The formation and structure of Escherichia coli K-12 haemolysin E pores

doi:10.1099/mic.0.2007/011700-0

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The formation and structure of Escherichia coli K-12 haemolysin E pores

Stuart Hunt, Arthur J. G. Moir, Svetomir Tzokov, Per A. Bullough, Peter J. Artymiuk and Jeffrey Green

Krebs Institute for Biomolecular Research, Department of Molecular Biology and Biotechnology, University of Sheffield, Western Bank, Sheffield S10 2TN, UK

Correspondence
Jeffrey Green
jeff.green{at}sheffield.ac.uk
Peter J. Artymiuk
p.j.artymiuk{at}sheffield.ac.uk

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Some enteric bacteria synthesize a pore-forming toxin, HlyE,which is cytolytic and cytotoxic to host cells. Measurementof HlyE binding to erythrocyte ghosts and the kinetics of HlyE-mediatederythrocyte lysis suggests that interaction with target membranesis not the rate-limiting step in the formation of HlyE pores,but that there is a temperature-dependent lag phase before afunctional pore is formed. Circular dichroism and fluorescenceenergy transfer analyses show that HlyE protomers retain an ${alpha}$ -helical structure when oligomerized to form a pore consistingof parallel HlyE protomers. Comparison of the proteolytic sensitivitiesof the water-soluble and oligomeric forms of HlyE identifiesinner and outer surfaces of the pore. This new information hasbeen used to constrain a model of the HlyE pore, which allowsa more detailed interpretation of previous low-resolution 3Dreconstructions and suggests a novel mechanism for insertionof HlyE into target membranes.

Abbreviations: β-OG, n-octyl β-D-glucopyranoside

Two supplementary figures of models of octameric and 13-mericHlyE pores showing proteolytic cleavage sites and of the locationsof proteolytic sites mapped onto an HlyE protomer are availablewith the online version of this paper.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Many pathogenic bacteria produce toxins to disrupt host-cellfunctions. Haemolysin E (HlyE; also known as ClyA or SheA) isa pore-forming toxin synthesized by Escherichia coli and otherenteric bacteria (del Castillo et al., 1997; Green & Baldwin,1997; Ludwig et al., 1999, 2004; Oscarsson et al., 1996, 2002).HlyE lyses mammalian erythrocytes, is cytotoxic toward culturedmammalian cells, and induces apoptosis in macrophages (Lai etal., 2000). Recently, it has been shown that HlyE antibodiesare present in humans that have been infected with either Salmonellaenterica serovar Typhi or serovar Paratyphi A, suggesting thatHlyE is involved in pathogenesis (von Rhein et al., 2006). Furthermore,the hlyE gene is present in 45 % of extraintestinal E. coliclinical isolates (Kerenyi et al., 2005). Regulation of hlyEexpression is complex and is influenced by several environmentalsignals. A single site in the hlyE promoter enhances expressionin response to oxygen starvation when occupied by FNR (regulatorof fumarate nitrate reduction) (Green & Baldwin, 1997; Wybornet al., 2004b) and in response to glucose starvation when occupiedby CRP (cAMP receptor protein) (Westermark et al., 2000; Wybornet al., 2004b). In addition, the nucleoid-structuring proteinH-NS has a negative effect on FNR-driven hlyE expression anda positive effect on CRP-driven hlyE expression (Westermarket al., 2000; Wyborn et al., 2004b). Furthermore, it is thoughtthat H-NS-mediated repression is antagonized by a fourth transcriptionfactor, SlyA (Wyborn et al., 2004b).

The 3D structure of the water-soluble form of HlyE shows thatit is a 34 kDa rod-shaped molecule consisting of a bundleof four long [80–90 Å (8–9 nm)]helices, which coil around each other with significant elaborationsat both poles of the four-helix bundle (Fig. 1; Wallaceet al., 2000). At the end containing the N- and C-terminal regionsof the protein a shorter [30 Å (3 nm)] helix( ${alpha}$ G) packs against the four long helices, forming a five-helixbundle for about one-third of the length of the molecule (thetail domain). Random and site-directed mutagenesis has revealedthat residues in the ${alpha}$ G region play important roles in HlyE activity(Atkins et al., 2000; Oscarsson et al., 1999). HlyE possessesonly two cysteine residues and these are housed in the taildomain (Fig. 1). It has been reported that the redox stateof the protein (dithiol, in the cytoplasm and outer-membranevesicles, or disulphide, in the periplasm) affects the oligomericstate of HlyE (Atkins et al., 2000; Wai et al., 2003), but morerecently both reduced and oxidized HlyE has been shown to beactive (Eifler et al., 2006). At the other end of the rod thereis a subdomain (the head domain) that consists of a short two-strandedhydrophobic antiparallel β-sheet flanked by two short helices(the β-tongue) (Fig. 1a; Wallace et al., 2000). Site-directedmutagenesis has shown that the hydrophobic nature of the β-tonguehas to be maintained to allow HlyE to bind to and lyse targetcells (Oscarsson et al., 1999; Wallace et al., 2000). In thecrystal structure, HlyE is a head-to-tail dimer in which thehydrophobic β-tongue of one protomer packs against a secondhydrophobic surface in the tail domain of the second protomer(Fig. 1b; Wallace et al., 2000). Furthermore, gel filtrationshows that in solution E. coli K-12 HlyE exists as a mixtureof monomers, dimers and higher-order aggregates (Atkins et al.,2000), and that HlyE from an avian pathogenic E. coli is predominantlydimeric (Wyborn et al., 2004a). Thus, it would appear that theoligomeric state of HlyE in solution is dynamic and that themonomeric form of the protein is perhaps the form most likelyto form initial interactions with a target membrane, becausethe hydrophobic β-tongue is exposed.

