Trivalent Vaccine against Botulinum Toxin Serotypes A, B, and E That Can Be Administered by the Mucosal Route

Most reports dealing with vaccines against botulinum toxin havefocused on the injection route of administration. This is unfortunate,because a mucosal vaccine is likely to be more efficacious forpatients and pose fewer risks to health care workers and tothe environment. Therefore, efforts were made to generate amucosal vaccine that provides protection against the botulinumserotypes that typically cause human illness (serotypes A, B,and E). This work demonstrated that carboxy-terminal peptidesderived from each of the three serotypes were able to bind toand penetrate human epithelial barriers in vitro, and therewas no cross inhibition of membrane binding and transcytosis.The three polypeptides were then tested in vivo as a trivalentvaccine that could be administered to mice by the intranasalroute. The results indicated that the mucosal vaccine evokedhigh secretory titers of immunoglobulin A (IgA), as well ashigh circulating titers of IgG and IgA, and it also evoked ahigh level of resistance to challenge with toxin. The immunoglobulinresponses and the levels of resistance to challenge were increasedby coadministration of adjuvants, such as chitosan and vitaminE. At least three mechanisms were identified to account forthe antibody-induced resistance: (i) blockade of toxin absorptionacross epithelial cells, (ii) enhanced clearance of toxin fromthe circulation, and (iii) blockade of toxin action at the neuromuscularjunction. These results are a compelling demonstration thata mucosal vaccine against multiple serotypes of botulinum toxinhas been identified.

INTRODUCTION

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INTRODUCTION

Botulinum toxin (BoNT) is a uniquely potent agent that is synthesizedby the organisms Clostridium botulinum, Clostridium beratii,and Clostridium butyricum. This toxin, which exists in sevendifferent serotypes (serotypes A to G) and more than 40 subtypes(30, 35), causes a serious and potentially life-threateningdisease called botulism (12, 14). This disease can occur naturally,but it can also be a result of bioterrorism and biological warfare(3).

All serotypes of BoNT are synthesized as relatively inactivesingle-chain polypeptides with molecular masses of ca. 150 kDa.These precursors must undergo posttranslational modification("nicking"), which yields dichain molecules in which a lightchain (LC) is linked by a single disulfide bond to a heavy chain(HC). The three-dimensional structures of some of the serotypeshave been determined (17, 37). This work has revealed that themolecule is composed of three lobes, which represent LC, theamino-terminal portion of HC, and the carboxy-terminal portionof HC.

Considerable progress has been made in determining the mechanismof toxin action, as well as the structure-function relationshipsthat govern this action (31, 32). Botulinum toxin typicallyacts as an oral poison, although it can also be an inhalationpoison (27). The sequence of events is the same for both routesof exposure (32). The toxin binds to the apical surface of epithelialcells, undergoes endocytosis and transcytosis, and then is releasedinto the general circulation (1, 21, 22). A portion of the toxinescapes from the blood and lymph and reaches the extracellularspace, where it acts on peripheral cholinergic nerve endings.The toxin molecule binds with high affinity to the plasma membraneand then undergoes receptor-mediated endocytosis and pH-inducedtranslocation to reach the cytosol. The toxin acts inside cellsto cleave polypeptides that are essential for transmitter release.Blockade of exocytosis produces the muscle weakness and paralysisthat are hallmarks of the disease botulism (31, 32).

The fact that BoNT can produce a devastating disease, combinedwith the fact that it is a potential bioterrorism and biologicalwarfare agent, has sparked intense efforts to develop a vaccine.Most current work on a botulism vaccine can be traced to previouspreclinical studies of an injectable tetanus vaccine. The tetanustoxin molecule, like the BoNT molecule, is a protein with amolecular mass of ca. 150 kDa (4, 11, 28). It too is composedof three domains that can be designated LC, the amino-terminalportion of HC, and the carboxy-terminal portion of HC. Earlystudies of isolation and fragmentation of the tetanus toxinmolecule led to the discovery that limited proteolysis combinedwith disulfide bond reduction produced two polypeptides: (i)LC linked to the amino-terminal portion of HC and (ii) the carboxy-terminalportion of HC. The latter was shown to be an efficacious parenteralvaccine against tetanus toxin (10, 13, 20).

Investigators in the BoNT field have subsequently generatedthe carboxy-terminal portion of HC, both by limited proteolysisof the wild-type toxin and by recombinant techniques. This polypeptidedomain has been shown to be an injectable vaccine that is effectiveagainst the parent toxin (5, 6).

In a completely different line of research, an effort has beenmade to identify the minimum essential domain of the BoNT moleculethat is needed for binding and penetration of gut and airwayepithelial cells (23). This work has demonstrated that (i) theBoNT molecule by itself contains the information for bindingand transcytosis across epithelial monolayers, and there isno need for auxiliary proteins that bacteria release in associationwith the toxin; (ii) both LC and the amino-terminal portionof HC can be removed from the holotoxin, and the residual carboxy-terminaldomain is able to cross epithelial barriers; and (iii) the carboxy-terminaldomain that undergoes binding and transcytosis retains all ofits characteristic structural and functional properties (1,21-23).

The different lines of research on the BoNT molecule have coalescedin what may be an exciting coincidence of findings. On the onehand, the carboxy-terminal end of HC has the properties of animmunogen. On the other hand, the same polypeptide has the abilityto bind to and penetrate epithelial barriers in the gut andairway. These findings suggest that this molecule could be amucosal vaccine against botulism.

In this report, a substantial body of evidence is presentedto show that a mucosal vaccine against botulism has been identified.In addition, this report is the first to describe a recombinanttrivalent vaccine against botulism, and it is the first to identifyand quantify the various layers of antibody-induced protectionagainst the toxin. Beyond this, the report introduces noveladjuvants to the clostridial toxin field, and it introducesthe concept of a universal vaccine to the BoNT literature.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Toxin. Homogeneous BoNT type A (BoNT/A) was isolated from bacterialcultures as previously described (9, 30, 34). Homogeneous BoNT/Band BoNT/E were purchased from Metabiologics (Madison, WI).The homogeneity of the preparations was confirmed by sodiumdodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)(18).

BoNT/A was isolated in a nicked and biologically active form.BoNT/B and BoNT/E were isolated in the single-chain form andsubsequently nicked. To generate the two-chain form of thesetoxins, the single-chain molecules were proteolytically activatedwith trypsin. To facilitate subsequent separation of the toxinfrom the nicking enzyme, L-1-tosylamido-2-phenylethyl chloromethylketone-treated trypsin cross-linked to 4% beaded agarose wasused (immobilized trypsin; Pierce Chemical, Rockford, IL). Thetrypsin slurry was washed three times with reaction buffer (10mM sodium phosphate buffer, pH 7.5). Toxin was added and incubatedwith the enzyme at room temperature (21°C) for 1 h at aratio of trypsin to toxin of 1:10. After incubation, the nickedtoxin was separated from the beaded trypsin by filtration througha 0.2-µm centrifugal filter (Centrex microfilter unit;Schleicher & Schuell, Keene, NH). The nicked toxin was collected,aliquoted, and stored at –20°C until it was used.A sample of the material was examined by electrophoresis toverify the degree of nicking and the integrity of the dichaintoxin.

