Identification of a Prepore Large-Complex Stage in the Mechanism of Action of Clostridium perfringens Enterotoxin

Clostridium perfringens enterotoxin (CPE) is the etiologicalagent of the third most common food-borne illness in the UnitedStates. The enteropathogenic effects of CPE result from formationof large CPE-containing complexes in eukaryotic cell membranes.Formation of these $~$ 155- and $~$ 200-kDa complexes coincides withplasma membrane permeability changes in eukaryotic cells, causinga Ca²⁺ influx that drives cell death pathways. CPE containsa stretch of amino acids (residues 81 to 106) that alternatesmarkedly in side chain polarity (a pattern shared by the transmembranedomains of the ß-barrel pore-forming toxin family).The goal of this study, therefore, was to investigate whetherthis CPE region is involved in pore formation. Complete deletionof the CPE region from 81 to 106 produced a CPE variant thatwas noncytotoxic for Caco-2 cells and was unable to form CPEpores. However, this variant maintained the ability to formthe $~$ 155-kDa large complex. This large complex appears to bea prepore present on the plasma membrane surface since it showedgreater susceptibility to proteases, increased complex instability,and a higher degree of dissociation from membranes comparedto the large complex formed by recombinant CPE. When a D48Amutation was engineered into this prepore-forming CPE variant,the resultant variant was unable to form any prepore $~$ 155-kDalarge complex. Collectively these findings reveal a new stepin CPE action, whereby receptor binding is followed by formationof a prepore large complex, which then inserts into membranesto form a pore.

INTRODUCTION

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INTRODUCTION

Among the several potent toxins produced by the gram-positive,spore-forming anaerobe Clostridium perfringens is the C. perfringensenterotoxin (CPE). Despite being produced by less than 5% ofglobal type A isolates, CPE remains biomedically relevant dueto its role in enteric disease. CPE causes the symptoms of severalhuman gastrointestinal diseases, one of which (C. perfringenstype A food poisoning) is currently ranked as the third mostprevalent food-borne illness in the United States (23).

CPE is a single polypeptide chain of 319 amino acids with amolecular weight of 35,346 (4). As a pore-forming toxin (12),CPE permeabilizes plasma membranes of sensitive cells to moleculesup to 200 Da within a short period of time (18). CPE first bindsvia protein receptors which are thought to be certain membersof the claudin family of proteins involved in tight junctionstructure and function (6, 15, 37). Under physiologic conditions,the enterotoxin rapidly forms a large CPE-containing complexthat is resistant to sodium dodecyl sulfate (SDS) and has anapproximate molecular mass of 155 kDa (40). Changes in cellularmembrane permeability typically accompany formation of the $~$ 155-kDalarge complex, suggesting that this complex functions as thetransmembrane pore (or a subunit thereof). Upon longer CPE treatment,intoxicated cells can also form a second SDS-resistant, CPE-containinglarge complex with an estimated molecular mass of 200 kDa (31).This second large complex also includes another tight junctionprotein, named occludin (30). Calcium influx through CPE poresdrives cell death via either the apoptotic or oncotic pathways,depending on the CPE dose (1, 2).

Previous studies using CPE variants blocked for one or moreCPE functions have provided important insights into the actionof this toxin (8, 10, 16, 17, 32). Binding activity has beenmapped to the extreme C terminus, based upon the binding abilityof recombinant CPE (rCPE) fragments containing C-terminal sequences(8-11) and the binding deficiencies of rCPE fragments lacking5, 10, or 30 amino acids from the C terminus (17). In contrast,rCPE fragments lacking 36 or 44 amino acids at the N terminuswere found to be approximately twofold more cytotoxic than full-lengthrCPE, indicating that sequences in the N terminus of CPE aremildly inhibitory for cytotoxicity (17). The same study alsoidentified a region between amino acids 45 and 53 of rCPE thatis essential for cytotoxicity, since rCPE fragments lackingthese 9 amino acids were unable to form a large complex or inducepore formation. A subsequent site-directed mutagenesis studyfine mapped this N-terminal CPE cytotoxicity region and demonstratedthat the aspartic acid at position 48 is essential for large-complexformation and cytotoxicity (32).

While previous structure-function studies have mainly focusedon regions of CPE important for binding and large-complex formation,the region (if any) involved in pore formation/membrane insertionhas not yet been investigated. Despite lacking primary sequencehomology with other bacterial pore-forming toxins, CPE aminoacids 81 to 106 show a marked alternating side chain hydrophobicitypattern (Fig. 1) closely resembling transmembrane domains (TMDs)found in members of the ß-barrel pore-forming toxin(ß-PFT) family. In this family, one or two ß-hairpinsfrom each monomer in a toxin oligomer collectively insert intothe membrane to form the phospholipid bilayer-penetrating channel(25, 35, 36). In efforts to begin ascertaining whether aminoacids 81 to 106 in CPE might be important for membrane insertion/poreformation, the present study deleted this region in both thewild-type and D48A point mutant rCPE backgrounds. Careful characterizationof these variants provided qualitative, as well as temporal,insights into the molecular mechanism of CPE action.

