Interaction of the pore-forming domain of colicin A with phospholipid vesicles

Electroinsertion and activation of the C-terminal domain of colicin A, a voltage gated bacterial toxin, into mammalian cell membranes

The C-terminal fragment of colicin, a protein that is highly soluble in aqueous solution, is spontaneously and irreversibly inserted into the membranes of mammalian cells, which are locally permeabilized by a transmembrane voltage increase. Insertion is detected by immunodetection. This is obtained by mixing the protein with electropermeabilized cells. The same result is observed by pulsing the colicin/cell mixture. Electroinsertion is therefore obtained for the first time with a multi-fragment spanning protein. The cell viability is not affected beyond the effect of electropermeabilization. A train of low voltage repetitive transmembrane modulation, which cannot trigger membrane permeabilization, is applied a day after the electroinsertion. This induces no effect on unmodified cells but triggers the lysis of cells in which colicin has been inserted by the first electropulsation. The low-level electrical treatment is high enough to trigger the voltage gated opening of colicin and to induce the associated toxicity. A transmembrane configuration of colicin is therefore obtained by electroinsertion. The toxic effect of their voltage gating is only obtained when a critical number of voltage gated channels are activated.

Studies of mitochondrial porin incorporation parameters and voltage-gated mechanism with different black lipid membranes

Our work in general aims to clarify the mechanism of what can be considered as a process of the kinetics of porin incorporation into bilayer planar membranes and to identify the parameters involved. In this paper, we report the results of systematically investigating the kinetics of porin incorporation into bilayer membranes made up of phosphatidylinositol or oxidized cholesterol using a simple and low-cost ac method. By means of a mathematical model, we provide evidence that two concurrent processes are present during the kinetics which can be interpreted as positive/negative cooperativity, and we investigate the parameters' dependence on external applied voltages. We observed a phase transition (or similar phenomenon) which seems to take place during the insertion process. The conductance measurement obtained by using data at the steady state conditions, provided indirect indications of two possible gating mechanisms.

Molecular and functional characterization of a recombinant protein of Trichuris trichiura

The pore-forming protein of the human whipworm, Trichuris trichiura, has been postulated to facilitate invasion of the host gut and enable the parasite to maintain its syncytial environment. The data presented here describe the first, to our knowledge, molecular characterization of a pore-forming protein in any helminth and provide a unique demonstration of the functional interaction between a parasite antigen and host molecules. Immunological screening of a T. trichiura cDNA library with T. trichiura infection sera identified a clone of 1.4 kB, the cDNA consisting of 1495 base pairs encoding a protein of 50 kDa. The sequence has a highly repetitive nature containing nine four-disulphide-bonded core domains. Structural prediction analyses reveals an amphipathic nature. TT50 induced pore formation in bilayers in a manner identical to that of the native protein. IgG antibody isolated from T. trichiura infection serum was observed to abolish channel activity.

Solid-state NMR studies of the membrane-bound closed state of the colicin E1 channel domain in lipid bilayers

The colicin E1 channel polypeptide was shown to be organized anisotropically in membranes by solid-state NMR analysis of samples of uniformly 15N-labeled protein in oriented planar phospholipid bilayers. The 190 residue C-terminal colicin E1 channel domain is the largest polypeptide to have been characterized by 15N solid-state NMR spectroscopy in oriented membrane bilayers. The 15N-NMR spectra of the colicin E1 show that: (1) the structure and dynamics are independent of anionic lipid content in both oriented and unoriented samples; (2) assuming the secondary structure of the polypeptide is helical, there are both trans-membrane and in-plane helical segments; (3) trans-membrane helices account for approximately 20-25% of the channel polypeptide, which is equivalent to 38-48 residues of the 190-residue polypeptide. The results of the two-dimensional PISEMA spectrum are interpreted in terms of a single trans-membrane helical hairpin inserted into the bilayer from each channel molecule. These data are also consistent with this helical hairpin being derived from the 38-residue hydrophobic segment near the C-terminus of the colicin E1 channel polypeptide.