Iodination. BoNT/A was iodinated using ¹²⁵I-Bolton-Hunter reagent, essentiallyaccording to the manufacturer's instructions. Pure neurotoxin(300 µg) in 200 µl of borate buffer (pH 7.8) wasadded to dried iodinated ester and incubated on ice for 15 min.The reaction was terminated by addition of 50 µl of 1M glycine in borate buffer and incubation for 15 min. The totalreaction mixture (250 µl) and rinse (250 µl) wereloaded onto a Sephadex G-25 column that was preequilibratedwith filtration buffer (150 mM Na₂HPO₄, 150 mM NaCl, 0.11% gelatin;pH 7.4). The labeled toxin was eluted with filtration buffer,and 0.5-ml fractions were collected. An aliquot (5 µl)of each fraction was assayed to determine the radioactivity.The labeled toxin peak, which eluted at the void volume, waspooled and stored at 4°C. The toxin concentration in thepooled fraction was determined spectrophotometrically at 278nm using the following relationship: 1.63 A₂₇₈ units = 1 mg/ml(9).

Iodinated samples were assayed with a gamma-counter to determinethe number of disintegrations per minute. Sample concentrationsand associated counts were used to calculate the specific activity.

Iodinated toxin purity and biological activity. The homogeneity of ¹²⁵I-labeled BoNT/A was determined by SDS-PAGE.The BoNT/A samples were separated on a 10% polyacrylamide gelby the method of Laemmli (18). Gels were run under nonreducingconditions and stained with Coomassie blue, followed by dryingunder a vacuum (Bio-Rad Laboratories model 224 gel slab dryer)for 2 h. The gels were exposed to Hyperfilm ECL (GE-AmershamBiosciences, Bucks, United Kingdom) for 24 to 48 h and developedusing a Kodak O-XMAT film processor (Eastman Kodak Co., Rochester,NY). Developed film was analyzed to determine the presence ofa ¹²⁵I-labeled BoNT/A band ( $~$ 150 kDa).

BoNT/A was iodinated three times during the study, and the averagespecific activity was 2.76 x 10² Ci/mmol. Each batch of toxinwas used for ca. 60 days. Aliquots of material that were usedin individual experiments during this period were subjectedto additional chromatography (Sephadex G-25) prior to use toensure that free isotope and small polypeptide fragments wereremoved.

Nomenclature. According to accepted nomenclature (26), BoNT is the abbreviationfor botulinum neurotoxin. LC is the accepted designation forthe light chain, and HC is the designation for the heavy chain.Unfortunately, there is no accepted terminology for identifyingpolypeptides that represent HC fragments that are various lengths.Therefore, in this report, a simple convention is used. HC witha subscript indicates a polypeptide that begins at the carboxyterminus of the HC and has the molecular mass (in kilodaltons)indicated by the subscript. Thus, HC₅₀ is a carboxy-terminalpeptide that is derived from the HC and has a molecular massof 50 kDa.

Cloning, expression, and purification of recombinant HC₅₀ domains of BoNT/A, BoNT/B, and BoNT/E. Gene segments encoding the HC₅₀ fragments of BoNT/A (strain62A; amino acids 861 to 1296), BoNT/B (strain Okra; amino acids853 to 1291), and BoNT/E (strain NCTC 11219; amino acids 840to 1252) were cloned into the vector pQE30 (QIAGEN, Germantown,MD), yielding expression plasmids pQEHC₅₀ A, pQEHC₅₀ B, andpQEHC₅₀ E, respectively.

Escherichia coli BL21-codon plus(DE3)-RIL (Stratagene, CedarCreek, TX) was used as the host strain for expression of HC₅₀domains. Cells were grown in Terrific broth (1.2% peptone, 2.4%yeast extract, 0.94% K₂HPO₄, 0.22% KH₂PO₄; Difco, Sparks, MD)at 37°C, with shaking to an A₆₀₀ of 0.6 to 0.8. Isopropyl-β-D-thiogalactopyranoside(IPTG) at a final concentration of 0.5 mM was added, and theculture was incubated for 12 h at 25°C. The bacteria in1 liter of an induced culture were harvested by centrifugation(6,000 x g, 15 min) at 4°C.

Cells were suspended in 200 ml of bacterial protein extractreagent (Pierce, Rockford, IL) at 4°C. Lysozyme (Sigma,St. Louis, MO) at a final concentration of 0.1 mg/ml, DNase(Sigma) at a final concentration of 0.01 mg/ml, and a proteaseinhibitor cocktail (Roche, Indianapolis, IN) were added to thecell suspension and incubated on a rotating shaker for 2 h.Four hundred milliliters of 50 mM sodium phosphate buffer containing300 mM NaCl (pH 8.0) was added to the lysed cell suspensionand allowed to stand for 30 min. The suspension was centrifugedat 27,000 x g for 40 min to remove the precipitate.

The clear supernatant was loaded onto a 5-ml column of Ni-nitrilotriaceticacid Superflow (QIAGEN) which was equilibrated with 50 mM sodiumphosphate buffer containing 300 mM NaCl (pH 8.0). The columnwas washed with 50 volumes of washing buffer (50 mM sodium phosphatebuffer containing 300 mM NaCl and 20 mM imidazole; pH 8.0).Bound protein was eluted from the column with an imidazole gradient(20 to 250 mM imidazole in 50 mM sodium phosphate buffer containing300 mM NaCl [pH 8.0]). The active fractions (which eluted with $~$ 100 mM imidazole) were pooled and dialyzed against 50 mM sodiumphosphate (pH 6.8). The dialysate was centrifuged at 27,000x g for 30 min to remove the precipitate.

The clear supernatant was loaded onto a cation-exchange columncontaining 4 ml of CM Sepharose Fast Flow (GE-Amersham Bioscience)equilibrated with 50 mM sodium phosphate (pH 6.8). The columnwas washed with 50 volumes of 50 mM sodium phosphate (pH 6.8).Bound protein was eluted from the column with an NaCl gradient(50 to 500 mM NaCl in 50 mM sodium phosphate buffer [pH 6.8]).The active fractions (which eluted with $~$ 200 mM NaCl) were pooledand dialyzed against 50 mM sodium phosphate (pH 7.4). Approximately15 to 20 mg of each HC₅₀ polypeptide was obtained from 1 literof bacterial culture. The purity of the HC₅₀ polypeptides wasconfirmed by 10% SDS-PAGE.

Western blot analysis. Rabbit and mouse antisera against HC₅₀/A, HC₅₀/B, and HC₅₀/Ewere prepared in our laboratory. For Western blotting, sampleswere separated under reducing conditions by 10% SDS-PAGE usinga Mini-Protean III electrophoresis cell (Bio-Rad Laboratories,Hercules, CA). Proteins were then transferred to a Nitropurenitrocellulose membrane using a Mini Trans-Blot electrophoretictransfer cell (Bio-Rad Laboratories) in Tris-glycine transferbuffer at 75 V for 90 min, as described by Towbin et al. (38).Blotted membranes were rinsed with phosphate-buffered saline-0.05%Tween 20 (PBST) (pH 7.5) and blocked with 5% nonfat powder milkin PBST at room temperature. For identification of recombinanttoxin fragments, the membranes were washed three times withPBST and then incubated with the appropriate antiserum at a1:5,000 dilution in PBST with 0.5% nonfat powdered milk at 4°Covernight. The membranes were then washed three times with PBSTand incubated with secondary antibody at a 1:10,000 dilutionin PBST with 0.5% nonfat powder milk for 1 h at room temperature.After this the membranes were washed three times with PBST atroom temperature and visualized using SuperSignal West Picochemiluminescence (Pierce Chemical) according to the manufacturer'sinstructions. The membranes were exposed to Hyperfilm ECL film(GE-Amersham Biosciences) for times adequate to visualize thechemiluminescent bands. HC₅₀ fragments were identified by comparisonwith known protein standards.

