only when the outer membrane barrier is permeabilized.     

Ascorbate-phenazine methosulfate-dependent membrane energization in respiratory chain mutants of Escherichia coli

Ascorbate with phenazine methosulfate was able to energize the membrane of inside-out membrane vesicles from cytochrome-containing but not cytochrome-deficient cells of the E., coli, hem A^? mutant SASX76 as measured by the quenching of the fluorescence of acridine dyes. This substrate could also energize vesicle membranes from the ubiquinone-deficient mutant E., coli AN59 in the absence of exogenous ubiquinone. These results suggest that there is site of membrane energization coupled to substrate oxidation in the respiratory chain of E., coli in the cytochrome region between ubiquinone and oxygen.     

Structural changes in the cell membrane of lambda-lysogenic Escherichia coli induced by colicin E2.

The structural changes in the cell membrane of λ-lysogenic $\text{Escherichia coli}$ induced by colicin E₂ were examined. The addition of colicin E₂ made the cells susceptible to various detergents and the transport rate of o-nitrophenyl-β-D-galactoside into the colicin-treated cells was stimulated markedly by adding a low concentration of sodium dodecyl sulfate. The fluorescence intensity of 8-anilino-1-naphthalenesulfonate bound to the cells was markedly increased by adding colicin E₂. Colicin E₂ stimulated the incorporation of ${}^{32}\text{P}$ from prelabeled phosphatidylglycerol to cardiolipin. All these changes probably suggesting the structural alteration of the cell membrane were dependent on the presence of the $\text{rex}$ gene of λ prophage in the cells.     

Mutant of Escherichia coli defective in response to colicin K and in active transport.

A mutant of Escherichia coli has been isolated that grows poorly on succinate and exhibits a markedly reduced sensitivity to colicin K. This mutant is also deficient in the respiration-linked transport of proline and thiomethyl-beta-D-galactoside but appears normal for the adenosine triphosphate-dependent transport of glutamine and arginine. A temperature-conditional revertant of the mutant grows on succinate and is sensitive to colicin K at 27 C, but fails to grow on succinate and is insensitive to colicin K at 42 C. Proline transport in the temperature-conditional revertant is reduced at 42 C when either glucose or succinate is used as energy source. Glutamine transport, on the other hand, is normal at 42 C with glucose as energy source, but is reduced with succinate, although not to the same extent as is proline transport. The lack of growth on succinate and the deficiencies in transport at 42 C are not due to a temperature-dependent lesion in either the electron transport chain or in Ca2+, Mg2+-activated adenosine triphosphatase activity. Membrane vesicles prepared from the temperature-conditional revertant are impaired in proline transport at both 27 and 42 C. These findings suggest the existence in the cytoplasmic membrane of E. coli cells of a component, presumably protein, that is required for colicin K action and that functions in respiration-linked and, to a lesser degree, in adenosine triphosphate-dependent active transport systems. This protein may serve as the primary target of colicin K action.     

Defeat of colicin tolerance in Escherichia coli ompA mutants: evidence for interaction between colicin L-JF246 and the cytoplasmic membrane.

Escherichia coli ompA mutants are tolerant to colicin L-JF246. This tolerance can be overcome by a variety of treatments that have as their target the outer membrane or the peptidoglycan layers of the cell envelope. Thus, increasing the concentration of colicin L, releasing lipopolysaccharide from the outer membrane by treatment of intact cells with ethylenediaminetetracetic acid (EDTA), converting cells to spheroplasts by treatment with lysozyme-EDTA or penicillin, or trypsin, treatment of intact cells will result in an increased colicin sensitivity. These treatments alter the outer membrane of ompA mutants and suggest that the altered outer membrane may allow the penetration of at least a portion of the colicin L molecule to a site of action located within this barrier. To substantiate this, we have demonstrated that membrane vesicles prepared from ompA mutants are sensitive to colicin L and that 14C-labeled colicin L binds rapidly to both the outer and inner membrane fractions of the cell.     

Characterization of F-pilin as an inner membrane component of Escherichia coli K12.