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Fig. 1. 3D structure of HlyE. (a) The HlyE monomer; the HlyE protein main chain is shown. The locations of the N and C termini, ${alpha}$ G, the two Cys residues (black circles), the four-helix bundle, the β-tongue and the head and tail domains are indicated. (b) The structure of the HlyE dimer. The two HlyE monomers form a head-to-tail dimer across the twofold axis. The hydrophobic β-tongue of one monomer packs against a hydrophobic surface, formed from residues at the C-terminal end of ${alpha}$ B and neighbouring side chains in ${alpha}$ C and ${alpha}$ G, of the other monomer. The individual monomers are shown in dark and light grey.

HlyE disrupts host cells by forming pores in target membranes(Wallace et al., 2000

). Initial electron micrographs of thepores suggested that HlyE does not undergo large conformationalchanges during pore formation (Wallace et al., 2000

). However,two recent descriptions of 3D reconstructions have revealedthat the HlyE pores are longer than the water-soluble form ofthe protein, indicating that significant conformational changesare necessary to form a functional pore (Eifler et al., 2006

;Tzokov et al., 2006

). Although both reconstructions were generatedfrom very similar objects, the interpretation of the data ledto the conclusion that the HlyE pore was predominantly octamericin one case (Tzokov et al., 2006

) and predominantly 13-mericin the other (Eifler et al., 2006

). The reason for the discrepancyis unclear.

Eifler et al. (2006) proposed a model of pore formation in whichmembrane-bound HlyE monomers undergo a rate-limiting conformationalchange that precedes oligomerization to form a pore. We reporthere an analysis of the formation and structure of the HlyEpore that shows: (i) interaction with target membranes is notthe rate-limiting step in the formation of HlyE pores; (ii)HlyE protomers retain a mostly ${alpha}$ -helical structure when oligomerizedto form a pore; (iii) HlyE protomers in the oligomer are parallel.In addition, we have used partial proteolysis of the water-solubleand oligomeric forms of HlyE to identify the inner and outersurfaces of the HlyE pore. This information was used to constraina model of an octameric assembly of HlyE protomers, allowinga more detailed interpretation of the 3D reconstructions ofthe HlyE pore obtained by electron microscopy.

METHODS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Haemolysin assay.
HlyE activity was measured essentially as described by Rowe& Welch (1994). Briefly, HlyE protein (isolated as previouslydescribed; Atkins et al., 2000) was incubated with defibrinatedsterile horse blood (TCS Microbiology) in Tris-buffered saline(50 mM Tris/HCl, pH 8.0, containing 150 mM NaCl).The amount of haemolysis was determined spectrophotometricallyby measuring haemoglobin release at 543 nm in cell-freesupernatants prepared by centrifugation of reactions at 3000 r.p.m.in a bench top microcentrifuge for 30 s. Total haemolysis(100 %) was defined by incubation of red blood cells in water,in place of buffer, and measuring A₅₄₃ of the supernatant. Theeffects of n-octyl β-D-glucopyranoside (β-OG; Roche)on HlyE activity were determined by measuring the haemolyticactivity of samples of HlyE protein (1 µM final concentration)after incubation at 20 °C for 30 min in the presenceof the indicated concentrations of β-OG.

Measurement of haemolysis kinetics.
Erythrocyte suspension (400 µl of $~$ 1x10⁸ cells ml^–1)in Tris-buffered saline was placed in a fluorimetry cuvette.The contents were equilibrated to the indicated temperaturesand the reaction was initiated by the addition of HlyE (10 µl;final concentration 2.5 µM). Haemolysis was monitoredin a Cary Eclipse Fluorescence Spectrophotometer set at 590 nmfor both excitation and detection. Each assay was repeated atleast twice. Activation energies for the lag and haemolyticphases were calculated as described by Harris et al. (1991).

