Channels formed by colicin E1 in planar lipid bilayers are large and exhibit pH-dependent ion selectivity

Summary The E1 subgroup (E1, A, Ib, etc.) of antibacterial toxins called colicins are known to form voltage-dependent channels in planar lipid bilayers. The genes for colicins E1, A and Ib have been cloned and sequenced, making these channels interesting models for the widespread phenomenon of voltage dependence in cellular channels. In this paper we investigate ion selectivity and channel size—properties relevant to model building. Our major finding is that the colicin E1 channel is large, having a diameter ofat least 8 Å at its narrowest point. We established this from measurements of reversal potentials for gradients formed by salts of large cations or large anions. In so doing, we exploited the fact that the colicin channel is permeable to both cations and anions, and its relative selectivity to them is a functions and anions, and its relative selectivity to them is a function of pH. The channel is anion selective (Cl^– over K⁺) in neutral membranes, and the degree of selectivity is highly dependent on pH. In negatively charged membranes, it becomes cation selective at pH's higher than about 5. Experiments with pH gradients cross the membrane suggest that titratable groups both within the channel lumen and near the channel ends affect the selectivity. Individual E1 channels have more than one open conductance state, all displaying comparable ion selectivity. Colicins A and Ib also exhibit pH-dependent ion selectivity, and appear to have even larger lumens than E1.     

Siderophore production and outer membrane proteins of selected Vibrio vulnificus strains under conditions of iron limitation

Abstract The tonB gene product is necessary for the energy-dependent transport of ferric chelates and vitamin B₁₂ across the Escherichia coli outer membrane. When carried on multicopy plasmids, the cloned tonB gene complemented tonB hosts, restoring transport of ferri-siderophone complexes and vitamin B₁₂, and susceptibility to the group B colicins and phage ф80. The levels of these activities were all markedly lower than when the tonB ⁺ gene was present in single copy. This depression of TonB function occurred even when the chromosome carried the normal tonB ⁺ allele, but plasmids carrying only a portion of the tonB gene, including the 5'-regulatory region, were not inhibitory.     

THE PHENOTYPIC AND FITNESS EFFECTS OF COLICIN RESISTANCE IN ESCHERICHIA COLI K-12

Previous studies indicate that most natural isolates of Escherichia coli are resistant to most or all colicins (antibiotics produced by E. coli) when assessed in the laboratory. Additionally, resistance to different colicin types appears to arise in a nonindependent manner. One possible mechanism to explain this nonindependence is pleiotropy: Multiple resistances are selected after exposure to a single colicin. This study, which was designed to address the role of pleiotropy in the generation of colicin resistance, revealed that 96% of colicin resistant mutants were resistant to two or more colicins. Mutational class was important because putative translocation mutants (Tol pathway mutants) resisted fewer colicins than putative receptor mutants. To determine whether colicin resistance is costly, the effects of colicin resistance mutations on maximal growth rate in a rich medium were also examined. Relative to the sensitive ancestor, translocation mutations lowered maximal growth rates by 17%, whereas putative receptor mutations did not significantly lower growth rates. Thus, when nutrients are abundant, the most advantageous forms of colicin resistance may not impose a cost. The ecological consequences of pleiotropic colicin resistance could involve population cycling between colicin sensitivity and resistance. Additionally, if the cost of resistance depends on the environment, ecological diversification could result.     

NMR characterisation of the relationship between frustration and the excited state of Im7

Previous work shows that Im9 folds in a two-state transition while its homologue Im7 folds in a three-state transition via an on-pathway kinetic intermediate state (KIS), with this difference being related to frustration in the structure of Im7. We have used NMR spectroscopy to study conformational dynamics connected to the frustration. A combination of equilibrium peptide N¹H/N²H exchange, model-free analyses of backbone NH relaxation data and relaxation dispersion (RD)-NMR shows that the native state of Im7 is in equilibrium with an intermediate state that is lowly populated [equilibrium intermediate state (EIS)]. Comparison of kinetic and thermodynamic parameters describing the EIS native-state equilibrium obtained by RD-NMR with previously reported parameters describing the KIS native-state equilibrium obtained from stopped-flow fluorescence studies of refolding His-tagged Im7 shows that the KIS and the EIS are the same species. ¹⁵N chemical shifts of the EIS obtained from the RD-NMR analysis show that residues forming helix III in the native state are unstructured in the EIS while other residues experiencing frustration in the native state are in structured regions of the EIS. We show that binding of Im7 and its L53A/I54A variant (which resembles the EIS as shown in previous work) to the cognate partner for Im7, the DNase domain of colicin E7, causes the dynamic processes associated with the frustration to be dampened.     