Cell culture. T-84 human epithelial cells were grown in a l:1 mixture of Dulbecco'smodified Eagle's medium containing 1 g/liter D-glucose and Ham'sF-12 nutrient medium supplemented with 5% newborn calf serum,100 U/ml penicillin, 100 µg/ml ampicillin, and 15 mM HEPES.Cultures were maintained at 37°C in 6% CO₂. T-84 cells werefed every 3 days and passaged (1:2) when they were 95% confluent,approximately every 6 days. Passages 65 through 90 were usedfor experiments described below.

Transcytosis assay. Cells were grown in Transwell porous-bottom dishes on polycarbonatemembranes with a 0.4-µm pore size. The growth area withineach insert was 1.12 cm². The Transwells were coated with 10µg/cm² rat tail collagen type 1. The coated wells wereallowed to dry at room temperature overnight (18 h). After drying,the wells were sterilized under UV light for 1 h, which wasfollowed by preincubation with cell culture medium (30 min).The preincubation medium was removed immediately before additionof cells and fresh medium.

T-84 cells were plated at a confluent density (ca. 1.5 x 10⁵cells) in the Transwells with 0.5 ml of medium in the upperchamber and 1.0 ml of medium in the lower chamber. The mediumin the upper chamber bathed the apical (or mucosal) surfaceof cells, and the medium in the lower chamber bathed the basolateral(or serosal) surface of cells. The culture medium was changedevery 2 days. The cultures were allowed to differentiate forat least 10 days before a transcytosis assay was performed.The formation of tight junctions was confirmed experimentallyby measuring transepithelial electrical resistance. Experimentswere performed with cultures that were between 10 and 15 daysold.

The transcytosis assay was initiated by adding BoNT or HC₅₀to the upper chamber. Transport of these molecules was monitoredfor 18 to 20 h by collecting all of the medium from the bottomchamber. An aliquot (0.5 ml) of each sample was filtered througha Sephadex G-25 column, and 0.5-ml fractions were collected.The amount of polypeptide that crossed epithelial monolayerswas determined in various ways, as described in Results.

Neuromuscular transmission. Mouse phrenic nerve-hemidiaphragm preparations were excisedand placed in tissue baths to assay the toxicity of BoNT inbiological specimens (15). The tissues were suspended in physiologicalbuffer that was aerated with 95% O₂ and 5% CO₂ (33). Phrenicnerves were stimulated continuously (0.2 Hz; 0.1- to 0.3-mspulses), and muscle twitch was recorded. Toxin-induced paralysiswas defined as a 90% reduction in the muscle twitch responseto neurogenic stimulation.

Vaccination protocol. Animals (18- to 20-g female BALB/c mice; Charles River Laboratories,Wilmington, MA) were immunized by the intranasal (i.n.) routeor by the intramuscular (i.m.) route. For the former route,individual antigens or combinations of antigens (20 µgeach) were administered by a single application of 20 µlof a phosphate-buffered saline solution (pH 7.4) to the naresof mice. For the latter route, antigens (5 or 20 µg) wereadministered in a single bolus (50 µl) of a phosphate-bufferedsaline solution. In both cases, animals received a prime doseat zero time and booster doses on days 14 and 28.

In some experiments, antigen was admixed with an adjuvant priorto administration. Two mucosal adjuvants (1% [wt/vol] chitosanand 5% [wt/vol] vitamin E TPGS) and one parenteral adjuvant(0.2% [wt/vol] alum) were tested.

In addition to the traditional modes of vaccine administration(e.g., exclusively i.n. or exclusively i.m.), one mixed modeof administration was tested. This involved an initial or primedose administered by the injection route and two subsequentbooster doses administered by the mucosal route. When an adjuvantwas included, alum was used for the prime dose and vitamin Ewas used for each booster dose.

In all vaccination paradigms, biological specimens (blood andserum) were collected on day 42. Within 1 to 5 days of specimencollection, animals were challenged with BoNT. Survivors weremonitored for >1 week, an amount of time that exceeds thetime necessary to detect 1 50% lethal dose (LD₅₀) (96 h).

Enzyme-linked immunosorbent assay (ELISA). Antibody titers in mouse serum were determined by standard procedures.Briefly, flat-bottom, 96-well Corning plates (Corning Incorporated,Corning, NY) were coated with the HC₅₀ domains of BoNT (300ng/well) and incubated at 4°C overnight, followed by washingwith phosphate-buffered saline containing 0.1% Tween 20 (pH7.4). The plates were blocked with 1% bovine serum albumin.Twofold serial dilutions of serum samples were added to theplates and incubated at 37°C for 60 min. ImmunoglobulinG (IgG) titers were determined using peroxidase-conjugated goatanti-mouse IgG (Sigma-Aldrich, Inc., St. Louis, MO), and IgAtiters were determined using peroxidase-conjugated goat anti-mouseIgA (Santa Cruz Biotechnology, Inc., Santa Cruz, CA). Secondaryantibodies were diluted 1:1,000 in phosphate-buffered saline.The primary and secondary antibodies were incubated for 30 minat 37°C, after which 2,2'-azinobis(3-ethylbenthiazoline-6-sulfonicacid) was added as a substrate, and the plates were incubatedfor an additional 30 min at 37°C. The end point titers werethe reciprocals of the last dilutions yielding an absorbanceat 405 nm that was greater than the control value (preimmuneserum).

Antibody titers were also determined for bronchoalveolar lavage(BAL) samples from mice. Specimens were obtained by anesthetizinganimals with pentobarbital sodium (Nembutal; 50 mg/kg, givenintraperitoneally [i.p.]). The complete lung along with thetrachea was excised, and BAL samples were collected from individualmice by internal flushing through the trachea with cold 50 mMphosphate-buffered saline (pH 7.6) containing Complete proteaseinhibitors (Roche, Indianapolis, IN). The samples collected(1.5 ml per mouse) were then centrifuged at 6,000 rpm at 4°Cfor 10 min. Supernatants were collected and stored at –4°Cfor subsequent analysis.

The levels of antigen-specific secretory IgA in BAL sampleswere determined using an ELISA kit (Bethyl, Montgomery, TX).Briefly, 96-well polystyrene plates were coated with HC₅₀ domains(100 µl, 20 µg/ml protein) in 0.05 M carbonate-bicarbonatebuffer (pH 9.6). The plates were incubated at 37°C for 1h and then overnight at 4°C. The plates were washed withbuffer (50 mM Tris, 0.14 M NaCl, 0.05% Tween 20; pH 8.0) andblocked with 200 µl of 1% bovine serum albumin (Sigma)in Tris-NaCl buffer for 2 h at 37°C. After two washes withbuffer, 100-µl portions of serially diluted BAL samples(starting at a 1:10 dilution in Tris-NaCl-Tween 20 buffer containing1% bovine serum albumin) were added to the plates, which wereincubated for 1 h at 37°C. The secretory IgA was detectedby adding 100 µl/well of a 1:5,000 dilution of peroxidase-conjugatedgoat anti-mouse IgA antibody. Color was developed by adding100 µl/well of a 1-mg/ml ortho-phenylenediamene substratesolution in sodium citrate buffer (pH 5.0) containing 2 µlof 30% H₂O₂. After incubation for 15 to 20 min at room temperature,the reaction was stopped using 50 µl of 2 N H₂SO₄. Theoptical density at 490 nm was determined using an ELISA reader(VERSA max; Molecular Devices).