Western blotting.
The amount of HlyE bound to horse erythrocytes was estimatedby Western blotting. After incubation of HlyE protein (12 nM,600 ng) with horse red blood cells (2x10⁹ cells in 1.5 ml,measured by counting the number of red blood cells using a haemocytometerand suitable dilutions of the red blood cell suspension) forthe indicated times, the reactions were centrifuged (see above)to isolate supernatant and membrane fractions. The membranefraction was washed once with 1 ml Tris-buffered salineand then solubilized in loading buffer for SDS-PAGE (Sambrook& Russell, 2001). After determining the amount of haemolysisby measuring the A₅₄₃ of the supernatants, aliquots were alsoprepared for electrophoresis by mixing with SDS-PAGE loadingbuffer. After electrophoresis, the proteins were transferredfrom the polyacrylamide gels (15 %) to nitrocellulose (HybondC extra, Amersham). The blots were probed with anti-HlyE serum(1 : 20 000, raised in rabbits) for 3 h, before washingand exposure to HRP-linked anti-rabbit IgG and detection byECL-Plus (Amersham). The resulting films were analysed by quantitativedensitometry using the Imagemaster software package (Amersham).

Circular dichroism spectroscopy.
Far-UV circular dichroism spectra were recorded using a JascoJ-810 spectropolarimeter with HlyE protein (400 nM) in20 mM sodium phosphate buffer, pH 7.0. To observethe effects of oligomerization on HlyE secondary structure,the protein was pre-incubated for 30 min at 20 °Cwith β-OG (20 mM).

Electron microscopy.
Negatively stained images of HlyE pores in β-OG were obtainedessentially as described by Tzokov et al. (2006), except thatthe β-OG concentration used was 20 mM (1x criticalmicelle concentration).

Fluorimetry.
Aliquots of HlyE protein (6 µM) were labelled byincubation at 4 °C for 16 h in the presence ofa 10-fold molar excess of either isothiocyanate or maleimidederivatives of fluorescein or rhodamine (Molecular Probes) dissolvedin dimethylformamide. Unreacted probe was quenched by additionof either lysine (1 mM) or DTT (1 mM), as appropriate.Labelled protein was isolated by size exclusion chromatographyusing Hi-Trap desalting columns (GE Healthcare) equilibratedwith Tris-buffered saline, and the extent of protein labellingwas estimated spectrophotometrically using molar absorptioncoefficients of 83 000 M^–1 cm^–1 forfluorescein and 95 000 M^–1 cm^–1 for rhodoamine.The HlyE proteins ( $~$ 0.2 mg ml^–1) labelled atLys residues carried an average of 3.3 labels per molecule,whereas the Cys-labelled proteins carried 0.4 labels per HlyE.The haemolytic activities of the labelled proteins were similarto that of unlabelled HlyE, which had been similarly treatedwith dimethylformamide only, except for HlyE labelled at Lysresidues with fluorescein, which retained 30 % of the activityobserved with the unlabelled protein. In all experiments theratio of donor molecules to acceptor molecules based on proteinconcentration was 1 : 7. Erythrocyte ghosts were prepared byadding 2 ml defibrinated horse blood ( $~$ 10¹⁰ cells) to 100 ml5 mM phosphate buffer, pH 7.5 containing 1 mMEDTA to lyse the red blood cells. The membrane fraction wasseparated from the soluble fraction by centrifugation for 20 minat $~$ 20 000 g at 4 °C. After repeated washing, haemoglobin-freemembranes were collected by centrifugation. The membranes weresuspended in 2 ml 10 mM phosphate buffer, pH 7.5containing 5 mM MgCl₂ and partially resealed by incubationat 37 °C for 30 min. Erythrocyte ghosts were addedto a final concentration equivalent to $~$ 5x10⁷ erythrocytes ml^–1.Fluorescence energy transfer was measured by exciting the fluorescein-labelleddonor molecules at 470 nm and recording the emission spectrafrom 500 to 600 nm using a Cary Eclipse Fluorescence Spectrophotometer(Varian).

For intrinsic tryptophan fluorescence measurements the excitationwavelength was 280 nm and emission spectra were collectedat 300–480 nm using a Cary Eclipse Fluorescence Spectrophotometer(Varian).

Partial proteolysis of HlyE.
Aliquots of HlyE (35 µg) in PBS, in the presenceor absence of 50 mM β-OG, were proteolytically digestedwith trypsin, ${alpha}$ -chymotrypsin, Asp-N or V8 protease, with proteaseto protein ratios of 1 : 20 at 37 °C. Samples weretaken hourly and either immediately frozen at –20 °Cfor analysis by MS or mixed with SDS-PAGE loading buffer (Sambrook& Russell, 2001) and heated at 95 °C for 10 minfor analysis by SDS-PAGE. In the latter case, after electrophoresisthe polypeptides were blotted onto a PVDF membrane and excisedfor analysis by N-terminal sequencing (Procise 392, ABI). Alternatively,samples were analysed by MS using an ABI Voyager-DE STR MALDImass spectrometer operating in positive-ion mode. Peptide analysiswas performed in reflector mode using ${alpha}$ -cyano-4-hydroxy-cinnamicacid (Sigma) as matrix; sinapinic acid (ABI and Fluka) was usedas the matrix for protein analysis. Both were prepared immediatelybefore use at a concentration of 10 mg ml^–1in 50 % acetonitrile containing 0.05 % trifluoroacetic acid.Typically, peptide and protein samples were diluted three- tofivefold with matrix and 1 µl was spotted onto theMALDI plate. The spectrometer was calibrated using commerciallyavailable calibration standards (ABI and Sigma).