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FIG. 1. Functional map of CPE. Previous analysis of CPE identified two major functional regions (10, 17). Within the 5-amino-acid core cytotoxicity sequence at CPE's N terminus, the aspartic acid residue at position 48 (inverted triangle) is essential for cytotoxicity (32). At the C terminus, binding activity maps to the last 30 amino acids. The putative TMD examined in this study exists between residues 81 to 106 and contains alternating hydrophobic (asterisks) and hydrophilic amino acids.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Bacterial strains, plasmids, and growth media. All mutagenesis and protein expression work was performed withthe XL1-Blue strain of Escherichia coli. The plasmid pJKFLt-1(17), which served as the template construct for all deletionand site-directed mutagenesis, contains the entire cpe openreading frame ligated into the multiple cloning site of thepTrcHis A vector (Invitrogen, Carlsbad, CA). Fused to the 5'end of the cpe gene is a vector-encoded, 42-amino-acid hexahistidinetag, which enables the affinity enrichment of rCPE or its derivatives.All plasmids used or generated in this study can be found inTable 1. Bacterial cultures needed for DNA manipulation weregrown with Luria-Bertani (solid or liquid) medium containing100 µg/ml ampicillin. rCPE affinity enrichments were performedwith cultures grown in liquid super optimal broth (SOB) mediathat contained 100 µg/ml ampicillin and 5 mM IPTG (isopropyl-ß-D-thiogalactopyranoside)when induction of rCPE expression was required. All cultureswere grown at 37°C overnight unless otherwise indicated.

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TABLE 1. Plasmid constructs

Deletion mutagenesis of rCPE. Splicing by overlap extension (14) was used to generate theinternal deletion variants of CPE in this study. Regions upstreamand downstream from each cpe sequence to be deleted were amplifiedby PCR, with the 3' upstream reaction primer having complementaritywith the 5' downstream reaction primer. Products from thesetwo PCRs were then used as the template in a third PCR, addingthe 5' upstream reaction primer and 3' downstream reaction primerafter three cycles to allow the amplification of the entirecpe gene (minus the sequence to be deleted). The product fromthe third PCR was excised from an agarose gel and purified withFreeze n' Squeeze spin columns (Bio-Rad, Hercules, CA). Aftersimultaneous digestion with BamHI and EcoRI, the DNA was againgel purified, as described above, before it was precipitatedusing 0.1 volume of sodium acetate and 2.0 volumes of cold ethanolfor 30 min at –20°C. The DNA was pelleted by centrifugationat 4°C for 30 min and then washed once with 70% ethanol,recentrifuged, and resuspended in the desired volume. This DNAwas then ligated into a BamHI- and EcoRI-digested pTrcHis Avector, and this ligation mixture was used to transform XL1-SupercompetentBlue E. coli.

Site-directed mutagenesis. Introduction of the D48A mutation into the TM1 construct, therCPE internal deletion variant generated in this study, wasperformed using the QuikChange site-directed mutagenesis kit(Stratagene, La Jolla, CA). Primers used in the reaction canbe found in Table 2, and reaction parameters were in accordancewith the manufacturer's instructions. Mutated plasmid DNA resultingfrom the site-directed mutagenesis reaction was used to transformXL1-Supercompetent Blue E. coli.

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TABLE 2. Primers used for deletion mutagenesis, site-directed mutagenesis, and sequencing

DNA sequencing. The presence of all mutations in the cpe gene of pJKFLt-1 wasconfirmed by nucleotide sequencing. Plasmids containing themutated cpe gene were isolated from overnight E. coli cultureswith the QIAGEN Plasmid Mini Kit. Primers used for sequencingcan be found in Table 2, and sequencing reactions were performedby the University of Pittsburgh Genomics and Proteomics CoreLaboratories. BioEdit DNA analysis software (7) was used toconfirm the presence of the desired mutation and the absenceof unintended mutations.

Affinity enrichment of rCPE variants. For use in this study, rCPE (or its derivatives) was affinityenriched (via its vector-encoded N-terminal hexahistidine tag)from lysates of E. coli transformed with the indicated construct(Table 1). One liter of SOB medium was inoculated with 20 mlof an overnight SOB culture of the desired rCPE-expressing E.coli strain. After vigorous shaking for 3 h at 37°C, rCPEexpression was induced by adding IPTG to 5 mM. After an additional4 h of incubation at 37°C, the bacteria were harvested bycentrifugation. Final pellets were resuspended in HiTrap bindingbuffer (20 mM NaH₂PO₄, 500 mM NaCl, 10 mM imidazole, pH 7.4)and then stored at –80°C overnight. After the bacterialsuspension was thawed, a Heat Systems ultrasonic sonicator (Misonix,Farmingdale, NJ) was used to lyse the bacteria. Cell debriswas pelleted by centrifugation at 7,500 x g, and supernatantcontaining the His₆-tagged rCPE was passed through a MILLEXHV0.45-µm polyvinylidene difluoride filter (Millipore, Billerica,MA). This supernatant was then loaded on a cobalt-charged HiTrapchelating affinity column (Amersham Biosciences, Piscataway,NJ). The column was washed with HiTrap binding buffer, and rCPEwas then eluted with a linear imidazole gradient from 0 to 100%.Protein-containing fractions from the elution were pooled anddialyzed overnight against sterile deionized H₂O, pH 7.0. rCPEharvested from the each affinity enrichment was quantified withquantitative Western blotting, as described previously (32).