Challenge with toxin. The most characteristic outcome of BoNT action is neuromuscularblockade. This outcome is easily discernible as weakness andeventual paralysis of the muscles of locomotion and the musclesof respiration. During bioassays of resistance, as well as theassociated experiments with antiserum, animals received dosesof toxin sufficient to produce paralysis of respiration anddeath within minutes (ca. 100 to 120 min). To minimize the painand suffering, animals were observed throughout the variousprotocols. When signs of neuromuscular weakness became obvious,animals were sacrificed in accordance with AAALAC guidelines(e.g., with CO₂).

Blood and organ levels of toxin. Iodinated BoNT/A was administered intravenously to mice viathe tail vein, and 30 min later specimens were obtained by retroorbitalbleeding. Experiments were performed using control animals (toxinonly) and experimental animals (toxin preincubated with antiserumfrom vaccinated animals). The goal of the experiments was todetermine the extent of toxin clearance in animals that hada circulating titer of antibody adequate to completely neutralizethe dose of toxin administered.

In addition to monitoring the levels of toxin in blood, oneset of experiments determined the extent of local toxin accumulationin tissues. Mice were anesthetized by administration of pentobarbitalsodium (50 mg/kg), after which the thorax was opened and theheart was exposed. A butterfly needle (23 gauge) was insertedinto the left ventricle, an incision was made in the right ventricle,and the body of the animal was perfused with a heparinized solutionof phosphate-buffered saline (45 to 60 ml). Six major organswere removed from the body (liver, spleen, kidney, lung, brain,and heart), and the accumulation of iodinated toxin was determined.

RESULTS

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RESULTS

BoNT/A HC₅₀ is a mucosal vaccine. In previous work, an effort has been made to identify the minimumessential domain of the BoNT molecule that retains full competenceto bind to and penetrate human gut and airway epithelial cells.To date, this work has demonstrated that HC, HC₈₈, HC₆₆, andHC₅₀ of BoNT/A all have within them the properties of a minimumessential domain (22, 23). In a parallel series of experiments,an effort has been made to identify an antigen that can actby the mucosal route (oral and/or inhalation) to evoke resistanceto homologous toxin. This work has demonstrated that a modifiedbotulinum holotoxin with point mutations in the histidine motif(15), as well as a full-length HC without modifications (27),can act as mucosal vaccines.

The current studies are a continuation of previous work on aminimum essential domain for binding and transcytosis and onan immunogenic domain that can act by the mucosal route to evokeresistance. Thus, BoNT/A HC₅₀ is a rational choice for evaluationas a potential i.n. vaccine. Mice (n = 10) were vaccinated withthis polypeptide i.n. (20 µg in 20 µl) at time zero,14 days, and 28 days. Fourteen days after the final boost, aliquotsof blood were obtained to determine the circulating levels ofantibody. The results of the ELISA, which are shown in Fig.1, demonstrate that there was a substantial IgG response anda more modest IgA response.

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FIG. 1. Immunoglobulin responses to the HC₅₀ domain of BoNT/A. The polypeptide was administered to mice (n = 10) as an i.n. vaccine. Two weeks after the second booster, the dilution titers for IgG ( ${triangleup}$ ) and for IgA ( ${square}$ ) in serum were determined. The data show that mucosal vaccination evoked circulating titers of both antibodies.

Both control animals and vaccinated animals were challengedi.p. with BoNT/A (1 x 10³ LD₅₀ in 50 µl). As expected,control animals became seriously ill within a short time (100min or less). Vaccinated animals survived the challenge, andthere was never any evidence of illness.

The addition of an adjuvant enhances the immunoglobulin response to BoNT/A HC₅₀. Mice (10 mice per group) were vaccinated with BoNT/A HC₅₀ asdescribed above in the absence or presence of an adjuvant. Asdescribed in Materials and Methods, two types of adjuvants weretested (chitosan and vitamin E). As shown in Fig. 2, both chitosanand vitamin E increased the levels of the immunoglobulin responses.The results of a quantitative comparison of the immunoglobulinresponses in the absence and presence of adjuvant are shownin Table 1.

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FIG. 2. Immunoglobulin responses to the HC₅₀ domain of BoNT/A when it was coadministered with an adjuvant. (a) The polypeptide was administered to mice (10 mice per group) as an i.n. vaccine with chitosan ( ${blacksquare}$ ) or with vitamin E (•), and the magnitudes of the IgG responses were determined. (b) The polypeptide was administered to mice (10 mice per group) as an i.n. vaccine with chitosan ( ${blacklozenge}$ ) or with vitamin E ( ${blacktriangleup}$ ), and the magnitudes of the IgA responses were determined. The adjuvants enhanced the responses to both immunoglobulins, but the effect with IgA was greater. This was probably a reflection of the fact that the response to IgA in the absence of adjuvant (see Fig. 1) was lower.

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TABLE 1. Fifty percent dilution titers of sera from mice vaccinated with BoNT/A HC₅₀

The results of the i.p. challenge experiments (1 x 10³ mouseLD₅₀ in 50 µl) were identical to those described above.Thus, control animals succumbed to the effects of toxin withinca. 100 min, but vaccinated animals never developed signs ofbotulism, even when they were monitored for an extended time(>1 week).

BoNT HC₅₀, in the absence or presence of an adjuvant, can function as an injection vaccine. Several investigators have shown that the HC₅₀ domains of tetanustoxin and BoNT can evoke immunity to the parent holotoxins (seethe introduction for references). This work typically involvedadministration of an adjuvant (alum) (see Materials and Methods)but did not typically involve measurement of circulating IgAtiters. Therefore, mice (n = 10) were vaccinated by i.m. injection(5 µg BoNT/A HC₅₀ in 50 µl) in the absence or presenceof an adjuvant (alum). Fourteen days after the second booster,aliquots of blood were obtained for determination of the immunoglobulinresponses. In addition, animals were challenged with holotoxinby the i.p. route.

In the absence of the adjuvant the HC₅₀ polypeptide evoked astrong IgG response, and in the presence of the adjuvant thisresponse was somewhat elevated (Fig. 3a). In the absence ofthe adjuvant there was a modest IgA response, but in the presenceof the adjuvant there was a strong response (Fig. 3b).

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FIG. 3. Immunoglobulin responses to the HC₅₀ domain of BoNT/A administered as an injection (i.m.) vaccine. The polypeptide was given to mice (10 mice per group) in the absence (open symbols) or in the presence (solid symbols) of an adjuvant (alum). (a) Magnitudes of IgG responses. (b) Magnitudes of IgA responses. The adjuvant enhanced the responses to both classes of immunoglobulin, and the magnitude of the enhancement was substantial for IgA.

Two types of challenge experiments were performed. Vaccinatedanimals that did not receive an adjuvant, as well as the matchedcontrols, were challenged i.p. with 1 x 10³ mouse LD₅₀ (50 µl).As described above, all control animals were seriously ill after100 min or less. All vaccinated animals survived without anysigns of illness for >1 week. Vaccinated animals that receivedthe adjuvant, as well as matched controls, were challenged i.p.with 1 x 10⁴ mouse LD₅₀ (50 µl). Again, the control animalswere clearly ill within a matter of minutes, whereas the vaccinatedanimals survived without illness for an extended time (>1week).