Model building.
Models of HlyE multimeric assemblies were created by applicationof symmetry to the crystallographic coordinates of the monomer(Wallace et al., 2000). The centre of gravity of the monomerwas placed on the origin and its major axis aligned with thez axis of the coordinate system. The distribution of protectedand unprotected cleavage sites on monomeric coordinates wasobserved, and the monomer was translated orthogonally from thez axis so as to maximize the number of unprotected proteolyticcleavage sites on the outside of the model of the multimer.A translation of $~$ 40 Å ( $~$ 4 nm) was used to giveagreement with the electron microscopic observations of thesize of the pore (Eifler et al., 2006; Tzokov et al., 2006).Symmetric pore models were then created by application of n-foldsymmetry around the z axis (where n=7–13), and improvedby rigid-body rotations of the initial monomeric model.

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Binding of HlyE to target cells
After recognizing a membrane target, HlyE must switch from awater-soluble dimer (Wallace et al., 2000; Wyborn et al., 2004a)to a membrane-bound oligomer. To investigate the kinetics ofthis switch, horse blood (2x10⁹ cells in 1.5 ml) was incubatedwith purified HlyE (12 nM; 600 ng) at 15 and 37 °C,and samples (0.15 ml) were withdrawn at the indicated times(Fig. 2a). Membrane-bound HlyE was estimated by Westernblotting and red blood cell haemolysis was measured. This revealedthat although the extent of haemolysis was much greater at 37 °Cthan at 15 °C and cell lysis continued to increaseup to 180 min, the binding of HlyE at both temperatureswas maximal within 5 min (the first sample point in theseexperiments) (Fig. 2a). In other experiments the amountof HlyE remaining in solution was found to be similar afterincubation with red blood cells for 1, 2, 5 and 10 minat 17, 22, 27, 32 and 37 °C (not shown). Furthermore,pre-incubation of HlyE (12 nM) with erythrocytes (2x10⁸cells) at 15 °C for 20 min to allow HlyE bindingwith minimum cell lysis (8.9±0.7 % lysis) did not enhancecell lysis upon transfer to 37 °C for 15 min (82±0.3% lysis) compared to control reactions that were not pre-incubatedat 15 °C, but held at 37 °C for 15 min(70±5.5 % lysis). Thus, it was concluded that the bindingof HlyE to a target membrane is not the rate-limiting step inpore formation.

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Fig. 2. The effect of temperature on HlyE binding to and lysis of target cells and the effects of detergent on the secondary structure, oligomeric state and activity of HlyE. (a) A sample of HlyE (12 nM, 600 ng) was added to horse erythrocytes (2x10⁹ cells in 1.5 ml) and incubated at 15 or 37 °C. The extent of haemolysis of the red blood cells ( ${blacklozenge}$ , 15 °C; ${blacksquare}$ , 37 °C) and the relative amounts of erythrocyte-associated HlyE, measured by Western blotting ( ${lozenge}$ , 15 °C; ${square}$ , 37 °C) were estimated at the indicated times. (b) Inhibition of HlyE activity by pre-incubation at 20 °C for 30 min in the presence of the indicated concentrations of β-OG. HlyE activity was measured at 37 °C in reactions containing 1 µM HlyE. An activity of 100 % was defined as that obtained in the absence of β-OG. The points represent means±SD (n=3). (c) Electron micrograph of HlyE after incubation with β-OG. The micrograph shows negatively stained HlyE oligomers after incubation with β-OG (20 mM) at 20 °C for 30 min. Top views of HlyE pores (arrowed) with similar dimensions to those observed in lipid vesicles are visible. (d) Circular dichroism spectra of HlyE protein (400 nM) in 20 mM sodium phosphate buffer, pH 7.0, in the absence (solid line) and presence (dashed line) of β-OG (20 mM, pre-incubated at 20 °C for 30 min). (e) Intrinsic tryptophan fluorescence spectra of HlyE protein (600 nM) in 20 mM sodium phosphate buffer, pH 7.0, in the absence (lower line) and presence (upper line) of 20 mM β-OG.