Competitive binding assay. Binding activity of the rCPE variants was determined using apreviously described (32) competition assay of ¹²⁵I-labeledCPE binding to rabbit brush border membranes (BBMs). These membraneswere isolated by a previously described protocol (29) from NewZealand White rabbits. This animal work was approved by AnimalCare and Use Committee protocol 11594 from the University ofCalifornia, Davis. To prepare ¹²⁵I-labeled CPE, 0.5 mg of nativeCPE was labeled with 2.5 mCi of Na¹²⁵I (specific activity, 17.0mCi/mg; MP Biomedicals, Inc., Irvine, CA) using IODO-GEN precoatediodination tubes (Pierce, Rockford, IL). ¹²⁵I-labeled CPE preparedby the Iodogen method retains significant specific binding andbiologic activity (data not shown). As described previously(32), binding competition experiments were carried out by pretreating100 µg of BBMs with the rCPE variant for 20 min at roomtemperature (RT) with gentle shaking. ¹²⁵I-CPE was then addedto a final concentration of 2.5 µg/ml, and this mixturewas incubated again at RT for 20 min. BBMs were washed twice,and ¹²⁵I-CPE bound to membranes was quantitated with a CobraQuantum gamma counter (PerkinElmer). Data from these experimentsare expressed as ng of competing rCPE required to inhibit 50%of specifically bound ¹²⁵I-CPE. The binding-deficient pointmutant W226Stop, which was generated in a previous study (16),was used as a negative binding control in these experiments.

Morphological damage assay. Caco-2 cells were cultured in 100-mm dishes using Eagle minimalessential medium (Sigma, St. Louis, MO) with 10% fetal bovineserum (Mediatech, Herndon, VA), 1% minimal essential mediumnonessential amino acids (Sigma), 100 units/ml ampicillin, 100µg/ml streptomycin, and 2 mM L-glutamine. Cells were keptin 5% atmospheric CO₂ at 37°C. Once confluent, Caco-2 monolayerswere washed once with prewarmed Hanks' balanced salt solutionwith Ca²⁺ and Mg²⁺ (HBSS²⁺; Mediatech) and then treated with2.5 µg/ml of toxin in 2 ml of HBSS²⁺. Cellular morphologicaldamage (nuclear condensation, cell rounding, detachment fromthe well bottom) was assayed after 1 h using a Zeiss Axiovert25 inverted microscope at 10x magnification. A Powershot G5digital camera (Canon, Inc., Lake Success, NY) and Canon UtilitiesRemoteCapture software were used to capture images of cells,and subsequent image processing was performed with Photoshopsoftware (Adobe Systems, Inc., San Jose, CA).

⁸⁶Rubidium release experiments. Formation of a CPE membrane pore was determined by measuring⁸⁶Rb release from Caco-2 cells, as described previously (32).Briefly, confluent Caco-2 cell monolayers were preloaded with4 µCi/well of ⁸⁶RbCl (specific activity, 6.4 mCi/mg; PerkinElmer,Boston, MA) for 4 to 5 h at 37°C. After two washes withprewarmed HBSS²⁺, the radiolabeled cultures were treated withtoxin for 15 min at 37°C. ⁸⁶Rb released into the culturesupernatant was collected and quantitated with a Cobra Quantumgamma counter (PerkinElmer). Spontaneous release of ⁸⁶Rb fromcells was measured by incubation of radiolabeled monolayerswith HBSS²⁺ alone, and maximal release was determined by treatingmonolayers with 1 ml each of 0.5% saponin and 1.0 M citric acid.Data from ⁸⁶Rb release experiments were converted and plottedas percent maximal release using the following formula: [(experimentalrelease – spontaneous release)/(maximal release –spontaneous release)] x 100.

Large-complex formation. The ability of each variant rCPE to form SDS-resistant largecomplexes was measured as described elsewhere (32). Briefly,isolated Caco-2 cells were treated with 2.5 µg/ml of toxinand incubated at 37°C for 20 min with gentle mixing. Thesecells were then pelleted by microcentrifugation, washed oncewith Hanks' balanced salt solution without Ca²⁺ or Mg²⁺ (Mediatech),and lysed with Laemmli buffer. All samples were treated for10 min at RT with Benzonase nuclease (Novagen, Inc., Darmstadt,Germany) to degrade cellular DNA before loading on an SDS-containing,4.25% acrylamide SDS-polyacrylamide gel (PAG). Electrophoresisof the samples was performed at 5 mA for $~$ 19 h, after which electrotransferand CPE Western blotting (as described above) were used to detectCPE-containing complexes on the blot.

Pronase resistance of CPE large complex. Experiments used to analyze the pronase susceptibility of largecomplexes formed by rCPE or its variants were adapted from apreviously published procedure (39). BBMs (100 µg) weretreated for 20 min at RT with 1.5 µg of rCPE or 4.5 µgof TM1, in 100 µl of phosphate-buffered saline containingCa²⁺ and Mg²⁺ (PBS²⁺; Mediatech). The BBMs were then washedonce with 100 µl of ice-cold PBS²⁺, before treatment for5 or 60 min in 50 µl of PBS²⁺ containing pronase. BBMswere then washed three times with ice-cold PBS²⁺ containingthe Complete protease inhibitor cocktail (Roche Applied Science,Penzberg, Germany). Final pellets were resuspended in Laemmlibuffer without 2-mercaptoethanol, loaded on a 6% acrylamideSDS-PAG, and subsequently treated as a CPE Western blot as detailedabove.

Dissociation of CPE large complex from membranes. rCPE or its variants were added to 100 µg of BBMs at afinal concentration of 2.5 µg/ml. Large-complex formationwas allowed to occur at 37°C for 20 min, followed by a washingstep with phosphate-buffered saline without Ca²⁺ or Mg²⁺ (Mediatech)containing the Complete protease inhibitor cocktail at 2x concentration(PBS-PI; Roche). After this wash, toxin-treated BBMs were resuspendedin 200 µl of PBS-PI and inverted gently at 4°C forvarious time periods. At the end of this incubation, the toxin-treatedBBMs were pelleted by centrifugation, and both the supernatantsand pellets from this spin were separated on a 4% acrylamideSDS-PAG and Western immunoblotted for CPE as described above.