Membrane topology of the colicin A pore-forming domain analyzed by disulfide bond engineering

Four colicin A double-cysteine mutants possessing a disulfide bond in their pore-forming domain were constructed to study the translocation and the pore formation of colicin A. The disulfide bonds connected alpha-helices 1 and 2, 2 and 10, 3 and 9, or 3 and 10 of the pore-forming domain. The disulfide bonds did not prevent the colicin A translocation through the Escherichia coli envelope. However, the mutated colicins were able to exert their in vivo channel activity only after reduction of their disulfide bonds. In vitro studies with brominated phospholipid vesicles and planar lipid bilayers revealed that the disulfide bond that connects the alpha-helices 2 and 10 prevented the colicin A membrane insertion, whereas the other double-cysteine mutants inserted into lipid vesicles. The disulfide bonds that connect either the alpha-helices 1 and 2 or 3 and 10 were unable to prevent the formation of a conducting channel in presence of membrane potential. These results indicate that alpha-helices 1, 2, 3, and 10 remain at the membrane surface after application of a membrane potential.

In vivo and in vitro studies of the inhibition of the channel activity of colicins by gadolinium

The primary effects of the ionophoric colicins A, E1 and B on Escherichia coli cells include triggering an efflux of cytoplasmic potassium, and a decrease of internal ATP as consequences of the opening of ionic channels in the cytoplasmic membrane. We report that micromolar concentrations of gadolinium and other members of the lanthanide family inhibited the efflux of potassium and the ATP decrease and that the cells recovered both ATP and potassium within a few minutes. Gadolinium, in the same concentration range also efficiently inhibited the channel activity of colicins A, E1, B and of the isolated channel-forming domain of colicin A in planar lipid bilayers. Colicin N was much less sensitive to the trivalent ion in planar lipid bilayers, consistent with the lack of effect of gadolinium on this colicin in vivo. Our data suggest that lanthanide ions act by direct binding to the colicin molecule and that this binding affects both its single-channel conductance and gating behaviour.

The colicin A pore-forming domain fused to mitochondrial intermembrane space sorting signals can be functionally inserted into the Escherichia coli plasma membrane by a mechanism that bypasses the Tol proteins

Colicin A is a pore-forming bacteriocin that depends upon the Tol proteins in order to be transported from its receptor at the outer membrane surface to its target, the inner membrane. The presequence of yeast mitochondria cytochrome c1 (pc1) as well as the first 167 amino acids of cytochrome b2 (pb2) were fused to the pore-forming domain of colicin A (pfColA). Both hybrid proteins (pc1-pfCoIA and pb2-pfColA) were cytotoxic for Escherichia coli strains devoid of colicin A immunity protein whereas the pore-forming domain without presequence had no lethal effect. The entire precursors and their processed forms were found entirely associated with the bacterial inner membrane and their cytotoxicities were related to their pore-forming activities. The proteins were also shown to kill the tol bacterial strains, which are unable to transport colicins. In addition, we showed that both the cytochrome c1 presequence fused to the dihydrofolate reductase (pc1-DHFR) and the cytochrome c1 presequence moiety of pc1-pfCoIA were translocated across inverted membrane vesicles. Our results indicated that: (i) pc1-pfCoIA produced in the cell cytoplasm was able to assemble in the inner membrane by a mechanism independent of the tol genes; (ii) the inserted pore-forming domain had a channel activity; and (iii) this channel activity was inhibited within the membrane by the immunity protein.