Incubation of HlyE for 30 min at 20 °C in thepresence of different concentrations of the detergent β-OGresulted in inhibition of HlyE activity (Fig. 2b

), andinduced the formation of HlyE pores that resembled those formedin lipid vesicles (Fig. 2c

). Incubation of HlyE with β-OG(20 mM) resulted in the protein eluting in the void volumewhen subjected to gel filtration on Sepharose 6B, indicatinga molecular mass of $~$ 500 000 (results not shown). However, incubationwith β-OG did not significantly alter the circular dichroismspectrum of HlyE, which was typical of a protein rich in ${alpha}$ -helices,consistent with the crystal structure (Fig. 2d

). Together,these results suggest that HlyE oligomerization is not accompaniedby major changes in the ${alpha}$ -helical content of the protein. However,this does not mean that there are no significant structuralrearrangements upon pore formation. For example, the circulardichroism spectra of pneumolysin show relatively small changesin the presence or absence of cholesterol (Kelly & Jedrzejas,2000

), but there are major rearrangements of pneumolysin proteindomains during the process of pore formation (Tilley et al.,2005

The HlyE protein has two Trp residues (Trp37 and Trp86). Inthe water-soluble form these Trp residues are located closetogether approximately at the mid-point of the HlyE rod. Intrinsictryptophan emission spectra of HlyE exhibited an emission maximumat 334 nm, suggesting that both Trp residues are essentiallysolvent-shielded (Fig. 2e). This is consistent with thecrystal structure, which shows that only the edge of Trp37 issurface-exposed and that Trp86 is buried. Detergent (20 mMβ-OG)-triggered oligomerization of HlyE caused a significantincrease in intrinsic tryptophan fluorescence without alteringthe emission maximum (Fig. 2e). This suggests that uponoligomerization there are conformational changes in which theHlyE Trp residues remain solvent-shielded but become less ordered,causing an enhancement in fluorescence.

Kinetics of HlyE-mediated red blood cell lysis
Measurement of the kinetics of HlyE-mediated lysis of red bloodcells showed that there was a temperature-dependent lag phasebefore haemolysis was detected (Fig. 3a). By plotting thereciprocal of the length of the lag phase against the reciprocalof the temperature it was possible to obtain a value of 60.2±2.7 kcal mol^–1(251.9±11.3 kJ mol^–1) for the activationenergy of the events occurring during the lag phase. From therates of haemolysis following the lag phases the activationenergy for haemolysis was calculated to be 23.3±0.5 kcal mol^–1(97.5±2.1 kJ mol^–1) (Fig. 3b).

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Fig. 3. Kinetics of HlyE-mediated erythrocyte lysis at different temperatures. (a) Lysis of erythrocytes ( $~$ 4x10⁷ cells in Tris-buffered saline) was determined by the decrease in light scattering upon addition of HlyE (2.5 µM final concentration) at the indicated temperatures. (b) Arrhenius plots of HlyE lag phase and haemolysis. The activation energy for the lag phase ( ${blacksquare}$ ) was determined by plotting the reciprocal of the lag phase (1/t_lag) against the reciprocal of the temperature (1/T). The activation energy for haemolysis ( ${blacklozenge}$ ) was determined by plotting the log of the initial rate (k₀) against the reciprocal of the temperature.

Conformational changes in HlyE upon membrane binding
The HlyE monomer possesses 32 Lys residues that could potentiallybe labelled with isothiocyanate derivatives of the fluorescentdyes fluorescein and rhodamine. The emission spectrum of HlyElabelled with fluorescein (HlyE_DK) in the absence of an acceptorwas enhanced in the presence of erythrocyte ghost membranes(Fig. 4a

, compare spectra I and II). This suggests thatupon interaction with a membrane, HlyE undergoes conformationalchanges that enhance HlyE_DK fluorescence. In the presence ofmembranes and an acceptor (HlyE labelled with rhodamine; HlyE_AK),HlyE_DK fluorescence was quenched and a fluorescence energy transfersignal was apparent at 560–580 nm (Fig. 4a

,spectrum III). However, a fluorescence energy transfer signalwas observed in the absence of membrane (Fig. 4a

, spectrumIV), suggesting that, at least in part, the fluorescence energytransfer is due to exchange of protomers between HlyE dimers.Therefore, a second experiment, using fluorescent labels attachedto the Cys residues of HlyE, was done.

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Fig. 4. Fluorescence energy transfer between HlyE molecules in the presence of target membranes. (a) All samples contained HlyE (2.5 µg) labelled with fluorescein at Lys residues (HlyE_DK). Spectra were obtained in the absence of membranes (spectrum I), the presence of membranes (spectrum II), the presence of membranes and acceptor [HlyE, 10 µg, labelled with rhodamine at Lys residues (HlyE_AK) (spectrum III)] and the presence of acceptor without membranes (spectrum IV), at 37 °C in a total volume of 450 µl. The excitation wavelength was 470 nm. (b) As for (a), except that the donor was HlyE labelled with fluorescein at Cys residues (HlyE_DC), and the acceptor was HlyE labelled with rhodamine at Cys residues (HlyE_AC).