Heat denaturation of CPE large complex. rCPE or TM1 was added to 100 µg of BBMs for 20 min at37°C in PBS-PI. After centrifugation and one washing with200 µl of PBS-PI, BBMs containing the large complex wereextracted with Laemmli buffer containing 2-mercaptoethanol.Extraction samples were then heated at 90°C in a heatingblock for various time periods. After this incubation, sampleswere separated on a 4% acrylamide SDS-PAG and Western immunoblottedfor CPE as described above.

RESULTS

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RESULTS

Deletion mutagenesis of the CPE region from 81 to 106. As mentioned in the introduction, CPE shares several structuralsimilarities with toxins of the ß-PFT family, includingthe presence of a 25-amino-acid region (residues 81 to 106)that strikingly alternates in side chain hydrophobicity (Fig.1). Because similar regions serve as the TMDs for ß-PFTs(25, 35, 36) and since no CPE region involved with membranepenetration has yet been identified, we targeted this putativeTMD for deletion mutagenesis. A complete deletion in this CPEregion was generated using "splicing by overlap extension" PCR(14), which amplifies sequences upstream and downstream fromthe intended deletion and splices these two products togetherin a third reaction (see Materials and Methods for a detaileddescription). This methodology has also been helpful with otherß-PFTs to identify and characterize TMDs (3, 20, 22).TM1 had a 100% deletion of the CPE region from amino acids 81to 106 (Fig. 2A).

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FIG. 2. Constructs used in the present study. (A) Each of the four constructs in this study contains an N-terminal His₆ for affinity enrichment from E. coli lysates. The D48A construct is a single point mutant generated previously (32). TM1 and TM1-D48A both have an internal deletion of 25 amino acids corresponding to the putative TMD; the TM1-D48A construct also contains the D48A point mutation described above. (B) Affinity-enriched samples (100 ng) of affinity enrichments of these constructs were electrophoresed on an SDS-containing 12% acrylamide gel and Western blotted with rabbit polyclonal anti-CPE antiserum to assess their stability. Arrows to the left of the blot represent the migration of molecular mass standards run with these samples.

To aid in identifying the temporal order of CPE functional regionsduring cytotoxicity, an additional variant was generated byintroducing a point mutation into the TM1 deletion variant background.As mentioned above, D48 of CPE is a critical residue for formingthe large complex and cytotoxicity. While the CPE point variantD48A is functional for receptor binding, it does not form thelarge complex and is unable to alter the plasma membrane permeabilityof Caco-2 cells (32). Therefore, to determine whether D48 contributesto CPE action before or after the involvement of the putativeTMD in CPE, a D48A mutation was introduced into TM1, producingthe combination variant TM1-D48A (Fig. 2A).

After DNA sequencing confirmed these mutations, affinity enrichmentsof rCPE, D48A, TM1, and TM1-D48A were performed, facilitatedby the N-terminal His₆ tag contributed by the pTrcHis A vector.While substantially enriched for rCPE or rCPE variants, as reportedpreviously (17), these affinity-enriched preparations were notpure. Therefore, similar mock enrichments of pTrcHis A emptyvector transformants were also performed and used throughoutthis study as a negative control. When the enriched samplescontaining rCPE or its variants were subjected to CPE Westernblotting, each variant migrated to its expected molecular weight(Fig. 2B), confirming that these CPE species were stable andnot proteolytically degraded.

Cytotoxicity of TM1 and TM1-D48A rCPE variants. To initially assess whether deletion of the CPE region from81 to 106 affects the ability of an rCPE variant to cause cytotoxicity,a qualitative Caco-2 morphological damage assay was used. Treatmentof Caco-2 cells with 2.5 µg/ml of rCPE for 60 min causedthe development of typical CPE cytopathology, including nuclearcondensation, membrane blebbing, and cellular detachment fromthe plate (Fig. 3). No morphological damage was observed ifCaco-2 cells were treated with HBSS²⁺ alone, an affinity-enrichedempty vector negative control, or (consistent with previousstudies [32]) the D48A point variant. Caco-2 monolayers alsoshowed no observable morphological damage after 60 min (Fig.3) or 24 h (data not shown) of treatment with 2.5 µg/mlof TM1 or TM1-D48A. These results provided an initial indicationthat the TM1 and TM1-D48A variants are deficient in some postbindingCPE activity.

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FIG. 3. Caco-2 morphological damage assay. Constructs were initially screened for cytotoxic activity by treating confluent Caco-2 cell monolayers with 2.5 µg/ml of each toxin for 60 min at 37°C. The control panel represents cells treated with HBSS²⁺ alone, while the pTrcHis panel depicts cells after treatment with a mock enrichment from E. coli transformed with an empty vector. After treatment, Caco-2 cells were photomicrographed at 200x total magnification.

Pore formation by the TM1 and TM1-D48A variants. The variants were next assayed for their ability to elicit ⁸⁶Rbrelease from Caco-2 cells via formation of a CPE pore. Usinga standard quantitative assay (32), rCPE was measured to elicit50% maximal ⁸⁶Rb release at a concentration of $~$ 1.0 µg/ml,while the empty vector negative control and D48A point variantpredictably did not elicit any ⁸⁶Rb release (Fig. 4). When TM1and TM1-D48A were similarly tested, neither was able to elicitany appreciable ⁸⁶Rb release, even at artificially high toxinconcentrations (up to 50 µg/ml). These results indicatethat TM1 and TM1-D48A are both noncytotoxic to cells becausethey cannot alter the plasma membrane permeability of Caco-2cells.