The role of electrostatic charge in the membrane insertion of colicin A. Calculation and mutation

The bacterial toxin colicin A binds spontaneously to the surfaces of negatively charged membranes. The surface-bound toxin must subsequently, however, become an acidic 'molten globule' before it can fully insert into the lipid bilayer. Clearly, electrostatic interactions must play a significant role in both events. The electrostatic field around the toxin in solution was calculated using the finite-difference Poisson-Boltzmann method of the Delphi programme and the known X-ray structure. A large positively charged surface was identified which could be involved in the binding of colicin to negatively charged membranes. The applicability of the result was tested by also calculating the fields around modelled structures of the closely related colicins B and N. Surprisingly, colicin N showed a similar charge distribution in spite of its isoelectric point of pI 10.20 (colicin A has pI 5.44). One reason for this is the strong conservation of certain negative charges in all colicins. There is a single highly conserved aspartate residue (Asp78) on the positively charged face which provides a small but discrete region of negative charge. This residue, Asp78, was replaced by asparagine in the mutant D78N. D78N binds faster to negatively charged vesicles but inserts only half as fast as the wild-type protein into the membrane core. This indicates that, first, the initial membrane binding has a significant electrostatic component and, second, that the isolated charge on Asp78 plays a role in the formation of the insertion intermediate.

Structure of the membrane-bound form of the pore-forming domain of colicin A: a partial proteolysis and mass spectrometry study

The ion-channel-forming thermolytic fragment (thA) of colicin A binds to negatively charged vesicles and provides an example of the insertion of a soluble protein into a lipid bilayer. The soluble structure is known and consists of a 10-helix bundle containing a hydrophobic helical hairpin. In this study, partial proteolysis and mass spectrometry were used to determine the accessible sites to proteolytic attack by trypsin and alpha-chymotrypsin in the thA fragment in its membrane-bound state. Electrospray mass spectrometry was quite an efficient method for the identification of the cleavage products, even with partially purified peptide mixtures and with only few controls by N-terminal sequencing. This work confirms that a major part of the peptide chain lies at the membrane surface and that even the hydrophobic hairpin is not protected by the lipid bilayer from proteolytic degradation. In the absence of a membrane potential, the hydrophobic hairpin in the colicin A membrane-bound form seems not fixed in a transmembrane orientation.

Mapping a membrane-associated conformation of colicin Ia

Channel-forming colicins exist in at least two different membrane-associated conformations: a voltage-independent closed-channel state and a voltage-dependent open-channel state. In a voltage-independent membrane-associated conformation, we find that two major regions of colicin Ia are protected from pepsin proteolysis after association with negatively charged membranes. In contrast, colicin Ia is rapidly and completely proteolyzed in the absence of membranes. The major protected region includes an electrophysiologically defined C-terminal channel-forming domain as well as 96 residues upstream of this region. Approximately 100 residues spanning Ala79- approximately Arg189 within the N-terminal domain are protected as well. The first N-terminal 76 residues of colicin Ia and a large region which includes much of the putative central receptor-binding domain are not protected from proteolysis. Both N- and C-termini of protected peptides have been identified using a combination of gel electrophoresis, N-terminal sequencing, and mass spectrometry, thereby defining specific residues that are located on the outside of the lipid bilayer. These data suggest a role for regions other than the electrophysiologically defined C-terminal channel-forming domain in membrane insertion and channel formation.

Role of acidic lipids in the translocation and channel activity of colicins A and N in Escherichia coli cells

Colicins A and N are pore-forming bacterial toxins that kill Escherichia coli cells. Their mode of action involves three steps; binding to specific receptors located in the outer membrane, translocation through this membrane and the periplasm, and channel formation in the inner membrane. In-vitro studies have shown that negatively charged phospholipids are an absolute requirement for the channel formation of colicin A. Using HDL11 strain, in which the phosphatidylglycerol (PtdGro) content was altered by varying the synthesis of the PtdGro-phosphate synthase, the effect of envelope PtdGro content on the activity of colicin A was studied in vivo. The formation by colicin A of a voltage-gated channel in the cytoplasmic membrane results in an efflux of cytoplasmic potassium. This efflux is preceded by a lag time which is related to the time needed by the toxin to cross the cell envelope. This lag time is higher when the cells have a reduced PtdGro level, suggesting that the receptor/translocation machinery of colicin A (OmpF, BtuB and Tol QRAB proteins) is altered in the absence of PtdGro. The rate of potassium efflux is also greatly reduced when the PtdGro content is decreased, suggesting that a certain level of PtdGro is indeed required for proper insertion of the colicin-A channel. In contrast, the activity of colicin N does not show any PtdGro dependence. The difference between the behavior of colicin A and that of colicin N is discussed.