The HlyE protein contains two Cys residues that are capableof forming an intramolecular disulphide bond (Atkins et al.,2000

). These Cys residues are located at the opposite pole (thetail region; Fig. 1

) of the protein to that which interactswith target membranes (Atkins et al., 2000

; Eifler et al., 2006

;Tzokov et al., 2006

; Wallace et al., 2000

), and in the HlyEdimer the two pairs of cysteine residues are $~$ 45 Å(4.5 nm) apart. The Cys thiol groups were labelled withmaleimide derivatives of the fluorescent dyes fluorescein andrhodamine. The emission spectrum of HlyE labelled with fluorescein(HlyE_DC) in the absence of an acceptor was enhanced upon additionof erythrocyte ghost membranes, suggesting that the tail regionof HlyE undergoes conformational changes that enhance HlyE_DCfluorescence (Fig. 4b

, compare spectra I and II). In thepresence of an acceptor (HlyE labelled with rhodamine; HlyE_AC)and a target membrane, HlyE_DC fluorescence was quenched anda fluorescence energy transfer signal was apparent at 560–580 nm(Fig. 4b

, spectrum III). This fluorescence energy transfersignal was not observed in the absence of membrane (Fig. 4b

,spectrum IV), suggesting that membrane-bound HlyE moleculesare parallel, in contrast to the anti-parallel arrangement ofthe soluble dimer (Wallace et al., 2000

). All the responsesdescribed above were rapid, the reactions being complete within30 s at temperatures in the 17–37 °C range.These observations suggest that HlyE dimer–monomer transitions,HlyE–membrane interactions and HlyE–HlyE interactionsare not likely to be rate-limiting steps in target cell lysis.

Partial proteolysis of water-soluble and oligomeric HlyE, and construction of oligomeric pore models
To map regions that interact in the HlyE oligomer, the proteolyticdigest patterns of water-soluble and β-OG (50 mM)-triggeredHlyE oligomers were compared (Table 1). The identifiedcleavage points were plotted on the water-soluble HlyE structure,revealing regions that were protected from digestion in theHlyE oligomer (residues highlighted in purple, Fig. 5),and further regions that were accessible in both the water-solublemonomeric and dimeric forms and the oligomeric forms of theprotein (residues highlighted in green, Fig. 5).

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Table 1. Identification of sites sensitive to proteolysis in water-soluble and oligomeric HlyE

Aliquots of HlyE protein (1 nmol in 250 µl PBS) were incubated at 37 °C with trypsin, ${alpha}$ -chymotrypsin, Asp-N or V8 protease. Samples (10 µl) were removed at intervals and analysed by SDS-PAGE and N-terminal amino acid sequencing or by MS to identify the peptide bonds in HlyE that are sensitive to proteolytic cleavage. Sites highlighted in bold type are unique to the indicated condition.

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Fig. 5. Model of the proposed octameric HlyE assembly showing proteolytic cleavage sites. Views are shown of a simple space-filling model of an octameric pore assembly illustrating the relative orientations of the HlyE protomers (a) from the side and (b) from above. (c) A slightly tilted view of the model with six of the protomers made semi-transparent to give a clear view of the remaining two, chosen to show the positions of the proteolytic cleavage points on the outside (left protomer) and inside (right protomer) of the assembly. (d) A view of the inside surface of the pore model with dimensions of the model indicated. (e) A cartoon view of the HlyE backbone indicating the spatial relationship between ${alpha}$ G (light blue) and the C-terminal (red) of one protomer (pale brown) and the adjacent protomer (white). In all the representations, alternate protomers are coloured white and pale brown, and the 24-residue hydrophobic sequence that includes the β-tongue, which is required for membrane binding, is coloured dark grey. The C-terminal ${alpha}$ G helix is coloured light blue. Proteolytic cleavage sites observed in both the water-soluble and oligomeric forms of HlyE are coloured green and labelled in black, cleavage sites protected in the oligomer are coloured and labelled in purple, and the residue (Asp21) that is sensitive in the oligomer, but not in the water-soluble form of HlyE, is coloured and labelled in dark blue. Diagrams were produced using PyMOL (DeLano & Lam, 2005

Recently, two 3D reconstructions based on analyses of electronmicrographs of the HlyE pore have been described (Eifler etal., 2006

; Tzokov et al., 2006

). These analyses suggest thatthe HlyE pore is either predominantly octameric (Tzokov et al.,2006

), or predominantly 13-meric (Eifler et al., 2006

). Here,pore models constrained by partial proteolysis data were generatedas described in Methods. Both octameric and nonameric modelshad radial dimensions that agreed well with the electron microscopicobservations (Eifler et al., 2006

; Tzokov et al., 2006

). However,because the water-souble HlyE monomer is only 100 Å(10 nm) long, the length of the assembly is significantlyshorter than the 140 Å (14 nm) observed in electronmicrographs (Eifler et al., 2006

; Tzokov et al., 2006

). Theoctameric model yielded a lightly packed assembly of subunits(Fig. 5a–d

), whereas there were a small number ofsteric clashes in the nonameric model, which became more severein larger oligomers, unless the diameter of the model was increased.Thus, a 13-meric pore with similar interactions to the octamericmodel can be constructed, but requires a maximum diameter ofmore than 150 Å (15 nm; see Supplementary Fig.S1). This diameter is larger than that observed in electronmicrographs, but possibly at the outer limit of the errors insize measurement. Therefore, because of its agreement with thedata presented here, and with the symmetry analyses of HlyEelectron micrographs by Tzokov et al. (2006)