Antipeptide antibodies were used to detect, purify, and characterize nonfilament F-pilin in the cell envelope of an F'tra+ strain of Escherichia coli. Affinity-purified goat antibodies raised against a peptide corresponding to the amino-terminal 14 amino acids of F-pilin detected F-pilin in immuno-overlay ("Western") blots of electrophoretically separated inner and outer membrane proteins. As expected, the molecule was absent from inner membrane preparations of F- or F'traA[Am] strains. Immunoreactive material was purified from inner membrane fractions and shown to be F-pilin by amino acid analysis. The anti-peptide antibodies also detected membrane forms of F-pilin produced by cells containing plasmid pTG801 (Grossman, T. & Silverman, P. (1989) J. Bacteriol. 171, 650-656). Most cell envelope pilin was in the inner membrane fraction, but a significant quantity fractionated with the outer membrane as well. The hydropathy profile of F-pilin suggested that the molecule is an integral membrane protein with two membrane-spanning domains. In confirmation, F-pilin and pTG801 pilins in inner membrane preparations were solubilized by a single extraction with the nonionic detergents Nonidet P-40 (2%) or Triton X-100 (2%), but not by 2 M KCl or 0.1 M NaOH. Moreover, analysis of traA'-'phoA constructs indicated that both the amino and carboxyl termini of F-pilin face the periplasm. The periplasmic location of the amino terminus was confirmed by immunoelectron microscopy of spheroplasts from F' and pTG801 strains, using a monoclonal antibody that recognizes an amino-terminal epitope. These data suggest a specific structure for membrane F-pilin. We discuss that structure in relation to the probable structure of filament F-pilin.     

N-acetylmuramoyl-L-alanine amidase of Escherichia coli K12. Possible physiological functions

Various experiments were carried out in an attempt to determine the possible physiological function of the N-acetylmuramoyl-L-alanine amidase purified from Escherichia coli K12 on the basis of its activity on N-acetylmuramoyl-L-alanyl-D-gamma-glutamyl-meso-diaminopimelic acid [MurNAc-LAla-DGlu(msA2pm)]. A Km value of 0.04 mM was determined with this substrate. Specificity studies revealed that compounds with a MurNAc-LAla linkage are the most probable substrates of this enzyme in vivo. Purified amidase had no effect on purified peptidoglycan and only low levels (1-2.5%) of cleaved MurNAc-LAla linkages were detected in peptidoglycan isolated from normally growing cells. However, the action of the amidase in vivo on peptidoglycan was clearly detectable during autolysis. The amidase activity of cells treated by osmotic shock, ether or toluene, as well as that of mutants with altered outer membrane composition was investigated. Attempts to reveal a transfer reaction catalysed by amidase were unsuccessful. Furthermore, by its location and specificity, amidase was clearly not involved in the formation of UDP-MurNAc. The possibility that it might be functioning in vivo as a hydrolase degrading exogeneous peptidoglycan fragments in the periplasma was substantiated by the fact that MurNAc itself and MurNAc-peptides could sustain growth of E. coli as sole carbon and nitrogen sources. Finally, out of 200 thermosensitive mutants examined for altered amidase activity, only two strains had less than 50% of the normal level of activity, whereas ten strains were found to possess more than 50%. In fact, two of the overproducers encountered presented a 4-5-fold increase in activity.     

Translocation of ProOmpA possessing an intramolecular disulfide bridge into membrane vesicles of Escherichia coli. Effect of membrane energization

In the absence of delta mu H+, the in vitro translocation of proOmpA resulted in the stable accumulation of a possible translocation intermediate in addition to a transiently accumulating one. The stable intermediate was detected on a polyacrylamide gel as two proteinase K-resistant bands corresponding to a molecular weight of about 28,000. The appearance of the bands was appreciably enhanced when proOmpA was oxidized with ferricyanide. No mature OmpA appeared. When proOmpA reduced with dithiothreitol was used, on the other hand, the bands did not appear at all. Upon the replacement of Cys302 of OmpA with Gly, the intermediate accumulation was abolished. The proOmpA treated with dithiothreitol was labeled with N-[3H]-ethylmaleimide, whereas that treated with ferricyanide was not. The ferricyanide-treated proOmpA was translocated into membrane vesicles in the presence of delta mu H+. The mature OmpA thus translocated and processed was not labeled with N-[3H]ethylmaleimide. It is concluded that proOmpA possessing the Cys290-Cys302 disulfide bridge can be translocated without cleavage of the bridge, when delta mu H+ is imposed. The accumulation of the disulfide bridge-containing intermediate was ATP-dependent, whereas its conversion to the translocated mature form was not blocked in the presence of adenosine 5'-(beta, gamma-imino)triphosphate. It is concluded that the early and late stages of the translocation reaction require ATP and delta mu H+ differently.     