Colicin Ia inserts into negatively charged membranes at low pH with a tertiary but little secondary structural change

Colicin Ia, a member of the channel-forming family of colicins, inserts into model membranes in a pH- and lipid-dependent fashion. This insertion occurs with single-hit kinetics, requires negatively charged lipids in the target membrane, and increases in rate as the pH is reduced below 5.2. The low-pH requirement does not act by inducing a secondary structural change in colicin Ia, which remains 66% +/- 4% alpha-helical between pHs 7.3 and 3.1 as determined by circular dichroism. The secondary structure also remains unchanged between pHs 7.3 and 4.2 in the hydrophobic environment provided by the detergent octyl beta-D-glucopyranoside (beta-OG). However, at pH 3.1 in the presence of beta-OG, an 11% +/- 3% decrease in the alpha-helical content is observed. Further, beta-OG induces a change in tryptophan fluorescence and an altered pattern of proteolytic digestion, indicative of a tertiary structural changes. This suggests that colicin Ia undergoes a tertiary but little or no secondary structural change in its transition from a soluble to a transmembrane protein.

Interaction of the colicin-A pore-forming domain with negatively charged phospholipids

The interaction of colicin-A thermolytic fragment with negatively charged liposomes was studied by fluorescence spectroscopy. 1,2-Dioleoyl-sn-glycero-3-phospho-1-sn-glycerol (Ole2GroPGro) containing liposomes do not significantly alter the fluorescence properties of the protein, and thus cannot give much information about this interaction. 1,2-Bis(9,10-dibromooleoyl-sn-glycero-3-phospho-1-sn-glycerol (Br4Ole2GroPGro) is easily synthesized by addition of bromine atoms to the double bond located at the mid-point of the fatty-acid acyl chain of Ole2GroPGro. The brominated phospholipid forms vesicles that strongly quench the protein fluorescence emission. The results presented here show that conversion of Ole2GroPGro to Br4Ole2GroPGro does not change either the affinity for the protein or the extent of lipid binding. This observation allows for the estimation of the distribution of the quenching phospholipid molecules around the fluorophores [Yeager, M. D. & Feigenson G. W. (1990) Biochemistry 29, 4380-4392]. Binding of the protein to the vesicles is an irreversible process, since inserted molecules do not dissociate from the vesicle. From steady-state measurements, it can be concluded that in the membrane-bound form, the tryptophans are located within quenching distance of the bromine atoms, i.e. close to the lipid head-group/hydrocarbon boundary, completely accessible to the quencher, protected from the polar phase and that the maximum number of phospholipid molecules in contact with the fluorescent domain of the protein is nine.

The membrane insertion of colicins

Pore-forming toxins, such as colicin A, are water-soluble proteins that insert into lipid bilayers. The water-soluble structure of Colicin A is known at a high resolution and this review describes the kinetic and structural steps involved in its soluble-to-membrane bound transformation.

Refined structure of the pore-forming domain of colicin A at 2.4 A resolution

The E1 subgroup (E1, A, B, IA, IB, K and N) of anti-bacterial toxins called colicins is known to form voltage-dependent channels in lipid bilayers. The crystal structure of the pore-forming domain of colicin A from Escherichia coli has been refined to the diffraction limit of the crystals at 2.4 A resolution by means of molecular dynamics and restrained least-squares methods to a conventional R-factor of 0.18 for all data between 6.0 and 2.4 A resolution. The polypeptide chain of 204 amino acid residues consists of ten alpha-helices organized in a three-layer structure. The helices range in length from 9 to 23 residues with an average length of 125 residues. The packing arrangement of the helices has been analysed; the packing is different from that observed in four-helix bundle proteins. The sites of 83 water molecules have been located and refined. Analysis of the structure provides insights into the mechanism of formation of a voltage-gated channel by the protein. Although it is proposed that substantial tertiary structural changes occur during membrane insertion, the secondary structural elements remain conserved. This idea has been proposed recently for a number of other protein-membrane events and thus may have more general applicability.