, the octamericmodel was adopted (Fig. 5d

The model places the majority of the sites cleaved in the oligomeron the outside of the assembly (Fig. 5). The exceptionto this is Glu258, which is situated at the beginning of theturn between ${alpha}$ F and ${alpha}$ G and is located on the inside ‘upperrim’ of the assembly (Fig. 5c, and see SupplementaryFig. S2). Examination of the octameric model in detail revealsthat ${alpha}$ G of each protomer leans towards the groove between ${alpha}$ A and ${alpha}$ F in the neighbouring protomer (Fig. 6a, e), positioningthe C-terminal residues (which are only partially ordered inthe crystal structure of the monomer) in the groove. This featureof the model is congruent with the deleterious effects on poreassembly of the deletion of ${alpha}$ G and the C-terminal residues (Atkinset al., 2000; Oscarsson et al., 1999). It is also notable thatthe only proteolytic cleavage point that is seen in the multimer,but not in the monomer, is at Asp21 (Fig. 5c). Asp21 formsa hydrogen bond with Thr284 in ${alpha}$ G, possibly indicating a minorconformational change in this region, which may also accountfor the protection of Glu18, the only cleavage point on theoutside of the model that is protected. The paucity of new cleavagesites in the oligomer compared to the water-soluble proteinsuggests that any conformational changes are likely to be limited.

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Fig. 6. Model of an HlyE pore showing a putative membrane-spanning helical structure. (a) Structure of the head domain of HlyE with the hydrophobic residues in grey and the hydrophilic ones in orange; the hydrophobic putative transmembrane sequence including the β-tongue is on the left, the amphipathic (orange and grey) helix E is on the right; part of the main body of the protomer is in cyan. (b) Model in which the hydrophobic sequence becomes a single transmembrane helix (grey, left) and the polypeptide chain returns to the main body of the protomer via a realigned amphipathic helix E (orange and grey, right). (c) The hydrophilic face of helix E (shown entirely in orange for clarity) can then form the inner lining of a pore, while its hydrophobic face packs against the new transmembrane helix (grey) which interacts with lipid (shown schematically). (d) An octameric pore can be constructed based on the octameric ${alpha}$ -helical barrel observed in Wza, shown in side view and looking down the eightfold axis (e). (f) An overview of the resulting model coloured as in Fig. 5

and Supplementary Figs S1 and S2.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

HlyE-mediated cell lysis is the product of a complex seriesof steps in which HlyE must recognize and bind to the targethost-cell membrane and then assemble to form a functional pore.Previous evidence suggests that water-soluble HlyE exists asa mixture of monomers and dimers (Atkins et al., 2000

; Wallaceet al., 2000

; Wyborn et al., 2004a

). It is suggested that theHlyE dimer, in which the hydrophobic surfaces in the head (β-tongue)and tail (residues located in helices B, C and G) are shieldedfrom the solvent, helps maintain HlyE in a water-soluble form.Thus, it is likely that the monomeric and dimeric forms of HlyEare in equilibrium, and the data presented here suggest thatbinding of HlyE monomers, with a solvent-exposed β-tongue,to a target membrane is fast. The fluorescence energy transferexperiments suggest that following interaction with the membrane,HlyE protomers rapidly oligomerize. Thus, it is suggested thatneither membrane binding nor initial interactions between membrane-boundHlyE monomers are rate-limiting steps in creating a functionalpore. Nevertheless, during these rapid phases HlyE undergoesconformational changes in regions, including those (tail domain,Fig. 1

) that are remote from the β-tongue, which areessential for interaction with a membrane (Wallace et al., 2000

;Oscarsson et al., 1999

). The changes in HlyE conformation arelikely to be required for binding the membrane and for subsequentinitial interactions between HlyE protomers to form parallelmembrane-bound HlyE oligomers. This rapid phase is then followedby a slow component, most apparent as a temperature-dependentlag phase, with relatively high activation energy, before haemolysisoccurs. Taken together, these observations indicate that whereasHlyE binding to a host-cell membrane and initial oligomerizationare rapid, functional pore formation is a slower process. Sucha mechanism accounts for the relatively poor haemolysis observedat 15 °C compared to 37 °C and the need forprolonged incubation for cell lysis to occur at low HlyE concentrations.In these respects, HlyE resembles the HlyA protein of E. coli(Eberspacher et al., 1989

). Thus, the data presented broadlysupport the conclusions of Eifler et al. (2006)

, who also suggestthat there is a rate-limiting conformational transition in membrane-boundHlyE that precedes the formation of a functional pore. It isnow suggested that the slowly reacting monomeric intermediateproposed by Eifler et al. (2006)

contains an oligomeric component.