Distinct conformational stability and functional activity of four highly homologous endonuclease colicins

The family of conserved colicin DNases E2, E7, E8, and E9 are microbial toxins that kill bacteria through random degradation of the chromosomal DNA. In the present work, we compare side by side the conformational stabilities of these four highly homologous colicin DNases. Our results indicate that the apo-forms of these colicins are at room temperature and neutral pH in a dynamic conformational equilibrium between at least two quite distinct conformers. We show that the thermal stabilities of the apo-proteins differ by up to 20 degrees C. The observed differences correlate with the observed conformational behavior, that is, the tendency of the protein to form either an open, less stable or closed, more stable conformation in solution, as deduced by both tryptophan accessibility studies and electrospray ionization mass spectrometry. Given these surprising structural differences, we next probed the catalytic activity of the four DNases and also observed a significant variation in relative activities. However, no unequivocal link between the activity of the protein and its thermal and structural stability could easily be made. The observed differences in conformational and functional properties of the four colicin DNases are surprising given that they are a closely related (> or =65% identity) family of enzymes containing a highly conserved (betabetaalpha-Me) active site motif. The different behavior of the apo-enzymes must therefore most likely depend on more subtle changes in amino acid sequences, most likely in the exosite region (residues 72-98) that is required for specific high-affinity binding of the cognate immunity protein.     

Intraguild predation provides a selection mechanism for bacterial antagonistic compounds

Bacteriocins are bacterial proteinaceous toxins with bacteriostatic or bacteriocidal activity towards other bacteria. The current theory on their biological role concerns especially colicins, with underlying social interactions described as an example of spite. This leads to a rock–paper–scissors game between colicin producers and sensitive and resistant variants. The generality of this type of selection mechanism has previously been challenged with lactic acid bacterial (LAB) bacteriocins as an example. In the natural environment of LAB, batch cultures are the norm opposed to the natural habitats of Escherichia coli where continuous cultures are prevailing. This implies that fitness for LAB, to a large degree, is related to survival rates (bottleneck situations) rather than to growth rates. We suggest that the biological role of LAB bacteriocins is to enhance survival in the stationary growth phase by securing a supply of nutrients from lysed target cells. Thus, this social interaction is an example of selfishness rather than of spite. Specifically, it fits into an ecological model known as intraguild predation (IGP), which is a combination of competition and predation where the predator (LAB bacteriocin producer) and prey (bacteriocin susceptible bacteria) share similar and often limited resources. We hypothesize that IGP may be a common phenomenon promoting microbial production of antagonistic compounds.     

Purification and reconstitution into liposomes of an integral membrane protein conferring immunity to colicin A

Abstract The immunity protein to colicin A protects producing cells from the action of this pore-forming toxin. It is located into the cytoplasmic membrane. This protein has been 'tagged' with an epitope from the colicin A protein for which a monoclonal antibody is available. The fusion protein (named VL1) has been purified after extraction from the membrane in two steps using a chromatofocusing and an immunoadsorbant chromatography. The purified protein has then been reconstituted into lipid vesicles.     

HIGH LEVELS OF COLICIN RESISTANCE IN ESCHERICHIA COLI

Colicins are plasmid-encoded antibiotics that are produced by and kill Escherichia coli and other related species. The frequency of colicinogeny is high, on average 30% of E. coli isolates produce colicins. Initial observations from one collection of 72 strains of E. coli (the ECOR collection) suggest that resistance to colicin killing is also ubiquitous, with over 70% of strains resistant to one or more colicins. To determine whether resistance is a common trait in E. coli, three additional strain collections were surveyed. In each of these collections levels of colicin production were high (from 15 to 50% of the strains produce colicins). Levels of colicin resistance were even higher, with most strains resistant to over 10 colicins. A survey of 137 non-E. coli isolates revealed even higher levels of resistance. We discuss a mechanism (pleiotropy) that could result in the co-occurrence of such high levels of colicin production and colicin resistance.     

TonB-dependent energy transduction between outer and cytoplasmic membranes

The TonB system of Escherichia coli (and most other Gram-negative bacteria) is distinguished by its importance to iron acquisition, its contribution to bacterial pathogenesis, and a unique and mysterious mechanism of action. This system somehow gathers the potential energy of the cytoplasmic membrane (CM) proton gradient and delivers it to active transporters in the outer membrane (OM). Our understanding of this system is confounded by the challenge of reconciling often contradictory in vivo and in vitro studies that are presented in this review.     

The Evolution of Mass Cell Suicide in Bacterial Warfare

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