Secondary structure of the membrane-bound form of the pore-forming domain of colicin A. An attenuated total-reflection polarized Fourier-transform infrared spectroscopy study

The structure of the pore-forming domain of the bacterial toxin colicin A was studied by attenuated total-reflection polarized Fourier-transform infrared spectroscopy. This channel-forming fragment interacts with dimyristoylglycerophosphoglycerol (Myr2GroPGro) vesicles and forms disk-like complexes. Analysis of the shape of the amide I' band indicates that its secondary structure is not affected by the pH 5.0-7.2. However, 5-10% of the peptide amino acids adopt an alpha-helical structure upon complex formation with Myr2GroPGro, while the random-coil and beta-sheet structure contents decrease. Interestingly, the increase in alpha-helical content is essentially due to an increase in the high-frequency component of the alpha-helical domain of amide I'. The fact that only this component was 90 degrees polarized (i.e. the helix is parallel to the acyl chain) suggests that only this particular type of helix is associated with the Myr2GroPGro bilayer.

Fluorescence energy transfer distance measurements using site-directed single cysteine mutants. The membrane insertion of colicin A

The ion-channel-forming C-terminal fragment of colicin A binds to negatively charged lipid vesicles and provides an example of insertion of a soluble protein into a lipid bilayer. The soluble structure is known from X-ray crystallography and consists of a ten-helix bundle containing a hydrophobic helical hairpin. In this work fluorescence spectroscopy was used to study the membrane-bound structure. An extrinsic probe, N'-(iodoacetyl)-N'-(5-sulfol-naphthyl)ethylenediamine (IAEDANS) was attached to mutant proteins each of which bears a unique cysteine residue. Three mutants K39C (helix 2), T127C (between helices 6 and 7) and S16Crpt (helix 1, which bears a decapeptide repeat before the mutation) gave useful derivatives. In the soluble protein they showed emission wavelengths decreasing in the order K39C greater than T127C greater than S16Crpt and although all showed blue shifts on addition of dimyristoylphosphatidylglycerol (DMPG) this order was maintained in the membrane-bound state. These shifts were not indicative of deep membrane insertion. Polarization of IAEDANS revealed differences in mobility between mutants. The three tryptophan residues were used as a compound donor to IAEDANS in resonance energy transfer distance determinations. The values obtained for the soluble form were 1.2 A to 3.2 A longer than in the crystal structure. On addition of lipids the indicated distances increased: S16Crpt-I(AEDANS) 6.45 A (22%), K39C-I 5.45 A (18%) and T127C-I 2.4 A (14%). N-bromosuccinimide (NBS) completely abolishes the tryptophan emission from the thermolytic fragment. When lipids were added to a mixture containing ten NBS-treated channel-forming fragments to one IAEDANS labelled fragment the indicated distances increased rather more: S16Crpt-I 9.7 A (38%), K39C-I 8.1 A (36%) and T127C-I 2.5 A (16%). This showed that intermolecular transfer reduces the distance estimated in samples containing only labelled protein. The ensemble of results shows that the amphipathic helices of the C-terminal fragment open out on the surface of the lipid bilayer during the initial phase of membrane insertion.