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FIG. 4. ⁸⁶Rubidium release from Caco-2 cells. Caco-2 cells grown to confluence in 24-well plates were radiolabeled with 4 µCi/well of ⁸⁶Rb and, after a washing, treated with the indicated concentration of toxin for 15 min at 37°C. After treatment, ⁸⁶Rb released into the culture supernatant was collected and gamma radiation was quantitated. Background release was corrected for by treating cells with HBSS²⁺ alone, and data were converted to percent maximal release (see Materials and Methods). All data points are the statistical means of three independent experiments, with error bars representing the standard deviations.

Assessment of TM1 and TM1-D48A competitive binding. Since the TM1 and TM1-D48A variants appeared to be deficientat cytotoxicity, it was of interest to determine whether theywere able to complete the first step in CPE action, receptorbinding. To assess this, a competitive binding assay that measuredthe ability of the TM1 and TM1-D48A rCPE variants to inhibitbinding of ¹²⁵I-CPE was performed. Although Caco-2 cells areused for cytotoxic evaluations of rCPE or its variants, thesecells demonstrate high levels of nonspecific binding of CPE,making them a nonoptimal model for binding analysis. Conversely,while BBMs isolated from rabbits obviously cannot be used toassess cytotoxicity, they are often used to examine CPE binding(16, 17, 19, 21, 31, 32, 40, 41) because they show much greaterlevels of specific binding versus nonspecific binding than Caco-2cells.

A binding inhibition index, which represents the amount of competingrCPE species (in ng) required to cause a 50% inhibition of ¹²⁵I-CPEspecific binding to BBMs, was calculated for each construct.The binding-capable D48A variant (32) had a binding inhibitionindex similar to that of rCPE (240 ± 30 for D48A comparedto 330 ± 80 for rCPE), while the C-terminally truncatedvariant W226Stop, as described previously (16), was incapableof competing with ¹²⁵I-CPE for BBM binding (index of over 20,000).The affinity-enriched empty vector pTrcHis sample had a similareffect in these experiments, also having a competitive bindingindex of over 20,000. For the rCPE variants produced in thisstudy, TM1 showed a binding inhibition index similar to thatof rCPE (410 ± 120), while TM1-D48A showed only slightlyless competitive binding activity, with an index of 650 ±40. The similarity in competitive binding of TM1, TM1-D48A,and rCPE demonstrates that the introduced mutations do not exerta major effect on receptor binding. Thus, it appears that TM1and TM1-D48A can complete the first step in CPE action.

Formation of SDS-resistant large complexes by the TM1 and TM1-D48A variants. The data presented above indicated that, despite maintainingreceptor binding activity, TM1 and TM1-D48A are both deficientat inducing cytotoxicity. Since CPE cytotoxicity requires theformation of an $~$ 155-kDa, SDS-resistant complex in the membranesof sensitive cells (19), we next determined whether TM1 or TM1-D48Acan form this complex in mammalian cell membranes. Since Caco-2cells have been shown to form two SDS-resistant large complexesof $~$ 155 and $~$ 200 kDa when treated with CPE (31), these cells wereinitially used to assess large-complex formation by the TM1and TM1-D48A variants. As reported previously (32), treatmentof isolated Caco-2 cells with 2.5 µg/ml of rCPE resultedin the formation of the $~$ 155-kDa large complex, as well as asecond $~$ 200-kDa CPE complex (Fig. 5). As also reported previously(32), the D48A rCPE variant did not form either of the two largeCPE complexes, although this rCPE variant can bind and is membraneassociated (note the immunoreactivity at the dye front in Fig.5).

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FIG. 5. Formation of SDS-resistant large complexes in Caco-2 cells. To assay for large-complex formation in Caco-2 cells, cultures were harvested from 100-mm plates by gentle scraping and treated with 2.5 µg/ml of toxin for 45 min at 37°C with inversion. After a washing, the treated cells were lysed and Western blotted with rabbit polyclonal anti-CPE antiserum. Lanes labeled "Cells only" and "pTrcHis" represent cells treated with Hanks' balanced salt solution without Ca²⁺ or Mg²⁺ alone or a mock enrichment from empty vector transformants, respectively. Arrows to the left of the blot represent the migration of molecular mass standards run with these samples.

Interestingly, the TM1 variant was able to form the $~$ 155-kDalarge complex in Caco-2 cells, despite its complete loss ofcytotoxicity depicted in earlier figures. However, the TM1 variantdid not form any detectable $~$ 200-kDa complex in Caco-2 cells.This novel phenotype (formation of the $~$ 155-kDa large complexin the absence of cytotoxicity) did not extend to the TM1-D48Acombination variant. Although this variant was membrane associated,no detectable large-complex formation was observed with thiscombination variant (Fig. 5).

Analysis of the TM1 prepore large complex. The ability of the TM1 deletion variant to form the $~$ 155-kDacomplex (Fig. 5) in the complete absence of cytotoxicity (Fig.3) or pore formation (Fig. 4) led us to investigate whetherthe TM1 large complex could represent a previously unidentifiedprepore step in the mechanism of action of CPE. To this end,we examined the integrity of the TM1 large complex in membranesby assaying protease resistance, dissociation from the membrane,and disassembly of membrane-extracted complexes by heat denaturation.BBMs were used in these experiments since the long CPE treatmenttimes and the large amount of proteases would lyse Caco-2 cellsand thus cause sample loss. In addition, previous studies havedemonstrated the stability of BBMs under similar conditions(39).