HC₅₀ domain of BoNT/A can function as a mixed-mode vaccine. The most rational approach for vaccine administration may notbe solely by the injection route or solely by the mucosal route.A realistic alternative may be to use a combination of the two.Therefore, mice were vaccinated by combining an initial injection(20 µg of antigen in 50 µl physiological saline,given i.m.) at time zero with two boosters (20 µg of antigenin 20 µl physiological saline, given i.n.) at 14 and at28 days. Alum was used as the adjuvant for the initial injection,and vitamin E was used as the adjuvant for the subsequent i.n.boosters.

Fourteen days after the final booster, aliquots of blood wereobtained to determine the circulating titers of IgG and IgA.As shown in Fig. 4, the mixed mode of vaccine administrationevoked substantial responses for both classes of immunoglobulin.The magnitudes of these responses were comparable to the magnitudesobserved after i.m. injection alone (Fig. 3) and after i.n.administration alone (Fig. 2).

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FIG. 4. Immunoglobulin responses to the HC₅₀ domain of BoNT/A when it was administered as a mixed-mode vaccine. The polypeptide was given to mice (n = 10) in an initial i.m. injection with alum as an adjuvant and in two subsequent i.n. boosters with vitamin E as an adjuvant. The results demonstrated that the mixed-mode vaccination paradigm elicited substantial IgG ( ${blacklozenge}$ ) and IgA (•) responses.

Vaccinated animals and control animals were challenged i.p.with the holotoxin (1 x 10³ mouse LD₅₀ in 50 µl), andthe results were consistent with the results described above.All control animals succumbed to the poison within minutes (120min or less), and all mixed-mode-vaccinated animals survivedwithout signs of illness for >1 week.

BoNT/B HC₅₀ and BoNT/E HC₅₀ can bind to and penetrate monolayers of human epithelial cells. The HC, HC₈₈, HC₆₆, and HC₅₀ domains of BoNT/A have all beenshown to cross barriers formed by immortalized human epithelialcells (T-84 and Caco-2) (1, 22, 23), as well as barriers formedby primary human epithelial cells (A. B. Maksymowych and L.L. Simpson, unpublished data). This process involves bindingof polypeptide to the apical surface, endocytosis, and transcytosis,followed by release of polypeptide on the basolateral surface.Therefore, experiments to assess the abilities of BoNT/B HC₅₀and BoNT/E HC₅₀ to cross epithelial barriers were performed.

T-84 cells were grown in a Transwell apparatus, as describedin Materials and Methods. BoNT/B holotoxin and its HC₅₀ domain,as well as BoNT/E holotoxin and its HC₅₀ domain, were addedto the apical surface of epithelial cells, and the accumulationof these polypeptides on the basal side of cells was monitored.Parallel experiments were done with BoNT/A holotoxin and itsHC₅₀ domain for comparison. The results (Fig. 5) revealed thatthe HC₅₀ subunit of each serotype and the homologous neurotoxinat an equimolar concentration were comparable in terms of theability to penetrate monolayers of human epithelial cells. Theseresults make it clear that the minimum essential domain fortranscytosis of each serotype is localized in the HC₅₀ domain.

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FIG. 5. Transcytosis of BoNT/A HC₅₀ (gel A), BoNT/B HC₅₀ (gel B), and BoNT/E HC₅₀ (gel E). Equimolar concentrations of the three polypeptides (1 x 10^–8 M) or the corresponding parent toxins were added to the upper wells of T-84 monolayers in a Transwell apparatus, and the accumulation in the lower wells was assayed by Western blotting. Lane 1, holotoxin added; lane 2, HC₅₀ domains added. Note that the levels of transcytosis for each holotoxin and its HC₅₀ domain were comparable.

Transcytosis in the presence of multiple serotypes. Research on multivalent vaccines appears to reflect two expectations:(i) vaccination should evoke resistance to multiple serotypesof toxin, but (ii) protection is needed for only one serotypeat a time. Although it is appropriate to expect that a multivalentvaccine will provide protection against several serotypes, itmay not be appropriate to expect that a bioterrorism or biologicalwarfare incident will involve only one serotype at a time. Therefore,experiments were performed to monitor transcytosis of multipleserotype polypeptides given together.

Figure 6 shows the results of experiments in which the threeserotypes of greatest concern to human health (serotypes A,B, and E) were added simultaneously to the apical surfaces ofepithelial cells. As this figure shows, the transcytosis ofeach HC₅₀ domain remained constant, regardless of whether thedomain was added alone or with other domains.

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FIG. 6. Individual and combined rates of transcytosis of BoNT/A HC₅₀ (gel A), BoNT/B HC₅₀ (gel B), and BoNT/E HC₅₀ (gel E). Equimolar concentrations of the three polypeptides (1 x 10^–8 M) were added to the apical surfaces of T-84 monolayers, and the accumulation of the polypeptides on the basal side of the cells was assayed by Western blotting. Lane 1, HC₅₀ domain added alone; lane 2, three HC₅₀ domains added together. The results indicate that simultaneous addition of HC₅₀ domains did not inhibit or reduce the extent of transcytosis of any of the domains.

Multiple HC₅₀ domains can be administered simultaneously to create a multivalent mucosal vaccine. The HC₅₀ domains of BoNT/A, BoNT/B, and BoNT/E were administeredtogether (20 µg each) in the presence of vitamin E asan i.n. vaccine. A total of 20 mice were vaccinated. At theend of the protocol, animals were randomly assigned to two groupscontaining 10 mice each that were challenged by the i.n. routeor the i.p. route.

The ELISA data indicated that all three antigens evoked a substantialIgG response (Fig. 7a) and a substantial IgA response (Fig.7b). These data provide further support for the premise thatcombined administration of three antigens does not lead to inhibitionof absorption of any one of the antigens. Also, as a comparisonof Fig. 7 with Fig. 2 shows, the magnitude of the immunoglobulinresponse for an individual antigen in the trivalent formulation(e.g., BoNT/A HC₅₀) was in the same range as the magnitude ofthe immunoglobulin response for the individual antigen in amonovalent formulation. Thus, simultaneous administration ofmultiple antigens did not result in immune suppression.

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FIG. 7. Immunoglobulin responses to i.n. administration of a trivalent vaccine. The HC₅₀ domains of three serotypes were administered as described in the text, and the magnitudes of the IgG responses (a) and IgA responses (b) were determined. The results indicate that all three antigens evoked substantial responses. ${blacktriangleup}$ , BoNT/A; ${blacksquare}$ , BoNT/B; •, BoNT/E.

Mice were challenged by two routes with BoNT, i.p. (n = 10)and i.n. (n = 10). For each route of administration, half ofthe mice received 1 x 10³ mouse LD₅₀ (n = 5), and the otherhalf received 1 x 10⁴ mouse LD₅₀ (n = 5). In addition, animalswere challenged simultaneously with all three serotypes (serotypesA, B, and E), and thus the cumulative dose was either 3 x 10³LD₅₀ or 3 x 10⁴ LD₅₀. Control animals that received either 3x 10³ or 3 x 10⁴ LD₅₀ became seriously ill within minutes. Bycontrast, all vaccinated animals survived at least 1 week, regardlessof the dose or the route of challenge. This means that not onlywere animals protected against a substantial monovalent challenge,but they were also protected against a substantial polyvalentchallenge.