Liposomes as carriers of macrolides: preferential association of erythromycin A and azithromycin with liposomes of phosphatidylglycerol containing unsaturated fatty acid(s)

To assess the most favourable phospholipid composition of a liposomal carrier for antibiotics, small multilamellar liposomes were prepared from phosphatidylcholine, phosphatidylethanolamine and phosphatidylglycerol of varying fatty acid composition in the presence of erythromycin A and azithromycin. Crude liposomes were subjected to Sepharose CL-4B column chromatography, and liposomes containing antibiotics were well separated from free antibiotics. These experiments established that the greatest association of antibiotics was achieved with liposomes prepared from phosphatidylglycerol rather than phosphatidylcholine or phosphatidylethanolamine. Furthermore, the composition of fatty acids in phosphatidylglycerol liposomes influenced the amount of antibiotics associated with liposomes; the highest amount was obtained with dioleoylphosphatidylglycerol followed by phosphatidylglycerol of fatty acid composition similar to that of egg yolk lecithin. It was established that purified liposomes, prepared from [3H]phosphatidylglycerol containing unsaturated fatty acid(s) bind about 25 per cent of originally present antibiotic. Both antibiotics, erythromycin A and azithromycin, were similar in respect to the amount of their association with liposomes. Determination of the size of phosphatidylglycerol/antibiotic liposomes established that the mean diameter of liposomes containing antibiotics was 200-350 nm, very close to that of liposomes without them.

Membrane insertion of the pore-forming domain of colicin A. A spectroscopic study

In order to gain some insight into the mechanism of insertion into membranes of the pore-forming domain of colicin A and the structure of its membrane-bound form, circular dichroism (in the near and far ultraviolet), fluorescence and ultraviolet spectroscopy experiments were carried out. Because the structure of the water-soluble form of this fragment has been determined by X-ray crystallography, these spectroscopic methods provided valuable information on the secondary structure and the environment of aromatic residues within the two forms of the peptide. These results strongly suggest that the pore-forming domain of colicin A does not undergo drastic unfolding upon insertion into membrane. The conformational change associated with this process is triggered by the negatively charged lipids and probably consists of a reorientation of helix pairs with respect to each other. Exposure of the aromatic residues to the aqueous phase decreases on binding to lipids whilst the exposure of the tryptophans to the membrane phase increases. This cannot occur without a reorientation of helices 3-10. All data from this study support the model presented previously in which the known crystal structure opens like an 'umbrella' inserting the hydrophobic hairpin (helix 8-9) perpendicular to the membrane plane and the helical pair 1-2 and the domain containing the three tryptophans (helices 3-7) lying more or less parallel to the membrane plane. Lipids are bound more tightly to the protein at acidic pH than at neutral pH although a similar lipid protein complex is formed with 1,2-dimyristoyl-sn-glycero(3)-phospho(1)- -sn-glycerol at both pH values.

Interaction of phospholipids with proteins, peptides and amino acids. New advances 1987-1989

1. The review deals with the recent achievements in the study of the various interactions of phospholipids with proteins, peptides and amino acids. The interactions are classified according to the hydrophobic, hydrophilic or mixed character of the interactive forces. The effect of the interaction on the structure and biological activity of the interacting biomolecules is discussed.

Insights into membrane insertion based on studies of colicins

The recently determined three-dimensional structure of the pore-forming domain of colicin A has led to a hypothetical model for membrane insertion and channel formation. Certain features of this model have implications for understanding the mechanism of membrane insertion by other toxins and may have a broader relevance to protein transport in general.

Interaction of mitochondrial porin with cytosolic proteins

Intracellular phosphorylation is an important step in active uptake and utilization of carbohydrates. For example glucose and glycerol enter the liver cell along the extra intracellular gradient by facilitated diffusion through specific carriers and are concentrated inside the cell by phosphorylation via hexokinase or glycerol kinase. Depending on the function of the respective tissue the uptake of carbohydrates serves different metabolic purposes. In brain and kidney medulla cells which depend on carbohydrates, glucose and glycerol are taken up according to the energy demand. However, in tissues such as muscle which synthesize glycogen or like liver which additionally produce fat from glucose, the uptake of carbohydrates has to be regulated according to the availability of glucose and glycerol. How the reversible coupling of the kinases to the outer membrane pore and the mitochondrial ATP serves to fulfil these specific requirements will be explained as well as how this regulates the carbohydrate uptake in brain according to the activity of the oxidative phosphorylation and how this allows glucose uptake in liver and muscle to persist in the presence of high glucose 6-phosphate without activating the rate of glycolysis.