Pronase resistance of the TM1 large complex. Previous work has shown that, when associated with BBMs, CPEin the $~$ 155-kDa large complex becomes resistant to pronase, ahighly active protease cocktail from Streptomyces griseus (39).This same previous study showed that the $~$ 155-kDa large complexbecomes susceptible to pronase when extracted from membranes.Those findings were interpreted as indicating that the membrane-associatedCPE large complex gains pronase resistance because of its insertioninto membranes, which is consistent with CPE being a membrane-penetrating,pore-forming toxin.

In order to test the hypothesis that the TM1 large complex mightbe trapped in a prepore stage unable to insert into BBMs, similarpronase resistance assays were performed with the TM1 largecomplex. While TM1 was shown in Fig. 5 to form only the $~$ 155-kDalarge complex in Caco-2 cell membranes, it was first necessaryto evaluate whether TM1 showed similar CPE complex formationin BBMs. When BBMs were treated with wild-type rCPE (Fig. 6,rCPE lane 0), the $~$ 155-kDa large complex, but no other complex,was observed. This was expected since the protein required forthe formation of the $~$ 200-kDa large complex, occludin (31), isnot present in BBM preparations (U. Singh and B. A. McClane,unpublished observations). As also seen in Caco-2 cells, theTM1 variant did form the $~$ 155-kDa large complex, but no $~$ 200-kDalarge complex, in BBMs (Fig. 6, TM1 lane 0), thus demonstratingthe consistency between the two model systems.

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FIG. 6. Pronase resistance of the CPE large complex. Isolated rabbit BBMs were treated with either rCPE or TM1 for 20 min and then washed to remove unbound toxin. Membranes were treated with the indicated concentrations of pronase and incubated at 4°C for the denoted amounts of time. After digestion, membranes were pelleted and resuspended in Laemmli buffer before separation and Western blotting with rabbit polyclonal anti-CPE antiserum. Arrows to the left of the blot represent the migration of molecular mass standards run with these samples.

In order to assay complex susceptibility to pronase, BBMs containingthe $~$ 155-kDa large complex formed by rCPE were digested with600, 60, or 6 µg/ml of pronase for 5 or 60 min. Significantamounts of rCPE large complex remained present in BBMs evenafter a 60-min treatment with 60 µg/ml of pronase (Fig.6). In contrast, pronase treatment of membranes containing theTM1 large complex caused a nearly complete disappearance ofthis complex after only a 5-min treatment with 60 µg/mlof pronase. This effect is directly attributable to the additionof pronase since rCPE or TM1 complex levels did not similarlydecrease when BBMs were incubated for 3 h in the absence ofpronase (Fig. 7).

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FIG. 7. Dissociation of the large complex from membranes. BBMs were treated with rCPE or TM1 (2.5 µg/ml) for 20 min at 37°C to allow formation of the $~$ 155-kDa large complex. After a washing, the BBMs were incubated in PBS-PI at 4°C for the indicated periods of time (numbers at top of gel). After microcentrifugation, samples from both the supernatant and pellet were Western blotted with rabbit polyclonal anti-CPE antiserum. P, samples from the pellet; S, samples from the supernatants of the microcentrifugation; OE, overnight exposures of lanes containing the 20-h supernatant for either rCPE- or TM1-treated BBMs. Arrows to the left of the blot represent the migration of molecular mass standards run with these samples, along with the migration of free rCPE and rCPE-treated BBMs.

Enhancing these findings is the fact that the BBM samples inFig. 6 were deliberately prepared to contain approximately threefoldmore TM1 large complex than rCPE large complex at the startof the experiment. Therefore, the $~$ 155-kDa large complex formedby TM1 is between 10- and 30-fold more sensitive to pronasedigestion than is the $~$ 155-kDa large complex formed by wild-typerCPE. This finding is consistent with the TM1 variant formingthe $~$ 155-kDa large complex but (due to the lack of the putativeTMD) with the membrane insertion step required for pore formationand development of pronase resistance being blocked.

Membrane dissociation of the TM1 large complex. Once sequestered in CPE large complexes, only limited dissociationof CPE from BBMs is observed (39). If the $~$ 155-kDa large complexmade by TM1 remains on the membrane surface trapped in a preporestate, it might be anticipated that this TM1 large complex wouldexhibit dissociation from BBMs that was faster than dissociationof the large complex formed by rCPE. To test this hypothesis,isolated BBMs containing the $~$ 155-kDa large complex formed byeither rCPE or TM1 were harvested by centrifugation at the indicated(Fig. 7) time intervals and samples from both the supernatantsand pellets were Western blotted for CPE. These studies showedthat the $~$ 155-kDa large complex formed by rCPE remained largelymembrane associated, even after 20 h (Fig. 7). In contrast,little of the $~$ 155-kDa large complex formed by TM1 remained membraneassociated after a similar 20-h incubation. In addition, a steadykinetic increase in lower-molecular-weight material accompaniedthe loss of large-complex immunoreactivity in the pellet lanesof the TM1-treated membranes (Fig. 7). This smaller complexmay represent an intermediate species from the breakup of theTM1 large complex and is noticeably absent from the pellet lanesof similar experiments with rCPE-treated membranes.

Overnight film exposure of these blots also allowed the visualizationof the intact TM1 large complex that had dissociated from themembrane (Fig. 7, TM1 lane OE). Very little (if any) large complexcould be detected in similarly overexposed lanes containingrCPE-treated BBMs. Because these reactions were performed at4°C and constantly in the presence of a strong proteaseinhibitor cocktail, the TM1 large-complex instability notedin Fig. 7 is unlikely to be the result of proteolytic activity.In support of this conclusion, no differences in total proteincontent were detected between rCPE-, TM1-, or control-treatedBBMs after overnight dissociation experiments (data not shown).