HC₅₀ domains of BoNT/A, BoNT/B, and BoNT/E can be administered simultaneously to create a multivalent mixed-mode vaccine. Mice were vaccinated by combining an initial injection of antigenswith two subsequent i.n. administrations of antigens. For theinitial i.m. injection, all three antigens (20 µg each)were mixed with alum prior to administration. For the subsequentboosters, all three antigens (20 µg each) were mixed withvitamin E prior to administration. Fourteen days after the lastbooster, aliquots of blood were obtained to determine the circulatingtiters of IgG and IgA. At the same time, animals were randomlyassigned to two groups (10 mice per group) for inhalation challengeand i.p. challenge.

The results obtained with the multivalent mixed-mode vaccine(Fig. 8a and b) were similar to the results obtained with themultivalent mucosal vaccine (Fig. 7a and b). Thus, all threeof the HC₅₀ domains evoked substantial IgG and IgA responses.

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FIG. 8. Immunoglobulin responses to mixed-mode administration of a trivalent vaccine. The HC₅₀ domains of three serotypes were administered as described in the text, and the magnitudes of the IgG responses (a) and IgA responses (b) were determined. The results clearly show that all three antigens evoked substantial responses. ${blacktriangleup}$ , BoNT/A; ${blacksquare}$ , BoNT/B; •, BoNT/E.

Mice were challenged with toxin by two routes of administration,as described above. As before, animals received a combinationchallenge in which serotype A, B, and E toxins were given together(1 x 10⁴ mouse LD₅₀ each). Similar to the results obtained withmucosal vaccination, the results obtained with mixed-mode vaccinationrevealed that all control animals quickly became ill (<80min), whereas the vaccinated animals survived without signsof illness (>1 week).

Antibodies can associate with toxin to block binding and transcytosis across epithelial cells. There are several possible mechanisms by which antibodies directedagainst BoNT can diminish or eliminate the lethal effects ofthe molecule. One obvious possibility is that these antibodiesbind at or near the toxin domain responsible for associationwith epithelial cells, which in turn would block absorptionof the toxin molecule. This possibility was assessed by usingBoNT/A as a prototype.

There are two potential sources of antibody that could act toblock toxin absorption: (i) secretory IgA generated in the lumenof the airway and (ii) circulating immunoglobulin that is transportedinto the lumen. Experiments described above demonstrated thatmucosal vaccination led to a robust circulating IgA response.It was necessary to show that an identical vaccination paradigmwould elicit a strong secretory IgA response.

Mice (n = 5) were vaccinated i.n. using BoNT/A HC₅₀ as a prototype.As described above, there was an initial administration, followedby two boosters (20 µg per administration), each of whichwas given with vitamin E as an adjuvant. Two weeks after thefinal boost, animals were sacrificed, and BAL samples were obtained.The ELISA titers for antigen-specific secretory IgA revealedthat there was a substantial response (Fig. 9).

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FIG. 9. Mucosal antibody responses to vaccination with BoNT/A HC₅₀. The antigen was administered as an i.n. vaccine in combination with vitamin E, and the magnitude of the secretory IgA response was determined ( ${blacksquare}$ ). The data show that there was a substantial response. A matched group of animals was vaccinated by the i.m. route (antigen plus alum), and again the responses were measured. As expected, parenteral administration of the HC₅₀ domain did not evoke a significant mucosal antibody response (•). O.D., optical density.

Secretory IgA (0.1 ml of lavage fluid) or a combination of circulatingIgG and IgA (0.1 ml of antiserum) was obtained from vaccinatedanimals and incubated with BoNT/A (1 x 10^–8 M). After30 min, the mixtures were added to the apical surfaces of T-84monolayers in a Transwell apparatus. Medium in the basal chamberwas collected and handled as described in Materials and Methods.Aliquots were used for Western blot analyses, as shown in Fig.10. As expected, untreated toxin was able to bind to and penetrateepithelial barriers, whereas antibody-pretreated toxin had virtuallyno ability to cross these barriers.

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FIG. 10. Effect of neutralizing antibodies on binding and transcytosis of BoNT/A. Toxin (1 x 10^–8 M) was incubated alone or with BAL samples (0.1 ml) or antiserum (0.1 ml) obtained from mice that had been immunized with BoNT/A HC₅₀ vaccine. After incubation (1 h), the solutions were added to apical wells containing monolayers of epithelial cells, and transcytosis was monitored. The results demonstrated that untreated toxin crossed epithelial barriers (lane 1) but antibody-pretreated toxin did not cross these barriers (lane 2, antiserum; lane 3, BAL sample).

Antiserum from immunized animals promotes toxin clearance from the general circulation and enhances accumulation in the liver and spleen. Control mice (three or more mice per group) received a singleintravenous bolus of ¹²⁵I-labeled BoNT/A, and 30 min after thisaliquots of blood were collected and assayed to determine thepresence of toxin. The total duration of the experiment was(i) less than the half-time for toxin elimination from the generalcirculation and (ii) less than the time necessary for significantmetabolic transformation of toxin in blood (29). Experimentalanimals received an equivalent dose of toxin that had been preincubatedwith a neutralizing dose of antiserum collected from animalsthat received trivalent vaccine (0.01 ml; 30 min of incubation;room temperature). The data revealed that neutralizing antibodygreatly increased the rate of toxin clearance from the blood(Fig. 11). The toxin levels in the blood and serum of experimentalanimals were approximately 1 order of magnitude less than thosein control animals.

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FIG. 11. Effect of neutralizing antibodies on the circulating levels of BoNT/A. ¹²⁵I-labeled BoNT/A was incubated alone (open bars) or with antiserum (cross-hatched bars) from animals that had been immunized with trivalent mucosal vaccine (0.01 ml; 30 min; room temperature). Mice were injected intravenously with the material, and 30 min later samples of blood were collected. The results demonstrated that neutralizing antibodies resulted in a dramatic reduction in blood and serum levels of toxin.

The BoNT molecule (ca. 150 kDa), especially when the toxin moleculeis decorated with antibody, is too large to undergo significantrenal clearance. On the other hand, hepatic uptake and splenicuptake are likely mechanisms for clearance of an antigen-antibodycomplex. Therefore, ¹²⁵I-labeled BoNT/A was injected into controlanimals and vaccinated animals as described above, and 30 minlater the animals were anesthetized and perfused. The liversand spleens were subsequently excised and assayed to determinethe accumulation of toxin (Fig. 12a). In control animals thepercentage of the total dose administered that could be recoveredin the liver was 4.43%, and in experimental animals the percentagethat could be recovered in the liver was 48.3%; the differencewas quantitatively (ca. 11-fold) and statistically (P < 0.001)significant. Similarly, the percentage of the total dose administeredthat could be recovered in the spleens of control animals was0.3%, whereas the percentage that could be recovered in thespleens of experimental animals was 3.6%; the difference wasalso quantitatively (12-fold) and statistically (P < 0.001)significant. The levels of labeled BoNT/A were also determinedfor four other tissues (kidney, lung, heart, and brain). Asshown in Fig. 12b, neutralizing antiserum did not result inenhanced accumulation of toxin in any of these tissues.