Recently, two 3D reconstructions of the HlyE pore have beenreported, which although they represent the same object, apparentlycontain different numbers of subunits (Eifler et al., 2006;Tzokov et al., 2006). The reasons for this discrepancy are notclear. Nevertheless, several features of the modelled HlyE poreshown in Fig. 5 are consistent with the 3D reconstructions(Eifler et al., 2006; Tzokov et al., 2006). Thus, in the simplemodel shown in Fig. 6 the hydrophobic β-tongue isoutward facing, and thus has the potential to interact withthe lipid tails of a target membrane bilayer. At the oppositeend of the pore there is a region of $~$ 35 Å ( $~$ 3.5 nm)in length over which the channel wall is thicker (Eifler etal., 2006; Tzokov et al., 2006). The tail domain of HlyE occupiesthis region in the constrained model shown in Fig. 6, andthe presence of the 35 Å (3.5 nm) ${alpha}$ G helix thatcontributes to the five-helix bundle of the tail domain (Fig. 1)is consistent with the channel wall thickening in this regionof the reconstructions (Eifler et al., 2006; Tzokov et al.,2006). Furthermore, the orientation of the HlyE subunits inFig. 5 creates a negatively charged inner surface, consistentwith zero-current membrane potential measurements (Ludwig etal., 1999). The nature of the conformational changes that resultin the observed elongation of the HlyE pores remains unknown(Eifler et al., 2006; Tzokov et al., 2006), but the model usingeight HlyE protomers shown in Fig. 5 exhibits plausiblesubunit packing with good matches to the pore dimensions obtainedby electron microscopy, except for pore length. Thus, the lengthof the HlyE pore in the model is $~$ 120 Å ( $~$ 12 nm),compared to $~$ 100 Å ( $~$ 10 nm) for the water-solubleform of HlyE and $~$ 140 Å ( $~$ 14 nm) as measured fromnegatively stained and cryo-electron micrographs (Eifler etal., 2006; Tzokov et al., 2006; Wallace et al., 2000). Therefore,some of the observed elongation of the HlyE molecule that occursupon pore formation is accounted for in the model, and it ispossible that some of the remaining difference is due to errorsin the electron microscopy measurements.

It has been suggested that the β-tongue region of HlyEforms a 26-stranded β-barrel cap structure as part of theprocess of insertion into the membrane (Eifler et al., 2006).However, it has not been suggested that this would constitutethe final pore structure and indeed it is unlikely to do so.The β-tongue is composed almost entirely of hydrophobicresidues, and a β-barrel transmembrane structure wouldresult in an unprecedented pore structure with a hydrophobiclining as well as a hydrophobic membrane interface. This wouldbe in stark contrast to the porin-like barrels of the majorityof outer-membrane proteins (Schulz, 2002; Parker & Feil,2005), which have a hydrophilic lining and a hydrophobic outerface, made possible by their strand sequences which alternatebetween hydrophilic and hydrophobic residues. It is worthy ofnote that there is no such peptide sequence at any point inthe HlyE sequence (Wallace et al., 2000). Thus, Parker &Feil (2005) have argued that the transmembrane portion of HlyEis almost certainly helical. The position of the head domainin our pore model (Fig. 5) is potentially consistent withthis. The head domain commences with the amphipathic ${alpha}$ D helix,followed by a long hydrophobic sequence consisting of shorthelical segments and the β-tongue, which then rejoins themain body of the molecule (Fig. 1). It is an intriguingpossibility that ${alpha}$ D could form an octameric ${alpha}$ -helical barrel pore,similar to that observed in the C terminus of E. coli Wza (Donget al., 2006), creating a hydrophilic pore of 20 Å(2 nm) diameter with the hydrophobic residues of ${alpha}$ D facingoutwards towards the membrane lipids (Fig. 6). This wouldbe facilitated if the long hydrophobic sequence that includesthe β-tongue, which has in fact been predicted to be atransmembrane helix (Oscarsson et al., 1999), were to undergoa conformational change into an ${alpha}$ -helix, which then returns tothe original side of the membrane (Fig. 6a, b). This wouldincrease the ${alpha}$ -helical content of the molecule by only $~$ 5 %, consistentwith the circular dichroism data that suggest there is no largechange in the helical content of HlyE upon pore formation. Thenew hydrophobic helix would make favourable interactions withthe outward-facing side chains of the Wza-like ${alpha}$ -helical barreland with lipid (Fig. 6c, d). In order to make the requiredconnections this helix would have to return at an angle of approximately4 ° to the membrane perpendicular, which would be consistentwith the extreme curvature of the membrane observed in electronmicrographs of membranes and lipid vesicles treated with HlyE(Eifler et al., 2006; Tzokov et al., 2006; Wai et al., 2003;Wallace et al., 2000). Although the model is consistent withthe available data it is speculative, and a definitive accountof how and when the water-soluble HlyE structure becomes elongated,and the full details of the conformational changes that takeplace to enable the formation of the transmembrane channel,must await a high-resolution structure of the pore form of HlyE.

ACKNOWLEDGEMENTS

We thank the UK Biotechnology and Biological Sciences ResearchCouncil for financial support, and Dr R. Staniforth (Universityof Sheffield) for help with the circular dichroism experiments.

Edited by: P. van der Ley

REFERENCES

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

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Received 16 July 2007; revised 25 September 2007; accepted 5 November 2007.

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