Heat denaturation of the TM1 large complex. Since the $~$ 155-kDa large complex formed by TM1 appeared in Fig.7 experiments to be less stable and more likely to disassemblethan that formed by rCPE, a heat denaturation experiment wasperformed to test the stability of the TM1 large complex afterits extraction from membranes. Heating of large complexes madeby rCPE prior to SDS-PAG electrophoresis was previously shownto cause very limited complex disassembly, although it can promotecomplex aggregation (40). Therefore, it was of interest to assessthe ability of the TM1 large complex to resist disassembly asa result of heating.

To perform these experiments, the large complex formed by rCPEor TM1 was extracted from BBMs and then heated for 0 s, 20 s,1 min, 5 min, 10 min, or 20 min. While no decrease in the rCPElarge complex could be seen at 1 min of heating, the TM1 largecomplex began to show obvious breakdown after only 1 min andwas undetectable as a complex past this time point (Fig. 8).A qualitative change of the rCPE large complex, in the formof some kind of aggregation, started to appear at the 5-mintime point; however, the immunoreactivity remaining as an intactcomplex was strikingly more heat resistant than that of theTM1 complex, as evident from TM1 lanes after 5 min of heating(Fig. 8). When urea was also included in similar heat denaturationexperiments, it had no discernible effect on the stability ofthe large complex formed by either rCPE or TM1 (data not shown).

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FIG. 8. Heat denaturation of extracted large complexes. Heat sensitivity of the large complexes was assayed by treating BBMs with rCPE or TM1 (2.5 µg/ml) for 20 min at 37°C to allow formation of the $~$ 155-kDa large complex. After a washing, the BBMs were extracted with Laemmli buffer and heated at 90°C for the indicated time periods. After heat denaturation, samples were Western blotted with rabbit polyclonal anti-CPE antiserum. Arrows to the left of the blot represent the migration of molecular mass standards run with these samples, along with the migration of free rCPE.

DISCUSSION

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DISCUSSION

While previous structure-function analyses of CPE have identifiedtwo major functional regions (Fig. 1), a stretch of amino acidsbetween residues 81 and 106 of native CPE was investigated inthis study for its potential role in membrane insertion. Asmentioned in the introduction, the striking pattern of alternatingside group polarity exhibited by these residues resembles thatexhibited by the TMDs of the ß-PFTs (25, 35, 36) andtherefore makes amino acids 81 to 106 in CPE an ideal candidatefor a membrane insertion domain. Complete deletion of this putativeTMD led to a novel CPE variant phenotype: formation of the $~$ 155-kDalarge complex in the absence of cytotoxicity (Fig. 3 and 5).In addition to not being toxic for Caco-2 cells, the TM1 deletionvariant was defective for pore formation (Fig. 4) and appearednot to insert into membranes (Fig. 6). These observations collectivelysuggest that the TM1 large complex is trapped in a somewhatunstable (Fig. 7 and 8) prepore state on the surfaces of cells,unable to insert into the membrane to form a CPE pore.

Several possible explanations alone or in combination couldexplain the prepore phenotype of the TM1 deletion variant. First,amino acids 81 to 106 could form a beta hairpin secondary structurethat CPE uses to penetrate the phospholipid bilayer, as is thecase with members of the ß-PFT family (25, 35, 36).Consistent with this explanation, secondary-structure analysesof CPE predict two beta strands between V81 and T92 and againbetween F95 and I106 (double-prediction method [5], ProteinSequence Analysis server [33, 34, 38], and PROF [27]). As mentionedabove, the amino acid hydrophobicity pattern aligns very closelywith those of many other ß-PFTs, including severalother toxins produced by C. perfringens. In addition, when theTMDs from the Staphylococcus aureus alpha hemolysin, Bacillusanthracis protective antigen, and Clostridium septicum alpha-toxinwere deleted in previous studies, all resultant variant toxinswere unaffected in binding and could form SDS-resistant oligomersbut (like TM1) were impaired at membrane insertion/pore formation(3, 20, 22). These phenotypic similarities with the CPE TM1variant, along with the shared distinctive amino acid pattern,are consistent with amino acids 81 to 106 in CPE acting as aTMD. Efforts are under way to probe the environments of theseresidues after pore formation using Cys scanning mutagenesisand labeling with environmentally sensitive fluorescent dyes,as performed with several other ß-PFTs (20, 24, 28).

Alternatively, amino acids 81 to 106 of CPE could mediate someprotein-membrane interactions other than direct membrane penetration.Perfringolysin O (PFO), a cholesterol-dependent cytolysin fromC. perfringens in the ß-PFT family, contains severalsmall loops at the bottom of its membrane-interacting domain4 (26). Although residues in these loops were implicated directlyin pore formation in early models of PFO action (26), it waslater shown that they do not insert deeply into the membranebut instead participate in membrane anchoring of PFO (13). Severalhydrophobic residues are located in these small loops of PFO,similar to the many hydrophobic residues found between aminoacids 81 and 106 of CPE. Therefore, the large complex formedby the TM1 variant could be deficient in the membrane anchoringnecessary for subsequent insertion of CPE into the membrane.Also consistent with this possible explanation is the greaterdissociation from BBMs of TM1 versus rCPE shown in Fig. 7.