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FIG. 12. Effects of neutralizing antibodies on the accumulation of toxin in various tissues. ¹²⁵I-labeled BoNT/A was incubated alone (open bars) or with antiserum (cross-hatched bars) and administered as described in the legend to Fig. 11. After 30 min, animals were anesthetized and perfused for subsequent removal of organs. The data show that pretreatment of toxin with neutralizing antibodies resulted in marked increases in the accumulation in livers and spleens (a). Antibody pretreatment did not increase the accumulation in tissues that are ordinarily not related to immune processing (b).

Antibodies from immunized animals can block the neuroparalytic actions of BoNT. The HC₅₀ domain of BoNT is known to possess the molecular determinantsthat govern toxin binding to neuronal membranes (31). This raisesthe possibility that at least one of the clonal antibodies inthe serum of immunized animals could associate with the toxinin a way that would block toxin binding and/or block toxin internalization.To test the possibility that antiserum directed against HC₅₀could antagonize toxin-induced paralysis, unlabeled BoNT/A (1x 10^–8 M) was incubated without or with mouse trivalentantiserum (0.1 ml; 30 min; room temperature). The mixtures weresubsequently diluted and added to murine phrenic nerve-hemidiaphragmpreparations (four preparations per group) to obtain a finaltoxin concentration of 1 x 10^–11 M. The results (Fig.13) demonstrated that the paralysis times for control tissueswere ca. 100 to 140 min. Tissues that were treated with toxinthat had been preincubated with immune serum showed no onsetof neuromuscular blockade during a 100- to 140-min period.

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FIG. 13. Effects of neutralizing antibodies on the neuromuscular blocking properties of BoNT/A. Toxin (1 x 10^–8 M) was incubated alone or with antiserum from animals that had been immunized with trivalent vaccine (0.1 ml; 30 min; room temperature). The mixtures were then added to phrenic nerve-hemidiaphragm preparations (four preparations per group) to obtain a final toxin concentration of 1 x 10^–11 M. Untreated toxin caused paralysis of transmission (i.e., a 90% reduction in twitch amplitude) within 100 to 140 min ( ${blacklozenge}$ ). In the same time frame, antibody-pretreated toxin did not paralyze transmission ( ${blacktriangleup}$ ). An equivalent experiment was done in which toxin was preincubated with preimmune serum (inset). This pretreatment did not significantly affect the potency of the toxin.

DISCUSSION

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DISCUSSION

BoNT is the etiologic agent that causes the disease botulism.This disease can occur naturally, but it can also be a resultof bioterrorism or biological warfare. The number of outbreaksof naturally occurring botulism and the number of cases peroutbreak are too low to be a driving force in the developmentof a vaccine. On the other hand, concern about the potentialuse of the toxin in acts of bioterrorism or biological warfarehas served as a powerful motivation to develop a vaccine.

Although it is understandable that there is a sense of urgencyconcerning the need for a vaccine, this should not obscure thefact that development of the final product should be governedby the principles of rational vaccine design. Two of the mostimportant areas in which these principles should apply are (i)the selection of an antigen and (ii) the selection of a routeof administration for that antigen.

Selection of an antigen. In historical attempts to develop a botulinum vaccine workersfocused on chemical toxoids (i.e., formalin inactivation ofimpure toxin preparations), whereas in more recent attemptsworkers have focused on recombinant toxoids (6). Vaccine candidatesin the latter category have included the holotoxin with pointmutations to eliminate catalytic activity (15) and various subunitpolypeptides. The subunit vaccine that has emerged as the favoredcandidate is HC₅₀ (also known as HC_C and fragment C [6]).

There are a variety of reasons to believe that HC₅₀ is a rationalchoice. To begin with, it is modeled after an analogous polypeptidefrom tetanus toxin that has been shown to be a highly efficaciousvaccine against the parent molecule (10, 13, 20). In addition,the HC₅₀ domain of BoNT has a large number of epitopes. In fact,there are more epitopes in this polypeptide than there are inthe rest of the toxin molecule combined (7). This suggests that(i) this polypeptide should evoke a robust polyclonal responseagainst the native toxin and (ii) increasing the length of thepolypeptide (HC₆₆, HC₈₈, etc.) may not lead to increases inresistance that would be clinically significant.

These observations, combined with reports that HC₅₀ is an efficientimmunogen in laboratory animal studies, strongly support thepremise that a rational vaccine candidate has been identified.However, there is even more evidence that supports the use ofthis subunit vaccine. As previously reported, the HC₅₀ domainof BoNT/A possesses all of the structural information necessaryfor binding to and penetration of gut and airway epithelialbarriers (23). This means that the BoNT/A HC₅₀ domain can simultaneouslyserve as a delivery device and as an immunogen in a mucosalbotulinum vaccine.

Selection of a route of administration. There are at least two powerful reasons to seek a mucosal ("needle-free")vaccine against BoNT. One of these reasons is broad and is relatedto the discipline of immunology; the second is highly specificand is related to the mechanism of BoNT action. In broad terms,there is wide recognition in the field of immunology that injectablevaccines should give way to needle-free vaccines (24). Indeed,every major health care entity that supports vaccine research,including the National Institutes of Health, the World HealthOrganization, and the Bill and Melinda Gates Foundation, hasencouraged efforts to develop needle-free approaches. The reasonsfor this are compelling, and they include (i) the reduced needfor, and cost of, health care personnel; (ii) the eliminationof accidental needle sticks and their potential contributionto blood-borne diseases; (iii) the reduced burden of storingmedical waste; and (iv) the elimination of the potential forenvironmental contamination. There is no reason why a vaccineagainst BoNT should be exempt from these considerations.

The second reason for pursuing a mucosal vaccine is relatedspecifically to the mechanism of toxin action. The majorityof all reported cases of naturally occurring botulism are dueto mucosal exposure, and it is anticipated that most if notall cases of a potential bioterrorism incident or biologicalwarfare incident would also be due to mucosal exposure. Thisis a strong argument against an injection vaccine and in favorof a mucosal vaccine, because the latter has the potential toact in the lumen of the gut and airway to evoke the productionof antibodies (i.e., secretory IgA) that could block absorptionof the toxin. An injection vaccine does not have this benefit.

To return to a point discussed above, the HC₅₀ domain may bean ideal choice as a mucosal vaccine, because this moleculehas the properties of both an immunogen and a delivery device.These dual functions represent a major advance over currentefforts to develop a mucosal vaccine. For example, use of therecombinant polypeptide obviates the need for chemically inducedtoxoids (16). Similarly, the inherent ability of the polypeptideto penetrate epithelial barriers and evoke an immune responsecircumvents the need for ancillary devices, such as a virus(19).

Identification of a mucosal vaccine. The data presented in this paper demonstrate that the HC₅₀ domainis an effective inhalation vaccine. In an initial series ofexperiments utilizing BoNT/A as a prototype, the HC₅₀ domainevoked a significant IgG response and a more modest IgA response.It also provided resistance against a challenge dose of BoNT.

One well-recognized approach for enhancing an immunoglobulinresponse is to combine the antigen of interest with an adjuvant.This concept is technically sound, but it presents a difficultyin the context of trying to develop a vaccine that can be licensedfor human use. Almost all agents that have been examined asmucosal adjuvants, such as the cholera toxin B subunit, arenot approved for clinical use. One potential solution to thisproblem is to select an agent for which there are a minimumof regulatory obstacles. Therefore, we used vaccination protocolsin which two natural products (chitosan and vitamin E) wereevaluated to determine their utility as adjuvants (2, 8, 25,36). Administration of the HC₅₀ domain of BoNT/A simultaneouslywith chitosan or with vitamin E (Fig. 2) had the intended effectof boosting the levels of the immunoglobulin responses.