Reduced nicotinamide adenine dinucleotide dependent reduction of fumarate coupled to membrane energization in a cytochrome deficient mutant of Escherichia coli K12.

Escherichia coli SASX76 does not form cytochromes unless supplemented with 5-aminolevulinic acid. It can grow anaerobically on glycerol and DL-glycerol 3-phosphate in the absence of 5-aminolevulinic acid with fumarate but not with nitrate as the terminal electron acceptor. Cytochrome-independent NADH oxidase, glycerol 3-phosphate- and NADH-fumarate oxidoreductase activities are induced by anaerobic growth on a glycerol-fumarate medium. The pathway of electrons from substrate to fumarate involves menaquinone. The NADH-fumarate oxidoreductase and cytochrome-independent NADH oxidase systems are inhibited by piericidin A, 2-heptyl-4-hydroxyquinoline N-oxide, and iron chelating agents. Both systems can energize the membrane particles as indicated by quenching of atebrin fluorescence.     

Characterization of nucleotide pools as a function of physiological state in Escherichia coli

Using a modified method that involves minimal manipulation of cells, we report new information about nucleotide pool sizes and changes throughout the Escherichia coli growth curve. Nucleotide pool sizes are critically dependent on sample manipulation and extraction methods. Centrifugation and even short (2 min) lapses in sample preparation can dramatically affect results. The measured ATP concentration at three different growth rates is at least 3 mM, well above the 0.8 mM needed to saturate the rRNA promoter P1 in vitro. Many of the pools, including ATP, GTP, and UTP, begin to decrease while the cells are still in mid-log growth. After an almost universal drop in nucleotide concentration as the cells transition from logarithmic to stationary phase, there is a “rebound” of certain nucleotides, most notably ATP, after the cells enter stationary phase, followed by a progressive decrease. UTP, in contrast, increases as the cells transition into stationary phase. The higher UTP values might be related to elevated UDP-glucose/galactose, which was found to be at higher concentrations than expected in stationary phase. dTTP is the most abundant deoxynucleoside triphosphate (dNTP) in the cell despite the fact that its precursors, UDP and UTP, are not. All dNTPs decrease through the growth curve but do not have the abrupt drop, as seen with other nucleotides when the cells transition into stationary phase.     

Growth inhibition of Escherichia coli by E colicin plasmids

Plasmids were isolated from E colicinogenic strains and transformed into prototrophic Escherichia coli K 12 strain DB364. Screening of E colicinogenic transformants for growth on defined medium revealed an apparent amino acid auxotrophy mediated by E4 and, to a lesser extent, E7 colicin plasmids. The auxotrophy was further investigated in E4 colicinogenic strains. From such auxotrophic transformants, denoted Pmi+ (plasmid-mediated inhibition of growth), Pmi- variants were obtained at a frequency of 3 X 10(-4) per bacterium. Plasmid loss was not detected among Pmi- clones. Isolation of E4 colicin plasmids from Pmi- clones and retransformation of strain DB364 with these plasmids showed that 40% of the plasmids were unable to inhibit growth of DB364 and were inferred to have alterations in an E4 colicin plasmid gene termed pmi. All such plasmids were indistinguishable from native E4 colicin plasmids, with respect to colicin immunity, colicin production and excretion, and sensitivity to lysis by mitomycin C. Experiments examining the nutritional basis of the plasmid-mediated auxotrophy indicated that at least seven amino acids, isoleucine, leucine, valine, arginine, methionine, serine and glycine, were involved in the auxotrophy. However, supplementation with only these seven amino acids did not completely restore growth. Assays of the activities of enzymes involved in amino acid biosynthesis in colicinogenic and non-colicinogenic strains under repressing and derepressing growth conditions suggested that E4 colicin plasmids did not repress synthesis of the implicated amino acids.