A final possibility is that this CPE region mediates criticalprotein-protein interactions between CPE and other proteins,which then allow for membrane insertion/pore formation. Deletionof these residues may have removed crucial contact points betweenCPE and other proteins in the $~$ 155-kDa large complex, althoughit remains unclear whether other proteins are present in thisCPE complex. The instability of the TM1 large complex (in additionto greater dissociation) seen in Fig. 7 and 8 could supportthis explanation, especially given the kinetic increase in alower-molecular-weight complex on Fig. 7 blots immunoreactivefor CPE. These TM1 species might represent pieces of the $~$ 155-kDalarge complex that broke apart due to the loss of contacts normallyprovided by amino acids 81 to 106. It is also notable in Fig.7 that the TM1 large complex disassembles while still membraneassociated, while the rCPE complex breaks apart only after dissociatingfrom BBMs. This effect is also consistent with the idea thatTM1 forms a structurally compromised large complex on the membranesurface, whereas the rCPE complex is remarkably stable sinceit has undergone insertion into membranes.

Introduction of a D48A mutation into the TM1 background helpedassign a temporal order to the cytotoxic contributions of knownCPE functional regions. Interestingly, the TM1-D48A combinationmutant paralleled the attenuated phenotype of the TM1 variantexcept that it could not form the $~$ 155-kDa large complex (Fig.5). This result indicates that the D48 residue in CPE's N-terminalcytotoxicity domain acts prior to the involvement of amino acids81 to 106 in CPE. This finding agrees with the idea that CPEfirst forms an SDS-resistant complex and then uses amino acids81 to 106 as a TMD or membrane anchor or for some other functionto insert and form a pore. It also demonstrates that the N-terminalcytotoxicity domain is not directly involved in membrane penetrationor pore formation since the TM1 variant (containing native D48)formed the $~$ 155-kDa large complex but could not insert into themembrane or form a pore (Fig. 4, 5, and 6).

Another interesting finding from this study was that the TM1variant formed the $~$ 155-kDa large complex but not the larger $~$ 200-kDa complex in Caco-2 cells (Fig. 5). This is particularlyintriguing because all CPE variants generated in the past formboth or neither of these two complexes in these cells. The $~$ 200-kDalarge complex formed by Caco-2 cells, which has been shown toinclude the tight junction protein occludin (31), generallyforms only upon longer CPE treatments or physical disruptionof Caco-2 monolayers (30). However, the large-complex experimentsin this study utilized isolated Caco-2 cells, a condition whereoccludin is exposed to CPE from the beginning of the experiment.In support of this claim, rCPE rapidly formed the $~$ 200-kDa largecomplex in the same experiments where TM1 was deficient forformation of this second large complex (Fig. 5). One interpretationfrom these results is that insertion of the $~$ 155-kDa large complexinto membranes is a required precursor for $~$ 200-kDa large-complexformation. Another possible explanation for TM1's lack of $~$ 200-kDalarge-complex formation is that amino acids 81 to 106 of CPEmay directly or indirectly mediate CPE-occludin interactions.Therefore, deletion of this region could lead to a variant capableonly of forming the $~$ 155-kDa large complex.

Taken together, results from this study have shed new lighton both temporal and qualitative aspects of the molecular mechanismof action of CPE. A new model incorporating CPE's functionalregions generated from these and previous data is presentedin Fig. 9. CPE begins its mechanism of action by binding viaits C-terminal residues to the second extracellular loops ofcertain claudins, which are transmembrane tight junction proteins(6). Next, residues (particularly D48) in the N-terminal cytotoxicityregion of CPE directly mediate the formation of the SDS-resistant $~$ 155-kDa large complex, consisting of other CPE molecules and/orother cellular proteins. This large complex then undergoes amembrane insertion event (dependent on CPE's amino acids 81to 106 as a TMD) that provides protection from proteases andforms a Ca²⁺-permeable pore. Additional biochemical analysesof CPE variants and large complexes are under way to test thevalidity of this model.

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FIG. 9. Updated model of CPE action. Stage 1 is binding. CPE action begins when CPE binds certain claudins, transmembrane tight junction proteins, using sequences at the CPE C terminus. Stage 2 is prepore large-complex formation. After membrane localization via receptor binding, CPE joins with other proteins (and/or additional molecules of CPE) to form an SDS-resistant complex. Formation of this complex is dependent upon the presence of an intact N terminus, particularly the aspartic acid residue at position 48. However, without the presence of CPE's putative TMD, this complex is trapped at the prepore stage and is unable to resist degradation by proteases. Stage 3 is membrane insertion/pore formation. With an intact N terminus and putative TMD, the CPE large complex can undergo the conformational changes necessary for insertion into the membrane. This stage not only protects the complex from proteases but also allows the penetration of the phospholipid bilayer of enterocytes, causing the influx of Ca²⁺ into the cell. Check marks and "x" indicate rCPE species which can or cannot, respectively, undergo this stage in CPE action.

ACKNOWLEDGMENTS

This work was supported by Public Health Service grant R37-AI019844-24from the National Institute of Allergy and Infectious Diseases.

We acknowledge helpful conversations with Rodney K. Tweten,Julian I. Rood, and Derek J. Fisher throughout this study.

FOOTNOTES

* Corresponding author. Mailing address: E1240 BSTWR, University of Pittsburgh School of Medicine, Pittsburgh, PA 15261. Phone: (412) 648-9022. Fax: (412) 624-1401. E-mail: bamcc{at}pitt.edu

Published ahead of print on 16 February 2007.

Editor: D. L. Burns

REFERENCES

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