Trivalent vaccine against botulism. BoNT serotypes A, B, and E are the serotypes most often implicatedin human illness. This suggests that the greatest need is fora multivalent preparation that provides protection against allthree of these serotypes. This goal appears to be attainable,because (i) the HC₅₀ domains of these serotypes are able topenetrate epithelial barriers (Fig. 5) and (ii) the same domainsare immunogens that evoke protection against the correspondingparent toxins (Fig. 7). This is an encouraging basis on whichto seek a trivalent vaccine, but at the same time it leavesthree important questions unanswered. First, can HC₅₀ domainsgiven in combination penetrate epithelial barriers as well asHC₅₀ domains given individually? Second, can HC₅₀ domains givenin combination evoke an immune response comparable to that evokedby peptides that are given individually? Third, can a trivalentvaccine evoke resistance of a magnitude sufficient to affordprotection against a combination challenge?

The question about membrane penetration has been addressed usingmonolayers of human epithelial cells. These cells have provento be useful in studies in which the kinetics of BoNT/A bindingand transcytosis have been analyzed, as well as in studies inwhich BoNT/A molecules crossing epithelial barriers have beenvisualized (1, 22). This work was extended here to include theHC₅₀ domains of BoNT/B and BoNT/E. In the context of vaccineresearch, the important observation resulting from these experimentsis that each HC₅₀ domain retained its characteristic abilityto cross epithelial barriers, even when it was added along withother such domains (Fig. 6). This is predictive evidence thatthe three domains could be administered as a trivalent vaccine.

The question about immunogenicity was answered by coadministrationof the three HC₅₀ domains by two regimens, mucosal vaccinationalone and an initial injection followed by mucosal boosters.Interestingly, these two approaches produced very similar outcomes.Both resulted in substantial IgG and IgA responses. Using BoNT/AHC₅₀ as an indicator, one can deduce that the magnitudes ofthe immunoglobulin responses for monovalent vaccination (Fig.2) and trivalent vaccination (Fig. 7 and 8) were not significantlydifferent. The data indicate that simultaneous vaccination withthree antigens did not compromise the ability of the immunesystem to respond to any one of the antigens.

Finally, the question about induced resistance was answeredby challenging animals with a mixture of the three holotoxins.Equal doses of the holotoxins were mixed to produce final dosesof 3 x 10³ or 3 x 10⁴ LD₅₀. Regardless of whether animals receivedthe trivalent vaccine by mucosal administration or by mixed-modeadministration, all test animals survived. These data demonstratethat a trivalent vaccine that acts by the mucosal route hasbeen identified.

Mechanisms of resistance. There are a number of mechanisms by which immunoglobulin-mediatedresistance could decrease toxicity. The sequence of events thatunderlies toxin action suggests that an ideal vaccine candidateshould possess at least three of these mechanisms. A clonalpopulation should possess within it antibodies that act (i)in the lumen of the gut or airway to block toxin absorption,(ii) in the general circulation to enhance clearance from theblood and accumulation in the liver and spleen, and (iii) atthe neuromuscular junction to antagonize blockade of exocytosis.The clonal population evoked by trivalent vaccination had init antibodies that could be shown to act at all three sites.

When tested with a model system for binding and transcytosisin human epithelial cells, both BAL samples (secretory IgA)and antiserum (circulating IgG and IgA) from animals that hadreceived HC₅₀ as a vaccine blocked the ability of BoNT to crossepithelial barriers (Fig. 10). The results indicated that thelevel of inhibition of binding and transcytosis was greaterthan 99%. If this outcome were a close approximation of eventsin vivo, it would mean that mucosal immunity in the lumen ofthe gut or airway can be an important factor contributing toresistance.

In related experiments, the pharmacokinetics of BoNT/A eliminationwere studied using control and experimental animals. The experimentswere conducted over a period of time (30 min) during which thefractional distribution of toxin out of the circulation andinto peripheral cholinergic nerve endings of control animalshad not yet produced serious neuromuscular blockade (29). Theseexperiments demonstrated that a neutralizing dose of trivalentantiserum resulted in a rapid and dramatic increase in the rateof clearance of BoNT/A from the blood (Fig. 11). This phenomenonwas accompanied by an equally dramatic accumulation of toxinin the liver and spleen (Fig. 12). It is very likely that hepaticand splenic accumulation is a prelude to metabolic degradationand eventual systemic elimination of toxin fragments.

The final mechanism by which an ideal vaccine candidate couldevoke immunoresistance is antagonism of toxin-induced neuromuscularblockade (31, 32). The possibility that this occurs was testedby using an isolated phrenic nerve-hemidiaphragm preparation,which means that mechanisms such as inhibition of luminal absorptionand enhancement of systemic clearance could not have contributedto the outcome. These experiments clearly demonstrated thatanti-HC₅₀ antibodies antagonized toxin action in isolated neuromuscularpreparations.

Concept of a universal vaccine. The discipline of immunology typically uses the term "universalvaccine" to convey one of two concepts: (i) a single antigencan be administered by all of the routes that are commonly usedfor vaccines or (ii) a single antigen can be used to evoke resistanceto multiple strains, serotypes, or other variants of a pathogen.The data suggest that the HC₅₀ domain is close to satisfyingthe expectation for a single antigen that is active when itis administered by multiples routes.

Numerous investigators have contributed to the observation thatthe HC₅₀ domain of all BoNT serotypes can be administered byinjection to evoke an immune response. It has also been shownthat the inactive holotoxin, the entire HC, and the HC₅₀ domainsof several serotypes are active when they are administered bythe oral and/or inhalation routes (see the Introduction). Inaddition, a single paradigm that incorporates both injectionand nasal routes of administration can evoke robust immunity(this study).

It is customary to divide routes of potential vaccine administrationinto three broad categories: injection, mucosal, and cutaneous(24). As mentioned above, the HC₅₀ domain of BoNT is alreadyknown to be effective as an injection vaccine, a mucosal vaccine,and a mixed-mode vaccine. To date, the HC₅₀ domain has not beenshown to be a cutaneous vaccine. In fact, this domain by itselfdoes not penetrate the stratum corneum (unpublished data). However,there have been several recent and notable advances in the transcutaneousdelivery of antigens. Therefore, vaccination protocols aimedat transcutaneous delivery of HC₅₀ are currently being investigated,in the hope of establishing that HC₅₀ is a true universal vaccine.

ACKNOWLEDGMENTS

This work was supported in part by National Institutes of Healthcontract N01-AI30028, by National Institutes of Health grantsNS22153 and GM57342, and by a sponsored research agreement withDOR Biopharma.

FOOTNOTES

* Corresponding author. Mailing address: Room 314-JAH, Jefferson Medical College, 1020 Locust Street, Philadelphia, PA 19107. Phone: (215) 955-8381. Fax: (215) 955-2169. E-mail: Lance.Simpson{at}jefferson.edu

Published ahead of print on 19 March 2007.

Editor: D. L. Burns

E.R. and F.H.A.-S. contributed equally to this study.

REFERENCES

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